Abstract
For a floating tidal current power station moored in the sea, the mutual interactions between the carrier and the turbine are pretty complex. Current simulation methods based on potential flow theory could not consider the complicated viscous effects between the carrier motion and rotor rotation. To accurately account for the viscous effect, developing a different numerical simulation method based on computational fluid dynamics is necessary. This paper deals with a moored FTCPS (floating tidal current power station) with 6-degree-of-freedom motion in uniform flow based on dynamic fluid body interactions (DFBI) method. Results showed that the blockage effect caused by the columns would increase the average power output of the turbine, while the power output fluctuation also increased. When the carrier is individually moored in the sea, the motion response of the carrier is pretty small, and the carrier is obviously trimming by the bow. However, when the turbine is mounted on the carrier, the carrier motion response is simple harmonic. The motion response frequency of the carrier is in relation to the rotation frequency of the turbine.
Highlights
The tidal current energy is one of the most abundant clean renewable energy resources worldwide [1]
Tidal current turbines can be classified into fixed turbine and floating turbine based on their supporting platforms [3]
2.5 m/s, and the direction is alongtenthe dency of the hydrodynamic characteristics of the floating turbines under different tip negative direction of the y-axis
Summary
The tidal current energy is one of the most abundant clean renewable energy resources worldwide [1]. Due to its high energy density, strong predictability, and energy stability, tidal current energy has become a hot topic in ocean energy research in recent years [2]. Tidal current turbines can be classified into fixed turbine and floating turbine based on their supporting platforms [3]. Compared to fixed turbines, floating tidal current turbines are suitable for different kinds of complex marine environments. Floating tidal current turbines are easy to install [4]. The turbines can better make use of the strong ocean surface tidal current kinetic energy.
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