Determining Dynamic Properties of Elastomer-Dampers by Means of Impact Testing

Background Damping elements made of elastomer materials are used in almost every mechanical system to prevent damage to components caused by impact-like excitations and the resulting high-frequency, large-amplitude oscillations. The dynamics of these operating conditions exceed the performance limits of conventional experimental testing methods, impeding validated predictions of the damper's transmission behaviour. Objective A method is proposed to directly investigate the influence of impacts on the transmission behaviour of elastomeric dampers by impact testing. Methods Torsional-loaded elastomer dampers were experimentally investigated using a drop tower. During the experiment, a mass is brought into impact contact with a lever arm connected to the tested coupling. Measurements on resulting torsional oscillations and a comparison of the measurement results with a simple analytical model of the system allow for determining the coupling parameters stiffness and damping ratio. Results The characteristic parameters stiffness and damping ratio of the elastomer damper were mapped as a function of excitation-amplitude and frequency. A comparison of drop-tower test results with servo-hydraulic measurements validated the determined parameters. Conclusions Determining the transmission behaviour of elastomeric dampers from highly dynamic and impact-induced oscillation states proved to be a good approach to supplement established testing methods.

Automated summary

This study proposes a method to directly investigate the influence of impacts on the transmission behavior of elastomeric dampers through impact testing. The characteristic parameters of the elastomer damper are determined and validated, providing a supplement to traditional testing methods.