دانلود رایگان ترجمه مقاله خواص ریزساختاری و سایشی آلیاژ با روکش سخت Fe-Cr-C – الزویر 2010
دانلود رایگان مقاله انگلیسی ویژگی های ریزساختاری و سایشی آلیاژ با روکش سخت Fe-Cr-C با کربن بالا به همراه ترجمه فارسی
عنوان فارسی مقاله: | ویژگی های ریزساختاری و سایشی آلیاژ با روکش سخت Fe-Cr-C با کربن بالا |
عنوان انگلیسی مقاله: | Microstructural and abrasive characteristics of high carbon Fe–Cr–C hardfacing alloy |
رشته های مرتبط: | مهندسی مواد و جوشکاری، صنایع فلزی، شناسایی و انتخاب مواد مهندسی، متالوژی صنعتی، متالوژی |
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نشریه | الزویر – Elsevier |
کد محصول | F491 |
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بخشی از ترجمه فارسی مقاله: 1 – مقدمه |
بخشی از مقاله انگلیسی: 1. Introduction Fe–Cr–C alloys are widely used in severe abrasive conditions due to their superior abrasion resistance. The excellent abrasive wear resistance results from high volume fraction of carbides and the toughness of the matrix also contribute to the wear resistance [1]. Properties such as abrasion wear resistance, surface roughening resistance and seizing or sticking resistance are essentially significant to these alloyed white cast irons used for the rolls and other wear resistant parts of steel rolling and mineral pulverizing mills. Among these properties, the abrasion wear resistance is reported to be dependent upon not only type, morphology, amount, and distribution pattern of the carbides precipitated from the melt, but also the type of matrix structure [2]. (Cr,Fe)7C3 carbides are found in Fe–Cr–C alloys with higher contents of carbon (2–5 wt%) and chromium (18–30 wt%). These microstructures indicate good wear resistance properties. These kinds of hard material can be represented by high Cr white cast iron which has high hardness M7C3 (about 1600 HV) [3–6]. Cr7C3 is well known for its excellent combination of high hardness, excellent wear resistance as well as good corrosion and oxidation resistance, so it has been widely used as the reinforcing phase in the composite coatings [7–10]. The (Cr,Fe)7C3 carbide reinforces composite coating has an excellent wear resistance. First, with the high hardness, the proeutectic (Cr,Fe)7C3 carbides can successfully retard plastic deformation when interacting with the counter surface during the sliding wear process. Therefore, the effect of adhesive deformation on material removal rate is low. High-energy density sources have been widely applied in the hardfacing alloys to enhance wear and corrosion resistance of materials surface, such as electron beam, plasma arc, and laser [11–13]. The gas tungsten arc welding (GTAW) process (also called TIG welding) is used when a good weld appearance and high quality weld are required. In this process, an electric arc forms between a tungsten electrode and a base metal. The arc region is protected by a kind of inert gas or a mixture of inert gases. Electrons emit from the tungsten electrode and accelerate while traveling through the arc. A significant amount of energy, called the work function, is required for an electron to be emitted from the electrode. When the electron enters the workpiece, an amount of energy equivalent to the work function is released to melt the filler and base metal. The purpose of this study is to investigate the effect of carbon addition on microstructure and abrasive property in the hypereutectic Fe–Cr–C alloy. Therefore, a series of high carbon Fe–Cr–C hardfacing alloys are produced by gas tungsten arc welding in this study. The abrasive characteristics of hardfacing alloys with different carbon contents are discussed from the observation of microstructural variation. |