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Index
Cover
Table of Contents
Preface
Introduction
1 Methods for Determining Convection Heat Transfer Coefficients
1.1. Introduction
1.2. Characterizing the motion of a fluid
1.3. Transfer coefficients and flow regimes
1.4. Using dimensional analysis
1.5. Using correlations to calculate h
2 Forced Convection inside Cylindrical Pipes
2.1. Introduction
2.2. Correlations in laminar flow
2.3. Correlations in transition zone
2.4. Correlations in turbulent flow
2.5. Dimensional correlations for air and water
3 Forced Convection inside Non-cylindrical Pipes
3.1. Introduction
3.2. Concept of hydraulic diameter
3.3. Hydraulic Nusselt and Reynolds numbers
3.4. Correlations in established laminar flow
3.5. Correlations in turbulent flow for non-cylindrical pipes
4 Forced Convection outside Pipes or around Objects
4.1. Introduction
4.2. Flow outside a cylindrical pipe
4.3. Correlations for the stagnation region
4.4. Correlations beyond the stagnation zone
4.5. Forced convection outside non-cylindrical pipes
4.6. Forced convection above a horizontal plate
4.7. Forced convection around non-cylindrical objects
4.8. Convective transfers between falling films and pipes
4.9. Forced convection in coiled pipes
5 Natural Convection Heat Transfer
5.1. Introduction
5.2. Characterizing the motion of natural convection
5.3. Correlations in natural convection
5.4. Vertical plates subject to natural convection
5.5. Inclined plates subject to natural convection
5.6. Horizontal plates subject to natural convection
5.7. Vertical cylinders subject to natural convection
5.8. Horizontal cylinders subject to natural convection
5.9. Spheres subject to natural convection
5.10. Vertical conical surfaces subject to natural convection
5.11. Any surface subject to natural convection
5.12. Chambers limited by parallel surfaces
5.13. Inclined-plane chambers
5.14. Chambers limited by two concentric cylinders
5.15. Chambers limited by two concentric spheres
5.16. Simplified correlations for natural convection in air
5.17. Finned surfaces: heat sinks in electronic systems
5.18. Optimizing the thermal resistance of a heat sink
5.19. Optimum circuit-board assembly
5.20. Superimposed forced and natural convections
6 Convection in Nanofluids, Liquid Metals and Molten Salts
6.1. Introduction
6.2. Transfers in nanofluids
6.3. Transfers in liquid metals
6.4. Transfers in molten salts
6.5. Reading: Eugène Péclet and Lord Rayleigh
7 Exercises and Solutions
Appendices
Appendix 1 Database
Appendix 2 Regressions
Bibliography
Index
End User License Agreement
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