Week
|
Topics
|
Course Outcomes
|
1
|
Basic concepts of heat transfer mechanisms.
|
I
|
2
|
The concept of conduction heat transfer,
|
I-II
|
3
|
Steady and transient conduction problems.
|
I-III
|
4
|
Basic steady and transient conduction problems using numerical methods.
|
IV
|
5
|
The basics of heat convection:Reynolds, Prandtl, and Nusselt numbers, external forced convection problems over a flat plate, cylinders and spheres for laminar and turbulent flows.
|
V,VI,VII
|
6
|
Convection equations.External forced convection: Parallel flow over a flat plate, flow across cylinders and spheres, flow across tube banks.
|
VIII,IX, X
|
7
|
Natural convection: Grashof number. Natural convection over surfaces, from finned surfaces, inside enclosures, combined forced and natural convection
|
X
|
8
|
Natural convection: Grashof number. Natural convection over surfaces, from finned surfaces, inside enclosures, combined forced and natural convection
|
X
|
9
|
Midterm exam
|
|
10
|
Boiling heat transfer, pool boiling, and flow boiling. Condensation heat transfer, film condensation, inside horizontal tubes, and dropwise condensation.
|
XI
|
11
|
Fundamentals of thermal radiation, blackbody radiation, radiation intensity, atmospheric and solar radiation.
|
XII
|
12
|
Analysis of radiation heat transfer: black surfaces, diffuse, gray surfaces, radiation shields, problems about radiation exchange.
|
XIII
|
13
|
Heat exchanger types, overall heat transfer coefficient, log mean temperature difference, the effectiveness NTU method, selection of heat exchangers, project presentations.
|
XIV
|
14
|
Heat exchanger types. overall heat transfer coefficient, log mean temperature difference, the effectiveness NTU method, selection of heat exchangers, projects presentations.
|
XIV
|