Copper-Ti_3SiC_2 composite powder prepared by electroless plating under ultrasonic environment

In this article, a new type of Cu-Ti3SiC2 composite powder prepared using the electroless plating technique was introduced. The initial Ti3SiC2 particles are 11 μm in diameter on an average. The Cu plating was carried out at middle temperature （62-65℃） with the application of ultrasonic agitation. The copper deposition rate was determined by measuring the weight gain of the powder after plating. It has been found that the pretreatment of Ti3SiC2 powder is very important to obtain copper nanoparticles on the surface of Ti3SiC2 The optimum procedure before plating aimed to add activated sites and the adjustment of the traditional composition of the electroless copper plating bath could decelerate the copper deposition rate to 0.8 gm/h. X-ray diffraction （XRD） indicates that the chemical composition of the plating layer is copper. SEM images show that the surface of the Ti3SiC2 particles is successfully coated with continuous copper layer. The wetting property between the copper matrix and Ti3SiC2 can be improved so as to increase the interfacial strength.

纳米Al_(2)O_(3)颗粒掺杂对化学镀Ni-Cu-P镀层耐蚀性的影响

为提高镀锌铁片表面化学镀层Ni-Cu-P的耐蚀性,在镀液中添加纳米Al_(2)O_(3)颗粒制备了Ni-Cu-P-Al_(2)O_(3)复合镀层。采用贴滤纸法、扫描电镜(SEM)及其附带的能谱仪(EDS)、电化学工作站对镀层孔隙率、表面形貌、元素含量及耐蚀性进行测试分析。结果表明,掺杂纳米Al_(2)O_(3)颗粒得到的Ni-Cu-P-Al_(2)O_(3)复合镀层相较于Ni-Cu-P镀层孔隙率降低了0.02 N/cm^(2)、腐蚀电流降低了2.01×10^(-8)A/cm^(2)、腐蚀电位正移了0.015 V。

复合镀液中Al_(2)O_(3)掺杂量对Ni-P-Al_(2)O_(3)-PTFE复合镀层性能的影响

在复合镀液中添加不同含量的Al_(2)O_(3),采用化学镀方法制备Ni-P-Al_(2)O_(3)-PTFE(聚四氟乙烯)复合镀层,研究了复合镀液中Al_(2)O_(3)质量浓度(0~3.0 g·L^(-1))对复合镀层显微组织、硬度、耐磨性能的影响。结果表明:随着复合镀液中Al_(2)O_(3)掺杂量的增加,化学镀Ni-P-Al_(2)O_(3)-PTFE复合镀层中Al_(2)O_(3)含量先升高后降低,Ni-P基质的结晶性先增强后减弱,硬度先升高后降低,磨损质量损失先减小后增加;当Al_(2)O_(3)质量浓度为2.0 g·L^(-1)时,Ni-P基质结晶性优良,Ni-P-Al_(2)O_(3)-PTFE层与Ni-P过渡层结合良好,复合镀层中Al_(2)O_(3)的含量最高,PTFE、Al_(2)O_(3)粒子均匀弥散地镶嵌在Ni-P基质中,复合镀层的硬度最高,为7.6 GPa,磨损质量损失最低,复合镀层具有优异的耐磨性能。

Ag复合中空纤维膜的制备与性能

以化学镀法制备了Ag复合中空纤维膜,考察了温度对Ag膜的影响,测试了气体渗透性能。结果表明,化学镀温度45℃时,有利于Ag颗粒在载体上的有效沉积,可以形成连续致密的Ag膜。150~300℃,氧渗透通量随压力和温度的增大而增加,氮气渗透通量逐渐减小。300℃时,O_(2)渗透通量为0.027 mol·m^(-2)·s^(-1)。

镍包覆氧化铝增强铁基复合材料的界面行为及其耐磨性(英文)

采用化学沉积法在Al_(2)O_(3)表面制备了Ni镀层,将所制得的Ni包覆Al_(2)O_(3)颗粒(Al_(2)O_(3)p@Ni)作为铁基体的增强颗粒,采用SPS法制备了镀镍氧化铝增强铁基复合材料(Al_(2)O_(3)p@Ni/Fe)。通过优化化学镀工艺,使得Al_(2)O_(3)表面被Ni层均匀覆盖。Ni镀层呈典型的花椰菜状结构,尺寸为1~4μm,施镀过程中镍首先沉积在Al_(2)O_(3)表面的凹坑和孔洞中,然后逐渐长大向外扩展。Ni镀层与Al_(2)O_(3)紧密结合,厚度可达100μm。在烧结过程中,Ni镀层不仅提高了Al_(2)O_(3)与铁基体之间的润湿性,而且促进了Al_(2)O_(3)与铁基体在界面处的扩散和反应。最终,通过机械结合、扩散反应和冶金反应形成了Al_(2)O_(3)/Ni A1_(2)0_(4)/(Al_(0.8)Cr_(0.2))_(2)O_(3)/Ni Fe_(2)O_(4)/Ni/铁基体界面,大大提高了界面结合强度。同时,对Al_(2)O_(3)p@Ni/Fe复合材料和无表面处理的Al_(2)O_(3)p/Fe复合材料进行了磨损试验,结果表明,与Al_(2)O_(3)p/Fe复合材料相比,Al_(2)O_(3)p@Ni/Fe复合材料的磨损质量损失降低了50%,摩擦系数降低了12.5%。Al_(2)O_(3)p@Ni/Fe复合材料的耐磨性明显提高。