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Transport Processes I: Heat and Mass Transfer

Transport Processes I: Heat and Mass Transfer. Instructor: Prof. V. Kumaran, Department of Chemical Engineering, IISc Bangalore. Physical and chemical transformations of raw materials to products are accomplished in unit operations which involve mixing, heating/cooling, reactions and flow. The efficiency of these processes is critically dependent on the transport of heat and mass carried along with flowing fluid, and across solid/fluid interfaces. The transport across interfaces is entirely due to molecular diffusion, which is the transport in a stationary fluid due to gradients in concentration or temperature. The combination of convection (transport by flowing fluids) and diffusion determine the rate of transport, and the overall efficiency, in unit operations. In this course, we will obtain a physical understanding of how the balance between convection and diffusion determines the overall transport rates in chemical processes, and gives rise to many of the empirical correlations used in chemical engineering design. (from nptel.ac.in)

Why do We Study Transport Processes?


Lecture 01 - Why do We Study Transport Processes?
Lecture 02 - Transport by Convection and Diffusion
Lecture 03 - Non-dimensional Analysis of Beams
Lecture 04 - Dimensional Analysis: Force on a Particle Settling in a Fluid
Lecture 05 - Dimensional Analysis: Heat Transfer in a Heat Exchanger
Lecture 06 - Dimensional Analysis: Mass Transfer from a Particle Suspended in a Fluid
Lecture 07 - Dimensional Analysis: Power of an Impeller
Lecture 08 - Dimensional Analysis: Scaling up of an Impeller
Lecture 09 - Dimensional Analysis: Convection and Diffusion
Lecture 10 - Dimensional Analysis: Physical Interpretation of Dimensionless Groups
Lecture 11 - Dimensional Analysis: Correlations for Dimensionless Groups
Lecture 12 - Dimensional Analysis: Natural and Forced Convection
Lecture 13 - Continuum Description of Fluids
Lecture 14 - Conservation Equations and Constitutive Relations
Lecture 15 - Diffusion: Mechanism of Mass Diffusion in Gases
Lecture 16 - Diffusion: Estimation of Mass Diffusion Coefficient
Lecture 17 - Diffusion: Momentum Diffusion Coefficient
Lecture 18 - Diffusion: Thermal Diffusion Coefficient
Lecture 19 - Unidirectional Transport: Conservation Equation for Heat and Mass Transfer
Lecture 20 - Unidirectional Transport: Conservation Equation for Momentum Transfer
Lecture 21 - Unidirectional Transport: Similarity Solution for Infinite Domain
Lecture 22 - Unidirectional Transport: Similarity Solution for Infinite Domain (cont.)
Lecture 23 - Unidirectional Transport: Similarity Solution for Mass Transfer into a Falling Film
Lecture 24 - Unidirectional Transport: Similarity Solution for Decay of a Pulse
Lecture 25 - Unidirectional Transport: Similarity Solution for Decay of a Pulse (cont.)
Lecture 26 - Unidirectional Transport: Separation of Variables for Transport in a Finite Domain 1
Lecture 27 - Unidirectional Transport: Separation of Variables for Transport in a Finite Domain 2
Lecture 28 - Unidirectional Transport: Separation of Variables for Transport in a Finite Domain 3
Lecture 29 - Unidirectional Transport: Separation of Variables for Transport in a Finite Domain 4
Lecture 30 - Unidirectional Transport: Balance Laws in Cylindrical Coordinates; Heat Transfer across the Wall of a Pipe
Lecture 31 - Unidirectional Transport: Balance Laws in Cylindrical Coordinates; Unsteady Heat Conduction from a Cylinder
Lecture 32 - Unidirectional Transport: Balance Laws in Cylindrical Coordinates; Unsteady Heat Conduction from a Cylinder (cont.)
Lecture 33 - Unidirectional Transport: Balance Laws in Cylindrical Coordinates; Unsteady Heat Conduction from a Cylinder (cont.)
Lecture 34 - Unidirectional Transport: Balance Laws in Cylindrical Coordinates; Similarity Solution for Heat Conduction from a Wire
Lecture 35 - Unidirectional Transport: Effect of Body Force in Momentum Transfer
Lecture 36 - Unidirectional Transport: Effect of Pressure in Momentum Transfer
Lecture 37 - Unidirectional Transport: Friction Factor for Flow in a Pipe
Lecture 38 - Unidirectional Transport: Laminar and Turbulent Flow in a Pipe
Lecture 39 - Unidirectional Transport: Laminar and Turbulent Flow in a Pipe (cont.)
Lecture 40 - Unidirectional Transport: Oscillatory Flow in a Pipe 1
Lecture 41 - Unidirectional Transport: Oscillatory Flow in a Pipe 2
Lecture 42 - Unidirectional Transport: Oscillatory Flow in a Pipe 3
Lecture 43 - Unidirectional Transport: Oscillatory Flow in a Pipe - Low and High Reynolds Number Solutions
Lecture 44 - Unidirectional Transport: Heat Conduction from a Sphere
Lecture 45 - Mass and Energy Balance Equations in Cartesian Coordinates
Lecture 46 - Mass and Energy Balance Equations in Cartesian Coordinates: Vector Notation
Lecture 47 - Mass and Energy Balance Equations in Spherical Coordinates
Lecture 48 - Mass and Energy Balance Equations in Spherical Coordinates (cont.)
Lecture 49 - Momentum Balance: Incompressible Navier-Stokes Equations
Lecture 50 - Balance Equation: Convection and Diffusion Dominated Regimes
Lecture 51 - Diffusion Equation: Heat Conduction in a Rectangular Solid
Lecture 52 - Diffusion Equation: Heat Conduction in a Rectangular Solid (cont.)
Lecture 53 - Diffusion Equation: Heat Conduction around a Spherical Inclusion
Lecture 54 - Diffusion Equation: Heat Conduction around a Spherical Inclusion (cont.)
Lecture 55 - Diffusion Equation: Effective Conductivity of a Composite
Lecture 56 - Diffusion Equation: Spherical Harmonic Solutions
Lecture 57 - Diffusion Equation: Conduction from a Point Source
Lecture 58 - Diffusion Equation: Method of Green's Functions
Lecture 59 - Diffusion Equation: Method of Images
Lecture 60 - Diffusion Equation: Equivalence of Spherical Harmonics and Multipole Expansion

References
Transport Processes I: Heat and Mass Transfer
Instructor: Prof. V. Kumaran, Department of Chemical Engineering, IISc Bangalore. This course will deal with mostly heat and mass transfer and some momentum transfer.