A mesh-based geometric deep learning framework for rapid response prediction of large-scale and multi-component mechanical structures in engineering

IF 7.3 1区工程技术 Q1 ENGINEERING, MULTIDISCIPLINARY

Computer Methods in Applied Mechanics and Engineering Pub Date : 2025-10-07 DOI:10.1016/j.cma.2025.118435

Gongxi Zhang, Ying Liu, Yi Quan, Junfei Yan

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引用次数: 0

Abstract

Mesh-based finite element method (FEM) plays a critical role in simulating structural response. However, the analysis of complex physical processes, such as vehicle crashworthiness, is hindered by inherent high nonlinearities and large-scale meshes, leading to significant computational overhead and impeding rapid structure design. In recent years, the use of machine learning (ML) or deep learning (DL) methods to build surrogate models for simulations has gained much attention, which offers the potential to drastically reduce computational time while preserving accuracy. In this paper, we develop an end-to-end and mesh-based geometric DL framework that takes finite element (FE) solver files (such as.k file for LS-Dyna) containing mesh and material information as input, and quickly outputs response prediction of large-scale and multi-component mechanical structures in engineering, thus serving a promising alternative to FE solvers. We innovatively introduce the graph self-supervised learning (SSL) to transform FE data of structural component with varied material properties, complex geometric shapes and arbitrary number of unstructured meshes into low-dimensional embeddings, which are then employed to build an equivalent small-scale graph representation of the large-scale assembly, effectively alleviating the computational costs of subsequent prediction models. Then, we present GNN-FNN and GNN-Transformer models specifically designed for three different prediction tasks, including forecasting static and dynamic structural performance metrics, and constructing time-dependent physical fields. Using a large-scale industrial case of the electric vehicle (EV) under side pole impact, three regression tasks are carried out to assess the effectiveness of the proposed approach. Results reveal that the non-parametric model, free from the need for manually defined explicit parameters, excels in extracting implicit parameters for diverse structures, which support satisfactory prediction accuracy in each task with a considerable speedup than the simulation. Besides, it is surprising that our model is weakly sensitive to the moderate variation in the mesh resolution, which is valuable for practical engineering applications. The adaptability and scalability of our method are further verified on three additional industrial cases with varied structural simulation scenarios and progressively increasing FE model complexity. This work offers an effective surrogate model to accelerate the response evaluation of mechanical structures in engineering and shorten the design cycle requiring iterative optimization.

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基于网格的几何深度学习框架，用于工程中大型多构件机械结构的快速响应预测

基于网格的有限元法在结构响应模拟中起着至关重要的作用。然而，复杂物理过程的分析，如车辆耐撞性，受到固有的高非线性和大规模网格的阻碍，导致巨大的计算开销，阻碍了快速的结构设计。近年来，使用机器学习（ML）或深度学习（DL）方法来构建模拟的代理模型受到了广泛关注，这有可能在保持准确性的同时大幅减少计算时间。在本文中，我们开发了一个端到端和基于网格的几何深度学习框架，该框架采用有限元（FE）求解器文件(如。k文件（LS-Dyna）包含网格和材料信息作为输入，并快速输出工程中大型和多部件机械结构的响应预测，从而为有限元求解器提供了一个有希望的替代方案。我们创新地引入了图自监督学习（SSL），将具有不同材料特性、复杂几何形状和任意数量非结构化网格的结构部件的有限元数据转换为低维嵌入，然后利用这些嵌入构建等效的大规模装配的小尺度图表示，有效地降低了后续预测模型的计算成本。然后，我们提出了专门为三种不同预测任务设计的GNN-FNN和GNN-Transformer模型，包括预测静态和动态结构性能指标，以及构建与时间相关的物理场。以电动汽车侧极碰撞的大规模工业案例为例，进行了三个回归任务来评估所提出方法的有效性。结果表明，非参数模型不需要手动定义显式参数，在提取不同结构的隐式参数方面表现出色，在每个任务中都有令人满意的预测精度，而且速度比仿真模型快得多。此外，令人惊讶的是，我们的模型对网格分辨率的适度变化很弱，这在实际工程应用中是有价值的。在另外三个具有不同结构仿真场景和逐步增加的有限元模型复杂度的工业案例中，进一步验证了该方法的适应性和可扩展性。为加快工程中机械结构的响应评估，缩短需要迭代优化的设计周期提供了有效的替代模型。

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

Computer Methods in Applied Mechanics and Engineering 工程技术-工程：综合

CiteScore

12.70

自引率

15.30%

发文量

719

审稿时长

44 days

期刊介绍： Computer Methods in Applied Mechanics and Engineering stands as a cornerstone in the realm of computational science and engineering. With a history spanning over five decades, the journal has been a key platform for disseminating papers on advanced mathematical modeling and numerical solutions. Interdisciplinary in nature, these contributions encompass mechanics, mathematics, computer science, and various scientific disciplines. The journal welcomes a broad range of computational methods addressing the simulation, analysis, and design of complex physical problems, making it a vital resource for researchers in the field.