Physical and Computational Aspects of Convective Heat Transfer

Physical and Computational Aspects of Convective Heat Transfer by Tuncer Cebeci, Peter Bradshaw.

From the reviews: "The book has a broad and general coverage of both the mathematics and the numerical methods well suited for graduate students." Applied Mechanics Reviews #1 "This is a very well written book. The topics are developed with separate headings making the matter easily u...

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Bibliographic Details
Main Authors: Cebeci, Tuncer (Author), Bradshaw, Peter (Author)
Corporate Author: SpringerLink (Online service)
Format: eBook
Language:English
Published: New York, NY : Springer New York : Imprint: Springer, 1988.
Edition:1st ed. 1988.
Series:Springer Study Edition,
Springer eBook Collection.
Subjects:
Fluids.
Physics.
Electronic resources (E-books)
Online Access:Click to view e-book
Holy Cross Note:Loaded electronically.
Electronic access restricted to members of the Holy Cross Community.
Table of Contents:
  • 1 Introduction
  • 1.1 Momentum Transfer
  • 1.2 Heat and Mass Transfer
  • 1.3 Relations between Heat and Momentum Transfer
  • l.4 Coupled and Uncoupled Flows
  • 1.5 Units and Dimensions
  • l.6 Outline of the Book
  • Problems
  • References
  • 2 Conservation Equations for Mass, Momentum, and Energy
  • 2.1 Continuity Equation
  • 2.2 Momentum Equations
  • 2.3 Internal Energy and Enthalpy Equations
  • 2.4 Conservation Equations for Turbulent Flow
  • 2.5 Equations of Motion: Summary
  • Problems
  • References
  • 3 Boundary-Layer Equations
  • 3.l Uncoupled Flows
  • 3.2 Estimates of Density Fluctuations in Coupled Turbulent Flows
  • 3.3 Equations for Coupled Turbulent Flows
  • 3.4 Integral Equations
  • 3.5 Boundary Conditions
  • 3.6 Thin-Shear-Layer Equations: Summary
  • Problems
  • References
  • 4 Uncoupled Laminar Boundary Layers
  • 4.1 Similarity Analysis
  • 4.2 Two-Dimensional Similar Flows
  • 4.3 Two-Dimensional Nonsimilar Flows
  • 4.4 Axisymmetric Flows
  • 4.5 Wall Jets and Film Cooling
  • Problems
  • References
  • 5 Uncoupled Laminar Duct Flows
  • 5.1 Fully Developed Duct Flow
  • 5.2 Thermal Entry Length for a Fully Developed Velocity Field
  • 5.3 Hydrodynamic and Thermal Entry Lengths
  • Problems
  • References
  • 6 Uncoupled Turbulent Boundary Layers
  • 6.1 Composite Nature of a Turbulent Boundary Layer
  • 6.2 The Inner Layer
  • 6.3 The Outer Layer
  • 6.4 The Whole Layer
  • 6.5 Two-Dimensional Boundary Layers with Zero Pressure Gradient
  • 6.6 Two-Dimensional Flows with Pressure Gradient
  • 6.7 Wall Jets and Film Cooling
  • Problems
  • References
  • 7 Uncoupled Turbulent Duct Flows
  • 7.1 Fully Developed Duct Flow
  • 7.2 Thermal Entry Length for a Fully Developed Velocity Field
  • 7.3 Hydrodynamic and Thermal Entry Lengths
  • Problems
  • References
  • 8 Free Shear Flows
  • 8.1 Two-Dimensional Laminar Jet
  • 8.2 Laminar Mixing Layer between Two Uniform Streams at Different Temperatures
  • 8.3 Two-Dimensional Turbulent Jet
  • 8.4 Turbulent Mixing Layer between Two Uniform Streams at Different Temperatures
  • 8.5 Coupled Flows
  • Problems
  • References
  • 9 Buoyant Flows
  • 9.1 Natural-Convection Boundary Layers
  • 9.2 Combined Natural- and Forced-Convection Boundary Layers
  • 9.3 Wall Jets and Film Heating or Cooling
  • 9.4 Natural and Forced Convection in Duct Flows
  • 9.5 Natural Convection in Free Shear Flows
  • Problems
  • References
  • 10 Coupled Laminar Boundary Layers
  • 10.1 Similar Flows
  • 10.2 Nonsimilar Flows
  • 10.3 Shock-Wave/Shear-Layer Interaction
  • 10.4 A Prescription for Computing Interactive Flows with Shocks
  • Problems
  • References
  • 11 Coupled Turbulent Boundary Layers
  • 11.1 Inner-Layer Similarity Analysis for Velocity and Temperature Profiles
  • 11.2 Transformations for Coupled Turbulent Flows
  • 11.3 Two-Dimensional Boundary Layers with Zero Pressure Gradient
  • 11.4 Two-Dimensional Flows with Pressure Gradient
  • 11.5 Shock-Wave/Boundary-Layer Interaction
  • References
  • 12 Coupled Duct Flows
  • 12.1 Laminar Flow in a Tube with Uniform Heat Flux
  • 12.2 Laminar, Transitional and Turbulent Flow in a Cooled Tube
  • References
  • 13 Finite-Difference Solution of Boundary-Layer Equations
  • 13.1 Review of Numerical Methods for Boundary-Layer Equations
  • 13.2 Solution of the Energy Equation for Internal Flows with Fully Developed Velocity Profile
  • 13.3 Fortran Program for Internal Laminar and Turbulent Flows with Fully Developed Velocity Profile
  • 13.4 Solution of Mass, Momentum, and Energy Equations for Boundary-Layer Flows
  • 13.5 Fortran Program for Coupled Boundary-Layer Flows
  • References
  • 14 Applications of a Computer Program to Heat-Transfer Problems
  • 14.1 Forced and Free Convection between Two Vertical Parallel Plates
  • 14.2 Wall Jet and Film Heating
  • 14.3 Turbulent Free Jet
  • 14.4 Mixing Layer between Two Uniform Streams at Different Temperatures
  • References
  • Appendix A Conversion Factors
  • Appendix B Physical Properties of Gases, Liquids, Liquid Metals, and Metals
  • Appendix C Gamma, Beta and Incomplete Beta Functions
  • Appendix D Fortran Program for Head’s Method.

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