Convergence properties of detonation simulations

Chengeng Qian; Cheng Wang; Jian Nan Liu; Axel Brandenburg; Nils E.L. Haugen; Mikhael A. Liberman

doi:10.1080/03091929.2019.1668382

Convergence properties of detonation simulations

Chengeng Qian, Cheng Wang, Jian Nan Liu, Axel Brandenburg^*, Nils E.L. Haugen, Mikhael A. Liberman

^*Corresponding author for this work

School of Mechatronical Engineering

Research output: Contribution to journal › Article › peer-review

8 Citations (Scopus)

Abstract

We present a high-resolution convergence study of detonation initiated by a temperature gradient in a stoichiometric hydrogen–oxygen mixture using the PENCIL CODE and compare with a code that employs a fifth order weighted essentially non-oscillating (WENO) scheme. With Mach numbers reaching 10–30, a certain amount of shock viscosity is needed in the PENCIL CODE to remove or reduce numerical pressure oscillations on the grid scale at the position of the shock. Detonation is found to occur for intermediate values of the shock viscosity parameter. At fixed values of this parameter, the numerical error associated with those small wiggles in the pressure profile is found to decrease with decreasing mesh width δx like δx^−1.4 down to δx = 0.2μm. With the WENO scheme, solutions are smooth at δx = 10μm, but no detonation is obtained for δx = 5μm. This is argued to be an artifact of a decoupling between pressure and reaction fronts.

Original language	English
Pages (from-to)	58-76
Number of pages	19
Journal	Geophysical and Astrophysical Fluid Dynamics
Volume	114
Issue number	1-2
DOIs	https://doi.org/10.1080/03091929.2019.1668382
Publication status	Published - 3 Mar 2020

Keywords

Combustion
chemical reaction
detonation
numerical methods
shock waves

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title = "Convergence properties of detonation simulations",

abstract = "We present a high-resolution convergence study of detonation initiated by a temperature gradient in a stoichiometric hydrogen–oxygen mixture using the PENCIL CODE and compare with a code that employs a fifth order weighted essentially non-oscillating (WENO) scheme. With Mach numbers reaching 10–30, a certain amount of shock viscosity is needed in the PENCIL CODE to remove or reduce numerical pressure oscillations on the grid scale at the position of the shock. Detonation is found to occur for intermediate values of the shock viscosity parameter. At fixed values of this parameter, the numerical error associated with those small wiggles in the pressure profile is found to decrease with decreasing mesh width δx like δx−1.4 down to δx = 0.2μm. With the WENO scheme, solutions are smooth at δx = 10μm, but no detonation is obtained for δx = 5μm. This is argued to be an artifact of a decoupling between pressure and reaction fronts.",

keywords = "Combustion, chemical reaction, detonation, numerical methods, shock waves",

author = "Chengeng Qian and Cheng Wang and Liu, {Jian Nan} and Axel Brandenburg and Haugen, {Nils E.L.} and Liberman, {Mikhael A.}",

note = "Publisher Copyright: {\textcopyright} 2019, {\textcopyright} 2019 The Author(s). Published by Informa UK Limited, trading as Taylor & Francis Group.",

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doi = "10.1080/03091929.2019.1668382",

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AU - Qian, Chengeng

AU - Wang, Cheng

AU - Liu, Jian Nan

AU - Brandenburg, Axel

AU - Haugen, Nils E.L.

AU - Liberman, Mikhael A.

PY - 2020/3/3

Y1 - 2020/3/3

N2 - We present a high-resolution convergence study of detonation initiated by a temperature gradient in a stoichiometric hydrogen–oxygen mixture using the PENCIL CODE and compare with a code that employs a fifth order weighted essentially non-oscillating (WENO) scheme. With Mach numbers reaching 10–30, a certain amount of shock viscosity is needed in the PENCIL CODE to remove or reduce numerical pressure oscillations on the grid scale at the position of the shock. Detonation is found to occur for intermediate values of the shock viscosity parameter. At fixed values of this parameter, the numerical error associated with those small wiggles in the pressure profile is found to decrease with decreasing mesh width δx like δx−1.4 down to δx = 0.2μm. With the WENO scheme, solutions are smooth at δx = 10μm, but no detonation is obtained for δx = 5μm. This is argued to be an artifact of a decoupling between pressure and reaction fronts.

AB - We present a high-resolution convergence study of detonation initiated by a temperature gradient in a stoichiometric hydrogen–oxygen mixture using the PENCIL CODE and compare with a code that employs a fifth order weighted essentially non-oscillating (WENO) scheme. With Mach numbers reaching 10–30, a certain amount of shock viscosity is needed in the PENCIL CODE to remove or reduce numerical pressure oscillations on the grid scale at the position of the shock. Detonation is found to occur for intermediate values of the shock viscosity parameter. At fixed values of this parameter, the numerical error associated with those small wiggles in the pressure profile is found to decrease with decreasing mesh width δx like δx−1.4 down to δx = 0.2μm. With the WENO scheme, solutions are smooth at δx = 10μm, but no detonation is obtained for δx = 5μm. This is argued to be an artifact of a decoupling between pressure and reaction fronts.

KW - Combustion

KW - chemical reaction

KW - detonation

KW - numerical methods

KW - shock waves

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DO - 10.1080/03091929.2019.1668382

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SN - 0309-1929

VL - 114

SP - 58

EP - 76

JO - Geophysical and Astrophysical Fluid Dynamics

JF - Geophysical and Astrophysical Fluid Dynamics

IS - 1-2

ER -

Convergence properties of detonation simulations

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Keywords

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