1) Ni-Sn alloy
Ni-Sn合金
1.
The characteristics and catalytic ability for hydrogen evolution reaction of Ni-Sn alloys prepared by electroplating
电沉积制备Ni-Sn合金电极材料的结构与电化学性能
2) Sn-Ni alloy
Sn-Ni合金
1.
By introducing amino acid additives in the pyrophosphate plating bath,the Sn-Ni alloy coating containing 67% Sn(mass fraction),having similar color to Ni coating and excellent corrosion resistance as well,was prepared using electro-deposition.
采用氨基酸类添加剂在焦磷酸盐体系中电沉积出锡含量67%、颜色与镍镀层相仿、耐腐蚀性能优异的Sn-Ni合金镀层。
2.
The effect of process parameters such as current density,time,temperature,pH value,mixing method on the electric resistance and wear resistance of the gun colour Sn-Ni alloy coating were studied by orthogonal test,and the optimum process parameters were determined as follows: current density,0.
利用正交试验方法研究了电流密度、时间、温度、pH、搅拌方式等工艺参数对Sn-Ni合金枪黑色镀层电阻及耐磨性能的影响,确定了较优的工艺条件:Jκ=0。
3.
An ab initio method with the first-principles plane-wave pseudopotentials based on the density functional theory has been used to calculate the physical character and electrochemical performance of various alloy phases in Sn-Ni alloy.
采用基于密度泛函理论的第一性原理平面波赝势方法计算了Sn-Ni合金中2种稳定相结构的物理性质和电化学性质。
3) Ni-Sn-P alloy
Ni-Sn-P合金
1.
Research progress of electroless Ni-Sn-P alloy plating;
化学镀Ni-Sn-P合金的研究进展
2.
Study and application of electroless plating Ni-Sn-P alloy deposit;
化学镀Ni-Sn-P合金镀层的研究与应用
3.
Effects of Sn content on the anticorrosion property of Ni-Sn-P alloy plating
Sn含量对Ni-Sn-P合金镀层耐腐蚀性能的影响
4) Ni-Cu-Sn alloys
Ni-Cu-Sn合金
1.
Ni-Cu-Sn alloys are formed by Laser Engineered Net Shaping (LENS) and no apparent deformation can be found in this study.
利用激光近净成形技术成形出无变形的Ni-Cu-Sn合金样品。
5) tin-nickel-copper alloy
Sn-Ni-Cu合金
6) Cu-Ni-Sn alloy
Cu-Ni-Sn合金
1.
In this paper, the composition of Cu-Ni-Sn alloy has been studied.
本文研完了Cu-Ni-Sn合金的成份配比,经反复试验对比,表明含Ni8%,Sn3~5%的铜合金,通过固溶淬火、冷变形、时效处理后,可获得较高的强度(σ_b=980MPa),其延性和韧性均优于锌白铜,抗钎焊软化性能优良,适合于制作各类金属眼镜架。
补充资料:Ni3Al基金属间化合物高温合金
Ni3Al基金属间化合物高温合金
Ni_(3)Al-base intermetallic compound superalloy
N一3AIJ一J旧shuJ一an huahewu goowen heJ一nNi3AI基金属间化合物高温合金(Ni3AI一baseintermetallie eompound superalloy)以Ni3AI相为基体的金属间化合物高温合金。Ni3AI作为高温合金材料中的强化相口)早已被人们所熟知。单晶Ni3AI有较好的室温塑性和加工性,但多晶Ni3AI在室温的塑性儿乎为零。1979年,日本和泉修等发现,添加微量硼可使Ni3AI韧化。硼强烈地偏聚于晶界,从而提高晶界的结合强度并使晶界区无序化,因此提高了晶界区塑性变形能力,使Ni3AI的室温拉伸伸长率可达50%以上。纯净N珠AI的室温、高温强度偏低,与高温合金相比需要进一步提高。固溶强化(见高温合金固溶强化)是提高强度的一条有效途径。Ni3AI可以固溶很多元素,其中以错和铅的强化效果最显著。美国橡树岭国家试验室已发展了一系列含铬、错、错等元素的Ni3AI基金属间化合物高温合金,具有良好的强度、塑性和高温抗氧化性。中国也对Ni3AI基合金进行了深入研究,并添加微量镁显著改善了热加工塑性。Ni3AI基合金可能是最先在工业上得到使用的金属间化合物高温合金之一,已制成各种部件在试用,如汽轮机和柴油机的耐热部件、高温模具、加热元件以及航空用的紧固件等。 〔邹敦叙)
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