Application of artificial neural network to predict Vickers microhardness of AA6061 friction stir welded sheets 被引量：5

Application of artificial neural network to predict Vickers microhardness of AA6061 friction stir welded sheets

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摘要 The application of friction stir welding(FSW) is growing owing to the omission of difficulties in traditional welding processes. In the current investigation, artificial neural network(ANN) technique was employed to predict the microhardness of AA6061 friction stir welded plates. Specimens were welded employing triangular and tapered cylindrical pins. The effects of thread and conical shoulder of each pin profile on the microhardness of welded zone were studied using tow ANNs through the different distances from weld centerline. It is observed that using conical shoulder tools enhances the quality of welded area. Besides, in both pin profiles threaded pins and conical shoulders increase yield strength and ultimate tensile strength. Mean absolute percentage error(MAPE) for train and test data sets did not exceed 5.4% and 7.48%, respectively. Considering the accurate results and acceptable errors in the models' responses, the ANN method can be used to economize material and time. The application of friction stir welding （FSW） is growing owing to the omission of difficulties in traditional welding processes. In the current investigation, artificial neural network （ANN） technique was employed to predict the microhardness of AA6061 friction stir welded plates. Specimens were welded employing triangular and tapered cylindrical pins. The effects of thread and conical shoulder of each pin profile on the microhardness of welded zone were studied using tow ANNs through the different distances from weld centerline. It is observed that using conical shoulder tools enhances the quality of welded area. Besides, in both pin profiles threaded pins and conical shoulders increase yield strength and ultimate tensile strength. Mean absolute percentage error （MAPE） for train and test data sets did not exceed 5.4% and 7.48%, respectively. Considering the accurate results and acceptable errors in the models’ responses, the ANN method can be used to economize material and time.

作者 Vahid Moosabeiki Dehabadi Saeede Ghorbanpour Ghasem Azimi

机构地区 Department of Mechanical Engineering Educational Workshop Center

出处《Journal of Central South University》 SCIE EI CAS CSCD 2016年第9期2146-2155,共10页 中南大学学报（英文版）

关键词 friction stir welding artificial neural network aluminum 6061 alloy Vickers microhardness 人工神经网络方法摩擦搅拌焊接神经网络预测搅拌摩擦焊显微硬度应用薄板极限拉伸强度

分类号 TG453.9 [金属学及工艺—焊接] TS941.732 [轻工技术与工程—服装设计与工程]

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