Numerical Study on Effects of Different Excitation Forms on Forced Film Cooling Characteristics

doi:10.13675/j.cnki.tjjs.190318

Journal of Propulsion Technology ›› 2020, Vol. 41 ›› Issue (4): 860-867.DOI: 10.13675/j.cnki.tjjs.190318

• Combustion and Heat Transfer • Previous Articles Next Articles

Numerical Study on Effects of Different Excitation Forms on Forced Film Cooling Characteristics

School of Energy Science and Engineering，Harbin Institute of Technology，Harbin 150001，China

Published:2021-08-15

不同激励形式对脉动气膜冷却特性影响的数值研究

陈佳伟¹，蔡乐¹，王松涛¹

哈尔滨工业大学能源科学与工程学院，黑龙江哈尔滨 150001

作者简介:陈佳伟，硕士生，研究领域为叶轮机械气动与冷却研究。E-mail：chen_jiawei@163.com

Abstract

Abstract: In order to study the effects of different excitation forms on forced film cooling characteristics, relevant investigation was performed in a 35° inclined jet-in-crossflow model by unsteady numerical simulation method. The commonly used waves, square wave and sinusoidal wave were selected as excitations to the coolant and the nondimensional forcing frequencies of Strouhal numbers are 0.019, 0.047, 0.093, 0.263 and 0.441. This paper mainly compared the attachment of the coolant as well as the ingestion of the hot mainstream. The results show that coolant with sinusoidal excitation has stronger attachment to the wall and higher cooling effectiveness, whereas coolant with square excitations has stronger penetration but relatively weaker attachment. Besides, ingestion of hot mainstream exists under square excitation, which can cause ablation to the holes and parts of the wall. However, sinusoidal excitation makes the coolant change gradually, which significantly restrains the ingestion. Further, improving the lowest blowing ratio is not the best way to restrain the ingestion, since the ingestion is mainly caused by the excessively changed amount of coolant. As for sinusoidal excitation, the coolant with Strouhal numbers higher than 0.263 also results in the ingestion of mainstream. Considering cooling effectiveness and restraining ingestion, continuous wave with relatively low frequency is recommended for practical use.

Key words: Unsteady numerical simulation;Forced film cooling;Square wave;Sinusoidal wave;Cooling effectiveness;Ingestion of crossflow;Continuity

摘要： 为了探究不同激励形式对脉动气膜冷却特性的影响，在35°倾角平板射流模型中，采用非定常数值模拟方法进行相关研究。挑选常用的方波和正弦波作为冷气激励，无量纲激励频率斯特劳哈尔数St=0.019,0.047,0.093,0.263,0.441，重点对冷气附着和高温主流入侵现象进行了对比研究。结果表明：正弦激励下的冷气对壁面有更强的附着和更高的冷却效率；方波激励下的冷气穿透能力较强但对壁面附着相对较弱。此外，方波激励下存在主流入侵，会烧蚀气膜孔及局部壁面；而正弦激励使得冷气连续变化，能明显抑制主流入侵。更进一步，提高脉动周期内的最低吹风比不是抑制主流入侵的最佳方式，因为主流入侵主要是因为冷气量变化过于剧烈。针对正弦激励，冷气的无量纲激励频率St>0.263后也会导致主流入侵。考虑冷却效果和避免主流入侵，建议在实际应用中选用较低频连续波形作为激励。

关键词: 非定常数值模拟;脉动气膜冷却;方波;正弦波;冷却效率;主流入侵;连续性

CHEN Jia-wei¹, CAI Le¹, WANG Song-tao¹. Numerical Study on Effects of Different Excitation Forms on Forced Film Cooling Characteristics[J]. Journal of Propulsion Technology, 2020, 41(4): 860-867.

陈佳伟，蔡乐，王松涛. 不同激励形式对脉动气膜冷却特性影响的数值研究[J]. 推进技术, 2020, 41(4): 860-867.

References

[1] Muldoon Frank, Acharya Sumanta. DNS Study of Pulsed Film Cooling for Enhanced Cooling Effectiveness [J]. International Journal of Heat and Mass Transfer， 2009， 52（13-14）： 3118-3127.
[2] Bell C M， Ligrani P M， Hull W A， et al. Film Cooling Subject to Bulk Flow Pulsations: Effects of Blowing Ratio， Freestream Velocity， and Pulsation Frequency[J]. International Journal of Heat and Mass Transfer， 1999， 42(23): 4333-4344.
[3] Ligrani P M， Gong R， Cuthrell J M， et al. Bulk Flow Pulsations and Film Cooling-II. Flow Structure and Film Effectiveness[J]. International Journal of Heat and Mass Transfer， 1996， 39(11): 2283-2292.
[4] Ligrani P M， Gong R， Cuthrell J M， et al. Bulk Flow Pulsations and Film Cooling-I. Injectant Behavior[J]. International Journal of Heat and Mass Transfer， 1996， 39(11): 2271-2282.
[5] Womack K M， Volino R J， Schultz M P. Measurements in Film Cooling Flows with Periodic Wakes[J]. Journal of Turbomachinery， 2008， 130 (4).
[6] M’Closkey R T， King J M， Cortelezzi L， et al. The Actively Controlled Jet in Crossflow[J]. Journal of Fluid Mechanics， 2002， 452： 325-335.
[7] Johari H， Pacheco-Tougas M， Hermanson J C. Penetration and Mixing of Fully Modulated Turbulent Jets in Crossflow[J]. AIAA Journal， 1999， 37（7）： 842-850.
[8] Eroglu A， Breidenthal R E. Structure， Penetration， and Mixing of Pulsed Jets in Crossflow[J]. AIAA Journal， 2001， 39（3）： 417-423.
[9] Ekkad S， Ou S， Rivir R B. Effect of Jet Pulsation and Duty Cycle on Film Cooling from a Single Jet on a Leading Edge Model[J]. Journal of Turbomachinery， 2006， 128： 564-571.
[10] Bidan G， Vezier C， Nikitopoulos D E. Study of Unforced and Modulated Film-Cooling Jets Using Proper Orthogonal Decomposition， Part II: Forced Jets[J]. Journal of Turbomachinery， 2013， 135(2).
[11] Muldoon Frank， Acharya Sumanta. Direct Numerical Simulation of Pulsed Jets-in-Crossflow[J]. Computers & Fluids， 2010， 39(10): 1745-1773.
[12] Vermeulen P J， Grabinski P， Ramesh V. Mixing of an Acoustically Excited Air Jet with a Confined Hot Crossflow[J]. Journal of Engineering for Gas Turbines and Power， 1992， 114： 46-54.
[13] Narayanan S， Barooah P， Cohen J M. Dynamics and Control of an Isolated Jet in Crossflow[J]. AIAA Journal， 2003， 41（12）： 2316-2330.
[14] 蔡乐. 超高负荷扩压叶栅分离结构及其定常与非定常控制研究[D]. 哈尔滨：哈尔滨工业大学， 2015.
[15] 张洪鑫，陈绍文，巩赟，等. 孔式非定常脉动抽吸控制高负荷压气机叶栅内流动分离的参数研究[J]. 推进技术， 2019， 40(3): 552-560.
[16] 张洪鑫，陈绍文，李伟航，等. 变攻角下端壁非定常脉动抽吸对高负荷压气机叶栅性能的影响［J］. 推进技术， 2019， 40（10）： 2206-2215.
[17] 张洪鑫，陈绍文，王松涛，等. 定常抽吸与非定常脉动抽吸对高负荷压气机叶栅性能的影响[J]. 大连海事大学学报， 2018， 44(4): 92-98.
[18] Babaee Hessam， Acharya Sumanta， Xiaoliang Wan. Optimization of Forcing Parameters of Film Cooling Effectiveness[J]. Journal of Turbomachinery， 2013， 135(6).
[19] Burd S W， Kaszeta R W， Simon T W. Measurements in Film Cooling Flows: Hole L/D and Turbulence Intensity Effects[J]. Journal of Turbomachinery， 1998， 120(4): 791-798.
[20] Goldstein R J， Eckert E R G， Burggraf F. Effects of Hole Geometry and Density on Three-Dimensional Film Cooling[J]. International Journal of Heat and Mass Transfer， 1974， 17(5): 595-607.
[21] Lutum E， Johnson B V. Influence of the Hole Length-to-Diameter Ratio on Film Cooling with Cylindrical Holes[J]. Journal of Turbomachinery， 1999， 121(2): 209-216.
[22] Sarkar S， Ranakoti G. Effect of Vortex Generators on Film Cooling Effectiveness[J]. Journal of Turbomachinery， 2015， 137(6).
[23] An B T， Liu J J， Zhou S J. Effects of Inclination Angle， Orientation Angle， and Hole Length on Film Cooling Effectiveness of Rectangular Diffusion Holes[J]. Journal of Turbomachinery， 2018， 140(7).
[24] An B T， Liu J J. Numerical Investigation on Diffusion Slot Hole with Various Cross-Sectional End Shapes[J]. ASME Journal of Heat Transfer， 2017， 139(9).
[25] 李蕾，吴海玲，彭晓峰. 脉动横向射流特性[C]. 吉林：2004年中国工程热物理学会学术会议， 2004.

Numerical Study on Effects of Different Excitation Forms on Forced Film Cooling Characteristics

不同激励形式对脉动气膜冷却特性影响的数值研究

PDF

Knowledge

Abstract

Cite this article

share this article

References

Related Articles 0

Recommended Articles

Metrics

Comments