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Shock-induced vibrations of a beam-like panel

This example is intended as a verification test for AMROC-SFC. It repeats the calculation of Shock-induced Beam Vibrations in with SFC. The computation is carried out in 3D, but panel and fluid domain are very shallow to ensure beam-like structural behavior.

  • SFC mesh of thin panel: 352 elements SFC mesh of thin panel

Numerical simulations

  • Three-dimensional Euler equations, shock wave of M=1.21 in air at rest (\gamma=1.4, 100kPa, 293K)
  • Hybrid Roe-HLL Riemann solver, MUSCL reconstruction with Minmod limiter, dimensional splitting
  • Source code: [fluid codes] [solid codes]

Fluid-structure interaction verification

  • Apply instantaneous, constant pressure difference of 100kPa along entire beam, no dynamic fluid interaction (Beam)
  • Compare tip displacement with FSI simulations for beam solver and plate strip in SFC with initial condition of 100kPa pressure difference Verification beam solver and SFC

Fluid-structure interaction results with fully dynamic impact

  • Fluid domain: 0.4m x 0.08m x 0.005m, AMR base mesh 320x64x2 cells, 2 additional levels with refinement factors 2, 2. Forward facing step geometry with step of 0.015m height and 0.265m length. Reflective boundaries everywhere except left boundary (inflow).
  • 322h CPU on 8 nodes with Intel 3.4GHz Xeon dual processors connected with Gigabit Ethernet (7 fluid nodes + 1 solid node), 4500 coupled time steps, expense for level set evaluation 0.74% of overall run-time
  • Comparison of tip displacement with beam solver and SFC plate strip for beam of 50mm length Tip displacement beam / SFC, 50mm
  • Tracks of fluid pressure 0.01m before beam at upper boundary. Pressure difference is roughly 100kPa. Beam length 50mm. pressure tracks, 50mm

-- RalfDeiterding - 12 Jul 2007

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