Fluid-structure interaction (FSI) is the interaction of some movable or deformable structure with an internal or surrounding fluid flow. This book covers the fundamentals and mechanisms giving rise to flow-induced vibration, with a particular focus on the challenges associated with pipes conveying fluid.
Fluid-structure interaction (FSI) is the interaction of some movable or deformable structure with an internal or surrounding fluid flow. This book covers the fundamentals and mechanisms giving rise to flow-induced vibration, with a particular focus on the challenges associated with pipes conveying fluid.
Michael Païdoussis is the Thomas Workman Emeritus Professor of Mechanical Engineering at McGill University and a Fellow of the Canadian Society for Mechanical Engineering (CSME), the Institution of Mechanical Engineers (IMechE), the American Society of Mechanical Engineers (ASME), the Royal Society of Canada, the Canadian Academy of Engineering and the American Academy of Mechanics (AAM). He is the Founding Editor of the Journal of Fluids and Structures, as of 1986. He has won the ASME Fluids Engineering Award in 1999 and the CANCAM prize in 1995. His principal research interests are in fluid-structure interactions, flow-induced vibrations, aero- and hydroelasticity, dynamics, nonlinear dynamics and chaos, all areas in which he is recognized as a leading expert.
Inhaltsangabe
1. Concepts, Definitions and Methods2. Pipes Conveying Fluid: Linear Dynamics I3. Pipes Conveying Fluid: Linear Dynamics II4. Pipes Conveying Fluid: Nonlinear and Chaotic Dynamics5. Curved Pipes Conveying Fluid6. Cylindrical Shells Containing or Immersed in Flow: Basic Dynamics Appendix A: A First-Principles Derivation of the Equation of Motion of a Pipe Conveying FluidAppendix B: Analytical Evaluation of bsr, csr and dsr Appendix C: Destabilization by Damping: T. Brooke Benjamin's WorkAppendix D: Experimental Methods for Elastomer PipesAppendix E: Timoshenko Equations of Motion and Associated AnalysisAppendix F: Some of the Basic Methods for Nonlinear DynamicsAppendix G: Newtonian Derivation of Nonlinear Equations of Motion of a pipe Conveying FluidAppendix H: Nonlinear Dynamics Theory Applied to a Pipe Conveying FluidAppendix I: The Fractal Dimension from the Experimental Pipe-Vibration SignalAppendix J: Detailed Analysis for the Derivation of the Equations of Motion of Chapter 6Appendix K: Matrices for the Analysis of an Extensible Curved Pipe Conveying FluidAppendix L: Matrices in Hybrid Analytical/Finite-Element Method of Lakis et al. Appendix M: Anisotropic ShellsAppendix N: Nonlinear Motions of a Shell Conveying Fluid
1. Concepts, Definitions and Methods2. Pipes Conveying Fluid: Linear Dynamics I3. Pipes Conveying Fluid: Linear Dynamics II4. Pipes Conveying Fluid: Nonlinear and Chaotic Dynamics5. Curved Pipes Conveying Fluid6. Cylindrical Shells Containing or Immersed in Flow: Basic Dynamics Appendix A: A First-Principles Derivation of the Equation of Motion of a Pipe Conveying FluidAppendix B: Analytical Evaluation of bsr, csr and dsr Appendix C: Destabilization by Damping: T. Brooke Benjamin's WorkAppendix D: Experimental Methods for Elastomer PipesAppendix E: Timoshenko Equations of Motion and Associated AnalysisAppendix F: Some of the Basic Methods for Nonlinear DynamicsAppendix G: Newtonian Derivation of Nonlinear Equations of Motion of a pipe Conveying FluidAppendix H: Nonlinear Dynamics Theory Applied to a Pipe Conveying FluidAppendix I: The Fractal Dimension from the Experimental Pipe-Vibration SignalAppendix J: Detailed Analysis for the Derivation of the Equations of Motion of Chapter 6Appendix K: Matrices for the Analysis of an Extensible Curved Pipe Conveying FluidAppendix L: Matrices in Hybrid Analytical/Finite-Element Method of Lakis et al. Appendix M: Anisotropic ShellsAppendix N: Nonlinear Motions of a Shell Conveying Fluid
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