This document outlines a lesson plan for teaching heat transfer over 15 class periods. It covers 8 units: 1) Introduction to heat transfer modes and mechanisms, 2) Steady and unsteady conduction, 3) Transient conduction, 4) Convection, 5) Forced and free convection, 6) Heat transfer with phase change, 7) Heat exchangers, and 8) Radiation heat transfer. Key topics include the heat conduction equation, boundary conditions, fins, the Biot and Fourier numbers, dimensional analysis, empirical convection correlations, boiling and condensation, LMTD and NTU methods, and radiation laws.
1. HEAT TRANSFER, Lesson Planning
Class III B Tech I semester
Number of Cumulative Date of
Sr.
Name of the Topic to be Covered Periods Number of Completion
No.
Required Periods
Unit I
Introduction : Modes and mechanisms of heat
1 01 01
transfer
Basic laws of heat transfer –General discussion about
2 applications of heat transfer. 01 02
3 Conduction Heat Transfer : Fourier rate equation 01 03
General heat conduction equation in Cartesian
4 01 04
coordinates
General heat conduction equation in Cylindrical
5 01 05
coordinates
General heat conduction equation in Spherical
6 01 06
coordinates
Unit II
Simplification and forms of the field equation –
7 01 07
steady, unsteady and periodic heat transfer
8 Initial and boundary conditions 01 08
One Dimensional Steady State Conduction Heat
9 Transfer: Homogeneous slabs, hollow cylinders and 02 10
spheres
overall heat transfer coefficient – electrical analogy –
10 Critical radius of insulation 02 12
One Dimensional Steady State Conduction Heat
11 01 13
Transfer: Variable Thermal conductivity
systems with heat sources or Heat generation.
12 01 14
Extended surface (fins) Heat Transfer –
Long Fin, Fin with insulated tip and Short Fin,
13 01 15
Application to error measurement of Temperature
2. Unit - III
One Dimensional Transient Conduction Heat
14 Transfer: Systems with negligible internal 02 17
resistance
15 Significance of Biot and Fourier Numbers 02 19
16 Chart solutions of transient conduction systems 02 21
17 Concept of Functional Body 02 23
Unit - IV
Convective Heat Transfer : Classification of
18 systems based on causation of flow, condition of 02 25
flow, configuration of flow and medium of flow
Dimensional analysis as a tool for experimental
19 investigation – Buckingham Pi Theorem and 01 26
method
application for developing semi – empirical non-
20 01 27
dimensional correlation for convection heat transfer
Significance of non-dimensional numbers –
21 Concepts of Continuity, Momentum and Energy 01 28
Equations
Forced convection: External Flows: Concepts
about hydrodynamic and thermal boundary layer
22 and use of empirical correlations for convective 02 30
heat transfer -Flat plates and Cylinders.
Internal Flows: Concepts about Hydrodynamic
and Thermal Entry Lengths – Division of internal
23 flow based on this –Use of empirical relations for 02 31
Horizontal Pipe Flow and annulus flow.
Unit V
Free Convection: Development of Hydrodynamic
24 03 34
and thermal boundary layer along a vertical plate
Use of empirical relations for Vertical plates and
pipes.
25 03 37
26 Problems on convection 03 40
Unit - VI
Heat Transfer with Phase Change: Boiling: –
27 02 42
Pool boiling –
Regimes Calculations on Nucleate boiling, Critical
28 02 44
Heat flux and Film boiling
Condensation: Film wise and drop wise
29 01 45
condensation –Nusselt’s Theory of Condensation
3. on a vertical plate -
Film condensation on vertical and horizontal
30 01 46
cylinders using empirical correlations
Unit- VII
Heat Exchangers:Classification of heat 01 47
31
exchangers
overall heat transfer Coefficient and fouling factor 02 49
32
– Concepts of LMTD and NTU methods
Problems using LMTD and NTU methods. 03 52
33
Unit- VIII
Radiation Heat Transfer : 02 54
Emission characteristics and laws of black-body
34
radiation – Irradiation – total and monochromatic
quantities
laws of Planck, Wien, Kirchoff, Lambert, Stefan 02 56
35
and Boltzmann–
heat exchange between two black bodies – concepts 02 58
36
of shape factor – Emissivity
heat exchange between grey bodies – radiation 02 60
shields – electrical analogy for radiation networks.
37