Rigid Connector
The Rigid Connector is a boundary condition for modeling rigid regions and kinematic constraints such as prescribed rigid rotations. The selected points will move as a single rigid object.
You can add the Rigid Connector node at the edge (2D: boundary) and point levels.
When added at the edge level you can connect edges and points as long as at least one edge is selected. Selecting points is optional.
When added at the point level, you can connect a set of points to each other.
If the study step is geometrically nonlinear, the rigid connector takes finite rotations into account.
Rigid connectors are available in the Solid Mechanics, Multibody Dynamics, Shell, Beam, and Pipe Mechanics interfaces. Rigid connectors from different interfaces can be attached to each other.
You can add functionality to the rigid connector through the following subnodes:
Applied Force (Rigid Connector) to apply a force in given point.
Applied Moment (Rigid Connector) to apply a moment.
Mass and Moment of Inertia (Rigid Connector) to add extra mass and moment of inertia in a given point.
Spring Foundation (Rigid Connector) to add a translational or rotational spring or damper in a given point.
When physics symbols are shown, a rigid connector is represented by a symbol at the center of rotation, together with a set of lines connecting the center of rotation with the centers of gravity of the selected entities.
When the rigid connector is added at the edge level, such symbols are shown only for the selected edges, but not for auxiliary selections of points.
Because of the way physics symbols are evaluated, as a lightweight operation when moving between physics nodes in the model builder tree, it is sometimes not possible to determine the center of rotation. In particular, if an offset is supplied, it will not be taken into account.
Edge Selection
This section is present when the Rigid Connector node has been added at the edge level. Select one or more edges to be part of the rigid region.
Boundary Selection
This section is present when the Rigid Connector node has been added at the boundary level. Select one or more edges to be part of the rigid region.
Point Selection
This section is always present.
When the Rigid Connector is added at the point level, select a number of points that form the rigid region.
When the Rigid Connector is added at the edge (2D: boundary) level, this section is initially collapsed. Here, you can add optional points to the rigid region. The points cannot be adjacent to the selected boundaries or edges.
Coordinate System Selection
The Global coordinate system is selected by default. The Coordinate system list contains all applicable coordinate systems in the model. Prescribed displacements or rotations are specified along the axes of this coordinate system. It is also used for defining the axis directions of the moment of inertia tensor of the Mass and Moment of Inertia subnode.
In order to be applicable, a coordinate system must have axis directions that are independent of the location in space.
Center of Rotation
The center of rotation serves two purposes.
If you prescribe the displacement of the rigid connector, this is the place where it is fixed.
Results are interpreted with respect to the center of rotation.
Select a Center of rotation Automatic, Centroid of selected entities, or User defined.
For Automatic the center of rotation is at the geometrical center of the selected points. The constraints are applied at the center of rotation.
For Centroid of selected entities a subnode for selection of the points is added to the Model Builder.
For User defined, in the Global coordinates of center of rotation XC table enter coordinates based on space dimension.
Once Centroid of selected entities is chosen, a default Center of Rotation: Point subnode is added.
The center of rotation is located at the centroid of the selected points, which do not need to be related to the objects to which the rigid connector is attached. The points do not even have to belong to the physics interface. As a special case, you can select a single point, and thus locate the center of rotation at a certain point.
Select the Offset check box to add an optional offset vector to the definition of the center of rotation. Enter values for the offset vector Xoffset.
The center of rotation used is the sum of the vector obtained from any of the input methods and the offset vector.
Prescribed Displacement at Center of Rotation
To define a prescribed displacement at the center of rotation for each space direction, select one or several of the available check boxes then enter values or expressions for the prescribed displacements. The direction coordinate names can vary depending on the selected coordinate system.
Prescribed in x direction u0x
Prescribed in y direction u0y
For 3D components: Prescribed in z direction u0z
Prescribed Rotation at Center of Rotation
Specify the rotation at the center of rotation. Select from the By list: Free (the default), Constrained rotation, or Prescribed rotation at center of rotation.
For 2D components, the Constrained rotation and Prescribed rotation at center of rotation is always about the z-axis, so no component selection is necessary.
Constrained Rotation (3D Components)
For Constrained rotation select one or more of the available check boxes to enforce zero rotation about the corresponding axis in the selected coordinate system:
Constrain rotation about x-axis
Constrain rotation about y-axis
Constrain rotation about z-axis
Prescribed Rotation at Center of Rotation
For Prescribed rotation at center of rotation enter an Angle of rotation φ0. For 3D components also enter an Axis of rotation Ω for the x, y, and z coordinates.
You can add a Harmonic Perturbation subnode for specifying a harmonic variation of the values of the prescribed displacements and rotations in a frequency domain analysis of perturbation type.
You can activate and deactivate the rigid connector by assigning it to a constraint group. See Load Cases in the Structural Mechanics Modeling chapter.
You can assign the value of the prescribed displacement and rotation to a load group. See Load Cases in the Structural Mechanics Modeling chapter.
Rigid Connector Theory
Harmonic Perturbation
Load Cases
Reaction Force Settings
Select Evaluate reaction forces to compute the reaction force caused by a prescribed motion. The default is to not compute the reaction force. When selected, the prescribed motion is implemented as a weak constraint.
Select Apply reaction only on rigid body variables to use a unidirectional constraint for enforcing a prescribed motion. The default is that bidirectional constraints are used. This setting is useful in a situation where a bidirectional constraint would give an unwanted coupling in the equations. This would happen if the prescribed value of the motion is a variable solved for in other equations.
Formulation
Some contributions from a rigid connector will, under geometric nonlinearity, result in a nonsymmetric local stiffness matrix. If all other aspects of the model are such that the global stiffness matrix would be symmetric, then such a nonsymmetric contribution may have a heavy impact on the total solution time and memory usage. In such cases, it is often more efficient to use an approximative local stiffness matrix that is symmetric.
Select Use symmetric formulation for geometric nonlinearity to force all matrix contributions from the rigid connector and its subnodes to be symmetric.
Using an approximative stiffness matrix will in general require more iterations. However, since the computational cost per iteration will be cut at least by a factor of two if a symmetric matrix can be used, it is usually more efficient to ignore a weak nonsymmetry.
In particular, if the rotation of the rigid connector per time step or parameter increment is small, there will in general be no increase in the number of iterations at all if this option is used.
When the global stiffness matrix is nonsymmetric for other reasons, then there is nothing to be gained from symmetrizing the contribution from the rigid connector.
Constraint Settings
On the boundaries where the rigid connector is coupled to a flexible material, all nodes on such a boundary are constrained to move as a rigid body. As a default these constraints are implemented as pointwise constraints. If you want to use a weak constraint formulation, select Use weak constraints for rigid-flexible connection.
This formulation cannot be combined with the Flexible formulation of the rigid connector, which in itself is a special form of weak constraint.
Constraint Settings
On the points where the rigid connector is coupled to a flexible material, all nodes are constrained to move as a rigid body. As a default, these constraints are implemented as pointwise constraints. If you want to use a weak constraint formulation, select Use weak constraints for rigid-flexible connection.
Advanced
It is possible to couple rigid connectors to each other. In the Connect to list, you can select any rigid connector defined in the Solid Mechanics, Multibody Dynamics, or Shell interfaces as being rigidly connected to the current one.
When coupling rigid connectors to each other, you must be careful not to add conflicting settings. Typically, you should only assign constraints to one of the connectors, and it is recommended to use a common center of rotation. It is, however, possible to deviate from these recommendations and create other meaningful combinations.
Rigid Connector Theory
Location in User Interface
Context Menus
Beam>Line Constraints>Rigid Connector (3D: Edge, 2D: Boundary)
Beam>Connections>Rigid Connector (Point)
Pipe Mechanics>Line Constraints>Rigid Connector (3D: Edge, 2D: Boundary)
Pipe Mechanics>Connections>Rigid Connector (Point)
Ribbon
Physics tab with Beam or Pipe Mechanics selected:
Boundaries>Line Constraints>Rigid Connector (2D)
Edges>Line Constraints>Rigid Connector (3D)
Points>Connections>Rigid Connector