NOC:Turbulence Modeling

Lecture 1 - Introduction to turbulence

Lecture 2 - Statistical Analysis: An approach of modelling turbulence - I

Lecture 3 - Statistical Analysis: An approach of modelling turbulence - II

Lecture 4 - Statistical Analysis and Cartesian tensors - I

Lecture 5 - Statistical Analysis and Cartesian tensors - II

Lecture 6 - Navier Stokes: the governing equations - 1

Lecture 7 - Navier Stokes: the governing equations - 2

Lecture 8 - RANS equations I - 1

Lecture 9 - RANS equations I - 2

Lecture 10 - RANS equations II - 1

Lecture 11 - RANS equations II - 2

Lecture 12 - Reynold's stress: governing equations - I

Lecture 13 - Reynold's stress: governing equations - II

Lecture 14 - Statistical Stationarity and Homogenity in Plane Couttee Flows - I

Lecture 15 - Statistical Stationarity and Homogenity in Plane Couttee Flows - II

Lecture 16 - Pressure-strain-rate and redistribution of turbulence in flows - I

Lecture 17 - Pressure-strain-rate and redistribution of turbulence in flows - II

Lecture 18 - Turbulence Kinetic Energy and it's dissipation rate - I

Lecture 19 - Turbulence Kinetic Energy and it's dissipation rate - II

Lecture 20 - Production rate of TKE and Mean TKE - I

Lecture 21 - Production rate of TKE and Mean TKE - II

Lecture 22 - Turbulent Boundary Layer: Order of Magnitude analysis - I

Lecture 23 - Turbulent Boundary Layer: Order of Magnitude analysis - II

Lecture 24 - Inner and Outer TBL: Order of magnitude analysis - I

Lecture 25 - Inner and Outer TBL: Order of magnitude analysis - II

Lecture 26 - Inner layer equation, constant stress layer, and inner velocity scaling - I

Lecture 27 - Inner layer equation, constant stress layer, and inner velocity scaling - II

Lecture 28 - Reynold's Averaged Navier-Stokes (RANS) models - I

Lecture 29 - Reynold's Averaged Navier-Stokes (RANS) models - II

Lecture 30 - Different approaches to solve turbulence closure problem - I

Lecture 31 - Different approaches to solve turbulence closure problem - II

Lecture 32 - Modelling of turbulent kinetic energy (k): production, destruction, and dissipation rate - I

Lecture 33 - Modelling of turbulent kinetic energy (k): production, destruction, and dissipation rate - II

Lecture 34 - Standard k-? model and the model constants - I

Lecture 35 - Standard k-? model and the model constants - II

Lecture 36 - Standard k-? model, RNG k-? model, and Prandlt’s one equation model - I

Lecture 37 - Standard k-? model, RNG k-? model, and Prandlt’s one equation model - II

Lecture 38 - New model k- ? and model constants - I

Lecture 39 - New model k- ? and model constants - II

Lecture 40 - Introduciton to wall-functions - I

Lecture 41 - Introduciton to wall-functions - II

Lecture 42 - Introduction to wall-resolved simulations - I

Lecture 43 - Introduction to wall-resolved simulations - II

Lecture 44 - Damping functions for LRN - I

Lecture 45 - Damping functions for LRN - II

Lecture 46 - Boundary and Initial conditions for RANS simulations - I

Lecture 47 - Boundary and Initial conditions for RANS simulations - II

Lecture 48 - Realizability constraints in eddy-viscoscity models - I

Lecture 49 - Realizability constraints in eddy-viscoscity models - II

Lecture 50 - Correctors for eddy-viscoscity models - I

Lecture 51 - Correctors for eddy-viscoscity models - II

Lecture 52 - Reynold’s Stress Modelling (RSM): governing equations - I

Lecture 53 - Reynold’s Stress Modelling (RSM): governing equations - II

Lecture 54 - Dissipation rate and Pressure-Strain rate modelling for RSM - I

Lecture 55 - Dissipation rate and Pressure-Strain rate modelling for RSM - II

Lecture 56 - Pressure-Strain rate modelling for RSM - I

Lecture 57 - Pressure-Strain rate modelling for RSM - II

Lecture 58 - Pressure-Strain rate modelling and wall corrections for RSM - I

Lecture 59 - Pressure-Strain rate modelling and wall corrections for RSM - II

Lecture 60 - Introduction to Eddy Resolved Models - I

Lecture 61 - Introduction to Eddy Resolved Models - II

Lecture 62 - Introduction to Direct Numerical Simulations (DNS) - I

Lecture 63 - Introduction to Direct Numerical Simulations (DNS) - II

Lecture 64 - Introduction to Large Eddy Simulations (LES) Filtering operation and SGS stresses - I

Lecture 65 - Introduction to Large Eddy Simulations (LES) Filtering operation and SGS stresses - II

Lecture 66 - Large Eddy Simulations: Filtered Navier-Stokes Equations - I

Lecture 67 - Large Eddy Simulations: Filtered Navier-Stokes Equations - II

Lecture 68 - Large Eddy Simulations: Filters and its types - I

Lecture 69 - Large Eddy Simulations: Filters and its types - II

Lecture 70 - Large Eddy Simulations: Smagorinsky model - I

Lecture 71 - Large Eddy Simulations: Smagorinsky model - II

Lecture 72 - LES: Dynamic Smagorinsky model and Scale similarity models - I

Lecture 73 - LES: Dynamic Smagorinsky model and Scale similarity models - II

Lecture 74 - Numerics in LES and Hybrid models