Fundamentals of heat and mass transfer:
Gespeichert in:
| Format: | Buch |
|---|---|
| Sprache: | English |
| Veröffentlicht: |
Hoboken, NJ
Wiley
2007
|
| Ausgabe: | 6. ed. |
| Schlagworte: | |
| Online-Zugang: | Inhaltsverzeichnis |
| Beschreibung: | Ab 7. ed. u.d.T.: Principles of heat and mass transfer. |
| Beschreibung: | XXV, 997 S. Ill., graph. Darst. |
| ISBN: | 0471457280 9780471457282 |
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Datensatz im Suchindex
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| adam_text | SIXTH EDITION FUNDAMENTALS OF HEAT AND MASS TRANSFER FRANK P. INCROPERA
COLLEGE OF ENGINEERING UNIVERSITY OF NOTRE DAME DAVID P. DEWITT SCHOOL
OF MECHANICAL ENGINEERING PURDUE UNIVERSITY THEODORE L. BERGMAN
DEPARTMENT OF MECHANICAL ENGINEERING UNIVERSITY OF CONNECTICUT ADRIENNE
S. LAVINE MECHANICAL AND AEROSPACE ENGINEERING DEPARTMENT UNIVERSITY OF
CALIFORNIA, LOS ANGELES JOHN WIUA CONTENTS CHAPTER 1 INTRODUCTION
SYMBOLS XXUI 1.1 1.2 1.3 1.4 WHAT AND HOW? PHYSICAL ORIGINS AND RATE
EQUATIONS 1.2.1 CONDUCTION 3 1.2.2 CONVECTION 6 1.2.3 RADIATION 9 1.2.4
RELATIONSHIP TO THERMODYNAMICS 12 THE CONSERVATION OF ENERGY REQUIREMENT
1.3.1 CONSERVATION OF ENERGY FOR A CONTROL VOLUME 1.3.2 THE SURFACE
ENERGY BALANCE 25 1.3.3 APPLICATION OF THE CONSERVATION LAWS:
METHODOLOGY 28 ANALYSIS OF HEAT TRANSFER PROBLEMS: METHODOLOGY 13 13 29
XIV CONTENTS 1.5 RELEVANCE OF HEAT TRANSFER 1.6 UNITS AND DIMENSIONS 1.7
SUMMARY REFERENCES PROBLEMS 32 35 38 41 41 CHAPTER 2 INTRODUCTION TO
CONDUCTION 2.1 THE CONDUCTION RATE EQUATION 2.2 THE THERMAL PROPERTIES
OF MATTER 2.2.1 THERMAL CONDUCTIVITY 60 2.2.2 OTHER RELEVANT PROPERTIES
67 2.3 THE HEAT DIFFUSION EQUATION 2.4 BOUNDARY AND INITIAL CONDITIONS
2.5 SUMMARY REFERENCES PROBLEMS 57 58 60 70 77 81 82 82 CHAPTER 3
ONE-DIMENSIONAL, STEADY-STATE CONDUCTION 3.1 THE PLANE WALL 3.1.1
TEMPERATURE DISTRIBUTION 96 3.1.2 THERMAL RESISTANCE 98 3.1.3 THE
COMPOSITE WALL 99 3.1.4 CONTACT RESISTANCE 101 3.2 AN ALTERNATIVE
CONDUCTION ANALYSIS 3.3 RADIAL SYSTEMS 3.3.1 THE CYLINDER 116 3.3.2 THE
SPHERE 122 3.4 SUMMARY OF ONE-DIMENSIONAL CONDUCTION RESULTS 3.5
CONDUCTION WITH THERMAL ENERGY GENERATION 3.5.1 THE PLANE WALL 127 3.5.2
RADIAL SYSTEMS 132 3.5.3 APPLICATION OF RESISTANCE CONCEPTS 137 3.6 HEAT
TRANSFER FROM EXTENDED SURFACES 3.6.1 A GENERAL CONDUCTION ANALYSIS 139
3.6.2 FINS OF UNIFORM CROSS-SECTIONAL AREA 141 3.6.3 FIN PERFORMANCE 147
3.6.4 FINS OF NONUNIFORM CROSS-SECTIONAL AREA 150 3.6.5 OVERALL SURFACE
EFFICIENCY 153 3.7 THE BIOHEAT EQUATION 3.8 SUMMARY REFERENCES PROBLEMS
95 96 112 116 125 126 137 162 166 168 169 CONTENTS XV FER ^-DIMENSIONAL,
STEADY-STATE CONDUCTION 201 4.1 4.2 4.3 4.4 4.5 4.6 ALTERNATIVE
APPROACHES THE METHOD OF SEPARATION OF VARIABLES THE CONDUCTION SHAPE
FACTOR AND THE DIMENSIONLESS CONDUCTION HEAT RATE FINITE-DIFFERENCE
EQUATIONS 4.4.1 THE NODAL NETWORK 213 4.4.2 FINITE-DIFFERENCE FORM OF
THE HEAT EQUATION 214 4.4.3 THE ENERGY BALANCE METHOD 215 SOLVING THE
FINITE-DIFFERENCE EQUATIONS 4.5.1 THE MATRIX INVERSION METHOD 222 4.5.2
GAUSS-SEIDEL ITERATION 223 4.5.3 SOME PRECAUTIONS 229 SUMMARY REFERENCES
PROBLEMS 4S.1 THE GRAPHICAL METHOD 45.1.1 METHODOLOGY OF CONSTRUCTING A
FLUX PLOT W-L 45.1.2 DETERMINATION OF THE HEAT TRANSFER RATE W-2 45.1.3
THE CONDUCTION SHAPE FACTOR W-3 REFERENCES PROBLEMS 202 203 207 212 222
234 235 235 W-L W-6 W-6 PER ^TRANSIENT CONDUCTION 5.1 THE LUMPED
CAPACITANCE METHOD 5.2 VALIDITY OF THE LUMPED CAPACITANCE METHOD 5.3
GENERAL LUMPED CAPACITANCE ANALYSIS 5.4 SPATIAL EFFECTS 5.5 THE PLANE
WALL WITH CONVECTION 5.5.1 EXACT SOLUTION 272 5.5.2 APPROXIMATE SOLUTION
273 5.5.3 TOTAL ENERGY TRANSFER 274 5.5.4 ADDITIONAL CONSIDERATIONS 275
5.6 RADIAL SYSTEMS WITH CONVECTION 5.6.1 EXACT SOLUTIONS 276 5.6.2
APPROXIMATE SOLUTIONS 277 5.6.3 TOTAL ENERGY TRANSFER 277 5.6.4
ADDITIONAL CONSIDERATIONS 278 5.7 THE SEMI-INFINITE SOLID 5.8 OBJECTS
WITH CONSTANT SURFACE TEMPERATURES OR SURFACE HEAT FLUXES 5.8.1 CONSTANT
TEMPERATURE BOUNDARY CONDITIONS 290 5.8.2 CONSTANT HEAT FLUX BOUNDARY
CONDITIONS 292 5.8.3 APPROXIMATE SOLUTIONS 293 5.9 PERIODIC HEATING 255
256 259 263 270 272 276 283 290 299 XVI CONTENTS 5.10 FINITE-DIFFERENCE
METHODS 5.10.1 DISCRETIZATION OF THE HEAT EQUATION: THE EXPLICIT METHOD
5.10.2 DISCRETIZATION OF THE HEAT EQUATION: THE IMPLICIT METHOD 5.11
SUMMARY REFERENCES PROBLEMS 55.1 GRAPHICAL REPRESENTATION OF
ONE-DIMENSIONAL, TRANSIENT CONDUCTION IN THE PLANE WALL, LONG CYLINDER,
AND SPHERE 55.2 ANALYTICAL SOLUTION OF MULTIDIMENSIONAL EFFECTS
REFERENCES PROBLEMS 302 310 CHAPTER 6 INTRODUCTION TO CONVECTION 302 317
319 319 W-8 W-13 W-18 W-18 347 6.1 THE CONVECTION BOUNDARY LAYERS 6.1.1
THE VELOCITY BOUNDARY LAYER 348 6.1.2 THE THERMAL BOUNDARY LAYER 349
6.1.3 THE CONCENTRATION BOUNDARY LAYER 350 6.1.4 SIGNIFICANCE OF THE
BOUNDARY LAYERS 352 6.2 LOCAL AND AVERAGE CONVECTION COEFFICIENTS 6.2.1
HEAT TRANSFER 352 6.2.2 MASS TRANSFER 353 6.2.3 THE PROBLEM OF
CONVECTION 355 6.3 LAMINAR AND TURBULENT FLOW 6.3.1 LAMINAR AND
TURBULENT VELOCITY BOUNDARY LAYERS 359 6.3.2 LAMINAR AND TURBULENT
THERMAL AND SPECIES CONCENTRATION BOUNDARY LAYERS 361 6.4 THE BOUNDARY
LAYER EQUATIONS 6.4.1 BOUNDARY LAYER EQUATIONS FOR LAMINAR FLOW 365 6.5
BOUNDARY LAYER SIMILARITY: THE NORMALIZED BOUNDARY LAYER EQUATIONS 6.5.1
BOUNDARY LAYER SIMILARITY PARAMETERS 368 6.5.2 FUNCTIONAL FORM OF THE
SOLUTIONS 368 6.6 PHYSICAL SIGNIFICANCE OF THE DIMENSIONLESS PARAMETERS
6.7 BOUNDARY LAYER ANALOGIES 6.7.1 THE HEAT AND MASS TRANSFER ANALOGY
377 6.7.2 EVAPORATIVE COOLING 381 6.7.3 THE REYNOLDS ANALOGY 384 6.8 THE
CONVECTION COEFFICIENTS 6.9 SUMMARY REFERENCES PROBLEMS . 6S.1
DERIVATION OF THE CONVECTION TRANSFER EQUATIONS 6S.1.1 CONSERVATION OF
MASS W-21 6S. 1.2 NEWTON S SECOND LAW OF MOTION W-22 6S. 1.3
CONSERVATION OF ENERGY W-26 6S. 1.4 CONSERVATION OF SPECIES W-28
REFERENCES PROBLEMS 348 352 359 364 367 374 377 385 385 386 387 W-21
W-33 W-33 CONTENTS XVLL TER T IXTERNAL FLOW 401 7.1 THE EMPIRICAL METHOD
7.2 THE FLAT PLATE IN PARALLEL FLOW 7.2.1 LAMINAR FLOW OVER AN
ISOTHERMAL PLATE: A SIMILARITY SOLUTION 7.2.2 TURBULENT FLOW OVER AN
ISOTHERMAL PLATE 410 7.2.3 MIXED BOUNDARY LAYER CONDITIONS 411 12.A
UNHEATED STARTING LENGTH 412 7.2.5 FLAT PLATES WITH CONSTANT HEAT FLUX
CONDITIONS 413 7.2.6 LIMITATIONS ON USE OF CONVECTION COEFFICIENTS 414
7.3 METHODOLOGY FOR A CONVECTION CALCULATION 7.4 THE CYLINDER IN CROSS
FLOW 7.4.1 FLOW CONSIDERATIONS 423 7.4.2 CONVECTION HEAT AND MASS
TRANSFER 425 7.5 THE SPHERE 7.6 FLOW ACROSS BANKS OF TUBES 7.7 IMPINGING
JETS 7.7.1 HYDRODYNAMIC AND GEOMETRIC CONSIDERATIONS 447 7.7.2
CONVECTION HEAT AND MASS TRANSFER 449 7.8 PACKED BEDS 7.9 SUMMARY
REFERENCES PROBLEMS 405 403 405 414 423 433 436 447 452 454 456 457
TPTER 8 INTERNAL FLOW 485 8.1 HYDRODYNAMIC CONSIDERATIONS 486 8.1.1 FLOW
CONDITIONS 486 8.1.2 THE MEAN VELOCITY 487 8.1.3 VELOCITY PROFILE IN THE
FULLY DEVELOPED REGION 488 8.1.4 PRESSURE GRADIENT AND FRICTION FACTOR
IN FULLY DEVELOPED FLOW 490 8.2 THERMAL CONSIDERATIONS 491 8.2.1 THE
MEAN TEMPERATURE 492 8.2.2 NEWTON S LAW OF COOLING 493 8.2.3 FULLY
DEVELOPED CONDITIONS 493 8.3 THE ENERGY BALANCE 497 8.3.1 GENERAL
CONSIDERATIONS 497 8.3.2 CONSTANT SURFACE HEAT FLUX 498 8.3.3 CONSTANT
SURFACE TEMPERATURE 501 8.4 LAMINAR FLOW IN CIRCULAR TUBES: THERMAL
ANALYSIS AND CONVECTION CORRELATIONS 505 8.4.1 THE FULLY DEVELOPED
REGION 505 8.4.2 THE ENTRY REGION 512 8.5 CONVECTION CORRELATIONS:
TURBULENT FLOW IN CIRCULAR TUBES 514 8.6 CONVECTION CORRELATIONS:
NONCIRCULAR TUBES AND THE CONCENTRIC TUBE ANNULUS 518 8.7 HEAT TRANSFER
ENHANCEMENT 521 XVIN CONTENTS 8.8 MICROSCALE INTERNAL FLOW 8.8.1 FLOW
CONDITIONS IN MICROSCALE INTERNAL FLOW 524 8.8.2 THERMAL CONSIDERATIONS
IN MICROSCALE INTERNAL FLOW 8.9 CONVECTION MASS TRANSFER 8.10 SUMMARY
REFERENCES PROBLEMS 525 524 528 531 533 534 CHAPTER 9 FREE CONVECTION
559 9.1 PHYSICAL CONSIDERATIONS 9.2 THE GOVERNING EQUATIONS 9.3
SIMILARITY CONSIDERATIONS 9.4 LAMINAR FREE CONVECTION ON A VERTICAL
SURFACE 9.5 THE EFFECTS OF TURBULENCE 9.6 EMPIRICAL CORRELATIONS:
EXTERNAL FREE CONVECTION FLOWS 9.6.1 THE VERTICAL PLATE 571 9.6.2
INCLINED AND HORIZONTAL PLATES 574 9.6.3 THE LONG HORIZONTAL CYLINDER
579 9.6.4 SPHERES 583 9.7 FREE CONVECTION WITHIN PARALLEL PLATE CHANNELS
9.7.1 VERTICAL CHANNELS 585 9.7.2 INCLINED CHANNELS 587 9.8 EMPIRICAL
CORRELATIONS: ENCLOSURES 9.8.1 RECTANGULAR CAVITIES 587 9.8.2 CONCENTRIC
CYLINDERS 590 9.8.3 CONCENTRIC SPHERES 591 9.9 COMBINED FREE AND FORCED
CONVECTION 9.10 CONVECTION MASS TRANSFER 9.11 SUMMARY REFERENCES
PROBLEMS 560 563 564 566 568 571 584 587 593 594 595 596 597 CHAPTER 1
0 BOILING AND CONDENSATION 619 10.1 DIMENSIONLESS PARAMETERS IN BOILING
AND CONDENSATION 10.2 BOILING MODES 10.3 POOL BOILING 10.3.1 THE BOILING
CURVE 622 10.3.2 MODES OF POOL BOILING 624 10.4 POOL BOILING
CORRELATIONS 10.4.1 NUCLEATE POOL BOILING 627 10.4.2 CRITICAL HEAT FLUX
FOR NUCLEATE POOL BOILING 629 10.4.3 MINIMUM HEAT FLUX 629 10.4.4 FILM
POOL BOILING 630 10.4.5 PARAMETRIC EFFECTS ON POOL BOILING 631 620 621
622 627 CONTENTS XIX 10.5 10.6 10.7 10.8 10.9 10.10 10.11 10.12 FORCED
CONVECTION BOILING 10.5.1 EXTERNAL FORCED CONVECTION BOILING 637 10.5.2
TWO-PHASE FLOW 637 10.5.3 TWO-PHASE FLOW IN MICROCHANNELS 640
CONDENSATION: PHYSICAL MECHANISMS LAMINAR FILM CONDENSATION ON A
VERTICAL PLATE TURBULENT FILM CONDENSATION FILM CONDENSATION ON RADIAL
SYSTEMS FILM CONDENSATION IN HORIZONTAL TUBES DROPWISE CONDENSATION
SUMMARY REFERENCES PROBLEMS PER 1 1 EAT EXCHANGERS 11.1 11.2 11.3 11.4
11.5 11.6 11.7 HEAT EXCHANGER TYPES THE OVERALL HEAT TRANSFER
COEFFICIENT HEAT EXCHANGER ANALYSIS: USE OF THE LOG MEAN TEMPERATURE
DIFFERENCE 11.3.1 THE PARALLEL-FLOW HEAT EXCHANGER 676 11.3.2 THE
COUNTERFLOW HEAT EXCHANGER 679 11.3.3 SPECIAL OPERATING CONDITIONS 679
HEAT EXCHANGER ANALYSIS: THE EFFECTIVENESS-NTU METHOD 11.4.1 DEFINITIONS
686 11.4.2 EFFECTIVENESS-NTU RELATIONS 688 HEAT EXCHANGER DESIGN AND
PERFORMANCE CALCULATIONS: USING THE EFFECTIVENESS-NTU METHOD COMPACT
HEAT EXCHANGERS SUMMARY REFERENCES PROBLEMS 11S.1 LOG MEAN TEMPERATURE
DIFFERENCE METHOD FOR MULTIPASS AND CROSS-FLOW HEAT EXCHANGERS
REFERENCES PROBLEMS CHAPTER 1 2 RADIATION: PROCESSES AND PROPERTIES 12.1
12.2 12.3 FUNDAMENTAL CONCEPTS RADIATION INTENSITY 12.2.1 MATHEMATICAL
DEFINITIONS 727 12.2.2 RADIATION INTENSITY AND ITS RELATION TO EMISSION
12.2.3 RELATION TO IRRADIATION 733 12.2.4 RELATION TO RADIOSITY 735
BLACKBODY RADIATION 12.3.1 THE PLANCK DISTRIBUTION 737 12.3.2 WIEN S
DISPLACEMENT LAW 737 728 636 641 643 646 651 654 655 655 656 657 669 670
673 675 686 694 700 705 706 707 W-37 W-41 W-41 723 724 727 736 XX
CONTENTS 12.3.3 THE STEFAN-BOLTZMANN LAW 738 12.3.4 BAND EMISSION 739
12.4 EMISSION FROM REAL SURFACES 12.5 ABSORPTION, REFLECTION, AND
TRANSMISSION BY REAL SURFACES 12.5.1 ABSORPTIVITY 754 12.5.2
REFLECTIVITY 755 12.5.3 TRANSMISSIVITY 756 12.5.4 SPECIAL CONSIDERATIONS
757 12.6 KIRCHHOFFSLAW 12.7 THE GRAY SURFACE 12.8 ENVIRONMENTAL
RADIATION 12.9 SUMMARY REFERENCES PROBLEMS 744 752 762 764 770 776 780
780 CHAPTER 1 3 RADIATION EXCHANGE BETWEEN SURFACES 811 13.1 THE VIEW
FACTOR 812 13.1.1 THE VIEW FACTOR INTEGRAL 812 13.1.2 VIEW FACTOR
RELATIONS 813 13.2 RADIATION EXCHANGE BETWEEN OPAQUE, DIFFUSE, GRAY
SURFACES IN AN ENCLOSURE 822 13.2.1 NET RADIATION EXCHANGE AT A SURFACE
823 13.2.2 RADIATION EXCHANGE BETWEEN SURFACES 824 13.2.3 BLACKBODY
RADIATION EXCHANGE 830 13.2.4 THE TWO-SURFACE ENCLOSURE 831 13.2.5
RADIATION SHIELDS 832 13.2.6 THE RERADIATING SURFACE 835 13.3 MULTIMODE
HEAT TRANSFER 839 13.4 RADIATION EXCHANGE WITH PARTICIPATING MEDIA 842
13.4.1 VOLUMETRIC ABSORPTION 843 13.4.2 GASEOUS EMISSION AND ABSORPTION
843 13.5 SUMMARY 847 REFERENCES 849 PROBLEMS 849 CHAPTER 1 4 DIFFUSION
MASS TRANSFER 879 14.1 PHYSICAL ORIGINS AND RATE EQUATIONS 14.1.1
PHYSICAL ORIGINS 880 14.1.2 MIXTURE COMPOSITION 881 14.1.3 FICK S LAW OF
DIFFUSION 882 14.1.4 MASS DIFFUSIVITY 883 14.2 MASS TRANSFER IN
NONSTATIONARY MEDIA 14.2.1 ABSOLUTE AND DIFFUSIVE SPECIES FLUXES 14.2.2
EVAPORATION IN A COLUMN 888 14.3 THE STATIONARY MEDIUM APPROXIMATION 880
885 885 893 CONTENTS XXI 894 14.4 CONSERVATION OF SPECIES FOR A
STATIONARY MEDIUM 14.4.1 CONSERVATION OF SPECIES FOR A CONTROL VOLUME
14.4.2 THE MASS DIFFUSION EQUATION 894 14.4.3 STATIONARY MEDIA WITH
SPECIFIED SURFACE CONCENTRATIONS 897 14.5 BOUNDARY CONDITIONS AND
DISCONTINUOUS CONCENTRATIONS AT INTERFACES 14.5.1 EVAPORATION AND
SUBLIMATION 901 14.5.2 SOLUBILITY OF GASES IN LIQUIDS AND SOLIDS 902
14.5.3 CATALYTIC SURFACE REACTIONS 905 14.6 MASS DIFFUSION WITH
HOMOGENEOUS CHEMICAL REACTIONS 14.7 TRANSIENT DIFFUSION 14.8 SUMMARY
REFERENCES PROBLEMS APPENDIX A THERMOPHYSICAL PROPERTIES OF MATTER 894
900 908 911 916 917 917 927 APPENDIX B MATHEMATICAL RELATIONS AND
FUNCTIONS 959 APPENDIX C THERMAL CONDITIONS ASSOCIATED WITH UNIFORM
ENERGY GENERATION IN ONE-DIMENSIONAL, STEADY-STATE SYSTEMS 965 APPENDIX
D THE CONVECTION TRANSFER EQUATIONS 973 D.I CONSERVATION OF MASS D.2
NEWTON S SECOND LAW OF MOTION D.3 CONSERVATION OF ENERGY D.4
CONSERVATION OF SPECIES APPENDIX E BOUNDARY LAYER EQUATIONS FOR
TURBULENT FLOW 974 974 975 976 977 APPENDIX F AN INTEGRAL LAMINAR
BOUNDARY LAYER SOLUTION FOR PARALLEL FLOW OVER A FLAT PLATE 981 INDEX
985
|
| adam_txt |
SIXTH EDITION FUNDAMENTALS OF HEAT AND MASS TRANSFER FRANK P. INCROPERA
COLLEGE OF ENGINEERING UNIVERSITY OF NOTRE DAME DAVID P. DEWITT SCHOOL
OF MECHANICAL ENGINEERING PURDUE UNIVERSITY THEODORE L. BERGMAN
DEPARTMENT OF MECHANICAL ENGINEERING UNIVERSITY OF CONNECTICUT ADRIENNE
S. LAVINE MECHANICAL AND AEROSPACE ENGINEERING DEPARTMENT UNIVERSITY OF
CALIFORNIA, LOS ANGELES JOHN WIUA CONTENTS CHAPTER 1 INTRODUCTION
SYMBOLS XXUI 1.1 1.2 1.3 1.4 WHAT AND HOW? PHYSICAL ORIGINS AND RATE
EQUATIONS 1.2.1 CONDUCTION 3 1.2.2 CONVECTION 6 1.2.3 RADIATION 9 1.2.4
RELATIONSHIP TO THERMODYNAMICS 12 THE CONSERVATION OF ENERGY REQUIREMENT
1.3.1 CONSERVATION OF ENERGY FOR A CONTROL VOLUME 1.3.2 THE SURFACE
ENERGY BALANCE 25 1.3.3 APPLICATION OF THE CONSERVATION LAWS:
METHODOLOGY 28 ANALYSIS OF HEAT TRANSFER PROBLEMS: METHODOLOGY 13 13 29
XIV CONTENTS 1.5 RELEVANCE OF HEAT TRANSFER 1.6 UNITS AND DIMENSIONS 1.7
SUMMARY REFERENCES PROBLEMS 32 35 38 41 41 CHAPTER 2 INTRODUCTION TO
CONDUCTION 2.1 THE CONDUCTION RATE EQUATION 2.2 THE THERMAL PROPERTIES
OF MATTER 2.2.1 THERMAL CONDUCTIVITY 60 2.2.2 OTHER RELEVANT PROPERTIES
67 2.3 THE HEAT DIFFUSION EQUATION 2.4 BOUNDARY AND INITIAL CONDITIONS
2.5 SUMMARY REFERENCES PROBLEMS 57 58 60 70 77 81 82 82 CHAPTER 3
ONE-DIMENSIONAL, STEADY-STATE CONDUCTION 3.1 THE PLANE WALL 3.1.1
TEMPERATURE DISTRIBUTION 96 3.1.2 THERMAL RESISTANCE 98 3.1.3 THE
COMPOSITE WALL 99 3.1.4 CONTACT RESISTANCE 101 3.2 AN ALTERNATIVE
CONDUCTION ANALYSIS 3.3 RADIAL SYSTEMS 3.3.1 THE CYLINDER 116 3.3.2 THE
SPHERE 122 3.4 SUMMARY OF ONE-DIMENSIONAL CONDUCTION RESULTS 3.5
CONDUCTION WITH THERMAL ENERGY GENERATION 3.5.1 THE PLANE WALL 127 3.5.2
RADIAL SYSTEMS 132 3.5.3 APPLICATION OF RESISTANCE CONCEPTS 137 3.6 HEAT
TRANSFER FROM EXTENDED SURFACES 3.6.1 A GENERAL CONDUCTION ANALYSIS 139
3.6.2 FINS OF UNIFORM CROSS-SECTIONAL AREA 141 3.6.3 FIN PERFORMANCE 147
3.6.4 FINS OF NONUNIFORM CROSS-SECTIONAL AREA 150 3.6.5 OVERALL SURFACE
EFFICIENCY 153 3.7 THE BIOHEAT EQUATION 3.8 SUMMARY REFERENCES PROBLEMS
95 96 112 116 125 126 137 162 166 168 169 CONTENTS XV FER ^-DIMENSIONAL,
STEADY-STATE CONDUCTION 201 4.1 4.2 4.3 4.4 4.5 4.6 ALTERNATIVE
APPROACHES THE METHOD OF SEPARATION OF VARIABLES THE CONDUCTION SHAPE
FACTOR AND THE DIMENSIONLESS CONDUCTION HEAT RATE FINITE-DIFFERENCE
EQUATIONS 4.4.1 THE NODAL NETWORK 213 4.4.2 FINITE-DIFFERENCE FORM OF
THE HEAT EQUATION 214 4.4.3 THE ENERGY BALANCE METHOD 215 SOLVING THE
FINITE-DIFFERENCE EQUATIONS 4.5.1 THE MATRIX INVERSION METHOD 222 4.5.2
GAUSS-SEIDEL ITERATION 223 4.5.3 SOME PRECAUTIONS 229 SUMMARY REFERENCES
PROBLEMS 4S.1 THE GRAPHICAL METHOD 45.1.1 METHODOLOGY OF CONSTRUCTING A
FLUX PLOT W-L 45.1.2 DETERMINATION OF THE HEAT TRANSFER RATE W-2 45.1.3
THE CONDUCTION SHAPE FACTOR W-3 REFERENCES PROBLEMS 202 203 207 212 222
234 235 235 W-L W-6 W-6 PER ^TRANSIENT CONDUCTION 5.1 THE LUMPED
CAPACITANCE METHOD 5.2 VALIDITY OF THE LUMPED CAPACITANCE METHOD 5.3
GENERAL LUMPED CAPACITANCE ANALYSIS 5.4 SPATIAL EFFECTS 5.5 THE PLANE
WALL WITH CONVECTION 5.5.1 EXACT SOLUTION 272 5.5.2 APPROXIMATE SOLUTION
273 5.5.3 TOTAL ENERGY TRANSFER 274 5.5.4 ADDITIONAL CONSIDERATIONS 275
5.6 RADIAL SYSTEMS WITH CONVECTION 5.6.1 EXACT SOLUTIONS 276 5.6.2
APPROXIMATE SOLUTIONS 277 5.6.3 TOTAL ENERGY TRANSFER 277 5.6.4
ADDITIONAL CONSIDERATIONS 278 5.7 THE SEMI-INFINITE SOLID 5.8 OBJECTS
WITH CONSTANT SURFACE TEMPERATURES OR SURFACE HEAT FLUXES 5.8.1 CONSTANT
TEMPERATURE BOUNDARY CONDITIONS 290 5.8.2 CONSTANT HEAT FLUX BOUNDARY
CONDITIONS 292 5.8.3 APPROXIMATE SOLUTIONS 293 5.9 PERIODIC HEATING 255
256 259 263 270 272 276 283 290 299 XVI CONTENTS 5.10 FINITE-DIFFERENCE
METHODS 5.10.1 DISCRETIZATION OF THE HEAT EQUATION: THE EXPLICIT METHOD
5.10.2 DISCRETIZATION OF THE HEAT EQUATION: THE IMPLICIT METHOD 5.11
SUMMARY REFERENCES PROBLEMS 55.1 GRAPHICAL REPRESENTATION OF
ONE-DIMENSIONAL, TRANSIENT CONDUCTION IN THE PLANE WALL, LONG CYLINDER,
AND SPHERE 55.2 ANALYTICAL SOLUTION OF MULTIDIMENSIONAL EFFECTS
REFERENCES PROBLEMS 302 310 CHAPTER 6 INTRODUCTION TO CONVECTION 302 317
319 319 W-8 W-13 W-18 W-18 347 6.1 THE CONVECTION BOUNDARY LAYERS 6.1.1
THE VELOCITY BOUNDARY LAYER 348 6.1.2 THE THERMAL BOUNDARY LAYER 349
6.1.3 THE CONCENTRATION BOUNDARY LAYER 350 6.1.4 SIGNIFICANCE OF THE
BOUNDARY LAYERS 352 6.2 LOCAL AND AVERAGE CONVECTION COEFFICIENTS 6.2.1
HEAT TRANSFER 352 6.2.2 MASS TRANSFER 353 6.2.3 THE PROBLEM OF
CONVECTION 355 6.3 LAMINAR AND TURBULENT FLOW 6.3.1 LAMINAR AND
TURBULENT VELOCITY BOUNDARY LAYERS 359 6.3.2 LAMINAR AND TURBULENT
THERMAL AND SPECIES CONCENTRATION BOUNDARY LAYERS 361 6.4 THE BOUNDARY
LAYER EQUATIONS 6.4.1 BOUNDARY LAYER EQUATIONS FOR LAMINAR FLOW 365 6.5
BOUNDARY LAYER SIMILARITY: THE NORMALIZED BOUNDARY LAYER EQUATIONS 6.5.1
BOUNDARY LAYER SIMILARITY PARAMETERS 368 6.5.2 FUNCTIONAL FORM OF THE
SOLUTIONS 368 6.6 PHYSICAL SIGNIFICANCE OF THE DIMENSIONLESS PARAMETERS
6.7 BOUNDARY LAYER ANALOGIES 6.7.1 THE HEAT AND MASS TRANSFER ANALOGY
377 6.7.2 EVAPORATIVE COOLING 381 6.7.3 THE REYNOLDS ANALOGY 384 6.8 THE
CONVECTION COEFFICIENTS 6.9 SUMMARY REFERENCES PROBLEMS . 6S.1
DERIVATION OF THE CONVECTION TRANSFER EQUATIONS 6S.1.1 CONSERVATION OF
MASS W-21 6S. 1.2 NEWTON'S SECOND LAW OF MOTION W-22 6S. 1.3
CONSERVATION OF ENERGY W-26 6S. 1.4 CONSERVATION OF SPECIES W-28
REFERENCES PROBLEMS 348 352 359 364 367 374 377 385 385 386 387 W-21
W-33 W-33 CONTENTS XVLL TER T IXTERNAL FLOW 401 7.1 THE EMPIRICAL METHOD
7.2 THE FLAT PLATE IN PARALLEL FLOW 7.2.1 LAMINAR FLOW OVER AN
ISOTHERMAL PLATE: A SIMILARITY SOLUTION 7.2.2 TURBULENT FLOW OVER AN
ISOTHERMAL PLATE 410 7.2.3 MIXED BOUNDARY LAYER CONDITIONS 411 12.A
UNHEATED STARTING LENGTH 412 7.2.5 FLAT PLATES WITH CONSTANT HEAT FLUX
CONDITIONS 413 7.2.6 LIMITATIONS ON USE OF CONVECTION COEFFICIENTS 414
7.3 METHODOLOGY FOR A CONVECTION CALCULATION 7.4 THE CYLINDER IN CROSS
FLOW 7.4.1 FLOW CONSIDERATIONS 423 7.4.2 CONVECTION HEAT AND MASS
TRANSFER 425 7.5 THE SPHERE 7.6 FLOW ACROSS BANKS OF TUBES 7.7 IMPINGING
JETS 7.7.1 HYDRODYNAMIC AND GEOMETRIC CONSIDERATIONS 447 7.7.2
CONVECTION HEAT AND MASS TRANSFER 449 7.8 PACKED BEDS 7.9 SUMMARY
REFERENCES PROBLEMS 405 403 405 414 423 433 436 447 452 454 456 457
TPTER 8 INTERNAL FLOW 485 8.1 HYDRODYNAMIC CONSIDERATIONS 486 8.1.1 FLOW
CONDITIONS 486 8.1.2 THE MEAN VELOCITY 487 8.1.3 VELOCITY PROFILE IN THE
FULLY DEVELOPED REGION 488 8.1.4 PRESSURE GRADIENT AND FRICTION FACTOR
IN FULLY DEVELOPED FLOW 490 8.2 THERMAL CONSIDERATIONS 491 8.2.1 THE
MEAN TEMPERATURE 492 8.2.2 NEWTON'S LAW OF COOLING 493 8.2.3 FULLY
DEVELOPED CONDITIONS 493 8.3 THE ENERGY BALANCE 497 8.3.1 GENERAL
CONSIDERATIONS 497 8.3.2 CONSTANT SURFACE HEAT FLUX 498 8.3.3 CONSTANT
SURFACE TEMPERATURE 501 8.4 LAMINAR FLOW IN CIRCULAR TUBES: THERMAL
ANALYSIS AND CONVECTION CORRELATIONS 505 8.4.1 THE FULLY DEVELOPED
REGION 505 8.4.2 THE ENTRY REGION 512 8.5 CONVECTION CORRELATIONS:
TURBULENT FLOW IN CIRCULAR TUBES 514 8.6 CONVECTION CORRELATIONS:
NONCIRCULAR TUBES AND THE CONCENTRIC TUBE ANNULUS 518 8.7 HEAT TRANSFER
ENHANCEMENT 521 XVIN CONTENTS 8.8 MICROSCALE INTERNAL FLOW 8.8.1 FLOW
CONDITIONS IN MICROSCALE INTERNAL FLOW 524 8.8.2 THERMAL CONSIDERATIONS
IN MICROSCALE INTERNAL FLOW 8.9 CONVECTION MASS TRANSFER 8.10 SUMMARY
REFERENCES PROBLEMS 525 524 528 531 533 534 CHAPTER 9 FREE CONVECTION
559 9.1 PHYSICAL CONSIDERATIONS 9.2 THE GOVERNING EQUATIONS 9.3
SIMILARITY CONSIDERATIONS 9.4 LAMINAR FREE CONVECTION ON A VERTICAL
SURFACE 9.5 THE EFFECTS OF TURBULENCE 9.6 EMPIRICAL CORRELATIONS:
EXTERNAL FREE CONVECTION FLOWS 9.6.1 THE VERTICAL PLATE 571 9.6.2
INCLINED AND HORIZONTAL PLATES 574 9.6.3 THE LONG HORIZONTAL CYLINDER
579 9.6.4 SPHERES 583 9.7 FREE CONVECTION WITHIN PARALLEL PLATE CHANNELS
9.7.1 VERTICAL CHANNELS 585 9.7.2 INCLINED CHANNELS 587 9.8 EMPIRICAL
CORRELATIONS: ENCLOSURES 9.8.1 RECTANGULAR CAVITIES 587 9.8.2 CONCENTRIC
CYLINDERS 590 9.8.3 CONCENTRIC SPHERES 591 9.9 COMBINED FREE AND FORCED
CONVECTION 9.10 CONVECTION MASS TRANSFER 9.11 SUMMARY REFERENCES
PROBLEMS 560 563 564 566 568 571 584 587 593 594 595 596 597 CHAPTER 1
0 BOILING AND CONDENSATION 619 10.1 DIMENSIONLESS PARAMETERS IN BOILING
AND CONDENSATION 10.2 BOILING MODES 10.3 POOL BOILING 10.3.1 THE BOILING
CURVE 622 10.3.2 MODES OF POOL BOILING 624 10.4 POOL BOILING
CORRELATIONS 10.4.1 NUCLEATE POOL BOILING 627 10.4.2 CRITICAL HEAT FLUX
FOR NUCLEATE POOL BOILING 629 10.4.3 MINIMUM HEAT FLUX 629 10.4.4 FILM
POOL BOILING 630 10.4.5 PARAMETRIC EFFECTS ON POOL BOILING 631 620 621
622 627 CONTENTS XIX 10.5 10.6 10.7 10.8 10.9 10.10 10.11 10.12 FORCED
CONVECTION BOILING 10.5.1 EXTERNAL FORCED CONVECTION BOILING 637 10.5.2
TWO-PHASE FLOW 637 10.5.3 TWO-PHASE FLOW IN MICROCHANNELS 640
CONDENSATION: PHYSICAL MECHANISMS LAMINAR FILM CONDENSATION ON A
VERTICAL PLATE TURBULENT FILM CONDENSATION FILM CONDENSATION ON RADIAL
SYSTEMS FILM CONDENSATION IN HORIZONTAL TUBES DROPWISE CONDENSATION
SUMMARY REFERENCES PROBLEMS PER 1 1 \EAT EXCHANGERS 11.1 11.2 11.3 11.4
11.5 11.6 11.7 HEAT EXCHANGER TYPES THE OVERALL HEAT TRANSFER
COEFFICIENT HEAT EXCHANGER ANALYSIS: USE OF THE LOG MEAN TEMPERATURE
DIFFERENCE 11.3.1 THE PARALLEL-FLOW HEAT EXCHANGER 676 11.3.2 THE
COUNTERFLOW HEAT EXCHANGER 679 11.3.3 SPECIAL OPERATING CONDITIONS 679
HEAT EXCHANGER ANALYSIS: THE EFFECTIVENESS-NTU METHOD 11.4.1 DEFINITIONS
686 11.4.2 EFFECTIVENESS-NTU RELATIONS 688 HEAT EXCHANGER DESIGN AND
PERFORMANCE CALCULATIONS: USING THE EFFECTIVENESS-NTU METHOD COMPACT
HEAT EXCHANGERS SUMMARY REFERENCES PROBLEMS 11S.1 LOG MEAN TEMPERATURE
DIFFERENCE METHOD FOR MULTIPASS AND CROSS-FLOW HEAT EXCHANGERS
REFERENCES PROBLEMS CHAPTER 1 2 RADIATION: PROCESSES AND PROPERTIES 12.1
12.2 12.3 FUNDAMENTAL CONCEPTS RADIATION INTENSITY 12.2.1 MATHEMATICAL
DEFINITIONS 727 12.2.2 RADIATION INTENSITY AND ITS RELATION TO EMISSION
12.2.3 RELATION TO IRRADIATION 733 12.2.4 RELATION TO RADIOSITY 735
BLACKBODY RADIATION 12.3.1 THE PLANCK DISTRIBUTION 737 12.3.2 WIEN'S
DISPLACEMENT LAW 737 728 636 641 643 646 651 654 655 655 656 657 669 670
673 675 686 694 700 705 706 707 W-37 W-41 W-41 723 724 727 736 XX
CONTENTS 12.3.3 THE STEFAN-BOLTZMANN LAW 738 12.3.4 BAND EMISSION 739
12.4 EMISSION FROM REAL SURFACES 12.5 ABSORPTION, REFLECTION, AND
TRANSMISSION BY REAL SURFACES 12.5.1 ABSORPTIVITY 754 12.5.2
REFLECTIVITY 755 12.5.3 TRANSMISSIVITY 756 12.5.4 SPECIAL CONSIDERATIONS
757 12.6 KIRCHHOFFSLAW 12.7 THE GRAY SURFACE 12.8 ENVIRONMENTAL
RADIATION 12.9 SUMMARY REFERENCES PROBLEMS 744 752 762 764 770 776 780
780 CHAPTER 1 3 RADIATION EXCHANGE BETWEEN SURFACES 811 13.1 THE VIEW
FACTOR 812 13.1.1 THE VIEW FACTOR INTEGRAL 812 13.1.2 VIEW FACTOR
RELATIONS 813 13.2 RADIATION EXCHANGE BETWEEN OPAQUE, DIFFUSE, GRAY
SURFACES IN AN ENCLOSURE 822 13.2.1 NET RADIATION EXCHANGE AT A SURFACE
823 13.2.2 RADIATION EXCHANGE BETWEEN SURFACES 824 13.2.3 BLACKBODY
RADIATION EXCHANGE 830 13.2.4 THE TWO-SURFACE ENCLOSURE 831 13.2.5
RADIATION SHIELDS 832 13.2.6 THE RERADIATING SURFACE 835 13.3 MULTIMODE
HEAT TRANSFER 839 13.4 RADIATION EXCHANGE WITH PARTICIPATING MEDIA 842
13.4.1 VOLUMETRIC ABSORPTION 843 13.4.2 GASEOUS EMISSION AND ABSORPTION
843 13.5 SUMMARY 847 REFERENCES 849 PROBLEMS 849 CHAPTER 1 4 DIFFUSION
MASS TRANSFER 879 14.1 PHYSICAL ORIGINS AND RATE EQUATIONS 14.1.1
PHYSICAL ORIGINS 880 14.1.2 MIXTURE COMPOSITION 881 14.1.3 FICK'S LAW OF
DIFFUSION 882 14.1.4 MASS DIFFUSIVITY 883 14.2 MASS TRANSFER IN
NONSTATIONARY MEDIA 14.2.1 ABSOLUTE AND DIFFUSIVE SPECIES FLUXES 14.2.2
EVAPORATION IN A COLUMN 888 14.3 THE STATIONARY MEDIUM APPROXIMATION 880
885 885 893 CONTENTS XXI 894 14.4 CONSERVATION OF SPECIES FOR A
STATIONARY MEDIUM 14.4.1 CONSERVATION OF SPECIES FOR A CONTROL VOLUME
14.4.2 THE MASS DIFFUSION EQUATION 894 14.4.3 STATIONARY MEDIA WITH
SPECIFIED SURFACE CONCENTRATIONS 897 14.5 BOUNDARY CONDITIONS AND
DISCONTINUOUS CONCENTRATIONS AT INTERFACES 14.5.1 EVAPORATION AND
SUBLIMATION 901 14.5.2 SOLUBILITY OF GASES IN LIQUIDS AND SOLIDS 902
14.5.3 CATALYTIC SURFACE REACTIONS 905 14.6 MASS DIFFUSION WITH
HOMOGENEOUS CHEMICAL REACTIONS 14.7 TRANSIENT DIFFUSION 14.8 SUMMARY
REFERENCES PROBLEMS APPENDIX A THERMOPHYSICAL PROPERTIES OF MATTER 894
900 908 911 916 917 917 927 APPENDIX B MATHEMATICAL RELATIONS AND
FUNCTIONS 959 APPENDIX C THERMAL CONDITIONS ASSOCIATED WITH UNIFORM
ENERGY GENERATION IN ONE-DIMENSIONAL, STEADY-STATE SYSTEMS 965 APPENDIX
D THE CONVECTION TRANSFER EQUATIONS 973 D.I CONSERVATION OF MASS D.2
NEWTON'S SECOND LAW OF MOTION D.3 CONSERVATION OF ENERGY D.4
CONSERVATION OF SPECIES APPENDIX E BOUNDARY LAYER EQUATIONS FOR
TURBULENT FLOW 974 974 975 976 977 APPENDIX F AN INTEGRAL LAMINAR
BOUNDARY LAYER SOLUTION FOR PARALLEL FLOW OVER A FLAT PLATE 981 INDEX
985 |
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| dewey-full | 621.402/2 |
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| genre_facet | Einführung |
| id | DE-604.BV021515042 |
| illustrated | Illustrated |
| index_date | 2024-07-02T14:20:18Z |
| indexdate | 2024-08-01T10:37:50Z |
| institution | BVB |
| isbn | 0471457280 9780471457282 |
| language | English |
| oai_aleph_id | oai:aleph.bib-bvb.de:BVB01-014731612 |
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| physical | XXV, 997 S. Ill., graph. Darst. |
| publishDate | 2007 |
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| publisher | Wiley |
| record_format | marc |
| spellingShingle | Fundamentals of heat and mass transfer Chaleur - Transmission Transfert de masse Heat Transmission Mass transfer Wärmeübertragung (DE-588)4064211-2 gnd Stoffübertragung (DE-588)4057696-6 gnd Stoffübergang (DE-588)4183410-0 gnd Wärmeübergang (DE-588)4188877-7 gnd |
| subject_GND | (DE-588)4064211-2 (DE-588)4057696-6 (DE-588)4183410-0 (DE-588)4188877-7 (DE-588)4151278-9 |
| title | Fundamentals of heat and mass transfer |
| title_auth | Fundamentals of heat and mass transfer |
| title_exact_search | Fundamentals of heat and mass transfer |
| title_exact_search_txtP | Fundamentals of heat and mass transfer |
| title_full | Fundamentals of heat and mass transfer Frank P. Incropera ... |
| title_fullStr | Fundamentals of heat and mass transfer Frank P. Incropera ... |
| title_full_unstemmed | Fundamentals of heat and mass transfer Frank P. Incropera ... |
| title_short | Fundamentals of heat and mass transfer |
| title_sort | fundamentals of heat and mass transfer |
| topic | Chaleur - Transmission Transfert de masse Heat Transmission Mass transfer Wärmeübertragung (DE-588)4064211-2 gnd Stoffübertragung (DE-588)4057696-6 gnd Stoffübergang (DE-588)4183410-0 gnd Wärmeübergang (DE-588)4188877-7 gnd |
| topic_facet | Chaleur - Transmission Transfert de masse Heat Transmission Mass transfer Wärmeübertragung Stoffübertragung Stoffübergang Wärmeübergang Einführung |
| url | http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=014731612&sequence=000001&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA |
| work_keys_str_mv | AT incroperafrankp fundamentalsofheatandmasstransfer |
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| Exemplar 1 | ausleihbar Verfügbar Bestellen |
| Exemplar 2 | ausleihbar Verfügbar Bestellen |
| Exemplar 3 | ausleihbar Verfügbar Bestellen |
| Exemplar 4 | ausleihbar Verfügbar Bestellen |
| Exemplar 5 | ausleihbar Verfügbar Bestellen |
| Exemplar 6 | ausleihbar Verfügbar Bestellen |