Comparative study of the discrete velocity and the moment method for rarefied gas flows

Weiqi Yang; Xiao Jun Gu; David Emerson; Yonghao Zhang; Shuo Tang

doi:10.1063/1.5119619

Comparative study of the discrete velocity and the moment method for rarefied gas flows

Weiqi Yang, Xiao Jun Gu, David Emerson, Yonghao Zhang, Shuo Tang

School of Astronautics

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

3 Scopus citations

Abstract

In the study of rarefied gas dynamics, the discrete velocity method (DVM) has been widely employed to solve the gas kinetic equations. However, it is usually computationally expensive in dealing with complex geometry and high Mach number flows. In the present work, both classical third-order time implicit DVM and the moment method are employed in finding steady-state solutions of the force-driven Poiseuille flow and flow past a circle cylinder. Their performance, in terms of accuracy, has been compared and analyzed. Choosing the velocity distribution functions (VDFs) obtained from DVM solutions as the benchmark, we reconstruct the expanded VDFs using regularized 13 moment equations (R13) and regularized 26 moment equations (R26) and then compare the accuracy of the expanded VDFs with different order of Hermite polynomial expansions. From the computed velocity profiles and reconstructed VDFs, we have found that the moment method can extend the macroscopic equations into the early transition regime, and the R26 can relatively accurately represent the characteristics of the VDFs in comparison with the gas kinetic model. Conversely, the Navier-Stokes-Fourier (NSF) equations are not able to produce an accurate description of the expanded distribution functions.

Original language	English
Title of host publication	31st International Symposium on Rarefied Gas Dynamics, RGD 2018
Editors	Duncan Lockerby, David R. Emerson, Lei Wu, Yonghao Zhang
Publisher	American Institute of Physics Inc.
ISBN (Electronic)	9780735418745
DOIs	https://doi.org/10.1063/1.5119619
State	Published - 5 Aug 2019
Event	31st International Symposium on Rarefied Gas Dynamics, RGD 2018 - Glasgow, United Kingdom Duration: 23 Jul 2018 → 27 Jul 2018

Publication series

Name	AIP Conference Proceedings
Volume	2132
ISSN (Print)	0094-243X
ISSN (Electronic)	1551-7616

Conference

Conference	31st International Symposium on Rarefied Gas Dynamics, RGD 2018
Country/Territory	United Kingdom
City	Glasgow
Period	23/07/18 → 27/07/18

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10.1063/1.5119619

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Yang, W., Gu, X. J., Emerson, D., Zhang, Y., & Tang, S. (2019). Comparative study of the discrete velocity and the moment method for rarefied gas flows. In D. Lockerby, D. R. Emerson, L. Wu, & Y. Zhang (Eds.), 31st International Symposium on Rarefied Gas Dynamics, RGD 2018 Article 120006 (AIP Conference Proceedings; Vol. 2132). American Institute of Physics Inc.. https://doi.org/10.1063/1.5119619

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title = "Comparative study of the discrete velocity and the moment method for rarefied gas flows",

abstract = "In the study of rarefied gas dynamics, the discrete velocity method (DVM) has been widely employed to solve the gas kinetic equations. However, it is usually computationally expensive in dealing with complex geometry and high Mach number flows. In the present work, both classical third-order time implicit DVM and the moment method are employed in finding steady-state solutions of the force-driven Poiseuille flow and flow past a circle cylinder. Their performance, in terms of accuracy, has been compared and analyzed. Choosing the velocity distribution functions (VDFs) obtained from DVM solutions as the benchmark, we reconstruct the expanded VDFs using regularized 13 moment equations (R13) and regularized 26 moment equations (R26) and then compare the accuracy of the expanded VDFs with different order of Hermite polynomial expansions. From the computed velocity profiles and reconstructed VDFs, we have found that the moment method can extend the macroscopic equations into the early transition regime, and the R26 can relatively accurately represent the characteristics of the VDFs in comparison with the gas kinetic model. Conversely, the Navier-Stokes-Fourier (NSF) equations are not able to produce an accurate description of the expanded distribution functions.",

author = "Weiqi Yang and Gu, {Xiao Jun} and David Emerson and Yonghao Zhang and Shuo Tang",

note = "Publisher Copyright: {\textcopyright} 2019 Author(s).; 31st International Symposium on Rarefied Gas Dynamics, RGD 2018 ; Conference date: 23-07-2018 Through 27-07-2018",

year = "2019",

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Yang, W, Gu, XJ, Emerson, D, Zhang, Y & Tang, S 2019, Comparative study of the discrete velocity and the moment method for rarefied gas flows. in D Lockerby, DR Emerson, L Wu & Y Zhang (eds), 31st International Symposium on Rarefied Gas Dynamics, RGD 2018., 120006, AIP Conference Proceedings, vol. 2132, American Institute of Physics Inc., 31st International Symposium on Rarefied Gas Dynamics, RGD 2018, Glasgow, United Kingdom, 23/07/18. https://doi.org/10.1063/1.5119619

Comparative study of the discrete velocity and the moment method for rarefied gas flows. / Yang, Weiqi; Gu, Xiao Jun; Emerson, David et al.
31st International Symposium on Rarefied Gas Dynamics, RGD 2018. ed. / Duncan Lockerby; David R. Emerson; Lei Wu; Yonghao Zhang. American Institute of Physics Inc., 2019. 120006 (AIP Conference Proceedings; Vol. 2132).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

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T1 - Comparative study of the discrete velocity and the moment method for rarefied gas flows

AU - Yang, Weiqi

AU - Gu, Xiao Jun

AU - Emerson, David

AU - Zhang, Yonghao

AU - Tang, Shuo

PY - 2019/8/5

Y1 - 2019/8/5

N2 - In the study of rarefied gas dynamics, the discrete velocity method (DVM) has been widely employed to solve the gas kinetic equations. However, it is usually computationally expensive in dealing with complex geometry and high Mach number flows. In the present work, both classical third-order time implicit DVM and the moment method are employed in finding steady-state solutions of the force-driven Poiseuille flow and flow past a circle cylinder. Their performance, in terms of accuracy, has been compared and analyzed. Choosing the velocity distribution functions (VDFs) obtained from DVM solutions as the benchmark, we reconstruct the expanded VDFs using regularized 13 moment equations (R13) and regularized 26 moment equations (R26) and then compare the accuracy of the expanded VDFs with different order of Hermite polynomial expansions. From the computed velocity profiles and reconstructed VDFs, we have found that the moment method can extend the macroscopic equations into the early transition regime, and the R26 can relatively accurately represent the characteristics of the VDFs in comparison with the gas kinetic model. Conversely, the Navier-Stokes-Fourier (NSF) equations are not able to produce an accurate description of the expanded distribution functions.

AB - In the study of rarefied gas dynamics, the discrete velocity method (DVM) has been widely employed to solve the gas kinetic equations. However, it is usually computationally expensive in dealing with complex geometry and high Mach number flows. In the present work, both classical third-order time implicit DVM and the moment method are employed in finding steady-state solutions of the force-driven Poiseuille flow and flow past a circle cylinder. Their performance, in terms of accuracy, has been compared and analyzed. Choosing the velocity distribution functions (VDFs) obtained from DVM solutions as the benchmark, we reconstruct the expanded VDFs using regularized 13 moment equations (R13) and regularized 26 moment equations (R26) and then compare the accuracy of the expanded VDFs with different order of Hermite polynomial expansions. From the computed velocity profiles and reconstructed VDFs, we have found that the moment method can extend the macroscopic equations into the early transition regime, and the R26 can relatively accurately represent the characteristics of the VDFs in comparison with the gas kinetic model. Conversely, the Navier-Stokes-Fourier (NSF) equations are not able to produce an accurate description of the expanded distribution functions.

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A2 - Lockerby, Duncan

A2 - Emerson, David R.

A2 - Wu, Lei

A2 - Zhang, Yonghao

PB - American Institute of Physics Inc.

T2 - 31st International Symposium on Rarefied Gas Dynamics, RGD 2018

Y2 - 23 July 2018 through 27 July 2018

ER -

Comparative study of the discrete velocity and the moment method for rarefied gas flows

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