Modeling Rapid Solidification and Melting Processes for Multiphase Flows in a Welding Technology Application

IF 2.8 Q2 MECHANICS
Xin Xiong, L. Könözsy
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引用次数: 0

Abstract

This article presents unsteady simulations of laser welding based on a rapid solidification/melting model using the ANSYS-FLUENT software package with the implementation of a UDF (User Defined Function) C code. It assumes a flat interface of liquid and gas without plasma plume, evaporation and reflection and absorption effect. In the simulations, a variety of parameters are considered with different welding speeds and laser powers. The results show that with the increase of laser power, liquid fraction and velocity, penetration depth and bead width all increase. In contrary, with the increase of welding speed, the temperature, liquid fraction, penetration depth, and bead width all decrease, while the velocity magnitude is an exception. It has also been found that the increase of welding speed distorts the pool shape and forms a long tail in temperature, liquid fraction and velocity contour. The buoyancy force did not have a significant impact on the results, while the convective term makes the velocity, temperature and liquid fraction smaller. Furthermore, the negative Marangoni shear stress makes the velocity along the height and the width direction smaller in the middle of the workpiece and larger on the edges. The simulation results show a similar tendency to that obtained by other authors. The reason for the possible differences is due to the unsteadiness of the fluid flow field and the slightly different boundary conditions imposed in the model presented here. The novelties of this work are unsteady simulations, new boundary conditions and parametric studies relevant to industrial applications.
多相流快速凝固和熔化过程建模在焊接技术中的应用
本文介绍了基于快速凝固/熔化模型的激光焊接非定常仿真,并使用ANSYS-FLUENT软件包实现了UDF(用户定义函数)C代码。它假定液体和气体的界面是平坦的,没有等离子体羽流、蒸发和反射吸收效应。仿真中考虑了不同焊接速度和激光功率下的各种参数。结果表明:随着激光功率的增大,液体分数、速度、穿透深度和熔头宽度均增大;相反,随着焊接速度的增加,焊接温度、焊液分数、焊深和焊头宽度均减小,但速度大小不同。焊接速度的增加使熔池形状发生扭曲,并在温度、液率和速度曲线上形成长尾。浮力对结果的影响不显著,而对流项对速度、温度和液率的影响较小。负马兰戈尼剪切应力使工件沿高度和宽度方向的速度在工件中部较小,而在工件边缘较大。仿真结果与其他作者的结论有相似的趋势。可能存在差异的原因是由于流体流场的非定常以及此处模型中施加的边界条件略有不同。这项工作的新颖之处在于非定常模拟、新的边界条件和与工业应用相关的参数研究。
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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来源期刊
CiteScore
6.90
自引率
3.20%
发文量
0
审稿时长
8 weeks
期刊介绍: The Journal of Applied and Computational Mechanics aims to provide a medium for dissemination of innovative and consequential papers on mathematical and computational methods in theoretical as well as applied mechanics. Manuscripts submitted to the journal undergo a blind peer reviewing procedure conducted by the editorial board. The Journal of Applied and Computational Mechanics devoted to the all fields of solid and fluid mechanics. The journal also welcomes papers that are related to the recent technological advances such as biomechanics, electro-mechanics, advanced materials and micor/nano-mechanics. The scope of the journal includes, but is not limited to, the following topic areas: -Theoretical and experimental mechanics- Dynamic systems & control- Nonlinear dynamics and chaos- Boundary layer theory- Turbulence and hydrodynamic stability- Multiphase flows- Heat and mass transfer- Micro/Nano-mechanics- Structural optimization- Smart materials and applications- Composite materials- Hydro- and aerodynamics- Fluid-structure interaction- Gas dynamics
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