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Mod-01 Lec-01 Motivation for CFD and Introduction to the CFD approach

Mod-01 Lec-02 Illustration of the CFD approach through a worked out example

Mod-02 Lec-03 Eulerian approach, Conservation Equation, Derivation of Mass Conservation Equation

Mod-02 Lec-04 Eulerian approach, Conservation Equation, Derivation of Mass Conservation Equation

Mod-02 Lec-05 Forces acting on a control volume; Stress tensor;

Mod-02 Lec-06 Kinematics of deformation in fluid flow; Stress vs strain rate relation

Mod-02 Lec-07 Equations governing flow of incompressible flow;

Mod-03 Lec-08 Cut out the first 30s; Spatial discretization of a simple flow domain;

Mod-03 Lec-09 Finite difference approximation of pth order of accuracy for qth order derivative;

Mod-03 Lec-10 One-sided high order accurate approximations,Explicit and implicit formulations

Mod-03 Lec-11 Numerical solution of the unsteady advection equation using different finite.

Mod-03 Lec-12 Need for analysis of a discretization scheme; Concepts of consistency

Mod-03 Lec-13 Statement of the stability problem

Mod-03 Lec-14 Consistency and stability analysis of the unsteady diffusion equation

Mod-03 Lec-15 Interpretation of the stability condition,Stability analysis of the generic scalar equ

Mod-04 Lec-16 Template for the generic scalar transport equation and its extension to the solution

Mod-04 Lec-17 Illustration of application of the template using the MacCormack scheme

Mod-04 Lec-18 Stability limits of MacCormack scheme

Mod-04 Lec-19 Artificial compressibility method and the streamfunction-vorticity method

Mod-04 Lec-20 Pressur e equation method for the solution of NS equations

Mod-04 Lec-21 Pressure-correction approach to the solution of NS equations on a staggered grid

Mod-05 Lec-22 Need for effici ent solution of linear algebraic equations

Mod-05 Lec-23 Direct methods for linear algebraic equations; Gaussian elimination method

Mod-05 Lec-24 Gauss-Jordan method; LU decomposition method; TDMA and Thomas algorithm

Mod-05 Lec-25 Basic iterative methods for linear algebraic equations: Description of point -Jacobi

Mod-05 Lec-26 Convergence analysis of basic iterative schemes,Diagonal dominance condition

Mod-05 Lec-27 Application to the Laplace equation

Mod-05 Lec-28 Advanced iterative methods: Alternating Direction Implicit Method; Operator splitting

Mod-05 Lec-29 Advanced iterative methods,Strongly Implicit Procedure,Conjugate gradient method

Mod-05 Lec-30 Illustration of the Multigrid method for the Laplace equation

Mod-06 Lec-31 Overview of the approach of numerical solution of NS equations for simple domains

Mod-06 Lec-32 Derivation of the energy conservation equation

Mod-06 Lec-33 Derivation of the species conservation equation; dealing with chemical reactions

Mod-06 Lec-34 Turbulence,Characteri stics of turbulent flow,Dealing with fluctuations

Mod-06 Lec-35 Derivation of the Reynolds -averaged Navier -Stokes equations

Mod-06 Lec-36 Reynol ds stresses in turbulent flow,Time and length scales of turbulence

Mod-06 Lec-37 One-equation model for turbulent flow

Mod-06 Lec-38 Two -equation model for turbulent flow; Numerical calculation of turbulent

Mod-06 Lec-39 Calculation of near-wall region in turbulent flow; wall function approach

Mod-07 Lec-40 Need for special methods for dealing with irregular fl ow geometry

Mod-07 Lec-41 Transformation of the governing equations; Illustration for the Laplace equation

Mod-07 Lec-42 Finite volume method for complicated flow domain

Mod-07 Lec-43 Finite volume method for the general case

Mod-07 Lec-44 Generation of a structured grid for irregular flow domain; Algebraic methods

Mod-07 Lec-45 Unstructured grid generation,Domain nodalization

Mod-07 Lec-46 Delaunay triangulation method for unstructured grid generation

Mod-07 Lec-47 Co -located grid approach for irregular geometries; Pressure correction equations

Description:

COURSE OUTLINE: The course deals with the numerical solution of equations governing fluid flow and would be of interest to engineers and scientists—both spiring and professional—with chemical/ mechanical/ civil/ aerospace engineering applications. In all these fields, one needs to deal extensively with fluid flow-related phenomena and one needs to resolve flow-related features of the processes and equipment. Although the equations governing fluid flow have been formulated more than 150 years ago, it is only in recent years that these are being solved in the practical applications in which the flow occurs. The course deals with the basic techniques that enable the numerical solution of these equations.

Computational Fluid Dynamics

NPTEL

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Computational Fluid Dynamics

1 Mod-01 Lec-01 Motivation for CFD and Introduction to the CFD approach