High-brightness laser welding with beam wobbling: Achieving high-strength Al/Steel joints for battery busbars

IF 3.8 Q2 MATERIALS SCIENCE, MULTIDISCIPLINARY

Journal of Advanced Joining Processes Pub Date : 2025-04-28 DOI:10.1016/j.jajp.2025.100305

M Chelladurai Asirvatham , Iain Masters , Geoff West , Paul Haney

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Abstract

Laser welding of aluminium tabs to nickel-plated interstitial-free (IF) steel was investigated using a high-brightness, single-mode laser with beam wobbling. The influence of interaction time, controlled by wobble amplitude and traverse speed, regulating energy distribution on weld microstructure and mechanical properties was systematically studied. Short interaction times (<25 µs) and large inter-wobble distances (>150 µm) minimized intermetallic compound (IMC) formation and maximized weld strength. Optimizing these parameters (wider wobble amplitudes of 0.6–0.8 mm and faster speeds of 75–100 mm/s) suppressed IMC-induced cracking, resulting in microstructures containing Fe-rich IMCs and Al-Fe₄Al₁₃ eutectic phases. Conversely, lower wobble amplitudes (<0.6 mm) and slower speeds (50–75 mm/s) promoted crack-prone Al-rich Fe₂Al₅ phases. Optimized welds exhibited excellent fatigue performance, withstanding 1 million cycles at 175 N, demonstrating the potential for using lighter, cost-effective aluminium busbars in battery interconnect applications.

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高亮度光束摆动激光焊接：实现电池母线的高强度铝/钢接头

采用高亮度、单模光束摆动激光器，研究了铝片与镀镍无间隙钢的激光焊接。系统研究了由摆动幅度和横移速度控制的相互作用时间、调节能量分布对焊缝组织和力学性能的影响。较短的相互作用时间（<25µs）和较大的摆动距离（>150µm）最大限度地减少了金属间化合物（IMC）的形成，最大限度地提高了焊接强度。优化这些参数（更宽的摆动幅度为0.6-0.8 mm，更快的速度为75-100 mm/s）抑制了imc引起的开裂，导致微观结构中含有富铁imc和Al- fe₄Al₁₃共晶相。相反，较低的摆动幅度（<0.6 mm）和较慢的速度（50-75 mm/s）促进了容易破裂的富Al Fe₂Al₅相。优化后的焊缝具有优异的疲劳性能，可承受175 N的100万次循环，这表明在电池互连应用中使用更轻、更具成本效益的铝母线的潜力。

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