IC4291 Computational Fluid Dynamics Syllabus:
IC4291 Computational Fluid Dynamics Syllabus – Anna University PG Syllabus Regulation 2021
COURSE OBJECTIVES:
This course aims to introduce numerical modeling and its role in the field of heat, fluid flow and combustion. It will enable the students to understand the various discretisation methods and solving methodologies and to create confidence to solve complex problems in the field of heat transfer and fluid dynamics.
To develop finite volume discretised forms of the governing equations for diffusion processes.
To develop finite volume discretised forms of the convection-diffusion processes.
To develop pressure-based algorithms for flow processes.
To introduce various turbulence models, Large Eddy Simulation and Direct Numerical Simulation.
UNIT – I GOVERNING DIFFERENTIAL EQUATIONS AND DISCRETISATION TECHNIQUES
Basics of Heat Transfer, Fluid flow – Mathematical description of fluid flow and heat transfer – Conservation of mass, momentum, energy and chemical species – Classification of partial differential equations – Initial and Boundary Conditions – Discretisation techniques using finite difference methods – Taylor’s Series – Uniform and non-uniform Grids, Numerical Errors, Grid Independence Test.
UNIT – II DIFFUSION PROCESSES: FINITE VOLUME METHOD
Steady one-dimensional diffusion, Two- and three-dimensional steady state diffusion problems, Discretisation of unsteady diffusion problems – Explicit, Implicit and Crank-Nicholson’s schemes, Stability of schemes.
UNIT – III CONVECTION-DIFFUSION PROCESSES: FINITE VOLUME METHOD
One dimensional convection – diffusion problem, Central difference scheme, upwind scheme – Hybrid and power law discretization techniques – QUICK scheme.
UNIT – IV FLOW PROCESSES: FINITE VOLUME METHOD
Discretisation of incompressible flow equations – Pressure based algorithms, SIMPLE, SIMPLER & PISO algorithms.
UNIT – V TURBULENCE MODELS
Turbulence – RANS equation – Algebraic Models, One equation model, Two equation models – k & standard k – ϵ model, Low Reynold number models of k- ϵ, Large Eddy Simulation (LES), Direct Numerical Simulation (DNS) – Introduction. Solving simple cases using standard CFD codes. COURSE OUTCOMES:
On successful completion of this course the students will be able to:
Analyse the governing equations and boundary conditions.
Analyse various discretization techniques for both steady and unsteady diffusion problems.
Analyse the various convection-diffusion problems by Finite-Volume method.
Analyse the flow processes by using different pressure bound algorithms.
Select and use the different turbulence models according to the type of flows.
REFERENCES:
1. Versteeg and Malalasekera, N, “An Introduction to computational Fluid Dynamics The Finite Volume Method,” Pearson Education, Ltd., Second Edition, 2014.
2. Ghoshdastidar, P.S., “Computer Simulation of Flow and Heat Transfer”, Tata McGraw-Hill Publishing Company Limited, New Delhi, 1998.
3. Muralidhar, K., and Sundararajan, T., “Computational Fluid Flow and Heat Transfer”, Narosa Publishing House, New Delhi, 2003.
4. Subas and V.Patankar “Numerical heat transfer fluid flow”, Hemisphere Publishing Corporation, 1980.
5. JiyuanTu, Guan Heng Yeoh, Chaogun Liu, “Computational Fluid Dynamics A Practical Approach” Butterworth – Heinemann An Imprint of Elsevier, Madison, U.S.A., 2008
6. John D. Anderson. JR. “Computational Fluid Dynamics the Basics with Applications” McGraw-Hill International Editions, 1995.