Lecturer : Prof. A.W. Date
University of : Bombay ( India )
Year : 2012
Level : Undergraduate
Course Description :
This course assumes that the students have undergone UG courses in Engineering Mathematics, Thermodynamics, Heat Transfer and Fluid Mechanics and are familiar with the use of experimentally derived CORRELATIONS for estimating heat/mass transfer coefficient in a variety of flow situations. The purpose of this course is to justify the basis and the form of these correlations on the basis of fundamental transport laws governing heat/mass transfer.
The treatment is highly mathematical and, through assignments, students are expected to formulate and solve problems to derive expressions for the heat/mass transfer coefficient in different situations. The course will interest students wishing to embark on a research career in heat/mass transfer.
some of Contents in this course is Definitions of Heat/Mass Transfer Coefficient, Main Flow Classifications, Transport Equations of Bulk Mass, Momentum, Energy and Sepcies transfer, Boundary Layer Theory and its approximations, Laminar and Turbulent External boundary layers with effects of Pressure Gradient, Wall thermal conditions, Viscous dissipation, Wall mass transfer. Similarity, Integral and Finite-difference solutions of boundary layer equations. Developing Internal ( ducted ) flows within boundary layer approximations, Fully developed flows and heat transfer in non-circular ducts, use of superposition techniques. Turbulent Flows, laminar-turbulent transition, Universal law-of-the wall for smooth and rough surfaces, mixing-length and 2-equation models, the energy budget for boundary layer and fully-developed pipe flow.Approximate theories of Mass Transfer , Stefan-Couette-Reynolds flow models, Applications to Inert mass transfer with and without heat transfer, Mass transfer with heterogeneous and homogeneous chemical reactions.
List of Lectures :
Lecture 1: Introduction
Lecture 2: Flow Classifications
Lecture 3: Laws of Convection
Lecture 4: Scalar Transport Equations
Lecture 5: Laminar Boundary Layers
Lecture 6: Similarity Method
Lecture 7: Similaity Solns Velocity BL
Lecture 8: Similaity Solns Temperature BL-I
Lecture 9: Similaity Solns Temperature BL-II
Lecture 10: Integral BL Equations
Lecture 11: Integral Solns Laminar Velocity BL
Lecture 12: Integral Solns Laminar Temperature BL
Lecture 13: Superposition Theory
Lecture 14: Laminar Internal Flows
Lecture 15: Fully-Developed Laminar Flows- 1
Lecture 16: Fully-Developed Laminar Flows- 2
Lecture 17: Fully-Developed Laminar Flows Heat Transfer - 1
Lecture 18: Fully-Developed Laminar Flows Heat Transfer - 2
Lecture 19: Laminar Internal Developing Flows Heat Transfer
Lecture 20: Superposition Technique
Lecture 21: Nature of Turbulent Flows
Lecture 22A: Sustaining Mechanism of Turbulence- 1
Lecture 22B: Sustaining Mechanism of Turbulence- 1
Lecture 23: Sustaining Mechanism of Turbulence- 2
Lecture 24: Near-Wall Turbulent Flows - 1
Lecture 25: Near-Wall Turbulent Flows - 2
Lecture 26: Turbulence Models - 1
Lecture 27: Turbulence Models - 2
Lecture 28: Turbulence Models - 3
Lecture 29: Prediction of Turbulent Flows
Lecture 30: Prediction of Turbulent Heat Transfer
Lecture 31: Convective Mass Transfer
Lecture 32: Stefan Flow Model
Lecture 33: Couette Flow Model
Lecture 34: Reynolds Flow Model
Lecture 35: Boundary Layer Flow Model
Lecture 36: Evaluation of g and Nw
Lecture 37: Diffusion Mass Transfer Problems
Lecture 38: Convective MT Couette Flow
Lecture 39: Convective MT Reynolds Flow Model - 1
Lecture 40: Convective MT Reynolds Flow Model - 2
لينك خريد: