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Handbook of heat transfer

[editors], Warren M. Rohsenow, James P. Hartnett, Young I. Cho

(McGraw-Hill handbooks)

McGraw-Hill, c1998

3rd ed

大学図書館所蔵 件 / 24

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注記

Includes bibliographical references and index

内容説明・目次

内容説明

Publisher's Note: Products purchased from Third Party sellers are not guaranteed by the publisher for quality, authenticity, or access to any online entitlements included with the product. A single reference source covering all aspects of heat transfer problem-solving in engineering. Written by the most eminentengineering authorities in the field, this authoritative and comprehensive Handbook has now been completely revised and updated to include all the latest advances in heat transfer principals with special coverage of micro scale heat transfer...heat transfer in materials processing...new heat transfer augmentation techniques...thermophysical properties of new refrigerants...innovative heat exchanger methods. The staff of expert contributors covers the essential heat transfer issues involved in every industrial and environmental process, as well as in energy production and transport. Designed to be the one and only source book the engineer needs, the Handbook presents key, fundamental subjects in condensed, readable form for on-the-job use. New findings in conduction, convection, radiation, and multi-phase heat transfer are also presented. The authors have kept the discussions of theory to a minimum, focusing more on a practical, hands-on-approach, to meet the day-to-day needs of engineers, designers, and technicians.

目次

  • Contributors Preface Chapter 1-Basic Concepts of Heat Transfer Heat Transfer Mechanisms Conduction Radiation Convection Combined Heat Transfer Mechanisms Conservation Equations The Equation of Continuity The Equation of Motion (Momentum Equation) The Energy Equation The Conservation Equations for Species Use of Conservation Equations to Set Up Problems Dimensionless Groups and Similarity in Heat Transfer Units and Conversion Factors Nomenclature References Chapter 2-Thermophysical Properties Conversion Factors Thermophysical Properties of Gases Thermophysical Properties of Liquids Thermophysical Properties of Solids Thermophysical Properties of Saturated Refrigerants Acknowledgements Nomenclature References Selected Additional Sources of Thermophysical Properties Chapter 3-Conduction and Thermal Contact Resistance (Conductances) Introduction Basic Equations, Definitions, and Relationships Shape Factors Shape Factors for Ellipsoids: Integral Form for Numerical Calculations Shape Factors for Three-Dimensional Bodies in Unbounded Domains Three-Dimensional Bodies with Layers: Langmuir Method Shape Factors for Two-Dimensional Systems Transient Conduction Introduction Internal Transient Conduction Lumped Capacitance Model Heisler and Grober Charts--Single-Term Approximations Multidimensional Systems Transient One-Dimensional Conduction in Half-Spaces External Transient Conduction from Long Cylinders Transient External Conduction from Spheres Instantaneous Thermal Resistance Transient External Conduction from Isothermal Convex Bodies Spreading (Constriction) Resistance Introduction Definitions of Spreading Resistance Spreading Resistance of Isoflux Arbitrary Areas on Half-Space Circular Annular Contact Areas on Half-Space Doubly Connected Isoflux Contact Areas on Half-Space Effect of Contact Conductance on Spreading Resistance Spreading Resistance in Flux Tubes and Channels Effect of Flux Distribution on Circular Contact Area on Half-Space Simple Correlation Equations of Spreading Resistance for Circular Contact Area Accurate Correlation Equations for Various Combinations of Contact Area, Flux Tubes, and Boundary Condition General Spreading Resistance Expression for Circular Annular Area on Circular Flux Tube Spreading Resistance within Two-Dimensional Channels Effect of Single and Multiple Layers (Coatings) on Spreading Resistance Circular Contact Area on Single Layer (Coating) on Half-Space Circular Contact Area on Multiple Layers on Circular Flux Tube Transient Spreading Resistance Transient Spreading Resistance of Isoflux Hyperellipse Contact Area on Half-Space Transient Spreading Resistance of Isoflux regular Polygonal Contact Area on Half-Space Transient Spreading Resistance Within Semi-Infinite Flux Tubes and Channels Contact, Gap, and Joint Resistances and Contact Conductances Point and Line Contact Models Thermal Contact, Gap, and Joint Conductance Models Gap Conductance Model and Integral Acknowledgments Nomenclature References Chapter 4-Natural Convection Introduction Basics Equations of Motion and Their Simplification Problem Classification Heat Transfer Correlation Method External Natural Convection Flat Plates Cylinders Open Cavity Problems Cooling Channels Extended Surfaces Natural Convection within Enclosures Introduction Geometry and List of Parameters for Cavities Without Interior Solids The Conduction Layer Model Horizontal Rectangular Parallelepiped and Circular Cylinder Cavities Heat Transfer in Vertical Rectangular Parallelepiped Cavites: zero-ninety degrees Heat Transfer in Inclined Rectangular Cavities Heat Transfer in Enclosures with Interior Solids at Prescribed Temperature Transient Natural Convection External Transient Convection Internal Transient Convection Natural Convection with Internal Generation Internal Problems Convection in Porous Media Properties and Dimensionless Groups External Heat Transfer Correlations Internal Heat Transfer Correlations Mixed Convection External Flows Internal Flows Acknowledgments Nomenclature References Chapter 5-Forced Convection, Internal Flow in Ducts Introduction Scope of the Chapter Characteristics of Laminar Flow in Ducts Characteristics of Turbulent Flow in Ducts Hydraulic Diameter Fluid Flow Parameters Heat Transfer Parameters Thermal Boundary Conditions Circular Ducts Laminar Flow Turbulent Flow Transition Flow Concentric Annular Ducts Four Fundamental Thermal Boundary Conditions Laminar Flow Turbulent Flow Parallel Plate Ducts Laminar Flow Turbulent Flow Rectangular Ducts Laminar Flow Turbulent Flow Triangular Ducts Laminar Flow Turbulent Flow Elliptical Ducts Laminar Flow Turbulent Flow Curved Ducts and Helicoidal Pipes Fully Developed Laminar Flow Developing Laminar Flow Turbulent Flow in Coils with Circular Cross Sections Fully Developed Laminar Flow in Curved, Square, and Rectangular Ducts Fully Developed Turbulent Flow in Curved, Rectangular, and Square Ducts Laminar Flow in Coiled Annular Ducts Laminar Flow in Curved Ducts with Elliptic Cross Sections Longitudinal Flow Between Cyclinders Laminar Flow Fully Developed Turbulent Flow Internally Finned Tubes Circular Ducts with Thin Longitudinal Fins Square Ducts with Thin Longitudinal Fins Rectangular Ducst with Longitudinal Fins from Opposite Walls Circular Ducts with Longitudinal Triangular Fins Circular Ducts with Twisted Tape Semicircular Ducts with Internal Fins Elliptical Ducts with Internal Longitudinal Fins Other Singly Connected Ducts Sine Ducts Trapezoidal Ducts Rhombic Ducts Quadrilateral Ducts Regular Polygonal Ducts Circular Sector Ducts Circular Segment Ducts Annular Sector Ducts Stadium-Shaped Ducts Moon-Shaped Ducts Corrugated Ducts Parallel Plate Ducts with Spanwise Periodic Corrugations at One Wall Cusped Ducts Cardioid Ducts Unusual Singly Connected Ducts Other Doubly Connected Ducts Confocal Elliptical Ducts Regular Polygonal Ducts with Centered Circular Cores Circular Ducts with Centered Regular Polygonal Cores Isosceles Triangular Ducts with Inscribed Circular Cores Elliptical Ducts with Centered Circular Cores Concluding Remarks Nomenclature References Chapter 6-Forced Convection, External Flows Introduction Definition of Terms Two-Dimensional Laminar Boundary Layer Two-Dimensional Boundary Layers Transitional Boundary Layers Complex Configurations Nomenclature References Chapter 7-Radiation Introduction Radiation Intensity and Flux Blackbody Radiation Nonblack Surfaces and Materials Radiative Exchange: Enclosures Containing a Nonparticipating Medium Black Surfaces Exchange Among Gray Diffuse Surfaces Radiative Exchange with a Participating Medium Fundamentals and Definitions Solution Techniques for the RTE Solutions to Benchmark Problems Radiative Properties for Participating Media Radiative Properties of Gases Radiative Properties of Particulates Radiative Properties of Porous Materials Radiative Properties of Semitransparent Materials Combined Modes with Radiation The General Energy Equation Interaction with Conduction and Convection Interaction with Combustion and Turbulence Closing Remarks Appendix A: Radiative Property Tables Appendix B: Radiation Configuration Factors Nomenclature References Chapter 8-Microscale Transport Phenomena Introduction Time and Length Scales Kinetic Theory Formulation Thermal Conductivity of Crystalline and Amorphous Solids Boltzmann Transport Theory General Formulation Fourier and Ohm's Laws Hyperbolic Heat Equation Mass, Momentum, and Energy Conservation--Hydrodynamic Equations Equation of Radiative Transfer for Photons and Phonons Nonequilibrium Energy Transfer Joule Heating in High-Field Electronic Devices Radiative Heating by Ultrashort Laser Pulses Summary Nomenclature References Chapter 9-Heat Transfer in Porous Media Introduction Single-Phase Flow Conduction Heat Transfer Convection Heat Transfer Radiation Heat Transfer Two-Medium Treatment Two-Phase Flow Momentum Equations for Liquid-Gas Glow Local Volume Averaging of Energy Equation Effective Thermal Conductivity Thermal Dispersion Phase Change Condensation at Vertical Impermeable Bounding Surfaces Evaporation at Vertical Impermeable Bounding Surfaces Evaporation at Horizontal Impermeable Bounding Surfaces Evaporation at Thin Porous-Layer-Coated Surfaces Melting and Solidification Nomenclature Glossary References Chapter 10-Nonnewtonian Fluids Introduction Overview Classification of Onnewtonian Fluids Material Functions of Nonnewtonian Fluids Rheological Property Measurements Thermophysical Properties of Nonnewtonian Fluids Governing Equations of Nonnewtonian Fluids Use of Reynolds and Prandtl Numbers Use of the Weissenberg Number Laminar Nonnewtonian Flow in a Circular Tube Velocity Distribution and Friction Factor Fully Developed Heat Transfer Laminar Heat Transfer in the Thermal Enrance Region Laminar Nonnewtonian Flow in a Rectangular Duct Velocity Distribution and Friction Fac tor Fully Developed Heat Transfer-Purely Viscous Fluids Heat Transfer in the Thermal Entrance Region-Purely Viscous Fluids Laminar Heat Transfer to Viscoelastic Fluids in Rectangular Ducts Turbulent Flow of Purely Viscous Fluis in Circular Tubes Fully Established Friction Factor Heat Transfer Turbulent Flow of Viscoelastic Fluids in Circular Tubes Friction Factor and Velocity Distribution Heat Transfer Degradation Solvent Effects Failure of the Reynolds-Colburn Analogy Turbulent Flow of Purely Viscous Fluids in Rectangular Ducts Friction Factor Heat Transfer Turbulent Flow of Viscoelastic Fluids in Rectangular Ducts Friction Factor Heat Transfer Anomalous Behavior of Aqueous Polyacrylic Acid Solutions Flow over Surfaces
  • Free Convection
  • Boiling Flow over Surfaces Free Convection Boiling Suspensions and Surfactants Flow of Food Products Electrorheological Flows Nomenclature References Chapter 11-Techniques to Enhance Heat Transfer Introduction General Background Classification of Heat Transfer Enhancement Techniques Performance Evaluation Criteria Treated and Structured Surfaces Boiling Condensing Rough Surfaces Single-Phase Flow Boiling Condensing Extended Surfaces Single-Phase Flow Boiling Condensing Displaced Enhancement Devices Single-Phase Flow Flow Boiling Condensing Swirl-Flow Devices Single-Phase Flow Boiling Condensing Surface-Tension Devices Additives for Liquids Solid Particles in Single-Phase Flow Gas Bubbles in Single-Phase Flow Liquid Additives for Boiling Additives for Gases Solid Particles in Single-Phase Flow Liquid drops in Single-Phase Flow Mechanical Aids Stirring Surface Scraping Rotating Surfaces Surface Vibration Single-Phase Flow Boiling Condensing Fluid Vibration Single-Phase Flow Boiling Condensing Electric and Magnetic Fields Injection Suction Compound Enhancement Prospects for the Future Nomenclature References Chapter 12-Heat Pipes Introduction Fundamental Operating Principles Capillary Limitation Other Limitations Design and Manufacturing Considerations Working Fluid Wicking Structures Materials Compatibility Heat Pipe Sizes and Shapes Reliability and Life Tests Heat Pipe Thermal Resistance Types of Heat Pipes Variable-Conductance Heat Pipes Micro-Heat Pipes Nomenclature References Chapter 13-Heat Transfer in Packed and Fluidized Beds Introduction Hydrodynamics Packed Beds Fluidized Beds Heat Transfer in Packed Beds Particle-to-Fluid Heat Transfer Effective Thermal Conductivity Wall-to-Bed Heat Transfer Relative Heat Transfer Heat Transfer in Fluidized Beds Gas-Solid Fluidized Beds Liquid-Solid Fluidized Beds Concluding Remarks Nomenclature References Chapter 14-Condensation Introduction Modes of Condensation Condensation Curve Thermal Resistance Film Condensation on a Verical Plate Approximate Analysis Boundary Layer Analysis Film Condensation on Horizontal Smooth Tubes Single Tube Tube Bundles Film Condensation on HOrizontal Finned Tubes Single Tube Other Body Shapes Inclined Circular Tubes Inclined Upward-Facing Plates Horizontal Upward-Facing Plates and Disks Bottom of a Container Horizontal and Inclined Downward-Facing Plates and Disks General Axisymmetric Bodies Horizontal and Inclined Elliptical Cylinders Vertically Oriented Helical Coils Consdensation with Rotation Zero Gravity In-Tube Condensation Flow Regimes Vertical Tubes Horizontal Tubes Pressure Losses Condenser Modeling Noncircular Passages Direct Contract Condensation Condensation on Drops (Spray Condensers) Condensation on Jets and Sheets Condensation on Films Condensation on Vapor Bubbles Condensation of Mixtures Equilibrium Methods Nonequilibrium Methods Nomenclature References Chapter 15-Boiling Introduction General Considerations Manifestations of Boiling Heat Transfer Structure of this Chapter Phase Equilibrium Single-Component Systems Multicomponent Systems Nucleation and Bubble Growth Equilibrium of a Bubble Homogenous Nucleation Heterogeneous Nucleation Bubble Growth Bubble Release Diameter and Frequency Pool Boiling Pool Boiling Heat Transfer Before the Critical Heat Flux Limit The Critical Heat Flux Limit in Pool Boiling Heat Transfer Beyond the Critical Heat Flux Limit in Pool Boiling Cross Flow Boiling Heat Transfer Before the Critical Heat Flux Limit in Cross Flow Boiling Critical Heat Flux in Cross Flow Boiling Heat Transfer Beyond the Critical Heat Flux Limit in Cross Flow Boiling Forced Convective Boiling in Channels Heat Transfer Below the Critical Heat Flux Limit in Forced Convective Boiling in Channels Critical Heat Flux in Forced Convective Boiling in Channels Heat Transfer Beyond the Critical Heat Flux Limit in Forced Convective Boiling in Channels Thin Film Heat Transfer Evaporating Liquid Films: Laminar Flow Evaporating Liquid Films: Turbulent Flow Evaporating Liquid Films: Multicomponent Mixtures Evaporating Liquid Films with Nucleate Boiling Heat Transfer to a Nonevaporating (Subcooled) Falling Liquid Film Film Breakdown Rewettng of Hot Surfaces Nomenclature References Chapter 16-Measurement of Temperature and Heat Transfer Introduction Temperature Measurement Basic Concepts and Definitions Standards and Temperature Scales Sensors Local Temperature Measurement Calibration of Thermometers and Assurance of Measurements Heat Flux Measurement Basic Principles Methods Thermal Resistance Gauges Measurement by Analogy Introduction Sublimation Technique Electrochemical Technique Acknowledgments Nomenclature List of Abbreviations References Chapter 17-Heat Exchangers Introduction Classification of Heat Exchangers Shell-and-Tube Exchangers Newer Designs of Shell-and-Tube Exchangers Compact Heat Exchangers Exchanger Heat Transfer and Pressure Drop Analysis Heat Transfer Analysis The e-NTU, P-NTU, and MTD Methods Fin Efficiency and Extended Surface Efficiency Extensions of the Basic Recuperator Thermal Design Theory e-NTU, and lambda-pi Methods for Regeneration Single-Phase Pressure Drop Analysis Single-Phase Surface Basic Heat Transfer and Flow Friction Characteristics Experimental Methods Analytical Solutions Experimental Correlations Influence of Temperature-Dependent Fluid Properties Influence of Superimposed Free Convection Two-Phase Heat Transfer and Pressure Drop Correlations Flow Patterns Two-Phase Pressure Drop Correlations Heat Transfer Correlations for Condensation Heat Transfer Correlations for Boiling Thermal Design for Single-Phase Heat Exchangers Exchanger Design Methodolgy Extended Surface Heat Exchangers Shell-and-Tube Heat Exchangers Thermal Design for Two-Phase Heat Exchangers Condensers Vaporizers Flow-Induced Vibration Tube Vibration Acoustic Vibrations Design Guidlines for Vibration Mitigation Flow Maldistribution Geometry-Induced Flow Maldistribution Flow Maldistribution Induced by Operating Conditions Mitigation of Flow Maldistribution Fouling and Corrosion Fouling Corrosion Concluding Remarks Nomenclature References Chapter 18-Heat Transfer in Materials Processing Introduction Heat Transfer Fundamentals Relevant to Materials Processing Conduction Heat Transfer Conduction Heat Transfer in Beam-Irradiated Materials Conduction Heat Transfer with Thermomechanical Effects Single-Phase Convective Heat Transfer Two-Phase Convective Heat Transfer Radiation Heat Transfer System-Level Thermal Phenomena Heating of a Load Inside Industrial Furnaces Quenching Processing of Several Advanced Materials Concluding Remarks Nomenclature References Index

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