Effect of internal material damping on the dynamics of a slider-crank mechanism

Citation data:

Journal of Mechanical Design, Transactions of the ASME, ISSN: 1050-0472, Vol: 105, Issue: 3, Page: 452-459

Publication Year:
1983
Usage 3
Abstract Views 3
Citations 12
Citation Indexes 12
Repository URL:
http://scholarsmine.mst.edu/mec_aereng_facwork/2313
DOI:
10.1115/1.3267381
Author(s):
Badlani, M. L.; Midha, Ashok
Publisher(s):
ASME International; American Society of Mechanical Engineers (ASME)
Tags:
Engineering; Computer Science; Dynamics (Mechanics); Damping; Mechanisms; Steady State; Vibration; Dynamic Response; Equations; Nonlinear Equations; Stability; Viscoelastic Materials; Dynamics (Mechanics); Damping; Mechanisms; Steady State; Vibration; Dynamic Response; Equations; Nonlinear Equations; Stability; Viscoelastic Materials; Aerospace Engineering; Mechanical Engineering
article description
A study of the effect of internal material damping on the dynamic response behavior of a slider-crank mechanism is presented in this paper. In developing the governing equations of motion, an assumption of a linear viscoelastic model for the connecting rod is made. A perturbation approach is utilized for reducing these coupled axial and transverse nonlinear equations to a nonhomogeneous damped Mathieu equation, describing the transverse vibration of the connecting rod. Both steady-state and transient solutions are determined and compared to those obtained from the use of an undamped connecting rod. It is demonstrated that the viscoelastic material damping can have significant influence, both favorable and adverse, in attempting to attenuate the steady-state and transient response of the connecting rod. The response is computed for several combinations of the excitation parameter and the frequency ratio. The stability of the transverse vibration of the connecting rod is also investigated in this paper. © 1983 by ASME.