Machine generated contents note: Foreword v Preface vii Images Credits ix 1 Fluid-Structure Interaction 1 1.1 A wide variety of problems 2 1.2 Analytical modelling of Fluid-Structure Interactions 3 1.2.1 Potential flow. Inertial coupling 4 1.2.2 Viscous flow. Viscous damping 8 1.2.3 Compressible flow. Radiation damping 10 1.3 Numerical simulation of Fluid-Structure Interactions 14 1.4 Finite element and boundary element methods 24 References 25 2 Structure Finite Elements 27 2.1 Vibrations of an elastic structure 28 2.1.1 Modelling assumptions 28 2.1.2 Equations of motion 36 2.2 Finite Element Method: practical implementation 38 2.2.1 Weighted integral formulation 38 2.2.2 Finite elements 40 2.2.3 Elementary matrices 43 2.2.4 Mass and stiffness matrices 44 2.2.5 Calculating and assembling matrices 49 2.2.6 Modal analysis 54 2.3 Example: bending modes 57 2.3.1 Bending motion of a straight elastic beam 57 2.3.2 Bernoulli beam elements 58 2.3.3 Bending modes 62 2.4 Example : coupled bending/membrane modes 66 2.4.1 Bending and membrane motion of a circular elastic ring 66 2.4.2 Fourier component representation: 0D element 67 2.4.3 Bending/membrane modes 69 References 79 3 Fluid Finite Elements 81 3.1 Fluid flow equations 82 3.2 Compressibility waves 91 3.2.1 Wave equation 91 3.2.2 Boundary conditions 95 3.3 Finite element method 103 3.3.1 Pressure-based formulation 103 3.3.2 Displacement-based formulations 108 3.3.3 Finite element matrices 111 3.4 Boundary element method 113 3.4.1 Green function and Green's integral theorem 113 3.4.2 Interior and exterior problems 114 3.4.3 Direct and indirect boundary element method 116 3.4.4 Boundary element matrices 120 3.5 Example: Sloshing modes 121 3.5.1 Circular reservoir with fluid free surface 121 3.5.2 2D axi-symmetric elements with gravity 124 3.5.3 Sloshing modes 126 3.6 Example: Acoustic modes in an open reservoir 128 3.6.1 Cylindrical acoustic opened cavity 128 3.6.2 2D axi-symmetric elements with compressibility 129 3.6.3 Acoustic modes 130 3.7 Example: Acoustic modes in a closed reservoir 132 3.7.1 Rectangular acoustic closed cavity 132 3.7.2 2D fluid elements with compressibility 134 3.7.3 Acoustic modes 134 3.8 Example: Acoustic radiation in infinite fluid 135 3.8.1 Pulsating ring in infinite acoustic fluid 135 3.8.2 1D axi-symmetric element with radiation condition 137 3.8.3 1D boundary elements 138 3.8.4 Acoustic radiation 141 References 146 4 Inertial Coupling 149 4.1 Mathematical modelling 150 4.2 Added mass matrix 152 4.2.1 Coupling matrix 152 4.2.2 Added mass matrix 154 4.2.3 Inertial effect 156 4.3 Modelling inertial coupling for complex systems: example of tube bundle 163 4.3.1 Analytical models for added mass 164 4.3.2 'Term-to-term' computation of the added mass matrix 164 4.3.3 A homogenisation technique 167 4.4 Examples : inertial effect in bounded domain 178 4.4.1 Analytical calculation of the added mass matrix 178 4.4.2 Numerical computation of the added mass matrix 185 4.5 Example: inertial effect in unbounded domain 191 4.5.1 Elastic ring immersed in a fluid 191 4.5.2 Finite element coupling with infinite element 194 References 200 5 Fluid-Structure Coupling 203 5.1 Modelling assumption 204 5.2 Interior problems: vibro-acoustic and hydro-elastic coupling 205 5.2.1 Non-symmetric formulation 205 5.2.2 Symmetric formulation 208 5.3 Exterior problem: vibro-acoustic 217 5.4 Example: vibro-acoustic coupling and hydro-elastic sloshing 223 5.5 Example: Acoustic damping 231 5.5.1 Analytical modelling 231 5.5.2 Numerical computation 235 References 245 6 Structural Dynamics with Fluid-Structure Interaction 247 6.1 Introduction 248 6.2 Time-domain analysis 250 6.2.1 Direct methods 250 6.2.2 Modal methods 261 6.3 Frequency-domain analysis 271 6.3.1 Direct and modal methods 271 6.3.2 Computation of the projection basis 273 6.4 Example: time-domain analysis 278 6.4.1 Accelerated cantilever beam with fluid coupling 278 6.4.2 System and excitation spectra 281 6.4.3 Seismic response: Direct and modal methods 283 6.5 Example: frequency-domain analysis 289 6.5.1 Acoustic radiation of a damped structure immersed in a fluid 289 6.5.2 Frequency response: Direct and modal methods 293 References 304 Index 307
Includes bibliographical references and index
Fluid-Structure Interaction -- A Wide Variety of Problems -- Analytical Modelling of Fluid-Structure Interactions -- Potential Flow. Inertial Coupling -- Viscous Flow. Viscous Damping -- Compressible Flow. Radiation Damping -- Numerical Simulation of Fluid-Structure Interactions -- Finite Element and Boundary Element Methods -- Structure Finite Elements -- Vibrations of an Elastic Structure -- Modelling Assumptions -- Equations of Motion -- Finite Element Method: Practical Implementation -- Weighted Integral Formulation -- Finite Elements -- Elementary Matrices -- Mass and Stiffness Matrices -- Calculating and Assembling Matrices -- Modal Analysis -- Example: Bending Modes -- Bending Motion of a Straight Elastic Beam -- Bernoulli Beam Elements: ID Element -- Bending Modes -- Example: Coupled Bending/Membrane Modes -- Bending and Membrane Motion of a Circular Elastic Ring -- Fourier Component Representation: 0D Element -- Bending/Membrane Modes -- Fluid Finite Elements -- Fluid Flow Equations -- Compressibility Waves -- Wave Equation -- Boundary Conditions -- Finite Element Method -- Pressure-Based Formulation -- Displacement-Based Formulations -- Finite Element Matrices -- Boundary Element Method -- Green Function and Green's Integral Theorem -- Interior and Exterior Problems -- Direct and Indirect Boundary Element Method -- Boundary Element Matrices -- Example: Sloshing Modes -- Circular Reservoir with Fluid-Free Surface -- 2D Axisymmetric Elements with Gravity -- Sloshing Modes -- Example: Acoustic Modes in an Open Reservoir -- Cylindrical Acoustic Opened Cavity -- 2D Axisymmetric Elements with Compressibility -- Acoustic Modes -- Example: Acoustic Modes in a Closed Reservoir -- Rectangular Acoustic Closed Cavity -- 2D Fluid Elements with Compressibility -- Acoustic Modes -- Example: Acoustic Radiation in Infinite Fluid -- Pulsating Ring in Infinite Acoustic Fluid -- 1D Axisymmetric Element with Radiation Condition -- ID Boundary Elements -- Acoustic Radiation -- Inertial Coupling -- Mathematical Modelling -- Added Mass Matrix -- Coupling Matrix -- Added Mass Matrix -- Inertial Effect -- Modelling Inertial Coupling for Complex Systems: Example of Tube Bundle -- Analytical Models for Added Mass -- 'Perm-to-Term' Computation of the Added Mass Matrix -- A Homogenisation Technique -- Examples: Inertial Effect in Bounded Domain -- Analytical Calculation of the Added Mass Matrix -- Numerical Computation of the Added Mass Matrix -- Example: Inertial Effect in Unbounded Domain -- Elastic Ring Immersed in a Fluid -- Finite Element Coupling with Infinite Element -- Fluid-Structure Coupling -- Modelling Assumption -- Interior Problems: Vibro-Acoustic and Hydro-Elastic Coupling -- Non-Symmetric Formulation -- Symmetric Formulation -- Exterior Problem: Vibro-Acoustic -- Example: Vibro-Acoustic Coupling and Hydro-Elastic Sloshing -- Example: Acoustic Damping -- Analytical Modelling -- Numerical Computation -- Structural Dynamics with Fluid-Structure Interaction -- Introduction -- Time-Domain Analysis -- Direct Methods -- Modal Methods -- Frequency-Domain Analysis -- Direct and Modal Methods -- Computation of the Projection Basis -- Example: Time-Domain Analysis -- Accelerated Cantilever Beam with Fluid Coupling -- System and. Excitation Spectra -- Seismic Response: Direct and Modal Methods -- Example: Frequency-Domain Analysis -- Acoustic Radiation of a Damped Structure Immersed in a Fluid -- Frequency Response: Direct and Modal Methods
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"Fulfills the need for an introductive approach to the general concepts of FSI from the mathematical formulation to the physical interpretation of numerical simulations. Based on the author's experience in developing numerical codes for industrial applications in shipbuilding and in teaching FSI to both practicing engineers and within academia, it provides a comprehensive and self-contained guide that is geared toward both students and practitioners of mechanical engineering"--