摩擦电喷镀摩擦机理及复合镀层工艺的研究

摩擦电喷镀是一项新发明的金属表面高速电沉积技术,具有高速、优质、低耗等特点.本文利用扫描电镜、X射线衍射、X射线应力测试仪等物理测试手段,首次研究了摩擦对镍镀层组织、结构和力学性能的作用机理.此外,通过对摩擦电喷镀Ni基Al_2O_3复合镀层测试,分析了工艺因素及其对镀层质量的影响,并给出了有参考价值的优化工艺参数.     

复合材料的弹性常数与损伤的直接测试

本文将复合材料细观力学和复合材料微裂纹损伤理论与直接测试方法结合起来,在一次加载条件下直接测得复合材料结构件的弹性常数和损伤变量随外载的变化规律,从而可避免直接测试方法的多次加载的困难。由碳纤维／环氧复合材料圆筒壳的轴压实验的直接测试所得结果比较合理,表明该方法是合理可靠的,特别是在加载条件下直接测得复合材料结构件的损伤发展规律之后,可将复合材料微裂纹损伤理论直接用于工程结构件的动态损伤监测。     

横观各向同性压电材料中的运动螺位错

考虑横观各向同性压电材料中螺位错的亚音速运动问题。应用复变函数方法 ,得到了运动螺位错产生的电弹场的解析解。当螺位错的运动速度为零时 ,其解便退化成由Pak给出的静止螺位错产生的电弹场。     

战场物资无人机配送研究

战场物资无人机配送是未来信息化战争后勤保障发展的重点方向,是适应未来高强度、快节奏战争的重要手段。对国内外配送无人机的应用与战场物资配送保障的情况进行概述,重点讨论了无人机在配送过程中涉及的任务分配问题。提出了未来战场物资无人机配送的一些重点研究方向,包括战场物资无人化保障理论研究、军民融合式战场物资无人机配送研究、战场物资无人机配送过程一体化研究以及传统车辆与无人机联合配送的研究。     

装备研发与制造一体化物资供应支持系统研究

首先分析了研发与制造一体化技术是适应武器装备柔性化制造需求的先进制造技术,然后介绍了装备研发与制造一体化技术的涵义和体系结构,分为以研发为中心的研发与制造一体化技术和以制造为中心的研发与制造一体化技术。最后详细研究了其中的物资供应支持系统及其体系结构。     

剪切变形对夹芯复合材料悬臂箱梁挠度的影响

为了分析剪切变形对夹芯复合材料悬臂箱梁挠度的影响,推导了夹芯复合材料薄壁箱梁的等效弯曲刚度和剪切刚度,将夹芯复合材料悬臂箱梁等效为具有等跨度等刚度的均质箱梁;利用初等梁理论得到了考虑剪切变形的夹芯复合材料悬臂箱梁的挠曲线方程;分析了剪切变形对夹芯复合材料薄壁箱梁挠度的影响,为复合材料薄壁箱梁的设计提供了理论参考.     

提升装备物资采购保障能力的策略设计

装备物资采购关系到装备保障职能的充分发挥和作战效能发挥能力的积累,其采购保障过程涉及极其复杂的技术问题和管理问题。采购保障策略是开展采购和管理项目所确定的思路和实现途径,完善的采购保障策略设计对于重大的装备物资采购项目的成败具有举足轻重的作用。本文从军队装备物资采购的基本内涵与特点入手,结合工作实践和调查研究,从采购信息运用、流程管控、权责修订、法规约束和需求预测等业务管理层面进行分析,阐述了当前装备物资采购的发展现状,提出了提升装备物资采购保障能力的策略设计,以期实现采购组织、流程和系统的整体优化,为装备物资采购改革中相关措施的修订与完善提供新思路和新方法。     

Dynamic parameters of multi-cabin protective structure subjected to low-impact load – Numerical and experimental investigations

The dynamic response of a multi-cabin protective structure subjected to impact load directly affects the protective performance of materials; thus, studying the dynamic response and communication law of wave effect of the load plays an important role in the prediction of protective performance. In this study, the protection experiments of box-structure under air- and/or water-medium are conducted, the dynamic response of the structure subjected to low-impact load is analyzed, and the corresponding numerical simulations are analyzed using the theory of finite element method (FEM). Combined with experimental and FEM simulations, the shock strain distribution, acceleration attenuation, and signal energy in defensive materials are determined. Based on the results, the metal structure exhibits good absorption characteristics for shock vibration. Using the experimental data, we also show that the attenuation of shock wave in water medium should be significantly better than that in air medium, and the protective structure should be designed for a combination of water and air mediums. Meanwhile, the numerical simulation can provide a quantitative analysis process for dynamic analysis of defensive materials.     

Analysis of sliding electric contact characteristics in augmented railgun based on the combination of contact resistance and sliding friction coefficient

The contact resistance between the armature and rails is an important indicator of the contact characteristics in electromagnetic launches. As the contact resistance depends not only on the contact state but also on the contact stress and temperature, there are some limitations in analyzing the contact characteristics using only the contact resistance. In this paper, the contact characteristics of the augmented railgun are analyzed by the combination of contact resistance and sliding friction coefficient. Firstly, the theoretical calculation model of the contact resistance and friction coefficient of the augmented electromagnetic railgun is established. Then the contact resistance and friction coefficient are calculated by the measured values of the muzzle voltage, rail current and armature displacement. Finally, the contact characteristics are analyzed according to the features of the waveforms of the contact resistance and the friction coefficient, and the analysis conclusions are verified by experimental rail images. The results showed that: the aluminum melt film gradually formed on the contact surface reduces the contact resistance and the friction coefficient; the wear and erosion of the armature cause deterioration of the contact state; after the transition, the reliability of the sliding contact between the armature and rails decreases, resulting in an increase in contact resistance.     

Consequence of reinforced SiC particles and post process artificial ageing on microstructure and mechanical properties of friction stir processed AA7075

Friction stir processing and post process artificial ageing was successfully carried out on AA7075 with and without reinforcement of SiC particles producing defect free processed zone with uniform distribution of filler material. Effect of SiC particle reinforcement and artificial ageing times on the microstructural modifications was characterized using optical and electron microscopy, electron backscattered diffraction and X-Ray diffraction. Hardness, impact and wear tests were carried out to investigate mechanical behaviour before and after processing. Reinforcement of SiC particles during FSP and subsequent age hardening treatment brought about nearly twofold increase in hardness and impact toughness values by the combined effect of grain refinement, Zener pinning, dispersion strengthening and precipitation hardening. Significant improvement in wear resistance in terms of wear loss was also observed after processing compared to the reference material AA7075-T6. Fractured surface of post FSP age hardened AA7075 alloy exhibited features of ductile fracture during Charpy impact test.