Optimization of process parameters of cold metal transfer arc welding of AA 6061 aluminium Alloy-AZ31B magnesium alloy dissimilar joints using response surface methodology

Prasanna Nagasai Bellamkonda , Ramaswamy Addanki , Malarvizhi Sudersanan , Balasubramanian Visvalingam , Maheshwar Dwivedy
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Abstract

The fabrication of dissimilar metal joints, particularly between AA 6061 aluminum alloy (Al) and AZ31B magnesium alloy (Mg), poses significant technical challenges due to their distinct metallurgical characteristics and the inherent difficulties associated with welding such materials. These challenges include the propensity for intermetallic compound formation, thermal cracking, and differences in thermal and mechanical properties between the two alloys. Cold Metal Transfer (CMT) welding, known for its low heat input and controlled metal transfer, offers a potential solution to these issues. However, optimizing the process parameters to ensure strong, defect-free joints requires a systematic approach. This study aims to optimize CMT welding parameters using parametric mathematical modeling (PMM) to produce high-strength Al and Mg dissimilar joints and to study the effects of CMT parameters on tensile strength (TS) and weld metal hardness (WMH), as well as the microstructural features of AA 6061 aluminum alloy/AZ31B magnesium alloy (Al/Mg) dissimilar joints. Al/Mg dissimilar butt joints were produced by the CMT process using ER4043 as filler wire. CMT, a low-heat input welding technique, was used to mitigate issues such as intermetallic compounds (IMCs), wider heat-affected zone (HAZ), and distortion. The CMT parameters, particularly wire feed speed (WFS), welding speed (WS), and arc length correction (ALC), were optimized using response surface methodology (RSM) to maximize the TS and WMH of the Al/Mg dissimilar joints. Polynomial regression was employed to create PMMs that integrated these CMT parameters to forecast the TS and WMH of the joints. An analysis of variance (ANOVA) was applied to assess the feasibility of the PMMs. The results indicated that the Al/Mg dissimilar joints, produced using a WFS of 4700 mm/min, a WS of 280 mm/min, and an ALC of 10%, exhibited higher TS and WMH values of 33 MPa and 95.8 HV, respectively. The PMMs provided precise forecasts for the TS and WMH of the Al/Mg joints with an error rate of less than 1% and a confidence level of 97%.

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利用响应面方法优化 AA 6061 铝合金-AZ31B 镁合金异种接头冷金属转移弧焊的工艺参数
异种金属接头的制造,尤其是 AA 6061 铝合金(Al)和 AZ31B 镁合金(Mg)之间的接头,因其截然不同的冶金特性以及与此类材料焊接相关的固有困难而带来了重大的技术挑战。这些挑战包括金属间化合物的形成倾向、热裂纹以及两种合金在热性能和机械性能上的差异。冷金属转移 (CMT) 焊接以其低热量输入和可控金属转移而著称,为解决这些问题提供了潜在的解决方案。然而,优化工艺参数以确保牢固、无缺陷的接头需要系统的方法。本研究旨在利用参数数学建模(PMM)优化 CMT 焊接参数,以生产高强度的铝镁异种接头,并研究 CMT 参数对 AA 6061 铝合金/AZ31B 镁合金(Al/Mg)异种接头的拉伸强度(TS)和焊接金属硬度(WMH)以及微观结构特征的影响。铝/镁异种对接接头采用 CMT 工艺生产,使用 ER4043 作为填充焊丝。CMT 是一种低热输入焊接技术,用于缓解金属间化合物 (IMC)、更宽的热影响区 (HAZ) 和变形等问题。采用响应面方法 (RSM) 优化了 CMT 参数,特别是送丝速度 (WFS)、焊接速度 (WS) 和弧长修正 (ALC),以最大限度地提高铝/镁异种接头的 TS 和 WMH。采用多项式回归创建 PMM,整合这些 CMT 参数,以预测接头的 TS 和 WMH。应用方差分析 (ANOVA) 评估了 PMM 的可行性。结果表明,使用 4700 mm/min 的 WFS、280 mm/min 的 WS 和 10% 的 ALC 生产的铝/镁异种接头的 TS 和 WMH 值较高,分别为 33 MPa 和 95.8 HV。PMM 对铝/镁接头的 TS 和 WMH 进行了精确预测,误差率小于 1%,置信度为 97%。
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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
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