Fluid mechanics:
Gespeichert in:
| Format: | Buch |
|---|---|
| Sprache: | English |
| Veröffentlicht: |
Harlow ; Munich [u.a.]
Pearson - Prentice Hall
2007
|
| Ausgabe: | 5. ed., [Nachdr.] |
| Schlagworte: | |
| Online-Zugang: | Inhaltsverzeichnis |
| Beschreibung: | XXXIII, 958 S. Ill., graph. Darst. |
| ISBN: | 0131292935 9780131292932 |
Internformat
MARC
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| 245 | 1 | 0 | |a Fluid mechanics |c John F. Douglas ; Janusz M. Gasiorek ; John A. Swaffield ; Lynne B. Jack |
| 250 | |a 5. ed., [Nachdr.] | ||
| 264 | 1 | |a Harlow ; Munich [u.a.] |b Pearson - Prentice Hall |c 2007 | |
| 300 | |a XXXIII, 958 S. |b Ill., graph. Darst. | ||
| 336 | |b txt |2 rdacontent | ||
| 337 | |b n |2 rdamedia | ||
| 338 | |b nc |2 rdacarrier | ||
| 650 | 4 | |a Strömungsmechanik - Lehrbuch | |
| 650 | 0 | 7 | |a Strömungsmechanik |0 (DE-588)4077970-1 |2 gnd |9 rswk-swf |
| 689 | 0 | 0 | |a Strömungsmechanik |0 (DE-588)4077970-1 |D s |
| 689 | 0 | |5 DE-604 | |
| 700 | 1 | |a Douglas, John F. |e Sonstige |0 (DE-588)1157936652 |4 oth | |
| 700 | 1 | |a Gasiorek, J. M. |d 1927- |e Sonstige |0 (DE-588)172092736 |4 oth | |
| 700 | 1 | |a Swaffield, John A. |e Sonstige |4 oth | |
| 700 | 1 | |a Jack, Lynne B. |e Sonstige |4 oth | |
| 856 | 4 | 2 | |m Digitalisierung UB Bayreuth |q application/pdf |u http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=017384090&sequence=000002&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA |3 Inhaltsverzeichnis |
| 999 | |a oai:aleph.bib-bvb.de:BVB01-017384090 | ||
Datensatz im Suchindex
| _version_ | 1804138920616656896 |
|---|---|
| adam_text | Contents
Preface
to the Fifth Edition
xix
Preface to the Fourth Edition
xxi
Preface to the Third Edition
xxiv
Preface to the Second Edition
xxvi
Preface to the First Edition
xxvii
Acknowledgements
xxviii
List of Computer Programs
xxix
List of Symbols
xxxi
PART I ELEMENTS OF FLUID MECHANICS
Chapter
1
Fluids and their Properties
2
1.1
Fluids
4
1.2
Shear stress in a moving fluid
4
1.3
Differences between solids and fluids
5
1.4
Newtonian and non-Newtonian fluids
6
1.5
Liquids and gases
7
1.6
Molecular structure of materials
7
1.7
The continuum concept of a fluid
9
1.8
Density
10
1.9
Viscosity
11
1.10
Causes of viscosity in gases
12
1.11
Causes of viscosity in a liquid
13
1.12
Surface tension
14
1.13
Capillarity
15
1.14
Vapour pressure
16
1.15
Cavitation
17
1.16
Compressibility and the bulk modulus
17
1.17
Equation of state of a perfect gas
19
1.18
The universal gas constant
19
1.19
Specific heats of a gas
19
1.20
Expansion of a gas
20
Concluding remarks
22
Summary of important equations and concepts
22
viii Contents
Chapter
2
Pressure and Head
24
2.1
Statics of fluid systems
26
2.2
Pressure
27
2.3
Pascal s law for pressure at a point
28
2.4
Variation of pressure vertically in a fluid under gravity
29
2.5
Equality of pressure at the same level in a static fluid
30
2.6
General equation for the variation of pressure due to gravity from
point to point in a static fluid
32
2.7
Variation of pressure with altitude in a fluid of constant density
33
2.8
Variation of pressure with altitude in a gas at constant temperature
34
2.9
Variation of pressure with altitude in a gas under adiabatic conditions
35
2.10
Variation of pressure and density with altitude for a constant
temperature gradient
38
2.11
Variation of temperature and pressure in the atmosphere
39
2.12
Stability of the atmosphere
41
2.13
Pressure and head
43
2.14
The hydrostatic paradox
44
2.15
Pressure measurement by manometer
45
2.16
Relative equilibrium
51
2.17
Pressure distribution in a liquid subject to horizontal acceleration
51
2.18
Effect of vertical acceleration
52
2.19
General expression for the pressure in a fluid in relative equilibrium
52
2.20
Forced vortex
56
Concluding remarks
57
Summary of important equations and concepts
57
Problems
57
Chapter
3
Static Forces on Surfaces. Buoyancy
60
3.1
Action of fluid pressure on a surface
62
3.2
Resultant force and centre of pressure on a plane surface under
uniform pressure
62
3.3
Resultant force and centre of pressure on a plane surface immersed in
a liquid
63
3.4
Pressure diagrams
68
3.5
Force on a curved surface due to hydrostatic pressure
71
3.6
Buoyancy
73
3.7
Equilibrium of floating bodies
76
3.8
Stability of a submerged body
76
3.9
Stability of floating bodies
77
3.10
Determination of the metacentric height
78
3.11
Determination of the position of the
metacentro
relative to the centre
of buoyancy
78
3.12
Periodic time of oscillation
81
3.13
Stability of a vessel carrying liquid in tanks with a free surface
82
Concluding remarks
85
Summary of important equations and concepts
85
Problems
85
Contents ix
PART II CONCEPTS OF FLUID FLOW
88
Chapter
4
Motion of Fluid Particles and Streams
90
4.1
Fluid flow
92
4.2
Uniform flow and steady flow
93
4.3
Frames of reference
93
4.4
Real and ideal fluids
94
4.5
Compressible and incompressible flow
94
4.6
One-, two- and three-dimensional flow
95
4.7
Analyzing fluid flow
96
4.8
Motion of a fluid particle
96
4.9
Acceleration of a fluid particle
98
4.10
Laminar and turbulent flow
100
4.11
Discharge and mean velocity
102
4.12
Continuity of flow
104
4.13
Continuity equations for three-dimensional flow using
Cartesian coordinates
107
4.14
Continuity equation for cylindrical coordinates
109
Concluding remarks
109
Summary of important equations and concepts
110
Problems
110
Chapter
5
The Momentum Equation and its Applications
112
5.1
Momentum and fluid flow
114
5.2
Momentum equation for two- and three-dimensional flow
along a streamline
115
5.3
Momentum correction factor
116
5.4
Gradual acceleration of a fluid in a pipeline neglecting elasticity
119
5.5
Force exerted by a jet striking a flat plate
120
5.6
Force due to the deflection of a jet by a curved vane
123
5.7
Force exerted when a jet is deflected by a moving curved vane
124
5.8
Force exerted on pipe bends and closed conduits
126
5.9
Reaction of a jet
129
5.10
Drag exerted when a fluid flows over a flat plate
136
5.11
Angular motion
138
5.12
Euler s equation of motion along a streamline
141
5.13
Pressure waves and the velocity of sound in a fluid
143
5.14
Velocity of propagation of a small surface wave
146
5.15
Differential form of the continuity and momentum equations
148
5.16
Computational treatment of the differential forms of the continuity and
momentum equations
151
5.17
Comparison of CFD methodologies
155
Concluding remarks
162
Summary of important equations and concepts
162
Further reading
163
Problems
163
χ
Contents
Chapter
6
The Energy Equation and its Applications
166
6.1
Mechanical energy of a flowing fluid
168
6.2
Steady flow energy equation
172
6.3
Kinetic energy correction factor
174
6.4
Applications of the steady flow energy equation
175
6.5
Representation of energy changes in a fluid system
178
6.6
The Pitot tube
180
6.7
Determination of volumetric flow rate via Pitot tube
181
6.8
Computer program VOLFLO
183
6.9
Changes of pressure in a tapering pipe
183
6.10
Principle of the
venturi
meter
185
6.11
Pipe orifices
187
6.12
Limitation on the velocity of flow in a pipeline
188
6.13
Theory of small orifices discharging to atmosphere
188
6.14
Theory of large orifices
192
6.15
Elementary theory of notches and weirs
193
6.16
The power of a stream of fluid
197
6.17
Radial flow
198
6.18
Flow in a curved path. Pressure gradient and change of total energy across
the streamlines
199
6.19
Vortex motion
202
Concluding remarks
208
Summary of important equations and concepts
209
Problems
209
Chapter
7
Two-dimensional Ideal Flow
212
7.1
Rotational and irrotational flow
214
7.2
Circulation and vorticity
216
7.3
Streamlines and the stream function
218
7.4
Velocity potential and potential flow
220
7.5
Relationship between stream function and velocity potential. Flow nets
224
7.6
Straight
hne
flows and their combinations
228
7.7
Combined source and sink flows. Doublet
236
7.8
Flow past a cylinder
241
7.9
Curved flows and their combinations
244
7.10
Flow past a cylinder with circulation. Kutta-Joukowsky s law
249
7.11
Computer program ROTCYL
252
Concluding remarks
253
Summary of important equations and concepts
253
Problems
254
PART III DIMENSIONAL ANALYSIS AND SIMILARITY
256
Chapter
8
Dimensional Analysis
258
8.1
Dimensional analysis
260
8.2
Dimensions and units
260
Contents xi
8.3
Dimensional
reasoning, homogeneity and dimensionless groups
260
8.4
Fundamental and derived units and dimensions
261
8.5
Additional fundamental dimensions
263
8.6
Dimensions of derivatives and integrals
265
8.7
Units of derived quantities
266
8.8
Conversion between systems of units, including the treatment of dimensional
constants
266
8.9
Dimensional analysis by the
indiciai
method
269
8.10
Dimensional analysis by the group method
271
8.11
The significance of dimensionless groups
279
Concluding remarks
280
Summary of important equations and concepts
280
Further reading
280
Problems
281
Chapter
9
Similarity
282
9.1
Geometric similarity
286
9.2
Dynamic similarity
286
9.3
Model studies for flows without a free surface. Introduction to
approximate similitude at high Reynolds numbers
291
9.4
Zone of dependence of
Mach
number
293
9.5
Significance of the pressure coefficient
294
9.6
Model studies in cases involving free surface flow
295
9.7
Similarity applied to rotodynamic machines
297
9.8
River and harbour models
299
9.9
Groundwater and seepage models
305
9.10
Computer program GROUND, the simulation of groundwater
seepage
310
9.11
Pollution dispersion modelling, outfall effluent and stack plumes
311
9.12
Pollutant dispersion in one-dimensional steady uniform flow
314
Concluding remarks
319
Summary of important equations and concepts
319
Further reading
320
References
320
Problems
321
PART IV BEHAVIOUR OF REAL FLUIDS
322
Chapter
10
Laminar and Turbulent Flows in
Bounded Systems
324
10.1
Incompressible, steady and uniform laminar flow between
parallel plates
326
10.2
Incompressible, steady and uniform laminar flow in circular
cross-section pipes
331
10.3
Incompressible, steady and uniform turbulent flow in
bounded conduits
335
xii Contents
10.4
Incompressible,
steady and uniform turbulent flow in circular
cross-section pipes
338
10.5
Steady and uniform turbulent flow in open channels
342
10.6
Velocity distribution in turbulent, fully developed pipe flow
343
10.7
Velocity distribution in fully developed, turbulent flow in
open channels
352
10.8
Separation losses in pipe flow
352
10.9
Significance of the Colebrook-White equation in pipe and
duct design
359
10.10
Computer program CBW
362
Concluding remarks
362
Summary of important equations and concepts
363
Further reading
363
Problems
364
Chapter
11
Boundary Layer
366
1
1
.1
Qualitative description of the boundary layer
368
11.2
Dependence of pipe flow on boundary layer development at entry
370
11.3
Factors affecting transition from laminar to turbulent
flow regimes
371
11.4
Discussion of flow patterns and regions within the turbulent
boundary layer
372
11.5
Prandtl mixing length theory
374
11.6
Definitions of boundary layer thicknesses
377
11.7
Application of the momentum equation to a general section of
boundary layer
378
11.8
Properties of the laminar boundary layer formed over a flat plate in
the absence of a pressure gradient in the flow direction
379
11.9
Properties of the turbulent boundary layer over a flat plate in the
absence of a pressure gradient in the flow direction
384
11.10
Effect of surface roughness on turbulent boundary layer
development and skin friction coefficients
388
11.11
Effect of pressure gradient on boundary layer development
388
Concluding remarks
391
Summary of important equations and concepts
391
Further reading
392
Problems
392
Chapter
12
Incompressible Flow around a Body
394
12.1
Regimes of external flow
396
12.2
Drag
397
12.3
Drag coefficient and similarity considerations
401
12.4
Resistance of ships
403
12.5
Flow past a cylinder
407
12.6
Flow past a sphere
411
12.7
Flow past an infinitely long aerofoil
418
Contents xiii
12.8
Flow past an aerofoil of finite length
426
12.9
Wakes and drag
430
12.10
Computer program WAKE
435
Concluding remarks
436
Summary of important equations and concepts
436
Problems
436
Chapter
13
Compressible Flow around a Body
438
13.1
Effects of compressibility
440
13.2
Shockwaves
445
13.3
Oblique shock waves
455
13.4
Supersonic expansion and compression
457
13.5
Computer program NORSH
459
Concluding remarks
459
Summary of important equations and concepts
460
Problems
460
PART V STEADY FLOW IN PIPES, DUCTS AND OPEN CHANNELS
462
Chapter
14
Steady Incompressible Flow in Pipe and
Duct Systems
464
14.1
General approach
466
14.2
Incompressible flow through ducts and pipes
467
14.3
Computer program SIPHON
470
14.4
Incompressible flow through pipes in series
471
14.5
Incompressible flow through pipes in parallel
473
14.6
Incompressible flow through branching pipes. The three-reservoir
problem
475
14.7
Incompressible steady flow in duct networks
478
14.8
Resistance coefficients for pipelines in series and in parallel
486
14.9
Incompressible flow in a pipeline with uniform draw-off
490
14.10
Incompressible flow through a pipe network
490
14.11
Head balance method for pipe networks
491
14.12
Computer program
H
ARDYC
492
14.13
The quantity balance method for pipe networks
494
14.14
Quasi-steady flow
497
Concluding remarks
503
Summary of important equations and concepts
503
Further reading
504
Problems
504
Chapter
15
Uniform Flow in Open Channels
508
15.1
Flow with a free surface in pipes and open channels
510
15.2
Resistance formulae for steady uniform flow in open channels
512
xiv Contents
15.3 Optimum
shape of cross-section for uniform flow in open
channels
517
15.4
Optimum depth for flow with a free surface in covered channels
521
Concluding remarks
524
Summary of important equations and concepts
525
Further reading
525
Problems
526
Chapter
16
Non-uniform Flow in Open Channels
528
16.1
Specific energy and alternative depths of flow
530
16.2
Critical depth in non-rectangular channels
532
16.3
Computer program CRITNOR
534
16.4
Non-dimensional specific energy curves
535
16.5
Occurrence of critical flow conditions
536
16.6
Flow over a broad-crested weir
537
16.7
Effect of lateral contraction of a channel
538
16.8
Non-uniform steady flow in channels
541
16.9
Equations for gradually varied flow
542
16.10
Classification of water surface profiles
544
16.11
The hydraulic jump
547
16.12
Location of a hydraulic jump
549
16.13
Computer program CHANNEL
550
16.14
Annular water flow considerations
551
Concluding remarks
556
Summary of important equations and concepts
556
Further reading
557
Problems
558
Chapter
17
Compressible Flow in Pipes
560
17.1
Compressible flow. The basic equations
562
17.2
Steady isentropic flow in non-parallel-sided ducts neglecting
friction
563
17.3
Mass flow through
a venturi
meter
564
17.4
Mass flow from a reservoir through an orifice or
convergent-divergent nozzle
567
17.5
Conditions for maximum discharge from a reservoir through
a convergent-divergent duct or orifice
568
17.6
The Laval nozzle
569
17.7
Normal shock wave in
a
diffuser 573
17.8
Compressible flow in a duct with friction under adiabatic conditions.
Fanno
flow
578
17.9
Isothermal flow of a compressible fluid in a pipeline
582
Concluding remarks
585
Summary of important equations and concepts
586
Problems
586
Contents xv
PART
VI FLUID
MECHANICS FOR ENVIRONMENTAL CHANGE
588
Chapter
18
Environmental Change and Renewable
Energy Technologies
590
18.1
Environmental change
592
18.2
The application of wind turbines to electrical power generation
602
18.3
Wave energy conversion for electrical power generation
616
18.4
Tidal power
631
Concluding remarks
632
Summary of important concepts
633
Further reading
634
References
635
Chapter
19
Environmental Change and Rainfall Runoff
Flow Modelling
636
19.1
Gradually varied unsteady free surface flow
638
19.2
Computer program UNSCHAN
646
19.3
Implicit four-point scheme
648
19.4
Flood routeing
650
19.5
The prediction of flood behaviour
652
19.6
Time-dependent urban storm water routeing
657
19.7
Combined free surface and pressure surge analysis. Siphonic rainwater
systems
660
Concluding remarks
669
Summary of important equations and concepts
669
Further reading
670
References
670
PART
VII
UNSTEADY FLOW IN BOUNDED SYSTEMS
672
Chapter
20
Pressure Transient Theory and Surge Control
674
20.1
Wave propagation velocity and its dependence on pipe and
fluid parameters and free gas
682
20.2
Computer program WAVESPD
688
20.3
Simplification of the basic pressure transient equations
690
20.4
Application of the simplified equations to explain pressure
transient oscillations
690
20.5
Surge control
695
20.6
Control of surge following valve closure, with pump running and
surge tank applications
697
20.7
Computer program SHAFT
704
20.8
Control of surge following pump shutdown
706
Concluding remarks
711
Summary of important equations and concepts
711
xvi Contents
Further reading
712
Problems
714
Chapter
21
Simulation of Unsteady Flow Phenomena in Pipe,
Channel and Duct Systems
716
21.1
Development of the St
Venant
equations of continuity and motion
718
21.2
The method of characteristics
724
21.3
Network simulation
737
21.4
Computer program FM5SURG. The simulation of waterhammer
739
21.5
Computer programs FM5WAVE and FM5GUTT. The simulation
of open-channel free surface and partially filled pipe flow, with
and without lateral inflow
749
21.6
Simulation of low-amplitude air pressure transient propagation
755
21.7
Computer program FMSAIR. The simulation of unsteady air flow in
pipe and duct networks
756
21.8
Entrained air flow analysis review
760
Concluding remarks
763
Summary of important equations and concepts
764
Further reading
764
References
765
PART
VIII
FLUID MACHINERY. THEORY, PERFORMANCE AND
APPLICATION
766
Chapter
22
Theory of Rotodynamic Machines
768
22.1
Introduction
770
22.2
One-dimensional theory
772
22.3
Isolated blade and cascade considerations
780
22.4
Departures from Euler s theory and losses
788
22.5
Compressible flow through rotodynamic machines
794
Concluding remarks
798
Summary of important equations and concepts
798
Further reading
798
Problems
799
Chapter
23
Performance of Rotodynamic Machines
800
23.1
The concept of performance characteristics
802
23.2
Losses and efficiencies
803
23.3
Dimensionless coefficients and similarity laws
809
23.4
Computer program SIMPUMP
815
23.5
Scale effects
816
23.6
Type number
817
23.7
Centrifugal pumps and fans
820
Contents xvii
23.8 Axial
flow pumps and fans
822
23.9
Mixed flow pumps and fans
825
23.10
Water turbines
826
23.11
The Pelton wheel
827
23.12
Francis turbines
831
23.13
Axial flow turbines
836
23.14
Hydraulic transmissions
839
Concluding remarks
846
Summary of important equations and concepts
847
Problems
848
Chapter
24
Positive Displacement Machines
850
24.1
Reciprocating pumps
852
24.2
Rotary pumps
863
24.3
Rotary gear pumps
864
24.4
Rotary vane pumps
865
24.5
Rotary piston pumps
866
24.6
Hydraulic motors
868
Concluding remarks
868
Summary of important equations and concepts
869
Problems
870
Chapter
25
Machine-Network Interactions
872
25.1
Fans, pumps and fluid networks
874
25.2
Parallel and series pump operation
881
25.3
Fans in series and parallel
883
25.4
Fan and system matching. An application of the steady flow
energy equation
888
25.5
Change in the pump speed and the system
892
25.6
Change in the pump size and the system
895
25.7
Changes in fan speed, diameter and air density
897
25.8
Jet fans
900
25.9
Computer program MATCH
908
25.10
Cavitation in pumps and turbines
909
25.11
Fan and pump selection
914
25.12
Fan suitability
918
25.13
Ventilation and airborne contamination as a criterion for fan
selection
921
25.14
Computer program
CONTAM
929
Concluding remarks
931
Summary of important equations and concepts
932
Further reading
933
Problems
933
xviii Contents
Appendix 1
Some Properties of Common Fluids
938
Al
. 1
Variation of some properties of water with temperature
938
A
1.2
Variation of bulk modulus of elasticity of water with temperature
and pressure
939
Al
.3
Variation of some properties of air with temperature at
atmospheric pressure
939
A
1.4
Some properties of common liquids
939
A1.5 Some properties of common gases (at
ρ
= 1
atm, T=
273
K)
940
Al.
6
International Standard Atmosphere
940
A1.7 Solubility of air in pure water at various temperatures
941
Al
.8
Absolute viscosity of some common fluids
941
Appendix
2
Values of Drag Coefficient CD for Various
Body Shapes
942
Index
943
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| any_adam_object | 1 |
| author_GND | (DE-588)1157936652 (DE-588)172092736 |
| building | Verbundindex |
| bvnumber | BV035464307 |
| classification_rvk | UF 4000 |
| ctrlnum | (OCoLC)255595210 (DE-599)BVBBV035464307 |
| dewey-full | 620.106 |
| dewey-hundreds | 600 - Technology (Applied sciences) |
| dewey-ones | 620 - Engineering and allied operations |
| dewey-raw | 620.106 |
| dewey-search | 620.106 |
| dewey-sort | 3620.106 |
| dewey-tens | 620 - Engineering and allied operations |
| discipline | Physik |
| edition | 5. ed., [Nachdr.] |
| format | Book |
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| id | DE-604.BV035464307 |
| illustrated | Illustrated |
| indexdate | 2024-07-09T21:35:51Z |
| institution | BVB |
| isbn | 0131292935 9780131292932 |
| language | English |
| oai_aleph_id | oai:aleph.bib-bvb.de:BVB01-017384090 |
| oclc_num | 255595210 |
| open_access_boolean | |
| owner | DE-703 |
| owner_facet | DE-703 |
| physical | XXXIII, 958 S. Ill., graph. Darst. |
| publishDate | 2007 |
| publishDateSearch | 2007 |
| publishDateSort | 2007 |
| publisher | Pearson - Prentice Hall |
| record_format | marc |
| spelling | Fluid mechanics John F. Douglas ; Janusz M. Gasiorek ; John A. Swaffield ; Lynne B. Jack 5. ed., [Nachdr.] Harlow ; Munich [u.a.] Pearson - Prentice Hall 2007 XXXIII, 958 S. Ill., graph. Darst. txt rdacontent n rdamedia nc rdacarrier Strömungsmechanik - Lehrbuch Strömungsmechanik (DE-588)4077970-1 gnd rswk-swf Strömungsmechanik (DE-588)4077970-1 s DE-604 Douglas, John F. Sonstige (DE-588)1157936652 oth Gasiorek, J. M. 1927- Sonstige (DE-588)172092736 oth Swaffield, John A. Sonstige oth Jack, Lynne B. Sonstige oth Digitalisierung UB Bayreuth application/pdf http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=017384090&sequence=000002&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA Inhaltsverzeichnis |
| spellingShingle | Fluid mechanics Strömungsmechanik - Lehrbuch Strömungsmechanik (DE-588)4077970-1 gnd |
| subject_GND | (DE-588)4077970-1 |
| title | Fluid mechanics |
| title_auth | Fluid mechanics |
| title_exact_search | Fluid mechanics |
| title_full | Fluid mechanics John F. Douglas ; Janusz M. Gasiorek ; John A. Swaffield ; Lynne B. Jack |
| title_fullStr | Fluid mechanics John F. Douglas ; Janusz M. Gasiorek ; John A. Swaffield ; Lynne B. Jack |
| title_full_unstemmed | Fluid mechanics John F. Douglas ; Janusz M. Gasiorek ; John A. Swaffield ; Lynne B. Jack |
| title_short | Fluid mechanics |
| title_sort | fluid mechanics |
| topic | Strömungsmechanik - Lehrbuch Strömungsmechanik (DE-588)4077970-1 gnd |
| topic_facet | Strömungsmechanik - Lehrbuch Strömungsmechanik |
| url | http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=017384090&sequence=000002&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA |
| work_keys_str_mv | AT douglasjohnf fluidmechanics AT gasiorekjm fluidmechanics AT swaffieldjohna fluidmechanics AT jacklynneb fluidmechanics |