NPTEL : NOC:Heat Transfer (Chemical Engineering)

Co-ordinators : Prof. Ganesh A. Viswanathan


Lecture 1 - Introduction

Lecture 2 - Introduction to Conduction

Lecture 3 - Energy Balance

Lecture 4 - 1D Steadystate Conduction - Resistance Concept

Lecture 5 - Resistances in Composite Wall Case

Lecture 6 - Resistances in Radial Systems

Lecture 7 - Heat Generation - I Plane and Cylindrical Wall

Lecture 8 - Heat Generation - II Problem; Introduction to Extended Surfaces

Lecture 9 - Extended Surfaces I - General Formulation

Lecture 10 - Extended Surfaces II - Fixed Cross-section Area

Lecture 11 - Extended Surfaces III - Varying Cross-section Area

Lecture 12 - 2D Plane Wall

Lecture 13 - Transient Analyses I : Lumped Capacitance Method

Lecture 14 - Transient Analyses II : Full Method

Lecture 15 - Transient Analyses : Semi-infinite Case

Lecture 16 - Introduction to Convective Heat Transfer

Lecture 17 - Heat and Mass Transport Coefficients

Lecture 18 - Boundary Layer : Momentum, Thermal and Concentration

Lecture 19 - Laminar and Turbulent Flows; Momentum Balance

Lecture 20 - Energy and Mass Balances; Boundary Layer Approximations

Lecture 21 - Order of Magnitude Analysis

Lecture 22 - Transport Coefficients

Lecture 23 - Relationship between Momentum, Thermal and Concentration Boundary Layer

Lecture 24 - Reynolds and Chilton-Colburn Analogies

Lecture 25 - Forced Convection : Introduction

Lecture 26 - Flow Past Flat Plate I - Method of Blasius

Lecture 27 - Flow Past Flat Plate II - Correlations for Heat and Mass Transport

Lecture 28 - Flow Past Cylinders

Lecture 29 - Flow through Pipes - I

Lecture 30 - Flow through Pipes - II

Lecture 31 - Flow through Pipes - III

Lecture 32 - Flow through Pipes - IV - Mixing-cup Temperature

Lecture 33 - Flow through Pipes - V - Log mean Temperature Difference

Lecture 34 - Flow through Pipes - VI - Correlations for Laminar and Turbulent Conditions

Lecture 35 - Example problems : Forced Convection

Lecture 36 - Introduction to Free/Natural Convection

Lecture 37 - Heated Plate in a Quiescent Fluid - I

Lecture 38 - Heated Plate in a Quiescent Fluid - II

Lecture 39 - Boiling - I

Lecture 40 - Boiling - II

Lecture 41 - Condensation - I

Lecture 42 - Condensation - II

Lecture 43 - Radiation : Introduction

Lecture 44 - Spectral Intensity

Lecture 45 - Radiation : Spectral properties, Blackbody

Lecture 46 - Properties of a Blackbody

Lecture 47 - Surface Adsorption

Lecture 48 - Kirchoff’s Law

Lecture 49 - Radiation Exchange - View Factor

Lecture 50 - View Factor Examples

Lecture 51 - View Factor - Inside Sphere Method, Blackbody Radiation Exchange

Lecture 52 - Diffuse, Gray Surfaces in an Enclosure

Lecture 53 - Resistances - Oppenheim Matrix Method

Lecture 54 - Resistances - Examples

Lecture 55 - More Examples: Volumetric Radiation

Lecture 56 - Introduction and Examples

Lecture 57 - Parallel Flow Heat Exchangers

Lecture 58 - LMTD I

Lecture 59 - Shell and Tube Heat Exchangers

Lecture 60 - Epsilon-NTU Method