Title page for ETD etd-05252004-140431


Type of Document Dissertation
Author Molisani, Leonardo Rafael
Author's Email Address lmolisan@vt.edu
URN etd-05252004-140431
Title A Coupled Tire Structure-Acoustic Cavity Model
Degree PhD
Department Mechanical Engineering
Advisory Committee
Advisor Name Title
Burdisso, Ricardo A. Committee Chair
Hendricks, Scott L. Committee Member
Johnson, Martin E. Committee Member
Klaus, Martin Committee Member
Preidikman, Sergio Committee Member
Wicks, Alfred L. Committee Member
Keywords
  • resonance control techniques
  • acoustic cavity-tire structure interaction
  • acoustic cavity resonances
Date of Defense 2004-05-07
Availability unrestricted
Abstract
Recent experimental results have shown that the vibration induced by the tire air cavity resonance is transmitted into the vehicle cabin and may be responsible for significant interior noise. The tire acoustic cavity is excited by the road surface through the contact patch on the rotating tire. The effect of the cavity resonance is that results in significant forces developed at the vehicle’s spindle, which in turn drives the vehicle’s interior acoustic field. This tire-cavity interaction phenomenon is analytically investigated by modeling the fully coupled tire-cavity systems. The tire is modeled as an annular shell structure in contact with the road surface. The rotating contact patch is used as a forcing function in the coupled tire-cavity governing equation of motion. The contact patch is defined as a prescribed deformation that in turn is expanded in its Fourier components. The response of the tire is then separated into static (i.e. static deformation induced by the contact patch) and dynamic components due to inertial effects. The coupled system of equations is solved analytically in order to obtain the tire acoustic and structural responses. The model provides valuable physical insight into the patch-tire-acoustic interaction phenomenon. The influence of the acoustic cavity resonance on the spindles forces is shown to be very important. Therefore, the tire cavity resonance effect must be reduced in order to control the tire contribution to the vehicle interior. The analysis and modeling of two feasible approaches to control the tire acoustic cavity resonances are proposed and investigated. The first approach is the incorporation of secondary acoustic cavities to detune and damp out the main tire cavity resonance. The second approach is the addition of damping directly into the tire cavity. The techniques presented in this dissertation to suppress the adverse effects of the acoustic cavity in the tire response, i.e. forces at the spindle, show to be very effective and can be easily applied in practice.
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