梳状电容式微加速度计温度性能优化

零偏温度漂移是影响高精度MEMS加速度计整体性能的关键指标，敏感结构机械零位的温度漂移和电路零位(电容检测电路）的温度漂移是加速度计零偏温度漂移的直接原因。分析了影响加速度计零偏温度系数的3种主要影响因素，提出了某型加速度计伺服电路温度性能测试筛选方法，有效减小了电路零位的温度漂移。采用了全硅表头，同时对表头封装粘接方式进行优化，大幅减小了表头机械零位的温度漂移。经过这些优化措施后，加速度计的温度性能得到了明显改善，零偏温度系数由1.3mg/℃减小到0.5mg/℃，零偏的常温稳定性(1h）达到0.108mg，重复性(6次）达到0.141mg。     

Physical model for acoustic resonance in annular cavity structure

A physical model for acoustic resonance in the annular cavity structure is developed to represent the typical characteristic when acoustic resonance occurs. Firstly, the measurement of sound pressure in the casing and rotor blades vibration is operated in a multistage high pressure compressor. The sharp peak frequency and discrete multi-tone occur in the frequency spectrum of sound pressure in the compressor, and the vibration of the first stage of rotor blades synchronously presents the high amplitude. The frequencies associated with rotor blades vibration can be calculated with rotating sound source theory. It is also confirmed that acoustic resonance occurs in the multistage compressor. With acoustic similarity principle, an annular cavity model is established to simulate the typical characteristics of acoustic resonance in the compressor based on Large Eddy Simulation (LES) and Lighthill acoustic analogy. The coupling relationship between cavity acoustic mode and disc vibration mode shape is expounded when acoustic resonance occurs in the model. And acoustic resonance will be locked in the certain flow rate range. All these characteristics match well with those occur in the multistage high pressure compressor.     

Possible evidence for small-scale wave seeding of equatorial plasma bubbles

The small-scale wave-like structure (SSWS) of F region bottomside plasma density was proposed to be an important seeding for equatorial plasma bubble (EPB) generation, and employed in theoretical simulations of EPBs in recent years. The seeding role of SSWS, however, is waiting to be demonstrated by observation. Here we present two cases of SSWS and EPB observed by the Fuke all-sky airglow imager (19.3°N, 109.1°E; dip latitude 14.3°N). For each case, the results show that two large-scale wave-like structures (LSWSs) initially appeared around sunset in the longitude regions separated by 3–4°, but EPB irregularities were only generated in one of the LSWSs where SSWSs were seen riding on LSWS. For the other LSWS, no SSWS and EPB irregularities were seen. Considering that the two LSWSs were situated closely in longitude where the amplitude of pre-reversal enhancement of background eastward electric field should be similar, the observation that EPB was only generated in the longitude with simultaneous LSWS and SSWS could provide supporting evidence for SSWS seeding of EPB.     

Microstructure,thermophysical property and ablation behavior of high thermal conductivity carbon/carbon composites after heat-treatment

Uni-directional carbon/carbon composites with high thermal conductivity are suitable to supply continuous thermal protection for future reentry vehicles since they could reduce surface temperature and ablation rates simultaneously in harsh environments. In this work, the high thermal conductivity carbon/carbon composites were prepared by chemical vapor infiltration. After heat-treatment, both their open porosity and internal friction increase due to the fiber/matrix thermal expansion mismatch; while their thermal conductive performance become better due to more complete carbon structure. With raising heat-treatment temperature from 1800 °C to 2450 °C, the mass and linear ablation rates of C/C composites with fibers vertical to the oxyacetylene torch for 60 s decrease from 0.66 mg/s and 2.95 μm/s to 0.51 mg/s and 2.05 μm/s respectively. The improved ablation resistance is resulted from the increased thermal conductivity from 282 to 508 W/(m·K) and more carbon fibers exposed to the flame during ablation, which have better oxidation resistance than those of carbon matrix. While such ablation rates become larger for composites with fibers parallel to the flame, from 1.02 mg/s and 3.73 μm/s to 1.28 mg/s and 5.01 μm/s respectively since the ablation occurred more easily through gaps at the fiber/matrix interfaces, which become larger and are always exposed to the flame for this case.     

石英陶瓷与碳纤维增强复合材料间胶接增强的优化工艺

为提高硅橡胶胶黏剂胶接石英陶瓷和碳纤维增强复合材料的强度和耐温性能,研究了胶接面湿热状态、打磨程度、胶层厚度、操作等待时间等工艺参数对胶接强度的影响。在试片正常烘干、打磨的情况下,当胶层厚度为0.4 mm、操作等待时间小于0.5 h时,胶接效果最优,其压缩剪切强度达到了3.06 MPa。探索了底涂剂处理对胶接强度和耐温性能的影响。在温度不高于100℃时,底涂剂A的效果较好。经底涂剂A处理后,胶接试片常温下的强度提高了13.7%,达到3.48 MPa;100℃时的强度提升率达到37.7%。在更高温度下,底涂剂B的效果更为显著。经底涂剂B处理后,胶接试片常温下的强度提升了10.1%,达到3.37 MPa;300℃时的强度提升了44.0%,达到1.57 MPa;200℃时的强度提升率最高,为49.0%。测试结果为高温条件下石英陶瓷胶接结构的胶接工艺优化及其应用提供了参考。     

K8飞机襟翼装配工艺的改进

Ｋ８飞机襟翼装配长期达不到设计要求，成为技术关键。本文从多方面分析了产生问题的原因，并详细介绍了改进方法及其效果。     

三角形截面高柔结构横风向振动的风洞试验研究

本文介绍了正三角形截面高柔结构模型在均匀流场和湍流场中三种迎角下的横风向风振响应风洞试验结果，分析了三角形截面高柔结构的横风向涡激振动现象与驰振危险性，获得了一些数据和结论。     

具有周期性薄膜热源的多层介质非稳态传热数值仿真

为分析具有薄膜热源的多层介质非稳态传热问题,以某型飞机层合电加温风挡为例,构建了一种热流密度-温度边界条件,实现了薄膜热源热流和温度属性向多层介质内外两个方向上的实时传递,再现了薄膜热源温度对临近多层介质表面温度的影响,为具有薄膜热源的多层介质传热问题分析和加温控制规律设计提供了一种可行方法.     

植物细胞响应重力变化的Ca2+信号

重力大小的改变(微重力和超重力)可以对植物的生长发育、生理生化特性、细胞超微结构、基因和蛋白的表达等产生广泛的影响,而Ca~(2+)可能在此过程中起信号物质的作用.重力刺激在植物细胞中引发事件的顺序可能是:重力刺激的感受—细胞膜系统张力改变—膜理化特性改变—膜透性、离子转运、膜连接酶活性等改变—Ca~(2+)信号的产生和转导—新陈代谢变化—生理反应.植物对重力水平变化应激响应的至关重要一步是引起细胞内Ca~(2+)分布区域和浓度的变化,这是将细胞外重力刺激转换为细胞内化学信号的关键步骤.由于机械力敏感的C~(2+)通道的活化和Ca~(2+)-ATPase酶活性受到抑制,重力改变时细胞质中自由Ca~(2+)浓度增加,随后Ca~(2+)作为第二信使介导相关酶活性发生改变,最终引起一连串的生理生化反应.本文探讨了重力变化对植物细胞质内自由Ca~(2+)浓度的影响、Ca~(2+)信号的产生机制.以及Ca~(2+)作为次级信号对细胞生理生化过程调节作用的途径和机制,介绍了常用的Ca~(2+)研究方法,并分析了研究的关键点和难点.     

提高UV-LIGA制备金微细零件的尺寸精度研究(英文)

在众多影响UV-LIGA(Ultra-violet lithography Galvanik abformung)技术制备微细金属零件尺寸精度的因素中,SU-8胶溶胀性是最主要的。通常采用隔离带方法降低SU-8胶的溶胀性,以提高电铸微细零件的尺寸精度。由于贵重金属会沉积到隔离带内,造成了贵重金属的浪费,增加制造成本,因此该方法不适合贵重金属微细零件制造。针对隔离带方法的弊端,提出了半隔离带方法,在保证电铸微细金属零件尺寸精度的前提下,避免了贵重金属的浪费。另外,还采用电解液喷射方法实现了高电流密度电铸,缩短了电铸时间,进一步提高了电铸微细金属零件的尺寸精度。试验结果表明:采用半隔离带方法和高电流密度,可以有效提高金微细零件的尺寸精度,当电流密度提高到0.6A/dm2,金微细零件的尺寸精度可以达到5μm。