Design performance optimization of laser beam welded joints made for vehicle chassis application using deep neural network-based Krill Herd method

Q4 Materials Science

Welding International Pub Date : 2023-07-03 DOI:10.1080/09507116.2023.2233889

Sanjay S. Surwase, S. Bhosle

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引用次数: 0

Abstract

Abstract The welding to be performed must be defect free, offer lower residual stress and strain, be compact in size and withstand different load conditions. However, the existing investigations in this scenario are still not modernized. Therefore, in this study, a specific welding method called laser beam welding (LBW) is performed and different weld parameters have been inspected and analysed. Advanced instruments based on the non-destructive (ND) are implemented to find the variable LBW responses such as weld bead defects, residuals and strain. The experimentation has been designed using Design Expert software, response surface methodology (RSM) and Box Behnken design (BBD) and verified by analysis of variance (ANOVA) analysis and FIT statistics. Moreover, a hybrid deep neural network-based Krill Herd optimization (DNN-KHO) is implemented to predict the output parameters like, undercut (µm), overlap (µm), total strain (mm/mm) and residual stress (MPa) during welding. The proposed DNN-KHO was also used to optimize LBW input parameters such as, peak power (W), weld speed (mm/s), gas flow rate (l/min) and beam diameter (µm) simultaneously. Predictions show that the proposed DNN-KHO algorithm outperformed by 21.53%, 45.428% and 41.31% higher in accuracy compared to respective hybrid random forest based grey wolf method (RF-GWO), RF and DNN predictions.

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基于深度神经网络的Krill Herd方法优化汽车底盘激光焊接接头设计性能

要进行的焊接必须是无缺陷的，提供较低的残余应力和应变，紧凑的尺寸和承受不同的负载条件。然而，在这种情况下的现有调查仍然没有现代化。因此，本研究采用了一种特殊的焊接方法——激光束焊接(LBW)，并对不同的焊接参数进行了检测和分析。采用基于无损检测技术的先进仪器，对焊缝缺陷、残余和应变等LBW变量响应进行了检测。实验采用Design Expert软件、响应面法(response surface methodology, RSM)和Box Behnken设计(Box Behnken Design, BBD)进行设计，并采用方差分析(ANOVA)和FIT统计进行验证。此外，实现了基于混合深度神经网络的Krill Herd优化(DNN-KHO)，以预测焊接过程中切边(µm)、重叠(µm)、总应变(mm/mm)和残余应力(MPa)等输出参数。同时，利用DNN-KHO算法对峰值功率(W)、焊接速度(mm/s)、气体流速(l/min)和光束直径(µm)等LBW输入参数进行优化。预测结果表明，与基于混合随机森林的灰狼方法(RF- gwo)、RF和DNN预测相比，提出的DNN- kho算法的准确率分别提高了21.53%、45.428%和41.31%。

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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来源期刊

Welding International Materials Science-Metals and Alloys

CiteScore

0.70

自引率

0.00%

发文量

期刊介绍： Welding International provides comprehensive English translations of complete articles, selected from major international welding journals, including: Journal of Japan Welding Society - Japan Journal of Light Metal Welding and Construction - Japan Przeglad Spawalnictwa - Poland Quarterly Journal of Japan Welding Society - Japan Revista de Metalurgia - Spain Rivista Italiana della Saldatura - Italy Soldagem & Inspeção - Brazil Svarochnoe Proizvodstvo - Russia Welding International is a well-established and widely respected journal and the translators are carefully chosen with each issue containing a balanced selection of between 15 and 20 articles. The articles cover research techniques, equipment and process developments, applications and material and are not available elsewhere in English. This journal provides a valuable and unique service for those needing to keep up-to-date on the latest developments in welding technology in non-English speaking countries.