尖顶弯折三角翼气动特性研究

对75°后掠三角翼在40%根弦处弯折引起的升阻特性及俯仰特性的变化进行了低速风洞实验研究,初步分析了尖顶弯折对三角翼气动特性的影响趋势. 得出尖顶弯折在低速大攻角下,可以使升力系数Cy增大、升阻比提高,并推迟失速攻角amax,从而说明顶部弯折对三角翼气动特性的改善作用是显著的.     

两种椭圆翼型高速气动特性实验研究

新概念旋转机翼飞机的主机翼既能高速旋转作为旋翼,又可锁定作为固定翼,所以只能使用特殊的前后对称翼型。针对主机翼翼型的这一特殊要求,对16％相对厚度,相对弯度分别为0％和3％的两种椭圆翼型的高速气动特性进行了风洞实验研究,试验分别在中国空气动力研究发展中心FL-21风洞和荷兰代尔夫特大学TST-27风洞进行,采用表面测压和尾排型阻测量技术。试验结果的对比分析表明,有弯度椭圆翼型的升力和力矩特性优于无弯度椭圆翼型,而阻力特性和最大升阻比劣于无弯度椭圆翼型。试验结果为旋转机翼飞机主机翼翼型的选取提供了参考。     

一种微型轴流风扇扭叶片设计方法及其气动特性的数值研究

本文利用"径向平衡"原理,建立了轴流叶轮出口通流速度沿叶高的分布方程,并基于此提出了一种新的扭叶片设计方法.将该方法运用于某微型风扇的设计,并采用CFD技术,数值研究了不同扭曲形式下该型风扇的气动特点.通过与用传统方法设计的扭叶片及原始直叶片的气动性能的对比发现,按本文提出的方法所设计的扭叶片不仅能扩大微型风扇小流量稳定工况范围,而且其风压明显增加,有助于提高微型风扇的气动性能.     

高空长航时无人机高升阻比两段翼型设计研究

针对某特定无人机的使用设计要求,在单段翼型设计研究的基础上,尝试了高升阻比低雷诺数两段翼型的设计方法的分析与研究.采用求解椭圆型方程加控制点约束条件的"椭圆-控制点切割法"完成了两段翼型外形的生成,并针对巡航构型的襟翼偏角对缝道参数进行了优化;应用MSES计算分析程序对所设计的两段翼型的气动特性进行了分析评估.计算结果表明:本文所设计的两段翼型的最大升力系数达到2.72,最大升阻比为158.71;与原始单段翼型相比,最大升力系数增大了74.35%,最大升阻比增大了28.64%.     

环空后台阶管道内气固两相流动的数值模拟研究

环空管道后台阶突扩流动是空气正循环钻井过程中十分重要的关键部分,直接决定了钻探岩屑是否能够顺利上返地面.本文采用Euler-Lagrange两相流研究方法,气相湍流采用Realizable k-ε模型,固相采用离散相模型(DPM),固相的湍流耗散采用随机轨道模型,对环空后台阶突扩管道内气固两相流动进行了数值模拟研究.得出了气相场大涡演变规律,在此基础上研究了不同粒径时颗粒在流道中的浓度分布规律、运动轨迹,以及速度场分布规律.这为细观框架下研究气固两相相互作用规律提供了依据.     

高速滚动轴承滑蹭试验系统研制

为研究高速、超高速条件下精密滚动轴承打滑蹭伤机理,自行设计并研制高速滚动轴承滑蹭试验系统.该系统可以通过调节影响高速滚动轴承打滑蹭伤的各种滑差组合因素,用以模拟滚动体与内外圈的动态接触情况,进而分析高速滚动轴承的滑蹭机理.详细介绍了系统的工作原理、系统构成及其主要功能.以圆柱滚子轴承滑蹭试验为例,初步研究了滑差率、内圈转速、径向载荷、润滑状况等滑差组合因素作用下高速滚动轴承的滑蹭规律,验证了该系统的可行性与有效性.本文所开发的试验系统简单便捷,易于扩展,可为未来超高速、超精密滚动轴承设计提供一定的参考与支持.     

翼面气动外形对栅格翼减阻的影响

从节约空间的角度考虑,带一定弧度的翼面有利于栅格翼在弹体上的安装.通过风洞实验研究了两种不同安装方式的弧形翼面栅格翼的气动特性,并和翼面无弧度的栅格翼进行比较.结果显示,弧形翼面的栅格翼阻力系数均小于翼面无弧度的栅格翼,升阻比除跨音速阶段外比后者表现更好,同时对一种前缘后掠的栅格翼模型进行了数值计算,比较研究结果显示,对栅格翼的迎风面栅格进行一定角度的后掠能有效减小超音速阶段的波阻,是一种栅格翼减阻设计的新思路.     

Investigation of the control of the flow around a wing using mini-flaps

The flow around an airfoil with a mini-flap mounted on the lower or upper wing surface is investigated. The results are obtained by measuring the pressure distribution over the airfoil surface and the forces acting on it for Mach and Reynolds numbers M = 0.1?0.8 and Re = (0.6?3.8) × 10⁶. It is shown that, as distinct from known devices such as Gurney flaps, blunt trailing edge, etc., for controlling the flow in the vicinity of the trailing edge of an airfoil, a mini-flap mounted on the undersurface produces gas flow from the upper to the lower surface around a sharp edge. In this case the flow pattern is considerably affected not only near the trailing edge but also over the entire airfoil. The pressure redistribution over the airfoil makes it possible to increase or decrease the wing lift. Thanks to the low hinge moment, the mini-flap can serve as an effective means of low-inertia control of the flow around a wing.     

环板在局部线性荷载作用下的塑性极限分析的计算方法探讨

本文结合环板在线性荷载作用下的塑性极限分析问题,给出一种简便的计算方法,即奇异函数法。文中用此法计算了具有外边界或内边界支承的环板的极限荷载,并画出几何参数对极限荷载的影响曲线。所得的结果具有良好的规律性而且是比较合理的。     

不同构型和多点喷射对短环型燃烧室燃烧性能的影响

对短环形流燃烧室内有较强回流的湍流旋流流动进行了模拟,并从两个方面(燃烧室构型和多点喷射)对燃烧室性能的影响进行了分析。计算中采用Reynoldes应力湍流模型(RSM)、EBU-Arrheniue湍流燃烧模型和离散坐标辐射模型描述其燃烧流动,液相采用Lagrange法处理,气相采用SIMPLE法求解。研究表明:在燃料和空气总流量不变的情况下,燃烧室构型对燃烧室出口平均温度影响不大,对出口温度分布、燃烧室内空气流场有比较大的影响。喷嘴数目的改变对出口处的平均温度和平均速度影响不大,但是对出口截面处的温度分布影响比较大,在局部范围可能产生温度比较高的热斑。     

Input-output reduced-order modeling of unsteady flow over an airfoil at a high angle of attack based on dynamic mode decomposition with control

Due to the damage caused by stall flutter, the investigation and modeling of the flow over a wind turbine airfoil at high angles of attack are essential. Dynamic mode decomposition (DMD) and dynamic mode decomposition with control (DMDc) are used to analyze unsteady flow and identify the intrinsic dynamics. The DMDc algorithm is found to have an identification problem when the spatial dimension of the training data is larger than the number of snapshots. IDMDc, a variant algorithm based on reduced dimension data, is introduced to identify the precise intrinsic dynamics. DMD, DMDc and IDMDc are all used to decompose the data for unsteady flow over the S809 airfoil that are obtained by numerical simulations. The DMD results show that the dominant feature of a static airfoil is the adjacent shedding vortices in the wake. For an oscillating airfoil, the DMDc results may fail to consider the effect of the input and have an identification problem. IDMDc can alleviate this problem. The dominant IDMDc modes show that the intrinsic flow for the oscillating case is similar to the unsteady flow over the static airfoil. Moreover, the input–output model identified by IDMDc can give better predictions for different oscillating cases than the identified DMDc model.     

Mathematical Modeling of Time-Dependent Aerodynamic Loads on an Airfoil with Dynamic Deflection of a Control on the Trailing Edge

The linear problem of the time-dependent inviscid flow past a thin symmetric airfoil with a control on its trailing edge deflected in accordance with an arbitrary law is considered. The aerodynamic loads on the airfoil are calculated. The intensity of the vortex wake shed from the airfoil is determined by numerically solving a Volterra integral equation of the first kind. Questions of the mathematical modeling of the time-dependent aerodynamic loads in a form convenient for the joint solution of the problems of aerodynamics and flight dynamics are also considered. The results of the modeling are compared with the numerical solutions obtained.__________Translated from Izvestiya Rossiiskoi Academii Nauk, Mekhanika Zhidkosti i Gaza, No. 3, 2005, pp. 157–169.Original Russian Text Copyright © 2005 by Khrabrov.