充气气囊减速方案的气动设计研究

减速是航天飞行器必须面对的问题。充气气囊减速方案利用柔性编织材料外加涂层方式构成气囊，利用气体发生器快速产生高压气体，集防热、减速和着陆减振功能于一体，重量轻、成本低、适用范围广、可靠性高。设计了满足减速需求的气囊外形，利用数值求解NS方程和工程计算方法进行了气动力的预测和比较分析，利用六自由度动力学模型与气动力的耦合计算，对减速效果进行了计算与分析，并对热环境、温度场、应力、热应力及变形进行了计算，还对分离不确定性进行了研究。地面引导性风洞试验和理论分析表明，充气气囊减速方案具有十分明确的减速效果和优点，可用于未来航天飞行器实现减速飞行目的的技术方案。     

箭体上的凸起物对火箭气动特性的影响

综合大量实验研究结果,本文给出了火箭箭体上的环形凸起物和纵向凸起物对火箭气动特性的影响。其中最主要的是改变滚转力矩的大小和方向。而这正是姿态控制系统设计的重要依据之一。因此,给出凸起物的设计原则,对火箭气动设计有实际意义。     

短螺旋型燃烧室旋流结构及气动边界发展规律数值模拟研究

短螺旋型燃烧室的头部轴线沿发动机周向与发动机轴线偏转一定角度,可以在保证燃烧效率不变的条件下有效缩短燃烧室轴向长度。短螺旋型燃烧室流场的最大特点是旋流流动单侧受限。为了研究头部安装角α变化对燃烧室旋流流动特性的影响,基于数值方法对短螺旋型燃烧室进行了计算分析。结果表明:随着α变化,旋流器下游旋涡依次出现对称环状、马蹄状、环状结构;随着α增加,气动边界逐渐出现并抑制旋流的周向扩张,导致流场出现不同的旋涡结构;不同α下的切向角动量随轴向距离增加而衰减,但α为35°和45°时,气动边界在非受限侧出现并对旋流产生约束,角动量衰减变慢;当α为0°,15°,35°,45°时,燃油液滴依次集中分布在旋流器下游两旋涡边缘、侧壁面和头部端壁、非受限旋涡边缘。本文研究了不同α下的旋涡结构及气动边界沿轴向的演化过程,为短螺旋型燃烧室进一步的设计与优化提供基础。     

Assessment on critical technologies for conceptual design of blended-wing-body civil aircraft

Civil aviation faces great challenges because of its robust projected future growth and potential adverse environmental effects. The classical Tube-And-Wing(TAW) configuration following the Cayley's design principles has been optimized to the architecture's limit, which can hardly satisfy the further requirements on green aviation. By past decades' investigations the BlendedWing-Body(BWB) concept has emerged as a potential solution, which can simultaneously fulfill metrics of noise, emission and fuel burn. The purpose of the present work is to analyze the developments of critical technologies for BWB conceptual design from a historical perspective of technology progress. It was found that the high aerodynamic efficiency of BWB aircraft can be well scaled by the mean aerodynamic chord and wetted aspect ratio, and should be realized with the trade-offs among stability and control and low-speed performance. The structure concepts of non-cylinder pressurized cabin are of high risks on weight prediction and weight penalty. A static stability criterion is recommended and further clear and adequate criteria are required by the evaluations of flying and handling qualities. The difficulties of propulsion and airframe integration are analyzed. The energy to revenue work ratios of well-developed BWB configurations are compared,which are 31.5% and 40% better than that of TAW, using state-of-art engine technology and future engine technology, respectively. Finally, further study aspects are advocated.     

Application of a PCA-DBN-based surrogate model to robust aerodynamic design optimization

An efficient method employing a Principal Component Analysis (PCA)-Deep Belief Network (DBN)-based surrogate model is developed for robust aerodynamic design optimization in this study. In order to reduce the number of design variables for aerodynamic optimizations, the PCA technique is implemented to the geometric parameters obtained by parameterization method. For the purpose of predicting aerodynamic parameters, the DBN model is established with the reduced design variables as input and the aerodynamic parameters as output, and it is trained using the k-step contrastive divergence algorithm. The established PCA-DBN-based surrogate model is validated through predicting lift-to-drag ratios of a set of airfoils, and the results indicate that the PCA-DBN-based surrogate model is reliable and obtains more accurate predictions than three other surrogate models. Then the efficient optimization method is established by embedding the PCA-DBN-based surrogate model into an improved Particle Swarm Optimization (PSO) framework, and applied to the robust aerodynamic design optimizations of Natural Laminar Flow (NLF) airfoil and transonic wing. The optimization results indicate that the PCA-DBN-based surrogate model works very well as a prediction model in the robust optimization processes of both NLF airfoil and transonic wing. By employing the PCA-DBN-based surrogate model, the developed efficient method improves the optimization efficiency obviously.     

基于重叠网格的唇口移动变几何进气道数值模拟研究

吸气式冲压发动机的进气道需要在比较宽广的马赫数范围内工作,而变几何进气道具有良好的气动性能,成为了最佳选择。重叠网格技术是解决存在复杂运动边界流动模拟问题的有效策略,在应用于变几何进气道非定常流动模拟时需要进一步完善。采用发展的重叠网格技术,对变几何平动方式的进气道开展了数值模拟研究。针对存在物面接触重叠网格的挖洞操作在执行时无法取得合理的插值模板问题,引入了虚拟单元赋值方法和“Collar”网格方法,实现了多体相交时重叠网格的计算。为了引入“Collar”型重叠网格,对其算法作了适当修改以适应本论文所建立的洞面优化方法。对平移过程中内收缩变化所造成的对启动过程的影响进行了研究。通过迎着来流方向平移唇口,增大了进气道的内收缩比,导致内压缩段出现边界层分离,分离泡随着唇口的前移而增大,当其移出内压缩段时,原本启动的进气道进入不启动状态,而后移唇口减小了内收缩比,使分离泡减小并向下游移动,辅以边界层排移,可以改善进气道的启动性能。此外,平移速度和振荡频率对启动过程的影响也进行了研究,进气道迟滞效应随平移速度和振荡频率增大而增大。     

遗传算法在机翼气动优化设计中的应用

把最优化方法与机翼的气动力求解相结合,进行跨音速机翼的气动优化设计。采用最优化方法为遗传算法,机翼的气动力由三维欧拉方程的数值解来提供。与基准机翼相比较,优化设计的机翼其气动性能有较大幅度的提高,表明遗传算法在机翼优化设计中的可行性和有效性     

不均匀进气对压缩系统稳定性影响的逐级动态响应模型研究

发展了一种分析进口畸变对多级轴流压气机影响的逐级动态响应模型。采用动态压缩系统模型和动态加载技术,建立了一种压缩系统气动稳定性分析的新方法。应用新的模拟方法对一８级跨声多级压气机进行了详细的数值分析。结果表明,所发展的逐级动态响应模型更合理和可靠。基于流动阻塞,给出了一种更为迅速的压缩系统失稳识别方法。     

分析计算航天飞机气动系数的边界元局部方法

空间运载工具设计阶段为分析比较不同外形高超音速各流动领域的性能,广泛应用局部方法。在其原始形式下,形状函数计算繁复,并限于简单几何外形组成的轴对称体。用边界元局部方法进行形状函数计算,可免去原局部方法面积分的繁复和藉助表格的局限。对STS-1轨道飞行器外形进行计算得到丁形状函数,并根据实验数据确定领域系数。由此计算出飞行器的法向力、轴向力和俯仰力矩系数,计算结果与实验数据相符。     

几何和气动参数对多孔板波涡相互作用影响的研究

本文对以涡声相互作用为基础的通气的多孔板共振腔结构的声学性质进行了一些实验研究和分析。着重于声衬的孔径、腔深、孔板厚度对声衬性能的影响。对实验的结果进行了一些分析,给出了厚板通气声衬声抗的一种算法。对吹气与吸气情况下声衬的性质进行了对比。