We found a match
Your institution may have access to this item. Find your institution then sign in to continue.
- Title
1357. Nonlinear behavior evolution and squeal analysis of disc brake based on different friction models.
- Authors
Haixia Wang; Xiandong Liu; Yingchun Shan; Tian He
- Abstract
A four-degree-of-freedom model of disc brake with friction and contact loss nonlinearities is developed to investigate the mechanism and dynamic characteristics of brake squeal. The nonlinear equations of motion are presented, and Coulomb and Stribeck friction models are applied and compared in the analysis. The effects of key parameters on system stability are investigated based on the linear equations around the equilibrium point using the complex eigenvalue analysis method. Mode-coupling motion is found to be one significant mechanism to initiate the system instability and lead to brake squeal, and is exceptionally reliant on the parameter configurations of brake system. Numerical solutions of the nonlinear equations of motion are obtained to examine the dynamic behaviors and find the routes to squeal of the brake system with nonlinearities. Results demonstrate that the tangential stiffness of the pad and the rotating velocity of the disc play important roles on the occurrence of stick-slip vibration resulting from the falling characteristic of friction coefficient, and contact loss nonlinearity may make system become unstable even for constant friction coefficient. The separation between the brake pad and disc is dependent on the ratio of normal stiffness of pad/disc and contact stiffness. Strong nonlinear items of the brake system may lead to complicated quasi-periodic and chaotic motions, resulting in squeal problem.
- Subjects
DISC brakes; NONLINEAR equations; FRICTION; MATHEMATICAL models; EIGENVALUES; DYNAMICS; STIFFNESS (Mechanics)
- Publication
Journal of Vibroengineering, 2014, Vol 16, Issue 5, p2593
- ISSN
1392-8716
- Publication type
Article