Abstract
Hard-facing process is widely used for improving the wear resistance of mild steel. During the application of hard-facing, due to high temperatures, residual stresses and deformations may occur. The tensile residual stresses may cause crack propagation on the hard-faced part. The purpose of this study is to utilise minimum computer work for minimizing these residual stresses and deformations during the hard-facing of mild steel. The fully coupled transient heat transfer and structural analysis was performed for calculations. The double-ellipsoidal moving heat source was utilised to simulate the heat input from the gas metal arc welding (GMAW). Only eight numerical simulations were performed to minimize the computer work; the grey relational analysis was used for minimizing both the residual stresses and deformations. Welding speed, welding current, and welding pattern were considered as changing parameters. At the end of the numerical and statistical solutions, it is observed that heat input should be kept minimum to minimize the stresses and deformations. But it is obvious that the heat input must provide a temperature greater than the melding point. Straight patterns always produce better results for minimizing stresses and deformations. Transverse stress at the beginning and end of the longitudinal path gets higher significantly after cooling. Cooling does not affect the total deformation.
Highlights
Most of the hard-facing applications are performed by the arc welding processes commonly known as gas tungsten arc welding (GTAW), shielded metal arc welding (SMAW), or gas metal arc welding (GMAW)
They concluded that welding conditions and heat source parameters influence peak temperatures in the fusion zone (FZ) and affect the welded plate's transient temperature distributions
Numerical Procedure The most critical input of the GMAW hard-facing process is the transient heat generated by the arc
Summary
Most of the hard-facing applications are performed by the arc welding processes commonly known as gas tungsten arc welding (GTAW), shielded metal arc welding (SMAW), or gas metal arc welding (GMAW). Goldak et al proposed a new geometrical method to simulate the heat input during the arc welding processes [1]. Since their model, which is called the double ellipsoidal moving heat source model, has been used by many authors. The effects of welding conditions and heat source parameters on temperature variations in butt joint welding were analyzed by Gery et al [2]. They concluded that welding conditions and heat source parameters influence peak temperatures in the fusion zone (FZ) and affect the welded plate's transient temperature distributions
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