轮缘封严气流与主流干涉的损失机理研究

doi:10.13675/j.cnki.tjjs.180812

推进技术 ›› 2020, Vol. 41 ›› Issue (2): 285-293.DOI: 10.13675/j.cnki.tjjs.180812

轮缘封严气流与主流干涉的损失机理研究

杨帆¹,周莉¹,王占学¹

西北工业大学动力与能源学院，陕西西安 710129

发布日期:2021-08-15
基金资助:
国家自然科学基金（51876176；51576163）。

Investigation on Interaction Loss Mechanism Between Rim Seal Flow and Mainstream

School of Power and Energy,Northwestern Polytechnical University, Xi’an 710129, China

Published:2021-08-15

摘要/Abstract

摘要： 为了研究涡轮转静盘腔中轮缘封严气流与主流干涉的损失机理，开展了在有无封严气流工况下轮缘封严气流与主流干涉的损失机制和分解量化方法研究。结果表明，轮缘封严气流与主流干涉存在四种损失机制：粘性剪切损失、堵塞效应损失、二次流交互作用损失以及第二级静子的附加损失。设计工况下粘性剪切损失的比例为67.68%，而其它三种损失的比例相当。随着封严流量增大，封严出流的流量和径向速度不断增大而周向速度不断减小，造成四种损失都不断增大。相对于设计工况，每1%封严流量使得总损失平均增大约为104.25%。所建立的损失量化体系准确地捕捉到了转子堵塞效应损失和二次流交互作用损失不断增大的分布，证明损失量化体系是可行和有效的。

关键词: 涡轮;转静盘腔;封严气流;干涉;损失机理

Abstract: In order to investigate the interaction loss mechanisms between turbine stator-rotor cavity rim seal flow and mainstream, investigations were conducted on the loss factors and isolation method for interaction between the rim seal flow and mainstream for the case with and without the rim seal flow. The results show that four loss factors are considered, namely viscous shear loss, blockage effect loss, secondary flow interaction loss and second stator additional loss. Among these four loss factors, the percent of viscous shear loss is 67.68% at design condition. In addition, the percent of other three loss factors approaches each other. With the increment of rim seal flow rate, the mass flow rate and radial velocity of egress flow increase and the circumferential velocity of egress flow reduces, which leads four losses to increase. Relative to the design condition, the total loss increases by approximately 104.25% per 1% increase in the rim seal flow rate. Furthermore, the established loss quantitative system exactly captures the increasing trend of blockage effect loss in rotor domain and secondary flow interaction loss. Therefore, the loss quantitative system is further proven to be feasible and effective.

Key words: Turbine;Stator-rotor cavity;Rim seal flow;Interaction;Loss mechanism

杨帆,周莉,王占学. 轮缘封严气流与主流干涉的损失机理研究 [J]. 推进技术, 2020, 41(2): 285-293.

YANG Fan¹,ZHOU Li¹,WANG Zhan-xue¹. Investigation on Interaction Loss Mechanism Between Rim Seal Flow and Mainstream[J]. Journal of Propulsion Technology, 2020, 41(2): 285-293.

参考文献

[1] 张晶辉, 马宏伟 . 轮缘封严气体对涡轮转子性能影响的非定常数值研究[J]. 推进技术， 2014， 35( 4): 470- 478.
[2] 杨帆，周莉，王占学 . 轮缘封严气流与转子干涉损失机理的数值研究[J]. 推进技术， 2018， 39( 11): 2481- 2489.
[3] 杨帆，周莉，王占学 . 轮缘封严气流与主流涡系交互作用的非定常数值研究[J]. 推进技术， 2019， 40( 2): 315- 323.
[4] Cui J ， Tucker P . Numerical Study of Purge Flows in a Low-Pressure Turbine[R]. ASME 2016-GT-5678 9.
[5] HU Jian-lin ， DU Qiang ， LIU Jun ， et al . Flow Development Through HP & LP Turbines， Part II: Effects of the Hub Endwall Secondary Sealing Air Flow on the Turbine’s Mainstream Flow[J]. Journal of Thermal Science， 2017， 26( 4): 308- 315.
[6] WANG Li-xiang ， MA Hong-wei ， ZHANG Jing-hui . Experimental Investigation of Effects of Rim Sealing Flow on the Flow Field in a Turbine Cascade Passage with Different Rim Seal Configuration[R]. ASME 2016-GT-5684 8.
[7] Schadler R ， Kalfas A I ， Abhari R S ， et al . Modulation and Radial Migration of Turbine Hub Cavity Modes by the Rim Seal Purge Flow[R]. ASME 2016-GT-5666 1.
[8] SONG Li-ming ， ZHU Pei-yuan ， LI Jun ， et al . Effect of Purge Flow on Endwall Flow and Heat Transfer Characteristic of a Gas Turbine Blade[J]. Applied Thermal Engineering， 2017， 110( 5): 504- 520.
[9] Reid K ， Denton J ， Pullan G ， et al . The Effect of Sator-rotor Hub Sealing Flow on the Mainstream Aerodynamics of a Turbine[R]. ASME 2006-GT-9083 8.
[10] Pau M ， Paniagua G . Investigation of the Flow Field on a Transonic Turbine Nozzle Guide Vane with Rim Seal Cavity Flow Ejection[J]. Journal of Fluid Engineering， 2010， 133( 11).
[11] Ong J ， Miller R J ， Uchida S . The Effect of Coolant Injection on the Endwall Flow of a High Pressure Turbine[J]. Journal of Turbomachinery， 2012， 134( 5).
[12] Zlatinov M B ， Tan V S ， Montgomery M ， et al . Turbine Hub and Shroud Sealing Flow Loss Mechanisms[J]. Journal of Turboimachinery， 2012， 134( 11): 1- 12.
[13] Schrewe S ， Werschnik H ， Schiffer H P . Experimental Analysis of the Interaction Between Rim Seal and Main Annulus Flow in a Low Pressure Two Stage Axial Turbine[R]. ASME 2013-GT-0510 03.
[14] JIA Wei ， LIU Huo-xing . Numerical Investigation of the Interaction Between Upstream Purge Flow and Mainstream in a Highly-Loaded Turbine[R]. ASME 2014-GT-2527 6.
[15] Behr T . Control of Rotor Tip Leakage and Secondary Flow by Casing AIR Injection in Unshrouded Axial Turbines[D]. Dresden: Dresden University of Technology， 2007.
[16] Schuepbach P ， Abhari R S ， Rose M G ， et al . Sensitivity of Turbine Efficiency and Flow Structures to Varying Purge Flow[J]. Journal of Propulsion and Power， 2010， 26( 1): 46- 56.
[17] Schuepbach P . Influence of Rim Seal Purge Flow on Performance of an End Wall Profiled Axial Turbine[D]. Swiss: Swiss Federal Institute of Technology， 2009.
[18] Young J B ， Wilcock R C . Modeling the Air-Cooled Gas Turbine: Part 2-Coolant Flows and Losses[J]. Journal of Turbomachinery， 2002， 124( 2): 214- 221.
[19] Cumpsty N A ， Horlock J H . Modeling the Air-Cooled Averaging Nonuniform Flow for Purpose[J]. Journal of Turbomachinery， 2006， 128( 1): 120- 129.
[20] Horlock J H . The Basic Thermodynamics of Turbine Cooling[J]. Journal of Turbomachinery， 2001， 123( 3): 583- 592.

轮缘封严气流与主流干涉的损失机理研究

Investigation on Interaction Loss Mechanism Between Rim Seal Flow and Mainstream

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