布泽曼双翼及其壅塞问题研究

为了降低超音速飞行时产生的波阻,通过斜激波基本公式建立了设计马赫数为2的布泽曼双翼翼型,借助CFD软件计算其升阻特性,并与菱形单翼翼型作对比,同时分析了在非设计条件下布泽曼双翼翼型的壅塞问题.结果表明,布泽曼双翼在设计马赫数下,其波阻较传统菱形单翼降低90％,壅塞问题也得到很好地解决.     

潜入喷管背部容腔对点火初期压强振荡影响的数值研究

为深入了解点火初期药柱表面的压强振荡情况,采用计算流体力学软件FLUENT对固体火箭发动机喷管堵盖打开前的点火增压过程进行了轴对称数值计算,探讨了潜入喷管背部容腔对压强振荡的影响.计算结果表明,发动机头部和背部容腔内压强振荡最为剧烈,压强峰值和升压梯度峰值随容腔体积的增加而递减.结论可为药柱裂纹的扩展研究及固体火箭发动...     

民用飞机起落架缓冲器选型与对比分析研究

以民用飞机前起落架和主起落架为研究对象,首先运用Delphi和SQLServer开发了民用飞机缓冲器参数设计程序,计算了前起落架采用单腔定油孔型式和单腔变油孔型式、主起落架采用单腔定油孔型式和双腔定油孔型式的缓冲器的设计参数;然后基于ADAMS/Aircraft模块分别建立了前起落架和主起落架的虚拟样机,并进行落震仿真分析,仿真结果符合要求;最后通过仿真结果进行起落架缓冲器不同型式的对比分析。研究结果表明：单腔变油孔型式较单腔定油孔型式提高了缓冲器的缓冲效率、双腔定油孔型式较单腔定油孔型式在大的下沉速度下降低了缓冲器的过载。     

高效弯掠对转桨扇流动特点与桨距调节规律

采用数值计算的方法分析了高亚声速来流条件下弯掠对转桨扇的流动特点,开展了不同自由来流马赫数下的高效对转桨扇桨距调节规律的研究。研究表明：在弯掠桨扇的内部流场,从约30%相对叶高位置处开始形成明显激波结构,但当弯掠桨扇通道内峰值马赫数在1.2及以下时激波强度相对较弱,流动损失在可接受范围。由于桨距角对桨扇的推进效率影响显著,研究提出了可行有效的对转桨扇桨距调节方法,数值计算表明桨扇的推进效率均在75%以上。数值仿真预测的各马赫数下桨扇的推力值表明前叶推力对马赫数的变化更加敏感。     

绕跨声速三角翼的激波/涡干扰流场数值模拟

 在绕三角翼的跨声速流动中,随着迎角的增加,三角翼上的涡破裂位置会出现突然前移的现象。针对这一与亚声速下不同的流动现象,采用带曲率修正的Spalart-Allmaras(SAR)湍流模型,求解定常雷诺平均Navier-Stokes(RANS)方程,对不同迎角下绕65°后掠尖前缘三角翼的跨声速流动进行数值模拟,并在此基础上,采用基于SAR湍流模型的脱体涡模拟(DES)方法,对由激波干扰导致的前缘涡破裂位置的运动规律进行了初步探讨。模拟结果与试验结果对比表明:SAR湍流模型能准确地模拟出三角翼上的激波系统和旋涡结构,并能准确模拟出由于激波干扰导致的涡破裂位置突然前移的现象。此外,对涡破裂后流场的非定常数值研究发现,支架前端正激波的干扰作用使得涡破裂位置向下游移动比较突然,而向上游移动则相对缓慢。     

基于壁面压力分布的二元高超声速弯曲激波压缩进气道反设计与优化方法

为进一步提高高超声速进气道的性能,发展了通过指定压力分布规律来反设计整个二元进气道的方法,实现了气动参数可控的进气道内外压缩一体化设计,建立了基于Isight软件的进气道自动化设计分析和优化平台。初步的研究表明,使用此设计方法,能够得到综合性能优秀的进气道设计方案,该方案在来流马赫数6下喉道总压恢复系数为0.68,在来流马赫数4时流量系数达0.77。      

激波风洞流场密度测量的聚焦纹影技术

在激波风洞试验中发展了聚焦纹影显示技术,对流场的密度进行了定量测量。聚焦纹影显示具有对流场区域聚焦显示的特点,可获得流场某个聚焦测试区域的密度变化信息。依据聚焦纹影成像原理建立了密度计算数学模型,对试验中获得的带窗口模型流场聚焦纹影图像与试验前获得的流场图像灰度变化处理后,得到了流场聚焦区域的密度定量值。试验测量密度值与数值计算结果进行了比较,结果表明试验获得的密度值变化规律与数值模拟吻合较好,证实了利用聚焦纹影技术开展流场密度测量是可行的。     

Interplanetary Physics Research in China During 2004 - 2005

This brief report summarized the latest advances of the interplanetary physics research in China during the period of 2004-2005, made independently by Chinese space physicists and through international collaboration. The report covers all aspects of the interplanetary physics, including theoretical studies, numerical simulation and data analysis.     

Cosmic rays in the dynamic heliosheath

Cosmic ray modulation in the outer heliosphere is discussed from a modeling perspective. Emphasis is on the transport and acceleration of these particles at and beyond the solar wind termination shock in the inner heliosheath region and how this changes over a solar cycle. We will show that by using numerical models, and by comparing results to spacecraft observations, much can be learned about the dependence of cosmic ray modulation on solar cycle changes in the solar wind and heliospheric magnetic field. While the first determines the heliospheric geometry and shock structure, the latter results in a time-dependence of the transport coefficients. Depending on energy, both these effects contribute to cosmic ray intensities in the inner heliosheath changing over a solar cycle.     

Flow field and pressure loss analysis of junction and its structure optimization of aircraft hydraulic pipe system

The flow field in junction is complicated due to the ripple property of oil flow velocity and different frequencies of two pumps in aircraft. In this study, the flow fields of T-junction and Y-junction were analyzed using shear stress transport (SST) model in ANSYS/CFX software. The simulation results identified the variation rule of velocity peak in T-junction with different frequencies and phase-differences, meanwhile, the eddy and velocity shock existed in the corner of the T-junction, and the limit working state was obtained. Although the eddy disappeared in Y-junction, the velocity shock and pressure loss were still too big. To address these faults, an arc-junction was designed. Based on the flow fields of arc-junction, the eddy in the junction corner disappeared and the maximum of velocity peak declined compared to T-and Y-junction. Additionally, 8 series of arc-junction with different radiuses were tested to get the variation rule of velocity peak. Through the computation of the pressure loss of three junctions, the arc-junction had a lowest loss value, and its pressure loss reached the minimum value when the curvature radius is 35.42 mm, meanwhile, the velocity shock has decreased in a low phase.