Oscillating water column wave energy converter arrays coupled with a parabolic-wall energy concentrator in regular and irregular wave conditions

IF 4.2 2区 工程技术 Q1 ENGINEERING, CIVIL
Robert Mayon , Dezhi Ning , Jin Xu , Lei Fu
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引用次数: 0

Abstract

Based upon previous research on a single, high-efficiency Oscillating Water Column (OWC) wave energy capture system (Mayon et al., 2021), this work further extends the numerical investigation to the layout design and performance of the wave energy convertor (WEC) array coupled with a parabolic, energy concentrating wall in both regular and irregular incident wave conditions. A heuristic method to identify the optimal siting of the component, cylindrical OWC WECs in the array, installed in the concave opening of the wall is presented. The most advantageous location of the chambers is found to lie on a parabolic curvature line which is inset from the wall. Two separate arrays composed of three and five component OWCs are investigated in a range of regular wave conditions. The hydrodynamic power and efficiency of each chamber in each of the arrays is determined, and subsequently the aggregated array performance is established. It is found that the primary OWC chamber in the array configuration can attain approximately the same hydrodynamic power output as a single, isolated OWC chamber located the parabolic wall focus, albeit with a narrower energy capture bandwidth. The secondary and tertiary component chambers in the arrays contribute a lesser, yet still considerable quantity of hydrodynamic power to the consolidated system. The cumulative hydrodynamic efficiency of the collective arrays is less than the hydrodynamic efficiency of a single OWC chamber at the wall focus, but more efficient than an isolated OWC chamber positioned in open-sea conditions. Moreover, the hydrodynamic efficiency of the arrays exhibits better stability across the range of incident wave periods investigated, denoting that the individual component chambers in the array are efficacious at different incident wave conditions. The five chamber array is comprehensively analysed in irregular incident wave conditions. The array system is demonstrated to maintain a high power output and efficient behaviour in irregular incident wave conditions-an effect attributable to the reflecting wall influence. In summary, the five-chamber array configuration yields a higher power output and improved stability in terms of efficiency performance when compared with the three-chamber array configuration in regular waves. The array maintains this exceptional performance in irregular incident wave conditions.

在规则和不规则波浪条件下与抛物面波浪能聚能器耦合的振荡水柱波浪能转换器阵列
基于之前对单个高效振荡水柱(OWC)波能捕获系统的研究(Mayon 等人,2021 年),这项工作将数值研究进一步扩展到波能转换器(WEC)阵列与抛物面聚能墙在规则和不规则入射波条件下的布局设计和性能。本文提出了一种启发式方法,用于确定阵列中安装在墙凹口处的圆柱形有源波浪能转换器组件的最佳位置。研究发现,最优越的风室位置位于从墙壁嵌入的抛物线曲率线上。在一系列规则波浪条件下,对由三个和五个组件组成的两个独立 OWC 阵列进行了研究。确定了每个阵列中每个舱室的水动力功率和效率,随后确定了阵列的总体性能。研究发现,阵列配置中的主要 OWC 腔室可以获得与位于抛物面壁焦点的单个孤立 OWC 腔室大致相同的水动力输出功率,尽管能量捕获带宽较窄。阵列中的二级和三级组件腔室对综合系统的流体动力贡献较小,但仍然相当可观。集合阵列的累积水动力效率低于位于壁面焦点的单个 OWC 舱室的水动力效率,但高于位于开放海域条件下的孤立 OWC 舱室的效率。此外,在所研究的入射波周期范围内,阵列的流体动力学效率表现出更好的稳定性,这表明阵列中的单个组件腔室在不同的入射波条件下具有不同的效率。在不规则入射波条件下对五室阵列进行了全面分析。结果表明,该阵列系统在不规则入射波条件下仍能保持高功率输出和高效性能--这归因于反射墙的影响。总之,与规则波浪中的三室阵列配置相比,五室阵列配置能产生更高的功率输出和更稳定的效率性能。在不规则入射波条件下,该阵列仍能保持这种优异性能。
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来源期刊
Coastal Engineering
Coastal Engineering 工程技术-工程:大洋
CiteScore
9.20
自引率
13.60%
发文量
0
审稿时长
3.5 months
期刊介绍: Coastal Engineering is an international medium for coastal engineers and scientists. Combining practical applications with modern technological and scientific approaches, such as mathematical and numerical modelling, laboratory and field observations and experiments, it publishes fundamental studies as well as case studies on the following aspects of coastal, harbour and offshore engineering: waves, currents and sediment transport; coastal, estuarine and offshore morphology; technical and functional design of coastal and harbour structures; morphological and environmental impact of coastal, harbour and offshore structures.
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