共查询到20条相似文献,搜索用时 346 毫秒
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某低成本小型固体运载器采用侧喷流和栅格舵联合进行姿态控制。针对该布局,设计引入闭环姿态控制的一、二级级间冷分离方案。在描述级间分离过程的基础上,建立了分离运动学与动力学模型,解锁与分离冲量装置模型,气动力模型以及分离姿态控制律模型,讨论了碰撞判断条件,通过Monte Carlo仿真验证了参数不确定条件下分离姿态控制律设计对于避免碰撞和减小上面级初始姿态偏差的有效性。结果表明所设计的分离方案在充分发挥冷分离优势的同时能够弥补由冷分离时间长引起的上面级初始姿态偏差,能够有效避免级间碰撞。为该运载器的级间分离方案提供了一种可能的选择。 相似文献
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基于水下应用栅格翼动态展开过程动力学模型,根据展开特征角度定常水动力方法,拟合获得展开全程受到的流体力矩,并引入考虑相对速度影响的修正因子,形成水下应用栅格翼动态展开过程参数工程预示方法,以典型展开时序点航行体运动参数为设计输入,对栅格翼展开过程运动参数进行预示。通过与水下应用栅格翼非定常流场仿真计算数据以及水下航行体弹射试验数据对比,验证了上述预示方法的正确性及工程适用性,为水下应用栅格翼方案设计的优化及展开不同步性分析提供设计参考。 相似文献
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《防务技术》2019,15(5):680-689
A launching system with novel structure using optimization method is investigated to improve the muzzle velocity of guns in this article. This system has two tandem chambers of which the front one is ignited first and the other is ignited after a while. The launching process of this novel system is modelled and a series of different schemes are simulated, to discover the interior ballistic performance of this novel launching system. In order to obtain the optimal loading conditions, an optimization model combined with the combustion model is established. The optimal schemes can improve the muzzle velocity by 20.6% without changing the parameters of barrel. It means that this novel launch system could improve the interior ballistics performance significantly and it still has considerable potential to be ameliorated. 相似文献
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利用直线电机实现无人机在短距离内可控地加速起飞已是固定翼无人机弹射起飞一种新的发展方向。为了使飞机分离后弹射台能在较短距离里完成制动,提出了直线电机弹射轨道末段定子实铁心涡流制动、运用Halbach永磁体阵列的涡流制动和橡胶阻尼制动等三种方式的综合方案,并分别对它们进行了分析计算。当弹射台的速度大于10m/s时,定子实铁心产生的涡流制动效果明显,当弹射台的速度低于3m/s时,定子实铁心涡流制动产生的制动力将迅速下降。Halbach永磁体阵列的涡流制动方式在飞机分离点开始实施,可以增加30%以上的制动效果。通过模型分析和碰撞试验,橡胶阻尼制动作为最后一级制动方式,能够有效吸收能量,实现在较短距离里的制动。 相似文献
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针对垂线偏差对弹道落点精度的影响,结合弹道飞行器质点动力学模型,系统分析了垂线偏差对发射坐标系、初始参数、飞行过程中受力、程序角控制基准、地心坐标系弹道参数等的影响机理,并建立了相应的数学模型。进一步,基于给定的弹道落点偏差计算方法,以某飞行弹道为例,定量给出了不同发射点大地纬度、不同发射方位角下垂线偏差引起的落点偏差。本文研究工作对提高弹道飞行器落点精度具有重要参考意义。 相似文献
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《防务技术》2022,18(11):2065-2073
Electromagnetic coil launch is an important branch of electromagnetic launch (EML) technology, which is suitable for launching anti-torpedo torpedo (ATT). This paper focuses on the EML parameters and the interception probability of the EML two ATTs salvo. Based on the launching model of a multi-stage coil launcher, the trajectory model of the ATT and the attacking torpedo, a calculation method for the EML two ATTs salvo parameters is proposed, with the conditions of capture and interception given reasonably. An adaptive particle swarm optimization (APSO) algorithm is proposed to calculate the optimal launching parameters, by designing the adaptive inertia weight and time-varying study factors. According to the analysis of the simulation with Monte Carlo method, EML will improve the interception probability effectively, and the interception probability is affected by the launching range. The results demonstrate good performance of the proposed APSO in calculating EML parameters for the two ATTs salvo in certain combat situation. Implications of these results are particular regarding the command and decision in the anti-torpedo combat. 相似文献
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提出只更新飞行剖面参数的航程更新方法及相应的RLV再入标准轨道制导规律;结合轨道在线生成与跟踪技术,采用Runge-Kutta-Fehlberg自适应变步长轨道快速预报方法,研究了RLV再入轨道预测制导。进一步对两种制导方法进行了比较分析研究,研究认为标准轨道制导与轨道预测制导都是可行的RLV再入制导方案,其有机结合是未来可重复使用跨大气层飞行器再入制导的发展趋势。 相似文献
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针对垂直发射飞航式火箭助飞鱼雷,分析其在空中各阶段的受力和运动情况,建立相应的空中弹道模型,并对模型进行了仿真,分析了火箭助飞鱼雷总质量、助推发动机推力、巡航发动机推力变化对飞行时间的影响。仿真结果表明,所建立的模型符合火控弹道模型要求,而且文中所建立的模型简明直观,可用于垂直发射飞航式火箭助飞鱼雷的火控解算。 相似文献
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现代战争日趋透明给导弹发射车战场生存带来了严峻挑战。围绕发射车的抗毁伤能力分析和评估技术,分析了发射车面临的毁伤威胁和毁伤作用机理,从抗毁伤能力评估应用的角度阐述了冲击波、动能、热和电磁四种毁伤类型的研究现状,提出了不同毁伤类型在抗毁伤能力分析和评估中的应用方向;基于易损性分析空间理论,总结了装备易损性分析的发展历程,认为从物理空间到性能空间的逻辑传递关系是现阶段发射车易损性分析的核心所在,并从物理判据、性能判据和分级标准介绍了易损性判据的研究动态,提出了发射车易损性判据的关键;明确阐述了发射车抗毁伤能力的研究概念和分析方法面临的主要问题,研究结论可以为导弹发射车抗毁伤能力分析和评估相关研究提供参考。 相似文献
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This paper develops a modular modeling and efficient formulation of launch dynamics with marching fire (LDMF) using a mixed formulation of the transfer matrix method for multibody systems (MSTMM) and Newton-Euler formulation. Taking a ground-borne multiple launch rocket systems (MLRS), the focus is on the launching subsystem comprising the rocket, flexible tube, and tube tail. The launching subsystem is treated as a coupled rigid-flexible multibody system, where the rocket and tube tail are treated as rigid bodies while the flexible tube as a beam with large motion. Firstly, the tube and tube tail can be elegantly handled by the MSTMM, a computationally efficient order-N formulation. Then, the equation of motion of the in-bore rocket with relative kinematics w.r.t. the tube using the Newton-Euler method is derived. Finally, the rocket, tube, and tube tail dynamics are coupled, yielding the equation of motion of the launching subsystem that can be regarded as a building block and further integrated with other subsystems. The deduced dynamics equation of the launching subsystem is not limited to ground-borne MLRS but also fits for tanks, self-propelled artilleries, and other air-borne and naval-borne weapons undergoing large motion. Numerical simulation results of LDMF are given and partially verified by the experiment. 相似文献