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Uncertainty-Based Design : Finite Element and Explainable Machine Learning Modeling of Carbon–Carbon Composites for Ultra-High Temperature Solar Receivers Daghigh, Vahid; Daghigh, Hamid; Keller, Michael W.
Abstract
Design under uncertainty has significantly grown in research developments during the past decade. Additionally, machine learning (ML) and explainable ML (XML) have offered various opportunities to provide reliable predictable models. The current article investigates the use of finite element modeling (FEM), ML and XML predictions, and uncertain-based design of carbon-carbon (C-C) composites for use in ultra-high temperatures. A C-C composite concentrating solar power (CSP) as a microvascular receiver is considered as a case study. These C-C composites are fiber composites with directly integrated carbonized microchannels to form a lightweight, high-absorptivity material that includes an embedded microvascular network of channels. The topology of these microchannels is engineered to optimize heat transfer to a supercritical carbon dioxide (sCO²) heat transfer fluid. The mechanical characterization of C-C composites is highly challenging. Thus, designing every component made of C-C composites for ultra-high temperature applications needs an uncertainty-based analysis. As a part of a comprehensive project on the development of a novel carbonized microvascular C-C composite, this paper explores C-C composite sensitivity analysis, FEM, ML prediction, and XML analysis. The resulting composite can then be carbonized and coated with an oxidation-resistant coating to form a thermally efficient and mechanically robust C-C composite. An ANSYS 3-D-FE model was used to analyze the CSP’s stress/strain. To consider the variability in the mechanical and thermal properties of C-C composites, various mechanical properties are considered as the ANSYS FEM’s input. A synthetic dataset from 730 ANSYS runs was produced to feed into the ML and XML algorithms for uncertainty analysis and prediction. The ML and XML algorithms could accurately predict the CSP stresses/strains.
Item Metadata
| Title |
Uncertainty-Based Design : Finite Element and Explainable Machine Learning Modeling of Carbon–Carbon Composites for Ultra-High Temperature Solar Receivers
|
| Creator | |
| Publisher |
Multidisciplinary Digital Publishing Institute
|
| Date Issued |
2025-02-23
|
| Description |
Design under uncertainty has significantly grown in research developments
during the past decade. Additionally, machine learning (ML) and explainable ML (XML)
have offered various opportunities to provide reliable predictable models. The current
article investigates the use of finite element modeling (FEM), ML and XML predictions,
and uncertain-based design of carbon-carbon (C-C) composites for use in ultra-high temperatures.
A C-C composite concentrating solar power (CSP) as a microvascular receiver
is considered as a case study. These C-C composites are fiber composites with directly
integrated carbonized microchannels to form a lightweight, high-absorptivity material
that includes an embedded microvascular network of channels. The topology of these
microchannels is engineered to optimize heat transfer to a supercritical carbon dioxide
(sCO²) heat transfer fluid. The mechanical characterization of C-C composites is highly
challenging. Thus, designing every component made of C-C composites for ultra-high
temperature applications needs an uncertainty-based analysis. As a part of a comprehensive
project on the development of a novel carbonized microvascular C-C composite, this
paper explores C-C composite sensitivity analysis, FEM, ML prediction, and XML analysis.
The resulting composite can then be carbonized and coated with an oxidation-resistant
coating to form a thermally efficient and mechanically robust C-C composite. An ANSYS
3-D-FE model was used to analyze the CSP’s stress/strain. To consider the variability in
the mechanical and thermal properties of C-C composites, various mechanical properties
are considered as the ANSYS FEM’s input. A synthetic dataset from 730 ANSYS runs was
produced to feed into the ML and XML algorithms for uncertainty analysis and prediction.
The ML and XML algorithms could accurately predict the CSP stresses/strains.
|
| Subject | |
| Genre | |
| Type | |
| Language |
eng
|
| Date Available |
2025-05-02
|
| Provider |
Vancouver : University of British Columbia Library
|
| Rights |
CC BY 4.0
|
| DOI |
10.14288/1.0448724
|
| URI | |
| Affiliation | |
| Citation |
Journal of Composites Science 9 (3): 100 (2025)
|
| Publisher DOI |
10.3390/jcs9030100
|
| Peer Review Status |
Reviewed
|
| Scholarly Level |
Faculty; Researcher
|
| Rights URI | |
| Aggregated Source Repository |
DSpace
|
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CC BY 4.0