Yongqi Zhang, Lun Zhao, Zhonghua Shen, Zeshan Abbas, Tao Gong, Wei Chen, Xu Long, Vivek Patel, Md Shafiqul Islam
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However, relying solely on porosity as a criterion for judging the overall forming quality of joints may be insufficient. Scanning electron microscope and energy-dispersive X-ray elemental analysis revealed that certain wires underwent plastic deformation at elevated temperatures without attaining atomic bonding. Additionally, the welded joint exhibits a compact structure externally and a more relaxed structure internally. The upper side of the joint in contact with the briquette and the lower side in contact with the welding head exhibit minimal gaps, while numerous gaps are evident in the middle of the joint. Furthermore, upon examining the fracture morphology, two distinct failure modes are identified at the joint surface of the conductor. The first involves the fracture of the wire core with a completely separated joint surface, resulting in poor mechanical properties of the joint. 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引用次数: 0
摘要
本研究探讨了用超声波金属焊接法制造不同线芯直径的 10 mm2 铜 (Cu) 线接头。本研究的主要目的是探讨线芯直径对超声波焊接接头性能的影响。线芯直径与接头的抗剥离性呈正相关。线芯直径越大,接头的机械性能越好。线芯直径为 0.25 mm 的双线焊接接头的剥离强度达到 306.8 N。然而,仅仅依靠气孔率作为判断接头整体成型质量的标准可能是不够的。扫描电子显微镜和能量色散 X 射线元素分析表明,某些焊丝在高温下发生了塑性变形,但并未形成原子结合。此外,焊接接头外部结构紧凑,内部结构较为松散。与煤球接触的焊点上侧和与焊头接触的焊点下侧间隙极小,而焊点中部则有许多间隙。此外,在检查断裂形态时,还发现导体接合面有两种不同的失效模式。第一种是线芯断裂,接合面完全分离,导致接合面的机械性能变差。第二种模式是线芯在接头表面发生韧性断裂,表明接头具有良好的机械性能。
Exploring the impact of wire core diameter on microstructure and joint properties in ultrasonic wire harness welding
The present study investigates ultrasonic metal welding to manufacture 10 mm2 copper (Cu) wire joints with different core diameters. The primary purpose of this study is to explore the influence of wire core diameter on the performance of ultrasonic welded joints. Wire core diameter is positively correlated with the peeling resistance of the joint. Superior mechanical properties of the joint are achieved with an increased diameter of the wire core. The peeling strength of the welded joint of two wires with a wire core diameter of 0.25 mm reaches 306.8 N. Examining the welding temperature and assessing the joint's porosity reveals a significant impact of temperature on porosity. However, relying solely on porosity as a criterion for judging the overall forming quality of joints may be insufficient. Scanning electron microscope and energy-dispersive X-ray elemental analysis revealed that certain wires underwent plastic deformation at elevated temperatures without attaining atomic bonding. Additionally, the welded joint exhibits a compact structure externally and a more relaxed structure internally. The upper side of the joint in contact with the briquette and the lower side in contact with the welding head exhibit minimal gaps, while numerous gaps are evident in the middle of the joint. Furthermore, upon examining the fracture morphology, two distinct failure modes are identified at the joint surface of the conductor. The first involves the fracture of the wire core with a completely separated joint surface, resulting in poor mechanical properties of the joint. The second mode entails the ductile fracture of the wire core at the joint surface, indicating good mechanical properties of the joint.
期刊介绍:
The Journal of Materials: Design and Applications covers the usage and design of materials for application in an engineering context. The materials covered include metals, ceramics, and composites, as well as engineering polymers.
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