振梁加速度计温度误差模型及补偿技术研究

研究了振梁加速度计温度误差建模及补偿问题。分析了振梁加速度计受温度影响的主要因素,应用最小二乘算法得到零偏、标度因数与温度的多项式拟合关系,进而得到振梁加速度计的温度误差模型。利用该误差模型进行温度补偿。结果表明：经过温度建模和补偿,振梁加速度计精度有明显的提高。     

激光陀螺磁特性研究

本文分析了激光陀螺磁敏感原理,研究了腔内激光束椭偏度的产生机理,设计了高消光比激光束椭偏度测量系统。实验结果表明,激光陀螺磁灵敏度大小与磁场方向有关,输出激光束的椭偏度越大,磁灵敏度越大。研究表明,通过减小输出激光束的椭偏度,可减小激光陀螺磁灵敏度,从而增强激光陀螺环境适应性,提高激光陀螺的成品率。     

硅微加速度计系统设计技术

本文探讨了硅微加速度计的系统设计方法,采用专用MEMS设计软件建立了“三明治”式硅微加速度计自顶向下的系统模型,该模型对于硅微加速度计的系统设计和优化具有指导意义。通过优化改进设计,目前硅微加速度计零位重复性已达到2×10-4g（3个月,1σ）,正在开展探月二期工程的应用研究。     

冲角变化对涡轮叶栅内间隙流动的影响

航空发动机涡轮工作效率的损失很大程度在于涡轮叶尖间隙损失,而叶尖区域泄漏流动的形成机理强烈地依赖于叶栅的运行工况,因此有必要研究来流冲角的变化对涡轮叶栅内间隙流动的影响。为此在低速风洞中对三套不同叶片积迭线形状的矩形叶栅进行了实验,测量了间隙内以及沿流动方向8个横截面的气动参数。通过对实验结果的分析和讨论,认为随着冲角的增加叶顶压差与端壁流道横向压力梯度增大,同时叶栅的总流动损失也随之增加。     

冲角变化对涡轮静叶栅流场的影响

为了研究亚临界600MW汽轮机高压第九级静叶原型和改型叶栅的变冲角气动特性,对两套环形叶栅在0°和±10°冲角下在哈尔滨工业大学能源科学与工程学院的低速环形风洞中进行了对比实验研究。实验结果表明,冲角变化仅影响改型和原型叶栅流道前半部分的横向压力梯度,对流道后半部分的流动影响不大;与原型叶栅相比较,改型叶栅不仅降低了流动损失,而且比原型叶栅具有更好的变冲角特性。     

超宽带脉冲无线电在近距编队中的应用研究

编队飞行航天器间可靠的实时通信和精确的定位是需要解决的关键技术之一。超宽带脉冲无线电技术具有抗多径干扰、传输速率高、结构简单且可进行通信和导航一体化设计等鲜明特点。本文首先介绍超宽带脉冲无线电的基本原理,分析其主要特点,在跟踪编队飞行无线链路现有技术的基础上,研究了超宽带技术在近距编队中的潜在应用,最后分析了超宽带技术在航天器近距编队应用中需要注意的问题。     

单通道单脉冲自跟踪系统交叉耦合分析

单通道单脉冲跟踪体制具有节省通道、可靠性高、成本低等优点,因此在卫星、遥感、气象等接收系统中得到广泛应用。它只用一个接收通道,简化了角误差检测系统,但增加了方位与俯仰的交叉耦合。本文结合工程实践,对遥测系统中常用的自跟踪体制的交叉耦合产生机理进行了分析,并给出工程应用中减少交叉耦合的几点建议。     

Influence of leading edge with real manufacturing error on aerodynamic performance of high subsonic compressor cascades

To investigate the influence of real leading-edge manufacturing error on aerodynamic performance of high subsonic compressor blades, a family of leading-edge manufacturing error data were obtained from measured compressor cascades. Considering the limited samples, the leading-edge angle and leading-edge radius distribution forms were evaluated by Shapiro-Wilk test and quantile–quantile plot. Their statistical characteristics provided can be introduced to later related researches. The parameterization design method B-spline and Bezier are adopted to create geometry models with manufacturing error based on leading-edge angle and leading-edge radius. The influence of real manufacturing error is quantified and analyzed by self-developed non-intrusive polynomial chaos and Sobol’ indices. The mechanism of leading-edge manufacturing error on aerodynamic performance is discussed. The results show that the total pressure loss coefficient is sensitive to the leading-edge manufacturing error compared with the static pressure ratio, especially at high incidence. Specifically, manufacturing error of the leading edge will influence the local flow acceleration and subsequently cause fluctuation of the downstream flow. The aerodynamic performance is sensitive to the manufacturing error of leading-edge radius at the design and negative incidences, while it is sensitive to the manufacturing error of leading-edge angle under the operation conditions with high incidences.     

Integration of high-fidelity model of forward variable area bypass injector into zero-dimensional variable cycle engine model

Forward Variable Area Bypass Injector (FVABI) is one of key components which contributes to modulate the cycle parameters of Variable Cycle Engine (VCE) under various operation conditions. The modeling method of zero-dimensional FVABI was reviewed and its deficiency was analyzed based on FVABI flow characteristic. In order to improve the accuracy of VCE performance simulation, the high-fidelity modeling method of FVABI was developed based on its working characteristics. Then it was coupled with the zero-dimensional VCE model and the multi-level VCE model was built. The results indicate that the geometric and aerodynamic parameters can affect the interaction between the two airflows and the zero-dimensional FVABI model is too simple to predict the component performance accurately, especially when the FVABI inner bypass is chocked. Based on the performance curves for single bypass mode and the regression model of multi-scale support vector regression for double bypass mode, the high-fidelity model can predict FVABI performance accurately and rapidly. The integration of high-fidelity FVABI model into zero-dimensional VCE model can be done by adjusting iterative variables and balance equations. The multi-level model has good convergence and it can predict VCE performance when the FVABI inner bypass is chocked.     

Parameter studies and evaluation principles of delamination damage in laminated composites

Delamination represents one of the most severe failure modes in composite laminates, especially when they are subjected to uniaxial compression loads. The evaluation of the delamination damage has always been an essential issue of composite laminates for durability and damage tolerance in engineering practice. Focusing on the most typical and representative elliptical delamination issue, an analytical model simultaneously considering the conservative buckling process and non-conservative delamination propagation process is implemented. Various computational cases considering different delamination depths, directions, aspect ratios, and areas are established, and the predicted results based on the analytical model are carefully compared. Effects of these geometrical delamination parameters on the buckling, delamination propagation, and failure behaviors of composite laminates are thoroughly analyzed, and innovative evaluation principles of the delamination damage have been concluded. It is found that the delamination area is the key factor that truly affecting the failure behaviors of delaminated composites, and the local / global buckling and failure loads show clear linearity with the delamination area, whilst the delamination depth and direction only have slight effects.