Discussion Closed This discussion was created more than 6 months ago and has been closed. To start a new discussion with a link back to this one, click here.
point loads on amphora
Posted May 24, 2016, 10:57 a.m. EDT Geometry, Modeling Tools & Definitions, Parameters, Variables, & Functions, Studies & Solvers, Structural Mechanics Version 5.0 1 Reply
Please login with a confirmed email address before reporting spam
Hi,
We, students from TU Delft are currently busy with a materials engineering project on structure of ancient ceramics.
I would like to model an Amphora (imported from solidworks) positioned in between four other amphora.(see picture afbeelding stapeling contact punten 2.png) Because the amphora have point contacts, I need to model a Force on a curved surface, no edges nor plane surfaces. therefore I have made partitions so I can set a boundary on these small created domains (see picture comsol contact punten.png). I did this via Geometry -> Work plane -> Partition objects. After that I placed an equally distributed load on those small surfaces.
I was wondering:
- Since the amphora are symmetric, if there is a quicker way to place planes/make partitions? Or is there in general a faster way to do this? if so how?
- Is there a way I can place a normally distributed or gaussian load, so it is more representative as point load? if so how?
- Maybe there is another, much easier way to place point loads on curved surfaces? if so, what method?
Then I have a question about the physics. How should I set the boundaries to represent this amphora in this position. (stationary)
What I have know:
- I added gravity to the body. -g_const in y direction (the body is on it's side)
- I made the 4 lower contact points fixed. here I don't know if this is representative for leaning on 4 point loads. Should I replace this with equal forces perpendicular to the tangent on these points? and how do I do that?
- I put 4 equal forces to represent the weight of 4 amphora on top
(results see picture stress.png )
Comsol is not something we are very skillful with
waiting for response
Thank you
We, students from TU Delft are currently busy with a materials engineering project on structure of ancient ceramics.
I would like to model an Amphora (imported from solidworks) positioned in between four other amphora.(see picture afbeelding stapeling contact punten 2.png) Because the amphora have point contacts, I need to model a Force on a curved surface, no edges nor plane surfaces. therefore I have made partitions so I can set a boundary on these small created domains (see picture comsol contact punten.png). I did this via Geometry -> Work plane -> Partition objects. After that I placed an equally distributed load on those small surfaces.
I was wondering:
- Since the amphora are symmetric, if there is a quicker way to place planes/make partitions? Or is there in general a faster way to do this? if so how?
- Is there a way I can place a normally distributed or gaussian load, so it is more representative as point load? if so how?
- Maybe there is another, much easier way to place point loads on curved surfaces? if so, what method?
Then I have a question about the physics. How should I set the boundaries to represent this amphora in this position. (stationary)
What I have know:
- I added gravity to the body. -g_const in y direction (the body is on it's side)
- I made the 4 lower contact points fixed. here I don't know if this is representative for leaning on 4 point loads. Should I replace this with equal forces perpendicular to the tangent on these points? and how do I do that?
- I put 4 equal forces to represent the weight of 4 amphora on top
(results see picture stress.png )
Comsol is not something we are very skillful with
waiting for response
Thank you
1 Reply Last Post May 25, 2016, 2:28 a.m. EDT
Please login with a confirmed email address before reporting spam
Posted:
9 years ago
Dear Semih Yikilmaz,
I suggest you address your post directly to: support@comsol.com
Best regards,
François Mandias
I suggest you address your post directly to: support@comsol.com
Best regards,
François Mandias