能量密度对内燃机用Ti600表面激光熔覆Ni-Co涂层组织及耐蚀性的影响

为了提高内燃机用Ti600表面的耐蚀性能,对Ti600合金实施激光熔覆处理制得Ni-Co涂层,测试分析了能量密度对Ni-Co涂层组织及耐蚀性的影响。结果表明:在涂层内形成了(Ni,Co) Ti2.5组织以及α-Ti组织结构。当激光能量密度降低后,涂层保持基本稳定的物相结构,而涂层中的各组织相都形成了更大的半峰宽。更大的激光能量密度可降低涂层晶粒尺寸。当激光能量密度降低后,形成了更大的涂层混合熵。Ni-Co涂层内部有孔洞,但涂层与基体结合良好。Ni-Co涂层形成了比Ti600合金更宽范围的钝化区域,具备更优的耐点蚀性能,设定更大激光能量密度可以提升涂层耐蚀性。在NaCl与H2SO4共同组成的混合溶液中,涂层依然形成了明显的钝化区,表现出良好的钝化性能。

激光熔覆Ni-Co基合金复合涂层的组织与耐磨性

借助于光学显微镜、X射线衍射仪、维氏硬度计、摩擦磨损试验机等研究了1Cr17Mn6Ni5N不锈钢表面激光熔覆Ni/Co基合金复合涂层的组织与干滑动摩擦磨损性能。结果表明：涂层材料由含35%WC的Ni基合金（Ni35WC）和一定量的Co基合金粉混合构成。激光熔覆Ni35WC＋30%Co基合金复合涂层硬度比单一的Ni基合金熔覆层的提高50~70 HV;复合涂层的干滑动摩擦磨损速率相比不锈钢基材的下降约51%,相比Ni基合金熔覆层的下降约25%。干滑动摩擦磨损抗力的提高被认为是固溶强化、细晶强化和硬质点化合物产生的弥散硬化共同作用的结果。

球墨铸铁表面激光熔覆Ni-Co复合涂层的耐腐蚀及高温摩擦学性能

为降低球墨铸铁激光熔覆过程中白口组织的含量,改善其高温摩擦学性能和耐腐蚀性能,采用激光熔覆技术,通过添加Ni基过渡层在球墨铸铁表面制备Co基涂层。利用XRD、SEM、EDS表征不同熔覆层的物相组成、微观结构。采用高温摩擦磨损试验机测试不同温度下Co基涂层与球墨铸铁的摩擦磨损性能,分析Co基涂层在不同温度下的磨损机理。利用电化学工作站测试Co基涂层与球墨铸铁的耐腐蚀性能。结果表明:Ni基过渡层的物相为γ-Ni固溶体和Ni_(3)Si陶瓷相。Co基涂层主要由γ-Co固溶体和Cr_(7)C_(3)陶瓷相构成。Ni基过渡层的添加抑制了基材中C元素扩散,降低了结合界面处白口化趋势。由于Cr_(7)C_(3)陶瓷相的强化作用,Co基涂层的显微硬度为球墨铸铁基材的2.1倍。与球墨铸铁基材相比,当温度高于200℃时,Co基涂层在与Si_(3)N_(4)配副对磨时表现出较低的平均摩擦因数与磨损率。在中低温条件下Co基涂层与Si3N4配副对磨时的磨损机制为黏着磨损与磨粒磨损,高温条件下的磨损机制为形成连续光滑的氧化层起到减摩抗磨的作用。Co基涂层表现出更高的自腐蚀电位(-362.36 mV)和更低的自腐蚀电流密度(13.95 nA·cm^(-2))。所制备的Ni-Co复合涂层能有效提高球墨铸铁表面的高温摩擦学性能和耐腐蚀性能,在发动机领域具有较好的应用前景。

Viscoplastic friction and microstructural evolution behavior of laser-clad Co-Cr-Ni-Mo coating

The viscoplastic friction and nanostructure formation mechanism of laser-clad Co-based coating were studied by rotary friction between laser-clad Co-Cr-Ni-Mo coating and WC-Co rod.The friction coefficient,friction interface temperature and axial displacement—time curves during rotary friction process were measured.The results showed that all the curves firstly experienced rising stage and then steady stage.The rising stage corresponded to sliding friction while the steady stage corresponded to viscoplastic friction.After viscoplastic friction processing,three typical zones of viscoplastic deformation zone,thermo-mechanically affected zone,and original laser-clad zone can be observed successively from the friction surface to the interior.The viscoplastic deformation significantly crushed the network M23C7 phase in original laser-clad zone and made it dispersively distributed with equiaxial shape and in nano-scale.The viscoplastic zone,in width of 37-131 μm,is mainly characterized by refined M23C7 and α-Co phase with grain size bellow 50 nm,and even a small quantity of amorphous.Thus,the hardness of viscoplastic zone about HV997 was improved compared with the hardness of original laser-clad zone about HV600.