Self-similar Reynolds-averaged mechanical–scalar turbulence models for Rayleigh–Taylor, Richtmyer–Meshkov, and Kelvin–Helmholtz instability-induced mixing in the small Atwood number limit

The ability of turbulence models to predict self-similar mixing layers is investigated. The influence of velocity is well captured but no model reproduces the sensitivity of the mixing layer to density differences. A correction proposed for boundary layer flows hardly affects mixing layer predictions. A correction is proposed but is not satisfactory. At last, compressible turbulence effects are investigated. Without corrections, models cannot predict the spreading rate reduction. Standard corrections predict too weak a reduction. The sonic eddy concept is validated whatever the turbulence model. A form suitable for Navier-Stokes codes is proposed.

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Vortex-merger statistical-mechanics model for the late time self-similar evolution of the Kelvin–Helmholtz instability

Physics of Fluids ◽

10.1063/1.1624837 ◽

2003 ◽

Vol 15 (12) ◽

pp. 3776-3785 ◽

Cited By ~ 24

Author(s):

A. Rikanati ◽

U. Alon ◽

D. Shvarts

Keyword(s):

Statistical Mechanics ◽

Late Time ◽

Helmholtz Instability ◽

Mechanics Model ◽

Self Similar ◽

Vortex Merger

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Statistical Model of a Self-Similar Turbulent Plane Shear Layer

Journal of Fluids Engineering ◽

10.1115/1.2820643 ◽

1998 ◽

Vol 120 (2) ◽

pp. 263-273 ◽

Cited By ~ 2

Author(s):

Zuu-Chang Hong ◽

Ming-Hua Chen

Keyword(s):

Shear Layer ◽

Moment Method ◽

Turbulence Models ◽

Equation Model ◽

Turbulence Energy ◽

Turbulence Structure ◽

Mean Velocity ◽

Plane Shear ◽

Self Similar ◽

Turbulent Plane

A turbulence probability density function (pdf) equation model is employed to solve a self-similar turbulent plane shear layer. The proper similarity variable was introduced into the problem of interest to reduce the pdf equation into a spatially one-dimensional equation, which is still three dimensional in velocity space. Then the approximate moment method is employed to solve this simplified pdf equation. By the solutions of this equation, the various one-point mean quantities are immediatelly available. Agreement of the calculated mean velocity, turbulent energy and Reynolds stress with the available experimental data is generally satisfactory indicating that the pdf equation model and the moment method can quantitatively describe the statistics of free turbulence. Additionally, the balance of turbulence energy was calculated and discussed subsequently. It shows that the pdf methods are of more potential in revealing turbulence structure than conventional turbulence models.

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Experimental Investigation of Statistically Steady Rayleigh-Taylor Mixing at High Atwood Numbers

Volume 1: Symposia, Parts A and B ◽

10.1115/fedsm2005-77154 ◽

2005 ◽

Cited By ~ 1

Author(s):

Arindam Banerjee ◽

Malcolm J. Andrews

Keyword(s):

Mixing Layer ◽

Splitter Plate ◽

Hot Wire ◽

Single Wire ◽

Mixture Flow ◽

Gas Channel ◽

Gas Streams ◽

Velocity Statistics ◽

Self Similar ◽

Atwood Number

In the present work, a novel gas channel experiment was used to study the non-equilibrium development of high Atwood number Rayleigh-Taylor mixing. Two gas streams, one containing air and the other containing a Helium-Air mixture, flow parallel to each other separated by a thin splitter plate. The streams meet at the end of the splitter plate leading to the formation of an unstable interface and initiation of buoyancy driven mixing. This buoyancy driven mixing experiment allows for long data collection times, short transients and was statistically steady. The facility was capable of large Atwood number studies (At ∼ 0.75). Here, we describe recent work to measure the self similar evolution of mixing at large density differences (At ∼ 0.1). Diagnostics include a constant temperature Hot Wire anemometer, and high resolution thermocouple measurements. The Hot Wire probe gives velocity statistics of the mixing layer. A multi-position single-wire technique was used to measure the velocity fluctuations in three mutually perpendicular directions. Analysis of the measured data was used to explain the structure of mixing as it develops to a self-similar regime in this flow.

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Challenging Mix Models on Transients to Self-Similarity of Unstably Stratified Homogeneous Turbulence

Journal of Fluids Engineering ◽

10.1115/1.4032533 ◽

2016 ◽

Vol 138 (7) ◽

Cited By ~ 4

Author(s):

Benoît-Joseph Gréa ◽

Alan Burlot ◽

Jérôme Griffond ◽

Antoine Llor

Keyword(s):

Isotropic Turbulence ◽

Turbulence Models ◽

Homogeneous Turbulence ◽

Navier Stokes ◽

Late Time ◽

Data Set ◽

Long Range Correlations ◽

Transient Flows ◽

Transient Regimes ◽

Self Similar

The present work aims at expanding the set of buoyancy-driven unstable reference flows—a critical ingredient in the development of turbulence models—by considering the recently introduced “Unstably Stratified Homogeneous Turbulence” (USHT) in both its self-similar and transient regimes. The previously established accuracy of an anisotropic Eddy-Damped Quasi-Normal Markovian Model (EDQNM) on the USHT has allowed us to: (i) build a data set of well defined transient flows from Homogeneous Isotropic Turbulence (HIT) to late-time self-similar USHT and (ii) on this basis, calibrate, validate, and compare three common Reynolds-Averaged Navier–Stokes (RANS) mixing models (two-equation, Reynolds stress, and two-fluid). The model calibrations were performed on the self-similar flows constrained by predefined long range correlations (Saffman or Batchelor type). Then, with fixed constants, validations were carried out over the various transients defined by the initial Froude number and mixing intensity. Significant differences between the models are observed, but none of them can accurately capture all of the transient regimes at once. Closer inspection of the various model responses hints at possible routes for their improvement.

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