车载运输振动环境对电弧增材制造碳钢形貌、组织及性能的影响

doi:10.3901/JME.2025.03.411

摘要/Abstract

摘要： 当前，战场环境增材制造维修保障系统的应用范围和前景已日趋明朗。其中，电弧增材制造技术凭借其高沉积效率和卓越的环境适应性，能够迅速完成修复任务，使装备得以迅速重返战场。然而，在车载移动环境中实现实时制造修复仍是一大技术难题。为探究电弧增材制造在车载移动平台上应用的可能性，对车载振动环境(1.5～5.0 Hz)下制备的低碳钢成形件进行了形貌、组织和力学性能的全面评估。结果表明，随着车载平台振动频率的增加，焊枪和基板的加速度也在不断增加，使得成形试样从形貌良好向成形失败转变，振动频率超过3 Hz后，飞溅和熄弧现象频发。相关性分析表明焊枪振动对成形的影响比基板振动更为显著。稳态下成形试样的抗拉强度、屈服强度和延伸率分别为489 MPa、385 MPa和0.34；与之相比，较低频率的振动有细化晶粒、提高力学性能的作用，极限抗拉强度可达501 MPa，最大延伸率可达0.35；较高频率的振动则会粗化晶粒、略微降低力学性能，抗拉强度和延伸率降低至483 MPa和0.31；更为严重的是，较高频率振动会导致成形件外观形貌恶化甚至无法顺利成形，从而达不到生产制造要求。总的来说，本研究为在作战部队中实现“随时随地”进行电弧增材制造提供了坚实的实验基础和理论依据。

关键词: 车载, 振动, 电弧增材制造, 形貌, 性能

Abstract: At present, the application scope and prospects of the battlefield environment additive manufacturing and maintenance support system have become relatively clear. Wire arc additive manufacturing technology has the advantages of high deposition efficiency and strong environmental adaptability, which can quickly complete the repair work and enable equipment to be quickly put into use on the battlefield. However, how to perform real-time manufacturing and repair in a mobile vehicle environment remains a challenge. To investigate the potential of applying wire arc additive manufacturing to the manufacturing and repair of components on mobile platforms, a study was conducted under vehicle-induced vibrations ranging from 1.5 Hz to 5 Hz, focusing on the morphology, microstructure, and mechanical properties of low carbon steel specimens. The results indicate that with the increase in the vibration frequency of the vehicle platform, the acceleration of both the welding gun and the substrate continuously rises. This transition leads to a change from well-formed specimens to failed formations, with spattering and arc extinction becoming prevalent beyond 3 Hz. Correlation analysis reveals that the vibration of the welding gun has a more significant impact on the formation process compared to substrate vibration. Under steady-state conditions, the formed specimen exhibited tensile strength, yield strength, and elongation of 489 MPa, 385 MPa, and 0.34, respectively. In contrast, lower frequency vibrations contributed to grain size refinement and improved mechanical properties, achieving a maximum ultimate tensile strength of 501 MPa and maximum elongation of 0.35. However, higher frequency vibrations led to coarser grain structures, a slight reduction in mechanical properties, resulting in reduced tensile strength of 483 MPa and elongation of 0.31. Crucially, higher frequency vibrations caused deterioration in the appearance of the formed parts, hindering successful formation and ultimately failing to meet manufacturing requirements. Overall, this study provided a solid experimental foundation for realizing "anytime, anywhere" wire arc additive manufacturing in combat units.

Key words: vehicle, vibration, wire arc additive manufacturing, morphology, performance

中图分类号:

TG156

蔡成恒, 邝伟峰, 李振华, 石学智. 车载运输振动环境对电弧增材制造碳钢形貌、组织及性能的影响[J]. 机械工程学报, 2025, 61(3): 411-421.

CAI Chengheng, KUANG Weifeng, LI Zhenhua, SHI Xuezhi. Effect of Vehicle Vibration on Morphology, Microstructure and Properties of Carbon Steel Produced by Wire Arc Additive Manufacturing[J]. Journal of Mechanical Engineering, 2025, 61(3): 411-421.

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