DLC镀膜钢领磨损原因与镀膜工艺改进

为了解决国产钢领使用寿命短、锭速低,制约纺纱效率提高的问题,以DLC镀膜钢领为对象,重点对纺织纤维粘着物粘着在钢领表面引起的钢领轨道破坏,以及相关的粘着磨损和疲劳磨损破坏机理进行了分析。针对其失效情况,探讨将单一DLC镀膜改进为Ti-DLC镀膜,即采用非平衡闭合磁控溅射技术和钛(Ti)掺杂多层复合镀膜技术,在基体温度低于100℃的条件下,在钢领表面制备Ti-DLC复合膜,并研究不同钛含量对膜的结构、摩擦磨损性能的影响。改进后的Ti-DLC膜比DLC膜具有更高沉积率、更高粘附力、更高的硬度和耐磨性、低摩擦因数和低磨损率等性能,改善了钢领表面膜的摩擦磨损性能,克服了常规DLC镀膜的缺点,从而保证其抗粘着性、抗疲劳性更好。

类金刚石薄膜摩擦机理及其摩擦学性能影响因素的研究现状

类金刚石薄膜(DLC)具有十分优异的减摩耐磨性能,是一种极具发展潜力的固体润滑材料。但其摩擦学性能受到很多因素的影响,这些因素主要可以分为两大类:固有因素和外在因素。在不同的固有因素和外界因素影响下DLC薄膜的摩擦学性能会产生较大差异,这大大制约了人们对其摩擦学行为及摩擦机理的认识,限制了其应用范围的扩展。总结了目前有关DLC薄膜摩擦机理的三种理论,即转移膜理论、滑行界面石墨化理论和化学吸附钝化悬键理论,并在此基础上概括分析了各固有因素和外界因素对DLC薄膜摩擦学性能的影响及其机理,提出未来可以从基础理论和相关技术两方面对DLC薄膜的摩擦学性能展开深入研究。

类金刚石膜的制备及其影响因素

概述了近年来制备类金刚石膜的新方法如双射频辉光放电 (RF-RF)法、射频-直流辉光放电 (RF-DC)法和微波-射频 (MW-RF)法等;并且对影响类金刚石膜制备及性能的因素如基体材料、制备类金刚石膜时在膜中添加元素、类金刚石膜与基材之间的中间层等进行了较全面的分析。

Investigation of stress corrosion cracking behavior and mechanism analysis of a 1900 MPa-grade ultra-high-strength stainless steel

The stress corrosion cracking(SCC)behavior of a 1900 MPa-grade ultra-high-strength stainless steel in 3.5 wt.% NaCl solution was investigated by X-ray diffractometer,scanning electron microscopy,electron back-scattered diffraction,X-ray photoelectron spectroscopy,and potentiodynamic polarization curves.The results showed that USS122G stel has good SCC resistance,and the critical stress intensiy factor(K_(iscc))of USS122G steel was about 68.906 MPa m^(1/2) and Kiscc/K_(ic)=0.76(K_(ic) is plane strain fracture toughness).The existence of film-like austenite along the lath martensite boundary and the protective effect of thecc passivation flm were the main factors for its high Kiscc.Among them,the main components of the passivation film on the surface of USS122G steel were Cr_(2)O_(3),Cr(OH)_(3),FeOOH,and Ni(OH)_(2).The fracture morphology of SCC zone was intergranular and transgranular.Through the slow and fast scanning rate polarization curve test results,it can be concluded that SCC mechanism of USS122G steel in 3.5 wt.%NaCl solution at the open-circuit potential was a mixed mechanism involving hydrogen embritlement and anodic dissolution.