Multiscale eigenelement method for periodical composites: A review

Based on the eigenvector expansion idea, the Multiscale Eigenelement Method (MEM) was proposed by the author and co-workers. MEM satisfies two equivalent conditions, one condition is the equivalence of strain energy, and the other is the deformation similarity. These two equivalent conditions character the structure-preserving property of a multiscale analysis method. The equivalence of strain energy is necessary for achieving accurate macro behaviors such as lower order frequencies, while the deformation similarity is essential for predicting accurate micro behaviors such as stresses. The MEM has become a powerful multiscale method for the analysis of composite structures because of its high accuracy and efficiency. In this paper, the research advances of MEM are reviewed and all types of eigenelement methods are compared, focusing on superiorities and deficiencies from practical viewpoint. It is concluded that the eigenelement methods with smooth shape functions are more suitable for the analysis of macro behaviors such as lower order frequencies, and the eigenelement methods with piecewise shape functions are suitable for the analysis of both macro and micro behaviors.     

Stability of relative equilibria of the full spacecraft dynamics around an asteroid with orbit–attitude coupling

The full dynamics of spacecraft around an asteroid, in which the spacecraft is considered as a rigid body and the gravitational orbit–attitude coupling is taken into account, is of great value and interest in the precise theories of the motion. The spectral stability of the classical relative equilibria of the full spacecraft dynamics around an asteroid is studied with the method of geometric mechanics. The stability conditions are given explicitly based on the characteristic equation of the linear system matrix. It is found that the linearized system decouples into two entirely independent subsystems, which correspond to the motions within and outside the equatorial plane of the asteroid respectively. The system parameters are divided into three groups that describe the traditional stationary orbit stability, the significance of the orbit–attitude coupling and the mass distribution of the spacecraft respectively. The spectral stability of the relative equilibria is investigated numerically with respect to the three groups of system parameters. The relations between the full spacecraft dynamics and the traditional spacecraft dynamics, as well as the effect of the orbit–attitude coupling, are assessed. We find that when the orbit–attitude coupling is strong, the mass distribution of the spacecraft dominates the stability of the relative equilibria; whereas when the orbit–attitude coupling is weak, both the mass distribution and the traditional stationary orbit stability have significant effects on the stability. We also give a criterion to determine whether the orbit–attitude coupling needs to be considered.     

加筋壁板大开口结构稳定性分析及试验验证

为了研究加筋壁板大开口结构的压缩承载极限问题,规划了两组具有不同设计参数的试验件进行了静力试验,并同时采用了线性特征值法以及非线性的弧长法对其压缩极限进行了对比分析。在采用弧长法分析时,引入了模态扰动技术,而且考虑了材料的弹塑性性质。计算结果与试验的对比表明:针对复杂结构稳定性问题,屈曲特征值法具有较大局限性,而结合模态扰动的弧长法对这种复杂的加筋壁板类结构压缩极限的分析精度较好。通过分析给出了加筋壁板大开口结构设计的一些建议。     

A drilling tool design and in situ identification of planetary regolith mechanical parameters

The physical and mechanical properties as well as the heat flux of regolith are critical evidence in the study of planetary origin and evolution. Moreover, the mechanical properties of planetary regolith have great value for guiding future human planetary activities. For planetary subsurface exploration, an inchworm boring robot (IBR) has been proposed to penetrate the regolith, and the mechanical properties of the regolith are expected to be simultaneously investigated during the penetration process using the drilling tool on the IBR. This paper provides a preliminary study of an in situ method for measuring planetary regolith mechanical parameters using a drilling tool on a test bed. A conical-screw drilling tool was designed, and its drilling load characteristics were experimentally analyzed. Based on the drilling tool-regolith interaction model, two identification methods for determining the planetary regolith bearing and shearing parameters are proposed. The bearing and shearing parameters of lunar regolith simulant were successfully determined according to the pressure-sinkage tests and shear tests conducted on the test bed. The effects of the operating parameters on the identification results were also analyzed. The results indicate a feasible scheme for future planetary subsurface exploration.     

固体火箭发动机专用ICT机械扫描系统

以成熟的组合精密镗床为本体, 研制了固体发动机专用ＩＣＴ机械扫描系统。采用４５０ ｋＶ Ｘ射线源, 设计了准直器系统、探测器系统、机械扫描系统（传动控制系统、夹具及同步台）, 实测证明扫描系统符合精度要求     

F12/环氧复合材料力学性能研究

测定了Ｆ１２／环氧复合材料的基本力学性能,并比较了Ｆ１２纤维在单向板、强力环及薄壁容器中的纤维强度转化率。实验结果表明,Ｆ１２／环氧单向复合材料与其ＮＯＬ环的拉伸强度相近,而薄壁容器中的复合强度约为单向拉伸强度的６０％,但三种复合材料的纤维强度转化率相近,约为（７０．１±１．６）％。     

复合材料薄壁梁扭转的高次翘曲理论

利用翘曲连续修正概念导出表示剖面翘曲位移的形函数序列,据此建立单闭室复合材料薄壁梁扭转分析的高次翘曲理论,并结合分层的具体情况,考察分层对复合材料薄壁梁扭转翘曲的影响。算例表明,该高次翘曲理论具有很好的收敛性。     

智能结构动力系统控制器设计和结构优化的综合分析

通过由两个压电作动器控制的空间桁架,将最优控制问题和结构中杆件截面积动态优化相结合,综合分析了二者的混合优化问题.计算结果表明,在结构动态响应特性不变的条件下,结构重量和控制需求均有显著下降.      

基于结构随机跳变系统的反干扰信息处理方法

为了解决在复杂的干扰对抗环境中提高信息处理的准确性问题(例如,对具有多种干扰对抗手段的机动目标的跟踪问题),基于结构随机跳变系统理论提出了一种反干扰信息处理的新方法,该方法针对干扰环境的随机剧烈变化,适时地辨识干扰环境的当前状态,并作出相应的决策来优化和利用系统的资源(例如传感器的优化重组、信息融合算法的转换等),最大限度地降低干扰对信息处理精度的影响.以有效地提高信息优化处理的精确度.在本文中就该方法的性能与其它算法做了仿真比较,其仿真结果证实了该方法的有效性.      

一类非线性系统的变结构控制问题

本文研究了简约型非线性控制系统的变结构控制问题,针对变结构控制切换函数的确定问题进行了深入研究,给出了一类非线性系统切换函数的确定方法。研究结果表明,该方法适用于一类难于或不能可控正则化和线性化的非线性控制系统的综合。最后通过仿真证实了该方法的有效性。