用于高效分析大型多级增量板材成型的数值模型

IF 3.3 Q2 ENGINEERING, MANUFACTURING

Journal of Manufacturing and Materials Processing Pub Date : 2023-12-22 DOI:10.3390/jmmp8010003

Yehia A. Abdel-Nasser, Ninshu Ma, Sherif Rashed, Kenji Miyamoto, Hirotaka Miwa

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引用次数: 0

摘要

增量式板材成型（ISF）是一种先进的柔性制造工艺，用于生产复杂的三维产品。与传统的冲压工艺不同，ISF 不需要任何高成本的专用模具。然而，大尺寸 ISF 工艺的数值计算耗时较长，而且其对 ISF 后因工具松开而产生的回弹的精度也无法满足工业需求。本文开发了一种先进的数值模型，该模型考虑了复杂的成形刀具路径、修剪和回弹，可有效模拟增量式板材成形过程的多阶段变形现象。考虑到工具路径、坯料材料属性、网格尺寸和边界条件的影响，研究了数值建模的精度和效率。通过一系列案例研究以及与实验结果的比较，可以看出具有运动学材料属性和适中元素尺寸（5 毫米）的数值模型可以很好地再现 ISF 的变形特征，并能为大尺寸 ISF 零件带来实用效率。

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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Numerical Modelling for Efficient Analysis of Large Size Multi-Stage Incremental Sheet Forming

Incremental sheet forming (ISF) is an advanced flexible manufacturing process to produce complex 3D products. Unlike the conventional stamping process, ISF does not require any high cost dedicated dies. However, numerical computation for large-size ISF processes is time-consuming, and its accuracy for spring back due to unclamping tools after ISF cannot satisfy industrial demand. In this paper, an advanced numerical model considering complicated forming tool paths, trimming, and spring back was developed to efficiently simulate the multi-stage deformation phenomena of incremental sheet forming processes. Numerical modeling accuracy and efficiency are investigated considering the influence of tool path, material properties of the blank, mesh size, and boundary conditions. Through a series of case studies and comparisons with experimental results, it is observed that the numerical model with kinematics material properties and a moderate element size (5 mm) may reproduce the deformation characteristics of ISF with good accuracy and can obtain practical efficiency for a large-size ISF part.

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