Flow separation control by using bowed blade in highly loaded turbine cascades 被引量：3

Flow separation control by using bowed blade in highly loaded turbine cascades

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摘要 Due to the serious flow separations and centralized vortices,there are high secondary losses in highly loaded turbines.It is imperative to find measures to control the flow separation and vortices hence improve the turbine performance.This paper reports our recent progress on flow separation and vor-tices control in highly loaded turbine cascades by using bowed blades.Two sets of highly loaded tur-bine cascades with the turning angles of 113° and 160°,and each with 7 bowed blade angles 0°(straight),±10°,±20° and ±30° were experimentally investigated.Both internal flow field measurement and flow visualization on the blade surfaces were conducted,and the effects of blade bowing on the flow topology,distribution of vorticity and the flow energy loss were discussed.The results show that,for the cascade with the turning angle of 113°,the appropriately positive bow angle could reduce the flow energy loss;whereas for the cascade with the turning angle of 160°,the well selected negative bow angle can give the better aerodynamic performance. Due to the serious flow separations and centralized vortices, there are high secondary losses in highly loaded turbines. It is imperative to find measures to control the flow separation and vortices hence improve the turbine performance. This paper reports our recent progress on flow separation and vortices control in highly loaded turbine cascades by using bowed blades. Two sets of highly loaded turbine cascades with the turning angles of 113° and 160°, and each with 7 bowed blade angles 0° (straight), ±10°, ±20° and ±30° were experimentally investigated. Both internal flow field measurement and flow visualization on the blade surfaces were conducted, and the effects of blade bowing on the flow topology, distribution of vorticity and the flow energy loss were discussed. The results show that, for the cascade with the turning angle of 113°, the appropriately positive bow angle could reduce the flow energy loss; whereas for the cascade with the turning angle of 160°, the well selected negative bow angle can give the better aerodynamic performance.

作者 YAMAMOTO Atsumasa

机构地区 Japan Aerospace Exploration Agency

出处《Science China(Technological Sciences)》 SCIE EI CAS 2009年第6期1471-1477,共7页 中国科学（技术科学英文版）

基金 Supported by the National Natural Science Foundation of China(Grant No.10577019)

关键词 TURBINE CASCADE TURNING ANGLE flow SEPARATION bowed BLADE turbine cascade turning angle flow separation bowed blade

分类号 TB126 [理学—工程力学]

引文网络
相关文献

参考文献10

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同被引文献24

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引证文献3

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Flow separation control by using bowed blade in highly loaded turbine cascades 被引量：3

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