基于压力的推力矢量角优化估算法

IF 2.1 3区工程技术 Q2 ENGINEERING, AEROSPACE

Aerospace Pub Date : 2023-11-22 DOI:10.3390/aerospace10120978

Nanxing Shi, Yunsong Gu, Tingting Wu, Yuhang Zhou, Yi Wang, Shuai Deng

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引用次数: 0

摘要

这项研究为流体推力矢量喷嘴开发了一种基于压力的推力矢量角估算方法。该方法仅利用喷嘴内表面的壁压信息就能准确估算出飞行中的实时推力矢量角。我们提出了一种根据喷嘴内壁压力计算推力矢量角的算法。应用非支配排序遗传算法 II 寻找最佳传感器阵列，减少壁压传感器数量。为验证基于压力的推力矢量角估算方法的准确性和实时响应，进行了同步力和壁压测量实验。结果表明，至少使用三个压力传感器就能实现推力矢量角的精确估算。本研究提出的基于压力的推力矢量角估算方法具有良好的工程应用前景，它能够对飞行中的推力矢量角进行准确的实时监测。该方法对于流体推力矢量控制技术的闭环反馈控制和飞机姿态控制具有不可或缺的重要意义。

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An Optimized Pressure-Based Method for Thrust Vectoring Angle Estimation

This research developed a pressure-based thrust vectoring angle estimation method for fluidic thrust vectoring nozzles. This method can accurately estimate the real-time in-flight thrust vectoring angle using only wall pressure information on the inner surface of the nozzle. We proposed an algorithm to calculate the thrust vectoring angle from the wall pressure inside the nozzle. Non-dominated sorting genetic algorithm II was applied to find the optimal sensor arrays and reduce the wall pressure sensor quantity. Synchronous force and wall pressure measurement experiments were carried out to verify the accuracy and real-time response of the pressure-based thrust vectoring angle estimation method. The results showed that accurate estimation of the thrust vectoring angle can be achieved with a minimum of three pressure sensors. The pressure-based thrust vectoring angle estimation method proposed in this study has a good prospect for engineering applications; it is capable of accurate real-time in-flight monitoring of the thrust vectoring angle. This method is important and indispensable for the closed-loop feedback control and aircraft attitude control of fluidic thrust vectoring control technology.

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来源期刊

Aerospace ENGINEERING, AEROSPACE-

CiteScore

3.40

自引率

23.10%

发文量

661

审稿时长

6 weeks

期刊介绍： Aerospace is a multidisciplinary science inviting submissions on, but not limited to, the following subject areas: aerodynamics computational fluid dynamics fluid-structure interaction flight mechanics plasmas research instrumentation test facilities environment material science structural analysis thermophysics and heat transfer thermal-structure interaction aeroacoustics optics electromagnetism and radar propulsion power generation and conversion fuels and propellants combustion multidisciplinary design optimization software engineering data analysis signal and image processing artificial intelligence aerospace vehicles'' operation, control and maintenance risk and reliability human factors human-automation interaction airline operations and management air traffic management airport design meteorology space exploration multi-physics interaction.