以一套含有多个发电机组的波浪能发电装置液压系统样机为研究对象,介绍系统组成及运行原理,并通过研发的液压测试平台对两种发电控制策略开展试验研究。首先,对流量控制阀变开度发电控制策略开展试验,结果表明采用该策略可使输出电压在一段时间内趋于稳定,提高发电质量,同时提出两种基于液压测试平台获取比例流量控制阀有效输入电信号的方法。其次,通过在液压系统样机输出端接入多个发电机组实现梯度发电控制策略,数据结果证实可有效提高瞬时输出功率,提升波浪能发电装置在不同波况下的自适应性,同时对在实海况中实现该控制策略的条件进行初步讨论。
Abstract
Taking the hydraulic system of a wave energy converter (WEC) with several generators as the research object,the composition and working principle of the hydraulic system are introduced, and the experimental study on two power generation control strategies are carried out through the self-made hydraulic test platform. The power generation control strategy of changing the opening of flow control valve is first tested. The results show that using this control strategy can stabilize the output voltage for a period of time and improve the power generation quality. Two methods based on hydraulic test platform to obtain the effective input electrical signal of the proportional flow control valve are also proposed. Secondly,the gradient power generation control strategy is realized by connecting generator sets to the output end of the hydraulic system. The data results confirm that the gradient power generation control strategy can effectively improve the instantaneous output power and enhance the adaptability of the WEC under different wave conditions. The conditions for realizing this control strategy in actual sea conditions are discussed preliminary.
关键词
海洋能 /
波浪能 /
液压系统 /
控制策略
Key words
ocean energy /
wave energy /
hydraulic system /
control strategy
{{custom_sec.title}}
{{custom_sec.title}}
{{custom_sec.content}}
参考文献
[1] YOU Y G, ZHENG Y H, SHEN Y M, et al.Wave energy study in China: advancements and perspectives[J]. China ocean engineering, 2003, 17(1): 99-107.
[2] 李强, 何宏舟, 刘森明, 等. 浮子式波浪能转换装置研究概述[J]. 海洋开发与管理, 2016, 33(3): 64-68.
LI Q, HE H Z, LIU S M, et al.On the float type wave energy converters[J]. Ocean development and management, 2016, 33(3): 64-68.
[3] 王锰, 李蒙, 夏增艳, 等. 浮力摆式波浪能发电装置模型试验[J]. 海洋技术, 2013, 32(1): 79-82.
WANG M, LI M, XIA Z Y, et al.Model test of buoyant pendulum wave-power generation device[J]. Ocean technology, 2013, 32(1): 79-82.
[4] 盛松伟. 漂浮鸭式波浪能发电装置研究[D]. 北京: 中国科学院大学, 2011.
SHENG S W.Study on floating duck wave power generation device[D]. Beijing: University of Chinese Academy of Sciences, 2011.
[5] 盛松伟, 王坤林, 吝红军, 等. 100 kW鹰式波浪能发电装置“万山号”实海况试验[J]. 太阳能学报, 2019, 40(3): 709-714.
SHENG S W, WANG K L, LIN H J, et al.Open sea tests of 100 kW wave energy convertor sharp eagle Wanshan[J]. Acta energiae solaris sinica, 2019, 40(3): 709-714.
[6] 叶寅, 游亚戈, 王振鹏, 等. 波浪能装置液压自动分级控制系统研究[J]. 太阳能学报, 2019, 40(6): 1481-1486.
YE Y, YOU Y G, WANG Z P, et al.Automatic classification control system of wave energy device research[J]. Acta energiae solaris sinica, 2019, 40(6): 1481-1486.
[7] 王坤林, 田联房, 王孝洪, 等. 液压蓄能式波浪能装置发电系统的特性[J]. 华南理工大学学报(自然科学版), 2014, 42(6): 25-31.
WANG K L, TIAN L F, WANG X H, et al.Characteristics of power generation system with hydraulic energy-storage wave energy converter[J]. Journal of South China University of Technology (natural science edition), 2014, 42(6): 25-31.
[8] 张家明, 黎明, 张帅, 等. 100 kW组合型振荡浮子式波浪发电装置能量转换系统研究[J]. 太阳能学报, 2017, 38(12): 3355-3362.
ZHANG J M, LI M, ZHANG S, et al.Energy conversion system research of 100 kW combined oscillating float wave power plant[J]. Acta energiae solaris sinica, 2017, 38(12): 3355-3362.
基金
中国-东盟国家蓝色伙伴关系建设(N3220DM03)
PDF(1858 KB)
