Abaqus Analysis User's Guide  


32.3.1 Flexible joint element

Product: Abaqus/Standard  

References

Overview

JOINTC elements:

  • are used to model joint interactions; and

  • are made up of translational and rotational springs and parallel dashpots in a local, corotational coordinate system.

Details of the element formulation can be found in Flexible joint element, Section 3.9.6 of the Abaqus Theory Guide.

Typical applications

The JOINTC element is provided to model the interaction between two nodes that are (almost) coincident geometrically and that represent a joint with internal stiffness and/or damping (such as a rubber bushing in a car suspension system) so that the second node of the joint can displace and rotate slightly with respect to the first node.

Joints that have only one or two axes of rotation and no relative displacement are better modeled by the REVOLUTE- or UNIVERSAL-type MPCs (see General multi-point constraints, Section 35.2.2).

Similar functionality is available using connectors; see Connectors: overview, Section 31.1.1.

Defining the joint behavior

The joint behavior consists of linear or nonlinear springs and dashpots in parallel, coupling the corresponding components of relative displacement and of relative rotation in the joint. You define the spring and dashpot behavior as described in Springs, Section 32.1.1, and Dashpots, Section 32.2.1.

Each spring or dashpot definition defines the behavior for one of the six local directions; up to six spring and six dashpot definitions can be included. If no specification is given for a particular local relative motion in the joint, the joint is assumed to have no stiffness with respect to that component.

The joint behavior can be defined in a local coordinate system that rotates with the motion of the first node of the element (Orientations, Section 2.2.5). If a local coordinate system is not defined, the global system is used.

You must associate the joint behavior with a set of JOINTC elements.

The kinematic behavior of JOINTC elements is described in detail in Flexible joint element, Section 3.9.6 of the Abaqus Theory Guide.

Input File Usage:          Use the following options to define the joint behavior:
*JOINT, ELSET=name, ORIENTATION=name
*DASHPOT
*SPRING
Up to six *SPRING and *DASHPOT options can appear.

Using JOINTC elements in large-displacement analyses

In large-displacement analysis the formulation for the relationship between moments and rotations limits the usefulness of these elements to small relative rotations. The relative rotation across a JOINTC element should be of a magnitude to qualify as a small rotation.

 
Abaqus Analysis User's Guide  
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32.3.1 Flexible joint element

Product: Abaqus/Standard  

References
Your query was poorly formed. Please make corrections.

Overview

JOINTC elements:

  • are used to model joint interactions; and

  • are made up of translational and rotational springs and parallel dashpots in a local, corotational coordinate system.

Details of the element formulation can be found in Flexible joint element, Section 3.9.6 of the Abaqus Theory Guide.

Your query was poorly formed. Please make corrections.
Your query was poorly formed. Please make corrections.

Typical applications

The JOINTC element is provided to model the interaction between two nodes that are (almost) coincident geometrically and that represent a joint with internal stiffness and/or damping (such as a rubber bushing in a car suspension system) so that the second node of the joint can displace and rotate slightly with respect to the first node.

Joints that have only one or two axes of rotation and no relative displacement are better modeled by the REVOLUTE- or UNIVERSAL-type MPCs (see General multi-point constraints, Section 35.2.2).

Similar functionality is available using connectors; see Connectors: overview, Section 31.1.1.

Your query was poorly formed. Please make corrections.
Your query was poorly formed. Please make corrections.

Defining the joint behavior

The joint behavior consists of linear or nonlinear springs and dashpots in parallel, coupling the corresponding components of relative displacement and of relative rotation in the joint. You define the spring and dashpot behavior as described in Springs, Section 32.1.1, and Dashpots, Section 32.2.1.

Each spring or dashpot definition defines the behavior for one of the six local directions; up to six spring and six dashpot definitions can be included. If no specification is given for a particular local relative motion in the joint, the joint is assumed to have no stiffness with respect to that component.

The joint behavior can be defined in a local coordinate system that rotates with the motion of the first node of the element (Orientations, Section 2.2.5). If a local coordinate system is not defined, the global system is used.

You must associate the joint behavior with a set of JOINTC elements.

The kinematic behavior of JOINTC elements is described in detail in Flexible joint element, Section 3.9.6 of the Abaqus Theory Guide.

Input File Usage:          Use the following options to define the joint behavior:
*JOINT, ELSET=name, ORIENTATION=name
*DASHPOT
*SPRING
Up to six *SPRING and *DASHPOT options can appear.

Your query was poorly formed. Please make corrections.
Your query was poorly formed. Please make corrections.

Using JOINTC elements in large-displacement analyses

In large-displacement analysis the formulation for the relationship between moments and rotations limits the usefulness of these elements to small relative rotations. The relative rotation across a JOINTC element should be of a magnitude to qualify as a small rotation.

Your query was poorly formed. Please make corrections.
Your query was poorly formed. Please make corrections.