Optimization of Bottom-hinged Flap-type Wave Energy Converter for a Specific Wave Rose 被引量：1

Optimization of bottom-hinged flap-type wave energy converter for a specific wave rose

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摘要 In this paper, we conducted a numerical analysis on the bottom-hinged flap-type Wave Energy Convertor (WEC). The basic model, implemented through the study using ANSYS-AQWA, has been validated by a three-dimensional physical model of a pitching vertical cylinder. Then, a systematic parametric assessment has been performed on stiffness, damping, and WEC direction against an incoming wave rose, resulting in an optimized flap-type WEC for a specific spot in the Persian Gulf. Here, stiffness is tuned to have a near-resonance condition considering the wave rose, while damping is modified to capture the highest energy for each device direction. Moreover, such sets of specifications have been checked at different directions to present the best combination of stiffness, damping, and device heading. It has been shown that for a real condition, including different wave heights, periods, and directions, it is very important to implement the methodology introduced here to guarantee device performance. In this paper, we conducted a numerical analysis on the bottom-hinged flap-type Wave Energy Convertor (WEC). The basic model, implemented through the study using ANSYS-AQWA, has been validated by a three-dimensional physical model of a pitching vertical cylinder. Then, a systematic parametric assessment has been performed on stiffness, damping, and WEC direction against an incoming wave rose, resulting in an optimized flap-type WEC for a specific spot in the Persian Gulf. Here, stiffness is tuned to have a near-resonance condition considering the wave rose, while damping is modified to capture the highest energy for each device direction. Moreover, such sets of specifications have been checked at different directions to present the best combination of stiffness, damping, and device heading. It has been shown that for a real condition, including different wave heights, periods, and directions, it is very important to implement the methodology introduced here to guarantee device performance.

作者 Hamed Behzad Roozbeh Panahi

机构地区 Department of Civil Engineering

出处《Journal of Marine Science and Application》 CSCD 2017年第2期159-165,共7页 船舶与海洋工程学报（英文版）

关键词 WAVE energy converter bottom-hinged flap power TAKE-OFF system directional analysis OPTIMIZATION WAVE ROSE wave energy converter bottom-hinged flap power take-off system directional analysis optimization wave rose

分类号 U6 [交通运输工程—船舶与海洋工程]

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