表面温度传感器自动检定系统

介绍了一种用于表面温度传感器检定的数据采集、处理系统,此系统具有操作简单,使用方便,运行可靠等特点。     

卫星表面材料物性与电荷积累

卫星表面在地磁亚暴环境下积累电荷的现象是必然的。由于表面间物性的差别,这种积累将是不均衡的,然而一旦建立了电势差,那末表面与表面,表面与构架间就会存在电荷交换,使电势差逐渐趋于减小。文章试图通过物理模型的建立,由此推导出面间电势差变化与表面电势值及表面的电导、电容的关系,从而建立一种明确的数学模型,以利卫星表面充电状态的分析。     

激光辅助车削工艺参数对单晶硅表面质量的影响

为了提高单晶硅激光辅助车削加工表面质量,通过开展激光辅助和常规车削加工试验,结合表面粗糙度、表面形貌及拉曼光谱检测,研究激光辅助车削技术对加工质量的影响。基于正交试验方法,研究单晶硅激光辅助车削工艺参数对表面粗糙度的影响;通过方差分析和极差分析评估各因素对表面粗糙度的影响。研究结果表明：与常规车削相比,激光辅助车削可有效提高加工表面质量,降低材料表面的残余应力。主轴转速、进给速度、切削深度和脉冲占空比对表面粗糙度的贡献率分别为17.51%、44.48%、6.69%和14.70%。确定最佳加工参数组合如下：主轴速度为4 000 r/min,进给速度为2 mm/min,切削深度为5μm,脉冲占空比为30%,最终获得表面粗糙度Rq为2.4 nm的高质量表面。     

一种新的鲁棒非线性卡尔曼滤波

Huber方法是一种基于l1/l2联合范数的估计方法,该方法可以实现估计的鲁棒性,同时尽量不损失滤波精度和效率.基于Huber估计的无味卡尔曼滤波虽提高了无味卡尔曼滤波的鲁棒性,但这种方法用统计线性回归模型来近似非线性的观测模型,损失了无味变换的精度.从Huber方法的数学意义出发,对观测信息(观测值或观测噪声)进行重新构造,然后对精确的非线性观测方程进行标准的无味卡尔曼滤波,这种新的基于Huber方法的无味卡尔曼滤波无需对非线性观测方程进行线性近似,在保持鲁棒性的前提下提高了滤波精度.通过一个具有混合高斯分布观测噪声的简明实例,验证了新算法在鲁棒性、滤波精度以及估计一致性方面的优势.     

复杂产品研制项目标准化效益评估模型

旨在量化计算标准化工作的效益,凸显标准化工作的重要作用.通过分析复杂产品研制项目标准化工作的特点,确定标准化工作权重计算方法,建立了复杂产品研制项目标准化工作项目体系及效益指标体系.深入研究复杂产品研制项目标准化效益评估模型的构建方法,编制总效益调研问卷,收集有关型号标准化工作效果数据,构建了复杂产品研制项目标准化效益评估模型.运用本方法建立了航空领域复杂产品研制项目标准化效益评估模型,并以某型飞机研制项目的真实数据验证了模型的准确度.     

基于支持向量机的航空发动机滑油监控分析

提出了一种基于支持向量机的航空发动机滑油金属含量预测方法。详细分析了支持向量机用于时间序列预测的理论基础,并给出了运用支持向量回归进行多步预测的一般公式,提出了用最终预报误差(FPE)准则优化选取嵌入维数。与传统的AR预测模型相比,支持向量机由于采用了新型的结构风险最小化准则表现出优秀的推广能力。经过数值仿真得出自回归(AR)模型仅适合于短期预测;支持向量机预测推广能力强、具有较强的鲁棒性和容错性,对较长区间预测仍具有较好的效果。最后,将其应用于某型发动机滑油的铁金属含量预测,取得了较好的效果。      

Performance analysis and application on Ti-6Al-4V of micro-forging system

Micro-forging (MF) is a novel surface modification technology which is capable of smoothening and strengthening the workpiece surface simultaneously. Based on analysis of the mechanism and energy conversion of micro-forging process, an electromagnetically driven micro-forging system is developed. To further grasp the kinetic characteristic of the equipment, a simulation model is established and its accuracy is verified. With the help of simulation and experimental results, we propose an input voltage optimization method, which drives the micro-forging head moving in a uniform and stable way. In this study, the influence of MF on surface integrity of Ti-6Al-4V (TC4) is firstly reported. Experimental results show that MF treatment reduces surface roughness (R_a) and increases micro-hardness by 48% and 11.8% at most, respectively. Besides, a compressive stress layer with an amplitude of −1000 MPa and a depth of 0.8 mm is observed. This study analyzes the performance and reveals the potential of micro-forging technology, which lays a solid foundation for expanding its application in TC4 surface modification.     

Grinding force and surface quality in creep feed profile grinding of turbine blade root of nickel-based superalloy with microcrystalline alumina abrasive wheels

Creep feed profile grinding of the fir-tree blade root forms of single crystal nickel-based superalloy was conducted using microcrystalline alumina abrasive wheels in the present study. The grinding force and the surface quality in terms of surface topography, subsurface microstructure, microhardness and residual stress obtained under different grinding conditions were evaluated comparatively. Experimental results indicated that the grinding force was influenced significantly by the competing predominance between the grinding parameters and the cross-sectional root workpiece profile. In addition, the root workpiece surface, including the root peak and valley regions, was produced with the large difference in surface quality due to the nonuniform grinding loads along the root workpiece profile in normal section. Detailed results showed that the surface roughness, subsurface plastic deformation and work hardening level of the root valley region were higher by up to 25%, 20% and 7% in average than those obtained in the root peak region, respectively, in the current investigation. Finally, the superior parameters were recommended in the creep feed profile grinding of the fir-tree blade root forms. This study is helpful to provide industry guidance to optimize the machining process for the high-valued parts with complicated profiles.     

Influence of lunar topography on simulated surface temperature

The surface temperature of the Moon is one of the essential parameters for the lunar exploration, especially to evaluate the Moon thermophysical features. The distribution of the temperature is heavily influenced by the Moon topography, which, however, is rarely studied in the state-of-art surface temperature models. Therefore, this paper takes the Moon topography into account to improve the surface temperature model, Racca model. The main parameters, such as slopes along the longitude and latitude directions, are estimated with the topography data from Chang’E-1 satellite and the Horn algorithm. Then the effective solar illumination model is then constructed with the slopes and the relative position to the subsolar point. Finally, the temperature distribution over the Moon surface is obtained with the effective illumination model and the improved Racca model. The results indicate that the distribution of the temperature is very sensitive to the fluctuation of the Moon surface. The change of the surface temperature is up to 150 K in some places compared to the result without considering the topography. In addition, the variation of the surface temperature increases with the distance from the subsolar point and the elevation, along both latitude and longitude directions. Furthermore, the simulated surface temperature coincides well with the brightness temperature in 37 GHz observed by the microwave sounder onboard Chang’E-2 satellite. The corresponded emissivity map not only eliminates the influence of the topography, but also hints the inherent properties of the lunar regolith just below the surface. Last but not the least, the distribution of the permanently shadowed regions (PSRs) in the lunar pole area is also evaluated with the simulated surface temperature result.     

基于非结构网格的燃面推进算法

根据惠更斯波传播原理,构建了一种在通用CFD软件的非结构网格系统上直接计算燃面推进的数值方法。该方法将燃面对应的计算网格面作为一系列平面波源,利用网格几何关系对边界节点奇异性进行判定,通过所有平面波源影响区域的叠加求解新的燃面位置。数值实现过程中,根据节点奇异性和波源影响区域以三维矢量运算得到节点的推进矢量。结合网格的重分,在通用CFD软件环境中实现了燃面的推进,所用数值算法具有良好的精度。另外,对三维动态内弹道模拟中燃面计算的稳定性和精度等问题进行了研究。