人工神经网络在铝钢爆炸包壳抗拉和抗剪强度预测中的应用

Q4 Engineering

Academic Journal of Manufacturing Engineering Pub Date : 2023-03-01 DOI:10.37255/jme.v18i1pp026-029

Saravanan., Kumararaja K

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引用次数: 0

摘要

在本研究中，建立了人工神经网络(ANN)模型来预测铝不锈钢爆炸包壳的抗拉和抗剪强度。改变爆炸包覆过程的装填比(炸药与飞片质量比0.6 ~ 1.0)、离爆距离(5 ~ 9 mm)、预设角度(0°~ 10°)、底板槽(V/Dovetail)等参数。人工神经网络算法在Python中训练，使用从80%的实验(60)、试验和先前结果中收集的拉伸和剪切强度。利用剩余的实验结果对构建的模型进行评价。人工神经网络模型成功地预测了抗拉和抗剪强度，与实验结果的误差小于10%。

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Performance of ANN in Predicting the Tensile and Shear Strength of Al-Steel Explosive Clads

In this study, an artificial neural network (ANN) model is created to predict aluminium-stainless steel explosive clads' tensile and shear strengths. The parameters for the explosive cladding process, such as the loading ratio (mass ratio of the explosive and the flyer, 0.6-1.0), standoff distance (5-9 mm), preset angle (0°-10°), and groove in the base plate (V/Dovetail), were altered. The ANN algorithm was trained in Python using the tensile and shear strengths gathered from 80% of the experiments (60), trials, and prior results. The constructed model was evaluated utilizing the remaining experimental results. The ANN model successfully predicts the tensile and shear strengths with an accuracy of less than 10% deviation from the experimental result.

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来源期刊

Academic Journal of Manufacturing Engineering Engineering-Industrial and Manufacturing Engineering

CiteScore

0.40

自引率

0.00%

发文量