Contribution of Seven Electroplating Factors on Some Properties of Zn-Ni Coating on Medium Carbon Steel using Taguchi's L27 Orthogonal Array

Q4 Materials Science

Journal of Surface Science and Technology Pub Date : 2021-04-09 DOI:10.18311/JSST/2020/26019

Basem Ammar

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引用次数: 1

Abstract

The protective Zn-alloy coating enhances the carbon steels' corrosion resistance. Seven factors of Zn-Ni coating electroplating on medium carbon steel were optimized using Taguchi L27 (37) orthogonal array. The impact of nickel chloride concentration (N), distance factor between anode and cathode (X), plating process time (P), bath temperature (T), deposition current density (I), substrate hardness (H), and substrate roughness (R) on the corrosion current density (ICorr) and the coating thickness were examined. Two different samples were also morphologically studied. Results indicated that N:20 g l-1; X:9 cm; P:20 min; T:45 °C; I:3 A dm-2; H:44 HRC; and R:P500 can produce Zn-Ni coating with the highest corrosion resistance (lowest ICorr) with inhibition efficiency of 96.5%. Among factors, T, P, H, and N had the highest impact on ICorr with a total percentage contribution of about 60%. In addition, the thickness was mainly affected by I, P, and H, with a total percentage contribution >90%. The optimal combination for lowest ICorr resulted in a smooth and more homogenous and compact structure of coating without microcracks. Higher microhardness was also obtained due to the high nickel content in Zn-Ni coating (14.7%wt). However, the worst combination gave semi-spherical-shaped crystallites with non-uniform distribution of particles.

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田口L27正交阵列法测定中碳钢表面镀锌-镍镀层中7个因素对某些性能的影响

锌合金保护涂层提高了碳钢的耐腐蚀性。采用田口L27（37）正交试验法，对中碳钢镀锌镍镀层的7个因素进行了优化。考察了氯化镍浓度（N）、阳极和阴极之间的距离因子（X）、电镀工艺时间（P）、浴温度（T）、沉积电流密度（I）、基底硬度（H）和基底粗糙度（R）对腐蚀电流密度（ICorr）和涂层厚度的影响。还对两个不同的样品进行了形态学研究。结果表明：N:20g l-1；X： 9厘米；P： 20分钟；T： 45°C；I： 3 A dm-2；H： 44 HRC；R:P500可以制备出耐腐蚀性最高（ICorr最低）的Zn-Ni涂层，抑制率为96.5%。其中，T、P、H和N对ICorr的影响最大，总贡献率约为60%。此外，厚度主要受I、P和H的影响，总百分比贡献>90%。最低ICorr的最佳组合导致涂层结构光滑、更加均匀和紧凑，没有微裂纹。由于Zn-Ni涂层中的镍含量较高（14.7%wt），也获得了较高的显微硬度。然而，最差的组合产生了颗粒分布不均匀的半球形晶粒。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Journal of Surface Science and Technology PHYSICS, APPLIED-

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期刊介绍： The Indian Society for Surface Science and Technology is an organization for the cultivation, interaction and dissemination of knowledge in the field of surface science and technology. It also strives to promote Industry-Academia interaction