用小波变换对机匣处理抑制旋转失速的机理研究

本文利用小波变换对轴流压气机旋转失速时的压力信号进行时频分析。通过Ｍｏｒｌｅｔ连续小波变换,详细分析压气机失稳过程中非定常信号的变化,并研究旋转失速初始扰动信号在处理机匣气室中的局部行为。通过对比实壁机匣与处理机匣的失速初始信号相干波形的结构特性,发现不同机匣结构对相干波形结构中压力脉动信号的不同影响,提出处理机匣抑制旋转失速初始扰动发展的机理。     

交叉剪切混合层中拟序结构的数值研究

采用拟谱方法对时间模式的交叉剪切混合层进行了直接数值模拟。计算结果表明:与平面混合层一样,展向涡的拉伸作用是交叉剪切混合层中流向涡形成的主要机制。当展向剪切强度较大时(如两主流交叉角为40°),与初期展向KelvinHelmholtz相关的单向旋转流向涡在拉伸作用下很快增长起来,并“坍缩”成“肋状”涡。当交叉角为40°时,涡核区存在类似平面混合层中“方块状”涡的流向涡结构,展向涡辫区还存在一组符号相反的流向涡,不过与“肋状”涡对应的涡结构呈扁平状,始终没有“坍缩”。当交叉角为60°时,“肋状”涡非常强,以致完全抑制了平面混合层“对称模式”的发展。当交叉角小到20°时,流向涡结构更接近于对称分布,然而“肋状”涡却没有形成。另外,计算结果还证实:与二维混合层相比,大强度展向剪切的引入能够加强流场的混合,同时,适当增加展向扰动波初始强度和波数也是提高混合效率的有效手段。     

飞机结构件在当量环境谱下加速腐蚀试验和日历寿命估算方法

首次成功地进行了构件在当量环境谱下的加速腐蚀试验,取得了防护层日历有效期和基体腐蚀扩展速率;建立了一套由试验数据估算日历首翻期、日历翻修间隔、日历总寿命的方法和公式;提出了由使用中真实的腐蚀损伤数据来估算日历首翻期的方法;在构件加速腐蚀试验和使用中真实腐蚀损伤数据统计处理的基础上,给出了 HX型机群日历寿命。     

沟槽面湍流边界层近壁区拟序结构实验研究

应用氢气泡流动显示技术,对沟槽面湍流边界层近壁区带条结构进行了研究。通过分析流动显示结果,发现沟槽面的带条比较平坦,低速带条有较好的直线性,说明沟槽限制了流体的横向流动,增强了流动的稳定性。通过统计分析发现沟槽板湍流边界层中无量纲低速带条间距及无量纲高速带条间距均符合对数正态分布。对同种沟槽板而言,两种带条的分布特性无明显差别。沟槽板的平均无量纲低速带条间距比光滑板的要小,最多小30%,且沟槽尺寸对平均无量纲低速带条间距亦有影响。对同一种沟槽板同一位置而言,平均无量纲低速带条间距随离开壁面的无量纲距离的减小而减小,但最可几概率增大,表明沟槽板对近壁流动影响最为强烈。另外,还对低速带条与减阻特性的关系做了初步探讨,得到的沟槽无量纲高度和间距为15～18的沟槽板有较好的减阻效果。     

Statistical study of radio drifting pulsation structures with associated CMEs and other observations

Solar radio burst, especially the fine structures (FSs) and the drifting pulsation structures (DPSs), may be used as an important diagnostics tool to draw the evolution map of the flare loop in the initial phase of solar flares. In this work, 52 radio events were found accompanying with DPSs. They were all observed with the Solar Radio Spectrometers (0.625–7.6 GHz) of China during 1998–2004. Combining the radio observations with LASCO-C2, Goes-8 SXR, H_α, EUV and Trace observations, we analyzed all these events and obtained some statistic conclusions: First, 88% DPSs take place at the initial phase of the radio burst, and their rich spectrum characteristics are helpful to understand the events further. Second, 83% DPSs are associated with CMEs or ejection events, and all the events are accompanied by Goes SXR flare. Third, for CMEs and DPSs, which take the first step, there is no significant predominance of either of them. The relationship between the DPSs and CMEs is still not clear in this study because of the lack of spatial resolution in the centimeter–decimeter band. However, the EIT or Trace ejection happened during the onset/end time of DPSs. They are signatures of the initial phase of CMEs. Two events will be illustrated to explain this.     

空间站充气式下载系统的概念研究

空间站充气式下载系统 (IDS)是在俄罗斯充气式再入与降落技术 (IRDT)基础上发展起来的一种新概念航天回收技术。详细介绍了IDS基本概念和工作原理 ,通过与传统降落伞回收方式的比较 ,总结了该技术的特点。讨论了该技术对结构、轨道、气动力、气动热、热防护层等关键子系统的设计需求。归纳了国外研究现状及发展趋势 ,分析了航天和军事领域的应用前景。     

Design of aircraft structures against threat of bird strikes

In this paper, a method to design bird-strike-resistant aircraft structures is presented and illustrated through examples. The focus is on bird strike experiments and simulations. The explicit finite element software PAM-CRASH is employed to conduct bird strike simulations, and a coupled Smooth Particles Hydrodynamic (SPH) and Finite Element (FE) method is used to simulate the interaction between a bird and a target structure. The SPH method is explained, and an SPH bird model is established. Constitutive models for various structural materials, such as aluminum alloys, composite materials, honeycomb, and foam materials that are used in aircraft structures, are presented, and model parameters are identified by conducting various material tests. Good agreements between simulation results and experimental data suggest that the numerical model is capable of predicting the dynamic responses of various aircraft structures under a bird strike, and numerical simulation can be used as a tool to design bird-strike-resistant aircraft structures.     

Fatigue life research and experimental verification of superalloy thin-walled structures subjected to thermal-acoustic loads

Rapid alternating stress is formed in structure subjected to harsh thermal-acoustic loads, which will affect fatigue performance and reduce fatigue life seriously. First, fatigue experiment of superalloy thin-walled structure was carried out to obtain fatigue damage location and failure time of the experiment specimen, and S-N curves of superalloy thin-walled structure at 723 K were fitted. Then, dynamic response simulation of superalloy thin-walled structure under the same load as experiment was implemented, and fatigue life was estimated based on the fatigue life prediction model which mainly included: improved rain-flow counting method, Morrow average stress model and Miner linear cumulative damage theory. Further, comparisons between simulation solutions and experimental results achieved a consistency, which verified the validity of the Fatigue Life Prediction Model (FLPM). Moreover, taking a rectangle plate as the analysis object, the distributions of Fain-low circulation blocks and damage levels of the structure were discussed respectively. Finally, current research indicates that in pre-buckling the structure is in softened area and fatigue life decreases with the increase of temperature; in post-buckling the structure is in hardened area and fatigue life increases with the increase of temperature within a certain range.     

基于Kriging形函数的线性时变结构模态参数辨识

近年来,对航空航天飞行器随时间变化的动力学特性研究需求越来越迫切。仅输出参数化时域的时变时间序列模型以其结构简约、精度高且跟踪能力强而成为研究热点,尤其是泛函向量时变自回归(FS-VTAR)模型已经得到了广泛应用。然而传统的FS-VTAR模型在保证其辨识优势的同时却需要针对不同时变结构选择合适的基函数形式及较高的基函数阶数,该过程相当复杂且耗时。本文借鉴无网格法中移动最小二乘(MLS)法构造形函数的思想,提出一种基于Kriging形函数的线性时变结构模态参数辨识方法。该方法首先引入自适应于辨识信号的Kriging形函数;再把时变系数在形函数上线性展开,利用最小二乘(LS)法得到形函数的展开系数;最后把时变模型特征方程转换为广义特征值问题提取出模态参数。利用时变刚度系统非平稳振动信号验证该方法,结果表明:基于Kriging形函数的FS-VTAR模型相比于传统的FS-VTAR模型能有效地避免基函数形式的选择和较高的基函数阶数,且精度相当;相比于移动最小二乘法能有效地解决其数值条件问题且具有更高的模态参数辨识精度。     

Active vibration control of piezoelectric bonded smart structures using PID algorithm

Thin-walled structures are sensitive to vibrate under even very small disturbances. In order to design a suitable controller for vibration suppression of thin-walled smart structures, an electro-mechanically coupled finite element(FE) model of smart structures is developed based on first-order shear deformation(FOSD) hypothesis. Considering the vibrations generated by various disturbances, which include free and forced vibrations, a PID control is implemented to damp both the free and forced vibrations. Additionally, an LQR optimal control is applied for comparison.The implemented control strategies are validated by a piezoelectric layered smart plate under various excitations.