Finite Element Simulation for Residual Stresses in Weling Process

He Yu; Shou Ju Li; Ying Xi Liu

doi:10.4028/www.scientific.net/KEM.353-358.1915

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Development of Diamond-Like Carbon (DLC) Coating Compatible Surface by Fine Particle Bombardment (FPB)
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The Research of Integral Cu-W Electric Contact by Friction Welding
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Three Dimensional Monte Carlo Simulation of Grain Growth in HAZ of Stainless Steel SUS316
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Static and Dynamic Force Analysis to Large-Scale Bed of Leather Cutting Machine Tool
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Finite Element Simulation for Residual Stresses in Weling Process

Abstract:

Owing to localized heating by the welding process and subsequent rapid cooling, the residual stresses can arise in the weld itself and in the base metals. The prediction procedures of the residual stresses in welding process were presented by using finite element techniques. The bilinear elastic-plastic material model based on Von Mises yield criterion was developed. The material non-linearity of weldment and welding fluid was dealt with using an incremental technique. Inside each step, the Newton-Raphson iteration method was utilized. A fully coupled thermo-mechanical two-dimensional analysis was performed with finite element method. The model applied in this study adopts the technique of element birth and death to simulate the weld filler variation with time in multi-pass welded joints. The effects of welding speed on residual stresses are discussed.