Mathematical modeling of the electron-beam wire deposition additive manufacturing by the smoothed particle hydrodynamics method

IF 4.03
Dmitriy Nikolayevich Trushnikov, Elena Georgieva Koleva, Roman Pozolovich Davlyatshin, Roman Mikhailovich Gerasimov, Yuriy Vitalievich Bayandin
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引用次数: 7

Abstract

The actual problem for calculating a shape of free surface of the melt when analyzing the processes of wire-based electron-beam surfacing on the substrate, being introduced into additive manufacturing, is the development of adequate mathematical models of heat and mass transfer. The paper proposed a formulation of the problem of melt motion in the framework of the Lagrangian description. The mathematical statement includes the balance equations for mass, momentum and energy, and physical equations for describing heat and mass transfer.

The smoothed particle hydrodynamics method was used for numerical simulation of the process of wire-based electron-beam surfacing on the substrate made from same materials (titanium or steel). A finite-difference analog of the equations is given and the algorithm for solving the problem is implemented. To integrate the discretized equations Verlet method was utilized. Algorithms are implemented in the open software package LAMMPS.

The numerical simulation results allow the estimation of non-stationary volume temperature distributions, melt flow velocities and pressures, and characteristics of process.

The possibility of applying the developed mathematical model to describe additive production is shown. The comparison of numerical calculations with experimental studies showed good agreement.

Abstract Image

用光滑粒子流体力学方法建立电子束丝沉积增材制造的数学模型
在分析金属丝电子束在基体上堆焊的过程时,计算熔体自由表面形状的实际问题是建立适当的传热传质数学模型,该模型被引入到增材制造中。本文在拉格朗日描述的框架下提出了熔体运动问题的表述。数学表述包括质量、动量和能量的平衡方程,以及描述热量和质量传递的物理方程。采用光滑粒子流体力学方法,对金属丝电子束在钛和钢两种材料基板上的堆焊过程进行了数值模拟。给出了该方程的有限差分模拟,并实现了求解该问题的算法。采用Verlet法对离散方程进行积分。算法在开放软件包LAMMPS中实现。数值模拟结果可以估计非平稳体积温度分布、熔体流动速度和压力以及过程特征。指出了应用所建立的数学模型来描述增材生产的可能性。数值计算结果与实验结果吻合较好。
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