An approximate analysis method for brake squeal is presented. Using MSC/NASTRAN, a geometric nonlinear solution is run using a friction stiffness matrix to model the contact between the pad and rotor. The friction coefficient can be pressure dependent. Next, linearised complex modes are found where the interface is set in a slip condition. Since the entire interface is set sliding, it produces the maximum friction work possible during the vibration. It is a conservative measure for stability evaluation. An averaged friction coefficient is measured and used during squeal. Dynamically unstable modes are found during squeal. They are due to friction coupling of neighbouring modes. When these modes are decoupled, they are stabilised and squeal is eliminated. Good correlation with experimental results is shown. It will be shown that the complex modes base-line solution is insensitive to the type of variations in pressure and velocity that occur in a test schedule. This is due to the conservative nature of the approximation. Convective mass effects have not been included.
[1]
Guan Dihua,et al.
A Study on Disc Brake Squeal Using Finite Element Methods
,
1998
.
[2]
Wayne V. Nack,et al.
Friction Induced Vibration: Brake Moan
,
1995
.
[3]
J. T. Oden,et al.
Numerical Modeling of Friction-Induced Vibrations and Dynamic Instabilities
,
1994
.
[4]
Alois Steindl,et al.
Nonlinear Stability and Bifurcation Theory: An Introduction for Engineers and Applied Scientists
,
1991
.
[5]
Toru Matsushima,et al.
FE Analysis of Low-frequency Disc Brake Squeal (In Case of Floating Type Caliper)
,
1998
.
[6]
J. Thompson,et al.
Nonlinear Dynamics and Chaos: Geometrical Methods for Engineers and Scientists
,
1986
.
[7]
H. Troger,et al.
Nonlinear stability and bifurcation theory
,
1991
.
[8]
Wanda Szemplińska-Stupnicka,et al.
The Behavior of Nonlinear Vibrating Systems
,
1990
.
[9]
Gregory D. Liles.
Analysis of Disc Brake Squeal Using Finite Element Methods
,
1989
.