Computational Study on Base Drag Reduction for a Boat-tailed Axisymmetric Jet Nozzle Through Base Geometry Modifications

2021 IEEE Pune Section International Conference (PuneCon) Pub Date : 2021-12-16 DOI:10.1109/punecon52575.2021.9686520

Tanmay B. Gholap, Ruturaj V. Salokhe, Ganesh V. Ghadage, Shankar V. Mane, D. Sahoo

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Abstract

A Computational Fluid Dynamics (CFD) analysis was conducted on an axisymmetric boat-tailed afterbody operating at an angle of incidence of zero degrees. The boat-tail drag can significantly affect the performance of overall propulsion system in rockets and missiles. These computations show a very complex regime when the base region flow connects with the flow from the nozzle and the ambient air, with strong adverse pressure gradients and shock induced separations in the flow field. Computations have been carried out at transonic Mach number 0.9 with nozzle pressure ratio (NPR) of 4. The Shear Stress Transport (SST) turbulence model has been used in calculations to study the flow difference in pressure and velocity contours as it provides more accurate results with the data obtained from experiments. Nevertheless, the boat tail surface pressure coefficient for a straight cylinder and a tapered cylinder (or boat tail) has been plotted and analyzed. The boat tail configuration model demonstrated a better performance in terms of drag experienced by the system.

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船尾轴对称喷管基底几何形状修正减阻的计算研究

对零入射角工况下的轴对称船尾后体进行了计算流体力学分析。艇尾阻力对火箭和导弹整体推进系统的性能影响很大。这些计算表明，当基区流与喷嘴和周围空气的流相连接时，流场中存在很强的逆压梯度和激波分离，情况非常复杂。在跨声速马赫数为0.9、喷管压力比为4的条件下进行了计算。由于剪切应力输运(Shear Stress Transport, SST)湍流模型能较准确地反映实验数据，因此在计算中应用于研究压力和速度轮廓的流动差。然而，已绘制和分析了直筒和锥形筒(或艇尾)的艇尾表面压力系数。艇尾结构模型在系统所经历的阻力方面表现出较好的性能。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2021 IEEE Pune Section International Conference (PuneCon)

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