金属热处理 ›› 2023, Vol. 48 ›› Issue (12): 65-73.DOI: 10.13251/j.issn.0254-6051.2023.12.010

• 工艺研究 • 上一篇    下一篇

激光功率对Ni60/WC涂层组织演变及力学性能的影响

韩基泰   

  1. 无锡学院 自动化学院, 江苏 无锡 214105
  • 收稿日期:2023-07-12 修回日期:2023-10-08 出版日期:2023-12-25 发布日期:2024-01-29
  • 作者简介:韩基泰(1991—),男,副教授,博士,主要研究方向为激光增材制造,E-mail:18851501880@163.com
  • 基金资助:
    江苏省高等学校基础科学(自然科学)面上项目(21KJB480012);无锡市科技发展计划“太湖之光”科技攻关项目(K20221051);无锡市社会发展科技示范工程项目(N20191008)

Effect of laser power on microstructure evolution and mechanical properties of Ni60/WC coatings

Han Jitai   

  1. College of Automation, Wuxi University, Wuxi Jiangsu 214105, China
  • Received:2023-07-12 Revised:2023-10-08 Online:2023-12-25 Published:2024-01-29

摘要: 采用激光熔覆技术在Cr12MoV基体上成功制备了Ni60/WC复合涂层,研究了激光功率对复合涂层力学性能的影响。使用扫描电镜、维氏硬度计及往复式摩擦磨损试验机分别对复合涂层的显微组织、硬度及耐磨损性能进行表征,并进一步揭示了复合涂层磨损机理。研究表明,较低的激光能量输入不能满足WC颗粒的熔化要求,削弱了复合涂层的成形质量,较高的激光功率条件下复合粉体中WC颗粒可以充分熔化产生Ni2W4C、M7C3与M6C型碳化物,随着激光功率的增大,Ni60/WC复合涂层摩擦学性能呈现先升高后降低的趋势,WC颗粒对复合材料产生了细晶强化,还诱导了复合材料原位碳化物硬质相提升力学性能。在一定范围内,随着激光功率的增大,复合涂层平均显微硬度增加,最大达到852.35 HV0.2,平均摩擦因数与磨损率均减小,最小分别为0.117 45与0.5849×10-8 mm2/N。磨痕表面犁沟、片状剥落减少,涂层耐磨性能显著提升,然而随着激光功率的增大,复合涂层由于内部残余热应力较大且晶粒粗化等原因使力学性能降低。

关键词: 原位生成碳化物, Ni60/WC涂层, 激光熔覆, 耐磨性能

Abstract: Ni60/WC composite coatings were successfully prepared on Cr12MoV substrate by laser cladding technology. The effect of laser power on the mechanical properties of the composite coatings was studied. The microstructure, microhardness and wear resistance of the composite coatings were characterized by SEM, Vickers hardness tester, reciprocating friction and wear tester, respectively. The wear mechanism of the composite coatings was further revealed. The results show that lower laser energy input cannot satisfy the melting requirements of WC particles, which weakens the forming quality of composite coatings. The WC particles in composite powders can be fully melted to generate Ni2W4C, M7C3, M6C type carbides under relatively higher laser power conditions. With the increase of laser power, the wear resistance of the Ni60/WC composite coatings first increases and then decreases, where the WC particles produce fine grain strengthening and induce the in-situ carbide hard phase to improve the mechanical properties of the composites. In a certain range, with the increase of laser power, the average microhardness of the composite coating increases, reaching 852.35 HV0.2 at most, and the average friction coefficient and wear rate decrease, reaching 0.117 45 and 0.5849×10-8 mm2/N at least, respectively. The furrow and flake peeling on the wear scar surface are reduced, and the wear resistance of the coating is significantly improved. However, with the increase of laser power, the mechanical properties of the composite coating are reduced due to the large internal residual thermal stress and grain coarsening.

Key words: in-situ carbide formation, Ni60/WC coating, laser cladding, wear resistance

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