Journal
POLYMERS
Volume 15, Issue 5, Pages -Publisher
MDPI
DOI: 10.3390/polym15051299
Keywords
granular material; TPU polymer; vibration damping; energy criterion; lightweight design
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This study investigates the vibration-damping properties of prestressed granular material, and finds that granular form provides better vibration-damping performance compared to bulk material. This improvement is achieved through the interaction of two effects: the pressure-frequency superposition principle at the molecular scale and the physical interactions between the granules (force-chain network) at the macro scale. Further improvements can be achieved by varying the material of the granules and applying a lubricant to facilitate reorganization of the force-chain network.
Granular materials promise opportunities for the development of high-performance, lightweight vibration-damping elements that provide a high level of safety and comfort. Presented here is an investigation of the vibration-damping properties of prestressed granular material. The material studied is thermoplastic polyurethane (TPU) in Shore 90A and 75A hardness grades. A method for preparing and testing the vibration-damping properties of tubular specimens filled with TPU granules was developed. A new combined energy parameter was introduced to evaluate the damping performance and weight-to-stiffness ratio. Experimental results show that the material in granular form provides up to 400% better vibration-damping performance as compared to the bulk material. Such improvement is possible by combining both the effect of the pressure-frequency superposition principle at the molecular scale and the effect of the physical interactions between the granules (force-chain network) at the macro scale. The two effects complement each other, with the first effect predominating at high prestress and the second at low prestress. Conditions can be further improved by varying the material of the granules and applying a lubricant that facilitates the granules to reorganize and reconfigure the force-chain network (flowability).
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