A new vibration isolator integrating tunable stiffness-damping and active driving properties based on radial-chains magnetorheological elastomer

In this study, a new vibration isolator integrating tunable stiffness-damping and active driving properties based on Magnetorheological Elastomer (MRE) embedding radial iron chains is proposed. Displacement/base excitations and periodic fluctuation current tests have been utilized to illustrate the fundamental dynamic properties and function of the proposed MRE vibration isolator. The force-displacement/velocity characteristics under different amplitudes/frequencies/ currents input show the significant tunable range of the stiffness and damping and hysteresis loop area under the displacement excitation test, which is also described by the established Hyperbolic hysteresis model. Under the base excitation test with the sweep sinusoidal acceleration signals, it has been shown that the transmission properties can be adjusted by the applied current, and has a significant dependency on the amplitude of the acceleration excitation due to the Payne effect. Finally, it has been illustrated that the MRE component can drive a mass of 78 times self-weight in a 10 Hz excitation frequency under the periodic fluctuation current input. Therefore, the adjustable stiffness-damping and active driving force properties of the MRE material itself make the proposed MRE vibration isolator show great application potential in the passive, semi-active and active vibration control area with the fail-safe property.

Automated summary

This study proposes a new vibration isolator based on Magnetorheological Elastomer (MRE) with tunable stiffness-damping and active driving properties. Experimental tests demonstrate the significant tunable range of stiffness and damping, as well as the adjustable transmission properties of the isolator. It is also shown that the MRE component can drive a mass of considerable weight under specific excitation frequencies. Therefore, the proposed MRE vibration isolator holds great potential in the field of vibration control with fail-safe properties.