C_(2)H_(2)气体流量对WC-DLC涂层结构与性能的影响

文章采用直流磁控溅射技术制备WC-DLC耐磨涂层,为了探究C_(2)H_(2)流量对WC-DLC涂层表截面形貌、微观结构、力学和摩擦学性能的影响,在10−50 mL/min C_(2)H_(2)流量下制备了WC-DLC涂层并进行表征分析。结果表明,随着C_(2)H_(2)流量的增加,涂层中碳含量增加,晶粒逐渐细化,由柱状晶逐渐转变为细晶粒,涂层变得更加致密;涂层纳米硬度与sp3杂化的C原子含量密切相关,随着涂层中sp3-C含量的增加,硬度先升高然后降低,磨损率也先升高降低;随着碳原子含量升高,涂层中出现大量的非晶碳,表面晶粒非晶化,涂层的摩擦系数逐渐减小且更加稳定。

5,5−二甲基乙内酰脲体系无氰镀镉层的结构及耐蚀性

[目的]研究5,5−二甲基乙内酰脲(DMH)体系无氰镀镉层的结构及性能,为拓宽其应用提供实验数据。[方法]选用碱性DMH体系电镀镉,采用扫描电镜和X射线衍射仪分析Cd镀层的微观结构,通过电化学测试、中性盐雾试验及长期浸泡试验研究Cd镀层的耐蚀性及其腐蚀行为演变规律。[结果]DMH体系Cd镀层外观呈亮白色,晶粒呈六棱柱形,尺寸虽略大于氰化物Cd镀层,但更致密,并且在(002)晶面呈高择优取向,其织构系数达到了99.834%。DMH体系Cd镀层在3.5%NaCl溶液中的腐蚀电流密度约为氰化物Cd镀层的40%,可以经受876 h中性盐雾腐蚀。经六价铬钝化的Cd镀层在2384 h的中性盐雾试验后仍未出现红锈。长期浸泡腐蚀过程中,镉镀试样的腐蚀控制步骤及腐蚀速率会随腐蚀产物的生成和破坏而变化。[结论]碱性DMH体系Cd镀层的耐蚀性可与氰化物Cd镀层相媲美,有望用于航空结构钢部件的防护。

柠檬酸铵对5,5-二甲基乙内酰脲配位体系碱性无氰镀镉的影响

选用5,5-二甲基乙内酰脲(DMH)为主配位剂开发碱性无氰镀镉体系,通过赫尔槽试验、电化学测试、扫描电镜等分析研究了柠檬酸铵作为辅助配位剂对碱性DMH镀镉体系中镉电沉积行为及镀层性能的影响。结果表明:柠檬酸铵可以拓宽碱性DMH镀镉体系的光亮电流密度窗口,阻碍镉配离子的放电还原,增大阴极极化,提高电流效率,细化镀层晶粒,改善镀层耐蚀性。少量柠檬酸铵的阴极极化作用较弱,镀层结晶不够细致;过量的柠檬酸铵会增大析氢反应,降低镀液稳定性;30 g/L的柠檬酸铵辅助配位效果较佳,所得镀层结晶细致、耐蚀性良好。

Wear and corrosion resistant coatings on surface of cast A356 aluminum alloy by plasma electrolytic oxidation in moderately concentrated aluminate electrolytes

Plasma electrolytic oxidation of a cast A356 aluminum alloy was carried out in aluminate electrolytes to develop wear and corrosion resistant coatings. Different concentrations of 2, 16 and 24 g/L NaAlO2 solutions and a silicate electrolyte （for comparison） were employed for the investigation. Wear performance and corrosion resistance of the coatings were evaluated by WC （tungsten carbide） ball-on-flat dry sliding tests and electrochemical methods, respectively. The results show that the coating formed for a short duration of 480 s in 24 g/L NaAlO2 solution generated the best protection. The coating sustained 30 N load for sliding time of 1800 s, showing very low wear rate of -4.5×10^-7 mm3/（N· m）. A low corrosion current density of -8.81×10^-9 A/cm2 was also recorded. Despite low α-Al2O3 content of the coating, the compact and nearly single layer nature of the coating guaranteed the excellent performances.

Effect of NaOH on plasma electrolytic oxidation of A356 aluminium alloy in moderately concentrated aluminate electrolyte

Plasma electrolytic oxidation(PEO)of cast A356 aluminum alloy was carried out in 32 g/L NaAlO_(2) with the addition of different concentrations of NaOH.The stability of the aluminate solution is greatly enhanced by increasing the concentration of NaOH.However,corresponding changes in the PEO behaviour occur due to the increment of NaOH concentration.Thicker precursor coatings are required for the PEO treatment in a more concentrated NaOH electrolyte.The results show that the optimal NaOH concentration is 5 g/L,which improves the stability of storage electrolyte to about 35 days,and leads to dense coatings with high wear performance(wear rate:4.1×10^(−7) mm^(3)·N^(−1)·m^(−1)).

镀前处理对GH4169电镀铬的影响

采用阴极活化、阳极腐蚀、酸洗、吹砂、预镀镍或吹砂与预镀镍结合等镀前处理方式,研究了镀前处理对GH4169电镀铬的影响。结果表明:吹砂和吹砂与预镀镍结合的镀前处理方式能有效在GH4169圆形表面形成铬层,铬层外观、结合力好;仅吹砂与预镀镍结合的镀前处理方式,并利用辅助阳极和保护阴极,能有效在锥形块垫片表面均匀成膜,铬层厚度均匀,外观和结合力好。

离子注渗工艺参数对9310钢表面WC–DLC薄膜性能影响

为提高9310钢表面WC–DLC薄膜结合力与摩擦磨损性能,分别探究了不同注渗时间和注渗电压工艺参数对9310钢表面硬度、WC–DLC涂层结合力以及摩擦性能的影响。研究结果显示:当注渗电压从10kV升高到20kV时,9310钢表面硬度从7.34GPa增加到8.36GPa,膜基结合力从39.9N增加到49.3N,薄膜表面摩擦系数从0.161下降到0.119,薄膜摩擦学测试磨损深度从2.39μm下降到2.03μm;注入时间从1h增加到3h时,9310钢表面硬度从7.06GPa增加到8.84GPa,膜基结合力从34.1N增加到49.9N,薄膜表面摩擦系数从0.161下降到0.118,薄膜摩擦学测试磨痕深度从2.48μm下降到1.99μm。研究表明,9310钢表面离子注渗对WC–DLC涂层结合力与力学性能有一定的改善,结合力增加,摩擦学性能优化。