波形环式弹性支座刚度的测试与数值模拟

进行了波形环式弹性支座刚度数值模拟研究,推导了波形环支承刚度与其离散弧段刚度之间的关联式,建立了环弧段刚度分析模型,用有限元分析程序“APOLANS”计算了环弧段的载荷-位移场静力问题。与原有分析方法相比,精度有显着的提高,相当接近测试刚度,起到了理论分析与测试数据相互校验的作用,并为波形环式弹性支座刚度设计提供了可靠的理论依据。      

航天器系统工程技术发展思路

系统工程技术水平是航天器系统研制和创新能力的重要体现。对我国航天器系统工程技术发展问题进行了思考。首先对比分析了国内外航天器系统工程技术发展差距,阐述了国内面临的空间任务形势及系统工程技术发展要求;然后,研究构建了以系统工程过程和活动为核心,并包含任务能力支撑要素、发展基础要素和发展保障要素的航天器系统工程技术体系框架;随后,提出了航天器系统工程技术发展目标,并从专业技术发展、经验继承、活动过程研究、工具方法完善、标准规范开发和发展机制健全等方面梳理了航天器系统工程技术建设内容;此外,还探讨了航天器系统工程技术发展的实施途径。     

基于预测零控脱靶量的拦截器中制导段导引

针对三维空间内的高速飞行目标,提出了一种基于预测零控脱靶量的中制导段导引方法。建立了拦截器与目标的相对运动关系模型,分析了确定修正轨道的约束条件,并在此基础上推导出修正轨道根数的计算方法。同时根据待增速度给出了推力定向和推力发动机工作时长的确定方法。仿真结果表明,该方法能有效实现拦截器中制导段的制导控制。     

英语中的中国元素对提高中国文化软实力的积极意义

"中国英语"融合了中国传统和现代文化元素,是一种以标准英语为基础的特殊英语变体。中国元素体现在英语语言的各个方面及社会生活的各个领域,它对提高中华民族文化软实力具有重要意义。     

Galactic Evolution of the Light Elements: A New Set of B Observations

The boron 2500 spectral region has been observed with the Goddard High Resolution Spectrograph (GHRS) of the Hubble Space Telescope (HST) in a new set of metal-poor stars and analyzed by spectrum synthesis technique, adopting the most recent model atmospheres. By taking into account the Li and Be abundances available from the literature for this same set of objects, the resulting patterns of their light elements abundances cannot be easily justified with the currently known stellar structure scenarios. The finding of real differences in the B content between stars with very similar stellar characteristics suggest that also production effects, rather than depletion and/or mixing only, should be taken into account as a possible and valuable explanation.     

升阶谱元素在正交各向异性复合材料剪切板中的应用

本文对近年发展的一种新的有限元元素—升阶谱元素进行了探讨,并把改进过的这种元素具体应用于当代直升机广泛采用的正交各向异性复合材料层合板(厚板)问题,实例表明:采用改进过的升阶谱元素,根据应力梯度的变化来选择元素的阶次是能够收敛于正确解的,从经济角度和实用角度来看,该元素性能比较优越。     

Integration of lessons from recent research for “Earth to Mars” life support systems

Development of reliable and robust strategies for long-term life support for planetary exploration must be built from real-time experimentation to verify and improve system components. Also critical is incorporating a range of viable options to handle potential short-term life system imbalances. This paper revisits some of the conceptual framework for a Mars base prototype which has been developed by the authors along with others previously advanced (“Mars on Earth^®”) in the light of three years of experimentation in the Laboratory Biosphere, further investigation of system alternatives and the advent of other innovative engineering and agri-ecosystem approaches. Several experiments with candidate space agriculture crops have demonstrated the higher productivity possible with elevated light levels and improved environmental controls. For example, crops of sweet potatoes exceeded original Mars base prototype projections by an average of 46% (53% for best crop) ultradwarf (Apogee) wheat by 9% (23% for best crop), pinto bean by 13% (31% for best crop). These production levels, although they may be increased with further optimization of lighting regimes, environmental parameters, crop density etc. offer evidence that a soil-based system can be as productive as the hydroponic systems which have dominated space life support scenarios and research. But soil also offers distinct advantages: the capability to be created on the Moon or Mars using in situ space resources, reduces long-term reliance on consumables and imported resources, and more readily recycling and incorporating crew and crop waste products. In addition, a living soil contains a complex microbial ecosystem which helps prevent the buildup of trace gases or compounds, and thus assist with air and water purification. The atmospheric dynamics of these crops were studied in the Laboratory Biosphere adding to the database necessary for managing the mixed stands of crops essential for supplying a nutritionally adequate diet in space. This paper explores some of the challenges of small bioregenerative life support: air-sealing and facility architecture/design, balance of short-term variations of carbon dioxide and oxygen through staggered plantings, options for additional atmospheric buffers and sinks, lighting/energy efficiency engineering, crop and waste product recycling approaches, and human factor considerations in the design and operation of a Mars base. An “Earth to Mars” project, forging the ability to live sustainably in space (as on Earth) requires continued research and testing of these components and integrated subsystems; and developing a step-by-step learning process.     

材料非线性有限元分析的一种有效方法——预测割线刚度变刚法

 材料非线性有限元增量解法中如何减少加载次数,保证精度是两个重要的问题;而误差估计也是与之密切相关的问题,特别是对每次加载不进行迭代的增量变刚法。本文针对这些问题提出预测割线刚度变刚法。     

材料非线性对复合材料层板损伤的影响

根据Hahn-Tsai非线性应力应变关系,用有限元方法对受拉伸载荷作用的含孔复合材料层板损伤演变进行了模拟计算,由非线性有限元方法得到的应力、应变以及最终载荷与以往线性分析方法得到的结果比较表明:考虑材料非线性可以提高计算精度;参数研究表明非线性系数的变化对正交各向异性板的影响较大,而对准各向同性板的影响较少.     

Effects of uncertainties and flexible dynamic contributions on the control of a spacecraft full-coupled model

One of the most important problems for performing a good design of the spacecraft attitude control law is connected to its robustness when some uncertainty parameters are present on the inertial and/or on the elastic characteristics of a satellite. These uncertainties are generally intrinsic on the modeling of complex structures and in the case of large flexible structures they can be also attributed to secondary effects associated to the elasticity. One of the most interesting issues in modeling large flexible space structures is associated to the evaluation of the inertia tensor which in general depends not only on the geometric ‘fixed’ characteristic of the satellite but also on its elastic displacements which of course in turn modify the ‘shape’ of the satellite. Usually these terms can be considered of a second order of magnitude if compared with the ones associated to the rigid part of a structure. However the increasing demand on the dimension of satellites due to the presence for instance of very large solar arrays (necessary to generate power) and/or large antennas has the necessity to investigate their effects on their global dynamic behavior in more details as a consequence. In the present paper a methodology based on classical Lagrangian approach coupled with a standard Finite Element tool has been used to derive the full dynamic equations of an orbiting flexible satellite under the actions of gravity, gravity gradient forces and attitude control. A particular attention has been paid to the study of the effects of flexibility on the inertial terms of the spacecraft which, as well known, influence its attitude dynamic behavior. Furthermore the effects of the attitude control authority and its robustness to the uncertainties on inertial and elastic parameters has been investigated and discussed.