Xingwang Bai scite author profile

A three-dimensional numerical model has been developed to investigate the fluid flow and heat transfer behaviors in multilayer deposition of plasma arc welding (PAW) based wire and arc additive manufacture (WAAM). The volume of fluid (VOF) and porosity enthalpy methods are employed to track the molten pool free surface and solidification front, respectively. A modified double ellipsoidal heat source model is utilized to ensure constant arc heat input in calculation in the case that molten pool surface dynamically changes. Transient simulations were conducted for the 1 st , 2 nd and 21 st layer depositions. The shape and size of deposited bead and weld pool were predicted and compared with experimental results. The results show that for each layer of deposition the Marangoni force plays the most important role in affecting fluid flow, conduction is the dominant method of heat dissipation compared to convection and radiation to the air. As the layer number increases, the length and width of molten pool and the width of deposited bead increase, whilst the layer height decreases. However these dimensions remain constant when the deposited part is sufficiently high. In high layer deposition, where side support is absent, the depth of the molten pool at the rear part is almost flat in the Y direction. The profile of the deposited bead is mainly determined by static pressure caused by gravity and surface tension pressure, therefore the bead profile is nearly circular. The simulated profiles and size dimensions of deposited bead and molten pool were validated with experimental weld appearance, cross-sectional images and process camera images. The simulated results are in good agreement with experimental results.

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Modeling of the moving induction heating used as secondary heat source in weld-based additive manufacturing

Bai

Zhang

Wang

2014

Int J Adv Manuf Technol

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Simulation of microstructure evolution during hybrid deposition and micro-rolling process

et al. 2016

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Improving prediction accuracy of thermal analysis for weld-based additive manufacturing by calibrating input parameters using IR imaging

Bai

Zhang

Wang

2013

Int J Adv Manuf Technol

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Three-dimensional numerical simulation of arc and metal transport in arc welding based additive manufacturing

Zhou

Zhang

Wang

et al. 2016

International Journal of Heat and Mass Transfer

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Xingwang Bai

Numerical analysis of heat transfer and fluid flow in multilayer deposition of PAW-based wire and arc additive manufacturing

Modeling of the moving induction heating used as secondary heat source in weld-based additive manufacturing

Simulation of microstructure evolution during hybrid deposition and micro-rolling process

Improving prediction accuracy of thermal analysis for weld-based additive manufacturing by calibrating input parameters using IR imaging

Three-dimensional numerical simulation of arc and metal transport in arc welding based additive manufacturing

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