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Application of Fluid-Structure Interaction Algorithms to Seismic Analysis Zuhal OZDEMIR, Mhamed SOULI Université des Sciences et Technologies de Lille Laboratoire de Mécanique de Lille University of Bosphor, Istanbul GDR IFS 3 - 4 Juin 2010 UTC Compiegne Outline of the Presentation General Objective of the Studies Carried out on Tanks Difficulties in the Analysis of Tanks Analysis Methods for Tanks Fluid-Structure Interaction for Tank Problems 2D Rigid Tank 3D Flexible Tank General Objective of the Studies Carried out on Tanks - Limit the tank damages observed during earthquakes - Determine the response parameters in order to take precautions - sloshing wave height (freeboard) - uplift displacement (flexible attachments for pipes) Difficulties in the Analysis of Tanks - Three different domains * Structure * Fluid * Soil - Material and geometric nonlinearities - Complex support condition * Anchored * Unanchored General Performance of Tanks during Earthquakes - Violent sloshing which causes damage at the tank wall and shell - Large amplitude wall deformations (Buckling) - High plastic deformation at the tank base Sloshing damage Tank Shell Buckling Elephant-Foot Buckling (Elasto-Plastic Buckling) Diamond Shape Buckling (Elastic Buckling) Analysis Methods for Tanks - Simplified Analytical Methods Fluid : Laplace equation 2 0 Irrotational flow, incompressible and inviscid fluid (potantiaql flow theory) Structure : rigid tank Spring-Mass Equivalent Analogue k5 / 2 M5 k3 / 2 M3 k1 / 2 M1 k5 / 2 k3 / 2 k1 / 2 M0 h3 h1 h0 h5 Base Shear and Overturning Moment Ordinary Beam Theory Shell Stresses (Axial Compressive and Hoop) Most of the provisions recommended in the current tank design codes employ a modified version of Housner’s method Fluid-Structure Interaction for Tank Problems Structure Lagrangian Formulation Fluid Dynamic Structure equation dv div ( ) f dt Navier Stokes equations in ALE Formulation 2D Tank Problem width = 57 cm height = 30 cm Hwater= 15 cm Sinusoidal harmonic motion non-resonance case resonance case The sketch of the 2D sloshing experiment (Liu and Lin, 2008) 2n g (2 n 1) (2 n 1) tanh 2a 2a o = 6.0578 rad/s h 2D Tank Problem Lagrangian 2D Tank Problem non-resonance case amplitude = 0.005 m = 0.583 o resonance case amplitude = 0.005 m = 1 o 3D Tank Problem Cylindrical tank size: - radius of 1.83 m - a total height of 1.83 m - filled up to height of 1.524 m 3 Maximum ground acceleration = 0.5 g in horizontal direction (El Centro Earthquake record scaled with 3 ) Large mesh Deformation Large mesh Deformation Lagrangian Method Coupling Method Fluid Structure Coupling 2) Euler Lagrange Coupling Structure Fluid Up Lift for sloshing Tank 3D Tank Problem Comparisons of the time histories of pressure for the numerical method and experimental data 3D Tank Problem Comparisons of the time histories of pressure for the numerical method and experimental data 3D Tank Problem Comparisons of the time histories of surface elevation for the numerical method and experimental data 3D Tank Problem Comparisons of the time histories of tank base uplift for the numerical method and experimental data Conclusions (1) ALE algorithm lead highly consisted results with the experimental data in terms of peak level timing, shape and amplitude of pressure and sloshing. (2) Method gives reliable results for every frequency range of external excitation. (3) ALE method combined with/without the contact algorithms can be utilized as a design tool for the seismic analysis of rigid and flexible liquid containment tanks. (4) As a further study, a real size tank will be analysed Merci Analysis Methods for Tanks (cond) - Numerical Methods * 2D finite difference method * FEM * BEM * Volume of fluid technique (VOF) FEM is the best choice, because -structure, fluid and soil can be modelled in the same system -proper modelling of contact boundary conditions -nonlinear formulation for fluid and structure -nonlinear formulation for fluid and structure interaction effects 3D Tank Problem Pressure distribution inside the tank Analysis Methods for Tanks (cond) - Experimental Methods * Static tilt tests * Shaking table tests Schematic view of static tilt test A cylindrical tank mounted on the shaking table 3D Tank Problem Change of free surface in time 3D Tank Problem Von Mises stresses on the anchored tank shell 3D Tank Problem Von Mises stresses on the unanchored tank shell (displacements magnified 10 times) 2D Tank Problem ALE 2D Tank Problem width = 57 cm height = 30 cm Hwater= 15 cm Sinusoidal harmonic motion non-resonance case resonance case The sketch of the 2D sloshing experiment (Liu and Lin, 2008) 2n g (2 n 1) (2 n 1) tanh 2a 2a o = 6.0578 rad/s h