Henrik Sönnerlind
COMSOL Employee
Please login with a confirmed email address before reporting spam
Posted:
4 years ago
19 mai 2021, 02:24 UTC−4
The Linear Spring Dashpot (LSD) in DEM is a way to add flexibility and loss to the otherwise rigid interacting particles.
If you are actually modeling the deformations in the material coming into contact, for example with plastic dissipation (as with the Johnson-Cook material model) or with viscoelasticity (as in this example: https://www.comsol.com/model/impact-analysis-of-a-golf-ball-89461 ) , then the dissipative process is already accounted for, so it should not also be part of the contact condition as such.
This said, if you are going to model impact contact, you should use either the Penalty, dynamic or Augmented Lagrangian, dynamic method in the Contact node. Those methods include both a stiffness and a viscosity term, but they should be considered more as numerical tools. You could however also choose to view it as a type of distributed LSD.
-------------------
Henrik Sönnerlind
COMSOL
The Linear Spring Dashpot (LSD) in DEM is a way to add flexibility and loss to the otherwise rigid interacting particles.
If you are actually modeling the deformations in the material coming into contact, for example with plastic dissipation (as with the Johnson-Cook material model) or with viscoelasticity (as in this example: ) , then the dissipative process is already accounted for, so it should not also be part of the contact condition as such.
This said, if you are going to model impact contact, you should use either the *Penalty, dynamic* or *Augmented Lagrangian, dynamic* method in the *Contact* node. Those methods include both a stiffness and a viscosity term, but they should be considered more as numerical tools. You could however also choose to view it as a type of distributed LSD.
Please login with a confirmed email address before reporting spam
Posted:
4 years ago
20 mai 2021, 10:18 UTC−4
Updated:
4 years ago
20 mai 2021, 10:23 UTC−4
Hi Henrik!
Thank you very much for the comments, I will review my contact condition.
Although, I still have doubts about the formulation of the dynamics of the ball itself. I'm trying to simulate a free-fall of a rigid ball in a steel plate (which I set the plasticity material model). And I want to validate this model by measuring the indentation (plastic deformation) in the target plate.
However, by assigning a function that describes the ball movement, I am imposing the penetration depth (I am using a wave function for the ball). There is some other boundary condition that you recommend to simulate this case?
It is a similar simulation to Xuemei Wang's 2013 work ("Validation of Johnson-Cook plasticity and damage model using impact experiment").
Hi Henrik!
Thank you very much for the comments, I will review my contact condition.
Although, I still have doubts about the formulation of the dynamics of the ball itself. I'm trying to simulate a free-fall of a rigid ball in a steel plate (which I set the plasticity material model). And I want to validate this model by measuring the indentation (plastic deformation) in the target plate.
However, by assigning a function that describes the ball movement, I am imposing the penetration depth (I am using a wave function for the ball). There is some other boundary condition that you recommend to simulate this case?
It is a similar simulation to Xuemei Wang's 2013 work ("Validation of Johnson-Cook plasticity and damage model using impact experiment").
Henrik Sönnerlind
COMSOL Employee
Please login with a confirmed email address before reporting spam
Posted:
4 years ago
21 mai 2021, 02:40 UTC−4
I would suggest that you place the free ball just touching the plate, and assign an initial velocity. Then you let the contact condition and material model do the rest. You will probably have to do some experiments with tuning the contact parameters.
Remember to make use of any symmetries. If the impact is perpendicular to the plate, using 1/4 of the geometry should be sufficient. That will speed up the analysis by one order of magnitude.
-------------------
Henrik Sönnerlind
COMSOL
I would suggest that you place the free ball just touching the plate, and assign an initial velocity. Then you let the contact condition and material model do the rest. You will probably have to do some experiments with tuning the contact parameters.
Remember to make use of any symmetries. If the impact is perpendicular to the plate, using 1/4 of the geometry should be sufficient. That will speed up the analysis by one order of magnitude.