Dusting Hole Film Cooling Heat Transfer on a Transonic Turbine Blade Tip

IF 0.9 Q4 ENGINEERING, MECHANICAL

International Journal of Rotating Machinery Pub Date : 2022-10-06 DOI:10.1155/2022/2006572

Ward Manneschmidt, H. Collopy, P. Ligrani, Kyle Goethals, Matthew W. Cox, Hongzhou Xu, M. Fox

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Abstract

Investigated is a transonic turbine blade tip with a squealer rim and a squealer recess, with a single dusting film cooling hole contained within the leading edge region of the squealer recess. Data are provided for transonic flow conditions for a range of film cooling blowing ratios for two tip gap values, using a linear cascade, with no relative motion between the blade and the casing. Surface heat transfer characteristics are measured using the transient impulse-response measurement approach, employed with infrared thermography. Line-averaged adiabatic film cooling effectiveness values, for the 1.4 mm tip gap, are generally very small along the pressure side rim, with only small, locally increased values along the suction side rim. For the 0.8 mm tip gap, line-averaged adiabatic film cooling effectiveness values are generally somewhat higher along the pressure side rim and along the suction side rim. In general, effectiveness values for both tip gap values, for these locations, and for the recess region, increase as the blowing ratio increases. As the tip gap decreases from 1.4 mm to 0.8 mm, line-averaged adiabatic film cooling effectiveness generally increases on the rims and downstream regions of the recess, with increased magnitudes which are spread over larger spatial surface areas. For tip gaps of 0.8 mm and 1.4 mm, for regions where the line-averaged heat transfer coefficient ratio deviates significantly from 1.00, values generally decrease as the blowing ratio increases. Across every region of the blade, line-averaged heat transfer coefficient ratios either decrease or remain approximately invariant, as the tip gap value decreases from 1.4 mm to 0.8 mm.

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跨声速涡轮叶片尖端的喷尘孔膜冷却传热研究

研究了一种带尖叫边缘和尖叫凹槽的跨声速涡轮叶片尖端，在尖叫凹槽的前缘区域内包含一个单尘膜冷却孔。数据提供了跨声速流动条件下的膜冷却吹风比范围的两个叶顶间隙值，使用线性叶栅，在叶片和机匣之间没有相对运动。表面传热特性测量采用瞬态脉冲响应测量方法，采用红外热像仪。对于1.4 mm叶顶间隙，沿压力侧边缘的线平均绝热膜冷却效率值通常非常小，只有沿吸力侧边缘的值很小，局部增加。对于0.8 mm的叶顶间隙，沿压力侧边缘和吸力侧边缘的线平均绝热膜冷却效率值一般略高。一般来说，随着吹气比的增加，这些位置的叶尖间隙值和凹槽区域的有效性值都增加。当叶尖间隙从1.4 mm减小到0.8 mm时，线平均绝热膜冷却效率在凹槽边缘和下游区域普遍增加，且增加幅度分布在更大的空间表面积上。对于0.8 mm和1.4 mm的叶顶间隙，对于线平均传热系数比明显偏离1.00的区域，该值一般随着吹气比的增加而减小。随着叶顶间隙值从1.4 mm减小到0.8 mm，在叶片的每个区域，线平均传热系数比值要么减小，要么保持近似不变。

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来源期刊

International Journal of Rotating Machinery ENGINEERING, MECHANICAL-

CiteScore

2.40

自引率

0.00%

发文量

审稿时长

25 weeks

期刊介绍： This comprehensive journal provides the latest information on rotating machines and machine elements. This technology has become essential to many industrial processes, including gas-, steam-, water-, or wind-driven turbines at power generation systems, and in food processing, automobile and airplane engines, heating, refrigeration, air conditioning, and chemical or petroleum refining. In spite of the importance of rotating machinery and the huge financial resources involved in the industry, only a few publications distribute research and development information on the prime movers. This journal is the first source to combine the technology, as it applies to all of these specialties, previously scattered throughout literature.