Study on Fatigue Strength of Automotive Wire Harness Terminal Crimping

doi:10.16638/j.cnki.1671-7988.2025.017.014

Abstract

Abstract: As a core component of the automotive electrical system, the reliability of the terminal crimping points in automotive wire harnesses directly relates to vehicle performance and driving safety. Conducting research on the fatigue strength of terminal crimping points holds significant engineering value for ensuring the stable and reliable operation of automotive wire harnesses during long-term service. This paper adopts a method combining vibration tests, fatigue strength tests, and working condition simulations. Targeting common typical scenarios in the process of vehicle driving, such as acceleration, deceleration, turning, and bumping, it constructs a terminal simulation model that conforms to actual operating conditions. With the help of ANSYS software, it simulates and analyzes the vehicle's movement process, focusing on studying the displacement changes, stress distribution, and fatigue strength characteristics of the terminal crimping points. The research reveals that under normal vehicle driving conditions, the stress level at the terminal crimping points is low, and the rate of fatigue damage accumulation is slow; however, under bumpy working conditions, the stress at the crimping points rises sharply, leading to a significant acceleration in the rate of fatigue damage accumulation. The research results can provide theoretical basis and technical support for the design optimization, processing technology improvement, and manufacturing quality control of automotive wire harnesses.

Key words: vibration test; fatigue strength test; simulation analys

摘要： 汽车线束作为汽车电气系统的核心组成部分，其端子压接处的可靠性直接关乎整车性能与行驶安全。开展端子压接处疲劳强度研究，对保障汽车线束在长期服役过程中的稳定可靠运行具有重要工程价值。文章通过振动试验、疲劳强度试验结合工况模拟的方法，针对汽车行驶过程中常见的加速、减速、转弯、颠簸等典型场景，构建贴合实际运行状态的端子仿真模型。借助 ANSYS 软件对汽车运动过程进行模拟分析，重点研究端子压接处的位移变化、应力分布及疲劳强度特性。研究表明，在汽车正常行驶工况下，端子压接处应力水平较低，疲劳损伤累积速率缓慢，而在颠簸工况下，压接处应力会急剧攀升，导致疲劳损伤累积速度显著加快。研究成果可为汽车线束的设计优化、加工工艺改进及制造质量控制提供理论依据与技术支撑。

关键词: 振动试验；疲劳强度试验；仿真分析

ZHENG Weihong1 , GONG Yingyu 2 , WEI Chenxi2. Study on Fatigue Strength of Automotive Wire Harness Terminal Crimping[J]. Automobile Applied Technology, 2025, 50(17): 71-79,124.

郑伟宏 1，龚应育 2，卫晨曦 2. 汽车线束端子压接处疲劳强度研究[J]. 汽车实用技术, 2025, 50(17): 71-79,124.

References

[ 1 ] 左亚军,李金强,程祖意.机械结构疲劳强度的研究分析与应用[J].机电工程技术,2023,52(4):270-274. [ 2 ] SCHIJVE J.Fatigue of Structures and Materials[M]. England:Springer-Verlag,2001. [ 3 ] STEPHENS R I,FATEMI A,STEPHENS R R,et al. Metal Fatigue in Engineering,2nd Edition[M].England: Wiley Interscience,2000. [ 4 ] SCHIJVE J.结构与材料的疲劳[M].吴学仁,译.2 版. 北京:航空工业出版社,2014. [ 5 ] LI Z,ZHAO T,ZHANG J,et al.Fusing Image and Physical Data for Fatigue Life Prediction of Nickel-based Single Crystal Superalloys[J].Engineering Failure Analysis,2024,162:1-14. [ 6 ] ZHU S P,NIU X P,KESHTEGAR B,et al.Machine Learning-Based Probabilistic Fatigue Assessment of Turbine Bladed Disks under Multisource Uncertainties [J].International Journal of Structural Integrity,2023, 14(6):1000-1024. [ 7 ] SHEN Z,LV G,FU D,et al.A Machine Learning Study on the Fatigue Crack Path of Short Crack on an α Titanium Alloy[J].Philosophical Transactions of the Royal Society A,2023,381(22):391-2022. [ 8 ] SUN X,ZHOU K,SHI S,et al.A New Cyclical Generative Adversarial Network Based Data Augmentation Method for Multiaxial Fatigue Life Prediction[J]. International Journal of Fatigue,2022,162:1-17. [ 9 ] YAN J,ZHOU J,ZHANG J,et al.AP-GAN-DNN Based Creep Fracture Life Prediction for 7050 Aluminum Alloy[J].Engineering Fracture Mechanics,2024,303:1- 18. [10] 甘磊,吴昊,仲政.数据驱动的金属疲劳寿命模型研究进展[J].力学进展,2025,55(1):30-79. [11] 赵娜,车军,刘潇潇,等.振动疲劳载荷作用下动车用压接端子电性能试验研究[J].计算机与数字工程,2019, 47(4):975-979. [12] 文保华,徐凤林,赵华,等.三轴随机振动条件下电连接器插孔簧片疲劳损伤研究[J].机械强度,2023,45(6): 1465-1473. [13] 骆燕燕,祁侨绅,王永鹏,等.随机振动下电连接器性能退化及磨屑迁移[J].哈尔滨工业大学学报,2024,56(9):38-47. [14] 卢祥丰,顾沛沛,彭斐,等.7050T7451 和 7150T7751 铝合金疲劳强度研究[J].轻合金加工技术,2023,51(3): 57-62. [15] 杨冰,赵永翔,邬平波,等.16MnR 钢焊接头的延拓概率疲劳 S-N 曲线[J].交通运输工程学报,2004(4):25-29. [16] 李智敏.高强度齿轮单齿弯曲疲劳强度试验[J].机电信息,2014(21):78-79,81. [17] 陈旭,徐磊鑫,王万章,等.基于 ANSYS Workbench 的联合收获机滚筒轴疲劳强度分析与优化[J].农业装备与车辆工程,2024,62(2):1-7. [18] BUDYNAS R G,NISBETT J K,SHIGLEY J E,et al. Mechanical Engineering Design[M].9th ed.New York: McGraw-Hill,2011:312-315. [19] SHIGLEY J E,MISCHKE C R.Mechanical Engineering Design[M].9th ed.New York:McGraw-Hill Science, 2011. [20] DOWLING N E.Mechanical Behavior of Materials: Engineering Methods for Deformation,Fracture,and Fatigue[M].4th ed.London:Pearson,2012. [21] 严岳.S-N 曲线和疲劳损伤安全系数的选择及对计算结果的影响[J].中国海洋平台,1993(1):14-17,4. [22] 王艳鹏,王武军,陈国强,等.汽车连接器簧片结构参数对振动特性影响分析[J].汽车电器,2024(4):56-60.