Wave energy capture system ¡V surge motion tank

Huang, Kuang-Li

17 February 2011

Liquid sloshing in a 2D tank applied on a wave energy capture system and reducing the oscillation of an offshore platform are discussed in this study. A fully nonlinear time-independent finite difference method and the forth-order Runge-Kutta method are implemented to solve the coupled motions of liquid sloshing in a 2D tank with a floating platform. When the external forcing frequency of the Dynamic Vibration Absorber System composed by a tuned liquid damper and a tuned mass damper is identical to the fundamental frequency of the tank, the external force can be effectively diminished by the sloshing-induced force. In the meantime, the maximum effect of tuned mass damper on reducing the amplitude of the floating platform appears. When the frequency of external forcing is close to the first natural frequency of the liquid tank, the coupled effect between the motions of both the tank and the platform can effectively reduce the vibration of the platform and the total energy of the whole system. The Eigenfrequency of a wave capture system is formed by the coupled effect of a liquid tank and a wave capture system. When the excitation frequency of the wave capture system is near its Eigenfrequency, the sloshing-induced force is much larger than that of external and the maximum displacement of the wave energy capture system occurs. As a result, the wave energy capacity of the wave capture system can be averagely increased to 150% by the influence of liquid sloshing in the tank.

tuned mass damper

liquid tank

wave energy capture system

coupled motions

tuned liquid damper

Dynamic Vibration Absorber System

Ultrafast Collective Dynamics of Water-Protein Interactions

Houston, Patrick R.

January 2020

No description available.

Biophysics

Biochemistry

Physics

Physical Chemistry

hydration shell dynamics

protein sidechain fluctuations

coupled motions

tryptophan scan

femtosecond fluorescence spectroscopy