基于浮空器的新型应急通信监测系统

介绍了一种新型的机动式空中应急通信监测系统,该系统以机动式系留气球和小型遥控飞艇为空中平台,搭载各种通信、侦察、监测等电子设备,具有快速灵活、机动性强、费用低廉等特点,能够适应复杂环境,面对突发事件时可以快速布置到任何需要的地方。     

捷联惯性导航系统姿态算法研究

用四元数和旋转矢量在捷联惯导系统中表示姿态矩阵,在圆锥运动的条件下,对旋转矢量算法进行了优化。对四元数、旋转矢量优化算法进行了仿真比较。仿真结果表明:等效旋转矢量算法明显优于四元数算法。     

Stifness modeling and analysis of a novel 4-DOF PKM for manufacturing large components

Faster response to orientation varying is one of the outstanding abilities of a parallel kinematic machine（PKM）.It enables such a system to act as a reconfgurable module employed to machine large components effciently.The stiffness formulation and analysis are the beforehand key tasks for its parameters design.A novel PKM with four degrees of freedom（DOFs）is proposed in this paper.The topology behind it is 2PUS-2PRS parallel mechanism.Its semianalytical stiffness model is frstly obtained,where the generalized Jacobian matrix of 2PUS-2PRS is formulated with the help of the screw theory and the stiffness coeffcients of complicated components are estimated by integrating fnite element analysis and numerical ftting.Under the help of the model,it is predicted that the property of system stiffness distributes within the given workspace,which features symmetry about a certain plane and is also verifed by performing fnite element analysis of the virtual prototype.Furthermore,key parameters affecting the system stiffness are identifed through sensitivity analysis.These provide insights for further optimization design of this PKM.     

浅析大飞机数字化设计与制造技术

大飞机工程是一个国家具有战略性的高技术产业链,而数字化技术在大飞机设计制造过程中的应用有效推进了大飞机的设计制造进程.论述了大飞机数字化技术的几个典型特征,并从设计制造的9个方面浅析了数字化技术在大飞机设计制造中的应用,涵盖了大飞机设计制造的大多数领域.展望未来数字化技术将会越来越深入地融入到大飞机设计与制造的每个角落.     

复合材料格栅结构研究进展与应用

介绍了格栅复合材料的结构特征及其制备工艺。同时,对复合材料格栅结构分析设计、性能测试和该结构在航空、航天工程中的应用现状进行了概述。     

转子叶片加工误差对1.5级跨声速压气机气动性能的影响

压气机叶片加工误差不可避免,将在一定程度上影响压气机的气动性能.为研究叶片加工误差对跨声速压气机气动性能的影响,以燃气轮机进口1.5级跨声速压气机为对象,通过三坐标测量跨声速转子叶片叶型数据,获得了加工误差分布特征;针对实测转子叶片,采用三维CFD数值模拟方法,研究了轮廓度、位置度和扭转角综合误差对压气机转子和级特性线...     

航天ATS快速测试体系结构研究

快速发射是未来空间信息作战和导弹武器发展面临的新课题,快速测试是快速发射的重要环节。航天ATS快速测试需要遵循一定的体系结构而发展。以国际通用测试系统体系结构为背景,结合我国航天测试的需求,提出了航天ATS快速测试体系结构,分析了航天ATS快速测试的测试流程并行化、关键参数连续监测化和测试数据处理快速化等目标,以及所涉及到的图形化程序开发、仪器可互换等关键技术。结论有利于促进航天ATS快速测试技术的进步,并为其发展提供参考。     

高精度电磁标定力数值模拟及实验研究

高精度电磁标定力源是微推力测量系统的重要组成要素之一。为了获得性能优良的电磁标定力,本文综合采用数值模拟及实验测量两种方法分析研究了线圈和永磁铁相对位置变化时,磁铁几何尺寸对电磁力输出特性的影响：对于直径较大、厚度较小的永磁铁而言,其电磁力随相对位置的变化会存在极值,且极值点附近的电磁力具有较好的稳定性和一致性。根据电磁力变化趋势特性,提出了线圈和永磁铁相对基准中心（极值点）位置的高精度设置方案,且基准中心位置附近的电磁力变异系数可达0.00252,为高性能电磁力的获得提供了基础。最后,确定了大直径永磁铁+线圈组合型电磁力产生装置,并基于拟合方法建立了一定包络区间内的高精度电磁力控制关系式,其拟合曲线的估计标准误差约为0.0137,为微推力测量台架的标定提供了理论指导和技术支持。     

关于设计保证系统适航独立核查的思考

民用飞机主制造商建立设计保证系统,旨在民机研制过程中充分发挥自主适航的能力,通过组织机构、职责、程序和资源落实设计、适航以及独立监督三大职能,以保证航空产品的设计或者设计更改满足适航当局的要求。其中,设计保证系统适航职能的适航独立核查功能正是这一保证的关键。基于对设计保证系统适航独立核查功能的具体分析基础上,从设计保证系统的规划与设计层面提出了实现适航独立核查功能的机制,给出了机制中需明确的责任主体、职责与资质要求、工作流程与支撑工具以及管理程序等方面的建议,并从大数据知识的技术支撑和阶梯式递进的人才培训保障两方面以不断优化改进的方法工具与人力配置来深化适航独立核查的功能与效果,进而增强设计保证系统对飞机型号研制的保证作用。     

Science operations planning expertise: A neglected component of mission design

In this paper, Science Operations Planning Expertise (SOPE) is defined as the expertise that is held by people who have the two following qualities. First they have both theoretical and practical experience in operations planning, in general, and in space science operations planning in particular. Second, they can be used, on request and at least, to provide with advice the teams that design and implement science operations systems in order to optimise the performance and productivity of the mission. However, the relevance and use of such SOPE early on during the Mission Design Phase (MDP) is not sufficiently recognised. As a result, science operations planning is often neglected or poorly assessed during the mission definition phases. This can result in mission architectures that are not optimum in terms of cost and scientific returns, particularly for missions that require a significant amount of science operations planning. Consequently, science operations planning difficulties and cost underestimations are often realised only when it is too late to design and implement the most appropriate solutions. In addition, higher costs can potentially reduce both the number of new missions and the chances of existing ones to be extended. Moreover, the quality, and subsequently efficiency, of SOPE can vary greatly. This is why we also believe that the best possible type of SOPE requires a structure similar to the ones of existing bodies of expertise dedicated to the data processing such as the International Planetary Data Alliance (IPDA), the Space Physics Archive Search and Extract (SPASE) or the Planetary Data System (PDS). Indeed, this is the only way of efficiently identifying science operations planning issues and their solutions as well as of keeping track of them in order to apply them to new missions. Therefore, this paper advocates for the need to allocate resources in order to both optimise the use of SOPE early on during the MDP and to perform, at least, a feasibility study of such a more structured SOPE.