Kakaç S. Heat exchangers: selection, rating, and thermal design / S.Kakaç, H.Liu, A.Pramuanjaroenkij. - 3rd ed. - Boca Raton: CRC Press, 2012. - xvi, 615 p.: ill. - Incl. bibl. ref. - Ind.: p.607-615. - ISBN 978-1-4398-4990-3  Место хранения:   019 | Институт теплофизики им. С.С.Кутателадзе CO РАН | Новосибирск | Библиотека

Оглавление / Contents

Preface ...................................................... xiii 1 Classification of Heat Exchangers ............................ 1 1.1 Introduction ............................................ 1 1.2 Recuperation and Regeneration ........................... 1 1.3 Transfer Processes ...................................... 6 1.4 Geometry of Construction ................................ 8 1.4.1 Tubular Heat Exchangers .......................... 8 1.4.2 Plate Heat Exchangers ........................... 12 1.4.3 Extended Surface Heat Exchangers ................ 17 1.5 Heat Transfer Mechanisms ............................... 23 1.6 Flow Arrangements ...................................... 24 1.7 Applications ........................................... 25 1.8 Selection of Heat Exchangers ........................... 26 References .................................................. 30 2 Basic Design Methods of Heat Exchangers ..................... 33 2.1 Introduction ........................................... 33 2.2 Arrangement of Flow Paths in Heat Exchangers ........... 33 2.3 Basic Equations in Design .............................. 35 2.4 Overall Heat Transfer Coefficient ...................... 37 2.5 LMTD Method for Heat Exchanger Analysis ................ 43 2.5.1 Parallel- and Counterflow Heat Exchangers ....... 43 2.5.2 Multipass and Crossflow Heat Exchangers ......... 47 2.6 The e-NTU Method for Heat Exchanger Analysis ........... 56 2.7 Heat Exchanger Design Calculation ...................... 66 2.8 Variable Overall Heat Transfer Coefficient ............. 67 2.9 Heat Exchanger Design Methodology ...................... 70 Nomenclature ................................................ 73 References .................................................. 78 3 Forced Convection Correlations for the Single-Phase Side of Heat Exchangers .......................................... 81 3.1 Introduction ........................................... 81 3.2 Laminar Forced Convection .............................. 84 3.2.1 Hydrodynamically Developed and Thermally Developing Laminar Flow in Smooth Circular Ducts ........................................... 84 3.2.2 Simultaneously Developing Laminar Flow in Smooth Ducts .................................... 85 3.2.3 Laminar Flow through Concentric Annular Smooth Ducts ........................................... 86 3.3 Effect of Variable Physical Properties ................. 88 3.3.1 Laminar Flow of Liquids ......................... 90 3.3.2 Laminar Flow of Gases ........................... 92 3.4 Turbulent Forced Convection ............................ 93 3.5 Turbulent Flow in Smooth Straight Noncircular Ducts .... 99 3.6 Effect of Variable Physical Properties in Turbulent Forced Convection ..................................... 103 3.6.1 Turbulent Liquid Flow in Ducts ................. 103 3.6.2 Turbulent Gas Flow in Ducts .................... 104 3.7 Summary of Forced Convection in Straight Ducts ........ 107 3.8 Heat Transfer from Smooth-Tube Bundles ............... 111 3.9 Heat Transfer in Helical Coils and Spirals ............ 114 3.9.1 Nusselt Numbers of Helical Coils-Laminar Flow .. 116 3.9.2 Nusselt Numbers for Spiral Coils-Laminar Flow .. 117 3.9.3 Nusselt Numbers for Helical Coils-Turbulent Flow ........................................... 117 3.10 Heat Transfer in Bends ................................ 118 3.10.1 Heat Transfer in 90° Bends ..................... 118 3.10.2 Heat Transfer in 180° Bends .................... 119 Nomenclature ............................................... 120 References ................................................. 125 4 Heat Exchanger Pressure Drop and Pumping Power ............. 129 4.1 Introduction .......................................... 129 4.2 Tube-Side Pressure Drop ............................... 129 4.2.1 Circular Cross-Sectional Tubes ................. 129 4.2.2 Noncircular Cross-Sectional Ducts .............. 132 4.3 Pressure Drop in Tube Bundles in Crossflow ............ 135 4.4 Pressure Drop in Helical and Spiral Coils ............. 137 4.4.1 Helical Coils-Laminar Flow ..................... 138 4.4.2 Spiral Coils-Laminar Flow ...................... 138 4.4.3 Helical Coils-Turbulent Flow ................... 139 4.4.4 Spiral Coils-Turbulent Flow .................... 139 4.5 Pressure Drop in Bends and Fittings ................... 140 4.5.1 Pressure Drop in Bends ......................... 140 4.5.2 Pressure Drop in Fittings ...................... 142 4.6 Pressure Drop for Abrupt Contraction, Expansion, and Momentum Change ....................................... 147 4.7 Heat Transfer and Pumping Power Relationship .......... 148 Nomenclature ............................................... 150 References ................................................. 155 5 Micro/Nano Heat Transfer ................................... 157 5.1 PART A-Heat Transfer for Gaseous and Liquid Flow in Microchannels ......................................... 157 5.1.1 Introduction of Heat Transfer in Microchannels .................................. 157 5.1.2 Fundamentals of Gaseous Flow in Microchannels .. 158 5.1.3 Engineering Applications for Gas Flow .......... 163 5.1.4 Engineering Applications of Single-Phase Liquid Flow in Microchannels ................... 177 5.2 PART B-Single-Phase Convective Heat Transfer with Nanofluids ............................................ 186 5.2.1 Introduction of Convective Heat Transfer with Nanofluids ..................................... 186 5.2.2 Thermal Conductivity of Nanofluids ............. 188 5.2.3 Thermal Conductivity Experimental Studies of Nanofluids ..................................... 203 5.2.4 Convective Heat Trasfer of Nanofluids .......... 207 5.2.5 Analysis of Convective Heat Transfer of Nanofluids ..................................... 212 5.2.6 Experimental Correlations of Convective Heat Transfer of Nanofluids ......................... 216 Nomenclature ............................................... 224 References ................................................. 228 6 Fouling of Heat Exchangers ................................. 237 6.1 Introduction .......................................... 237 6.2 Basic Considerations .................................. 237 6.3 Effects of Fouling .................................... 239 6.3.1 Effect of Fouling on Heat Transfer ............. 240 6.3.2 Effect of Fouling on Pressure Drop ............. 241 6.3.3 Cost of Fouling ................................ 243 6.4 Aspects of Fouling .................................... 244 6.4.1 Categories of Fouling .......................... 244 6.4.2 Fundamental Processes of Fouling ............... 246 6.4.3 Prediction of Fouling .......................... 248 6.5 Design of Heat Exchangers Subject to Fouling .......... 250 6.5.1 Fouling Resistance ............................. 250 6.5.2 Cleanliness Factor ............................. 256 6.5.3 Percent over Surface ........................... 257 6.6 Operations of Heat Exchangers Subject to Fouling ...... 262 6.7 Techniques to Control Fouling ......................... 264 6.7.1 Surface Cleaning Techniques .................... 264 6.7.2 Additives ...................................... 265 Nomenclature ............................................... 266 References ................................................. 270 7 Double-Pipe Heat Exchangers ................................ 273 7.1 Introduction .......................................... 273 7.2 Thermal and Hydraulic Design of Inner Tube ............ 276 7.3 Thermal and Hydraulic Analysis of Annulus ............. 278 7.3.1 Hairpin Heat Exchanger with Bare Inner Tube .... 278 7.3.2 Hairpin Heat Exchangers with Multitube Finned Inner Tubes .................................... 283 7.4 Parallel-Series Arrangements of Hairpins .............. 291 7.5 Total Pressure Drop ................................... 294 7.6 Design and Operational Features ....................... 295 Nomenclature ............................................... 297 References ................................................. 304 8 Design Correlations for Condensers and Evaporators ......... 307 8.1 Introduction .......................................... 307 8.2 Condensation .......................................... 307 8.3 Film Condensation on a Single Horizontal Tube ......... 308 8.3.1 Laminar Film Condensation ...................... 308 8.3.2 Forced Convection .............................. 309 8.4 Film Condensation in Tube Bundles ..................... 312 8.4.1 Effect of Condensate Inundation ................ 313 8.4.2 Effect of Vapor Shear .......................... 317 8.4.3 Combined Effects of Inundation and Vapor Shear .......................................... 317 8.5 Condensation inside Tubes ............................. 322 8.5.1 Condensation inside Horizontal Tubes ........... 322 8.5.2 Condensation inside Vertical Tubes ............. 327 8.6 Flow Boiling .......................................... 329 8.6.1 Subcooled Boiling .............................. 329 8.6.2 Flow Pattern ................................... 331 8.6.3 Flow Boiling Correlations ...................... 334 Nomenclature ............................................... 353 References ................................................. 356 9 Shell-and-Tube Heat Exchangers ............................. 361 9.1 Introduction .......................................... 361 9.2 Basic Components ...................................... 361 9.2.1 Shell Types .................................... 361 9.2.2 Tube Bundle Types .............................. 364 9.2.3 Tubes and Tube Passes .......................... 366 9.2.4 Tube Layout .................................... 368 9.2.5 Baffle Type and Geometry ....................... 371 9.2.6 Allocation of Streams .......................... 376 9.3 Basic Design Procedure of a Heat Exchanger ............ 378 9.3.1 Preliminary Estimation of Unit Size ............ 380 9.3.2 Rating of the Preliminary Design ............... 386 9.4 Shell-Side Heat Transfer and Pressure Drop ............ 387 9.4.1 Shell-Side Heat Transfer Coefficient ........... 387 9.4.2 Shell-Side Pressure Drop ....................... 389 9.4.3 Tube-Side Pressure Drop ........................ 390 9.4.4 Bell-Delaware Method ........................... 395 Nomenclature ............................................... 419 References ................................................. 425 10 Compact Heat Exchangers .................................... 427 10.1 Introduction .......................................... 427 10.1.1 Heat Transfer Enhancement ...................... 427 10.1.2 Plate-Fin Heat Exchangers ...................... 431 10.1.3 Tube-Fin Heat Exchangers ....................... 431 10.2 Heat Transfer and Pressure Drop ....................... 433 10.2.1 Heat Transfer .................................. 433 10.2.2 Pressure Drop for Finned-Tube Exchangers ....... 441 10.2.3 Pressure Drop for Plate-Fin Exchangers ......... 441 Nomenclature ............................................... 446 References ................................................. 449 11 Gasketed-Plate Heat Exchangers ............................. 451 11.1 Introduction .......................................... 451 11.2 Mechanical Features ................................... 451 11.2.1 Plate Pack and the Frame ....................... 453 11.2.2 Plate Types .................................... 455 11.3 Operational Characteristics ........................... 457 11.3.1 Main Advantages ................................ 457 11.3.2 Performance Limits ............................. 459 11.4 Passes and Flow Arrangements .......................... 460 11.5 Applications .......................................... 461 11.5.1 Corrosion ...................................... 462 11.5.2 Maintenance .................................... 465 11.6 Heat Transfer and Pressure Drop Calculations .......... 466 11.6.1 Heat Transfer Area ............................. 466 11.6.2 Mean Flow Channel Gap .......................... 467 11.6.3 Channel Hydraulic Diameter ..................... 468 11.6.4 Heat Transfer Coefficient ...................... 468 11.6.5 Channel Pressure Drop .......................... 474 11.6.6 Port Pressure Drop ............................. 474 11.6.7 Overall Heat Transfer Coefficient .............. 475 11.6.8 Heat Transfer Surface Area ..................... 475 11.6.9 Performance Analysis ........................... 476 11.7 Thermal Performance ................................... 481 Nomenclature ............................................... 484 References ................................................. 488 12 Condensers and Evaporators ................................. 491 12.1 Introduction .......................................... 491 12.2 Shell and Tube Condensers ............................. 492 12.2.1 Horizontal Shell-Side Condensers ............... 492 12.2.2 Vertical Shell-Side Condensers ................. 495 12.2.3 Vertical Tube-Side Condensers .................. 495 12.2.4 Horizontal in-Tube Condensers .................. 497 12.3 Steam Turbine Exhaust Condensers ...................... 500 12.4 Plate Condensers ...................................... 501 12.5 Air-Cooled Condensers ................................. 502 12.6 Direct Contact Condensers ............................. 503 12.7 Thermal Design of Shell-and-Tube Condensers ........... 504 12.8 Design and Operational Considerations ................. 515 12.9 Condensers for Refrigeration and Air-Conditioning ..... 516 12.9.1 Water-Cooled Condensers ........................ 518 12.9.2 Air-Cooled Condensers .......................... 519 12.9.3 Evaporative Condensers ......................... 519 12.10 Evaporators for Refrigeration and Air-Conditioning ... 522 12.10.1 Water-Cooling Evaporators (Chillers) .......... 522 12.10.2 Air-Cooling Evaporators (Air Coolers) ......... 523 12.11 Thermal Analysis ..................................... 525 12.11.1 Shah Correlation .............................. 526 12.11.2 Kandlikar Correlation ......................... 528 12.11.3 Güngör and Winterton Correlation .............. 529 12.12 Standards for Evaporators and Condensers ............. 531 Nomenclature ............................................... 536 References ................................................. 540 13 Polymer Heat Exchangers .................................... 543 13.1 Introduction .......................................... 543 13.2 Polymer Matrix Composite Materials (PMC) .............. 547 13.3 Nanocomposites ........................................ 551 13.4 Application of Polymers in Heat Exchangers ............ 552 13.5 Polymer Compact Heat Exchangers ....................... 563 13.6 Potential Applications for Polymer Film Compact Heat Exchangers ............................................ 567 13.7 Thermal Design of Polymer Heat Exchangers ............. 570 References ................................................. 573 Appendix A .................................................... 577 Appendix В .................................................... 583 Index ......................................................... 607