{"@context":{"@language":"en","Affiliation":"http:\/\/vivoweb.org\/ontology\/core#departmentOrSchool","AggregatedSourceRepository":"http:\/\/www.europeana.eu\/schemas\/edm\/dataProvider","Campus":"https:\/\/open.library.ubc.ca\/terms#degreeCampus","Creator":"http:\/\/purl.org\/dc\/terms\/creator","DateAvailable":"http:\/\/purl.org\/dc\/terms\/issued","DateIssued":"http:\/\/purl.org\/dc\/terms\/issued","Degree":"http:\/\/vivoweb.org\/ontology\/core#relatedDegree","DegreeGrantor":"https:\/\/open.library.ubc.ca\/terms#degreeGrantor","Description":"http:\/\/purl.org\/dc\/terms\/description","DigitalResourceOriginalRecord":"http:\/\/www.europeana.eu\/schemas\/edm\/aggregatedCHO","FullText":"http:\/\/www.w3.org\/2009\/08\/skos-reference\/skos.html#note","Genre":"http:\/\/www.europeana.eu\/schemas\/edm\/hasType","IsShownAt":"http:\/\/www.europeana.eu\/schemas\/edm\/isShownAt","Language":"http:\/\/purl.org\/dc\/terms\/language","Program":"https:\/\/open.library.ubc.ca\/terms#degreeDiscipline","Provider":"http:\/\/www.europeana.eu\/schemas\/edm\/provider","Publisher":"http:\/\/purl.org\/dc\/terms\/publisher","Rights":"http:\/\/purl.org\/dc\/terms\/rights","ScholarlyLevel":"https:\/\/open.library.ubc.ca\/terms#scholarLevel","Title":"http:\/\/purl.org\/dc\/terms\/title","Type":"http:\/\/purl.org\/dc\/terms\/type","URI":"https:\/\/open.library.ubc.ca\/terms#identifierURI","SortDate":"http:\/\/purl.org\/dc\/terms\/date"},"Affiliation":[{"@value":"Applied Science, Faculty of","@language":"en"},{"@value":"Chemical and Biological Engineering, Department of","@language":"en"}],"AggregatedSourceRepository":[{"@value":"DSpace","@language":"en"}],"Campus":[{"@value":"UBCV","@language":"en"}],"Creator":[{"@value":"Dai, Jianjun","@language":"en"}],"DateAvailable":[{"@value":"2011-02-14T20:08:12Z","@language":"en"}],"DateIssued":[{"@value":"2007","@language":"en"}],"Degree":[{"@value":"Doctor of Philosophy - PhD","@language":"en"}],"DegreeGrantor":[{"@value":"University of British Columbia","@language":"en"}],"Description":[{"@value":"Successful feeding is critical to biomass utilization processes, but is difficult due to the heterogeneity, peculiar physical characteristics and moisture content of the biomass particles. The objectives of this project were to define what limits screw feeding in terms of the mechanisms of blockage and to examine the effects of key properties like mean particle size, size distribution, shape, moisture content (10-60%), density and compressibility on screw feeding of biomass. Wood pellets, ground wood pellets, sawdust, hog fuel, ground hog fuel and wood shavings were used in a screw feeder\/lock hopper system previously employed to feed biomass to a circulating fluidized-bed gasifier. Three hopper levels (0.3, 0.45, 0.6 m), five casing configurations (common straight, tapered and extended sections) and two screws with different configurations were investigated. Experimental results showed that large particles, wide size distributions, irregular shapes, rough particle surfaces, large bulk densities and high moisture contents, as well as higher hopper levels and special casing configurations, generally led to large torque requirements for screw feeding. The \"choke section\" and seal plug play important roles in determining torque requirements for biomass fuels. The unique characteristics of biomass and system requirements of biomass processes create special challenges for biomass feeding. A fundamental study on a Particulate Flow Loop was also conducted to investigate the probability of blockage\/bridging as a function of particle size, shape, density, hardness, flexibility and compressibility. Experimental results showed that large particle size, irregular shape, and large ratio of particle to constriction dimension can all increase the blockage tendency. Reynolds number based on water mean velocity and hydraulic diameter of duct, constriction dimensions and shape, particle density, particle hardness, flexibility and compressibility are also important factors affecting blockage probability. The present study developed a new theoretical model with consideration of compression, aimed to understand the mechanism of biomass screw feeding and to predict torque requirements to turn the screw feeder instead of being blocked. Boundaries around the bulk material within a pocket were considered, and forces acting on these surfaces were analyzed. Two parameters are employed in this model to describe stress in screw pockets in the hopper and to analyze compression in the choke section. The model extends previous models by considering effects of all boundaries on torque, and allowing for compression in the choke section. The torque requirement is approximately proportional to the vertical stress exerted on the hopper outlet by the bulk material in the hopper and to the third power of the screw diameter based on the theoretical analysis. This indicates that large screws and high feed loads require large torque. The starting torque and volumetric efficiency of screw feeding with consideration of compression in the choke section were also estimated with reasonable success based on this model. Special casing configurations (e.g. tapered and extended sections) are also considered in the model, leading to better understanding of blockage in the choke section and approximate prediction of torque requirements for screw feeders of special casing configurations. The choke section length, screw and casing configurations were closely related to plug formation and plug sealing of the reactor, while also affecting the torque requirements. The new theoretical model successfully predicted torque requirements and efficiencies for both compressible and incompressible materials for certain screw configuration. The present experiments and model are expected to be very useful for biomass utilization.","@language":"en"}],"DigitalResourceOriginalRecord":[{"@value":"https:\/\/circle.library.ubc.ca\/rest\/handle\/2429\/31282?expand=metadata","@language":"en"}],"FullText":[{"@value":"BIOMASS GRANULAR FEEDING FOR GASIFICATION AND COMBUSTION by Jianjun Dai B. A. Sc. Tianjin University, Tianjin, China, 1993 M . A . Sc. Tianjin University, Tianjin, China, 1996 A THESIS SUBMITTED IN PARTIAL FULFILMENT OF THE REQUIREMENTS FOR THE DEGREE OF DOCTOR OF PHILOSOPHY in THE F A C U L T Y OF G R A D U A T E STUDIES (Chemical and Biological Engineering) THE UNIVERSITY OF BRITISH C O L U M B I A May 2007 \u00a9Jianjun Dai, 2007 11 ABSTRACT Successful feeding is critical to biomass utilization processes, but is difficult due to the heterogeneity, peculiar physical characteristics and moisture content of the biomass particles. The objectives of this project were to define what limits screw feeding in terms of the mechanisms of blockage and to examine the effects of key properties like mean particle size, size distribution, shape, moisture content (10-60%), density and compressibility on screw feeding of biomass. Wood pellets, ground wood pellets, sawdust, hog fuel, ground hog fuel and wood shavings were used in a screw feeder\/lock hopper system previously employed to feed biomass to a circulating fluidized-bed gasifier. Three hopper levels (0.3, 0.45, 0.6 m), five casing configurations (common straight, tapered and extended sections) and two screws with different configurations were investigated. Experimental results showed that large particles, wide size distributions, irregular shapes, rough particle surfaces, large bulk densities and high moisture contents, as well as higher hopper levels and special casing configurations, generally led to large torque requirements for screw feeding. The \"choke section\" and seal plug play important roles in determining torque requirements for biomass fuels. The unique characteristics of biomass and system requirements of biomass processes create special challenges for biomass feeding. A fundamental study on a Particulate Flow Loop was also conducted to investigate the probability of blockage\/bridging as a function of particle size, shape, density, hardness, flexibility and compressibility. Experimental results showed that large particle size, irregular shape, and large ratio of particle to constriction dimension can all increase the blockage tendency. Reynolds number based on water mean velocity and hydraulic diameter of duct, in constriction dimensions and shape, .particle density, particle hardness, flexibility and compressibility are also important factors affecting blockage probability. The present study developed a new theoretical model with consideration of compression, aimed to understand the mechanism of biomass screw feeding and to predict torque requirements to turn the screw feeder instead of being blocked. Boundaries around the bulk material within a pocket were considered, and forces acting on these surfaces were analyzed. Two parameters are employed in this model to describe stress in screw pockets in the hopper and to analyze compression in the choke section. The model extends previous models by considering effects of all boundaries on torque, and allowing for compression in the choke section. The torque requirement is approximately proportional to the vertical stress exerted on the hopper outlet by the bulk material in the hopper and to the third power of the screw diameter based on the theoretical analysis. This indicates that large screws and high feed loads require large torque. The starting torque and volumetric efficiency of screw feeding with consideration of compression in the choke section were also estimated with reasonable success based on this model. Special casing configurations (e.g. tapered and extended sections) are also considered in the model, leading to better understanding of blockage in the choke section and approximate prediction of torque requirements for screw feeders of special casing configurations. The choke section length, screw and casing configurations were closely related to plug formation and plug sealing of the reactor, while also affecting the torque requirements. The new theoretical model successfully predicted torque requirements and efficiencies for both compressible and incompressible materials for certain screw configuration. The present experiments and model are expected to be very useful for biomass utilization. IV TABLE OF CONTENTS T A B L E OF CONTENTS iv LIST OF TABLES vii LIST OF FIGURES ix A C K N O W L E D G M E N T xv CHAPTER 1. INTRODUCTION 1 1.1 Biomass and Biomass Feeding 1 1.2 Scope of This Study 4 CHAPTER 2. B A C K G R O U N D 6 2.1 Biomass Properties 6 2.1.1 Physical properties 6 2.1.2 Flow properties 13 2.2 Biomass Feeding Systems 15 2.2.1 Review of biomass feeding 15 2.2.2 Hopper or locker hopper systems 24 2.2.3 Screw feeders 31 2.3 Some Related Problems about Biomass Properties and Feeding 42 2.3.1 Effects of biomass physical properties on feeding 42 2.3.2 Effects of feeding rate and feeding fluctuations 42 2.3.3 Effects of feeding positions 43 2.3.4 Multi-point feeding and spare feeders 44 2.3.5 Pressurization in feeding system 44 2.3.6 Feeding for co-combustion and co-gasification systems 45 2.4 Summary and Objectives for This Project '.45 CHAPTER 3. PARTICULATE FLOW LOOP 48 3.1 Introduction 48 3.1.1 Flow in a rectangular duct 48 3.1.2 Flow past obstacles and through nozzles 51 V 3.1.3 Saltation, suspension and surface creep 52 3.2 Experimental Set-up and Methodology 56 3.3 Experimental Results and Discussion 72 3.3.1 Observations of particle-liquid flows 72 3.3.2 Effect of aspect ratio on blockage for cuboidal particles 74 3.3.3 Effect of particle density on blockage 78 3.3.4 Effect of particle stiffness on blockage..: \u201e 78 3.3.5 Effect of constriction type and dimension on blockage 79 3.3.6 Effect of Reynolds number on blockage 81 3.3.7 Effect of ratio of maximum particle dimension to minimum gap dimension 82 3.3.8 Effect of compressibility and flexibility of particles on blockage 83 3.4 Horizontal Motion of One Neutrally Buoyant Spherical Particle along Centreline .87 3.4.1 Centerline water velocity 88 3.4.2 Particle velocity in horizontal direction 91 3.5 Estimation of pressure drop for blockage 94 3.6 Conclusions 101 CHAPTER 4. PILOT STUDY OF BIOMASS FEEDING 105 4.1 Material Properties of Interest 105 4.1.1 Bulk density 105 4.1.2 Particle density 106 4.1.3 Voidage 106 4.1.4 Compressibility and compaction ratios 106 4.1.5 Angle of friction and friction coefficient 106 4.1.6 Internal friction angle and coefficient of internal friction 107 4.1.7 Flowability 108 4.1.8 Granular materials 108 4.2 Experimental Set up and Methodology ..109 4.3 Material Preparation and Properties 114 CHAPTER 5. PILOT STUDY: E X P E R I M E N T A L RESULTS ...120 5.1 Experimental Results and Discussion 120 5.1.1 Feed rate and variability 120 5.1.2 Blockage tests and analysis 126 5.1.3 Torque analysis 131 5.2 Summary 158 CHAPTER 6. MODELING OF BIOMASS FEEDING 161 6.1 Introduction 161 6.2 Estimation of Volumetric and Mass Flow Rates 164 6.3 Mechanics, Torque and Power Analysis for Hopper-Screw Feeders 170 6.3.1 Estimation of feeder load for initial filling and flow conditions 172 6.3.2 Forces, torque and power analysis in hopper feeding section 176 6.3.3 Forces, torque and power analysis in choke section 196 6.3.4 Comparison of model predictions with experimental measurements 210 6.4 Summary 228 CHAPTER 7. CONCLUSIONS A N D SUGGESTIONS FOR FURTHER W O R K 230 7.1 Conclusions 230 7.1.1 Biomass feeding system ' 230 7.1.2 Particulate flow loop 233 7.2 Recommendations for Further Work 235 N O M E N C L A T U R E : 238 LITERATURE CITED 246 APPENDICES 261 Appendix A. Program Listings for Fourth-Order Runge-Kutta Method with Variable Stepsize for Particulate Flow Loop 262 Appendix B. Materials Size Distributions 265 Appendix C. Stress Ratio of Bulk Solid Sliding on Confined Surface 266 Appendix D. Tangential Force on Driving Flight 268 Appendix E. Torque Generated by Driving Side of Screw 270 Appendix F. Torque Generated by Trailing Side of Screw 272 Appendix G. Listings of Experimental Data Samples 273 Appendix H. Program Listings of Model Predicting Torque Requirements 290 LIST OF TABLES Table 2-1. Main physical and chemical properties of biomass fuels compared with a bituminous coal \u2014\u2014--- \u2022\u2014 7 Table 2-2. Jenike classification of flowability by flow index 14 Table 2-3. Typical biomass gasification projects and their feeding systems 17 Table 2-4. Summary of fuels requirements and feeders by reactor type (combustion systems) 20 Table 2-5 Summary of fuels requirements and feeders by reactor type (gasification system)\u2014 21 Table 2-6. Main feeders used in biomass industry 23 Table 3-1. Proposed characterization of blockage type for Particulate Flow Loop 54 Table 3-2. Reynolds number and water mean velocity for experimental tests in Particulate Flow Loop 55 Table 3-3. Sequences of particles in Particulate Flow Loop 65 Table 3-4. Main specifications of digital video camcorder 67 Table 3-5. Configurations of various constrictions 71 Table 3-6. Particle number density and solid volume fraction of particles 79 Table 3-7. Static pressure and centerline water velocity along streamwise direction 90 Table 3-8. Measured positions and velocities in horizontal direction for neutrally buoyant polyethylene-red-1 particle 93 Table 3-9. Calculated particle Reynolds numbers (void fraction=0.5) 100 Table 4-1. Hopper and screw dimensions 109 Table 4-2. Main specifications of scale system 112 Table 4-3. Main specifications of torque measurement system 113 Table 4-4. Hydrodynamic properties of materials used in the present study 119 Table 5-1. Size distribution of wood pellets containing some fines 127 Table 5-2. Time corresponding to starting torque 132 Table 6-1. Comparison of predicted and measured torques for screw-1 189 Table 6-2. Predicted initial feeder load and vertical stress for screw-1\u2014 192 Table 6-3. Predicted flow feeder load and stresses for screw-1 198 Table 6-4. Parameters for stress and compression analysis for screw-1 201 Table 6-5. Comparison of predicted and experimental efficiencies for screw-1 213 Table 6-6. Recommended critical length of extended section (ID: 102 mm) for various materials 225 Table 6-7. Predicted torques with extended sections for 0.45 m hopper level and various biomass materials for screw-1~ 225 Table 6-8. Relative contributions of different surfaces to total torque (in % of total) 227 Table B - l . Size distribution of biomass materials (sieve analysis) 265 IX LIST OF FIGURES Figure 2-1. Status of feedstock technology reliability and market potential 8 Figure 2-2. Flow-functions: easy flow versus difficult flow \u2014 15 Figure 2-3. Lock hopper feeding system 24 Figure 2-4. Non-uniform flow in hopper \u2014 \u2014 30 Figure 2-5. Screw feeder for wood chips 32 Figure 3-1. Schematic of Biomass Granular Feeding Study \u2014 55 Figure 3-2. Schematic of Particulate Flow Loop, and filter and particle recycle system 58 Figure 3-2-1. Schematic of filter and particle recycle 57 Figure 3-2-2. Schematic of Particulate Flow Loop 58 Figure 3-3. Photo of Particulate Flow Loop 59 Figure 3-4. Photos of main particles used in the present study 64 Figure 3-5. Rectangular constriction-1 with 25.4 (W) x 12.5 (H) mm gap 69 Figure 3-6. Circular constriction-1 with 25.4 (W) x 12.5 (H) mm gap 70 Figure 3-7. Ramp constriction-1 with 25.4 (W) x 12.5 (H) mm gap 70 Figure 3-8. Ramp constriction-4 with 12.5 (W) x 12.5 (H) mm gap 70 Figure 3-9. Percentage of blocked particles of hardness 40, 60, 70 76 Figure 3-10. Blockage index comparison for different particles of hardness 40, 60 and 70\u2014 76 Figure 3-11. Particles (Silicon-rubber70-cuboid-4) blocked in Rectangular constriction-1\u2014 77 Figure 3-12. Effect of particle size and shape on blockage 77 Figure 3-13. Constriction type and dimension effect on blockage for Re=38100 80 Figure 3-14. Constriction type and dimension effect on blockage for Re= 29700 81 Figure 3-15 Effect of Reynolds number on blockage 82 Figure 3-16. Effect of ratio of maximum particle dimension to minimum constriction dimension on blockage for cuboidal rubber particles of different sizes 83 Figure 3-17. Effect of compressibility of particles on blockage for ABS and rubber particles 86 X Figure 3-18. Production of neutrally buoyant spherical particle 87 Figure 3-19. Schematic of view section with ramp constriction-3 89 Figure 3-20. Centerline water velocity along streamwise direction and curve fitting 92 Figure 3-21. Horizontal particle position vs time and comparison of calculated and measured particle velocities in horizontal direction 94 Figure 3-22. Schematic of blockage in rectangular constriction\u2014- 95 Figure 3-23. Schematic of blockage in converging ramp constriction 95 Figure 3-24. Schematic of blockage in constriction \u2014 96 Figure 3-25. Effects of superficial velocity of water on predicted pressure drop per unit length of horizontal blockage bed 99 Figure 3-26. Effects of superficial velocity of water on critical shear stress at boundary of horizontal blockage bed\u2014 101 Figure 4-1. Schematic of lower hopper and screw feeder \u2014 110 Figure 4-2. Schematic of biomass feeding system 110 Figure 4-3. Configuration of test screws 111 Figure 4-4. Particle size distributions of biomass fuels as initially fed 115 Figure 4-5. Photo of wood pellets 116 Figure 4-6. Photo of sawdust-1 116 Figure 4-7. Photo of ground wood pellets-1 116 Figure 4-8. Photo of ground wood pellets-2 \u2014\u2014 117 Figure 4-9. Photo of hog fuel-1 117 Figure 4-10. Photo of ground hog fuel 117 Figure 4-11. Photo of wood shavings 118 Figure 4-12. Photo of polyethylene particles 118 Figure 4-13. Relations of bulk density and consolidating pressure 118 Figure 5-1. Relationship between mass flow rate and screw speed for screw-1 for different biomass materials with initial hopper level=0.3m 121 Figure 5-2. Relationship between volumetric flow rate and screw speed for screw-1 with different biomass materials and initial hopper level=0.3 m 122 Figure 5-3. Hopper level effects on volumetric flow rate for sawdust-1 and screw-1 123 Figure 5-4. Effects of moisture content on volumetric flow rate for sawdust and screw-1 124 Figure 5-5. Dependence of coefficient of variation on screw speed for screw-1 125 Figure 5-6. Fluctuations of flow rate at a rotational speed of 5 rpm for sawdust-1 and screw-1 at initial hopper level=0.45 m (mass flow rate: 27 kg\/h) 125 Figure 5-7. Effect of screw speed and difference in pressure between hopper and receiver on mass flow rate for wood pellets and screw-1 at initial hopper level=0.3 m 128 Figure 5-8. Schematics of particle motion at entrance of choke section 130 Figure 5-9. Torque vs time for screw feeder with no solids present 134 Figure 5-10. Torque vs time for screw feeder at 10 rpm for sawdust-1 and screw-1 at initial hopper level=0.45 m 134 Figure 5-11. Ratio of average to maximum torque for various materials and screw-1 at different screw speeds (initial hopper level=0.45 m) 135 Figure 5-12. Ratio of starting to maximum torque for various materials and screw-1 at different screw speeds (initial hopper level=0.45 m) 135 Figure 5-13. Variability of torque, expressed as standard deviation vs average torque for different materials and screw-1 with initial hopper level=0.3 m 137 Figure 5-14. Variability of torque, expressed as standard deviation vs maximum torque for different materials and screw-1 with initial hopper level=0.3 m 138 Figure 5-15. Standard deviation vs starting torque for different materials and screw-1 with initial hopper level=0.3 m 138 Figure 5-16. Effects of screw speed and particle size on average torque for screw-1 for wood pellets and ground wood pellets with initial hopper level=0.3 m 140 Figure 5-17. Effects of screw speed and particle size on maximum torque for screw-1 for wood pellets and ground wood pellets with initial hopper level=0.3 m 141 Figure 5-18. Effects of screw speed and particle size on starting torque for screw-1 for wood pellets and ground wood pellets with initial hopper level=0.3 m 141 Figure 5-19. Effects of particle shape and screw speed on average torque for screw-1 for polyethylene particles and ground wood pellets-1 with initial hopper level=0.3 m\u2014 142 Figure 5-20. Effects of moisture content and screw speed on maximum torque for screw-1 for sawdust-1 and sawdust-3 with initial hopper level=0.3 m 143 Figure 5-21. Effects of hopper level and screw speed on average torque for hog fuel-1 and screw 1 144 Figure 5-22. Effects of hopper level and screw speed on average torque for sawdust-1 and screw-1 146 Figure 5-23. Effects of hopper level and screw speed on average torque for polyethylene particles and screw-1 146 Figure 5-24. Effects of choke section length and screw speed on average torque for screw-1 for wood shavings-3 with initial hopper level=0.45 m 147 Figure 5-25. Effects of casing configuration on average torque for sawdust-1 and screw-1 with initial hopper level=0.45 m 150 Figure 5-26. Effects of mode of filling on average torque for ground hog fuel (3.5 kg) and screw-1 150 Figure 5-27. Effects of pressure difference between hopper and receiving vessel on average torque for wood pellets and screw-1 with initial hopper level=0.3 m 152 Figure 5-28. Effects of pressure difference between hopper and receiving vessel on maximum torque for wood pellets and screw-1 with initial hopper level=0.3 m\u2014 153 Figure 5-29. Effects of pressure difference between hopper and receiving vessel on mass flow rate of wood pellets for screw-1 with initial hopper level=0.3 m 153 Figure 5-30. Effects of pressure difference between hopper and receiving vessel on average torque for ground wood pellets-2 and screw-1 with initial hopper level=0.45 m\u2014 154 Figure 5-31. Effects of pressure difference between hopper and receiving vessel on maximum torque for ground wood pellets-2 and screw-1 with initial hopper level=0.45 m 154 Figure 5-32. Effects of pressure difference between hopper and receiving vessel on mass flow rate of ground wood pellets-2 for screw-1 with initial hopper level=0.45 m- 155 Figure 5-33. Effects of screw configurations on torque requirements for wood pellets with initial hopper level=0.3 m 156 Figure 5-34. Effects of screw configurations on torque requirements for ground wood pellets-1 with initial hopper level=0.45 m 156 Figure 5-35. Effects of screw configurations on torque requirements for ground wood pellets-2 with initial hopper level=0.45 m 157 Figure 5-36. Effects of screw configurations on mass flow rate for wood pellets (hopper level=0.3 m) and ground wood pellets (hopper level=0.45 m)\u2014 157 Figure 5-37. Effects of screw configurations on volumetric flow rate for wood pellets (hopper level=0.3 m) and ground wood pellets (hopper level^O.45 m) 158 Figure 6-1. Stress around boundary in hopper section 162 Figure 6-2. Five boundary surfaces for a material element in a pocket 163 Figure 6-3. Theoretical volumetric flow rate prediction neglecting particle properties 166 Figure 6-4. Velocity and displacement diagram for element at screw radius 167 Figure 6-5. Prediction of volumetric efficiency 171 Figure 6-6. Directions of major principal stress in a hopper during filling and discharge 171 Figure 6-7. Coordinates of hopper 174 Figure 6-8. Stress around boundary in choke section 177 Figure 6-9. Forces on shear surface 178 Figure 6-10. Forces on core shaft surface ; 180 Figure 6-11. Stress on material element in a pocket 180 Figure 6-12. Forces on trailing side of flight 183 Figure 6-13. Forces on trough surface 185 Figure 6-14. Forces on driving side of flight 187 Figure 6-15. Schematics of the two tapered sections tested in this work 203 Figure 6-16. Stresses on material element in tapered section 203 Figure 6-17. Comparison of predicted and measured torques for screw-1 212 Figure 6-18. Comparison of predicted and measured average torques for 0.3 m hopper level and screw-1 214 Figure 6-19. Comparison of predicted and measured average torques for 0.45 m hopper level and screw-1 214 Figure 6-20. Comparison of average predicted and measured torques for 0.3 and 0.45 m hopper levels for screw-1 215 Figure 6-21. Comparison of predicted and measured starting torques for screw-1 215 Figure 6-22. Comparison of predicted and measured starting torques for 0.3 m hopper level and screw-1 \u2014 \u2014 216 Figure 6-23. Comparison of predicted and measured starting torques for 0.45 m hopper level and screw-1 \u2014 216 Figure 6-24. Comparison of average predicted and measured starting torques for 0.3 and 0.45 m hopper level and screw-1 217 Figure 6-25'. Predicted ratio of torque generated in choke section to overall torque for 0.3 and 0.45 m hopper level and screw-1 217 Figure 6-26. Comparison of predicted (with consideration of compression) and measured volumetric efficiencies for 0.3 and 0.45 m hopper level and screw-1 218 Figure 6-27. Comparison of predicted and averaged measured efficiencies for 0.3 and 0.45 m hopper level and screw-1 218 Figure 6-28. Comparison of predicted average power and measured average power for different screw speeds for 0.3 m initial hopper level and screw-1 219 X I V Figure 6-29. Comparison of predicted starting power and measured starting power for different screw speeds for 0.3 m hopper level and screw-1 219 Figure 6-30. Comparison of torque predictions and experimental measurements with 0.15 m tapered sections and a 0.45 m hopper level 221 Figure 6-31. Comparison of torque predictions and experimental measurements with 0.3 m tapered sections and a 0.45 m hopper level 221 Figure 6-32. Stress on material element in extended section 223 Figure 6-33. Comparison of torque predictions and experimental measurements for screw-1 with 0.15 m extended sections with a 0.45 m hopper level 223 Figure 6-34. Comparison of torque predictions and experimental measurements for screw-1 with 0.3m extended sections with a 0.45 m hopper level 224 Figure 6-35. Comparison of torque predictions and experimental measurements for different choke section lengths 224 Figure 6-36. Comparison of torque predictions and experimental measurements for screw-1 and screw-2 226 Figure 7-1. Schematic of conceptual design of biomass feeding to pressurized reactors 237 Figure C - l . Mohr circle representation of stress in a material element on a confining surface 266 X V ACKNOWLEDGMENT I am most grateful to my supervisor, Dr. John R. Grace. This thesis would have been inconceivable without his support, guidance and encouragement. He has helped in every possible way: lecturing my courses, leading discussion, proofreading the thesis and improving its quality both scientifically and editorially, and offering financial support. I am also grateful to the National Research Council of Canada (in particular, Dr. M . Sayed) and Natural Sciences and Engineering Research Council of Canada for providing funding for this project. Many thanks are given to Drs. Richard J. Kerekes and Paul McFarlane for kindly being members of my supervising committee. Special thanks are given to Mr. Horace Lam, Mr. David Adam and Mrs. Chee Chen in the Stores for helping me with all kinds of procurement, and to Mr. Peter Roberts, Mr. Doug Yuen, Mr. Graham Liebelt, Tim Paterson, and Mr. Alex Thng in the workshop for making a number of components and control panels. My fellow graduate students and all of my friends have made my program a completely pleasant experience. I would also like to thank A X T O N Incorporated and Sunrise Manufacturing for fabricating the screw and tapered sections. Thanks, also, to the Centre for Advanced Wood Processing at UBC, for generously providing wood shavings for use in the experimental study. Finally, I am deeply indebted to my wife Jing L i and my parents, as well as my sisters, for their consistent backing and encouragement, which have been a steady source of pleasure and inspiration. Chapter 1. Introduction 1 CHAPTER 1. INTRODUCTION 1.1 Biomass and Biomass Feeding Interest in biomass feedstocks to produce heat, power, liquid fuels and hydrogen, as well as to reduce greenhouse gas emissions, is increasing in Canada and worldwide in recent decades. The biomass share of current world energy consumption is 14%, with 4% in North America, 38% on average in developing countries, and 85% in the least developed ones (Hall and Rosillo-Calle, 1998). Biomass includes all matter that can be derived, directly or indirectly, from plant photosynthesis. It is organic matter, as well as a renewable energy source, which could replace some fossil fuels. Biomass feedstocks are potentially available in five categories: mill wastes, urban wastes, forest residues, agricultural residues, and energy crops. 50% of the biomass globally available is woody, whereas 20-40% is grassy (ECN, 2004). The chemical composition and physical properties of feedstocks influence the design of gasifiers\/combustors, as well as the composition of the product gas and downstream cleanup requirements. In general, fuels with high inherent energy content, high carbon-to-nitrogen ratio, relatively little sulfur, low ash content, regular particle shapes, small particle sizes, narrow particle size distribution, low moisture content < 55% (wet basis), suitable bulk density, and low contaminant concentrations are preferred as raw materials. Biomass fuel particles tend to be unusual, varying greatly in size and shape. Some are wet, leading to sticking. They also tend to be compressible and pliable (e.g. sawdust, hog fuel, straw, rice hull, sugar cane, bagasse and grass). Some are easily fractured (e.g. wood pellets, walnut shells, other hard and brittle husks), Chapter 1. Introduction 2 while others may be stringy and very resilient (e.g. grass, straw, hay, cotton stalks, corn stover, wood chips and wood shavings). Demolition woods (either pure or mixed with other materials such as sewage sludge and paper sludge) have also been used for gasification (van der Drift, 2001). Biomass processes, including direct combustion, gasification and pyrolysis, have been under development for many years in various countries. A critical problem is how to feed biomass into the reactors. Frequently the solids feeding devices become blocked and do not provide uniform and continuous flow of the feedstock materials required for the process. Fuel feeding problems often impede smooth operation in industry. Feeding is made more difficult by a number of factors. Improperly sized particles, excessive moisture content and an insufficient or excessive pressure differential between the feed vessel and reactor, as well as poor design of feeders, can all lead to feeding failures. If the reactor operates at high-pressure and\/or high temperature, there are additional challenges in establishing reliable feeding (Elliott, 1989; FBT, 1994; Cuenca and Anthony, 1995; Cummer and Brown, 2002). Feeding method choices are closely related to the above characteristics of biomass feedstocks. Wood pellets tend to be denser than normal biomass feedstocks, and to have volume-equivalent diameters from 8 to 16 mm. Typical bulk densities are of the order of 750 kg\/m3, and final moisture content is typically ~8%. These characteristics are generally suitable for gasification or other processes that require uniform and smooth feeding, but at a cost. In general, particle size, size distribution, shape, surface texture (e.g. smooth, rough or sharp edges), density, moisture content, compressibility and other properties (e.g. strength of large particles, time consolidation, etc.) should be considered when choosing the feeding method. Bulk flow properties (e.g. cohesion strength, internal and wall friction), which can be used to characterize the flowability of biomass fuels, are closely related to the physical properties. Chapter 1. Introduction 3 Biomass feeding systems typically consist of two parts: fuel transport from storage to the conveying line, and injection into the reactor. Special attention is paid in this thesis to the latter, i.e. injection into the reactor, since this directly affects the reactor performance and plays a major role in achieving continuous, reliable and efficient operation of the reactor. Biomass feeding systems vary greatly depending on fuel properties and the entire system requirements. For example, several conveyors and feeders, as well as storage vessels, may be connected together in order to implement smooth feeding (Wilen and Rautalin, 1993; Koch, et al, 1996; Cummer and Brown, 2002; Aldred et al., 2003). The feeding systems considered in the present study exclude drying and sizing units. In biomass energy processes, several kinds of feeders and their combinations have been reported including hopper or lock hopper systems, screw feeders, rotary valves, piston feeders and pneumatic feeders. These feeders have been developed for a variety of solids, and they have limitations in handling certain types of biomass and\/or operating in conjunction with pressurized reactors. These feeders require careful design to handle heterogeneous and fibrous biomass feedstocks. Some screw or piston-type plug feeders, commonly used to feed coal or in the pulp and paper industry, have been tested with biomass (Bundalli et al., 1986; Ghaly et al., 1989; Wilen and Rautalin, 1993; Nelson, 1994; Babu, 1995; Gabra et al., 1998; Cummer and Brown, 2002; Li et al, 2004). The flow patterns developed by a screw feeder coupled to a hopper have been studied extensively (Bates, 1969; Bates, 1986; Haaker et al., 1993; Bates, 2000). The mechanics and transport function of screw feeders have also been investigated in some detail (Metcalf, 1966; Roberts, 1996; Yu and Arnold, 1996; Yu and Arnold, 1997). The motion of particles in screw feeders has been simulated by a Discrete Element Method. Mixing and transportation of particles inside the screw feeder have also been analyzed (Tanida et al., 1998). . Chapter 1. Introduction 4 Kinetics and reaction chemistry have received much attention in previous research work on combustion and gasification. On the other hand, not enough research on biomass feeding systems has been carried out, and little detailed information has been published, partly because of patent protection. The wide variations in feeder characteristics and in the physical properties of biomass materials make research on biomass feeding complex, with general rules difficult to formulate. 1.2 S c o p e o f T h i s S t u d y Hoppers and screw feeders are among the most widely used feeders for biomass processes. Screw feeders share similarities with rotary valve feeders in lateral motion and with piston feeders in axial motion of bulk materials. Research on screw feeders could also assist in understanding the basic principles and operation of rotary valve feeders and piston feeders, which are also commonly used in the biomass industries. The present study focuses on screw feeding of biomass fuels, largely ignored in previous research. The objectives are to define what limits screw feeding in terms of the mechanisms of blockage and to examine the effects of key properties like mean particle size, size distribution, shape, moisture content (10-80%) (CIWMB, 2007), density and compressibility on screw feeding of biomass. Chapter 2 provides an overview of current research efforts, as well as a critical review of biomass feeding for combustion and gasification. This background knowledge helps provide an understanding of biomass properties, hopper flow, screw feeding and existing feeding problems. This leads to a statement of the objectives of this thesis. In order to further understand blockage mechanism and effects of particle size, shape and compressibility on particle flow through constrictions, a Particulate Flow Loop was assembled, Chapter 1. Introduction 5 providing qualitative information in Chapter 3. This Chapter provides introduction, experimental set-up, experimental results and analysis of pressure drop required to break up the blockage. This Chapter aims at deepening.understanding of effects-of particle size, shape, density, stiffness and compressibility on blockage and particle flow through constrictions. The next part of the thesis presents a study of the feeding system of UBC's existing Circulating Fluidized Bed Gasifier. In Chapter 4, we introduce the experimental system, biomass materials, and experimental methods and procedure for biomass feeding systems employed in the present study. Chapter 5 reports and discusses the experimental results and summarizes the findings. Chapter 6 provides a model to predict torque requirements and efficiency for biomass screw feeding and compares the predictions with the experimental results of the previous Chapter. Finally, in Chapter 7, a brief summary of conclusions is given, together with recommendations for biomass feeding and for future work. Chapter 2. Background 6 CHAPTER 2. BACKGROUND 2.1 Biomass Properties Biomass properties, including chemical and physical properties as shown in Table 2-1, influence feeder design and reactor performance. 2.1.1 Physical properties Diverse biomass feedstocks have been tested for different biomass processes for centuries, especially in recent decades with market potential and technological reliability indicated in Figure 2-1. From this figure, one can see that woody biomass, short-rotation forest (SRF) and refuse-derived fuel (RDF) have relatively high market potential and overall technological reliability, while the market potential and technological reliability of sludge, straw and grasses are relatively low due to their low energy density and peculiar properties. Biomass fuels fall into three categories according to their size and states: granular material (typically > 0.5 mm, see Chapter 3), powder (typically < 0.5 mm) and slurry. Granular materials differ significantly from powders in flow properties. Biomass varies greatly in size, shape, density and compressibility, with moisture content as high as 80% (CIWMB, 2007), and it may even be in sludge or slurry form. Although biomass particles are usually between 0.5 and 50 mm in volume-equivalent diameter for gasification and combustion processes, fine biomass materials, such as fine sawdust, are also common. Slurries (e.g. sludge and wastes plus water, or mixtures of oil and finely ground biomass) have also been used for gasification. Solids loading, viscosity, stability and heating value are important factors for slurries as fuels (Furimsky, 1998; Agarwal and Agarwal, 1999; DOE, 2001; Henrich and Weirich, 2004). Fuel preparation and feeding problems often impede smooth Chapter 2. Background 7 operation in biomass industries. Biomass physical properties play a major role in these problems. The influences of these properties need to be understood before designing and operating feeding systems. Table 2-1. Main physical and chemical properties of biomass fuels compared with bituminous coa l ( 1 ) Proximate analysis Biomass Bituminous coal Fixed carbon (db (2 )) ASTM D-3172 17-23 % for woody biomass (e.g. black locust, . sycamore, eucalyptus, hybrid poplar). 12-23 % for herbaceous biomass (e.g. wheat straw, bagasse, switch grass and corn stover). 45 % (typical value) Volatile matter (db) ASTM D-3175 77-83 % for woody biomass. 69-82 % for herbaceous biomass. 35 % (typical value) Ash content (db) ASTM E-1755-95 < 2.5 % for woody biomass. Generally 2-14 % for herbaceous (19-23 % for rice hull, 9-11 % for wheat straw, 9-14 % for corn stover, 2-10 % for bagasse, 0.8-2.5 % for bamboo, 1.5-4.5 % for miscanthus) (CSIRO, 2002; EERE, 2006). 1-12 % Moisture content (wet basis) 30-60 % for woody biomass. 8-30 % for herbaceous biomass. 2-15 % Ultimate analysis Carbon (db) 49-55 % for woody biomass. 43-49 % for herbaceous biomass. 66 % Hydrogen (db) 5-7 % for woody and herbaceous biomass. 4.4 % Oxygen (db) 35-45 % for woody and herbaceous biomass. 5.7% Nitrogen content (db) ASTM D-537 < 0.7 % for woody biomass. 0.2-1.54 % for herbaceous biomass. 1.4 % Sulphur content (db) ASTM D-4239 < 0.07 % for woody biomass. 0.07-0.16 % for herbaceous biomass. \"\u2022\u2022 0.5-1.5% Chlorine content (db) < 0.1 % for woody biomass. 0.07-0.18 % for herbaceous (e.g. straw and grass). 0.1 % Potassium content (db) < 0.04 % for woody biomass. < 1 % for herbaceous biomass. 0.06-0.15 % Bulk density (kg\/mJ) 100 - 700 for herbaceous and woody biomass (700-900 for densified pellets) 850-1200 HHV moisture free (MJ\/kg) ASTM D-2015 14- 19 MJ\/kg (air dry) for herbaceous biomass 15- 20 MJ\/kg (air dry) for woody biomass 28 Notes: (1) All data are average or typical values and are mainly based on North America and European Countries. Data are from Hislop and Hall, 1996; Bridgwater, 2002; Ayhan, 2002, CSIRO, 2002; and Henrich and Weirich, 2004; EERE, 2006. (2) db denotes dry basis. Chapter 2. Background 8 Low \u2022 Woody biomass \u2022 SRF c CD O RDF o Q . (0 A A Sludge \u2022 Straw O \u2022 Grasses High High Low Overall technology reliability Figure 2-1. Status of feedstock technology reliability and market potential. (Bridgwater, 2002) 2.1.1.1 Particle size distribution Particle size generally refers to the average volume-equivalent diameter of a particle. Biomass fuels rarely consist of particles of a given size. Thus to specify a fuel system, it is necessary to define not only a mean size, but also the relative numbers or masses of particles of different size, i.e. the size distribution. Sieving is the most commonly used method for size distribution analysis. Other technologies are also available (e.g. based on laser diffraction), especially for fine particles. In sieving, longer sieving times lead to more particles falling through sieves due to irregularity and compressibility of biomass particles. So longer sieving times result in smaller mean sizes and finer size distributions. For convenience and comparison, a fixed time is usually adopted, e.g. 20 minutes is a suitable sieving time for most fuels. Different types of reactors have different fuel size requirements. Particles of uniform size are generally preferred to reduce the blockage tendency in feeders and to improve the Chapter 2. Background 9 performance of the reactor (e.g. pressure drop and product gas quality). Oversize particles, especially those with high density and strength, are more likely to block the feeding system and to cause problems when the particles are fluidized. Too fine particles (e.g. those with diameters < 100 um) can also lead to increased blockage propensity in the feeding system due to large cohesion and adhesion forces, as well as to elutriation in fluidized beds. It is generally important to remove oversize (e.g. > 50 mm) material, especially cube-shape particles of size > 6 mm, as these can increase the chances of bridging or blockage in fuel feeders. Excessive fine material (e.g. particles < 38 uxn) is less of a problem, but the proportion should be limited to 10% of the fuel by mass in order to maintain reliable and stable operation of the reactor (McLellan, 2000). Requirements of fuel size and size distribution are determined by feeder configurations and reactor characteristics. 2.1.1.2 Irregular particle shapes and surfaces Particle shape plays an important role in determining flow properties. Most particles encountered in practice are irregular in shape. Irregular shapes increase the tendency to bridge over openings. For example, a high proportion of hook-shaped or long and thin particles increases the tendency for a material to bridge (Mattsson, 1990\/1997; Klausner, 2001; Mattsson and Kofman, 2001; Mattsson and Kofman, 2002). It is almost impossible to describe complex shapes by a single shape factor (Gift et al., 1978; Ming et a l , 1986). Of the many possible shape factors, the most common are volumetric shape factor, sphericity and aspect ratio. The lack of suitable methods for measuring and characterizing particle shapes and the roughness of particle surfaces makes it difficult to quantitatively study their effects on flow properties of biomass. Image processing is a convenient technique for determining the shape of irregular particles. Chapter 2. Background 10 2.1.1.3 Moisture content Moisture content, the mass of water associated with the material per unit mass of dry or wet material, is one of the most important fuel characteristics. It usually refers to inherent moisture plus surface moisture. The moisture content of raw materials can be as high as 80% (wet basis). As the moisture content of a solid increases, so does its cohesive strength. Increasing moisture content usually accentuates the tendency to bridge and block in biomass feeding systems, especially for long and thin particles (Mattsson, 1990; Mattsson, 1997; Cuenca and Anthony, 1995; Mattsson and Kofman, 2001; Mattsson and Kofman, 2002). Excessive fuel moisture can also cause corrosion of processing equipment. On the other hand, fuels which are too dry have larger permeability and increase the possibility of backflow of gases and bed materials. In addition, the energy required for drying may greatly reduce the net energy generated from biomass processes. Moisture content of 10-20% (wet basis) is suitable for most biomass processes. More moisture reduces the efficiency for combustion systems, but it can lead to better carbon conversions, lower tar emissions, lower heating values of the product gas and lower cold gas efficiencies for gasification systems (FBT, 1994; Hughes and Larson, 1998; van der Drift et al., 2000). Woody biomass is a hygroscopic material. Its moisture content is a dynamic property which changes with environmental conditions. The equilibrium moisture content (EMC) is affected more by variations in relative humidity (RH) than temperature. Small particles with large surface areas exposed to air respond very quickly to changes of RH. Other biomass materials have similar responses to RH changes. Although some researchers have proposed that moisture content be defined on an ash-free basis rather than based on total mass (Asadullah et al., 2003), moisture content is generally expressed on a wet basis. This is the convention in the present study, except where otherwise specified. Moisture contents were obtained from weight loss after Chapter 2. Background 11 drying the fuel samples at 105\u00b0C for 5-72 hours, depending on biomass characteristics and requirements of the energy process. An understanding of moisture content, including its changes with time and environmental conditions, is necessary to estimate the flow properties and to design effective feeding systems. 2.1.1.4 Bulk and particle densities Loose bulk density is the overall density of loose material, including inter-particle spaces (interstices). It is measured simply by pouring a quantity of particles into a graduated cylinder whose diameter is much larger than the particle diameter. The weight and volume occupied by particles determine the bulk density. Oven-dry bulk density and wet bulk density at different moisture contents may be reported. Apparent particle density (called solid density in some literature) is defined as the density of the particles, including the voids inside individual particles. It can be approximately measured and calculated according to procedures of the loose bulk density, except that the volume is compacted with the aid of mechanical pressure up to 0.5-1 MPa, or many (e.g. >1000) taps by mechanical tapping devices (Abdullah et al., 2003; Fitzpatrick et al., 2004). Pycnometry, a common technique for determining skeleton density, is based on gas displacement principles, and is sometimes also used to estimate particle density. From the bulk and particle density, voidage (volume fraction of inter-particle interstices) can be obtained readily since ph = pp(l-e) . Bulk density is not only a function of the material density, but also of how tightly the material is packed. The density can also be altered by deterioration of the biomass particles. Bulk density is important when discussing biomass transportation and feeding, since it directly affects the flow properties of biomass, as well as transportation costs. To obtain a mechanically stable plug with a suitable low gas permeability, the plug should have a bulk density in the range from 1300-1500 kg\/m3, depending on the texture of biomass and the flow requirements (Koch, 2002; T K Energi, 2006). Chapter 2. Background 12 2.1.1.5 Compressibility and compaction ratios Compressibility is the relationship of the bulk density and consolidation pressure acting on the bulk material, which can be expressed by ph =a(i + a)h or ph = a(a + b)c, where ph is bulk density, cr is the consolidation stress acting on bulk solid, and a, b and c are constants (Arnold et al., 1980; Marinelli, 2000). Compressibility is the reciprocal of the bulk modulus, and is expressed by (AV\/V)\/AP, where P is the consolidation pressure and V is volume of materials (Beer et al., 2002). Compressibility is affected by moisture content, particle size, elasticity and temperature (Marinelli, 2000). The bulk density increases as the bulk material is subjected to increasing pressure or solids loading. More details of compressibility are provided in Chapter 6. The compaction ratio (CR) is defined as ratio of compacted density to loose bulk density or loose volume to compacted volume (Briggs, 1994; Marinelli, 2000; Marinelli, 2004). Compressibility is an important factor affecting biomass flow properties. Greater compressibility augments the resistance to bulk motion, i.e. contributes to low flowability. Hard robust particles tend to be incompressible, generally leading to low resistance to flow. However, they can be easily blocked if the outlet dimensions are not large enough relative to the particle dimensions. 2.1.1.6 Contaminants The contaminant level is not a true material property, but it is included in this section since it can significantly affect the flow of biomass. Major contaminants in biomass fuels include stones, dirt, metals, paints, wood preservatives, and other non-combustible or hard materials intermixed with, or embedded in, biomass during collection and transportation. Contaminants should be eliminated, or at least minimized, since they can cause serious wear and stoppage in feeding, as well as severe problems in reactor performance. Ferrous metals can be removed with a magnet, with various types available. Detectors can tell the presence of non-ferrous metals and Chapter 2. Background 13 stop the conveyor. The metal can then be identified and removed manually. Various types of equipment are available for removing stones and dirt from biomass feedstocks. The absence of stones and other debris is generally contractually dictated by the fuel suppliers. As mentioned above, bridging and blockage in biomass feeding systems are mainly attributed to particle mean size and size distribution, low bulk density, irregular shape and cohesive\/adhesive characteristics. Too large and too fine particles should be avoided since they may cause feeding stoppage and adversely affect reactor performance. Fluffy low-density materials, such as straw, bagasse and rice husks, present extreme difficulties in feeding, especially for fluidized bed and entrained flow reactors. Pelletizing and briquetting can change these physical properties and improve biomass flowability, but require extra costs. Wood pellets are denser than normal biomass feedstocks, with typical size 8-16 mm in volume-equivalent diameter. Bulk densities are usually of order 750 kg\/m3, and the final moisture content is typically 8% (wet basis). RDF (refuse derived fuel) pellets are also produced to suit both moving bed and fluidized bed gasifiers, promoting smooth feeding and favorable performance (Hislop and Hall, 1996). High-density materials of large size (e.g. > 50 mm wood blocks) are also difficult to feed. Although other physical properties, such as particle surface roughness, hardness and strength, are hard to measure, they are also important parameters that affect flow properties. 2.1.2 Flow properties Particle physical properties commonly measured are particle size, size distribution, moisture content, bulk density, particle density and compressibility. Particle shape and surface characteristics can be analyzed by image processing. These properties depend on the state of the material as determined by its stress history and the current stress acting on the bulk. The stress is strongly affected by environmental conditions (RH, temperature, vibration, external pressure Chapter 2. Background 14 and microbial activity). Physical properties (as well as chemical properties) tend to change with time (e.g. due to consolidation) for any particular biomass, and special attention is required when measuring these properties. There are no direct widely-used correlations that allow these variables to be used to calculate flow properties. At least four flow properties need to be measured to estimate the flowability (see Table 2-2 and Chapter 4). They are flow-function, cohesion strength, internal friction and wall friction. Flow- function is a plot of the unconfined yield strength of the bulk solid versus major consolidating stress (see Figure 2-2), and represents the strength developed within a bulk solid when consolidated, which must be overcome in making the bulk solid flow. The unconfined yield strength is the major consolidating stress that causes the material to yield in shear. A flow-function lying towards the bottom of the graph represents easy flow, whereas moving upwards in an anticlockwise direction in the graph indicates more difficult flow. The flow index in Table 2-2 is defined as the inverse of the slope of the flow-function. Jenike (1964) used the flow index to classify flowability, with higher values representing easier flow. This was extended by Tomas and Schubert (1979) as shown in Table 2-2. Bulk density, as well as compressibility, should also be considered for hopper design. These properties are typically measured and quantified using shear cell techniques depending on ISO, A S T M or EFCE standards (Arnold et al., 1980; Bates, 2000; Fitzpatrick et al, 2004; Jenike and Johanson, 2006). Analysis of flowability and physical properties can assist in the design of an effective feeder for biomass feeding. Chemical constituents and thermal properties of various biomass fuels have been reported in the literature (e.g. L i et al., 2004). and on-line databases (e.g. EERE, 2006). Table 2-2. Jenike classification of flowability by flow index Flowability Hardened Very Cohesive Cohesive Easy flow Free flowing Flow index < 1 <2 <4 < 10 > 10 (1) Data from Jenike (1964), Tomas and Schubert (1979) and Fitzpatrick et al. (2004). Chapter 2. Background 15 more difficult flow \/ UYS e a s y flow MCS Figure 2-2. Flow-functions: easy flow versus difficult flow. (UYS is unconfined yield Strength and MCS is major consolidating stress). 2.2 B i o m a s s F e e d i n g S y s t e m s 2.2.1 Review of biomass feeding An ideal feeding system provides smooth and continuous feeding with accurate control of the feed rate (e.g. coefficient of variation < 5% based on 1 sample taken over a 1 min interval). The system should be relatively insensitive to variations of fuel size, shape and moisture content, and it must maintain sufficient pressurization to prevent backflow of gases and bed material. Although a variety of biomass feeders have been designed and tested for biomass energy processes in Canada, Europe and the US, most of these feeders have encountered problems and may not be reliable, efficient or economical, particularly for herbaceous feedstocks and pressurized systems (Babu, 1995). The feeding technique for biomass fuels depends on fuel properties, the type of reactor, throughput requirements and the operating conditions (e.g. pressure and temperature). Details of Chapter 2. Background 16 reported feeders are summarized in Tables 2-3 to 2-5. Some feeders may work for specific conditions and have been developed in an ad hoc fashion, but most have limitations, such as being fuel-specific, suffer from pressure seal failure, or encounter bridging or blockages, inaccuracy, complex design and operation, noise, high cost or inability to survive due to wear in long-term service. Dust explosion may be a hazard with decreasing particle size due to spontaneous ignition of dust, especially for pressurized processes. Pyrolysis in the feeding system may also cause severe problems (e.g. tar accumulation in feeders) (Babu, 1995). The operating pressure varies greatly among gasifiers and combustors, from slightly negative pressure or virtually atmospheric to pressures greater than 100 bar (i.e. >10 MPa). Feeding devices for pressurized reactors often function well at atmospheric pressure with little or no modification (Reed, 1981; Babu, 1995; Cummer and Brown, 2002). It is pertinent to classify feeding systems based on their pressure limitations, i.e. low pressure (< 100 kPag), medium pressure (< 300 kPag), high pressure (< 1000 kPag) (Marcus, et al, 1990). If the feeding system operates at pressures above 1000 kPa g, it may be termed extra-high-pressure and special attention is required. Note that the classification of feeders in terms of pressure differs from that of gasifiers or combustors, which may be categorized according to A S M E Boiler and Pressure Vessel Codes. Feeders operating at relatively high pressure (e.g. > 2 bara) are more difficult to design and operate than those intended for normal pressure operation. There is no universal choice of feeder due to the wide variety of equipment choices and biomass properties. For difficult-to-handle materials, the number of options is reduced. In biomass gasification and combustion processes, several kinds of feeders or their combinations have been reported in previous research and industrial applications. They include hopper or lock hopper systems, screw feeders (including single screw and twin screw feeders, etc.), rotary valve feeders, piston feeders, belt feeders, vibratory feeders, reciprocating pan feeders, rotary cu T3 i\u2014\u00bb\u2022 0 Table 2-3. Typical biomass gasification projects and their feeding systems Project information Fuels and gasifying agents Design parameters Main feeders Supplementary comments Source Amer, ACFBG, 600MWe and 350 MW\u201e, for the entire boiler system (Netherlands) Demolition wood; Air blown. Atmospheric pressure 800-950 \u00b0C Silos and screw feeders. (Bottom feeding) ACFBG for demolition wood produces gas which can be burned in coal boilers; Co-firing. Willeboer, 1998 ARBRE, ACFBG B1GCC, 8-10 MW e (Yorkshire, UK) Wood chips from forestry residues and from short rotation coppices; Air blown. Atmospheric pressure Typically 850 \u00b0C Silos, screw feeders and rotary valve feeders. (Bottom feeding) TPS gasification process Babu, 1995; Pitcher et al., 1998 BIG\/GT project ACFBG 30 MW e (Bahia, Brazil) Wood chips from eucalyptus plantation; Air-blown. Atmospheric pressure Typically 850 \u00b0C Silos, screw feeders and rotary valve feeders. (Bottom feeding) TPS gasification process Babu, 1995; Waldheim and Carpentieri, 2001. Varnamo Project\/Bioflow PCFBG, IGCC, 6 MW e and 9 MW l h (Sweden) Wood chips, forest residues, sawdust and bark pellets, willow, straw and refuse-derived fuel (RDF) of a defined size distribution; M C U ) : 10-20%; Air-blown. Pressure: 20 - 22 bar 950- 1000\u00b0C Silos, lock hopper and screw feeders (Bottom feeding) Modifications had to be made to the fuel feed system. Plant shut-down Oct. 1999. Foster Wheeler technology. Kwant, 2001 BIOSYN, PBFBG, (Canada) Sludge, RDF, rubber residues (containing 5 - 15 % Kevlar), and granulated polyethylene and propylene residues; Size: < 50 mm, MC: <20%; Air or oxygen blown. Pressure: 1.6 MPa; Temperature: 800-900\u00b0C Sunds plug screw feeders. Large ball valve was installed between reactor arid feeder, BIOSYN process Wilen and Rautalin, 1993; Kwant, 2001 ACFBG, IGCC, 6.7 MWe (30 M W W ) (Chianti, Italy) Refuse-derived fuel (RDF) Pellets; Air-blown; Atmospheric pressure Typically 850 \u00b0C Storage silos, screw feeders, twin-screw feeders, bucket conveyors, feed hoppers and rotary valve feeders. (Bottom feeding) TPS gasification process Waldheim and Carpentieri, 2001; Granatstein, \u2022 2002. Project information Fuels and gasifying agents Design parameters Main feeders Supplementary comments Source BioCoComb, CFBG, 3.5 MWC(10 MW t h) (Zeltweg, Austria) Wet wood chips, bark and sawdust with MC up to 70%; Size:<30 X 30 X 100 mm; Air-blown. Atmospheric pressure Typically 850 \u00b0C. Hoppers, weighing belt conveyors, screw feeders and rotary valves with purging mechanism; reverse control to prevent blockage (bottom feeding) Product gas is directly fed into pulverised coal (PC) boiler, co-fired with a PC boiler Mory and Zotter, 1998; Granatstein, 2002. Hawaii PDU and BGF project, PFBG, 5 MW e (Hawaii, USA) Wood chips, whole tree chips, barks, refuse-derived fuel, paper mill sludge, alfalfa stems and bagasse, MC: <20 %, Oxygen\/air and steam blown. 0.6-2.14 MPa; 750-980 \u00b0C. Hopper and lock hopper systems, screw feeders (Bottom feeding) Had to operate at reduced capacity and pressure. Feed system did not perform consistently and was modified with addition of lock hopper (bottom feeding). RENUGAS process. Lau, 1998. Lahti project, ACFBG, 60-70 MW t h (Lahti, Finland) Sawdust, wood chips and recycled refuse fuels with MC up to 20-60 %; Air-blown. Atmospheric pressure 800-1000 \u00b0C. Chain conveyors, belt conveyors, silos and screw feeders (bottom feeding). Excellent performance reported, produced fuel gas co-fired with a PC boiler. Foster Wheeler technology. Nieminen and Kivela, 1998. Small-scale demonstration plant, fixed bed gasifier (downdraft), 75 kWth, (Technical University of Denmark, Denmark) Wood chips from beech, Air blown. Atmospheric pressure < 1100-1200 \u00b0 C Hopper and lock hopper system, screw feeders. Feeding system worked well during the test, with only one stop, caused by blockage by a large piece of wood. Gasifier was controlled by a PLC. The only essential parameter, which was not adjusted automatically, was the fuel-feeding rate. Two-stage gasifier with pyrolysis and char gasification in separate reactors Henriksen et al, 2005 Lab-scale dual-bed gasifier. (Bangladesh and Japan) Jute stick, bagasse, rice straw, and cedar sawdust, Size: 0.1-0.3 mm, MC: 4-10 %. Oxygen blown. Atmospheric pressure 550-650\u00b0C. Hopper and lock hopper system, vibrating feeder with N 2 flow. Feeding fluctuation. Dual-bed gasifier composed of two fluidized-bed sections (top feeding). Asadullah et al, 2004. 1.5 MWth (PFBG) (Netherlands) 10-50 kWth (DWSA system) (Netherlands) Coal, German brown coal (BC), and wood; Air blown (DWSA) Air\/steam-blown (PFBG) 0.12-1.6 MPa; 750-1000 \u00b0C. Belt conveyors, hopper and lock hopper system, rotary valve feeders, screw feeders and pneumatic feeding. Bottom feeding from bottom plate and central nozzle or at the bottom just above the distributor by a screw feeder. Jong et al, 2003 Project information Fuels and gasifying agents Design parameters Main feeders Supplementary comments Source Pulverised-coal CHP-unit (79 MW e and 124 MW t h), Entrained flow, (Vantaa, Finland) Pine sawdust (< 10 mm, MC: 50-65%), coal (< 2 mm, MC: 9-13%). Sawdust needs to be dried. Pressure: 180 bar; Temperature: not specified Hoppers, belt conveyers, bucket chargers and pneumatic injectors Co-firing of biomass and coal Savolainen, 2003 ACFBG, 500 KW l h , (BIVKIN, Netherlands) Demolition wood (both pure and mixed with sewage sludge and paper sludge), verge grass, railroad ties, cacao shells and different woody fuels. Railroad ties contained very little heavy metals. Air-blown. Atmospheric pressure 850 \u00b0C Fuel bunkers, rotary valve feeders, screw feeders. (Bottom feeding). Initially, feeding problems often impeded smooth operation. Application of various feeding systems for various fuel mixtures. van der Drift et al., 2001 Cyclone gasifier and combustor (Two-stage) (Sweden) Bagasse, cane trash and their' pellets; Air or steam injection Atmospheric pressure Ambient temperature for tests Storage bin, screw conveyer, feed bin with two twin-screw feeders in bottom; pneumatic injector (Top feeding) Gabra et al, 1998. ABFBG, (Iowa State University, USA) Biomass fuels, Air\/steam blown. Atmospheric pressure 649 - 900 \u00b0C Feed hopper, metering screw feeder, rotary valve feeder, screw injector feeder, purge air or nitrogen to prevent backflow of producer gas and bed materials. Bottom feeding Pletkaetal, 1998 Entrained flow gasifier, 130 MW(th), (SVZ, German) Various waste slurries (e.g. char\/pyrolysis oil slurry from short straw chops or wood sawdust) 20 bar and 1200\u00b0C Pump Henrich and Weirich, 2004 Pilot scale CFBC, 0.3 MWth. Co-combustion of coal and biomass in CFB boiler (USA) Pine bark < 30 mm; Atmospheric pressure 800-900 \u00b0C Hoppers and screw feeders. (Bottom feeding) Biomass and coal are fed simultaneously to a third screw feeder leading to boiler. Rotation speed of this screw is kept constant and high. Bahillo et al., 2003 Notes: (1) MC stands for moisture content, wet basis unless otherwise specified. Table 2-4. Summary of fuels requirements and feeders by reactor type (combustion systems)1 System Fixed or moving bed combustors (Grate firing) Suspension combustion system Fluidized bed combustors (BFBC and CFBC) Pile burners (wet cells) Underscrew Thin-pile spreader-Stoker Cyclonic or air spreader stoker AFBC PFBC Particle size Generally < 500 mm (typically < 300 mm), and not too fine, depending on grate openings and feeder dimensions Generally < 50 mm (typically 6-38 mm), non-stringy, not too large or too fine, depending on the auger size. Generally 6-50 mm, depending on grate openings and feeder dimensions Generally < 6 mm, not too fine, non-stringy Generally < 500 mm for BFBC (typically < 50 mm for BFBC and CFBC), non-stringy, not too fine, depending on feed system Generally < 500 mm for BFBC (typically < 50 mm for BFBC and CFBC), non-stringy, not too fine, depending on feeding system Moisture content (wet basis) < 65 % <40 % (typically 10-30%) 10-50% < 15 % (typically < 10%) < 60 % < 60 % Main feeders Hoppers or lock hoppers, rotary valves, screw feeders, piston feeders Screw feeders Spreader stokers Pneumatic feeding and\/or spreader stokers Hoppers or lock hoppers, rotary valves, screw feeders, pneumatic feeders, piston feeders Lock hoppers, rotary valves, screw feeders, pneumatic feeders, piston feeders, can be used in series for better seal \u2022 Feeding positions Mostly over-bed except underfeed stokers Over-bed Over-bed Over-bed Over-bed, under-bed or in-bed Over-bed, under-bed or in-bed Main feeding problems (Please also see Table 5) Bridging and blockage, tar accumulation, dust explosion, feed rate fluctuations, poor gas and fuel distribution in the bed Blockage, insufficient or excess biomass, poor gas and fuel distribution in bed, through-screw is better for ash removal Blockage, insufficient or excess biomass, poor gas and fuel distribution. in the bed Blockage, insufficient or excess biomass, poor gas and fuel distribution in the bed Bridging and blockage, tar accumulation in the fed line, dust explosion, feed rate fluctuations, poor gas and fuel distribution in the bed, seal Bridging and blockage, tar accumulation in the fed line, dust explosion, feed rate fluctuations, poor gas and fuel distribution in the bed, pressure seal and leakage Notes: (1) Data from Quaak et al., 1999; Badger, 2002; Agarwal and Agarwal, 1999. Table 2-5. Summary of fuels requirements and feeders by reactor type (gasification system) System Fixed bed or moving bed gasifiers Fluidized bed gasifiers (BFBG and C F B G ) Downdraft Updraft Open-core AFBG PFBG Scale range Generally 0.01-10 MW t h Generally 2-12 MW\u201e, Generally 2-12 MW t h Typically 2-50 MW\u201e, for BFBG; 8-150 MW t h for CFBG Typically > 80 MW t h . Particle size Generally 20-100 mm, depending on grate openings and feeder dimensions, as well as different reaction characteristics Generally 5-100 mm, depending on grate openings and feeder dimensions, as well as different reaction characteristics Generally 1-5 mm, depending on grate openings and feeder dimensions, as well as different reaction characteristics, especially suitable for low bulk density fuels (e.g. rice husks) Generally 6-50 mm, not too fine or too stringy, depending on feeder and reaction characteristics. Relatively fine fuel sizes are preferred compared to FBC. Generally 6-50 mm, not too fine or too stringy, depending on feeder and reaction characteristics, more flexible than BFBG, Relatively fine fuel sizes preferred compared to FBC. Moisture content (wet basis) < 25 % (typically < 12%) < 60 % (typically < 40 %) < 15 % (typically 7-15 %) < 65 % (typically 10-60%) < 65 % (typically 10-60 %) Main feeders Hoppers or lock hoppers, rotary valves, screw feeders, piston feeders Hoppers or lock hoppers, rotary valves, screw feeders, piston feeders Hoppers or lock hoppers, rotary valves, screw feeders, piston feeders, pneumatic feeders Hoppers or lock hoppers, rotary valves, screw feeders, piston feeders, pneumatic feeders Hoppers or lock hoppers, rotary valves, screw feeders, piston feeders, pneumatic feeders, in series for better seal Feeding positions Over-bed (top) Over-bed (top) Over-bed (top) Over-bed, under-bed or in-bed Over-bed, under-bed or in-bed Main feeding problems Bridging and blockage, tar accumulation, dust explosion, insufficient or excess biomass, poor gas and fuel distribution in bed Bridging and blockage, tar accumulation, dust explosion, insufficient or excess biomass, poor gas and fuel distribution in bed Bridging and blockage, tar accumulation, dust explosion, insufficient or excess biomass, poor gas and fuel distribution in bed Bridging and blockage, tar accumulation in feed line, dust explosion, feed rate fluctuations, seal, poor gas and fuel distribution in bed Bridging and blockage, tar accumulation in feed line, dust explosion, feed rate fluctuations, poor gas and fuel distribution in bed, pressure seal and leakage Notes: (1) Data from Quaak et al., 1999; Badger, 2002; Agarwal and Agarwal, 1999. Chapter 2. Background 22 table feeders, pumps and pneumatic feeding systems, as shown in Table 2-6 (Reed, 1981; Bundalli et al., 1983; Bundalli et al., 1985; Bundalli et a l , 1986; Ghaly, 1989; Wilen and Rautalin, 1993; Cuenca and Anthony, 1995; Babu, 1995; Gabra et al., 1998; Cummer and Brown, 2002; Henrich and Weirich, 2004; van der Drift et al., 2004). Most of these feeders can inject biomass directly into the reactor, whereas others (e.g. belt feeders) are generally not used for direct feeding. Pumps used for feeding in the coal and concrete industries, have also been tested with biomass (typically for biomass slurries), including feeding to pressurized vessels (Wilen and Rautalin, 1993; UONDEERC and GE1, 2001; Henrich and Weirich, 2004). Lock hoppers and piston feeders are common when there is significant pressurization and the need for a seal in the feeding system, whereas screw feeders, rotary valves and pneumatic feeders have considerable ability to seal and resist modest backpressures. For slurry feeding, pumps can feed and resist backpressure from the reactor. These feeders can provide feed rate control and injection into the reactor, and they are often used in combination rather than separately, especially for continuous operation. More detailed information about feeder types, their applications, properties and costs have been given by Rautalian and Wilen (1992) and Wilen and Rautalin (1993). These feeders have been developed for handling a variety of solids, but they have certain limitations in handling biomass with peculiar physical and chemical properties and\/or operating in conjunction with pressurized and\/or high temperature reactors. Therefore these feeders need be modified for handling heterogeneous and fibrous herbaceous biomass feedstocks (Babu, 1995). There is no ideal feeding system for all applications. The chance of problems is -80% for biomass feeding systems according to industrial experience, the highest risk rating in entire biomass reactor systems. Similar probability of problems occurs for fuel gas clean-up systems (van der Drift et al., 2000). With any feeding system, the feed line temperature and pressure, as Table 2-6. Main feeders used in biomass industry Feeder type Pressure range Volumetric capability Main fuel requirements Main advantages Main problems Hopper or Lock-hopper <3.5Mpaa 0.1-32000 kg\/h Size: smaller than outlet width, typically the maximum particle size < 1\/5 outlet width; Moisture ( 2 ) : < 50 %. Simple construction; compatibility with other feeding mechanisms; low energy consumption, cost effective. Bridging; ratholes; flushing; aeration failure; pressure seal failure; incorrect choices of construction materials; linings cracked. Screw feeder <1.5 Mpaa Single screw feeder: 1 x 10\"4-56m3\/h Twin screw feeder: 2 x 10\"4-40 nvVh Size: smaller than clearance (typically < 1\/5 clearance) or two-thirds of minimum pitch, generally < 50 mm; Moisture: < 60 %. Volumetric feeding; suitable for cohesive and adhesive materials, especially for multi-screws; flexible arrangement; low energy consumption, cost effective. Sticking on flights, shafts and casing surfaces; blockage; pressure seal failure; mechanical wear; particle attrition; short distance (typically < 6 m); fabrication and installation tolerance Rotary valve < 1.5 Mpaa 0.01-566 nrVh Size: depending on valve configuration and dimension; Moisture: < 60 %. Positive displacement; suitable for cohesive and adhesive fuels; low energy consumption and cost effective. Sticking in pockets and on casing surfaces; jamming; carryover; mechanical wear; particle attrition; seal failure; fabrication and installation tolerance Piston feeder : <15 Mpaa U-115m3\/h Size: wide range; Moisture: wide range; Positive displacement; suitable for cohesive and adhesive fuels. Gas leakage; intermittent feeding; mechanical wear; high energy consumption; fabrication tolerance; installation errors Pneumatic feeder Not available Not available Size: 0.02-50 mm, typically < 6 mm; Moisture: < 15 % (typically < 10%) Long distance transport (up to 150 m); flexible arrangement (e.g. vertical, horizontal or inclined); drying during transport; low capital cost. Strict fuel requirement; gas and dust leakage; blockage; wear; intermittent feeding; high energy consumption; nozzle design failure; fabrication tolerance. Weigh-belt feeder Atmospheric 22 kg\/h-2500 t\/h Size: wide range; Moisture: wide range; Suitable for cohesive and adhesive fuels with wide size and moisture range; low energy consumption and cost effective. Mechanical wear; limited to 15\u00b0 incline; light dry particles are easily blown off; not suitable for feeding fuels into pressurized reactors. Pump < 35 Mpaa Not available Slurry Can feed fuels to high pressure . Wear; leakage; corrosion Notes: (1) Data from Wilson and Dunnington, 1991; Wilson, 1998; Cummer and Brown, 2002; Badger, 2002; Hao et al., 2003. (2) Wet basis for moisture content, unless otherwise specified. Chapter 2. Background 24 well as the feed hopper level and other flow conditions (e.g. rotation speeds and torque readings if screw feeders are used), should be monitored to facilitate corrective measures (manual or automatic) to ensure safety and smooth feeding. Such measures might include pressurizing the feed line with air or inert gases to prevent reverse flow, providing agitation or starting spare feeding systems to ensure continuous feeding. For overall plant safety, reliable shut-off should be provided to isolate feed bins and hoppers from reactors. Biomass gasifiers are more difficult to operate and require more sophisticated instrumentation and controls than combustors. Instrumentation and control systems for fuel handling and feeding vary from plant to plant depending on operating policies. 2.2.2 Hopper or locker hopper systems One of the most common devices for feeding solid fuel directly or indirectly into a reactor is a hopper or lock hopper system. One prominent design of the lock hopper system developed by Thomas R. Miles Consulting Engineers (Cummer and Brown, 2002) is shown in Figure 2-3. I CHARGf. r -f H O P P E R A I R \\ , \/ C Y L I N D E R ) \\ 1 ] f*\"\" '. . ' i V A L V E SCREWS Figure 2-3. Lock hopper feeding system. (Reproduced with permission: Thomas R. Miles Consulting Engineers.) (feed rate: 5 t\/h of biomass; reactor pressure: 10-25 bar) Chapter 2. Background - , . . \u2022 25 There are many types of hoppers in industrial applications, mainly conical hoppers and wedge-shaped hoppers. A hopper has a converging sloping lower section, typically attached to the bottom of a silo. The hopper flow mainly depends on gravity, but may be assisted by mechanical means inside the hopper (e.g. stirrers) and rotating extractors (e.g. rotary valves and screw feeders). As solids flow from a hopper, the boundaries between flowing and non-flowing regions define the flow patterns. There are three common patterns, internal flow (i.e. funnel flow or core flow), mass flow and expanded flow. For internal flow, solids travel to the outlet through a channel within a stagnant region of solids. The stagnant materials may form a stable rathole. In addition, fine powders can become aerated and flush uncontrollably when bridges or ratholes collapse (Jenike, 1964; Thomson, 1997; van der Kooi, 1997). Internal flow hoppers have variable flow rates, depending on the material properties, hopper configurations, fill level in the hopper and operating conditions. On the other hand, internal flow diminishes the wear to the hopper wall surface, and the reduced investment and maintenance costs make internal flow hoppers attractive in many cases. Mass flow hoppers deliver uniform flow at the outlet and the flow rate is easy to regulate. Erratic flow, channeling, flooding and stagnant regions are avoided, and particle segregation is minimized. Flow of bulk solids in the hopper can also provide a gas seal. Some wear-resistant linings can be used on the inside surface of the hopper. The term \"expanded flow\" describes flow in a vessel that combines an internal flow converging hopper with a mass flow hopper attached below it. For biomass processes, mass flow hoppers are generally preferred, but it is impossible to avoid internal flow completely due to low bulk density, irregular shape and cohesion of biomass. Internal flow hoppers are common in biomass processes, especially when the flowability of the biomass fuels is poor. The main problems for hopper flow are formation of bridges (i.e. arching) and ratholes. These problems are especially common for biomass fuels. There are two basic types of bridges: Chapter 2. Background 26 cohesive and mechanical bridges, formed by different bridging mechanisms. A rathole is a stable void that develops through a mass of static bulk material. Some hoppers are fitted with discharge aids such as vibrators, air bladders, air injection, fluidizing pads, hopper inserts and various mechanical agitators. Passive flow aids (e.g. special hopper design and fixed inserts) are generally preferred over active aids (e.g. vibrators and agitators), since the latter have large uncertainties in promoting biomass flow and need more maintenance (Marcus et al, 1990; Thomson, 1997; Wilson, 1998). Tests are essential before choosing discharge aids to promote uniform flow in the hopper and in the discharger. For example, vibrators may not work well for wet biomass and fine powders due to high adhesion to the wall surfaces, as well as increased cohesion (Joppich and Salman, 1999). For a lock hopper system, the lock hopper is used as an air lock or lock vessel to receive biomass at atmospheric pressure and, after pressurization, to discharge biomass under gravity into a feed vessel, i.e. lower hopper. A pinch valve may be installed as the lock hopper discharge valve. The lower hopper operates at almost constant pressure, slightly above that of the reactor, to prevent reverse flow of hot gases and bed materials from the reactor to the feeding system (Marcus et al, 1990; Cuenca and Anthony, 1995; Li et al., 2004). Lock hoppers work best at < 3.5 MPa. Air injection and pressurizing the hopper by air or inert gases (e.g. nitrogen) can effectively promote hopper flow and prevent backflow (Wilen and Rautalin, 1993; Pletka et al., 1998; Li et al., 2004; Cummer and Brown, 2002; Eriksson et al, 2004). Industrial experience, as well as some research facilities, have widely employed these methods, with a pressure differential of 0.5-20 kPa between the feed hopper and reactor (e.g. McLendona, 2004). Too small a pressure differential cannot effectively improve hopper flow and resist backpressure. Too large a pressure differential increases the feed rate of biomass unpredictably and interferes with reactor performance, while also expending energy and Chapter 2. Background 27 increasing the difficulties in hopper design and operations. The pressure differential range depends on fuel properties, hopper configurations and reactor requirements. Hopper flows have been subjected to modeling for many years. Most studies assume perfect spherical particles (elastic or plastic), but non-spherical particles have also been considered (Favier et al., 2001; Cleary and Sawley, 2002). So far no papers explicitly model biomass flow in hoppers due to the complex and unusual properties of biomass particles. Many experimental studies have focused on hopper flow in recent decades, including biomass hopper flow and bridging tendency. The tendency to bridge across openings is mainly a function of particle shape, mean size, size distribution, moisture content, compressibility, particle surface characteristics (e.g. roughness, hardness), and bed depth above the opening. Particles interact with each other in a complex manner resulting in interlocking and interior friction. Increasing the bed depth above the opening increases the tendency to bridge, particularly for fuels containing long thin particles. Wood chips have a relatively low tendency to bridge compared to grass and straw due to their relatively large bulk density, lower compressibility and greater hardness. Changing the particle size or mixing different fuel feedstocks can change the bridging tendency. For example, mixing wood chips into straw and reed canary grass may reduce the tendency of the latter to bridge. Fuels have been compared to roughly determine the relative likelihood of bridging (Bundalli et al., 1983; Bundalli et al., 1985; Bundalli et al., 1986; Mattsson, 1990; Mattsson, 1997; Klausner, 2001; Mattsson and Kofman, 2001\/2002\/2003; Jensen et al., 2004; Fitzpatrick et al., 2004). Drying and sizing, as well as suitable design of hoppers, can reduce hopper flow problems. Hopper performance is closely related to the geometric characteristics and dimensions of the hopper (e.g. cone or wedge angle, and outlet dimensions), as well as vessel pressure and filling fraction. Jenike's mathematical methodology is the engineering standard practice for Chapter 2. Background 28 designing a hopper in terms of calculating the minimum hopper angle and opening size for mass flow (Jenike, 1964; Fitzpatrick et al., 2004). Values of effective angle of internal friction and angle of wall friction are used to calculate the hopper angle and hopper opening size (Jenike, 1964; Fitzpatrick et al., 2004). Jenike's design principle has seldom been used for small hoppers, although it is widely used for designing large hoppers (Bates, 2000). Results from small hoppers are valuable, but special attention must be taken when using these data to design large hoppers. Typically shear cell techniques (e.g. Jenike shear tester and ring shear tester) are used for hopper design. The physical properties and flow properties which need to be considered and measured in hopper design include bulk density, compressibility, cohesion, internal and wall friction, and flow-function. These parameters are in turn affected by particle size, size distribution, particle shape, moisture content and particle surface characteristics. Hopper type, geometric shape and dimensions, as well as the hopper pressure, fill level and refilling procedures, are other factors which can affect design and performance, especially for mass flow hoppers (Jenike, 1964; Arnold et a l , 1980; Bundalli and Martinez, 1982; Bundalli et al., 1983\/1985\/1986; Bates, 1986; van der Kooi, 1997; Fitzpatrick et al., 2004). In addition, hopper outlet shape and dimensions, as well as cone or wedge angle, are very critical to hopper performance. Once the radial stress field in hoppers is formed after initiation of feeding, the outlet plays a major role in hopper transport capacity no matter what mechanical or pneumatic aids are used in the hopper. The outlet width should not be too wide or too narrow compared to the screw diameter i f a screw feeder is used as the discharge device. Too narrow outlets can cause bridging and blockage, while too wide an opening causes large stress at the hopper outlet for given bulk solid and hopper level, leading to large power consumption or large blockage possibility. Outlets which are too wide tend to cause dead zones in the corner. The critical arching span for many biomass fuels in a conventional Chapter 2. Background 29 converging flow hopper is very large if no aids (e.g. inserts, mechanical aids, air injection) are employed. Despite its great value, the classical Jenike method only covers conical and V-shaped hoppers and does not apply to discharging devices. Arnold et al. (1980) gave a more practical presentation on hopper design. A comprehensive approach to the design of an effective hopper demands not only an understanding of flow mechanics in different flow channels, but of interfacing considerations with available feeding devices (e.g. screw feeder), as well as inserts, mechanical aids and air injection characteristics. Hopper operating pressure is important, but is ignored in almost all previous research. For example, for wedge-shaped hoppers, special care should be taken when the hopper operates at high pressure since the wedge-shape is not well suited to pressure vessels. Higher hopper levels generally lead to higher vertical stress at the hopper outlet and increase higher fullness of screw pockets, tending to increase the feeder load and transport capacity of screw feeding. Hopper level is supposed to have insignificant effects on feeder load beyond a certain height above the outlet of the hopper (e.g. 2 times hopper outlet width) (Arnold, 1980; Nelson, 1996). The hopper can.be refilled manually or automatically. Refilling can be activated automatically when a minimum level is reached. Refilling affects hopper performance, as well as discharger performance. Linings are sometimes used to promote hopper flow, thermal insulation, or for improved wear, erosion and corrosion resistance. These linings include high-molecular-weight polymers, glass-coated steel, various epoxy paints, Teflon, smooth stainless steel, or other refractory linings (e.g. silica ceramic and aluminum oxide). Abrasion-resistant plates and replaceable metal liners are also used for hoppers (Ondik et al., 1982; Bundalli et al., 1986; Thomson, 1997). When a screw feeder with constant pitch, shaft and screw diameters is combined with the hopper, the screw tends to withdraw material only from the rear (i.e. the upstream end of the Chapter 2. Background 30 screw), as shown in Figure 2-4. At the front of the hopper, biomass particles are pushed against the front wall, resulting in severe compaction. More uniform withdrawal of biomass particles from the full length of the opening is highly desirable. Several methods have been proposed to restrict flow at the rear, while, at the same time, improving motion at the front of the hopper. For example, internals (e.g. stirrers) can be installed in the hopper, or the transport capability in the screw feeding direction can be increased (e.g. by increasing the pitch, increasing screw diameter or reducing shaft diameter along the screw), but these measures may complicate fabrication, operation and maintenance or risk pressure seal failure. Such measures may not work, especially for herbaceous biomass of low bulk density and for pressurized operations. Pressurizing the hopper has been widely used to promote hopper flow and resist backflow from the reactor in biomass processes. I . . 1 Free Surface of Material Reactor Figure 2-4. Non-uniform flow in hopper. Chapter 2. Background 31 The huge size of industrial hoppers leads to difficulties in manufacturing (e.g. weld techniques) and installations besides the special hopper design. Lock hoppers have high pressures and pressure fluctuations, while temperature is normally < 420\u00b0 C. Temperature-resistant pressure vessel steels with good mechanical properties (e.g. strength, toughness, fatigue and stress rupture), are leading candidates for construction materials for hoppers and lock hoppers (Ondik et al., 1982). A reliable and economical hopper-feeder system for biomass may be achieved by a converging flow hopper, an effective extractor and mechanical or pneumatic aids. Correct hopper profile and bed height of material on the feeder are essential for satisfactory performance. Hopper level is best determined by non-intrusive measurements (e.g. ultrasonic, radioactive, radar or laser level detectors). 2.2.3 Screw feeders 2.2.3.1 Operating principles Screw feeders are common feeding devices which can deliver bulk solids over a wide range of feed rates. Single and twin-screw feeders are common types for biomass feeding. Screw feeders are volumetric devices. The volume delivered depends on the screw flight diameter and shaft diameter, pitch (distance between adjacent flights) and fullness (degree of fill) (Bell, 2003). In theory, the volumetric capacity is linearly proportional to the screw rotational speeds, and most published results show that the power requirements are also proportional to speed within the limits of normal operation (up to about 10 rpm) (Carleton et al, 1969; Wilson, 1998). If the solids entering the screw are compressible (like most biomass fuels), the mass delivered per unit time may not be proportional to rotation speed. The velocity of the solid material as it is conveyed is a vector having an angle to the direction of rotation. As the screw rotates, bulk solids move in a helical path of direction opposite to that of the screw (Bates, 1969; Bates. 2000). Volumetric efficiency is defined (Roberts, 1996) as ratio of volumetric flow rate Chapter 2. Background 32 to maximum theoretical throughput with screw feeder completely full and particles moving at the feeder speed without slip and\/or rotational motion as described in Chapter 6. The frictional effects of the solids on the screw flights and adjacent casing, together with the configuration of the screw itself and material properties, determine the efficiency. Higher filling fraction and less slip lead to higher efficiency. The efficiency decreases as the clearance between the discharge casing surface and screw flight tips increases (Roberts, 1996; Bell et al., 2003). Feed rate fluctuations, variability (i.e. coefficient of variation) and linearity are commonly used to describe the accuracy and stability of screw feeding (Joppich and Salman, 1999; Bell et al., 2003). 2.2.3.2 Main problems and solutions When biomass is fed into a reactor, especially a pressurized reactor, the screw compresses the feedstock into a compact plug. Compaction of the plug is usually aided by tapering the feed channel or gradually reducing the pitch of the screw as it nears the reactor as shown in Figure 2-5. REPLA.CEABLE SCREW SECTION 4 \/ Figure 2-5. Screw feeder for wood chips. (Cummer and Brown, 2002) The feed plug then forms a barrier, preventing backflow of gases and reactor material. A backpressure adjuster (hydraulically adjustable throttle) can be employed to regulate the strength of the plug formed in the feeder and also its pressure sealing against backpressure. Owing to the conical shape of the backpressure adjuster, which also breaks extrudates, no Chapter 2. Background 33 extrudate breaker is required in the reactor when feeding biomass. Sweden and Canada have employed this kind of screw feeder or its modified version in the pulp and biomass industries (Wilen and Rautalin. 1993; Cummer and Brown, 2002). When reducing pitch screws are used, the short pitch may more easily bridge in the screw pockets, especially for cohesive and\/or adhesive materials, decreasing the transport capacity of the screw. Compression of biomass to form a seal plug in the screw casing only by reducing the pitch is not always effective and reliable, due to various properties of solid fuels (e.g. compressibility, permeability, cohesion and adhesion) and operating conditions (e.g. filling fraction of screw pockets, dilation of solids, screw vibration). Attention must be given to both pitch and hopper design to make the compression and seal plug in the screw feeder effective and reliable. Even so, pressurization of the feed hopper is also advisable. For tapered feed channels, Bates (2003) advised that the screw should terminate before the casing so that the material is pushed forward within a confined channel. However, he did not advise converging the delivery pipe to increase the seal pressure, although this is used in the biomass industries. There are several other choices for the feed channel, such as a pipe with a converging part and enlarged mouth (similar to a venturi tube). Other screw geometries have also been recommended for hopper-screw feeders to form a seal plug or to increase the transport capacity in the feeding direction (e.g. increasing pitch, variable shaft diameter, and variable screw flight diameter). The challenge lies in maintaining both uniform flow and the pressure seal. Bundalli et al (1986) and Nelson (1996) found that variable pitch screws appear to have little benefit in achieving uniform flow along the full length of the opening for biomass (e.g. hog fuel and wood chips). Nelson (1996) also introduced multiple screw feeders (screw rotation speed 1-6 rpm) with tapered shaft diameter to successfully feed wood chips, hogged bark and other wood refuse to a power boiler. Chapter 2. Background 34 Further experiments for different kinds of screws and channel geometries have shown promise, especially for combinations of different screw configurations. However, modifying screw or channel geometries are likely to increase manufacturing difficulties and costs. Other methods of promoting flow in hopper-screw feeders include various inserts and mechanical agitators, air injection and aeration, linings of the hopper surface and pressurization of the hopper (Bundalli et al, 1986; Nelson, 1996). A system for feeding bagasse to a fluidized bed gasifier, with a plug screw feeder followed by a shredding conveyer, has also been tested (Turn, 1977). Screw feeders are commonly combined with a hopper or lock hopper system, rotary valve feeders, piston feeders or pneumatic feeding, as well as pressurization inside the feed line. In the UBC CFB plant gasifier (Li et al., 2004)(see Chapter 4), a lock hopper and a hopper-screw feeder were combined, and pressurized air was introduced into the feed hopper to assist feeding biomass into the pressurized circulating fluidized bed gasifier The main problems of screw feeders are slippage, blockage and feed rate fluctuations. Lack of flow is usually caused by a bridge or a rathole in the hopper if the motor drive works well. Blockage is related to overload of materials, as well as fuel properties (e.g. large particles with large density and high strength, cohesive or adhesive particles). Cyclic variations due to angular position of screw flight rotation, intermittent bridging in the hopper, solids build-up on the screw and blockage in the screw feeder, as well as under- powered drive, may all cause feed rate fluctuations. As a rule, the clearance should exceed the particle size to prevent interlocking of particles between the screw flight tips and the channel, especially for relatively strong particles (e.g. wood chips), although backpressure may also prevent the particles from moving forward. Special attention must be paid when using screw feeders on cohesive or adhesive fuels (e.g. < 100 pm in size or moisture content > 50%) due to cohesive or adhesive build-up and blockage. Chapter 2. Background 35 Most common feeders shear material from a head load (e.g. hopper load), which can lead to compaction. Such compaction should be avoided or at least minimized. Fibrous materials (e.g. wood wastes and chips) are especially prone to compaction and plugging. In addition, particle attrition and mechanical wear can lead to a higher fraction of fines, which can also cause blockage in the screw feeder and elutriation of small particles in fluidized bed reactors. Reversing screw rotation may help to break blockages. Care is needed that the drive power is large enough to feed fuels and that the screw feeder is strong enough to resist the reversing axial forces required to disrupt the blockage. A brush-like device can be placed at the outlet of the screw feeder to help homogenize the flow and disperse the solids evenly in the reactor. It has also been suggested (e.g. Bates, 2003) that the delivery pipe be chamfered at an inclination less steep than the angle of repose of the biomass. This allows the advancing plug to shield the total inner surface of the screw casing, thereby avoiding accumulated build-up which obstructs the discharge. The disadvantage is that the discharge pipe protruding inside can interfere with the flow in the reactor. Moreover, the delivery pipe may encounter high temperature, severe abrasion and corrosion. A vibrator has also been tested to homogenize screw feeding of wood powders with mean size 0.368 mm and moisture content < 10% (Joppich and Salman, 1999). Caution must be exercised when using vibrators and agitators to stimulate flow of cohesive or adhesive fuels (e.g. too fine or too wet), since this can cause undue compaction, aggravating the problem. For cohesive materials that tend to arch across the hopper outlet, it is desirable to have as wide a slot as possible. A pair of screws installed side-by-side provide the same slot width as a single screw of twice the diameter. However, the volumetric capacity of the twin screw is one-half that of one single larger screw. An even more pronounced effect is seen when three or more parallel screws replace a single larger screw. However, these arrangements are relatively rare in Chapter 2. Background 36 the biomass industry. For multiple screw feeders (e.g. twin screw feeders), intermesh or non-intermesh, as well as the rotation direction (e.g. upward or downward relative to the casing), spacing of the non-intermesh screws, and clearance between the screw and the casing, are all important. Generally intermesh twin screws, with screws of opposite hand and counter-rotating, are used for cohesive material since they can prevent arching and self-clean one another (Wilson, 1996). The principal drawbacks of multiple screws are the increased cost and mechanical complexity of the drive train. Nelson (1996), Bates (2000) and Arnold (2003) provide more information regarding multi-screw feeders. To prevent reactions in the feed line, measures should be taken to prevent the system from reaching temperatures at which pyrolysis commences. Inert gases (e.g. nitrogen) are often used to provide pressurization seal to the reactor and prevent reactions in the feed line. A large ball valve can be installed between the reactor and feeder for safety (Cummer and Brown, 2002). Minor manufacturing eccentricities, shaft deflection and imperfect fabrication tolerances often result in poor flow, increased power consumption, and excessive compaction of material within the screw, especially for variable-pitch and tapered-shaft screws. Special operator attention is needed when feeding to gasification and combustion reactors. The feeding system can be controlled separately, or by a central control system. Torquemeters, revolution counters, zero speed switches and level detectors are among the simplest instruments to monitor and adjust hopper-screw feeding systems. Whatever control system is used, it should be able to detect flow problems (e.g. no flow, reduced or zero screw speed, or significant torque fluctuations) and take corrective measures (e.g. reversing the motor for several seconds, starting mechanical or pneumatic aids, pressurizing gases in the hopper, starting spare feeding systems or stopping the drive and shutting down the plant). The control system is essential for Chapter 2. Background 37 continuous and reliable operation of the entire system, as well as for safety and minimizing operator attention. 2.2.3.3 Design guidelines Screw designs depend on fuel properties, various feeder combinations and system requirements. The principles of screw feeders design are to ensure feeding capacity and uniform flow without bridging, ratholes and blockage and to prevent backflow of gases and bed materials from the reactor. The shaft and flights must be able to endure the torsional and bending loads, as well as the axial force. The parameters needed to design screw feeders are bulk density, compressibility, cohesion strength, internal and wall friction (Jenike, 1964; Bates, 1969; Bates, 1986; Carson, 1987; Maton, 1994; Y u and Arnold, 1996; Yu and Arnold, 1997; Bates, 2000). Short pitch screws (pitch less than screw diameter) are generally recommended for inclined conveyors and screw feeders due to increased mixing, reduced dilation of the solids and higher filling fraction (Tsai, 1994; Maton, 1994). The minimum ratio of pitch to the screw diameter should exceed 0.25 to ensure reliable operation (Haaker et a l , 1994). Pitch, screw flight diameter, shaft diameter, flight thickness and clearance determine the effective spaces for particle movement and therefore affect feeding capacity. Both too large or too small a pitch can decrease the feeding capacity. There should be an optimal pitch corresponding to the maximum feeding capacity for any screw feeder. 1-25 mm is a reasonable range for clearance depending on screw configurations, with standard clearance for most materials being V\" (12.7 mm). Too large a clearance causes efficiency loss, while too small clearances tend to cause particle jamming and severe mechanical wear. Too large flight thickness and too large ratio of shaft diameter to flight diameter may decrease transport capacity and cause a loss in efficiency. Too thin flights or ratios of shaft diameter to flight diameter which are too small may lead to Chapter 2. Background 38 manufacturing difficulties and insufficient strength. For variable pitch screws, special attention must be given to the pitch nearest the outlet end of the hopper (i.e. start of the choke section), as well as the pitch at the discharge end, since they play a major role in determining the transport capacity of the feeder. Screw feeders are well suited for hoppers with elongated rectangular outlets. The screw feeder design must be coordinated with the hopper design, so that bulk solids do not arch or rathole across the hopper outlet. Constant-pitch screws are generally not suited to rectangular hopper outlets as they only withdraw material from approximately one pitch length near the rear of the hopper (Figure 2-4). Increasing pitch, tapered shaft (reducing shaft diameter) and tapered screw diameter (i.e. increasing flight diameter) are commonly used to increase the screw capacity in the screw feeding direction. Obtaining sealed plugs is usually accomplished by reducing pitch, reducing screw diameter, missing flights in one section for plug formation, or tapering the feed channel. U-shaped, instead of V-shaped, troughs promote flow from the hopper outlet into the screw pockets and prevent fuels from accumulating on the hopper walls (Carson, 1987; Bates, 2000). The hopper outlet length is generally -3-9 times the outlet width, while the length of the choke section in the hopper-screw feeder is at least one pitch (Bates, 1969) or twice standard pitch (CEMA, 1980; Y u and Arnold, 1997). A longer choke section may improve the pressure seal at the expense of power consumption. Special screws (e.g. ribbon and coreless screws) are recommended to transport cohesive materials, but may not be good for metering and direct injection of biomass into the reactor. Twin-screw or multi-screw feeders can be designed according to fuels properties and outlet width. For more information on design of screw feeders see Carson (1987), Maton (1994), Van der Kooi (1997), Bortolamasi and Fottner (2001) and Bell et al. (2003). Chapter 2. Background 39 The effect of rotation speed of screw feeders has received limited attention for biomass. 15-100 rpm, and typically < 70 rpm, are usually recommended (CEMA, 1980; Carson, 1987; Bates, 2000; Arnold, 2003). For free flowing materials, slow screw speeds tend to cause high efficiency and feeding irregularity, whereas relatively high speeds reduce fluctuations, but also decrease efficiency, as well as enhancing wear and particle attrition. Owing to the poor flowability of biomass and plug seal inside the screw feeder, relatively slow screw speeds (e.g. 2-40 rpm) are preferred although higher screw speeds have also been reported (Pletka et al., 1998; Bahillo et al., 2003). Slow speeds increase mixing inside the feeder (Tsai, 1994). On the other hand, screw feeders with a cantilever structure, common in feeding biomass into reactors, may shake or vibrate when the rotational speed is increased. Shaking or vibrating may cause erratic flow, as well as mechanical wear and other operating problems. Some experiments have indicated that higher screw speeds reduce the blockage tendency inside the screw feeder, possibly because of higher dilation at relatively high screw speed and intense interlocking of particles at lower speeds, as well as blockage break-up due to significant shaking or vibration at higher speeds (Rautenbach. and Schumacher, 1987). Most commercially available screw feeders are < 1 m in diameter, typically < 0.6 m. Oversized screws, while providing an extra margin of capacity, may lead to large feed rate variability, difficulties in manufacturing, installation and maintenance, and uneven distribution of fuels in the reactor. Multiple point feeding should be considered in such cases. One can choose larger screw feeders with fewer feed points, or smaller screw feeders and more feed points. The choice depends on the scale and type of the reaction system, reactor type and material properties. Standard screw feeders (with, pitch equal to flight diameter) should be considered first. Modification (e.g. variable pitch, shaft, screw diameter, or tapered feed channel) may be unavoidable for biomass applications. Chapter 2. Background 40 Although screw conveyors with up to 45% fill and no feed rate control can be more than 50 m long, screw feeders have much shorter length, especially for cantilever structures. Intermediate bearings are needed if the screw feeder is too long. In general, screw feeders shorter than 6 m long work well, without too much deflection for cantilever structure, including inclined cases (Bates, 2000). Cantilever-mounted screw feeders have the advantages of flexible design, fabrication, installation and maintenance over screw feeders with bearings at both ends or intermediate bearings. They allow easy-clean, direct end outlet configurations, simple direct-acting cut-off valves, and plug seals to prevent pressure differentials, high temperature and reactions in the feed line. Screw feeders are usually horizontal. Inclined screw feeders (typically with inclination to the horizontal < 15\u00b0) are sometimes used to overcome headroom problems. The maximum design temperature for industrial screw feeders is generally about 550\u00b0C, whereas for biomass gasification and combustion, the reactor temperature can be -1000\u00b0 C. Sometimes the screw is water-cooled to prevent biomass devolatilization, and formation of char and tar. Caution is needed in the choice of construction materials. Mechanical wear and corrosion of the screw and housing are among the concerns. Stainless steel and carbon steel are used for most industrial applications. For biomass, stainless steel (usually SS 310 or SS 316) is preferred for long-term operation. The housing surfaces can be coated with liner (e.g. epoxy, ceramic or aluminum oxide) to prevent wear, corrosion and \/or high temperature. Wear-resistant steel coating is also employed on key flight areas. As a rule, a relatively smooth screw finish and a relatively rough trough or casing finish are used to reduce particle rotation and to increase the efficiency. Scale-up of a screw feeder is generally based on semi-empirical methods or on experimental studies using dynamic similarity. The motor must be large enough to allow the screw feeder to start up. Analytical formulae in the form of Equation 5-128 (Roberts, 1996) and Chapter 2. Background 41 semi-empirical formulae (e.g. C E M A formulae) are commonly used to calculate the power requirement, but they may differ by as much as 30-40 % from experimental results. Note that Roberts (1996) adopted three empirical pressure ratios, as shown in Figure 5-6, to calculate the axial force and ignored the choke section. In fact, all such equations neglect the choke section and starting torque, which is also important in industrial practice and is typically several times (at least 1.5-2 times) larger than the operating torque due to the higher initial shear strength of confined bulk solids, particularly for firm granular materials (e.g. wood pellets) or very cohesive\/adhesive fuels (Bates, 2000; Bortolamasi and Fottner, 2001). However, in some cases the starting torque is almost the same as the operating torque (Carson, 1987). However, it is advisable to choose a motor large enough (e.g. to work in the range of 30-75 % of its nominal capacity) to allow for normal start-up. Torque is primarily a function of the geometric characteristics of the screw and hopper, and fuel flow properties (e.g. internal and wall friction angle). The screw speed has little effect on torque except for fuels with large shear strength. The vertical stress at the hopper outlet for initial and flow conditions can be estimated based on approaches recommended by Jenike (1964\/1977) and Arnold et al. (1980). For plug screw feeder design and selection, power and torque requirements should be calculated with special attention since a large proportion of the feeder power is needed to compact the materials. The mechanics and power requirements of screw feeders have been analyzed (Metcalf, 1966; Carson, 1987; Roberts, 1996; Y u and Arnold, 1997; Bortolamasi and Fottner, 2001). Screw feeders work at combined torsional and bending loading, usually with torsion as the governing load. Imperfect design and fabrication tolerance, as well as manufacturing eccentricities or material deficiencies, often cause service failure (Aghdam, 2002; Sattarifar, 2002; Sattarifar, 2003). Chapter 2. Background 42 2.3 Some Related Problems in Biomass Properties and Feeding 2.3. i Effects of biomass physical properties on feeding and fluidization Generally all physical properties, as well as chemical properties, affect feeding. Particle size and shape should meet requirements of feeding systems and reaction. Too large or too fine particles present difficulties in feeding (e.g. bridging and blockage) and reactor operations, affecting reliability and efficiency. Large particles with irregular shape, such as long and thin particles, tend to cause mechanical bridging in the feeder, as well as channeling in fluidized bed reactors. Fine particles tend to cause more elutriation in the reactor and larger tendency to bridge and block in the feeding system due to cohesion and adhesion effects, especially for particle sizes < 100 pm. High moisture content promotes cohesion and adhesion, which may cause problems in the feed line, including bridging and blockage. Pelletizing and briquetting often improve flow properties of biomass, making it easier to feed. In addition, Pelletizing some biomass feedstocks (e.g. bagasse and cane trash) and then grinding the pellets to powder can lead to easier feeding compared to crushed bagasse and cane trash, although Pelletizing and grinding pellets increases costs and reduces overall energy efficiency, mainly because Pelletizing and grinding lead to harder particles, higher bulk density, reduced sliver-shape effects and larger particles. 2.3.2 Effects of feeding rate and feeding fluctuations Fluctuations in the fuel feed rate may affect the operation of the entire biomass plant. Feeding problems cause immediate change in the air\/fuel ratio, triggering temperature excursions. Bed agglomeration and sub-optimal carbon conversion can be attributed, at least in part, to feeding problems. Too large feeding fluctuations may disturb the reactor operation and cause fluctuations of the fuel gas constituents (e.g. CO, H 2 and CO2, etc.) (Asadullah et al., 2003). Typically fluctuations should be limited to-within \u00b1 15% (Gabra et al., 1998). The Chapter 2. Background 43 possibility of bridging and blockage, including intermittent stoppage, must be minimized to ensure smooth and efficient feeding. Monitoring the feed line is essential to take immediate measures in time to handle the problems. 2.3.3 Effects of feeding positions Biomass feedstock can be fed above, below, or directly into fluidized bed reactors. As a rule, large particles with large particle density are introduced from the top, whereas small particles with relatively low particle density are fed under-bed or by in-bed methods. Under-bed and in-bed feeding provide longer residence times promoting high gasification or combustion conversions. But pre-crushing and drying are then needed to make sure that the particle size is small enough (e.g. < 6 mm) and that the moisture content is no higher than 15% (typically < 10%). Screw feeders, rotary valves and piston feeders, temperature-resistant or with a cooling system, can also be used for under-bed and in-bed feeding. In smaller reactors, fuels can enter the reactor through sidewalls, while for large units, nozzles for fuel injection can be arranged uniformly on the air distributor. In coal feeding to fluidized bed reactors, one injection point is needed for each 1-1.5 m 2 of bed surface (Oka, 2003). Erosion and corrosion of pipelines for pneumatic conveying can be severe. Moreover, pressure sealing is more difficult for under-bed and in-bed feeding to prevent backflow of gases and bed materials from the reactor. Despite deficiencies, pneumatic in-bed conveying may be the best way to feed fine biomass (Oka, 2003). Over-bed feeding is often accomplished by gravity from elevated hoppers with the aid of a screw feeder, rotary valve, piston feeder or pneumatic feeder, all of which also act as seal devices to prevent backflow of gases and bed materials into the feeder hopper. Over-bed feeding reduces complexity, but may allow the feedstock to become entrained without reacting and yield lower carbon conversion (van den Enden and Lora, 2004). One such feed point is needed for every 3-4 m 2 of bed surface according to experience from the coal industry (Oka, 2003). Chapter 2. Background 44 Studies comparing top feeding with bottom feeding of a gasifier have shown differences in product distribution (Corella et al., 1988; Vriesman, 2000). However, comparison is difficult since other reactor-specific parameters can also influence the results. From the gasification experiments of Vriesman (2000), the position of the feeding points affects conversion of fuel-N to ammonia and CO levels. Top feeding leads to a lower conversion of fuel-N to ammonia and a higher percentage of product CO. No significant differences in carbon conversion to tar were found for top and bottom feeding. 2.3.4. Multi-point feeding and spare feeders When the diameter of the reactor is relatively small, it is relatively easy to distribute the particles inside the reactor. However, large size fluidized beds in commercial power production may not achieve good mixing of fuel within the bed. Poor mixing of fuel yields uneven combustion or gasification. In such cases, multiple inlets are required (Cummer and Brown, 2002; Oka, 2002). Each gasifier or combustor is usually served by several feeders or feed lines that enable full feeding capacity to be maintained in the event of a blockage and allow routine maintenance on one of the units at a time (McLellan, 2000). This also limits the dimensions for screws and feed channels to meet feed capacity requirements. Feed rates can be adjusted by screw rotation speeds or turning on\/off some feed points for multi-point feeding. 2.3.5 Pressurization in feeding system One function of biomass feeding systems is to provide reliable seals to prevent backflow of gases and bed materials, as discussed above. Seal failure may cause serious problems, such as gasification or pyrolysis in the feed line, feed stoppage, or dust explosions. A mechanically stable plug with a suitable low gas permeability can help resist backpressure. Typically if the leakage velocity of gases from the reactor is lower than the plug velocity towards the reactor, Chapter 2. Background 45 the feed line can be successfully isolated from the reactor. Piston and screw feeders are often used to form a seal plug inside the feeder to prevent backflow. Other feeders, such as lock hoppers, rotary valves and pumps, can also provide effective seals. Even so, air or inert gases (e.g. nitrogen) are often used to pressurize feeders to minimize gas leakage and ensure sufficient pressure seal to the reactor, especially for pressurized processes. 2.3.6 Feeding for co-combustion and co-gasification systems There is increasing interest in co-combustion of two or more fuels. For example, one can co-fire biomass and coal in existing boilers, or gasify biomass in a separate gasifier and burn the syngas with coal in a boiler. Co-gasification of various biomass feedstocks, particularly wastes and coals, is also promising. Efforts are being made to develop technologies to co-feed various biomass fuels, particularly with wastes and coals, or fuels and sorbents (DOE, 2001). Co-feeding different biomasses may cause rapid changes in the feed line, as well as the reactor, making control difficult. Even biomass sources differing only in moisture content can cause significant variations in operating conditions and cause control problems. Fuel characteristic variations must be mitigated by blending before co-feeding (Tillman, 2000; Badger, 2002). As a result, separate feeding system may be used to increase reliability and fuel flexibility. Fuel processing, tar formation, ash slagging, catalyst deactivation, emissions, and boiler tube corrosion associated with co-firing are major barriers to co-combustion and co-gasification systems (Green et al., 1991; EERC, 2000; Bahillo et al., 2003; Savolainen, 2003). 2.4 Summary and Objectives for This Project In this chapter key biomass properties and biomass feeding techniques for combustion and gasification are presented. Chapter 2. Background 46 Biomass is organic matter with potential for renewable energy applications. Biomass feedstocks are potentially available as mill wastes, urban wastes, forest residues, agricultural residues and energy crops and roughly fall into three forms according to their size and states: granular material (typically > 0.5 mm), powder (typically < 0.5 mm) and slurry. Biomass tends to have peculiar physical properties and various chemical properties. Properties may change with time and environmental conditions. Cohesion, internal and wall friction, bulk density and compressibility all affect flow. Smooth feeding is essential for biomass conversion processes. Reliable, efficient and economical feeding systems suitable for a wide range of biomass fuels are required for biomass utilization. Biomass feeding plays a critical role in continuous and reliable operations of reactor systems. Hopper or lock hopper systems, screw feeders (including single screw and twin screw feeders, etc.), rotary valve feeders, piston feeders, pumps and pneumatic feeding systems are the main feeders used for biomass. They may appear together, rather than separately, especially for continuous operations and pressurized processes, to ensure smooth, reliable and efficient feeding and pressure seals. Bridging, ratholes, blockage, seal failure, feeding fluctuations, reaction in the feed line, mechanical wear and corrosion are major problems for biomass feeders. Pressurization of feeders can promote and prevent backpressure. Monitoring and excellent control systems are essential for safety and reliable operations. Lock hopper and piston feeders are mainly used for significant pressurization, while other feeders, such as screw feeders, rotary valve feeders and pneumatic feeders feed biomass into reactors, with considerable ability to resist backpressure. Pumps are mainly used for slurry feeding, with excellent ability to overcome backpressure. Feeding rate and fluctuations influence reactor performance. Feeding methods and feeding location depend on biomass properties and system requirements. Multi-point feeding and spare feed lines may be necessary Chapter 2. Background 47 for large-scale biomass plants. Slurry feeding has some advantages over dry feeding. Co-feeding of different fuels or materials is also of increasing interest. Not enough research has been done on biomass feeding systems, and little detailed information has been published. Varieties of feeders and materials make it difficult to formulate general rules. Hoppers and screw feeders are among the most widely used feeders for biomass processes. Screw feeders share similarities with rotary valve feeders in lateral motion and with piston feeders in axial motion of bulk materials. Although screw feeders have been studied extensively, screw feeding of biomass and the effects of the choke section, as well as variations of the screw casing and seal plug examination, have been ignored in previous research. No reports of previous detailed experiments with respect to biomass feeding could be found, making the present study unique. The present study focuses primarily on screw feeding of biomass materials. The objectives of the present work are to determine experimentally and also by modeling: (1) Mechanisms of blockage; (2) Effects of mean particle size, size distribution, shape, moisture content (10-60%), bulk density and compressibility on screw feeding of biomass; (3) The importance of the choke section on torque requirements and transport functions in screw feeding of biomass; (4) The influence of casing variations (e.g. tapered section and extended section) on torque requirements, blockage and seal plug formation; (5) Prediction of the efficiency of screw feeding of biomass. (6) The effects of pressurization of the hopper on torque requirements and feeder performance. Chapter 3. Particulate flow loop 48 CHAPTER 3. PARTICULATE FLOW LOOP 3.1 Introduction The Particulate Flow Loop was designed and fabricated to investigate the fundamentals of the movement of clusters of particles of different well-characterized shapes through narrow gaps or constrictions as they are conveyed by water. The work undertaken in this equipment was intended to provide background information and a better understanding of key hydrodynamic multiphase flow factors which cause, or contribute to, stalling and blockage in particulate feeding systems such as those used for the feeding of biomass. 3.1.1 Flow in a rectangular duct Experimental study and modeling of flow, both laminar and turbulent, in rectangular ducts of different aspect ratios have been widely conducted in past decades (Han, 1960; Hartnett et al., 1962; Goldstein and Kreid, 1967; Sparrow et al., 1967; Fleming and Sparrow, 1969; Beavers et al, 1970; Launder and Ying, 1972; Gessner, 1973; Melling and Whitelaw, 1976; Gessner and Po, 1976; Gessner and Emery, 1981; Su and Friedrich, 1994; Islam et al., 2002). The local flow structure in a rectangular duct may be dominated by traverse flow, commonly known as secondary flow (Gessner and Emery, 1981). This secondary motion can be caused by different mechanisms and strongly depends on the Reynolds number and aspect ratio of the cross-section. Secondary flow not only causes a reduction of the volumetric flow rate for a given pressure drop, but it also causes the axial velocity field to be distorted. Furthermore, the secondary motion produces an increase in wall shear stress towards the corner. A clear understanding of the evolution and consequences of secondary flow in ducts in its fully developed state is quite important. Little is known about the structure of internal turbulent flows, even in straight ducts Chapter 3. Particulate flow loop 49 (Su and Friedrich, 1994). Various turbulence models have been developed and tested for turbulent flow in rectangular ducts of different aspect ratios. The entrance length, Le, where fully developed flow is achieved is commonly expressed in terms of the dimensionless downstream position, Le l(DH Re), at which Uc IUcfd along the axis reaches 0.99 (McComas, 1967; Goldstein and Kreid, 1967, Garg, 1985), where DH is the hydraulic diameter of the duct and Re is the Reynolds number based on DH and the mean fluid velocity, while Uc and Ucfd are the local centreline fluid velocity and fully developed centreline fluid velocity, respectively. Generally, Le IDH * 0.0567 Re, and Le IDH * 0.693 Re 0 2 5 for laminar and turbulent flow, respectively (Brodkey and Hershey, 1988). At similar Reynolds numbers, the development length for turbulent flow is less than for laminar flow. A number of researchers have determined the entrance length for both laminar and turbulent flow in circular and rectangular ducts (Klein, 1981; Su and Friedrich, 1994). Han (1960) gave a dimensionless entrance length of 0.066 for a 2:1 ratio rectangular duct and 0.0427 for a 4:1 ratio rectangular duct for incompressible laminar flow. Goldstein and Kreid (1967) investigated laminar flow development in a square duct using Laser Doppler Velocimetry and reported measured and predicted dimensionless entrance lengths of 0.09 and 0.0752, respectively. Sparrow et al (1967) performed experiments on laminar flow to obtain a dimensionless entrance length of 0.08 for a 5:1 duct and concluded that hydrodynamic development in a 2:1 duct was somewhat slower than in a 5:1 duct, whereas Fleming and Sparrow (1969) obtained approximately 0.07 for 2:1 duct and 0.052 for 5:1 duct for the dimensionless entrance length of laminar flow. Wiginton and Dalton (1970) recommended a dimensionless entrance length of 0.08 for incompressible laminar flow for a rectangular duct. Garg (1985) found dimensionless entrance lengths for laminar flow of 0.0734, 0.075, 0.0533 for square, 2:1 and 5:1 ducts, respectively. Chapter 3. Particulate flow loop 50 Gessner and Emery (1981) suggested that fully developed flow for turbulent flow occurred beyond ^ e ^ H ~ Klein (1981) found that the length required for full flow development in a pipe may exceed 140 pipe diameters. According to these viewpoints, fully developed flow has rarely been achieved. Although the solution to laminar fully developed flow through a round pipe is the well-known parabolic profile, the corresponding analytical solution for flow through a channel of rectangular cross-section is less well known. McComas (1967) and Nguyen and Wereley (2002) provided experiments for fully developed laminar flow through a rectangular duct. Sufficiently far from the wall, the analytical solution in the short-side direction converges to the well-known parabolic profile for flow between infinite parallel plates. In the long-side direction, the flow profile is unusual in that it has a very steep velocity gradient near the wall, which reaches a constant value away from the wall. Experimental research and numerical prediction of turbulent flow and turbulence-induced secondary flow have also been widely conducted (Launder and Ying, 1972; Gessner, 1973; Melling and Whitelaw, 1976; Gessner and Emery, 1981; Su and Friedrich, 1994; Eggels et al, 1994). Kim et al (1987) applied Direct Numerical Simulation (DNS) to investigate fully developed turbulent flow between two parallel plates at a Reynolds number based on mean centreline velocity and channel half-width of 3300. The general characteristics of turbulent statistics showed good agreement with experimental results of Eckelmann (1974) and Kreplin and Eckelmann (1979), except in the wall layer. A similar DNS was performed at a larger Reynolds number of 7900. Several other direct simulations of wall-bounded turbulent flows have been reported (Spalart, 1988; Lyons et al, 1991; Gavrilakis, 1992; Kristoffersen and Andersson, 1993). These computations all considered turbulent flow in a geometry with a rectangular cross-section or over a flat plate. Flows in cylindrical cross-section geometries differ Chapter 3. Particulate flow loop 51 from those in ducts of rectangular cross-sections (Patel and Head, 1969; Eggels, et al, 1994). Generally, Ucfd I Um in cylindrical pipes exceeds that in channel flow. Despite the fact that square duct flow shows a secondary flow pattern, Gavrilakis (1992) reported Ucfd \/1\/\u201e, =133, in very close agreement with pipe flow predictions of Eggels, et al (1994), whereas Kim et al (1987) recommended Ucfd I Um = 1.16 for turbulent plane channel flow. This illustrates that additional wall friction at the side-walls of the pipe\/square duct causes the mean flow to differ from plane channel flow. An abrupt entrance caused transition to turbulence at a Reynolds number of approximately 2000, whereas with a smooth entrance, transition Reynolds numbers were as high as 7,000 (Hartnett et al., 1962). Eckert and Irvine (1957) and Hartnett (1962) recommended critical Reynolds numbers of 4300, 2200, 6000 for rectangular ducts of aspect ratio 1:1 (smooth entrance), 1:1 (abrupt entrance), and 3:1 (smooth entrance), respectively. Re=6000 is taken as the transition Reynolds number for the rectangular duct of aspect ratio of (2.68:1) in the present study. A measure of flow development is the blockage factor, defined by the ratio of the centreline velocity to the mean velocity (i.e. B = 1 - Um I Uc) (Sovran and Klomp, 1967; Klein, 1981). Based on the experimental data of Carpinlioglu and Gundogdu (1998), the entrance length for two-phase particulate flow decreases as Re increases. 3.1.2 Flow past obstacles and through nozzles Circular and non-circular (e.g. rectangular) jets have been studied experimentally and theoretically for both single and multiphase flows (Leschziner and Rodi, 1981; Ogg, 1983; Nadeau et al., 1991; Miller et al., 1995; Ye et al., 1995; Tazibt et al., 1996; Ye and Kovacevic, 1999; Rembold et al., 2002; Eskin and Kalman, 2002; Uchiyama and Naruse, 2003). This previous work mainly focused on jet velocity profile, turbulence, particle motion, and cavitation. Nozzle configuration and nozzle design have also been investigated (Garrison and Byers, 1980; Chapter 3. Particulate flow loop 52 Eisert and Dennenloehr, 1981; L i et al., 1995; Gotoh et al., 2000; Kwon, 2002). Flow past obstacles is also widely investigated, concentrating on velocity and pressure fields, turbulence and flow characteristics (Shieh, 1980; Islam et al., 2002). A survey of related literature indicates that nozzle or jet flow, and flow over obstacles are complex, especially for multiphase flow. The basic parameters influencing the flow are Reynolds number and turbulence, fluid properties, particles properties (e.g. size, shape and density), particle loading, obstacle or constriction dimensions and shape, and flow direction. Particles may block constrictions, due to particle-particle\/particle-wall\/particle-turbulence interactions. Like the blockage factor defined for turbulent pipe flow, a blockage index is defined in the present investigation of the blockage probability of particles in constrictions. No previous record of this could be found in previous studies. 3.1.3 Saltation, suspension and surface creep Bagnold (1941) defined three transport modes for sand particles: saltation, suspension and surface creep. The term \"saltation\" denotes particles being picked up and displaced by the fluid. Due to the gravity, the particles return to the bed surface when they collide with other particles, exchanging mass, momentum, and energy with the bed. Due to collisions, some particles are ejected or rebound away from the bed with a lift-off velocity (Zheng et al., 2005). Saltation depends on how particles ejected into the flow are accelerated, and how, on impact with the bed, collisions lead to ejection of other particles into the flow stream (Anderson 1989; Nishimura and Hunt, 2000). The fluid threshold velocity (velocity that must be exceeded for saltation to be initiated) is generally thought to be greater than the impact threshold (fluid velocity that must be exceeded for saltation to be maintained). At higher fluid speeds, particles are transported upwards by turbulent eddies and by this means can be transported far downwind. This is the Chapter 3. Particulate flow loop 53 process of suspension. Surface creep (also called reptation) describes particles making short hops, and rolling and jostling along the surface. Saltation is the principal transport mechanism of wind-blown sand particles, accounting for 75% of total sand transport. Particle saltation has received considerable attention, and several researchers have investigated the trajectories of saltating particles. Most previous studies have obtained trajectory data by photography (White and Schulz, 1977; Willetts and Rice, 1985; Nalpanis et al., 1993; Zhang et al., 2006). Despite the considerable work, the mechanism by which particles leave the surface and the velocities of saltating particles are still not well understood. The saltation of sand particles in air has been shown to be a stochastic process. The ejection process, i.e. particles rebounding or not, angle of ejection and velocity of ejection, are all stochastic (Zhang, 2006). The forces acting on a single saltating particle include lift (Magnus force associated with particle rotation and Saffman force due to shear), drag, gravity, etc. (Saffman, 1965; White and Schulz, 1977). The relative influences of these forces depend on the environmental conditions, complicating numerical prediction. In addition, the effect of the size, shape and density of particles on saltation, complex interactions among the particles, and turbulent fluid flow are not clearly understood. As a result, an accurate theoretical model of the saltation process has not yet been developed (White and Tsoar, 1998; Zhang et al.. 2006; Herrmann et al., 2006). For fibres in the suspensions, a complication is that fibers do not always move affinely with the fluid, but rather aggregate (Mason, 1950; Kerekes et al. 1985; Kerekes and Schell, 1992;\u201e Schmid et al., 2000). Much is known about the motion of isolated fibers in low Reynolds number flow. Forgacs and Mason (1959) and Goldsmith and Mason (1967) have theoretically and experimentally investigated the flow induced deformation of single fibers in simple shear flow. Less is known about the processes by which fibers flocculate. Mason (1950) postulated Chapter 3. Particulate flow loop 54 that flocculation is a dynamic equilibrium process, with fibers continuously entering and leaving floes, both rates being equal at steady state. Kerekes (1995) has identified dimensionless groups that help predict flocculation in specific experiments. Particle-turbulence interactions, particle-particle\/particle-wall interactions and collisions, and particle motion, have also been widely investigated in previous research (Fukagata et al., 1998; Huber and Sommerfeld, 1998; L i et al., 1999; Hagiwara et al., 2002). Figure 3-1 gives key details for the two main experimental systems utilized in the current project: a Particulate Flow Loop and a Biomass Feeding System, in terms of the fluids and particles investigated, the relative particle concentrations, and the principal forces acting on the particles as they travel through the two devices. The key factors which can lead to blockage and the main factors influencing blockage are also listed. Possible modes of blockage are identified in Table 3-1, together with a \"Blockage Index\" used below to categorize the frequency and seriousness of blockages or partial blockages. The principal objectives of the particulate flow loop were to: (1) Demonstrate how blockage\/bridging occurs. (2) Perform experiments to measure the probability of blockage\/bridging as a function of particle size, shape, density and compressibility. Table 3-1. Proposed characterization of blockage type for Particulate Flow Loop Blockage Type Particulate Flow Loop Blockage Index 1 Stable blockage 1 2 Unstable blockage, blockage breaks up on its own within 5 s without intervention from the operator. 0.5 3 No blockage 0 Chapter 3. Particulate flow loop 55 Blockage and particle flow through constrictions Biomass feeding system Fluid: Air Particles: Biomass (sawdusts, hog fuel, etc) including both coarse parti des and fine powders Equipment: Screw feeder and hopper with pressurization Flow pattern: Dense phase Forces: Mechanical, gravitational, collisional, adhesive and cohesive forces. I Blockage type: Cohesive blockage, adhesive and cohesive forces are the main forces Important factors: Van der waals forces, moisture content, electrical charges, particle size and size distribution, constriction shape and dimensions. Particulate flow loop t Fluid: Water Particles: Rubber, plastic, glass, only coarse particles with minimum dimension > 1 mm Equipment: Transparent rectangular duct with constriction i Flow pattern: Relatively dilute Forces: Hydrodynamics, gravitational, collisional i Blockage type: Mechanical blockage Important factors: Particle size, size distribution, shape, particle surface friction, density, compressibility, strength; equipment geometry, constriction dimensions. Figure 3-1. Schematic of Biomass Granular Feeding Study Table 3-2. Reynolds number and water mean velocity for experimental tests in Particulate Flow Loop Water mean velocity, Um (m\/s) Reynolds number, Re, based on water mean velocity and hydraulic diameter of duct Reynolds number, Reh, based on water mean velocity and half-height of duct 0.02 730 650 0.04 1450 1300 0.06 2200 1960 0.08 2900 2610 0.1 3600 3260 0.2 7300 6520 0.3 10900 9780 0.4 14500 13000 0.5 18100 16300 0.6 21800 19600 0.7 25400 22800 0.8 29000 26100 0.9 32600 29400 1 36000 32600 1.1 39900 35900 1.2 43500 , ' 39100 Chapter 3. Particulate flow loop 56 3.2 Exper imenta l Set -up and M e t h o d o l o g y The test section is a rectangular duct (25.4 mm (wide) x 66 mm (high) x 600 mm (long)) with interchangeable narrow gaps of different shapes (ramp, circular, and rectangular constrictions). Upstream of the test section, there is a rectangular duct of length 5.18 m to ensure that the flow of the water and particles is fully developed before reaching the constriction. The Reynolds number based on the mean velocity of the conveying water and hydraulic diameter (DH = 0.0367 m) of the rectangular duct ranged from -730 to 44,000, as shown in Table 3-2. The corresponding mean velocity of the water was 0.02-1.2 m\/s. From previous work, the maximum development length for laminar flow in rectangular duct is Le l(DH Re) =0.09 (Goldstein and Kreid, 1967), whereas the development length is 140 times the hydraulic diameter for turbulent duct flow (Klein, 1981). Hence fully developed flow was achieved for turbulent flow (Re > 6000) in the rectangular duct in the present study. When Re < 2000, fully developed laminar flow could be achieved. For 2000 < Re < 6000, the flow was unable to reach the fully developed state. A screen with 0.71 mm openings is installed upstream to prevent particles from entering the pump (Model: LEESON 62RS1C-3.5, head: 15.2 m, capacity: 0.001 m3\/s). To ensure higher water flow rates and pressure, pressurized water . (<83 PSI g, <0.005 m7s) was introduced into the flow loop as shown in Figures 3-2 and 3-3. The rectangular duct is horizontal (confirmed with a level) with its centreline 39 mm above the laboratory floor. A plastic tank of capacity 300 litres containing a baffle separating the return flow region from the outlet region, is installed 2.64 m above the ground. Three vent holes on the upper plate of the duct (50, 350 and 1380 mm in front of the test section) are connected to plastic tubes to disengage air bubbles to ensure that only water and particles (two phases) pass through the constriction. Rubber and plastic particles (dimensions: 2 to 50 mm, density: 860-2100 kg\/m ) of different shapes (spheres, cylinders, disks and cuboids) were employed in the Chapter 3. Particulate flow loop 57 experiments, with water as the conveying fluid. Water absorption of all particles was very low (typically < 1 wt% over 24 hours, and < 0.03 w% within 24 hours for PTFE and polyethylene particles). Therefore, change of physical properties (e.g. density) of all particles during flow is neglected. Photos of the various particles are provided in Figure 3-4. Physical properties appear in Table 3-3. Shore A durometer measurements (see Table 3-3) indicate that rubber particles with durometer 40-70 in the present study had significant compressibility. These rubber particles could experience elastic deformation. The particle density was obtained by putting a known mass of particles into a graduated cylinder with water (for particles with densities greater than that of water) or alcohol (for particles with densities are less than for water and greater than for alcohol). By keeping the liquid volume at certain value (e.g. 500 ml) before and after the particles are added to the graduated cylinder and measuring the corresponding mass, the particle volume and hence particle density, were obtained. Particles Figure 3-2-1. Schematic of filter and particle recycle Figure 3-2-2. Schematic of Particulate Flow Loop Figure 3-2. Schematic of Particulate Flow Loop and filter and particle recycle system co Chapter 3. Particulate flow loop 59 Figure 3-3. Photo of Particulate Flow Loop Figure 3-4-1. Photo of silicon-rubber70-cuboid-l particles (7x7x3 mm) Chapter 3. Particulate flow loop 60 Figure 3-4-2. Photo of silicon-rubber70-cuboid-2 particles (9x9x3 mm) Figure 3-4-3. Photo of silicon-rubber70-cuboid-3 particles (15x5x3 mm) Chapter 3. Particulate flow loop 61 Chapter 3. Particulate flow loop 62 Chapter 3. Particulate flow loop Figure 3-4-8. Photo of ABS-cone-1 particles Figure 3-4-9. Photo of PTFE-rod-2 particles Chapter 3. Particulate flow loop 64 When valves 1, 2, 3 and 4 in Figure 3-2 were closed and valve 5 was opened, a number of particles (e.g. 200) entered through the union into the section (diameter: 51 mm) above valve 3. When the union was closed tightly and valve 3 was opened, particles fell into the flow loop. Valves 3 and 5 were then closed and valve 4 opened. Alternatively valves 1, 3 and 4 were open and valves 2 and 5 closed. The pressurized water from valves 1 and 3 carried particles into the loop. Valve 1 or 3 was shut off within 3 s to avoid disturbing the flow in the duct. Most particles in the present study had densities greater than that of water. Hence, once valve 3 in Figure 3-2 was opened, most particles fell immediately into the loop by gravity. However, there were commonly still 5-15% particles of irregular shape deposited along the duct, from the particle inlet section to the constriction, due to corners and irregular particle shapes. Therefore, slightly more particles were put into the particle inlet section than desired to ensure the expected number Table 3-3. Sequences of particles in Particulate Flow Loop Particle type Neo-rubber60-cuboid-0 ( 5 ) Neo-i'ubber60-cuboid-l Neo-rubber60-cuboid-2 Neo-rubber60-cuboid-3 Neo-rubber60-cuboid-4 Neo-rubber40-cuboid-1 Neo-rubber40-cuboid-2 Neo-rubber40-cuboid-3 Neo-rubber40-cuboid-4 Nitril-rubber60-cuboid-l Nitril-rubber60-cuboid-2 Nitril-rubber60-cuboid-3 Nitril-rubber60-cuboid-4 Silicon-rubber70-cuboid-0 Silicon-rubber70-cuboid-1 Particle density (kg\/m3) 1445 1445 1445 1445 1445 1080 1080 1080 1080 1517 1517 1517 1517 1610 1610 Shape Dimensions (mm) Cuboid 5(1) x 5(w) x3 (h) Cuboid 7(1) x 7(w) x3 (h) Cuboid 9(1) x 9(w) x3 (h) Cuboid 15(l)x5(w)x3(h) Cuboid 25(1) x 3(w) x3 (h) Cuboid 5(1) x 5(w) x3 (h) Cuboid 9(1) x 9(w) x3 (h) Cuboid 15(1) x 5(w) x3 (h) Cuboid 25(1) x 3(w) x3 (h) Cuboid 5(1) x 5(w) x3 (h) Cuboid 7(1) x 7(w) x3 (h) Cuboid 9(1) x 9(\\v) x3 (h) Cuboid 25(1) x 3(w) x3 (h) Cuboid 5(1) x 5(w) x3 (h) Cuboid 7(1) x 7(w) x3 (h) D v ( , ) (mm) 5.23 6.55 7.74 7.55 7.55 5.23 7.74 7.55 7.55 5.23 6.55 7.74 7.55 5.23 6.55 D s ( 2 ) (mm) 2.96 3.81 4.64 4.64 5.03 2.96 4.64 4.64 5.03 2.96 3.81 4.64 5.03 2.96 3.81 Sphericity Aspect ratio ( 3 ) D\"shoreA) 0.78 0.74 0.7 0.66 0.56 0.78 0.7 0.66 0.56 0.78 0.74 0.7 0.56 0.78 0.74 1.7 2.3 8.3 1.7 3 5 8.3 1.7 2.3 1.7 2.3 60 60 60 60 60 40 40 40 40 60 60 60 60 70 70 Q 5= -a aT -i -a a o' c o o o -a Particle type Silicon-rubber70-cuboid-2 Particle density (kg\/m3) 1610 Shape Cuboid Dimensions (mm) 9(1) x 9(w) x3 (h) D v ( 1 ) (mm) 7.74 D s ( 2 ) (mm) 4.64 Sphericity Aspect ratio ( 3 ) 0.7 3 Durometer ( (Shore A) 70 Silicon-rubber70-cuboid-3 1610 Cuboid 15(1) x5(w) x3 (h) 7.55 4.64 0.66 5 70 Silicon-rubber70-cuboid-4 1610 Cuboid 25(1) x 3(w) x3 (h) 7.55 5.03 0.56 \u2022 8.3 70 ABS-Cone-1 1020 Cone (j) 5-(j) 3 x 33 9.3 5.9 0.62 8.3 100 PTFE-Rod-1 2040 \u2022 Cylinder (b 5 x 10 7.2 3.7 0.83 2 100 PTFE-Rod-2 2040 Cylinder 4> 5 x 25 9.8 5.7 0.7 5 100 Polyethylene-red-1 1019 Sphere (j) 11.5 11.5 11.5 1.0 1 100 Polyethylene-red-2 926 Sphere <|) 11.5 11.5 11.5 1.0 1 100 Polyethylene-yellow-1 866 Sphere <p 6.4 6.4 6.4 1.0 1 100 3 Notes: (1) Diameter of sphere of equivalent volume. (2) Diameter of sphere of equivalent surface area. (3) Ratio of maximum to minimum dimension. (4) Shore Hardness, using either the Shore A or Shore D scale, is the preferred method for characterizing the hardness of rubbers\/elastomers and is also commonly used for 'softer' plastics. The Shore A scale is used for 'softer' rubbers, while the Shore D scale is used for 'harder' ones. The shore A hardness is the relative hardness of elastic materials such as rubber or soft plastics. It is determined with an instrument called a Shore A durometer. If the indenter completely penetrates the sample, a reading of 0 is obtained, and if no penetration occurs, a reading of 100 results. The reading is dimensionless. High values correspond to high hardness. The hardness of relatively hard plastic particles in present study is approximately equal to 100. (5) Neo denotes neoprene rubber. Chapter 3. Particulate flow loop 67 of particles passing through the constriction. A l l particles were re-used after being recovered from the fdter system. Swarms of particles were investigated to elucidate the influence of particle interactions with each other and with the gaps. Table 3-4. Main specifications of digital video camcorder Item Comments Model Canon x L l Frames per second Set at 30 Image size 720 x 480 pixel image is obtained Tape format Videocassettes bearing the Min iDV mark Lens mount X L interchangeable lens system (16x zoom (supplied): f\/1.6-2.6, 5.5-88 mm) Focusing system TTL autofocus, manual focusing possible Minimum focusing distance 20 mm on maximum wide angle; telephoto end: 1 m Maximum shutter speed 1\/15,000 second Recommended illumination More than 100 lux Filter diameter 72 mm (XL lens) Viewfinder 18 mm, colour L C D (approx. 180,000 pixels) Five differential pressure transmitters (Endress+Hauser, Deltabar S PMD 230, -0.25-0.25 mHiO) were installed to measure the pressure variation along the test section. An electromagnetic flowmeter (Endress+Hauser, promag 33) measured the mean velocity of the water. The flow visualization system included a digital video camcorder (Canon x L l ) , whose details are listed in Table 3-4), as well as a mirror and three 100 W lamps. The camcorder was connected to the serial port of a computer (Pentium III, 601 MHz, 128 M B of RAM). Information from every frame, including the time, was stored on the hard disk. During visualization, the laboratory lights were turned off so that the surroundings were dark. The three light bulbs were adjusted to a suitable brightness to give clear pictures on the viewfinder. A Chapter 3. Particulate flow loop 68 shutter speed of 1\/1000 s was employed. The camcorder was used not only to capture images of particles blockage, but also to record particle trajectories. It captured simultaneous images from the front and top surfaces of the test section, aided by a mirror fixed at 45\u00b0 to the horizontal to provide a top view. The video camcorder, electromagnetic flowmeter and all pressure sensors were connected to the data acquisition system. Particle velocities were determined by timing the passage of particles between grid lines inscribed on the test section. The refractive index, n, (relative to air at 20\u00b0C and 101.3 kPa for a wavelength of 589.3 nm) of Plexiglas is 1.491, while that of water is 1.332. Since the camcorder was directly in front of, and at some distance from, the area of interest, the difference in refractive indices between the water and Plexiglas was neglected. The flow pattern data were stored on videotape for later analysis. With image analysis software (Ulead, Pinnacle Systems DV300-Adobe Premiere LE 4.2, Adobe Photoshop 6.0 and Matlab 6.1), the data were transferred to digital values, which could be handled by the computer. Image analysis involved: (1) Grabbing a frame from the videotape and digitizing; (2) Minimization of background noise; (3) Sharpening of images; (4) Correcting the dimensions with the aid of the grid lines on the test section, and identifying the relationship between the pixel dimensions in the images and actual dimensions; (5) Identifying the threshold (starting point) of particle motion. (6) Identifying the edge of the particles in the images and finding the x, y and z coordinates of the particle centroid; Chapter 3. Particulate flow loop 69 (7) Computing of the particle position and velocity at each time step (1\/30 s); the number density and volume fraction of particles in each zone of an image could also be calculated. The particle number density is the number of particles per unit volume of the test section 0.28 (L) x 0.0254 (W) x 0.066 (H) m just upstream of the constriction, whereas the volume fraction of particles is the total particle volume divided by the volume of the test section just upstream of the constriction. From image analysis, the number of particles entering and leaving the test section in each frame can be counted, so that the number of particles in the test section can be calculated. The volume of particles in the test section can be obtained from the number of particles because the volume of every particle is known. The volume of clusters in the test section is also based on particle number analysis. A schematic of the experimental flow loop appears in Figure 3-2. Drawings of the ramp, circular and rectangular test sections are included in Figures 3-5 to 3-8 and Table 3-5. The surface of all blocks, including ramp, rectangular and circular blocks, were made smooth (roughness < 0.05 mm) during fabrication. Water O r 12.5 mm 66 mm Corner upstream constriction O Corner downstream constriction o 40 mm Figure 3-5. Rectangular constriction-1 with 25.4 (W) x 12.5 (H) mm gap Chapter 3. Particulate flow loop 70 66 mm Figure 3-6. Circular constriction-1 with 25.4 (W) x 12.5 (H) mm gap Comer upstream constriction 61 mm Figure 3-7. Ramp constriction-1 with 25.4 (W) x 12.5 (H) mm gap Side View Fronl View U 25.4 mm Figure 3-8. Ramp constriction-4 with 12.5 (W) x 12.5 (H) mm gap Chapter 3. Particulate flow loop 71 Table 3-5. Configurations of various constrictions Constriction No. Block Dimensions ( 1 ) Minimum Gap Dimensions ( 2 ) Constriction Shape Ramp Constriction -1 (Gap between two wedges) Length: 61 mm Maximum Height: 26.8 mm Width: 25.4 mm Angle: 23.9\u00b0 Height: 12.5 mm Width: 25.4 mm Ramp Constriction -2 (Gap between two wedges) Length: 71 mm Maximum Height: 23.6 mm Width: 25.4 mm Angle: 18.4\u00b0 Height: 18.8 mm Width: 25.4 mm Ramp Constriction -3 (Gap between two wedges) Length: 61 mm Maximum Height: 20.3 mm Width: 25.4 mm Angle: 18.4\u00b0 Height: 25.4 mm Width: 25.4 mm Ramp Constriction -4 (3 dimensional wedge gap) Length: 61 mm; Maximum Height: 23.6 mm Width: 25.4 mm Angle: 18.4\u00b0 Height: 12.5 mm Width: 12.5 mm ( 3 ) Circular Constriction -1 (Gap between two half-cylinders) Diameter: 26.8 mm Width: 25.4 mm Maximum Height: 12.5 mm Width: 25.4 mm Circular Constriction -2 (Gap between two half-cylinders) Diameter: 20.3 mm Width: 25.4 mm Maximum Height: 25.4 mm Width: 25.4 mm Rectangular Constriction -1 (Gap between two rectangular blocks) Length: 40 mm Height: 26.8 mm Width: 25.4 mm Height: 12.5 mm Width: 25.4 mm Rectangular Constriction -2 (Gap between two rectangular blocks) Length: 40 mm Height: 20.3 mm Width: 25.4 mm Height: 25.4 mm Width: 25.4 mm Rectangular Constriction -3 (Gap between two rectangular blocks) Length: 20 mm Height: 26.8 mm Width: 25.4 mm Height: 12.5 mm . Width: 25.4 mm Notes: (1)(2) Length is the dimension in the streamwise direction; height is dimension in vertical direction (at right angles to the flow direction); width is dimension in spanwise direction. (3) See Figure 3-8 to see how thinner width was achieved. Chapter 3. Particulate flow loop 72 3.3 Exper imenta l Resu l ts a n d D i s c u s s i o n 3.3.1 Observations of particle-liquid flows The trajectories and velocities of small numbers of particles passing through the constrictions were visualized. Spherical particles of low density (e.g. polyethylene-yellow-1 in Table 3-3) were easily transported and were unlikely to block the constriction. These particles were transported along at the top of the duct due to buoyancy and lift forces, and there were always some particles trapped by bubbles sticking to the inner wall of the duct. When many particles passed through the constriction, particle-particle interactions became more important. Five polyethylene-red-2 particles (see Table 3-3) were tested in the present study. If these particles were very close to each other, they clearly interacted and experienced behaviour similar to what has been called \"drifting\", \"kissing\" and \"tumbling\" in the literature (Fortes et al., 1987; Hu et al., 2004) when passing through the constrictions. The wake produced by one particle can have an important effect on the motion of a nearby particle, even when the two particles do not collide with each other. Small particles with density close to that of water (e.g. polyethylene-yellow-1) or denser than water (e.g. glass beads of 2 mm diameter), were easily trapped in the vortex behind the constriction. The motion of particles downstream of the constriction depends on many factors, such as fluid velocity, upstream turbulence level, constriction dimensions and shape, particle properties (e.g. density, dimensions and shape). Particles near the wall beyond the constriction risk being captured by the vortex. Some particles (e.g. polyethylene-red-2 and polyethylene-yellow-1) experienced a relatively stationary state for ~3-4 s near the wall downstream of the Chapter 3. Particulate flow loop 73 constriction before being trapped by the vortex or travelling downstream. Fluid velocity and turbulence level upstream of the constriction, constriction configurations and particle properties together determine whether or not the particles proceed directly downstream. Larger particles with density greater than that of water were not readily trapped by the vortex because of their larger dimension and increased inertia. These particles were also more likely to collide with the block surface. Such collisions led to much more rotation, at the same time causing abrupt changes in particle trajectory and velocity. The larger or heavier the particle, the greater the chance of it colliding with the wall surface because of inertial effects. When Um < 0.35 m\/s, non-spherical particles of density greater than that of water (e.g. Silicon-rubber70-cuboid-0, in Table 3-3) were difficult to transport in the duct because of sedimentation. For 0.35< Um <0.55 m\/s, non-spherical particles were easier to move (creep and saltation), with some piling upstream of the constriction and others passing through the gap almost one by one. Blockage was unlikely for this case. For 0.55< Um < 1.2 m\/s, more and more heavier non-spherical particles were transported and lifted vigorously (saltation and suspension), increasing the probability of different particles passing through the constriction simultaneously, thereby increasing the probability of blockage. For the conditions of the present study, 3 to 10 non-spherical particles were sufficient to block the constriction if the ratio of particle maximum dimension to constriction minimum dimension > 0.4. On the other hand, as Um increased, blockage was less likely to occur and was more readily broken up, especially for small-particle-blockage in the constriction, because of the increased particle inertia, increased drag and increased pressure gradient immediately upstream of the constriction. The blockage Chapter 3. Particulate flow loop 74 probability depended on the interactions of the fluid, particles and constriction. Re>29,000 or a water mean velocity > 0.8 m\/s was required for PTFE-Rod-02 particles to move forward smoothly along the bottom of the duct (similar to creep). These particles were also more likely to block the constriction at high Re. Ramp constriction\u20143 was relatively easy for particles to pass through because of its smooth profile and large gap dimensions, while the other constrictions (e.g. rectangular constriction-1 and ramp constriction-4) created a challenge because of their steep slope and small gap dimensions, and the vortex formed immediately downstream of the constriction. In the runs described below, all experiments were performed at least 20 times for the same particles and same experimental conditions. The blockage index (see Table 3-1) is the average weighted value. The particle number density and volume fraction are important factors affecting blockage in the constriction. They were not identical in each test, even when the same particles and experimental conditions were employed. On the other hand, the differences were small for the same experimental procedures (e.g. particle injection method) with the same particles and same experimental conditions. Particle number densities were in the range 8000 to 4xl0'7m 3, while particle volume fractions ranged from 0.001 to 0.1. 3.3.2 Effect of aspect ratio on blockage for cuboidal particles These tests involved particles of Silicon-rubber70-cuboid-2, Silicon-rubber70-cuboid-3, Silicon-rubber70-cuboid-4, Neo-rubber40-cuboid-4 and Neo-rubber60-cuboid-4. 200 particles were released each time. The duct Reynolds number was Re=29700 with the water mean velocity being 0.8 m\/s and rectangular constriction-1 (25.4 (W) x 12.5 (H) x 40 (L) mm). A l l of Chapter 3. Particulate flow loop 75 these particles were cuboids, with almost the same equivalent volume diameter (7.74 mm for 9 x 9 x 3 mm, and 7.55 mm for both the 1 5 x 5 x 3 and 25 x 3 x 3 mm particles). The maximum dimensions of some particles (e.g. 15 x 5 x 3 and 25 x 3 x 3 mm particles) exceeded the minimum gap dimension (i.e. 12.5 mm). The experiments indicated that cuboidal silicon-rubber particles of large aspect ratio (e.g. 8.3 for 25 x 3 x 3 mm Silicon-rubber70-cuboid-4 particles) were not easily transported by water. Some particles always deposited in the duct or blocked the gap instead of passing through the constriction. They were more likely to block compared to particles of smaller aspect ratio (silicon-rubber70-cuboid-3 15 x 5 x 3 mm particles). On the other hand, particles of smaller aspect ratios (e.g. 9 x 9 x 3 mm silicon-rubber70-cuboid-2 particles) were generally harder to transport than those of larger aspect ratio (e.g. 1 5 x 5 x 3 mm silicon-rubber70-cuboid-3 particles) as shown in Figures 3-9 and 3-10. It seems that there should be an optimum aspect ratio for particles with the same or similar equivalent volume diameter to reduce the blockage tendency. 7 x 7 x 3 mm silicon rubber particles of 70 durometer did not block the rectangular constriction, although some of these particles always deposited immediately upstream of the constriction. Irregular-shape particles readily deposited along the duct, low water mean velocities (e.g. < 0.6 m\/s) were unable to transport these particles. Hence higher water mean velocities were employed (> 0.8 m\/s) to avoid deposition. Even so, a small number of particles deposited along the duct, especially in front of the constrictions. If blockage occurred in the constriction, as shown in Figure 3-11, the particles retained in front of the constriction were counted. Upstream deposition is not considered to constitute blockage. Figure 3-12 also shows Chapter 3. Particulate flow loop 76 the effects of particle size and shape on blockage, demonstrating that larger particles of more irregular shapes (larger aspect ratios and smaller sphericity) are generally more likely to become lodged in a given constriction. 3 5 O TO 3 0 a> 2 5 o O 2 0 JD 15 0) ro \"c <u o it> 3, 1 2 3 4 5 6 Particle type 1: Si l icon-rubber70-cuboid-2 4: Neo-rubber40-cuboid-4 2: Si l icon-rubber70-cuboid-3 5: Neo-rubber60-cuboid-4 3: Si l icon-rubber70-cuboid-4 6: Nitri l-rubber60-cuboid-4 Figure 3-9. Percentage of blocked particles of hardness 40, 60, 70. (200 particles released each time, Re= 29700, rectangular constriction-1). Bars show 95% confidence intervals. For properties of particles and constrictions, see Tables 3-3 and 3-5. 3 4 Particle type 1: Si l icon-rubber70-cuboid-2 4: Neo-rubber40-cuboid-4 . 2: Si l icon-rubber70-cuboid-3 5: Neo-rubber60-cuboid-4 3: Si l icon-rubber70-cuboid-4 6: Nitri l-rubber60-cuboid-4 Figure 3-10. Blockage index comparison for different particles of hardness 40, 60 and 70. (200 particles released each time, Re= 29700, rectangular constriction-1).). Bars show 95% confidence intervals. For properties of particles and constriction, see Tables 3-3 and 3-5. . Chapter 3. Particulate flow loop Figure 3-11. Particles (Silicon-rubber70-cuboid-4) blocked in Rectangular constriction-1 Re=29700, Converging Ramp constriction-4 Re=38100, Rectangular constriction-1r Cuboid Particles 1: Sil icon-rubber70-cuboid-0 2: Silicon-rubber70-cuboid-1 3: Sil icon-rubber70-cuboid-3 Figure 3-12. Effect of particle size and shape on blockage. (Injected particles each time=400, 200, 200 for Silicon-rubber70-cuboid-0,l,3). Bars show 95% confidence intervals. At < 0.13 level, the differences of the population means differ significantly from the test difference (Null Hypothesis: difference of two population means is 0), two samples t test. For properties of particles and constrictions, see Tables 3-3 and 3-5. Chapter 3. Particulate flow loop 78 3.3.3 Effect of particle density on blockage Neo-rubber60-cuboid-4 and Nitril-rubber60-cuboid-4 have slightly different particle densities, as shown in Table 3-3. This did not appear to cause an appreciable difference in blockage index or in deposition upstream of the constriction as shown in Figures 3-9 and 3-10. Denser particles are expected to deposit more easily than light ones for the same geometry and dimensions, and the same experimental conditions. Particles of density less than water (e.g. polyethylene-red-2 and polyethylene-yellow-1 particles) were transported readily, with no deposition along the duct. However, they were more likely to be trapped in the corners upstream and downstream of the constriction. Moreover, lower density corresponded to greater flexibility, making it easier for particles to adjust their orientations, velocities and positions, thereby reducing the probability of blockage. The blockage of particles of density less than that of water was not investigated in the present study. 3.3.4 Effect of particle stiffness on blockage Neoprene rubber with 40 durometer was easily transported through the gap due to its low particle density. Stable blockages were less likely for soft rubber particles due to their softness (i.e. low bending\/flexural strength), large compressibility (as defined in Chapters 2 and 6), and large flexibility (discussed below in this Chapter) than for relatively hard particles, as shown in Figures 3-9 and 3-10. Particle number density and solid volume fraction of particles in the above tests are shown in Table 3-6. Chapter 3. Particulate flow loop 79 Table 3-6. Particle number density and solid volume fraction of particles PND(l\/mm3)and SVF (2) Lower limit Upper limit Mean Passing time (3) (s) Silicon-rubber70-cuboid-1 (7x7x3mm) PND (mm-3) 1.28E-05 2.56E-04 1.34E-04 5-9 SVF (-) 1.88E-03 3.76E-02 1.97E-02 5-9 Silicon-rubber70-cuboid-2 (9x9x3mm) PND (mm-3) 1.28E-05 2.56E-04 1.34E-04 7-11 SVF (-) 3.11E-03 6.21E-02 3.26E-02 7-11 Silicon-rubber70-cuboid-3 (15x5x3mm) PND (mm-3) 1.28E-05 2.56E-04 1.34E-04 6-10 SVF (-) 2.8.8E-03 5.75E-02 3.02E-02 6-10 Silicon-rubber70-cuboid-4 (25x3x3mm) PND (mm-3) 8.52E-06 . 1.28E-04 6.83E-05 8-16 SVF (-) 1.92E-03 2.88E02 1.44E+02 8-16 Neo-rubber40-cuboid-4 (25x3 x3mm) PND (mm-3) 8.52E-06 1.07E-04 5.78E-05 5-7 SVF (-) 1.92E-3 2.4E-02 1.30E-02 5-7 Neo-rubber60-cuboid-4 (25x3 x3mm) PND (mm-3) 8.52E-06 1.28E-04 6.83E-05 6-10 SVF (-) 1.92E-3 2.88E-02 1.54E-02 6-10 Nitril-rubber60-cuboid-4 (25x3 x3mm) PND (mm-3) 8.52E-06 1.28E-04 6.83E-05 6-10 SVF (-) 1.92E-3 2.88E-02 1.54E-02 6-10 Notes: (1) Number of particles released every time = 200, Re= 29700. (2) PND denotes particle number density (mm\"3), SVF denotes solid volume fraction. (3) Time for all particles to pass through the view section (as shown in Figure 3-19 below). 3.3.5 Effect of constriction type and dimensions on blockage To investigate the influence of constriction type, clusters of 160 conical ABS-cone-1 particles were released with Re=38,100 (Um =1.05 m\/s) to reach ramp constriction-4 (12.5 (W) x 12.5 (H) mm) and rectangular constriction-1 (25.4 (W) x 12.5 (H) mm). Experiments were also conducted with the same two constrictions with the release of 220 silicon-rubber-cuboid-0 particles. The smaller converging constriction showed a greater tendency to block than the larger rectangular constriction, as shown in Figure 3-13. For Ramp-constriction-4, the smaller dimension in the spanwise direction than for Rectangular constriction-1 led to more particle collisions with each other and with the gap, enhancing the probability of blockage. Chapter 3. Particulate flow loop 80 1.0 0.8 x \"g 0.6 <D D ) CD \u2022g 0.4 O CD 0.2 0.0 \"J ABS-cone-01 7J Silicon-rubber70-cuboid-0 1 2 Constrictions 1-Ramp constriction-4 2-Rectangular constriction-1 Figure 3-13. Effects of constriction type and dimensions on blockage for Re=38100 for 160 and 220 injected particles for ABS and silicon particles, respectively. Bars show 95% confidence intervals. At the 0.001 level, the differences of the population means differ significantly from the test difference (Null Hypothesis: difference of two population means is 0), two samples t test. For properties of particles and constrictions, see Tables 3-3 and 3-5. Ramp constriction-1 and Rectangular constriction-1 had the same minimum gap dimension, i.e. 25.4(W) x 12.5(H) mm. 200 Neo-rubber60-cuboid-4 particles of dimensions 25 x 3 x 3 mm were released into the water flow at Re=29,700 ( Um =0.8 m\/s). The maximum particle dimension (25 mm) exceeded the minimum dimension of the gap (12.5 mm). Due to the abrupt change of the.dimension of rectangular constriction-1, water and particles also abruptly changed their velocities and directions of motion, promoting collisions with the wall and with each other, thereby increasing likelihood of blockage. The smooth convergence of ramp-constriction-1 reduced the probability of particle collisions and also provided more space for particles to migrate and disentangle before reaching the minimum cross section of the gap (see Figure 3-14). Chapter 3. Particulate flow loop 81 x 03 TJ _C <D ro o o CD 1.0 0.9 0.8 0.7 0.6 0.5 0.4 0.3 0.2 0.1 0.0 1 2 Cons t r i c t i ons 1-Rectangular constriction-1 2-Ramp constriction-1 Figure 3-14. Constriction type and dimension effect on blockage for Re= 29700.(200 Neo-rubber60-cuboid-4 particles injected each time). For properties of particles and constrictions, see Tables 3-3 and 3-5. 3.3.6 Effect of Reynolds number on blockage The effect of water velocity and Reynolds number over limited ranges can be seen by comparing results for conical ABS-01 and cuboidal silicon-rubber70-cuboid-3 particles with the rectangular (abrupt) and ramp constrictions. Figure 3-15 indicates that a larger Reynolds number (i.e. greater water mean velocity) generally caused more blockage. This appears to be because higher Reynolds number tends to cause more particles to pass through the constriction simultaneously, increasing the probability of particle collisions with each other and with the gap, in turn increasing the probability of jamming and blockage. For the Reynolds number range covered in the present study, smaller Reynolds numbers led to deposition along the duct, whereas larger Reynolds numbers increased the blockage tendency for the range covered. Chapter 3. Particulate flow loop 82 X CD T3 CD D ) CO o o m 1.0 h 0.8 0.6 0.4 h 0.2 0.0 \\-ABS-cone-1 with ramp constriction-4 ] Silicon-rubber70-cuboid-3 with rectangular constriction-1 1 2 3 Reynolds number based on water mean velocity 1: Re=38100, 2: Re=29700, 3: Re=21800 Figure 3-15 Effect of Reynolds number on blockage for release of 160 and 200 particles. (ABS and silicon rubber, respectively). Bars show 95% confidence intervals. At the 0.05 level, the differences of the population means differ significantly from the test difference (Null Hypothesis: difference of two population means is 0), two samples t test. For properties of particles and constrictions, see Tables 3-3 and 3-5. 3.3.7 Effect of ratio of maximum particle dimension to minimum gap dimension Tests were carried out for particles of Silicon-rubber70-cuboid-0, -1 and -3, with release each time of 400, 200 and 200 particles, respectively. With rectangular constriction-1 (25.4 (W) x 12.5 (H) x 40 (L) mm) and ramp constriction-4 (12.5(W) x 12.5 (H) mm), Figure 3-16 shows that larger ratios of maximum particle dimension to minimum constriction dimension reduced the ability of particles to pass through the constriction, especially for ramp constriction-4, which did not provide as much space as rectangular contriction-1 for particles to migrate in the spanwise direction. As expected, larger particle size increased the propensity to block. Chapter 3. Particulate flow loop 83 1 R e = 2 9 7 0 0 , R a m p const r ic t ion-4 \u2022 R e = 3 8 1 0 0 , R e c t a n g u l a r const r ic t ion-1 i l i con - rubber70 -cubo id -0 i l i con- rubber70-cubo id -1 i l i con- rubber70-cubo idT3 1 2 3 ( r a t i o=0 .4 ) ( r a t i o = 0 . 5 6 ) ( r a t i o = 1 . 2 ) R a t i o o f m a x i m u m d i m e n s i o n o f p a r t i c l e s t o m i n i m u m d i m e n s i o n o f c o n s t r i c t i o n Figure 3-16. Effect of ratio of maximum particle dimension to minimum constriction dimension on blockage for cuboidal rubber particles of different sizes. (Number of particles released each time=400, 200, 200 for silicon-rubber70-cuboid-0, 1, 3, respectively). Bars show 95% confidence intervals. At < 0.09 level, the differences of the population means differ significantly (Null Hypothesis: difference of two population means is 0), two samples t test. For properties of particles and constrictions, see Tables 3-3 and 3-5. 3.3.8 Effect of particle compressibility and flexibility on blockage To investigate the influence of particle compressibility and flexibility, 160 conical ABS-cone-1 and cuboidal Silicon-rubber70-cuboid-3 particles were released each time with Re=29,700 (Um=0.8 m\/s) to reach ramp constriction-4 (12.5 (W) x 12.5 (H) mm). As mentioned above, when these particles collided with each other and with the gap, they tended to stick together due to compressibility and to increase the blockage probability. Neoprene rubber particles with 40 durometer were more easily transported along the duct due to their low density, and blockages were more easily dislodged due to their softness, flexibility (discussed below), and large compressibility than relatively hard particles, as shown in Figures X 0) \"D a> O ) ro o o m 1.0 0 .9 0 .8 0 .7 0 .6 0 . 5 0 .4 0 . 3 0 .2 0.1 0 .0 1: S 2: S 3: S Chapter 3. Particulate flow loop 84 3-9 and 3-10. Particles with low bending\/flexural strengths and low particle densities passed more easily through constrictions, and when they did block, the jam was more likely to break up. Compressible particles with relatively higher bending strengths and greater particle densities (e.g. silicon rubber particles with 70 durometer) caused more stable blockages. Incompressible particles of relatively low density (e.g. ABS-cone-1) were more likely to pass through constrictions over a certain Re range (e.g. 26,000<Re<38,000 in the present study). Increased Re and intensive particle collisions increased the probability of blockage. Flexibility, F, is defined as the reciprocal of fibre stiffness in bending, S, which is the product of elastic modulus, E, and the area moment of inertia, \/ , of the fibre (Kumar, 1990). This can also be used to quantify the ability for particles to pass through a constriction. Thus F = - = \u2014 (3-1) S EI The elastic modulus E is defined by a = Ee (3-2) where a and e are the stress and strain, respectively. Compressibility is inversely proportional to elastic modulus (i.e. E), which indicates that large compressibility leads to large flexibility for equal area moments of inertia. The larger the flexibility, the easier it is for particles to pass through constrictions. We see that soft rubber (e.g. 40 durometer) has a small E relative to hard rubber (e.g. 70 durometer). For cuboid particles, the mass moment of inertia (Ih) and area moment of inertia (Iw) are given, respectively, by rh=\u2014m(w2+l2), \/ w = \u2014 (3-3) * 12 12 Chapter 3. Particulate flow loop 85 where m is the particle mass, and h, w, and \/ are the height, width and length of the cuboidal particle. Ih is the mass moment of inertia about the axis in the h direction which passes through the particle centroid. Mass moment of inertia is the rotational analogue to mass. Large mass and particle dimensions lead to large mass moments of inertia. We assume that the object has uniform density. The larger the area moment of inertia, the less the particle will bend. From the particle flexibility point of view, (1) For the same rubber, smaller particles lead to smaller area moments of inertia and greater flexibility, as indicated in Figures 3-9 and 3-10. (2) For the same particle dimensions, softer particles (e.g. 40 durometer), smaller E leads to larger flexibility causing the behaviour indicated in Figures 3-9 and 3-10. (3) For particles of different materials, flexibility is a trade-off between area moment of inertia, elastic modulus and other particle properties (see below), as indicated in Figure 3-17. ABS-cone-1 and Silicon-rubber70-cuboid-3 have similar dimensions and shapes, but the latter have greater density and smaller elastic modulus. The larger density tends to increase the mass moment of inertia, whereas the smaller elastic modulus increases the flexibility. From Figure 3-17, the Silicon-rubber70-cuboid-3 particles demonstrated a larger blockage tendency than ABS-cone-1. The Silicon-rubber70-cuboid-3 particles bent more easily than the ABS-cone-1 particles, so that the former should pass through the constrictions more easily than the latter. However, the experimental results did not agree with this prediction. Note that silicon-rubber70-cuboid-3 particles with significant compressibility tend to stick together after collision with each other and\/or with the wall. The resulting \"agglomerate\" could not be as readily broken up by Chapter 3. Particulate flow loop 86 hydrodynamic forces as for the soft rubbers (e.g. 40 durometer), leading to enhanced blockage. Another major reason for the larger blockage tendency for the Silicon-rubber70-cuboid-3 particles was their large particle density, which increases the mass moment of inertia, reducing flexibility. ABS-cone-1 particles can easily adjust their orientation, position and velocity, while silicon-rubber70-cuboid-3 particles cannot adapt to fluid acceleration as easily as the ABS-cone-1 particles, thereby increasing the blockage probability. In fact, the ABS-cone-1 particles distributed across the cross-section of the duct more uniformly than the silicon-rubber70-cuboid-3 particles due to the effects of particle density as they approached the constrictions. The former underwent intense particle collision with each other and with the wall, increasing the probability of stall. D \"O C CO c n ns o o CO 1.0 0.9 0.8 0.7 0.6 0.5 0.4 0.3 0.2 0.1 0.0 t 1 2 1: Silicon-rubber70-cuboid-3 2: ABS-cone-1 Figure 3-17. Effect of compressibility of particles on blockage for 160 ABS and rubber particles. Re= 29700, ramp constriction-4). Bars show 95% confidence intervals. At the 0.001 level, the differences of the population means differ significantly (Null Hypothesis: difference of two population means is 0), two samples t test. For properties of particles and constrictions, see Tables 3-3 and 3-5. Chapter 3. Particulate flow loop 87 3.4 Horizontal Motion of a Neutrally Buoyant Spherical Particle Particle motion in the vicinity of a constriction is complex, especially for irregular particles. Motion depends on the fluid velocity, upstream turbulence level, constriction dimensions and shape, particle density, particle dimensions and particle shape. Since particle motion is mainly in the streamwise direction, a single neutrally buoyant polyethylene-red-1 spherical particle (see properties in Table 3-3) was employed to investigate the horizontal motion. Vertical motion and rotation of the particle are difficult to analyze. Particles of density greater than water experienced complicated changes in position, velocity and orientation. Abrupt changes in direction, velocity and orientation caused inter-particle or particle-wall collisions, leading to more blockage. The neutrally buoyant spherical polyethylene-red-1 particle was prepared by first drilling a small hole (1 mm diameter) radially into a polyethylene-red-2 particle to a depth slightly beyond the centre. Metal bead(s) or wires were then inserted into the hole and pushed to the centre. The hole was then plugged with glue (silicon sealant of density slightly less than that of water) so that the surface of the glue was flush with the particle surface as shown in Figure 3-18. The resulting particle then had virtually the same density as water (i.e. p =1019 vs pw =998 kg\/m ). Drilled Hole Later Filled with Glue Metal Bead Figure 3-18. Production of neutrally buoyant spherical particle Chapter 3. Particulate flow loop 88 In these tests, ramp constriction-3 was first employed (see Table 3-5). The length of the ramp in the streamwise direction was 61 mm, while the maximum height of each ramp block was 20.3 mm, and the width in the spanwise direction was 25.4 mm for a minimum gap dimension of 25.4 x 25.4 mm. The mean water velocity was 0.243 m\/s, giving a Reynolds number based on hydraulic diameter of the duct of 8900, indicating that the flow was turbulent. It was assumed that: o The neutrally buoyant particle moved along the centreline of the test section. Only the horizontal direction is considered. Drag, added mass and fluid acceleration are taken into account, whereas the effects of gravity, buoyancy, lift and the Basset history term are ignored. The centreline water velocity is considered to be the local fluid velocity affecting the particle, o The centreline water velocity upstream of the test section was obtained from previous study as discussed below. o The centreline water velocity distribution is estimated from the pressure distribution along the constriction by the Navier-Stokes equation with viscous effects neglected. o The coordinates are shown in Figure 3-19. The origin, point O, is at the geometric centre of the duct cross-section. The horizontal coordinate x is positive in the streamwise direction, while vertical coordinate y is positive in the upward direction; z is the spanwise direction as shown. o The temperature is constant at 20 \u00b0C. 3.4.1 Centreline water velocity It is reasonable to use the arithmetic mean ratio of Ucfd I Um provided by Gavrilakis (1992) and Kim et al (1987), i.e. Ucfd IUm =1.25, as the ratio of the centreline velocity to mean velocity Chapter 3. Particulate flow loop 89 for turbulent flow through a rectangular duct (aspect ratio \/?=0.38) in the present study. Note that this is much less that the ratio of 1.92 obtained for steady fully developed laminar rectangular\/square duct flow from the relationship given by McComas (1967). Hence, the centreline water velocity upstream of the test section is Uc = Ucfd =0.243 x 1.25= 0.3 m\/s. y(HJ \" \" 0 \/ \/ \u20ac. 1 x CU Water |_ -\u20144-15mm O 0 \u00a3 45 mm H \u2022 ^ C ( l rt irf i w <j> -15mm f * 50 mm\u2014\u20141 m 91 mm H U U 1 1 II 1 1 -\u201428 m m \u2014 ' V View Section: 182 mm A Figure 3-19. Schematic of view section with ramp constriction-3 The continuity and momentum equations (2-D) of the incompressible Newtonian fluid are (Hu, 1996; Marghzar et al., 2003): dx - = 0 (Continuity equation) (3-4) dU, d(U,U ) dh BP d ,dU, dU p + p J\u2014 = -p g + ju ( '- + J-) dt dxj dxj dxf ' dXj dxj dxt (Momentum conservation equation) (3-5) In two-dimensions, Equation 3-5 gives dux TT dux TT eux. BP du] du* dh . . . . dt dx dy dx dx dy dx Chapter 3. Particulate flow loop 90 In the vicinity of duct centreline, viscous effects can be neglected. Steady state is assumed for the centreline water velocity. The gradient of Ux in the y-direction can be neglected due to the symmetry at the centreline of the duct. Gravity is also ignored in the horizontal duct flow. Hence, Equation 3-6 can be approximated by PfUx dx dP_ dx (3-7) Hence, the centreline water velocity profile through the constrictions can be estimated by Equation 3-7 from the measured static pressure approaching the constriction, as in Table 3-7. Table 3-7. Static pressure and corresponding calculated centreline water velocity along streamwise direction for ramp constriction-3 (see Table 3-5) x-coordinate of particles (m) * Static Pressure Centreline water velocity (see Figure 3-19) (Pa(g)) (m\/s) 0 5800 0.305 0.043 5790 0.337 0.119 5738 0.466 0.159 (throat) 5585 0.723 0.194 5546 0.776 0.26 5617 0.678 Ramp constriction position is from 0.089 to 0.15 m, with 0.15 m corresponding to the throat. The Saffman lift force is negligible at very small shear rates (e.g. in the vicinity of centreline) or very low R e p . When the particle is small or the spin velocity low (e.g. near the vicinity of centreline), the Magnus lift force is negligible (Fan and Zhu, 1998). At very low particle Reynolds numbers, particle motion is governed by the BBO (Basset, Boussinesq and Oseen) equation (Rudinger, 1969; Soo, 1990; Fan and Zhu, 1998; Massoudi, 2003), Chapter 3. Particulate flow loop 91 n d\\ dup pf ~T~Pn ,. ~ C d U {-Up (Uf-uD)AD ndl dt ndl (dUf du A 2 6 Pf dt dt dU f du, (3-8) d\\^PfTf{ d t r - - dt'ppg The left-hand side represents the inertia. The right side sums the forces on the particle, the first term being the drag force, the second the effect of the pressure gradient and the third the force required to accelerate the added mass. The integral Basset history term accounts for deviation of the flow around the particle from undisturbed steady flow. The final term is gravity. Beyond the Stokes regime, the effect of convective acceleration of the fluid surrounding the particle is important and the BBO equation must be modified. The modified equation with the history term neglected takes the form (Odar and Hamilton, 1964; Hansell et al., 1992): dU\/ dup duP _ 3 CDPf\\Uf~uP\\(Uf-uP) | 1 pf d t 4 d\u201ePn ' 2 P p dt dt PP dt pp (3-9) Table 3-7 and Figure 3-20 show the calculated centreline water velocity profile through ramp constriction-3. Based on fourth order polynomial curve fitting to the calculated centreline water velocities, the centreline water velocity can be expressed by (\/\u201e =-828.3x 4 +267.79x3 -9.77x 2 +0.41x + 0.31 (3-10) with R2 = 0.98 and a standard deviation of 0.07 m\/s, respectively. 3.4.2 Particle velocity in horizontal direction Measured particle velocities in the streamwise direction appear in Table 3-8. From Equation 3-10, the change of centreline velocity following the fluid is Chapter 3. Particulate flow loop 92 dUc dt \u2022= (-3313.2x3 + 803.37x2 - 19.54* + 0A\\)Uc (3-11) The following equations can then be obtained to predict particle velocity: duP = 3 CD,Wa,iPJ\\Uc-u\\(Uc-uP) AA pw dt 4 d'PPp 2 PP dUc dup dt dt Pw dUc PP d t 2 1 6 CD= + T77 + 0.28 (0.1 < Re p < 4000) (Clift et al., 1978) 1 \\-\\.6(dpIDH) (d <0.6DH) (Clift etal., 1978) 1.6 v P CD,wall=CDKF (Clift etal., 1978) (3-12) (3-13) (3-14) (3-15) Boundary conditions: x(0) = 0.0331 m, Uc(0) = 0.337 m\/s, up =0.291 m\/s. Here we assume an added mass coefficient of A . = 1. The particle Reynolds number based on (Uc - up) at t = 0 is R e p = c \/ p ( ( y c - , p ) ^ = 0.0 1 1 5x ( 0.337-0.297)x998 = 4 6 0 < 1 0 0 ( ) 0.001 (3-16) Beg inn ing of ramp ^ E n d o f r a m p 0.00 0.05 0.10 0.15 0.20 0.25 0.30 x coordinate along streamwise direction (m) Figure 3-20. Centreline water velocity along streamwise direction for a neutrally buoyant spherical polyethylene-red-1 particle, (ramp constriction-3 position is 0.09-0.15 m) Chapter 3. Particulate flow loop 93 Table 3-8. Measured positions and velocities in horizontal direction for neutrally buoyant polyethylene-red-1 particle Time Velocity at each time step Position along streamwise direction (s) (m\/s) at each time step (m) 0 0.297 0.033 0.033 0.296 0.043 0.067 0.305 0.053 0.100 0.311 0.063 0.133 0.311 0.073 0.167 0.337 0.084 0.200 0.359 0.095 0.233 0.397 0.107 0.267 0.470 0.120 0.300 0.651 0.136 0.333 0.802 0.158 0.367 0.732 0.184 0.400 0.546 0.209 0.433 0.394 0.227 0.467 0.286 0.240 0.500 0.413 0.250 0.533 ' 0.489 0.263 0.567 0.467 0.280 Rep varies as the flow develops and is in the range of 270 to 460 in the above-mentioned ' calculation with Equations 3-13 to 3-15 used to calculate the drag coefficient. The Reynolds number based on the water mean velocity upstream of the constriction and hydraulic diameter of the duct is Re = D\u00abV-P- = 0-0367x0.243x998 = ^ 0.001 Since Re > 6000, the flow is in the turbulent regime, as considered above. The fourth-order Runge-Kutta method with variable stepsize was used to solve the three ordinary differential equations, dxldt = Uc plus Equations 3-11 and 3-12 (see Appendix A). From Figure 3-21, we see that agreement between calculated horizontal particle velocities and Chapter 3. Particulate flow loop 94 the experimental results is only fair. The deviation is mainly attributed to particle motion in the vertical and spanwise directions, inaccurate centreline velocity prediction, neglect of some terms (e.g. lift and Basset history forces) and only the horizontal direction being considered. Investigation of the horizontal particle velocity could help to understand the particle behaviour while passing through constrictions. Blockage in the constrictions is mainly attributed to particle behaviour, especially particle collisions with each other and with the wall. Further work is needed for particle collisions in both dilute and dense flow. 0.0 0.1 0.2 0.3 Time (s) Figure 3-21. Horizontal particle position vs time and comparison of calculated and measured particle velocities in horizontal direction for a neutrally buoyant spherical polyethylene-red-1 particle passing through ramp constriction-3 (see Table 3-5). (0.17-0.32 s corresponds to the constriction) 3.5 Estimation of Pressure Drop for Blockage For the rectangular (abrupt) constrictions investigated in the present study (see Table 3-5), blockage only occurred at the entrance of the constriction (zone 1 in Figure 3-22) when particles moved and collided with each other and with the wall, eventually leading to blockage. For the Chapter 3. Particulate flow loop 95 dilute water-particle flows, no blockage was observed inside the rectangular constriction (zone 2 in Figure 3-22). For converging ramp constrictions, the particles blocked inside the ramp, as indicated schematically in Figure 3-23. No stable blockages were observed in circular constrictions (see Table 3-5) since particles slipped relatively easily through the gap due to the smooth profile of the circular semi-cylinders. Figure 3-22. Schematic of blockage in rectangular (abrupt) constriction Figure 3-23. Schematic of blockage in converging ramp constriction Chapter 3. Particulate flow loop 96 From Figures 3-22 and 3-23, imagine that a blockage can only be broken from the rectangular region shown by a dashed line in both figures. Particles inside the rectangle are influenced by fluid and particles around the dashed boundary. A rectangular control surface is considered as shown in Figure 3-24, where the surface represents the real wall or interlocked particles surrounding the rectangular control volume. Figure 3-24. Schematic of blockage in constriction. (Lb, W b , Hb are length, width, height of blockage bed, respectively) To estimate the pressure drop through the blockage, the following assumptions are made: (1) Horizontal packed bed; (2) Gravity is neglected; (3) Particles pack uniformly giving rise to continuous flow channels; (4) Flow inside the horizontal bed is at intermediate Reynolds number (typically 10<Re\/, <1000 ) or in turbulent flow. Hb Lb Chapter 3. Particulate flow loop 97 The Ergun equation (Ergun, 1952; Nemec and Levee, 2005; Keyser et al., 2006) can be written as: AP _AjufU0(l-\u00a3y | BpfUl(\\-e) Lh tfdfe3 (\/)sdvs where A= Blake-Kozeny-Carman constant, typically =150; F3= Burke-Plummer constant, typically= 1.75. dsv = Equivalent surface-volume diameter of particle, m. dv = Equivalent volume diameter of particle, m. Lb = Length of blockage bed, m. S = Particle surface area, m 2 . U0 = Superficial velocity of water, m\/s. V= Particle volume, m . AP = Pressure drop, Pa. jiif = Dynamic viscosity of water, = 0.001 Pa.s at 20 \u00b0C. s = Void fraction of blockage bed, -. fa = 6 V P KdvSp) = dsv I dv, sphericity, -. For cylindrical particles, Nemec and Levee (2005) recommend 150 R-hl5 Since cylindrical particles are reasonably similar to cuboidal particles (maximum aspect ratio much greater than 1) in shape, Equation 3-19 was employed to calculate A and B. A void Chapter 3. Particulate flow loop 98 fraction of 0.5 was assumed for all irregular particles, and the absolute water velocity, Ui, inside the horizontal blockage bed (formed by the \"log-jammed particles\") was calculated from U,.=U0\/s (3-20) The particle Reynolds number based on the hydraulic diameter of the flow channel can be expressed by Rep=DhU,pf\/juf (3-21) where Dh is the hydraulic diameter expressed by Dh=4xVJSw (3-22) Vw is the volume available for flow, and Sw is the wetted surface area. For a packed bed of spherical particles, Dh=4x 6 =1^*2- (3-23) {\\-s)ndl 3(1-s) so that 2 dUnpf Re = - \" \u00b0 f (3-24) Equation 3-24 can also be replaced by Re = > v 0 H f = * H f (3-25) Particle Reynolds numbers calculated from Equation 3-25 are listed in Table 3-9. For the superficial velocities in the present study, the particle Reynolds number was in the range of 1,900-12,960 if particles inside the horizontal blockage bed are assumed to be stationary. When blockage occurred, the static pressure upstream of the blockage increased abruptly. This excess Chapter 3. Particulate flow loop 99 pressure was released either by opening the by-pass valve 6 (see Figure 3-2) or by collapse of the blockage bed. Figure 3-25 indicates that the higher the superficial velocity of the water, the larger the pressure drop across a horizontal blockage bed of given length. The larger pressure drop of silicon-rubber70-cuboid-4 (right-hand column) is mainly attributed to the extreme particle shape (small sphericity). Different sphericity also may lead to different void fractions. Generally, the more non-spherical (i.e. small sphericity) the particle, the larger the void fraction (Nemec and Levee, 2005), whereas a void fraction of 0.5 is assumed throughout the above analysis. The friction between particles and wall, as well as the interlocking characteristics and bending strength of particles, determines whether or not the blockage can be broken. 6000 5500 \u2014^ r\u2014 Silicon-rubber70-cuboid-1 # Silicon-rubber70-cuboid-2 \u2014\u2022\u2014 Silicon-rubber70-cuboid-3 ,o 0.6 0.7 0.8 0.9 1.0 1.1 1.2 Superficial velocity (m\/s) Figure 3-25. Effect of superficial velocity of water on predicted pressure drop per unit length of horizontal blockage bed. (For Reynolds numbers, see Table 3-9. For properties of particles see Table 3-3). Chapter 3. Particulate flow loop Table 3-9. Calculated particle Reynolds numbers (void fraction=0.5) for cuboids 100 u W 0 7x7x3 mm 9x9x3 mm 15x5x3 mm 25x3x3 mm 0.2 0.4 1932 2172 1992 1692 0.3 0.6 2904 3252 2988 2532 0.4 0.8 3876 4332 3984 3384 0.5 1 4848 5424 4980 4224 0.6 1.2 5820 6504 5976 5076 0.7 1.4 6792 7584 6972 5916 0.8 1.6 7752 8664 7968 6768 0.9 1.8 8724 9756 8976 7608 1 2 9696 10836 9972 8460 1.1 2.2 10668 11916 10968 9300 1.2 2.4 11628 12960 11964 10152 From the dimensions of the constrictions most subject to blockage in Table 3-5, we assume Wb = 0.0254m and Hb = 0.0125 m in Figure 3-24. In order to break the blockage, AP \u2014 xWbxHb>x,x2<iWb+Hb) b (3-26) where TS is the average shear stress on the boundary of the blockage bed and r v < TC , where r c is the critical shear stress on the boundary, calculated via. (3-27) AP T,. = - \u2022\u00bbWbxHb c 2Lh(W + Hh) Calculated shear stresses, plotted in. Figure 3-26, are in the range of 350-22,000 Pa, depending on the superficial water velocity, particle properties and packing characteristics of the blockage bed. When the average shear stress at the boundary is less than the critical shear stress, the blockage tends to collapse. Note that the average shear stress may be generated either by particle-wall friction or interlocking of particles at the boundary of the horizontal blockage. As the superficial water velocity increases, the blockage bed becomes more and more compact (i.e. Chapter 3. Particulate flow loop 101 void fraction decreases), increasing the shear stress required to break the blockage. Hydrodynamic forces cannot break up all blockages, especially when the blockage is tight. Mechanical means may then be required to force the particles through the constriction, as discussed in Chapters 4 to 6. Due to the effect of gravity, the packing of particles with p * pw tends to be non-uniform. For p > pw , the upper part of the blockage bed is more easily broken. CO C L <\/) 1\/1 CO <D JZ (\/) ni o 25000 20000 15000 10000 g 5000 \\-O 0 ~~k\u2014 Silicon-rubber70-cuboid-1 -\u2022\u2014 Silicon-rubber70-cuboid-2 -\u2022\u2014 Silicon-rubber70-cuboid-3 -O\u2014 Silicon-rubber70-cuboid-4 O P O P _l , I , I , I , I i I , I , I , 1_ 0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9 1.0 1.1 1.2 1.3 Superficial velocity (m\/s) Figure 3-26. Effects of superficial velocity of water on critical shear stress at boundary of horizontal blockage bed. (For Reynolds numbers, see Table 3-9. For properties of particles, see Table 3-3). 3.6 Conclusions (1) Spherical particles of small size and low density (e.g. polyethylene-yellow-1 in Table 3-3) were easily transported and were unlikely to block constrictions, while irregular rubber and plastic particles of density greater than water were difficult to convey. With increasing water mean velocity, particles experienced creep, saltation and suspension. Chapter 3. Particulate flow loop 102 (2) Large particles of high aspect ratio and density higher than water were difficult to transport. These particles were also more likely to block the constriction at high Re. (3) The maximum particle dimension does not solely determine whether or not blockage occurs when the minimum dimension of the particles is less than the maximum gap dimension. However, large particles were more likely to cause blockage, and a lower particle concentration was required to block a constriction for larger than for smaller particles. (4) Nearly neutrally buoyant conical particles (e.g. ABS-Cone-1) were more likely to block a constriction at a high water mean velocity. This appears to be mainly because of the unbalanced shape, intense fluid-particle and particle-particle interactions, and a large ratio of maximum particle dimension to minimum constriction dimension. (5) Particles with some compressibility (e.g. Silicon-rubber70-cuboid particles) were more likely to block constrictions than hard particles (e.g. PTFE-Rod particles), mainly because compressible particles tended to jam together instead of separating after colliding. However, soft particles (e.g. Neo-rubber40-cuboids) did not form stable blockages due to their low hardness, low bending strength and high flexibility. (6) Reynolds number affects particle motion and blockage tendency. At small water mean velocity, non-spherical particles of density greater than that of water were difficult to transport because of sedimentation. As the water mean velocity increased, non-spherical particles were easier to transport (via creep or saltation), with some piling upstream of the constriction and others passing through the gap almost one by one. Blockage was unlikely for this case. For higher water mean velocities, more and more heavier non-spherical particles were transported Chapter 3. Particulate flow loop 103 and lifted vigorously, increasing the probability of different particles passing through the constriction simultaneously, thereby augmenting the probability of blockage. For the conditions of the present study, 3 to 10 non-spherical particles were sufficient to block the constriction i f the ratio of particle maximum dimension to constriction minimum dimension > 0.4. As Um increased, blockage was less likely to occur and more readily broken, especially for small-particle-blockages, because of increased drag and increased pressure gradient immediately upstream of the constriction. The blockage probability depends on the interactions among the fluid, particles and constriction. (7) Ramp constriction-4 (see Table 3-5) with a square gap (12.5 (W) x 12.5 (H) mm) in the middle was more likely to cause blockage than a rectangular constriction-1 (25.4 (W) x 12.5 (H) mm). This is because the latter provides more space for particles to disperse laterally, reducing the probability of blockage. (8) Flow properties of the water upstream of the constriction, constriction configurations and particle properties (dimensions, shape, density, etc.) determined whether or not particles proceed directly downstream. Large particles denser than water were not readily trapped by the vortex immediately downstream of the constriction, especially at larger Re, because of their dimensions and inertia. (9) Particles of larger densities and dimensions were more likely to collide with the block surface and with each other. Such collisions led to more rotation, causing abrupt changes in particle trajectories and velocities. The larger or heavier the particles, the greater the chance of them colliding with the wall and with each other because of inertial effects. Preliminary Chapter 3. Particulate flow loop 104 observations show that understanding the motion of a single particle is helpful to understand the motion of swarms of particles. However, blockage is related to swarms of particles and cannot occur without particle-particle and particle-wall interactions. (10) The pressure drop needed to break a blockage was predicted based on horizontal packed bed assumption using a modified Ergun equation, to help understand the mechanism of blockage. Chapter 4. Experimental setup and methodology 105 CHAPTER 4. PILOT STUDY OF BIOMASS FEEDING: EXPERIMENTAL SETUP AND METHODOLOGY This chapter introduces the experimental set-up and methodology for the biomass feeding system. It also gives the properties of the biomass fuels tested. This work utilizes a screw feeder\/ lock-hopper system previously fabricated and commissioned to feed sawdust to a circulating fluidized bed gasifier (Li et al, 2004). The feeding system was decoupled from the gasifier for the current experiments. Experiments were then undertaken to investigate the influence on biomass screw feeding of such particle properties as moisture content and heterogeneity 4.1 Material Proper t ies of Interest 4.1.1 Bulk density Bulk density is the overall mass of loose material per total unit volume including interstices. For biomass feedstocks, both oven-dry bulk density and wet bulk density due to different moisture content are commonly employed. It is measured simply by weighing a certain quantity of sample of particles after pouring into a cylinder, i.e. where M , and M2 are the masses of filled and empty cylinders and V is the occupied internal volume of the cylinder which had a height of 0.12 m and a diameter of 0.1 m in the present study. The bulk solids were poured into the cylinder from a height of 0.2 m measured from the bottom of cylinder, and the top surface were gently flattened after gently shaking the cylinder. Chapter 4. Experimental setup and methodology 106 4.1.2 Particle density Apparent particle density (sometimes called solid density) is the density of particles, including any voids inside the particle, but excluding interstices between particles. It can be estimated by the same procedures as for the loose bulk density except that the volume is compacted with the aid of mechanical pressure up to 0.5-1 MPa. In our case, the material was poured into a mold and manually compressed to 0.5 MPa by mechanical pressure. 4.1.3 Voidage Particles rest on each other due to gravity to form a packed bed in the hopper. A certain volume of space between the particles remains unoccupied depending on particle density, particle shape and packing characteristics. The interstitial spaces are called voids. The volume fraction occupied by voids, called voidage, is related to particle and bulk density by: e = \\ - ^ - (4-2) \u2022 PP 4.1.4 Compressibility and compaction ratios Compressibility and compaction ratios are important concepts for biomass fuels. See Chapter 2 and Chapter 6 for more details. 4.1.5 Angle of friction and friction coefficient Friction is a measure of the resistance to the movement of one object in relation to another surface with which it is in contact. We can measure the friction in terms of a coefficient of friction, defined as the ratio of the force needed to move two objects in contact with one another and the normal force holding the two objects together. The arc tangent of the coefficient of friction is called the friction angle. For most material combinations, the static friction is higher than the kinetic or dynamic friction. To determine the former in this work, a spring balance connected to a block of the material (of depth 0.12 m in an open-at-both-ends cylinder of 0.1 m Chapter 4. Experimental setup and methodology 107 diameter) was pulled in a horizontal direction as it sat on a surface, slowly increasing the force until the block began to slide, ensuring that the spring balance was parallel to the surface. The reading on the spring balance scale when the block begins to slide is a measure of the static friction force required to initiate motion, whereas the reading when the block slides at constant speed is employed to calculate the dynamic coefficient of friction and hence the angle of kinetic friction. The angle of kinetic friction and the kinetic friction coefficient are used in the present study. 4.1.6 Internal friction angle and coefficient of internal friction Internal friction is a measure of the force required to cause particles to slide over each other. The internal friction angle is measured by building a flat-topped pile of the bulk material, with one side of the pile resting against the vertical face of a rigid block. To measure the internal friction coefficient, the block is pushed forward slightly into the pile and the position where shearing occurs at the top of the pile is noted. This is assumed to represent the upper limit of a shear plane extending upward from the foot of the block. The inclination of such a plane to the horizontal should be 45\u00b0 - S12, where 8 is the angle of internal friction. This method was recommended by Metcalf (1966). Some researchers instead use the angle of repose or the \"reclaim surface angle\" to estimate the angle of internal friction angle. The latter is the angle with the horizontal of the shear plane when material is withdrawn through a horizontal slot. Note that the angle of internal friction may not be single-valued, and it can be time- and velocity-dependent. The Metcalf (1966) method was adopted due to its simplicity in the present study and the measured angle of internal friction is assumed to be the effective angle of internal friction. Chapter 4. Experimental setup and methodology 108 4.1.7 Flowability Flowability, simply defined as the ability of bulk solids to flow, is an important concept for bulk materials. Jenike (1964) suggested a flow index (see Table 2-2) to quantify flowability, while others have proposed other tests. For the definition of flow-function and flow index see Chapter 2. Mohr-Coulomb model is also used to address flowability, leading to two measurable parameters (cohesion and internal friction angle) and two derived parameters (unconfined yield strength and major consolidation stress). Flowability relies on a combination of material physical properties that affect material flow and equipment for storing, feeding and handling the material (Prescott and Barnum, 2000; Fitzpatrick et al., 2004). 4.1.8 Granular materials Granular materials are collections of discrete and macroscopic solid particles and are defined in different ways. Granular materials do not quite fit any of the usual phases of matter: solid, liquid, or gas. The lower size limit of granular material were set at 1 um (Duran, 2000), whereas Richards (1966), and Chattopadhyay et al. (1994) recommend lower and upper size limits of 0.42 mm and 3.35 (or 6) mm, respectively. Granular materials are generally defined as > 0.5 mm and < 12.5 or 25 mm in size for industrial applications (Link Belt Co., 1959; IS-8730, 1978; CEMA-550, 1980; Chattopadhyay et al., 1994), while particles smaller than 0.5 mm are considered to constitute powders. Granular materials differ significantly from powders in flow properties. Biomass particles are unusual granular materials, varying greatly in size and shape, compressibility and pliability, with moisture content as high as 60%. Although biomass particles are usually between 0.5 and 15 mm in equivalent diameter for gasification and combustion applications, biomass powders are also quite common. Chapter 4. Experimental setup and methodology 109 4.2 Experimental Set up and Methodology Schematics of the biomass feeding systems used in the experiments (including the upper hopper, lower hopper and screw feeder) appear in Figures 4-1 and 4-2. The dimensions of the hopper-screw feeder are given in Table 4-1. Two screws were employed in the present study as shown in Figure 4-3. Before commencing feeding, biomass fuels (e.g. wood pellets, hog fuel and sawdust) were added to the lower hopper and the surface leveled from above. The air inlet to the hopper is at the front of the hopper lid. This was connected to the building air supply via a pressure regulator and a flow meter in order to pressurize the hopper. Table 4-1. Hopper and screw dimensions Parameters of screw configuration Screw-1 Screw-2 Screw length Feed hopper length, Lh 910 mm 910 mm Choke section length, Lc 610 mm 610 mm Screw diameter, D0 100;90;80 ( l )mm 80 mm Screw Shaft or core diameter, Dc 30 mm Variable { l ) Pitch, P 100 mm Variable ( 1 ) PI Do 1 Variable Clearance, c 1;6;11 ( 1 ) m m 11 mm Flight thickness, y 6.35 mm 6.35 mm Average helix angle of screw with vertical 14\u00b0 Variable Material 316SS Carbon steel Inside diameter, Dt 102 mm Trough Material Carbon steel Transparent test section Cast acrylic tube Type Wedge-shaped Length 910 mm Hopper Height 910 mm Angle of hopper wall with horizontal 70 0 Material Carbon steel Notes: (1) Screw diameter 100 mm for length of 800 mm, then 90 mm for length of 300 mm, and finally 80 mm for length of 420 mm. (2) P=40 mm, Dc=56 mm for first 100 mm length; .P=56 mm, Dc=43 mm for next 310 mm length; then P=71 mm, Dc =30.5 mm for 310 mm length; then P =80 mm, Dc=20.3 mm for length of 495 mm; P =70 mm, Dc =20.3 mm for final 305 mm length. Chapter 4. Experimental setup and methodology 110 \u2022760 mm--910 mm-Different configurations of test sections at discharge end of screw casing (b) opper feeding section- -Choke sectior Figure 4-1. Schematic of lower hopper and screw feeder: (a) Front view of lower hopper; (b) Side view of lower hopper and screw feeder Air flow Computer n Torque Counter transducer M-Q\u2014Q-e Motor and gear Upper hopper Pinch valve Lower hopper Rotation speed Torque Screw feeder V ideo camera Q M a s s flow rate T T Sca le XT Figure 4-2. Schematic of biomass feeding system -Hopper Feeding Section- -Choke Section-Screw 1 Pitch=100mm \u2014Shaft diameter=30.5'mm-Length=1520 mm Screw diameter=100 mm Length=800 mm Screw diameter=90 mm Lerigth=300 mm Screw diameter=80 mm Tength=420 mm Screw 2 Screw diameter=80 mm \"Length=1520 mm A A A A A A A A A A \u00bb - | (1) l~m (1) pitch=40 mm Shaft diameter: 56 mm Length: 100 mm V V V V V V V V -(2) (2) pitch=56 mm Shaft diameter: 43 mm Length: 310 mm - ( 3 ) -V V V V - < 5 ) -pitch=71 mm Shaft diameter: 30.5 mm Length: 310 mm (0 pitch=80 mm Shaft diameter: 20.3 mm Length: 495 mm (5) pitch=70 mm Shaft diameter: 20.3 mm Length: 305 mm Figure 4-3. Configuration of test screws Chapter 4. Experimental setup and methodology 112 A variable-speed DC motor (0.56 kW, Baldor CDP 3440) adjusted the rotational speed of the screw. A cpl02 (ID) x 305 mm long cast acrylic tube was installed between the lower hopper and receiving vessel. The transparency of the tube allowed the mode of flow through the screw feeder to be visualized. Different test section configurations were available as shown in Figure 4-1. A video camcorder (see Table 3-4) captured images of particles interacting with each other and with the inside wall of the transparent tube, as well as with the screw flights. The observed particle trajectories are helpful to understand the flow of particles inside the screw feeder and the mechanisms of blockage. A scale (Model: C A R D I N A L EF 100) with a digital weight indicator (see Table 4-2) was connected to a serial port of the computer for continuous measurement of the weight of material fed, with a time interval of 2 s between weight measurements. Table 4-2. Main specifications of scale system Items Models Specifications Supplier Scale CARDINAL EF 100 50 kg. x 0.02 kg. B.C. Scale Co. Ltd. 0.46 x 0.46 m base, Stainless Steel Indicator IQ plus 355 RS232 and analogue output (0-10 VDC) B.C. Scale Co. Ltd. A torquemeter with a counter (Model: MCRT28004T 5-3) with Model 721 Mechanical Power Instrument (see Table 4-3) was installed between the DC motor gear reducer and the lower hopper tp measure the torque and rotational speed of the screw during feeding. Blockages could be detected by changes in torque and rotational speed. A l l data were stored in the hard disk of the data acquisition computer for later analysis. The experimental work began with relatively coarse materials of spheroidal shape, such as polyethylene particles, then progressed Chapter 4. Experimental setup and methodology 113 to less regular materials such as wood pellets, and finally to materials of low bulk density, wide size distribution and significant compressibility, such as sawdust, hog fuel and wood shavings. A l l experiments were performed 2-5 times in order to determine the repeatability and range of flow rates and torque values for a given material and given set of experimental conditions. The work in this thesis does not emphasize hopper flows, which have been widely studied, but rather the transport of particles through the screw feeder. The fill level in' the feed hopper declines during each trial unless the hopper is periodically refilled. The draw-down pattern is not uniform for common screws with constant pitch, core shaft and screw diameter. On the other hand, refilling the hopper momentarily disturbs the feeder operation. Table 4-3. Main specifications of torque measurement system Items Models Specifications Supplier Torquemeter MCRT28004T 5-3; Rotary, inline, shaft-style, transformer-coupled, Frequency output sensor Capacity: \u00b1 565 N.m, 2 times safety overload for stall Accuracy (% of full scale): < \u00b1 0.1% Output (nominal): 1.5 mV\/V Instronics Inc. (produced by S. Himmelstein and Company) Mechanical Power Instrument 721 RS232 serial interface Sampling frequency: 36 Hz Instronics Inc. (produced by S. Himmelstein and Company) Flow rates given here were obtained by calculating the average flow rate during the first two minutes after stable feeding was established. Feed rates and torque readings for a given material and the same experimental conditions were then averaged. Standard deviation and error bars are used in later analysis in Chapter 6. Repeatability, sometimes referred to as equipment variation, is the ability of the measurement system to provide consistent readings when used by a single Chapter 4. Experimental setup and methodology . . . 114 operator. Reproducibility, sometimes called appraiser variation, is the ability for multiple operators to achieve consistent results. Repeatability is analyzed for flow rates and torque reading in Chapter 6. When blockage occurred and could not be broken, the materials were removed from the hopper manually before performing the next run. Three initial hopper levels were tested in the present experiments: a high (0.60 m), medium (0.45 m) and low level (0.30 m). 4.3 Material Preparation and Properties The present study employed polyethylene particles, wood pellets, sawdust, hog fuel and wood shavings as biomass materials. (The polyethylene particles provided a reference case for comparison with the less regular biomass particles). The wood pellets were supplied by FireMaster Ltd and were thoroughly dry when received. The ground wood pellets were collected from those fed through the screw feeder and sieved into ground wood pellets-1 and 2. The sawdust was obtained by spraying water onto the wood pellets, causing the pellets to disintegrate into the original sawdust which had been used to form the pellets in the first place. The hog fuel came from previous work in our laboratory. Ground hog fuel was obtained from another researcher who had been using them for feeding a combustor. The wood shavings were provided by the Wood Processing Center of UBC from planar shavings. The main physical properties of the materials tested are listed in Table 4-4. A l l measurements were carried out at room temperature (20\u00b0C) and atmospheric pressure. Material size distributions appear in Appendix B. Moisture contents were obtained from the weight loss after drying samples at 105\u00b0C for 5 hours. The particle mean diameters and size distributions shown in Figure 4-4 were determined by sieve analysis (RX-29, W.S. Tyler), with a sieving time of 10 minutes (see Table B- l ) . In all cases, the particles were mixed well before sampling Chapter 4. Experimental setup and methodology 115 and five separate samples were analyzed in order to obtain average and representative values. A Sauter mean particle diameter was employed, defined as 1 (4-4) where x, is the mass fraction of particles of mean diameter dj . The wood pellets were approximately cylindrical and almost uniform in size (average dimensions: (j) 6.5 mm x 15 mm) except for some fines. Fines were removed by sieving through a 4.75 mm opening screen. Some grinding of the wood pellets by the screw feeder occurred in our experiments. Therefore wood pellets were only reused after removal of generated fines by again sieving through a screen with 4.75 mm openings. When the dimensions of wood pellets were observed to have changed significantly, they were replaced by new pellets to ensure a uniform size of the wood pellets during the experiments. Photos of the main materials in the present study appear in Figures 4-5 to 4-12, while the relations of bulk density and consolidating pressure on these materials are shown in Figure 4-13 (discussed in Chapter 6). As shown in Figure 4-4, only sawdust-1 and wood pellets-2 are normal distribution at 0.05 level, the distribution of other materials are not normal at 0.05 level. 1.0 -c o 0.8 -u TO (0 0.6 -(0 TO E o> 0.4 -> TO 0.2 -E o 0.0 -\u2022 Sawdust-1 \u2022k Hog fuel-1 \u2022ir Ground hog fuel 3 Wood shaving-1 ^ j>-> Ground wood pellets-2 * it \u2022 \u2022 f t E 0.1 10 Size (mm) Figure 4-4. Particle size distributions of biomass fuels as initially fed Figure 4-5. Photo of wood pellets Figure 4-6. Photo of sawdust-1 Figure 4-7. Photo of ground wood pellets-1 Chapter 4. Experimental setup and methodology 117 Figure 4-10. Photo of ground hog fuel Chapter 4. Experimental setup and methodology 118 Figure 4-11. Photo of wood shavings Figure 4-12. Photo of polyethylene particles 550 500 co\u2014 450 I E 350 '\u00ab 300 \u2022\u00a7 250 3 200 CD 150 100 * * Ground wood pellets-2 \u2022\u2014Sawdust-1 \u2022*\u2014 Hog fuel-1 *\u2014Ground hog fuel 9\u2014Wood shavings-1 -20 0 20 40 60 80 100 120 140 160 Consolidation stress (KPa) Figure 4-13. Relations between bulk density and consolidating pressure Table 4-4. Hydrodynamic properties of materials in the present study Type Mean diameter(1) (mm) Size range (mm) Bulk density (kg\/m3) Particle density (kg\/m3) Moisture (wet basis)(2) Shape Polyethylene particles 4 3.0-5.0 610 908 , dry Spheroid Wood pellets 9.8 8.0-11.6 630 1200(3) 8% Cylinder Ground wood pellets-1 4.05 3.35-4.75 485 1200 8% Cylinder, cone, disk Ground wood pellets-2 0.55 100% < 3.35, 98.5 %> 0.09 423 1200 8% Cylinder, cone, disk Sawdust-1 0.45 100% <6.73, 96 % (0.09 to 2.8) 210 370 14% Irregular Sawdust-2 0.45 100% <6.73, 96 % (0.09 to 2.8) 330 550 40% Irregular Sawdust-3 0.45 100% <6.73, 96 % (0.09 to 2.8) 440 688 60% Irregular Hog fuel-1 0.72 100% < 25, 90 % (0.09 to 9.5) 200 360 11% Irregular Hog fuel-2 0.72 100% < 25, 90 % (0.09 to 9.5) 310 490 40% Irregular Hog fuel-3 0.72 100% < 25, 90 % (0.09 to 9.5) 322 510 60% Irregular Ground hog fuel 0.18 100% <4.75, 98.7 % (0.09 to 2.8) 150 330 14% Irregular Wood shavings-1 0.67 100% <12.5, 91 % (0.09 to 6.73) 110 300 10% Irregular Wood shavings-2 0.67 100% <12.5, 91 % (0.09 to 6.73) 156 380 40% Irregular Wood shavings-3 0.67 100% <12.5, 91 % (0.09 to 6.73) 188 430 60% Irregular Notes: (1) Sauter mean particle diameters, except for the first two which are volume-equivalent diameters; (2) Measured after drying at 105\u00b0C for 5 h. (3) Mass divided by volume, with volume calculated from the measured dimensions of wood pellets. Arithmetic mean density was used from 5 measurements. Chapter 5. Pilot study: Experimental results 120 CHAPTER 5. PILOT STUDY: EXPERIMENTAL RESULTS This chapter presents results from the pilot experimental study of biomass feeding. The effects of mean particle size (0.5-15 mm), size distribution, shape, moisture content (10-60%), density and biomass compressibility on screw feeding are examined. Screw and casing configurations, as well as pressurization of the hopper, are also investigated. 5.1 Experimental Results and Discussion 5.1.1 Feed rate and variability Figures 5-1 and 5-2 indicate that the mass and volumetric flow rates are. linearly proportional to screw rotational speeds, as expected. The standard deviation of the flow rate divided by the mean provides a percentage value (i.e. coefficient of variation), which can be used to describe the variability of feeding. This value is affected significantly by several factors, including the time interval and degree of fill of the screw pockets. The time interval to acquire each weight data point in the present study was 2 s. The flow rate and coefficient of variation were calculated for the first two minutes after establishing stable feeding. In this interval, no stable bridge formed in the hopper, so that bridging could be neglected during this period. A l l materials in the present study provide lower volumetric feed rates than the theoretical volumetric capacity of the screw feeder, as shown in Figure 5-2. Reduced filling fraction and unavoidable rotation of the particles both result in decreased volumetric efficiency, defined as the true volumetric flow rate divided by the theoretical volumetric flow rate. Hog fuel (11%> moisture) and wood shavings-1 (10%> moisture) had somewhat higher volumetric efficiencies than the polyethylene particles, wood pellets and Chapter 5. Pilot study: Experimental results 121 ground wood pellets due to their greater compressibility. The bulk density of compressible materials (e.g. hog fuel, sawdust) did not change much after they passed through the screw feeder. However, these materials were compressed inside the screw feeder, making their bulk density a little larger than in the loose state. This allowed the screw feeders to deliver more mass flow for compressible materials. Hog fuel-1 and wood shavings-1 also had slightly larger volumetric flow rates than sawdust-1 (14% moisture) at the same screw speed. Their wide size distributions are expected to be the main reason since fines can fill the spaces between larger particles, effectively increasing the mass and volumetric flow rates. Polyethylene particles provide volumetric flow rates similar to those of sawdust-1 and ground wood pellets at the same screw speed, despite differences in particle shape and surface roughness. The relatively low volumetric efficiency for the wood pellets can be attributed to their larger mean size, cylindrical shape, and rougher surfaces. 600 500 400 a> 2 300 5 o *- 200 (0 (0 \u00abJ S 100 0 0 5 10 15 20 25 30 35 40 45 Screw speed (rpm) Figure 5-1. Relationship between mass flow rate and screw speed for screw-1 for different biomass materials with initial hopper level=0.30m. For properties of the biomass materials, see Table 4-4. Chapter 5. Pilot study: Experimental results 122 1 4 - \u2022 Wood pellets -, \u2022 4 Ground wood pellets-1 1.2- X Ground wood pellets-2 le \u2022 Sawdust-1 Theoretical volumetric flow rate E 1 0 l * Hogfuel-1 ^ ' ir Ground hog fuel <D \u20225 M Wood shavings-1 ^ 0.8 - o Polyethylene particles o O \u00b0 6 \" E 0.4 1 3 o > 0.2 L 0.0 0 5 10 15 20 25 30 35 40 45 Screw speed (rpm) Figure 5-2. Relationship between volumetric flow rate and screw, speed for screw-1 with different biomass materials and initial hopper level=0.30 m. For properties of the biomass materials, see Table 4-4. The hopper level (i.e. distance from axis of screw to leveled free surface of bulk solid in the hopper) affects the flow rate, although the effect is relatively small as shown in Figure 5-3. A higher hopper level provides larger feeder load and increases the vertical stress on the screw feeder, increasing the fullness of the screw pockets and promoting bulk solids flow. For polyethylene particles, a larger hopper level led to larger flow rate for levels < 0.4 m due to greater filling of the screw pockets caused by higher vertical stress inside the hopper. For hopper levels > 0.4 m, the mass flow rate did not change significantly, and could even decrease with increasing hopper level. Higher hopper levels can increase the fullness of the screw pockets and hence the feeding efficiency, but excessive hopper levels give no further gain. The active stress field is replaced by a passive stress field in the hopper once feeding has been initiated, inhibiting hopper flow and reducing the influence of hopper level (Arnold et al., 1980). In general, higher feeder loads require larger torque for feeding if no bridging occurs, or if bridging Chapter 5. Pilot study: Experimental results 123 in the hopper is insignificant. No obvious bridging in the hopper nor blockage inside the screw feeder was found for the sawdust with 14% moisture content (wet basis) (hopper level < 0.7 m), nor for the polyethylene particles (hopper level < 0.60 m) during the present tests. The loose bulk density was used to calculate the volumetric flow rate at different hopper levels for sawdust-1. . \" . 0 5 10 15 20. 25 30 35 40 45 0 0 > 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 I 0 5 10 15 20 25 30 35 40 45 Screw speed (rpm) Figure 5-3. Hopper level effects on volumetric flow rate for sawdust-1 and screw-1. For properties of the biomass material, see Table 4-4. Moisture content also affects flow rate. Higher moisture content is more likely to cause bridging or rat-holes in the hopper, leading to reduced mass and volumetric flow rates for screw feeding. Sawdust of higher moisture content shows lower volumetric efficiencies (see section 6.2) than one of lower moisture content, as shown in Figure 5-4, although their mass flow rates are almost the same for a given screw speed. Sawdusts of high moisture content (e.g. 40%> or 60 %>, wet basis), especially after 24 hours of consolidation, easily bridged in the hopper due to increased cohesion, as well as increased wall and internal friction, especially for higher hopper Chapter 5. Pilot study: Experimental results 124 levels (e.g. > 0.2 m). Erratic flow of sawdusts of 60% moisture content (wet basis) indicated momentary bridging. The arches or bridges in the hopper had to be broken for the sawdust to fall into the screw pockets, whereas no blockages could be observed inside the screw feeder in the present study. However, loud \"screeching\" could be heard from time to time due to the pressure and friction of the sawdust on the screw surface and casing wall surface. Note that loose bulk densities were used in the calcilation of volumetric flow rates for each sawdust. E, re k. o \u00ab*-o CO E o > 1.4 1.2 Theoretical volumetric flow rate 1.0 moisture (wet basis): y * - * - 1 4 % 0.8 - _ # _ 4 o o \/ 0 - \u2022 - 60 % * 0.6 -0.4 0.2 \u2022 \u2014 \u2022 _ \u2014 0.0 . i , i . i . i . i 5 10 15 20 25 30 35 40 45 Screw speed (rpm) Figure 5-4. Effects of moisture content on volumetric flow rate for sawdust and screw-1. For properties of the biomass materials, see Table 4-4. As indicated in Figure 5-5, larger screw speeds generally led to lower coefficients of variation, although higher screw speeds also caused lower volumetric efficiencies (as defined in sections 5.1.1 and 6.2). The large coefficient of variation of ground hog fuel may be attributed to intermittent bridge in the hopper due to its fibrous shape and poor flowability. Figure 5-6 presents the fluctuations of the flow rate at a rotational speed of 5 rpm, with the deviations from the mean mass flow rate plotted versus time. This figure shows typical cyclic characteristics of Chapter 5. Pilot study: Experimental results 125 screw feeding. The peaks occurred at a frequency corresponding to the rotational speed of the screw feeder. 5.1.2 Blockage tests and analysis Two regions could be identified along the screw for the present hopper-screw feeder (Figures 4-1 and 4-2): a hopper feeding section and a choke section. c o ca > c o o o 1.2 1.1 1.0 0.9 0.8 0.7 0.6 0.5 0.4 0.3 0.2 0.1 0.0 \u2014\u2022\u2014 Wood pellets \u20144\u2014 Ground wood pellets-1 \u2014X\u2014 Ground wood pellets-2 \u2014\u2022\u2014 Sawdust-1 \u2014 H o g fuel-1 \u2014-ir\u2014 Ground hog fuel Wood shaving-1 -o\u2014 Polyethylene particles 0 5 10 15 20 25 30 35 40 45 S c r e w speed (rpm) Figure 5-5. Dependence of coefficient of variation on screw speed for screw-1. For properties of the biomass materials, see Table 4-4. Time (s) Figure 5-6. Fluctuations of flow rate at a rotational speed of 5 rpm for sawdust-1 and screw-1 at initial hopper level=0.45 m (mass flow rate: 27 kg\/h). For properties of the biomass material, see Table 4-4. Chapter 5. Pilot study: Experimental results 126 Higher hopper levels could trigger blockages, depending on the particle properties and equipment configuration. The hopper used here was wedge-shaped, as shown in Figure 4-1, which is better able than a cone-shaped hopper to prevent bridging (Marinelli, 1999, Fitzpatrick et al., 2004). For wood pellets of uniform size (average dimension of single particle: <p 6.5 (D) x 15 (L) mm), blockage inside the screw feeder tended to occur when the hopper level exceeded 0.35 m. When the feeder load was large enough (e.g. hopper level > 0.4 m), the screw feeder blocked almost immediately after it was started. Furthermore, the blockages could not be broken up by reversing or by restarting the motor. To recover, it was necessary to remove the wood pellets from the hopper manually. On the other hand, blockages could be broken up without intervention within 6 s, or by reversing or restarting the motor for hopper levels <0.4 m. Compared to the polyethylene particles, which did not block the screw for hopper levels up to 0.60 m, wood pellets blocked more easily. This is mainly attributed to their poor flowability caused by larger particle size (mean diameter = 9.8 mm), more irregular shapes (cylindrical), and rougher surfaces. The screeching due to the friction of the pellets on the screw and casing surfaces could often be heard when feeding wood pellets. Wood pellets containing some fines (see Table 5-1) were found to block more readily than wood pellets of uniform size. However, blockage was broken up relatively easily for these materials, without too much intervention. Wood pellets of relatively uniform size were provided by sieving wood pellets on each occasion, using a screen with 4.75 mm openings. New wood pellets were employed for further experiments as soon as some of the pellets were observed to have lost their original dimensions and shape. Our experiments suggest that 12-16% (mass) of the wood pellets are ground into particles smaller than 4.75 mm, including 6-9% (mass) of particles smaller than 3.35 mm, for each screw speed. Chapter 5. Pilot study: Experimental results 127 Table 5-1. Size distribution of wood pellets containing some fines Diameter range dp (mm) Mass (kg) Mass fraction U ) 0-0.25 0.72 0.016 0.25-0.5 0.72 0.016 0.5-1 0.72 0.016 1-2 0.72 0.016 2-3.35 0.72 0.016 3.35-4.75 2.7 0.06 4.75-19 38.7 0.86 Total mass: 45 kg The time at which the first blockage occurs provides an indication of how easily blockage occurs for a given material under different experimental conditions. Although the first blockage time should be measured many times (e.g. 20 times) for the same operating conditions, three runs for each screw speed gave preliminary results and trends. Higher screw speeds led to quicker blockage after the motor is started, but more fuel was delivered to the receiving vessel for higher screw speeds before blockage occurred. Experiments indicated that somewhat higher screw speeds (e.g. >30 rpm) reduced the tendency to block inside the screw feeder compared to slower speeds (e.g. 5 rpm) for relatively incompressible particles (e.g. wood pellets and polyethylene particles). However, when blockage occurred at the higher screw speeds, the blockage was harder to break up. The level of stress in the hopper section directly above the screw is influenced by the screw speed. With increasing screw speed, and consequently increasing flow rate, the porosity of the bulk material slightly increased near the screw. In other words, materials in the vicinity of the screw in the hopper section are dilated as a result of increasing screw speed. Even minimal increases of the material porosity, however, cause a Chapter 5. Pilot study: Experimental results 128 distinct decrease of the stress level at the hopper outlet (Rautenbach and Schumacher, 1987), also leading to a decrease in torque requirements as discussed below. For fine particles inside the bulk material, even slight increase of the inter-particle distance cause a drastic decrease of the van der Waals interactions, \"also contributing to reduced blockage tendency for higher screw speeds. Furthermore, the screw feeder may shake or vibrate during feeding due to its cantilever structure, minor manufacturing eccentricities and imperfect fabrication. Shaking or vibrating may cause erratic flow, as well as mechanical wear and other operating problems. The higher the screw speed, the more the screw shakes or vibrates, and the more the screw dilates the materials inside the screw feeder. This may partly explain why high screw speeds led to fewer blockages and why blockages at high screw speeds were difficult to break up. No clear relationship between screw speed and blockage tendency was found for compressible fuels, probably due to the interlocking characteristics of compressible materials. A small favourable pressure drop (0.02 bar) from the hopper to the downstream vessel led to an increase in mass flow rate and a reduction in the tendency to block, as indicated in Figure 5-7. I . \u2022 \u2014 . i i i i i . i . i i i i i . i 0 5 10 15 20 25 30 35 40 45 Screw speed (rpm) Figure 5-7. Effect of screw speed and difference in pressure between hopper and receiver on mass flow rate for wood pellets and screw-1 at initial hopper level=0.30 m. For properties of the biomass material, see Table 4-4. Chapter 5. Pilot study: Experimental results 129 When the hopper was at a somewhat higher pressure than the receiving container, the particles (e.g. ground, wood pellets) in the upper part of the screw pockets were mainly transported by air, reducing the fdling fraction and blockage tendency inside the screw feeder, whereas particles in the lower part of screw pockets were mainly transported by the screw flights. Feeder loads in the hopper put vertical stress on the screw, causing friction between the screw and bulk solids in the hopper. This is the source of the first resistance for the screw to rotate and push particles forward. We call this region the hopper feeding section. When particles enter the choke section, their movement is controlled by screw rotation and the casing as indicated in Figure 5-8. The screw flights press and shear particles, making them rotate and move forward. There are significant normal pressure and shear stresses on the wall surfaces, including casing surfaces and screw flight surfaces. If the flowability of the particles is adequate for screw feeding (e.g. for low bulk density, spherical, particle shape and smooth particle surfaces), the pressure and friction can be accommodated. However, materials that do not flow readily (e.g. those with for large bulk density, irregular shapes and rough surfaces), the screw flights must be able to push the particles forward, overcoming the normal and shear resistance, or the particles stay in place and do not move. When the power and torque delivered by the motor are large enough, the materials can be transported inside the screw feeder relatively smoothly. However, if the power and torque are too small, the particles cannot gain enough energy, momentum and friction from the screw surfaces to advance. For this case, blockage, possibly irreversible, may occur. When the power and torque provided by the motor are similar to those needed by particles to move forward, blockage may occur. This may break up without intervention, be resolved by reversing or restarting the motor, or be irreversible. If the screw speed does not change much, but the mass flow rate decreases, bridging or rat-holing may occur Chapter 5. Pilot study: Experimental results 130 in the hopper. When the screw slows down and the torque increases due to high resistance, blockage may occur inside the screw feeder. Screw speed reduction or fluctuations in torque readings provide good warning indicators of impending blockage. Choke section Hopper feeding section \/\"\"V\u2014^-Figure 5-8. Schematic of particle motion at entrance of choke section. The particles inside the screw pockets (spaces between the screw flights and core shaft surface) are transported by friction and pressure provided by the screw surfaces. Particles at the front (discharge end) of the hopper cannot enter the screw pockets because the pockets are already filled by particles from the back of the hopper. Hence particles at the front of the hopper pile against its front wall, forming a so-called stagnant region, as indicated in Figure 2-4. Experimental observations indicate that i f the stagnant region cannot be broken up and the hopper is refilled, particles from the back of the hopper are transported first just as before, and the strength of the stagnant region at the front of the hopper increases (dead zone), especially for cohesive and adhesive materials. This kind of flow pattern belongs to \"funnel\" or \"rat-hole\" Chapter 5. Pilot study: Experimental results 131 flow, a \"first in, last out\" pattern which should be avoided in hopper-screw feed systems (Marinelli, 1999). The stagnant region tends to cause blockage inside the hopper, as well as potential blockage in the screw feeder. The interface between the hopper and choke sections is a special region, from which particles are transported into a limited casing space. Some particles build up in a stack outside since not all particles can enter the casing smoothly. Observations suggest that wood pellets.at the front of the hopper pile up as a result of the periodic screw motion, making the screw expend larger torque and require more power to continue feeding. The stagnant region limits the screw feeding. Furthermore, once the material in the stagnant region collapses due to external forces, the screw may shear and press the materials from the stagnant region, which may, by this time, be strong and hard due to consolidation and other factors (such as temperature). In general, non-uniform draw-down in the hopper leads to larger torque and power requirements for screw feeding compared to uniform draw-down. Different screw configurations (e.g. variable pitch, screw diameter and core shaft diameter) and various mechanical aids may assist in achieving uniform draw-down. For biomass feeding, uniform draw-down and smooth feeding are even harder to realize due to the peculiar particle properties. 5.1.3 Torque analysis Increases in torque and power requirements were found to signify a larger blockage tendency for a given biomass and given feeder configuration. Starting torque and operating torque are used in analyzing screw feeders (Bortolamasi and Fottner, 2001). Average torque is determined under relatively steady state conditions after feeding is initiated. Maximum torque, a critical parameter for biomass feeding, is the largest torque recorded during feeding. If the screw feeder is unable to provide this torque, blockage may occur at any time. Starting torque is the largest torque, experienced at the onset of feeding, as shown in Table 5-2. For all materials tested in the present study, the screw speed increased from zero to the final speeds (e.g. 5 and 40 Chapter 5. Pilot study: Experimental results 132 rpm) within 1 s once feeding commenced. Hence the screw speed increased instantly when the screw feeder was started. The sampling frequency for torque and screw speed measurements was 36 Hz. We take the time corresponding to the first non-zero screw speed as 1\/36 s; hence the time corresponding to the adjacent zero screw speed is 0, as shown in Appendix G. We can see from Table 5-2 that compressible materials spend more time after the feeding commences to reach the starting torque for given screw speed. These torques are related to the blockage tendency. The larger they are, the more difficult it is to transport these materials. Table 5-2. Time corresponding to starting torque (unit: s) Bulk solids Time corresponding to starting torque 5 rpm 10 rpm 20 rpm 30 rpm 40 rpm Wood pellets ' 2.1-3.2 1.4-1.6 0.8-1.8 0.6-1 0.8-0.9 Ground wood pel lets-1 3.2-3.9 2.4-3.7 1.3-1.7 1-1.3 0.8-1.1 Ground wood pellets-2 5.9-6.1 3.4-4.7 1.8-2.1 1.2-2.1 0.9-1.1 Sawdust-1 7.1-7.9 3.7-4.8 2-2.4 1.9-2.2 1.5-1.6 Hog fuel-1 2.7-5.3 2.1-2.7 1.3-1.6 1.2-1.4 1.1-1.2 Ground hog fuel 3.3-7.3 3.2-3.8 1.5-2 1.4-1.9 1.3-1.6 Wood shavings-1 2.3-6 1.8-2 1.4-1.6 1.2-1.3 1-1.1 Polyethylene particles 2.3-2.5 1.5-1.9 0.8-1 0.5-0.6 0.6-0.8 Experiments were repeated 2-5 times in order to obtain a range of torque values and to provide a better sense of the errors for each material. With no feeder load inside the hopper, the screw feeder was found to run smoothly, with some torque spikes, depending on the screw speed (e.g. see Figure 5-9). The same was true for screw feeding with a limited feeder load (see Figure 5-10). Both figures show typical characteristics of screw feeding: counting the torque peaks during a 1-minute interval gives a number equal to the rotational speed of the screw. For example, a 5 rpm screw speed was found to produce 5 peaks per minute, implying that there is a direct relation between screw speed and the frequency of torque fluctuations. The fluctuations are due to cyclic characteristics of screw feeding and inherent features (e.g. slight eccentricities from manufacturing and\/or installation). When biomass is transported into the choke section, Chapter 5. Pilot study: Experimental results 133 the required torque increases. The choke section plays a critical role in biomass feeding. Generally the length of the choke section is at least one pitch (Bates, 1969) or twice the standard pitch (CEMA, 1980; Yu and Arnold, 1997). For biomass feeding, the choke section may be longer, e.g. 6-10 times the pitch, in order to promote plug formation and prevent backflow of hot gases and bed materials from the reactor (Li et al., 2004). This causes the torque reading to increase gradually after initiating feeding. When the biomass was distributed relatively evenly in the hopper and choke section, the torque was also observed to be relatively stable. From this relatively stable stage, average torque requirements could be obtained. Since the screw in our study was a common screw with a constant pitch, constant core shaft diameter and constant screw diameter in the hopper section, the draw-down pattern was not uniform. Instead a stagnant region formed at the front of the hopper, whereas the back end tended to be empty after some time as shown in Figure 2-4. The total feeder load also decreased as feeding continued (without refilling). Furthermore, the passive stress field became important after feeding commenced. A l l of these factors led to a decrease in the torque reading after a relatively stable stage of torque readings. The torque fluctuated significantly during feeding, probably because of intermittent bridging in the hopper and complex dilation and compression inside the choke section. Screw speeds also fluctuated due to torque fluctuations, with the screw speed decreasing as the torque reading increased and increasing as the torque decreased. Stopping and restarting the screw feeder did not affect the torque reading significantly (see Figure 5-10). Chapter 5. Pilot study: Experimental results 134 5 rpm 30 60 90 120 V W W W Y W W W W W W 10 rpm ^ 4 E Z 2 <u o ? 4 O 30 30 30 30 60 60 60 60 Time (s) 90 90 90 90 120 20 rpm 120 30 rpm 120 40 rpm 120 Figure 5-9. Torque vs time for screw feeder with no solids present Time (min) 12 16 20 24 28 40 35 30 25 20 3 15 | CT 10 5 0 Max. torque: 29.31 N.m which occurred 7.0 min after initiation Ave. torque: 24.88 N.m Standard deviation: 1.77 Data size: 8182 Starting torque: 10.45 N.m time: 3.7 s after initiation speed range: 10.2-11.9 rpm j I i I i I i L 240 480 720 960 Time (s) 1200 1440 100 90 80 70 E 60 \u00a3-TJ 50 CO d) a. 40 m CU 30 -CO 20 10 J o 1680 Figure 5-10. Torque vs time for screw feeder at 10 rpm for sawdust-1 and screw-1 at initial hopper level=0.45 m. For properties of the biomass material, see Table 4-4. Chapter 5. Pilot study: Experimental results 135 0) 3 cr o +-> E 3 E x ro E o + J 0) O) re k_ > re o o re a; 1.0 0.9 0.8 0.7 0.6 0.5 0.4 0.3 0.2 0.1 \u20144\u2014 Ground wood pellets-1 \u2014X - Ground wood pellets-2 \u2014\u2022\u2014 Sawdust-1 \u2014 H o g fuel-1 \u2014ft\u2014 Ground hog fuel \u2014s\u2014 Wood shaving-1 \u2014O\u2014 Polyethylene particles 0 10 15 20 25 30 35 40 45 Screw speed (rpm) Figure 5-11. Ratio of average to maximum torque for various materials and screw-1 at different screw speeds (initial hopper level=0.45 m). For properties of the biomass, see Table 4-4. Screw speed (rpm) Figure 5-12. Ratio of starting to maximum torque for various materials and screw-1 at different screw speeds (initial hopper level=0.45 m). For properties of the biomass, see Table 4-4. Chapter 5. Pilot study: Experimental results ! 136 Ratios of average-to-maximum torque and starting-to-maximum torque are plotted in Figures 5-11 and 5-12. The former ratio reflects, to some extent, the fluctuation of torque reading during feeding. This ratio is in the range of 0.25-0.70 for hog fuel, ground hog fuel and wood shavings, and 0.75-0.90 for the other materials tested. The smaller range is mainly attributed to the wider size distribution and more irregular shape of hog fuel, ground hog fuel and wood shavings relative to the other materials. The ratio of starting-to-maximum torque represents the percentage of starting torque in the actual torque requirement during feeding (i.e. maximum torque). The smaller this ratio, the less important the starting torque and the more important the choke section in determining the total torque. In this work, all materials except polyethylene were found to have a ratio in the range of 0.2 to 0.5, whereas polyethylene particles gave ratios of 0.5 to 0.6. These values indicate that the starting torque of all fuels was manageable relative to the overall torque requirements. Smaller ratios were mostly found for the low bulk density materials, especially biomass fuels, and in the long choke section for biomass screw feeding. The longer the choke section, the greater its influence in determining the total torque requirements in biomass screw feeding. Average torques are plotted in Figures 5-13 to 5-15. From these figures, it is seen that larger mean particle size, more irregular shape and higher bulk density (e.g. wood pellets and ground wood pellets) lead to higher torque (see also Table 4-4). Large standard deviations of average torque for ground wood pellets-2 are probably mainly due to their wide size distribution and relatively large density. It should be noted that larger particle mean size and wider particle size distributions cause larger maximum torque and starting torque for hog fuel-1 than for sawdust-1, while the larger bulk density of sawdust-1 may contribute to its somewhat higher average torque relative to hog fuel-1 (see Table 4-4). For wood shavings-1, the size distribution and particle strength cover wider ranges compared to the other materials, especially the latter (see Table 4-4). Chapter 5. Pilot study: Experimental results 137 Some particles in wood shavings are harder and have larger strengths due to the manufacturing process, making the standard deviation of the maximum torque second only to that of wood pellets. The smaller torque requirements of polyethylene particles are mainly attributed to their regular shape and smooth surfaces. Torque requirements are determined by material properties and equipment configurations, whereas feeder configurations vary greatly depending on the material properties and different applications. Biomass feeders differ significantly from feeders used for other materials (e.g. screw configurations and the choke section length), so that torque measurements in the present study cannot be readily compared with results from other facilities using different materials. 3.0 <3> Empty condition 2 5 l Initial hopper level=0.3 m \u2022 Wood pellets 1 b r ^ Ground wood pellets-1 X Ground wood pellets-2 0 n i \u2022 Sawdust-1 \u00a7 2 0 h ^ * Hogfuel-1 ns \u2022fe Ground hog fuel \u2022~ 1.5 L S Wood shaving-1 Q> [ O Polyethylene particles H 1.0 co T3 C JS 0.5 CO 0.0 o as* 0 10 20 30 40 50 60 Average torque for different materials (N.m) Figure 5-13. Variability of torque, expressed as standard deviation vs average torque for different materials and screw-1 with initial hopper level=0.30 m. For properties of the biomass materials, see Table 4-4. Chapter 5. Pilot study: Experimental results 138 o <^> Empty condition 7 \u2022 Wood pellets JJJ K A Gr und wood pellets-1 6 IE3 X Ground wood pellets-2 \u2022 Sawdust-1 5 * Hogfuel-1 \u2022fe Ground hog fuel 4 * \u00a33 Wood shaving-1 O Polyethylene particles 3 X 2 O 1 - \u2022 0 o i . i , Initial hopper level=0.3 m I . I . 0 10 , 20 30 40 50 60 70 80 Maximum torque for different materials (N.m) Figure 5-14. Variability of torque, expressed as standard deviation vs maximum torque for different materials and screw-1 with initial hopper level^OJO m. For properties of the biomass materials, see Table 4-4. 5 r c o TO > \u2022a TJ 3 1-k. co TJ CO 2 h (\/) 1 f 0 ' \u2022 Wood pellets 'A Ground wood pellets-1 \u2022 X Ground wood pellets-2 - \u2022 Sawdust-1 * Hog fuel-1 \u2022fe Ground hog fuel Wood shaving-1 \u2022 - O Polyethylene particles . ---I . I . I . I i . i 0 5 . 1 0 15 20 25 30 Starting torque for different materials (N.m) Figure 5-15. Standard deviation vs starting torque for different materials and screw-1 with initial hopper level=0.30 m. For properties of the biomass materials, see Table 4-4. Chapter 5. Pilot study: Experimental results 139 5.1.3.1 Effect of particle size Wood pellets, ground wood pellets-1 (3.35-4.75 mm) and ground wood pellets-2 (< 3.35 mm) are all irregular in shape with similar bulk density, particle strength and surface roughness. Wood pellets were relatively smooth compared to the ground wood pellets. Their differences in torque requirements are mainly attributable to differences in mean size. Figures 5-16 to 5-18 show that larger particles require more torque (maximum, average and starting torque). Furthermore, ground wood pellets-2 only contain 1.5% fines (< 0.09 mm), suggesting that the effect of fines is limited. This can be confirmed by experimental results. Ground wood pellets-2 have relatively low torque requirements compared to ground wood pellets-1, indicating that fines have negligible effect on torque. Fines increase the fullness of screw pockets and cohesive strength, tending to cause larger torque requirements, as indicated in Section 5.1.2. Maximum torque is an indicator of the instantaneous blockage potential during screw feeding. If the feeder cannot provide the maximum torque, the screw stalls, at least temporarily. Note that the maximum torque decreases as screw speed increases for wood pellets, as shown in Figure 5-17. Hence the blockage tendency was found to decrease as the screw speed increased, as mentioned above. This may be partly because of higher dilation of bulk materials at higher screw speeds and intense interlocking of particles at relatively low speeds, as well as blockage break-up due to shaking or vibration at the higher screw speeds. 5.1.3.2 Effect of particle shape Since Ground wood pellets-1 and polyethylene particles have similar mean sizes and size ranges, particle shape and surface roughness are the main reasons for their different torque requirements. Figure 5-19 shows that particles of more irregular shape (e.g. cylindrical or conical) need much more torque to feed, presumably due to poorer flowability. The maximum torque requirement for ground wood pellets-1 was almost independent of screw speed, whereas Chapter 5. Pilot study: Experimental results 140 that of the polyethylene particles was somewhat dependent on screw speed. For the wood pellets, the faster the screw rotated, the less the maximum torque requirement. Interlocking of ground wood pellets appears to be much more intense than for wood pellets and polyethylene particles due to their relatively small size, rough particle surfaces and high compressibility. Vibration of the screw and dilation of ground wood pellets inside the screw feeder are offset by intense interlocking of particles (even at relatively high screw speeds). As a result, high speeds cannot significantly reduce the required maximum torque for ground wood pellets-1. The maximum torque requirements for compressible materials (e.g. sawdust, hog fuel and wood shavings) appear to have been independent of screw speed in the present study. As in a previous study (Rautenbach and Schumacher, 1987), both the average torque and starting torque were nearly independent of screw speed for both compressible and incompressible materials. 100 90 ^ 8 0 E 70 z \u00a7\u2022 50 \u20222 401 CD O) 30 co CD 20 > < 10 1 - \u2022\u2014 Wood pellets: 8.0-11.6 mm Ground wood pellets-1: 3.35-4.75 mm - X \u2014 Ground wood pellets-2: < 3.35 mm _ i i i\u2014 100 90 80 70 60 50 40 30 20 10 10 15 20 25 30 35 40 45 Screw speed (rpm) Figure 5-16. Effects of screw speed and particle size on average torque for screw-1 for wood pellets and ground wood pellets with initial hopper level=0.30 m. For properties of the biomass materials, see Table 4-4. Chapter 5. Pilot study: Experimental results CD cr E 3 E \"x re 120 110 100 90 | -80 70 -60 -50 40 30 20 - \u2022\u2014Wood pellets: 8.0-11.6 mm -^\u2014Ground wood pellets-1: 3.35-4.75 mm - X \u2014 Ground wood pellets-2: < 3.35 mm 1: - X - - x - - x -0 5 10 15 . 20 25 30 35 40 45 Screw speed (rpm) Figure 5-17. Effects of screw speed and particle size on maximum torque for screw-1 for wood pellets and ground wood pellets with initial hopper level=0.30 m. For properties of the biomass materials, see Table 4-4. 60 55 50 45 -40 -<D 3 CT 35 \u20222 30 .E 25 JS 20 CO 15 10 \u2022\u2014Wood pellets: 8.0-11.6 mm -^ \u2014 Ground wood pellets-1: 3.35-4.75 mm -x\u2014 Ground wood pellets-2: < 3.35 mm 10 15 20 25 30 35 40 45 Screw speed (rpm) Figure 5-18. Effects of screw speed and particle size on starting torque for screw-1 for wood pellets and ground wood pellets with initial hopper level=0.30 m. For properties of the biomass materials, see Table 4-4. Chapter 5. Pilot study: Experimental results 142 60 \u00a3 50 CD 40 1_ o 30 CD O ) CO CD 20 > < 10 -4\\\u2014 Ground wood pellets: mean size: 4 mm, shape: cylindrical, conical and discal \u2014O\u2014 Polyethylene particles mean size: 4 mm, shape: spheroidal 1 o-T 4 -o- -o- -o 10 15 20 25 30 35 Screw speed (rpm) 40 45 Figure 5-19. Effects of particle shape and screw speed on average torque for screw-1 for polyethylene particles and ground wood pellets-1 with initial hopper level=0.30 m. For properties of the materials, see Table 4-4 5.1.3.3 Effect of moisture content Sawdust-1 (14% moisture) and sawdust-3 (60% moisture) were employed to investigate the effects of moisture content. The bridging of wet sawdust in the hopper was severe, whereas the tendency to block inside the screw casing decreased since the pockets were nearly empty. Any bridge in the hopper needs to be broken to allow the wet sawdust to enter the screw casing. Sawdust-3 had a lower average torque than sawdust-1, but sawdust-3 had higher maximum and starting torques than sawdust-1 (see Figure 5-20). This indicates that wet sawdust is more likely to block inside the screw feeder if no bridging occurs inside the hopper. Furthermore, both maximum and average torques decreased as the screw speed increased for wet sawdust (60 % moisture) due to increased bridging in the hopper and reduced fullness inside the screw feeder as the screw speed increased. There was no obvious relationship between starting torque and screw speeds for sawdust-3. For sawdust-1 (14% moisture), none of the recorded torque Chapter 5. Pilot study: Experimental results 143 values (maximum, average or starting) changed significantly as the screw speed varied. The same held approximately also for other dry biomass fuels (e.g. hog fuel, ground wood pellets and wood shavings). For wet biomass (e.g. 40% and 60% moisture-content sawdusts), the flow rates and torque requirements could vary considerably, depending on the bridging conditions inside the hopper. Wood shavings-1 (10% moisture), wood shavings-2 (40% moisture) and wood shavings-3 (60% moisture) were also compared in the present study. The torque requirements of wood shavings do not seem to have depended significantly on the moisture content. This is probably due to their wide size distribution, wide range of particle strengths and low bulk densities. 60 \u00a3 5. 50 <D 3 CJ O 40 \u00a3 3 E 30 'x re S 20 Sawdust - mean size: 0.45 mm # Moisture=14 % (wet basis), bulk density=210 kg\/m3 -^ Ar\u2014 Moisture=60 % (wet basis), bulk density=440 kg\/m3 \u2022I. 1 i I i 10 15 20 25 30 35 40 45 Screw speed (rpm) Figure 5-20. Effects of moisture content and screw speed on maximum torque for screw-1 for sawdust-1 and sawdust-3 with initial hopper level=0.30 m. For properties of the biomass materials, see Table 4-4. Hog fuel was stored in garbage cans at 30% moisture content (wet basis) at a temperature of 20 \u00b0C. The garbage cans were covered by the lids, but not perfectly sealed. After two months, the moisture content fell to 14-28% (wet basis), varying according to depth. When these hog Chapter 5. Pilot study: Experimental results 144 fuel particles with non-uniform moisture content were added to the hopper, a large torque requirement could be observed as shown in Figure 5-21 for a rotational speed of 5 rpm. The compacting and non-uniform moisture content, major characteristics of biomass fuels after time consolidation, appear to have been the main reasons for the large torque requirements. After the hog fuel was loosened and air-dried on a wood plate for three weeks, its moisture content fell to 11%, and the resulting hog fuel was relatively easy to feed with low torque requirements. Keeping this hog fuel with 11% moisture content in the hopper for two days did not cause significant differences in torque compared to feeding immediately after filling. 50 -^ 4 5 \" Initial hopper level: ^ 40 - \u2014\u2022\u20140.45 m ^ - \u2022 \u2014 0 . 3 m S 3 5 h 1 O 30 -10 -5 I . i . i . ' \u2022 ' 1 I I I I 1 1 1 L 0 5 10 15 20 25 30 35 40 45 Screw speed (rpm) Figure 5-21. Effects of hopper level and screw speed on average torque for hog fuel-1 and screw 1. For properties of the biomass material, see Table 4-4. 5.1.3.4 Effect of hopper level Hopper level affects feeder load through the passive stress field after the hopper flow begins (Arnold et al., 1980). In this work, the hopper level was found toplay an important role for hard and heavy particles on the torque, requirements. For compressible light bulk materials Chapter 5. Pilot study: Experimental results 145 (e.g. sawdust, hog fuel and wood shavings), especially for higher moisture contents, an increase in hopper level could increase the feeder load, as well as increasing the bridging tendency in the hopper. From Figures 5-21 to 5-23, a higher hopper level led to larger average and maximum torques. The starting torque seems to have been independent of screw speeds and hopper levels for sawdust-1 (14% moisture) and hog fuel-1 (11%) moisture), indicating again that the choke section plays an important role in torque requirements. For hopper levels < 0.5 m (e.g. 0.30 and 0.45 m), average torque and maximum torque were both independent of screw speeds, but when there was more material in the hopper (e.g. a depth of 0.60 m), the torque increased as the screw speed increased, although the increase was small. This may be partly because higher hopper levels increased the degree of fill of the screw pockets, leading to intense compression and dilation inside the screw pockets, with compaction dominant due to compressibility and intense interlocking of particles as the screw speed increased, causing larger average and maximum torque (see Figure 5-22). Incompressible particles (e.g. polyethylene particles and wood pellets) generally needed less torque to be fed at relatively high screw speeds due to dilation of bulk solids, vibration of the screw, and reduced interlocking. Note that the effect of screw speed on torque requirements was again relatively small for both compressible and incompressible materials. 5.1.3.5 Effect of choke section length Stress in the choke section is particularly difficult to analyze due to the complicated compression and dilation conditions inside the casing. So far, no satisfactory analysis is available for this section. Normally the length of the choke section is twice the pitch of the screw, but for biomass feeding, due to the need to form a plug seal to prevent backflow of hot gases and bed materials from the reactor, the choke section may be longer (Li et al., 2004). Chapter 5. Pilot study: Experimental results 146 50 | 45 -\u2014*\u2014Hopper level=0.3 m E 4 0 _ \u2014\u2022\u2014Hopper leveN0.45 m z \u2014\u2022\u2014Hopper level=0.6 m 10 -i i i i i i i i i i i i i i i i i 0 5 10 15 20 25 30 35 40 45 Screw speed (rpm) Figure 5-22. Effects of hopper level and screw speed on average torque for sawdust-1 and screw-1.For properties of the biomass material, see Table 4-4. 45 , 40 E 35 0) 30 h JT O 25 CU a? 20 o > < 15 10 5 Initial hopper level: \u2014 \u2022 - 0 . 4 5 m - \u2022 - 0 . 3 m 10 15 20 25 30 Screw speed (rpm) 35 40 45 Figure 5-23. Effects of hopper level and screw speed on average torque for polyethylene particles and screw-1 .For properties of the material, see Table 4-4. Chapter 5. Pilot study: Experimental results 147 E z 03 3 CT 18 16 h 14 12 k O 10 <u O) ra > < \u2014A\u2014 0.30 m long choke section \u2014\u2022\u20140.46 m long choke section \u2014\u2022\u20140.61 m long choke section \u2014 i f-t 4 10 15 20 . 25 30 35 Screw speed (rpm) 40 45 Figure 5-24. Effects of choke section length and screw speed on average torque for screw-1 for wood shavings-3 with initial hopper level=0.45 m. For properties of the biomass materials, see Table 4-4. The choke section plays an important role in screw feeding and reactor operations, as well as in determining the torque and power requirements. Five different lengths of choke section were tested, 0.30 m, 0.46 m, 0.61 m, 0.76 m and 0.91 m, with the 0.61 m choke section as the base value in the present study since the length of the screw outside the hopper is 0.61 m (Table 4-1 and Figure 4-2). From Figure 5-24, it is clear that a longer choke section led to larger torque requirements. For wood shavings-3 (60% moisture), 0.76 m and 0.91 m long choke sections (i.e. extending 0.15 m and 0.30 m long beyond the screw), both tended to cause stoppage of the screw feeder. A plug formed inside the extended section with a plug density in the range of 220-320 kg\/m , whereas the plug density in the screw region was 190-220 kg\/m for wet wood shavings (60% moisture). For ground hog fuel, the plug density inside the extended section ranged from 200 to 280 kg\/m3, whereas the plug density in the screw region of the choke section was 180-260 kg\/m3. To obtain a mechanically stable plug with a suitable low gas permeability, Chapter 5. Pilot study: Experimental results 148 plugs should have a bulk density from 1300 to 1500 kg\/m (similar to particle density of wood pellets), depending on the biomass texture and operating requirements (TK Energi, 2006). Special screw and casing configurations, as well as large torque and power, are needed to form such dense plug seals. Hoppers are also commonly pressurized to prevent backflow from the reactor, especially when plug sealing is unstable and unreliable. Plug formation inside the extended section is expected to play a significant role in blocking and stopping the screw feeder since no blockage occurred when there was no extension beyond the end of the screw. For extended sections, sawdust-1 (14% moisture) was much more likely to cause stoppage of the screw feeder than hog fuel-1 or ground hog fuel. Large mean size and wide size distribution of the hog fuel appeared to hinder plug formation inside the extended section, especially for the 0.15 m long extension, compared to sawdust-1. This is mainly because a larger particles tend to give a larger void fraction, providing more room for particle motion and readjustment inside the extended section, thereby reducing interlocking of particles and decreasing the probability of blockage. This indicates that uniform particle size and small voidages are preferred for forming plugs inside the extended section, even inside the screw casing. Blockage occurred for both 0.15 m and 0.30 m extended sections for sawdust-1, whereas only the 0.30 m extension caused blockage for hog fuel-1. Experiments with ground hog fuel indicated that the 0.15 m extended section may or may not lead to blockage and stoppage of the screw feeder, depending on the flow conditions inside the hopper and screw feeder, whereas the 0.30 m extension made ground hog fuel form a tight plug inside the extended section, contributing in a major way to blockage and stoppage of the feeder. Ground hog fuel bridged relatively easily in the hopper due to its fibrous cylindrical shape and low bulk density, reducing the fullness of the screw pockets. This was likely the main reason why ground hog fuel passed through the 0.15 m extended section more easily than sawdust-1. Chapter 5. Pilot study: Experimental results 149 5.1.3.6 Effect of casing configuration The choke section effects on torque requirements depended not only on the length of the casing, but also on the screw length and casing configuration. Different casing test sections were tested in the present study, with straight test section (cast acrylic), and 0.15 m and 0.30 m long tapered converging sections (carbon steel) (see Figure 4-1) with 2.6\u00b0 and 1.2\u00b0 half-taper angles, respectively. Experimental results are plotted in Figure 5-25. The 0.30 m tapered section was the most difficult of the three, needing more torque to feed for the biomass materials tested. On the other hand, plug seals were better than for the other two configurations. Large mean particle size and wide size distribution of hog fuel-1 caused it to be more prone to blockage in the tapered section. Large hog fuel particles played an important role in setting the torque requirements and in triggering blockage inside the tapered sections. For ground hog fuel, the fibrous cylindrical shape, as well as the poor flowability, caused blockage to occur more frequently in the tapered sections than for sawdust-1. Relatively uniform particle size, regular shapes and large compressibility of sawdust-1 (14% moisture) are likely the main factors explaining why sawdust-1 passed through the tapered sections more easily than hog fuel-1 and ground hog fuel. For the ground hog fuel (14%> moisture) and wood shavings (10, 40 and 60% moisture), the plug density formed in the taper section were both in the range of 150-300 kg\/m , depending on the compression conditions. 5.1.3.7 Refilling Refilling is essential for continuous industrial processes. To investigate the effect of refilling without consideration of bridging or rat-holes in the hopper, 3.5 kg ground hog fuel (14%o moisture) was first put into the hopper, with the top surface flat (0.15 m hopper level), and then the screw feeder was started. When the hopper was empty, the fed ground hog fuel was returned to the hopper while the screw was still turning. Chapter 5. Pilot study: Experimental results 150 120 110 100 E 90 -z 80 -\u2014\u2022 CD 3 . 70 -cr 60 -k. o CD 50 -D) ra 40 -CD > < 30 -20 -10 -\u2014*\u2014 Straight test section (cast acrylic) \u2014O\u2014 0.15 m taper section with 2.6\u00b0 half taper angle (carbon steel) \u2014\u2022\u2014 0.30 m taper section with 1.20 half taper angle (carbon steel) -o o o \u2014 \u2014f-0 10 15 20 25 30 35 40 45 Screw speed (rpm) Figure 5-25. Effects of casing configuration on average torque for sawdust-1 and screw-1 with initial hopper level=0.45 m. For properties of the biomass materials, see Table 4-4. 10.0 9.5 \"E 9.0 Z d) 8.5 3 cr CD Ui 7.5 ns I 7.0 < 6.5 6.0 Fill hopper first then turn the screw Refill while screw is turning 5 10 15 20 25 30 Screw speed (rpm) 35 40 45 Figure 5-26. Effects of mode of filling on average torque for ground hog fuel (3.5 kg) and screw-1. For properties of the biomass material, see Table 4-4. Chapter 5. Pilot study: Experimental results 151 The refdl material was added to the middle of the hopper (not leveled). As shown in Figure 5-26, these experiments did not show much difference in torque requirements. Refdling was tested for all materials while feeding continued, i.e. while the screw continued to turn, with a maximum refdling mass of 10 kg. Although there seemed to be some torque peaks during refilling, especially for the denser materials (e.g. wood pellets and polyethylene particles), it was unclear whether or not these peaks were caused by the refilling. For heavy particles and a large steep hopper, a large refilling \"dump\" can cause larger fluctuations of torque readings and feed rates. Ideally refilling should occur continuously, maintaining a nearly constant hopper level. In this case, there should be no interruption to feeding, especially for biomass of low bulk density. 5.1.3.8 Pressurization Experiments were conducted to test the influence of pressurizing the hopper for screw-1. Pressurization of the hopper relative to the receiving vessel reduced torque requirements and increased the flow rate, as shown in Figures 5-27 to 5-32. The permeability of biomass and flow conditions inside the hopper and the screw casing affected the pressurization. The larger the permeability and the more non-uniform flow in the hopper and in the screw casing, the easier it is for air to flow through the screw casing to the reactor, tending to equalize the pressure levels on the two sides. Ground wood pellets were better than wood pellets from a pressure-seal point of view, and ground wood pellets were more amenable to formation of a plug seal than wood pellets. Pressurization and air flow in the hopper can help break up bridges inside the hopper, especially for light feedstocks (e.g. wood shavings and ground hog fuel). Air flow can help break up the stagnant region that can form at the front of the hopper. From observations, small pressurization and low air flow rates did not affect screw feeding significantly when there was an effective pressure seal. Hence, little or no pressurization and small forward gas flow rates are preferred for biomass feeding, especially when the plug seal inside the screw casing works well. Chapter 5. Pilot study: Experimental results 152 0.5-20 kPa is the recommended pressure drop from the feed hopper to the reactor (e.g. McLendona, 2004). In the present system, the hopper was not designed for significant pressurization, and so the maximum absolute pressure in the hopper was limited to 110 kPa, whereas the pressure of the outlet of the screw feeder was atmospheric. A pressure drop of 0.3-10 kPa and air flux < 0.7 m\/s (based on cross-sectional area between shaft and casing surface at entrance of choke section) worked best in the present study. Higher pressure differentials and larger air flow rates not only lead to larger energy consumption, but may also interrupt the reactor operations. CD 3 CT CD O) CO d> > < 80 75 h 70 65 60 55 50 45 |-40 35 30 0 Pressure difference: - \u2022 - 2 0 0 0 P a , airf low: 0.01 m 3 \/s - \u2022 \u2014 1450 P a , air flow:0.008 m 3 \/s - O \u2014 500 P a , air flow: 0.004 m 3 \/s \u2014o\u2014 No pressurization 5 10 15 20 25 30 35 40 45 S c r e w s p e e d ( rpm) Figure 5-27. Effects of pressure difference between hopper and receiving vessel on average torque for wood pellets and screw-1 with initial hopper level=0.30 m. For properties of the biomass materials, see Table 4-4. Chapter 5. Pilot study: Experimental results 1 cu 3 CX o E \u2022 3 E 'x CC 120 110 100 90 80 h 70 60 50 40 30 Pressure difference: - \u2022 - 2 0 0 0 Pa, airflow: 0.01 m 3\/s - \u2022 - 1450 Pa, air flow: 0.008 m 3\/s \u2014<l\u2014 500 Pa, airflow: 0.004 m 3\/s \u2014o\u2014 No pressurization 0 5 10 15 20 25 30 35 S c r e w speed (rpm) 40 45 Figure 5-28. Effects of pressure difference between hopper and receiving vessel on maximum torque for wood pellets and screw-1 with initial hopper level=0.30 m. For properties of the biomass materials, see Table 4-4. Figure 5-29. Effects of pressure difference between hopper and receiving vessel on mass flow rate of wood pellets for screw-1 with initial hopper level=0.30 m. For properties of the biomass materials, see Table 4-4. Chapter 5. Pilot study: Experimental results 154 E z 80 70 60 0) 50 CT 2 40 D) ro 0) > < 30 20 10 Pressure difference: - \u2022 \u2014 1500 Pa, air flow: 0.002 m 3\/s - \u2022 - 1 0 0 0 Pa, airflow: 0.001 m 3\/s \u2014o\u2014 No pressurization i 5 10 15 20 25 30 35 40 45 S c r e w s p e e d (rpm) Figure 5-30. Effects of pressure difference between hopper and receiving vessel on average torque for ground wood pellets-2 and screw-1 with initial hopper level=0.45 m. For properties of the biomass materials, see Table 4-4. 90 80 |-? 7 0 Z oT 60 3 CT O 50 E 2 40 X ro 30 20 Pressure difference: - \u2022 - 1500 Pa, air flow: 0.002 m3\/s - \u2022 - 1000 Pa, airflow: 0.001 m3\/s \u2014O\u2014 No pressurization \u00a7 5 10 15 20 25 30 35 40 45 S c r e w s p e e d (rpm) Figure 5-31. Effects of pressure difference between hopper and receiving vessel on maximum torque for ground wood pellets-2 and screw-1 with initial hopper level=0.45 m. For properties of the biomass materials, see Table 4-4. Chapter 5. Pilot study: Experimental results 155 0 5 10 15 20 25 30 35 40 45 Screw speed (rpm) Figure 5-32. Effects of pressure difference between hopper and receiving vessel on mass flow rate of ground wood pellets-2 for screw-1 with initial hopper level=0.45 m. For properties of the biomass materials, see Table 4-4. 5.1.3.9 Effect of screw configurations Two different screw geometries, screw-1 and screw-2, shown in Figure 4-3, were compared in the present study. Figures 5-33 to 5-35 indicate that screw-2 reduced the torque requirements. The reason is mainly because screw-2 provides a relatively uniform flow in the hopper due to its increased capacity along the length of the screw, as well as a larger clearance between the flight tips and the casing surface due to the reduced screw diameter compared to screw-1. The reduced torque requirements were, however, accompanied by a decrease in efficiency as shown in Figures 5-36 and 5-37. A tapered or extended section beyond the screw can be employed to form seal plugs in order to prevent backflow of gases and bed materials from the reactor. Chapter 5. Pilot study: Experimental results 156 160 140 120 \u2014 100 h \u2014 \u2022 \u2014 Max. torque for screw-1 \u2014 \u2022 \u2014 Max. torque for screw -2 \u2014 o \u2014 A v e . torque for screw-1 \u2014 it\u2014 A v e . torque for screw -2 0) 3 tx 80 \\-Figure 5-33. Effects of screw configurations on torque requirements for wood pellets with initial hopper level=0.30 m. For properties of the biomass materials, see Table 4-4. CD 3 CX 150 140 130 120 110 100 90 80 70 h 60 50 40 30 20 |-10 - \u2022 \u2014 Max. torque for screw 1 - * \u2014 Max. torque for screw 2 - \u2022 \u2014 Ave . torque for screw 1 Ave. torque for screw 2 5 10 15 20 25 30 35 40 45 Screw speed (rpm) Figure 5-34. Effects of screw configurations on torque requirements for ground wood pellets-1 with initial hopper level=0.45 m. For properties of the biomass materials, see Table 4-4. Chapter 5. Pilot study: Experimental results 1 CD 3 ET 120 110 100 90 80 70 60 50 40 30 20 |-10 0 - \u2022 \u2014 Max. torque for screw 1 Max. torque for screw 2 - \u2022 \u2014 Ave . torque for screw 1 -iX\u2014 Ave . torque for screw 2 \u2022 - - s -10 15 20 25 30 S c r e w s p e e d (rpm) 35 40 45 Figure 5-35. Effects of screw configurations on torque requirements for ground wood pellets-2 with initial hopper level=0.45 m. For properties of the biomass materials, see Table 4-4. 600 25 30 35 40 45 Screw speed (rpm) Figure 5-36. Effects of screw configurations on mass flow rate for wood pellets (hopper level=0.30 m) and ground wood pellets (hopper level=0.45 m). For properties of the biomass materials, see Table 4-4. Chapter 5. Pilot study Experimental results 158 1.0 U - \u2022 - Wood pellets for screw 1 1 --O-- Wood pellets for screw 2 o 5 10 15 20 25 30 35 40 45 Screw speed (rpm) Figure 5-37. Effects of screw configurations on volumetric flow rate for wood pellets (hopper level=0.30 m) and ground wood pellets (hopper level=0.45 m). For properties of the biomass materials, see Table 4-4. 5.2 Summary (1) The level of solids in the hopper is an important factor affecting blockage inside screw feeders. For wood pellets of uniform size, when the hopper level exceeded 0.35 m, blockage could occur, whereas no blockage occurred for hopper levels less than 0.30 m. For a hopper level exceeding 0.4 m, blockage occurred almost immediately after starting the screw feeder. This blockage was irreversible and could not be broken up by reversing or restarting the motor. Spheroidal polyethylene particles never blocked for hopper levels < 0.60 m due to their regular shape and smooth surfaces. (2) Larger particles, more irregular particle shapes, rougher particle surfaces and larger bulk densities increased the tendency to block in the hopper-screw feeder. The torque required to Chapter 5. Pilot study: Experimental results 159 feed wood pellets was larger than for ground wood pellets due mainly to different sizes of the pellets. (3) Irregular particle shapes and rougher particle surfaces made ground wood pellets-1 more difficult to feed than polyethylene particles. (4) Particle size distribution plays a significant role in determining bulk flow. Wood pellets containing some fines blocked more frequently than wood pellets of uniform size. This is contrary to fluidization where fines promote better fluidization characteristics. Wider size distribution, especially large particles, required larger torque for hog fuel-1 compared to ground hog fuel and sawdust-1. (5) High moisture content (e.g. 40 and 60%) caused larger cohesion and adhesion, making biomass fuels more likely to bridge in the hopper. Intermittent bridging in the hopper reduced the volumetric flow rate for wet biomass fuels. Wet biomass generally needed much more torque to achieve blockage-free feeding than dry biomass. (6) Higher compressibility led to higher volumetric flow rates for screw feeding than for incompressible materials. Compressible biomass fuels passed through tapered sections more readily than incompressible materials. Plug formation inside the screw casing was also facilitated by increased compressibility, especially inside the extended \"choke\" section beyond the screw. (7) The choke section played an important role in biomass feeding. The choke section length and casing configurations (e.g. tapered and extended sections) were closely related to plug formation and plug sealing of the reactor, while also affecting the torque requirements. (8) Pressurizing the hopper slightly relative to the receiving vessel generally increased the feed rate and decreased the torque requirements, while also preventing backflow of gases and bed materials. Chapter 5. Pilot study: Experimental results 160 (9) More compact materials (i.e. larger bulk density) and non-uniform moisture content tend to increase the torque requirements for feeding. (10) Careful refdling does not disrupt feeding, especially for biomass fuels of low bulk density. (11) Large clearance and increasing capacity along the length of screw-2 led to reduced torque requirements. Small clearance caused larger torque requirements and a greater blockage tendency, as well as better plug sealing!, for screw-1. (12) For biomass feeding, the choke section may be longer, e.g. up to 6-10 times the pitch, in order to promote plug formation and prevent backflow of hot gases and bed materials from the reactor. Maximum torque, rather than starting torque, is critical to screw feeders with long choke sections. (13) Torque requirements were nearly independent of screw speeds, both for compressible and incompressible solid materials. Chapter 6. Modeling of biomass feeding 161 CHAPTER 6. MODELING OF BIOMASS FEEDING 6.1 Introduction The flow patterns developed by a screw feeder connected to a hopper have been studied extensively in previous work, with particular reference to the volumetric capacity, mechanics and torque characteristics. Metcalf (1966) analyzed the mechanics of a screw feeder, especially the delivery rate and the torque required to feed various coals. The resulting model assumed a rigid plug of bulk materials in the screw pockets moving helically at an angle to the screw axis. Some materials may move in this manner, especially those with large internal friction angles, but observations indicate that shear and velocity gradients exist within screw feeders for most materials. Burkhardt (1967) conducted experiments on the effects of pitch (i.e. distance between adjacent screw flights), radial clearance, hopper exposure and hopper level on the performance of screw feeders. Carleton et al. (1969) discussed the performance of screw conveyors and screw feeders based on experiments focused on the effects of screw geometry, speed, fill level and material properties. Bates (1969) provided detailed analysis of mechanics and entrained patterns of screw feeders, especially combinations of screw feeders and hoppers. Rautenbach and Schumacher (1987) derived a relevant set of dimensional parameters by dimensional analysis to calculate the power consumption and transport capacity. Two geometrically similar screws were compared for scale-up experiments. Several analyses have focused on flow in screw feeders. The geometry appears in Figure 6-1. Roberts (1991 ;1992), Roberts and Manjunath (1994), and Roberts (1996) analyzed the volumetric characteristics and mechanics of screw feeders in relation to the bulk solid draw-down characteristics of the feed hopper. Distribution of throughput along screw and uniform Chapter 6. Modeling of biomass feeding 162 draw-down patterns were investigated. It was assumed that the force exerted on the screw flights is distributed uniformly along the whole screw length, with three empirical ratios ( Kx, K2 and K3 in the hopper section, see Figure 6-1) to determine the required torque. Y u and Arnold (1995; 1996) estimated the volumetric capacity arid efficiency of screw feeders. They proposed an equivalent helix angle for screw flights and an equivalent helix angle for material motion. The effects of screw parameters (e.g. ratio of pitch to screw diameter) and clearance on the volumetric efficiency and volumetric capacity were also investigated. Y u and Arnold (1996) conducted experiments on flow in a wedge-shaped hopper. Different screw configurations and limitations of some methods of increasing the screw capacity were investigated. Shear surface O S c r e w flights Q Ana lys is circle Hopper Bulk sol ids Core shaft Figure 6-1. Stress around boundary in hopper section; (o~v is the vertical stress exerted by bulk solids at the hopper outlet). Yu and Arnold (1997) proposed a theoretical model for torque requirements for single screw feeders. They assumed that the load imposed on a screw feeder by the bulk solids in the hopper is determined by the major consolidation stress. Considering the bulk material boundary Chapter 6. Modeling of biomass feeding 163 in a pocket between adjacent flights, forces are imposed on five surfaces (see five labels in Figure 6-2) With boundary conditions applying to the bulk material moving within screw flights, two basic regions were specified in the hopper section: an upper region in which a \"shear surface\" is assumed, representing the interface between bulk material surrounding the screw and bulk material propelled by the screw, and a lower region in which bulk material moves within a limited space. In the choke section, a rigid upper casing surface was assumed to limit the screw flight space, instead of a shear surface. The motion of particles in screw feeders was simulated by a Discrete Element Method, to analyze mixing and transportation of the particles inside a screw feeder (Tanida et al., 1998). Background information on screw feeders was given by Bates (2000) and Bell (2003). Most analyses of the torque characteristics of screw feeders have been based on flow conditions, rather than an initial filling condition. Screw feeding of biomass and the effects of the choke section on screw feeding have been ignored in previous research. Shear surface Trailing side of flight D riving side of flight at o a: u P Z Figure 6-2. Five boundary surfaces for a material element in a pocket. Chapter 6. Modeling of biomass feeding 164 Schematics of our biomass feeding systems (including upper hopper, lower hopper and screw feeder) appear in Figures 4-2 and 4-3. The dimensions of the hopper-screw feeder are provided in Table 4-1. Biomass fuels (e.g. wood pellets, hog fuel and sawdusts) were added to the lower hopper and the surface flattened. The current model is intended to delineate what limits screw feeding in terms of the mechanisms of blockage and to predict torque requirements for biomass screw feeding. It extends previous models by considering effects of all boundaries (driving side, trailing side, core shaft and flight tips) on torque, and allowing for compression in the choke section, as well as in the hopper section. Unlike previous models, the choke section, whether straight or tapered, is explicitly included in this model. Predictions are compared with the experimental results presented in the previous chapter. Temperature variation and thermal effects are neglected in the present study. 6.2 Estimation of Volumetric and Mass Flow Rates Screw feeders are volumetric devices (see Chapter 2). The velocity of a particulate material as it is conveyed by a screw feeder is a vector having an angle to the direction of rotation (see Figure 6-2). As the screw rotates, particles move in helical paths of direction opposite to that of the screw. Friction between the solids and screw flights\/casing surface, together with the configuration of the screw itself, determines the efficiency of the screw feeder. The efficiency decreases as the clearance between the discharge casing surface and screw flight tips expands. In a screw feeder, an auger tends to compress the feedstock into a compact plug. The compression of the plug is aided by tapering (converging) the feed channel or gradually reducing the pitch of the screw as the feed material approaches the outlet. Chapter 6. Modeling of biomass feeding 165 The volumetric flow rate is predicted by Haaker et al. (1993), Yu and Arnold (1996), and Roberts (1996). The feeder volumetric flow rate is calculated based on screw and casing dimensions (see Figure 6-2) at the entrance to the choke section in the present study. where ' c = Clearance between screw flight tips and trough or casing inside surface, m. \/ = Rotational speed of screw feeder, rpm. k = Coefficient, 0 < k < 1, accounting for a possible dead layer of material between the screw flights and the trough or casing wall, k = 0 indicates full wall slip with no dead layer; k = 1 indicates an annular layer in the choke section with the material shearing at the flight radius, k needs to be fitted by experiments or based on experience. P = Pitch of screw, m. R0 = Screw flight radius, m. Rc = Core shaft radius, m. V =Volumetric flow rate, m3\/s. Vm = Maximum theoretical throughput with screw feeder completely full and particles moving at the feeder speed without slip and\/or rotational motion. y = Thickness of screw flight, m. r\/v = Volumetric efficiency, r\/v = VI Vm, dimensionless. In practice, the actual volumetric flow, V , is less than Vm for several reasons: (1) The axial velocity of particles is less than the ideal or optimum velocity owing to the rotary motion imparted by the screw. (6-1) Chapter 6. Modeling of biomass feeding 166 (2) Slip may occur in the clearance space between the screw and casing. (3) The filling fraction of screw pockets decreases as rotational speed increases. The corresponding mass flow rate M is obtained by multiplying by the bulk density, pb, at the hopper outlet (i.e. interface between hopper and screw). M = PbV = mjr(P - y)[(R2 -R2) + (\\- k)(2cRa + c2 )]ph x {- (6-2) 61) The thickness of the screw flight is usually neglected in predicting the flow rate. Typically the mass flow rate is employed to identify the transport capacity of screw feeders, especially for feeding into reactors. Since most biomass materials are compressible, their bulk density varies according to the compaction ratio. Inside the screw feeder, the bulk density is expected to depend on the radial and axial positions due to complicated dilation and compression conditions. The bulk density in the choke section is generally employed in estimating the mass flow rate. The loose bulk density can only be used if there is insignificant compression of the biomass in the hopper and screw feeder. h-oo 1 \u2022 1 \u2022 1 \u2022 1 \u2022 L-0 10 20 30 40 Screw speed (rpm) Figure 6-3. Theoretical volumetric flow rate prediction neglecting particle properties. Chapter 6. Modeling of biomass feeding 167 Different k values lead to different flowrate predictions. However, the differences are not very great as shown in Figure 6-3. In the present study, it is assumed that k = 1 , i.e. the clearance effect on the flow rate is neglected. For one revolution, the axial movement of each flight is P . Thus, the volumetric efficiency of screw feeder can be estimated from the geometry shown in Figure 6-4 (Yu and Arnold, 1997): Figure 6-4. Velocity and displacement diagram for element at screw radius r. S\u201e S\u201ecota. tan \/L c 1 + tan\/lr cot a . Op r r tan 2 P tana + tan \/ L (6-3) (6-4) (6-5) Hence the volumetric efficiency can be expressed by Chapter 6. Modeling of biomass feeding 168 17 = t a n A - (6-6) tan a r + tan \/L where a r = Flight helical angle at screw radius r , radians. <j>f = Wall friction angle between bulk solids and flight surfaces, radians. Here we make use of the relationship ar + Ar +0f = 90\u00b0, as shown in Figure 6-4. Because the flight face varies in helix angle (ar) from a minimum at the outside radius to a maximum at the core shaft, the bulk volume transported per revolution within a pocket can be estimated from the following equation, given by Haaker et al. (1993), Roberts and Manjunath (1994), and Yu and Arnold (1996): i 7 , = ^ T ^ f ^ rdr (6-7) R] -R- *c tana, +tanA r From Figure 6-4, the following expressions exist at r : P P tan a , = \u2014 = (6-8) 2ny.r TT 1- tana, tan^ r 2nx.r -Pt&nd>r tan Ar =tan(--cx r - ^ ) = cot(a f +#,) = \u2014 = \u2014 (6-9) 2 tan txr + tan <\/>f P + 2n x r tan <\/>f Substituting Equations 6-8 and 6-9 into Equation 6-6 gives: r n l + 2;rtan<zL \u2014 7\u201e = t a n \" f , =1 (6-10) tana, + tan Xr l + 4 7 r 2 ( f \\ i P The volumetric efficiency can be expressed as 2P2 fioip \\ + 2n\\and>f(r IP) i]v = , f (1 ? 1 7 )(r\/P)d(r\/P) (6-11) Chapter 6. Modeling of biomass feeding 169 Equation 6-11 is exactly the same as obtained by Robert and Manjunath (1994), and Yu and Arnold (1996). Equation 6-11 can be solved either analytically or numerically. Several other theories have also led to estimates of the volumetric efficiency: (1) Haaker et al. (1993) proposed a method based on the plug flow of bulk solids. It is assumed that the internal friction of bulk solids is great enough to prevent internal shear. The helical angle of the outer radius of the flight (aa) is then utilized, giving t a n a Q = - ^ - (6-12) 2 o = 9 0 \u00b0 -a0-<t>f (6-13) tan\/t0 <s IAS Vv=~ ; \u2014 - (6-14) tan aQ + tan A 0 (2) Bates (1969) proposed a mean radius, Rm , obtained from: TiRl - TtRl = nRl - nRl (6-15) so that p2 . r>2 Rm=,^4^- (6-16) A mean helical angle, am, can then be calculated from: p tana m = (6-17) 2nRm Hence the volumetric efficiency can be obtained from: \u201e v = (6-18) tan am + tan X mwhere Xm =90\u00b0-am-<\/>f (6-19) Chapter 6. Modeling of biomass feeding 170 (3) Roberts and Manjunath (1994) assumed an average radius expressed by: \u00ab - = ^ <M0) The volumetric efficiency is then given by 1 + 2 ^ - t a n ^ ^ r?v=l ~ r ^ - (6-21) 1 + 4 ^ 2 ( ^ 2 P Equation 6-21 is exactly the same as Equation 6-10 except that an average radius replaces r. Equation 6-11 provides a slightly smaller prediction than other methods, as indicated in Figure 6-5. For compressible materials (e.g. sawdusts and hog fuel), the volumetric flow rate tends to be larger than for incompressible materials if the compression inside the choke section is significant and the loose bulk density is assumed for materials leaving the screw feeder. In the present study, the theoretical prediction of volumetric efficiency is based on Equation 6-11, with modification due to compression of biomass inside the coke section, as discussed below. 6.3 Mechanics, Torque and Power Analysis for Hopper-Screw Feeders There are two main regions for the screw feeder, the hopper feeding section and choke (or conveying) section as shown in Figure 4-1. The analysis presented below considers both sections. Once flow is initiated, active stress fields change to passive or arched stress fields inside the hopper as shown in Figure 6-6. Initial filling and flow conditions lead to different vertical forces acting on screw surfaces at the hopper outlet, causing different mechanics and torque for screw feeders. For the initial condition, we focus on the hopper feeding section, since there is no flow in the choke section in this initial static state. Chapter 6. Modeling of biomass feeding 1 0.95 0.90 I O 0.85 c d> O 0.80 it \" 0.75 <U 0.70 E 3 \"g 0.60 u =5 0.55 o \u00b0 - 0.50 0.45 -Screw-1 ^ V - - ^^^^ Eq. 6-18 Eq. 6-14 \" Eq. 6-11\/ ^i>.^. \/ *-s, ^ -- \\ Eq. 6-21 1 Haakeretal.(1993) Bates (1969) ' \u2022 A \\ Roberts and Manjunath (1994) \\>. Yu and Arnold (1996) i . i . i . i V . i I i I 10 20 30 40 50 60 Friction angle on screw flight (degrees) Figure 6-5. Prediction of volumetric efficiency (For screw configurations, see Figure 4-3). partially active, active stress field passive stress field partially pa stress field (a) during filling (b) during discharge (c) partial discharge Figure 6-6. Directions of major principal stress in a hopper during filling and discharge (Arnold et al., 1980; Tardos, 1999). Chapter 6. Modeling of biomass feeding 172 6.3.1 Estimation of feeder load for initial filling and flow conditions The theoretical prediction for a mass flow hopper requires consideration of both initial and flow consolidation stresses acting on the bulk solids. Following the approach adopted by Mclean and Arnold (1979), the feeder load Qv and vertical stress av acting on the outlet of a mass flow hopper are given by Qv=qpbgL\\-'\"B2 + - (6-22) r\\~m r>2 + m = ^ \" = qpbgL?l?+\" (6-23) LhB where B = Hopper outlet width or diameter, m. g = Acceleration of gravity, m\/s Lh = Hopper outlet length, m. m= Hopper shape factor; m=l for axisymmetric flow or a conical hopper; m=0 for plane flow or a wedge-shaped hopper, dimensionless Qv = Feeder load exerted by bulk solids at hopper outlet, N . q = Dimensionless surcharge factor, dimensionless <TV - Vertical stress exerted by bulk solids at hopper outlet as shown in Figure 6-1, Pa. pb = Bulk density of solids in hopper, kg\/m We assume that the feeder load is distributed uniformly over the whole area of the hopper outlet, both initially and subsequently during flow. For the wedge-shaped hopper in the present study, Equations 6-22 and 6-23 become Qv=qpbgLhB2 (6-24) Chapter 6. Modeling of biomass feeding 173 o\\ = qphgB (6-25) 6.3.1.1 Initial filling condition An active state stress is assumed as the initial filling conditions. The feeder load at the outlet is considered to be given by the weight of the material in the hopper section, plus the surcharge (i.e. Qc, see Figure 6-7) at the transition of the vertical section and the hopper (if applicable), minus the vertical wall support. The original method of Jenike (1977) was employed by McLean and Arnold (1979), Arnold et al. (1980) and Manjunnath and Roberts (1986) for the initial stress in the hopper. The resulting dimensionless initial surcharge factor is given by D= Width of long rectangular vertical section of bin or solid surface width in hopper, m m - 0 for plane flow or wedge-shaped hoppers, or 1 for axisymmetric or conical hoppers. Qc = Surcharge force at transition between vertical section and hopper (see Figure 6-7), N . a = Hopper half-angle, radians. D in the denominator of the middle term of the section within the bracket was replaced by the hopper outlet width B by Manjunnath and Roberts (1986), leading to (6-26) where 2 Ac = Cross-sectional area of vertical section of bin, m . (6-27) Chapter 6. Modeling of biomass feeding 174 Since there was no surcharge force above the hopper (i.e. the hopper was never full, see Figure 6-7), then Q c I A c =0 in our case. Also the hopper was wedge-shaped in the present study. Hence both Equations 6-26 and 6-27 simplify to 9 1 0 m m Figure 6-7. Coordinates of hopper. 1 ( ^ - 1 ) (6-28) 2 tan a K B The vertical stress at the hopper outlet for initial conditions can be simplified to: ^,t=qtPbgB (6-29) For the hopper region, Jenike (1977) assumed a linear hydrostatic pressure gradient. In the present study, the upper surface of the bulk solids was flattened after the biomass was added to the hopper as indicated in Figure 6-7, where the coordinates are defined. The vertical stress at the hopper outlet can be expressed by Chapter 6. Modeling of biomass feeding 175 <Tvi=Pbg(H,-h0-y0) (6-30) Equations 6-29 and 6-30 are same, except that the former incorporated an initial dimensionless surcharge factor. Arnold et al. (1980) suggested that Equation 6-30 be used to calculate the filling stress providing that 2a + 2sx > n (6-31) The feeder load can be calculated from Equation 6-24, so that Q,i=crvlLhB = qipbgLhB2=pbg(Ht -h0 -y\u201e)LhB (6-32) where h0 = Distance between solids free surface and hopper top transition, see Figure 6-7, m. H, = Distance between apex and top transition of hopper as shown in Figure 6-7, m. Qvj = Initial feeder load exerted by bulk solids at hopper outlet, N . y = Vertical coordinate with apex of hopper as origin and upward direction as positive, m. y 0 = Distance between apex of hopper and axis of screw as shown in Figure 6-7, m. <7\u201e, = Vertical stress due to bulk solids at hopper outlet for initial condition, Pa. , , = ^ + ^ - + i c o s - 1 ( ^ ) , radians.. ' 4 2 2 sin\u00a3 = Angle of kinetic friction between bulk solids and hopper wall, radians. 5 = Effective angle of internal friction of bulk solids, radians. 6.3.1.2 Flow condition According to Mclean and Arnold (1979), Manjunnath and Roberts (1986), and Yu and Arnold (1996), the vertical stress at the hopper outlet for the flow condition can be calculated as o-v=qfPbgB (6-33) where Chapter 6. Modeling of biomass feeding 176 q f = Dimensionless surcharge factor for flow condition, dimensionless 1 4 tan or F(l + s in\u00a3cos2\/?)( tana + tan^M,) 1 ( X -1) sin a \\ + m (6-34) or alternatively = TT T(l + sin\u00a3) f 4 2 ( X - l ) s i n a sin 8 1 - sin <5 sin(2\/3 + a) sin a + 1 Y = (a + P) sin a + sin \/? sin(a + (3) (1 - s i n \u00a3 ) s i n 2 ( a + \/?) (6-35) (6-36) (6-37) with a and \/? in radians, and smo radians. (6-38) Here m = 0 for plane flow or wedge-shaped hoppers, or 1 for axisymmetric or conical hoppers. The second expression for qf provides a better prediction of the flow surcharge factor according to Manjunnath and Roberts (1986). Hence we use Equation 6-35 in the present study. By combining Equations 6-24 and 6-33, we obtain an expression for the feeder load, Qv=avLB = qfPbgLB2 (6-39) 6.3.2 Forces, torque and power analysis in hopper feeding section For the material within one pocket, forces are imposed on five boundary surfaces, i.e. the shear surface, driving side of the flight, trailing side of the flight, core shaft surface and trough surface (see Figure 6-2). In the choke section, a rigid upper casing surface limits the screw space instead of a shear surface (see Figure 6-8). There may or may not be bulk materials between the flight tips and the upper casing inside surface (i.e. upper clearance), depending on the feeding conditions. It is presumed that the forces on the individual surfaces within one pocket are Chapter 6. Modeling of biomass feeding 177 distributed uniformly or can be represented by average forces. The material element in a pocket is assumed to be at equilibrium, either static (initial filling condition) or moving at constant speed (flow condition) to simplify calculations through forces balances. Gravity, centrifugal force and cohesion are neglected. For comparison and convenience, we assume axial forces that push the material forward to be positive, whereas those that resist movement of the material are negative. KA<TV Figure 6-8. Stress around boundary in choke section. 6.3.2.1 Forces on shear surface The bulk solid in the hopper exerts pressure at the hopper outlet, enhancing the shear strength of the material and making it difficult for the screw to rotate. Cohesion is ignored and only internal friction is considered. The axial resisting force on the material element within one pocket on the shear surface, shown in Figure 6-9, is dFsa = -MeavRoPd0cos(ao + <\/>f) (6-40) Chapter 6. Modeling of biomass feeding 178 Fst, =-\/ie(7vR0Pcos(a0 + <\/>f)^d0 = -^\/iecp cos(a 0 + <j)f)(jvD20 or Fsa =-ksaavD0 with ksa = ^Mecp cos(a 0 + <j)f) (6-41) (6-42) (6-43) dFs: Tangential direction Axial direction Direction of material element moving on surface Direction of resisting force acting on surface Figure 6-9. Forces on shear surface. The tangential resisting force acting on the element on the shear surface in one pocket is dFst = -pie(jv R0 PdO sin(\u00ab 0 + <\/>f) (6-44) so that Fsl = -iiecrvR0Psm(a0 +tf)[dO = ~!*ecp sin(a 0 + tf)crvD20 (6-45) Hence Fsl = -ks,crvD2 (6-46) Chapter 6. Modeling of biomass feeding 179 with (6-47) where c = Ratio of pitch to screw flight diameter, cp = PI Do, -. a0 = Screw flight helix angle at outside screw diameter, radians. <\/>f = Wall friction angle of bulk solids on screw surface, radians. fj.e = Equivalent friction coefficient of bulk solids, with ju = (0.8 ~ l)sinc> recommended by Roberts (1996). 6.3.2.2 Forces on core surface The frictional force of the screw shaft contributes to turning the material inside the screw pockets, while, at the same time, preventing the material from moving forward. The axial resisting force acting on the element of bulk solid on the core surface, as shown in Figure 6-10, is When a moving element of material reaches steady states, there is equilibrium between the driving and resisting forces. Assuming that the axial and radial stresses are functions of x only, as shown in Figure 6-11, a force balance on the material element in a pocket gives e d F c a =-2nRc<Tm,M\u00a5Kdxsm(ac) (6-48) F =-' 1 ca 27rRco-wa\/uwc sm(ac)\\^dx = -ncdcpcrwa{iwc sin(a c)cr, r aD 0 2 (6-49) (R, -Rc)ax = (R, -Rc)(crx +dax) + 2zwdx (6-50) Let (6-51) so that (6-52) Chapter 6. Modeling of biomass feeding dFc Axial direction Tangential direction Direction of material element moving on shaftsurface Direction of resisting force acting on surface Figure 6-10. Forces on core shaft surface. Driving side Mater ia l mov ing direct ion Rt-Rc Trailing side Figure 6-11. Stress on material element in a pocket. Chapter 6. Modeling of biomass feeding 181 Integrating Equation 6-50 with the boundary condition erx = crv at x = P (6-53) we obtain Ox = o\\- e x P 2fiMP-x) (6-54) The average normal wall stress can be obtained from (6-55) After integration iPt ~Cd) exp( p - ) - \\ c, -cd (6-56) Hence Equation 6-49 can be expressed by Ka = -kcacrvD20 (6-57) . , , 7r(c. -cd)cd smac with kca ^ ^expj ^Mwc^sC p (c, -cd) 7T(C, -Cd)cdCp ^c2p+n cd exp 4MWC^SCP (c, -cd) -1 (6-58) The tangential resistance force on the material element in a pocket on the core surface is Fcl =ka(TvDl (6-59) where kr 7T(C, -cd)cd cosa c exp 4M\u201ecAscp (ct -cd) 7T2(C, -Cd)cd 4^C2p+7T2C2d exp (c, -cd) -1 (6-60) kca Cp ka n x c\u201e (6-61) with cd = Ratio of core shaft diameter to screw flight diameter, cd = Rc IR0 = Dcl D0, Chapter 6. Modeling of biomass feeding 182 cp = Ratio of pitch to screw flight diameter, cp = PI Do, -. c, = Ratio of trough or casing diameter to screw diameter, i.e. ct = 2Rt ID0, -. D0 = Screw flight diameter, m. R, - Trough inside radius, Rt = R0 + c, m. ac = Screw flight helix angle at core shaft surface such that tan ac = P12nRc, radians. \/uw = Wall friction coefficient between bulk solid and trough or core shaft surface, -. Mwc= Wall friction coefficient between bulk solid and core shaft surface, -. jjd = Effective coefficient of internal friction, jud = tanS, -. <TW = Normal wall stress perpendicular to trough wall and core shaft surface, Pa. crwo = Average normal wall stress perpendicular to trough wall and core shaft, Pa. crx = Axial compression stress inside screw feeder, Pa. TW = Shear stress on trough wall and core shaft surface, Pa. Xs \u2014 Ratio of normal wall stress to axial compression stress on a confining surface as shown in Appendix C. X = ^ = -snW-tJ\u2122** ( 6 . 6 2 ) o-x s i n ( 2 \/ ? - 0 J + c o s 2 G 0 - 0 J s i n ^ , where 2 < \u00bb . + \u00bb n - ' ( ^ . ) sind radians. Equation 6-62 is based on the assumption that yield takes place on the wall as shown in Figure C - l . Chapter 6. Modeling of biomass feeding 183 6.3.2.3 Forces on trailing side of a flight The frictional force due to the trailing side of a screw flight prevents the material from moving forward, while, at the same time, helping to turn the material inside the screw pockets i f the wall friction angle of the bulk solid on the screw flight exceeds the helix angle of the trailing flight in Figure 6-12. Since the wall friction angle of biomass particles on screw flights is generally greater than the helix angle of the trailing flight, we begin by assuming that the tangential force on the trailing side helps the material inside the screw pockets rotate. Figure 6-12. Forces on trailing side of flight. The axial force acting on the material element in a pocket on the trailing side is cos(dr -ar) dFfa = -Xsav \u2014 \u2014rdrdO = -A,crvrdrd0(l + tana r tan<\/>f) (6-63) cos ar cos <j)f Chapter 6. Modeling of biomass feeding 184 Substituting tana,. = PI2TU- and tan^r =\u2022 Hf and integrating Equation 6-63 for r from Rc to R0 and for 0 from 0 to 2n , we obtain Ffa=-kfacrvDt (6-64) with kfa = A s (6-65) The tangential force acting on the material element on the trailing side is vdvdO dFn = Xsav \u2014 sin(^ f - ar) (6-66) cos a,, cos ^ or Fft=kflcrvD20 (6-67) with kfl = X nu, c ' ( l - c j ) - ^ ( l - c ) (6-68) 4 \"2 i_ where ar = Screw flight helix angle at radius r, radians. \/j, = Wall friction coefficient between bulk solids and screw flight surface, = t an^ \/ 5 -. 6.3.2.4 Forces on trough surface The frictional force exerted by the inside surface of the trough on the material element resists the material from moving forward and turning. We assume that particles in the vicinity of the trough surface move in the same manner as those in the vicinity of the flight tips. Generally full wall slip is likely to take place when M\u00ab < ^  (6-69) Ra+c where c = Clearance between screw flight tips and trough or casing inside surface, m. juwl = Wall friction coefficient between bulk solids and trough surface, -. Chapter 6. Modeling of biomass feeding 185 \/jd = Effective coefficient of internal friction of bulk solids, -. For some biomass particles when \/\/\u201e,, <-judR0l(R0 +c), full wall slip may be assumed. When\/^,,,, > j.idR0 l(R0 +c), a coherent lining may form in the lower part of the screw in the hopper feeding section or in the choke section sheared by the flight tips. The axial resisting force acting on a material element within a pocket on the trough surface indicated in Figure 6-13, is dFla = -nR, \/\/\u201e, crwa dx cos(a0 +0f) (6-70) Figure 6-13. Forces on trough surface. Substituting tanor0 =PI27tR0&n& t a n ^ = juf and integrating Equation 6-70 for r from Rc to RQ and 0 from 0 to n, we obtain Chapter 6. Modeling of biomass feeding 186 Fla=-nC,{C' Q ) e o s ( a 0 + ^ ) e x p l o ovD] with Fla =-ktacrvD20 . 7TC,(C, - C D ) Ka \u2014\u2014cos(a 0 + ^)exp | 8 C, \u2014 CA (6-71) (6-72) (6-73) The tangential force acting on the material element within a pocket on the trough surface is dFtl = -TTR, juwt o-wa dx sin(\u00ab 0 + <\/>f) (6-74) or F\u201e = -kuavD] (7 Dl V o where k\u201e = \u2122t(Pt - c d ) . 8 sin(\u00abr0 + <\/>r)exp c, - c . (6-75) (6-76) (6-77) 6.3.2.5 Forces and torque on driving side of a flight The total axial force acting on the material element within a pocket transmitted by the driving side of the flight (see Figure 6-14) should equal the total resisting axial forces on the same material element due to the shear surface, core shaft surface, trailing side of flight and trough surface. It is assumed that the total force is applied uniformly to the surface of the driving side. The total force balance is P + p + p + p + p =0 C da ^ r s a ^ r c a + r fa + ta U (6-78) where da, sa, ca, fa, ta denote axial forces on the driving side of the flight, shear surface, core shaft surface, trailing side of the flight and trough surface, respectively. The resulting stress on the driving side of the flight is F: oda = da *{ksa+kca+kfa+kla) n{\\-c]) \u00b0 v = Kda\u00b0~v (6-79) Chapter 6. Modeling of biomass feeding 187 where *(Ka+Ka+kfa+kla) n(\\-c]) (6-80) The tangential force acting on the material element within a pocket transmitted by the driving flight is dFd, = adard Gdr tan(a r+<f>f) (6-81) Substituting tana, = P12m and tan^y = juf and integrating from 6=0 to 2n leads to: Fdl =27T(Tda\\^>r 1 + 2njj.fr ^ P 2m I P dr (6-82) Integrating Equation 6-82 from Rc to R0, we obtain (as derived in Appendix D) Chapter 6. Modeling of biomass feeding 188 Fdt = 2nadaD0 ^ ( l - ^ ) + i l ^ c p ( l - c J + ^ ( 1 : ^ ) C M n ( ^ An An1 ' 7TC,i (6-83) Note that the calculated stress on the driving side of a flight is not equal to the axial stress calculated from Equation 6-54 at x = 0 (i.e. ax = avexp[2juwAsP\/(\/?,- Rc)] ). Instead, the calculated axial stress at x = 0 in a pocket from Equation 6-54 is always larger than the stress on the driving side of the flight derived from Equation 6-79 for the boundary condition ax =nav at x = P (n>\\) (6-84) This indicates that the maximum axial stress at x - 0 in a pocket may not reach the theoretical maximum value, and that the axial stress distribution in a pocket may depend on flow conditions. The average axial stress is employed to reflect the magnitude of stress within a pocket. Equation 6-84 is the same as Equation 6-53 (i.e. <Jx = av at x = P) when n = 1. Note that n is introduced to adjust the boundary condition as discussed below. From Equations 6-51, 6-55, 6-56 and 6-84, the average axial stress (axa) in a pocket can be expressed by cr = no. exp( 4u A c (6-85) \u2022 The ratio of the average axial stress (<jxa) to the stress on the driving side (a d a ) for a material element within a pocket changes as n increases in Equation 6-84. Making the predicted starting torque equal to the measured starting torque leads to axa = O.S5ada for wood pellets. This also works well for polyethylene particles (see Table 6-1). Since average axial stress in the screw pockets oxa is not expected to be greater than the stress at the driving side of the flight, i.e. ada , we assume axa = 0.99crda for relatively light and compressible materials, which provides reasonable predictions of starting torques (see Table 6-1). Table 6-1. Gomparison of predicted and measured torques for screw-1 Name of specimen Mean particle diameter (mm) Bulk density (kg\/m3) Friction angle on carbon steel (deg) Internal friction angle (deg) Measured average torque (N.m) Measured maximum torque (N.m) Measured Starting torque (N.m) Calc averag (N ulated e torque .m) Calculated starting torque (N.m) 0.3 m 0.45 m 0.3 m 0.45 m 0.3 m 0.45 m 0.3 m 0.45 m 0.3 m 0.45 m Wood pellets 9.8 630 31.4 32.0 52.8 N\/A 72.6 N\/A 29.4 N\/A 58.3 75.9 30.0 44.9 Ground wood pellets-1 4.05 485 30.2 33.2 31.3 55.4 38.0 64.9 15.6 15.9 39.5 56.4 13.8 20.8 Ground wood pellets-2 0.55 423 . 30.4 38.0 27.7 43.5 32.6 51.6 13.1 \u202214.7 32.6 48.4 11.4 17.1 Sawdusts-1 0.45 210 31.8 38.0 16.5 21.7 19.9 25.8 8.9 9.0 16.3 23.6 6.3 9.4 Hog fuel-1 0.72 200 31.5 '. 39.0 13.0 21.7 25.2 33.1 10.5 11.8 15.5 23.0 5.5 8.2 Ground hog fuel 0.18 150 31.8 45.0 9.4 13.3 16.7 24.8 4.7. 5.5 9.7 15.1 3.4 5.0 Wood shavings-1 0.67 110 31.0 39.0 7.0 8.6 22.9 21.4 .4.2 6.8 7.1 10.4 2.99 4.48 Polyethylene particles 4 610 21.5 26.2 11.8 22.8 15.8 27.4 8.7 14.9 18.1 23.6 11.8 17.7 Chapter 6. Modeling of biomass feeding' \" ' 190 We do not consider the axa >crda case in the present study, although this would make starting torque predictions better for some materials (e.g. hog fuel-1). n is in the range of 1-1.5 for screw-1 in the present study. In other words, we set the boundary condition (see Equation 6-84) to make <jxa = O.S5crda and <jxa = 0.99crda for relatively incompressible and compressible materials, respectively. We do not consider n < 1 here since the minimum axial stress (on the trailing side of the flight, i.e. at x = P) for the material element is not expected to be less than the vertical stress at the hopper outlet (i.e. av). A different strategy is employed for screw-2 due to different screw configurations, as discussed below. Once the boundary condition is determined, the forces and stresses for a material element within a pocket can be predicted using the above procedures. The reason for the different stress ratios (i.e. 0.85 and 0.99) for incompressible and compressible materials is probably that the stress distribution for compressible materials within a pocket is more uniform than for incompressible particles. A uniform stress distribution within a pocket is expected to make the average axial stress very close to the stress on the driving side of a flight for compressible materials. If n = 1 were to be employed (Yu and Arnold, 1997) for the torque predictions, the predicted results would be slightly smaller than for n > 1, as adopted here. For compressible materials, the loose bulk density is first employed to calculate the vertical stress and torque requirements for both the initial and flow conditions. Once the vertical stress at the hopper outlet is determined, the compacted bulk density at the hopper outlet is estimated from the density-stress relation, py=a(cry+by (6-86) where a, b and c are constants, obtainable by curve fitting experimental data for the compacted bulk density and corresponding mean stress on the bulk solid surface. In this study, experiments were performed by adding weights to the top of biomass added to an initial depth of 0.12 m in a Chapter 6. Modeling of biomass feeding 191 cylinder of diameter 0.1 m. Least squares fitted values of a, b and c for various bulk materials are listed in Table 6-2. Although some researchers (e.g. Arnold et al., 1980) found that the bulk density could be well represented by equations of the form py =a(l + ay)b or py =acry, the former leads to a mathematically awkward expression, while the latter cannot give satisfactory predictions as the stress approaches zero. Hence they are replaced by Equation 6-86 in the present study without significant deviation. As an initial condition, ay can be expressed by Equation 6-30, so that where pyh is the compacted bulk density at y and H0 is the hopper level. The average bulk density, which does not differ significantly from the loose bulk density in the present study, can be used to calculate the initial vertical stress. The average bulk density was calculated as an arithmetic mean of the loose bulk density and compacted bulk density at the hopper outlet for simplicity. Values are listed in Table 6-2. During flow, the passive stress is not a simple function of y . The average bulk density obtained from the initial condition is adopted when there is flow in the present study. However, for relatively incompressible materials (e.g. polyethylene and wood pellets), the loose bulk density is employed in the calculations. The angle of kinetic wall friction and the effective angle of internal friction are used for both initial and flow conditions. Wall friction on the trough (carbon steel) and casing surfaces (carbon steel) are dominant compared to that on the stainless steel screw flight. Wall friction angles in the present study are based on slightly rusty carbon steel (see Chapter 4). (6-87) In view of Equation 6-86, the average bulk density can then be estimated by (6-88) Table 6-2. Predicted initial feeder load and vertical stress for screw-1 Name of specimen Mean diameter (mm)1'1 Bulk density (kg\/m3) a 121 b c Ave. bulk density 131 (kg\/m3) Initial vertical stress (Pa) Initial fe 0 ederload ^) Weight of bulk solid in hopper (N) @ 0.3 l 4 Jm @ 0.45 m @ 0.3 m @ 0.45 m @ 0.3 m @ 0.45 m @0.3 m @ 0.45 m Wood pellets 9.8 630 630 0 0 630 630 1850 2780 173 259 378 694 Ground wood pellets-1 4.05 485 485 0 0 485 485 1430 2140 133 199 291 534 Ground wood pellets-2 0.55 423 157 17800 0.1 427 428 1260 1890 117 176 254 466 Sawdusts-1 0.45 210 82 3297 0.12 212 . 213 624 941 58 88 126 231 Hog fuel-1 0.72 200 158 -359 0.05 199 202 584 892 55 83 120 220 Ground hog fuel 0.18 150 88 364 0.09 155 157 455 691 42 64 90 165 Wood shavings-1 0.67 110 35 1932 0.16 114 114 334 504 31 47 66 121 Polyethylene particles 4 610 610 0 0 610 610 1790 2690 167 251 370 678 Notes: [1] Volume-equivalent diameters for wood pellets and polyethylene particles, Sauter mean particle diameters for the other materials. [2] a, b and c constants for bulk density prediction, see Equation (6-86), R-square is 0.99 for ground hog fuel, 1.00 for Ground wood pellets-2, 0.99 for hog fuel-1, 1.00 for sawdust-1, 0.98 for wood shavings-1. [3] average bulk density obtained by arithmetic mean of loose bulk density and compacted bulk density at hopper outlet. [4] hopper level, 0.30 and 0.45 m in the present study. Chapter 6. Modeling of biomass feeding 193 The 0.30 m long cast acrylic tube at the discharge end of the screw feeder (used to assist visualization) is neglected. These simplifications are not expected to affect the predictions significantly. The torque generated within one pocket is given by T, = Td + Tc + Tf + TuP (6-89) where Tc = Torque due to core shaft surface, N.m. Td = Torque due to driving flight, N.m. Tf = Torque due to trailing flight, N.m. Ttj = Torque due to flight tip, N.m. The torque generated by the driving side of the screw flight is L = 2nada { r2 tan(ar + <j>f )dr (6-90) Substituting tana,. = PI2TTT and t a n ^ = fuf and integrating Equation 6-90 from r = Rc to R0, we obtain: Td=KscrdaD0=KsKdacrvDn (6-91) where 12 + 8 + An  + An2 n (6-92) Kda is calculated based on Equation 6-80. Equation 6-92 is derived in Appendix E. The torque generated by the core shaft surface is given by Chapter 6. Modeling of biomass feeding 194 Tc = FC[RC = - a C d - ^ <jvDl=\u2014km(T\u201eDl 2c, (6-93) Substitution of Equation 6-58 into Equation 6-93 leads to n2(c,-cd)cd T\u201e = \u2014 -exp 8^C^ + 7T2Ct 4\/\/ Xsc wc _ (c,~cd) -1 3 C7VD, (6-94) The torque generated by the trailing side of the screw flight is calculated from T,=*,crv\u00a3> siru^y -ar)r2dr cosa f costf>r gdO = 2nXscrv fo W f r J r2dr c cos>ar cosipf (6-95) Integrating Equation 6-95 from r = Rcto r = R0,we obtain Tf = nXspif(\\-c]) Xsc (\\-c2) 12 8 (6-96) Equation 6-96 is derived in Appendix F. A l l of these equations can also be solved by numerical integration to confirm the results. The torque required to overcome the flight tip surface resistance within a pocket is estimated by \"p 2 sin a\u201e (6-97) Rearranging Equation 6-97, we obtain T,IP = KpcrvDl (6-98) _ Ov +n<rwa)cbcpfif 4cr\u201e sin a\u201e (6-99) where cb = Ratio of flight thickness to screw diameter, -Chapter 6. Modeling of biomass feeding 195 The normal stresses on the flight tips are assumed to be <rv on the top and nawa on the bottom surfaces. The flight tip surface area in a pocket can be estimated by Aljp = yx P\/s'ma0. Note that the starting torque for the initial condition can be calculated if av is replaced by avj above. In the present study, the vertical stress for the flow condition crv was replaced by the arithmetic mean of crv\/ and crv, i.e. (avl +<Jv)\/2, considering the hopper level effects on the vertical stress at the hopper outlet. The influence of hopper level is generally neglected when there is flow in previous research, although some researchers (Arnold et al., 1980) considered the weight of a certain height of bulk solids above the hopper outlet as a feeder load. The hopper level is expected to have an insignificant effect on the vertical stress when there is flow if the hopper level exceeds twice the trough diameter, but higher hopper levels and refilling generally increase the fullness of screw pockets, including those in the choke section, leading to larger required torque, if bridging inside the hopper can be avoided during feeding. The torque required to rotate the material element in a pocket in the hopper section, with consideration of the flight tip resistance, is (6-100) where K. =k. 4K.. n(\\-cld) +k,. 4K ml -+-2cp +k.. 4Kr n(\\-c]) + k, 4\/C n(\\-c2d) + 7rAsJuf(\\-cd) slscp(\\-c]) 12 8 +k up (6-101) The first term reflects the contribution of the shear surface to torque requirements, the second the core shaft surface, the third the trough surface, the fourth and fifth the trailing side surface, and the final term reflects the flight tip surface contribution. Chapter 6. Modeling of biomass feeding 196 6.3.3 Forces, torque and power analysis in choke section 6.3.3.1 Straight casing in choke section The choke section (i.e. conveying section) is adjacent to the hopper (Figures 4-2 and 4-3). For effective flow control, the choke section should extend at least two standard pitch lengths (Yu and Arnold, 1997). For biomass feeding, especially to pressurized reactors, this section should be even longer for effective plug sealing. We assume that the screw is operating 100% full. The shear surface in the hopper section does not exist in the choke section. There may or may not be bulk material between the screw flight tips and the upper casing inside surface (i.e. upper clearance) due to different feeding conditions. For a cylindrical casing in the choke section, the above procedures apply, except that the shear surface must be replaced by a cylindrical sliding surface, giving. T,=K,ovDl (6-102) K. = k\u201e 4K.. 7TC\u201e TT(\\-C]) 2C, + 2k.. 4* , n(\\-c]) + k 4K, 7t(\\ + TTX^AX-C]) Xsc(\\-cd) 12 8 up (6-103) or 4K, TtC, n(\\-cd) 2c. + k\u201e 4* , n{\\-c2d) \\ + k 4KS 7T(l-Cd) 12 + k up (6-104) Equation 6-103 is based on the assumption that the screw pockets are close to 100% full, whereas Equation 6-104 assumes that there is no material in the upper part of the screw casing, Chapter 6. Modeling of biomass feeding 197 i.e. in the upper clearance. The shear surface term is eliminated and the trough surface term adjusted in Equations 6-103 and 6-104 compared to Equation 6-101. Equation 6-103 works well for screw-2 which has a relatively large clearance, with insignificant compression in the choke section compared to screw-1. When feeding is aided by air (or inert gases), the gas path generally lies in the upper clearance due to the effects of bulk solids gravity. Equation 6-104 can then be used to estimate the torque required for smooth screw feeding. When gases assist in feeding, the required torque is generally reduced since the fullness of screw pockets decreases due to the gas paths. Torque requirements for screw-2 are discussed below. Equations 6-103 and 6-104 underestimate torque requirements for the choke section for screw-1. The screw diameter of the screw feeder in the hopper section is 100 mm, so that the clearance is 1 mm, although the clearance in the choke section is higher (6-11 mm, as indicated in Figure 4-3). The increased clearance in the screw feeding direction for screw-1 is intended to release the axial and normal wall stresses at the discharge end of the screw feeder. Bulk solids are squeezed into the choke section when feeding is initiated. The accumulated solids in the choke section then make the axial stress even larger than in the hopper section, as shown in Table 6-3, and clearance effects are insignificant in the choke section. Although complicated compression and dilation make analysis of the choke section very difficult, we can reasonably assume the stress conditions in the choke section to be as follows: > The stress distribution within a pocket (i.e. in the space between adjacent flights) is of the same form as for the hopper section, but the boundary condition is now crx = CFx nav at x = P (CF > 1) (6-105) HereCF denotes the compression factor, which depends on the length of the choke section, screw configurations and material properties. Table 6-3. Predicted flow feeder load and stresses for screw-1 Name of specimen Wall friction angle on carbon steel (deg) Internal friction angle (deg) Vertical stress [ I ] (Pa) Feed ( ;r load N) Axial stress in hopperm (Pa) Axial stress in choke section [ 3 ' (Pa) @0.3 m @ 0.45 m @ 0.3 m @ 0.45 m @ 0.3 m @ 0.45 m @0.3 m @ 0.45 m Wood pellets 31.4 32.0 1680 2150 157 200 5820 7410 9760 13200 Ground wood pellets-1 30.2 33.2 1170 1530 109 143 2560 3340 11900 18300 Ground wood pellets-2 30.4 38.0 945 1260 88 117 2250 3000 12600 20200 Sawdusts-1 31.8 38.0 476 631 44 59 1180 1570 5450 8220 Hog fuel-1 31.5 39.0 446 594 42 55 1030 1370 5810 9320 Ground hog fuel 31.8 45.0 324 438 30 41 599 809 5110 8700 Wood shavings-1 31.0 39.0 251 334 23 31 573 764 2610 3960 Polyethylene particles 21.5 26.2 1570 2010 146 188 3270 421 4500 6000 Notes: [1] vertical stress at hopper outlet. [2] [3] average axial stresses for-a material element in a pocket. Chapter 6. Modeling of biomass feeding 199 From analysis of measured torques for different choke section lengths in the present study, it seems there is no significant change in CF as the choke section length varies from 3 to 8 time the pitch. In the present study, the compression factor is expressed by 2\/j X P CF = exp( M w ' xE) (6-106) where E can be calculated by E = C(f \\ )5 (6-107) c,D,2 with C = Constant dependant on material properties, -. c, = Ratio of casing diameter to screw flight diameter, c, = (DQ + 2c) I D0= 2R, ID0,-. D, = Casing inside diameter, m. H0 = Ht - h0 - y0, initial hopper level, m. Lc - Choke section length, m. qf = Dimensionless surcharge factor for flow condition. a = Hopper half-angle, radians. Here qf reflects the fullness of screw pockets when there is flow. The larger the surcharge factor, the larger the fullness in the choke section and the larger the compression factor. Larger H01 Dt and Lcl Dt, and smaller c( lead to a larger compression factor. Incompressible and compressible materials are expected to have different compression factors. C is closely related to torque predictions. The following two conditions are met for each material when C is determined: o Minimum value ((Tpre - T e x p ) 0 3,\u201e + (Tpre - T\u00a3xp )M5m) Chapter 6. Modeling of biomass feeding 200 ^ pre exp where Tpre is the predicted average torque and rexp is the measured average torque for each material. (Tpre -Texp)Q3m is the torque difference for a 0.30 m hopper level, and (Tpre -TexB) pre exp\/0.45m represents the torque difference for a hopper level of 0.45 m. These two conditions indicate that Tpre is equal to rexD or slightly larger than Texp ,and the difference between Tpre and Texp is minimized. C and CF are listed in Table 6-4. The minimum axial stress within a pocket in the choke section is expected to occur on the trailing side of the screw flight (i.e. at x = P ) and can be expressed (see Equations 6-54, 6-105 and 6-106) by nav exp R , - R c . (6-108) Hence the average axial stress within a pocket in the choke section is obtained from cr exp R. - R.. dx (6-109) Substituting and integrating yields the average axial stress that can be used to estimate the average compacted bulk density in the choke section based on Equation 6-86. The predicted average axial stress and compacted bulk density are listed in Tables 6-3 and 6-4. Due to compression in the choke section, compressible materials generally have larger volumetric efficiencies than incompressible materials. The average normal stress within a pocket in the choke section can be expressed by \u00ae' cwa exp 2MwZs(P-x) R. -R. dx (6-110) The torque generated within a pocket in the choke section can be estimated based on the above procedures. The total torque required to drive the screw feeder is then Table 6-4. Parameters for stress and compression analysis for screw-1 Name of specimen Compression factor in choke section [ 1 1 Compacted bulk density in choke section p l (kg\/m3) Density ratio t 3 ] n 14) X [si C [6 ] @ 0.3 m @ 0.45 m @ 0.3 m @ 0.45 m @0.3 m @0.3 m @ 0.45 m @ 0.45 m Wood pellets 1.65 1.72 630 630 1.00 1.38 1.38 1.00 0.48 0.15 Ground wood pellets-1 4.43 5.03 485 485 1.00 1.09 1.09 1.00 0.39 0.60 Ground wood pellets-2 5.67 6.57 452 461 1.07 1.45 1.45 1.09 0.28 1.00 Sawdusts-1 4.59 5.22 236 243 1.12 1.45 1.45 1.16 0.29 0.80 Hog fuel-1 5.69 6.59 225 229 1.13 1.41 1.41 1.15 0.27 1.00 Ground hog fuel 8.62 10.34 190 197 1.27 1.30 1.31 1.32 0.19 1.80 Wood shavings-1 4.55 5.18 131 136 1.20 1.41 1.41 1.24 0.27 0.9 Polyethylene particles 1.37 1.40 610 610 1.00 1.20 1.20 1.00 0.47 0.15 Notes: [1] Compression factors are expressed by Equation (6-106). [2] Compacted bulk density in choke section is calculated according to relation between bulk density and stress acting on the bulk solids surface. [3] Density ratio is defined as the ratio of compacted bulk density in the choke section to the loose bulk density.. This is used to describe compression choke section. [4] Defined by Equation (6-84). [5] Ratio of normal wall stress to axial stress for bulk solids sliding on surface, a function of wall friction angle and internal friction angle. [6] Constant used for analysis of compression in choke section: see Equation (6-107). Chapter 6. Modeling of biomass feeding 202 Tmai = \\\\Tx (6-111) m where m is the total number of pockets (each pocket being the space between adjacent flights) along the screw feeder, including the hopper section and the choke section. For special casing configurations (tapered and extended sections), further details are provided below. The shaft power, PW, (not including bearing and drive losses) required to rotate the screw is PW = TMalxa> = 60 (6-112) where \/ is the rotational speed of the screw in rpm. For torque and power readings, see Appendix G. For the computer program to predict the torque and power, see Appendix H. 6.3.3.2 Taper casing in choke section Tapered sections of length 0.15 and 0.30 m at the discharge end of the screw feeder were tested in the present study. The outlet diameter of both tapered sections was 88 mm, so that there were different taper angles for the two tapered sections, as shown in Figure 6-15. Taking axial resistance forces caused by the tapered casings into account increases the torque requirements. Volume-reducing flow channels (i.e. converging tapered sections) block more readily for incompressible materials (such as polyethylene and wood pellets) unless the feeder is powerful enough to break the particles. For compressible bulk materials (e.g. sawdust and ground hog fuel), blockage is difficult to estimate. It depends on the material properties and flow conditions inside the screw casings. The geometry affecting the stress of a material element within a pocket in the tapered section is shown in Figure 6-16. Assuming steady state for a moving material element and equilibrium between the diving force and resisting force, the balance of forces acting on an element of length dx results in Chapter 6. Modeling of biomass feeding 203 Dt = 102 mm: I) =88 nun: :Lt = 0.15 m: Dt = 102 mm : \u2022L> = 88 mm \u2022 :Lt = 0.30 m: Figure 6-15. Schematics of the two tapered sections tested in this work. Figure 6-16. Stresses on material element in tapered section. Chapter 6. Modeling of biomass feeding 204 axTcr2 = (<rx + dax)n:(r - dxtana,)2 +TW TTT2 n(r -dx tana) 2 tana tana + crM,[^r2 - n{r - dxtan a ) 2 ] Elimination of second order terms yields 2CT tana , 2TW , 2cr tana dax - dx + \u2014-dx + \u2014-r r r dx = 0 (6-113) (6-114) Substituting r = (\u00a3>, - 2xtana ( ) \/2 into Equation 6-114, we obtain d t T i + ^ L d r - J l ^ d r - ^ - d r = 0 r rtan a r (6-115) After substituting <Jw I <JX = XS, rw = JUw(TW and rearrangement, Equation 6-115 becomes ^ L = - ( 2 - ^ . - 2 A , ) ^ <T tana r (6-116) Boundary conditions for the 0.30 m long tapered section ( P = 0.1 m) are: o first pocket: crx = oin at r = R, o second pocket: ox = crM at r = Rn o third pocket: ax = cr\u201e2 at r = Ra Boundary condition for the 0.15 m long tapered section: o first pocket: ax = ain at r = Rt o second half pocket: <Jx = crM at r - Ra Here R, is the inside radius of the casing at JC = 0, Rn the inside radius of the casing at x = P , and Ra the inside radius of the casing at x = 2P (only for 0.30 m long tapered section), as shown in Figure 6-16. ain, aM, crjn2 are axial stresses at the starting point of successive gaps in the tapered section. Rt is used in the following sample calculations. Chapter 6. Modeling of biomass feeding 205 Integrating Equation 6-116 and substituting r = (D, - 2xtanor,)\/2 yields \u201e xtana, - ( 2 - ^ ^ - 2 4 ) crx=crin(l \u2014<-) *\u00bb\u00ab (6-117) K , The average axial stress within a pocket is Hence the average normal wall stress in a pocket is A f \u201e x tan a, - ( 2 - ^ ^ - 2 4 ) f xtana, - ( 2 - - ^ - 2 4 ) , | o - \/ f l ( l - ^ ~ ) \u2014 ax (6-119) For both the 0.15 and 0.30 m long tapered sections, the compression can be estimated by stress analysis in the choke section and along the screw axis as the volume changes in the tapered sections. The ratios of compacted bulk densities in the choke section to loose bulk densities are listed in Table 6-4. For each pocket in a tapered section, the screw pocket volume can be calculated, and then used to estimate the compacted bulk density. Average axial stresses within each pocket in the taper section for various materials can be estimated by an axial stress-bulk density relation, i.e. Equation 6-86. The stress cr,can be obtained from Equation 6-118 by iteration until the calculated average axial stress axa matches the calculated compacted bulk density. It should be noted that ajn is not equal to the stress on the driving side calculated from the above equations, although they are similar. The stress on the driving side is employed for torque calculations. The torque requirement generated within each pocket in the tapered section can be estimated from the above procedures. The 0.15m tapered section covers one-and-a-half pockets, whereas the 0.30 m tapered section includes three pockets. Total torque requirements for the tapered sections are obtained by summing the torque required for each pocket. (1) 0.30 m long tapered section Chapter 6. Modeling of biomass feeding 206 The axial resistance acting on an element of bulk solid on the core surface can be expressed by Equation 6-49, i.e. Fca = -27tRccrwa\/uwc sm(ac)\\^dx = -ncdcptrwajuwc s,m(ac)crwaD] (6-120) The axial resistance force acting on the material element in a pocket on the trough surface is expressed by Fla = -(27rRPjuw,awa + 2nRPcrwa tana,) (6-121) where R is the inside radius of the taper section on the driving side of the flight, i.e. at the beginning of each pocket (at x = 0, P and 2P for the 0.30 m long tapered section). awa is the average normal wall stress in each pocket in the taper section (see Equation 6-119). The axial force acting on the material within a pocket on the trailing side is FM = - 2 * ^ gSgglgrdr = _ 2 ^ ^ \u00a3 ( 1 + tana, tm^rdr ( 6 - , 2 2 ) After substituting tana, = P \/ 2 ^ r a n d t a n ^ = fif, Equation 6-122 can be solved numerically or analytically. The total axial force on the material element within a pocket caused by the driving side of a flight should equal the total resisting axial forces acting on the same material element due to the core shaft surface, trailing side of a flight and trough surface. It is again assumed that the total force is uniform on the surface of the driving side, so that Fia+Fca+Ffa+Fla=0 (6-123) - \u2022 . (6-124) The torque generated in one pocket is Ti=Td+Tc+Tf+T\u201ep \" (6-125) Chapter 6. Modeling of biomass feeding 207 where Td = Torque due to driving flight, N.m. Tc = Torque due to core shaft surface, N.m. Tf = Torque due to trailing flight, N.m. Tlip = Torque due to flight tip, N.m. The torque generated by the driving side of the screw flight is Td = 2nada\\R<>r2 tan(a r + <j>f )dr (6-126) After substituting tanar=P\/2nr and t a n ^ ~ juf. Equation 6-126 can be integrated numerically. The torque generated by the core shaft surface is Tc=2nR2cPMwc(jwacosac (6-127) The torque generated by the trailing side of the screw flight is \u2022 D sin(^, -a)r2dr l r r \u201e \u2022 \u201e Tf = ^ f & f . ^de=2n\\axf\\Ro^f -tmar)r2dr (6-128) Kc cosa^cos^. K Equation 6-128 can again be solved numerically. The torque generated by the flight tip is = r^r\u00bb,R\u201e ( 6 _ 1 2 9 ) sin a0 The normal stress on the flight tip surface is assumed to be <rwa . The flight tip surface area within a pocket can be estimated by Ati = y x PI sin a0. (2) 0.15 m long taper section Chapter 6. Modeling of biomass feeding 208 The 0.15 m long taper section includes one and a half pocket (P = 0.1 m). The average axial stress in the second half-pocket is <>\u2022\u00ab.=\u2014[ o-fcO L ) >wa dx (6-130) Hence the average normal wall stress in a pocket is P * ~ms' R, 2\/L (P'2 \u201e x t an\u00ab , - ( 2 - \u2014 \u00a3 ^ L - 2 4 ) . . . . 0 - _ = _ i - r CT o t(1 L) ^ (6-131) The trailing side of the flight is absent in the second half-pocket for the 0.15 m tapered section. The force and torque calculations in this case are based on P12 instead of P. 6.3.3.3 Extended section in choke section In order to propel bulk materials forward in the extended section, the axial force exerted by the driving side of the screw flight must equal or exceed the resisting force, i.e. xD,Leaewo\/uw<^craa (6-132) where aexa is the average axial stress, and aewa is the average normal wall stress in the extended section. Substituting aeuia = \/ls(Texa yields L.<Lal=-^- (6-133) There is another critical length defined by La2=D,tanS (6-134) Lcll and Lcl2 are critical lengths for extended sections, and 5 is the effective internal friction angle. Note that Z), (casing diameter) is employed instead of D0 (screw diameter) in these equations. When the length of the extended section exceeds the critical length, bulk materials Chapter 6. Modeling of biomass feeding 209 cannot be easily pushed out of the extended section since the force exerted by the screw flight is not transmitted forward effectively, but instead transmitted to the wall, tending to cause blockage for incompressible materials and significant compaction for compressible materials. The compression and blockage tendency for compressible materials in the extended section depends on the fullness of screw pockets and material properties. When \u00a3.>4,,=7r^' (6-135) or Le >Lcl2 =D, tanS (6-136) particular attention should be paid to ensure effective compression and prevent unwanted blockage inside the extended section. The average axial stress in the extended section can be calculated based on the measured compacted bulk density in the extended section. Then the average normal stress in the extended section can be estimated by crewa = Asacxa. From a force balance at steady state (i.e. static state, as during blockage, or moving at a constant speed), the following expression can also be obtained xD,Lecrm,aiuw=^o-da (6-137) Rearrangement of Equation 6-137 gives the stress on the driving side of the screw flight ada = \u20142 (6-138) TCD0 In Equation 6-138, Dg is employed instead of Dt. Chapter 6. Modeling of biomass feeding 210 6.3.4 Comparison of model predictions with experimental measurements 6.3.4.1 Straight casing in choke section for screw-1 The feeder load and vertical stress of initial and flow conditions at the hopper outlet for various materials for screw-1 are shown in Tables 6-1 and 6-2. Table 6-2 indicates that the initial feeder loads account for < 50% of the total initial weight of bulk materials in the hopper for a 0.30 m hopper level, whereas this ratio is reduced to < 40% for a 0.45 m hopper level. The initial feeder load can be calculated as the product of the initial vertical stress and the cross-sectional area (width of hopper outlet times length of hopper section) of the hopper outlet. The initial vertical stress can be estimated based on the hydrostatic pressure as noted above. This indicates that the initial vertical stress and initial feeder load are linearly proportional to the hopper level instead of the initial weight of bulk materials in the hopper. This is mainly attributable to partial support by the hopper wall. The feeder load when there is flow is slightly less than at the initial condition, mainly because a passive stress field is established when flow commences in the hopper, reducing the vertical stress at its outlet, as well as the feeder load. Although some researchers (e.g. Arnold et al., 1980) have approximated the feeder load during flow by taking the weight of a block of bulk material of a certain height (e.g. twice the outlet width) above the hopper outlet, calculations of the vertical stress and feeder load when there is flow (see Equation 6-33) generally do not consider the effects of hopper level. Here we use the initial vertical stress to calculate the initial feeder load, then an arithmetic mean of vertical stresses for the initial and flow conditions as vertical stresses for flow conditions listed in Table 6-3 in order to take the hopper level into consideration both initially and after the flow begins. Axial stresses in hopper and choke sections for screw-1 for flow conditions appear in Table 6-3. These can be used to estimate compacted bulk densities in the choke section, and ratios of compacted bulk densities to loose bulk densities in the choke section for various materials, as Chapter 6. Modeling of biomass feeding 211 shown in Table 6-4. Ratios of calculated compacted bulk densities in the choke section to loose bulk densities approximately match the measured values during feeding experiments for the various materials tested. Parameters for stress and compression analysis ( C and CF ) for screw-1 also appear in Table 6-4. Torque predictions and experimental measurements are compared in Table 6-1 and in Figures 6-17 to 6-24. Figure 6-25 plots predicted ratios of torque generated in the choke section to the overall torque. Figures 6-17 to 6-24 show that predicted torques, including average torques and starting torques, match the experimental results very well. Note that the average predicted and measured torques are the average values for the 0.30 and 0.45 m hopper levels in Figures 6-20 and 6-24. Figure 6-25 shows that the torque requirements of the choke section account for more than 50% of the total torque for all biomass materials tested, especially for compressible biomasses, where it is more than 70%. This occurs even though the length of the choke section is less than that of the hopper section. We see that the choke section played a dominant role in determining the torque requirements for biomass fuels in the present study. Table 6-5, Figures 6-26 and 6-27 compare experimental values with predicted efficiencies with and without allowance for compression in the choke section. Predicted efficiencies with allowance for compression in the choke section are obtained from products of predicted efficiencies without considering compression and corresponding density ratios (i.e. ratios of compacted to loose bulk density in the choke section). Figure 6-26 indicates that efficiencies are mostly in the 0.7-0.95 range in the present study, with the value depending on material properties and feeder configuration. Average measured efficiencies for the two hopper levels (0.30 and 0.45 m) are compared with predicted efficiencies in Figure 6-27. The flow rate in each run is estimated by calculating the average flow rate in the first 2 minutes after stable feeding is established (see Appendix G). Feed rates, as well as torque Chapter 6. Modeling of biomass feeding 212 readings, are averaged from 2-5 repeat experiments for the same experimental conditions. Three initial hopper levels were tested: high (0.60 m), medium (0.45 m) and low (0.30 m). The effect of hopper level in this range on flow rate was found to be insignificant in the present study. Power predictions and experimental measurements for screw-1 are compared in Figures 6-28 to 6-29. The product of predicted average torques and corresponding angular velocities is taken as the predicted power, while the measured power is taken as the time-average torque times the corresponding angular velocity. We see from these figures that the predicted average powermatches experimental values much better than the predicted starting power. This indicates that starting power, like starting torque, is difficult to predict, due to uncertain packing conditions in the hopper and different material properties (e.g. size, shape and bulk density). For biomass feeding, the starting torque is less critical than the operating torque due to the large torque consumption in the choke section. 100 \\- Experimental measurements: 90 h 80 \\ -it Ave.torque for 0.3 m hopper level * Max.torque for 0.3 m hopper level \u2022 Ave.torque for 0.45 m hopper level \u2022 Max.torque for 0.45 m hopper level 1- Polyethylene particles Greater compressibility 5-Hog fuel-1 2- Wood pellets 6-Sawdust-1 Figure 6-17. Comparison of predicted and measured torques for screw-1. Table 6-5. Comparison of predicted and experimental efficiencies for screw-1 Name of specimen Wall friction angle on carbon steel (deg) Internal friction angle (deg) Density ratio m Average density ratio Measured efficiency Average measured efficiency [ 2 1 Incompressible predicted efficiency ' 3 I Predicted efficiency with compression ' 4 | 0.3 0.45 0.3 m 0.45 m Wood pellets 31.4 32.0 1.00 1.00 1.00 0.69 0.69 0.74 0.74 Ground wood pellets-1 30.2 33.2 1.00 1.00 1.00 0.80 0.74 0.77 0.74 0.74 Ground wood pellets-2 30.4 38.0 1.07 1.09 1.08 0.81 0.78 0.80 0.74 0.80 Sawdusts-1 31.8 38.0 1.12 1.16 1.14 0.81 0.83 0.82 0.73 0.84 Hog fuel-1 31.5 39.0 1.13 1:15 1.14 0.87 0.86 0.87 0.74 0.84 Ground hog fuel 31.8 45.0 1.26 1.32 1.29 0.93 1.04 0.98 0.73 0.95 Wood shavings-1 31.0 39.0 1.21 1.27 1.24 0.89 0.93 0.91 0.74 0.91 Polyethylene particles 21.5 26.2 1.00 1.00 1.00 0.84 0.86 0.85 0.79 0.79 Notes: [1] Density ratio is defined as the ratio of compacted bulk density in the choke section to loose bulk density. This is used to describe compression in the choke section. [2] Average measured efficiency is obtained from arithmetic mean of measured efficiencies for 0.30 and 0.45 m hopper levels. [3] Predicted efficiency without consideration of compression in the choke section. [4] Predicted efficiency with consideration of compression in the choke section, i.e. density ratio times efficiency in [3]. Chapter 6. Modeling of biomass feeding 214 E\" 30 20 10 \u2022 \/ \" Hopper level = 0.3 m _ \u2022 Wood pellets 4 Ground wood pellets-1 ' X Ground wood pellets-2 - \u2022 Sawdust-1 < - X \/ - * Hog fuel-1 Ground hog fuel - Wood shavings-1 i . i . 0 i Polyethylene particles I . I . 10 20 30 40 Experimental measurement (N.m) Figure 6-18. Comparison of predicted and measured average torques for 0.30 m hopper level and screw-1. Figure 6-19. Comparison of predicted and measured average torques for 0.45 m hopper level and screw-1. Chapter 6. Modeling of biomass feeding 215 Experimental measurement (N.m) Figure 6-20. Comparison of average predicted and measured torques for 0.30 and 0.45 m hopper levels for screw-1. Material: 1 -Polyethylene particles 2- Wood pellets 3- Groundwood pellets-1 4- Ground wood pellets-2 Greater compressibility Bulk materials 5- Hog fuel-1 6- Sawdust-1 7- Ground hog fuel 8- Wood shavings-1 Figure 6-21. Comparison of predicted and measured starting, torques for screw-1. Chapter 6. Modeling of biomass feeding 216 0 5 10 15 20 25 30 35 Experimental measurement (N.m) Figure 6-22. Comparison of predicted and measured starting torques for 0.30 m hopper level and screw-1. Experimental measurement (N.m) Figure 6-23. Comparison of predicted and measured starting torques for 0.45 m hopper level and screw-1. Chapter 6. Modeling of biomass feeding 217 Experimental measurement (N.m) Figure 6-24. Comparison of average predicted and measured starting torques for 0.30 and 0.45 m hopper level and screw-1. 0.80 CD O sz o 0.75 0.70 c 0.65 2 0.60 <v cn 0.55 <D I 0 5 0 ns or 0.45 0.40 - \u2022 \u2022 l * *%^5 - Screw-1 Hopper section length: 0.91 m - \/ Choke section length: 0.62 m -Torque ratio at 0.3 m hopper level - \/ Torque ratio at 0.45 m hopper level Average torque ratio 1 1 1 from 0.3 and 0.45 m hopper level i . i . i . i . i . i Material: 1 1- Polyethylene particles G r e a t e r compressibility 5 \" H o 9 fuel-1 2- Wood pellets 6-Sawdust-1 3- Ground wood pellets-1 g u | k m a t e r j a | s 7-Ground hog fuel 4- Ground wood pellets-2 8-Wood shavings-1 Figure 6-25. Predicted ratio of torque generated in choke section to overall . torque for 0.30 and 0.45 m hopper level and screw-1. Chapter 6. Modeling of biomass feeding 218 \u2022 Measured efficiency at 0.3 m hopper level \u2022 Measured efficiency at 0.45 m hopper level Predicted line without consideration of compression J I I 1 I I I 1 I I I 1 I 1 1 L Material: 1 2 3 4 5 6 7 8 1- Polyethylene particles Greater compressibility 5 \" H o 9 f u e M 2- Wood pellets 6-Sawdust-1 3- Ground wood pellets-1 Bulk materials 7-Ground hog fuel 4- Ground wood pellets-2 8-Wood shavings-1 Figure 6-26. Comparison of predicted (with consideration of compression) and measured volumetric efficiencies for 0.30 and 0.45 m hopper level and screw-1. Experimental efficiency Figure 6-27. Comparison of predicted and averaged measured efficiencies for 0.30 and 0.45 m hopper level and screw-1. Chapter 6. Modeling of biomass feeding 219 Figure 6-28. Comparison of predicted average power and measured average power for different screw speeds for 0.30 m initial hopper level and screw-1. Figure 6-29. Comparison of predicted starting power and measured starting power for different screw speeds for 0.30 m hopper level and screw-1. Chapter 6. Modeling of biomass feeding 220 6.3.4.2 Taper casing in choke section for screw-1 Torque predictions and experimental measurements are compared in Figures 6-30 and 6-31. For sawdust and' ground hog fuel, the predictions agree well with the experimental results, but the experimental results are much higher than the predictions for wood shavings. Blockage occurred for both the 0.15 and 0.30 m long taper sections for the wood shavings. The large deviations are probably due to the wide size distribution and wide range of particle strength for wood shavings. The torque predictions for hog fuel in the 0.15 and 0.30 m long tapered sections with a hopper level of 0.45 m are 276 and 419 N.m respectively, suggesting blockage (motor capacity < 100 N.m), although this could not be confirmed in the present experiments. For the 0.30 m long tapered section, blockage always occurred, whereas blockage sometimes, but not always, occurred for the 0.15 m long tapered section. The difference is attributed to the complicated flow patterns in the hopper and in the choke sections, leading to varying levels of fullness in the choke section. Higher fullness tended to cause blockage for both the 0.15 and 0.30 m long tapered section. Although the taper angle for the 0.15m tapered section was larger than for the 0.30 m tapered section, the longer length made blockage more likely. Screw rotational speeds affected the tendency to block in the tapered section. Higher screw speeds (e.g. 30 and 40 rpm) tended to transport more bulk materials into the tapered section per unit time, increasing the likelihood of blockage compared to lower screw speeds. The torque predictions neglect any effect of screw speed. From observations on blockage of hog fuel during experiments, torque > 100 N.m is expected to disrupt blockage inside the tapered section and make feeding smoother. It should be noted that predictions for hog fuel and wood shavings are particularly uncertain for the tapered section cases due to the wide particle size distributions, wide ranges of particle strength and complex flow patterns in the hopper and choke sections. Chapter 6. Modeling of biomass feeding 221 Experimental Measurement (N.m) Figure 6-30. Comparison of torque predictions and experimental measurements with 0.15m tapered sections and a 0.45 m hopper level. 0 10 20 30 40 50 60 70 80 Experimental Measurement (N.m) Figure 6-31. Comparison of torque predictions and experimental measurements with 0.30 m tapered sections and a 0.45 m hopper level. Chapter 6. Modeling of biomass feeding 222 6.3.4.3 Extended section in choke section for screw-1 Stresses on a material element in the extended section are shown in Figure 6-32. The torque generated by the extended section can be predicted by the above equations. The recommended critical lengths for various materials are listed in Table 6-6, while the predicted torques with extended sections appear in Table 6-7 and Figures 6-33 to 6-34. Although the predicted torques with a 0.15 m extended section for sawdust-1 do not match the experimental data very well, approximate estimates can be provided for biomass materials with consideration of torque fluctuations. Torque readings generally fluctuated in the range 10-30 N.m during the experimental tests. For blockage conditions, the predicted torques are those required to reach certain compression levels inside the extended sections, not those required to break up a blockage or to advance the plug inside the extended section. The plug formed in the extended section becomes even tighter when the axial stress exerted by the screw flight increases. A tighter plug also increases the resistance exerted by the casing wall, depending on the length of the extended section and the material properties. It is difficult to predict the required torque to expel the plug into the receiving vessel for different biomass materials. The critical length of the extended section is important if a screw feeder with extended sections is employed. It then acts like a piston feeder. Several plug formation regions (i.e. casings without screw flights) along the screw in the choke section are expected to provide better performance from a plug seal point of view (Bates, 2000). 6.3.4.4 Different choke section length for screw-1 The model developed above is intended for different choke section lengths, i.e. 0.30, 0.46 and 0.61 m in the present study, as shown in Figure 6-35. For the shortest length (0.30 m), the compression factor for torque predictions is the same as for the longest choke section (0.61 m) in the present experiments. Hence the torque requirements are reduced compared to the longer Chapter 6. Modeling of biomass feeding 223 section. Longer choke sections are expected to provide better plug sealing and a greater probability of blockage. For biomass feeding, 4-10 times the screw pitch is recommended for the choke section length. Material moving direction Figure 6-32. Stress on material element in extended section. CD cr T3 o T J CD 100 90 80 70 60 h 50 40 30 20 10h 0 \u2022Sawdust-1 \u2022 Hog fuel-1 Ground hog fuel 0.15 m extended section 0 10 20 30 40 50 60 70 80 90 100 Experimental measurement (N.m) Figure 6-33. Comparison of torque predictions and experimental measurements for screw-1 with 0.15 m extended sections with a 0.45 m hopper level. Chapter 6. Modeling of biomass feeding 224 Experimental measurement (N.m) Figure 6-34. Comparison of torque predictions and experimental measurements for screw-1 with 0.30 m extended sections with a 0.45 m hopper level. 110 100 90 80 70 60 50 40 -30 -20 -10 Screw-1 O Measured ave. torque for wood pellets # Measured max. torque for wood pellets -fa Measured ave. torque for wood shavings-1 J{ Measured max. torque for wood shavings-1 Predicted line for wood pellets \u2014 Predicted line for wood shavings-1 % Hopper level: Wood pellets: 0.3 m Wood shavings-1: 0.45 m * * 0.3 0.4 0.5 0.6 Length of choke section (m) Figure 6-35. Comparison of torque predictions and experimental measurements for different choke section lengths. Table 6-6. Recommended critical length of extended section (ID: 102 mm) for various materials Name of specimen Wall friction angle on carbon steel (deg) Internal friction angle (deg) 4,1 ( m ) 4,2 (m) Wood pellets 31.4 32.0 0.09 0.06 Ground wood pellets-1 30.2 33.2 0.11 0.07 Ground wood pellets-2 30.4 38.0 0.15 0.08 Sawdusts-1 31.8 38.0 0.14 0.08 Hog fuel-1 31.5 39.0 . 0.15 0.08 Ground hog fuel 31.8 45.0 0.21 0.10 Wood shavings-1 31.0 39.0 0.16 0.08 Polyethylene particles 21.5 26.2 0.14 0.05 Table 6-7. Predicted torques with extended sections for 0.45 m hopper level and various biomass materials for screw-1 Biomass Materials Sawdusts-1 Hog fuel Ground hog fuel Wood shavings-1' Mean particle diameter (mm) 1 _ 0.45 0.72 0.18 0.67 Bulk density (kg\/m ) 210 200 150 110 . eL iad \u2022 * ' Bulk density in 0.15 m extended section (kg\/ m ) 315 240 .210 154 ,\u2014, d. . \u2022 \u2022 :\u2014^ 1\u2014~ Bulk density in 0.30 m extended section (kg\/ m ) 378 270 270 231 Axial stress in 0.15 m extended section (kPa) 102 26 17.8 11.2 Axial stress in 0.30 m extended section (kPa) 508 330 299 178 Measured ave. torque with 0.15 m extended section [ 1 ] (N.m) Blocked p l 27.5 12.5 13.0 Measured max. torque with 0.15 m extended section (N.m) Blocked 42.4 42 24.1 Predicted torque with 0.15 m extended section [ 3 1 (N.m) 64.6 32.5 19.8 15.7 Measured ave. torque with 0.30 m extended section* (N.m) Blocked Blocked Blocked Blocked Measured max. torque with 0.30 m extended section* (N.m) Blocked Blocked Blocked Blocked Predicted torque with 0.30 m extended section (N.m) 105.5 132.5 99.4 102.0 Note: [1] 0.45 m hopper level [2] Max. torque reading < 100 N.m. [3] Predicted torque should be predicted average torque Chapter 6. Modeling of biomass feeding 226 110 -100 -90 -80 -E 70 -S. 60 -g- 5 0 -\u00a3 40 -30 -20 -10 -it Measured ave. torque for screw-2 Measured max. torque for screw-2 O Measured ave. torque for screw-1 # Measured max. torque for screw-1 - \u2014 Predicted line for screw-2 Predicted line for screw-1 o Hopper level: Wood pellets: 0.3 m Ground wood pellets-1: 0.45 m Ground wood pellets-2: 0.45 m * \"\"\"-\"Ifr\"\"'.-\u2014-o \u2022 3 -1 2 3 1-Wood pellets; 2-Ground wood pellets-1; 3-Ground wood pellets-2 Bulk material Greater compressibi l i ty Figure 6-36. Comparison of torque predictions and experimental measurements for screw-1 and screw-2. 6.3.4.5 Comparison of predictions for screw-1 and screw-2 Screw-1 and screw-2 are compared in Figure 6-36. From this figure, we see that the torque requirements, as well as the torque predictions, are less for screw-2 than for screw-1. This is mainly due to the relatively large clearance (11 mm) and increased screw pocket space (increased pitch) for screw-2, as shown in Figure 4-3. The latter should lead to relatively uniform flow in the hopper and reduced torque requirements. In addition, the fullness of screw pockets in the choke section is lower due to the enlarged clearance for screw-2, which also reduced the torque requirements. Smaller clearance (1 mm for screw-1 in the hopper section) for given trough or casing diameter can increase the transport capacity and torque requirements, but may cause mechanical wear and increase the tendency to block. For screw-1, the clearance was greater, up to 5-11 mm in the choke section in order to reduce the blockage tendency in the Chapter 6. Modeling of biomass feeding 227 choke section. Special attention is required if reduced clearance is combined with tapered or extended sections in the choke section due to the tight plug formation and large blockage tendency. For biomass feeding, the clearance should be 2-11 mm for particles similar to those tested here. Note that c r t m a x ~ oda when the boundary condition ax = crv at x = P is employed for Equation 6-50 in each pocket for screw-2 in the hopper section, where <rda is the stress on the driving side of the flight calculated from the above procedures, while <Jxmax is the maximum stress in a pocket calculated from Equation 6-54, i.e. cr J m a x = crv exp[2\/uwASPl(Rt -Rc)]- Using the boundary condition- without consideration of n (i.e. ax = av at x = P ) and neglecting compression in the choke section can make the torque prediction match the experimental results very well for screw-2. The new model for screw-2 extended the model recommended by Yu and Arnold (1997), who analyzed axial forces with only the driving side of the screw flight considered for torque predictions, i.e. they neglected the effects of the core shaft surface, trailing side of the flight and flight tips on torque predictions. Note that the torque predicted from the driving side of a flight accounts for -90% of the total torque requirements for screw-1 and -80% for screw-2 for both compressible and incompressible materials in the present study. This indicates that the driving side of flight is dominant in determing the torque requirements. The contributions from the other terms appear in Table 6-8. The larger the screw diameter or the smaller the clearance (screw-1), the larger proportions the driving side of flight in total torque. Table 6-8. Relative contributions of different surfaces to total torque (in % of total) Surfaces Screw-1 Screw-2 Driving side of flight 89.1-90.6 79.6-80.0 Core shaft surface 4.2-5.7 7.5-9.6 Trailing side of flight -0.13-1.1 2.5-2.6 Flight tip 4.1-5.4 7.9-10.3 Chapter 6. Modeling of biomass feeding 228 6.4 Summary (1) A new theoretical model for the torque requirement of a screw feeder is developed by applying principles of bulk solid mechanics to a material element moving within a pocket. The torque requirement is proportional to the vertical stress exerted on the hopper outlet by the bulk material in the hopper and approximately proportional to the third power of the screw diameter (cd ,c ,c, ,juf are assumed constant) according to theoretical analysis. It is a function of screw configurations (e.g. screw diameter, shaft diameter, pitch, clearance), hopper configurations (e.g. hopper outlet width, half hopper angle) and flow properties of the bulk material (e.g. bulk density, wall friction and internal friction). Starting torque is also predicted, with reasonable accuracy, by stress analysis in the hopper section, which has also been neglected in previous studies. (2) Consideration of the forces on the five confining surfaces surrounding the bulk material contained within a pocket between adjacent flights, and the stress distribution in the pocket, leads to better understanding of torque characteristics and to reasonable predictions of the torque requirement for a screw feeder. Incompressible and compressible materials are treated differently in the stress analysis within a pocket, including the hopper and choke sections, for different screw configurations. Predictions are mostly in good agreement with measurements. (3) Effects of the driving side, trailing side, core shaft surface and flight tips, as well as trough\/casing surface and shear surface, on torque predictions are considered in the new model. This approach differs from previous research. (4) Consideration of compaction, especially in the choke section, is shown to be essential for successful torque predictions for screw feeding of compressible materials like biomass. (5) Another novel feature of the work is that special casing configurations (e.g. tapered and extended sections) are considered, leading to better understanding of blockage in the choke Chapter 6. Modeling of biomass feeding 229 section and approximate prediction of torque requirements and volumetric efficiency for screw feeders of given geometry. (6) For one of the two screws tested, the torque required for biomass feeding is determined mainly by the choke section, accounting for > 50% of the total torque requirement for biomass particles, especially for compressible materials (> 70%), even though the choke section is shorter than the hopper section. Different screw and choke section configurations cause different compression in the choke section, as well as different torque requirements. As a rule, smaller clearances and longer choke sections lead to greater compression and require larger torque for screw feeding. Chapter 7. Conclusions and suggestions 230 CHAPTER 7. CONCLUSIONS AND SUGGESTIONS FOR FURTHER WORK 7.1 Conclusions 7.1.1 Biomass feeding system Biomass combustion and gasification are very promising clean energy options for reducing greenhouse gas emissions. In the present study, wood pellets, ground wood pellets, sawdust, hog fuel, ground hog fuel and wood shavings were tested with polyethylene particles as reference particles for comparison. The feeding system combined a wedge-shaped hopper, a lock hopper and a screw feeder to feed biomass. The diameter of the screw casing was 102 mm. Two screws were employed with clearance of 1-11 mm and pitch in the range of 40-100 mm. Tapered and extended sections, as well as hopper pressurization, were also tested. Screw speeds were from 5 to 40 rpm. The volumetric efficiencies of the screw feeder mainly ranged from 60-95%, while the volumetric flow rate varied from 0.09-1.2 m3\/h. The torque was mainly in the range of 7-60 N.m. When maximum torque readings exceeded ~70 N.m, blockage was likely to occur for the present motor drive system. The following conclusions can be drawn from this study: (1) The level of solid in the hopper affected blockage inside the screw feeder. For wood pellets of uniform size, when the hopper level exceeded 0.35 m, blockage could occur, whereas no blockage occurred for hopper levels less than 0.3 m. For a hopper level exceeding 0.4 m, blockage occurred almost immediately after starting the screw feeder. Polyethylene particles never blocked for hopper levels < 0.6 m due to their regular shape and smooth surfaces. (2) Larger particles, irregular particle shapes, rougher surfaces and larger bulk densities increase the tendency for wood pellets to block in the hopper. The larger torques required to Chapter 7. Conclusions and suggestions 231 feed wood pellets compared to ground wood pellets are mainly attributable to the larger particle size of the wood pellets. (3) Particle size distribution plays a significant role in determining bulk flow properties. Wood pellets containing fines blocked more frequently inside the screw feeder than wood pellets of uniform size, because fines decrease void fraction of bulk solids, increasing the contacting areas between bulk solids and screw. Moreover, fines tend to cause large cohesive resistance. Wider size distribution, especially large particles, required larger torque for hog fuel-1 compared to ground hog fuel and sawdust-1. (4) High moisture content (e.g. 40 and 60%) caused larger cohesion and adhesion, making biomass fuels more likely to bridge in the hopper. Intermittent bridging in the hopper reduced the volumetric flow rate for wet biomass fuels. Wet biomass generally needed much more torque to achieve blockage-free feeding than dry biomass. (5) Higher compressibility led to higher volumetric flow rates for screw feeding. Compressible biomass fuels passed through tapered sections more readily than incompressible materials. Plug formation inside the screw casing was also facilitated by increased compressibility. (6) The choke section played an important role iii biomass feeding. The choke section length and casing configurations (e.g. tapered and extended sections) were closely related to plug formation and plug sealing of the reactor, while also affecting the torque requirements. (7) Pressurizing the hopper slightly (e.g. by 0.01 bar) relative to the receiving vessel generally increased the feed rate and decreased the torque requirement, while also preventing backflow of gases and bed materials. (8) More compact materials (i.e. larger bulk density) and non-uniform moisture content tend to increase the torque requirements for feeding. Chapter 7. Conclusions and suggestions 232 (9) Careful refilling need not disrupt feeding, especially for biomass fuels of low bulk density. (10) Large clearance and increasing capacity along the length of the screw resulted in reduced torque for screw-2 relative to screw-1. Small clearance caused larger torque and more blockage, as well as better plug sealing, for screw-1. (11) For biomass feeding, the choke section may need to be longer, e.g. 6-10 times the pitch, to promote plug formation and prevent backflow of hot gases and bed materials. Maximum torque instead of starting torque is critical for screw feeders with small clearance and long choke sections. (12) Torque requirements are nearly independent of screw speeds, both for compressible and incompressible solid materials. (13) Clearance and choke section length are critical factors affecting compression, torque requirements and blockage tendency, neglected in previous experimental work and modeling. A new model based on stress analysis was developed to predict the torque requirements and efficiency for screw feeding. A new strategy was adopted in the stress analysis within a pocket (both in the hopper and choke sections), with incompressible and compressible materials treated differently. Yu and Arnold (1997) only used the force on the driving side of screw flights to estimate the torque requirements and neglected other boundaries (e.g. core shaft and trailing side of screw flights). The new model developed in this thesis extends previous models by considering the effects of all boundaries on torque, and allowing for compression in the choke section, as well as in the hopper section. Special casing configurations (e.g. tapered and extended sections) are also considered, leading to better understanding of blockage in the choke section and approximate prediction of torque requirements for screw feeders of given geometry. For the material element in a pocket, forces are imposed on five boundary surfaces, i.e. shear Chapter 7. Conclusions and suggestions 233 surface, driving side of the flight, trailing side of the flight, core shaft surface and trough surface. In the choke section, a rigid upper casing surface limits the screw space, instead of a shear surface. The torque requirement is proportional to the vertical stress exerted on the hopper outlet by the bulk material in the hopper and approximately proportional to the third power of the screw diameter (cd,c ,c, ,\/Jf are assumed constant) according to theoretical analysis. Starting torque is also predicted, with reasonable accuracy, by stress analysis in the hopper section. The new model predicts: o Average torque requirements of screw feeding for various biomass materials, including screw feeders with tapered and extended discharge sections. o Starting torque requirements for screw feeding of various biomass materials. o Efficiency of biomass screw feeding with consideration of compression in the choke section. 7.1.2 Particulate flow loop A Particulate Flow Loop was designed and fabricated to investigate the movement of clusters of particles of different regular shapes through narrow gaps or constrictions as they are conveyed by water. The work undertaken in this equipment was intended to provide background information and a better understanding of key hydrodynamic multiphase flow factors which cause, or contribute to, stalling and blockage in particulate feeding systems such as those used for feeding biomass to reactors. The following conclusions can be drawn from the study: (1) Spherical particles of small size and low density were easily transported and were unlikely to block the constriction, while irregular rubber and plastic particles of density greater Chapter 7. Conclusions and suggestions 234 than water were difficult to convey. With increasing water mean velocity, the. particles experienced creep, saltation and suspension. (2) Large particles of high aspect ratio and density higher than water were difficult to transport. These particles were also more likely to block the constriction at high Reynolds number. (3) The maximum particle dimension does not solely determine whether or not blockage occurs when the minimum dimension of the particles is less than the maximum gap dimension. However, large particles were more likely to cause blockage, and a lower particle concentration was required to block a constriction for larger than for smaller particles. (4) Nearly neutrally buoyant conical particles were more likely to block a constriction at a high water mean velocity. This appears to be mainly because of the unbalanced shape, intense fluid-particle and particle-particle interactions, and a large ratio of maximum particle dimension to minimum constriction dimension. (5) Particles with some compressibility were more likely to block constrictions than hard particles, because compressible particles tended to jam together instead of separating after colliding. However, soft particles did not form stable blockages due to their low hardness and high flexibility. (6) The blockage probability depends on the interactions of the fluid, particles and constriction. Reynolds number affects particle motion and the blockage tendency. At small water mean velocity, non-spherical particles of density greater than water were difficult to transport because of sedimentation. As the water mean velocity increased, non-spherical particles were easier to transport, with some piling upstream of the constriction and others passing through the gap almost one by one. Blockage was unlikely for this case. For higher water mean velocities, more and more heavier non-spherical particles were transported and Chapter 7. Conclusions and suggestions 235 lifted vigorously (saltation or suspension), increasing the probability of different particles passing through the constriction simultaneously, thereby increasing the probability of blockage. For the conditions of the present study, 3 to 10 non-spherical particles were sufficient to block the constriction if the ratio of particle maximum dimension to constriction minimum dimension > 0.4. As Um increased, blockage was less likely to occur and was more readily broken up because of increased particle inertia, increased drag and increased pressure gradient immediately upstream of the constriction. (7) A wider slot which provided more space for particles to disperse laterally reduced the probability of blockage. (8) The larger or heavier the particles, the greater the chance of them colliding with the wall and with each other because of inertial effects. Preliminary observations show that understanding the motion of a single particle is helpful to understand the motion of swarms of particles. However, blockage is related to swarms of particles and cannot occur without particle-particle and particle-wall interactions. (9) The pressure drop needed to break a blockage was predicted based on horizontal packed bed assumption using a modified Ergun equation. 7.2 Recommendations for Further Work Further research is required to examine a number of factors: (1) Although the model works well in predicting the average and starting torques, it should be modified for different hopper and screw configurations. More screw configurations (e.g. different clearances and pitches), as well as different hopper configurations (e.g. hopper length and internals), should be tested to validate or modify the present model. Chapter 7. Conclusions and suggestions 236 (2) Plug formation and plug seal are critical for screw feeding, especially for feeding to pressurized vessels. More screw configurations need to be tested for adverse pressure gradients in order to achieve better plug seals. (3) Only internal and wall friction are considered in the model. Gravity, centrifugal force and cohesion are neglected in the present model. Their neglect should be reconsidered. (4) A wider range of biomass materials with different mean sizes, size distributions, shapes and moisture contents should be tested. Data from industrial application are preferred. (5) Innovative feeding systems are needed for reactor systems. Deep understanding of bulk solids properties, reactor types and operating conditions, feeder configurations, and diverse combinations of feeders, may be needed for successful feeder design and operation. A schematic of one conceptual design of biomass screw feeding to pressurized reactors is shown in Figure 7-1. (6) Further study on blockage is still needed, typically cohesive blockage involving fine powders with certain moisture content (e.g. < 10% wet basis). Chapter 7. Conclusions and suggestions 237 1 M Lock hopper Pinch valve Lower hopper Screw feeder R o t a r y ^ valve ^ Air, nitrogen \u2014\u2022 or carbon dioxide \\ A A M N K Screw feeder Reactor Figure 7-1. Schematic of conceptual design of biomass feeding to pressurized reactors Nomenclature 238 NOMENCLATURE a Constant defined by Equation 6-86. A Cross-sectional area of screw feeder, A = n(D] - D2 ) \/ 4, m 2 A Blake-Kozeny-Carman constant in Equation 3-19, typically =150. Ac Cross sectional area of vertical section of bin in Equation 6-26, m . b Constant defined by Equation 6-86. B Hopper outlet width in Equation 6-22, m B Burke-Plummer constant in Equation 3-19, typically= 1.75. c Clearance between screw flight tips and trough or casing inside surface, m. c Constant defined by Equation 6-86. cb Ratio of flight thickness to screw diameter, -. cd Ratio of core shaft diameter to screw flight diameter, = Rc 1R0 = Dc 1D0, -. CP Ratio of pitch to screw flight diameter, = Pi Do,-. c, Ratio of trough or casing diameter to screw flight diameter, = 2Rt 1D0,-. C Factor defined by Equation 6-107. cd Drag coefficient, -. CF Compression factor defined by Equation 6-106. dt Arithmetic mean sieve aperture, m . dm Mean particle diameter, m dP Sieve aperture size, m ds Equivalent surface area diameter of particles, m. dsv Equivalent surface area-volume ratio diameter of particles, m dv Equivalent volume diameter of particles, m D Width of long rectangular vertical section of bin or solid surface width in hopper defined by Equation 6-26, m. Core shaft diameter, m. Nomenclature 239 Hydraulic diameter of duct, m. Dh Hydraulic diameter of flow channels in packed bed as shown in Equation 3-22, m. D0 Screw flight diameter, m. D, Inside diameter of trough or casing in Table 4-1, m E Factor defined by Equation 6-107, = c[q fH0Lc \/ (c ( D, 2 )] ' \/ 5 , -. E Elastic modulus defined in Equation 3-2, Pa. f Rotational speed of screw feeder, rpm. F Flexibility defined in Equation 3-1, l\/(Pa.m4). Fc Force on core surface as shown in Figure 6-10, N . F c a Axial force on core surface as shown in Figure 6-10, N . Fcl Tangential force on core surface as shown in Figure 6-10, N . Fd Force on driving side of flight in Figure 4-1, N Fda Axial force on driving side of flight in Figure 4-1, N Fdl Tangential force on driving side of flight in Figure 4-1, N Ff Force on trailing side as shown in Figure 6-12, N . Ffa Axial force on trailing side as shown in Figure 6-12, N . Fj\\ Tangential force on trailing side as shown in Figure 6-12, N . Fs Force on shear surface as shown in Figure 6-9, N . F sa Axial force on shear surface as shown in Figure 6-9, N . Fst Tangential force on shear surface as shown in Figure 6-9, N . F, Force on trough or casing surface as shown in Figure 6-13, N . Fta Axial force on trough or casing surface as shown in Figure 6-13, N . Ft, Tangential force on trough or casing surface as shown in Figure 6-13, N . g Acceleration due to gravity, m\/s2 h Height of cuboidal particle in Table 3-3, m. K Distance between bulk solids free surface and top transition of hopper in Figure 6-7, m H Height of rectangular duct in Chapter 3, m. Nomenclature 240 Hb Height of horizontal packed bed in Figure 3-24, m. H0 Hopper level, m. H, Distance between apex of hopper and top transition of hopper, m. I Area moment of inertia in Equation 3-3, m 4 . lh Mass moment of inertia Equation 3-3, kg.m . k Coefficient in Equation 6-1. K Bulk modulus of compression, Pa. Kx Empirical ratio in Figures 6-1 and 6-8, -. K2 Empirical ratio in Figures 6-1 and 6-8, -. Empirical ratio in Figures 6-1 and 6-8, -. K4 Empirical ratio in Figure 6-8, -. KF Ratio of drag in bounded fluid to that in infinite fluid defined in Equation 3-15, -. \/ Particle length in Table 3-3, m L Length (dimension along streamwise direction) of rectangular duct in Chapter 3, m. Lb Length of horizontal packed bed in Figure 3-24, m. Lh Hopper outlet length in Table 4-1, m Lc Choke section length of screw in Table 4-1, m M{ Mass of bulk solids and cylinder in Equation 4-1, kg M2 Mass of empty cylinder in Equation 4-1, kg m Hopper shape factor; m=l for axisymmetric flow or a conical hopper; m=0 for plane flow or a wedge-shaped hopper, dimensionless. M Mass flow rate in Equation 6-2, kg\/s. n Factor defined by Equation 6-84, -. P Consolidation pressure, Pa. P Pitch of screw in Table 4-1, m PW Shaft power required to rotate screw feeder defined by Equation 6-112, N.m\/s. q Dimensionless surcharge factor, -. q Dimensionless surcharge factor for flow condition,-. qi Dimensionless initial surcharge factor, -. Nomenclature 241 QC Surcharge force at transition of vertical section of bin and hopper in Equation 6-26, N . QV Feeder load exerted by bulk solids at hopper outlet during flow, N . QVJ Initial feeder load exerted by bulk solids at hopper outlet, N . R Screw core shaft radius, m. R Average screw flight radius defined by Equation 6-20, m. Re Reynolds number based on hydraulic diameter of rectangular duct, = DHU mpw I pw, -. Keh Reynolds number based on half-height of rectangular duct, = HUmpw l(2p.w), -. Re Particle Reynolds number, -. R m Mean screw radius defined by Equation 6-16. Ro Screw flight radius, m R, Trough or casing inside radius, m. s Fibre stiffness in bending, Pa.m4. sP Peripheral displacement of screw flight at radius r per revolution in Figure 6-4, m sP Particle surface area in Equation 3-19, m 2 . T, Torque generated in one pocket, N.m. Td Torque generated by driving flight, N.m. Tc Torque generated by core shaft surface, N.m. Tf Torque generated by trailing flight, N.m. T up Torque generated by flight tip, N.m! T cxp Measured average torque, N.m. T pre Predicted average torque, N.m. um Mean fluid velocity in Table 3-2, m\/s. u0 Superficial fluid velocity in Equation 3-21, m\/s. uc Centerline fluid velocity, m\/s. Local fluid velocity, m\/s. Fully developed local fluid velocity, m\/s. Nomenclature 242 Ucfd Fully developed centerline fluid velocity, m\/s. u Particle velocity, m\/s. V Internal volume of cylinder in Equation 4-1, m V Volumetric flow rate in Equation 6-1, m \/s. F r M Maximum theoretical throughput of screw feeder, m\/s. Va Absolute velocity of particle in Figure 4-1, m\/s. Vh Axial velocity of particle in Figure 4-1, m\/s. Vu, Axial velocity of screw in Figure 4-1, m\/s. Vs Tangential velocity of screw in Figure 4-1, m\/s. V,. Relative velocity of particle with respect to screw surface in Figure 4-1, m\/s. V, Tangential velocity of particle in Figure 4-1, m\/s. w Particle width in Table 3-3, m. W Width (dimension along spanwise direction) of rectangular duct in Figure 3-24, m. Wb Width of horizontal packed bed in Figure 3-24, m. x Coordinate in streamwise or horizontal direction, Figure 3-19 or 6-7, m. Xj-d Development length in axial coordinate at which 99% of the centerline velocity is attained, m. xt Mass fraction of particles of size i , -. X Factor defined by Equation 6-36, = s in\u00a3\/( l -sin\u00a3)[sin(2\/? + or)\/sina +1], -. V Factor defined by Equation 6-37, = [(a + \/?) sin a + sin\/? sin(a + \/?)]\/[(!-smJ) sin 2 (a + JB)\\, -. y Vertical coordinate with apex of hopper as origin and upward direction as positive in Figure 6-7, m. y Coordinate in vertical direction in Figure 3-19, m. z Coordinate in spanwise direction in Figure 3-19, m. Greek letters a Half-hopper angle, radians. a Helical angle of screw flight in Figure 4-1, radians Nomenclature 243 a Angle in Figure C - l , radians. ac Screw flight helical angle at core shaft surface, = arctan(P\/2;rf?c), radians. a Mean screw flight helical angle defined by Equation 6-17, radians. a0 Screw flight helical angle at outside radius, = arctan(P \/ 2nR0), radians. a Flight helical angle at screw radius r, radians. (3 Factor defined by Equation 6-38, = \\flw + sin\"1 (sin <j)w I sin 8)\\l 2, radians (5 Ratio of short-to-long side dimension of duct in Chapter 3, =W IH, -. 8 Effective angle of internal friction of bulk solids, radians. e Voidage, -. s Strain in Equation 3-2, -. \u00a3 t Angle defined by Equation 6-31, n \/ 4 + 0w\/2 + \\\/2x cos\"1 (sin <f>w I sin 8) , radians <j)f Wall friction angle of bulk solids on flight surface, radians. <j)w Angle of kinetic friction between bulk solids and hopper wall, trough wall or casing surface, radians. Y Screw flight thickness in Table 4-1, m. Added mass coefficient in Equation 3-13, -. rjv Volumetric efficiency, = V IVm , -. r\/vr Volumetric efficiency at screw radius r, -. X Angle between absolute velocity of particles and vertical direction to screw axis in Figure 4-1, radians. X Angle between absolute velocity of particles and vertical direction to screw axis at screw radius r in Figure 6-2, radians. Xs Ratio of normal wall stress to axial stress for bulk solids sliding on surface, -. \/\/ Effective coefficient of internal friction of bulk solids, = tane), -. d Mf Wall friction coefficient between bulk solids and screw flight surface, = t a n ^ , -. fj.w Wall friction coefficient between bulk solids and trough or core shaft surface, -. juw Dynamic viscosity of water, Pa.s. juwc Wall friction coefficient between bulk solids and core shaft surface, -. juwl Wall friction coefficient between bulk solids and trough surface or casing surface, -. Nomenclature 244 Me Equivalent friction coefficient of bulk solids, = (0.8 - l)sin<5 , -. Pb Bulk density of bulk solids in hopper, kg\/m Pp Particle density, kg\/m Pf Fluid density, kg\/m3 Pw Water density, kg\/m Pya Average bulk density in hopper defined by Equation 6-88. Pyb Compacted bulk density at y defined by Equation 6-88. CT Stress in Equation 3-2, Pa. Stress on material element in a pocket due to driving flight side, Pa. ov Vertical stress exerted by bulk solids at hopper outlet, Pa. Vertical stress exerted by bulk solids at hopper outlet for initial condition, Pa. &w Normal wall stress perpendicular to trough wall and core shaft surface, Pa. \u00ae' wa Average normal wall stress perpendicular to trough wall and core shaft, Pa. <7 X Axial compression stress in a pocket inside screw feeder, Pa. Average axial stress in a pocket, Pa. ^\"min x Minimum axial stress in a pocket in choke section, = ncrv exp(2juwAsPEl(Rt - Rc)), Pa. ^cxa Average axial stress in a pocket in choke section defined by Equation 6-109, Pa. \u00aecwa Average normal stress in a pocket in choke section defined by Equation 6-110, Pa. Tw Shear stress on trough wall and core shaft, Pa. 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Appendices APPENDICES Appendices A p p e n d i x A P r o g r a m L i s t i n g s for F o u r t h - O r d e r R u n g e - K u t t a M e t h o d w i t h V a r i a b l e S t e p s i z e for Pa r t i cu la t e F l o w L o o p File name: PFL_RK2.m Function: rkfuncp, funnp, sovledupdt Source code: see below % % PFL_RK4.m % Compute water velocity and particle velocity using Runge-Kutta RK4 algorithm % with variable steps clc clear n=600; % iteration number h=0.01; % h is the time step un=(n-l)*h; t=[0:h:un]; % initialize time variable. delta0=le-6; deltal=l; hh=0; guess=l; x=zeros(l,n); % intialize x, u, up u=zeros(l,n); up=zeros(l,n); x(l)=0.0331; % initial condition for x,u and up u( 1)=0.4663; up(l)=0.2947; wl=zeros(3,l); % vector used to store Kl and LI in RK4. w2=zeros(3,1); % vector used to store K2 and L2 in RK4. w3=zeros(3,1); % vector used to store K3 and L3 in RK.4. w4=zeros(3,l); % vector used to store K4 and L4 in RK4. for j=l: 1 :n-l while delta 1 > 1.01 *delta0 % criterion to change time and recalculate wl=h*rkfuncp(tG),x(j),uO),upG),guess); % w=[K,L]; w2=h*rkfuncp((t(j)+h.\/2),x(j)+w 1 (1 ).\/2,u(j)+w 1 (2).\/2,up(j)+w 1 (3).\/2,guess); w3=h*rkfuncp((t(j)+h.\/2),x(j)+w2(l).\/2,u0)+w2(2).\/2,upG)+w2(3).\/2,guess); w4=h*rkfuncp((t(j)+h),xG)+w3(l),u(j)+w3(2),up0)+w3(3),guess); xG+l)=xG)+(wl(l)+2*(w2(l)+w3(l))+w4(l)).\/6; % compute x,u and up at j+1 uG+1 )=uO)+(w 1 (2)+2*(w2(2)+w3(2))+w4(2)).\/6; upG+1 )=upG )+(w 1 (3 )+2 *( w2(3)+w3 (3 ))+w4(3 )).\/6; vvO=[xG+l),uG+l),upG+l)]; % store x,u,up in vvO h=h.\/2; % replace h by h\/2 wl=h*rkfuncp(tG),xG),uG),upG),guess); % w=[K,L]; w2=h*rkfuncp((tG)+h.\/2),xG)+wl(l).\/2,uG)+wl(2).\/2,upG)+wl(3).\/2,guess); w3=h*rkfuncp((tG)+h.\/2),xG)+w2(l).\/2,uG)+w2(2).\/2,upG)+w2(3).\/2,guess); w4=h*rkfuncp((tG)+h),xG)+w3(l),uG)+w3(2),upG)+w3(3),guess); xlG)=xG)+(wl(l)+2*(w2(l)+w3(l))+w4(l)).\/6; % value of x, u and up at h\/2 u 1 G)=uG)+(w 1 (2)+2*(w2(2)+w3(2))+w4(2)).\/6; UplG)=upG)+(wl(3)+2*(w2(3)+w3(3))+w4(3)).\/6; wl=h*rkfuncp(tG),xlG),ulG),uplG),guess); % w=[K,L]; w2=h*rkfuncp((tG )+h.\/2),x 1Q )+w 1 (1 ).\/2,u 1Q )+w 1 (2).\/2,up 1Q )+w 1 (3 ).\/2,guess); w3=h*rkfuncp((tG)+h.\/2),xlG)+w2(l).\/2,ulG)+w2(2).\/2,uplG)+w2(3).\/2,guess); Appendices 263 w4=h*rkfuncp((t(j)+h),xG)+w3(l),u(j)+w3(2),upG)+w3(3),guess); x(j+l)=xl(j)+(wl(l)+2*(w2(l)+w3(l))+w4(l)).\/6; % value of x,u and up at h using h\/2 method (j+1) u(j+l)=ul(j)+(wl(2)+2*(w2(2)-i-w3(2))+w4(2)).\/6; upQ+1 )=up 1 G)+(w 1 (3)+2*(w2(3)+w3(3))+w4(3)).\/6; vvl=[xG+l),u(j+l),up(j+l)]; % store x,u,up in vvl deltal=max(abs(vvl-vvO)); % compute deltal using vvl and vvO hh=2*h; hO=2*h*((deltaO.\/deltal).A0.2); % change h value h=hO; end t(j+l)=tG)+hh; delta 1 = 1; 11=0.41; % 0.4 s is the final time point for R-K with variable step-. ift(j+l)>=tl h2=tl-t0); wl=h*rkfuncp(t(j),x(j),u(j),upG),guess); % w=[K,L]; w2=h*rkfuncp((tG)+h2.\/2),xG)+wl(l).\/2,uG)+wl(2).\/2,upG)+wl(3).\/2,guess); w3=h*rkfuncp((tG)+h2.\/2),xG)+w2(I).\/2,uG)+w2(2).\/2,upG)+w2(3).\/2,guess); w4=h*rkfuncp((tG)+h2),xG)+w3(l),uG)+w3(2),upG)+w3(3),guess); xG+l)=xG)+(wl(l)+2*(w2(l)+w3(l))+w4(l)).\/6; % compute x,u and up at j+1 uG+l)=uG)+(wl(2)+2*(w2(2)+w3(2))+w4(2)).\/6; upG+l)=upG)+(wl(3)+2*(w2(3)+w3(3))+w4(3)).\/6; tG+i)=ti; break; end end for i=l :j+l tp(i)=t(i); end fori=l:j+l uu(i)=u(i); end for i=l:j+l uup(i)=up(i); end tt=[0:0.0333:0.5667]; % This is the experimental data for particle velocity. But I only draw t=[0-0.4] in the figure. e=[0.2974,0.2963,0.3048,0.3112,0.3112,0.3366,0.3588,0.3969,0.4699,0.6509,0.8020,0.7315,0.5459,0.3939,0.2858, 0.4128,0.4889,0.4667]; position=[0.0331, 0.0430, 0.0529, 0.0631, 0.0734, 0.0838, 0.0950, 0.1070, 0.1202, 0.1359, 0.1576, 0.1843, 0.2087, 0.2269,0.2400, 0.2496, 0.2633, 0.2796]; fprintf O %10.6f\\n '); % plot the figute fprintf('\\n t \\n\\n'); fori=l:j+l fprintf('%12.6f %12.6f %12.6f\\n', uup(i)); fprintf(V); end plot(tp,uu,'.',tp,uup,'*'); % plot calculated water velocity and particle velocity. axis([0,0.4,0,1.28]); xlabel('time (s)'); ylabel('Water Velocity U and Particle Velocity Up'); title('Calculated Water Velocity U and Calculated Particle Velocity Up'); legend('Calculated Water Velocity U','Calculated Particle Velocity Up'); Appendices figure; plot(tp,uup,'-',tt,e,'*', tt, position, 'o'); % plot experimental data and calculated data for particle velocity. axis([0,0.4,0,1.28]); xlabel('Time (s)'); ylabel('Particle velocity in horizontal direction (m\/s)'); legend('Calculated particle velocity','Experimental data of particle velocity'); % Functions for program Function name: rkfuncp, funnp, sovle_dupdt Source code: see below % function ff=rkfuncp(t,x,u,up,guess) dxdt=u; dudt=(-3313.2.*xA3+803.37.*xA2-19.54.*x+0.41).*u; ff=[dxdt;dudt;sovle_dupdt(u,up,dudt,guess)]; % function y=funnp(u,up,dudt,xl) global dp Dh cdd Re Ret cddtj dp=0.0115; Dh=0.0367; Re=dp*(u-up)*998\/0.001; cd0=21 .\/Re+6\/(Re.A0.5)+0.28; KF=l\/(l-1.6*(dp.\/Dh)A1.6); cdd=cdO*KF; RetQ)=Re; cddt(j)=cdd; y=(0.125*3.14*dpA2*cdd*998*(u-up).A2+3.14*dp.A3*998\/12*(dudt-xl)).*6.\/((3.14*dp.A3).*1019)+998.\/1019*dudt; % function x=sovle_dupdt(u,up,dudt,x 1) % Successive Substitution for one-dimensional root finding % find dup\/dt % xl is guess for dup\/dt, dudt is known value for relevant du\/dt yl =funnp(u,up,dudt,xl); while abs(yl-xl)>le-8 xl=yl; yl =funnp(u,up,dudt,xl); end x=yl; return; % Appendices 265 Appendix B Materials Size Distributions Table B - l . Size distribution of biomass materials (sieve analysis). (1) Size distribution density dp fh (%) (mm) Sawdusts-1 Hog fuel Ground hog fuel Wood shavings-1 Ground wood pellets-2 0.09 [ \" 2.33 0.94 12.56 2.02 1.50 0.25 8.81 7.37 31.57 6.22 6.34 0.5 17.97 11.67 26.69 8.82 13.90 0.71 14.14 6.22 9.92 4.85 12.35 1 18.38 7.26 10.40 7.39 18.12 1.4 17.10 7.64 5.49 8.95 18.87 1.7 8.83 5.60 1.90 7.12 11.74 2 4.75 4.40 0.61 4.96 7.56 2.8 5.84 10.21 0.59 14.02 9.34 6.73 1.85 25.35 0.25 28.43 0.28 9.5 0 \u2022 3.42 0 0 0 12.5 0 3.02 0 7.22 0 25 0 6.90 0 0 0 mean d (21 0.45 0.72 0.18 0.67 0.55 Initial mass (g) 180 180 100 70 180 Notes: [1] upper limit o f a sieve size range; [2] - See Chapter 4, E q . (4-4) for definition. (2) Cumulative size distribution (sieve analysis) dp Ui- (%) (mm) Sawdusts-1 Hog fuel Ground hog fuel Wood shavings-1 Ground wood pellets-2 0.09 33.2 0.94 . 12.56 ; ' 2.02 1.50 0.25 11.15 8.31 44.13 8.24 7.84 0.5 29.11 19.98 70.82 17.06 21.74 0.71 43.26 26.20 80.75 21.91 34.08 1 61.63 33.45 91.14 29.30 52.21 1.4 78.74 41.10 96.63 38.25 71.08 1.7 87.56 46.70 98.54 45.37 82.82 2 92.31 51.10 99.15 50.33 90.38 2.8 98.15 61.30 99.75 64.36 99.72 6.73 100.00 86.66 100.00 92.78 100.00 9.5 90.08 N \/ A 12.5 93.10 100 25 100.00 Appendices 266 A p p e n d i x C S t r e s s Rat io of Bulk S o l i d S l id ing o n C o n f i n e d S u r f a c e A Mohr circle diagram is shown in Figure C-1. This is used to represent the stress of a material element on a confining surface. A EYL Figure C - l . Mohr circle representation of stress in a material element on a confining surface Considering the geometry of the Mohr circle and using the sine rule in the triangle AOB in Figure C - l , we obtain: rm OP OB ( ( M ) s in^ , cos ^ w sin 2a sin(180 - {(\/>\u201e + 2a)) _ _ _ _ _ = __ ^ c _ 2 ^ sin <j)w sin 8 sin(l 80 - {<j)w + 2a)) From Equation C-1, we obtain Appendices 267 r\u201e, cos 2a + OB OD sin (j)w cos 2a + sin(^. + 2a) cos (f>w sin 2a \u2022 (C-3) The stress ratio of the bulk solid sliding on a confined surface can be written (see Equation 6-62) as X = \u2014 = OD cos0w sin 2a ax rm cos 2a + OB sin <f>w cos 2a + sin(^H, + 2a) From Equation C-2, we obtain s i n ^ = sin c> sin(^w +2a) (C-4) (C-5) or \u2022 ,sin^ 2a = arcsin( ) - <pH sin 8 We can get 2a = 2\/3-2^ where . ,sin^ <j)w + arcsin(\u2014-f) sind> (C-6) (C-7) (C-8) In Equation (C-6)-(C-8), <j>w, 8, a and \/? are all in radians. Appendices 268 Appendix D Tangential Force on Driving Flight The tangential force acting on the material element in a pocket due to the driving flight (see Equation 6-83) is dFdl = <JdardOdr tan(a r + <f>f) (D-l) Substituting tana, = P 12m and tan^ y = fif and integrating for 0 from 0 to 2n , the following equation is obtained: Fd, =2nada\\^>r\\ f 27T\/j,fr^ 2m dr \u2022 (D-2) let x = r IP, then dr = Pdx x = Rcl P at r = RC x = RJP at r = R\u201e Equation D-2 becomes Fd,=2^adol\u00abo\/p ^X + 27TjUfX2 ^ 2izx-dx (D-3) let y = 2;zx - fj,f, then dx = dy 2n x = y + Mf 2n Equation D-3 becomes Appendices 269 \u2022 ; 2nRf. I r - 11 c \" ' ff 1 + 2\/\/; \/ \/ . +\/\/;. PiX An' \u2022 + An2y An' dy (D-4) The solution of Equation D-4 is Fd, = 2XP2CJda 2 P2 P2 In P P An2 2nRc-PjUfn Employing non-dimensional parameters, i.e. ______ Ro D0 Equation D-5 becomes Fd, = 2ncrdaD0 n *(i-c2d)+{^cpii-cd)x]:xH^ \u2022Pf 8 An An1 TIC, (D-6) Equation D-2 can also be solved using numerical methods. Appendices 270 A p p e n d i x E T o r q u e Genera ted by Dr iv ing S i d e of S c r e w The torque generated by driving side of the screw (see Equation 6-92) is (E- l ) Substituting tana,. = PI2nr and tan^r = jjf and integrating for 6 from 0 to 2K, the following equation is obtained: T, =2n(jda\\R\u00b0r2 f^ 2?Tjufr^ V 2w dr (E-2) Let x = r IP, then dr = Pdx x = Rc\/P a t r = R x = RJP a t r = R0 Hence Td=2*P3vJRo11, ^x2 + 2nfifx3 ^ 2nx- fj.f dx (E-3) Let y = 2nx - fJ.f, then dx -2n y + P\/ 2n Equation E-3 becomes Appendices 271 2xRc I P - \u201ef %n*y dy (E-4) Employing non-dimensional parameters, i.e. R L = D \u00a3 _ R0 D0 P C ' = D1 The solution of Equation E-4 is Td = Dlcrda n 7TjUf(l-Cd) | (\\ + \/U2f){\\-C2d)Cp t \/lf(l + Jj})(l-Cd)c2p | \/J2f(l + jUJ)cl Cp 12 An An1 ncn (E-5) Equation E-2 can also be solved using numerical methods. Appendices 272 A p p e n d i x F T o r q u e G e n e r a t e d by Tra i l ing S i d e of S c r e w The torque generated by the trailing side of the screw flight (see Equation 6-96) is R sm(<f>f-ar)r2dr 2 n R sm{<l>f-ar) Tf = Xsav \\*o~ \" %*dG = 2^,o- v ft \"r*dr (F-l) K c cosc^cos^ u K c cosa r c o s ^ where sin(^. - ar) = sin<fi, cos ar - cos0 f s ina r . Hence Equation F-1 becomes TF = 2TCXSGY \/^ -\"(tan^ y - tanar)r dr (F-2) Substituting tan ar - P127ir and tan <j)f - juf and integrating for r from Rc to R0, the following equation is obtained: Tf=2nXscjv\\Ro 2n dr (F-3) Integrating Equation F-3 yields nslsnf(\\-c]) ' Xscp(\\-c]) 12 8 3 v o o~\u201eD. (F-4) Appendices 273 Appendix G Listings of Experimental Data Samples G-1. Torque and Power Readings G-l-1 . Hog fuel-1 (40 rpm for screw-1 at 0.45 m hopper level) Number Time Time (min) Torque reading Screw speed Power (s) (N. m) (rpm) (N. m\/s) 1 0.000 0.000 2.429 0 0.000 2 0.021 0.000 2.542 0 0.000 3 0.043 0.001 2.711 0.85 0.000 4 0.066 0.001 2.937 0.85 0.257 5 0.090 0.001 3.107 1.7 0.543 6 0.114 0.002 3.333 3.4 0.860 7 0.138 0.002 . 3.558 5.1 1.207 8 0.161 0.003 3.784 6.8 2.359 9 0.186 0.003 4.067 8.5 3.214 10 0.255 0.004 4.914 14.45 6.760 11 0.280 0.005 5.253 17 7.967 12 0.303 0.005 5.592 19.55 10.844 13 0.329 0.005 5.931 21.25 12.434 14 0.353 0.006. 6.270 23.8 14.666 15 0.447 0.007 7.795 30.6 23.941 16 0.515 0.009 9.094 34 30.601 17 0.539 0.009 9.546 34.85 32.794 18 0.563 0.009 9.941 34.85 36.088 19 0.588 0.010 10.280 35.7 38.025 20 0.611 0.010 10.506 36.55 38.870 21 0.635 0.011 10.675 36.55 40.444 22 0.662 0.011 10.845 37.4 42.491 23 0.686 0.011 10.958 37.4 42.934 24 0.709 0.012 11.071 38.25 43.155 25 0.779 0.013 11.353 38.25 45.041 26 0.804 0.013 11.410 39.1 46.736 27 0.828 0.014 11.523 39.1 46.967 28 0.852 0.014 11.579 39.1 47.431 29 0.876 0.015 11.692 39.1 47.662 30 0.900 0.015 11.805 39.1 48.356 31 0.926 0.015 11.918 39.1 48.819 32 0.949 0.016 12.031 39.1 49.050 33 0.973 0.016 12.144 39.1 49.513 34 1.041 0.017 12.483 39.1 51.132 35 1.066 0.018 12.652 39.1 51.595 36 1.090 0.018 12.765 39.1 52.058 37 1.114 0.019 12.935 39.95 52.752 38 1.139 0.019 13.161 39.95 54.371 39 1.164 0.019 13.387 39.95 55.790 40 1.188 0.020 13.669 39.95 56.736 Appendices 274 mber Time Time (min) Torque reading Sc rew speed Power (s) (N. m) (rpm) (N. m\/s) 41 1.214 0.020 14.064 39.95 57.917 42 1.238 0.021 14.516 39.95 59.336 43 1.307 0.022 15.759 39.1 64.089 44 1.332 0.022 16.154 39.1 65.477 45 1.356 0.023 16.437 39.1 66.634 46 1.380 0.023 16.663 39.1 67.559 47 1.404 0.023 16.832 39.1 68.948 48 1.427 0.024 17.002 39.1 69.642 49 1.452 0.024 17.171 39.1 70.105 50 1.476 0.025 17.227 39.1 70.336 51 1.499 0.025 17.284 39.1 70.798 52 1.571 0.026 17.114 39.95 71.865 53 1.598 0.027 16.945 39.95 71.392 54 1.622 0.027 16.776 39.95 70.210 55 1.647 0.027 16.606 39.95 69.738 56 1.671 0.028 16.493 39.95 69.265 57 1.695 0.028 16.437 39.95 69.028 58 1.720 0.029 16.380 39.95 68.555 59 1.745 0.029 16.380 39.95 68.555 60 1.769 0.029 16.380 39.95 68.555 61 1.838 0.031 16.324 39.95 68.555 62 1.868 0.031 16.154 39.95 67.846 63 1.897 0.032 15.928 39.95 67.373 64 1.922 0.032 15.702 39.95 65.955 65 1.952 0.033 . 15.420 39.95 65.009 66 1.976 0.033 15.250 39.95 64.300 67 2.001 0.033 15.138 39.95 63.355 68 2.024 0.034 15.081 39.95 63.118 69 2.092 0.035 15.025 39.95 62.882 70 2.117 0.035 15.025 39.95 62.882 71 2.141 0.036 15.025 39.95 62.882 72 2.166 0.036 14.968 39.95 62.645 73 2.193 0.037 14.855 39.95 62.409 74 2.216 0.037 14.686 40.8 61.936 75 2.241 0.037 14.460 40.8 61.805 76 2.266 0.038 14.121 40.8 60.598 77 2.290 0.038 13.838 40.8 59.632 78 2.359 0.039 12.991 40.8 56.494 79 2.383 0.040 12.709 40.8 54.562 80 2.408 0.040 12.539 40.8 53.838 81 2.432 0.041 12.370 40.8 53.114 82 2.458 0.041 12.200 40.8 52.631 83 2.482 0.041 12.087 40.8 51.666 84 2.506 0.042 12.031 40.8 51.666 85 2.531 0.042 12.031 39.95 51.424 86 2.556 0.043 12.087 39.95 50.353 87 2.625 0.044 12.539 39.95 52.244 Appendices 275 umber Time Time (min) Torque reading Screw speed Power (s) (N. m) (rpm) (N. m\/s) 88 2.650 0.044 12.822 39.95 53.190 89 2.674 0.045 13.048 39.95 53.899 90 2.698 0.045 13.161 39.95 54.608 91 2.725 0.045 13.161 39.95 55.317 92 2.748 0.046 13.104 39.95 55.081 93 2,777 0.046 12.935 40.8 54.608 94 2.801 0.047 12.709 40.8 54.321 95 2.827 0.047 12.426 40.8 53.355 96 2.894 0.048 11.805 40.8 50.941 97 2.919 0.049 11.636 40.8 50.217 98 2.943 0.049 11.523 40.8 49.251 99 2.970 0.049 11.523 39.95 49.251 100 2.996 0.050 11.579 39.95 48.225 101 3:019 0.050 11.636 39.95 48.462 102 3.044 0.051 11.805 39.95 49.170 103 3.068 0.051 11.974 39.95 49.880 104 3.093 0.052 12.200 39.95 50.589 105 3.162 0.053 12.991 39.95 54.135 106 3.188 0.053 13.274 39.95 55.317 107 3.213 0.054 13.556 39.95 56.263 108 3.236 0.054 13.782 39.95 56.972 109 3.262 0.054 14.008 39.95 58.627 110 3.286 0.055 14.177 39.95 59.100 111 \u20223.310 0.055 14.290 39.95 59.573 112 3.334 0.056 14.347 39.95 59.808 113 3.357 0.056 14.347 39.95 60.045 114 3.426 0.057 14.121 39.95 59.336 115 .3.452 0.058. 14.008 39:95 58.863 116 3.475 0.058 13.838 39.95 58.390 117 3.500 0.058 13.669 39.95 57.917 118 3.527 0.059 13.500 39.95 56.736 119 3.551 0.059 13.330 39.95 56.263 120 3.576 0.060 13.217 39.95 55.553 121 3.604 0.060 12.991 39.95 54.608 122 3.627 0.060 12.878 40.8 54.135 123 3.702 0.062 12.370 40.8 52.873 124 3.728 0.062 12.200 40.8 52.390 125 3.754 0.063 12.031 40.8 51.907 126 3.779 0.063 11.918 40.8 51.424 127 3.803 0.063 11.805 40.8 50.459 128 3.827 0.064 11.692 40.8 49.975 129 3.852 0.064 11.579 40.8 49.734 130 3.878 0.065 11.523 40.8 49.493 131 3.902 0.065 11.466 40.8 49.010 132 3.973 0.066 11.410 40.8 48.768 133 3.998 0.067 11.410 40.8 48.768 134 4.024 0.067 11.523 40.8 49.251 Appendices 276 jmber Time Time (min) Torque reading Sc rew speed Power (s) (N. m) (rpm) (N. m\/s) 135 4.049 0.067 11.692 39.95 48.698 136 4.073 0.068 11.861 39.95 49.170 137 4.099 0.068 12.087 39.95 49.880 138 4.125 0.069 12.313 39.95 51.534 139 4.148 0.069 12.483 39.95 52.007 140 4.172 0.070 12.652 39.95 52.717 141 4.243 0.071 12.822 39.95 53.662 142 4.268 0.071 12.878 40.8 55.045 143 4.291 0.072 12.878 40.8 55.045 144 4.316 0.072 12.878 40.8 55.045 145 4.340 0.072 12.935 40.8 55.045 146 4.364 0.073 12.935 40.8 55.287 147 4.389 0.073 13.048 39.95 54.371 148 4.414 0.074 13.104 39.95 54.608 149 4.438 0.074 13.217 39.95 55.081 150 4.507 0.075 13.669 39.95 56.972 151 4.531 0.076 13.782 39.95 57.445 152 4.555 0.076 13.951 39.95 57.917 153 4.580 0.076 14.121 39.95 59.100 154 4.604 0.077 14.290 39.95 59.573 155 5.148 0.086 15.081 40.8 64.703 156 5.205 0.087 14.573 40.8 62.530 157 5.220 0.087 14.460 40.8 61.805 158 5.236 0.087 14.290 40.8 61.805 159 5.253 0.088 14.177 40.8 61.081 160 5.268 0.088 14.121 40.8 60.357 161 5:284 0.088 14.008 40.8 60.116 162 5.299 0.088 13.951 40:8 60.116 163 5.315 0.089 13.895 40.8 59.632 164 5.333 0.089 13.895 40.8 59.391 165 5.348 0.089 13.838 40.8 59.150 166 5.363 0.089 13.838 \u2022 39.95 59.150 167 5.379 0.090 13.838 39.95 59.150 168 5.398 0.090 13.895 39.95 57.917 169 5.413 0.090 13.951 39.95 58.154 170 5.474 0.091 14.347 39.95 59.573 171 5.489 0.091 14.516 39.95 60.281 172 5.504 0.092 14.686 39.95 61.227 173 5.523 0.092 14.912 39.95 62.172 174 5.539 0.092 15.081 39.95 62.172 175 5.555 0.093 15.250 39.95 63.118 176 5.571 0.093 15.420 39.95 64.063 177 5.588 0.093 15.589 39.95 65.009 178 5.605 0.093 15.646 39.95 65.482 179 5.621 0.094 15.646 39.95 65.482 180 5.636 0.094 15.589 39.95 65.482 181 5.654 0.094 15.533 39.95 65.246 Appendices 277 G-l-2. Sawdust-1 (20 rpm for screw-1 with 0.15 m tapered section at 0.45 m hopper level) Number Time (s) Time (min) Torque reading Screw speed Power (N. m) (rpm) (N. m\/s) 1 0.000 0.000 1.864 0 0.000 2 0.068 0.001 2.090 0 0.000 3 0.087 0.001 2.203 0 0.000 4 0.109 0.002 2.372 0.85 0.201 5 0.132 0.002 2.485 1.7 0.442 6 0.156 0.003 2.655 2.55 0.694 7 0.181 0.003 2.824 4.25 0.985 8 0.204 0.003 2.994 5.1 1.282 9 0.228 0.004 3.163 6.8 1.902 10 0.253 0.004 3.333 7.65 2.671 11 0.326 0.005 3.841 11.05 3.984 12 0.350 0.006 4.010 11.9 4.512 13 0.377 0.006 4.236 12.75 5.583 14 0.401 0.007 4.406 13.6 5.809 15 0.425 0.007 4.575 14.45 6.357 16 0.451 0.008 4.745 14.45 7.182 17 0.475 0.008 - 4.971 15.3 7.876 18 0.499 0.008 0 5.140 16.15 8.148 19 0.524 0.009 5.309 16.15 8.792 20 0.593 0.010 5.874 17 10.361 21 0.615 0.010 6.044 17.85 10.663 22 0.640 0.011 6.213 17.85 11.513 23 0.666 0.011 6.439 17.85 11.830 24 0.690 0.011 6.609 17.85 12.041 25 0.716 0.012 6.778 18.7 13.168 26 0.739 0.012 6.947 18.7 13.500 27 0.763 0.013 7.117 18.7 13.721 28 0.788 0.013 7.286 18.7 14.053 29 0.856 0.014 7.738 19.55 15.733 30 0.881 0.015 7.908 19.55 16.080 31 0.905 0.015 8.021 19.55 16.311 32 0.929 0.015 8.190 19.55 16.543 33 0.953 0.016 8.303 19.55 17.006 34 0.981 0.016 8.473 19.55 17.237 35 1.008 0.017 8.585 19.55 17.353 36 1.033 0.017 8.698 19.55 17.815 37 1.059 0.018 8.811 19.55 17.931 38 1.128 0.019 9.037 19.55 18.394 39 1.151 0.019 9.150 20.4 19.556 40 1.176 0.020 9.263 20.4 19.676 41 1.200 0.020 9.320 20.4 19.917 42 1.224 0.020 9.433 20.4 20.038 43 1.249 0.021 9.546 20.4 20.280 44 1.273 0.021 9.659 20.4 20.642 45 1.296 0.022 9.828 20.4 20.884 46 1.322 0.022 9.941 20.4 21.125 47 1.390 0.023 10.336 20.4 21.849 48 1.414 0.024 10.449 20.4 22.332 Appendices 278 mber Time (s) Time (min) Torque reading Screw speed Power (N. m) (rpm) (N. m\/s) 49 1.439 0.024 10.562 20.4 22.453 50 1.462 . 0.024 10.675 20.4 22.694 51 1.487 0.025 10.788 20.4 22.936 52 1.512 0.025 10.845 20.4 23.177 53 1.537 0.026 10.958 20.4 23.298 54 1.560 0.026 11.014 20.4 23.418 55 1.585 0.026 11.071 20.4 23.539 56 1.655 0.028 11.240 20.4 24.022 57 1.679 0.028 11.297 20.4 24.143 58 1.703 0.028 11.353 20.4 24.143 59 1.728 0.029 11.353 20.4 24.264 60 1.752 0.029, 11.353 20.4 24.264 61 1.778 \u2022 0.030 11.353 . 20.4 24.264 62 1.802 0.030 11.353 20.4 24.264 63 1.826 0.030 11.353 20.4 24.264 64 1.851 0.031 . 11.297 20.4 24.143 65 1.919 0.032 11.184 21.25 25.023 66 1.943 0.032 11.127 21.25 24.897 67 1.968 0.033 11.127 21.25 24.772 68 1.993 0.033 11.071 \u20222.1.25 24.646 69 2.017 0.034 ; 11.014 , 21,25 24.520 70 2.042 0.034 10.958 21.25 24.394 71 2.066 0.034 10.901 21.25 24.394 72 2.092 0.035 10.901 21.25 24.268 73 2.117 0.035 10.845 21.25 24.143 74 2.184 0.036 10.788 20.4 23.057 75 2.211 0.037 10.788 20.4 23.057 76 2.236 0.037 10.788 .20.4 23.057 77 2.261 0.038 10.788 20.4 23.057 78 2.284 0.038 10.788 20.4 23.057 79 2.310 0.039 10.788 20.4 23.057 80 2.335 0.039 10.788 20.4 23.057 81 2.358 0.039 10.845 21.25 24.143 82 2.385 0.040 10.845 21.25 24.143 83 2.455 0.041 10.958 21.25 24.394 84 2.479 0.041 10.958 21.25 24.394 85 2.503 0.042 10.958 21.25 24.394 86 2.529 0.042 10.958 21.25 24.394 87 2.552 0.043 10.901 21.25 24:268 88 2.577 0.043 10.901 21.25 24.268 89 2.601 0.043 10.845 21.25 24.143 90 2.628 0.044 10.788 21.25 24.143 91 2.653 0.044 10.788 21.25 24.017 92 2.720 0.045 10.788 21.25 24.017 93 2.745 0.046 10.845 21.25 24.143 94 2.770 0.046 10.845 21.25 24.143 95 2.794 0.047 10.845 21.25 24.143 96 2.818 0.047 10.845 21.25 24.143 97 2.844 0.047 10.845 21.25 24.143 98 2.868 0.048 10.788 21.25 24.143 99 2.891 0.048 10.788 21.25 24.017 Appendices . 279 Number Time (s) Time (min) Torque reading Screw speed Power (N. m) (rpm) (N. m\/s) 100 2.917 0.049 10.675 21.25 23.891 101 2.985 0.050 10.506 21.25 23.514 102 3.009 0.050 10.449 21.25 23.389 103 3.033 0.051 10.336 21.25 23.011 104 3.058 0.051 10.223 21.25 22.885 105 3.081 0.051 10.167 21.25 22.760 106 3.109 0.052 10.054 21.25 22.508 107 3.132 0.052 9.998 21.25 22.257 108 3.157 0.053 9.941 21.25 22.131 109 3.184 0.053 9.885 21.25 22.005 110 3.252 0.054 9.772 21.25 21.753 111 3.275 0.055 9.715 21.25 21.628 112 3.301 0.055 9.715 21.25 21.628 113 3.326 0.055 9.715 21.25 21.628 114 3.350 0.056 9.715 21.25 21.628 115 3.377 0.056 9.715 21.25 21.628 116 3.400 0.057 9.715 21.25 21.628 117 3.425 0.057 9.715 2.1.25 21.628 118 3.450 0.057 9.772 21.25 21.753 119 3.517 0.059 9.885 21.25 22.005 120 3.542 0.059 9.941 21.25 22.005 121 3.567 0.059 9.941 21.25 22.131 122 3.593 0.060 9.998 21.25 22.257 123 3.617 0.060 10.054 21.25 22.382 124 3.644 0.061 10.111 21.25 22.508 125 3.668 0.061 10.223 21.25 22.634 126 3.693 0.062 10.280 21.25 22.885 127 3.722 0.062 10.393 21.25 23.011 128 3.789 0.063 10.732 21.25 23.640 129 3.813 0.064 10.901 21.25 24.268 130 3.838 0.064 11.071 21.25 24.520 131 3.863 0.064 11.184 21.25 24.772 132 3.887 0.065 11.353 21.25 25.023 133 3.913 0.065 11.466 21.25 25.526 134 3.936 0.066 11.579 21.25 25.777 135 3.961 0.066 11.749 21.25 26.029 136 3.987 0.066 11.861 21.25 26.280 137 4.057 0.068 12.257 20.4 26.074 138 4.083 0.068 12.426 20.4 26.316 139 4.109 0.068 12.539 20.4 26.678 140 4.132 0.069 12.709 20.4 27.160 141 4.157 0.069 12.878 20.4 27.402 142 4.182 0.070 12.991 20.4 27.644 143 4.205 0.070 13.161 20.4 27.885 144 4.229 0.070 13.274 20.4 28.126 145 4.255 0.071 13.387 20.4 28.609 146 4.325 0.072 13.726 20.4 29.213 147 4.348 0.072 13.782 20.4 29.333 148 4.372 0.073 13.838 20.4 29.575 149 4.396 0.073 13.838 20.4 29.575 150 4.419 0.074 13.838 20.4 29.575 Appendices 280 umber T ime (s) Time (min) Torque reading Screw speed Power (N. m) (rpm) (N. m\/s) 151 4.444 0.074 13.838 21.25 29.575 152 4.470 0.074 13.782 21.25 30.807 153 4.493 0.075 13.726 2125 30.555 154 4.519 0.075 13.613 21.25 30.430 155 4.588 0.076 13.330 21.25 29.801 156 4.612 0.077 13.161 21.25 29.298 157 4.637 0.077 13.048 21.25 29.172 158 4.662 0.078 12.878 21.25 28.921 159 4.685 0.078 12.765 21.25 28.670 160 4.711 0.079 12.596 21.25 28.041 161 4.736 0.079 12.483 21.25 27.789 162 4.760 0.079 12.313 21.25 27.538 163 4.784 0.080 12.200 21.25 27.286 164 4.855 0.081 11.805 21.25 26.280 165 4.880 0.081 11.692 21.25 26.155 166 4.906 0.082 11.579 21.25 25.903 167 4.930 0.082 11.466 21.25 25.777 168 4.954 0.083 11.410 21.25 25.400 169 4.979 0.083 11.353 21.25 25.274 170 5.003 0.083 11.297 21.25 25.274 171 5.028 0.084 11.240 21.25 25.148 172 5.051 0.084 11.240 21.25 25.023 173 5.119 0.085 11.184 20.4 23.901 174 5.143 0.086 11.184 20.4 23.901 175 5.167 0.086 11.240 21.25 23.901 176 5.192 0.087 11.240 21.25 25.023 177 5.216 0.087 11.297 21.25 25.148 178 5.242 0.087 11.353 21.25 25.274 179 5.266 0.088 11.410 21.25 25.274 180 5.290 0.088 11.466 21.25 25.400 181 5.316 0.089 11.523 21.25 25.652 182 5.386 0.090 11.579 21.25 25.777 183 5.410 0.090 11.636 21.25 25.777 184 5.435 0.091 11.692 21.25 25.903 185 5.460 0.091 11.692 21.25 26.029 186 5.484 0.091 11.749 21.25 26.155 187 5.510 0.092 11.805 21.25 26.280 188 5.533 0.092 11.861 21.25 26.406 189 5.558 0.093 11.918 21.25 26.532 190 5.583 0.093 11.974 21.25 26.658 191 5.652 0.094 12.087 21.25 26.909 192 5.678 0.095 12.087 21.25 26.909 193 5.703 0.095 12.087 21.25 26.909 194 5.727 0.095 12.087 21.25 26.909 195 5.752 0.096 12.087 21.25 26.909 196 5.776 0.096 12.031 . 21.25 26.784 197 5.801 0.097 11.974 21.25 26.784 198 5.827 0.097 11.918 21.25 26.658 199 5.852 0.098 11.861 21.25 26.406 200 5.923 0.099 11.636 21.25 26.029 201 5.953 0.099 11.523 21.25 25.777 Appendices 281 G-l-3. Ground wood pellets-2 (20 rpm for screw-1 at 0.45 m hopper level with 1500 Pa pressurization in hopper) mber Time Time Torque reading Screw speed Power (s) (min) (N. m) (rpm) (N. m) 1 0.000 0.000 2.090 0 0.000 2 0.034 0.001 2.542 0.85 0.000 3 0.068 0.001 2.994 1.7 0.513 4 0.086 0.001 3.276 2.55 0.860 5 0.149 0.002 4.293 5.95 2.203 6 0.193 0.003 4.914 7.65 3.802 7 0.223 0.004 5.309 9.35 5.145 8 0.239 0.004 5.535 10.2 5.145 9 0.255 0.004 5.705 11.05 5.915 10 0.271 0.005 5.874 11.9 6.669 11 0.287 0.005 6.044 11.9 7.464 12 0.304 0.005 6.213 12.75 8.224 13 0.338 0.006 6.496 13.6 9.094 14 0.419 0.007 7.060 16.15 11.136 15 0.441 0.007 7.173 16.15 12.137 16 0.457 0.008 7.286 16.15 12.137 17 0.473 0.008 7.343 17 12.328 18 0.493 0.008 7.456 17 13.178 19 ; 0.528 0.009 7.625 17.85 13.479 20 0.568 0.009 7.795 17.85 14.576 21 0.584 0.010 7.908 17.85 14.682 22 0.604 0.010 7.964 17.85 14.893 23 0.703 0.012- 8.416 18.7 16.487 24 0.729 0.012 8.585 18.7 16.709 25 0.745 0.012 8.642 19.55 17.584 26 0.766 0.013 8.698 19.55 17.815 27 0.782 0.013 8.811 19.55 17.931 28 0.798 0.013 8.868 19.55 17.931 29 0.843 0.014 9.037 19.55 18.510 30 0.873 0.015 9.207 19.55 18.741 31 0.938 0.016 9.489 19.55 19.204 32 0.954 0.016 9.546 19.55 19.435 33 0.970 0.016 9.659 19.55 19.666 34 1.003 0.017 9.772 20.4 20.884 35 1.046 0.017 9.998 20.4 21.245 36 1.061 0.018 10.054 20.4 21.487 37 1.077 0.018 10.111 20.4 21.487 38 1.099 0.018 10.167 20.4 21.608 39 1.115 0.019 10.223 20.4 21.849 40 1.130 0.019 10.280 20.4 21.970 41 1.237 0.021 10.675 20.4 22.573 42 1.256 0.021 10.732 20.4 22.815 43 1.272 0.021 10.788 20.4 22.936 44 1.289 0.021 10.845 20.4 23.057 Appendices 282 imber Time Time Torque reading Sc rew speed Power (s) (min) (N. m) (rpm) (N. m) 45 1.305 0.022 10.901 20.4 23.298 46 1.348 0.022 11.071 20.4 23.539 47 1.382 0.023 11.184 20.4 23.901 48 1.449 0.024 11.410 20.4 24.264 49 1.465 0.024 11.410 20.4 24.385 50 1.492 0.025 11.466 20.4 24.505 51 1.541 0.026 11.579 20.4 24.746 52 1.557 0.026 11.636 20.4 24.746 53 1.572 0.026 11.636 20.4 24.867 54 1.594 0.027 11.692 20.4 24.867 55 1.609 0.027 11.692 20.4 24.988 56 1.627 0.027 11.749 20.4 25.108 57 1.658 0.028 11.805 20.4 25.108 58 1.746 0.029 11.918 20.4 25.350 59 1.763 0.029 11.918 20.4 25.471 60 1.778 0.030 11.918 20.4 25.471 61 1.794 0.030 11.974 20.4 25.592 62 1.815 0.030 12.031 20.4 25.592 63 1.852 0.031 12.087 20.4 25.832 64 1.886 0.031 12.200 20.4 25.953 65 1.901 0.032 12.200 20.4 26.074 66 1.921 0.032 12.313 20:4 26.316 67 2.023 , , 0.034 - v 12.709 20.4 27.040 68 2.041 0.034 12.765 20.4 27.281 69 2.056 0.034 12.822 20.4 27.281 70 2.071 0.035 12.878 20.4 27.402 71 2.095 0.035 12.935 20.4 27.523 72 2.110 0.035 12.935 20.4 27.644 73 2.126 0.035 12.991 20.4 27.764 74 2.184 0.036 13.104 20.4 28.006 75 2.243 0.037 13.104 21.25 29.172 76 2.262 0.038 13.104 21.25 29.172 77 2.278 0.038 13.048 21.25 29.172 78 2.295 0.038 13.048 21.25 29.047 79 2.327 0.039 12.991 21.25 28.921 80 2.362 0.039 12.935 21.25 28.796 81 2.389 0.040 12.878 21.25 28.670 82 2.404 0.040 12.822 21.25 28.670 83 2.420 0.040 12.822 21.25 28.543 84 2.437 0.041 12.765 21.25 28.543 85 2.541 0.042 12.539 21.25 27.915 86 2.557 0.043 12.539 21.25 27.915 87 2.577 0.043 12.483 21.25 27.915 88 2.593 0.043 12.426 21.25 27.789 89 2.609 0.043 12.426 21.25 27.664 90 2.626 0.044 12.370 21.25 27.538 91 2.659 0.044 12.257 21.25 27.412 Appendices 283 jmber Time Time Torque reading Screw speed Power (s) (min) (N. m) (rpm) (N. m) 92 2.698 0.045 12.144 21.25 27.160 93 2.767 0.046 11.974 21.25 26.658 94 2.783 0.046 11.918 21.25 26.658 95 2.818 0.047 11.861 21.25 26.532 96 2.857 0.048 11.749 21.25 26.280 97 2.874 0.048 11.692 21.25 26.155 98 2.889 0.048 11.692 21.25 26.029 99 2.905 0.048 11.636 21.25 25.903 100 2.921 0.049 11.579 21.25 25.903 101 2.938 0.049 11.579 21.25 25.903 102 2.955 0.049 11.523 21.25 25.777 103 3.036 0.051 11.353 21.25 25.400 104 3.079 0.051 11.297 21.25 25.274 105 3.096 0.052 11.297 21.25 25.148 106 3.112 0.052 11.240 21.25 25.148 107 3.128 0.052 11.240 21.25 25.023 108 3.144 0.052 11.240 21.25 25.023 109 3.162 0.053 11.240 21.25 25.023 110 3 :180 0.053 11.184. 21.25 24.897 111 3.213 0.054 11.184 21.25 24.897 112 3.292 0.055 11.071 21.25 24.646 113 3.321 0.055 11.014 21.25 24.520 114 3:340 0.056 11.014 . 21.25 24.520 115 3.355 0.056 10.958 21.25 24.394 116 3.377 0.056 10.901 21.25 24.394 117 3.393 \u2022 0.057 10.901 21.25 24.268 118 3.409 0.057 10.845 21.25 24.268 119 3.427 0.057 10.845 21.25 24.143 120 3.443 0.057 10.788 21.25 24.017 121 3.479 0.058 10.732 21.25 23.891 122 3.574 0.060 10.562 21.25 23.514 123 3.590 0.060 10.562 21.25 23.514 124 3.605 0.060 10.506 21.25 23.389 125 3.643 0.061 10.506 21.25 23.389 126 3.683 0.061 10.506 21.25 23.389 127 3.700 0.062 10.506 21.25 23.389 128 3.716 0.062 10.562 21.25 23.389 129 3.732 0.062 10.562 21.25 23.514 130 3.813 0.064 10.619 21.25 23.640 131 3.849 0.064 10.619 21.25 23.640 132 3.867 0.064 10.619 21.25 23.640 133 3.882 0.065 10.619 21.25 23.640 134 3.899 0.065 10.619 21.25 23.640 135 3.915 0.065 10.619 21.25 23.640 136 3.930 0.066 10.619 21.25 23.640 137 3.968 0.066 10.562 21.25 23.514 138 4.004 0.067 10.562 21.25 23.514 Appendices 284 jmber Time Time Torque reading Sc rew speed Power (s) (min) (N. m) (rpm) (N. m) 139 4.064 0.068 10.449 21.25 23.263 140 4.081 0.068 10.449 21.25 23.263 141 4.118 0.069 10.449 21 .25 23.263 142 4.152 0.069 10.393 21.25 23.136 143 4.174 0.070 10.393 21 .25 23.136 144 4.190 0.070 10.393 21 .25 23.136 145 4.206 0.070 10.393 21 .25 23.136 146 4.224 0.070 10.393 21 .25 23.136 147 4 .246 0.071 10.393 21 .25 23.136 148 4.261 0.071 10.449 21 .25 23.263 149 4.366 0.073 10.506 21 .25 23.389 150 4.382 0.073 10.562 21 .25 23.514 151 4.411 0.074 10.562 21 .25 23.514 152 4.466 0.074 10.675 21.25 23.765 153 4.505 0.075 10.788 21.25 24.017 154 4 .959 0.083 13.669 20.4 28.851 155 5.031 0.084 14.008 20.4 29.816 156 5.082 0.085 14.234 21 .25 31.687 157 5.123 0.085 14.290 21.25 31.813 158 5.152 0.086 14.347 21.25 31.938 159 5.176 0.086 14.347 21.25 31.938 160 5.200 0.087 14.290 21.25 31.938 161 5.243 0.087 14.234 21 .25 31.687 162 5.334 0.089 13.895 ' 21 .25 31.059 163 5.363 0.089 13.726 21 .25 30.681 164 5.393 0.090 13.556 21 .25 30.430 165 5.419 0.090 13.443 21 .25 30.179 166 5.445 0.091 13.274 21 .25 29.550 167 5.469 0.091 13.161 21.25 29.298 168 5.535 0.092 12.878 21.25 28.796 169 5.609 0.093 12.596 21 .25 28.167 170 5.633 0.094 12.539 21 .25 28.041 171 5.658 0.094 12.370 21 .25 27.789 172 5.682 0.095 12.257 21 .25 27.286 173 5.707 0.095 12.144 21.25 27.160 174 5.762 0.096 11.861 21.25 26.532 175 5.786 0.096 11.805 21.25 26.280 176 5.916 0.099 11.466 21.25 25.526 177 5.940 0.099 11.410 21 .25 25.526 178 5.965 0.099 11.410 21 .25 25.400 179 5.992 0.100 11.353 21 .25 25.274 180 6.016 0.100 11.353 21.25 25.274 181 6.041 0.101 11.297 21.25 25.148 182 6.147 0.102 11,184 21 .25 24 .897 183 6.175 0.103 11.127 21 .25 24.772 184 6.199 0.103 11.071 21 .25 24.772 Appendices 285 G-l-4. Ground wood pellets-1 (20 rpm for screw-2 at 0.45 m hopper level) imber Time Time Torque reading Screw speed Power (s) (min) (N. m) (rpm) (N. m\/s) 1 0.000 0.000 6.383 0 0.000 2 0.021 0.000 6.496 0 0.000 3 0.042 0.001 6.665 0 0.000 4 0.063 0.001 6.947 0 0.000 5 0.084 0.001 7.230 0 0.000 6 0.153 0.003 8.585 0.85 0.734 7 0.177 0.003 9.094 2.55 1.549 8 0.200 0.003 9.546 3.4 3.380 9 0.225 0.004 9.998 4.25 4.401 10 0.249 0.004 10.449 5.95 5.462 11 0.274 0.005 10.788 6.8 6.584 12 0.299 0.005 11.127 8.5 9.908 13 0.323 0.005 11.410 9.35 11.121 14 0.347 0.006 11.636 11.05 12.313 15 0.416 0.007 12.031 13.6 15.994 16 0.442 0.007 12.087 13.6 17.222 17 0.466 0.008 12.144 14.45 18.384 18 0.492 0.008 12.200 15.3 19.556 19 0.516 0.009 12.200 16.15 19.556 20 0.540 0.009 12.257 16.15 20.737 21 0.566 0.009 12.313 17 20.737 22 0.589 0.010 12.313 17 21.929 23 0.613 0.010\" 12.370 17 21.929 24 0.683 0.011 12.426 17.85 23.237 25 0.708 0.012 12.426 18.7 24.344 26 0.732 0.012 12.426 18.7 24.344 27 0.757 0.013 12.483 18.7 24.344 28 0.780 0.013 12.539 18.7 24.565 29 0.804 0.013 12.596 18.7 24.565 30 0.829 0.014 12.652 19.55 25.797 31 0.852 0.014 12.709 19.55 25.913 32 0.878 0.015 12.765 19.55 26.144 33 0.947 0.016 12.991 19.55 26.492 34 0.972 0.016 13.048 19.55 26.608 35 0.996 0.017 13.104 20.4 26.723 36 1.021 0.017 13.161 20.4 28.126 37 1.046 0.017 13.161 20.4 28.126 38 1.069 0.018 13.161 20.4 28.126 39 1.095 0.018 13.161 20.4 28.126 40 1.119 0.019 13.104 20.4 28.006 41 1.143 0.019 13.048 20.4 27.885 42 1.215 0.020 12.709 20.4 27.402 43 1.240 0.021 12.539 20.4 26.799 44 1.264 0.021 12.370 21.25 26.557 45 1.289 0.021 12.200 21.25 27.412 Appendices 286 mber Time Time Torque reading Sc rew speed Power (s) (min) (N. m) (rpm) (N. m\/s) 46 1.313 0.022 12.031 21.25 27.035 47 1.337 0.022 11.861 21.25 26.784 48 1.361 0.023 11.692 21.25 26.155 49 1.385 0.023 11.579 21.25 25.903 50 1.409 0.023 11.410 21.25 25.526 51 1.477 0.025 11.127 21.25 24.897 52 1.503 0.025 11.127 21.25 24.772 53 1.528 0.025 11.071 21.25 24.646 54 1.553 0.026 11.071 21.25 24.646 55 1.578 0.026 11.071 21.25 24.646 56 1.602 0.027 11.071 21.25 24.646 57 1.628 0.027 11.071 21.25 24.646 58 1.651 0.028 11.071 21.25 24.646 59 1.676 0.028 11.071 21.25 24.646 60 1.743 0.029 11.014 21.25 24.520 61 1.770 0.030 11.014 21.25 24.520 62 1.794 0.030 10.958 21.25 24.394 63 1.819 0.030 10.958 21.25 24.394 64 1.843 0.031 10.958 21.25 24.394 65 1.867 0.031 , 10.901 21.25 24.268 66 1.890 0.032 10.901 21.25 24.268 67 1.916 0.032 10.845 21.25 24.268 68 1.940 0.032 10.845 21.25 24.143 69 2.008 0.033 10.675 21.25 23.891 70 2.034 0.034 10.619 21.25 23.765 71 2.058 0.034 10.506 21.25 23.389 72 2.084 0.035 10.449 21.25 23.263 73 2.109 0.035 10.336 21.25 23.136 74 2.133 0.036 10.280 21.25 23.011 75 2.159 0.036 10.167 21.25 22.634 76 2.182 0.036 \" 10.054 21.25 22.382 77 2.207 0.037 9.941 21.25 22.257 78 2.274 0.038 9.659 21.25 21.628 79 2.300 0.038 9.602 21.25 21.377 80 2.324 0.039 9.546 21.25 21.251 81 2.350 0.039 9.546 21.25 21.251 82 2.373 0.040 9.546 21.25 21.251 83 2.398 0.040 9.659 21.25 21.502 84 2.423 0.040 9.715 21.25 21.502 85 2.448 0.041 9.772 21.25 21.753 86 2.472 0.041 9.885 21.25 21.879 87 2.540 0.042 10.054 21.25 22.382 88 2.566 0.043 10.167 21.25 22.508 89 2.590 0.043 10.223 21.25 22.634 90 2.615 0.044 10.280 21.25 22.760 91 2.639 0.044 10.336 21.25 23.011 92 2.664 0.044 10.393 21.25 23.136 Appendices 287 jmber Time Time Torque reading Screw speed Power (s) (min) (N. m) (rpm) (N. m\/s) 93 2.691 0.045 10.449 21.25 23.136 94 2.715 0.045 10.506 21.25 23.263 95 2.739 0.046 10.562 21.25 23.514 96 2.807 0.047 10.732 21.25 23.765 97 2.833 0.047 10.788 21.25 23.891 98 2.857 0.048 10.788 21.25 24.017 99 2.882 0.048 10.845 21.25 24.143 100 2.908 0.048 10.845 21.25 24.143 101 2.932 0.049 10.901 21.25 24.268 102 2.960 0.049 10.958 21.25 24.394 103 2.984 0.050 11.014 21.25 24.394 104 3.008 0.050 11.014 21.25 24.520 105 3.075 0.051 11.071 \u20222-1.25 24.646 106 3.100 0.052 11.071 21:25 24.646 107 3.124 0.052 11.071 21.25 24.646 108 3.149 0.052 11.014 21.25 24.520 109 3.174 0.053 10.958 21.25 24.520 110 3.198 0.053 10.901 . 2.1.25 24.268 111 3.224 0.054 10.788 21.25 24.143 112 3.248 0.054 10.732 21.25 23.891 113 3.273 0.055 10.675 21.25 23.765 114 3.340 0.056 10.562 21.25 23.514 115 3.365 0.056 10.562 21.25 23.514 116 3.389 0.056 10.562 21.25 23.514 117 3.412 0.057 10.619 21.25 23.514 118 3.436 0.057 10.619 21.25 23.640 119 3.460 0.058 10.675 21.25 23.765 120 3.488 0.058 10.732 21.25 23.891 121 3.513 0.059 10.788 21.25 23.891 122 3.536 0.059 10.901 21.25 24.143 123 3.605 0.060 11.127 21.25 24.646 124 3.629 0.060 11.184 21.25 24.897 125 3.655 0.061 11.297 21.25 25.023 126 3.679 0.061 11.353 21.25 25.274 127 3.704 0.062 11.353 21.25 25.274 128 3.727 0.062 11.410 21.25 25.400 129 3.754 0.063 11.466 21.25 25.400 130 3.778 0.063 11.466 21.25 25.526 131 3.802 0.063 11.466 21.25 25.526 132 3.871 0.065 11.466 21.25 25.526 133 3.897 0.065 11.466 21.25 25.526 134 3.921 0.065 11.466 21.25 25.526 135 3.946 0.066 11.466 21.25 25.526 136 3.970 0.066 11.466 - 21.25 25.526 137 3.994 0.067 11.410 21.25 25.526 138 4.023 0.067 11.410 21.25 25.400 139 4.046 0.067 11.353 21.25 25.274 Appendices 288 Number Time Time Torque reading Screw speed Power (s) (min) (N. m) (rpm) (N. m\/s) 140 4.071 0.068 11.297 21.25 25.274 141 4.137 0.069 11.297 21.25 25.148 142 4.161 0.069 11.240 21.25 25.023 143 4.187 0.070 11.240 21.25 25.023 144 4.212 0.070 11.184 21.25 25.023 145 4.236 0.071 11.127 21.25 24.897 146 4.260 0.071 11.071 21.25 24.646 147 4.287 0.071 11.014 2.1.25 24.646 148 4.311 0.072 10.958 - 21.25 24.520 149 4.335 0.072 10.901 21.25 24.394 150 4.403 0.073 10.845 21.25 24.143 151 4.429 0.074 10.901 21.25 24.143 152 4.453 0.074 10.901 21,25 24.268 153 4.478 0.075 10.901 21.25 24.268 154 4.503 0.075 10.901 21.25 24.268 155 4.528 0.075 10.958 21.25 24.268 156 4.554 0.076 10.958 21.25 24.394 157 4.580 0.076 10.958 21.25 24.394 158 4.604 0.077 10.958 21.25 24.394 159 4.672 0.078 10.901 21.25 24.268 160 4.698 0.078 10.788 21.25 24.143 161 4.721 0.079 10.732 21.25 23.891 162 4.746 0.079 10.675 21.25 23.765 163 4.772 0.080 10.562 21.25 23.640 164 4.796 0.080 10.506 21.25 23.514 165 4.822 0.080 10.393 21.25 23.136 166 4.846 0.081 10.280 21.25 23.011 167 4.870 0.081 10.167 21.25 22.760 168 4.938 0.082 9.941 21.25 22.131 169 4.964 0.083 9.828 21.25 22.005 170 4.988 0.083 9.772 21.25 21.879 171 5.013 0.084 9.715 21.25 21.753 172 5.038 0.084 9.659 21.25 21.502 173 5.063 0.084 9.602 21.25 21.502 174 5:088 0.085 9.602 21.25 21.377 175 5.115 0.085 9.602 21.25 21.377 176 5.139 0.086 9.546 21.25 21.251 177 5.208 0.087 9.546 21.25 21.251 178 5.233 0.087 9.602 21.25 21.377 179 5.258 0.088 9.602 21.25 21.377 180 5.283 0.088 9.546 21.25 21.251 181 5.307 0.088 9.546 21.25 21.251 182 5.331 0.089 9.546 21.25 21.251 183 5.356 0.089 9.489 21.25 21.251 184 5.381 0.090 9.489 21.25 21.125 Appendices 289 G-2. Weight Readings and Flow Rate Calculations for Sawdust-1 at 30 rpm Time Time Time interval Weight Weight increment Mass flow rate (s) (min) (s) (kg) (kg) (kg\/h) 0.00 0.00 2.03 0.00 0.08 141.87 2.03 0.03 2.04 0.08 0.08 141.18 4.07 0.07 2.08 0.16 0.10 173.08 6.15 0.10 2.04 0.26 0.08 141.18 8.19 0.14 2.03 0.34 0.10 177.34 10.22 0,17 2.09 0.44 0.08 137.80 12.31 0.21 2.03 0.52 0.10 177.34 14.34 0.24 4.12 0.62 0.18 157.28 18.46 0.31 2.08 0.80 0.10 173.08 20.54 0.34 2.04 0.90 0.10 176.47 22.58 0.38 2.03 1.00 0.08 141.87 24.61 0.41 2.14 1.08 0.10 168.22 26.75 0.45 2.03 1.18 0.10 177.34 28.78 0.48 2.09 1.28 0.10 172.25 30.87 0.51 2.03 1.38 0.08 141.87 32.90 0.55 4.12 1.46 0.20 174.76 37.02 0.62 2.03 1.66 0.10 177.34 39.05 0.65 2.04 1.76 0.08 141.18 41.09 0.68 2.03 1.84 \u2022 0.10 177.34 43.12 0.72 2.09 1.94 0.10 172.25 45.21 0.75 2.03 2.04 0.10 177.34 47.24 0.79 2.03 2.14 0.08 141.87 49.27 0.82 2.03 2.22 0.10 177.34 51.30 0.86 2.09 2.32 0.10 172.25 53.39 0.89 2.03 2.42 0.10 177.34 55.42 0.92 2.03 2.52 0.10 177.34 57.45 0.96 2.04 2.62 0.10 176.47 59.49 0.99 2.14 2.72 0.08 134.58 61.63 1.03 2.03 2.80 0.10 177.34 63.66 1.06 2.09 2.90 0.10 172.25 65.75 1.10 2.09 3.00 0.10 172.25 67.84 1.13 2.08 3.10 0.10 173.08 69.92 1.17 2.03 3.20 0.10 177.34 71.95 1.20 2.04 3.30 0.10 176.47 73.99 1.23 2.03 3.40 0.10 177.34 76.02 1.27 6.21 3.50 0.30 173.91 82.23 1.37 2.03 3.80 0.10 177.34 84.26 1.40 2.09 3.90 0.10 172.25 86.35 1.44 2.03 4.00 0.08 141.87 88.38 1.47 2.08 4.08 0.10 173.08 90.46 1.51 2.09 4.18 0.10 172.25 92.55 1.54 2.03 4.28 0.10 177.34 94.58 1.58 2.09 4.38 0.10 172.25 96.67 1.61 2.03 4.48 0.10 177.34 98.70 1.64 2.09 4.58 0.08 137.80 100.79 1.68 2.03 4.66 0.10 177.34 Appendices 290 Appendix H Program Listings of Model Predicting Torque Requirements H - l : Torque prediction for wood pellets File name: Torque_Woodpellets.m Function: taoxavel, taoxh, trailing, integrndTd and integrnd_Tf Source code: see below % Hopper-screw feeder load and torque calculation for static and dynamic conditions. % Screw speeds, gravity and centrifugal forces are neglected in screw torque analysis clc clear % % fixed parameters for screw feeder and hopper global P taofv muf muwt muwh lamdas Rt Rc alphas phi phif lamdasa CCC rou_bulk=630; % bulk density of bulk solid, kg\/mA3. H0=0.3; % initial bed height in the hopper, m P=0.1; %pitch,m Do=0.1; % screw diameter, m Ro=Do\/2; % screw radius, m. Dc=0.030; % screw core shaft diameter, m Rc=Dc\/2; % screw core shaft radius, m Dt=0.102; % trough diameter,m Rt=Dt\/2; % trough radius, m cp=P\/Do; % ratio of pitch to screw diameter. ct=Dt\/Do; % ratio of trough diameter to screw diameter. cd=Dc\/Do; % ratio of core shaft diameter to screw diameter. Lh=0.914; % hopper outlet length,m L=0.8; % length of screw with . 1 m screw diameter, a little shorter than outlet length (.914 m). Lc=0.62; % choke section length, m B=0.102; % width of the trough,m A_cross=pi*(RoA2-RcA2) % Effective cross section area of screw casing, mA2. alpha=20\/l 80*pi; % half hopper angle, radian g=9.8; % gravitational acceleration, m\/sA2. alphao=atan(P\/(2*pi*Ro)); % helical angle at outside screw diameter, radian. alphac=atan(P\/(2*pi*Rc)); % helical angle at core shaft surface, radian. alphao_deg=atan(P\/(2*pi*Ro))\/pi* 180; % helical angle at outside screw diameter, degree. alphac_deg=atan(P\/(2*pi*Rc))\/pi* 180; % helical angle at core shaft surface, degree. % % variable parameters for biomass fuels and hopper-screw feeder % initial vertical stress and initial feeder load m=l; deltal_deg=32; % set effective internal friction angle, degree delta2_deg=32; delta_deg=[deltal_deg:m:delta2_deg]; % effective internal friction angle, degree. n=(delta2_deg-deltal_deg).\/m+1; delta=[deltal_deg\/180*pi:m\/180*pi:delta2_deg\/180*pi]; phi=31.4\/180*pi; % angle of friction between bulk solids and hopper wall (or casing surface), radian. phif=31.4\/180*pi; % angle of friction between bulk solids and screw flight, radian. muf=tan(phif); % coefficient of friction between solids and flight surface muwc=muf; % friction coefficient of bulk solid on core surface muwh=tan(phi); % friction coefficient of bulk solid on hopper surface. muwt=muwh; % friction coefficient of bulk solid on trough surface. D=2*(H0+B.\/2*cot(alpha))*tan(alpha); Appendices 29 % compute width of bulk solid free surface in hopper (flate surface), m qi=l\/(2*tan(alpha))*(D\/B-l); % compute non-dimensional surcharge factor for initial condition, taoi_v=qi*rou_bulk*g*B; % compute vertical stress at hopper outlet for initial condition Fv_i=taoi_v*Lh*B; % compute feeder load at hopper outlet for initial condition % . . . % vertical stress and feeder load for flow condition for i = l : 1 :n mud(i)=tan(delta(i)); % effective coefficient o f internal friction. mue(i)=sin(delta(i)); % equivalent friction coefficient o f bulk solid,.from Roberts alpha_Mohr(i)=(asin(sin(phi)\/sin(delta(i)))-phi)\/2; lamdas(i)=cos(phi)*sin(2*aIpha_Mohr(i))\/(sin(phi)*cos(2^ % stress ratio o f normal stress acting perpendicularly to wall % of trough and core shaft surfaces to axial compression stress % derived from M o h r circle beta(i)=0.5*(phi+asin(sin(phi)\/sin(delta(i)))); % compute beta(i), constant X(i)=sin(delta(i))\/(l-sin(delta(i)))*(sin(2*beta(i)+alpha)\/sin(alpha)+l); % constant to compute feeder load Y0^=((alpha+beta0))*sin(alpha)+sin(beta(i))*sin(alpha+beta(i))).\/((l-sin(delta(i)))*sin(alpha+beta(i))A2); qf(i)=Y(i)*(l+sin(delta(i)))\/(2*(X(i)-l)*sin(alpha)); % surcharge factor for flow conditions % q f 1 (i)= 1 \/4*(l\/tan(alpha))*(Y(i)*( 1 +sin(delta(i))*cos(2*beta(i)))*(tan(alpha)+tan(phi))\/sin(alpha)\/(X(i)-1)-1); taof_vO(i)=qf(i)*rou_bulk*g*B; % use loose bulk density for incompressible solids in the present study Fv_fU(i)=taof_vO(i).*Lh.*B; % vertical stress and feeder load for flow condition taof_v(i)=(taofvO(i)+taoi_v).\/2; % average vertical stress for flow condition Fv_f(i)=taof_v(i).*Lh.*B; % average feeder load for flow condition end -% 1 \u2014...........\u2014\u2014. % hopper section, for a material element in a pitch first then entire hopper section t=1.0; % factor used to modify boundary condition at trailing side o f flight eps=0.0001; % one small number a=0; % set initial value for'a, a is ratio,i.e. taoxa(i)\/tao_daf(i) while abs(0.85-a) > eps for i = l : l : n taoxamax(i)=t*taof_v(i)*(exp(2*tan(phi)*lamdas(i)*P\/(Rt-Rc))); % maximum stress at driving side o f flight according to stress analysis taoxamin(i)=t*taof_v(i); % minimum stress at trailing side o f flight according to stress analysis lamdas_a=lamdas(i); % stress ratio o f normal wall stress to axial stress on confined surface taoxa(i)=l\/P*t*taof_v(i)*quadl(@taoxh, 0,P); % average axial stress in a pitch for flow condition taoxai(i)=l\/P*t*tao i_v*quadl(@taoxh, 0,P); % average axial stress in a pitch for initial condition taowa(i)=lamdas(i)*taoxa(i); % average normal wall stress in a pitch for flow condition taowai(i)=lamdas(i)*taoxai(i); % average normal wall stress in a pitch for initial condition % - 1 . shear surface ksa(i)=pi*mue(i)*cp*cos(alphao+phif).\/2; % parameter for axial force calculations on shear surface Fsaf(i)=-ksa(i).*taof_v(i).*Do.A2; % axial force on shear surface for flow condition Fsai(i)=-ksa(i)*taoi_v*DoA2; % axial force on shear surface for initial condition kst(i)=pi*mue(i)*cp*sin(alphao+phif).\/2; % parameter for tangential force calculations on shear surface Fstf(i)=-kst(i).*taof_v(i)*DoA2; % tangential force on shear surface for flow condition Fsti(i)=-kst(i)*taoi_v*DoA2; % tangential force on shear surface for initial condition Fstfp_try(i)=l\/2*(taof_v(i)+taowa(i))*0.00635*P\/sin(atphao)*tan(phif); % tangential force from flight tips for flow condition Fstip_try(i)=l\/2*(taoi_v+taowai(i))*0.00635*P\/sin(alphao)*tan(phif); % tangential force from flight tips for initial condition Tstfp(i)=Fstfp_try(i)*Ro; Tstip(i)=Fstip_try(i)*Ro; % torque from flight tips for flow condition % torque from flight tips for initial condition Appendices 292 %-2. core shaft kca(i)=t*pi*(ct-cd)*cd*cp*(exp(4*m^ % parameter for axial force calculations on core shaft surface Fcaf(i)=-kca(i)*taof_v(i)*DoA2; % axial force on core surface for flow condition Fcai(i)=-kca(i)*taoi_v*DoA2; % axial force on core surface for initial condition Fcal_try(i)=2*pi*Rc*P*tan(phif)*taowa(i)*sin(alphac); % axial force on core surface for flow condition kct(i)=t*piA2*(ct-cd)*cdA2*(exp(4*muwc*lamdas(i)*cp\/(ct-cd))-l)\/4\/(cpA2+piA2*cdA2)A0.5; % parameter for tangential force calculations on core shaft surface Fctf(i)=kct(i)*taof_v(i)*DoA2; % tangential force on core surface for flow condition Fcti(i)=kct(i)*taoi_v*DoA2; % tangential force on core surface for initial condition %-3. trailing flight side kfa(i)=t*lamdas(i)*(pi*(l-cdA2)\/4+cp*muf*(l-cd)\/2); % parameter for axial force calculations on trailing side surface Ffaf(i)=-kfa(i)*taof_v(i)*DoA2; % axial force on trailing side surface for flow condition Ffai(i)=-kfa(i)*taoi_v*DoA2; % axial force on trailing side surface for initial condition Ffafl_try(i)=2.*pi.*lamdas(i).*taoxamin(i).*quadl(@trailing, Rc, Ro); % axial force on trailing side surface for flow condition kft(i)=t*Iamdas(i)*(pi*muP(l-cdA2)\/4-cp*(l-cd)\/2); % parameter for tangential force calculations on trailing side surface Fftf(i)=kft(i)*taof_v(i)*DoA2; % tangential force on trailing side surface for flow condition Ffti(i)=kft(i)*tao i_v*DoA2; % tangential force on trailing side surface for initial condition %-4. trough surface kta(i)=t*pi*(ct-cd)*ct*cos(alphao+phi0\/8*(exp(4*muwt*lamdas(i)*cp\/(ct-cd))-l); % parameter for axial force calculations on trough surface Ftaf(i)=-kta(i).*taof_v(i).*Do.A2; % axial force on trough surface for flow condition Ftai(i)=-kta(i)*taoi_v*DoA2; % axial force on trough surface for initial condition ktt(i)=t*pi*(ct-cd)*ct*sin(alphao+phif)\/8*(exp(4*muwt*lamdas(i)*cp\/(ct-cd))-l); % parameter for tangential force calculations on trough surface Fttf(i)=-ktt(i)*taof_v(i)*DoA2; % tangential force on trough surface for flow condition Ftti(i)=-ktt(i)*taoi_v*DoA2; % tangential force on trough surface for initial condition %-5. stress on driving side Kda(i)=4*(ksa(i)+kca(i)+kfa(i)+kta(i))\/pi\/(l-cdA2); % parameter for axial force calculations on driving side surface tao_daf(i)=Kda(i)*taof_v(i); % compute axial stress on driving surface for flow condition tao_dai(i)=Kda(i)*taoi_v; % compute axial stress on driving surface for initial condition Ftao_daf(i)=tao_daf(i)*A_cross; % compute axial force on driving surface for flow condition Ftao_dai(i)=tao_dai(i)*A_cross; % compute axial force on driving surface for initial condition % torque calculation Tdf(i)=2*pi*tao_daf(i)*quadl(@integrnd_Td, Rc, Ro); % compute torque generated by driving side of screw for flow condition Tdi(i)=2*pi*tao_dai(i)*quadI(@integrnd_Td, Rc, Ro); % compute torque generated by driving side of screw for initial condition Tcf(i)=2*pi*Rc*P*taowa(i)*tan(phif)*cos(alphac)*Rc;; % compute torque generated by core shaft surface for flow condition Tci(i)=2*pi*Rc*P*taowai(i)*tan(phif)*cos(alphac)*Rc; % compute torque generated by core shaft surface for initial condition Tff(i)=2*pi*lamdas(i)*t*taof_v(i)*quadl(@integrnd_Tf, Rc, Ro); % compute torque from trough surface for flow condition Tfl(i)=2*pi*lamdas(i)*t*taoi_v*quadl(@integrnd_Tf, Rc, Ro); % compute torque from trough surface for initial condition T_hopperf(i)=Lh\/P*(Tdf(i)+Tcf(i)+Tff(i)+Tstfp(i)); % compute total torque in hopper section for flow condition T_hopperi(i)=Lh\/P*(Tdi(i)+Tci(i)+Tfi(i)+Tstip(i)); % compute total torque in hopper section for initial condition Appendices 293 ratio01(i)=tao_daf(i)\/taoxamax(i); % ratio of stress on driving side to theoretical maximum stress in a pitch ratio02(i)=taoxa(i)\/tao_daf(i); % ratio of average axial stress to stress on driving side in a pitch end a=ratio02(l); % ratio of average axial stress to stress on driving side t=t+0.0001; % 0.0001 as increment fort end t=t-0.0001; % . . -% Choke section-0.9 m screw diameter P=0.1; %pitch,m Do=0.09; % screw diameter, m Ro=Do\/2; % screw radius, m. Dc=0.030; % screw core shaft diameter, m Rc=Dc\/2; % screw core shaft radius, m Dt=0.102; % trough diameter,m Rt=Dt\/2; % trough radius, m cp=P\/Do; % ratio of pitch to screw diameter. ct=Dt\/Do; % ratio of trough diameter to screw diameter. cd=Dc\/Do; % ratio of core shaft diameter to screw diameter. A_cross=pi*(RoA2-RcA2) % Effective cross section area of the screw casing LI =0.2; % length of screw with 0.09 m screw diameter. alphao=atan(P\/(2*pi*Ro)); % helical angle at the outside screw diameter, radian. alphac=atan(P\/(2*pi*Rc)); % helical angle at the core shaft surface, radian. alphao_deg=atan(P\/(2*pi*Ro))\/pi* 180; % helical angle at the outside screw diameter, degree. alphacdeg=atan(P\/(2*pi*Rc))\/pi* 180; % helical angle at the core shaft surface, degree. % torque calculation for i=l:l:n con=0.15; % constant for estimating the axial stress in choke section e=0.2; CCl(i)=con*(qf(i)*H0\/Dt*Lc\/Dt\/ct)A(e); % exponent to estimate the axial stress on trailing side of flight taoxaml(i)=t*taof_v(i)*(exp(2*tan(phi)*lamdas(i)*P\/(Rt-Rc))).A(CCl(i)+l); % theoretical maximum stress on driving side of flight taoxamll(i)=t*taof_v(i)*(exp(2*tan(phi)*lamdas(i)*P\/(Rt-Rc))).A(CCl(i)); % theoretical minimum stress on trailing side of flight EEl(i)=(exp(2*tan(phi)*lamdas(i)*P\/(Rt-Rc))).A(CCl(i)); % how many times for stress on trailing side compared to vertical stress taofv % for flow condition, compression factor in choke section lamdas_a=lamdas(i); % compute lamdas for function taoxavel CCC=CC 1 (i); % compute CC1 for function taoxave 1 taoxl_a(i)=l\/P*t*taof_v(i)*quadl(@taoxavel, 0,P); % average axial stress in choke section taowal(i)=lamdas(i)*taoxl_a(i); % average normal wall stress in choke section Fea 1 (i)=2*pi*Rc*P*tan(phif)*taowa 1 (i)*sin(alphac); % axial force on core surface in choke section Ffafl(i)=2.*pi.*lamdas(i).*taoxaml l(i).*quadl(@trailing, Rc, Ro); % axial force on trailing side surface in choke section Ftafl(i)=2*pi*tan(phi)*taowal(i)*Rt*P*cos(alphao+phif); % axial force on trough surface in choke section Fdaf 1 (i)=Fca 1 (i)+Ffaf 1 (i)+Ftaf 1 (i); % axial force on driving side surface in choke section tao_dafl(i)=Fdafl(i).\/pi.\/(RoA2-RcA2); % compute axial stress on driving surface for flow condition in choke section Tdfl(i)=2*pi*tao_dafl(i)*quadl(@integrnd_Td, Rc, Ro); % compute torque generated by driving side surface for choke section Appendices 294 Tcfl(i)=taowal(i)*2*pi*Rc*P*tan(phif)*Rc*cos(alphac); % compute torque generated by trailing side surface for choke section Tffl(i)=2*pi*lamdas(i)*taoxaml l(i)*quadl(@integrnd_Tf, Rc, Ro); % compute torque generated by trough side surface for choke section Ttip 1 (i)=tao wa 1 (i)*0.0063 5 * P.\/sin(alphao)*tan(phi f)* Ro; % compute torque generated by flight tips for choke section Tchoke 1 (i)=L 1 \/P*(Tdf 1 (i)+Tcf 1 (i)+Tff 1 (i)+Ttip 1 (i)); % compute total torque in choke section 1 for flow condition end % . % Choke section-0.8 m screw diameter P=0.1; % pitch,m Do=0.08; % screw diameter, m Ro=Do\/2; % screw radius, m. Dc=0.030; % screw core shaft diameter, m Rc=Dc\/2; % screw core shaft radius, m Dt=0.102; % trough diameter,m Rt=Dt\/2; % trough radius, m cp=P\/Do; % ratio of pitch to screw diameter. ct=Dt\/Do; % ratio of trough diameter to screw diameter. cd=Dc\/Do; % ratio of core shaft diameter to screw diameter. A_cross=pi*(RoA2-RcA2) % Effective cross section area of the screw casing L2=0.42; % length of screw with 0.08 m screw diameter. alphao=atan(P\/(2*pi*Ro)); % helical angle at outside screw diameter, radian. alphac=atan(P\/(2*pi*Rc)); % helical angle at core shaft surface, radian. alphaodeg=atan(P\/(2*pi*Ro))\/pi* 180; % helical angle at outside screw diameter, degree. alphac_deg=atan(P\/(2*pi*Rc))\/pi* 180; % helical angle at core shaft surface, degree. % torque calculation fori=l:l:n CC2(i)=con*(qf(i)*H0\/Dt*Lc\/Dt\/ct)A(e); % exponent to estimate axial stress on trailing side of a flight taoxam2(i)=t*taof_v(i)*(exp(2*tan(phi)*lamdas(i)*P\/(Rt-Rc)))A(CC2(i)+l); % theoretical maximum stress on driving side of flight taoxam22(i)=t*taof_v(i)*exp(2*tan(phi)*lamdas(i)*P\/(Rt-Rc))A(CC2(i)); % theoretical minimum stress on trailing side of flight EE2(i)=(exp(2*tan(phi)*lamdas(i)*P\/(Rt-Rc))).A(CC2(i)); % how many times for stress on trailing side compared to vertical stress taofv % for flow condition, compression factor in choke section lamdas_a=lamdas(i); % compute lamdas for function taoxavel CCC=CC2(i); % compute CC2 for function taoxave 1 taox2_a(i)=l\/P*t*taof_v(i)*quadl(@taoxavel, 0,P); % average axial stress in choke section taowa2(i)=lamdas(i)*taox2_a(i); % average normal wall stress in choke section Fca2(i)=2*pi*Rc*P*tan(phi)*taowa2(i)*sin(alphac); % axial force on core surface in choke section Ffaf2(i)=2*pi*lamdas(i)*taoxam22(i)*quadl(@trailing, Rc, Ro); % axial force on trailing side surface in choke section Ftaf2(i)=2*pi*tan(phi)*taowa2(i)*Rt*P*cos(alphao+phif); % axial force on trough surface in choke section Fdaf2(i)=Fca2(i)+Ffaf2(i)+Ftaf2(i); % axial force on driving side surface in choke section tao_daf2(i)=Fdaf2(i).\/pi.\/(RoA2-RcA2);; % compute axial stress on driving surface in choke section Tdf2(i)=2*pi*tao_daf2(i)*quadl(@integrnd_Td, Rc, Ro); % compute torque generated by driving side surface for choke section 2 Tcf2(i)=taowa2(i)*2*pi*Rc*P*tan(phiO*Rc*cos(alphac); % compute torque generated by trailing side surface for choke section 2 Tff2(i)=2*pi*lamdas(i)*taoxam22(i)*quadl(@integrnd_Tfi Rc, Ro); Appendices % compute torque generated by trough surface for choke section 2 Ttip2(i)=taowa2(i)*0.00635*P.\/sin(alphao)*tan(phif)*Ro; % compute torque generated by flight tips for choke section T_choke2(i)=L2\/P*(Tdf2(i)+Tcf2(i)+Tff2(i)+Ttip2(i)); % compute total torque in choke section 2 for flow condition end Tor totalf=(T choke 1 +T_choke2)+T_hopperf; % compute total torque for flow condition Tor_initial=T_hopperi; % compute initial torque for hopper section tao_dft=[tao_daf taodafl tao_daf2]; % axial stress in hopper, choke 1 and choke 2 % % power estimation screwspeed=[5 10 20 30 40]; for j=l:l:5 power(j)=Tor_totalf(l)*2*pi*screwspeed(j)\/60; end result=[taoxa(l) taoxla(l) taox2_a(l) taoijv Fv_i taofvO(l) FvJO(l) taofv(l) Fv_f(l) Torinitial(l) T_hopperf( 1) Tchoke 1(1) T_choke2( 1) Tor_totalf( 1)]; fprintf('The solution is \\n') fprintf('axial stress in hopper=%8.4f\\n',result(l)) fprintf('axial stressl=%8.4f\\n',result(2)) fprintf('axial stress2=%8.4f \\n',result(3)) fprintf('initial vertical stress=%8.4f \\n',result(4)) fprintf('initial feeder load=%8.4f \\n',result(5)) fprintf('vertical stress for flow condition=%8.4f \\n',result(6)) \u2022 fprintf('feeder load for flow condition=%8.4f \\n',result(7)) fprintf('modified vertical stress for flow condition=%8.4f \\n',result(8)) fprintf('modified feeder load for flow condition=%8.4f \\n',result(9)) fprintf('torque requirement for hopper in initial condition=%8.4f \\n',result(10)) fprintf('torque requirement for hopper in flow conditioh=%8.4f \\n',result(l 1)) fprintf('torque requirement for choke 1 in flow condition=%8.4f \\n',result( 12)) fprintf('torque requirement for choke 2 in flow condition=%8.4f \\n',result(13)) fprintf('torque requirement for flow condition=%8.4f \\n',result(14)) x=[5 10 20 30 40]; power2=zeros(5,2); for i=l:l:5 ; power2(i,l)=x(i); power2(i,2) =power(i); end fprintf('\\n Power requirements for 5, 10, 20 ,30 ,40 rpm is \\n'); Appendices 296 H-2: Torque prediction for sawdust-1 for 0.15 m tapered section File name: Torque_sawdust_taper6inch.m Function: taoxavel, taoxh, trailing, integrnd_Td, integrnd_Tf, taotaper Source code: see below % Hopper-screw feeder load and torque calculation for static and dynamic conditions with taper section % Screw speeds, gravity and centrifugal forces are neglected in screw torque analysis clc clear % % fixed parameters for screw feeder and hopper global P taofv muf muwt lamdas Rt Rc alphas muwh phi phif lamdasa CCC rou_bulk=212; % bulk density of bulk solid, kg\/mA3. H0=0.45; % initial bed height in hopper, m P=0.1; %pitch,m Do=0.1; % screw diameter, m Ro=Do\/2; % screw radius, m. Dc=0.030; % screw core shaft diameter, m Rc=Dc\/2; % screw core shaft radius, m Dt=0.102; % trough diameter,m Rt=Dt\/2; % trough radius, m cp=P\/Do; % ratio of pitch to screw diameter. ct=Dt\/Do; % ratio of trough diameter to screw diameter. cd=Dc\/Do; % ratio of core shaft diameter to screw diameter. Lh=0.914; % hopper outlet length,m L=0.8; % length of screw with 0.1 m screw diameter, a little shorter than outlet length, i.e. 0.914 m. Lc=0.62; B=0.102; % width of trough,m t=0.00635; % flight thiclcness,m A_cross=pi*(RoA2-RcA2); % effective cross section area of the screw casing alpha=20\/180*pi; % half hopper angle, radian . g=9.8; % gravitational acceleration, m\/sA2. alphao=atan(P\/(2*pi*Ro)); % helical angle at outside screw diameter, radian. alphac=atan(P\/(2*pi*Rc)); % helical angle at core shaft surface, radian. alphao_deg=atan(P\/(2*pi*Ro))\/pi* 180; % helical angle at outside screw diameter, degree. alphacdeg=atan(P\/(2*pi*Rc))\/pi* 180; % helical angle at core shaft surface, degree. % % variable parameters for biomass fuels and hopper-screw feeder; initial vertical stress and initial feeder load m=l; deltal_deg=38; % set effective internal friction angle, degree delta2_deg=38; delta_deg=[deltal_deg:m:delta2_deg]; % effective internal friction angle, degree. nn=(delta2_deg-delta 1 _deg).\/m+1; delta=[deltal_deg\/180*pi:m\/180*pi:delta2_deg\/180*pij; phi=31.8\/180*pi; % angle of friction between bulk solids and hopper wall (or casing surface), radian phif=31.8\/180*pi; % angle of friction between bulk solids and screw flight, radian.PE muf=tan(phif); % coefficient of friction between solids and screw flight surface muwc=muf; % friction coefficient of bulk solid on core surface muwh=tan(phi); % friction coefficient of bulk solid on hopper surface. muwt=muwh; % friction coefficient of bulk solid on trough surface. D=2*(H0+B.\/2*cot(alpha))*tan(alpha); % compute width of bulk solid free surface in hopper (flate surface), m qi=l\/(2*tan(alpha))*(D\/B-l); % compute non-dimensional surcharge factor for initial condition taoi_v=qi*rou_bulk*g*B; % compute vertical stress at hopper outlet for initial condition Fv_i=taoi_v*Lh*B; % compute feeder load at hopper outlet for initial condition % \u2014 Appendices 297 % vertical stress and feeder load for flow condition fori=l:l:nn mud(i)=tan(delta(i)); % effective coefficient of internal friction. mue(i)=sin(delta(i)); % equivalent friction coefficient of bulk solid,.from Roberts %lamdas(i)=l\/(l+2*mud(i)A2+2*((l+mud(i)A2)*(mud(i)A2-muwtA2))A0.5); % stress ratio of normal stress acting perpendicularly to wall % of trough and core shaft surfaces to axial compression stress % derived from Mohr circle alpha_Mohr(i)=(asin(sin(phi)\/sin(delta(i)))-phi)\/2; lamdas(i)=cos(phi)*sin(2*alpha_Mohr(i))\/(sin(phi)*cos(2*alpha_Mohr(i))+sin(phi+2*alpha_Mohr(i))); % stress ratio of normal stress acting perpendicularly to wall % of trough and core shaft surfaces to axial compression stress % derived from Mohr circle beta(i)=0.5*(phi+asin(sin(phi)\/sin(delta(i)))); % compute beta(i), constant X(i)=sin(delta(i))\/(l-sin(delta(i)))*(sin(2*beta(i)+alpha)\/sin(alpha)+l); % constant to compute feeder load Y(i)=((alpha+beta(i))*sin(alpha)+sin(beta(i))*sin(alpha+beta(i))).\/((l-sin(delta(i)))*sin(alpha+beta(i)).A2); % constant to compute feeder load qf(i)=Y(i)*(l+sin(delta(i)))\/(2f(X(i)-l)*sin(alpha)); % surcharge factor for flow conditions taof_vO(i)=qf(i)*rou_bulk*g*B; % use average bulk density for compressible solids in the present study Fv_fO(i)=taof_vO(i).*Lh.*B; % vertical stress and feeder load for flow condition taof_v(i)=(taof_v0(i)+taoi_v).\/2; % average vertical stress for flow condition Fv_f(i)=taof_v(i).*Lh.*B; % average feeder load for flow condition end % . . . % hopper section, for a material element in a pitch first then entire hopper section n=1.0; eps=le-4; a=0; while abs(0.99-a) > eps for i=l:l:nn taoxamax(i)=n*taof_v(i)*(exp(2*tan(phi)*lamdas(i)*P\/(Rt-Rc))); % maximum stress at driving side of flight according to stress analysis taoxamin(i)=n*taof_v(i); % minimum stress at trailing side of flight according to stress analysis lamdas_a=lamdas(i); % stress ratio of normal wall stress to axial stress on confined surface taoxa(i)=l\/P*n*taof_v(i)*quadl(@taoxh, 0,P); % average axial stress in a pitch for flow condition taoxai(i)=l\/P*n*taoi_v*quadl(@taoxh, 0,P); % average axial stress in a pitch for initial condition taowa(i)=lamdas(i)*taoxa(i); % average normal wall stress in a pitch for flow condition taowai(i)=lamdas(i)*taoxai(i); % average normal wall stress in a pitch for initial condition %-1. shear surface ksa(i)=pi*mue(i)*cp*cos(alphao+phif).\/2; % parameter for axial force calculations on shear surface Fsaf(i)=-ksa(i).*taof_v(i).*Do.A2; % axial force on shear surface for flow condition Fsai(i)=-ksa(i)*taoi_v*DoA2; % axial force on shear surface for initial condition kst(i)=pi*mue(i)*cp*sin(alphao+phif).\/2; % parameter for tangential force calculations on shear surface Fstf(i)=-kst(i).*taof_v(i)*DoA2; % tangential force on shear surface for flow condition Fsti(i)=-kst(i)*taoi_v*DoA2; % tangential force on shear surface for initial condition Fstfp_try(i)=l\/2*(taof_v(i)+taowa(i))*t*P\/sin(alphao)*tan(phifj; % tangential force from flight tips for flow condition Fstip_try(i)=l\/2*(taoi_v(i)+taowai(i))*t*P\/sin(alphao)*tan(phif); % tangential force from flight tips for initial condition Tstfp(i)=Fstfp_try(i)*Ro; % torque from flight tips for flow condition Tstip(i)=Fstip_try(i)*Ro; % torque from flight tips for initial condition %-2. core shaft Appendices 298 kca(i)=n*pi*(ct-cd)*cd*cp*(exp(4*m % parameter for axial force calculations on core shaft surface Fcaf(i)=-kca(i)*taof_v(i)*DoA2; % axial force on core surface for flow condition Fcai(i)=-kca(i)*taoi_v*DoA2; % axial force on core surface for initial condition Fcal_try(i)=2*pi*Rc*P*tan(phif)*taowa(i)*sin(alphac); % axial force on core surface for flow condition kct(i)=n*piA2*(ct-cd)*cdA2*(exp(4*muwc*lamdas(i)*cp\/(ct-cd))-l)\/4\/(cpA2+piA2*cdA2)A0.5; % parameter for tangential force calculations on core shaft surface Fctf(i)=kct(i)*taof_v(i)*DoA2; % tangential force on core.surface for flow condition Fcti(i)=kct(i)*taoiv*DoA2; % tangential force on core surface for initial condition Fctl_try(i)=2*pi*Rc*P*tan(phif)*taowa(i)*cos(alphac); % tangential force on core surface for flow condition %-3. trailing flight side kfa(i)=n*lamdas(i)*(pi*( 1-cdA2)\/4+cp*muf*( 1-cd)\/2); % parameter for axial force calculations on trailing side surface Ffaf(i)=-kfa(i)*taof_v(i)*DoA2; % axial force on trailing side surface for flow condition Ffai(i)=-kfa(i)*taoi_v*DoA2; % axialforce on trailing side surface for,initial condition Ffafl_try(i)=2.*pi.*lamdas(i).*taoxamin(i).*quadl(@trailing, Rc, Ro); kft(i)=n*lamdas(i)*(pi*muP(l-cdA2)\/4-cp*(l-cd)\/2); % parameter for tangential force calculations on trailing side surface Fftf(i)=kft(i)*taof_v(i)*DoA2; % tangential force on trailing side surface for flow-condition Ffti(i)=kft(i)*ta6i_v*DoA2; % tangential force on trailing side surface for initial condition %-4. trough surface kta(i)=n*pi*(ct-cd)*ct*cos(alphao+phif)\/8*(exp(4*muwt*lamdas(i)*cp\/(ct-cd))-l); % parameter for axial force calculations on trough surface Ftaf(i)=-kta(i).*taof_v(i).*Do.A2; % axial force on trough surface for flow condition Ftai(i)=-kta(i)*taoi_v*DoA2; % axial force on trough surface for initial condition Ftaf_try(i)=pi*Rt*P*tan(phi)*cos(alphao+phif)*taowa(i); % axial force on trough surface for flow condition ktt(i)=n*pi*(ct-cd)*ct*sin(alphao+phif)\/8*(exp(4*muwt*lamdas(i)*cp\/(ct-cd))-l); % parameter for tangential force calculations on trough surface Fttf(i)=-ktt(i)*taof_v(i)*DoA2; % tangential force on trough surface for flow condition Ftti(i)=-ktt(i)*taoi_v*DoA2; % tangential force on trough surface for initial condition %-5. stress on driving side Kda(i)=4*(ksa(i)+kca(i)+kfa(i)+kta(i))\/pi\/(l-cdA2); % parameter for axial force calculations on driving side surface tao_daf(i)=Kda(i)*taof_v(i); % compute axial stress on driving surface for flow condition tao_dai(i)=Kda(i)*taoi_v; % compute axial stress on driving surface for initial condition Ftao_daf(i)=tao_daf(i)*A_cross; % compute axial force on driving surface for flow condition Ftao_dai(i)=tao_dai(i)*A_cross; % compute axial force on driving surface for initial condition % torque calculation Tdf(i)=2*pi*tao_daf(i)*quadl(@integrnd_Td, Rc, Ro); % compute torque generated by driving side of screw for flow condition Tdi(i)=2*pi*tao_dai(i)*quadl(@integrnd_Td, Rc, Ro); % compute torque generated by driving side of screw for initial condition Tcf(i)=2*pi*Rc*P*taowa(i)*tan(phif)*cos(alphac)*Rc;; % compute torque generated by core shaft surface for flow condition Tci(i)=2*pi*Rc*P*taowai(i)*tan(phif)*cos(alphac)*Rc; % compute torque generated by core shaft surface for initial condition Tff(i)=2*pi*lamdas(i)*n*taof_v(i)*quadl(@integrnd_Tf, Rc, Ro); % compute torque from trough surface for flow condition Tfi(i)=2*pi*lamdas(i)*n*taoi_v*quadl(@integrnd_Tf, Rc, Ro); % compute torque from trough surface for initial condition T_hopperf(i)=Lh\/P*(Tdf(i)+Tcf(i)+Tff(i)+Tstfp(i)); % compute total torque in hopper section for flow condition Appendices 299 T_hopperi(i)=Lh\/P*(Tdi(i)+Tci(i)+Tfi(i)+Tstip(i)); % compute total torque in hopper section for initial condition ratioO 1 (i)=tao_daf(i)\/taoxamax(i); % ratio of stress on driving side to theoretical maximum stress in a pitch ratio02(i)=taoxa(i)\/tao_daf(i); % ratio of average axial stress to stress on driving side in a pitch end a=ratio02(l); % ratio of average axial stress to stress on driving side n=n+0.0001; % 0.0001 as increment for t end n=n-0.0001; % . % Choke section-0.9 m screw diameter P=0.1; %pitch,m Do=0.09; % screw diameter, m Ro=Do\/2; % screw radius, m. Dc=0.030; % screw core shaft diameter, m Rc=Dc\/2; % screw core shaft radius, m Dt=0.102; % trough diameter,m Rt=Dt\/2; % trough radius, m cp=P\/Do; % ratio of pitch to screw diameter. ct=Dt\/Do; % ratio of trough diameter to screw diameter. cd=Dc\/Do; % ratio of core shaft diameter to screw diameter. Across=pi*(RoA2-RcA2) % effective cross section area of the screw casing LI =0.2; % length of the screw with 0.1 m screw diameter. alphao=atan(P\/(2*pi*Ro)); % helical angle at the outside screw diameter, radian. alphac=atan(P\/(2*pi*Rc)); % helical angle at the core shaft surface, radian. alphao_deg=atan(P\/(2*pi*Ro))\/pi* 180; % helical angle at the outside screw diameter, degree. a!phac_deg=atan(P\/(2*pi*Rc))\/pi* 180; % helical angle at the core shaft surface, degree. % torque calculation for i=l:l:nn con=0.8; % constant for estimating axial stress in choke section e=0.2 CC 1 (i)=con*(qf(i)* HO\/Dt* Lc\/Dt\/ct)A(e); % exponent to estimate axial stress on trailing side of a flight taoxam 1 (i)=n*taof_v(i)*(exp(2*tan(phi)*lamdas(i)*P\/(Rt-Rc))).A(CC 1 (i)+1); % stress on driving side of a flight taoxamll(i)=n*taof_v(i)*(exp(2*tan(phi)*lamdas(i)*P\/(Rt-Rc))).A(CCl(i)); % stress on trailing side of a flight EEl(i)=(exp(2*tan(phi)*lamdas(i)*P\/(Rt-Rc))) A(CCl(i)); % how many times for stress on trailing side compared to vertical stress % for flow condition, compaction ration in choke section lamdas_a=lamdas(i); % compute lamdas for function taoxave 1 CCC=CC l(i); % compute CC 1 for function taoxave 1 taoxl_a(i)=l\/P*n*taof_v(i)*quadl(@taoxavel, 0,P); % average axial stress in choke section taowal(i)=lamdas(i)*taoxl a(i); % average normal wall stress in choke section Fcal(i)=2*pi*Rc*P*tan(phif)*taowal(i)*sin(alphac); % axial force on core surface in choke section Ffafl(i)=2.*pi.*lamdas(i).*taoxaml l(i).*quadl(@trailing, Rc, Ro); % axial force on trailing side surface in choke section Ftafl(i)=2*pi*tan(phi)*taowal(i)*Rt*P*cos(alphao+phif); % axial force on trough surface in choke section Fdafl(i)=Fcal(i)+Ffafl(i)+Ftafl(i); % axial force on driving side surface in choke section tao_dafl(i)=Fdafl(i).\/pi.\/(RoA2-RcA2); % compute axial stress on the driving surface for flow condition in choke section Appendices 300 Tdfl(i)=2*pi*tao_dafl(i)*quadl(@integrnd_Td, Rc, Ro); % compute the torque generated by driving side surface for choke section 1 Tcfl(i)=taowal(i)*2*pi*Rc*P*tan(phif)*Rc*cos(alphac); % compute the torque generated by trailing side surface for choke section 1 Tffl(i)=2*pi*lamdas(i)*taoxaml l(i)*quadl(@integrnd_Tf, Rc, Ro); % compute the torque generated by trough side surface for choke section 1 Ttipl(i)=taowal(i)*0.00635*P.\/sin(alphao)*tan(phiO*Ro; ratio_choke 1 (i)=taox l_a(i)\/tao_daf 1 (i); Tchoke 1 (i)=L 1 \/P*(Tdfl (i)+Tcf 1 (i)+Tff 1 (i)+Ttip 1 (i)); % compute total torque in choke section 1 for flow condition end % % Choke section-taper section and 0.8 m screw diameter P=0.1; % pitch.m Do=0.08; % screw diameter, m Ro=Do\/2; % screw radius, m. Dc=0.030; % screw core shaft diameter, m Rc=Dc\/2; % screw core shaft radius, m Dt=0.102; % trough diameter,m Rt=Dt\/2; % trough radius, m cp=P\/Do; % ratio of pitch to screw diameter. ct=Dt\/Do; % ratio of trough diameter to screw diameter. cd=Dc\/Do; % ratio of core shaft diameter to screw diameter. A_cross=pi*(RoA2-RcA2) % effective cross section area of the screw casing alphao=atan(P\/(2*pi*Ro)); % helic angle at the outside screw diameter, radian. alphac=atan(P\/(2*pi*Rc)); % helic angle at the core shaft surface, radian. alphao_deg=atan(P\/(2*pi*Ro))\/pi* 180; % helic angle at the outside screw diameter, degree. alphac_deg=atan(P\/(2*pi*Rc))\/pi* 180; % helic angle at the core shaft surface, degree. % % taper section global Ef Httf taoinf Taperinch=6; % length of taper section, inch LLt=Taperinch*0.0254; % length of taper section, m alphat=atan((Rt-0.044)\/LLt) % half angle of taper section, radian Ht0=0.044\/tan(alphat); % length from apex of taper section to discharge outlet of screw feeder Htt=Rt\/tan(alphat); % length from apex of taper section to starting point of taper section mm=0.01; % incremental distance along screw axis from HtO to Htt xt=[Ht0:mm:Htt]; % array of distance along screw axis number=floor((Htt-Ht0)\/mm+l); % number of array data for i=l:l:nn EE(i)=-2*(l-lamdas(i)-lamdas(i)*tan(phi).\/tan(alphat)); % exponent in relation of axial stress and axial position in choke section; T_choke_tapersum=0; % set Tchoketapersum equal to 0 v=ceil(Taperinch\/4); % number of pitch (including the second half pitch) h = zeros(l,v); % iteration times taoxt_aa=80000; % initial stress value s=[22000 81000]; % stress calculated from stress-bulk density relation for pitch-1 and half pitch-2 in taper section for j=l:v-l taoin(j)=s(j)*2.8; % initial stress value for stress at the beginning of each pitch in taper section Ht01(j)=Htt-j*P; % axial position of trailing side of flight for each pitch in taper section Httl(j)=Ht01(j)+P; % axial position of driving side of flight for each pitch in taper section Appendices 301 while abs(taoxt_aa-s(j))>50 Ef=EE(i); % exponent in relation of axial stress and axial position in choke section; Httf=Httl(j); % axial position of driving side of flight for each pitch in taper section taoinf=taoin(j); % initial stress value for stress at the beginning (driving side) of each pitch in taper section taoxt_a(i,j)= 1 .\/P*quadl(@taotaper, HtO 1 (j), Httftj)); % average axial stress in each pitch in taper section taowt_a(i,j)=lamdas(i)*taoxt a(i,j); % average normal stress in each pitch in taper section taoxt_aa=taox ta(ij); % adjust initial stress taoin(j)=taoin(j)-5; % adjust maximum stress in the second half pitch h(j)=h(j)+l; % iteration times end taox _aa=80000; % restore initial value end forj=l:v-l xtl=[Ht01(j):mjm:Httl(j)]; % array of distance'along'screw axis numberlO)=floor((Httl(j)-Ht01(j))\/mm+l); % number of array data for m=l:l: numberl(j) taoxt(j,m)=(xtl(m).\/Httl(j)).A(Ef)*taoinO'); % stress distribution in a pitch end end % % torque calculation for taper section - . forj=l:v-l Fcataperl(ij)=2*pi*Rc*P*tan(phi)*taowt_a(ij)*sin(alphac); % axial force on core surface in choke section Ffaftaperl(i,j)=2*pi*lamdas(i)*taoxt(j,l)*quadl(@trailing, Rc, Ro); % axial force on trailing side surface in choke section Ftaftaperl(i,j)=tan(phi)*taowt_a(ij)*2*pi*Rt*P+taowt_a(ij)*2*pi*Rt*P*tan(alphat); % axial force on trough surface in choke section Fdaftaper 1 (i j)=Fcataper 1 (i,j)+Ffaftaper 1 (i j)+Ftaftaper I (ij); % axial force on driving side surface in choke section tao_daftaperl(i,j)=Fdaftaperl(i,j).\/pi.\/(RoA2-RcA2);; % compute axial stress on the driving surface in choke section Tdtaperl(ij)=2*pi*tao_daftaperl(ij)*quadl(@integmd_Td, Rc, Ro); % compute torque generated by driving side of screw for flow condition Tcftaperl(ij)=2*pi*tan(phi)*taow t_a(ij)*Rc*Rc*P*cos(a!phac); % compute torque generated by core shaft surface for flow condition Tfftaperl(ij)=2*pi*lamdas(i)*taoxt(j, 1 )*quadl(@integrnd_Tf, Rc, Ro); % compute torque generated by core shaft surface for flow condition Ttiptaperl(ij)=taowt_a(ij)*0.00635*P\/sin(alphao)*tan(phi0*Ro; % compute torque generated by flight tips for flow condition T_choketaperl(i,j)=(Tdtaperl(i,j)+Tcftaperl(i,j)+Tfftaperl(i,j)+Ttiptaperl(i,j)); % compute total torque in hopper section for flow condition T_choke_tapersum=T_choke_tapersum+T_cKoke_taper 1 (ij); % torque generated by each pitch in taper section end T_choke_tapertt 1 (i)=T_choke_tapersum; % % for 0.15 m taper section-second half pitch taper section HtO 1 (v)=Htt-(v-0.5)*P; % axial position of taper section outlet Httl(v)=Ht01(v)+(0.5)*P; % axial position of the last second half pitch in taper section taoin(v)=s(v)*3.8; % initial stress value for stress at the beginning of each pitch in taper section taoxt_aa=80000; % initial stress value while abs(taoxt_aa-s(v))>50 Ef=EE(i); % exponent in relation of axial stress and axial position in choke section; Appendices 302 Httf=Httl(v); % axial position of the last second half pitch in taper section taoinf=taoin(v); taoxt_a(i,v)=2.\/P*quadl(@taotaper, Ht01(v), Httl(v)); % average axial stress in the second half pitch taowt_a(i,v)=lamdas(i)*taoxt_a(i,v); % average normal wall stress in the second half pitch taoxt_aa=taoxt_a(i,v); % adjust initial stress taoin(v)=taoin(v)-5; % adjust maximum stress in the second half pitch h(v)=h(v)+l; % iteration times end Fcataperl(i,v)=2*pi*Rc*P\/2*tan(phi)*taowt_a(i,v)*sin(alphac); % axial force on core surface in choke section Ftaftaperl(i,v)=tan(phi)*taowt_a(i,v)*2*pi*Rt*P\/2+taowt_a(i,v)*2*pi*Rt*P\/2*tan(alphat); % axial force on trough surface in choke section Fdaftaper 1 (i, v)=Fcataper 1 (i, v)+Ftaftaper 1 (i,v); % axial force on driving side surface in choke section tao_daftaper 1 (i, v)=Fdaftaper 1 (i, v).\/pi.\/(RoA2-RcA2);; % compute axial stress on driving surface in choke section Tdtaperl(i,v)=2*pi*tao daftaperl(i,v)*quadl(@integrnd_Td, Rc, Ro); % compute torque generated by driving side of screw for flow condition Tcftaperl(i,v)=2*pi*tan(phi)*taowt_a(i,v)*Rc*Rc*P\/2*cos(alphac); % compute torque generated by core shaft surface for flow condition Ttiptaperl(i,v)=taowt_a(i,v)*0.00635*P\/2\/sin(alphao)*tan(phif)*Ro; % compute torque generated by flight tips for flow condition T_choke_taperl(i,v)=(Tdtaperl(i,v)+Tcftaperl(i,v)+Ttiptaperl(i,v)); % compute total torque in hopper section for flow condition T_choke_tapertt2(i)=T choke_taperl(i,v); ' % torque generated by the second half pitch T_choke_tapert(i)=T_choke_tapertt 1 (i)+T_choke_tapertt2(i); % torque generated by taper section end % . . % Choke section-0.8 m screw diameter L2=0.42-LLt; % the length of the screw with 0.1 m screw diameter. % torque calculation fori=l:l:nn CC2(i)=con*(qf(i)*H0\/Dt*Lc\/Dt\/ct)A(e); % exponent to estimate axial stress on trailing side of a flight taoxam2(i)=n*taof_v(i)*(exp(2*tan(phi)*lamdas(i)*P\/(Rt-Rc)))A(CC2(i)+l); % theoretical maximum stress in a pitch taoxam22(i)=n*taof_v(i)*exp(2*tan(phi)*lamdas(i)*P\/(Rt-Rc))A(CC2(i)); % theoretical minimum stress in a pitch EE2(i)=(exp(2*tan(phi)*lamdas(i)*P\/(Rt-Rc))).A(CC2(i)); % how many times for stress on trailing side compared to vertical stress in hopper % for flow condition, compression factor in choke section lamdas_a=lamdas(i); % compute lamdas for function taoxavel CCC=CC2(i); % compute CC2 for function taoxave 1 taox2_a(i)=l\/P*n*taof_v(i)*quadl(@taoxavel, 0,P); % average axial stress in choke section taowa2(i)=lamdas(i)*taox2_a(i); % average normal wall stress in choke section Fca2(i)=2*pi*Rc*P*tan(phi)*taowa2(i)*sin(alphac); % axial force on core surface in choke section Ffaf2(i)=2*pi*lamdas(i)*taoxam22(i)*quadl(@trailing, Rc, Ro); % axial force on trailing side surface in choke section Ftaf2(i)=2*pi*tan(phi)*taowa2(i)*Rt*P*cos(alphao+phiO; % axial force on trough surface in choke section Fdaf2(i)=Fca2(i)+Ffaf2(i)+Ftaf2(i); % axial force on driving side surface in choke section tao_daf2(i)=Fdaf2(i).\/pi.\/(RoA2-RcA2);; % compute axial stress on driving surface in choke section Tdf2(i)=2*pi*tao_daf2(i)*quadl(@integrnd_Td, Rc, Ro); Appendices % compute torque generated by driving side surface for choke section 2 TcO(i)=taowa2(i)*2*pi*Rc*P*tan(phif)*Rc*cos(alphac); % compute torque generated by core shaft surface for choke section 2 Tff2(i)=2*pi*lamdas(i)*taoxam22(i)*quadl(@integrnd_Tf, Rc, Ro); % compute torque generated by trailing side surface for choke section 2 Ttip2(i)=taowa2(i)*0.00635*P\/sin(alphao)*tan(phif)*Ro; % compute torque generated by flight tips surface for choke section 2 ratio_choke2(i)=taox2_a(i)\/tao_daf2(i); % ratio of average stress to stress on the driving side of flight T_choke2(i)=L2\/P*(Tdf2(i)+Tcf2(i)+Tff2(i)+Ttip2(i)); % compute total torque in choke section 2 for flow condition end % Tor_totalf=T_choke 1 +T_choke2+T_hopperf+T_choke_tapert; % compute total torque for flow condition Tor_initial=TJiopperi; % compute initial torque for hopper section % power estimation screwspeed=[5 10 20 30 40]; forj=l:l:5 po wer(j )=Tor_totalf( 1 )*2 * pi * sere wspeed(j )\/60; end \u2022 \" ' result=[taoxa(l) taoxla(l) taox2_a(l) taoiv F v i taofvO(l) FvJO(l) taofv(l) Fv_f(l) Torinitial(l) T_hopperf( 1) Tchoke 1(1) T_choke2( 1) T_choke_tapert( 1) Tor_totalf( 1)]; fprintf(The solution is \\n') fprintf('axial stress in hopper=%8.4f \\n',result(l)) fprintf('axial stress 1 =%8.4f \\n',result(2)) fprintf('axial stress2=%8.4f \\n',result(3)) fprintf('initial vertical stress=%8.4f \\n',result(4)) fprintf('initial feeder load=%8.4f \\n',result(5)) fprintf('vertical stress for flow condition=%8.4f \\n',result(6)) fprintf('feeder load for flow condition=%8.4f \\n',result(7)) fprintf('modified vertical stress for flow condition=%8.4f \\n',result(8)) fprintf('modified feeder load for flow condition=%8.4f \\n',result(9)) fprintf('torque requirement for hopper in initial condition=%8.4f \\n',result(10)) fprintf('torque requirement for hopper in flow condition=%8.4f \\n',result(l 1)) tprintf('torque requirement for choke 1 in flow condition=%8.4f \\n',result( 12)) fprintf('torque requirement for choke 2 in flow condition=%8.4f \\n',result(13)) fprintf('torque requirement for 12\" taper section=%8.4f \\n',result(14)); fprintf('torque requirement for flow condition=%8.4f \\n',result(15)) Appendices H-3: Torque prediction for sawdust-1 for 0.3 m tapered section File name: Torque_sawdust_taperl2inch.m Function: taoxave 1, taoxh, trailing, integrndTd, integrndTf, taotaper Source code: see below % Hopper-screw feeder load and torque calculation for static and dynamic conditions with taper section % Screw speeds, gravity and centrifugal forces are neglected in screw torque analysis clc clear % -% fixed parameters for screw feeder and hopper global P taofv muf muwt lamdas Rt Rc alphas muwh phi phif lamdasa CCC rou_bulk=212; % bulk density of bulk solid, kg\/mA3. H0=0.45; % initial bed height in hopper, m P=0.1; %pitch,m Do=0.1; % screw diameter, m Ro=Do\/2; % screw radius, m. Dc=0.030; % screw core shaft diameter, m Rc=Dc\/2; % screw core shaft radius, m Dt=0.102; % trough diameter,m , ;. Rt=Dt\/2; % trough radius, m cp=P\/Do; % ratio of pitch to screw diameter. ct=Dt\/Do; % ratio of trough diameter to screw diameter. cd=Dc\/Do; % ratio of core shaft diameter to screw diameter. Lh=0.914; % hopper outlet length,m L=0.8; % length of screw with 0.1 m screw diameter, a little shorter than outlet length, i.e. 0.914 n Lc=0.62; B=0.102; % width of trough,m t=0.00635; % flight thickness,m A_cross=pi*(RoA2-RcA2); % effective cross section area of the screw casing alpha=20\/180*pi; % half hopper angle, radian g=9.8; % gravitational acceleration, m\/sA2. alphao=atan(P\/(2*pi*Ro)); % helical angle at outside screw diameter, radian. alphac=atan(P\/(2*pi*Rc)); % helical angle at core shaft surface, radian. alphao_deg=atan(P\/(2*pi*Ro))\/pi* 180; % helical angle at outside screw diameter, degree, alphac_deg=atan(P\/(2*pi*Rc))\/pi* 180; % helical angle at core shaft surface, degree. % . % variable parameters for biomass fuels and hopper-screw feeder; initial vertical stress and initial feeder load m=l; deltal_deg=38; % set effective internal friction angle, degree delta2_deg=38; delta_deg=[deltal_deg:m:delta2_deg]; % effective internal friction angle, degree. nn=(delta2_deg-de Ita 1 deg) .\/m+1; delta=[deltal_deg\/180*pi:m\/180*pi:delta2_deg\/180*pi]; phi=31.8\/180*pi; % angle of friction between bulk solids and hopper wall (or casing surface), radian phif=31.8\/180*pi; % angle of friction between bulk solids and screw flight, radian.PE muf=tan(phif); % coefficient of friction between solids and screw flight surface muwc=muf; % friction coefficient of bulk solid on core surface muwh=tan(phi); % friction coefficient of bulk solid on hopper surface. muwt=muwh; % friction coefficient of bulk solid on trough surface. D=2*(H0+B.\/2*cot(alpha))*tan(alpha); % compute width of bulk solid free surface in hopper (flate surface), m qi=l\/(2*tan(alpha))*(D\/B-l); % compute non-dimensional surcharge factor for initial condition taoi_v=qi*rou_bulk*g*B; % compute vertical stress at hopper outlet for initial condition Fv_i=taoi v*Lh*B; % compute feeder load at hopper outlet for initial condition % Appendices 305 % vertical stress and feeder load for flow condition fori=l:l:nn mud(i)=tan(delta(i)); % effective coefficient of internal friction. mue(i)=sin(delta(i)); % equivalent friction coefficient of bulk solid,.from Roberts %lamdas(i)=l\/(l+2*mud(i)A2+2*((l+mud(i)A2)*(mud(i)A2-muwtA2))A0.5); % stress ratio of normal stress acting perpendicularly to wall % of trough and core shaft surfaces to axial compression stress, derived from Mohr circle alpha_Mohr(i)=(asin(sin(phi)\/sin(delta(i)))-phi)\/2; lamdas(i)=cos(phi)*sin(2*alpha_Mohr(i))\/(sin(phi)*cos(2*alpha_Mohr(i))+sin(phi+2*alpha_Mohr(i))); % stress ratio of normal stress acting perpendicularly to wall % of trough and core shaft surfaces to axial compression stress % derived from Mohr circle beta(i)=0.5*(phi+asin(sin(phi)\/sin(delta(i)))); % compute beta(i), constant X(i)=sin(delta(i))\/(l-sin(delta(i)))*(sin(2*beta(i)+alpha)\/sin(alpha)+l); % constant to compute feeder load Y(i)K(alpha+beta(i))*sin(alpha)+sin(beta(0^ % constant to compute feeder load qf(i)=Y(i)*(l+sin(delta(i)))\/(2*(X(i)-l)*sin(alpha)); % surcharge factor for flow conditions %qfl(i)=l\/4*(l\/tan(alpha))*(Y(i)*(l+sin(delta(i))*cos(2*beta(0))*(tan(alpha)+tan(phi))\/sin(alpha)\/(X(i)-^ % smaller than the above one taof_vO(i)=qf(i)*rou_bulk*g*B; % use average bulk density for compressible solids in the present study Fv_fD(i)=taof_vO(i).*Lh.*B; % vertical stress and feeder load for flow condition taof_v(i)=(taof_v0(i)+taoi_v).\/2; % average vertical stress for flow condition Fv_f(i)=taof_v(i).*Lh.*B; % average feeder load for flow condition end % % hopper section, for a material element in a pitch first then entire hopper section n=1.0; eps=le-4; a=0; while abs(0.99-a) > eps for i=l:l:nn taoxamax(i)=n*taof_v(i)*(exp(2*tan(phi)*lamdas(i)*P\/(Rt-Rc))); % maximum stress at driving side of flight according to stress analysis taoxamin(i)=n*taof_v(i); % minimum stress at trailing side of flight according to stress analysis lamdas_a=lamdas(i); % stress ratio of normal wall stress to axial stress on confined surface taoxa(i)=l\/P*n*taof_v(i)*quadl(@taoxh, 0,P); % average axial stress in a pitch for flow condition taoxai(i)=l\/P*n*taoi_v*quadl(@taoxh, 0,P); % average axial stress in a pitch for initial condition taowa(i)=lamdas(i)*taoxa(i); % average normal wall stress in a pitch for flow condition taowai(i)=lamdas(i)*taoxai(i); % average normal wall stress in a pitch for initial condition %-1. shear surface ksa(i)=pi*mue(i)*cp*cos(alphao+phif).\/2; % parameter for axial force calculations on shear surface Fsaf(i)=-ksa(i).*taof_v(i).*Do.A2; % axial force on shear surface for flow condition Fsai(i)=-ksa(i)*taoi v*DoA2; % axial force on shear surface for initial condition kst(i)=pi*mue(i)*cp*sin(alphao+phif).\/2; % parameter for tangential force calculations oh shear surface Fstf(i)=-kst(i).*taofv(i)*DoA2; % tangential force on shear surface for flow condition Fsti(i)=-kst(i)*taoi_v*DoA2; % tangential force on shear surface for initial condition Fstfp_try(i)=l\/2*(taof_v(i)+taowa(i))*t*P\/sin(alphao)*tan(phif); % tangential force from flight tips for flow condition Fstip_try(i)=l\/2*(taoiv(i)+taowai(i))*t*P\/sin(alphao)*tan(phif); % tangential force from flight tips for initial condition Tstfp(i)=Fstfp_try(i)*Ro; % torque from flight tips for flow condition Tstip(i)=FstipJry(i)*Ro; % torque from flight tips for initial condition Appendices %-2. core shaft kca(i)=n*pi*(ct-cd)*cd*cp*(exp(4*muwc*lamdas(i)*cp\/(ct-cd))-l)\/4\/(cpA2+piA2*cdA2)A0.5; % parameter for axial force calculations on core shaft surface Fcaf(i)=-kca(i)*taof_v(i)*DoA2; % axial force on core surface for flow condition Fcai(i)=-kca(i)*taoi_v*DoA2; % axial force on core surface for initial condition Fcal_try(i)=2*pi*Rc*P*tan(phif)*taowa(i)*sin(alphac); % axial force on core surface for flow condition kct(i)=n*piA2*(ct-cd)*cdA2*(exp(4*muwc*lamdas(i)*cp\/(ct-cd))-l)\/4\/(cpA2+piA2*cdA2)A0.5; % parameter for tangential force calculations on core shaft surface Fctf(i)=kct(i)*taof_v(i)*DoA2; % tangential force on core surface for flow condition Fcti(i)=kct(i)*taoi_v*DoA2; . % tangential force on core surface for initial condition Fctl_try(i)=2*pi*Rc*P*tan(phif)*taowa(i)*cos(alphac); % tangential force on core surface for flow condition %-3. trailing flight side kfa(i)=n*lamdas(i)*(pi*(l-cdA2)\/4+cp*muf*(l-cd)\/2); % parameter for axial force calculations on trailing side surface Ffaf(i)=-kfa(i)*taof_v(i)*DoA2; % axial force on trailing side surface for flow condition Ffai(i)=-kfa(i)*taoi_v*DoA2; % axial force on trailing side surface for initial condition Ffafl_try(i)=2.*pi.*lamdas(i).*taoxamin(i).*quadl(@trailing, Rc, Ro); kft(i)=n*lamdas(i)*(pi*muf*(l-cdA2)\/4-cp*(l-cd)\/2); % parameter for tangential force calculations on trailing side surface Fftf(i)=kft(i)*taof_v(i)*DoA2; % tangential force on trailing side surface for flow condition Ffti(i)=kft(i)*tao i_v*DoA2; % tangential force on trailing side surface for initial condition %-4. trough surface kta(i)=n*pi*(ct-cd)*ct*cos(alphao+phif)\/8*(exp(4*muwt*lamdas(i)*cp\/(ct-cd))-l); % parameter for axial force calculations on trough surface Ftaf(i)=-kta(i).*taof_v(i).*Do.A2; % axial force on trough surface for flow condition Ftai(i)=-kta(i)*taoi_v*DoA2; % axial force on trough surface for initial condition Ftaf_try(i)=pi*Rt*P*tan(phi)*cos(alphao+phif)*taowa(i); % axial force on trough surface for flow condition ktt(i)=n*pi*(ct-cd)*ct*sin(alphao+phi0\/8*(exp(4*muwt*lamdas(i)*cp\/(ct-cd))-l); % parameter for tangential force calculations on trough surface Fttf(i)=-ktt(i)*taof_v(i)*DoA2; % tangential force on trough surface for flow condition Ftti(i)=-ktt(i)*taoi_v*DoA2; % tangential force on trough surface for initial condition %-5. stress on driving side Kda(i)=4*(ksa(i)+kca(i)+kfa(i)+kta(i))\/pi\/(l-cdA2); % parameter for axial force calculations on driving side surface tao_daf(i)=Kda(i)*taof_v(i); % compute axial stress on driving surface for flow condition tao_dai(i)=Kda(i)*taoi_v; % compute axial stress on driving surface for initial condition Ftao_daf(i)=tao_daf(i)*A_cross; % compute axial force on driving surface for flow condition Ftao_dai(i)=tao_dai(i)*A_cross; % compute axial force on driving surface for initial condition % torque calculation Tdf(i)=2*pi*tao_daf(i)*quadl(@integrnd_Td, Rc, Ro); % compute torque generated by driving side of screw for flow condition Tdi(i)=2*pi*tao_dai(i)*quadl(@integrnd_Td, Rc, Ro); % compute torque generated by driving side of screw for initial condition Tcf(i)=2*pi*Rc*P*taowa(i)*tan(phif)*cos(alphac)*Rc;; % compute torque generated by core shaft surface for flow condition Tci(i)=2*pi*Rc*P*taowai(i)*tan(phif)*cos(alphac)*Rc; % compute torque generated by core shaft surface for initial condition Tff(i)=2*pi*lamdas(i)*n*taof_v(i)*quadl(@integrnd_Tf, Rc, Ro); % compute torque from trough surface for flow condition Tfi(i)=2*pi*lamdas(i)*n*taoi_v*quadl(@integrnd_Tf, Rc, Ro); % compute torque from trough surface for initial condition T_hopperf(i)=Lh\/P*(Tdf(i)+Tcf(i)+Tff(i)+Tstfp(i)); Appendices 307 % compute total torque in hopper section for flow condition T_hopperi(i)=Lh\/P*(Tdi(i)+Tci(i)+Tfi(i)+Tstip(i)); % compute total torque in hopper section for initial condition ratioO 1 (i)=tao_daf(i)\/taoxamax(i); % ratio of stress on driving side to theoretical maximum stress in a pitch ratio02(i)=taoxa(i)\/tao_daf(i); % ratio of average axial stress to stress on driving side in a pitch end a=ratio02(l); % ratio of average axial stress to stress on driving side n=n+0.0001; % 0.0001 as increment for t end n=n-0.0001; % --% Choke section-0.9 m screw diameter P=0.1; % pitch,m Do=0.09; % screw diameter, m Ro=Do\/2; % screw radius, m. Dc=0.030; % screw core shaft diameter, m Rc=Dc\/2; % screw core shaft radius, m Dt=0.102; % trough diameter,m Rt=Dt\/2; % trough radius, m cp=P\/Do; % ratio of pitch to screw diameter. ct=Dt\/Do; % ratio of trough diameter to screw diameter. cd=Dc\/Do; % ratio of core shaft diameter to screw diameter. A_cross=pi*(RoA2-RcA2); % effective cross section area of the screw casing LI =0.2; % length of the screw with 0.1 m screw diameter. alphao=atan(P\/(2*pi*Ro)); % helical angle at the outside screw diameter, radian. alphac=atan(P\/(2*pi*Rc)); % helical angle at the core shaft surface, radian. alphao_deg=atan(P\/(2*pi*Ro))\/pi*180; % helical angle at the outside screw diameter, degree. alphac_deg=atan(P\/(2*pi*Rc))\/pi* 180; % helical angle at the core shaft surface, degree. % torque calculation fori=l:l:nn con=0.8; % constant for estimating axial stress in choke section e=0.2 CCl(i)=con*(qf(i)*H0\/Dt*Lc\/Dt\/ct)A(e); % exponent to estimate axial stress on trailing side of a flight taoxam 1 (i)=n*taof_v(i)*(exp(2*tan(phi)* lamdas(i)*P\/(Rt-Rc))). A(CC 1 (i)+1); % stress on driving side of a flight taoxamll(i)=n*taof_v(i)*(exp(2*tan(phi)*lamdas(i)*P\/(Rt-Rc))).A(CCl(i)); % stress on trailing side of a flight EEl(i)=(exp(2*tan(phi)*lamdas(i)*P\/(Rt-Rc))).A(CCl(i)); % how many times for stress on trailing side compared to vertical stress % for flow condition, compaction ration in choke section lamdas_a=lamdas(i); % compute lamdas for function taoxave 1 CCC=CC 1 (i); % compute CC 1 for function taoxave 1 taoxl_a(i)=l\/P*n*taof_v(i)*quadl(@taoxavel, 0,P); % average axial stress in choke section taowal(i)=lamdas(i)*taoxl_a(i); % average normal wall stress in choke section Fcal(i)=2*pi*Rc*P*tan(phif)*taowal(i)*sin(alphac); % axial force on core surface in choke section Ffafl(i)=2.*pi.*lamdas(i).*taoxaml l(i).*quadl(@trailing, Rc, Ro); % axial force on trailing side surface in choke section Ftafl(i)=2*pi*tan(phi)*taowal(i)*Rt*P*cos(alphao+phi0; % axial force on trough surface in choke section Fdafl(i)=Fcal(i)+Ffafl(i)+Ftafl(i); % axial force on driving side surface in choke section taodaf 1 (i)=Fdaf 1 (i).\/pi.\/(RoA2-RcA2); % compute axial stress on the driving surface for flow condition in choke section Tdfl(i)=2*pi*tao_dafl(i)*quadl(@integrnd_Td, Rc, Ro); % compute the torque generated by driving side surface for choke section 1 Tcfl(i)=taowal(i)*2*pi*Rc*P*tan(phiO*Rc*cos(alphac); Appendices 308 % compute the torque generated by trailing side surface for choke section 1 Tffl(i)=2*pi*lamdas(i)*taoxaml I (i)*quadl(@integrnd Tf, Rc, Ro); % compute the torque generated by trough side surface for choke section 1 Ttipl(i)=taowal(i)*0.00635*P.\/sin(alphao)*tan(phi0*Ro; ratiochoke l(i)=taox 1 _a(i)\/tao_daf 1 (i); T_choke 1 (i)=L 1 \/P*(Tdf 1 (i)+Tcf 1 (i)+Tff 1 (i)+Ttip 1 (i)); % compute total torque in choke section 1 for flow condition end % -% Choke section-taper section and 0.8 m screw diameter P=0.1; %pitch,m Do=0.08; % screw diameter, m Ro=Do\/2; % screw radius, m. Dc=0.030; % screw core shaft diameter, m Rc=Dc\/2; % screw core shaft radius, m Dt=0.102; % trough diameter,m Rt=Dt\/2; % trough radius, m cp=P\/Do; % ratio of pitch to screw diameter. ct=Dt\/Do; % ratio of trough diameter to screw diameter. cd=Dc\/Do; % ratio of core shaft diameter to screw diameter. A_cross=pi*(RoA2-RcA2) % effective cross section area of the screw casing alphao=atan(P\/(2*pi*Ro)); % helical angle at the outside screw diameter, radian. alphac=atan(P\/(2*pi*Rc)); % helical angle at the core shaft surface, radian. alphao_deg=atan(P\/(2*pi*Ro))\/pi* 180; % helical angle at the outside screw diameter, degree. alphac_deg=atan(P\/(2*pi*Rc))\/pi* 180; % helical angle at the core shaft surface, degree. % % taper section global Ef Httf taoinf Taperinch=12; % length of taper section, inch LLt=Taperinch*0.0254; % length of taper section, m alphat=atan((Rt-0.044)\/LLt) % half angle of taper section Ht0=0.044\/tan(alphat); % length from apex of taper section to discharge outlet of screw feeder Htt=Rt\/tan(alphat); % length from apex of taper section to starting point of taper section mm=0.01; % incremental distance along screw axis from HtO to Htt xt=[HtO:mm:Htt]; % array of distance along screw axis number=floor((Htt-HtO)\/mm+1); % number of array data for i=l:l:nn EE(i)=-2*(l-lamdas(i)-lamdas(i)*tan(phi).\/tan(alphat)); % exponent in relation of axial stress and axial position in choke section T_choke_tapersum=0; % set T_choke_tapersum equal to 0 v=ceil(Taperinch\/4); % number of pitch h = zeros(l,v); % iteration times taoxt_aa=80000; % initial stress value s=[ 13800 33600 81000]; % stress calculated from stress-bulk density relation for pitch-1 and half pitch-2 in taper section forj=l:v taoin(j)=s(j)* 1-8; % initial stress value for stress at the beginning of each pitch in taper section HtO l(j)=Htt-j*P; % axial position of trailing side of flight for each pitch in taper section Httl(j)=Ht01(j)+P; % axial position of driving side of flight for each pitch in taper section while abs(taoxt_aa-s(j))>50 Ef=EE(i); % exponent in relation of axial stress and axial position in choke section; Httf=Httl(j); % axial position of driving side of flight for each pitch in taper section taoinf=taoin(j); % initial stress value for stress at the beginning (driving side) of each pitch in taper section taoxt_a(i,j)=l.\/P*quadl(@taotaper, Ht01(j), Httl(j)); % average axial stress in each pitch in taper section taowt_a(i,j)=lamdas(i)*taoxt_a(i,j); % average normal stress in each pitch in taper section Appendices 309 taoxt_aa=taoxt_a(i,j); % adjust initial stress taoin(j)=taoin(j)-5; % adjust maximum stress in the second half pitch h(j)=h(j)+l; % iteration times end taoxt_aa=80000; % restore initial value end number 1 =floor(number\/v); forj=l:v xtl=[Ht01(j):mm:HttlO')]; % array of distance along screw axis numberl(j)=floor((Httl(j)-Ht010))\/mm+l); % number of array data form=l:l: number 1Q) taoxt(j,m)=(xtl(m).\/Httl(j)).A(EO*taoin(j); % stress distribution in a pitch end end forj=l:v Fcataperl(i,j)=2*pi*Rc*P*tan(phi)*taowt_a(i,j)*sin(alphac); % axial force on core surface in choke section Ffaftaperl(i,j)=2*pi*lamdas(i)*taoxt(j,l)*quadl(@trailing, Rc, Ro); % axial force on trailing side surface in choke section Ftaftaperl(i,j)=tan(phi)*taowt_a(i,j)*2*pi*Rt*P+taowt_a(ij)*2*pi*Rt*P*tan(alphat); Fdaftaperl(ij)=Fcataperl(ij)+Ffaftaperl(ij)+Ftaftaperl(i,j); % axial force on driving side surface in choke section tao_daftaperl(ij)=Fdaftaperl(ij).\/pi.\/(RoA2-RcA2);; % compute axial stress on driving surface in choke section Tdtaperl(ij)=2*pi*tao_daftaperl(i,j)*quadl(@integrnd_Td, Rc, Ro); % compute torque generated by driving side of screw for flow condition Tcftaperl(i,j)=2*pi*tan(phi)*taowt_a(i,j)*Rc*Rc*P*cos(alphac); % compute torque generated by core shaft surface for flow condition Tfftaperl(i,j)=2*pi*lamdas(i)*taoxt(j, l)*quadl(@integrnd_Tf, Rc, Ro); % compute torque generated by core shaft surface for flow condition Ttiptaperl(i,j)=taowt a(i,j)*0.00635*P\/sin(alphao)*tan(phif)*Ro; % compute torque generated by flight tips for flow condition Tchoketaper 1 (i,j )=(Tdtaper 1 (i j )+Tcftaper 1 (i j )+Tfftaper 1 (i j )+Ttiptaper 1 (ij)); % compute torque in taper ection for flow condition T choke_tapersum=T_choke_tapersum+T_choke_taperl (ij); % compute total torque in taper section for flow condition end T_choke_tapert(i)=T_choke_tapersum; % compute total torque in taper section for flow condition end % % Choke section-0.8 m screw diameter L2=0.42-LLt; % length of the screw with 0.1 m screw diameter. % torque calculation for i=l:l:nn CC2(i)=con*(qf(i)*H0\/Dt*Lc\/Dt\/ct)A(e); % exponent to estimate axial stress on trailing side of a flight taoxam2(i)=n*taof_v(i)*(exp(2*tan(phi)*lamdas(i)*P\/(Rt-Rc)))A(CC2(i)+l); % theoretical maximum stress in a pitch taoxam22(i)=n*taof_v(i)*exp(2*tan(phi)*lamdas(i)*P\/(Rt-Rc))A(CC2(i)); % theoretical minimum stress in a pitch EE2(i)=(exp(2*tan(phi)*lamdas(i)*P\/(Rt-Rc))).A(CC2(i)); % how many times for stress on trailing side compared to vertical stress in hoppper % for flow condition, compression factor in choke section lamdas_a=lamdas(i); % compute lamdas for function taoxave 1 CCC=CC2(i); % compute CC2 for function taoxave 1 taox2_a(i)=l\/P*n*taof_v(i)*quadl(@taoxavel, 0,P); % average axial stress in choke section taowa2(i)=lamdas(i)*taox2_a(i); % average normal wall stress in choke section Fca2(i)=2*pi*Rc*P*tan(phi)*taowa2(i)*sin(alphac); % axial force on core surface in choke section Appendices 3 Ffaf2(i)=2*pi*lamdas(i)*taoxam22(i)*quadl(@trailing, Rc, Ro); % axial force on trailing side surface in choke section Ftaf2(i)=2*pi*tan(phi)*taowa2(i)*Rt*P*cos(alphao+phif); % axial force on trough surface in choke section Fdaf2(i)=Fca2(i)+Ffaf2(i)+Ftaf2(i); % axial force on driving side surface in choke section tao_daf2(i)=Fdaf2(i).\/pi.\/(RoA2-RcA2);; % compute axial stress on the driving surface in choke section Tdf2(i)=2*pi*tao_daf2(i)*quadl(@integrnd_Td, Rc, Ro); % compute the torque generated by driving side surface for choke section 2 Tcf2(i)=taowa2(i)*2*pi*Rc*P*tan(phif)*Rc*cos(alphac); % compute the torque generated by trailing side surface for choke section 2 Tff2(i)=2*pi*lamdas(i)*taoxam22(i)*quadl(@integrnd_Tf, Rc, Ro); % compute the torque generated by trough surface for choke section 2 Ttip2(i)=taowa2(i)*0.00635*P\/sin(alphao)*tan(phif)*Ro; % compute the torque generated by flight tips for choke section 2 ratio_choke2(i)=taox2_a(i)\/tao_daf2(i); % ratio of axial stress to stress on driving side of flight T_choke2(i)=L2\/P*(Tdf2(i)+Tcf2(i)+Tff2(i)+Ttip2(i)); % compute total torque in choke section 2 for flow condition end % Tor_totalf=T_choke 1 +T_choke2+T_hopperf+T_choke_tapert; % compute total torque for flow condition Tor_initial=T_hopperi; % compute initial torque for hopper section % . . : \u201e . result=[taoxa(l) taoxl_a(l) taox2_a(l) taoiv F v i taofvO(l) FvfTj(l) taofv(l) Fv_f(l) Torjnitial(l) T_hopperf( 1) T_choke 1(1) T_choke2( 1) T_choke_tapert( 1) Tor_totalf( 1)]; fprintf('The solution is \\n') fprintf('axial stress in hopper=%8.4f \\n',result(l)) fprintf('axial stressl=%8.4f\\n',result(2)) fprintf('axial stress2=%8.4f \\n',result(3)) fprintf('initial vertical stress=%8.4f \\n',result(4)) fprintf('initial feeder load=%8.4f \\n',result(5)) fprintf('vertical stress for flow condition=%8:4f \\n',result(6)) fprintf('feeder load for flow condition=%8.4f \\n',result(7)) fprintf('modified vertical stress for flow condition=%8.4f \\n',result(8)) fprintf('modified feeder load for flow condition=%8.4f \\n',result(9)) fprintf('torque requirement for hopper in initial condition=%8.4f \\n',result(10)) fprintf('torque requirement for hopper in flow condition=%8.4f \\n',result(l 1)) fprintf('torque requirement for choke 1 in flow condition=%8.4f \\n',result(12)) fprintf('torque requirement for choke 2 in flow condition=%8.4f \\n',result(13)) fprintf('torque requirement for 12\" taper section=%8.4f \\n',result(14)); fprintf('torque requirement for flow condition=%8.4f \\n',result( 15)) Appendices 311 H-4: Torque prediction for hog fuel-1 with extended sections File name: Torque_hogfue lextendedsection Function: taoxavel, taoxh, trailing, integrndTd and integrndTf Source code: see below % Hopper-screw feeder load and torque calculation for static and dynamic conditions. % Screw speeds, gravity and centrifugal forces are neglected in screw torque analysis clc clear % : % fixed parameters for screw feeder and hopper global P taof_v muf muwt lamdas Rt Rc alphas muwh phi phif lamdasa CCC rou_bulk=202; % bulk density of bulk solid, kg\/mA3. H0=0.45; % initial bed height in hopper, m P=0.1; %pitch,m Do=0.1; % screw diameter, m Ro=Do\/2; % screw radius, m. Dc=0.030; % screw core shaft diameter, m Rc=Dc\/2; % screw core.shaft radius, m Dt=0.102; % trough diameter,m Rt=Dt\/2; % trough radius, m cp=P\/Do; % ratio of pitch to screw diameter. ct=Dt\/Do; % ratio of trough diameter to screw diameter. cd=Dc\/Do; % ratio of core shaft diameter to screw diameter. Lh=0.914; % hopper outlet length,m L=0.8; % length of the screw with 0.1 m screw diameter, a little shorter than outlet length, i.e. 0.914 m. Lc=0.62; % choke section length, m B=0.102; % width of the trough,m A_cross=pi*(RoA2-RcA2); % Effective cross section area of screw casing, mA2. alpha=20\/l 80*pi; % half hopper angle, radian g=9.8; % gravitational acceleration, m\/sA2. alphao=atan(P\/(2*pi*Ro)); % helical angle at outside screw diameter, radian. alphac=atan(P\/(2*pi*Rc)); % helical angle at core shaft surface, radian. alphao_deg=atan(P\/(2*pi*Ro))\/pi* 180; % helical angle at outside screw diameter, degree. alphac_deg=atan(P\/(2*pi*Rc))\/pi* 180; % helical angle at core shaft surface, degree. % % variable parameters for biomass fuels and hopper-screw feeder % initial vertical stress and initial feeder load m=l; deltal_deg=39; % set effective internal friction angle, degree delta2_deg=39; delta_deg=[deltal_deg:m:delta2_deg]; % effective internal friction angle, degree. n=(delta2_deg-delta l_deg).\/m+1; delta=[delta l_deg\/l 80*pi:m\/l 80*pi:delta2_deg\/180*pi]; phi=31.5\/180*pi; % angle of friction between bulk solids and hopper wall (or casing surface), radian. phif=31.5\/180*pi; % angle of friction between bulk solids and screw flight, radian. muf=tan(phif); % coefficient of friction between solids and flight surface muwc=muf; % friction coefficient of bulk solid on core surface muwh=tan(phi); % friction coefficient of bulk solid on hopper surface. muwt=muwh; % friction coefficient of bulk solid on trough surface. D=2*(H0+B.\/2*cot(alpha))*tan(alpha); % compute width of bulk solid free surface in hopper (flate surface), m qi=l\/(2*tan(alpha))*(D\/B-l); % compute non-dimensional surcharge factor for initial condition, taoi_v=qi*rou_bulk*g*B; % compute vertical stress at hopper outlet for initial condition Fv_i=taoi_v*Lh*B; % compute feeder load at hopper outlet for initial condition Appendices % . % vertical stress and feeder load for flow condition fori=l:l:n mud(i)=tan(delta(i)); % effective coefficient of internal friction. mue(i)=sin(delta(i)); % equivalent friction coefficient of bulk solid,.from Roberts alpha_Mohr(i)=(asin(sin(phi)\/sin(delta(i)))-phi)\/2; lamdas(i)=cos(phi)*sin(2*alpha_Mohr(i))\/(sin(phi)*cos(2*alpha_Mohr(i))+sin(phi+2*alpha_M % stress ratio of normal stress acting perpendicularly to wall % of trough and core shaft surfaces to axial compression stress % derived from Mohr circle beta(i)=0.5*(phi+asin(sin(phi)\/sin(delta(i)))); % compute beta(i), constant X(i)=sin(delta(i))\/(l-sin(delta(i)))*(sin(2*beta(i)+alpha)\/sin(alpha)+l); % constant to compute feeder load YOH(alpha+betaO))*sin(alpha)+sin(beta(i^  qf(i)=Y(i)*(l+sin(delta(i)))\/(2*(X(i)-l)*sin(alpha)); % surcharge factor for flow conditions % qf 1 (i)= 1 \/4*( 1 \/tan(alpha))*(Y(i)*( 1 +sin(delta(i))*cos(2*beta(i)))*(tan(alpha)+tan(phi))\/sin(alpha)\/(X(i)-1)-1); taof_vO(i)=qf(i)*rou_bulk*g*B; % use loose bulk density for incompressible solids in the present study Fv_fO(i)=taof_vO(i).*Lh.*B; % vertical stress and feeder load for flow condition taof_v(i)=(taof_v0(i)+taoi_v).\/2; % average vertical stress for flow condition Fv_f(i)=taof_v(i).*Lh.*B; % average feeder load for flow condition end ' . % : 1 . \u2014 - \u2014 - \u2014 % hopper section, for a material element in a pitch first then entire hopper section t=l .0; % factor used to modify boundary condition at trailing side of flight eps=0.0001; % one small number a=0; % set initial value for a, a is ratio, i.e. taoxa(i)\/tao_daf(i) while abs(0.99-a) > eps for i=l:l:n taoxamax(i)=t*taof_v(i)*(exp(2*tan(phi)*lamdas(i)*P\/(Rt-Rc))); % maximum stress at driving side of flight according to stress analysis taoxamin(i)=t*taof_v(i); % minimum stress at trailing side of flight according to stress analysis lamdas_a=lamdas(i); % stress ratio of normal wall stress to axial stress on confined surface taoxa(i)=l\/P*t*taof_v(i)*quadl(@taoxh, 0,P); % average axial stress in a pitch for flow condition taoxai(i)=l\/P*t*taoi_v*quadl(@taoxh, 0,P); % average axial stress in a pitch for initial condition taowa(i)=lamdas(i)*taoxa(i); % average normal wall stress in a pitch for flow condition taowai(i)=lamdas(i)*taoxai(i); % average normal wall stress in a pitch for initial condition %-1. shear surface ksa(i)=pi*mue(i)*cp*cos(alphao+phif).\/2; % parameter for axial force calculations on shear surface Fsaf(i)=-ksa(i).*taof_v(i).*Do.A2; % axial force on shear surface for flow condition Fsai(i)=-ksa(i)*taoi_v*DoA2; % axial force on shear surface for initial condition kst(i)=pi*mue(i)*cp*sin(alphao+phif).\/2; % parameter for tangential force calculations on shear surface Fstf(i)=-kst(i).*taof_v(i)*DoA2; % tangential force on shear surface for flow condition Fsti(i)=-kst(i)*taoi_v*DoA2; % tangential force on shear surface for initial condition Fstfp_try(i)=l\/2*(taof_v(i)+taowa(i))*0.00635*P\/sin(alphao)*tan(phif); % tangential force from flight tips for flow condition Fstip_try(i)=l\/2*(taoi_v+taowai(i))*0.00635*P\/sin(alphao)*tan(phif); % tangential force from flight tips for initial condition Tstfp(i)=Fstfp_try(i)*Ro; % torque from flight tips for flow condition Tstip(i)=Fstip_try(i)*Ro; % torque from flight tips for initial condition %-2. core shaft kca(i)=t*pi*(ct-cd)*cd*cp*(exp(4*muwc*lamdas(i)*cp\/(ct-cd))-l)\/4\/(cpA2+piA2*cdA2)A0.5; % parameter for axial force calculations on core shaft surface Fcaf(i)=-kca(i)*taof_v(i)*DoA2; % axial force on core surface for flow condition Fcai(i)=-kca(i)*taoi_v*DoA2; % axial force on core surface for initial condition Fcal_try(i)=2*pi*Rc*P*tan(phif)*taowa(i)*sin(alphac); % axial force on core surface for flow condition kct(i)=t*piA2*(ct-cd)*cdA2*(exp(4*muwc*lamdas(i)*cp\/(ct-cd))-l)\/4\/(cpA2+piA2*cdA2)A0.5; % parameter for tangential force calculations on core shaft surface Appendices 313 Fctf(i)=kct(i)*taof_v(i)*DoA2; % tangential force on core surface for flow condition Fcti(i)=kct(i)*taoi_v*DoA2; % tangential force on core surface for initial condition %-3. trailing flight side kfa(i)=t*lamdas(i)*(pi*(l-cdA2)\/4+cp*muf*(l-cd)\/2); % parameter for axial force calculations on trailing side surface Ffaf(i)=-kfa(i)*taof_v(i)*DoA2; % axial force on trailing side surface for flow condition Ffai(i)=-kfa(i)*taoi_v*DoA2; % axial force on trailing side surface for initial condition Ffafl_try(i)=2.*pi.*lamdas(i).*taoxamin(i).*quadl(@trailing, Rc, Ro); % axial force on trailing side surface for flow condition kft(i)=t*lamdas(i)*(pi*muf*(l-cdA2)\/4-cp*(l-cd)\/2); % parameter for tangential force calculations on trailing side surface Fftf(i)=kft(i)*taof_v(i)*DoA2; % tangential force on trailing side surface for flow condition Ffti(i)=kft(i)*taoi_v*DoA2; % tangential force on trailing side surface for initial condition %-4. trough surface kta(i)=t*pi*(ct-cd)*ct*cos(alphao+phi0\/8*(exp(4*muwt*lamdas(i)*cp\/(ct-cd))-l); % parameter for axial force calculations on trough surface Ftaf(i)=-kta(i).*taof_v(i).*Do.A2; % axial force on trough surface for flow condition Ftai(i)=-kta(i)*taoi_v*DoA2; % axial force on trough surface for initial condition ktt(i)=t*pi*(ct-cd)*ct*sin(alphao+phif)\/8*(exp(4*muwt*lamdas(i)*cp\/(ct-cd))-l); % parameter for tangential force calculations on trough surface Fttf(i)=-ktt(i)*taof_v(i)*DoA2; % tangential force on trough surface for flow condition Ftti(i)=-ktt(i)*taoi_v*DoA2; % tangential force on trough surface for initial condition %-5. stress on driving side Kda(i)=4*(ksa(i)+kca(i)+kfa(i)+kta(i))\/pi\/(l-cdA2); % parameter for axial force calculations on driving side surface tao_daf(i)=Kda(i)*taof_v(i); % compute axial stress on driving surface for flow condition tao_dai(i)=Kda(i)*taoi_v; % compute axial stress on driving surface for initial condition Ftao_daf(i)=tao_daf(i)*A_cross; % compute axial force on driving surface for flow condition Ftaodai(i)=tao_dai(i)*A_cross; % compute axial force on driving surface for initial condition % torque calculation Tdf(i)=2*pi*tao_daf(i)*quadl(@integrnd_Td, Rc, Ro); % compute torque generated by driving side of screw for flow condition Tdi(i)=2*pi*tao_dai(i)*quadl(@integrnd_Td, Rc, Ro); % compute torque generated by driving side of screw for initial condition Tcf(i)=2*pi*Rc*P*taowa(i)*tan(phif)*cos(alphac)*Rc;; % compute torque generated by core shaft surface for flow condition Tci(i)=2*pi*Rc*P*taowai(i)*tan(phif)*cos(alphac)*Rc; % compute torque generated by core shaft surface for initial condition Tff(i)=2*pi*lamdas(i)*t*taof_v(i)*quadl(@integrnd_Tf, Rc, Ro); % compute torque from trough surface for flow condition Tfi(i)=2*pi*lamdas(i)*t*taoi_v*quadl(@integrnd_Tf, Rc, Ro); % compute torque from trough surface for initial condition T_hopperf(i)=Lh\/P*(Tdf(i)+Tcf(i)+Tff(i)+Tstfp(i)); % compute total torque in hopper section for flow condition T_hopperi(i)=Lh\/P*(Tdi(i)+Tci(i)+Tfi(i)+Tstip(i)); % compute total torque in hopper section for initial condition ratio01(i)=taodaf(i)\/taoxamax(i); % ratio of stress on driving side to theoretical maximum stress in a pitch ratio02(i)=taoxa(i)\/tao_daf(i); % ratio of average axial stress to stress on driving side in a pitch end a=ratio02(l); % ratio of average axial stress to stress on driving side t=t+0.0001; % 0.0001 as increment for t end t=t-0.0001; % % Choke section-0.9 m screw diameter P=0.1; % pitch,m Do=0.09; % screw diameter, m Appendices 314 Ro=Do\/2; % screw radius, m. Dc=0.030; % screw core shaft diameter, m Rc=Dc\/2; % screw core shaft radius, m Dt=0.102; % trough diameter,m Rt=Dt\/2; % trough radius, m cp=P\/Do; % ratio of pitch to screw diameter. ct=Dt\/Do; % ratio of trough diameter to screw diameter. cd=Dc\/Do; % ratio of core shaft diameter to screw diameter. A_cross=pi*(RoA2-RcA2) % Effective cross section area of the screw casing L 1=0.2; % length of screw with 0.09 m screw diameter. alphao=atan(P\/(2*pi*Ro)); % helical angle at the outside screw diameter, radian. alphac=atan(P\/(2*pi*Rc)); % helical angle at the core shaft surface, radian. alphao_deg=atan(P\/(2*pi*Ro))\/pi* 180; % helical angle at the outside screw diameter, degree. alphac_deg=atan(P\/(2*pi*Rc))\/pi* 180; % helical angle at the core shaft surface, degree. % torque calculation fori=l:l:n con=l; % constant for estimating the axial stress in choke section e 0.2: ;: CCl(i)=con*(qf(i)*H0\/Dt*Lc\/Dt\/ct)A(e); %.exponent to estimate the axial stress on trailing side of flight taoxaml(i)=t*taof_v(i)*(exp(2*tan(phi)*lamdas(i)*P\/(Rt-Rc))).A(CCl(i)+l); % theoretical maximum stress on driving side of flight taoxamll(i)=t*taof_v(i)*(exp(2*tan(phi)*lamdas(i)*P\/(Rt-Rc))).A(CCl(i)); % theoretical minimum stress on trailing side of flight EEl(i)=(exp(2*tan(phi)*lamdas(i)*P\/(Rt-Rc))).A(CCl(i)); % how many times for stress on trailing side compared to vertical stress taofv % for flow condition, compression factor in choke section lamdas_a=lamdas(i); % compute lamdas for function taoxave 1 CCC=CC 1 (i); % compute CC 1 for function taoxave 1 taoxl_a(i)=l\/P*t*taof_v(i)*quadl(@taoxavel, 0,P); % average axial stress in choke section taowal(i)=lamdas(i)*taoxl a(i); % average normal wall stress in choke section Fcal(i)=2*pi*Rc*P*tan(phiO*taowal(i)*sin(alphac); % axial force on core surface in choke section Ffafl(i)=2.*pi.*lamdas(i).*taoxaml l(i).*quadl(@trailing, Rc, Ro); % axial force on trailing side surface in choke section Ftafl(i)=2*pi*tan(phi)*taowal(i)*Rt*P*cos(alphao+phif); % axial force on trough surface in choke section Fdafl(i)=Fcal(i)+Ffafl(i)+Ftafl(i); % axial force on driving side surface in choke section tao_dafl(i)=Fdafl(i).\/pi.\/(RoA2-RcA2); % compute axial stress on driving surface for flow condition in choke section Tdfl(i)=2*pi*tao_dafl(i)*quadl(@integrnd_Td, Rc, Ro); % compute torque generated by driving side surface for choke section Tcfl(i)=taowal(i)*2*pi*Rc*P*tan(phif)*Rc*cos(alphac); % compute torque generated by trailing side surface for choke section Tffl(i)=2*pi*lamdas(i)*taoxaml l(i)*quadl(@integrnd_Tf, Rc, Ro); % compute torque generated by trough side surface for choke section Ttipl(i)=taowal(i)*0.00635*P.\/sin(alphao)*tan(phif)*Ro; % compute torque generated by flight tips for choke section T_chokel(i)=Ll\/P*(Tdfl(i)+Tcfl(i)+Tffl(i)+Ttipl(i)); % compute total torque in choke section 1 for flow condition end % % Choke section-0.8 m screw diameter P=0.1; %pitch,m Do=0.08; ; % screw diameter, m ': Ro=Do\/2; '\u2022 % screw radius, m. Dc=0.030; % screw core shaft diameter, m Rc=Dc\/2; % screw core shaft radius, m Dt=0.102; % trough diameter,m Appendices 3 Rt=Dt\/2; % trough radius, m cp=P\/Do; % ratio of pitch to screw diameter. ct=Dt\/Do; % ratio of trough diameter to screw diameter. cd=Dc\/Do; % ratio of core shaft diameter to screw diameter. A_cross=pi*(RoA2-RcA2); % Effective cross section area of the screw casing L2=0.42; % length of screw with 0.08 m screw diameter. alphao=atan(P\/(2*pi*Ro)); % helical angle at outside screw diameter, radian. alphac=atan(P\/(2*pi*Rc)); % helical angle at core shaft surface, radian. alphao_deg=atan(P\/(2*pi*Ro))\/pi*180; % helical angle at outside screw diameter, degree. alphac_deg=atan(P\/(2*pi*Rc))\/pi* 180; % helical angle at core shaft surface, degree. % torque calculation for i=l:l:n CC2(i)=con*(qf(i)*H0\/Dt*Lc\/Dt\/ct)A(e); % exponent to estimate axial stress on trailing side of a flight taoxam2(i)=t*taof_v(i)*(exp(2*tan(phi)*lamdas(i)*P\/(Rt-Rc)))A(CC2(i)+l); % theoretical maximum stress on driving side of flight taoxam22(i)=t*taof_v(i)*exp(2*tan(phi)*lamdas(i)*P\/(Rt-Rc))A(CC2(i)); % theoretical minimum stress on trailing side of flight EE2(i)=(exp(2*tan(phi)*lamdas(i)*P\/(Rt-Rc))).A(CC2(i)); \u2022 '' ' % how many times for stress on trailing side compared to vertical stress taofv % for flow condition, compression factor in choke section lamdas_a=lamdas(i); % compute lamdas for function taoxave 1 CCC=CC2(i); % compute CC2 for function taoxave I taox2_a(i)=l\/P*t*taof_v(i)*quadl(@taoxavel, 0,P); % average axial stress in choke section taowa2(i)=lamdas(i)*taox2_a(i); % average normal wall stress in choke section Fca2(i)=2*pi*Rc*P*tan(phi)*taowa2(i)*sin(alphac); % axial force on core surface in choke section Ffaf2(i)=2*pi*lamdas(i)*taoxam22(i)*quadl(@trailing, Rc, Ro); % axial force on trailing side surface in choke section Ftaf2(i)=2*pi*tan(phi)*taowa2(i)*Rt*P*cos(alphao+phif); % axial force on trough surface in choke section Fdaf2(i)=Fca2(i)+Ffaf2(i)+Ftaf2(i); % axial force on driving side surface in choke section tao_daf2(i)=Fdaf2(i).\/pi.\/(RoA2-RcA2); % compute axial stress on driving surface in choke section Tdf2(i)=2*pi*tao_daf2(i)*quadl(@integrnd_Td, Rc, Ro); % compute torque generated by driving side surface for choke section 2 Tcf2(i)=taowa2(i)*2*pi*Rc*P*tan(phif)*Rc*cos(alphac); % compute torque generated by trailing side surface for choke section 2 Tff2(i)=2*pi*lamdas(i)*taoxam22(i)*quadl(@integrnd_Tf, Rc, Ro); % compute torque generated by trough surface for choke section 2 Ttip2(i)=taowa2(i)*0.00635*P.\/sin(alphao)*tan(phif)*Ro; % compute torque generated by flight tips for choke section T_choke2(i)=L2\/P*(Tdf2(i)+Tcf2(i)+Tff2(i)+Ttip2(i)); % compute total torque in choke section 2 for flow condition end % tao_daO=239256.2904; % axial stress from compacted bulk density in extended section TdO=2*pi*tao_daD*quadl(@integrnd_Td, Rc, Ro); % compute torque generated by last driving side surface Tor_totalf=(T_chokel+T_choke2)+T_hopperf+TdO; % compute total torque for flow condition Torinitial=T_hopperi; % compute initial torque for hopper section % result=[taoxa(l) taoxla(l) taox2_a(l) taoiv Fv_i taofvO(l) FvfD(l) taofv(l) Fv_f(l) Tor_initial(l) T_hopperf(l) Tchokel(l) T_choke2(l) Tor_totalf(l)]; Appendices H-5: Torque prediction for ground wood pellets-1 for screw-2 File name: Torque_GWP34_newscrew Function: taoxave 1, taoxh, trailing, integrndTd and integrndTf Source code: see below % Hopper-screw feeder load and torque calculation for static and dynamic conditions. % Flight thickness, screw speeds, gravity and centrifugal forces are neglected in screw torque analysis clc clear % \u2014 % fixed parameters for screw feeder and hopper global P taofv muf muwt lamdas Rt Rc alphas muwh phi phif lamdas JSL CCC rou_bulk=485; % bulk density of bulk solid, kg\/mA3. H0=0.45; % initial bed height in hopper, m P=0.04; % pitch,m Do=0.08; % screw diameter, m Ro=Do\/2; % screw radius, m. Dc=0.056; % screw core shaft diameter, m Rc=Dc\/2; % screw core shaft radius, m Dt=0.102; % trough diameter,m Rt=Dt\/2; % trough radius, m cp=P\/Do; % ratio of pitch to screw diameter. ct=Dt\/Do; % ratio of trough diameter to screw diameter. cd=Dc\/Do; % ratio of core shaft diameter to screw diameter. Lh=0.914; % hopper outlet length,m Ll=0.1; % length of the screw with P=0.04 m and Dc=0.056 m Lc=0.62 B=0.102; % width of trough,m A_cross=pi*(RoA2-RcA2) % effective cross section area of screw casing alpha=20\/180*pi; % half hopper angle, radian g=9.8; % gravitational acceleration, m\/sA2. alphao=atan(P\/(2*pi*Ro)); % helical angle at outside screw diameter, radian. alphac=atan(P\/(2*pi*Rc)); % helical angle at core shaft surface, radian. alphao_deg=atan(P\/(2*pi*Ro))\/pi* 180; % helical angle at outside screw diameter, degree. alphac_deg=atan(P\/(2*pi*Rc))\/pi* 180; % helical angle at core shaft surface, degree. % % variable parameters for biomass fuels and hopper-screw feeder; initial vertical stress and initial feeder load m=l; deltal_deg=33.2; % set effective internal friction angle, degree delta2_deg=33.2; delta_deg=[deltal_deg:m:delta2_deg]; % effective internal friction angle, degree. n=(delta2_deg-delta 1 _deg).\/m+1; delta=[deltal_deg\/180*pi:m\/180*pi:delta2_deg\/180*pi]; phi=30.2\/l80*pi; % angle of friction between bulk solids and hopper wall (or casing surface),radian phif=30.2\/180*pi; % angle of friction between bulk solids and screw flight, radian. muf=tan(phif); % coefficient of friction between solids and screw flight surface muwc=muf; % friction coefficient of bulk solid on core surface muwh=tan(phi); % friction coefficient of bulk solid on hopper surface. muwt=muwh; % friction coefficient of bulk solid on trough surface. D=2*(H0+B.\/2*cot(alpha))*tan(alpha); % compute width of bulk solid free surface in hopper (flate surface), qi=l\/(2*tan(alpha))*(D\/B-1); % compute non-dimensional surcharge factor for initial condition taoi_v=qi*rou_bulk*g*B; % compute vertical stress at hopper outlet for initial condition Fv_i=taoi_v*Lh*B; % compute feeder load at hopper outlet for initial'condition Appendices 317 % vertical stress and feeder load for flow condition fori=l:l:n mud(i)=tan(delta(i)); % effective coefficient of internal friction. mue(i)=sin(delta(i)); % equivalent friction coefficient of bulk solid,.from Roberts alpha_Mohr(i)=(asin(sin(phi)\/sin(delta(i)))-phi)\/2; lamdas(i)=cos(phi)*sin(2*alpha_Mohr(i))\/(sin(phi)*cos(2*alpha_Mohr(i))+sin(phi+2*alpha_M % stress ratio of normal stress acting perpendicularly to the wall % of trough and core shaft surfaces to axial compression stress % derived from Mohr circle beta(i)=0.5*(phi+asin(sin(phi)\/sin(delta(i)))); % compute beta(i), constant X(i)=sin(delta(i))\/(l-sin(delta(i)))*(sin(2!i:beta(i)+alpha)\/sin(alpha)+l); % constant to compute feeder load YO)=((alpha+betaG))*sin(alpha)+sin(beta(i))^  % constant to compute feeder load qf(i)=Y(i)*(l+sin(delta(i)))\/(2*(X(i)-l)*sin(alpha)); % surcharge factor for flow conditions %qf 1 (i)= l\/4*( l\/tan(alpha))*(Y(i)*( 1+sin(de^ % smaller than the above one taof_vO(i)=qf(i)*rou_bulk*g*B; % use loose bulk density, even for compressible solids in the present study Fv_fO(i)=taof_vO(i).*Lh.*B; % vertical stress and feeder load for flow condition taof_v(i)=(taof_vO(i)+taoi_v).\/2; % average vertical stress for flow condition Fv_f(i)=taof_v(i).*Lh.*B; % average feeder load for flow condition end % . . % hopper section, for a material element in a pitch first and entire hopper section t=1.0; for i=l:l:n taoxamaxl(i)=t*taof_v(i)*(exp(2*tan(phi)*lamdas(i)*P\/(Rt-Rc))); % maximum stress at driving side of flight according to stress analysis taoxaminl(i)=t*taof v(i); % minimum stress at trailing side of flight according to stress analysis lamdas_a=lamdas(i); % stress ratio of normal wall stress to axial stress on confined surface taoxal(i)=l\/P*t*taof_v(i)*quadl(@taoxh, 0,P); % average axial stress in a pitch for flow condition taoxail(i)=l\/P*t*taoi_v*quadl(@taoxh, 0,P); % average axial stress in a pitch for initial condition taowal(i)=lamdas(i)*taoxal(i); % average normal wall stress in a pitch for flow condition taowail(i)=lamdas(i)*taoxail(i); % average normal wall stress in a pitch for initial condition %-1. shear surface ksal(i)=pi*mue(i)*cp*cos(alphao+phif).\/2; % parameter for axial force calculations on shear surface Fsafl(i)=-ksal(i).*taof_v(i).*Do.A2; % axial force on shear surface for flow condition Fsail(i)=-ksal(i)*taoi_v*DoA2; % axial force on shear surface for initial condition kstl(i)=pi*mue(i)*cp*sin(alphao+phif).\/2; % parameter for tangential force calculations on shear surface Fstfl(i)=-kstl(i).*taof_v(i)*DoA2; % tangential force on shear surface for flow condition Fstil(i)=-kstl(i)*taoi_v*DoA2; % tangential force on shear surface for initial condition Fstfp_tryl(i)=l\/2*(taof_v(i)+taowal(i))*0.00635*P\/sin(alphao)*tan(phif); % tangential force from flight tips for flow condition Fstip_tryl(i)=l\/2*(taoi_v+taowail(i))*0.00635*P\/sin(alphao)*tan(phif); % tangential force from flight tips for initial condition Tstfp 1 (i)=Fstfp_try l(i)*Ro; % torque from flight tips for flow condition Tstipl(i)=Fstip_tryl(i)*Ro; % torque from flight tips for initial condition %-2. core shaft kcal(i)=t*pi*(ct-cd)*cd*cp*(exp(4*muwc*lamdas(i)*cp\/(ct-cd))-l)\/4\/(cpA2+piA2*cdA2)A0.5; % parameter for axial force calculations on core shaft surface Fcafl(i)=-kcal(i)*taof_v(i)*DoA2; % axial force on core surface for flow condition Fcail(i)=-kcal(i)*taoi_v*DoA2; % axial force on core surface for initial condition Fcal_try l(i)=2*pi*Rc*P*tan(phif)*taowal(i)*sin(alphac); kctl(i)=t*piA2*(ct-cd)*cdA2*(exp(^^ % parameter for tangential force calculations on core shaft surface Fctfl(i)=kctl(i)*taof_v(i)*DoA2; % tangential force on core surface for flow condition Fctil(i)=kctl(i)*taoi v*DoA2; % tangential force on core surface for initial condition Appendices 318 %-3. trailing flight side kfal(i)=t*lamdas(i)*(pi*(l-cdA2)\/4+cp*muP(l-cd)\/2); % parameter for axial force calculations on trailing side surface Ffafl(i)=-kfal(i)*taof_v(i)*DoA2; %.axial force on trailing side surface for flow condition Ffail(i)=-kfal(i)*taoi_v*DoA2; % axial force on trailing side surface for initial condition Ffafl_tryl(i)=2.*pi.*lamdas(i).*taoxaminl(i).*quadl(@trailing, Rc, Ro); % axial force on core surface for flow condition kft 1 (i)=t*lamdas(i)*(pi*muP( 1-cdA2)\/4-cp*( 1-cd)\/2); % parameter for tangential force calculations on trailing side surface Fftfl(i)=kftl(i)*taof_v(i)*DoA2; % tangential force on trailing side surface for flow condition Fftil(i)=kftl(i)*taoi_v*DoA2; % tangential force on trailing side surface for initial condition %-4. trough surface* '\u2022 \u2022 \u2022\u2022\u2022\u2022>\u2022 ' -\u2022 r-. ktal(i)=t*pi*(ct-cd)*ct*cos(alphao+phif)\/8*(exp(4*muwt*lamdas(i)*cp\/(ct-cd))-l); % parameter for axial force calculations on trough surface Ftafl(i)=-ktal(i).*taof_v(i).*Do.A2; % axial force on trough surface for flow condition Ftail(i)=-ktal(i)*taoi_v*DoA2; % axial force on trough surface for initial condition kttl(i)=t*pi*(ct-cd)*ct*sin(alphao+phi0\/8*(exp(4*muwt*lamdas(i)*cp\/(ct-cd))-l); % parameter for tangential force calculations on trough surface Fttfl(i)=-kttl(i)*taof_v(i)*DoA2; % tangential force on trough surface for flow condition Fttil(i)=-kttl(i)*taoi_v*DoA2; % tangential force on trough surface for initial condition %-5. stress on driving side Kdal(i)=4*(ksal(i)+kcal(i)+kfal(i)+ktal(i))\/pi\/(l-cdA2); % parameter for axial force calculations on driving side surface tao_dafl(i)=Kdal(i)*taof_v(i); % compute axial stress on driving surface for flow condition tao_dail(i)=Kdal(i)*taoi_v; % compute axial stress on driving surface for initial condition Ftao_dafl(i)=tao_dafl (i)*A_cross; % compute axial force on driving surface for flow condition Ftao dail(i)=tao_dai l(i)*A_cross; % compute axial force on driving surface for initial condition % torque calculation Tdfl(i)=2*pi*tao_dafl(i)*quadl(@integrnd_Td, Rc, Ro); % compute torque generated by driving side of the screw for flow condition Tdil(i)=2*pi*tao_dail(i)*quadl(@integrnd_Td, Rc, Ro); % compute torque generated by driving side of the screw for initial condition Tcfl(i)=2*pi*Rc*P*taowal(i)*tan(phiO*cos(alphac)*Rc; % compute torque generated by core shaft surface for flow condition Tcil(i)=2*pi*Rc*P*taowail(i)*tan(phif)*cos(alphac)*Rc; % compute torque generated by core shaft surface for initial condition Tffl(i)=2*pi*lamdas(i)*t*taof_v(i)*quadl(@integrnd_Tf, Rc, Ro); % compute torque from trailing surface for flow condition Tfil(i)=2*pi*lamdas(i)*t*taoi_v*quadl(@integrnd_Tf, Rc, Ro); % compute torque from trailing surface for initial condition Thopperfl (i)=L 1 \/P*(Tdf 1 (i)+Tcf 1 (i)+Tffl (i)+Tstfp 1 (i)); % compute total torque in hopper section 1 for flow condition Thopperi 1 (i)=L l\/P*(Tdi 1 (i)+Tci 1 (i)+Tfi 1 (i)+Tstip 1 (i)); % compute total torque in hopper section 1 for initial condition ratio01(i)=tao_dafl(i)\/taoxamaxl(i); % ratio of stress on driving side to theoretical maximum stress in a pitch ratio02(i)=taoxal(i)\/tao_dafl(i); % ratio of average axial stress to stress on driving side in a pitch end % % the second stage along the screw P=0.056; % pitch,m Do=0.08; % screw diameter, m Ro=Do\/2; % screw radius, m. Dc=0.043; \u2022 % screw core shaft diameter, m Rc=Dc\/2; % screw core shaft radius, m Dt=0.102; % trough diameter,m Rt=Dt\/2; % trough radius, m Appendices 3 cp=P\/Do; % ratio of pitch to screw diameter. ct=Dt\/Do; % ratio of trough diameter to screw diameter. cd=Dc\/Do; % ratio of core shaft diameter to screw diameter. Lh=0.914; % hopper outlet length,m L2=0.31; % length of the screw with P=0.056 m and Dc=0.043 m. Lc=0.62 B=0.102; % width of the trough,\u2122 A_cross=pi*(RoA2-RcA2) % effective cross section area of the screw casing alpha=20\/180*pi; % half hopper angle, radian g=9.8; % gravitational acceleration, m\/sA2. alphao=atan(P\/(2*pi*Ro)); % helical angle at the outside screw diameter, radian. alphac=atan(P\/(2*pi*Rc)); % helical angle at the core shaft surface, radian. alphao_deg=atan(P\/(2*pi*Ro))\/pi* 180; % helical angle at the outside screw diameter, degree. alphac_deg=atan(P\/(2*pi*Rc))\/pi* 180; % helical angle at the core shaft surface, degree. % % variable parameters for biomass fuels and hopper-screw feeder; initial vertical stress and initial feeder load fori=l:l:n taoxamax2(i)=t*taof_v(i)*(exp(2*tan(phi)*lamdas(i)*P\/(Rt-Rc))); % maximum stress at driving side of flight according to stress analysis taoxamin2(i)=t*taof_v(i); % minimum stress at driving side of flight according to stress analysis lamdas_a=lamdas(i); % stress ratio of normal wall stress to axial stress on confined surface taoxa2(i)=l\/P*t*taof_v(i)*quadl(@taoxh, 0,P); % average axial stress in a pitch for flow condition taoxai2(i)=l\/P*t*taoi_v*quadl(@taoxh, 0,P); % average axial stress in a pitch for initial condition taowa2(i)=lamdas(i)*taoxa2(i); % average normal wall stress in a pitch for flow condition taowai2(i)=lamdas(i)*taoxai2(i); % average normal wall stress in a pitch for initial condition % - l . shear surface ksa2(i)=pi*mue(i)*cp*cos(alphao+phif).\/2; % parameter for axial force calculations on shear surface Fsaf2(i)=-ksa2(i).*taof_v(i).*Do.A2; % axial force on shear surface for flow condition Fsai2(i)=-ksa2(i)*taoi_v*DoA2; % axial force on shear surface for initial condition kst2(i)=pi*mue(i)*cp*sin(alphao+phif).\/2; % parameter for tangential force calculations on shear surface Fstf2(i)=-kst2(i).*taof_v(i)*DoA2; % tangential force on shear surface for flow condition Fsti2(i)=-kst2(i)*tao i_v*DoA2; % tangential force on shear surface for initial condition Fstfp_try2(i)=l\/2*(taof_v(i)+taowa2(i))*0.00635*P\/sin(alphao)*tan(phi0; % tangential force from flight tips for flow condition FstipJry2(i)=l\/2*(taoi_v+taowai2(i))*0.00635*P\/sin(alphao)*tan(phif); % tangential force from flight tips for initial condition Tstfp2(i)=Fstfp_try2(i)*Ro; % torque from flight tips for flow condition Tstip2(i)=Fstip_try2(i)*Ro; % torque from flight tips for initial condition %-2. core shaft kca2(i)=t*pi*(ct-cd)*cd*cp*(exp(4*muwc*lamdas(i)*cp\/(ct-cd))-l)\/4\/(cpA2+piA2*cdA2)A0.5; % parameter for axial force calculations on core shaft surface Fcaf2(i)=-kca2(i)*taof_v(i)*DoA2; % axial force on core surface for flow condition Fcai2(i)=-kca2(i)*taoi_v*DoA2; % axial force on core surface for initial condition Fcaltry2(i)=2*pi*Rc*P*tan(phiO*taowa2(i)*sin(alphac); % axial force on core surface for flow condition kct2(i)=t*piA2*(ct-cd)*cdA2*(exp(4*muwc*lamdas(i)*cp\/(ct-cd))-l)\/4\/(cpA2+piA2*cdA2)A0.5; % parameter for tangential force calculations on core shaft surface Fctf2(i)=kct2(i)*taof_v(i)*DoA2; % tangential force on core surface for flow condition Fcti2(i)=kct2(i)*taoi_v*DoA2; % tangential force on core surface for initial condition %-3. trailing flight side kfa2(i)=t*lamdas(i)*(pi*(l-cdA2)\/4+cp*muP(l-cd)\/2); % parameter for axial force calculations on trailing side surface Ffaf2(i)=-kfa2(i)*taof_v(i)*DoA2; % axial force on trailing side surface for flow condition Ffai2(i)=-kfa2(i)*taoi_v*DoA2; % axial force on trailing side surface for initial condition Ffafl_try2(i)=2.*pi.*lamdas(i).*taoxamin2(i).*quadl(@trailing, Rc, Ro); kft2(i)=t*lamdas(i)*(pi*muP( l-cdA2)\/4-cp*( 1 -cd)\/2); Appendices 320 % parameter for tangential force calculations on trailing side surface Fftf2(i)=kft2(i)*taofv(i)*DoA2; % tangential force on trailing side surface for flow condition Ffti2(i)=kft2(i)*tao i_v*DoA2; % tangential force on trailing side surface for initial condition %-4. trough surface kta2(i)=t*pi*(ct-cd)*ct*cos(alphao+phif)\/8*(exp(4*muwt*lamdas(i)*cp\/(ct-cd))-l); % parameter for axial force calculations on trough surface Ftaf2(i)=-kta2(i).*taof_v(i).*Do.A2; % axial force on trough surface for flow condition Ftai2(i)=-kta2(i)*taoi_v*DoA2; % axial force on trough surface for initial condition ktt2(i)=t*pi*(ct-cd)*ct*sin(alphao+phif)\/8*(exp(4*muwt*lamdas(i)*cp\/(ct-cd))-l); % parameter for tangential force calculations on trough surface Fttf2(i)=-ktt2(i)*taof_v(i)*DoA2; % tangential force on trough surface for flow condition Ftti2(i)=-ktt2(i)*taoi_v*DoA2; % tangential force on trough surface for initial condition %-5. stress on driving side Kda2(i)=4*(ksa2(i)+kca2(i)+kfa2(i)+kta2(i))\/pi\/( 1 -cdA2); % parameter for axial force calculations on driving side surface tao_daf2(i)=Kda2(i)*taof_v(i); % compute axial stress on driving surface for flow condition tao_dai2(i)=Kda2(i)*tao i v ; % compute axial stress on driving surface for initial condition Ftao_daf2(i)=tao_daf2(i)*A_cross; % compute axial force on driving surface for flow condition Ftao_dai2(i)=tao_dai2(i)*A_cross; % compute axial force on driving surface for initial condition % torque calculation Tdf2(i)=2*pi*tao_daf2(i)*quadl(@integrnd_Td, Rc, Ro); % compute torque generated by driving side of screw for flow condition Tdi2(i)=2*pi*tao_dai2(i)*quadl(@integrnd_Td, Rc, Ro); % compute torque generated by driving side of screw for initial condition Tcf2(i)=2*pi*Rc*P*taowa2(i)*tan(phif)*cos(alphac)*Rc; % compute torque generated by core shaft surface for flow condition Tci2(i)=2*pi*Rc*P*taowai2(i)*tan(phif)*cos(alphac)*Rc; % compute torque generated by core shaft surface for initial condition Tff2(i)=2*pi*lamdas(i)*t*taof_v(i)*quadl(@integrnd_Tf, Rc, Ro); % compute torque from trough surface for flow condition Tfi2(i)=2*pi*lamdas(i)*t*taoi_v*quadl(@integrnd_Tf, Rc, Ro); % compute torque from trough surface for initial condition T_hopperf2(i)=L2\/P*(Tdf2(i)+Tcf2(i)+Tff2(i)+Tstfp2(i)); % compute total torque in hopper section for flow condition T_hopperi2(i)=L2\/P*(Tdi2(i)+Tci2(i)+Tfi2(i)+Tstip2(i)); % compute total torque in hopper section for initial condition ratio012(i)=tao_daf2(i)\/taoxamax2(i); % ratio of stress on driving side to theoretical maximum stress in a pitch ratio022(i)=taoxa2(i)\/tao_daf2(i); % ratio of average axial stress to stress on driving side in a pitch end % % the third stage of the screw P=0.071; %pitch,m Do=0.08; % screw diameter, m Ro=Do\/2; % screw radius, m. Dc=0.0305; % screw core shaft diameter, m Rc=Dc\/2; % screw core shaft radius, m Dt=0.102; % trough diameter,m Rt=Dt\/2; % trough radius, m cp=P\/Do; % ratio of pitch to screw diameter. ct=Dt\/Do; % ratio of trough diameter to screw diameter. cd=Dc\/Do; % ratio of core shaft diameter to screw diameter. Lh=0.914; % hopper outlet length,m L3=0.31; % length of the screw with P=0.071 m and Dc=0.0305 m. Lc=0.62 B=0.102; % width of the trough,m A_cross=pi*(RoA2-RcA2) % effective cross section area of the screw casing Appendices alpha=207180*pi; % half hopper angle, radian g=9.8; % gravitational acceleration, m\/sA2. for i=l:l:n taoxamax3(i)=t*taof_v(i)*(exp(2*tan(phi)*lamdas(i)*P\/(Rt-Rc))); % maximum stress at driving side of flight according to stress analysis taoxamin3(i)=t*taof_v(i); % minimum stress at driving side of flight according to stress analysis lamdas_a=lamdas(i); % stress ratio of normal wall stress to axial stress on confined surface taoxa3(i)=l\/P*t*taof_v(i)*quadl(@taoxh, 0,P); \u2022% average axial stress in a pitch for flow condition taoxai3(i)=l\/P*t*taoi_v*quadl(@taoxh, 0,P); % average axial stress in a pitch for initial condition taowa3(i)=lamdas(i)*taoxa3(i); % average normal wall stress in a pitch for flow condition taowai3(i)=lamdas(i)*taoxai3(i); % average normal wall in a pitch for initial condition %-1. shear surface ksa3(i)=pi*mue(i)*cp*cos(alphao+phif).\/2; % parameter for axial force calculations on shear surface FsaO(i)=-ksa3(i).*taof_v(i).*Do.A2; % axial force on shear surface for flow condition Fsai3(i)=-ksa3(i)*taoi_v*DoA2; % axial force on shear surface for initial condition kst3(i)=pi*mue(i)*cp*sin(alphao+phif)-\/2; % parameter for tangential force calculations on shear surface FstO(i)=-kst3(i).*taof_v(i)*DoA2; % tangential force on shear surface for flow condition Fsti3(i)=-kst3(i)*taoi_v*DoA2; % tangential force on shear surface for initial condition Fstfp_try3(i)=l\/2*(taof_v(i)+taowa3(i))*0.00635*P\/sin(alphao)*tan(phif); % tangential force from flight tips for flow condition Fstip_try3(i)=l\/2*(taoi_v+taowai3(i))*0.00635*P\/sin(alphao)*tan(phif); % tangential force from flight tips for initial condition Tstfp3(i)=Fstfp_try3(i)*Ro; % torque from flight tips for flow condition Tstip3(i)=Fstip_try3(i)*Ro; % torque from flight tips for initial condition %-2. core shaft kca3(i)=t*pi*(ct-cd)*cd*cp*(exp(4*muwc*lamdas(i)*cp\/(ct-cd))-l)\/4\/(cpA2+piA2*cdA2)A0.5; % parameter for axial force calculations on core shaft surface FcaO(i)=-kca3(i)*taof_v(i)*DoA2; % axial force on core surface for flow condition Fcai3(i)=-kca3(i)*taoi_v*DoA2; % axial force on core surface for initial condition Fcal_try3(i)=2*pi*Rc*P*tan(phif)*taowa3(i)*sin(alphac); kct3(i)=t*piA2*(ct-cd)*cdA2*(exp(4*muwc*lamdas(i)*cp\/(ct-cd))-l)\/4\/(cpA2+piA2*cdA2)A0.5; % parameter for tangential force calculations on core shaft surface FctD(i)=kct3(i)*taof_v(i)*DoA2; % tangential force on core surface for flow condition Fcti3(i)=kct3(i)*taoi_v*DoA2; % tangential force on core surface for initial condition %-3. trailing flight side kfa3(i)=t*lamdas(i)*(pi*(l-cdA2)\/4+cp*muf*(l-cd)\/2); % parameter for axial force calculations on trailing side surface FfaO(i)=-kfa3(i)*taof_v(i)*DoA2; % axial force on trailing side surface for flow condition Ffai3(i)=-kfa3(i)*taoi_v*DoA2; % axial force on trailing side surface for initial condition Ffaf 1 _try3(i)=2.*pi.*lamdas(i).*taoxamin3(i).*quadl(@trailing, Rc, Ro); % axial force on core surface for flow condition kft3(i)=t*lamdas(i)*(pi*muP( 1 -cdA2)\/4-cp*( 1 -cd)\/2); % parameter for tangential force calculations on trailing side surface Fftf3(i)=kft3(i)*taof_v(i)*DoA2; % tangential force on trailing side surface for flow condition Ffti3(i)=kft3(i)*taoi_v*DoA2; % tangential force on trailing side surface for initial condition %-4. trough surface kta3(i)=t*pi*(ct-cd)*ct*cos(alphao+phif)\/8*(exp(4*muwt*lamdas(i)*cp\/(ct-cd))-l); % parameter for axial force calculations on trough surface Ftaf3(i)=-kta3(i).*taof_v(i).*Do.A2; % axial force on trough surface for flow condition Ftai3(i)=-kta3(i)*taoi_v*DoA2; % axial force on trough surface for initial condition ktt3(i)=t*pi*(ct-cd)*ct*sin(alphao+phif)\/8*(exp(4*muwt*lamdas(i)*cp\/(ct-cd))-l); % parameter for tangential force calculations on trough surface FttD(i)=-ktt3(i)*taof_v(i)*DoA2; % tangential force on trough surface for flow condition Ftti3(i)=-ktt3(i)*taoi_v*DoA2; % tangential force on trough surface for initial condition %-5. stress on driving side Kda3(i)=4*(ksa3(i)+kca3(i)+kfa3(i)+kta3(i))\/pi\/(l-cdA2); % parameter for axial force calculations on driving side surface Appendices 322 tao_daf3(i)=Kda3(i)*taof_v(i); % compute axial stress on driving surface for flow condition tao_dai3(i)=Kda3(i)*taoi_v; % compute axial stress on driving surface for initial condition Ftao_daf3(i)=tao_daf3(i)* Across; % compute axial force on driving surface for flow condition Ftao_dai3(i)=tao_dai3(i)*A_cross; % compute axial force on driving surface for initial condition % torque calculation Tdf3(i)=2*pi*tao_daO(i)*quadl(@integrnd_Td, Rc, Ro); % compute torque generated by driving side of screw for flow condition Tdi3(i)=2*pi*tao_dai3(i)*quadl(@integrnd_Td, Rc, Ro); % compute the torque generated by the driving side of the screw for initial condition TcD(i)=2*pi*Rc*P*taowa3(i)*tan(phif)*cos(alphac)*Rc; % compute torque generated by core shaft surface for flow condition Tci3(i)=2*pi*Rc*P*taowai3(i)*fan(phif)*cos(alphac)*Rc;. \u2022 % compute torque generated by core shaft surface for initial condition Tff3(i)=2*pi*lamdas(i)*t*taof_v(i)*quadl(@integrnd_Tf, Rc, Ro); % compute torque from trailing surface for flow condition Tfi3(i)=2*pi*lamdas(i)*t*taoi_v*quadl(@integrnd_Tf, Rc, Ro); % compute torque from trailing surface for initial condition T_hopperO(i)=L3\/P*(TdG(i)+TcO(i)+TfG(i)+Tstfp3(i)); % compute total torque in hopper section for flow condition T_hopperi3(i)=L3\/P*(Tdi3(i)+Tci3(i)+Tfl3(i)+Tstip3(i)); % compute total torque in hopper section for initial condition ratioO 13(i)=tao_daf3(i)\/taoxamax3(i); % ratio of stress on driving side to theoretical maximum stress in a pitch ratio023(i)=taoxa3(i)\/tao_daf3(i); % ratio of average axial stress to stress on driving side in a pitch end % % the fourth- in the hopper P=0.08; % pitch,m Do=0.08; % screw diameter, m Ro=Do\/2; % screw radius, m. Dc=0.0203; % screw core shaft diameter, m Rc=Dc\/2; % screw core shaft radius, m Dt=0.102; % trough diameter,m Rt=Dt\/2; % trough radius, m cp=P\/Do; % ratio of pitch to screw diameter. ct=Dt\/Do; % ratio of trough diameter to screw diameter. cd=Dc\/Do; % ratio of core shaft diameter to screw diameter. Lh=0.914; % hopper outlet length,m L4=0.019; % length of the screw with P=0.08 m and Dc=0.0203 m. Lc=0.62 B=0.102; % width of the trough.m A_cross=pi*(RoA2-RcA2) % effective cross section area of the screw casing alpha=20\/180*pi; % half hopper angle, radian g=9.8; % gravitational acceleration, m\/sA2. for i=l:l:n taoxamax4(i)=t*taof v(i)*(exp(2*tan(phi)*lamdas(i)*P\/(Rt-Rc))); % maximum stress at driving side of flight according to stress analysis taoxamin4(i)=t*taof_v(i); % minimum stress at driving side of flight according to stress analysis lamdas_a=lamdas(i); % stress ratio of normal wall stress to axial stress on confined surface taoxa4(i)=l\/P*t*taof v(i)*quadl(@taoxh, 0,P); % average axial stress in a pitch for flow condition taoxai4(i)=l\/P*t*taoi_v*quadl(@taoxh, 0,P); % average axial stress in a pitch for initial condition taowa4(i)=lamdas(i)*taoxa4(i); % average normal wall stress in a pitch for flow condition taowai4(i)=lamdas(i)*taoxai4(i); % average normal wall in a pitch for initial condition %-1. shear surface ksa4(i)=pi*mue(i)*cp*cos(alphao+phif)-\/2; % parameter for axial force calculations on shear surface Fsaf4(i)=-ksa4(i).*taof_v(i).*Do.A2; % axial force on shear surface for flow condition Fsai4(i)=-ksa4(i)*tao _y*DoA2; % axial force on shear surface for initial condition Appendices 323 kst4(i)=pi*mue(i)*cp*sin(alphao+phif).\/2; % parameter for tangential force calculations on shear surface Fstf4(i)=-kst4(i).*taof_v(i)*DoA2; % tangential force on shear surface for flow condition Fsti4(i)=-kst4(i)*tao i_v*DoA2; % tangential force on shear surface for initial condition Fstfp_try4(i)=l\/2*(taof_v(i)+taowa4(i))*0.00635*P\/sin(alphao)*tan(phif); % tangential force from flight tips for flow condition Fstip_try4(i)=l\/2*(taoi_v+taowai4(i))*0.00635*P\/sin(alphao)*tan(phif); % tangential force from flight tips for initial condition Tstfp4(i)=Fstfptry4(i)*Ro; % torque from flight tips for flow condition Tstip4(i)=Fstip_try4(i)*Ro; % torque from flight tips for initial condition %-2. core shaft kca4(i)=t*pi*(ct-cd)*cd*cp*(exp(4*muwc*lamdas(i)*cp\/(ct-cd))-l)\/4\/(cpA2+piA2*cdA2)A0.5; % parameter for axial force calculations on core shaft surface Fcaf4(i)=-kca4(i)*taof_v(i)*DoA2; % axial force on core surface for flow condition Fcai4(i)=-kca4(i)*taoi_v*DoA2; % axial force on core surface for initial condition Fcal_try4(i)=2*pi*Rc*P*tan(phif)*taowa4(i)*sin(alphac); kct4(i)=t*piA2*(ct-cd)*cdA2*(exp(4*muwc*lamdas(i)*cp\/(ct-cd))-l)\/4\/(cpA2+piA2*cdA2)A0.5; % parameter for tangential force calculations on core shaft surface Fctf4(i)=kct4(i)*taof_v(i)*DoA2; % tangential force on core surface for flow condition Fcti4(i)=kct4(i)*taoi_v*DoA2; % tangential force on core surface for initial condition %-3. trailing flight side kfa4(i)=t*lamdas(i)*(pi*( 1 -cdA2)\/4+cp*muf*( 1 -cd)\/2); % parameter for axial force calculations on trailing side surface Ffaf4(i)=-kfa4(i)*taof_v(i)*DoA2; % axial force on trailing side surface for flow condition Ffai4(i)=-kfa4(i)*taoi_v*DoA2; % axial force on trailing side surface for initial condition Ffafl_try4(i)=2.*pi.*lamdas(i).*taoxamin4(i).*quadl(@trailing, Rc, Ro); % axial force on trailing side surface for flow condition kft4(i)=t*lamdas(i)*(pi*muf*( 1 -cdA2)\/4-cp*( 1 -cd)\/2); % parameter for tangential force calculations on trailing side surface Fftf4(i)=kft4(i)*taof_v(i)*DoA2; % tangential force on trailing side surface for flow condition Ffti4(i)=kft4(i)*taoi_v*DoA2; % tangential force on trailing side surface for initial condition %-4. trough surface kta4(i)=t*pi*(ct-cd)*ct*cos(alphao+phif)\/8*(exp(4*muwt*lamdas(i)*cp\/(ct-cd))-l); % parameter for axial force calculations on trough surface Ftaf4(i)=-kta4(i).*taof_v(i).*Do.A2; % axial force on trough surface for flow condition Ftai4(i)=-kta4(i)*taoi_v*DoA2; % axial force on trough surface for initial condition ktt4(i)=t*pi*(ct-cd)*ct*sin(alphao+phif)\/8*(exp(4*muwt*lamdas(i)*cp\/(ct-cd))-l); % parameter for tangential force calculations on trough surface Fttf4(i)=-ktt4(i)*taof_v(i)*DoA2; % tangential force on trough surface for flow condition Ftti4(i)=-ktt4(i)*taoi_v*DoA2; % tangential force on trough surface for initial condition %-5. stress on driving side Kda4(i)=4*(ksa4(i)+kca4(i)+kfa4(i)+kta4(i))\/pi\/(l-cdA2); % parameter for axial force calculations on driving side surface taodaf4(i)=Kda4(i)*taof_v(i); % compute axial stress on driving surface for flow condition tao_dai4(i)=Kda4(i)*taoi_v; % compute axial stress on driving surface for initial condition Ftao_daf4(i)=tao_daf4(i)*A_cross; % compute axial force on driving surface for flow condition Ftao_dai4(i)=tao_dai4(i)*A_cross; % compute axial force on driving surface for initial condition % torque calculation Tdf4(i)=2*pi*tao_daf4(i)*quadi(@integrnd_Td, Rc, Ro); % compute torque generated by driving side of screw for flow condition Tdi4(i)=2*pi*tao_dai4(,i)*quadl(@integrnd_Td, Rc, Ro); % compute torque generated by driving side of screw for initial condition Tcf4(i)=2*pi*Rc*P*taovva4(i)*tan(phif)*cos(alphac)*Rc; % compute torque generated by core shaft surface for flow condition Tci4(i)=2*pi*Rc*P*taowai4(i)*tan(phiO*cos(alphac)*Rc; % compute torque generated by core shaft surface for initial condition Tff4(i)=2*pi*lamdas(i)*t*taof_v(i)*quadl(@integrnd_Tf, Rc, Ro); % compute torque from trailing surface for flow condition Appendices 324 Tfl4(i)=2*pi*lamdas(i)*t*taoi_v*quadl(@integrnd_Tf, Rc, Ro); % compute torque from trailing surface for initial condition T_hopperf4(i)=L4\/P*(Tdf4(i)+Tcf4(i)+Tff4(i)+Tstfp4(i)); % compute total torque in hopper section for flow condition T_hopperi4(i)=L4\/P*(Tdi4(i)+Tci4(i)+Tfi4(i)+Tstip4(i)); % compute total torque in hopper section for initial condition ratioO 14(i)=taodaf4(i)\/taoxamax4(i); % ratio of stress on driving side to theoretical maximum stress in a pitch ratio024(i)=taoxa4(i)\/tao_daf4(i); % ratio of average axial stress to stress on driving side in a pitch end % % hopper total T_hopperf=T_hopperfl+T_hopperf2+T_hopperD+T_hopperf4; % compute total torque in hopper section for flow condition T_hopperi=T_hopperil+T_hopperi2+T_hopperi3+T_hopperi4; % compute total torque in hopper section for initial condition % . \u2014 . , . . . . \u2014 . . . % the fifth-in choke section P=0.08; %pitch,m Do=0.08; % screw diameter, m Ro \"Do\/2; % screw radius, m. Dc=0.0203; % screw core shaft diameter, m Rc=Dc\/2; % screw core shaft radius, m Dt=0.102; % trough diameter,m Rt=Dt\/2; % trough radius, m cp=P\/Do; % ratio of pitch to screw diameter. ct=Dt\/Do; % ratio of trough diameter to screw diameter. cd=Dc\/Do; % ratio of core shaft diameter to screw diameter. Lh=0.914; % hopper outlet length,m L5=0.305; % length of the screw with P=0.08 m and Dc=0.0203 m in choke section Lc=0.62 B=0.102; % width of trough,m A_cross=pi*(RoA2-RcA2); % effective cross section area of the screw casing alpha=20\/180*pi; % half hopper angle, radian g=9.8; % gravitational acceleration, m\/sA2. for i=l: 1 :n taoxamax5(i)=t*taof_v(i)*(exp(2*tan(phi)*Iamdas(i)*P\/(Rt-Rc))); % maximum stress at driving side of flight according to stress analysis taoxamin5(i)=t*taof_v(i); % minimum stress at driving side of flight according to stress analysis lamdas_a=lamdas(i); % stress ratio of normal wall stress to axial stress on confined surface taoxa5(i)=l\/P*t*taof_v(i)*quadl(@taoxh, 0,P); % average axial stress in a pitch for flow condition taowa5(i)=lamdas(i)*taoxa5(i); % average normal wall stress in a pitch for flow condition %-1. shear surface ksa5(i)=pi*mue(i)*cp*cos(alphao+phif).\/2; % parameter for axial force calculations on shear surface Fsaf5(i)=4csa5(i).*taof_v(i).*Do.A2; % axial force on shear surface for flow condition kst5(i)=pi*mue(i)*cp*sin(alphao+phif).\/2; % parameter for tangential force calculations on shear surface Fstf5(i)=-kst5(i).*taof_v(i)*DoA2; % tangential force on shear surface for flow condition FstfpJry5(i)=l\/2*(taof_v(i)+taowa5(i))*0.00635*P\/sin(alphao)*tan(phif); % tangential force from flight tips for flow condition Tstfp5(i)=Fstfp_try5(i)*Ro; % torque from flight tips for flow condition %-2. core shaft kca5(i)=t*pi*(ct-cd)*cd*cp*(exp(4*muwc*lamdas(i)*cp\/(ct-cd))-l)\/4\/(cpA2+piA2*cdA2)A0.5; % parameter for axial force calculations on core shaft surface Fcaf5(i)=-kca5(i)*taof_v(i)*DoA2; % axial force on core surface for flow condition Fcal_try5(i)=2*pi*Rc*P*tan(phif)*taowa5(i)*sin(alphac); kct5(i)=t*piA2*(ct-cd)*cdA2*(exp(4*muwc*lamdas(i)*cp\/(ct-cd))-l)\/4\/(cpA2+piA2*cdA2)A0.5; Appendices 325 % parameter for tangential force calculations on core shaft surface Fctf5(i)=kct5(i)*taofv(i)*DoA2; % tangential force on core surface for flow condition %-3. trailing flight side kfa5(i)=t*lamdas(i)*(pi*( 1 -cdA2)\/4+cp*muf*( l-cd)\/2); % parameter for axial force calculations on trailing side surface Ffaf5(i)=-kfa5(i)*taof_v(i)*DoA2; % axial force on trailing side surface for flow condition Ffafl_try5(i)=2.*pi.*lamdas(i).*taoxamin5(i).*quadl(@trailing, Rc, Ro); % axial force on trailing side surface for,flow condition kft5(i)=t*lamdas(i)*(pi*muf*(l-cdA2)\/4-cp*(l-cd)\/2); . -% parameter for tangential force calculations on trailing side surface Fftf5(i)=kft5(i)*taofv(i)*DoA2; % tangential force on trailing side surface for flow condition %-4. trough surface kta5(i)=t*pi*(ct-cd)*ct*cos(alphao+phif)\/8*(exp(4*muwt*lamdas(i)*cp\/(ct-cd))-l); % parameter for axial force calculations on trough surface Ftaf5(i)=-kta5(i).*taof v(i).*Do.A2; % axial force on trough surface for flow condition ktt5(i)=t*pi*(ct-cd)*ct*sin(alphao+phif)\/8*(exp(4*muwt*lamdas(i)*cp\/(ct-cd))-l); % parameter for tangential force calculations on trough surface Fttf5(i)=-ktt5(i)*taof_v(i)*DoA2; % tangential force on trough surface for flow condition %-5. stress on driving side Kda5(i)=4*(kca5(i)+kfa5(i)+2*kta5(i))\/pi\/(l-cdA2); % parameter for axial force calculations on driving side surface tao_daf5(i)=Kda5(i)*taof_v(i); % compute axial stress on driving surface for flow condition Ftao_daf5(i)=tao_daf5(i)*A_cross; % compute axial force on driving surface for flow condition % torque calculation Tdf5(i)=2*pi*tao_daf5(i)*quadl(@integrad_Td, Rc, Ro); % compute torque generated by driving side of the screw for flow condition Tcf5(i)=2*pi*Rc*P*taowa5(i)*tan(phif)*cos(alphac)*Rc; % compute torque generated by core shaft surface for flow condition Tff5(i)=2*pi*lamdas(i)*t*taof_v(i)*quadl(@integrnd_Tf, Rc, Ro); % compute torque from trailing surface for flow condition T_chokef5(i)=L5\/P*(Tdf5(i)+Tcf5(i)+Tff5(i)+Tstfp5(i)); % compute total torque in choke section5 for flow condition ratio015(i)=tao_daf5(i)\/taoxamax5(i); % ratio of stress on driving side to theoretical maximum stress in a pitch ratio025(i)=taoxa5(i)\/tao_daf5(i); % ratio of average axial stress to stress on driving side in a pitch end % % sixth stage of the screw-choke section P=0.07; % pitch,m Do=0.08; % screw diameter, m Ro=Do\/2; % screw radius, m. Dc=0.0203; % screw core shaft diameter, m Rc=Dc\/2; % screw core shaft radius, m Dt=0.102; % trough diameter,m Rt=Dt\/2; % trough radius, m cp=P\/Do; % ratio of pitch to screw diameter. ct=Dt\/Do; % ratio of trough diameter to screw diameter. cd=Dc\/Do; % ratio of core shaft diameter to screw diameter. Lh=0.914; % hopper outlet length,m L6=0.305; % length of the screw with 0.1 m screw diameter, a little shorter than outlet length, i.e. 0.914 m. Lc=0.62 B=0.102; % width of the trough,m A_c'ross=pi*(RoA2-RcA2) % effective cross section area of screw casing alpha=20\/180*pi; % half hopper angle, radian g=9.8; % gravitational acceleration, m\/sA2. fori=l:l:n taoxamax6(i)=t*taof_v(i)*(exp(2*tan(phi)*lamdas(i)*P\/(Rt-Rc))); Appendices 326 % maximum stress at driving side of flight according to stress analysis taoxamin6(i)=t*taof_v(i); % minimum stress at driving side of flight according to stress analysis lamdas_a=lamdas(i); % stress ratio of normal wall stress to axial stress on confined surface taoxa6(i)=l\/P*t*taof_v(i)*quadl(@taoxh, 0,P); % average axial stress in a pitch for flow condition taowa6(i)=lamdas(i)*taoxa6(i); % average normal wall stress in a pitch for flow condition %-1. shear surface ksa6(i)=pi*mue(i)*cp*cos(alphao+phif)\/2; % parameter for axial force calculations on shear surface Fsaf6(i)=-ksa6(i).*taof_v(i).*Do.A2; % axial force on shear surface for flow condition kst6(i)=pi*mue(i)*cp*sin(alphao+phif).\/2; % parameter for tangential force calculations on shear surface Fstf6(i)=-kst6(i).*taof_v(i)*DoA2; % tangential force on shear surface for flow condition Fstfp_try6(i)=l\/2*(taof_v(i)+taowa6(i))*0.00635*P\/sin(alphao)*tan(phif); % tangential force from flight tips for flow condition Tstfp6(i)=Fstfp_try6(i)*Ro; % torque from flight tips for flow condition %-2. core shaft kca6(i)=t*pi*(ct-cd)*cd*cp*(exp(4*muwc*lamdas(i)*cp\/(ct-cd))-l)\/4\/(cpA2+piA2*cdA2)A0.5; % parameter for axial force calculations on core shaft surface Fcaf6(i)=-kca6(i)*taof_v(i)*DoA2; % axial force on core surface for flow condition kct6(i)=t*piA2*(ct-cd)*cdA2*(exp(4*muwc*lamdas(i)*cp\/(ct-cd))-l)\/4\/(cpA2+piA2*cdA2)A0.5; % parameter for tangential force calculations on core shaft surface Fctf6(i)=kct6(i)*taof_v(i)*DoA2; % tangential force on core surface for flow condition %-3. trailing flight side kfa6(i)=t*lamdas(i)*(pi*(l-cdA2)\/4+cp*muP(l-cd)\/2); % parameter for axial force calculations on trailing side surface Ffaf6(i)=-kfa6(i)*taof_v(i)*DoA2; % axial force on trailing side surface for flow condition Ffafl_try6(i)=2.*pi.*lamdas(i).*taoxamin6(i).*quadl(@trailing, Rc, Ro); kft6(i)=t*lamdas(i)*(pi*muf*( 1 -cdA2)\/4-cp*( 1 -cd)\/2); % parameter for tangential force calculations on trailing side surface Fftf6(i)=kft6(i)*taof_v(i)*DoA2; % tangential force on trailing side surface for flow condition %-4. trough surface kta6(i)=t*pi*(ct-cd)*ct*cos(alphao+phif)\/8*(exp(4*muwt*lamdas(i)*cp\/(ct-cd))-l); % parameter for axial force calculations on trough surface Ftaf6(i)=-kta6(i).*taof_v(i).*Do.A2; % axial force on trough surface for flow condition ktt6(i)=t*pi*(ct-cd)*ct*sin(alphao+phif)\/8*(exp(4*muwt*lamdas(i)*cp\/(ct-cd))-l); % parameter for tangential force calculations on trough surface Fttf6(i)=-ktt6(i)*taof_v(i)*DoA2; % tangential force on trough surface for flow condition %-5. stress on driving side Kda6(i)=4*(kca6(i)+kfa6(i)+2*kta6(i))\/pi\/(l -cdA2); % parameter for axial force calculations on driving side surface tao_daf6(i)=Kda6(i)*taof_v(i); % compute axial stress on the driving surface for flow condition Ftao_daf6(i)=tao_daf6(i)*A_cross; % compute axial force on driving surface for flow condition % torque calculation Tdf6(i)=2*pi*tao_daf6(i)*quadl(@integrnd_Td, Rc, Ro); % compute torque generated by driving side of the screw for flow condition Tcf6(i)=2*pi*Rc*P*taowa6(i)*tan(phif)*cos(alphac)*Rc; % compute torque generated by core shaft surface for flow condition Tff6(i)=2*pi*lamdas(i)*t*taof_v(i)*quadl(@integrnd_Tf, Rc, Ro); % compute torque from trailing surface for flow condition T_chokef6(i)=L6\/P*(Tdf6(i)+Tcf6(i)+Tff6(i)+Tstfp6(i)); % compute total torque in choke section6 for flow condition ratioO 16(i)=tao_daf6(i)\/taoxamax6(i); % ratio of stress on driving side to theoretical maximum stress in a pitch ratio026(i)=taoxa6(i)\/tao_daf6(i); % ratio of average axial stress to stress on driving side in a pitch end % Tor_totalf=T_hopperf+T_chokef5+T_chokef6; % compute total torque for flow condition Tor_initial=T_hopperi; % compute total torque for initial condition % Appendices 327 ratio 1 =[ratioO 1 ratio012 ratio013 ratio014 ratioO 15 ratio016]; % ratios of stress on driving side to theoretical maximum stress in a pitch ratio2=[ratio02 ratio022 ratio023 ratio024 ratio025 ratio026]; % ratio of average axial stress to stress on driving side in a pitch taodft=[tao_dafl tao_daf2 taodaO tao_daf4 tao_daf5 tao_daf6]; % stresses on the driving side result=[taoi_v Fv_i taofvO(l) Fvju(l) taof_v(l) Fv_f(l) Torinitial(l) T_hopperf(l) T_chokef5(I) T chokef6(l) Tor_totalf(l)]; H-6: Functions for program Function: taoxave 1, taoxh, trailing, integrnd_Td, integrndTf and taotaper Source code: see below H-6-1: % compute average axial stress function y=taoxavel(x) global muwt lamdasa P Rt Rc CCC y=(exp(2*muwt *lamdas_a*P\/(Rt-Rc)))ACCC*exp(2*muwt*lamdas_a*(P-x)\/(Rt-Rc)); H-6-2: % compute average axial stress function y=taoxh(x) global muwt lamdasa P Rt Rc y=exp(2*muwt*lamdas_a*(P-x)\/(Rt-Rc)); H-6-3: % computer force on trailing side function y=trailing(x) global phifP y=x.*cos(phif-atan(P.\/(2.*pi.*x))).\/cos(atan(P.\/2.\/pi.\/x)).\/cos(phif); H-6-4: % compute torque on driving side function y=integrnd_Td(x) global P phif y=x,A2.*tan(atan(P.\/2.\/pi.\/x)+phif); %y=x A2.*(l+2.*pi.*muf.*x.\/P).\/(2.*pi.*x.\/P-mu0; H-6-5: % computer torque on trailing side function y=integrnd_Tf(x) global P muf phif y=x A2.*sin(phif-atan(P.\/(2.*pi.*x))).\/cos(atan(P.\/2.\/pi.\/x)).\/cos(phiO; %y=x.A2.*sin(atan(muf)-atan(P.\/2.\/pi.\/x)).\/cos(atan(P.\/.2.\/pi.\/x)).\/cos(atan(muf)); H-6-6: % computer torque for taper section function y=taotaper(x) global Httf Eftaoinf y=(x.\/Httf).A(Ef).*taoinf; ","@language":"en"}],"Genre":[{"@value":"Thesis\/Dissertation","@language":"en"}],"IsShownAt":[{"@value":"10.14288\/1.0058999","@language":"en"}],"Language":[{"@value":"eng","@language":"en"}],"Program":[{"@value":"Chemical and Biological Engineering","@language":"en"}],"Provider":[{"@value":"Vancouver : University of British Columbia Library","@language":"en"}],"Publisher":[{"@value":"University of British Columbia","@language":"en"}],"Rights":[{"@value":"For non-commercial purposes only, such as research, private study and education. Additional conditions apply, see Terms of Use https:\/\/open.library.ubc.ca\/terms_of_use.","@language":"en"}],"ScholarlyLevel":[{"@value":"Graduate","@language":"en"}],"Title":[{"@value":"Biomass granular feeding for gasification and combustion","@language":"en"}],"Type":[{"@value":"Text","@language":"en"}],"URI":[{"@value":"http:\/\/hdl.handle.net\/2429\/31282","@language":"en"}],"SortDate":[{"@value":"2007-12-31 AD","@language":"en"}],"@id":"doi:10.14288\/1.0058999"}