Jasutyn, Kevin scite author profile

Jasutyn, Kevin

3Publications

12Citation Statements Received

55Citation Statements Given

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RWTH Aachen University

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Application and benchmark of SPH for modeling the impact in thermal spraying

et al. 2022

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The properties of a thermally sprayed coating, such as its durability or thermal conductivity depend on its microstructure, which is in turn directly related to the particle impact process. To simulate this process, we present a 3D smoothed particle hydrodynamics (SPH) model, which represents the molten droplet as an incompressible fluid, while a semi-implicit Enthalpy-Porosity method is applied for modeling the phase change during solidification. In addition, we present an implicit correction for SPH simulations, based on well-known approaches, from which we can observe improved performance and simulation stability. We apply our SPH method to the impact and solidification of Al$$_2$$ 2 O$$_3$$ 3 droplets onto a substrate and perform a comprehensive quantitative comparison of our method with the commercial software Ansys Fluent using the volume of fluid (VOF) approach, while taking identical physical effects into consideration. The results are evaluated in depth, and we discuss the applicability of either method for the simulation of thermal spray deposition. We also evaluate the droplet spread factor given varying initial droplet diameters and compare these results with an analytic expression from the previous literature. We show that SPH is an excellent method for solving this free surface problem accurately and efficiently.

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Modeling the Droplet Impact on the Substrate with Surface Preparation in Thermal Spraying with SPH

et al. 2023

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The properties of thermally sprayed coatings depend heavily on their microstructure. The microstructure is determined by the dynamics of the impact of the droplets on the substrate surface and the subsequent overlapping of the previously solidified and deformed droplets. Substrate preparation prior to spraying ensures strong adhesion of the coating. This includes roughening and preheating of the substrate surface. In the present study, the smoothed particle hydrodynamics (SPH) method is used to model the Al2O3 impact on a preheated substrate and a roughened substrate surface. A semi-implicit enthalpy–porosity method is applied to simulate the solidification process in the mushy zone. In addition, an implicit correction for SPH simulations is used to improve the performance and stability of the simulation. To investigate the dynamics of heat transfer in the contact between the surface and the droplet, the discretization of the substrate is also taken into account. The results show that the studied substrate surface conditions affect the splat morphology and the solidification process. Subsequently, the simulation of multiple droplets for coating formation is also performed and analyzed.

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Application and Benchmark of SPH for Modeling the Impact in Thermal Spraying

Jeske¹,

Bender²,

Bobzin³

et al. 2021

Preprint

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Jasutyn, Kevin

Application and benchmark of SPH for modeling the impact in thermal spraying

Modeling the Droplet Impact on the Substrate with Surface Preparation in Thermal Spraying with SPH

Application and Benchmark of SPH for Modeling the Impact in Thermal Spraying

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