Abstract
Hardfacing layers on mild steel substrates were successfully manufactured using a plasma transferred arc welding (PTAW) process to combine tungsten carbide powder and binder metal. Three morphological types of tungsten carbide powder were employed: spherical, fused angular, and mixed powder. The effects of both the morphology and the quantity of tungsten carbide powder on the wear property of the products were determined using a dry sand wheel abrasion test. The results revealed that two conditions effectively increased the wear resistance of the hardfacing layers: the use of spherical tungsten carbide and the use of an increased quantity of tungsten carbide. Moreover, the formation of an interfacial layer of intermetallic compounds (IMCs) between the tungsten carbide and binder metal, and the relationship between the microstructure of the IMC layer and its wear property were also investigated. It was confirmed that, in general, preferential wear occurs in the binder metal region. It was also unveiled that the wear property improves when interfacial IMC bands are formed and grown to appropriate width. To obtain a sound layer more resistant to wear, the PTAW conditions should be adequately controlled. In particular, these include the process peak temperature and the cooling rate, which affect the formation of the microstructure.
Highlights
Introduction and Pasquale CavaliereThe hardfacing process is one of the most famous surface modification technologies.It is a metal working process where harder materials are applied on the surface of base materials by various characteristic methods
Plasma transferred arcarc welding was performed with tungsten carbide (WC)
Wear Mechanism and the IPs Bands Formed around the WC Powders in the Hardfacing Layer
Summary
The hardfacing process is one of the most famous surface modification technologies. It is a metal working process where harder materials are applied on the surface of base materials by various characteristic methods. Plasma transferred arc welding (PTAW) is one of the most effective hardfacing techniques because PTAW makes it easy to control the hardfacing layer, which determines mechanical properties like hardness and wear resistance [4,9]. It provides great flexibility for its application to industrial parts with various morphologies
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