基于自然激励技术的颤振边界预测

为了预测紊流激励条件下机翼的颤振边界,基于自然激励技术提取紊流响应的自由衰减信号,采用矩阵束方法识别模态参数,最后通过Z-W(Zimmerman-Weissenburger)方法计算稳定性判据,拟合判据变化曲线并外推颤振边界.对平板机翼模型进行了数值仿真分析,对单独机翼模型风洞颤振试验数据进行了计算.结果表明:采用自然激励技术与矩阵束方法能够较准确地识别紊流激励响应的模态参数,频率识别误差小于6％,阻尼比识别误差小于30％,结合Z-W方法能够在较低风速较早地预测颤振边界,有助于提高试验的安全性.     

俯仰姿态保持模式下飞机结冰边界保护方法

在研究飞机结冰机翼和平尾失速机理的基础上,以飞机迎角作为关键参数,飞机俯仰指令作为指令参数,提出一种基于飞机自驾仪的结冰后边界保护方法.通过引入铰链力矩检测模块,提前告警飞机失速,为边界保护提供了裕度.建立飞机纵向动力学方程,针对俯仰姿态保持（PAH）模式下机翼失速进行了仿真计算.结果表明:结冰条件下,通过铰链力矩的检测,飞机能在失速迎角为2°之前,进入边界保护模式,增加飞行安全的裕度.通过控制指令的限制,自动驾驶模式下飞机迎角能保持在失速迎角之内.      

Machining of a film-cooling hole in a single-crystal superalloy by high-speed electrochemical discharge drilling

Single-crystal superalloys are typical advanced materials used for manufacturing aeroengine turbine blades. Their unique characteristics of high hardness and strength make them exceedingly difficult to machine. However, a key structure of a turbine blade, the film-cooling hole,needs to be machined in a single-crystal superalloy; such machining is challenging, especially considering the increasing levels of machining efficiency and quality demanded by the aeroengine industry. Tube electrode high-speed electrochemical discharge drilling(TSECDD), a hybrid technique of high-speed electrical discharge drilling and electrochemical machining, provides high machining efficiency and accuracy, as well as eliminating the recast layer. In this study, TSECDD is used to machine a film-cooling hole in a nickel-based single-crystal superalloy(DD6). The Taguchi methods of experiment are used to optimise the machining parameters. Experimental results show that TSECDD can effectively drill the film-cooling hole; the optimum parameters that give the best performance are as follows: pulse duration: 12 ls, pulse interval: 30 ls, peak current:6 A, and salt solution conductivity: 3 m S/cm. Finally, a hole is machined by TSECDD, and the results are compared with those obtained by electrical discharge machining. TSECDD is found to be promising for improving the surface quality and eliminating the recast layer.     

大型飞机迎角保护控制律设计及试飞技术研究

针对大型飞机迎角保护控制律设计及试飞问题,通过杆位移-过载梯度的实时精确调整及取大值逻辑指令切换,设计了迎角保护控制律,实现拉杆到底飞机迎角达到且不超过限制迎角的目的。根据迎角保护控制律的功能及试飞目的,将整个试飞过程分为三个阶段,研究了各个阶段的试飞技术。仿真结果表明,所设计的控制律能够实现迎角保护功能,具有良好的控制效果。     

基于改进无模型自适应算法的涡扇发动机限制保护控制方法

针对发动机限制保护控制问题,提出了一种基于数据驱动的改进无模型自适应限制保护控制方法。以主回路闭环系统为设计对象,通过在常规无模型自适应控制律的准则函数中增加误差变化率,使超限保护系统具有更快的响应速度,给出了改进后系统的稳定性条件,并采用临界比例度法进行了控制器参数整定。仿真结果表明:在不同工作点,所设计的改进无模型自适应限制保护控制器相比常规无模型自适应限制保护控制器,最大超限平均减小2.97%,响应时间平均缩短2.30s,实现了发动机超限后的迅速回调,保证了发动机系统的安全运行。     

1 500℃极端高温环境下高超声速飞行器轻质隔热材料热/振联合试验

远程高超声速飞行器处于极为恶劣的气动加热与振动耦合环境中,长时间的高温与振动载荷相互叠加会导致飞行器热防护材料出现裂纹、错位、剥离或脱落,甚至会引发致命的安全事故。因此热防护材料在极端高温环境下的地面热/振联合试验测试,对于高超声速飞行器的安全可靠性设计极为重要。建立高温与振动复合试验环境,设法解决轻质多孔隔热材料在强振动下,表面温度难于准确测量与控制的难题,制作水冷式隔热装置保护价格昂贵的振动激励设备等,实现了1 500℃高温环境下高超声速飞行器轻质隔热材料的热/振联合试验。得到非金属隔热材料陶瓷纤维板内部的断裂形貌及裂纹断面特征。根据试验前、后材料的表观及微观变化以及内部结合剂的变化等试验结果,对材料进行改进。经过试验测试后,达到了使用要求。本文建立的1 500℃极端高温环境下的热/振联合试验系统及试验结果为远程高超声速飞行器热防护材料的抗振动能力评估、隔热效果确定以及材料性能的改进提供了重要支撑。     

有翼再入飞行器气动外形集成设计优化

气动外形设计是有翼再入飞行器（RV-W）的关键技术之一。分析了气动参数对再入飞行性能的影响,探讨了有翼再入飞行器气动外形设计的规律和准则。基于上述设计准则,以类X-37B飞行器为研究对象,集成几何参数化建模、气动力、气动热、热防护等学科快速分析方法,采用多学科设计优化方法,以最优气动特性为目标对飞行器气动外形进行了优化;得到优化气动外形后,对飞行器热防护系统（TPS）进行了轻量化设计优化。结果表明,优化外形的气动特性相比初始外形得到了较大的提升,设计优化得到的热防护系统重量占比（8.7%）优于同类飞行器的热防护系统重量占比统计数据,说明了本文有翼再入飞行器气动外形集成设计优化方法的有效性,可为同类飞行器提供参考。     

可重复使用热防护材料应用与研究进展

可重复使用热防护系统是为高速重复使用飞行器而发展的关键性技术,涵盖了地球大气环境及非地球大气环境下的弹道式再入、高马赫数巡航等应用场景。根据现有高马赫数飞行器热防护现状,对高马赫数飞行器的主要热防护系统类型、特点和使用场景进行了简要介绍。在此基础上,结合国外里程碑式可重复使用飞行器（X-15、SR-71、航天飞机、X-33、X-37B、Spaceliner等）,梳理了可重复使用热防护材料的应用与研究进展,论述了代表性可重复使用热防护材料的发展、性能、研制进度、特点及应用前景。对国外在可重复使用热防护材料研制中的设计及发展思路,以及所存在的主要问题进行了总结归纳,为可重复使用热防护材料未来的发展提供了思路。     

Advances in critical technologies for hypersonic and high-enthalpy wind tunnel

Hypersonic and high-enthalpy wind tunnels and their measurement techniques are the cornerstone of the hypersonic flight era that is a dream for human beings to fly faster, higher and further. The great progress has been achieved during the recent years and their critical technologies are still in an urgent need for further development. There are at least four kinds of hypersonic and high-enthalpy wind tunnels that are widely applied over the world and can be classified according to their operation modes. These wind tunnels are named as air-directly-heated hypersonic wind tunnel, light-gas-heated shock tunnel, free-piston-driven shock tunnel and detonation-driven shock tunnel, respectively. The critical technologies for developing the wind tunnels are introduced in this paper, and their merits and weakness are discussed based on wind tunnel performance evaluation. Measurement techniques especially developed for high-enthalpy flows are a part of the hypersonic wind tunnel technology because the flow is a chemically reacting gas motion and its diagnosis needs specially designed instruments. Three kinds of the measurement techniques considered to be of primary importance are introduced here, including the heat flux sensor, the aerodynamic balance, and optical diagnosis techniques. The techniques are developed usually for conventional wind tunnels, but further improved for hypersonic and high-enthalpy tunnels. The hypersonic ground test facilities have provided us with most of valuable experimental data on high-enthalpy flows and will play a more important role in hypersonic research area in the future. Therefore, several prospects for developing hypersonic and high-enthalpy wind tunnels are presented from our point of view.     

海洋环境下载人航天器电子设备防护技术

海南文昌发射场高温、高湿、高盐雾的气候条件以及由天津到海南长距离的海上运输给航天器电子设备的三防性能带来了挑战。文章首先对运输过程中高湿、盐雾和霉菌对航天器电子设备的影响进行了分析,然后对航天器电子设备的三防工艺及运输技术进行了研究,并提出了具有普遍适用性的三防措施,能够有效降低环境因素带来的不利影响。