Numerical simulation of broken pin effects on the flow field and cooling performance of a double-wall cooling configuration

In this paper, the flow characteristics of the double wall structure are presented and the effect of the broken pin size on the cooling performance and flow field of the double wall configuration is investigated. A periodic plate model with seven units is adopted, and there are an impingement hole and a film hole in each unit. Under five blowing ratios, six different sizes of the broken pin are compared, and the double wall configuration without broken pins is taken as the baseline. The results show that if the broken pins height is too small, the cooling effectiveness usually cannot be improved. With the presence of broken pins with a height of more than 0.4, the effectiveness is improved due to the enhancement of reattachment and recirculation of coolant. With the increase of the broken pin height, the cooling effectiveness increases. However, the increase of the diameter does not always improve the cooling performance, since the limiting effect of the wall jet. In this study, Case 6 with the largest broken pin always has the best cooling performance, but also the largest flow resistance. In Case 6 temperature is reduced by almost 15 K compared to the baseline, and more areas have relatively higher cooling effectiveness.     

热射流点火对爆震管内火焰加速及爆震波触发影响的数值研究

为研究热射流点火对爆震管内火焰加速及爆震波触发的影响,运用34步26组分丙烷基元反应进行了二维数值模拟,获得了5种不同的热射流发生器几何结构下的爆震管内火焰传播规律及缓燃向爆震转捩(deflagration to detonation transition,DDT)的时间与距离.结果表明:爆震管中湍流在火焰加速阶段起着重要作用,在爆震波触发阶段激波与火焰相互作用占有主导地位.根据DDT过程的定义,得到DDT时间在1.4~2.0ms之间,同时发现热射流发生器长度为150mm,热射流发生器孔径在8mm时DDT时间最短,热射流发生器长度及孔径对DDT距离的影响不大.      

第2级径向旋流器旋流数对燃烧室点火和贫油熄火性能的影响

双级旋流器是航空发动机燃烧室头部产生回流区所采用的主要形式,研究主要考察第2级径向旋流器的旋流数对点火与燃烧稳定性能的影响,数值模拟结果能够较好地匹配第2级径向旋流器设计参数.试验研究表明:第2级径向旋流器旋流数的改变对燃烧室点火性能无影响;但减小该旋流数会对贫油熄火性能产生明显地改善,旋流卷吸效果会影响回流区火焰稳定.减小第2级径向旋流器旋流数,使下游卷吸量增加,回流区流动与火焰匹配更好,更有利于燃烧稳定性的提高.      

吸附式压气机转子叶片气动优化设计

进行吸附式压气机转子叶片气动设计方法研究.提出通过迭代设计,应用三维流场计算结果提供S₂流面通流计算损失模型,提高了S₂流面流场计算精度;将最优化方法与数值模拟技术相结合,建立吸气与型面耦合的回转面二维叶型优化设计和三维叶片优化设计软件;应用所构建的设计软件,进行吸附式压气机转子设计,数值模拟结果表明:该转子在0.86的叶尖载荷下,设计点总压比为1.631、等熵效率为0.965,实现了高气动性能.      

U型进气管道对某离心压气机性能的影响

采用实验和数值模拟的方法研究了U型管道进气对某离心压气机性能的影响.实验结果显示,相比直管进气,U型管道进气在大流量工况下显著降低了压气机性能,压比、效率的下降量分别可达10%和18%以上.数值分析表明:U型管道进气时,其出口产生静压和总压畸变;压气机下游蜗壳因几何周向不均而存在相应的压力畸变,该畸变沿叶轮槽道向上游传播的过程中与进气畸变发生耦合.这种耦合作用改变了叶轮进口的流场结构,使叶轮槽道流量分布发生变化,叶轮对应畸变区域的熵值增加;同时还改变了叶片表面静压的分布形式,使整个叶轮主叶片的平均载荷增大约8%.      

浮升混合飞艇气动性能及总体参数分析

为了兼顾飞艇的气动性能和浮升特性,充分发挥二者的优势,并增强可控性,提出了一种基于NACA高升力翼型的组合嚢体式混合飞艇气动布局.采用计算流体力学(CFD)方法建立混合飞艇FLUENT计算模型,数值模拟了它在不同速度和迎角下的升阻特性、纵向静稳定性及浮升特性,并进行了总体性能评估,最后将其与常规飞艇进行了对比.结果表明:该组合嚢体飞艇布局具有较好的气动性能和效率,相同条件下提供的动升力为常规飞艇的3倍;当飞行速度大于26 m/s时,混合飞艇总升力效率开始大于常规飞艇,能够提供更好的浮升特性.此外,相同设计载荷下混合飞艇的外形尺寸更小,有利于增加有效载荷,可为低空大型混合飞艇的研发提供参考.      

量子点与TiO2电极参数对光阳极电子寿命及性能影响

通过对P25Ti O2光阳极薄膜厚度、敏化的量子点种类及量子点敏化方法研究,探讨了使用连续离子层吸附反应法的敏化方法(SILAR)时,P25Ti O2薄膜厚度与光阳极电子寿命的关系,以及量子点种类、共敏化工艺对光阳极光电性能的影响.采用电化学阻抗(EIS)、开路电压衰减(OCVD)及紫外-可见吸收方法,对影响光阳极光电性能的Ti O2薄膜厚度、量子点种类及共敏化工艺因素进行测试分析.实验结果表明:当光阳极薄膜厚度为12μm时,电子复合几率最小,光阳极的电子寿命相对最长;采用连续离子层吸附反应法(SILAR)对多种量子点共敏化的光阳极(Ti O2/Cd S/Cd Se/Zn S)与单一量子点敏化的光阳极(Ti O2/Cd S)相比,短路电流提高了34%,光转换效率提高了42%;合适的共敏化工艺也有助于提高光阳极的电子寿命、光谱吸收范围和吸收强度.     

可重复使用飞行器的保性能姿态跟踪控制方法

针对可重复使用飞行器再入姿态跟踪控制问题,在考虑执行器饱和、气动参数摄动和外部扰动的情况下,提出了一种保性能姿态跟踪控制方案。通过构造预设性能函数,使姿态跟踪误差在预先设置的包络内演化,保证了系统的瞬态和稳态性能;其次,借助于高增益扩张状态观测器解决了气动参数摄动和外部扰动的问题;之后,基于反步控制框架,设计了一种低复杂度的输出反馈扰动补偿控制方法,保证跟踪误差的收敛性。与已有方法相比,所设计的方法不包含一些复杂的非线性动力学近似技术,如神经网络等,降低了参数调节的复杂性,且无需对虚拟控制律重复微分,避免了"微分爆炸"问题。同时,Lyapunov稳定性分析表明,该方法能够保证误差变量的预期收敛以及其他闭环系统信号的有界性。最后,通过对比仿真验证了所提方法的有效性及可行性。     

背壁5-II材料高温热物理性能及微结构特征

研究了背壁5-II材料的密度、失重率和孔隙率随温度的变化规律,测试了温度对比定压热容、热导率的影响,研究了不同温度下和发动机长时间热试车下5-II材料的微结构特征。结果表明,5-II材料密度随温度升高而降低,热解后密度降至1.28 g/cm3,开孔率在30%左右;比定压热容随温度升高而增大,热导率随温度缓慢降低;随温度升高,其微结构特征表现为孔隙的大量增加和贯通,密度和孔隙率可作为固体发动机背壁热解失效的主要参量。     

Prescribed fast tracking control for flexible air-breathing hypersonic vehicles: An event-triggered case

In this paper, a prescribed fast tracking control scheme is proposed for Flexible Air-breathing Hypersonic Vehicles (FAHV) subject to lumped disturbances and limited resources. To maintain tracking errors of velocity and altitude converge to a predefined region with a prescribed time and release the transient intense fluctuations encountered in classical Prescribed Performance Control (PPC) using a fast decaying rate, a tracking differentiator-based PPC is presented, where the reaching time and the maximum time differentiation of preselected envelopes can be regulated as a prior via fixing an acceleration factor, so that a guaranteed fast convergence speed can be realized with reduced oscillations. Besides, to avoid the excessive occupation of limited resources (energy and communication) and guarantee a remarkable tracking accuracy, switching event-triggered mechanisms are constructed for FAHV control realization, which provide a promising way to pursue a desired level of tracking performance with a low energy consumption. Subsequently, Uncertainty and Disturbance Estimators (UDE) and Sigmoid function-based Tracking Differentiators (STD) are employed to provide disturbance estimation and reference derivation with a low computational complexity. Finally, robust control laws are designed to compensate for the sampling error induced by event-triggered conditions, meanwhile Zeno phenomena can be effectively eliminated. The simulation results and comparisons validate the effectiveness of the proposed scheme.