Positivity-preserving discontinuous spectral element methods for compressible multi-species flows

IF 2.5 3区 工程技术 Q3 COMPUTER SCIENCE, INTERDISCIPLINARY APPLICATIONS
Will Trojak , Tarik Dzanic
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引用次数: 0

Abstract

We introduce a novel positivity-preserving numerical stabilisation approach for high-order discontinuous spectral element approximations of compressible multi-species flows. The underlying stabilisation method is the adaptive entropy filtering approach (Dzanic and Witherden, J. Comput. Phys., 468, 2022), which is extended to the conservative formulation of the multi-species flow equations. We show that the straightforward enforcement of entropy constraints in the filter yields poor results around species interfaces and propose an adaptive switch for the entropy bounds based on the convergence properties of the pressure field which drastically improves its performance for multi-species flows. The proposed approach is shown in a variety of numerical experiments applied to the multi-species Euler and Navier–Stokes equations computed on unstructured grids, ranging from shock-fluid interaction problems to three-dimensional viscous flow instabilities. We demonstrate that the approach can retain the high-order accuracy of the underlying numerical scheme even at smooth extrema, ensure the positivity of the species density and pressure in the vicinity of shocks and contact discontinuities, and accurately predict small-scale flow features with minimal numerical dissipation.

用于可压缩多物种流动的正保全非连续谱元方法
我们为可压缩多物种流的高阶非连续谱元近似引入了一种新颖的保正值数值稳定方法。该稳定方法的基础是自适应熵滤波方法(Dzanic 和 Witherden,J. Comput. Phys.,468, 2022),并将其扩展到多物种流动方程的保守公式。我们发现,在滤波器中直接执行熵约束会在物种界面附近产生较差的结果,因此提出了一种基于压力场收敛特性的熵边界自适应切换方法,该方法大大提高了多物种流动的性能。我们在非结构网格上计算的多物种欧拉方程和纳维-斯托克斯方程的各种数值实验中展示了所提出的方法,包括冲击-流体相互作用问题和三维粘性流不稳定性问题。我们证明,该方法即使在平滑极值时也能保持基础数值方案的高阶精度,确保冲击和接触不连续附近的物种密度和压力为正值,并以最小的数值耗散准确预测小尺度流动特征。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Computers & Fluids
Computers & Fluids 物理-计算机:跨学科应用
CiteScore
5.30
自引率
7.10%
发文量
242
审稿时长
10.8 months
期刊介绍: Computers & Fluids is multidisciplinary. The term ''fluid'' is interpreted in the broadest sense. Hydro- and aerodynamics, high-speed and physical gas dynamics, turbulence and flow stability, multiphase flow, rheology, tribology and fluid-structure interaction are all of interest, provided that computer technique plays a significant role in the associated studies or design methodology.
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