Module 1 [08 Hrs.]. Transient and multi-dimensional heat conduction: Exact solution, use of Heisler and Grober chart, integral method, Heat Transfer through extended surfaces::radial fins of rectangular and hyperbolic profiles longitudinal fin of rectangular profile radiating to free space.

Module 2 [12 Hrs.]. Convection: Derivation of energy equation, Couette flow and Poiseuille flow, Forced convection: Order of magnitude analysis, Thermal boundary layer, Similarity solutions for laminar boundary layer over flat plate, Heat Transfer in circular tubes - Entrance region, Constant heat flux and constant wall temperature solutions with constant and parabolic velocity profiles, the Graetz problem. Integral methods - Momentum and energy integral equations, Boundary layer over a flat plate with unheated starting length, Turbulent boundary layer, Analogy between momentum and heat transfer.

Module 3 [08 Hrs.]. Natural convection: Natural convection from a vertical plate by similarity solution and integral solution, Natural convection in enclosed spaces. Combined forced and free convection. Boiling and Condensation: Pool and flow boiling, Condensation over vertical/inclined surfaces and outside cylinder.

Module 4 [08 Hrs.]. Radiation heat transfer: Radiation effect on temperature measurements, radiation properties of a participating medium, emissivity and absorptivity of gases and gases mixtures, heat transfer from the human body, radiative exchange and overall heat transfer in furnaces.

To enhance the understanding of heat transfer processes and their relevance to industrial problems.

To strengthen analytical skills and the ability to deal with complex problems, and

To provide experience in treating multi-mode heat transfer phenomena in solving realistic engineering problems.

After learning the course, the students should be able to:
1. Have comprehensive understanding of heat transfer mechanisms of conduction, convection (forced and natural), and radiation heat transfer, including their governing equations.
2. Apply various analytical techniques in mathematical modeling and mathematical methods to solve ODEs and PDEs to solve complex heat transfer problems in various geometries.
3. Understand fluid flow and heat transfer interactions, by analyzing the coupling between fluid flow and heat transfer, including boundary layer effects.
4. Apply heat transfer principles to solve 1D/2D steady/transient heat conduction problems.
5. Identify and formulate heat transfer problems in various engineering contexts to real-world engineering problems.

F.P. Incropera and D. P. Dewit,, Fundamentals of Heat and Mass Transfer, John Wiley , 4th Ed., 1998

Louis C. Burmeister, Convective Heat Transfer, John Willey , 1993

E.R.D Eckert and R.M. Drake, Analysis of Heat and Mass Transfer, McGraw Hill , 1980

Kays, W.M. and Crawford W, Convective Heat and Mass Transfer, McGraw Hil , 1993