无隔道超声速进气道附面层排除特性飞行试验研究

为了分析评估某型歼击机无隔道进气道附面层的排除特性,设计搭建鼓包表面附面层压力梯度测量试验系统,进行了不同飞行高度、马赫数和姿态角等工况下的飞行试验。通过对飞行试验数据的整理、计算和对比分析同型号的缩比模型风洞试验结果,研究了无隔道进气道鼓包表面附面层排除特性。研究结果表明：稳定平飞时,在亚音速范围内,随着飞行高度的增加,鼓包构型对附面层的排除效果增大,而在超音速范围内,变化规律相反；在接近马赫数1.8及以上飞行工况下,鼓包表面附面层的扫除能力有所减弱,附面层气流分离加速,进而会造成较大的进气压力损失和畸变。单纯迎角飞行有利于增强附面层的排除能力；而带侧滑角飞行时,附面层压力系数曲线的拐点沿鼓包中心线平行向“背风面”偏移,偏移量与侧滑角成正比,进气道鼓包表面“迎风面”附面层排除能力增大,而“背风面”受气流分离影响而减弱。     

基于3D Zernike矩的巡检器与空间站的相对导航算法

针对航天器相对导航问题，以空间站表面为"特殊地形"，提出一种基于大型航天器表面巡检的相对导航算法。首先，运用巡检飞行器上的TOF （Time of Flight）相机测量空间站表面局部点云数据，以该点云数据为实时图，以空间站表面先验点云数据为基准图。然后，利用3D Zernike矩与三维地形间的一一对应关系，将三维地形匹配转化为基于3D Zernike矩的特征向量匹配。在此基础上求解实时图与匹配上的基准图间的相对位置、相对姿态，从而确定两航天器间的相对导航参数，并通过实验分析了匹配精度及速度的主要影响因素。最后，将该相对导航参数与惯性系统推算的相对导航参数在扩展卡尔曼滤波器的框架下实现信息融合，估计了巡检飞行器与空间站间的相对位置、相对姿态，实验结果表明，相对位置精度优于0.002 m，相对姿态精度优于0.1°。     

A novel framework for liquid propellant engine’s cooling system design by sensitivity analysis based on RSM and multi-objective optimization using PSO

One of the challenges of combustion chamber and nozzle design in a Liquid Propellant Engine (LPE) is to predict the behavior and performance of the cooling system. Therefore, while designing, the optimization of the cooling system is always of great importance. This paper presents the multi-objective optimization of the LPE’s cooling system. To this end, a novel framework has been developed, resulting from the application of the Response Surface Method (RSM) and the correlation coefficients matrix, sensitivity analysis and the The Particle Swarm Optimization (PSO). based on this method, the input variables, constraints, objective functions, and their surfaces were identified. In terms of multi-optimization algorithms, RSM and PSO are utilized to get global optimum. In conclusion, the methodology capability is to optimize the LPE’s cooling system, 6 percentage increase in total heat transfer and 7 bar decrease cooling system pressure loss, which resulted in a 1.2-seconds increase in the specific impulse of the engine.     

Quantitative assessment and visualization of flight risk induced by coupled multi-factor under icing conditions

Aircraft icing has been proven to be one of the most serious threats to flight safety. During the analysis of flight risk under icing conditions, quantitative assessment and visualization of flight risk are quite essential as they provide safe manipulation strategies in intricate conditions. However, they are rarely studied. Since the icing flight accidents are the result of the coupling of multiple unfavorable factors, in present study, we have proposed a method to quantitatively assess flight risk induced by multi-factor coupling under icing conditions by Monte-Carlo simulation and multivariate extreme value theory. The results demonstrate that the flight risk probability increases with the rise of unfavorable factors. Besides, a flight risk visualization method named flight safety window has been presented to build the flight risk distribution cloud maps in different complex conditions. The cloud maps show that the icing would give rise to atrophy of the safety scope, and the consequence would be even more severe when coupled with other more unfavorable factors. The proposed methods in this study would be useful in flight risk analysis under icing conditions and can enhance the pilot's situational awareness in selecting correct strategies within the safety zone to avoid unsafe manipulation.     

Disturbance observer-based backstepping control for hypersonic flight vehicles without use of measured flight path angle

In this paper a nonlinear control method is proposed for the tracking control of hypersonic flight vehicles. The designed control laws do not utilize the measured flight path angle due to its inferior accuracy in practical engineering. For this, an estimated flight path angle is designed via the measurements of the altitude and velocity. A tracking differentiator is designed for constructing nonlinear disturbance observer which is used to estimate the model uncertainties including the parameter indeterminacies and external disturbances in the channels of velocity and pitch rate. A robust high-order differentiator is introduced to avoid the employment of the measured flight path angle and estimate the lumped disturbance in dynamics of flight path angle. Meanwhile, the possible saturation of the control inputs is considered and compensated by the auxiliary states. The boundness of closed-loop signals is proved through the Lyapunov theory. Comparative simulations are carried out and the results demonstrate the effectiveness of the proposed method.     

Preliminary study on heat flux measurement data of TT-0 flight test

With the explosive development of aerospace science, the design of the new generation airliner at higher speeds is attracting more attentions. To achieve this goal, it is necessary to achieve accurate prediction of the aerodynamic heating / force loads and successful reduction of drag and heat flux. As a remedy for the existing studies which are based upon the CFD and wind tunnel tests, this study presents a flight test for the drag and heat reduction spike technology. The principal goals of this flight test were to provide reference for verifying the accuracy of the prediction technology on ground and promote the development of the drag and heat reduction technology. By adopting the OS-X rocket, the TT-0 test vehicle designed by Shenyang Aircraft Design & Research Institute reached a maximum Mach number of 5.8 and a maximum altitude of 38 km. Hypersonic and supersonic pressure data by pressure scanning valves and heat fluxes by gauges at different locations were obtained successfully. Also, heat fluxes obtained by in-house CFD code are illustrated in comparison with the flight data. The results indicate that the numerical errors are large in most cases. More technologies, such as more CFD codes and more numerical procedures, should be adopted to conduct studies on this issue in the future.     

利用地月间空间站的载人登月飞行模式分析

为提高空间站利用率，降低载人登月任务成本，有效开发地月空间，研究了基于地月空间不同轨道空间站的载人登月飞行模式。首先对比直接往返登月飞行模式，对基于空间站的载人登月飞行模式进行任务分析，通过空间站将载人登月任务解耦为载人天地往返任务和登月任务两部分；其次通过轨道设计和稳定性分析提出考虑登月任务需求的地月间空间站可运行轨道和停泊点；最后建立一套飞行模式评价模型，从速度增量需求、飞行时间、空间环境、登月任务窗口、测控条件、交会对接技术难度、后续任务支持性和任务可靠性方面对6种不同位置空间站的登月飞行模式进行分析和定量评价。评价结果表明基于L2点Halo轨道空间站的载人登月飞行模式为更优飞行模式。     

民用飞机舱门飞行锁机构接触力计算分析

研究飞机飞行锁机构中的接触力对于民用飞机飞行锁机构的设计具有重要意义。首先介绍飞行锁机构的功能和主要设计依据,阐明某民用飞机飞行锁机构的工作原理,并对其传力路径进行分析;然后采用工程算法、多刚体模型和多柔体模型三种计算方法计算飞行锁工作时曲柄与飞行锁摇臂之间的接触力;最后对三种计算方法进行对比,分析不同方法计算得到的接触力力值产生差异的原因。结果表明:多刚体模型计算值与工程算法计算值产生差异的主要原因是机构空行程导致的力臂变化,多柔体模型计算值与多刚体模型计算值产生差异的原因主要是受力过程中的结构变形。     

一种未来大型天地往返运输系统平台气动方案

针对未来低运行成本、可直接水平起降、重复使用的大型天地往返运输系统平台飞行器研制所需重点解决的全速域气动力性能需求与气动热防护匹配等难题，分析了典型航天飞机方案所存在的能量运行缺陷等主要问题及可能的改善方案。基于放宽气动热防护设计、涡轮/冲压/火箭发动机三动力组合、嵌套式旋转机翼全速域变体、在爬升阶段将飞行动能转化为高度势能以及再入阶段“跳跃式”盘旋减速飞行轨迹控制等设计思想，从能量损失速率控制和回收利用等角度出发，开展了一种新型大型天地往返运输系统平台气动布局概念设计研究。全速域气动力/热性能工程估算以及内/外流整体气动效能初步分析结果表明，该方案可有效满足整个飞行包线内的升重平衡需求，相比航天飞机方案具有显著的整体气动效能优势，值得进一步开展深入研究。