Compressibility, turbulence and high speed flow / Thomas B. Gatski, Jean-Paul Bonnet.

Format:

Book

Author/Creator:

Gatski, T. B.

Bonnet, Jean-Paul, 1949- author.

Series:

Gale eBooks

Language:

English

Subjects (All):

Turbulence--Mathematical models.

Turbulence.

Compressibility.

Physical Description:

1 online resource (xiv, 328 pages) : illustrations (some color)

Edition:

2nd ed.

Place of Publication:

Amsterdam ; Boston : Elsevier/AP, 2013.

Oxford : Academic Press, 2013.

Language Note:

English

Summary:

Compressibility, Turbulence and High Speed Flow introduces the reader to the field of compressible turbulence and compressible turbulent flows across a broad speed range, through a unique complimentary treatment of both the theoretical foundations and the measurement and analysis tools currently used. The book provides the reader with the necessary background and current trends in the theoretical and experimental aspects of compressible turbulent flows and compressible turbulence. Detailed derivations of the pertinent equations describing the motion of such turbulent flows is provid

Contents:

Half Title; Title Page; Copyright; Dedication; Contents; Preface to the Second Edition; Preface to the First Edition; Kinematics, Thermodynamics and Fluid Transport Properties; 1.1 Kinematic Preliminaries; 1.1.1 Motion of Material Elements; 1.1.2 Deformation; 1.1.3 Reynolds Transport Theorem; 1.2 Equilibrium Thermodynamics; 1.3 Compressible Subsonic and Supersonic Flows; 1.4 Turbulent Flows and Compressible Turbulence; Compressible Flow Dynamics; 2.1 Mass Conservation; 2.2 Momentum Conservation; 2.2.1 Surface Forces: The Stress Tensor; 2.2.2 Body Forces; 2.3 Energy Conservation

2.4 Solenoidal Velocity Fields and Density Changes2.5 Two-Dimensional Flow and a Reynolds Analogy; Compressible Turbulent Flow; 3.1 Averaged and Filtered Variables; 3.1.1 Reynolds Average; 3.1.2 Average Over Fixed Phase; 3.1.3 Temporal LES Filters; 3.1.4 Spatial LES Filters; 3.2 Density-Weighted Variables; 3.3 Transport Equations for the Mean/Resolved Field; 3.4 Fluctuation Transport Equations; 3.5 Momentum and Thermal Flux Relationships; 3.5.1 Strong Reynolds Analogy; 3.5.1.1 Morkovin's Relations; 3.5.1.2 Extended Forms; 3.5.2 Morkovin's Hypothesis

Experimental Measurement and Analysis Strategies4.1 Experimental Constraints for Supersonic Flows; 4.1.1 Constraints on Wind Tunnel Testing; 4.1.2 Constraints on Data Collection and Measurement Apparatus; 4.2 Measurement Methods; 4.2.1 Intrusive Method: Hot-Wire Anemometry; 4.2.1.1 Anemometers and Probes; 4.2.1.2 Data Reduction; 4.2.2 Non-Intrusive Methods; 4.2.2.1 With Particles: LDV, PIV, and DGV; 4.2.2.2 Without Particles: Rayleigh-Scattering Methods; 4.3 Analysis Using Modal Representations; 4.4 Reynolds- and Favre-Averaged Correlations; Prediction Strategies and Closure Models

5.1 Direct Numerical Simulations5.1.1 Homogeneous Turbulence; 5.1.2 Homogeneous Sheared Turbulence; 5.1.3 Inhomogeneous Sheared Turbulence; 5.2 Large Eddy Simulations and Hybrid Methods; 5.3 Reynolds-Averaged Navier-Stokes Formulation; 5.3.1 Turbulent Stress and Stress Anisotropy; 5.3.1.1 Turbulent Stress and Kinetic Energy Transport Equations; 5.3.1.2 Turbulent Stress Anisotropy Transport Equation; 5.3.2 Turbulent Energy Dissipation Rate; 5.3.2.1 Dilatation Dissipation Rate; 5.3.2.2 Solenoidal Dissipation Rate Transport Equation; 5.3.3 Velocity-Pressure Gradient Correlation

5.3.3.1 Pressure-Dilatation5.3.3.2 Pressure-Strain Rate; 5.3.4 Scalar Fluxes and Variances; 5.3.4.1 Heat Flux and Temperature Variance; 5.3.4.2 Mass Flux and Density Variance; 5.3.5 Other Closure Issues; 5.3.5.1 Polynomial Representations for Second-Moments and Scalar Fluxes; 5.3.5.2 Wall Proximity Effects; Compressible Shear Layers; 6.1 Jets; 6.2 Mixing-Layers; 6.2.1 Flow Structure; 6.2.2 Spreading Rate; 6.2.2.1 Subsonic Spreading Rate; 6.2.2.2 Supersonic Spreading Rate; 6.2.2.3 Fluctuating Pressure Field and Prediction; 6.3 Wakes; 6.3.1 Base Flows; 6.3.2 Flat Plate Wakes

6.4 Boundary Layers

Notes:

Includes bibliographical references and index.

Previous ed.: Oxford: Elsevier Science, 2008.

ISBN:

9781299286832

1299286836

9780123973184

012397318X

OCLC:

860498376