The work presented here is an investigation of the wake flow field over a DARPA SUBOFF submarine model at a large range of Reynolds numbers based on model length, 1.1x106 ≤ ReL ≤ 25 x 106, on the centerline of the wake for locations 3, 6, 9, 12, and 15 diameters downstream from the tail. The model is an axisymmetric body without appendages (fins) supported by a streamlined support. The support models the flow of a semi-infinite sail. The wake experimental results, obtained using Particle Image Velocimetry (PIV) and crossed hot-wires, provide qualitative and quantitative insight into the flow field created by a submarine. In addition, the pressure was measured at 45 different locations along the submarine model for three different Reynolds numbers, ReL = 1.1 x 10 6, 12 x 106, and 25 x 106. Also, PIV measurements were conducted in the wake of the sail attached to a DARPA SUBOFF submarine model at ReL = 93.6 x 10 3. Four different yaw angles, 6 ≤ alpha ≤ 17, were investigated yielding insights into the behavior of the junction/hull and sail tip vortices.; For all Reynolds numbers studied, the mean velocity distribution attains self-similarity at distances between 3 and 6 diameters downstream for the side where the support is not located, and follows an exponential function as expected from similarity arguments. In contrast, the mean velocity distribution for the support side does not attain self similarity, and displays significant effects of the support wake and support/body junction flows. In addition, none of the Reynolds stress distributions of the flow attain self similarity. For the higher Reynolds numbers studied the presence of the support introduces an asymmetry into the wake which results in the overall decrease of radial and axial turbulence intensities for the support side. Also, the coefficient of pressure, CP, distribution along the top meridian line of the model, r/D > 0, is generally lower for ReL = 1.1 x 106 than that for ReL = 12 x 10 6 and 25 x 106, which seem to have collapsed. The sail wake experiments demonstrated the significance of the sail tip vortex when the submarine is at a nonzero yaw angle. As the yaw angle is increased the circulation of the sail tip vortex increases. As the yaw angle is further increased the boundary layer separates from the sail with an overall drop in circulation. A similar phenomenon is observed for the junction vortex with the exception that when the yaw angle is further increased to 17 degrees the circulation continues to increase at a slower rate. Also, the circulation values for the sail tip vortex are about an order of magnitude larger than those of the junction vortex.; The effects of the support on the wake development are similar to the effects introduced by the sail on a submarine wake (except for the absence of the tip flow). The presence of the support affects the flow differently for different Reynolds numbers emphasizing the importance of high Reynolds number studies to better understand submarine flows.
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机译:此处介绍的工作是根据模型长度1.1x106≤ReL≤25 x 106,在位置3、6的尾流中心线上,研究大范围雷诺数下DARPA SUBOFF潜艇模型上的尾流流场。尾部下游的直径分别为9、12和15。该模型是轴对称体,没有由流线型支撑件支撑的附件(鳍)。支架模拟半无限风帆的流动。使用粒子图像测速(PIV)和交叉热线获得的尾流实验结果提供了对潜艇产生的流场的定性和定量分析。此外,沿着潜艇模型在45个不同位置测量了三个不同的雷诺数,即ReL = 1.1 x 10 6、12 x 106和25 x 106的压力。此外,PIV测量是在帆附着后进行的对ReL = 93.6 x 10 3的DARPA SUBOFF潜艇模型进行了研究。研究了四个不同的偏航角(6≤alpha≤17),以深入了解接合处/船体和帆尖端涡流的行为。对于所有研究过的雷诺数,平均速度分布在下游3到6个直径之间的距离处(对于没有放置支撑的那一侧)达到自相似,并且遵循指数函数,这是相似论证所期望的。相反,支撑侧的平均速度分布没有达到自相似性,并且显示了支撑尾流和支撑/身体连接流的显着影响。此外,流动的雷诺应力分布均未达到自相似性。对于更高的雷诺数研究,支撑的存在将不对称性引入尾流,这导致支撑侧的径向和轴向湍流强度总体下降。同样,沿模型顶部子午线的压力系数CP分布r / D> 0,通常对于ReL = 1.1 x 106比对于ReL = 12 x 10 6和25 x 106更低。崩溃了帆尾流实验证明了当潜艇处于非零偏航角时,帆尖涡旋的重要性。随着偏航角的增加,帆尖涡流的循环也增加。随着偏航角的进一步增加,边界层与帆分离,从而使整体流通量下降。对于结旋涡,观察到类似的现象,除了当偏航角进一步增加到17度时,循环继续以较慢的速率增加。而且,帆尖涡旋的循环值比结旋涡的循环值大一个数量级。支撑物对尾流发展的影响类似于帆对海底尾流产生的影响(除了不存在叶尖流动外)。支持物的存在对不同雷诺数的流动产生不同的影响,强调了高雷诺数研究对更好地了解海底流动的重要性。
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