6.5马赫数钝前缘激波干扰气动热力学分析及后尾迹评估

IF 1 4区 工程技术 Q3 ENGINEERING, AEROSPACE
Gaurav Shivpratap Singh, Chirag Sharma, Siddhant Swaroop Padhy, Deepu Dinesan, Bibin John
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引用次数: 0

摘要

为了揭示激波相互作用对峰值加热和钝体空气动力学的影响,对高超声速流动中圆柱钝前缘的激波干扰进行了详细的数值研究。这项研究的独特之处在于它考察了相互作用对后尾流形成和作用在钝体上的气动力的影响。在自由流马赫数为6.5的条件下,研究了Edney描述的六种不同的激波干涉模式。采用有限体积法求解可压缩reynolds -average Navier-Stokes方程,得到了精确的流场和气动载荷预测。在进口边界施加Hugoniot跳变条件,实现所需强度的斜激波在特定位置与分离激波相互作用。数值预测与报告的实验测量结果非常吻合。研究结果表明,冲击-冲击相互作用模式的类型可以显著改变后尾流的特性。与无扰动流动条件的比较表明,II型到VI型相互作用导致尾迹大小增加,而I型相互作用则显示出边际减小。这些尾迹大小的变化归因于激波-激波相互作用引起的前体边界层的改变。然而,在I型相互作用的情况下,发现与后尾迹相互作用的透射波是尾迹尺寸边际减小的原因。研究还表明,由于相互作用类型的改变而引起的后尾迹结构的变化会影响气动载荷。VI型相互作用最大阻力系数为2.96,IV型相互作用最大升力系数为0.992。这些发现证明了通过操纵冲击干扰来动态调整飞行体的控制力的潜力。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Aerothermodynamic analysis and rear wake assessment of shock wave interference over blunt leading edge at Mach 6.5
A detailed numerical study of shock-wave interference on a cylindrical blunt leading edge in hypersonic flow is carried out to reveal the effect of shock-shock interaction on peak heating and blunt body aerodynamics. This study is unique in that it examines the effect of interactions on rear wake formation and aerodynamic forces acting on the blunt body. Six different shock wave interference patterns described by Edney are studied for a freestream Mach number of 6.5. Compressible Reynolds-averaged Navier–Stokes equations are solved using finite volume method to obtain accurate prediction of the flowfield and aerodynamic loads. Hugoniot jump conditions are imposed in the inlet boundary to realize oblique shock of desired strength to interact with the detached shock at specific location. Numerical predictions are in good agreement with reported experimental measurements. The results obtained in this study reveals that the type of shock-shock interaction pattern can significantly alter the characteristics of the rear wake. Comparisons to undisturbed flow conditions reveal that Type II to VI interactions lead to an increase in wake size, whereas Type I interaction shows a marginal reduction. These changes in wake size are attributed to modifications in the forebody boundary layer induced by the shock-shock interactions. In the case of Type I interaction, however, the transmitted wave interacting with the rear wake is found to be responsible for the marginal reduction in wake size. This study also shows that changes to the rear wake structure caused by the change in interaction type can affect aerodynamic loads. Type VI interaction recorded a maximum drag coefficient of 2.96, whereas Type IV interaction yielded a maximum lift coefficient of 0.992. These findings demonstrate the potential for dynamically adjusting the control forces of a flying body by manipulating shock interference.
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来源期刊
CiteScore
2.40
自引率
18.20%
发文量
212
审稿时长
5.7 months
期刊介绍: The Journal of Aerospace Engineering is dedicated to the publication of high quality research in all branches of applied sciences and technology dealing with aircraft and spacecraft, and their support systems. "Our authorship is truly international and all efforts are made to ensure that each paper is presented in the best possible way and reaches a wide audience. "The Editorial Board is composed of recognized experts representing the technical communities of fifteen countries. The Board Members work in close cooperation with the editors, reviewers, and authors to achieve a consistent standard of well written and presented papers."Professor Rodrigo Martinez-Val, Universidad Politécnica de Madrid, Spain This journal is a member of the Committee on Publication Ethics (COPE).
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