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Rotating fluids in engineering and science /
Invaluable for engineers and scientists whose projects require a knowledge of the theory. Part I reviews basic fluid mechanics. Part II introduces concepts, theories, and equations specific to rotating fluids, and Part III presents numerous practical applications of the theory, in fields ranging fro...
| Clasificación: | Libro Electrónico |
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| Autor principal: | |
| Formato: | Electrónico eBook |
| Idioma: | Inglés |
| Publicado: |
Mineola, N.Y. :
Dover Publications,
2001.
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| Temas: | |
| Acceso en línea: | Texto completo |
Tabla de Contenidos:
- Cover; Title Page; Copyright Page; Contents; Preface; Part I Fluid Mechanics Review; 1 Rotating Fluid Phenomena; 2 Mass and Momentum Conservation; 2.1 Eulerian Mechanics; 2.2 Mass Conservation; 2.3 Force and Momentum; 2.4 Navier-Stokes Equations; 2.5 Dimensionless Equations and Ratios; 3 Potential (Inviscid) Flow; 3.1 Bernoulli Equation; 3.2 Stream Functions and Velocity Potentials; 3.3 Flow Past a Circular Cylinder; 3.4 Pressure Components; 4 Boundary Layers and Turbulence; 4.1 Introduction and Two Solutions by Stokes; 4.2 Prandtl Boundary Layer Equations.
- 4.3 Flat Plate and Cylinder Solutions4.4 Momentum Integral Equation; 4.5 Turbulence and Stability; 5 Wave Theory; 5.1 Introduction and Definitions; 5.2 Longitudinal Waves; 5.3 Transverse Waves; 5.4 Mach Cones; Part II Rotating Fluid Theory; 6 Rotating Coordinate Systems; 6.1 Intermediate Reference Frames; 6.2 Fluids in a Rotating Frame; 6.3 Ekman and Rossby Numbers; 6.4 Application Examples; 7 Coriolis Phenomena; 7.1 Coriolis Forces vs. Accelerations; 7.2 Coriolis and Angular Momentum; 7.3 Coriolis Force-Acceleration Criteria; 7.4 Application Examples; 8 Rotation, Vorticity, and Circulation.
- 8.1 Rotation8.2 Vorticity; 8.3 Circulation and Stokes Theorem; 8.4 Application Examples; 9 Vorticity as the Variable; 9.1 Vorticity in Navier-Stokes Equations; 9.2 Viscous Production of Vorticity; 9.3 Relative Vorticity; 9.4 Application Examples; 10 Vortex Dynamics; 10.1 Vortex Interactions in Two Dimensions; 10.2 Conservation of Vorticity and Circulation; 10.3 The Formula of Biot and Savart; 10.4 Rankine's Combined Vortex; 10.5 Vortex Intensification by Stretching; 10.6 Application Examples; 11 Secondary Flows; 11.1 Boundary Layer Review; 11.2 A Rotating Disk in a Stationary Fluid.
- 11.3 A Rotating Fluid above a Stationary Surface11.4 Enclosed Secondary Flows; 11.5 Application Examples; 12 Circular Pathline Flows; 12.1 Theoretical Criteria; 12.2 Some Important Flows; 12.3 Application Examples; 13 Rotation and Inertial Waves; 13.1 Rayleigh Instability; 13.2 Stability of Circular Pathline Flows; 13.3 Rossby Waves and Inertial Waves; 13.4 Atmospheric Rossby Waves I; 13.5 Instability and Turbulence; 13.6 Application Examples; Part III Rotating Fluid Applications; 14 Pipes, Channels, and Rivers; 14.1 Swirl in Straight Sections; 14.2 Secondary Flow in Curved Sections.
- 14.3 River Meandering14.4 Abutment Undercutting; 14.5 Ştudy and Research Projects; 15 Rotors and Centrifuges; 15.1 Thin Disk in a Housing; 15.2 Flow in a Cylindrical Annulus; 15.3 Centrifuges; 15.4 Cyclone Separators; 15.5 Study and Research Projects; 16 Wings, Lift, and Drag; 16.1 Circulation and Lift (Inviscid); 16.2 Circulation and Lift (Viscous); 16.3 Kutta-Zhukowskii Theory; 16.4 Finite Wings and Vortices; 16.5 Vertical Momentum and Induced Drag; 16.6 Study and Research Projects; 17 Turbomachinery; 17.1 Definitions and Classifications; 17.2 Internal Flow Characteristics.