| Article ID | Journal | Published Year | Pages | File Type |
|---|---|---|---|---|
| 309183 | Thin-Walled Structures | 2012 | 9 Pages |
In this paper, the planar nonlinear dynamics of an axially accelerating beam in the subcritical speed regime is examined theoretically, via two different numerical techniques, employing a large enough number of modes in order to investigate modal interactions. The equation of motion is discretized via the Galerkin method which results in a set of coupled nonlinear ordinary differential equations (NODEs) with time-dependent coefficients. The set of NODEs is solved by means of the pseudo-arclength continuation technique and some of the results are tested and verified via direct time integration of the NODEs. The analyses include the system tuned to a three-to-one internal resonance, as well as for the case where it is not. Results are illustrated through frequency–response diagrams, time traces, phase–plane portraits, and fast Fourier transforms (FFTs).
► Nonlinear resonant responses of an axially accelerating beam in the subcritical regime are obtained numerically. ► The pseudo-arclength continuation technique along with direct time integration is employed to solve the equation of motion. ► Enough degrees of freedom are employed in the Galerkin discretization in order to analyze modal interactions.
