超薄型钢结构防火涂料的研究--防火涂料主要组分用量对防火性能的影响

选用氨基树脂和丙烯酸树脂混合体系为基料,聚磷酸铵、三聚氰胺、季戊四醇为阻燃体系,钛白粉和硅石粉为颜填料,制备超薄型钢结构防火涂料,并研究了基料、阻燃体系、颜填料用量对防火涂料防火性能的影响。研究表明:混合基料树脂占30%(质量分数,下同),其中m(氨基树脂):m(丙烯酸树脂)=3:1;阻燃体系占32%,其中m(聚磷酸铵):m(三聚氰胺):m(季戊四醇)=2:1:1;颜填料占10%时制得的防火涂料防火性能最佳。     

受任意钉载圆孔边径向裂纹分析

 本文利用权函数法求解了孔壁受径向及切向集中力作用的圆孔边径向裂纹的应力强度因子。计算了在磨蚀条件下的圆孔边裂纹的应力强度因子,讨论了销钉与孔壁摩擦力对裂纹扩展寿命的影响。     

含离散源损伤复合材料加筋板的压缩特性

 通过对含有离散源损伤的复合材料加筋板的压缩实验和有限元模拟,研究了离散源损伤的损伤扩展与破坏特性以及对复合材料加筋板剩余强度的影响。 结果表明，复合材料加筋板的离散源损伤用穿透蒙皮切断桁条的切口来模拟是合适的，蒙皮上的穿透切口前端有很高的应变集中，桁条被切断导致加筋板传力路线改变；离散源损伤使复合材料加筋板的压缩强度下降显著，达到60％左右； 基于Hashin失效准则的渐进损伤有限元数值模拟方法，可以有效地模拟含切口加筋板的宏观损伤扩展和破坏过程，计算结果与实验值吻合较好。     

APPLICATION OF DIRECT BTT GUIDANCE LAW BASED ON NONLINEAR INVERSE SYSTEM THEORY TO INTEGRATED FIRE／FLIGHT SYSTEMS（IFFS）

ＡＰＰＬＩＣＡＴＩＯＮ　ＯＦ　ＤＩＲＥＣＴ　ＢＴＴ　ＧＵＩＤＡＮＣＥ　ＬＡＷ　ＢＡＳＥＤ　ＯＮ　ＮＯＮＬＩＮＥＡＲ　ＩＮＶＥＲＳＥ　ＳＹＳＴＥＭ　ＴＨＥＯＲＹ　ＴＯ　ＩＮＴＥＧＲＡＴＥＤ　ＦＩＲＥ／ＦＬＩＧＨＴ　ＳＹＳＴＥＭＳ（ＩＦＦＳ）ＭａＸｉａｏ...     

LY12CZ铝合金干涉螺接件微动损伤防护技术

 本文分析研究LY12CZ铝合金干涉螺接件的微动损伤防护技术。讨论了不同干涉量、表面处理技术、孔的加工方法及防护夹层对其微动损伤及疲劳寿命的影响。应用断口分析的方法研究了其微动损伤区的形貌、裂纹的起始部位及形式。提出了提高LY12CZ干涉螺接件疲劳寿命的方法。     

复合材料飞机结构损伤容限和耐久性设计初探

虽然军机和民机规范对复合材料结构的损伤容限和耐久性均提出了要求,但迄今为止尚无成熟的设计方法可用。本文试图通过对国外经验的归纳总结,并结合自己的研究成果,提出一种切实可行的方法供参考。限于篇幅,本文仅就加筋结构蒙皮遇到的几个问题进行讨论。     

航空装备的完整性

 简述完整性概念在航空装备上的应用情况,提出了航空装备完整性概念,并简介了航空装备的完整性原理,     

远程空空导弹作战体系

探讨实现远程空空导弹作战的有效技术途径.将各种可调用的探测及通讯手段,组成远程目标运动信息获取及导弹制导指令信息传输网,与导弹载机以及导弹共同组成作战体系,实现对远程目标的攻击.提出了远程空空导弹作战体系方案,建立了各个组成的相关数学模型,分析了信息探测、传输、融合误差对作战效果的影响,完成了作战体系的仿真.结果表明该远程空空导弹作战体系方案是有效的.     

7B04-T6铝合金腐蚀疲劳交替寿命预测模型

利用7B04-T6铝合金进行了预腐蚀试验和"腐蚀+疲劳+腐蚀+疲劳+……"交替模式作用下的腐蚀疲劳交替试验.试验结果表明:在腐蚀疲劳交替作用下,试验件寿命比相同腐蚀时间作用下的预腐蚀试验件寿命长.利用试验结果建立了基于损伤力学和非线性损伤累积理论的腐蚀疲劳交替寿命预测模型.提出了利用损伤指数描述腐蚀损伤和疲劳损伤在交替过程中的耦合关系,并分析了损伤指数变化对模型迟滞因子和模型预测精度的影响.通过模型分析,在腐蚀疲劳交替过程中,疲劳加载次数对寿命的影响大于腐蚀时间的影响,并且随着加载次数增加试验件的寿命也增加.      

Unmanned aerial vehicle strike on a flat plate: Tests and numerical simulations

The incursion of Unmanned Aerial Vehicles (UAVs) into airports often occurs due to the popularity of drones, which may lead to a threat to aircraft flight safety. Therefore, estimating the dynamic impact load caused by drone strikes is essential. This paper proposes a test method with high precision and low cost involving launching of a UAV to impact a flat plate specimen by using an air gun. The test results of UAVs impacting flat plates at different impact velocities, such as the UAV damage deformation captured by a high-speed camera and strain vs time dynamic response curves of plates, were obtained and analysed. At the same time, a corresponding numerical simulation was carried out by using the explicit finite element software LS-DYNA. The predicted damage to the UAV and strain on the flat plate during the strike process were compared with the test results. The overall trend of the simulation results is in good agreement with the test results, at least for the first three milliseconds of the event. This shows that the numerical simulation model established in this paper is reasonable. The UAV numerical method established in the present paper can be used to carry out numerical simulations and evaluations of the collision safety of UAVs against large aircraft and high-value ground targets. The results show that the local deformation of the impacted target is uneven due to the distribution of concentrated mass components such as motors, battery, and camera. As the impact velocity of the UAV increases, all parts of the UAV are seriously damaged and basically in a fragmented state, and the battery is greatly deformed. The interaction between the UAV and the flat plate specimen is approximately 2.7 ms, and the UAV numerical simulation model established in this paper can well simulate the real UAV impact process.