An edition of Analytical heat transfer
(2012)
Analytical heat transfer
by Je-Chin Han
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"Developed from the authors 30 years of teaching a graduate-level intermediate heat transfer course, Analytical Heat Transfer explains how to analyze and solve conduction, convection, and radiation heat transfer problems. Suitable for entry-level graduate students, the book fills the gap between basic heat transfer undergraduate courses and advanced heat transfer graduate courses.The author places emphasis on modeling and solving engineering heat transfer problems analytically, rather than simply applying the equations and correlations for engineering problem calculations. He describes many well-known analytical methods and their solutions, such as Bessel functions, separation of variables, similarity method, integral method, and matrix inversion method. He also presents step-by-step mathematical formula derivations, analytical solution procedures, and numerous demonstration examples of heat transfer applications.By providing a strong analytical background, the text enables students to tackle complex engineering heat transfer problems encountered in practice. This analytical knowledge also helps them to read and understand heat transfer-related research papers"--Provided by publisher.
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Transmission, Heat, Heat, transmissionShowing 1 featured edition. View all 1 editions?
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Table of Contents
Machine generated contents note: 1.Heat Conduction Equations
1.1.Introduction
1.1.1.Conduction
1.1.1.1.Fourier's Conduction Law
1.1.2.Convection
1.1.2.1.Newton's Cooling Law
1.1.3.Radiation
1.1.3.1.Stefan-Boltzmann Law
1.1.4.Combined Modes of Heat Transfer
1.2.General Heat Conduction Equations
1.2.1.Derivations of General Heat Conduction Equations
1.3.Boundary and Initial Conditions
1.3.1.Boundary Conditions
1.3.2.Initial Conditions
1.4.Simplified Heat Conduction Equations
Problems
Reference
2.1-D Steady-State Heat Conduction
2.1.Conduction through Plane Walls
2.1.1.Conduction through Circular Tube Walls
2.1.2.Critical Radius of Insulation
2.2.Conduction with Heat Generation
2.3.Conduction through Fins with Uniform Cross-Sectional Area
2.3.1.Fin Performance
2.3.1.1.Fin Effectiveness
2.3.1.2.Fin Efficiency
2.3.2.Radiation Effect
2.4.Conduction through Fins with Variable Cross-Sectional Area: Bessel Function Solutions
2.4.1.Radiation Effect
Problems
References
3.2-D Steady-State Heat Conduction
3.1.Method of Separation of Variables: Given Temperature BC
3.2.Method of Separation of Variables: Given Heat Flux and Convection BCs
3.2.1.Given Surface Heat Flux BC
3.2.2.Given Surface Convection BC
3.3.Principle of Superposition for Nonhomogeneous BCs Superposition
3.3.1.2-D Heat Conduction in Cylindrical Coordinates
3.4.Principle of Superposition for Multidimensional Heat Conduction and for Nonhomogeneous Equations
3.4.1.3-D Heat Conduction Problem
3.4.2.Nonhomogeneous Heat Conduction Problem
Problems
References
4.Transient Heat Conduction
4.1.Method of Lumped Capacitance for 0-D Problems
4.1.1.Radiation Effect
4.2.Method of Separation of Variables for 1-D and for Multidimensional Transient Conduction Problems
4.2.1.1-D Transient Heat Conduction in a Slab
4.2.2.Multidimensional Transient Heat Conduction in a Slab (2-D or 3-D)
4.2.3.1-D Transient Heat Conduction in a Rectangle with Heat Generation
4.3.1-D Transient Heat Conduction in a Semiinfinite Solid Material
4.3.1.Similarity Method for Semiinfinite Solid Material
4.3.2.Laplace Transform Method for Semiinfinite Solid Material
4.3.3.Approximate Integral Method for Semiinfinite Solid Material
4.4.Heat Conduction with Moving Boundaries
4.4.1.Freezing and Solidification Problems Using the Similarity Method
4.4.2.Melting and Ablation Problems Using the Approximate Integral Method
4.4.2.1.Ablation
Problems
References
5.Numerical Analysis in Heat Conduction
5.1.Finite-Difference Energy Balance Method for 2-D Steady-State Heat Conduction
5.2.Finite-Difference Energy Balance Method for 1-D Transient Heat Conduction
5.2.1.Finite-Difference Explicit Method
5.2.2.Finite-Difference Implicit Method
5.3.2-D Transient Heat Conduction
Problems
References
6.Heat Convection Equations
6.1.Boundary-Layer Concepts
6.2.General Heat Convection Equations
6.3.2-D Heat Convection Equations
6.4.Boundary-Layer Approximations
6.4.1.Boundary-Layer Similarity/Dimensional Analysis
6.4.2.Reynolds Analogy
Problems
References
7.External Forced Convection
7.1.Laminar Flow and Heat Transfer over a Flat Surface: Similarity Solution
7.1.1.Summary of the Similarity Solution for Laminar Boundary-Layer Flow and Heat Transfer over a Flat Surface
7.2.Laminar Flow and Heat Transfer over a Flat Surface: Integral Method
7.2.1.Momentum Integral Equation by Von Karman
7.2.2.Energy Integral Equation by Pohlhausen
7.2.3.Outline of the Integral Approximate Method
Problems
References
8.Internal Forced Convection
8.1.Velocity and Temperature Profiles in a Circular Tube or between Parallel Plates
8.2.Fully Developed Laminar Flow and Heat Transfer in a Circular Tube or between Parallel Plates
8.2.1.Fully Developed Flow in a Tube: Friction Factor
8.2.2 Case 1 Uniform Wall Heat Flux
8.2.3 Case 2 Uniform Wall Temperature
Problems
References
9.Natural Convection
9.1.Laminar Natural Convection on a Vertical Wall: Similarity Solution
9.2.Laminar Natural Convection on a Vertical Wall: Integral Method
Problems
References
10.Turbulent Flow Heat Transfer
10.1.Reynolds-Averaged Navier-Stokes (RANS) Equation
10.1.1.Continuity Equation
10.1.2.Momentum Equation: RANS
10.1.3.Enthalpy/Energy Equation
10.1.4.Concept of Eddy or Turbulent Diffusivity
10.1.5.Reynolds Analogy for Turbulent Flow
10.2.Prandtl Mixing Length Theory and Law of Wall for Velocity and Temperature Profiles
10.3.Turbulent Flow Heat Transfer
Problems
References
11.Fundamental Radiation
11.1.Thermal Radiation Intensity and Emissive Power
11.2.Surface Radiation Properties for Blackbody and Real-Surface Radiation
11.3.Solar and Atmospheric Radiation
Problems
References
12.View Factor
12.1.View Factor
12.2.Evaluation of View Factor
12.2.1 Method 1 Hottel's Crossed-String Method for 2-D Geometry
12.2.2 Method 2 Double-Area Integration
12.2.3 Method 3 Contour Integration
12.2.4 Method 4 Algebraic Method
Problems
References
13.Radiation Exchange in a Nonparticipating Medium
13.1.Radiation Exchange between Gray Diffuse Isothermal Surfaces in an Enclosure
13.1.1 Method 1 Electric Network Analogy
13.1.2 Method 2 Matrix Linear Equations
13.2.Radiation Exchange between Gray Diffuse Nonisothermal Surfaces
13.3.Radiation Exchange between Nongray Diffuse Isothermal Surfaces
13.4.Radiation Interchange among Diffuse and Nondiffuse (Specular) Surfaces
13.5.Energy Balance in an Enclosure with Diffuse and Specular Surface
Problems
References
14.Radiation Transfer through Gases
14.1.Gas Radiation Properties
14.1.1.Volumetric Absorption
14.1.2.Geometry of Gas Radiation: Geometric Mean Beam Length
14.2.Radiation Exchange between an Isothermal Gray Gas and Gray Diffuse Isothermal Surfaces in an Enclosure
14.2.1.Matrix Linear Equations
14.2.2.Electric Network Analogy
14.3.Radiation Transfer through Gases with Nonuniform Temperature
14.3.1.Cryogenic Thermal Insulation
14.3.2.Radiation Transport Equation in the Participating Medium
Problems
References
Appendix A Mathematical Relations and Functions
A.1.Useful Formulas
A.2.Hyperbolic Functions
A.3.Bessel Functions
A.3.1.Bessel Functions and Properties
A.3.2.Bessel Functions of the First Kind
A.3.3.Modified Bessel Functions of the First and Second Kinds
A.4.Gaussian Error Function
References.
Edition Notes
Includes bibliographical references and index.
Classifications
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| August 15, 2020 | Edited by ImportBot | import existing book |
| July 4, 2012 | Created by LC Bot | import new book |