激光深熔焊接等离子体发射光谱诊断研究

综述了激光等离子体发射光谱诊断的基本假设;介绍了电子温度、密度光谱计算最常用的方法;同时综述了国内外激光焊接等离子体光谱诊断的研究进展.旨在对激光焊接等离子体光谱诊断基本理论和当前的研究进展进行全面的梳理,并对开展激光焊接等离子体光谱试验工作提供理论支持和技术参考.     

Laser time transfer and its application in the Galileo programme

We are presenting the new instrument, new technology available and new measurement technique proposal for the Galileo programme – optical detector for the laser time transfer and one way laser ranging ground to space.     

一种测量氦氖激光器功率的新方法

介绍利用照度计测量氦氖激光器功率的新方法。     

LARES successfully launched in orbit: Satellite and mission description

On February 13th 2012, the LARES satellite of the Italian Space Agency (ASI) was launched into orbit with the qualification flight of the new VEGA launcher of the European Space Agency (ESA). The payload was released very accurately in the nominal orbit. The name LARES means LAser RElativity Satellite and summarises the objective of the mission and some characteristics of the satellite. It is, in fact, a mission designed to test Einstein's General Relativity Theory (specifically ‘frame-dragging' and Lense-Thirring effect). The satellite is passive and covered with optical retroreflectors that send back laser pulses to the emitting ground station. This allows accurate positioning of the satellite, which is important for measuring the very small deviations from Galilei–Newton's laws. In 2008, ASI selected the prime industrial contractor for the LARES system with a heavy involvement of the universities in all phases of the programme, from the design to the construction and testing of the satellite and separation system. The data exploitation phase started immediately after the launch under a new contract between ASI and those universities. Tracking of the satellite is provided by the International Laser Ranging Service. Due to its particular design, LARES is the orbiting object with the highest known mean density in the solar system. In this paper, it is shown that this peculiarity makes it the best proof particle ever manufactured. Design aspects, mission objectives and preliminary data analysis will be also presented.     

激光推进中飞行器结构响应对聚焦性能的影响

利用ABAQUS软件对激光推进飞行器进行了单、多脉冲结构冲击响应的数值模拟;建立了变形抛物面焦点区域的数值计算方法,计算出结构变形后的焦点区域的变化程度:发现因结构变形引起的聚焦区域的变化不可忽视,是飞行器设计时必须考虑的因素。     

应用LDV研究二元管道内分离流动

应用二维激光多普勒仪测量了二元曲壁非对称扩张通道内的湍流附面层分离流动。得到了时均速度、雷诺应力、平均流动方向角及正反向间歇流动因子的分布。文中给出了所测结果的不确定度,并在激光测速的近壁测量上做了尝试。实验结果分析表明:间歇瞬时分离点对应于附面层内垂直压强梯度的最大值;Schofield的速度尺度和长度尺度可用于形成新的速度相似型;正反向间歇流动因子γpuo与平均流动方向角存在着简单的线性关系。     

抛物型激光推进光船构型设计与特性分析

以轴对称Navier-Stokes方程组为基础,将球面激光支持的爆轰波模型与流场控制方程组进行耦合求解,数值模拟了抛物型激光推进光船的工作过程。计算中对激光支持的爆轰波阵面进行实时追踪,以获得激光能量吸收源项,同时采用Gupta建立的高温平衡空气模型来计算工质的热力学参数和输运特性。并用所发展的数值模拟程序研究了不同构型设计光船的推进性能。最后分析了流场流动特性和推力生成机制。结果表明,推力面离焦点距离越近,光船获得的冲量耦合系数越大,而峰值推力越小。     

全方位旋转分离式激光推力器概念设计

为了更好的研究激光推进,提出了全方位360°可旋转的分离式激光推进发动机概念及其构型设计,其结构主要特点是:光学系统和推力系统彻底分离,光学系统只经过2次反射聚焦,结构简单;光学系统可以360°改变激光接收方向,以适应各种轨道条件;采用双光束、单/双发动机构型,可以降低单台激光器的功率,较平稳的实现激光器接力。对激光飞行器入轨轨道编制程序并进行数值计算。计算结果显示,为了更好的将飞行器推入近地轨道,则需采用较大冲量耦合系数的材料作为烧蚀工质,且比冲不宜过大。     

机载光电跟踪系统模糊控制的优化设计与仿真

 分析了机载光电跟踪系统的构成,并对机载光电跟踪系统的最主要组成部分——陀螺稳定平台框架系统设计了基于遗传算法的模糊控制器,通过遗传算法来优化模糊控制器的规则、参数以及量化因子和比例因子。并对系统进行了详细的仿真研究,仿真结果证明基于 GA的模糊控制器设计获得了良好的控制效果。     

大尺寸工件直线度视觉测量系统中摄像机标定的研究

根据大尺寸工件直线度激光视觉测量系统的现场标定需要,从分析点结构光传感器模型入手,推导了计算机像平面坐标系到世界坐标之间的映射关系,借助转轴实现系统旋转扫描测量;介绍了系统中摄像机坐标系、传感器坐标系、转轴坐标系、标定块坐标系及全局坐标系等各个坐标系的转换关系,结合测量系统特点设计了特有的靶标,提出了适于大尺寸工件视觉检测系统摄像机参数及全局标定方法。实验表明,该方法快速,可用于现场标定。