Scaling of maximum probability density function of velocity increments in turbulent Rayleigh-Bénard convection

In this paper, we apply a scaling analysis of the maximum of the probability density function(pdf) of velocity increments, i.e., max() = max()up p u, for a velocity field of turbulent Rayleigh-Bénard convection obtained at the Taylor-microscale Reynolds number Re60. The scaling exponent is comparabl...

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Published inJournal of hydrodynamics. Series B Vol. 26; no. 3; pp. 351 - 362
Main Author 邱翔 黄永祥 周全 孙超
Format Journal Article
LanguageEnglish
Published Singapore Elsevier Ltd 01.07.2014
Springer Singapore
Subjects
Engineering
Engineering Fluid Dynamics
Exponents
Fluctuation
Fluid dynamics
Fluid flow
Hydrology/Water Resources
Numerical and Computational Physics
PDF格式
probability density function (pdf)
Probability density functions
Rayleigh-Benard convection
Rayleigh-Bénard convection
scaling
Simulation
Turbulence
Turbulent flow
对流
标度指数
概率密度函数
瑞利
缩放
速度增量
Rayleigh-Bénard convection
scaling
probability density function (pdf)
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ISSN1001-6058
1878-0342
DOI10.1016/S1001-6058(14)60040-8

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Summary:In this paper, we apply a scaling analysis of the maximum of the probability density function(pdf) of velocity increments, i.e., max() = max()up p u, for a velocity field of turbulent Rayleigh-Bénard convection obtained at the Taylor-microscale Reynolds number Re60. The scaling exponent is comparable with that of the first-order velocity structure function, (1), in which the large-scale effect might be constrained, showing the background fluctuations of the velocity field. It is found that the integral time T(x/ D) scales as T(x/ D)(x/ D), with a scaling exponent =0.25 0.01, suggesting the large-scale inhomogeneity of the flow. Moreover, the pdf scaling exponent (x, z) is strongly inhomogeneous in the x(horizontal) direction. The vertical-direction-averaged pdf scaling exponent (x) obeys a logarithm law with respect to x, the distance from the cell sidewall, with a scaling exponent 0.22 within the velocity boundary layer and 0.28 near the cell sidewall. In the cell's central region, (x, z) fluctuates around 0.37, which agrees well with (1) obtained in high-Reynolds-number turbulent flows, implying the same intermittent correction. Moreover, the length of the inertial range represented in decade()IT x is found to be linearly increasing with the wall distance x with an exponent 0.65 0.05.
Bibliography:31-1563/T
QIU Xiang, HUANG Yong-xiang , ZHOU Quan,SUN Chao (School of Science, Shanghai Institute of Technology, Shanghai 200235, China;Shanghai Institute of Applied Mathematics and Mechanics, Shanghai University, Shanghai 200072, China ; Physics of Fluids Group, University of Twente, AE Enschede, The Netherlands)
In this paper, we apply a scaling analysis of the maximum of the probability density function(pdf) of velocity increments, i.e., max() = max()up p u, for a velocity field of turbulent Rayleigh-Bénard convection obtained at the Taylor-microscale Reynolds number Re60. The scaling exponent is comparable with that of the first-order velocity structure function, (1), in which the large-scale effect might be constrained, showing the background fluctuations of the velocity field. It is found that the integral time T(x/ D) scales as T(x/ D)(x/ D), with a scaling exponent =0.25 0.01, suggesting the large-scale inhomogeneity of the flow. Moreover, the pdf scaling exponent (x, z) is strongly inhomogeneous in the x(horizontal) direction. The vertical-direction-averaged pdf scaling exponent (x) obeys a logarithm law with respect to x, the distance from the cell sidewall, with a scaling exponent 0.22 within the velocity boundary layer and 0.28 near the cell sidewall. In the cell's central region, (x, z) fluctuates around 0.37, which agrees well with (1) obtained in high-Reynolds-number turbulent flows, implying the same intermittent correction. Moreover, the length of the inertial range represented in decade()IT x is found to be linearly increasing with the wall distance x with an exponent 0.65 0.05.
Rayleigh-Bénard convection,scaling,probability density function(pdf)
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ISSN:1001-6058
1878-0342
DOI:10.1016/S1001-6058(14)60040-8