外翼上壁板根部连接形式对飞机承载能力的影响研究

在飞机结构设计中,外翼上壁板根部连接处结构形式对飞机的传力、变形、承载能力具有重要影响.通过对3种不同形式的上壁板根部连接方案进行压缩试验,研究各方案的承载能力、破坏方式.通过三维有限元方法,计算了连接部位的主要螺钉所分配的载荷,研究了长桁根部斜角对结构屈服载荷的影响,得到了最优的选型方案.     

Geometric error analysis of an over-constrained parallel tracking mechanism using the screw theory

This paper deals with geometric error modeling and sensitivity analysis of an overconstrained parallel tracking mechanism. The main contribution is the consideration of overconstrained features that are usually ignored in previous research. The reciprocal property between a motion and a force is applied to tackle this problem in the framework of the screw theory. First of all, a nominal kinematic model of the parallel tracking mechanism is formulated. On this basis, the actual twist of the moving platform is computed through the superposition of the joint twist and geometric errors. The actuation and constrained wrenches of each limb are applied to exclude the joint displacement. After eliminating repeated errors brought by the multiplication of wrenches, a geometric error model of the parallel tracking mechanism is built. Furthermore,two sensitivity indices are defined to select essential geometric errors for future kinematic calibration. Finally, the geometric error model with minimum geometric errors is verified by simulation with SolidWorks software. Two typical poses of the parallel tracking mechanism are selected, and the differences between simulation and calculation results are very small. The results confirm the correctness and accuracy of the geometric error modeling method for over-constrained parallel mechanisms.     

基于ANSYS Workbench的行星滚柱丝杠动态特性分析

通过Pro/Engineer建立行星滚柱丝杠三维模型，基于ANSYS Workbench有限元分析技术进行模态与谐响应分析，得到前六阶固有频率与各阶模态振型，确定共振频率，掌握对应频率下的位移峰值响应，并研究螺母处于不同工作位置时对固有频率的影响，为基于行星滚柱丝杠传动的舵系统抗振设计提供数据支撑。     

一种液体火箭发动机试验台螺纹拧紧力矩量化控制方法

针对液体火箭发动机试验台工艺装配可靠性提升的需求,提出一种螺纹拧紧力矩量化控制方法。利用非试验和试验环境的力矩值统计与分析,确定液体火箭发动机试验台螺纹拧紧力矩值区间;通过拧紧力矩强度理论计算,验证力矩值区间的合理性;结合试验台螺纹空间位置的具体特点,确定适用不同空间位置的力矩量化控制方法和流程,并在试验中进行了应用。应用结果表明,本文提出的方法可有效提高发动机试验工艺的可靠性。     

基于镁合金基体的螺纹连接承载性能研究

利用螺纹扭拉试验原理，针对航天用铸造镁合金螺纹连接问题，进行了螺纹紧固连接的量化研究。通过探究镁合金螺纹抗扭强度、扭拉关系和轴向承载能力，系统性的给出了镁合金螺纹的基本性能指标，对工程应用具有指导意义。     

基于螺旋理论的环形桁架式可展天线构型综合

基于螺旋理论针对环形桁架式可展天线机构的构型综合问题进行研究，首先概述基于螺旋理论的约束综合法，然后分析环形桁架可展天线机构的收展原理，将环形桁架机构分为上下环形边两部分，通过综合环形边机构并连接上下环形边便可得到环形桁架机构；采用移动副(P)来描述各个节点花盘的运动特性，通过基于螺旋理论的约束综合法针对环形边支链机构进行分析与综合，得到了16种约束支链机构，通过分析与优选得到了两种约束支链机构；采用综合得到的约束支链机构组合得到了环形边链路机构并通过连接组合与推演得到了四种环形桁架可展开机构；最后针对综合得到的四种环形桁架机构在Solidworks软件中进行了三维建模与运动仿真，校验了各机构的可展性。本文的研究为可展天线机构的构型综合提供了一种新思路，综合得到的几种环形桁架机构在空间可展开天线领域具有较好的应用前景。     

接头螺纹咬死失效原因分析

管路接头在拆除时发生螺纹失效,本文对失效螺纹结构件形貌观察与测量,并对其材质进行硬度检验、金相分析。结果表明,管路接头螺纹发生了咬死,属损坏程度最严重的一类黏着磨损。依据黏着磨损发生的机理,结合螺纹连接结构的装配原理,最终确定选用同一种材料作为摩擦副是导致接头螺纹发生黏着磨损的内因;柱塞接头与螺纹接头间隙过小,导致安装过程中接头螺纹的螺纹齿形受损,产生多余物堆积,造成外套螺母向一侧偏斜是造成此次螺纹副发生咬死的主要原因。     

月壤剖面锥型螺旋刃成孔钻头设计

针对月壤剖面钻进成孔探测需求,提出一种锥型螺旋刃成孔钻头,建立其钻进排屑性能的理论模型,并以此开展钻头结构参数的优化设计。在此基础上,分析螺旋刃切削姿态及其切削参数,基于直线刃平面切削理论建立锥型螺旋刃成孔钻头钻进切削负载预估模型,开展锥型螺旋刃成孔钻头模拟月壤剖面钻进负载特性试验验证。研究结果表明,相比于直线刃钻头,锥型螺旋刃成孔钻头的钻进排屑性能更优,而且钻进切削负载模型与试验结果具有较好的吻合度。研究成果对我国拟实施的月面钻取采样工程具有重要的借鉴价值。     

Unsteady Flow and Pressure Pulsations in a ModelAxial-Vortex Stage Inducer

In consideration of improving cavitation capacity of centrifugal pump to inhibit pressure pulsations, vibrations and dynamic loads in flow passing areas, alleviating damages of reusable liquid rocket engine turbo-pumps caused by cavitation erosion and satisfying the requirements of high rotation speed, low inlet pressure, small sizes and light weight, three dimensional simulations of unsteady pressure pulsation and cavitation capacity are carried out to a single screw inducer and an inducer with axial-vortex stage utilizing CFD methods. The results show that compared with single screw inducer, inducer with axial-vortex stage has 25% higher cavitation coefficient, 30% higher initial cavitation coefficient and lower pressure pulsation of blade passing frequency in the outlet of inducer, which all prove that cavitation capacity is obviously ameliorated.     

Design and analysis of truss deployable antenna mechanism based on a novel symmetric hexagonal profile division method

As the deployment, supporting, and stability mechanisms of satellite antennas, space-deployable mechanisms play a key role in the field of aerospace. In order to design truss deployable antenna supporting mechanisms with large folding rate, high accuracy, easy deployment and strong stability, aiming at the geometric division of the parabolic reflector, a novel method based on symmetric hexagonal division and its corresponding modular truss deployable antenna mechanism is proposed, and the original method based on asymmetric triangular division and its corresponding mechanisms are presented for comparative analysis. Then, the screw theory is employed to analyze the mobility of different mechanisms. Furthermore, the improved three-dimensional mesh method is used to divide the reflector surface of a large parabolic antenna designed by the two different methods, and the profile accuracy and the type of links are taken as the evaluation indexes to quantitatively analyze the division results. Finally, a three-dimensional model of the modular deployable mechanism based on the symmetric hexagonal design is developed, and the deployable mechanisms with different configurations based on the two design methods are compared and analyzed from the mechanical perspective. The research results provide a good theoretical reference for the design of deployable truss antenna mechanisms and their application in the aerospace field.