Finite Element Solution of Fluid- Structure Interaction Problems Gordon C. Everstine Naval Surface Warfare Center, Carderock Div. Bethesda, Maryland 20817.

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Presentation transcript:

Finite Element Solution of Fluid- Structure Interaction Problems Gordon C. Everstine Naval Surface Warfare Center, Carderock Div. Bethesda, Maryland May 2000

Everstine 5/18/002 Fluid-Structure Interaction Exterior Problems: Vibrations, Radiation and Scattering, Shock Response Interior Problems: Acoustic Cavities, Piping Systems

Everstine 5/18/003 Structural Acoustics

Everstine 5/18/004 Large-Scale Fluid-Structure Modeling Approaches Structure –Finite elements Fluid –Boundary elements –Finite elements with absorbing boundary Infinite elements ρc impedance –Doubly asymptotic approximations (shock) –Retarded potential integral equation (transient)

Everstine 5/18/005 Exterior Fluid Mesh 383,000 Structural DOF 248,000 Fluid DOF 631,000 Total DOF

Everstine 5/18/006 Structural-Acoustic Analogy

Everstine 5/18/007 Fluid-Structure Interaction Equations

Everstine 5/18/008 Fluid Finite Elements Pressure Formulation –E e = G e,  e =G e /c 2, G e arbitrary –Direct input of areas in K and M matrices Symmetric Potential Formulation –u z represents velocity potential –New unknown: q=  p dt (velocity potential) –G e =-1/ , E e = / ,  e =-1/(  c 2 ) –Direct input of areas in B (damping) matrix

Everstine 5/18/009 Finite Element Formulations of FSI + 3-variable formulations

Everstine 5/18/0010 Displacement Formulation Fundamental unknown: fluid displacement (3 DOF/point) Model fluid domain with elastic F.E. (e.g., elastic solids in 3-D, membranes in 2-D) Any coordinate systems; constrain rotations (DOF 456) Material properties (3-D): G e  0  E e =(6  )  c 2, e =½- ,  e = , where  =10 -4 Boundary conditions: –Free surface: natural B.C. –Rigid wall: u n =0 (SPC or MPC) –Accelerating boundary: u n continuous (MPC), slip Real and complex modes, frequency and transient response 3 DOF/point, spurious modes

Everstine 5/18/0011 Displacement Method Mode Shapes 0 Hz Spurious 1506 Hz Good 1931 Hz Spurious 1971 Hz Good

Everstine 5/18/0012 Helmholtz Integral Equations

Everstine 5/18/0013 Matrix Formulation of Fluid-Structure Problem

Everstine 5/18/0014 Spherical Shell With Sector Drive

Everstine 5/18/0015 Added Mass by Boundary Elements

Everstine 5/18/0016 Frequencies of Submerged Cylindrical Shell N=circumferential, M=longitudinal, L=radial (end)

Everstine 5/18/0017 Low Frequency F.E. Piping Model Beam model for pipe 1-D acoustic fluid model for fluid (rods) Two sets of coincident grid points Pipe and fluid have same transverse motion Elbow flexibility factors are used Adjusted fluid bulk modulus for fluid in elastic pipes E=B/[1+BD/E s t)] Arbitrary geometry, inputs, outputs Applicable below first lobar mode

Everstine 5/18/0018 Planar Piping System: Free End Response

Everstine 5/18/0019 Needs Link between CAD model and FE model Infinite elements Meshing (e.g., between hull and outer fluid FE surface Modeling difficulties (e.g., joints, damping, materials, mounts) Error estimation and adaptive meshing

Everstine 5/18/0020 References G.C. Everstine, "Structural Analogies for Scalar Field Problems," Int. J. Num. Meth. in Engrg., Vol. 17, No. 3, pp (March 1981). G.C. Everstine, "A Symmetric Potential Formulation for Fluid-Structure Interaction," J. Sound and Vibration, Vol. 79, No. 1, pp (Nov. 8, 1981). G.C. Everstine, "Dynamic Analysis of Fluid-Filled Piping Systems Using Finite Element Techniques," J. Pressure Vessel Technology, Vol. 108, No. 1, pp (Feb. 1986). G.C. Everstine and F.M. Henderson, "Coupled Finite Element/Boundary Element Approach for Fluid-Structure Interaction," J. Acoust. Soc. Amer., Vol. 87, No. 5, pp (May 1990). G.C. Everstine, "Prediction of Low Frequency Vibrational Frequencies of Submerged Structures," J. Vibration and Acoustics, Vol. 13, No. 2, pp (April 1991). G.C. Everstine, "Finite Element Formulations of Structural Acoustics Problems," Computers and Structures, Vol. 65, No. 3, pp (1997).