Selected properties of aluminum ultrasonic wire bonded joints with nickel-plated steel substrate for 18650 cylindrical cells

IF 3.8 Q2 MATERIALS SCIENCE, MULTIDISCIPLINARY
K Bieliszczuk , J Zręda , T Chmielewski
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引用次数: 0

Abstract

Ultrasonic wire bonding is a process of connecting two or more surfaces using a metal wire. In battery manufacturing heavy wire bonding is used to connect battery cells with each other or more commonly with printed circuit board or metal (aluminum, plated or bare copper) busbar by means of metal (aluminum, copper) wire with diameters ranging 100–500 µm. Single sided battery cell bonding means that connections are made from one side on both positive (cap) and negative (crimp) battery terminals. The main advantages of this method are easy process automation, low production time, easier recyclability, self-fusing properties of the wire and high process flexibility allowing for more space efficient battery holder design and different material thermal expansions (in comparison with direct busbar to cell joining using resistance or laser welding). This study is focused on analysis of selected properties of 400 µm aluminum wire ultrasonic wedge heavy wire bonding on 18,650 Lithium-Ion cylindrical battery cells. Bonding process was conducted using a RBK03 bond head equipped on a Hesse Bondjet BJ985 CNC wire bonder. As part of the work, the transversal and the longitudinal cross-section profile of the weld, the microstructure of the weld and the heat-affected zones of the dissimilar joint were described using electron and optical microscopy, the microhardness distribution in the joint was characterized and the joint sheer tests were performed according to DVS-2811. Materials of the aluminum bonding wire and the battery cell cylinder used for joining were also characterized. Bonding process on the machine used in this study is controlled by its duration, wire deformation or both of these parameters and consist of wire touch down and several (usually 2 or 3) bonding phases. Parameters of each bonding phase consist of bonding force, bonding force ramp, ultrasonic generator current/voltage, ultrasonic generator current/voltage ramp and bonding time. Each wire has at least 2 bonds connected by wire loop and is ended with wire pre-cut and tear off.

用于 18650 圆柱形电池的镀镍钢基板铝超声波丝键合接头的选定特性
超声波焊线是一种使用金属线将两个或多个表面连接起来的工艺。在电池制造过程中,重型线键合用于将电池单体相互连接起来,更常见的是通过直径为 100-500 微米的金属(铝、铜)线将电池单体与印刷电路板或金属(铝、镀层或裸铜)汇流排连接起来。单面电池单元接合是指从电池正极(盖帽)和负极(压接)的一面进行连接。这种方法的主要优点是易于实现工艺自动化、生产时间短、更易于回收利用、金属丝具有自熔性、工艺灵活性高,可用于更节省空间的电池座设计和不同材料的热膨胀(与使用电阻焊接或激光焊接进行母线与电池的直接连接相比)。本研究的重点是对 18650 个锂离子圆柱形电池芯上 400 µm 铝线超声波楔形重线接合的选定特性进行分析。键合过程是使用配备在 Hesse Bondjet BJ985 CNC 焊线机上的 RBK03 键合头进行的。作为工作的一部分,使用电子显微镜和光学显微镜对焊缝的横向和纵向截面轮廓、焊缝的微观结构和异种接头的热影响区进行了描述,对接头的显微硬度分布进行了表征,并根据 DVS-2811 标准进行了接头剪切试验。此外,还对用于连接的铝键合丝和电池筒的材料进行了表征。本研究中使用的机器上的接合过程由其持续时间、线材变形或这两个参数控制,包括线材接触和几个(通常为 2 或 3 个)接合阶段。每个键合阶段的参数包括键合力、键合力斜坡、超声波发生器电流/电压、超声波发生器电流/电压斜坡和键合时间。每条接合线至少有 2 个接合点,由接合线环连接,并以预切和撕断接合线结束。
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
CiteScore
7.10
自引率
9.80%
发文量
58
审稿时长
44 days
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