漏斗形双通道与浮标集成式近海海浪发电机
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摘要
设计完成了一套用于近海海浪发电的装置,通过漏斗形双通道实现水流双向持续不间断地对发电机做功,充分利用冲击和回流两种浪的能量。装置借助于漏斗形进水口使水流集中冲击叶轮快速转动,并在通道允许空间内最大化集成浮标发电装置,实现了能在有限空间内将海浪所蕴藏的动能和势能最大化地转变为电能,得出了一个具有高可行性的方案和最优化高效率的近海海浪发电装置。相关计算表明,本装置的能量转换效率可达11.7%。
In this experiment,a set of devices for near-shore wave power generation is designed.The funnel-shaped dual-channel realizes the flow of water in two directions and continuously works on the generator,making full use of the energy of the two waves of impact and return.By means of the funnel-shaped water inlet,the water flow is concentrated to impact the impeller to rotate rapidly,and the integrated buoy power generating device is maximized in the space allowed by the channel.The device realizes that the kinetic energy and potential energy contained in the ocean wave can be converted into electric energy in a limited space,and a highly feasible solution and an optimized high-efficiency offshore wave power generating device are obtained.Related calculations show that the energy conversion efficiency of the device can reach 11.7%.
In this experiment,a set of devices for near-shore wave power generation is designed.The funnel-shaped dual-channel realizes the flow of water in two directions and continuously works on the generator,making full use of the energy of the two waves of impact and return.By means of the funnel-shaped water inlet,the water flow is concentrated to impact the impeller to rotate rapidly,and the integrated buoy power generating device is maximized in the space allowed by the channel.The device realizes that the kinetic energy and potential energy contained in the ocean wave can be converted into electric energy in a limited space,and a highly feasible solution and an optimized high-efficiency offshore wave power generating device are obtained.Related calculations show that the energy conversion efficiency of the device can reach 11.7%.
引文
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[2] 李丹,白保东,俞清,等.漂浮式海浪发电系统研究[J].太阳能学报,2011,32(10):1566-1570.
[3] 陈永华.波浪驱动式海洋要素垂直剖面测量系统关键技术[D].中国科学院研究生院(海洋研究所),2008.
[4] 刘强.各国开发海洋能源发电现状[J].发电设备,2007(6):507-508.
[5] 林江波.浮子式海浪发电船的动态分析与仿真[D].燕山大学,2006.
[6] 孙景力.海浪发电——取之不竭的能源[J].电器工业,2005(1):51-53.
[7] 杨恒山.海浪发电用圆筒型直线发电机设计与研究[D].东南大学,2010.DOI:10.7666/d.y1761153.
[8] 范航宇.一种新型漂浮式破浪发电系统研究[D].北京:清华大学硕士学位论文,2005(5).
[9] 李远林.波浪理论及波浪载荷[M].广州:华南理工大学出版社,1994(7).
[10] 邱大洪.波浪理论及其在工程中的应用[M].北京:海洋出版社,1985.
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