Parametric study of turbine NGV blade lean and vortex design

The effects of blade lean and vortex design on the aerodynamics of a turbine entry nozzle guide vane (NGV) are considered using computational fluid dynamics. The aim of the work is to address some of the uncertainties which have arisen from previous studies where conflicting results have been reported for the effect on the NGV. The configuration was initially based on the energy efficient engine turbine which also served as the validation case for the computational method. A total of 17 NGV configurations were evaluated to study the effects of lean and vortex design on row efficiency and secondary kinetic energy. The distribution of mass flow ratio is introduced as an additional factor in the assessment of blade lean effects. The results show that in the turbine entry NGV, the secondary flow strength is not a dominant factor that determines NGV losses and therefore the changes of loading distribution due to blade lean and the associated loss mecha-nisms should be regarded as a key factor. Radial mass flow redistribution under different NGV lean and twist is demonstrated as an addition key factor influencing row efficiency.     

华夏历史文明传承创新研究——基于寻根文化的视角

分析了寻根文化产生的原因、演化过程、基本内涵、内容组成,从家谱、宗祠、陵寝分析了物质层面的寻根文化建设,从神灵崇拜、人生思考、孝文化的角度分析了精神层面的寻根文化建设,从民间仪式的举办分析了行为层面的寻根文化建设,最后提出了寻根文化在传承过程中创新的建议.     

Reliability analysis of aero-engine blades considering nonlinear strength degeneration

To comprehensively consider the effects of strength degeneration and failure correlation, an improved stress-strength interference (SSI) model is proposed to analyze the reliability of aeroengine blades with the fatigue failure mode. Two types of TC4 alloy experiments are conducted for the study on the damage accumulation law. All the parameters in the nonlinear damage model are obtained by the tension-compression fatigue tests, and the accuracy of the nonlinear damage model is verified by the damage tests. The strength degeneration model is put forward on the basis of the Chaboche nonlinear damage theory and the Griffith fracture criterion, and determined by measuring the fatigue toughness during the tests. From the comparison of two kinds of degeneration models based on the Miner’s linear law and the nonlinear damage model respectively, the nonlinear model has a significant advantage on prediction accuracy especially in the later period of life. A time-dependent SSI reliability model is established. By computing the stress distribution using the finite element (FE) technique, the reliability of a single blade during the whole service life is obtained. Considering the failure correlation of components, a modified reliability model of aero-engine blades with common cause failure (CCF) is presented. It shows a closer and more reasonable process with the actual working condition. The improved reliability model is illustrated to be applied to aero-engine blades well, and the approach purposed in this paper is suitable for any actual machinery component of aero-engine rotor systems.     

对直升机齿轮齿根应力分布规律的研究

本文不但指出并纠正传统齿轮齿根应力分析中的错误及不妥，而且还提出一组可确定直升机齿根剖面上正应力、剪应力以及主应力等分布规律的解析表达式。     

A novel none once per revolution blade tip timing based blade vibration parameters identification method

The vibration caused blade High Cycle Fatigue (HCF) is seriously affects the safety operation of turbomachinery especially for aero-engine. Thus, it is crucial important to identify the blade vibration parameters and then evaluate the dynamic stress amplitude. Blade Tip Timing (BTT) method is one of the promising method to solve these problems. While, it need a high resolution Once Per Revolution (OPR) signal which is difficult to get for the aero-engine. Here, a Coupled Vibration Analysis (CVA) method for identifying blade vibration parameters by a none OPR BTT is proposed. The method assumes that every real blade has its own vibration performance at a given speed. Whereby, it can take any blade as the reference blade, and the other blades using the reference blade as the OPR for vibration displacement calculating and further parameter identifying. The proposed method is validated by numerical model. Also, experimental studies are carried out on a straight blade and a twisted three dimensional blade test rig as well as a large industrial axial compressor respectively. The results show that the proposed method can accurately identify the blade synchronous vibration parameters and quantitatively evaluate the mistuning in bladed disks, which lays a foundation for the reliability improvement of aero-engine.     

Effects of blade aspect ratio and taper ratio on hovering performance of cycloidal rotor with large blade pitching amplitude

In recent years, a lot of research work has been carried out on the cycloidal rotors. However, it lacks thorough understanding about the effects of the blade platform shape on the hover efficiency of the cycloidal rotor, and the knowledge of how to design the platform shape of the blades. This paper presents a numerical simulation model based on Unsteady ReynoldsAveraged Navier–Stokes equations(URANSs), which is further validated by the experimental results. The effects of blade aspect ratio and taper ratio are analyzed, which shows that the cycloidal rotors with the same chord length have quite similar performance even though the blade aspect ratio varies from a very small value to a large one. By comparing the cycloidal rotors with different taper ratios, it is found that the rotors with large blade taper ratio outperform those with small taper ratio. This is due to the fact that the blade with larger taper ratio has longer chord and hence better efficiency. The analysis results show that the unsteady aerodynamic effects due to blade pitching motion play a more important role in the efficiency than the blade platform shape. Therefore we should pay more attention to the blade airfoil and pitching motion than the blade platform shape.The main contributions of this paper include: the analysis of the effects of aspect ratio and taper ratio on the hover efficiency of cycloidal rotor based on both the experimental and numerical simulation results; the finding of the main influencing factors on the hover efficiency; the qualitative guidance on how to design the blade platform shape for cycloidal rotors.     

天津市宏观税收负担问题实证分析

采用计量分析方法对天津市1978～2005年数据区间的财政收入与经济总量、宏观税负与经济增长之间的关系进行研究。在结合天津市经济发展、税收增长、产业结构变化等实际情况的基础上，试图通过揭示变量之间的数量关系来印证和探寻天津市宏观税负与地区经济发展之间的关系。发现改革开放以来，天津总体税负适度，宏观税负呈下降趋势，但滨海新区的开发将为天津提供充足的税源，因而宏观税负会有所回升；20世纪90年代以来，天津第三产业发展迅速，第三产业对经济的贡献度与宏观税负的变化呈正向反应机制，而第二产业对GDP的贡献比重总体呈下降趋势；与其他直辖市相比，天津的宏观税负水平居于中游。     

基于模型大扭角叶片的三维矢量测量技术

针对接触式坐标测量机测量大扭角叶片截面存在余弦误差的问题，提出了基于模型的矢量测量方法。本文对此方法的测量精度及测量效率等方面进行论述，并通过实例验证了基于模型的矢量测量方法在精度与效率等方面优势，实现了此测量方法的工程化应用。     

直升机复合材料桨叶固化过程的多物理场有限元模拟

根据热传导、复合材料力学和固化动力学理论,采用基于偏微分方程的强耦合多物理场有限元方

法,计算在F650 双马来酰亚胺树脂建议温度周期下直升机复合材料桨叶固化过程中温度、固化度、固化度反应

速率和内应力变化历程。通过仿真结果对温度周期进行优化调整,改善工艺过程。计算结果表明:桨叶中树脂

固化反应同步度高,交联反应产热量少;调整后的加热周期与建议加热周期相比,最高加热温度由460 K 降低

为393 K,但固化度由0. 1 增加到1 的反应时间只由25 min 增加为30 min,固化反应速率峰值从1. 35×10-3 / s

降低为1. 15×10-3 / s,PMI(聚甲基丙烯酰亚胺,Polymethacrylimide)泡沫的Von Mises 热应力最大值从0. 82 MPa

降低为0. 482 MPa。

     

10MW风电机组空气动力设计初探

从风电机组系统角度探索了我国未来设计10MW风电机组在空气动力设计方面的一些问题及对策。从分析风能分布与风速分布关系以及风电机组风能利用系数随风速变化关系出发,研究了风轮基本参数确定方法,并以动量叶素理论为基础,建立了优化设计模型对10MW叶片外形优化设计进行了初步探索,并对风轮性能进行了评估,完成了10MW机组叶片及风轮外形建模。提出了通过适当提高叶尖线速度及拓宽风轮转速范围,可以达到优化机组塔头质量,节约成本,提高年发电量等多重有利目标的观点。