Definition of Turbulent Boundary-Layer with Entropy Concept

Rui Zhao; Jili Rong; Haibo Li; Fang Ren

doi:10.1051/matecconf/20167702005

Definition of Turbulent Boundary-Layer with Entropy Concept

Rui Zhao, Jili Rong, Haibo Li, Fang Ren

宇航学院

Beijing Institute of Structure and Environment Engineering

科研成果: 期刊稿件 › 会议文章 › 同行评审

1 引用（Scopus）

摘要

The relationship between the entropy increment and the viscosity dissipation in turbulent boundary-layer is systematically investigated. Through theoretical analysis and direct numerical simulation (DNS), an entropy function f_s is proposed to distinguish the turbulent boundary-layer from the external flow. This approach is proved to be reliable after comparing its performance in the following complex flows, namely, low-speed airfoil flows with different wall temperature, supersonic cavity-ramp flow dominated by the combination of free-shear layer, larger recirculation and shocks, and the hypersonic flow past an aeroplane configuration. Moreover, f_s is deduced from the point of energy, independent of any particular turbulent quantities. That is, this entropy concept could be utilized by other engineering applications related with turbulent boundary-layer, such as turbulence modelling transition prediction and engineering thermal protection.

源语言	英语
文章编号	02005
期刊	MATEC Web of Conferences
卷	77
DOI	https://doi.org/10.1051/matecconf/20167702005
出版状态	已出版 - 3 10月 2016
活动	3rd International Conference on Mechanics and Mechatronics Research, ICMMR 2016 - Chongqing, 中国期限: 15 6月 2016 → 17 6月 2016

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title = "Definition of Turbulent Boundary-Layer with Entropy Concept",

abstract = "The relationship between the entropy increment and the viscosity dissipation in turbulent boundary-layer is systematically investigated. Through theoretical analysis and direct numerical simulation (DNS), an entropy function fs is proposed to distinguish the turbulent boundary-layer from the external flow. This approach is proved to be reliable after comparing its performance in the following complex flows, namely, low-speed airfoil flows with different wall temperature, supersonic cavity-ramp flow dominated by the combination of free-shear layer, larger recirculation and shocks, and the hypersonic flow past an aeroplane configuration. Moreover, fs is deduced from the point of energy, independent of any particular turbulent quantities. That is, this entropy concept could be utilized by other engineering applications related with turbulent boundary-layer, such as turbulence modelling transition prediction and engineering thermal protection.",

author = "Rui Zhao and Jili Rong and Haibo Li and Fang Ren",

note = "Publisher Copyright: {\textcopyright} The Authors, published by EDP Sciences, 2016.; 3rd International Conference on Mechanics and Mechatronics Research, ICMMR 2016 ; Conference date: 15-06-2016 Through 17-06-2016",

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T1 - Definition of Turbulent Boundary-Layer with Entropy Concept

AU - Zhao, Rui

AU - Rong, Jili

AU - Li, Haibo

AU - Ren, Fang

PY - 2016/10/3

Y1 - 2016/10/3

N2 - The relationship between the entropy increment and the viscosity dissipation in turbulent boundary-layer is systematically investigated. Through theoretical analysis and direct numerical simulation (DNS), an entropy function fs is proposed to distinguish the turbulent boundary-layer from the external flow. This approach is proved to be reliable after comparing its performance in the following complex flows, namely, low-speed airfoil flows with different wall temperature, supersonic cavity-ramp flow dominated by the combination of free-shear layer, larger recirculation and shocks, and the hypersonic flow past an aeroplane configuration. Moreover, fs is deduced from the point of energy, independent of any particular turbulent quantities. That is, this entropy concept could be utilized by other engineering applications related with turbulent boundary-layer, such as turbulence modelling transition prediction and engineering thermal protection.

AB - The relationship between the entropy increment and the viscosity dissipation in turbulent boundary-layer is systematically investigated. Through theoretical analysis and direct numerical simulation (DNS), an entropy function fs is proposed to distinguish the turbulent boundary-layer from the external flow. This approach is proved to be reliable after comparing its performance in the following complex flows, namely, low-speed airfoil flows with different wall temperature, supersonic cavity-ramp flow dominated by the combination of free-shear layer, larger recirculation and shocks, and the hypersonic flow past an aeroplane configuration. Moreover, fs is deduced from the point of energy, independent of any particular turbulent quantities. That is, this entropy concept could be utilized by other engineering applications related with turbulent boundary-layer, such as turbulence modelling transition prediction and engineering thermal protection.

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U2 - 10.1051/matecconf/20167702005

DO - 10.1051/matecconf/20167702005

M3 - Conference article

AN - SCOPUS:84994032280

SN - 2261-236X

VL - 77

JO - MATEC Web of Conferences

JF - MATEC Web of Conferences

M1 - 02005

T2 - 3rd International Conference on Mechanics and Mechatronics Research, ICMMR 2016

Y2 - 15 June 2016 through 17 June 2016

ER -

Definition of Turbulent Boundary-Layer with Entropy Concept

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