Fluid-structure interactions : slender structures and axial flow. Volume 2 /
The second of two volumes concentrating on the dynamics of slender bodies within or containing axial flow, Volume 2 covers fluid-structure interactions relating to shells, cylinders and plates containing or immersed in axial flow, as well as slender structures subjected to annular and leakage flows....
Clasificación: | Libro Electrónico |
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Autor principal: | |
Formato: | Electrónico eBook |
Idioma: | Inglés |
Publicado: |
Kidlington, Oxford, U.K. ; Waltham, Mass. :
Academic Press,
[2016]
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Edición: | 2nd edition. |
Temas: | |
Acceso en línea: | Texto completo |
Tabla de Contenidos:
- Front Cover; Fluid-Structure Interactions: Slender Structures and Axial Flow; Copyright; Contents; Preface to the First Edition; Preface to the Second Edition; Chapter 1: Cylindrical Shells Containing or Immersed in Flow: Advanced Topics and Applications; 1.1 Introductory Comments; 1.2 Coaxial Shells; 1.2.1 Vibrations of fluid-coupled coaxial shells; 1.2.2 Coaxial shells with supported ends subjected to flow; 1.2.2(a) Inviscid model; 1.2.2(b) Steady viscous effects; 1.2.2(c) Unsteady viscous effects; 1.2.2(d) Nonlinear effects; 1.2.2(e) Experiments.
- 1.2.3 Coaxial cantilevered shells subjected to flow1.2.3(a) Analytical model of Pa�idoussis, Nguyen & Misra; 1.2.3(b) Experiments; 1.2.3(c): CFD model of Nguyen et al.; 1.2.4 The leakage flow approximation; 1.2.5 Wave propagation and simplified stability theory; 1.2.6 Practical experiences; 1.2.7 Concluding remarks; 1.3 Swirling Flow and Rotofluidelasticity; 1.3.1 Introductory remarks and literature review; 1.3.2. Rotating shell conveying co-rotating fluid; 1.3.3 The Intense Neutron Generator system; 1.3.4 Boundary-layer effects for small Ro; 1.4 Turbulence-Induced Vibration.
- 1.4.1 General formulation1.4.2 Response to an arbitrary random pressure field; 1.4.3 Response to a boundary-layer pressure field; 1.4.4 Sample results; 1.4.5 The joint acceptance approach; 1.4.6 Concluding remarks; 1.5 Collapsible Tubes/Pliable Shells; 1.5.1 Introduction; 1.5.2 Pressure waves in horizontal systems; 1.5.3 Physiological systems; 1.5.4 Steady flow; 1.5.4(a) The Starling resistor; 1.5.4(b) Flow limitation and elastic jumps; 1.5.5 Flow-induced oscillation; 1.5.5(a) The physical characteristics of the oscillation; 1.5.5(b) Analytical models; 1.5.5(c) Chaotic oscillations.
- 1.5.5(d) Rational models sloshing, slamming, and other mechanisms; 1.5.6 Distensible tubes; 1.6 Other Applications; 1.6.1 General applications; 1.6.2 Internal-annular flow cases; 1.6.3 Aeronautical applications; 1.6.4 Shell-type Coriolis mass-flow meters; 1.6.5 Micro- and nanotube applications; 1.6.6 Sky dancers; Chapter 2: Cylinders in Axial Flow I; 2.1 Introduction; 2.2 Linear Equations of Motion; 2.2.1 General formulation; 2.2.2 Solitary cylinder in unconfined flow; 2.2.3 Cylinder in a cluster or in confined flow; 2.2.4 Boundary conditions; 2.2.5 Dimensionless parameters.
- 2.2.6 Similarities to internal flow2.2.7 Methods of solution; 2.2.7(a) Systems with classical boundary conditions; 2.2.7(b) Cantilevered system with tapered free end; 2.2.8 Numerical studies; 2.3 Linear Dynamics; 2.3.1 Linear dynamical behaviour; 2.3.1(a) Basic dynamics for cylinders with supported ends; 2.3.1(b) Basic dynamics for cantilevered cylinders; 2.3.1(c) Effect of system parameters; cylinders with supported ends; 2.3.1(d) Effect of system parameters; cantilevered cylinders; 2.3.1(e) Divergence of cantilevered cylinders; analytical solution; 2.3.1(f) Pinned-free cylinders.