Steady-State Harmonic and Time Domain Point Absorber Modelling

American Journal of Geospatial Technology Pub Date : 2024-06-01 DOI:10.54536/ajgt.v3i1.2882

Saad Al-Sahlawi, Garvey Seamus, Kathy Johnson

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Abstract

This paper analysed the development of a steady-state harmonic model which, along the vertical axis, can simulate a single buoy’s motion with one degree of freedom (heave). The model can optimise a buoy’s geometric and control parameters to maximise power absorption from incident waves. The steady-state model revealed that at resonance, maximum power absorption of the buoy occurred in two region values with either low or high range of values of radiation damping coefficient (c2). In practice, achieving operation in the low c2 region is difficult. Therefore, it is recommended that the devices be designed to operate in the high c2 region to increase power capture. The model also revealed the best value for c1 (PTO damping coefficient) when the buoy with the peak frequency of the sea state is at resonance, and its mass is optimum. The PTO device size can therefore be manufactured accordingly to maximise power absorption. Out of all the tested buoy shapes (spike, bullet, and bi-cone), the bi-cone (60o/120o) buoy performed the best, and its response was most similar to the optimum mass response predicted by the model.

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稳态谐波和时域点吸收器建模

本文分析了稳态谐波模型的开发情况，该模型沿垂直轴可模拟单个浮标的单自由度运动（波浪）。该模型可优化浮标的几何和控制参数，以最大限度地吸收入射波的功率。稳态模型显示，在共振时，浮标的最大功率吸收发生在辐射阻尼系数（c2）值范围较低或较高的两个区域。实际上，要在低 c2 区域实现运行是很困难的。因此，建议将设备设计为在高 c2 区域运行，以提高功率捕获率。该模型还揭示了当海况峰值频率的浮标处于共振时 c1（PTO 阻尼系数）的最佳值，且其质量为最佳。因此，可以相应地制造 PTO 装置的尺寸，以最大限度地吸收功率。在所有测试过的浮标形状（尖头、子弹头和双锥体）中，双锥体（60o/120o）浮标的性能最好，其响应与模型预测的最佳质量响应最为相似。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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American Journal of Geospatial Technology

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