Related papers: Data-driven multi-scale modeling and robust optimization of composite structure with uncertainty quantification

Data-driven multi-scale modeling and robust optimization of composite structure with uncertainty quantification

URL: http://arxiv.org/abs/2210.09055v2
Date: Fri, 4 Nov 2022 21:41:34 GMT
Title: Data-driven multi-scale modeling and robust optimization of composite structure with uncertainty quantification
Authors: Kazuma Kobayashi, Shoaib Usman, Carlos Castano, Dinesh Kumar, Syed Alam
Abstract summary: This chapter demonstrates advanced data-driven methods and outlines the capability that must be developed/added for the multi-scale modeling of advanced composite materials. It proposes a multi-scale modeling method for composite structures based on a finite element method (FEM) simulation driven by surrogate models/emulators.
Score: 0.42581756453559755
License: http://creativecommons.org/licenses/by/4.0/
Abstract: It is important to accurately model materials' properties at lower length scales (micro-level) while translating the effects to the components and/or system level (macro-level) can significantly reduce the amount of experimentation required to develop new technologies. Robustness analysis of fuel and structural performance for harsh environments (such as power uprated reactor systems or aerospace applications) using machine learning-based multi-scale modeling and robust optimization under uncertainties are required. The fiber and matrix material characteristics are potential sources of uncertainty at the microscale. The stacking sequence (angles of stacking and thickness of layers) of composite layers causes meso-scale uncertainties. It is also possible for macro-scale uncertainties to arise from system properties, like the load or the initial conditions. This chapter demonstrates advanced data-driven methods and outlines the specific capability that must be developed/added for the multi-scale modeling of advanced composite materials. This chapter proposes a multi-scale modeling method for composite structures based on a finite element method (FEM) simulation driven by surrogate models/emulators based on microstructurally informed meso-scale materials models to study the impact of operational parameters/uncertainties using machine learning approaches. To ensure optimal composite materials, composite properties are optimized with respect to initial materials volume fraction using data-driven numerical algorithms.

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