Eng-Tips is the largest engineering community on the Internet
Intelligent Work Forums for Engineering Professionals
-
Congratulations waross on being selected by the Tek-Tips community for having the most helpful posts in the forums last week. Way to Go!
"Total Load at Point"
- Thread starter ysm
- Start date
- Thread starter
- #3
While using Total Load at Point you select a surface and a point. Through this option one can indicate to the software to apply a load on the selected surface which is statically equivalent to the resultant load at the specified point.
The point does not have to be with in the model. It does not have to have material or any geometry associated with it.
Thanks
ysm
The point does not have to be with in the model. It does not have to have material or any geometry associated with it.
Thanks
ysm
Composites_FEA_Guru
Aerospace
ysm,
There are many options for achieving the loading you describe. You can use Kinematic Coupling Constraints, Rigid Body Constraints, Equation Constraints, ... (there may be more).
I like to use Equation Constraints. In this case you define two node sets on the surface you want to apply a concentrated force on. One node set is a single node (driver node) and the other is every other node on that surface except for the driver node (slave nodes). Now you can define an Equation Constraint so that the load application direction D.O.F. of the driver node is equivalent to all the same D's.O.F of the slave nodes. Then simply apply a concentrated force to the driver node and you're set.
Hope this helps,
-CM
There are many options for achieving the loading you describe. You can use Kinematic Coupling Constraints, Rigid Body Constraints, Equation Constraints, ... (there may be more).
I like to use Equation Constraints. In this case you define two node sets on the surface you want to apply a concentrated force on. One node set is a single node (driver node) and the other is every other node on that surface except for the driver node (slave nodes). Now you can define an Equation Constraint so that the load application direction D.O.F. of the driver node is equivalent to all the same D's.O.F of the slave nodes. Then simply apply a concentrated force to the driver node and you're set.
Hope this helps,
-CM
- Thread starter
- #5
Composites_FEA_Guru
Aerospace
Hi ysm,
In your case you may want to use Rigid Body Constraints or Kinematic Coupling Constraints. With those methods, you can define a reference point at any location and then describe how the load applied to the reference point is transferred to the actual part. Kinematic Coupling Constraints give you a little more freedom as to which degrees of freedom are "linked".
If you have any questions as to the details once you get comfortable, I'd be interested to help as it helps me expand my understanding as well. As an aside, do you work primarily with metallic parts or something more exotic like composites, etc.?
Regards,
-CM
In your case you may want to use Rigid Body Constraints or Kinematic Coupling Constraints. With those methods, you can define a reference point at any location and then describe how the load applied to the reference point is transferred to the actual part. Kinematic Coupling Constraints give you a little more freedom as to which degrees of freedom are "linked".
If you have any questions as to the details once you get comfortable, I'd be interested to help as it helps me expand my understanding as well. As an aside, do you work primarily with metallic parts or something more exotic like composites, etc.?
Regards,
-CM
- Thread starter
- #7
- Status
