Abstract
This paper investigates the dynamics and performance of inerter-based vibration isolators. Force / displacement transmissibility and vibration power flow are obtained to evaluate the isolation performance. Both force and motion excitations are considered. It is demonstrated that the use of inerters can enhance vibration isolation performance by enlarging the frequency band of effective vibration isolation. It is found that adding inerters can introduce anti-resonances in the frequency-response curves and in the curves of the force and displacement transmissibility such that vibration transmission can be suppressed at interested excitation frequencies. It is found that the introduction of inerters enhances inertial coupling and thus have a large influence on the dynamic behaviour at high frequencies. It is shown that force and displacement transmissibility increases with the excitation frequency and tends to an asymptotic value as the excitation frequency increases. In the high-frequency range, it was shown that adding inerters can result in a lower level of input power. These findings provide a better understanding of the effects of introducing inerters to vibration isolation and demonstrate the performance benefits of inerter-based vibration isolators.
Highlights
There has been a growing demand for high performance vibration control devices that change the vibration transmission behaviour of dynamical systems to meet specific requirements [1, 2]
It was found that adding inerters can increase inertial coupling and have a large influence on performance of the inerterbased isolators at high frequencies
It was demonstrated that the addition of inerters can assist in enlarging the frequency band of effective vibration isolation
Summary
There has been a growing demand for high performance vibration control devices that change the vibration transmission behaviour of dynamical systems to meet specific requirements [1, 2] One such device is the recently proposed passive mechanical element, the inerter, which can be used to provide inertial coupling such as to modify the dynamic behaviour [3]. This paper aims to address the issues by investigating the influence of introducing inerters on vibration behaviour in terms of force and displacement transmissibility, as well as vibration power and energies. Both force and motion excitations will be considered. Conclusions and suggestions for engineering applications are provided at the end of the paper
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