Abstract:
Vibration suppression in harmonically forced viscously damped systems is considered using a new vibration absorber
setup. The absorber is placed between the primary system and the supporting ground. The optimal absorber parameters
are obtained with the aim of minimizing the maximum of the primary system frequency response. For a given damping
ratio of the primary system and mass ratio of the system, the optimal stiffness and damping ratios of the absorber are
calculated numerically. Two different numerical approaches are used in solving the problem; the first is based on the
genetic algorithm technique and the second on the downhill simplex method. It is shown that an optimal mass ratio
exists and it is calculated along with the corresponding absorber parameters for a range of the primary system damping
ratio. The utmost optimal parameters associated with the optimal mass ratios are tabulated to be used for the design of
such absorbers. The absorber efficiency is discussed and it is shown that this absorber becomes detrimental as the mass
ratio is increased or when damping in the primary system is high. The proposed and classical absorbers efficiencies are
compared.
Citation:
Harik, R. F., & Issa, J. S. (2013). Design of a vibration absorber for harmonically forced damped systems. Journal of Vibration and Control, 1077546313501928.