On the Ratio of Reactive to Active Power in Wave Energy Converter Control

Hafiz Ahsan Said;Demián García-Violini;Nicolás Faedo;John V. Ringwood
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Abstract

Optimal control of wave energy converters (WECs), while converting wave energy into a usable form, such as electricity, may inject (reactive) power into the system at various points in the wave cycle. Though somewhat counter-intuitive, this action usually results in improved overall energy conversion. However, recent experimental results show that, on occasion, reactive power peaks can be significantly in excess of active power levels, leaving device developers with difficult decision in how to rate the power take-off of the system i.e. whether to cater for these high reactive power peaks, or limit power flow to rated (active) levels. The origins of these excessive power peaks are currently poorly understood, creating significant uncertainty in how to deal with them. In this paper, we show that, using both theoretical results and an illustrative simulation case study, under matched controller conditions (impedance-matching optimal condition), for both monochromatic and panchromatic sea-states, that the maximum peak reactive/active power ratio never exceeds unity . However, under mismatched WEC/controller conditions, this peak power ratio can exceed unity, bringing unrealistic demands on the power take-off (PTO) rating. The paper examines the various origins of system/controller mismatch, including modelling error, controller synthesis inaccuracies, and non-ideal PTO behaviour, highlighting the consequences of such errors on reactive power flow levels. This important result points to the need for accurate WEC modeling, while also showing the folly of catering for excessive reactive power peaks.
论波浪能转换器控制中无功功率与有功功率之比
波浪能转换器(WECs)的优化控制在将波浪能转换成电能等可用形式时,可能会在波浪周期的不同点向系统注入(无功)功率。虽然有些违背直觉,但这种做法通常会改善整体能量转换效果。然而,最近的实验结果表明,有时无功功率峰值会大大超过有功功率水平,这让设备开发人员难以决定如何评定系统的功率输出,即是满足这些高无功功率峰值,还是将功率流限制在额定(有功)水平。目前,人们对这些过高功率峰值的起源知之甚少,因此在如何处理这些峰值方面存在很大的不确定性。在本文中,我们利用理论结果和一个说明性仿真案例研究表明,在匹配控制器条件下(阻抗匹配最佳条件),对于单色和全色海况,最大无功/有功功率峰值比永远不会超过 1。然而,在不匹配的风电机组/控制器条件下,该峰值功率比可能会超过 1,从而对额定功率输出(PTO)提出不切实际的要求。本文探讨了系统/控制器不匹配的各种原因,包括建模错误、控制器合成不准确和非理想的 PTO 行为,并强调了这些错误对无功功率流水平的影响。这一重要结果表明了精确的水力发电建模的必要性,同时也说明了迎合过高的无功功率峰值是愚蠢的。
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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