气液喷流与超声速凹腔流场的相互作用

为了解凹腔火焰稳定器的工作过程,通过试验和数值仿真手段,对超声速条件下凹腔的流动特性进行了深入细致的研究,探讨了气/液喷流与超声速凹腔流动的相互作用机理。研究结果表明,无喷流时超声速凹腔流场具有五个典型的特征;引入喷流会引入新的流场特征,同时流场结构会发生机理性的变化;气/液喷流对凹腔整体流动特征的影响是一致的;有气体喷流时,不同压降下凹腔流场结构是类似的;而对液体喷流而言,提高喷注压降会增加雾化距离、射流穿透度、喷流厚度,提高来流速度则会使其减小。     

超声速变马赫数风洞流场参数线性变化验证

旋转喷管型面使超声速变马赫数风洞在单次运行过程中可连续调节实验区的马赫数,便于研究飞行器的机动过程、进气道起动过程中的气动问题。在控制喷管型面旋转过程中,流场参数能否线性变化是衡量超声速变马赫数风洞性能的一个重要指标。分析变马赫数风洞实验区流场参数的线性变化规律,利用弹簧光顺的动网格技术建立数值仿真模型,验证喷管位于马赫数3.041~3.215 范围所对应的位置时,实验区流场参数是否满足线性变化规律。结果表明：通过对喷管型面旋转的控制实现了风洞实验区流场参数的线性变化,动态计算结果与预期实验区流场参数线性变化规律吻合良好;在不同加速度的流场参数线性变化过程中,各时刻实验区的平均参数与预期参数之间的偏差均小于0.13%。     

超临界机组末级叶片典型截面的叶型设计

针对超临界机组末级长叶片的设计特点,采用遗传算法和人工神经网络,提出对长叶片典型截面叶型进行分区优化设计思想,并对原型与改型进行了多工况点的数值计算,结果表明,将叶型吸力侧后半段由直线型改为内凹型,能够显著降低超声速叶型在超声速工况范围内的叶型损失。对叶型前缘以及压力侧的局部优化设计能够改善超声速叶型在临界马赫数工况下的气动性能。优化设计最大程度地减小了样本空间,提高了优化效率。     

超声速进气道喉部附面层抽吸

为研究超声速进气道喉部之后流场激波附面层干扰,采用FLUENT软件模拟了单楔角进气道在设计工况下流动情况。通过分析,提出进气道喉部抽吸。计算了三种抽吸缝大小下进气道喉部之后流场,计算结果表明,喉部抽吸能使激波稳定于喉部,通过抽吸能改善喉部之后流场状况,提高进气道性能,少量抽气不改变流场结构,加大抽气量,使喉部之后激波串转变成正激波,正激波之后流场不分离,进气道出口性能参数提高显著。     

几种超声速非常规压缩系统的研究

根据斜激波和膨胀波理论,数值计算得到给定非常规压缩型面所形成的弯曲激波型面和壁面静压分布,同Fluent计算结果进行比较。应用Fluent软件,计算了等压力梯度设计非常规曲面压缩二元进气道、常规等熵压缩二元进气道和三楔压缩二元进气道设计点性能。研究结果表明:数值计算得到的弯曲激波型面与Fluent计算结果吻合较好。等压力梯度设计的非常规压缩型面壁面静压均匀上升,有利于防止壁面附面层分离;其压缩面长度比等熵压缩面缩短21.6%,减轻了进气道的重量。     

设置空腔的超声速燃烧室流场数值模拟

用数值解二维 N- S动量守恒、能量及组分守恒方程 ,模拟了一个设置空腔的超燃燃烧室流场参数分布及性能。计算结果表明 ,空腔扩大了超燃燃烧室的火焰稳定工作范围 ,并提高了燃烧效率。在计算的燃烧室进口状态下 ,空腔内的平均温度、压力取决于空腔内的平均混气比 ,当混气比接近于恰当比时 ,空腔对燃烧室性能影响最大     

超声速燃烧不稳定性研究进展

对超声速燃烧不稳定性这一新兴领域的研究进行了综合评述，并对未来研究进行了展望。首先分析了超声速燃烧不稳定性现象的基本特性及其影响因素；随后讨论了超声速燃烧不稳定性的多种机理；接着概括了基于上述机理的超声速燃烧不稳定性建模；最后对超声速燃烧不稳定性还需重点研究的方向给出建议。综述表明，超声速燃烧不稳定性的现象、机理和建模都还需持续开展研究，特别需要关注的是燃烧室构型布局和燃料喷注方式对超燃冲压发动机燃烧不稳定性现象的影响，在超声速混合层和射流等典型流动中更深入探索超声速燃烧不稳定性机理，基于超声速燃烧系统的湍流时空演化特性进一步发展超声速燃烧不稳定性模型。     

Development of a coupled supersonic inlet-fan Navier–Stokes simulation method

A coupled supersonic inlet-fan Navier–Stokes simulation method was developed by using COMSOL-CFD code. The flow turning, pressure rise and loss effects across blade rows of the fan and the inlet-fan interactions were taken into account as source terms of the governing equations without a blade geometry by a body force model. In this model, viscous effects in blade passages can also be calculated directly, which include the exchange of momentum between fluids and detailed viscous flow close to walls. NASA Rotor 37 compressor test rig was used to validate the ability of the body force model to estimate the real performance of blade rows. Calculated pressure ratio characteristics and the distribution of the total pressure, total temperature, and swirl angle in the span direction agreed well with experimental and numerical data. It is shown that the body force model is a promising approach for predicting the flow field of the turbomachinery. Then, coupled axisymmetric mixed compression supersonic inlet-fan simulations were conducted at Mach number 2.8 operating conditions. The analysis includes coupled steady-state performance, and effects of the fan on the inlet. The results indicate that the coupled simulation method is capable of simulating behavior of the supersonic inlet-fan system.     

Mach reflection in steady supersonic flow considering wedge boundary-layer correction

Mach reflection in steady supersonic flow is an important phenomenon having received extensive studies, among which simplified theoretical models to predict the size of Mach stem and other flow structure are of particular interest. Past efforts for such models were based on inviscid assumption while in real cases the flow is viscous. Here in this paper we consider the influence of wedge boundary layer on the Mach stem height. This is done by including a simplified boundary layer model into a recently published inviscid model. In this viscous model, the wedge angle and the trailing edge height, which control the Mach stem height, are replaced by their equivalent ones accounting for the displacement effect of the wedge boundary layer, with the boundary layer assumed to be laminar or fully turbulent. This viscous model is shown to compare well with numerical results by computational fluid dynamics and gives a Mach stem height as function of the Reynolds number and Mach number. It is shown that due to the viscous effect, the Mach stem height is increased, through increasing the effective wedge angle.     

Supersonic flow over a pitching delta wing using surface pressure measurements and numerical simulations

Experimental and numerical methods were applied to investigating high subsonic and supersonic flows over a 60° swept delta wing in fixed state and pitching oscillation.Static pressure coefficient distributions over the wing leeward surface and the hysteresis loops of pressure coefficient versus angle of attack at the sensor locations were obtained by wind tunnel tests.Similar results were obtained by numerical simulations which agreed well with the experiments.Flow structure around the wing was also demonstrated by the numerical simulation.Effects of Mach number and angle of attack on pressure distribution curves in static tests were investigated.Effects of various oscillation parameters including Mach number, mean angle of attack, pitching amplitude and frequency on hysteresis loops were investigated in dynamic tests and the associated physical mechanisms were discussed.Vortex breakdown phenomenon over the wing was identified at high angles of attack using the pressure coefficient curves and hysteresis loops, and its effects on the flow features were discussed.