Application of artificial neural networks for characterisation of formability properties of sheet metals

Imre Czinege, Dóra Harangozó
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Abstract

Artificial neural network models were developed to estimate forming limit diagrams from tensile test results based on our own experiments and data from the literature for steel and aluminium sheet metals. Experimental data were obtained from tensile tests and Nakazima tests. The input parameters used in the models were yield strength, ultimate tensile strength, uniform elongation, elongation at fracture, anisotropy coefficient and hardening exponent or combinations of these. The forming limit curves were defined by the measured minor and major strains using seven standard test specimens. After training the artificial neural network, the difference between measured and predicted results was evaluated by linear regression parameters and by the absolute errors. For steel sheet data taken from the literature, the estimated outputs of ANN models were compared with the results of empirical formulae developed by different authors. It was found that there was a high correlation coefficient between predicted and measured values for models using neural networks, which gave better approximations than other linear and non-linear models.

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人工神经网络在金属板材成形性能表征中的应用
基于我们自己的实验和文献中对钢和铝板材的拉伸试验结果,我们开发了人工神经网络模型来估计成形极限图。实验数据来自拉力试验和Nakazima试验。模型输入参数为屈服强度、极限抗拉强度、均匀伸长率、断裂伸长率、各向异性系数和硬化指数或这些参数的组合。采用7个标准试样,用测得的主、小应变定义了成形极限曲线。人工神经网络训练完成后,用线性回归参数和绝对误差来评价实测结果与预测结果的差值。对于从文献中获取的钢板数据,将人工神经网络模型的估计输出与不同作者开发的经验公式的结果进行比较。研究发现,神经网络模型的预测值与实测值之间存在较高的相关系数,与其他线性和非线性模型相比,神经网络模型具有更好的近似性。
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来源期刊
International Journal of Lightweight Materials and Manufacture
International Journal of Lightweight Materials and Manufacture Engineering-Industrial and Manufacturing Engineering
CiteScore
9.90
自引率
0.00%
发文量
52
审稿时长
48 days
期刊最新文献
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