期刊文献+

潮流水轮机导流罩的水动力设计 被引量:26

Hydrodynamic design of diversion cover for a tidal-stream hydro turbine
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摘要 为了提高潮流水轮机的效率,参照风力机扩散器原理设计了一种适用于竖轴直叶片水轮机的导流罩.主要考虑潮流工作流场对称性的特点,提出了二大类型6种导流罩设计模型方案;应用F luent软件进行水动力性能计算,确定流速大,阻力小的S3为最优型线;在导流罩出口位置增加对称的扩张门,可以进一步提高导流罩内流场的流速和稳定性;模型实验验证了S3型导流罩设计模型的有效性,加导流罩后轮机功率系数曲线整体上升,峰值可提高39%.该设计研究为导流增强型潮流水轮机的研究和实践提供了理论基础. In order to improve the efficiency of a tidal-stream hydro turbine, a dome for a straight-blade turbine was devised based on diffusers used with wind turbines. After conside power station, six 2-D dome models of 2 types were suggested. Calc g ul the symmetry of flow fields in a tidal stream ations of their hydrodynamic properties were done with Fluent software. From the calculated results, S3 was determined to be the optimal profile, as it exhibits greatest velocity and smallest resistance. A pair of symmetrical diffusers were installed at the outlet of the dome, improving the velocity and stability of flow fields in the dome. The effectiveness of S3 was proved by experiments with models. After the dome was added, the power coefficient curve of the hydro turbine rose over the full range, and the peak value increased by 39%. This design and research work offers an academic basis for further research on tidal-stream hydro turbines with installed domes
出处 《哈尔滨工程大学学报》 EI CAS CSCD 北大核心 2007年第7期734-737,共4页 Journal of Harbin Engineering University
基金 国自然科学基金资助项目(50279004) 国家863计划后续能源技术领域资助项目(2002AA516010 2005AA516030)
关键词 导流罩 潮流能 扩散器 直叶轮机 dome tidal stream energy diffuser straight blade turbine
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参考文献4

  • 1RUDKIN E J,LOUGHNAN G L.Vortec-the marine energy solution[A].Marine Renewable Energy Conference[C].Newcastle,UK,2001:151-157.
  • 2汪建文,孙科,贾瑞博.风力机扩散放大器流场的数值仿真[J].能源技术,2004,25(5):185-187. 被引量:5
  • 3中国人民解放军总装备部军事训练教材编辑工作委员会.高低速风洞气动与结构设计[M].北京:国防工业出版社,2003.
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二级参考文献7

  • 1D.G. Phillips, P.J. Richards, R.G.J. Flay. Diffuser Development for a Diffuser Augmented Wind Turbine Using Computational Fluid Dynamics[Z]. Department of Mechanical, Engineering, the University of Auckland, New Zealand.
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  • 3Foreman, K.M., Maciulaitis, A. and Gilbert, B.L. Performance Predictions and Recent Data for Advanced DAWT Models[M]. ASME Solar Energy Division, Grumman Aerospace Corp., Bethpage, New York, April 1983.
  • 4Richards, P.J., Hoxey, R.P. Appropriate boundary conditions for computational wind engineering models using the k-? turbulence model[J]. J. Wind Engng and Ind. Aerodyn,1993,46 & 47:145-153.
  • 5Phillips, D.G.,Nash,T.A.,Oakey,A., Flay, R.G. J, Richards, P. J. Computational Fluid Dynamics and Wind Tunnel Modelling of a Diffuser Augmented Wingd Turbine[J]. Wind Engineering,1999,23(1):7.
  • 6Phillips, D.G., Richards, P. J. and Flay, R.G. J. CFD Modelling and The Development of The Diffuser Augmented Wind Turbine[M]. Proceedings of Wind Eng.2000, Birmingham, pp.189-192.
  • 7Wang Jianwen. The Experimental Research on Diffuser Augmented Wind Power[J]. SVBL Rep., 2002.2:1-15.

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