The component test rig has up to six prescribed motions to determine the dynamic stiffness and loss angle for each degree of freedom of an elastic component.

The test rig consists of an upper and lower part. The lower part is fixed to ground and the upper part is controlled by a six degree-of-freedom motion marker. You can activate or deactivate each motion degree of freedom.

The test component in the test-rig assembly defines its own mount location and communicates the location through a marker communicator. The upper mount point is at the upper part and the lower mount point is at the lower mount part of the test rig.

You can initialize multiple runs in one setup. For each simulation, you can compare measured data of dynamic stiffness and loss angle, or loss work, with the simulation result. This means that the component model being tested is excited with constant frequency and amplitude sinusoid until either of these conditions are met:

Convergence means that the component model has reached steady-state behavior. Dynamic stiffness and loss angle are only defined for a steady-state condition.

The test rig is also used for quasi-static analyses, which maintain a constant velocity motion between a minimum and maximum displacement. You can define a preload for each motion degree of freedom or for an initial displacement. The motion can be a constant-frequency or a linear-frequency sweep. The motion is defined between the marker lower_mount_point and upper_mount_point with respect to cfs_testrig_reference.

The test-rig setup determines the constraints for each component as motion, locked, or constraint released. The initial displacement and preload are exclusive options. The initial displacement or preload is applied during the initial static and its values are used as the start condition for the subsequent analysis.

The excitation function is defined in the dialog box, Component Analysis.

Amplitude - The amplitude is a single value or a set of amplitudes separated by commas. Each amplitude performs an analysis with the same test rig setup.

Phase - The phase of a sinusoidal motion during a constant or sweep frequency is achieved in different ways. The motion always starts with velocity = 0 and increases in a quarter of a period to the specified amplitude value. The sine function starts after a fourth of a period minus the phase shift value. The initial displacement or preload is held during the static analysis. The sinusoidal motion starts at the initial displacement.

For example: phase 0, 45 and 90 Deg, 1 Hz, initial displ. 0. See plot.

Direct - This method is used for the continuous sweep only. The sinusoidal motion starts with its phase and its initial displacement at time = 0, which causes a shift in displacement. The shift can be compensated with the initial displacement.

For example: phase 0, 45 and 90 Deg, 1 Hz, initial displ. 0. See plot.

Each analysis contains request data of the test rig. The test rig has two measure points: at the upper mount point, the I marker, and at the lower mount point, the J marker.

The location expressions for cfs_lower_mount_point and cfs_upper_mount_point are nonstandard Adams/Car expressions. The cis_lower_mount_point and cis_upper_mount_point are marker communicators.