This paper experimentally investigates the effect of blowing ratio and exit Reynolds number/Mach number on the film cooling performance of a showcrhead film cooled first stage turbine vane. The vane midspan was instrumented with single-sided platinum thin film gauges to experimentally characterize the Nusselt number and film cooling effectiveness distributions over the surface. The vane was arranged in a two-dimensional, linear cascade in a heated, transonic, blow-down wind tunnel. Three different exit Mach numbers of M_(ex) = 0.57, 0.76 and 1.0-corresponding to exit Reynolds numbers based on vane chord of 9.7 × 105, 1.1 × 106 and 1.5 × 106, respectively-were tested with an inlet free stream turbulence intensity (Tu) of 16% and an integral length scale normalized by vane pitch (Λ_x/P) of 0.23. A showerhead cooling scheme with five rows of cooling holes was tested at blowing ratios of BR = 0, 1.5, 2.0, and 2.5 and a density ratio of DR = 1.3. Nusselt number and adiabatic film cooling effectiveness distributions were presented on the vane surface over a range of s/C = -0.58 on the pressure side to s/C = 0.72 on the suction side of the vane.The primary effects of coolant injection were to augment the Nusselt number and reduce the adiabatic wall temperature downstream of the injection on the vane surface as compared to no film injection case (BR = 0) at all exit Mach number conditions. In general, an increase in blowing ratio (BR = 1.5 to 2.5) showed noticeable Nusselt number augmentation on pressure surface as compared to suction surface at exit Mach 0.57 and 0.75; however, the Nusselt number augmentation for these blowing ratios was found to be negligible on the vane surface for exit Mach 1.0 case. At exit Mach 1.0, an increase inblowing ratio (BR = 1.5 to 2.5) was observed to have an adverse effect on the adiabatic effectiveness on the pressure surface but had negligible effect on suction surface. The effectiveness trend on the suction surface was also found to be influenced by a favorable pressure gradient due to Mach number and boundary layer transition in the region s/C = 0.28 to s/C = 0.45 at all blowing ratio and exit Mach number conditions. An increase in Reynolds number from exit Mach 0.76 to 1.0 increased heat transfer levels on the vane surface at all blowing ratio conditions. A large increase in Reynolds number adversely affected adiabatic effectiveness on the pressure surface at all blowing ratio conditions. On the suction surface, a large increase in Reynolds number also affected adiabatic effectiveness in the favorable pressure gradient and boundary layer transition region.
展开▼
机译:本文实验研究了鼓风比和出口雷诺数/马赫数对showcrhead薄膜冷却的第一级涡轮叶片的薄膜冷却性能的影响。叶片中跨装有单侧铂薄膜液位计,可通过实验表征表面上的Nusselt数和薄膜冷却效率分布。叶片以二维,线性级联的形式布置在加热的跨音速排污风洞中。使用入口自由流湍流强度测试了三个不同的出口马赫数M_(ex)= 0.57、0.76和1.0-分别对应于基于9.7×105、1.1×106和1.5×106叶片翼弦的出口雷诺数(Tu)为16%,积分长度比例通过叶片间距(Λ_x/ P)归一化为0.23。以BR = 0、1.5、2.0和2.5的吹风比和DR = 1.3的密度比测试了具有五排冷却孔的莲蓬头冷却方案。在压力侧s / C = -0.58到叶片吸气侧s / C = 0.72的范围内,叶片表面上呈现出努塞尔数和绝热膜冷却效率分布。
与在所有出口马赫数条件下没有薄膜喷射的情况(BR = 0)相比,冷却剂喷射的主要作用是增加Nusselt数并降低喷射在叶片表面下游的绝热壁温。通常,吹气比的增加(BR = 1.5至2.5)表明,与出口0.57和0.75马赫处的吸力面相比,压力面上的努塞尔数明显增加。但是,发现对于出口马赫数为1.0的情况,这些吹气比的Nusselt值增加在叶片表面上可忽略不计。在1.0马赫出口处,
观察到鼓风比(BR = 1.5至2.5)对压力表面的绝热效果有不利影响,但对吸力表面的影响可忽略不计。还发现,在所有吹风比和出口马赫数条件下,由于马赫数和边界层在范围s / C = 0.28到s / C = 0.45的边界层过渡,吸力表面的效率趋势也受到有利的压力梯度的影响。在所有吹风比条件下,从出口马赫数0.76到雷诺数增加到1.0都会增加叶片表面的传热水平。在所有吹风比条件下,雷诺数的大幅增加都会对压力表面的绝热效果产生不利影响。在吸力表面,雷诺数的大量增加也影响了在有利的压力梯度和边界层过渡区的绝热效果。
展开▼
