Abstract
This work focuses on the thermal modeling of the Directed Energy Deposition of a composite coating (316L stainless steel reinforced by Tungsten carbides) on a 316L substrate. The developed finite element model predicts the thermal history and the melt pool dimension evolution in the middle section of the clad during deposition. Numerical results were correlated with experimental analysis (light optical and scanning electron microscopies and thermocouple records) to validate the model and discuss the possible solidification mechanisms. It was proven that implementation of forced convection in the boundary conditions was of great importance to ensure equilibrium between input energy and heat losses. The maximum peak temperature shows a slight increase trend for the first few layers, followed by an apparent stabilization with increasing clad height. That demonstrates the high heat loss through boundaries. While in literature, most of the modeling studies are focused on single or few layer geometries, this work describes a multi-layered model able to predict the thermal field history during deposition and give consistent data about the new materiel. The model can be applied on other shapes under recalibration. The methodology of calibration is detailed as well as the sensitivity analysis to input parameters.
Highlights
Directed Energy Deposition (DED) has become an attractive technique for manufacturing thanks to different promising features: fine grain size, low dilution and good mechanical properties
The 2D model calibration process is guided by the sensitivity of the temperature history at the thermocouple to different input parameters
According to [57], ignoring these effects lead to overestimate cooling rates
Summary
Directed Energy Deposition (DED) has become an attractive technique for manufacturing thanks to different promising features: fine grain size, low dilution and good mechanical properties. Zhang et al [21] developed a 3D thermal finite element model in order to study the heat transfer during DED of 420 SS + 4% of molybdenum on a mild steel A36 They found a good correlation in geometric predictions compared to experimentation. Knapp et al [22] developed a 3D model for a single pass AM deposition, applied on stainless steel 316L and Alloy 800H in order to estimate geometry (curved surfaces), transient temperature, cooling rates, velocity distribution as well as solidification mechanisms (secondary dendrite arm spacing) These authors mentioned that acceptable predictions of clad properties were obtained by some previous studies which neglected the effects of convective flow of molten metal inside the pool during the computation of temperature distributions [2,3,23]. These temperatures generated by the validated model provide interesting explanations of the microstructure evolution during deposition
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