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A front disc brake system is used as an example for an investigation of low frequency squeal. Many different modifications to this disc brake system have been proposed and this paper focuses on a solution that reduces the stiffness of the rotor. This is accomplished by a reduction in the Young's modulus of the rotor material. The complex eigenvalue method is used for a detailed analytical study in order to obtain a better understanding of this solution technique. Modal participation factors are calculated to examine the modal coupling mechanism. Parametric studies are also performed to find out the effects of friction coefficient and rotor stiffness. Results show that shifting rotor resonance frequencies may ecouple the modal interaction and eliminate dynamic instability, which is in agreement with experimental results.

Disc brake noise continues to be a major concern throughout the automotive industry despite efforts to reduce its occurrence. As a major supplier of automotive brake components, Delphi Chassis is continually investigating means to reduce disc brake noise. In this paper, experimental and analytical methods are discussed which reduce the occurrence of automotive disc brake noise. Three general categories of brake noise are discussed. These categories are low frequency noise, low frequency squeal, and high frequency squeal. A general description of all three categories and examples of relevant solutions are presented.