Symbols |
Introduction / Chapter 1: |
What and How? / 1.1: |
Physical Origins and Rate Equations / 1.2: |
Relationship to Thermodynamics / 1.3: |
Units and Dimensions / 1.4: |
Analysis of Heat Transfer Problems: Methodology / 1.5: |
Relevance of Heat Transfer / 1.6: |
Summary / 1.7: |
References |
Problems |
Introduction to Conduction / Chapter 2: |
The Conduction Rate Equation / 2.1: |
The Thermal Properties of Matter / 2.2: |
The Heat Diffusion Equation / 2.3: |
Boundary and Initial Conditions / 2.4: |
One-Dimensional, Steady-State Conduction / 2.5: |
The Plane Wall / 3.1: |
An Alternative Conduction Analysis / 3.2: |
Radial Systems / 3.3: |
Summary of One-Dimensional Conduction Results / 3.4: |
Conduction with Thermal Energy Generation / 3.5: |
Heat Transfer from Extended Surfaces / 3.6: |
The Bioheat Equation / 3.7: |
Thermoelectric Power Generation / 3.8: |
Micro- and Nanoscale Conduction / 3.9: |
Two-Dimensional, Steady-State Conduction / 3.10: |
Alternative Approaches / 4.1: |
The Method of Separation of Variables / 4.2: |
The Conduction Shape Factor and the Dimensionless Conduction Heat Rate / 4.3: |
Finite-Difference Equations / 4.4: |
Solving the Finite-Difference Equations / 4.5: |
Transient Conduction / 4.6: |
The Lumped Capacitance Method / 5.1: |
Validity of the Lumped Capacitance Method / 5.2: |
General Lumped Capacitance Analysis / 5.3: |
Spatial Effects / 5.4: |
The Plane Wall with Convection / 5.5: |
Radial Systems with Convection / 5.6: |
The Semi-Infinite Solid / 5.7: |
Objects with Constant Surface Temperatures or Surface Heat Fluxes / 5.8: |
Periodic Heating / 5.9: |
Finite-Difference Methods / 5.10: |
Introduction to Convection / 5.11: |
The Convection Boundary Layers / 6.1: |
Local and Average Convection Coefficients / 6.2: |
Laminar and Turbulent Flow / 6.3: |
The Boundary Layer Equations / 6.4: |
Boundary Layer Similarity: The Normalized Boundary Layer Equations / 6.5: |
Physical Interpretation of the Dimensionless Parameters / 6.6: |
Boundary Layer Analogies / 6.7: |
External Flow / 6.8: |
The Empirical Method / 7.1: |
The Flat Plate in Parallel Flow / 7.2: |
Methodology for a Convection Calculation / 7.3: |
The Cylinder in Cross Flow / 7.4: |
The Sphere / 7.5: |
Flow Across Banks of Tubes / 7.6: |
Impinging Jets / 7.7: |
Packed Beds / 7.8: |
Internal Flow / 7.9: |
Hydrodynamic Considerations / 8.1: |
Thermal Considerations / 8.2: |
The Energy Balance / 8.3: |
Laminar Flow in Circular Tubes: Thermal Analysis and Convection Correlations / 8.4: |
Convection Correlations: Turbulent Flow in Circular Tubes / 8.5: |
Convection Correlations: Noncircular Tubes and the Concentric Tube Annulus / 8.6: |
Heat Transfer Enhancement / 8.7: |
Flow in Small Channels / 8.8: |
Convection Mass Transfer / 8.9: |
Free Convection / 8.10: |
Physical Considerations / 9.1: |
The Governing Equations for Laminar Boundary Layers / 9.2: |
Similarity Considerations / 9.3: |
Laminar Free Convection on a Vertical Surface / 9.4: |
The Effects of Turbulence / 9.5: |
Empirical Correlations: External Free Convection Flows / 9.6: |
Free Convection Within Parallel Plate Channels / 9.7: |
Empirical Correlations: Enclosures / 9.8: |
Combined Free and Forced Convection / 9.9: |
Boiling and Condensation / 9.10: |
Dimensionless Parameters in Boiling and Condensation / 10.1: |
Boiling Modes / 10.2: |
Pool Boiling / 10.3: |
Pool Boiling Correlations / 10.4: |
Forced Convection Boiling / 10.5: |
Condensation: Physical Mechanisms / 10.6: |
Laminar Film Condensation on a Vertical Plate / 10.7: |
Turbulent Film Condensation / 10.8: |
Film Condensation on Radial Systems / 10.9: |
Condensation in Horizontal Tubes / 10.10: |
Dropwise Condensation / 10.11: |
Heat Exchangers / 10.12: |
Heat Exchanger Types / 11.1: |
The Overall Heat Transfer Coefficient / 11.2: |
Heat Exchanger Analysis: Use of the Log Mean Temperature Difference / 11.3: |
Heat Exchanger Analysis: The Effectiveness-NTU Method / 11.4: |
Heat Exchanger Design and Performance Calculations / 11.5: |
Additional Considerations / 11.6: |
Radiation: Processes and Properties / 11.7: |
Fundamental Concepts / 12.1: |
Radiation Heat Fluxes / 12.2: |
Radiation Intensity / 12.3: |
Blackbody Radiation / 12.4: |
Emission from Real Surfaces / 12.5: |
Absorption, Reflection, and Transmission by Real Surfaces / 12.6: |
Kirchhoff's Law / 12.7: |
The Gray Surface / 12.8: |
Environmental Radiation / 12.9: |
Radiation Exchange Between Surfaces / 12.10: |
The View Factor / 13.1: |
Blackbody Radiation Exchange / 13.2: |
Radiation Exchange Between Opaque, Diffuse, Gray Surfaces in an Enclosure / 13.3: |
Multimode Heat Transfer / 13.4: |
Implications of the Simplifying Assumptions / 13.5: |
Radiation Exchange with Participating Media / 13.6: |
Diffusion Mass Transfer / 13.7: |
Mass Transfer in Nonstationary Media / 14.1: |
The Stationary Medium Approximation / 14.3: |
Conservation of Species for a Stationary Medium / 14.4: |
Boundary Conditions and Discontinuous Concentrations at Interfaces / 14.5: |
Mass Diffusion with Homogeneous Chemical Reactions / 14.6: |
Transient Diffusion / 14.7: |
Thermophysical Properties of Matter / 14.8: |
Mathematical Relations and Functions / Appendix B: |
Thermal Conditions Associated with Uniform Energy Generation in One-Dimensional, Steady-State Systems / Appendix C: |
The Gauss-Seidel Method / Appendix D: |
The Convection Transfer Equations / Appendix E: |
Boundary Layer Equations for Turbulent Flow / Appendix F: |
An Integral Laminar Boundary Layer Solution for Parallel Flow over a Flat Plate / Appendix G: |
Index |
Symbols |
Introduction / Chapter 1: |
What and How? / 1.1: |