Numerical Investigation of Pin-Fin Influences on Cooling Air Flow Characteristics in Turbine Blade Trailing Edge Region

doi:10.13675/j.cnki.tjjs.200192

Journal of Propulsion Technology ›› 2021, Vol. 42 ›› Issue (1): 163-172.DOI: 10.13675/j.cnki.tjjs.200192

• Combustion, Heat and Mass Transfer • Previous Articles Next Articles

Numerical Investigation of Pin-Fin Influences on Cooling Air Flow Characteristics in Turbine Blade Trailing Edge Region

School of Engineering Science，University of Science and Technology of China，Hefei 230027，China

Online:2021-01-15 Published:2021-01-15

涡轮叶片带扰流柱尾缘通道冷气流动的数值分析

吴伟龙，徐华昭，王建华

中国科学技术大学工程科学学院，安徽合肥 230027

作者简介:吴伟龙，博士生，研究领域为涡轮叶片冷却技术。E-mail：552887221@qq.com
基金资助:
两机专项基础研究（2017-Ⅲ-0001-0025）。

Abstract

Abstract: Using pin-fin structure in turbine blade trailing edge helps to improve cooling air allocation and the uniformity of flow filed in the trailing edge slots of turbine blades. However， the added pin-fins inevitably increases the resistance to the fluid flow. Therefore， the geometry matching of pin-fin and trailing edge slots have obvious influence on heat transfer of turbine blade. With M0 as a reference model of a real turbine trailing edge with no pin-fins， this paper adopted the numerical method to compare the flow fields in the trailing edge of three models with different pin fin structures under both static and three rotating speeds. M1 has a single row of 13 pin-fins with a diameter of D=2mm. M2 and M3 have two staggered rows of pin-fins with a respective number of 16 and 17 and a diameter D=1.2mm. Only a slight difference in pin fin arrangement exists near Slot 1 between the two models. The results demonstrated that：（1） The pin-fin located in trailing passage can increase the uniformity of flow field， have a big influence on flow characteristic of #1~3 trailing slots， M2 and M3 with two staggered rows of pin-fins has a better results than M1 with a single row. （2） Compared to M0， the added pin fins in M1， M2 and M3 models cause a moderate increase in pressure losses. The pressure loss coefficients of M2 and M3 are of the same level， and are slightly higher than that of M1 due to higher disturbances to the flow. （3） Increasing blade rotating speed causes continual decrease of pressure loss coefficient， but the flow structure in the slots of all the four models is not evidently changed.

Key words: Pin-fin;Rotation;Numerical investigation;Flow characteristics;Pressure loss

摘要： 在涡轮叶片尾缘通道中添加扰流柱可以改变尾缝内冷气流量的分配及流场均匀性，但同时会增加流阻，因此尾缘通道中扰流柱和尾缝的几何匹配对叶片的换热性能有较大影响。本文采用数值方法，以尾缘通道内无扰流柱模型M0为基准模型，对比分析在静止和三种旋转速度下带有三种不同扰流柱结构的尾缘内部流动。其中，M1添加单列扰流柱，数目13，直径D=2mm；M2与M3添加双列叉排扰流柱，数目分别为16和17，直径D=1.2mm，两模型仅在靠近尾缝1处扰流柱布局不同。数值结果揭示：（1）尾缘通道扰流柱可有效增加各尾缝冷气出流的均匀性，对1~3尾缝内的流动影响较大，小直径叉排扰流柱布置形式更优于大直径单排；（2）与M0相比，三组带扰流柱模型的通道压力损失稍有增加。其中，M2和M3基本相同，因对流场扰动较大，略高于M1；（3）随着旋转速度的增加，尾缝内压力损失逐渐降低，但四组模型尾缝内的流场结构没有明显改变。

关键词: 扰流柱;旋转;数值分析;流动特性;压力损失

WU Wei-long, XU Hua-zhao, WANG Jian-hua. Numerical Investigation of Pin-Fin Influences on Cooling Air Flow Characteristics in Turbine Blade Trailing Edge Region[J]. Journal of Propulsion Technology, 2021, 42(1): 163-172.

吴伟龙，徐华昭，王建华. 涡轮叶片带扰流柱尾缘通道冷气流动的数值分析[J]. 推进技术, 2021, 42(1): 163-172.

References

[1] Otto M， Fernandez E， Kapat J S. Rib Turbulated Pin Fin Array for Trailing Edge Cooling［R］. ASME GT 2017-63044.
[2] Rao Y， Wan C Y， Zang S S. Comparisons of Flow Friction and Heat Transfer Performance in Rectangular Channels with Pin Fin-Dimple， Pin Fin and Dimple Arrays［R］. ASME GT 2010-22442.
[3] Kan R， Ren J， Jiang H D. Combined Effects of Perforated Blockages and Pin Fins in a Trailing Edge Internal Cooling Duct［R］. ASME GT 2014-25767.
[4] Horbach T， Schulz A， Bauer H J. Trailing Edge Film Cooling of Gas Turbine Airfoils—External Cooling Performance of Various Internal Pin Fin Configurations［J］. ASME Journal of Turbomachinery， 2011， 133： 393-401.
[5] Wu H W， Zirakzadeh H， Han J C， et al. Heat Transfer in a Rib and Pin Roughened Rotating Multipass Channel with Hub Turning Vane and Trailing-Edge Slot Ejection［J］. ASME Journal of Thermal Science and Engineering Applications， 2018， 10： 393-401.
[6] 张丽，朱惠人，刘松龄，等. 变流向梯形通道内短扰流柱列的流量分配实验［J］. 航空动力学报， 2006， 21（3）： 518-522.
[7] 张丽，朱惠人，刘松龄，等. 出流比对扰流柱通道弦向出流量影响实验［J］. 航空动力学报， 2007， 22（1）： 42-45.
[8] 张丽，朱惠人，刘松龄. 旋转对小间距扰流柱通道内的流动换热影响［J］. 航空动力学报， 2009， 24（11）： 2489-2494.
[9] Moon M A， Kim K Y. Computational Analysis of Trailing Edge Internal Cooling of a Gas Turbine Blade with Pin-Fin Arrays［J］. International Journal of Enhanced Heat Transfer， 2013， 20 （2）： 137-151.
[10] Jiang Y， Gurram N， Romero E， et al. CFD Investigation of the Flow of Trailing Edge Cooling Slots［R］. ASME GT 2018-75906.
[11] Bianchini C， Facchini B， Simonetti， et al. Numerical and Experimental Investigation of Turning Flow Effects on Innovative Pin Fin Arrangements for Trailing Edge Cooling Configurations［R］. ASME GT 2010-23536.
[12] 潘炳华. 流量分配对尾缘通道流动换热特性的影响［J］. 燃气涡轮试验与研究， 2017， 30（2）： 45-50.
[13] Menter F R. Two-Equation Eddy-Viscosity Turbulence Models for Engineering Applications［J］. AIAA Journal， 1994， 32： 1598-1605.
[14] Singh S， Acharya S. Numerical Investigation of Local Cooling Enhancement Using Pin-Finned Channel with Incremental Impingement［R］. ASME GT 2017-65083.
[15] Aillaud P， Duchaine F， Gicquel L， et al. On the Use of Periodic Boundary Condition For Large Eddy Simulation of Trailing Edge Cutback Film Cooling with Internal Ribs［R］. ASME GT 2018-75801.
[16] Andreini A， Bianchini C， Armellini A， et al. Flow Field Analysis of a Trailing Edge Internal Cooling Channel［R］. ASME GT 2011-45724.
[17] Taslim M E， Nongsaeng A. Experimental and Numerical Crossover Jet Impingement in an Airfoil Trailing-Edge Cooling Channel［J］. Journal of Turbomachinery， 2011， 133（3）： 1201-1210.
[18] Taslim M E， Huang X. Experimental/ Numerical Investigation on the Effects of Trailing-Edge Cooling Hole Blockage on Heat Transfer in a Trailing-Edge Cooling Channel［R］. ASME GT 2013-95859.
[19] Pu J， Ke Z Q， Wang J H， et al. An Experimental Investigation on Fluid Flow Characteristics in a Real Coolant Channel of LP Turbine Blade with PIV Technique［J］. Experimental Thermal and Fluid Science， 2013， 43： 43-53.
[20] Ke Z Q， Pu J， Wang J H. Investigations on Fluid Flow and Heat Transfer Performances Within a Real Turbine Blade Channel［R］. ASME GT 2014-25097.
[21] 谭晓茗，胡训尧，张靖周. 涡轮叶片尾缘梯形通道异形扰流柱流动换热特性实验［J］. 航空动力学报， 2012， 27（2）： 319-325.
[22] 徐虹艳，张靖周，谭晓茗. 涡轮叶片尾缘内冷通道旋流冷却特性［J］. 航空动力学报， 2014， 29（1）： 59-66.
[23] Armellini A， Casarsa L， Mucignat C. Flow Field Analysis Inside a Gas Turbine Trailing Edge Cooling Channel under Static and Rotating Conditions［J］. International Journal of Heat and Fluid Flow， 2011， 32： 1147-1159.
[24] Andreini A， Bianchini C， Armellini A， et al. Flow Field Analysis of a Trailing Edge Internal Cooling Channel［R］. ASME GT 2011-45724.
[25] Mucignat C， Armellini A， Casarsa L. Flow Field Analysis Inside a Gas Turbine Trailing Edge Cooling Channel under Static and Rotating Conditions： Effect of Ribs［J］. International Journal of Heat and Fluid Flow， 2013， 42： 236-250.
[26] Petukhov B S. Advances in Heat Transfer［M］. New York： Academic Press， 1970.

Numerical Investigation of Pin-Fin Influences on Cooling Air Flow Characteristics in Turbine Blade Trailing Edge Region

涡轮叶片带扰流柱尾缘通道冷气流动的数值分析

PDF

Knowledge

Abstract

Cite this article

share this article

References

Related Articles 0

Recommended Articles

Metrics

Comments