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Is it possible to model MAGNETOSTRICTIVE materials in comsol, just like for the piezoelectric materials?
Posted 6 nov. 2015, 18:55 UTC−5 Low-Frequency Electromagnetics, MEMS & Nanotechnology, Acoustics & Vibrations, MEMS & Piezoelectric Devices, Materials, Modeling Tools & Definitions, Parameters, Variables, & Functions, Studies & Solvers, Structural Mechanics Version 4.4, Version 5.0, Version 5.1 8 Replies
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In comsol, there are predefined models for the piezoelectric materials. For magnetostrictive materials, they have similar properties as the piezoelectric counterparts. However, a predefined physics for them is not available till today. Implementing the strong coupling magneto-mechanical relationship seems to be not easy. Does anyone have experience on this topic? Could you please share your skills on the magnetostrictive modeling using comsol?
For the modelers at comsol, could you please give some instructions?
Thank you very much.
A.R.
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Good luck!
--
Pu, ZHANG
DTU Fotonik
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You can find an example in our Application Gallery:
www.comsol.com/model/nonlinear-magnetostrictive-transducer-6063
Regards,
Henrik
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Thank you very much for your reply. It was a nice example. Still, I have another few questions for the magnetostrictive implementation.
Let's say the magnetostrictive model is linear and can be governed by the following constitutive equations:
{S} = [c(H,T)] {T} + [d(H,T)]^t {H} ---------- (1)
{B} = [d(H,T)] {T} + [mu(H,T)] {H} ---------- (2)
where {S} is the mechanical strain, {B} magnetic flux density, {T} mechanical stress, {H} magnetic field density. [c] is compliance matrix, [d] magneto-mechanical coupling matrix, [mu] permeabilities. [*]^t denotes a transpose.
In the example you have introduced, we can implement Eq.(1). If I have well understood, it works as follows:
1) define new variables 'Lambda' in the Definitions section
2) in the Solid Mechanics -> under Linear Elastic Materials, create a initial stress and strain node and put Lambda into the initial strain tables.
Though, the example is for an axisymmetric case, I suppose for an ordinary 3D case, it works the same way.
Then, how about implementing the Eq.(2) ? Will there be some special details to pay attention to when the strong coupling is added? e.g. some settings in the solver or something like that so as to accelerate the calculations.
I would be very grateful if you could provide me with more instructions.
Regards,
A.R.
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I am postdoc researcher from the Ohio State University. Our group led by Prof. Dapino has been working on model magnetostrictive materials using COMSOL for more than 8 years. There are multiple methods to model magnetostrictive materials in COMSOL:
1) If you would like to model the fully-coupled, 3D, hysteretic behavior, please refer to
jim.sagepub.com/content/early/2014/02/20/1045389X14521703.abstract
iopscience.iop.org/article/10.1088/0964-1726/20/10/105034/meta
However, these models require COMSOL 3.5a and are not efficient enough for parameter optimization.
2) If your magnetostriction and magnetization are along the same direction, please refer to
iopscience.iop.org/article/10.1088/0964-1726/24/12/125019/pdf
This model is very accurate and efficient. I recently developed another model that incorporates mechanical, magnetic, and electrical dynamics. You could attach electrical circuit to the magnetostrictive system in COMSOL. That paper is in print now, I could send you a link whenever it becomes available.
Dan
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Starting with version 5.2a, magnetostrictive materials are available right out of the box if your license includes the AC/DC Module along with either the Structural Mechanics Module, MEMS Module, or Acoustics Module.
For a starting point on this topic, please read the release highlights:
www.comsol.com/release/5.2a/structural-mechanics-module
Best regards,
Jeff
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Hi Amine,
I am postdoc researcher from the Ohio State University. Our group led by Prof. Dapino has been working on model magnetostrictive materials using COMSOL for more than 8 years. There are multiple methods to model magnetostrictive materials in COMSOL:
1) If you would like to model the fully-coupled, 3D, hysteretic behavior, please refer to
jim.sagepub.com/content/early/2014/02/20/1045389X14521703.abstract
iopscience.iop.org/article/10.1088/0964-1726/20/10/105034/meta
However, these models require COMSOL 3.5a and are not efficient enough for parameter optimization.
2) If your magnetostriction and magnetization are along the same direction, please refer to
iopscience.iop.org/article/10.1088/0964-1726/24/12/125019/pdf
This model is very accurate and efficient. I recently developed another model that incorporates mechanical, magnetic, and electrical dynamics. You could attach electrical circuit to the magnetostrictive system in COMSOL. That paper is in print now, I could send you a link whenever it becomes available.
Dan
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We can talk more about it
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