Buch, Englisch, 631 Seiten, Format (B × H): 161 mm x 241 mm, Gewicht: 1067 g
Buch, Englisch, 631 Seiten, Format (B × H): 161 mm x 241 mm, Gewicht: 1067 g
ISBN: 978-1-4398-4990-3
Verlag: CRC PR INC
Heat exchangers are essential in a wide range of engineering applications, including power plants, automobiles, airplanes, process and chemical industries, and heating, air conditioning and refrigeration systems. Revised and updated with new problem sets and examples, Heat Exchangers: Selection, Rating, and Thermal Design, Third Edition presents a systematic treatment of the various types of heat exchangers, focusing on selection, thermal-hydraulic design, and rating.
Topics discussed include:
Classification of heat exchangers according to different criteria
Basic design methods for sizing and rating of heat exchangers
Single-phase forced convection correlations in channels
Pressure drop and pumping power for heat exchangers and their piping circuit
Design solutions for heat exchangers subject to fouling
Double-pipe heat exchanger design methods
Correlations for the design of two-phase flow heat exchangers
Thermal design methods and processes for shell-and-tube, compact, and gasketed-plate heat exchangers
Thermal design of condensers and evaporators
This third edition contains two new chapters. Micro/Nano Heat Transfer explores the thermal design fundamentals for microscale heat exchangers and the enhancement heat transfer for applications to heat exchanger design with nanofluids. It also examines single-phase forced convection correlations as well as flow friction factors for microchannel flows for heat transfer and pumping power calculations. Polymer Heat Exchangers introduces an alternative design option for applications hindered by the operating limitations of metallic heat exchangers. The appendices provide the thermophysical properties of various fluids.
Each chapter contains examples illustrating thermal design methods and procedures and relevant nomenclature. End-of-chapter problems enable students to test their assimilation of the material.
Zielgruppe
Junior, senior, or first year graduate students in mechanical, nuclear, aerospace, and chemical engineering, and engineers in various industries.
Autoren/Hrsg.
Fachgebiete
Weitere Infos & Material
Classification of Heat ExchangersRecuperation and RegenerationTransfer ProcessesGeometry of ConstructionHeat Transfer MechanismsFlow Arrangements ApplicationsSelection of Heat Exchangers Basic Design Methods of Heat ExchangersArrangement of Flow Paths in Heat ExchangersBasic Equations in DesignOverall Heat Transfer Coefficient LMTD Method for Heat Exchanger AnalysisThe e-NTU Method for Heat Exchanger AnalysisHeat Exchanger Design CalculationVariable Overall Heat Transfer Coefficient Heat Exchanger Design Methodology Forced Convection Correlations for the Single-Phase Side of Heat Exchangers Laminar Forced ConvectionThe Effect of Variable Physical PropertiesTurbulent Forced ConvectionTurbulent Flow in Smooth Straight Noncircular DuctsEffect of Variable Physical Properties in Turbulent Forced Convection Summary of Forced Convection in Straight Ducts Heat Transfer from Smooth-Tube Bundles Heat Transfer in Helical Coils and Spirals Heat Transfer in Bends Heat Exchanger Pressure Drop and Pumping Power Tube-Side Pressure Drop Pressure Drop in Tube Bundles in Crossflow Pressure Drop in Helical and Spiral Coils Pressure Drop in Bends and Fittings Pressure Drop for Abrupt Contraction, Expansion, and Momentum Change Heat Transfer and Pumping Power Relationship Micro/Nano Heat Transfer PART A—Heat Transfer for Gaseous and Liquid Flow in Microchannels Introduction of Heat Transfer in Microchannels Fundamentals of Gaseous Flow in Microchannels Engineering Applications for Gas Flow Engineering Applications of Single-Phase Liquid Flow in Microchannels PART B—Single-Phase Convective Heat Transfer with NanofluidsIntroduction of Convective Heat Transfer with Nanofluids Thermal Conductivity of Nanofluids Thermal Conductivity Experimental Studies of Nanofluids Convective Heat Transfer of Nanofluids Analysis of Convective Heat Transfer of Nanofluids Experimental Correlations of Convective Heat Transfer of Nanofluids Fouling of Heat Exchangers Introduction Basic Considerations Effects of Fouling Aspects of Fouling Design of Heat Exchangers Subject to FoulingOperations of Heat Exchangers Subject to Fouling Techniques to Control FoulingDouble-Pipe Heat Exchangers Thermal and Hydraulic Design of Inner Tube Thermal and Hydraulic Analysis of Annulus Parallel–Series Arrangements of Hairpins Total Pressure Drop Design and Operational Features Design Correlations for Condensers and EvaporatorsCondensationFilm Condensation on a Single Horizontal TubeFilm Condensation in Tube Bundles Condensation Inside Tubes Flow Boiling Shell-and-Tube Heat Exchangers Basic Components Basic Design Procedure of a Heat Exchanger Shell-Side Heat Transfer and Pressure Drop Compact Heat ExchangersHeat Transfer and Pressure DropGasketed-Plate Heat Exchangers Mechanical Features Operational Characteristics Passes and Flow ArrangementsApplications Heat Transfer and Pressure Drop CalculationsThermal Performance Condensers and Evaporators Shell and Tube Condensers Steam Turbine Exhaust CondensersPlate Condensers Air-Cooled CondensersDirect Contact CondensersThermal Design of Shell-and-Tube CondensersDesign and Operational Considerations Condensers for Refrigeration and Air-Conditioning Evaporators for Refrigeration and Air-Conditioning Thermal Analysis Standards for Evaporators and Condensers Polymer Heat ExchangersPolymer Matrix Composite Materials (PMC)Nanocomposites Application of Polymers in Heat Exchangers Polymer Compact Heat ExchangersPotential Applications for Polymer Film Compact Heat Exchangers Thermal Design of Polymer Heat Exchangers Appendix A Appendix BIndex
