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.     

基于压差梯度的平流层飞艇艇囊应力计算和仿真

平流层飞艇体积庞大,艇囊表面曲率小,因而蒙皮材料的局部应力集中极易导致飞艇艇囊蒙皮发生过大变形而迅速超压损伤破坏.基于飞艇艇囊内外压力压差梯度载荷条件,建立飞艇艇囊蒙皮受内外压差真实工况下环向与轴向应力的理论计算模型,构建飞艇蒙皮应力分析的Von Mises强度准则.并采用ABAQUS有限元软件非线性仿真艇囊蒙皮分别在超压300,500,800 Pa载荷下的各点环向的Von Mises应力状况.仿真结果与理论模型计算的应力值基本保持一致,飞艇艇囊蒙皮环向Von Mises应力呈现随压差梯度增大而递增的规律,而轴向Von Mises应力大小由环向Von Mises应力、蒙皮局部经纬向曲率共同决定,且两方向的Von Mises应力均与超压载荷大小成正相关关系,为飞艇艇囊蒙皮超压应力评估和强度计算提供基础性研究.     

含炔基有机硅杂化聚合物的合成及热稳定性

采用双乙炔基封端的硅氮烷单体(双(4-乙炔基苯胺基) 二苯基硅烷,M1) 与含不同二甲基硅基
结构单元[—Si( CH3 )2—,—Si( CH3 )2—O—Si( CH3 )2—和—Si( CH3 )2—O—Si( CH3 )2—O—Si( CH3 )2—] 的
双溴苯基封端单体进行Sonogashira 交叉偶联反应,制备出一系列含炔基有机硅杂化聚合物。通过红外( FTIR)
、核磁氢谱(1H-NMR) 和凝胶渗透色谱( GPC) 对聚合物的结构和分子量进行了表征,并采用热重分析
(TGA)对聚合物的热性能进行了研究。结果表明,二甲基硅基结构的引入显著提高聚合物的溶解性,各组聚
合物均展现出良好的热稳定性能,其中引入—Si(CH3)2—结构的聚合物具有相对最好的热稳定性。     

Prediction of shock-layer ultraviolet radiation for hypersonic vehicles in near space

A systemic and validated model was developed to predict ultraviolet spectra features from the shock layer of near-space hypersonic vehicles in the ‘‘solar blind" band region. Computational procedures were performed with 7-species thermal non-equilibrium fluid mechanics, finite rate chemistry, and radiation calculations. The thermal non-equilibrium flow field was calculated with a two-temperature model by the finite volume technique and verified against the bow-shock ultra-violet(BSUV) flight experiments. The absorption coefficient of the mixture gases was evaluated with a line-by-line method and validated through laboratory shock tube measurements. Using the line of sight(LOS) method, radiation was calculated from three BSUV flights at altitudes of 38,53.5 and 71 km. The investigation focused on the level and structure of ultraviolet spectra radiated from a NO band system in wavelengths of 200–400 nm. Results predicted by the current model show qualitative spatial agreement with the measured data. At a velocity of 3.5 km/s(about Mach11), the peak absolute intensity at an altitude of 38 km is two orders of magnitude higher than that at 53.5 km. Under the same flight conditions, the spectra structures have quite a similar distribution at different viewing angles. The present computational model performs well in the prediction of the ultraviolet spectra emitted from the shock layer and will contribute to the investigation and analysis of radiative features of hypersonic vehicles in near space.     

Nutation instability of spinning solid rocket motor spacecraft

The variation of mass,and moment of inertia of a spin-stabilized spacecraft leads to concern about the nutation instability.Here a careful analysis on the nutation instability is performed on a spacecraft propelled by solid rocket booster (SRB).The influences of specific solid propellant designs on transversal angular velocity are discussed.The results show that the typical SRB of End Burn suppresses the non-principal axial angular velocity.On the contrary,the frequently used SRB of Radial Burn could amplify the transversal angular velocity.The nutation instability caused by a design of Radial Burn could be remedied by the addition of End Burn at the same time based on the study of the combination design of both End Burn and Radial Burn.The analysis of the results proposes the design conception of how to control the nutation motion.The method is suitable to resolve the nutation instability of solid rocket motor with complex propellant patterns.     

基于F-P腔的激光频率稳定传递方法

量子传感的发展需要频率高度稳定的激光器为基础,且实现大失谐激光频率稳定通常是提高其精度和灵敏度的关键。针对大失谐激光稳频问题,提出了一种利用法布里-珀罗（F-P）腔传递激光频率稳定性的方法。以饱和吸收稳频法锁定的激光器频率为参考,基于锁相原理,锁定F-P腔长度。利用F-P腔长度这个稳定的参考点,实现目标激光器的频率的精确锁定。实验将目标激光器波长锁定于767.001 nm,失谐频率为150 GHz,锁定后的频率漂移为1 MHz/h。该方法解决了激光大失谐稳频问题,对工程实践和科学研究有重要意义。      

飞行控制律全包线鲁棒稳定性评估

传统的飞行控制律评估方法只能对飞行包线内的离散点进行逐点分析,对不确定性参数也只考虑了上下界,分析过程缺乏完整性和系统性。针对这些不足,研究了基于一种改进遗传算法的分析方法,该方法将评估准则转化为某个适应度函数,通过对适应度函数寻优以找到最坏情况下的不确定参数组合,在其基础上进行评估并给出评估结果或控制律修改意见。仿真结果表明,该方法能连续地研究多个不确定性参数同时摄动时的飞行包线,克服了传统方法的不足。     

发动机气瓶热防护产品绝热性能评定研究

通过批抽检热真空试验,能够评定发动机气瓶热防护产品的绝热性能,由于试验设备和试验工艺过程对产品温升会产生巨大影响,依据绝热材料导热系数测试方法,在试验方法不变的条件下,提出新的试验评定要求:稳态过程中产品温升速率。新的产品测试评定要求,能够客观准确的评定产品的隔热性能,排除设备和工艺过程对评定结果的影响。此评定方法也可用于形状不规则、厚度不一致的整件产品绝热性能评定。