Numerical Investigation on Local Non-equilibrium Flows Using a Diatomic Nonlinear Constitutive Model

TL;DR

This paper introduces a nonlinear diatomic constitutive model (NCCR) for simulating hypersonic gas flows, outperforming traditional NSF in non-equilibrium regimes by providing more accurate results aligned with DSMC and experimental data.

Contribution

The paper develops a stable, efficient coupled algorithm for the NCCR model, demonstrating its superior accuracy over NSF in non-equilibrium hypersonic flow simulations.

Findings

NCCR matches NSF in continuum flow regimes.

NCCR provides more accurate results than NSF in non-equilibrium flows.

NCCR results agree well with DSMC and experimental data.

Abstract

The linear Navier-Stokes-Fourier (NSF) constitutive relations are capable of simulating the near-continuum flows, but fail in description of those flows which are removed far away from local equilibrium. In this paper, a diatomic nonlinear model named as nonlinear coupled constitutive relations (NCCR), derived from Eu's generalized hydrodynamics and proposed by Myong, is presented as an alternative for simulating these hypersonic gas flows with a goal of recovering NSF's solutions in continuum regime and being superior in transition regime. To guarantee stable computation, a reliable and efficient coupled algorithm is proposed for this diatomic nonlinear constitutive model. Constitutive-curve analysis is carried out in detail to compare this coupled algorithm with Myong's previous algorithm. Local flow regions are investigated carefully in these hypersonic flows past a cone tip, a hollow cylinder-flare and a HTV-type vehicle. The convergent solutions of NCCR model are compared with NSF, DSMC calculations and experiment. It is demonstrated that the NCCR model works as efficiently as the NSF model in continuum regime, but more accurately compared with DSMC and experiment than NSF in non-equilibrium flows. The discrepancies of flow- field and surface parameters, imply a potential for remedying NSF's deficiency in local non-equilibrium regions.