利用加速度FRF的质量控制区段求测刚体质量分布特性

本文详细地介绍了一种如何利用实验模态分析中测得的加速度频率响应函数的质量控制区段来求出被测刚体的质心位置及质量矩阵诸元的方法。     

角速率火控原理研究

论述并研究了角速率火控原理,利用“滤波──识别”方法,提出了一套新的角速率火控滤波和外推模型。仿真结果表明,这种模型对于机动运动的反舰导弹可以明显提高火控预报精度。     

紧固件用钢复验的动态抽验方案

本文针对现行紧固件原材料进厂抽样复验方法的不足,套改《ISO2859计数抽查程序和图表》,提出动态抽样方案,并对新旧方案实际应用进行了比较。以比较科学的决策,取得提高效益、降低消耗的结果.     

不同裂解温度对制备SiCf/Si-O-C复合材料性能研究

以聚硅氧烷为先驱体,研究先驱体转化过程中在不同的裂解温度下对制备SiCf/Si-O-C复合材料性能影响.结果表明,当裂解温度在700℃、800℃时,陶瓷基复合材料的弯曲强度分别为255.2 MPa、309.0 MPa;当裂解温度在1000℃时,陶瓷基复合材料的弯曲强度为45.3 MPa.对SiCf/Si-O-C复合材料的微观结构及载荷-位移曲线进行分析,发现界面结构是影响SiCf/Si-O-C复合材料性能的主要因素.     

对加强农村消防工作的思考

针对我国农村消防工作现状 ,就如何加强农村消防工作谈几点看法 ,旨在全面提高农村整体防灾能力。     

通用导弹告警设备的试验和研究

导弹在进攻时,其截面相当于一个偶极子天线或单根箔条,利用导弹对特定频率雷达信号的谐振特性来增大目标的散射截面积。通过反辐射导弹告警实验设备系统的实弹打靶试验,验证了该理论的正确性和可行性。     

一种面向对象类级状态测试的形式化方法研究

面向对象的软件开发给测试带来了新的挑战,传统的测试技术不能直接用于面向对象的软件测试中,必须对其进行扩充和完善.类级测试是面向对象测试过程中的一个重要阶段,而类状态的测试是类级测试的核心.作者将扩充后的黑盒测试技术应用到类状态的测试过程中,可直接使用方法级的测试数据有效测试类中方法间的交互及其类状态的变化.最后,通过一个实例说明对类级状态的测试及其测试用例的生成.     

动态威胁环境下单无人机测向定位航迹优化算法

为解决单架无人机在动态战场环境下的测向定位问题,提出了一种基于动态窗口法的单机测向定位航迹优化算法。以最大化Fisher信息矩阵行列式为测向定位评价准则,在由动态探测雷达和静/动障碍构成的动态战场环境中,基于动态窗口法思想,将测向定位航迹优化评价准则由传统的单步最优原则扩展到对多步预测航迹的评价,同时考虑雷达探测和静/动障碍环境对预测航迹的影响,通过滚动时域方法控制无人机最优航向。仿真结果表明,所提方法能够使无人机在有效逃避雷达探测威胁以及规避环境中静/动障碍的条件下保证对目标的高精度测向定位,为解决动态战场环境下的单架无人机测向定位问题提供了新思路。     

A novel launch dynamics measurement system for multiple launch rocket system and comparative analysis with numerical simulations

In this paper,a novel launch dynamics measurement system based on the photoelectric sensor pair is built.The actual muzzle time(i.e.a time duration that originates from the initial movement to the rocket's departure from the muzzle)and the muzzle velocity are measured.Compared with the classical methods,the actual muzzle time is obtained by eliminating the ignition delay.The comparative analysis method is proposed with numerical simulations established by the transfer matrix method for multibody systems.The experiment results indicate that the proposed measurement system can effectively measure the actual muzzle time and reduce the error of classical methods,which match well with the simulation results showing the launch dynamics model is reliable and helpful for further analysis and design of the MLRS.     

Supercritical carbon dioxide as a new working medium for pneumatic launch: A theoretical study

Compared with the conventionally gaseous or liquid working media, the specific internal energy of supercritical carbon dioxide (SCD) is higher at the same temperature and pressure, and the critical temperature of carbon dioxide is close to room temperature, making SCD a potential new working medium for pneumatic launch. To analyze the feasibility of this conception, an analytical model of a pneumatic catapult is established on basis of the conservations of mass and energy. The model consists of a high-pressure chamber and a low-pressure chamber connected by multiple valves, and there is a movable piston in the low-pressure chamber that can push an aircraft to accelerate. The effects of the launch readiness state of SCD in the high-pressure chamber, the initial volume of the low-pressure chamber and the valve control on the movement of the aircraft are analyzed. It is found that there is a restrictive relation between the temperature and pressure of the launch readiness state of SCD, i.e., there is a maximum allowable launch readiness pressure when the launch readiness temperature is fixed. If this restrictive relation is not satisfied, the working medium in the low-pressure chamber will drop to its triple point within a few milliseconds, leading to a launch failure. Owing to this restrictive relation, there is an optimal launch readiness state of SCD with the highest working capacity for any allowable launch readiness temperature. The pressure of the low-pressure chamber will decrease significantly as the initial volume increases, leading to a decreased acceleration of the aircraft. The ac-celeration can be controlled below a critical value by a designed sequential blasting technique of multiple valves. The calculated results show that a 500 kg aircraft can be accelerated from 0 to 58 m/s in 0.9 s with 36 kg of carbon dioxide. This research provides a new technique for the controllable cold launch of an aircraft.