军用电力系统频率测试研究

军用电力系统是火力与指挥控制系统最重要的能源,其供电质量直接影响火力与指挥控制系统的作战效能。频率是军用电力系统最重要的供电质量指标之一。频率测量也是军用电力系统运行控制中的重要技术。在军用电力系统中,频率测试不仅要考核稳态过程,而且还要考核瞬态过程。详细描述了军用电力系统的频率偏差,频率测试特点及测试平台设计,讨论分析了实际测试结果。     

FFT-MTD滤波器组优化设计与仿真

介绍了用FFT算法实现雷达信号动目标检测(MTD)的方法,为提升MTD在强杂波环境下的检测性能,对加权FFT优化MTD时窗函数的选取进行了讨论,比较了6种窗函数加权时FFT等效多普勒滤波器组的幅频特性和改善因子,得出了适合于MTD的最佳窗函数,并针对某型雷达信号体制进行了仿真分析和验证,结果表明优化方法增强了MTD在杂波背景下的检测性能.     

复杂波形反数字储频干扰思考

阐述了数字射频存储器的基本结构,以及干扰的优点和局限性,从设计复杂波形进行反数字储频干扰研究,对阶段相位扰动LFM信号、串并联信号、脉内非线性调频脉间相位编码信号进行了分析。这3种复杂信号能够造成干扰信号和雷达信号失配,弱化干扰和回波的相干度,能够区分出干扰信号和回波信号,达到反干扰的效果,为反数字储频干扰的研究提供理论依据。     

含水乙醇燃烧的对冲扩散火焰数值研究

为加深对低浓度乙醇燃气发生器燃烧过程化学动力学过程的理解,分析水组分在燃烧过程中所起的作用,利用对冲扩散火焰模型对不同浓度下的火焰结构进行了数值分析,并虚拟了一种惰性水组分以区分物理机制和化学机制对燃烧过程产生的影响.研究结果显示,随着乙醇浓度的不断降低,火焰锋面呈现出向燃料侧的整体移动趋势;随着浓度向极限浓度的趋近,...     

基于振动分析的坦克柴油机汽缸燃烧压力检测方法

针对在坦克实车上不易直接测量柴油机汽缸压力的问题,提出了一种通过测量柴油机汽缸盖振动信号来间接检测汽缸燃烧压力的方法。在某型坦克柴油机上同步测量了汽缸燃烧压力、汽缸盖振动信号和变速箱振动信号,利用自适应滤波方法滤除了汽缸盖振动信号中包含的变速箱振动信号形成的噪声干扰,利用配气相位从时间域分离出由气体燃烧压力激发的振动信号,利用Hilbert变换和小波分解方法分别提取了振动信号和压力信号的特征波形。建立了RBF神经网络模型,以汽缸盖振动信号的包络作为网络输入,实现了汽缸燃烧压力的间接检测。     

压制兵器火控系统发展趋势分析

从部队编制体制变革,数字化部队建设,新技术、新装备、新材料的出现等多方面分析压制兵器发展面临的形势,以及国外压制兵器发展现状,总结分析压制兵器的发展趋势,并归纳提炼出火控系统应从信息综合化、系统模块化、系统体系结构分布化、功能一体化、火控射击控制闭环化和快速实时解算等6个方面发展趋势,以实现精确、快速、协同的综合武器控制.     

基于数字鉴频器的内燃机瞬时转速延时测量法

将基于数字鉴频器的延时法用于内燃机瞬时转速测量.首先介绍了延时法解调电路原理,然后使用仿真手段对延时法测量的特点进行了研究.仿真结果表明,该方法能够较好地还原频率调制信号,最后经实测试验证明了测量的有效性.该方法可采用全硬件电路实现,测量设备简单,可抑制调幅因素的影响,是一种有效的瞬时转速测试方法.     

星载寄生式SAR系统频率同步分析

针对星载寄生式SAR系统对地观测应用背景,详细分析了频率同步误差对双站SAR成像的影响,以法国提出的“干涉车轮”构形为例,对同步误差进行了仿真。提出了一种新的频率同步方法,该方法通过接收主星的直达波信号并进行相关处理,从而得到频率同步误差。计算机仿真结果表明该同步方法的准确性和有效性。     

Recent advances in catalytic combustion of AP-based composite solid propellants

Composite solid propellants (CSPs) have widely been used as main energy source for propelling the rockets in both space and military applications. Internal ballistic parameters of rockets like characteristic exhaust velocity, specific impulse, thrust, burning rate etc., are measured to assess and control the performance of rocket motors. The burn rate of solid propellants has been considered as most vital parameter for design of solid rocket motors to meet specific mission requirements. The burning rate of solid propellants can be tailored by using different constituents, extent of oxidizer loading and its particle size and more commonly by incorporating suitable combustion catalysts. Various metal oxides (MOs), complexes, metal powders and metal alloys have shown positive catalytic behaviour during the com-bustion of CSPs. These are usually solid-state catalysts that play multiple roles in combustion of CSPs such as reduction in activation energy, enhancement of rate of reaction, modification of sequences in reaction-phase, influence on condensed-phase combustion and participation in combustion process in gas-phase reactions. The application of nanoscale catalysts in CSPs has increased considerably in recent past due to their superior catalytic properties as compared to their bulk-sized counterparts. A large surface-to-volume ratio and quantum size effect of nanocatalysts are considered to be plausible reasons for improving the combustion characteristics of propellants. Several efforts have been made to produce nanoscale combustion catalysts for advanced propellant formulations to improve their energetics. The work done so far is largely scattered. In this review, an effort has been made to introduce various combustion catalysts having at least a metallic entity. Recent developments of nanoscale combustion catalysts with their specific merits are discussed. The combustion chemistry of a typical CSP is briefly discussed for providing a better understanding on role of combustion catalysts in burning rate enhancement. Available information on different types of combustion nanocatalysts is also presented with critical comments.     

Influence of porosity distribution on nonlinear free vibration and transient responses of porous functionally graded skew plates

This article deals with the investigation of the effects of porosity distributions on nonlinear free vibration and transient analysis of porous functionally graded skew (PFGS) plates. The effective material properties of the PFGS plates are obtained from the modified power-law equations in which gradation varies through the thickness of the PFGS plate. A nonlinear finite element (FE) formulation for the overall PFGS plate is derived by adopting first-order shear deformation theory (FSDT) in conjunction with von Karman’s nonlinear strain displacement relations. The governing equations of the PFGS plate are derived using the principle of virtual work. The direct iterative method and Newmark’s integration technique are espoused to solve nonlinear mathematical relations. The influences of the porosity distributions and porosity parameter indices on the nonlinear frequency responses of the PFGS plate for different skew angles are studied in various parameters. The effects of volume fraction grading index and skew angle on the plate’s nonlinear dynamic responses for various porosity distributions are illustrated in detail.