共查询到17条相似文献,搜索用时 750 毫秒
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采用纳米掺杂方法制备纳米包覆微米级粒子的AT-13等离子喷涂粉末,并利用大气等离子喷涂技术制备出含有纳米复相结构的陶瓷涂层。采用常温干摩擦试验评价纳米复相结构涂层的耐磨损性能,并利用扫描电镜(SEM)观察磨损后的磨痕形貌。结果表明,纳米复相涂层的耐磨损性能明显好于传统陶瓷涂层,且磨损载荷高于400N后,纳米复相涂层磨损机制和传统涂层的不同,传统涂层的磨损主要是涂层的微裂纹产生和颗粒的剥落,而相同条件下纳米复相涂层,主要表现为涂层的粘着磨损与局部剥落。 相似文献
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对磨削加工后的纳米结构陶瓷涂层进行磨损性能试验.磨损试验首先对纳米结构陶瓷涂层Al2O3/13TiO2的圆柱形工件进行外圆磨削加工,然后将各种不同条件下磨削加工后的圆柱工件装夹到立式铣床的主轴上,进行定速、定载荷的磨损性能试验.磨损性能试验时,圆柱工件在旋转的同时与往复运动的长方形氮化硅陶瓷棒进行滑擦,在其圆柱表面形成磨损沟槽.使用扫描电子显微镜和表面轮廓仪对纳米陶瓷涂层的磨损沟槽进行观察与评定,并与传统陶瓷涂层的磨损沟槽进行对比与分析.为进一步揭示纳米陶瓷涂层的磨损机理,使用有限元法对接触区的应力场进行模拟,并分析纳米陶瓷涂层裂纹的形成与扩展.讨论了磨削工艺参数以及涂层晶粒大小对纳米结构陶瓷涂层耐磨损性能的影响. 相似文献
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以含有定量纳米Al粉的Co基新型合金为涂层的原材料,在Cu-Cr合金表面利用Nd:YAG固体激光器诱导原位反应制备陶瓷相增强Co基复合涂层。采用金相显微镜、扫描电镜和显微硬度等分析技术,对所制备样品涂层的结构和形成机制进行了研究。结果表明:通过激光诱导原位反应,在铜合金表面制备出了组织细小、界面呈冶金结合的陶瓷相增强Co基涂层;涂层的显微硬度由基体表面显微硬度HV87提高到HV426;纳米Al粉的加入为激光诱导原位反应制备Co基涂层提供内部热源,弥补了铜合金基体因导热快而带来的能量损失,充分诱导涂层内的物质发生化学反应,有利于Co基复合涂层的形成;涂层中原位生成的陶瓷相直径小于2.0 μm,弥散分布在涂层中起到骨骼强化作用。 相似文献
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纳米陶瓷等离子喷涂层硬度的Weibull分布及与涂层组构的对应特性 总被引:1,自引:0,他引:1
等离子喷涂层的硬度是反映其耐磨性、强度、使用寿命的重要指标,它与涂层的组构有对应的关系,但其测定结果分散性较大。为了精确测量陶瓷等离子喷涂层的硬度,在NiCrAl合金表面等离子喷涂制备了Al2O3-13%TiO2(AT13)纳米陶瓷涂层(ncc)和对照用微米涂层(mcc),采用显微硬度测试仪测量了其显微硬度,研究了其Weibull分布特性,通过SEM、XRD等分析了ncc涂层显微硬度与微观组织结构的关系,并通过TEM对涂层的微区结构进行了表征。结果表明:ncc涂层的平均显微硬度显著高于mcc,且呈双态分布;两者硬度的Weibull分布呈分散性,但ncc涂层的分布较均匀,微裂纹细小且粒径小,以α-Al2O3和γ-Al2O3及少量金红石型TiO2为主要物相;ncc涂层具有优异的力学性能主要归因于其组织的晶粒细化、纳米TiO2颗粒镶嵌于Al2O3孔隙中、Al2O3微晶弥散分布、微裂纹韧化等。 相似文献
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Catledge SA Fries MD Vohra YK Lacefield WR Lemons JE Woodard S Venugopalan R 《Journal of nanoscience and nanotechnology》2002,2(3-4):293-312
Recent progress in the synthesis, characterization, and biological compatibility of nanostructured ceramics for biomedical implants is reviewed. A major goal is to develop ceramic coating technology that can reduce the friction and wear in mating total joint replacement components, thus contributing to their significantly improved function and longer life span. Particular attention is focused on the enhancement of mechanical properties such as hardness, toughness, and friction coefficient and on the bioactivity as they pertain to the nanostructure of the material. The development of three nanostructured implant coatings is discussed: diamond, hydroxyapatite, and functionally graded metalloceramics based on the Cr-Ti-N ternary system. Nanostructured diamond produced by chemical vapor deposition (CVD) techniques and composed of nano-size diamond grains have particular promise because of the combination of ultrahigh hardness, improved toughness over conventional microcrystalline diamond, low friction, and good adhesion to titanium alloys. Nanostructured processing applied to hydroxyapatite coatings is used to achieve the desired mechanical characteristics and enhanced surface reactivity and has been found to increase osteoblast adhesion, proliferation, and mineralization. Finally, nanostructured metalloceramic coatings provide continuous variation from a nanocrystalline metallic bond at the interface to the hard ceramic bond on the surface and have the ability to overcome adhesion problems associated with ceramic hard coatings on metallic substrates. 相似文献
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