Hjem

1. BASIC MODES OF HEAT TRANSFER. Concepts and Analyses to Be Learned. The Relation of Heat Transfer to Thermodynamics. Dimensions and Units. Heat Conduction. Convection. Radiation. Combined Heat Transfer Systems. Thermal Insulation. Heat Transfer and the Law of Energy Conservation. Summary. References. Problems.
2. STEADY HEAT CONDUCTION. Concepts and Analyses to Be Learned. Introduction. The Conduction Equation. Steady Heat Conduction in Simple Geometries. Extended Surfaces or Fins. Multidimensional Steady Conduction. Summary. References. Problems.
3. TRANSIENT HEAT CONDUCTION. Concepts and Analyses to Be Learned. Introduction. Systems with Negligible Internal Resistance. Systems with Spatial Temperature Distribution. Semi-Infinite Solid. Multidimensional Systems. Summary. References. Problems.
4. NUMERICAL ANALYSIS OF HEAT CONDUCTION. Concepts and Analyses to Be Learned. Introduction. One-Dimensional Steady Conduction. One-Dimensional Unsteady Conduction. Two-Dimensional Steady and Unsteady Conduction. Cylindrical Coordinates. Irregular Boundaries. Summary. References. Problems.
5. ANALYSIS OF CONVECTION HEAT TRANSFER. Concepts and Analyses to Be Learned. Introduction. Convection Heat Transfer. Boundary Layer Fundamentals. Conservation Equations of Mass, Momentum, and Energy for Laminar Flow Over a Flat Plate. Dimensionless Boundary Layer Equations and Similarity Parameters. Evaluation of Convection Heat Transfer Coefficients. Dimensional Analysis. Analytic Solution for Laminar Boundary Layer Flow over a Flat Plate. Approximate Integral Boundary Layer Analysis. Turbulent Flow over a Flat Surface. Special Boundary Conditions and High-Speed Flow. Summary. References. Problems.
6. FORCED CONVECTION OVER EXTERIOR SURFACES. Concepts and Analyses to Be Learned. Flow over Bluff Bodies. Cylinders, Spheres, and Other Bluff Shapes. Tube Bundles in Cross-Flow. Finned Tube Bundles in Cross-Flow. Packed Beds. Free Jets. Summary. References. Problems.
7. FORCED CONVECTION INSIDE TUBES AND DUCTS. Concepts and Analyses to Be Learned. Introduction. Analysis of Laminar Forced Convection in a Long Tube. Correlations for Laminar Forced Convection. Analogy Between Heat and Momentum Transfer. Correlations for Turbulent Forced Convection. Heat Transfer Enhancement and Electronic-Device Cooling. Summary. References. Problems.
8. NATURAL CONVECTION. Concepts and Analyses to Be Learned. Introduction. Similarity Parameters for Natural Convection. Empirical Correlation for Various Shapes. Finned Surfaces. Rotating Cylinders, Disks, and Spheres. Combined Forced and Natural Convection. Summary. References. Problems.
9. HEAT TRANSFER WITH PHASE CHANGE. Concepts and Analyses to Be Learned. Introduction to Boiling. Pool Boiling. Boiling in Forced Convection. Condensation. Condenser Design. Heat Pipes. Freezing and Melting. Summary. References. Problems.
10. HEAT EXCHANGERS. Concepts and Analyses to Be Learned. Introduction. Basic Types of Heat Exchangers. Overall Heat Transfer Coefficient. Log Mean Temperature Difference. Heat Exchanger Effectiveness. Heat Transfer Enhancement. Microscale Heat Exchangers. Summary. References. Problems.
11. HEAT TRANSFER BY RADIATION. Concepts and Analyses to Be Learned. Thermal Radiation. Radiation Heat Flux. Blackbody Radiation. Radiation Properties. Solar Radiation and Global Warming. The Radiation Shape Factor. Enclosures with Black Surfaces. Enclosures with Gray Surfaces Enclosures with Nongray Surfaces. Radiation Combined with Convection and Conduction. Radiation Properties of Gases and Vapors. Summary. References. Problems. Appendix
1: The International System of Units. Appendix
2: Data Tables. Appendix
3: Tridiagonal Matrix Computer Programs. Appendix
4: Commercial Computer Codes for Heat Transfer. Appendix
5: Heat Transfer Literature. Index.