Abstract
The complexity of a semi-active vibration isolation system results in the difficulty of realizing its role on impact load effectively. Thus, a new self-sensing bearing based on modified anisotropic magnetorheological elastomer (MRE) is proposed in this study. This self-sensing bearing was fabricated by dispersed multi-walled carbon nanotubes and carbonyl iron particles into polydimethylsiloxane matrix under a magnetic field. The working conditions of the bearing were analyzed and decoupled. An optimal structure size of the bearing was selected and used for setting up the experiment test system. The self-sensing characteristic of the MRE bearing under the multi-field coupling of load and magnetic fields was then investigated by this test system. Results showed that the resistance of the modified MRE, in which a preload was applied by the bearing, could change approximately 28%–56% under extrusion force, mechanical force, and external magnetic field. The vibration isolation performance was tested based on the self-sensing characteristic. The bearing had excellent mechanical properties, which could reduce at least 30% of vibration. Thus, the modified MRE of the magnetorheological elastomer bearing could be simultaneously used as an actuator and a sensor.
Highlights
Vibration affects or harms surrounding buildings, the human body, and precision instruments
The semi-active vibration isolation system based on a magnetorheological elastomer bearing (MRB) system, which usually comprises sensors, actuators, and drivers, has been widely studied and applied due to its significant inhibitory effect on vibration[1,2]
The sensing and adaptive behaviors of a bearing subjected to the combined effect of magnetic fields and mechanical loadings was investigated based on a modified magnetorheological elastomer (MRE)
Summary
Vibration affects or harms surrounding buildings, the human body, and precision instruments. As a type of conductive filler composites, MREs possess magnetoelasticity[3] and piezoresistive properties.[4] On the basis of these characteristics, the design and implementation of a self-sensing bearing is proposed in this study to improve the performance of vibration isolation. The sensing and adaptive behaviors of a bearing subjected to the combined effect of magnetic fields and mechanical loadings was investigated based on a modified MRE. Such a bearing could be used for load sensing and could be incorporated readily in a semi-active vibration isolation system to improve the adaptive vibration effectively
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