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El. knyga: Fluid Dynamics: Part 1: Classical Fluid Dynamics, Part 1, Classical Fluid Dynamics [Oxford Scholarship Online E-books]

(Professor, Department of Mathematics, Imperial College London), (Professor of Applied Mathematics, School of Mathematics, University of Manchester)
  • Formatas: 328 pages, 186 b/w illustrations
  • Išleidimo metai: 08-May-2014
  • Leidėjas: Oxford University Press
  • ISBN-13: 9780199681730
Kitos knygos pagal šią temą:
  • Oxford Scholarship Online E-books
  • Kaina nežinoma
Fluid Dynamics: Part 1: Classical Fluid Dynamics, Part 1, Classical Fluid DynamicsDidesnis paveikslėlis
  • Formatas: 328 pages, 186 b/w illustrations
  • Išleidimo metai: 08-May-2014
  • Leidėjas: Oxford University Press
  • ISBN-13: 9780199681730
Kitos knygos pagal šią temą:
Wiley OnlineMore info about Oxford Scholarship Online e-books
Partnerių interneto svetainė: http://www.oxfordscholarship.com/view/10.1093/acprof:oso/9780199681730.001.0001/acprof-9780199681730
This is the first book in a four-part series designed to give a comprehensive and coherent description of Fluid Dynamics, starting with chapters on classical theory suitable for an introductory undergraduate lecture course, and then progressing through more advanced material up to the level of modern research in the field.

The present Part 1 consists of four chapters. Chapter 1 begins with a discussion of Continuum Hypothesis, which is followed by an introduction to macroscopic functions, the velocity vector, pressure, density, and enthalpy. We then analyse the forces acting inside a fluid, and deduce the Navier-Stokes equations for incompressible and compressible fluids in Cartesian and curvilinear coordinates.

In Chapter 2 we study the properties of a number of flows that are presented by the so-called exact solutions of the Navier-Stokes equations, including the Couette flow between two parallel plates, Hagen-Poiseuille flow through a pipe, and Karman flow above an infinite rotating disk.

Chapter 3 is devoted to the inviscid incompressible flow theory, with particular focus on two-dimensional potential flows. These can be described in terms of the "complex potential", allowing the full power of the theory of functions of complex variables to be used. We discuss in detail the method of conformal mapping, which is then used to study various flows of interest, including the flows past Joukovskii aerofoils.

The final Chapter 4 is concerned with compressible flows of perfect gas, including supersonic flows. Particular attention is given to the theory of characteristics, which is used, for example, to analyse the Prandtl-Meyer flow over a body surface bend and a corner. Significant attention is also devoted to the shock waves. The chapter concludes with analysis of unsteady flows, including the theory of blast waves.
Introduction 1(3)
1 Fundamentals of Fluid Dynamics
4(91)
1.1 The Continuum Hypothesis
4(3)
1.2 Forces Acting on a Fluid
7(7)
1.2.1 Surface forces
8(5)
1.2.2 The concept of a fluid
13(1)
1.3 Thermodynamic Relations
14(12)
1.3.1 The First Law of Thermodynamics
19(4)
1.3.2 Enthalpy and entropy
23(2)
Exercises 1
25(1)
1.4 Kinematics of the Flow Field
26(15)
1.4.1 Eulerian approach
27(2)
1.4.2 Streamlines and pathlines
29(2)
1.4.3 Vorticity
31(2)
1.4.4 Circulation
33(1)
Exercises 2
34(2)
1.4.5 Rate-of-strain tensor
36(5)
1.5 Constitutive Equation
41(10)
Exercises 3
50(1)
1.6 Equations of Motion
51(10)
1.6.1 Continuity equation in Eulerian variables
51(2)
1.6.2 Momentum equation
53(5)
1.6.3 The energy equation
58(3)
1.7 The Navier--Stokes Equations
61(12)
1.7.1 Incompressible fluid flows
61(1)
1.7.2 Compressible fluid flows
62(5)
1.7.3 Integral momentum equation
67(2)
1.7.4 Similarity rules in fluid dynamics
69(3)
Exercises 4
72(1)
1.8 Curvilinear Coordinates
73(22)
Exercises 5
93(2)
2 Solutions of the Navier--Stokes Equations
95(34)
2.1 Exact Solutions
95(28)
2.1.1 Couette flow
95(3)
2.1.2 Poiseuille flow
98(2)
2.1.3 Hagen--Poiseuille flow
100(3)
2.1.4 Flow between two coaxial cylinders
103(2)
2.1.5 Impulsively started flat plate
105(5)
2.1.6 Dissipation of the potential vortex
110(3)
2.1.7 Karman flow
113(5)
Exercises 6
118(5)
2.2 Numerical Solutions
123(6)
2.2.1 Viscous flow past a circular cylinder
123(3)
2.2.2 Lid-driven cavity flow
126(3)
3 Inviscid Incompressible Flows
129(104)
3.1 Integrals of Motion
129(10)
3.1.1 Bernoulli integral
130(1)
3.1.2 Kelvin's Circulation Theorem
130(4)
3.1.3 Cauchy-Lagrange integral
134(1)
Exercises 7
135(4)
3.2 Potential Flows
139(13)
3.2.1 Potential flow past a sphere
145(3)
3.2.2 Virtual mass
148(4)
3.3 Two-Dimensional Flows
152(8)
3.3.1 Stream function
155(2)
Exercises 8
157(3)
3.4 Complex Potential
160(21)
3.4.1 Boundary-value problem for the complex potential
164(1)
3.4.2 Flow past a circular cylinder
165(5)
3.4.3 Force on a cylinder
170(4)
Exercises 9
174(7)
3.5 The Method of Conformal Mapping
181(16)
3.5.1 Mapping with a linear function
181(3)
3.5.2 Conformal mapping
184(1)
3.5.3 Mapping with the power function
185(1)
3.5.4 Linear fractional transformation
186(3)
3.5.5 Application to fluid dynamics
189(2)
3.5.6 Circular cylinder with an angle of attack
191(1)
Exercises 10
191(3)
3.5.7 Joukovskii transformation
194(3)
3.6 Flat Plate at an Incidence
197(4)
3.7 Joukovskii Aerofoils
201(9)
Exercises 11
205(5)
3.8 Free Streamline Theory
210(23)
3.8.1 Kirchhoff model
210(13)
3.8.2 Two-dimensional inviscid jets
223(6)
Exercises 12
229(4)
4 Elements of Gasdynamics
233(80)
4.1 General Properties of Compressible Flows
233(6)
4.1.1 Euler equations for gas flows
234(1)
4.1.2 Piston theory
235(4)
4.2 Integrals of Motion
239(11)
4.2.1 Bernoulli's integral
239(2)
4.2.2 Entropy conservation law
241(1)
4.2.3 Kelvin's Circulation Theorem
242(2)
4.2.4 Crocco's formula
244(1)
4.2.5 D'Alembert's paradox
245(2)
Exercises 13
247(3)
4.3 Steady Potential Flows
250(2)
4.3.1 Two-dimensional flows
251(1)
4.4 The Theory of Characteristics
252(20)
4.4.1 The method of characteristics
256(1)
4.4.2 Supersonic flows
257(6)
4.4.3 Prandtl--Meyer flow
263(3)
Exercises 14
266(6)
4.5 Shock Waves
272(13)
4.5.1 The shock relations
273(3)
4.5.2 Normal shock
276(3)
4.5.3 Oblique shocks
279(6)
4.6 Supersonic Flows past a Wedge and a Cone
285(7)
4.6.1 Flow past a wedge
285(1)
4.6.2 Flow past a circular cone
286(5)
Exercises 15
291(1)
4.7 One-Dimensional Unsteady Flows
292(13)
4.7.1 Expansion wave
293(3)
4.7.2 Compression flow
296(3)
4.7.3 Shock-tube theory
299(2)
Exercises 16
301(4)
4.8 Blast-Wave Theory
305(8)
References 313(2)
Index 315
Anatoly Ruban: 1972: Received 1st class degree in Physics from Moscow Institute of Physics and Technology (MPhTI) 1977: PhD in Physics and Mathematics from Central Aerohydrodynamic Institute (TsAGI), Moscow 1991: Degree of Doctor of Science in Physics and Mathematics from Computing Centre of the Russian Academy of Sciences 1975 - 1995: Employed by TsAGI, starting as Junior Research Scientist and progressing to Head of Department of Gas Dynamics 1978 - 1995: Teaching at MPhPI, first as Associate Professor and then (1993 - 1995) as Professor in the Department of Theoretical Aerohydrodynamics 1995 - 2008: Chair in Computational Fluid Dynamics, University of Manchester, School of Mathematics 2008 - present: Chair in Applied Mathematics and Mathematical Physics, Imperial College London, Department of Mathematics

Jitesh S.B. Gajjar: 1977: Received 1st Class Hons in Mathematics from Imperial College, London 1984: Received PhD from Mathematics Department, Imperial College, London 1983 - 1985: Research Scientist at British Maritime Technology, Teddington, UK 1985 - 1991: Lecturer in Mathematics Department at Exeter University 1991 - current: Mathematics Department, University of Manchester 2007 - current: Professor of Applied Mathematics, University of Manchester
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