Fluid dynamics:
Gespeichert in:
| Hauptverfasser: | , |
|---|---|
| Format: | Buch |
| Sprache: | Undetermined |
| Veröffentlicht: |
Reading, Mass.
Addison-Wesley
1973
|
| Ausgabe: | 2. print. |
| Schriftenreihe: | Addison-Wesley series in mechanics and thermodynamics
|
| Schlagworte: | |
| Online-Zugang: | Inhaltsverzeichnis |
| Beschreibung: | IX, 454 S. Ill., graph. Darst. |
| ISBN: | 0201014211 |
Internformat
MARC
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| 100 | 1 | |a Daily, James W. |e Verfasser |4 aut | |
| 245 | 1 | 0 | |a Fluid dynamics |c James W. Daily ; Donald R. F. Harleman |
| 250 | |a 2. print. | ||
| 264 | 1 | |a Reading, Mass. |b Addison-Wesley |c 1973 | |
| 300 | |a IX, 454 S. |b Ill., graph. Darst. | ||
| 336 | |b txt |2 rdacontent | ||
| 337 | |b n |2 rdamedia | ||
| 338 | |b nc |2 rdacarrier | ||
| 490 | 0 | |a Addison-Wesley series in mechanics and thermodynamics | |
| 650 | 0 | 7 | |a Strömungsmechanik |0 (DE-588)4077970-1 |2 gnd |9 rswk-swf |
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| 700 | 1 | |a Harleman, Donald R. |e Verfasser |4 aut | |
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Datensatz im Suchindex
| _version_ | 1804135853421756416 |
|---|---|
| adam_text | Contents
ACKNOWLEDGMENTS x
Chapter 1 FLUID CHARACTERISTICS
1-1 Introduction 1
1-2 Units of measurement 3
1-3 Properties and states of fluids 4
1 Properties of importance in fluid dynamics 5
2 Equations of state 13
3 Change of state processes for gases 15
1- 4 Equilibrium of fluids 16
1 Stress at a point for fluids in equilibrium 17
2 Equilibrium in a gravity field 18
3 Capillarity effects 27
Chapter 2 KINEMATICS
2- 1 The velocity field 42
2-2 Steady versus uniform motion 44
2-3 Rotating and accelerating coordinate systems 44
2-4 Streamlines versus path lines 48
2- 5 Velocity gradients and shear 49
Chapter 3 DYNAMIC FEATURES AND METHODS OF ANALYSIS
3- 1 Introduction 51
3-2 Mass transport 52
3-3 Heat transport 53
3-4 Momentum transport 53
3-5 Transport analogies 54
1 Momentum transport 55
2 Heat transport 56
3 Mass transport 57
3-6 Particle and control-volume concepts 58
1 Infinitesimal elements and control volumes 58
2 Finite control volume 59
3- 7 Scope of analytical treatment 59
Chapter 4 CONTINUITY, ENERGY, AND MOMENTUM EQUATIONS FOR
FINITE CONTROL VOLUMES
4- 1 Conservation of matter in homogeneous fluids 60
1 Arbitrary control volume 60
2 Stream-tube control volume 62
3 Control volume coincident with conduit boundaries 63
V
vi
CONTENTS
4-2
4-3
4-4
Chapter 5
5-1
5-2
5-3
The general energy equation
1 The first law of thermodynamics
2 The general energy equation
3 One-dimensional steady-flow equations
4 Grade lines—energy (total head) and hydraulic
(piezometric head)
The linear momentum equation for finite control volumes
1 The momentum principle
2 The general linear momentum equation
3 Inertial control volume for a generalized apparatus
The moment of momentum equation for finite control volumes
1 The moment of momentum principle for inertial
reference systems
2 The general mofnent of momentum equation
3 Steady-flow equations for turbomachinery
STRESS-STRAIN RELATIONS
General stress-strain system
1 Surface stresses
2 Strain components
Relations between stress and strain for elastic solids
Relations between stress and rate of strain for Newtonian fluids
Chapter 6
6-1
6-2
6-3
6-4
6-5
6-6
6-7
6-8
EQUATIONS OF CONTINUITY AND MOTION
Continuity equation
Stream function in two-dimensional, incompressible flows
Rotational and irrotational motion
1 Rotation and vorticity
2 Circulation
Equations of motion
1 The Navier-Stokes equations
Examples of laminar motion
1 Laminar flow between parallel plates
2 Laminar flow in a circular tube of constant diameter
Equations for irrotational motion
1 Velocity potential and stream function
2 The Bernoulli equation
Equations for frictionless flow
1 Equations for flow along a streamline
2 Summary of Bernoulli-equation forms
3 Frictionless-flow examples
Vortex motion
1 Forced vortex
2 Irrotational or free vortex
CONTENTS
vii
64
64
66
69
74
76
76
78
79
84
84
85
86
97
97
99
100
102
106
108
109
109
110
111
112
115
116
117
118
119
121
123
123
125
126
129
130
131
Chapter 7 DYNAMIC SIMILITUDE
7-1 Introduction 137
7-2 Geometric similarity 138
7-3 Dynamic similarity 138
7-4 Similarity conditions for incompressible fluids Froude and
Reynolds numbers 141
1 Enclosed systems 144
2 Free-surface systems 147
7-5 Similarity conditions for compressible fluids Mach number 151
7- 6 Summary 153
Chapter 8 SOME FUNDAMENTAL CONCEPTS AND SPECIALIZED EQUATIONS
IN FLUID DYNAMICS
8- 1 Flow classifications 159
1 Laminar versus turbulent flow 159
2 Creeping motions 161
3 The boundary-layer concept 162
8-2 Equations for creeping motion and two-dimensional boundary
layers 164
1 Creeping motion 164
2 Equations for two-dimensional boundary layers 165
3 Boundary-layer thickness definitions 167
4 Integral momentum equation for two-dimensional boundary
layers 168
8- 3 The notion of resistance, drag, and lift 169
Chapter 9 CREEPING MOTIONS
9- 1 Stokes’ motion 173
9-2 Viscous effects on impact tubes 178
9-3 Flow through porous media 180
1 Creeping-motion equations for porous media 180
2 Examples for isotropic materials 184
3 Graphical method for two-dimensional flows 186
Chapter 10 LAMINAR BOUNDARY LAYERS
10-1 Introduction 193
10-2 Two-dimensional laminar layers on flat surfaces 193
1 General properties 193
2 The Blasius solution for laminar flow 196
10-3 Effects of boundary curvature in two-dimensional boundary
layers 200
1 The role of pressure gradients 201
2 Example for nonzero pressure gradient 202
10-4 Three-dimensional boundary layers 204
1 Skewed boundary layers on a rotating disk 205
viii
CONTENTS
Chapter 11 ORIGIN OF TURBULENCE AND TURBULENT SHEAR STRESS
11-1 Sources of turbulence 212
11-2 Velocities, energies, and continuity in turbulence 216
11-3 Turbulent shear stresses and eddy viscosities 218
11-4 Reynolds equations for incompressible fluids 220
11- 5 Mixing length and similarity hypotheses in shear flow 224
Chapter 12 WALL TURBULENCE BOUNDARY-LAYER FLOWS
12- 1 Introduction 227
12-2 Structure of a turbulent boundary layer 227
12-3 Mean flow characteristics 230
1 Universal velocity and friction laws: smooth walls 231
2 Power-law formulas: smooth walls 244
3 Laws for rough walls 246
12- 4 Turbulent boundary layers with pressure gradients 252
1 Effects of pressure gradients 252
2 Boundary-layer development computations 254
Chapter 13 WALL TURBULENCE FLOWS IN UNIFORM CONDUITS
13- 1 Inlet-region flow versus fully developed flow 259
13-2 Incompressible flow in pipes 262
1 Reynolds equations for axially symmetric flows 262
2 Equations of motion and energy for pipe flow 263
3 Structure of uniform shear flow in pipes 267
4 Velocity and friction laws: smooth pipes 267
5 Roughness effects 272
6 Pipe-flow computations 276
13-3 Incompressible flow in noncircular ducts 281
1 Friction losses in closed conduits 281
2 Two-dimensional flows 284
13-4 Compressible uniform flow in pipes 286
1 One-dimensional equations for compressible flow 286
2 Isothermal gas flow with friction 288
3 Adiabatic gas flow with friction in pipes 290
13- 5 Uniform flow in prismatic open channels 293
1 One-dimensional open-channel equations 294
2 Head-loss equations 297
3 Velocity and friction laws for two-dimensional channels 299
4 Uniform-flow computations 300
Chapter 14 NONUNIFORM FLOW IN CONDUITS
14- 1 Introduction 309
14—2 Incompressible, nonuniform flow in closed conduits Flow
features and losses 309
1 Energy dissipation in nonuniform flow 312
2 Expanding flows 314
CONTENTS ix
3 Converging flows 317
4 Flow meters 319
5 Change of flow direction 320
6 Pipeline systems 322
14-3 Compressible nonuniform flow 327
1 Multidimensional analysis in gas dynamics 328
2 One-dimensional isentropic channel flow 331
3 Shock waves 337
14- 4 Nonuniform free-surface flow 344
1 Rapidly varied flow 345
2 Varied flow in short channel transitions 349
3 Gradually varied flow 353
4 Free-surface shock waves 357
Chapter 15 IMMERSED BODIES DRAG AND LIFT
15- 1 Introduction 369
15-2 Hydrodynamic forces in steady irrotational motion 371
15-3 Hydrodynamic forces in accelerated motion 374
15-4 Drag of symmetrical bodies 376
1 Two-dimensional symmetrical bodies 377
2 Three-dimensional bodies 385
15-5 Lift and drag of nonsymmetrical bodies 387
1 Circulation and lift 387
2 Two-dimensional airfoils 388
3 Three-dimensional effects 390
15-6 Effect of cavitation on resistance 395
15-7 Interfacial effects on resistance 401
15- 8 Compressibility effects on drag 403
Chapter 16 TURBULENT JETS AND DIFFUSION PROCESSES
16- 1 Free turbulence 413
1 Dynamics of a plane jet 415
2 Axially symmetric jets 419
3 Free turbulence in wakes 423
16-2 Diffusion processes in nonhomogeneous fluids 424
1 Molecular diffusion in a binary system 424
2 Convective-diffusion equation 427
3 Diffusion and convection in turbulent flow 430
4 Dispersion in one-dimensional motion 432
ANSWERS TO ODD-NUMBERED PROBLEMS 441
INDEX
|
| adam_txt |
Contents
ACKNOWLEDGMENTS x
Chapter 1 FLUID CHARACTERISTICS
1-1 Introduction 1
1-2 Units of measurement 3
1-3 Properties and states of fluids 4
1 Properties of importance in fluid dynamics 5
2 Equations of state 13
3 Change of state processes for gases 15
1- 4 Equilibrium of fluids 16
1 Stress at a point for fluids in equilibrium 17
2 Equilibrium in a gravity field 18
3 Capillarity effects 27
Chapter 2 KINEMATICS
2- 1 The velocity field 42
2-2 Steady versus uniform motion 44
2-3 Rotating and accelerating coordinate systems 44
2-4 Streamlines versus path lines 48
2- 5 Velocity gradients and shear 49
Chapter 3 DYNAMIC FEATURES AND METHODS OF ANALYSIS
3- 1 Introduction 51
3-2 Mass transport 52
3-3 Heat transport 53
3-4 Momentum transport 53
3-5 Transport analogies 54
1 Momentum transport 55
2 Heat transport 56
3 Mass transport 57
3-6 Particle and control-volume concepts 58
1 Infinitesimal elements and control volumes 58
2 Finite control volume 59
3- 7 Scope of analytical treatment 59
Chapter 4 CONTINUITY, ENERGY, AND MOMENTUM EQUATIONS FOR
FINITE CONTROL VOLUMES
4- 1 Conservation of matter in homogeneous fluids 60
1 Arbitrary control volume 60
2 Stream-tube control volume 62
3 Control volume coincident with conduit boundaries 63
V
vi
CONTENTS
4-2
4-3
4-4
Chapter 5
5-1
5-2
5-3
The general energy equation
1 The first law of thermodynamics
2 The general energy equation
3 One-dimensional steady-flow equations
4 Grade lines—energy (total head) and hydraulic
(piezometric head)
The linear momentum equation for finite control volumes
1 The momentum principle
2 The general linear momentum equation
3 Inertial control volume for a generalized apparatus
The moment of momentum equation for finite control volumes
1 The moment of momentum principle for inertial
reference systems
2 The general mofnent of momentum equation
3 Steady-flow equations for turbomachinery
STRESS-STRAIN RELATIONS
General stress-strain system
1 Surface stresses
2 Strain components
Relations between stress and strain for elastic solids
Relations between stress and rate of strain for Newtonian fluids
Chapter 6
6-1
6-2
6-3
6-4
6-5
6-6
6-7
6-8
EQUATIONS OF CONTINUITY AND MOTION
Continuity equation
Stream function in two-dimensional, incompressible flows
Rotational and irrotational motion
1 Rotation and vorticity
2 Circulation
Equations of motion
1 The Navier-Stokes equations
Examples of laminar motion
1 Laminar flow between parallel plates
2 Laminar flow in a circular tube of constant diameter
Equations for irrotational motion
1 Velocity potential and stream function
2 The Bernoulli equation
Equations for frictionless flow
1 Equations for flow along a streamline
2 Summary of Bernoulli-equation forms
3 Frictionless-flow examples
Vortex motion
1 Forced vortex
2 Irrotational or free vortex
CONTENTS
vii
64
64
66
69
74
76
76
78
79
84
84
85
86
97
97
99
100
102
106
108
109
109
110
111
112
115
116
117
118
119
121
123
123
125
126
129
130
131
Chapter 7 DYNAMIC SIMILITUDE
7-1 Introduction 137
7-2 Geometric similarity 138
7-3 Dynamic similarity 138
7-4 Similarity conditions for incompressible fluids Froude and
Reynolds numbers 141
1 Enclosed systems 144
2 Free-surface systems 147
7-5 Similarity conditions for compressible fluids Mach number 151
7- 6 Summary 153
Chapter 8 SOME FUNDAMENTAL CONCEPTS AND SPECIALIZED EQUATIONS
IN FLUID DYNAMICS
8- 1 Flow classifications 159
1 Laminar versus turbulent flow 159
2 Creeping motions 161
3 The boundary-layer concept 162
8-2 Equations for creeping motion and two-dimensional boundary
layers 164
1 Creeping motion 164
2 Equations for two-dimensional boundary layers 165
3 Boundary-layer thickness definitions 167
4 Integral momentum equation for two-dimensional boundary
layers 168
8- 3 The notion of resistance, drag, and lift 169
Chapter 9 CREEPING MOTIONS
9- 1 Stokes’ motion 173
9-2 Viscous effects on impact tubes 178
9-3 Flow through porous media 180
1 Creeping-motion equations for porous media 180
2 Examples for isotropic materials 184
3 Graphical method for two-dimensional flows 186
Chapter 10 LAMINAR BOUNDARY LAYERS
10-1 Introduction 193
10-2 Two-dimensional laminar layers on flat surfaces 193
1 General properties 193
2 The Blasius solution for laminar flow 196
10-3 Effects of boundary curvature in two-dimensional boundary
layers 200
1 The role of pressure gradients 201
2 Example for nonzero pressure gradient 202
10-4 Three-dimensional boundary layers 204
1 Skewed boundary layers on a rotating disk 205
viii
CONTENTS
Chapter 11 ORIGIN OF TURBULENCE AND TURBULENT SHEAR STRESS
11-1 Sources of turbulence 212
11-2 Velocities, energies, and continuity in turbulence 216
11-3 Turbulent shear stresses and eddy viscosities 218
11-4 Reynolds equations for incompressible fluids 220
11- 5 Mixing length and similarity hypotheses in shear flow 224
Chapter 12 WALL TURBULENCE BOUNDARY-LAYER FLOWS
12- 1 Introduction 227
12-2 Structure of a turbulent boundary layer 227
12-3 Mean flow characteristics 230
1 Universal velocity and friction laws: smooth walls 231
2 Power-law formulas: smooth walls 244
3 Laws for rough walls 246
12- 4 Turbulent boundary layers with pressure gradients 252
1 Effects of pressure gradients 252
2 Boundary-layer development computations 254
Chapter 13 WALL TURBULENCE FLOWS IN UNIFORM CONDUITS
13- 1 Inlet-region flow versus fully developed flow 259
13-2 Incompressible flow in pipes 262
1 Reynolds equations for axially symmetric flows 262
2 Equations of motion and energy for pipe flow 263
3 Structure of uniform shear flow in pipes 267
4 Velocity and friction laws: smooth pipes 267
5 Roughness effects 272
6 Pipe-flow computations 276
13-3 Incompressible flow in noncircular ducts 281
1 Friction losses in closed conduits 281
2 Two-dimensional flows 284
13-4 Compressible uniform flow in pipes 286
1 One-dimensional equations for compressible flow 286
2 Isothermal gas flow with friction 288
3 Adiabatic gas flow with friction in pipes 290
13- 5 Uniform flow in prismatic open channels 293
1 One-dimensional open-channel equations 294
2 Head-loss equations 297
3 Velocity and friction laws for two-dimensional channels 299
4 Uniform-flow computations 300
Chapter 14 NONUNIFORM FLOW IN CONDUITS
14- 1 Introduction 309
14—2 Incompressible, nonuniform flow in closed conduits Flow
features and losses 309
1 Energy dissipation in nonuniform flow 312
2 Expanding flows 314
CONTENTS ix
3 Converging flows 317
4 Flow meters 319
5 Change of flow direction 320
6 Pipeline systems 322
14-3 Compressible nonuniform flow 327
1 Multidimensional analysis in gas dynamics 328
2 One-dimensional isentropic channel flow 331
3 Shock waves 337
14- 4 Nonuniform free-surface flow 344
1 Rapidly varied flow 345
2 Varied flow in short channel transitions 349
3 Gradually varied flow 353
4 Free-surface shock waves 357
Chapter 15 IMMERSED BODIES DRAG AND LIFT
15- 1 Introduction 369
15-2 Hydrodynamic forces in steady irrotational motion 371
15-3 Hydrodynamic forces in accelerated motion 374
15-4 Drag of symmetrical bodies 376
1 Two-dimensional symmetrical bodies 377
2 Three-dimensional bodies 385
15-5 Lift and drag of nonsymmetrical bodies 387
1 Circulation and lift 387
2 Two-dimensional airfoils 388
3 Three-dimensional effects 390
15-6 Effect of cavitation on resistance 395
15-7 Interfacial effects on resistance 401
15- 8 Compressibility effects on drag 403
Chapter 16 TURBULENT JETS AND DIFFUSION PROCESSES
16- 1 Free turbulence 413
1 Dynamics of a plane jet 415
2 Axially symmetric jets 419
3 Free turbulence in wakes 423
16-2 Diffusion processes in nonhomogeneous fluids 424
1 Molecular diffusion in a binary system 424
2 Convective-diffusion equation 427
3 Diffusion and convection in turbulent flow 430
4 Dispersion in one-dimensional motion 432
ANSWERS TO ODD-NUMBERED PROBLEMS 441
INDEX |
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| id | DE-604.BV021905566 |
| illustrated | Illustrated |
| index_date | 2024-07-02T16:04:56Z |
| indexdate | 2024-07-09T20:47:06Z |
| institution | BVB |
| isbn | 0201014211 |
| language | Undetermined |
| oai_aleph_id | oai:aleph.bib-bvb.de:BVB01-015120743 |
| oclc_num | 256645760 |
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| owner_facet | DE-706 |
| physical | IX, 454 S. Ill., graph. Darst. |
| publishDate | 1973 |
| publishDateSearch | 1973 |
| publishDateSort | 1973 |
| publisher | Addison-Wesley |
| record_format | marc |
| series2 | Addison-Wesley series in mechanics and thermodynamics |
| spelling | Daily, James W. Verfasser aut Fluid dynamics James W. Daily ; Donald R. F. Harleman 2. print. Reading, Mass. Addison-Wesley 1973 IX, 454 S. Ill., graph. Darst. txt rdacontent n rdamedia nc rdacarrier Addison-Wesley series in mechanics and thermodynamics Strömungsmechanik (DE-588)4077970-1 gnd rswk-swf Strömungsmechanik (DE-588)4077970-1 s DE-604 Harleman, Donald R. Verfasser aut HEBIS Datenaustausch application/pdf http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=015120743&sequence=000001&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA Inhaltsverzeichnis |
| spellingShingle | Daily, James W. Harleman, Donald R. Fluid dynamics Strömungsmechanik (DE-588)4077970-1 gnd |
| subject_GND | (DE-588)4077970-1 |
| title | Fluid dynamics |
| title_auth | Fluid dynamics |
| title_exact_search | Fluid dynamics |
| title_exact_search_txtP | Fluid dynamics |
| title_full | Fluid dynamics James W. Daily ; Donald R. F. Harleman |
| title_fullStr | Fluid dynamics James W. Daily ; Donald R. F. Harleman |
| title_full_unstemmed | Fluid dynamics James W. Daily ; Donald R. F. Harleman |
| title_short | Fluid dynamics |
| title_sort | fluid dynamics |
| topic | Strömungsmechanik (DE-588)4077970-1 gnd |
| topic_facet | Strömungsmechanik |
| url | http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=015120743&sequence=000001&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA |
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