Point Load

Add a to points for concentrated forces at points in 2D and 3D.


	This section is only present in the Layered Shell interface, where it is described in the documentation for the Point Load node.

Select the — , , or . Then enter values or expressions based on the selection.

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For enter values or expressions for the components of the point load Fp.

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For , COMSOL Multiphysics divides the total force by the number of points where the load is active. Then the force is applied in the same way as for .

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For , enter the and with respect to a point. Select the — , , or . For , the coordinates of the application point is the centroid of the selected points. For , select a geometrical point in the section . For , enter the global coordinates of the , xa.

When using the option, the following should be observed

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In 3D, the selection must contain at least three points, and all points cannot be located so that they are collinear.

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in 2D, the selection must contain at lease two points.

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While it is formally possible to select points that are not located in a plane, the force distribution may be unpredictable in such a case.


	The Load list normally only contains User defined. When combining with another physics interface that can provide this type of load, it is also possible to choose a predefined load from this list.

Traction Field

This section is only shown when has been selected as . The distribution of the forces over the selected points is controlled by the settings here.

Select a — or .

When is selected, the force distribution approximately matches the stress distribution over a beam cross section.

For , you can write expressions for the force distribution. Enter expressions for the six dimensionless vector-valued distribution functions, 1, 2, 3, 4, 5, and 6. Usually, the local coordinates of the loaded region would be used for this purpose, but there is no limitation on the form of the functions. The built-in variables for the local coordinates are named <physics_tag>.<load_tag>.x2 and <phys_tag>.<load_tag>.x3, for example solid.pl1.x2. The default value is the distribution that is used when the option is selected.

The local coordinates, x2 and x3, are defined in the following way:

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The origin is at the centroid of the selected points.

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The axis directions coincide with the principal axes of a virtual collection of points with unit mass.

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x2 is the axis around which the virtual principal area moment of inertia is larger.

When is selected, you can also select a — , , or . This function acts as a multiplier to the force distribution functions. When is selected, the weight function w = 1. For , enter a radius rw of a circle, outside of which no load is applied (w = 0). Inside the circle, w = 1. For , enter a weighting expression. Usually, the built-in local coordinates of the loaded region would be used for this purpose, but there is no limitation on the form of the function. A time- or parameter-dependent function can, for example, be used to model a moving load.

The traction distribution functions have the property that the forces are distributed as

where the coefficients ci are chosen so that the given force and moment resultants are obtained.

Symmetry

This section is only shown when has been selected as . If the resultant force is applied in a symmetry or antisymmetry plane, this fact needs to be taken into account when creating the corresponding force distribution.

Select a symmetry type — , , or . When one of the types of symmetry is chosen, specify the symmetry plane by entering a , nsym, and a , xsym, located in the plane.

When specifying a resultant load in a symmetry plane, you still provide the full value of force and moment, as if there were no symmetry in the model. Any components of the given load that do not fulfill the selected type of symmetry will be discarded.

Linear Buckling

To display this section, click the button (

) and select in the dialog box.

If you are performing a linear buckling analysis with a combination of live and dead loads, select the check box to indicate that the load contributions from this node are constant. The default is that a load is proportional to the load factor.


	For more information about live and dead loads, see Buckling Analysis.

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You can add the Phase subnode to specify the phase of this load in a frequency domain analysis.

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You can specify this load to be a Harmonic Perturbation in a frequency domain analysis.

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You can assign this load to a load group. See Load Cases in the Structural Mechanics Modeling chapter.

Location in User Interface

Context Menus

Ribbon

Physics tab with , , or selected:

Physics tab with selected:

Physics tab with or selected: