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WC颗粒增强激光定向能量沉积Co基耐磨涂层强韧化行为研究OA

Strength-toughness Behavior of WC Particles Reinforced Co-based Wear-resistant Coatings by Laser Direct Energy Deposition

中文摘要英文摘要

目的 满足工程机械关键零部件在高载荷、强摩擦和冲击等严苛工况下的服役需求.方法 采用激光定向能量沉积技术,结合变工艺间断搭接加工策略,制备了不同质量分数 WC 颗粒(0%~50%)的 WC/Co基复合涂层,系统性地分析了WC颗粒含量变化对WC/Co基复合涂层成形质量、显微组织、物相组成、宏微观硬度、抗冲击性、耐磨性及强韧化行为的影响规律.结果 研究结果表明,随着WC颗粒含量的增加,熔池流动性下降,气体逸出受阻,导致涂层表面间距增大、孔隙率上升.添加 WC 颗粒显著提升了涂层的硬度和耐磨性,其增强机制主要包括硬质颗粒强化、晶粒细化强化、弥散强化以及颗粒遮挡保护效应.随着WC含量从 0%增加至50%,涂层在冲击载荷下的抗变形能力持续增强,但WC含量过高会导致涂层内部产生裂纹缺陷,从而削弱局部承载能力.当WC颗粒含量为40%时,WC/Co涂层展现出最佳的强韧性平衡,兼具较高强度与良好韧性,有效提升了涂层的整体耐久性.结论 揭示了WC颗粒含量与WC/Co基复合涂层性能的内在关联,为高性能陶瓷颗粒增强金属基复合涂层的优化设计提供了普适性理论依据和性能调控技术指导.

With the growing demands for advanced materials in harsh operating conditions,such as high mechanical loads,severe wear,and repeated impacts,this research focuses on enhancing the surface performance of critical components by incorporating WC particles into Co-based alloy coatings with the primary goal to optimize the WC particle content to achieve a favorable balance between hardness,wear resistance,and toughness,and thus provide a theoretical and technical foundation for the development of high-performance composite coatings. In this study,WC/Co-based composite coatings were fabricated via laser directed energy deposition(LDED)according to the variable-process discontinuous overlapping multi-track strategy,with WC particle contents ranging from 0%to 50%.The effects of WC particle content on the coatings'forming quality,microstructure,phase composition,mechanical properties,and strength-toughness behavior were comprehensively evaluated.Advanced characterization techniques,including optical microscopy,scanning electron microscopy(SEM),energy-dispersive spectroscopy(EDS),and X-ray diffraction(XRD)were employed.Additionally,hardness tests(Rockwell,Vickers,and nano-indentation),impact testing,and friction-wear experiments were conducted to assess the coatings'macroscopic and microscale mechanical properties,as well as their resistance to deformation and wear. The results revealed that the addition of WC particles significantly enhanced the coatings'hardness and wear resistance,primarily through mechanisms such as hard particle strengthening,grain refinement,dispersion strengthening,and the pinning effect.However,excessive WC particles led to increased porosity,surface roughness,and internal defects,which negatively impacted the coatings'toughness and load-bearing capacity.Key findings are as follows:as WC particle content increased,the coatings exhibited finer grains and a higher density of hard phases(e.g.,Co6W6C and W2C).Nevertheless,excessive WC particles caused agglomeration and uneven distribution,resulting in defects such as cracks and pores.The coatings'hardness and wear resistance increased with the WC particle content,reaching optimal values at a 40%WC content;beyond this threshold,toughness decreased due to the formation of internal cracks and reduced ductility.Coatings with 40%WC displayed the lowest wear rate(62.3 μm³/(N·m))and friction coefficient(0.28),which was attributed to the synergistic effects of WC particles in disrupting wear mechanisms and enhancing the coatings'resistance to plastic deformation.While the coatings'resistance to deformation improved with increasing WC content,excessive WC particles raised the risk of cracking under impact loads.These findings demonstrated that the optimal WC particle content for achieving a favorable balance between hardness,wear resistance,and toughness was 40%.Beyond this point,the coatings'performance deteriorated due to increased defects and reduced ductility.The results provided valuable insights into the optimization of WC/Co composite coatings for applications requiring high durability and resistance to wear and impact. These findings demonstrate that the optimal WC particle content for achieving a favorable balance between hardness,wear resistance,and toughness is 40%.Beyond this point,the coatings'performance deteriorates due to increased defects and reduced ductility.The results provide valuable insights into the optimization of WC/Co composite coatings for applications requiring high durability and resistance to wear and impact,and offer a theoretical basis and practical guidance for the development of advanced composite coatings with enhanced mechanical properties.

岳海涛;王嘉鹏;吕宁;郭辰光;戴卫兵;薛胜利

辽宁工程技术大学 机械工程学院,辽宁 阜新 123000||辽宁省大型工矿装备实验室,辽宁 阜新 123000辽宁工程技术大学 机械工程学院,辽宁 阜新 123000辽宁工程技术大学 机械工程学院,辽宁 阜新 123000||辽宁省大型工矿装备实验室,辽宁 阜新 123000辽宁工程技术大学 机械工程学院,辽宁 阜新 123000||辽宁省大型工矿装备实验室,辽宁 阜新 123000辽宁工程技术大学 机械工程学院,辽宁 阜新 123000辽宁工程技术大学 机械工程学院,辽宁 阜新 123000

矿业与冶金

激光定向能量沉积WC颗粒复合涂层微观结构力学性能强韧化行为

laser directed energy depositionWC particlecomposite coatingmicrostructuremechanical propertystrength-toughness behavior

《表面技术》 2026 (4)

102-114,13

国家自然科学基金(52404124)中国博士后科学基金(2023M731481) National Natural Science Foundation of China(52404124)China Postdoctoral Science Foundation(2023M73148)

10.16490/j.cnki.issn.1001-3660.2026.04.009

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