Research on the Unsteady Hydrodynamic Characteristics of Vertical Axis Tidal Turbine 被引量：5

Research on the Unsteady Hydrodynamic Characteristics of Vertical Axis Tidal Turbine

下载PDF

导出

摘要 The unsteady hydrodynamic characteristics of vertical axis tidal turbine are investigated by numerical simulation based on viscous CFD method. The starting mechanism of the turbine is revealed through analyzing the interaction of its motion and dynamics during starting process. The operating hydrodynamic characteristics of the turbine in wave-current condition are also explored by combining with the linear wave theory. According to possible magnification of the cyclic loads in the maximum power tracking control of vertical axis turbine, a novel torque control strategy is put forward, which can improve the structural characteristics significantly without effecting energy efficiency. The unsteady hydrodynamic characteristics of vertical axis tidal turbine are investigated by numerical simulation based on viscous CFD method. The starting mechanism of the turbine is revealed through analyzing the interaction of its motion and dynamics during starting process. The operating hydrodynamic characteristics of the turbine in wave-current condition are also explored by combining with the linear wave theory. According to possible magnification of the cyclic loads in the maximum power tracking control of vertical axis turbine, a novel torque control strategy is put forward, which can improve the structural characteristics significantly without effecting energy efficiency.

作者张学伟张亮王峰赵东亚庞程燕

机构地区 Deepwater Engineering Research Center

出处《China Ocean Engineering》 SCIE EI CSCD 2014年第1期95-103,共9页 中国海洋工程（英文版）

基金 supported by the National Natural Science Foundation of China(Grant No.51106034) the Central Universities Fundamental Research Foundation(Grant No.HEUCFR1104) the Marine Renewable Energy Special Foundation(Grant Nos.ZJME2010CY01 and ZJME2010GC01)

关键词 tidal current energy vertical axis turbine wave-current condition torque control starting mechanism tidal current energy vertical axis turbine wave-current condition torque control starting mechanism

分类号 TK730.1 [交通运输工程—轮机工程]

引文网络
相关文献

参考文献2

1张亮,李志川,刘健,孙科.垂直轴水轮机耦合数值模拟研究[J].哈尔滨工业大学学报,2011,43(S1):228-231. 被引量：9
2贾要勤,曹秉刚,杨仲庆.风力发电的MPPT快速响应控制方法[J].太阳能学报,2004,25(2):171-176. 被引量：33

二级参考文献19

1Hatziargyriou N D, Karakatsanis T S, Papadopoulos M. Probabilistic load flow in distribution systems containing dispersed wind power generation [ J ]. IEEE Trans Power Systems, 1993, 8: 159-165.
2Kellogg W D, Nehrir M H, Venkataramanan G, et al. Generation unit sizing and cost analysis for standalone wind, photovoltaic, and hybrid wind/PV systems [J]. IEEE Trans Energy Conversion, 1998, 13:70-75.
3Papathanassiou S A, Kladas A G, Tegopoulos J A.Applications of artificial intelligence techniques in wind power generation [J]. Integrated Computer-Aided Engineering, 2001, 8: 231-242.
4Li Shuhui, Wunsch Donald C. O' Hair Edgar A, et al.Using neural networks to estimate wind turbine power generation [ J ]. IEEE Trans Energy Conversion,2001, 16: 276-282.
5Simoes Marcelo Godoy, Bose Bimal K, Ronald J Spiegel.Design and performance evaluation of a fuzzy-logic-based variable-speed wind generation system [J]. IEEE Trans Industry Applications, 1997, 33: 956-965.
6Muljadi Eduard, Butterfield C P. Pitch-controlled variable-speed wind turbine generation [J ]. IEEE Trans Industry Applications, 2001, 37: 240-246.
7Bhowmik Shibashis, Spee Rene, Enslin Johan H R.Performance optimization for doubly fed wind power generation systems [J ]. IEEE Trans Industry Applications, 1999, 35: 949-958.
8Eggleston David M, Stoddard Forrest S. Wind turbine engineering design [ M]. New York: VAN NOSTRAND REINHOLD COMPANY, 1987: 15-65.
9Paraschivoiu Ion. Double-multiple streamtube modelfor Darrieus wind turbines [A]. DOE / NASA Wind Turbine Dynamics Workshop 2nd Cleveland [ C] ,1981: 19-24.
10Klimas Paul C. Recent Darrieus vertical axis wind turbine aerodynamical experiments at Sandia National Laboratories[A]. DOE / NASA Wind Turbine Dynamics Workshop 2nd Cleveland[C], 1981: 67-74.

共引文献40

1刘吉成.基于CFD新模型和数学模型研究方形管道内垂直轴水轮机的特性[J].中国多媒体与网络教学学报（电子版）,2020(2):224-225.
2顾勇,张晓峰,吕英丽.小型风光互补能量控制策略探讨[J].河北建筑工程学院学报,2011,29(4):63-65.
3徐科,胡敏强,杜炎森,杨晓静.直流母线电压控制实现并网与最大风能跟踪[J].电力系统自动化,2007,31(11):53-58. 被引量：22
4孙国霞,李啸骢,蔡义明.大型变速恒频风电系统的建模与仿真[J].电力自动化设备,2007,27(10):69-73. 被引量：35
5李辉,何蓓.双馈风力发电系统的最大风能控制策略[J].太阳能学报,2008,29(7):797-803. 被引量：18
6黄永花,陆俊杰,朱立波.风力、水力双驱动发电控制策略的研究[J].电气开关,2009,47(3):61-64. 被引量：1
7耿华,杨耕,周伟松.考虑风机动态的最大风能捕获策略[J].电力自动化设备,2009,29(10):107-111. 被引量：29
8夏晓敏,王坤琳,吴必军.小型风电系统MPPT模糊／PID控制仿真研究[J].能源工程,2010(1):26-31. 被引量：5
9郭鹏.自回归滑动平均模型风速预测最大风能追踪策略研究[J].华北电力大学学报（自然科学版）,2010,37(2):89-93. 被引量：5
10陈毅东,杨育林,王立乔,贾志云,赵巍,万承宽.风力发电最大功率点跟踪技术及仿真分析[J].高电压技术,2010,36(5):1322-1326. 被引量：28

同被引文献40

1张亮,汪鲁兵,李凤来,张桂湘.竖轴变攻角潮流发电水轮机性能预报流管模型研究[J].哈尔滨工程大学学报,2004,25(3):261-266. 被引量：14
2汪鲁兵,张亮,曾念东.一种竖轴潮流发电水轮机性能优化方法的初步研究[J].哈尔滨工程大学学报,2004,25(4):417-422. 被引量：20
3辛公正,洪方文,黄振宇,唐登海,董世汤.与粘流耦合的导管螺旋桨升力面设计方法[J].船舶力学,2007,11(1):22-31. 被引量：7
4朱德祥,张志荣,吴乘胜,赵峰.船舶CFD不确定度分析及ITTC临时规程的初步应用[J].水动力学研究与进展（A辑）,2007,22(3):363-370. 被引量：43
5刘志华,熊鹰,叶金铭,谭廷寿.基于多块混合网格的RANS方法预报螺旋桨敞水性能的研究[J].水动力学研究与进展（A辑）,2007,22(4):450-456. 被引量：44
6张亮,孙科,罗庆杰.潮流水轮机导流罩的水动力设计[J].哈尔滨工程大学学报,2007,28(7):734-737. 被引量：25
7胡健,黄胜,王陪生,苏玉民.可调螺距螺旋桨水动力性能分析[J].船舶工程,2007,29(6):41-45. 被引量：13
8吕新刚,乔方利.海洋潮流能资源估算方法研究进展[J].海洋科学进展,2008,26(1):98-108. 被引量：42
9张楠,沈泓萃,姚惠之.阻力和流场的CFD不确定度分析探讨[J].船舶力学,2008,12(2):211-224. 被引量：41
10施科益,杨世锡.一种新型摆线推进器控制系统的设计[J].机电工程,2008,25(10):91-94. 被引量：2

引证文献5

1张亮,尚景宏,张之阳,姜劲,王晓航.潮流能研究现状2015--水动力学[J].水力发电学报,2016,35(2):1-15. 被引量：33
2张锦岚,王凯,张万超,周亚辉.浮式振荡立轴叶轮的三维效应影响[J].国防科技大学学报,2019,41(3):63-69.
3刘文涛,刘志华,骆飞洋.两种运动方式的直翼推进器水动力性能比较[J].推进技术,2022,43(5):386-398. 被引量：2
4张成林,刘安东,王世明,谢双义.不同纵荡幅值下浮式水平轴叶轮的水动力性能分析[J].太阳能学报,2022,43(12):482-488.
5刘文涛,刘志华,马骋,陈前.调距桨动态调距计算方法研究[J].中国造船,2022,63(6):14-30.

二级引证文献35

1方群.某型喷水推进器水动力性能分析与优化设计[J].新型工业化,2022,12(10):95-98.
2张其利,何隆英,赵阳,孙超,张雪明,郭景富.一种通用潮流能发电装置远程监控系统的设计与实现[J].太阳能学报,2018,39(12):3319-3324. 被引量：2
3张继生,曹运修,吴修广,宋凡,戴鹏.并排水平轴潮流能水轮机组水动力特性研究[J].河海大学学报（自然科学版）,2017,45(3):256-262. 被引量：3
4王世明,訾丹丹,邹伟,白连平.双向叶轮直驱式海浪发电装置设计与优化[J].水利水电技术,2017,48(9):216-222. 被引量：3
5胡秋皓,李晔,章丽骏.不同工况下潮流能水平轴水轮机大涡模拟研究[J].水动力学研究与进展（A辑）,2017,32(5):575-583. 被引量：2
6谭俊哲,李仁军,司先才,王树杰,梁兰健,袁鹏.海底地形对潮流能水轮机水动力学性能影响数值模拟研究[J].海洋技术学报,2018,37(1):94-101. 被引量：5
7张继生,王雅,唐子豪,范文彰,张田田.舟山潮流能示范工程水轮机组选址与阵列优化[J].河海大学学报（自然科学版）,2018,46(3):240-245. 被引量：5
8张建华,杨思远,孙科,佟丽莉,林佳悦.潮流能水轮机复合材料叶片优化设计[J].可再生能源,2018,36(10):1561-1566. 被引量：1
9姜劲,王润玉,张亮.摆线式潮流能垂直轴水轮机尾涡模拟[J].黑龙江大学自然科学学报,2018,35(4):493-498.
10陈文鹏,刘胤超,陈立卫.基于UDF的水平轴潮流能水轮机被动旋转水动力性能研究[J].海洋工程,2018,36(2):119-126. 被引量：6

1ZHANG Xue-weii,WANG Shu-qi,WANG Feng,ZHANG Liang,SHENG Qi-hu.THE HYDRODYNAMIC CHARACTERISTICS OF FREE VARIABLE-PITCH VERTICAL AXIS TIDAL TURBIN[J].Journal of Hydrodynamics,2012,24(6):834-839. 被引量：4
2汤金桦,李春,李润杰.垂直轴潮流能涡轮机水动特性研究[J].水资源与水工程学报,2017,28(1):130-135. 被引量：2
3可移动的水电站[J].军民两用技术与产品,2010(3):26-26.
4陈小鹏,沈昊,陈佳,王珊.泵站前池设计分析[J].中国水运（下半月）,2012,12(9):245-246. 被引量：1
5李林娟,郑金海,彭于轩,张继生,吴修广.Numerical Investigation of Flow Motion and Performance of A Horizontal Axis Tidal Turbine Subjected to A Steady Current[J].China Ocean Engineering,2015,29(2):209-222. 被引量：8
6马勇,李腾飞,张亮,盛其虎,张学伟,姜劲.Experimental Study on Hydrodynamic Characteristics of Vertical-Axis Floating Tidal Current Energy Power Generation Device[J].China Ocean Engineering,2016,30(5):749-762. 被引量：3
7Yucen LU Yongming SHEN.Influence of bathymetry evolution on position of tidal shear front and hydrodynamic characteristics around the Yellow River estuary[J].Frontiers of Earth Science,2012,6(4):405-419. 被引量：3
8陈南（编译）.水力发电的百年历程[J].治黄科技信息,2011(1):30-31.
9DU Qiang,WANG Pei,GONG JianBo,ZHU JunQiang.Design performance evaluation and vortex structure investigation of different S-shaped intermediate turbine ducts[J].Science China(Technological Sciences),2012,55(12):3510-3520. 被引量：2
10剑琳.大爆炸[J].科技新时代,2009(12):20-21.

China Ocean Engineering

2014年第1期

浏览历史

内容加载中请稍等...