Introduction to turbulence
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* [[Reynolds averaged equations and the Turbulence Closure Problem#The equations governing the instantaneous fluid motions | The equations governing the instantaneous fluid motions ]] | * [[Reynolds averaged equations and the Turbulence Closure Problem#The equations governing the instantaneous fluid motions | The equations governing the instantaneous fluid motions ]] | ||
Revision as of 17:00, 1 April 2007
Contents |
What is turbulence?
The elements of statistical analysis
- The ensemble and ensemble average
- Probability
- Multivariate random vaiables
- Estimation from a Finite Number of Realizations
- Generalization to the estimator of any quantity
Reynolds averaged equations and the turbulence closure problem
- The equations governing the instantaneous fluid motions
- Equations for the average velocity
- The turbulence problem
- The origins of turbulence
- The importance of non-linearity
- The Turbulence Closure problem and the Eddy Viscosity
- The Reynolds Stress Equations
Turbulence kinetic energy
Stationarity and homogeneity
Homogeneous turbulence
Free turbulent shear flows
Wall bounded turbulent flows
Credits
This text was based on "Introduction to Turbulence" by Professor William K.George, Chalmers University of Technology, Sweden.
Return to Turbulence modeling
