外翼上壁板根部连接形式对飞机承载能力的影响研究

在飞机结构设计中,外翼上壁板根部连接处结构形式对飞机的传力、变形、承载能力具有重要影响.通过对3种不同形式的上壁板根部连接方案进行压缩试验,研究各方案的承载能力、破坏方式.通过三维有限元方法,计算了连接部位的主要螺钉所分配的载荷,研究了长桁根部斜角对结构屈服载荷的影响,得到了最优的选型方案.     

A coupling VWM/CFD/CSD method for rotor airload prediction

A coupling fluid-structure method with a combination of viscous wake model(VWM),computational fluid dynamics(CFD) and comprehensive structural dynamics(CSD) modules is developed in this paper for rotor unsteady airload prediction. The hybrid VWM/CFD solver is employed to model the nonlinear aerodynamic phenomena and complicated rotor wake dynamics;the moderate deflection beam theory is implemented to predict the blade structural deformation; the loose coupling strategy based on the ‘delt method' is used to couple the fluid and structure solvers.Several cases of Helishape 7A rotor are performed first to investigate the effect of elastic deformation on airloads. Then, two challenging forward flight conditions of UH-60 A helicopter rotor are investigated, and the simulated results of wake geometry, chordwise pressure distribution and sectional normal force show excellent agreement with available test data; a comparison with traditional CFD/CSD method is also presented to illustrate the efficiency of the developed method.     

可变形翼战术导弹飞行动力学联合仿真研究

基于集中质量假设发展的一套适于可变形翼导弹的多体运动模型,以附加惯性项及快变气动参数的形式来反映弹翼变形对导弹动态特性的影响,涉及交叉求解不同弹翼外形对应的气动特性及运动方程.由此提出的一种基于Missile DATCOM与MATLAB/SIMULlNK的联合仿真方法,应用于典型轴对称导弹的变翼动态特性研究中,快速有效...     

柔性机翼阵风响应与被动减缓研究

高空长航时无人机的机翼展弦比大、柔性较强,飞行过程中极易受到阵风的影响。文章以几何精确本征理论建立结构模型,耦合 Pitt-Peters动力入流理论建立柔性机翼非线性气弹模型,研究了柔性机翼阵风响应以及翼尖被动阵风减缓效应。采用空间 -时间平行的有限元离散方法,将气弹方程转化为一阶微分代数方程,Newton-Raphson和 Generalized-α算法分别用于静态变形和动态响应的求解,通过算例研究了离散阵风载荷下柔性机翼的阵风响应,结果表明翼尖被动阵风减缓装置对机翼变形有明显的减缓效果。     

Flapping wing micro-aerial-vehicle:Kinematics,membranes, and flapping mechanisms of ornithopter and insect flight

The application of biomimetics in the development of unmanned-aerial-vehicles (UAV) has advanced to an exceptionally small scale of nano-aerial-vehicles (NAV), which has surpassed its immediate predecessor of micro-aerial-vehicles (MAV), leaving a vast range of development possi-bilities that MAVs have to offer. Because of the prompt advancement into the NAV research devel-opment, the true potential and challenges presented by MAV development were never solved, understood, and truly uncovered, especially under the influence of transition and low Reynolds number flow characteristics. This paper reviews a part of previous MAV research developments which are deemed important of notification; kinematics, membranes, and flapping mechanisms ranges from small birds to big insects, which resides within the transition and low Reynolds number regimes. This paper also reviews the possibility of applying a piezoelectric transmission used to pro-duce NAV flapping wing motion and mounted on a MAV, replacing the conventional motorized flapping wing transmission. Findings suggest that limited work has been done for MAVs matching these criteria. The preferred research approach has seen bias towards numerical analysis as com-pared to experimental analysis.     

Dynamic modeling and analysis of vortex filament motion using a novel curve-fitting method

Applications of a novel curve-fitting technique are presented to efficiently predict the motion of the vortex filament, which is trailed from a rigid body such as wings and rotors. The governing equations of the motion, when a Lagrangian approach with the present curve-fitting method is applied, can be transformed into an easily solvable form of the system of nonlinear ordinary differential equations. The applicability of Be′zier curves, B-spline, and Lagrange interpolating polynomials is investigated. Local Lagrange interpolating polynomials with a shift operator are proposed as the best selection for applications, since it provides superior system characteristics with minimum computing time, compared to other methods. In addition, the Gauss quadrature formula with local refinement strategy has been developed for an accurate prediction of the induced velocity computed with the line integration of the Biot–Savart law. Rotary-wing problems including a vortex ring problem are analyzed to show the efficiency, accuracy, and flexibility in the applications of the proposed method.     

燃料分级对旋流火焰的动态特性影响研究

为深入研究分级旋流火焰特性,以分级旋流模型燃烧室为研究对象,对四个不同燃料分级比(Rf)条件下的分级旋流火焰进行了数值研究,在时均燃烧场特性分析的基础上进一步对燃料分级比为1和3两个工况进行了基于壁面建模的大涡模拟(WMLES)研究。结果表明:燃料分级比的改变会影响中心回流区(CRZ)的长度和宽度。燃烧室中截面的散点分布图能够显示出不同燃料分级比条件下的燃烧特征。燃料分级比为1时,燃烧室剪切层仅存在零散的涡破碎区;而燃料分级比为3时,伴随涡破碎区还出现了单螺旋分支进动涡核(PVC)。通过FFT变换获得的燃烧室内剪切层速度能谱主频与进动涡核的旋转频率相同,表明内剪切层速度脉动的产生与进动涡核有关。另外进动涡核会使流场内的燃料分布和燃烧模式发生周期性的变化,进而影响燃烧过程。调整燃料分级比在1附近,能够使分级火焰达到稳定燃烧降低排放的目标。     

预旋系统稳态和非稳态计算对比研究

针对预旋系统由于旋转引起流场和温度场参数周期性瞬态变化的问题,分别采用滑移网格的瞬态法和固定转子相位的稳态法进行数值求解,并在稳态计算中通过改变转子相位来近似模拟非稳态问题的时空变化特性。通过稳态空间平均结果与非稳态时均结果的对比,以期为预旋系统非稳态问题的低成本求解提供方法依据。结果表明：稳态计算结果与非稳态计算结果相比,周期性波动频率一致,接受孔进口处,稳态计算的压力波动幅度小39%左右,温度波动幅度小15%左右;多个相位的稳态空间平均结果与非稳态时均结果相比,压力高0.2%,温度低0.1%;采用多个计算周期数与单个周期的非稳态计算结果差异微小。当采用喷嘴出口气流中心正对接受孔迎风面前缘的转子相位时,稳态计算结果与非稳态计算时均结果最接近。     

基于实验设计和响应面模型的风扇转子气动优化设计

针对跨声速风扇动叶中掠、弯结合叶片基于控制点的B样条曲线对积叠线进行参数化,以掠、弯为设计自由度,应用实验设计、三维粘性流场求解、响应面模型及遗传算法对Rotor 67以近尖峰效率工况点为设计点对风扇转子进行了气动优化设计,得到了前掠与弯向旋转方向的复合设计叶片,其总压比有较明显提高。但由于优化是在单一工况点下进行的,其变工况性能不佳。     

基于线化稳定性理论的后掠翼边界层内横流稳定性研究

采用Mack方法求解忽略曲率和压缩性的三维线化稳定性方程（Orr-Sommerfeld方程）,针对无限展长后掠翼,计算分析边界层内不同波长横流驻波沿弦向的放大率,确定最不稳定波的波长。计算结果与参考文献中的实验结论和计算结果符合较好,表明该方法能够准确的预测出最不稳定波的波长,可以用来指导横流驻波主导下的后掠翼流动稳定性问题研究。