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Acoustic-structure interaction (acsl) with preload

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Hello,

I'm having some trouble calculating the (plane wave) sound transmission through a preloaded metal disc.
Without preloading, this can simply be solved by using "Acoustic-structure interaction" physics.
However, I don't manage to calculate the static solution resulting from a face load on my disc. If I add a face load in acsl and use the static solver the deflection of the structure is simply zero, so it makes no sense to use it as "linearization point" in the time harmonic solver.

Does the static solver work with acsl at all?

If I do a similar thing (simply the metal disc) using only "solid mechanics", everything works fine:
I calculate the static solution (having checked "Include geometric nonlinearity" in the linear elastic model), store it and then use it, for example, in the Eigenfrequency solver. And, as one shall expect, pretension increses the resonance frequencies.

I already tried to do the static case with solid mechanics physics, store the solution and use it as an input to acsl, but is has no effect at all.

As this seems to be a rather common type of problem (at least for an acoustitian) I wonder if anybody knows a solution ...




0 Replies Last Post 19.01.2011, 08:35 GMT-5
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Hello Roland Kruse

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