Note: This discussion is about an older version of the COMSOL Multiphysics® software. The information provided may be out of date.
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.
Flux continuity along inner boundary
Posted 2014年7月30日 GMT-4 08:15 Low-Frequency Electromagnetics Version 4.3b 1 Reply
Please login with a confirmed email address before reporting spam
COMSOL community,
I have a simple 2D square as my geometry and a circle within the square. The electrical conductivity inside the circle is different from the rest of the square.
I need to make ensure that there is flux continuity (i.e. current density is continuous) along the boundary of the inner circle c1/VE1. How do I do that?
I also need a finer mesh just along the inner boundary. How do I do that?
Model attached.
Thanks
Deepika
I have a simple 2D square as my geometry and a circle within the square. The electrical conductivity inside the circle is different from the rest of the square.
I need to make ensure that there is flux continuity (i.e. current density is continuous) along the boundary of the inner circle c1/VE1. How do I do that?
I also need a finer mesh just along the inner boundary. How do I do that?
Model attached.
Thanks
Deepika
1 Reply Last Post 2014年8月1日 GMT-4 11:42
Please login with a confirmed email address before reporting spam
Posted:
1 decade ago
If you put no boundary conditions at the edge of the inner circle there shoud be no net consumption or production of current there. Is that what you mean by flux continuity?
About the mesh: first do a physics-controled mesh that has the appropriate density for 'normal' areas. This will create a 'free triangular' subnode on the 'mesh' node. To this free triangular node, add a 'distribution' node, and select for this operation the edges of your circle. You can now use the settings of this node to separately play with the mesh density at your edge. Also, in the 'size' subnode of the 'mesh' node you can play with the 'maximum element growth rate' to tune how fast the mesh becomes coarser away from your edge.
About the mesh: first do a physics-controled mesh that has the appropriate density for 'normal' areas. This will create a 'free triangular' subnode on the 'mesh' node. To this free triangular node, add a 'distribution' node, and select for this operation the edges of your circle. You can now use the settings of this node to separately play with the mesh density at your edge. Also, in the 'size' subnode of the 'mesh' node you can play with the 'maximum element growth rate' to tune how fast the mesh becomes coarser away from your edge.