基于深度学习的汽车梁类件冲压回弹研究

doi:10.3969/j.issn.1004-132X.2023.07.010

摘要/Abstract

摘要： 提出了基于深度学习的汽车梁类零件回弹预测方法。基于二维回弹理论，将三维梁类零件离散为若干截面，采用双平面投影法和图像二值化方法，将梁类零件的截面曲线转换为神经网络模型可识别的双通道图像数据。基于拉丁超立方采样法对影响梁结构零件的冲压工艺参数及板料材料参数变量进行采样，通过CAE回弹仿真得到后续深度学习网络的训练样本。为研究梁结构在不同几何截面、材料参数、工艺参数作用下的回弹问题，采用基于LeNet-5、AlexNet、NiN的卷积神经网络模型作为几何截面识别模型，同时使用全连接神经网络模型耦合材料参数和工艺参数的方法，得到该梁类零件回弹算法模型。以某汽车梁类结构零件作为研究对象，基于高斯混合聚类将回弹样本分为小回弹、中等回弹、大回弹三个类型。将各类回弹样本分别通过回弹算法模型进行验证，结果表明，基于AlexNet的模型准确度最高，同时算法鲁棒性相较于其他两种也更强，更适合梁类件的回弹预测。

关键词: 梁类零件, 冲压回弹, 深度学习, 拉丁超立方采样, 高斯混合聚类

Abstract: A method was proposed herein for springback prediction of automobile beam parts based on deep learning. Based on the two-dimensional springback theory, the three-dimensional beam parts were discretized into several sections, and the cross-section curve of the beam parts was converted into a dual-channel image that could be recognized by neural network model using the method of double-plane projection and the image binarization method. Based on Latin hypercube sampling method, the stamping process parameters and sheet material parameters of the beam structure parts were sampled, and the subsequent deep learning network training samples were obtained by CAE springback simulation. In order to study the springback of beam structures under different geometric cross-sections, material parameters, and processing parameters, convolutional neural network models based on LeNet-5, AlexNet and NiN were used as geometric cross-section recognition models. Meanwhile, the fully connected neural network model was used to couple material parameters and processing parameters to obtain the springback algorithm model of beam parts. Car beam structural parts were taken as the research object. Based on Gaussian mixture clustering, the springback samples were divided into three types: small springback, medium springback, and large springback. Each type of springback sample was verified by the springback algorithm model. Verification results show that the deep learning model has the highest accuracy based on AlexNet, and the algorithms robustness is also stronger than that of the other two, which is more suitable for springback prediction of beam parts.

Key words: beam part, stamping springback, deep learning, Latin hypercube sampling, Gaussian mixture clustering

中图分类号:

TG156
U466

聂昕, 谭天, 申丹凤. 基于深度学习的汽车梁类件冲压回弹研究[J]. 中国机械工程, 2023, 34(07): 838-846.

NIE Xin, TAN Tian, SHEN Danfeng. Research on Stamping Springback of Automobile Beam Parts Based on Deep Learning[J]. China Mechanical Engineering, 2023, 34(07): 838-846.

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