Ivar KJELBERG
COMSOL Multiphysics(r) fan, retired, former "Senior Expert" at CSEM SA (CH)
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Posted:
1 decade ago
14 nov. 2011, 10:51 UTC−5
Hi
as your tube is free I see a rotating tube there and not really a mode, or ?
--
Good luck
Ivar
Hi
as your tube is free I see a rotating tube there and not really a mode, or ?
--
Good luck
Ivar
Please login with a confirmed email address before reporting spam
Posted:
1 decade ago
14 nov. 2011, 11:13 UTC−5
Dear Ivar,
Thank you so much for your comment. You are absolutely right, the way I defined it induces also a rigid rotations. I fixed it by fixing the two faces at the tube entrance/exit.
However, after fixing the problem the differences between time domain and frequency domain are left unchanged. You can see it from the displacement arrows in plots 1 and 4.
Do you see any other problems?
Many thanks,
Silviu.
Dear Ivar,
Thank you so much for your comment. You are absolutely right, the way I defined it induces also a rigid rotations. I fixed it by fixing the two faces at the tube entrance/exit.
However, after fixing the problem the differences between time domain and frequency domain are left unchanged. You can see it from the displacement arrows in plots 1 and 4.
Do you see any other problems?
Many thanks,
Silviu.
Ivar KJELBERG
COMSOL Multiphysics(r) fan, retired, former "Senior Expert" at CSEM SA (CH)
Please login with a confirmed email address before reporting spam
Posted:
1 decade ago
14 nov. 2011, 14:54 UTC−5
Hi
try to change the mesh size and observe the pattern change, then compare the pattern to the mesh size, you will notice that you have a nice correlation (in frequency mode),
what kind of oscillation do you expect at that frequency ? then make an estimation of the standing wavelength hence the mesh density, as you need some five 2nd order elements per period of your standing wave
If you want to identify the rotations, you have the "small angle values" defined as Thx=0.5[rad]*solid.curlUX, respectively ...UY and UZ for Thy and Thz
--
Good luck
Ivar
Hi
try to change the mesh size and observe the pattern change, then compare the pattern to the mesh size, you will notice that you have a nice correlation (in frequency mode),
what kind of oscillation do you expect at that frequency ? then make an estimation of the standing wavelength hence the mesh density, as you need some five 2nd order elements per period of your standing wave
If you want to identify the rotations, you have the "small angle values" defined as Thx=0.5[rad]*solid.curlUX, respectively ...UY and UZ for Thy and Thz
--
Good luck
Ivar
Please login with a confirmed email address before reporting spam
Posted:
1 decade ago
15 nov. 2011, 07:17 UTC−5
Dear Ivar,
Thanks for your reply.
I tried using denser grids (to the extent my PC allows) but still I get the same qualitative behavior. Moreover, if it is a grid issue, how come it seems to be qualitatively correct in the time domain and incorrect (or at least different) in the frequency domain, for the same mesh. Is there a different sensitivity to mesh density in the two computation modes?
Could you also elaborate some more about identifying rotations using "small angle values"?
Many thanks,
Silviu.
Dear Ivar,
Thanks for your reply.
I tried using denser grids (to the extent my PC allows) but still I get the same qualitative behavior. Moreover, if it is a grid issue, how come it seems to be qualitatively correct in the time domain and incorrect (or at least different) in the frequency domain, for the same mesh. Is there a different sensitivity to mesh density in the two computation modes?
Could you also elaborate some more about identifying rotations using "small angle values"?
Many thanks,
Silviu.
Ivar KJELBERG
COMSOL Multiphysics(r) fan, retired, former "Senior Expert" at CSEM SA (CH)
Please login with a confirmed email address before reporting spam
Posted:
1 decade ago
15 nov. 2011, 15:11 UTC−5
Hi
an eigenfrequency analysis gives infinte energy to all modes, a time analysis is "softer" as you are driving it, and a frequency domin analysis is a harmonic development of the equations. All slightly different in the way modes and their energy might interact.
But have you anaysed by hand what you expect as twist modes, for these dimensions and material(s) ? It's always necesary to check and validate your model by some simple analytical checks.
And to make the model "lighter", if it's a "thin tube" you could consider to use a "shell tube" in "shell physics, or even a 2D-axi model, but then you restrict yourself only to 2d-axi symmetric modes, the other dissappear by design, which might not be what you want ;) be aware that shell physics has more and other dependent variables than solid
--
Good luck
Ivar
Hi
an eigenfrequency analysis gives infinte energy to all modes, a time analysis is "softer" as you are driving it, and a frequency domin analysis is a harmonic development of the equations. All slightly different in the way modes and their energy might interact.
But have you anaysed by hand what you expect as twist modes, for these dimensions and material(s) ? It's always necesary to check and validate your model by some simple analytical checks.
And to make the model "lighter", if it's a "thin tube" you could consider to use a "shell tube" in "shell physics, or even a 2D-axi model, but then you restrict yourself only to 2d-axi symmetric modes, the other dissappear by design, which might not be what you want ;) be aware that shell physics has more and other dependent variables than solid
--
Good luck
Ivar
Please login with a confirmed email address before reporting spam
Posted:
1 decade ago
16 déc. 2011, 05:22 UTC−5
Hi
an eigenfrequency analysis gives infinte energy to all modes, a time analysis is "softer" as you are driving it, and a frequency domin analysis is a harmonic development of the equations. All slightly different in the way modes and their energy might interact.
But have you anaysed by hand what you expect as twist modes, for these dimensions and material(s) ? It's always necesary to check and validate your model by some simple analytical checks.
And to make the model "lighter", if it's a "thin tube" you could consider to use a "shell tube" in "shell physics, or even a 2D-axi model, but then you restrict yourself only to 2d-axi symmetric modes, the other dissappear by design, which might not be what you want ;) be aware that shell physics has more and other dependent variables than solid
--
Good luck
Ivar
Hi Ivar,
I've just started working on the acoustic domain.
I'm stuck at a simple and elementary problem.
The model has a point source at the center with spherical wave radiation as a boundary condition.
I'm checking the polar plots for the sound levels at different distances from the point source.
Expected results would have concentric pressure level polar plots at different radii.
The model does not show that. I've attached the model in this post.
I'm quite confused and lost at this moment.
Am i missing a boundary condition or is my post processing at fault.
Any kind of response will be of great help.
Thanks a lot for your time and effort.
Regards
Glenston
[QUOTE]
Hi
an eigenfrequency analysis gives infinte energy to all modes, a time analysis is "softer" as you are driving it, and a frequency domin analysis is a harmonic development of the equations. All slightly different in the way modes and their energy might interact.
But have you anaysed by hand what you expect as twist modes, for these dimensions and material(s) ? It's always necesary to check and validate your model by some simple analytical checks.
And to make the model "lighter", if it's a "thin tube" you could consider to use a "shell tube" in "shell physics, or even a 2D-axi model, but then you restrict yourself only to 2d-axi symmetric modes, the other dissappear by design, which might not be what you want ;) be aware that shell physics has more and other dependent variables than solid
--
Good luck
Ivar
[/QUOTE]
Hi Ivar,
I've just started working on the acoustic domain.
I'm stuck at a simple and elementary problem.
The model has a point source at the center with spherical wave radiation as a boundary condition.
I'm checking the polar plots for the sound levels at different distances from the point source.
Expected results would have concentric pressure level polar plots at different radii.
The model does not show that. I've attached the model in this post.
I'm quite confused and lost at this moment.
Am i missing a boundary condition or is my post processing at fault.
Any kind of response will be of great help.
Thanks a lot for your time and effort.
Regards
Glenston