Efficient multi-objective optimization of composite microstructures for thermal protection systems

IF 7.1 2区材料科学 Q1 MATERIALS SCIENCE, COMPOSITES

Composite Structures Pub Date : 2025-09-23 DOI:10.1016/j.compstruct.2025.119679

Idan Distelfeld, Shmuel Osovski

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引用次数: 0

Abstract

This paper presents a surrogate model-based approach for multi-objective optimization of composite representative volume elements under thermo-mechanical loading. The RVE architecture, inspired by metallic honeycomb structures with inclined fibers, allows tailoring the anisotropy of thermal and mechanical properties. A parametric model is analyzed using Finite Element Analysis with periodic boundary conditions and homogenization theory. The 10-dimensional design space is sampled using Latin Hypercube Sampling, and simulated to calculate effective elastic moduli and thermal conductivity. This dataset is used to train a shallow neural network (SNN) model, offering computational efficiency and rapid exploration of complex design spaces. The SNN is employed in a multi-objective optimization process using the NSGA-II algorithm, allowing simultaneous optimization of elastic properties, thermal conductivity, and density. This reveals trade-offs between competing objectives, with resulting Pareto frontiers providing crucial information for informed design decisions. The method demonstrates a fast, accurate, and flexible approach for optimizing composite architectures. Combining advanced modeling techniques with efficient optimization algorithms, this work contributes to developing lightweight, multifunctional materials for aerospace, automotive, and other demanding applications. The approach has significant implications for optimizing composite materials in complex structures, advancing the state-of-the-art in composite materials research and providing a powerful tool for high-performance material design.

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热防护系统复合微结构的高效多目标优化

提出了一种基于代理模型的复合材料代表性体积元热-机械载荷多目标优化方法。RVE建筑的灵感来自金属蜂窝结构和倾斜纤维，可以定制热性能和机械性能的各向异性。采用周期边界条件和均匀化理论对参数化模型进行了有限元分析。采用拉丁超立方采样法对10维设计空间进行采样，并对其进行模拟，计算有效弹性模量和导热系数。该数据集用于训练浅层神经网络（SNN）模型，提供计算效率和对复杂设计空间的快速探索。SNN采用NSGA-II算法进行多目标优化，可同时优化弹性性能、导热性和密度。这揭示了竞争目标之间的权衡，由此产生的帕累托边界为明智的设计决策提供了关键信息。该方法为优化复合体系结构提供了一种快速、准确、灵活的方法。将先进的建模技术与高效的优化算法相结合，这项工作有助于开发用于航空航天、汽车和其他苛刻应用的轻质多功能材料。该方法对复杂结构复合材料的优化、复合材料研究的进步以及高性能材料的设计都具有重要意义。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Composite Structures 工程技术-材料科学：复合

CiteScore

12.00

自引率

12.70%

发文量

1246

审稿时长

78 days

期刊介绍： The past few decades have seen outstanding advances in the use of composite materials in structural applications. There can be little doubt that, within engineering circles, composites have revolutionised traditional design concepts and made possible an unparalleled range of new and exciting possibilities as viable materials for construction. Composite Structures, an International Journal, disseminates knowledge between users, manufacturers, designers and researchers involved in structures or structural components manufactured using composite materials. The journal publishes papers which contribute to knowledge in the use of composite materials in engineering structures. Papers deal with design, research and development studies, experimental investigations, theoretical analysis and fabrication techniques relevant to the application of composites in load-bearing components for assemblies, ranging from individual components such as plates and shells to complete composite structures.