Role of strut shape on the generation of internal side force and moments in A supersonic nozzle with strut insertion through diverging wall

IF 1 4区工程技术 Q3 ENGINEERING, AEROSPACE

Proceedings of the Institution of Mechanical Engineers Part G-Journal of Aerospace Engineering Pub Date : 2024-07-18 DOI:10.1177/09544100241260109

Lakshmi Srinivas A, Sridhar BTN

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Abstract

Cold flow experiments were conducted on a convergent-divergent (C-D) nozzle with a strut inserted through the nozzle diverging wall to study the internal wall pressure distribution. The objective of the work was to calculate the internal side force and hence the pitching moment generated as a consequence of the side insertion of the strut through the nozzle wall. The generation of side force/pitching moment would be useful for the development of a potential alternative thrust vector control system of flight vehicles employing a supersonic nozzle. The strut was inserted at a distance of 2/3rd of the diverging section length ( L d) of the nozzle from the throat. Two cross sectional shapes of the strut i.e. square with V-notch and semi-ellipse were employed in the experiments. Eight wall pressure ports each on the strut side and on counter strut side of the nozzle axis were used to acquire the pressure data. The design exit Mach number ( M d) corresponding to isentropic flow conditions of the nozzle was 1.84 with an area ratio of 1.48. The cold flow experiments were conducted at three nozzle pressure ratios (NPRs) which were 3.4,5 (both corresponded to over-expansion) and 6.9 (under-expansion). For each strut shape and at a given NPR, strut height ( h s) was varied to study the internal wall pressure distribution. The maximum height of the strut was restricted to the radius of the local cross section of the nozzle (r) where the strut was inserted. From the wall pressure ( p w) distribution, two-dimensional side force ( C s) and moment coefficients ( C m) were calculated. The variation of these coefficients with h s was plotted and the effect of the strut shape for each operational NPR was studied. These variations with h s in respect of square-notch shape and semi elliptical shape were also compared with variations corresponding to square shape available in the literature. The variations of C s and C m were highly nonlinear and trends of both the variations were similar. It was observed from these variations that the semi-elliptical strut shape exhibited a distinct behavior which was in contrast to two other shapes. Variation in h s resulted in both positive and negative values of coefficients in respect of square with V-notch and square shaped struts, whereas in case of semi-elliptical shape mostly positive values of the coefficients were observed. The maximum positive magnitude of C s was observed at strut heights which were 27% and 57% of the local radius of the nozzle cross section (where the strut was inserted) for square with V-notch and semi-elliptical struts respectively.

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支杆形状对通过发散壁插入支杆的超音速喷嘴产生内侧力和力矩的影响

在汇聚-发散（C-D）喷嘴上进行了冷流实验，在喷嘴发散壁上插入了一根支撑杆，以研究内壁压力分布。这项工作的目的是计算内部侧向力，进而计算因支撑杆侧向插入喷嘴壁而产生的俯仰力矩。侧向力/俯仰力矩的产生有助于开发采用超音速喷嘴的飞行器的潜在替代推力矢量控制系统。支撑杆插入喷嘴喉部的距离是其发散截面长度（L d）的三分之二。实验中使用了两种截面形状的支撑杆，即带 V 形缺口的正方形和半椭圆形。在喷嘴轴线的支杆侧和反支杆侧各使用了八个壁压端口来获取压力数据。喷嘴等熵流条件下的设计出口马赫数（M d）为 1.84，面积比为 1.48。冷流实验在三个喷嘴压力比（NPRs）下进行，分别为 3.4、5（均相当于过度膨胀）和 6.9（膨胀不足）。对于每种支杆形状和给定的 NPR，支杆高度（h s）均有变化，以研究内壁压力分布。支柱的最大高度限制为插入支柱的喷嘴局部横截面半径（r）。根据壁压（p w）分布，计算出二维侧力（C s）和力矩系数（C m）。绘制了这些系数随 h s 的变化曲线，并研究了支柱形状对每种运行 NPR 的影响。这些随 h s 变化的方形缺口形状和半椭圆形形状还与文献中与方形形状相对应的变化进行了比较。C s 和 C m 的变化是高度非线性的，两种变化的趋势相似。从这些变化中可以看出，半椭圆形支杆形状表现出与其他两种形状截然不同的行为。h s 的变化导致带 V 形缺口的方形支柱和方形支柱的系数出现正值和负值，而半椭圆形支柱的系数大多为正值。对于带 V 形缺口的正方形和半椭圆形支柱，在支柱高度分别为喷嘴横截面局部半径（支柱插入处）的 27% 和 57% 时，C s 的正值最大。

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来源期刊

Proceedings of the Institution of Mechanical Engineers Part G-Journal of Aerospace Engineering 工程技术-工程：机械

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).