水冲压发动机的热力循环性能预示

针对采用二次进水机制的水冲压发动机,基于特殊的工作方式初步建立了相应的热力循环模型,进而在不同的发动机工况下分析了循环热效率性能。选定水反应金属燃料基础配方为Mg/AP/HTPB的混合物,在不同组分配方条件下,相应发动机热力循环效率随各影响参数的变化规律一致,均随燃烧室压强和水反应金属燃料中金属含量的增加而呈增加趋势,相反,水燃比的增加会引起热效率的降低。特别地,给定一合理水燃比3.0,保持燃烧室压强和航行器航深分别为2.5 MPa和10 m,50%和60%镁含量的水反应金属燃料对应发动机的循环热效率分别为37.78%和44.38%,初步验证了基于联合循环的水冲压发动机良好的循环性能。     

低功率激光-TIG电弧复合焊接不锈钢熔深研究

建立了一套低功率YAG脉冲激光-TIG电弧复合热源焊接系统,并用本系统对不锈钢1Cr18Ni9Ti进行焊接.研究了3种热源作用下不锈钢的焊缝熔深.通过引入焊缝有效热输入概念,对复合热源影响熔深的机理进行了分析.     

基于红外热像技术的涡轮叶片损伤评价研究进展

主动红外热像技术作为一种新型无损检测手段,具有高效率、无污染、易操作等特点,适合用于材料表面和近表面缺陷检测,因此在叶片类薄壁零件损伤评价方面有一定优势。当前基于主动红外热像无损检测技术的高温涡轮叶片损伤评价研究主要集中于热障涂层厚度检测、涂层脱粘检测、涂层界面处热生长氧化物检测以及叶片基体疲劳裂纹检测4个方面。但现有研究仍然面临热激励理论不完善、红外热像仪识别精度不够高以及热图处理方法有待改进等主要问题和困难。随着这些理论问题和技术困难的解决,主动红外热像技术呈现出人工识别缺陷向自动识别发展、定性检测向定量检测发展的趋势。总体而言,该技术未来在涡轮叶片损伤评价方面具有较大的应用潜力。     

毫秒脉冲等离子体激励改善飞翼的气动性能实验

在来流速度为30m/s时,进行了毫秒脉冲介质阻挡放电等离子体激励改善飞翼气动性能的风洞实验.等离子体激励器布置在飞翼前缘,峰峰值电压为9.5kV时,放电的脉冲能量在0.1mJ/cm量级.通过六分量测力天平测力研究了脉冲激励频率和占空比对升/阻力系数、升阻比和俯仰力矩系数的作用效果.结果表明:等离子体激励可以有效改善飞翼大攻角气动特性;在最佳无量纲脉冲激励频率F+≈1时,临界失速迎角由14°提高到17°,最大升力系数提高10%;占空比对流动控制效果影响较大,减小占空比可以降低能耗,实验中最佳占空比为5%;俯仰力矩系数的变化表明施加等离子体激励改善了飞翼纵向静稳定性.      

An equivalent ground thermal test method for single-phase fluid loop space radiator

Thermal vacuum test is widely used for the ground validation of spacecraft thermal control system. However, the conduction and convection can be simulated in normal ground pressure environment completely. By the employment of pumped fluid loops’ thermal control technology on spacecraft, conduction and convection become the main heat transfer behavior between radiator and inside cabin. As long as the heat transfer behavior between radiator and outer space can be equivalently simulated in normal pressure, the thermal vacuum test can be substituted by the normal ground pressure thermal test. In this paper, an equivalent normal pressure thermal test method for the spacecraft single-phase fluid loop radiator is proposed. The heat radiation between radiator and outer space has been equivalently simulated by combination of a group of refrigerators and thermal electrical cooler(TEC) array. By adjusting the heat rejection of each device, the relationship between heat flux and surface temperature of the radiator can be maintained. To verify this method,a validating system has been built up and the experiments have been carried out. The results indicate that the proposed equivalent ground thermal test method can simulate the heat rejection performance of radiator correctly and the temperature error between in-orbit theory value and experiment result of the radiator is less than 0.5 C, except for the equipment startup period. This provides a potential method for the thermal test of space systems especially for extra-large spacecraft which employs single-phase fluid loop radiator as thermal control approach.     

航空表面涂层技术的应用与发展

航空表面涂层技术是航空制造技术的重要组成部分,涂层材料与涂层制造技术创新对提高航空零部件产品性能、降低能源消耗、提升产品可靠性及服役寿命具有重要意义.主要对涉及航空工业领域热障涂层、复合材料表面环境障涂层、高温可磨耗封严涂层及纳米涂层技术的应用现状与研究进展进行了阐述.     

高性能纤维增强树脂基复合材料3D打印及其应用探索

纤维增强树脂基复合材料具有优异的力学性能,能够实现轻质、高性能结构的制造,但传统的成型工艺过程复杂、成本高,难以实现纤维回收利用,限制了纤维增强树脂基复合材料的广泛应用.3D打印技术是一种新兴的零件成形工艺,将3D打印技术应用于纤维增强树脂基复合材料的制造,为实现复合材料低成本、绿色制造提供了可能性.综述了纤维增强树脂基复合材料3D打印技术研究的发展现状,提出了一种高性能连续纤维增强热塑性复合材料3D打印工艺及其回收再制造策略.     

空间相机热平衡试验温度预测方法改进及应用

为实现对航天器热平衡试验平衡温度的预测,建立了热平衡温度预测的方程式,对影响预测结果的各参数进行了分析。首先,由节点网络法推导出平衡温度表达式,介绍了其基于非线性最小二乘法的求解过程,建立了平衡温度的迭代方程;其次,结合大量的试验数据,对影响迭代结果的3个因素进行了统计分析,并最终确定了各因素的合理取值范围;最后,利用温度预测程序对某空间相机热平衡试验中低温工况的平衡温度进行了预测,并与试验结束后的结果进行了对比。结果表明,预测温度与试验数据的误差为±1℃（在3%之内）,满足精度要求,对热平衡温度准确的预测有效的缩短了试验时间,节省试验费用。     

星载可展开天线热振动数值分析

根据非耦合动力学理论及有限元方法,研究分析了星载可展开天线的热振动。利用半正弦波温度冲击模拟热动力荷载,对天线典型节点的热振动位移和应力以及形面精度进行了数值分析。研究表明,急剧变化的温度荷载将导致该天线结构发生热振动,热振动响应明显大于静力学响应。     

A comprehensive numerical model investigating the thermal-dynamic performance of scientific balloon

The increase of balloon applications makes it necessary for a comprehensive understanding of the thermal and dynamic performance of scientific balloons. This paper proposed a novel numerical model to investigate the thermal and dynamic characteristics of scientific balloon in both ascending and floating conditions. The novel model consists of a dynamic model and thermal model, the dynamic model was solved numerically by a computer program developed with Matlab/Simulink to calculate the velocity and trajectory, the thermal model was solved by the Fluent program to find out the balloon film temperature distribution and inner Helium gas velocity and temperature field. These models were verified by comparing the numerical results with experimental data. Then the thermal and dynamic behavior of a scientific balloon in a real environment were simulated and discussed in details.