Lecture 1 - Introduction to Convection - 1
Lecture 2 - Introduction to Convection - 2
Lecture 3 - Introduction to Convection - 3
Lecture 4 - Introduction to Convection - 4
Lecture 5 - Introduction to Convection - 5
Lecture 6 - Fluid Acceleration
Lecture 7 - Reynolds transport theorem
Lecture 8 - General motion of fluid
Lecture 9 - Conservation of Mass and Momentum
Lecture 10 - Conservation of Momentum
Lecture 11 - Conservation of Energy - 1
Lecture 12 - Conservation of Energy - 2
Lecture 13 - Dimensional Similarity
Lecture 14 - Scale Analysis - 1
Lecture 15 - Scale Analysis - 2
Lecture 16 - Scale Analysis - 3 and Reynolds Analogy
Lecture 17 - Relationship between Stress and Strain rate
Lecture 18 - Introduction to Similarity method
Lecture 19 - Similarity method : Momentum equation - 1
Lecture 20 - Similarity method : Momentum equation - 2
Lecture 21 - Similarity method : Blasius solution
Lecture 22 - Similarity method : Energy equation - 1
Lecture 23 - Similarity method : Energy equation - 2
Lecture 24 - Similarity method : Energy equation - 3
Lecture 25 - Definition of various thicknesses, Introduction to Integral method
Lecture 26 - Integral method - 1
Lecture 27 - Integral method - 2
Lecture 28 - Integral method - 3
Lecture 29 - Integral method : Energy equation - 1
Lecture 30 - Integral method : Energy equation - 2
Lecture 31 - Introduction to Turbulence
Lecture 32 - Reynolds averaging of Governing equations and Universal Velocity Profile
Lecture 33 - Reynolds averaging of Energy equation, Concept of Eddy Diffusivity of Momentum and Eddy Diffusivity of Heat
Lecture 34 - Boundary layer equation, Two Layer Assumptions, Prandtl's Mixing Length Hypothesis
Lecture 35 - Universal Velocity Distribution, Friction Factor for Turbulent Flow in Hydraulically Smooth pipe
Lecture 36 - Friction Factor for Turbulent Flow in a Hydraulically Rough pipe
Lecture 37 - Emperical Power Law Velocity Distribution for Turbulent Flow
Lecture 38 - Internal Flows : Concept of Average Velocity and Bulk Mean Temperature
Lecture 39 - Thermal Entrance Length : Boundary layer growth for Pr > 1, Pr ~ 1 and Pr C 1 cases, Concept of Thermally fully developed
Lecture 40 - Analysis of Internal Flows for Constant Heat Flux Boundary Condition
Lecture 41 - Internal Flow : Constant Wall Temperature case
Lecture 42 - Velocity Distribution for Laminar flow in Circular pipe
Lecture 43 - Nusselt number for Laminar Flow in a Circular pipe with Constant Wall Heat Flux, Nusselt number for other cases
Lecture 44 - Natural Convection : Introduction, Scaling Analysis, Derivation of Governing equation
Lecture 45 - Natural Convection : Scale Analysis for Pr > 1
Lecture 46 - Natural Convection : Scale Analysis for Pr C 1
Lecture 47 - Dimensional Similarity and criterion for Forced and Natural Convection correlations for various cases
Lecture 48 - Vertical Channel flow with Plates maintained at Constant Wall Temperature
Lecture 49 - Optimal Cooling of a stack of Vertical Heat generating plates
Lecture 50 - Effect of Viscous Dissipation on Nusselt number - 1
Lecture 51 - Effect of Viscous Dissipation on Nusselt number - 2
Lecture 52 - Boiling Heat transfer : Introduction and Classification
Lecture 53 - Pool Boiling curve - 1
Lecture 54 - Pool Boiling curve - 2
Lecture 55 - Pool Boiling curve - 3 : Introduction to Critical Heat Flux
Lecture 56 - Critical Heat flux (Continuation), Film Boiling, Basic analysis of Flow Boiling
Lecture 57 - Condensation - 1
Lecture 58 - Condensation - 2
Lecture 59 - Introduction to Electronics cooling
Lecture 60 - Pool Boiling curve - 3 : Introduction to Electronics cooling - Resistance network
Lecture 61 - Problem Solving - Part 1
Lecture 62 - Problem Solving - Part 2
Lecture 63 - Problem Solving - Part 3
Lecture 64 - Unheated starting length (Integral method) and Duhamel's theorem
Lecture 65 - Arbitrarily varying Boundary temperature - Duhamel's theorem
Lecture 66 - Heat transfer coefficient - IcePAK Analysis
Lecture 67 - Heat Sinks - Part 1
Lecture 68 - Heat exchanger theory - An approach to modeling heat sinks
Lecture 69 - Forced convection cooling
Lecture 70 - Honeycomb and Foam heat sink modeling - Approximation
Lecture 71 - Foam heat sink modeling - Approximation (Continuation)
