Abstract
Abstract The inerter pendulum vibration absorber is connected with a power take-off mechanism (called IPVA-PTO) to study its wave energy conversion potential. The resulting IPVA-PTO system is integrated between a spar and a floater (torus) using a ballscrew mechanism. The hydrodynamic stiffness, added mass and radiation damping effects on the spar-floater system are characterized using boundary element method via Ansys Aqwa. It has been observed that a 1:2 internal resonance between the spar-floater system and the pendulum is responsible for nonlinear energy transfer between the two systems. This nonlinear energy transfer occurs when the primary harmonic solution of the system becomes unstable, and a secondary solution emerges in the system characterized by harmonics of frequency half the excitation frequency. As a result of this energy transfer, the vibration of the spar-floater system is suppressed, and the energy is transferred to the pendulum. The focus of this paper is to analyze this 1:2 internal resonance phenomenon near the resonant frequency of the spar. The IPVA-PTO system, when integrated with the spar-floater system, is compared to a linear coupling between the spar and the floater in terms of the response amplitude operator (RAO) of the spar and the energy conversion capability defined by the capture width of the energy converter.
Published Version
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