前行桨叶概念旋翼气动弹性响应分析

基于CFD/CSD松耦合策略,建立了前行桨叶概念（ABC）旋翼气动弹性分析方法.CFD计算中以非定常Euler/N-S方程为控制方程,通过动态重叠网格及动网格方法实现桨叶的运动及变形;桨叶结构模型通过中等变形梁理论得到;CFD和CSD数据每隔一个旋转周期交换一次.以XH-59A直升机为例,对不同前飞速度下的旋翼效率进行了分析,计算结果与试验值吻合良好.然后对旋翼振动载荷、桨尖间距、升力偏移量及桨叶载荷进行了分析,研究了前飞速度、旋翼交叉角、提前操纵角等参数对上述动力学性能的影响.该文方法具有很好的分析精度和工程适用性,分析结果可为前行桨叶概念旋翼设计提供重要参考.     

基于CFD/CSD耦合方法的旋翼气动弹性载荷计算分析

为提高直升机前飞状态下旋翼非定常气动弹性载荷的预估精度,在旋翼气动弹性综合分析方法中引入旋翼CFD模块,建立了一套基于CFD/CSD松耦合分析的计算方法和程序。为高效解决流固耦合方法中由于桨叶挥舞、扭转等弹性变形带来的旋翼贴体网格变形问题,采用基于代数变换方法的网格变形技术,桨叶运动变形量和旋翼气动力信息通过流固交接面传递。旋翼流场分析方法中,主控方程采用耦合S-A湍流模型的Navier-Stokes方程,围绕旋翼流场的网格采用结构嵌套网格方法生成,无黏通量计算采用Roe格式,时间推进采用双时间法。旋翼结构分析中,考虑旋翼配平,基于Hamilton变分原理和20自由度Timoshenko梁模型求解弹性旋翼非线性运动方程。分别对CSD和CFD方法进行验证,在此基础上,计算了SA349/2旋翼桨叶在前飞状态下的非定常气动力、挥舞弯矩、摆振弯矩和扭转力矩,并与飞行测试数据进行了对比。计算表明:CFD/CSD耦合方法可以显著提高旋翼非定常气动弹性载荷的分析精度,精确捕捉桨叶表面压强峰值、激波位置等,表明本文发展的旋翼CFD/CSD耦合方法可以有效地运用到旋翼气动弹性载荷的预测分析中。     

基于非惯性系的悬停状态旋翼CFD/CSD耦合气动分析

旨在提高先进旋翼气动特性的分析精度,在旋翼高精度CFD分析中耦合气动弹性效应,取代传统方法中的刚性桨叶假设,并考虑悬停状态旋翼流场准定常的特性,在非惯性坐标系下建立了一套适合于悬停状态旋翼气动特性计算的CFD/CSD耦合分析方法。旋翼气动载荷通过求解三维Navier-Stokes方程求得,空间离散及通量计算采用Jameson中心格式,时间方向则选用五步Runge-Kutta迭代求解,湍流模型采用B-L模型;基于Hamilton原理建立了描述旋翼弹性运动的非线性微分方程,针对旋翼悬停状态的工作特点,采用Raphson迭代方法求解获得旋翼桨叶的弹性变形量。在CFD/CSD耦合计算中,旋翼桨叶交接面载荷及变形信息通过CFD与CSD模块进行传递,同时为提高桨叶弹性变形后贴体网格生成的效率和质量,采用基于网格点坐标转换的网格变形方法。在CFD和CSD程序分别验证基础上,采用建立的旋翼CFD/CSD耦合分析方法计算了先进的UH-60A直升机旋翼的表面压强及气动载荷。计算结果表明,与刚性旋翼CFD模拟结果比较,本文建立的CFD/CSD耦合分析模型可以更准确地预估旋翼气动载荷和性能。     

基于CFD/CSD耦合方法的新型桨尖旋翼气动弹性载荷计算

为提高旋翼非定常气动弹性载荷的分析精度,在刚性旋翼计算流体力学(CFD)方法中引入计算结构动力学(CSD)方法,建立了一套适合于新型桨尖旋翼气动弹性载荷分析的CFD/CSD耦合方法。旋翼流场分析采用NavierStokes/Euler方程作为控制方程,围绕旋翼生成运动嵌套网格。在流场求解中,采用双时间法推进,通量计算采用Jameson中心格式,并采用B-L(Baldwin-Lomax)湍流模型。基于Hamilton变分原理和中等变形梁理论开展桨叶弹性运动变形分析,并发展了一套具有任意转角梁单元的新方法以提高新型桨尖旋翼的动力学分析精度。采用基于代数变换方法的网格变形策略,建立了一套CFD/CSD松耦合方法,桨叶运动变形和旋翼气动力信息通过流固交接面传递。首先分别对CSD和CFD模块进行了验证,然后计算了UH-60A旋翼在高速前飞状态下的气动弹性载荷,并与试验值进行了对比,最后重点对旋翼桨尖形状进行了参数分析。计算结果表明,相比于升力线理论和刚性旋翼CFD方法,CFD/CSD耦合方法可以显著提高旋翼非定常气动弹性载荷的分析精度,并能更准确地反映新型桨尖旋翼的气动弹性耦合效应;同时采用后掠桨尖在桨叶前行侧30°~90°方位角范围可以显著降低激波强度,有利于改善旋翼的气动特性。     

直升机旋翼桨-涡干扰状态非定常气弹载荷高精度预估

为准确计算直升机旋翼在复杂的桨-涡干扰(BVI)状态下的气弹载荷,在刚性旋翼计算流体力学方法中引入桨叶弹性变形的影响,建立了一套适合于弹性旋翼BVI状态气动特性分析的计算流体力学/计算结构力学(CFD/CSD)耦合方法.CFD模块对Reynolds averaged Navier-Stokes(RANS)/Euler方程进行求解,并采用双时间法推进和Baldwin-Lomax(B-L)湍流模型.CSD模块采用中等变形梁假设的有限元模型,通过Newmark-Beta方法求解桨叶运动方程.通过代数变换方法进行桨叶网格变形,并建立一个适于流场/结构信息交换的CFD/CSD耦合方法.在分别验证CFD和CSD模块的有效性的基础上,开展UH-60A直升机旋翼的BVI 状态载荷分析,并与飞行测试数据进行了对比.计算结果表明:相比于旋翼综合分析中的升力线理论和刚性旋翼CFD方法,耦合的CFD/CSD方法可以更准确地预测BVI状态气弹载荷,并有效地模拟桨叶前行侧方位角和后行侧方位角附近的BVI现象,对BVI导致的升力波动幅值和相位的计算结果均与试验值吻合良好.      

悬停状态直升机桨叶扭转分布的优化数值计算

建立了一套基于高精度计算流体力学(CFD)技术和代理模型优化算法的旋翼气动外形设计方法。在该方法中,旋翼流场气动性能的计算采用了基于Navier-Stokes/Euler方程的CFD方法,并根据流场特点、精度和效率的要求采用Baldwin-Lomax(B-L)湍流模型,通量计算采用Roe-MUSCL格式进行。为提高网格生成质量和便于流场控制方程的求解,将流场分成两个区域,即围绕旋翼的黏性区和无黏的背景网格区。其中,桨叶网格使用了基于二维翼型网格的参数化方法生成,数值计算结果表明该方法有效地提高了网格生成质量及效率。在参考旋翼流场及桨叶细节流动分析的基础上给出设计变量及范围,有效减小了优化问题的规模;为满足优化和机理分析的需要,将基于置换遗传算法优化的拉丁超立方(PermGA LHS)方法和径向基函数(RBF)的代理模型优化方法引入到桨叶外形的优化设计中。首先以Helishape 7A旋翼为算例,检验了数值模拟方法的准确性。然后,应用所建立的优化方法针对旋翼负扭转分布进行了优化计算,结果表明优化后的旋翼悬停气动性能比优化前有了明显提高。     

低HSI噪声旋翼桨尖外形优化设计方法

建立了一套基于计算流体力学(CFD)/FW-H_pds方程(Ffowcs Williams-Hawkings equations with penetrable data surface)的气动噪声预估技术和组合优化算法的低噪声旋翼桨尖平面外形设计方法。首先,采用积分形式的可压雷诺平均Navier-Stokes(RANS)方程作为旋翼流场求解控制方程,围绕旋翼流场的网格采用嵌套网格方法生成。在优化过程中,桨叶网格生成采用提出的高效参数化的网格自动生成方法。在建立的CFD方法求解基础上,采用基于可穿透旋转积分面的鲁棒性较好的FW-H_pds方程来求解旋翼高速脉冲(HSI)噪声。然后,以降低旋翼HSI噪声为目标,以旋翼悬停气动性能为约束,提出具备前掠-后掠-尖削等组合特征的桨尖外形方案并进行优化分析。将基于拉丁超立方(LHS)方法和径向基函数(RBF)的代理模型方法耦合到遗传算法过程中,建立了一种高效的组合优化算法。在当前的计算状态下,优化后的桨尖外形的负压峰值相比于矩形桨叶降低了58.4%,优化后的桨叶有效地减弱了旋翼桨尖区域的跨声速"离域化"现象,因此可以降低旋翼HSI噪声特性,同时可以减弱旋翼桨尖涡强度达30%,旋翼悬停性能提高了2%~3%。     

旋翼非定常气动特性CFD模拟的通用运动嵌套网格方法

针对直升机旋翼非定常气动特性CFD模拟中的网格生成难题,提出了一套高效、通用的运动嵌套网格生成方法.首先,基于Poisson方程求解和翻折法生成旋翼桨叶的正交贴体网格.其次,针对旋翼桨叶的扭转分布及变距、挥舞等复杂运动,建立了一套通用的洞单元识别的扰动衍射法;为保证洞包络面的封闭性,完善了挖洞过程中网格加密策略;在洞边界确立基础上,提出了一种高效、鲁棒的最小距离法贡献单元搜索的改进方法.在此基础上,建立了基于RANS(Reynolds-averaged Navier-Stokes)方程的旋翼非定常流场CFD模拟方法.最后,采用所建立的方法分别对悬停和前飞状态下的C-T(Caradonna-Tung)旋翼和7A(Helishape 7A)旋翼的气动特性、桨尖涡的位置进行了计算,计算结果与试验值误差小于5%,验证了该运动嵌套网格生成方法在旋翼非定常气动特性CFD模拟中的有效性.      

基于IBC方法的旋翼BVI噪声主动控制机理

为揭示单片桨叶控制(IBC)主动控制技术抑制旋翼桨-涡干扰(BVI)噪声的降噪机理,建立了一套基于CFD/CSD/FW-H_pds方程的综合噪声分析方法。旋翼桨-涡干扰噪声与旋翼桨叶载荷特性、气动变形以及旋翼桨尖涡结构等密切相关,为有效模拟旋翼桨叶的载荷特性及桨尖涡结构,将Navier-Stokes方程作为前飞流场的主控方程,空间离散上采用三阶MUSCL插值格式与通量差分裂Roe格式相结合;时间方向上采用双时间法,使用隐式LU-SGS格式在伪时间方向上进行推进;湍流模型采用对分离流动具有较好捕捉能力的Spalart-Allmaras模型。为提高旋翼桨叶弹性变形运动的模拟精度,建立了基于Hamilton变分原理的CSD模型,并与高精度的CFD求解器结合,发展了适合旋翼桨叶变形及载荷特性模拟的流固耦合分析方法。在CFD/CSD耦合方法分析流场基础上,使用可穿透空间积分面的FW-H_pds方法对旋翼气动噪声特性进行计算。首先,对流场及噪声数值方法进行验证;然后,着重针对UH-60A旋翼的斜下降飞行状态,分别对有/无IBC噪声主动控制条件下的旋翼BVI气动噪声特性进行了模拟,相位角、幅值和频率等不同控制参数的影响对比分析结果表明:IBC主动控制减小了前行侧桨叶表面尤其是桨叶尖部的负压峰值,降低了桨-涡干扰发生位置附近的桨叶气动载荷;同时主动控制后的桨尖涡集中程度变弱,并且增加了桨叶与桨尖涡之间的相遇距离,从而显著降低了桨-涡干扰噪声;选取合理的相位角、幅值和频率等主动控制参数组合,BVI噪声降低可达5~7dB。     

悬停状态共轴刚性双旋翼非定常流动干扰机理

基于运动嵌套网格方法,建立了一套适合于悬停状态下共轴刚性双旋翼非定常干扰流场分析的计算流体力学(CFD)方法。首先,基于高效的运动嵌套网格技术,采用积分形式的可压雷诺平均Navier-Stokes(RANS)方程作为双旋翼非定常流场求解控制方程,湍流模型选用Baldwin-Lomax模型,时间推进采用双时间方法。在CFD方法的验证基础之上,对干扰过程中的桨尖涡涡核位置及强度演变规律进行了细致分析,揭示了共轴双旋翼非定常干扰流场中上、下旋翼桨尖涡与双旋翼桨叶之间的贴近干扰、碰撞现象,以及上、下旋翼桨尖涡之间的相互干扰机理。然后,进一步研究了不同总距角下的共轴旋翼系统中上、下旋翼的非定常气动特性以及影响规律。计算结果表明:上旋翼桨叶的桨尖涡会直接与下旋翼桨叶发生碰撞,导致下旋翼桨叶拉力损失;上旋翼桨叶的桨尖涡和下旋翼桨叶的桨尖涡相互干扰,改变了桨尖涡的强度和轨迹;上、下旋翼桨叶相互靠近时,上、下旋翼桨叶的拉力均会上升,之后相互远离时上、下旋翼桨叶拉力均会先下降再上升。     

The effect of inlet conditions on the flow and heat transfer in multiple rotating cavity with axial throughflow

This paper discusses experimental results from two different build configurations of a heated multiple rotating cavity test rig.Measurements of heat transfer from the discs and tangential velocities are presented.The test rig is a 70% full scale version of a high pressure compressor stack of an axial gas turbine engine.Of particular interest are the internal cylindrical cavities formed by adjacent discs and the interaction of these with a central axial throughflow of cooling air.Tests were carried out for a range of non-dimensional parameters representative of high pressure compressor internal air system flows(Re up to 5×106 and Rez up to 2×105).Two different builds have been tested.The most significant difference between these two build configurations is the size of the annular gap between the(non-rotating) drive shaft and the bores of the discs.The heat transfer data were obtained from thermocouple measurements of surface temperature and a conduction solution method.The velocity measurements were made using a two component,LDA system.The heat transfer results from the discs show differences between the two builds.This is attributed to the wider annular gap allowing more of the throughflow to penetrate into the cavity.There are also significant differences between the radial distributions of tangential velocity in the two builds of the test rig.For the narrow annular gap,there is an increase of non-dimensional tangential velocity V/Ωr with radial location to solid body rotation V/Ωr=1.For the wider annular gap,the non-dimensional velocities show a decrease with radial location to solid body rotation.      

Research on Auto-detection for Remainder Particles of Aerospace Relay Based on Wavelet Analysis

Aerospace relay is one kind of electronic components which is used widely in national defense system and aerospace system. The existence of remainder particles induces the reliability declining, which has become a severe problem in the development of aerospace relay. Traditional particle impact noise detection (PIND) method for remainder detection is ineffective for small particles, due to its low precision and involvement of subjective factors. An auto-detection method for PIND output signals is proposed in this paper, which is based on direct wavelet de-noising (DWD), cross-correlation analysis (CCA) and homo-filtering (HF), the method enhances the affectiv-ity of PIND test about the small particles. In the end, some practical PIND output signals are analysed, and the validity of this new method is proved.     

Preparation of Highly Dispersed Antimony-doped Tin Oxide Nano-powder via Ion-exchange Hydrolysis of SnCl4 and SbCl3 and Azeotropic Drying

Antimony-doped tin hydroxide colloid precipitates have been synthesized by hydrolysis of SnCl4 and SbCl3 using: (1) an ion-exchange hydrolysis to remove chlorine ions, and (2) isoamyl acetate as an azeotropic solvent to obviate water. The obtained dried powder is of high dispersivity without any need for further grinding. The size and dispersivity of the final particles are investigated with the aid of TG-DTA, BET, XRD and TEM. After having calcined, the antimony-doped tin oxide nanopowder possesses a tetragonal rutile structure with high dispersivity, uniform particles and low hard agglomeration.     

Effects of Mo on the Microstructure and Hydrogen Sorption Properties of Ti-Mo Getters

The effects of Mo on the microstructure evolution, porosity and hydrogen sorption properties of Ti-Mo getters are investigated in this work. The results show that the addition of Mo prolongs the densification process of Ti-Mo getters and results in a significant amount of sintered pores. With the Mo content increasing, the porosity of getters firstly increases reaching the maximum value as it at- tains about 7.5wt.%, and then drops. At the room temperature, the hydrogen sorption property of getters increases progressively with the Mo content increasing, but the tendency is not very clear before its content lies below 2.5wt.%. When the Mo content achieves about 7.5wt.%, the hydrogen sorption property proves to be the best. The discussion is made about the above mentioned phenomena inclusive of hydrogen sorption properties of getters under different activation conditions (from 500-750 ℃).     

超声速燃烧数值模拟中的湍流与化学反应相互作用模型

高精度数值模拟有助于理解超声速湍流燃烧中湍流与化学反应的相互作用,可为发动机燃烧室等工程应用设计提供可靠的预测模型。除直接数值模拟外,目前在湍流燃烧应用中使用的大涡模拟和雷诺平均Navier-Stokes模拟均需要借助模型模化发生在湍流小尺度上的流动与化学反应过程对湍流大尺度运动的影响。现有的湍流与化学反应相互作用模型大致可分为:火焰面类模型和概率密度函数类模型,2类模型在不同的应用中各自具有优势和局限性。此外,现有模型大都基于低马赫数燃烧,而超声速燃烧中通常会伴随快速混合、局部熄火和再着火以及激波等复杂过程,这为发展其中的湍流与化学反应相互作用模型提出了更多的挑战。     

适于低轨卫星IP网络的单核共享树组播算法(英文)

为了解决低轨卫星IP网络中现有典型源组播算法的信道资源浪费问题,本文提出了一套单核共享树组播算法,即核心群合并共享树(CCST)和加权核心群合并共享树(w-CCST)算法。CCST 算法包括动态近似中心(DAC)选核方法和核心群合并组播路径构建方法。DAC方法专为周期、规律运动的低轨卫星网络提出,不需要复杂的星上计算。在核心群合并方法中,以核节点作为初始核心群,通过核心群和剩余组成员的最短路径方法逐步扩展直至整棵组播树构建完成,从而使得组播树的树代价最小,大大提高了网络的带宽利用率和组播传输效率。w-CCST 算法中所提出的加权因子可以调整树代价和端到端传播时延之间的折衷程度,因此,可以通过调整加权因子来适度增大树代价、降低端到端传播时延以支持某些端到端时延要求苛刻的实时组播业务。最后,与低轨卫星 IP 网络中典型算法进行了性能比较,仿真结果说明,CCST 算法的平均树代价比其它算法显著降低,w-CCST 算法的平均端到端传播时延小于 CCST 算法。     

Jet Vectoring Control Using a Novel Synthetic Jet Actuator

A primary air jet vectoring control system with a novel synthetic jet actuator (SJA) is presented and simulated numerically. The results show that, in comparison with an existing traditional synthetic jet actuator, which is able to perform the duty of either “push” or “pull”, one novel synthetic jet actuator can fulfill both “push” and “pull” functions to vector the primary jet by shifting a slide block inside it. Therefore, because the new actuator possesses greater efficiency, it has potentiality to replace the existing one in various appli- cations, such as thrust vectoring and the reduction of thermal signature. Moreover, as the novel actuator can fulfill those functions that the existing one can not, it may well be expected to popularize it into more flow control systems.     

Nonlinear Adaptive Slewing Motion Control of Spacecraft Truss Driven by Synchronous V-gimbaled CMG Precession

The slewing motion control of a truss arm driven by a V-gimbaled control-moment-gyro (CMG) is a nonlinear control problem. The V-gimbaled CMG consists of a pair of gyros that must precess synchronously. The moment of inertia of the system, the angular momentum of the gyros and the external disturbances are not exactly known. With the help of feedback linearization and recursive Lyapunov design method, an adaptive nonlinear controller is designed to deal with the unknown items. Performance of the proposed controller is verified by simulation.     

An SOR Implicit Time-accurate Scheme in Calculating Unsteady Flows

A new time-accurate marching scheme for unsteady flow calculations is proposed in the present work. This method is the combination of classical Successive Over-Relaxation (SOR) iteration method and Jacobian matrix diagonally dominant splitting method of LUSGS. One advantage of this algorithm is the second-order accuracy because of no factorization error. Another advantage is the low computational cost because the Jacobian matrices and fluxes are only calculated once in each physical time step. And, the SOR algorithm has better convergence property than Gauss-Seidel. To investigate its accuracy and convergency, several unsteady flow computa- tional tests are carried out by using the proposed SOR algorithm. Roe’s FDS scheme is used to discritize the inviscid flux terms. Un- steady computational results of SOR are compared with the experiment results and those of Gauss-Seidel. Results reveal that the numerical results agree well with the experimental data and the second-order accuracy can be obtained as the Gauss-Seidel for unsteady flow computations. The impact of SOR factor is investigated for unsteady computations by using different SOR factors in this algorithm to simulate each computational test. Different numbers of inner iterations are needed to converge to the same criterion for different SOR factors and optimal choice of SOR factor can improve the computational efficiency greatly.