转子系统挤压油膜阻尼器设计与动力特性

鉴于挤压油膜阻尼器(SFD)设计必须要同时考虑转子系统的动力学特性,提出了一种转子系统与挤压油膜阻尼器耦合设计方法,给出了详细的设计流程。对所设计的阻尼器进行了CFD数值模拟、油膜压力测量以及减振效果实验,结果证明所提出的设计方法是有效的。相比未采用阻尼器,采用阻尼器后转子系统两个转盘的振幅分别下降了46%和39%。通过实验还研究了不平衡量、支承刚度、供油压力和滑油温度对挤压油膜阻尼器减振效果的影响。结果表明,相比于不平衡量和支承刚度对减振效果的影响,供油压力和滑油温度的影响并不显著。进行挤压油膜阻尼器设计时,重点应该关注转子上的不平衡量大小和支承刚度。     

不同环境因素对引压管腔动态特性影响

为了探索引压管腔在动态压力校准和使用中不同环境因素对动态特性的影响,推导了管腔传压模型和谐振频率关系式,确立了影响管腔动态特性的参数,包括静态压力、温度、气体介质等。采用引压管腔专用实验装置进行了不同环境参数状态的实验验证,结果表明:静态压力仅会影响管腔在谐振频率附近的输出,随着静态压力的增大而非线性增大,对动态特性并无明显改变;温度会改变管腔的谐振频率和动态特性,随着温度的升高,谐振频率增大但输出幅值随之减小;气体介质的不同会彻底改变管腔动态特性,主要取决于介质的声速。该研究为引压管腔在使用环境下数据的评价和数据修正上提供了一定参考依据。     

Sensitivity analysis of flowfield modeling parameters upon the flow structure and aerodynamics of an opposing jet over a hypersonic blunt body

Implementation of an opposing jet in design of a hypersonic blunt body significantly modifies the external flowfield and yields a considerable reduction in the aerodynamic drag. This study aims to investigate the effects of flowfield modeling parameters of injection and freestream on the flow structure and aerodynamics of a blunt body with an opposing jet in hypersonic flow. Reynolds-Averaged Navier-Stokes (RANS) equations with a Shear Stress Transport (SST) turbulence model are employed to simulate the intricate jet flow interaction. Through utilizing a Non-Intrusive Polynomial Chaos (NIPC) method to construct surrogates, a functional relation is established between input modeling parameters and output flowfield and aerodynamic quantities in concern. Sobol indices in sensitivity analysis are introduced to represent the relative contribution of each parameter. It is found that variations in modeling parameters produce large variations in the flow structure and aerodynamics. The jet-to-freestream total-pressure ratio, jet Mach number, and freestream Mach number are the major contributors to variation in surface pressure, demonstrating an evident location-dependent behavior. The penetration length of injection, reattachment angle of the shear layer, and aerodynamic drag are also most sensitive to the three crucial parameters above. In comparison, the contributions of freestream temperature, freestream density, and jet total temperature are nearly negligible.     

Water takeoff performance calculation method for amphibious aircraft based on digital virtual flight

Owing to the strong coupling among the hydrodynamic forces, aerodynamic forces and motion of amphibious aircraft during the water takeoff process, the water takeoff performance is difficult to calculate accurately and quickly. Based on an analysis of the dynamics and kinematics characteristics of amphibious aircraft and the hydrodynamic theory of high-speed planing hulls, a suitable mathematical model is established for calculating the hydrodynamics of aircraft during water takeoff. A pilot model is designed to illustrate how pilots are affected by the lack of visual reference and the necessity to simultaneously control the pitch angle, flight velocity and other parameters during water takeoff. Combined with the aerodynamic model, engine thrust model and aircraft motion model, a digital virtual flight simulation model is developed for amphibious aircraft during water takeoff, and a calculation method for the water takeoff performance of amphibious aircraft is proposed based on digital virtual flight. Typical performance indicators, such as the liftoff time and liftoff distance, can be obtained via digital virtual flight calculations. A comparison of the measured flight test data and the calculation results shows that the calculation error is less than 10%, which verifies the correctness and accuracy of the proposed method. This method can be used for the preliminary evaluation of airworthiness compliance of amphibious aircraft design schemes, and the relevant calculation results can also provide a theoretical reference for the formulation of flight test plans for airworthiness certification.     

空心气冷低压涡轮动叶气热耦合数值模拟

以空心气冷低压涡轮动叶为研究对象,采用高质量的流体域和固体域网格控制技术,带转捩模型的双方程SST湍流模型,开展了基于CFD方法的叶片气热耦合问题研究。获得了不同冷气流量比(分别为1.0%,1.38%,1.8%和2.2%)、温比(分别为2.1,2.25,2.3,2.4和2.5)和压比(分别为1.4,1.6和1.8)对叶片换热特性的影响规律,设计状态中截面按弧长平均的叶片壁面金属温度计算值较试验值偏小0.3%,气热耦合计算的叶片壁面温度分布与试验结果吻合良好,验证了气热强耦合计算方法的精度,为涡轮叶片温度场分析提供了一种有效的方法。     

基于GARCH族优选模型的舰船器材消耗预测

器材消耗量预测是做好技术保障工作的前提和基础,受设备生命周期、任务类型、海洋环境及使用设备人员的技能水平等因素的影响,舰船器材消耗量序列会随着时间的推移而产生波动现象,丛集效应和高峰厚尾特征明显。根据 AIC(A-Information Criterion)准则,对 GARCH(Generalized Autoregressive Conditional Heteroscedasticity)族模型进行比较优选,寻求一种更为合适的预测模型,实现对消耗量的准确预测。     

小样本条件下多应力加速寿命试验预测方法

鉴于导弹中的电子设备价格昂贵、可用于试验的样本量少,在开展加速试验以及寿命预测的实际工作中通常为小样本的背景。文章研究探索小样本条件下多应力加速试验寿命预测方法,分别建立通用对数线性模型、 BAS-BP神经网络模型、灰色–支持向量回归模型,结合多应力加速试验数据在各应力条件下的样本容量分别为 56组、20组、10组、5组的情况下,比较 3种模型的预测效果,分析各模型的适用场合和时机,探索小样本条件下模型的选优问题,为小样本条件下多应力加速试验寿命预测提供有益的借鉴。     

基于飞行签派员的航空公司运行效率提升研究

航空公司运行控制中心是航空公司的核心,而飞行签派员又是运行控制中心的核心,运行控制中心的 效率直接影响到航空公司的运行安全与效益。根据航空公司飞行签派员的特点和管理现状,对效率量化和效 率评估进行分析研究,采用改进层次分析法(AHP)和物元可拓模型相结合的方法,建立适合我国航空公司飞 行签派员运行效率评估模型;针对评价指标在实际情况下更具有针对性和可操作性,提出4项准则和16项指 标组成的基于签派员航空公司运行效率评价指标体系,并进行算例分析。结果表明:所构建的评价指标体系合 理有效,能够真实反映出航空公司的运行效率与飞行签派员、运控设备、AOC组织结构与工作环境和航空公司 管理规定有着密切联系,为公司运行效率的提升提出理论依据。     

考虑滑流影响的埋入式进气道气动特性分析与流动控制研究

研究滑流对埋入式进气道性能的影响机理对于发动机的稳定性具有重要意义。针对某型涡桨发动机 滑油散热器进排气道系统,基于 CFD技术建立系统的螺旋桨滑流与滑油散热器内流一体化数值模拟方法,进 行考虑滑流影响的滑油散热系统埋入式进气道气动设计仿真分析;针对埋入式进气道由于吸入边界层低能气 流导致通过散热器流量低的问题,设计4组涡流发生器进行主动流动控制。结果表明:滑流使得进气道中的气 流偏离,难以形成稳定漩涡,容易发生流动分离;而合理设计的涡流发生器可以有效改善埋入式进气道内流场 特性,并使通过散热器的流量提高12%。     

一种GPS定位信息可用性的实时判定方法

基于GPS接收机输出数据,采用3级AR模型来预测下一时刻的GPS输出值,并与实际的输出值相比较,以一定的检测门限,判断当前时刻定位信息的可用性。通过仿真证明该方法的有效性,为GPS的可用性判定提供了一种方法。