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Robot-based research on three-layer oriented flakeboards Wang, Kaiyuan
Abstract
The rapid development and continued worldwide production growth of Oriented Strand Board (OSB) since the early 1980's has led to the realization that the better understanding and improved of the theoretical description of OSB manufacturing processes are important. This knowledge is needed to improve the present day mat forming, quality control technology and effective design and engineering of the next generation of composite wood products. Horizontal density distribution (HDD) is one of the most important factors determining the presence of voids and high density areas inside mat that greatly influences the board properties. However the formation mechanism of HDD and how it influences the panel properties are not fully understood. This project focuses on studying the influence of the spatial organization of wood elements inside a three-layer oriented flake mat on the manufacturing process, HDD, and end-use properties of OSB. Unlike previous studies with limitation of one or two variables at one time which results in difficulties when comparing and applying the results to production practices, this study reveals the combined effect of three important processing parameters — flake slenderness ratio, flake orientation, and panel density on panel properties. Also, with the help of a robot mat formation system and a X-ray machine, the mat simulation model established by Dai and Steiner (1994) is verified. The research program was divided into two parts. A pilot study was conducted first to verify the possibility of using a robot mat formation system to manufacture panels. Four types of structures structures with different face-to-core ratios and core flake arrangements for three-layered OSB were formed using the robot as a tool. The panels were then hot-pressed and tested for horizontal density distribution (HDD), bending modulus of elasticity (MOE), internal bond (IB) and thickness swelling (TS). Linked with the existing panel simulation program and X-ray density data, a suitable panel structure was selected for further research. The results showed that the programmed robot formed panels with well-defined and reproducible structures. Also the validity of the simulation program describing the 2-dimensional mat structure is verified by robot-made mats. The second part of the study involved the use of Response Surface Method (RSM) to study the relationship between strength and physical properties of robot formed panels and the defined structure of the panels with different combinations of three processing parameters, namely, flake slenderness ratio, flake orientation and panel density. Regression models were established relating each panel property including MOE, MOR, IB and TS with flake aspect ratio, flake orientation and panel density. Results indicated that nonlinear models capable of including interactions were required to relate the three factors studied to panel properties. By applying FIACCO AND McCORMICK (SUMT Algorithm) and Linear Combination method, an optimization model is developed. The best combination of the three factors which can provide the optimum overall properties of the panels studied in the project is: 143 for slenderness ratio, 0° for flake orientation angle and 0.6g/cm³ for board density.
Item Metadata
| Title |
Robot-based research on three-layer oriented flakeboards
|
| Creator | |
| Publisher |
University of British Columbia
|
| Date Issued |
1997
|
| Description |
The rapid development and continued worldwide production growth of Oriented Strand Board
(OSB) since the early 1980's has led to the realization that the better understanding and
improved of the theoretical description of OSB manufacturing processes are important. This
knowledge is needed to improve the present day mat forming, quality control technology and
effective design and engineering of the next generation of composite wood products. Horizontal
density distribution (HDD) is one of the most important factors determining the presence of
voids and high density areas inside mat that greatly influences the board properties. However the
formation mechanism of HDD and how it influences the panel properties are not fully
understood.
This project focuses on studying the influence of the spatial organization of wood elements
inside a three-layer oriented flake mat on the manufacturing process, HDD, and end-use
properties of OSB. Unlike previous studies with limitation of one or two variables at one time
which results in difficulties when comparing and applying the results to production practices, this
study reveals the combined effect of three important processing parameters — flake slenderness
ratio, flake orientation, and panel density on panel properties. Also, with the help of a robot mat
formation system and a X-ray machine, the mat simulation model established by Dai and Steiner
(1994) is verified.
The research program was divided into two parts. A pilot study was conducted first to verify the
possibility of using a robot mat formation system to manufacture panels. Four types of structures
structures with different face-to-core ratios and core flake arrangements for three-layered OSB
were formed using the robot as a tool. The panels were then hot-pressed and tested for horizontal
density distribution (HDD), bending modulus of elasticity (MOE), internal bond (IB) and
thickness swelling (TS). Linked with the existing panel simulation program and X-ray density
data, a suitable panel structure was selected for further research. The results showed that the
programmed robot formed panels with well-defined and reproducible structures. Also the
validity of the simulation program describing the 2-dimensional mat structure is verified by
robot-made mats.
The second part of the study involved the use of Response Surface Method (RSM) to study the
relationship between strength and physical properties of robot formed panels and the defined
structure of the panels with different combinations of three processing parameters, namely,
flake slenderness ratio, flake orientation and panel density. Regression models were established
relating each panel property including MOE, MOR, IB and TS with flake aspect ratio, flake
orientation and panel density. Results indicated that nonlinear models capable of including
interactions were required to relate the three factors studied to panel properties. By applying
FIACCO AND McCORMICK (SUMT Algorithm) and Linear Combination method, an
optimization model is developed. The best combination of the three factors which can provide
the optimum overall properties of the panels studied in the project is: 143 for slenderness ratio,
0° for flake orientation angle and 0.6g/cm³ for board density.
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| Extent |
9095761 bytes
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| Genre | |
| Type | |
| File Format |
application/pdf
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| Language |
eng
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| Date Available |
2009-04-16
|
| Provider |
Vancouver : University of British Columbia Library
|
| Rights |
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.
|
| DOI |
10.14288/1.0088117
|
| URI | |
| Degree | |
| Program | |
| Affiliation | |
| Degree Grantor |
University of British Columbia
|
| Graduation Date |
1997-11
|
| Campus | |
| Scholarly Level |
Graduate
|
| Aggregated Source Repository |
DSpace
|
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Rights
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.