A comparative study of corrosive-erosive effects at AISI D3 steel, 304 stainless steel and CrN/AlN material

The Open Materials Science Journal Pub Date : 2012-02-17 DOI:10.2174/1874088X01206010014

J. Caicedo, G. Cabrera, H. H. Caicedo, W. Aperador

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引用次数: 3

Abstract

Corrosive-erosive effect on AISI D3 steel, 304 stainless steel and CrN/AlN coating in aqueous NaCl slurries was studied. CrN/AlN multilayer films with a thickness of 3 � m and bilayer period of � = 60 nm (50 bilayers) were obtained by using the physical vapor deposition (PVD) technique (magnetron sputtering). The corrosion-erosion experiments were performed in a test machine in which the impingement velocity, impact angle, concentration of solids and pH of the solution were controlled. Polarization curves were simultaneously obtained to correlate the electrochemical effects to the erosive wear mechanisms. The slurry used consists of silica particles suspended in a mixture of acid solution and 3.5% NaCl, with a pH value of 5.6. Electrochemical results showed the best corrosion resistance for 304 stainless steels. Additionally, the surface analysis by SEM micrograph revealed formation of cracks in CrN/AlN multilayers coating and plastic deformation in both steel substrates (AISI D3 steel, 304 stainless steel), especially when the mean impact angle is a critical value of 90°. Measurements of critical and passive current densities showed that the behavior of coated materials differed depending on the substrate that is used. Nonetheless, in a general way, by increasing the impact angle and by changing its incidence from normal to grazing, it led to a resistance to corrosion-erosion processes.

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AISI D3钢、304不锈钢和CrN/AlN材料腐蚀侵蚀效果的比较研究

研究了AISI D3钢、304不锈钢和CrN/AlN涂层在NaCl水溶液中的腐蚀侵蚀作用。采用物理气相沉积(PVD)技术(磁控溅射)制备了厚度为3 μ m、双层周期为60 nm(50层)的CrN/AlN多层膜。在控制冲击速度、冲击角度、固相浓度和溶液pH值的实验机上进行了腐蚀侵蚀实验。同时得到极化曲线，将电化学效应与冲蚀磨损机理联系起来。所使用的浆料由悬浮在酸溶液和3.5% NaCl的混合物中的二氧化硅颗粒组成，pH值为5.6。电化学结果表明，304不锈钢的耐蚀性最好。此外，通过SEM显微照片进行的表面分析显示，CrN/AlN多层涂层中形成了裂纹，两种钢基体(AISI D3钢和304不锈钢)都出现了塑性变形，特别是当平均冲击角为90°临界值时。临界和无源电流密度的测量表明，涂层材料的行为取决于所使用的衬底。尽管如此，在一般情况下，通过增加冲击角度并将其入射从正常变为放牧，它导致了对腐蚀侵蚀过程的抵抗。

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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The Open Materials Science Journal

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