Heat Exchanger Design Handbook - Online
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Table of Contents:Fluid mechanics and heat transferContributorsPreface Preface to 1998 Edition of Part 2 Preface to First Edition of Part 2 2.1 FUNDAMENTALS OF HEAT AND MASS TRANSFER 2.1.0 Introduction, E. U. Schlunder 2.1.1 Physical Mechanisms of Transport Phenomena, E. U. Schlunder 2.1.2 Industrial Applications of Heat and Mass Transfer, E. U. Schlunder 2.1.3 Presentation of Heat and Mass Transfer Data, E. U. Schlunder 2.1.4 Heat and Mass Transfer in Uniform and Nonuniform Systems, E. U. Schlunder 2.1.5 Analogy between Heat and Mass Transfer and Its Limitations, E. U. Schlunder 2.1.6 Combined Heat and Mass Transfer, E. U. Schlunder 2.1.7 State of the Art of Heat and Mass Transfer, E. U. Schlunder 2.2 SINGLE-PHASE FLUID FLOW 2.2.1 Introduction and Fundamentals, K. Gersten 2.2.2 Ducts, K. Gersten 2.2.3 Immersed Bodies, K. Gersten 2.2.4 Banks of Plain and Finned Tubes, A. Zukauskas and R. Ulinskas 2.2.5 Fixed Beds, P. J. Heggs 2.2.6 Fluidized Beds, K. E. Wirth 2.2.7 Headers, Nozzles, and Turnarounds, J. A. R. Henry 2.2.8 Non-Newtonian Fluids, Robert C. Armstrong and B. K. Rao 2.3 MULTIPHASE FLUID FLOW AND PRESSURE DROP 2.3.1 Introduction and Fundamentals, G. F. Hewitt 2.3.2 Gas-Liquid Flow, G. F. Hewitt 2.3.3 Solid-Gas Flow, M. Weber and W. Stegmaier 2.3.4 Solid-Liquid Flow, M. Weber and W. Stegmaier 2.3.5 Liquid-Liquid Two-Phase Flow, N. Brauner 2.3.6 Three-Phase Liquid-Liquid-Gas Flow, A. Valle 2.4 HEAT CONDUCTION 2.4.1 Basic Equations, H. Martin 2.4.2 Steady State, H. Martin 2.4.3 Transient Response to a Step Change of Temperature, H. Martin 2.4.4 Melting and Solidification, H. Martin 2.4.5 Periodic Change of Temperature, H. Martin 2.4.6 Thermal Contact Resistance, T. F. Irvine, Jr., and J. Taborek 2.4.7 Finite Difference Methods for Conduction, F. W. Schmidt 2.4.8 Finite-Element Methods for Conduction, G. E. Schneider 2.4.9 Extended Surfaces and Fin Efficiency, J. Taborek 2.5 SINGLE-PHASE CONVECTIVE HEAT TRANSFER 2.5.1 Forced Convection in Ducts, V. Gnielinski 2.5.2 Forced Convection around Immersed Bodies, V. Gnielinski (with contributions from A. Zukauskas and J. Zingzda) 2.5.3 Banks of Plain and Finned Tubes A. Zukauskas and A. Skrinska, J. Zingzda and V. Gnielinski 2.5.4 Fixed Beds, V. Gnielinski 2.5.5 Fluid-to-Particle Heat Transfer in Fluidized Beds, S. S. Zabrodsky with revisions by H. Martin 2.5.6 Impinging Jets, H. Martin 2.5.7 Free Convection around Imersed Bodies, S. W. Churchill 2.5.8 Free Convection in Layers and Enclosures, S. W. Churchill 2.5.9 Combined Free and Forced Convection around Immersed Bodies, S. W. Churchill 2.5.10 Combined Free and Forced Convection in Channels, S. W. Churchill 2.5.11 Augmentation of Heat Tansfer, Arthur E. Bergles 2.5.12 Heat Transfer for Non-Newtonian Fluids, Robert C. Armstrong, B. K. Rao and H. H. Winter 2.5.13 Heat Transfer in Liquid Metals, E. M. Firsova and M. E. Lebedev 2.5.14 Helically Coiled Tubes of Circular Cross Sections, V. Gnielinski 2.6 CONDENSATION 2.6.1 General Introduction, D. Butterworth 2.6.2 Film Condensation of Pure Vapor, J. McNaught and D. Butterworth 2.6.3 Condensation of Vapor Mixtures, D. R. Webb 2.6.4 Condensation of Vapor Mixtures Forming Immiscible Liquids, D. R. Webb 2.6.5 Dropwise Condensation, J. W. Rose 2.6.6 Condensation Enhancement, R. L. Webb 2.6.7 Fogging, D. Chisholm 2.7 BOILING AND EVAPORATION 2.7.1 Boiling of Single Component Liquids: Basic Processes, J. G. Collier and V. Wadekar 2.7.2 Pool Boiling, J. G. Collier and V. Wadekar 2.7.3 Boiling within Vertical Tubes, J. G. Collier and G. F. Hewitt 2.7.4 Convective Boiling Inside Straight, Horizontal and Inclined Tubes, Tubes with Bends and Helically Coiled Tubes, J. G. Collier and G. F. Hewitt 2.7.5 Boiling outside Tubes and Tube Bundles, J. G. Collier and G. F. Hewitt 2.7.6 Boiling of Binary and Multicomponent Mixtures; Basic Processes, J. G. Collier and G. F. Hewitt 2.7.7 Boiling of Binary and Muticomponet Mixtures: Pool Boiling, J. G. Collier and G. F. Hewitt 2.7.8 Boiling of Binary and Multicomponent Mixtures: Forced Convection Boiling, J. G. Collier and G. F. Hewitt 2.7.9 Augmentation of Boiling and Evaporation, Arthur E. Bergles 2.8 HEAT TRANSFER TO GAS-SOLID SYSTEMS 2.8.1 Stagnant Packed Beds, E. Tsotsas 2.8.2 Packed Beds with Fluid Flow, E. Tsotsas 2.8.3 Heat Transfer from a Wall to Granular Products, E. Tsotsas 2.8.4 Fluidized Beds, H. Martin 2.9 HEAT TRANSFER BY RADIATION 2.9.1 Introduction, D. K. Edwards 2.9.2 Surface Radiation Characteristics, D. K. Edwards 2.9.3 Radiation Transfer between Perfectly Diffuse Surfaces, D. K. Edwards 2.9.4 Radiation Transfer between Specular and Imperfectly Diffuse Surfaces, D. K. Edwards 2.9.5 Gas Radiation Properties, D. K. Edwards 2.9.6 Radiation Transfer with an Isothermal Gas, D. K. Edwards 2.9.7 Nonisothermal Gas Radiation, D. K. Edwards 2.9.8 Radiation Interaction with Conduction and/or Convection, K. T. Yang 2.10 DIRECT CONTACT HEAT TRANSFER 2.10.1 Introduction, H. R. Jacobs 2.10.2 Heat Transfer Between Parallel Continuous Streams, H. R. Jacobs 2.10.3 Heat Transfer with Phase Change, H. R. Jacobs 2.11 HEAT TRANSFER IN POROUS MEDIA 2.11.1 Fundamentals, A. Bejan 2.11.2 Heat conduction, A. Bejan 2.11.3 Forced convection, A. Bejan 2.11.4 Heat exchangers as porous media, A. Bejan 2.11.5 Natural convection: external flow, A. Bejan 2.11.6 Natural convection: internal flow, A. Bejan 2.11.7 Combined effects, A. Bejan 2.12 HEAT TRANSFER IN FOAM SYSTEMS 2.12.1 General Introduction, J. Gylys 2.12.2 Heat Transfer under Statically Stable Foam Cross Flow over Tubes and Tube Banks, J. Gylys 2.13 HEAT TRANSFER AND FLUID FLOW IN MICROCHANNELS 2.13.1 Introduction, G. P. Celata and G. Zummo 2.13.2 Single-Phase Fluid Flow, G. P. Celata, Z.-Y. Guo, Z.-X. Li and G. Zummo 2.13.3 Single-Phase Convective Heat Transfer, B. Palm and X.-F. Peng 2.13.4 Boiling and Evaporation, J. R. Thome, M. Groll and R. Mertz 2.13.5 Two-Phase Fluid Flow, A. Serizawa and Z. P. Feng 2.13.6 Condensation, A. Cavallini 2.13.7 Molecular Dynamics Methods in Microscale Heat Transfer, S. Maruyama 2.13.8 Micro Heat Pipes, M. Groll and S. Khandekar |