Lattice Boltzmann Computation of Plasma Jet Behaviors : part II Argon-Nitrogen Mixture

TL;DR

This paper uses lattice Boltzmann methods to simulate temperature-dependent plasma jet behaviors for an Argon-Nitrogen mixture, validating results against established software to enhance understanding of plasma spraying dynamics.

Contribution

It extends lattice Boltzmann simulations to temperature-dependent plasma jets with a focus on Argon-Nitrogen mixtures, validated against existing turbulence models.

Findings

Successful simulation of plasma jet dynamics with temperature-dependent parameters

Validation of lattice Boltzmann results against GENMIX and Jets & Poudres software

Insights into thermal and dynamic characteristics of plasma-jet flows

Abstract

. Plasma jets are a high temperature flows, then all physical parameters are temperature dependent. This work aims to address the issue of simulating plasma-jet from the point of view of extending the applications to simulating flows with temperature-dependent diffusion parameters (viscosity and diffusivity), focusing on the phenomena occurring in plasma-jet flow for a mixture of plasma gases, N2-Ar62.5% vol. Argon and Nitrogen are two gases of the most ones used in plasma spraying. The mixture is used when looking for some jet properties. We limit our effort to take out the dynamic and thermal characteristics of this complex flow using the lattice Boltzmann equation. An important section focuses mainly on the validation of our results with compute jet dynamics software such as GENMIX and Jets & Poudres developed in laboratory SPCTS in several updated edition. These codes established for many turbulence models (k-epsilon, k-omega, Prandtl's models...) are helpful numerical keys for understanding the physics of plasma jets and plasma spraying.