Abstract
Magnetorheological (MR) fluid is a smart material utilized for semi-active damping devices thanks to its ability to become viscoelastic solid under a magnetic field and provide variable damping. While most of these devices primarily utilize the fluid’s drastic increase in viscosity, its variable stiffness is rarely utilized. A MR fluid filled spring is a novel device with variable stiffness and damping and is the subject of the present study. First, the derived analytical model and the device’s controllable stiffness capability were experimentally validated by performing tensile tests with a fabricated hollow polymer spring filled with MRF-132DG. The analytical model was proved to describe the MR fluid static effect of increased spring stiffness accurately. Secondly, dynamic testing demonstrated the device’s controllable damping and capability to shift natural frequencies. In addition, the testing unveiled an enhanced dynamic performance of the spring due to the cumulative effect of MR fluid activation and specifically aligned uniform magnetic field. Finally, the hollow spring design was optimized through analytical and non-linear finite element buckling analysis to maximize MR fluid stiffness effect. The resulting critical parameters of the optimized design were used to estimate the effects of hollow spring material and operating conditions on the variable stiffness of the device.
Highlights
Magnetorheological (MR) fluid is a smart material formed through dispersing magneticallyresponsive microsized particles in a liquid carrier
When subjected to a magnetic field, the microsized particles link in chains along the magnetic lines, drastically increasing MR fluid’s viscosity up to a point making it semi-solid, which results in improved yield stress and complex modulus
The MR fluid filled spring’s capabilities to shift resonance frequencies and improve damping characteristics were demonstrated. The former improvement showed higher than expected performances, which was explained by the specifics of the utilized unidirectional magnetic field
Summary
Magnetorheological (MR) fluid is a smart material formed through dispersing magneticallyresponsive microsized particles in a liquid carrier. When subjected to a magnetic field, the microsized particles link in chains along the magnetic lines, drastically increasing MR fluid’s viscosity up to a point making it semi-solid, which results in improved yield stress and complex modulus. These parameters can be controlled rapidly and precisely by adjusting the amount of applied magnetic field (Wang and Meng 2001). Among recently reported studies on MR fluid application, some devices demonstrate variable stiffness by utilizing the variable modulus of MR fluid (Jackson, et al, 2018; Hong, et al, 2019; Park, et al, 2021)
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