利用平衡单元进行两级高分辨率结构拓扑优化

IF 4.3 3区 材料科学 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC ACS Applied Electronic Materials Pub Date : 2024-10-17 DOI:10.1016/j.cad.2024.103811
Rafael Merli , Antolín Martínez-Martínez , Juan José Ródenas , Marc Bosch-Galera , Enrique Nadal
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引用次数: 0

摘要

在当今的工业领域,为满足客户要求而进行的优化机械部件的设计和开发工作发展迅速,这对企业来说是一项重大挑战。这些公司寻求高效的解决方案,以提高产品的刚度和强度。拓扑优化是一种强有力的方法,其目的是确定预定域内的最佳材料分布,以最大限度地提高整个部件的刚度。实现高分辨率解决方案对于准确定义最终材料分布也至关重要。虽然标准的拓扑优化工具可以为整个部件提出最佳解决方案,但由于计算成本过高,它们在处理小尺度细节(如小梁结构)时显得力不从心。为解决这一问题,我们提出了一种两级拓扑优化方法,其中考虑了基于密度的技术。建议的方法包括三个步骤:第一步,将整个部件细分为单元,生成粗略优化的低定义材料分布,并为每个单元分配不同的密度。由于粗略问题的输出应力没有均衡到每个单元,因此不能直接用于精细层面。因此,第二步使用平衡牵引恢复法将单元节点力转换为单元边界上的平衡横向牵引力。最后,将粗优化的密度作为输入数据,并将这些横向牵引力作为新曼边界条件,对每个单元进行精细优化。这项工作的主要目标是使用两级机械连续方法高效地解决高分辨率拓扑优化问题,而标准计算设施和现有技术是无法负担这一工作的。
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Two-Level High-Resolution Structural Topology Optimization with Equilibrated Cells
In today’s industry, the rapid evolution in the design and development of optimized mechanical components to meet customer requirements represents a significant challenge for companies. These companies seek efficient solutions to enhance their products in terms of stiffness and strength. One powerful approach is Topology Optimization, which aims to determine the optimal material distribution within a predefined domain to maximize the overall component’s stiffness. Achieving high-resolution solutions is also crucial for accurately defining the final material distribution. While standard Topology Optimization tools can propose optimal solutions for entire components, they struggle with small-scale details (such as trabecular structures) due to prohibitive computational costs. To address this issue, our proposed approach introduces a two-level topology optimization methodology considering density-based techniques. The proposed methodology includes three steps: The first one subdivides the whole component in cells and generates a coarse optimized low-definition material distribution, assigning a different density to each cell. Since the output stresses from the coarse problem are not equilibrated into each cell, they must not be directly used in the fine level. Thus, the second step uses the equilibrating traction recovery approach to convert the cell nodal forces into equilibrated lateral tractions over the cell boundary. Finally, taking as input data the densities from the coarse optimization and imposing these lateral tractions as Neumann boundary conditions, each cell is optimized at fine level. The main goal of this work is to efficiently solve high-resolution topology optimization problems using a two-level mechanically-continuous method, which would be unaffordable with standard computing facilities and the current techniques.
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CiteScore
7.20
自引率
4.30%
发文量
567
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