Thermal radiation heat transfer /

Thermal radiation heat transfer /

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Bibliographic Details
Author / Creator:Siegel, Robert, 1927-
Edition:2d ed.
Imprint:Washington : Hemisphere Pub. Corp., c1981.
Description:xvi, 862 p. : ill. ; 25 cm.
Language:English
Series:Series in thermal and fluids engineering
Subject:
Heat -- Radiation and absorption
Heat -- Transmission
Materials -- Thermal properties
Heat -- Radiation and absorption.
Heat -- Transmission.
Materials -- Thermal properties.
Format: Print Book
URL for this record:http://pi.lib.uchicago.edu/1001/cat/bib/416788
Hidden Bibliographic Details
Other authors / contributors:Howell, John R. joint author.
ISBN:0070573166
Notes:Includes bibliographical references and index.
Table of Contents:
  • Preface to the Fourth Edition
  • CD-Rom Instructions
  • List of Symbols
  • Chapter 1. Introduction and Blackbody Radiation
  • 1-1. Importance of Thermal Radiation in Technology
  • 1-2. Complexities Inherent in Radiation Problems
  • 1-3. Electromagnetic Spectrum
  • 1-4. Definition and Characteristics of a Blackbody
  • 1-5. Blackbody Emission Characteristics
  • 1-6. Experimental Production of a Blackbody
  • 1-7. Summary of Blackbody Properties
  • 1-8. Historical Development
  • References
  • Problems
  • Chapter 2. Definitions of Properties for Nonblack Opaque Surfaces
  • 2-1. Introduction
  • 2-2. Emissivity
  • 2-3. Absorptivity
  • 2-4. Reflectivity
  • 2-5. Relations between Reflectivity, Absorptivity, and Emissivity
  • References
  • Problems
  • Chapter 3. Prediction of Radiative Properties by Classical Electromagnetic Theory
  • 3-1. Introduction
  • 3-2. Electromagnetic Equations
  • 3-3. Radiant Wave Propagation in a Medium
  • 3-4. Laws of Reflection and Refraction
  • 3-5. Application of Electromagnetic-Theory Relations to Radiative-Property Predictions
  • 3-6. Extensions of the Theory for Radiative Properties
  • References
  • Problems
  • Chapter 4. Radiative Properties of Real Materials
  • 4-1. Introduction
  • 4-2. Radiative Properties of Opaque Nonmetals
  • 4-3. Radiative Properties of Metals
  • 4-4. Selective and Directional Opaque Surfaces, and Selective Transmission
  • 4-5. Concluding Remarks
  • References
  • Problems
  • Chapter 5. Configuration Factors for Surfaces Transferring Uniform Diffuse Radiation
  • 5-1. Introduction to Enclosure Theory and Use of Geometric Configuration Factors
  • 5-2. Radiative Geometric Configuration Factors between Two Surfaces
  • 5-3. Methods for Evaluating Configuration Factors
  • 5-4. Constraints for Configuration Factor Accuracy
  • 5-5. Compilation of Known Configuration Factors and their References--Appendix C and Compact Disk
  • 5-6. Historical Note on Configuration Factors
  • References
  • Problems
  • Chapter 6. Radiation Exchange in Enclosures Composed of Black and/or Diffuse-Gray Surfaces
  • 6-1. Approximations and Restrictions for Analysis of Enclosures with Black and/or Diffuse-Gray Surfaces
  • 6-2. Radiative Transfer for Black Surfaces
  • 6-3. Radiation between Finite Diffuse-Gray Areas
  • 6-4. Radiation Analysis Using Infinitesimal Areas
  • 6-5. Computer Programs for Enclosure Analysis
  • References
  • Problems
  • Chapter 7. The Exchange of Thermal Radiation between Nondiffuse Nongray Surfaces
  • 7-1. Introduction
  • 7-2. Enclosure Theory for Diffuse Surfaces with Spectrally Dependent Properties
  • 7-3. Directional-Gray Surfaces
  • 7-4. Surfaces with Directionally and Spectrally Dependent Properties
  • References
  • Problems
  • Chapter 8. Radiation Exchange in Enclosures with Some Specularly Reflecting Surfaces
  • 8-1. Introduction
  • 8-2. Radiation Exchange among Surfaces with Specular Reflections
  • 8-3. Net-Radiation Method in Enclosures Having Specular and Diffuse Reflecting Surfaces
  • 8-4. Concluding Remarks
  • References
  • Problems
  • Chapter 9. Radiation Combined with Conduction and Convection at Boundaries
  • 9-1. Introduction
  • 9-2. Energy Relations and Boundary Conditions
  • 9-3. Radiation with Conduction
  • 9-4. Radiation with Convection and Conduction
  • References
  • Problems
  • Chapter 10. Numerical Solution Methods for Radiation Combined with Convection and Conduction
  • 10-1. Introduction
  • 10-2. Numerical Integration Methods for Use with Enclosure Equations
  • 10-3. Numerical Equations for Combined-Mode Energy Transfer
  • 10-4. Numerical Solution Techniques
  • 10-5. The Monte Carlo Method
  • References
  • Problems
  • Chapter 11. Fundamentals and Material Properties for Radiative Transfer in Absorbing, Emitting, and Scattering Media
  • 11-1. Introduction
  • 11-2. Definition of Radiation Intensity in a Medium
  • 11-3. Attenuation of Intensity by Absorption and Scattering
  • 11-4. The Increase of Intensity by Emission
  • 11-5. The Increase of Intensity by Incoming Scattering
  • 11-6. Property Definitions for a Path in a Uniform Absorbing and Emitting Medium without Scattering
  • 11-7. Spectral Lines and Bands for Absorption and Emission of Gases
  • 11-8. Band Models and Correlations for Gas Absorption and Emission
  • 11-9. Charts for Gas Total Emittance
  • 11-10. Scattering of Energy by Particles and Fibers
  • References
  • Problems
  • Chapter 12. Engineering Treatment of Radiation in Enclosures Containing Translucent Media with n [approximate] 1
  • 12-1. Introduction
  • 12-2. Net-Radiation Method for Enclosure Filled with Isothermal Medium of Uniform Composition
  • 12-3. Evaluation of Spectral Geometric-Mean Transmittance and Absorptance Factors
  • 12-4. Mean Beam-Length Approximation for Spectral Radiation from an Entire Volume of a Medium to All or Part of its Boundary
  • 12-5. Exchange of Total Radiation in an Enclosure by Use of Mean Beam Length
  • 12-6. Flames, Luminous Flames, and Particle Radiation
  • References
  • Problems
  • Chapter 13. Energy and Radiative Transfer Relations for an Absorbing, Emitting, and Scattering Medium with Conduction and Convection
  • 13-1. Introduction
  • 13-2. Energy Equation and Boundary Conditions for a Translucent Medium with Radiation
  • 13-3. The Radiative Transfer and Source Function Equations
  • 13-4. The Radiative Flux and its Divergence within a Medium
  • 13-5. Discussion of Solution Procedures
  • 13-6. Summary of Relations for Transfer in Absorbing, Emitting, and Scattering Media
  • References
  • Problems
  • Chapter 14. Relations for Energy Transfer in Plane Layers and Multidimensional Geometries
  • 14-1. Introduction
  • 14-2. Equations for Radiative Intensity, Flux, Flux Divergence, and Source Function in a Plane Layer
  • 14-3. Gray Plane Layer of Absorbing and Emitting Medium with Isotropic Scattering
  • 14-4. Gray Plane Layer with Energy Transfer Only by Radiation (Radiative Equilibrium)
  • 14-5. Radiation Combined with Heat Conduction
  • 14-6. Multidimensional Radiation in a Translucent Gray Medium with Isotropic Scattering
  • 14-7. Transient Solutions Including Heat Conduction
  • References
  • Problems
  • Chapter 15. Optically Thin and Thick Limits for Radiative Transfer in Translucent Media
  • 15-1. Introduction
  • 15-2. Some Analytical Methods for Optically Thin and Cold Media without Heat Conduction
  • 15-3. Optically Thick Medium without Heat Conduction; Radiative Diffusion
  • 15-4. Some Approximations for Combined Radiation and Conduction
  • 15-5. Approximate Solution for Combined Convection, Conduction, and Radiation in a Boundary Layer
  • 15-6. The Use of Mean Absorption Coefficients
  • References
  • Problems
  • Chapter 16. Multi-Flux and Discrete Ordinates Methods for Radiative Transfer in Translucent Media
  • 16-1. Introduction
  • 16-2. P[subscript N] (Differential) Methods
  • 16-3. Application of the P[subscript N] Method
  • 16-4. The Discrete Ordinates (S[subscript N]) Method
  • 16-5. Other Solution Methods
  • References
  • Problems
  • Chapter 17. Numerical Solution Methods for Combined Radiation, Conduction, and Convection in Participating Media
  • 17-1. Introduction
  • 17-2. Finite-Difference Methods
  • 17-3. Finite-Element Method (FEM)
  • 17-4. The Zonal Method
  • 17-5. Monte Carlo Technique for Radiatively Participating Media
  • 17-6. Numerical Boundary Conditions and Additional Solution Methods
  • 17-7. Results for Combined Convection, Conduction, and Radiation
  • 17-8. Benchmark Solutions for Computational Validation
  • References
  • Problems
  • Chapter 18. Radiative Effects in Translucent Solids, Windows, and Coatings with n ] 1
  • 18-1. Introduction
  • 18-2. Transmission, Absorption, and Reflection of Windows
  • 18-3. Enclosure Analysis with Partially Transparent Windows
  • 18-4. Radiative Effects of Coatings or Thin Films on Surfaces
  • 18-5. Refractive Index Effects on Radiative Behavior in a Translucent Medium
  • 18-6. Multiple Layers Including Heat Conduction, Absorption, Emission, and Scattering
  • References
  • Problems
  • Appendix A. Conversion Factors, Radiation Constants, and Blackbody Functions
  • Appendix B. Radiative Properties
  • Appendix C. Catalog of Selected Configuration Factors
  • Appendix D. Exponential Integral Relations and Two-Dimensional Radiation Functions
  • Index
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