Physically constrained 3D diffusion for inverse design of fiber-reinforced polymer composite materials

IF 12.7 1区材料科学 Q1 ENGINEERING, MULTIDISCIPLINARY

Composites Part B: Engineering Pub Date : 2025-04-23 DOI:10.1016/j.compositesb.2025.112515

Pei Xu , Yunpeng Wu , Alireza Zarei , Shahriar Ahmed , Srikanth Pilla , Gang Li , Feng Luo

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引用次数: 0

Abstract

Designing fiber-reinforced polymer composites (FRPCs) with a tailored nonlinear stress-strain response is crucial for applications such as energy absorption in crash structures, flexible robotics, and impact-resistant protective gear. However, the inherent complexities of composite materials and the multitude of parameters involved, render traditional design and optimization methods inadequate for achieving effective inverse design of composites. In this paper, we present an AI-based inverse design framework that effectively and efficiently generates FRPCs with targeted nonlinear stress-strain responses. We introduce a physically constrained diffusion model (PC3D_Diffusion) capable of managing the complexities of composite materials and producing detailed, high-quality designs. We propose a loss-guided, learning-free approach to generate physically feasible microstructure designs by explicitly enforcing physical constraints during the generation process. For training purposes, 1.35 million FRPC samples were created, and their corresponding stress-strain curves were computed using established physics-based computational models. The results show that PC3D_Diffusion consistently generates high-quality designs with tailored mechanical behaviors, while guaranteeing compliance with the physical constraints. PC3D_Diffusion advances FRPC inverse design and may facilitate the inverse design of other 3D materials, offering potential applications in industries reliant on materials with custom mechanical properties.

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基于物理约束的三维扩散纤维增强聚合物复合材料逆向设计

设计具有定制非线性应力应变响应的纤维增强聚合物复合材料（frpc）对于碰撞结构的能量吸收、柔性机器人和抗冲击防护装置等应用至关重要。然而，复合材料固有的复杂性和涉及的众多参数使得传统的设计和优化方法无法实现有效的复合材料反设计。在本文中，我们提出了一个基于人工智能的反设计框架，可以有效地生成具有目标非线性应力-应变响应的frpc。我们引入了一种物理约束扩散模型（PC3D_Diffusion），能够管理复合材料的复杂性，并产生详细的、高质量的设计。我们提出了一种损失导向、无学习的方法，通过在生成过程中明确地实施物理约束来生成物理上可行的微观结构设计。为了训练目的，我们制作了135万个FRPC样品，并利用建立的基于物理的计算模型计算了相应的应力-应变曲线。结果表明，PC3D_Diffusion在保证符合物理约束的同时，始终能够生成具有定制力学行为的高质量设计。PC3D_Diffusion推进了FRPC的逆向设计，并可能促进其他3D材料的逆向设计，在依赖于具有定制机械性能的材料的行业中提供潜在的应用。

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

Composites Part B: Engineering 工程技术-材料科学：复合

CiteScore

24.40

自引率

11.50%

发文量

784

审稿时长

21 days

期刊介绍： Composites Part B: Engineering is a journal that publishes impactful research of high quality on composite materials. This research is supported by fundamental mechanics and materials science and engineering approaches. The targeted research can cover a wide range of length scales, ranging from nano to micro and meso, and even to the full product and structure level. The journal specifically focuses on engineering applications that involve high performance composites. These applications can range from low volume and high cost to high volume and low cost composite development. The main goal of the journal is to provide a platform for the prompt publication of original and high quality research. The emphasis is on design, development, modeling, validation, and manufacturing of engineering details and concepts. The journal welcomes both basic research papers and proposals for review articles. Authors are encouraged to address challenges across various application areas. These areas include, but are not limited to, aerospace, automotive, and other surface transportation. The journal also covers energy-related applications, with a focus on renewable energy. Other application areas include infrastructure, off-shore and maritime projects, health care technology, and recreational products.