Jeff Hiller
COMSOL Employee
Please login with a confirmed email address before reporting spam
Posted:
8 years ago
15 juil. 2016, 09:35 UTC−4
Hello Lauren,
You will find more information on s1 and s2 in the Reference Manual, version 5.2a, page 257. As that page says,
"The surface parameters s1 and s2 in 3D are available on boundaries (faces). They can be difficult
to use because the relationship between x, y, and z (the spatial coordinates) and s1 and s2 is
nonlinear. Often it is more convenient to use expressions with x, y, and z for specifying distributed
boundary conditions. To see the values of s1 and s2, plot them using a surface plot."
Reading between the lines of your post, I understand that in 3D your channel is a cylinder and your inlet is a disc. If that disc is in the x,y plane and centered at x0,y0,0, you could simply use an expression along the lines of U0*(1-((x/x0)^2+(y/y0)^2)). Alternatively, you could define an additional, cylindrical coordinate system with its origin at x0,y0,0, and use an expression along the lines of U0*(1-(sys2.r/Radius)^2), as illustrated in the attached file (I cleared the solution to make the file small enough to post, so you'll need to compute the model to see the results).
Best,
Jeff
Hello Lauren,
You will find more information on s1 and s2 in the Reference Manual, version 5.2a, page 257. As that page says,
"The surface parameters s1 and s2 in 3D are available on boundaries (faces). They can be difficult
to use because the relationship between x, y, and z (the spatial coordinates) and s1 and s2 is
nonlinear. Often it is more convenient to use expressions with x, y, and z for specifying distributed
boundary conditions. To see the values of s1 and s2, plot them using a surface plot."
Reading between the lines of your post, I understand that in 3D your channel is a cylinder and your inlet is a disc. If that disc is in the x,y plane and centered at x0,y0,0, you could simply use an expression along the lines of U0*(1-((x/x0)^2+(y/y0)^2)). Alternatively, you could define an additional, cylindrical coordinate system with its origin at x0,y0,0, and use an expression along the lines of U0*(1-(sys2.r/Radius)^2), as illustrated in the attached file (I cleared the solution to make the file small enough to post, so you'll need to compute the model to see the results).
Best,
Jeff
Please login with a confirmed email address before reporting spam
Posted:
8 years ago
21 juil. 2016, 07:05 UTC−4
Hi Jeff,
Thanks for this, it has been very helpful!
My disc is actually in the x,z plane so would an expression of the form U0*(1-((x/x0)^2+(y/y0)^2)+(z/z0)^2)) work? If I do it by setting up a cylindrical system I assume I will have to make some adjustments? The centre of the disc is x=0, y=0.014025, z=0.0172.
Many thanks,
Lauren
Hi Jeff,
Thanks for this, it has been very helpful!
My disc is actually in the x,z plane so would an expression of the form U0*(1-((x/x0)^2+(y/y0)^2)+(z/z0)^2)) work? If I do it by setting up a cylindrical system I assume I will have to make some adjustments? The centre of the disc is x=0, y=0.014025, z=0.0172.
Many thanks,
Lauren
Walter Frei
COMSOL Employee
Please login with a confirmed email address before reporting spam
Posted:
8 years ago
21 juil. 2016, 13:18 UTC−4
Hello Lauren,
Please also be aware that several of the COMSOL Modules come with a built-in Laminar Inflow (and Outflow) boundary conditions that will automatically set up the appropriate laminar velocity profile for any arbitrary cross-sectional shape.
The specification chart details this information:
www.comsol.com/products/specifications/fluid-flow/
The attached screenshot from that page shows the Modules that include this boundary condition.
If, on the other hand, you are working purely with the base COMSOL Multiphysics package then yes, you will need to manually set up the appropriate equations.
Best Regards,
Hello Lauren,
Please also be aware that several of the COMSOL Modules come with a built-in Laminar Inflow (and Outflow) boundary conditions that will automatically set up the appropriate laminar velocity profile for any arbitrary cross-sectional shape.
The specification chart details this information:
https://www.comsol.com/products/specifications/fluid-flow/
The attached screenshot from that page shows the Modules that include this boundary condition.
If, on the other hand, you are working purely with the base COMSOL Multiphysics package then yes, you will need to manually set up the appropriate equations.
Best Regards,