Influences of the turbulence model and the slot width on the transverse slot injection flow field in supersonic flows

Transverse slot injection scheme is very important for the mixing process between the air and the fuel in supersonic flows. The effect of the turbulence model and slot width on the transverse slot injection flow field has been investigated numerically based on the grid independency analysis, and the predicted results have been compared with the experimental data available in the open literature. The obtained results show that the grid scale makes only a slight difference to the wall pressure profiles for all jet-to-crossflow pressure ratios employed in this study, and the wall pressure profile with low jet-to-crossflow pressure ratio is predicted accurately by the RNG k–ε turbulence model, the SST k–ω turbulence model for the flow field with high jet-to-crossflow pressure ratio. High jet-to-crossflow pressure ratio can increase the jet penetration depth in supersonic flows, and the gradient of the length of the upstream separation region is larger than that of the height of the Mach surface. At the same time, when the jet-to-crossflow pressure ratio is maintained constant, the jet penetration depth increases with the increase of the slot width.     

火箭垂直回收中发动机布局与喷流壁面效应影响研究

针对重复使用火箭垂直着陆过程的喷流流场问题开展研究,利用计算流体力学(Computational Fluid Dynamics, CFD)方法研究了壁面效应和发动机布局对超声速喷流的影响。研究表明,着陆距离(L)在2.24D～11.2D(D为喷管出口的直径)的范围内,地面效应对喷管出口中心处的温度分布影响较小;在当前计算条件下,当L<2.24D时,超声速喷流撞击地面会形成强烈的激波,随着离地高度的降低,该激波位置往喉部方向移动,由于壁面效应,喷管内部形成斜激波,导致中心喷管壁面处的温度升高;中心喷管相对外侧喷管往外突出增大了壁面流动速度,导致外侧喷管出口的温度降低;研究还表明子级火箭底部端面的喷管数量增加后,会导致喷管的温度升高。研究结果将为火箭发射及回收方案选取提供参考。     

超声速进气道及冲压发动机动态特性分析

基于小偏差线性化思想,利用超声速进气道动力学模型计算得到,进气道激波位置和波后压力的响应幅值随频率增大整体趋于减小,但在各阶纵向谐振频率上存在谐振峰。并进一步考虑了燃烧室加质燃烧,分析了冲压发动机气路动态特性,推导出适用于冲压发动机的集中燃烧模型,研究表明在燃油喷注流量的扰动下,冲压发动机幅频响应谐振峰显著。     

壁面孔型对超声速气流中喷注特性的影响

超声速气流中,燃料与来流空气的高效混合是燃烧室实现点火、稳焰及高效燃烧组织的前提。国内外研究者已对比研究了不同壁面孔型对超声速气流中喷注、混合特性的影响,相比于最常见的圆形喷孔,菱形、楔形-半圆、箭形及针形等喷孔用于超声速气流燃料喷注时,不仅有利于降低喷孔前缘边界层的分离,而且也有利于提升射流穿透深度;相比于单孔喷注,组合型喷孔能进一步增强燃料与来流空气在射流远场的混合效果。通过综述各型喷孔的喷注特性,分析提出了适用于超声速燃烧组织的壁面喷注孔型及其工程应用条件。     

液体亚燃燃烧室点火装置工作特性数值研究

基于气体动力学和计算流体力学的相关理论,采用CFD-ACE＋流场计算软件,对液体亚燃燃烧室点火装置单独工作时的稳态流场进行了数值模拟.在试验验证的基础上分析了点火器室压、点火导管内径和导管的结构形式对火焰点火性能的影响.结果表明：当点火器室温和燃气流量恒定时,若保持管道的扩张比不变,选用较低室压的点火器更利于点火;在一定范围内增大导管内径可以提高火焰的点火性能;燃气在直管内的流动损失较小,出口射流的速度较高,穿透深度较大,带弯头的点火导管出口火焰特征类似,有无弯头对火焰的影响很大,而角度差异产生的影响很小.     

Numerical validation and parametric investigation on the cold flow field of a typical cavity-based scramjet combustor

The three-dimensional coupled implicit Reynolds Averaged Navier–Stokes (RANS) equations and the two equation standard k–ε turbulence model has been employed to numerically simulate the cold flow field in a typical cavity-based scramjet combustor. The numerical results show reasonable agreement with the schlieren photograph and the pressure distribution available in the open literature. The pressure distribution after the first pressure rise is under-predicted. There are five shock waves existing in the cold flow field of the referenced combustor. The first and second pressure rises on the upper wall of the combustor are predicted accurately with the medium grid. The other three shock waves occur in the core flow of the combustor. The location of the pressure rise due to these three shock waves could not be predicted accurately due to the presence of recirculation zone downstream of the small step. Further, the effect of length-to-depth ratio of the cavity and the back pressure on the wave structure in the combustor has been investigated. The obtained results show that there is an optimal length-to-depth ratio for the cavity to restrict the movement of the shock wave train in the flow field of the scramjet combustor. The low velocity region in the cavity affects the downstream flow field for low back pressure. The intensity of the shock wave generated at the exit of the isolator depends on the back pressure at the exit of the combustor and this in turn affects the pressure distribution on the upper wall of the combustor.     

发动机喷流对飞行器底部流动影响数值模拟

针对发动机燃气喷流对底部流动的影响开展研究。建立冷喷与热喷计算方法,与经典的高压空气尾喷管喷流试验数据进行了对比,验证了本文建立的三维喷流方法的可靠性。对本文选用的飞行器外形采用冷喷与热喷方法开展了对比计算并与飞行试验值进行比较,分析了两种方法结果的差异。采用热喷方法对来流马赫数 2.5 ,不同飞行高度及喷管进口总压开展计算,研究飞行高度及喷管进口总压对发动机喷流及底部流场的影响。结果表明,保持飞行高度、来流马赫数不变,喷管进口总压增加,底部压力系数逐渐提高。燃气质量浓度最大值位于底部空腔的壁面处,且保持一个恒定值。保持喷管进口总压、来流马赫数不变,飞行高度增加,喷流高速区向后移动且中心区最大马赫数增加。在一定飞行高度下,底部压力系数由负转正,即飞行器底部会出现正推力,这对飞行器的射程会产生重要影响,需要提前评估。     

类火星环境中火箭起降过程喷流影响研究

采用尺度自适应模拟（Scale Adaptive Simulation, SAS）方法对火箭在起降过程中喷流的地面效应进行了数值研究，对比分析了在海平面和类火星环境下的喷流冲击倾斜地面和水平地面时的流场结构以及喷管的侧向载荷。在海平面环境下，喷管内部出现流动分离，喷管内壁压力先减小，在分离点处压力达到最低点，然后压力增加至环境压力。喷流冲击倾斜地面时具有更强烈的流动不稳定性，喷流出现明显的时间演化现象。在类火星环境下，喷管内部不发生流动分离，内壁的压力沿着流向逐渐减小。喷流冲击倾斜地面时，在喷管出口的外侧形成了上下移动的马赫盘；喷流冲击水平地面时，喷流和地面反弹气流相互作用，阻碍了马赫盘的形成。研究结果还表明在类火星环境和海平面环境下，喷流冲击倾斜地面时喷管内壁温度均上升。研究结果将为火箭回收和火星着陆的方案选取提供参考。     

合成射流激励器增强同向燃气-氧气掺混数值模拟及机理研究

建立了将合成射流激励器腔体、出口喉道及外部受控流场作为单连域计算处理的全流场计算模型(X L模型)。基于此计算模型,对合成射流激励器增强同向燃气 氧气掺混的流场进行了数值仿真和机理研究。研究表明,应用合成射流激励器可以显著增强同向燃气/氧气的掺混,其主要控制机理是合成射流激励器对同向燃气/氧气流起到流动方向控制作用,使两侧两股氧气平行射流向内发生偏转,从而大大缩短了每股射流的核心区长度;同时,激励器工作改变和加强了射流出口附近的涡结构,通过涡结构的强对流作用极大地增强了燃气/氧气平行射流在出口附近的混合。     

Transient analysis of counterflowing jet over highly blunt cone in hypersonic flow

Understanding the characteristics of various Counterflowing jets exiting from a nose cone is crucial for determining heat load reduction and usage of this device in various conditions. Such jets can undergo several flow regimes during venting, from initial supersonic flow, to transonic, to subsonic flow regimes as the pressure of jet decreases. A bow shock wave is a characteristic flow structure during the initial stage of the jet development, and this paper focuses on the development of the bow shock wave and the jet structure behind it. The transient behavior of a sonic counterflow jet is investigated using unsteady, axisymmetric Navier–Stokes solved with SST turbulence model at free stream Mach number of 5.75. The coolant gas (Carbon Dioxide and Helium) is chosen to inject into the hypersonic air flow at the nose of the model. The gases are considered to be ideal, and the computational domain is axisymmetric. The jet structure, including the shock wave and flow separation due to an adverse pressure gradient at the nose is investigated with a focus on the differences between high diffusivity coolant jet (Helium) and low diffusivity coolant jet (CO₂) flow scenarios.     

固体火箭冲压发动机的若干技术问题

简述了固体火箭冲压发动机类型及工作原理,总体评价了固体火箭冲压发动机发展时快时慢的原因,弹-机一体化设计、贫氧推进剂、进气道、转级机构、补燃室等设计中应注意的问题,提出了应加强的研究工作,即开展高能低沉积燃烧产物贫氧推进剂研究;完善多种燃气流量调节装置方案,提高其可靠性;进一步开展一次燃烧和二次掺混燃烧的理论和实验研究,提高燃烧效率;尽快建立自由射流等试验研究手段,开展相关的研究工作;适时开展固体燃料冲压、固体超燃冲压及膏体冲压等发动机的研究,不断拓宽应用领域。     

Performance evaluation and parametric analysis on cantilevered ramp injector in supersonic flows

The cantilevered ramp injector is one of the most promising candidates for the mixing enhancement between the fuel and the supersonic air, and its parametric analysis has drawn an increasing attention of researchers. The flow field characteristics and the drag force of the cantilevered ramp injector in the supersonic flow with the freestream Mach number 2.0 have been investigated numerically, and the predicted injectant mole fraction and static pressure profiles have been compared with the available experimental data in the open literature. At the same time, the grid independency analysis has been performed by using the coarse, the moderate and the refined grid scales, and the influence of the turbulence model on the flow field of the cantilevered ramp injector has been carried on as well. Further, the effects of the swept angle, the ramp angle and the length of the step on the performance of the cantilevered ramp injector have been discussed subsequently. The obtained results show that the grid scale has only a slight impact on the flow field of the cantilevered ramp injector except in the region near the fuel injector, and the predicted results show reasonable agreement with the experimental data. Additionally, the turbulence model makes a slight difference to the numerical results, and the results obtained by the RNG k−ε and SST k−ω turbulence models are almost the same. The swept angle and the ramp angle have the same impact on the performance of the cantilevered ramp injector, and the kidney-shaped plume is formed with shorter distance with the increase of the swept and ramp angles. At the same time, the shape of the injectant mole fraction contour at X/H=6 goes through a transition from a peach-shaped plume to a kidney-shaped plume, and the cantilevered ramp injector with larger swept and ramp angles has the higher mixing efficiency and the larger drag force. The length of the step has only a slight impact on the drag force performance of the cantilevered ramp injector. However, it makes a difference to the flow field in the vicinity of the fuel injector, and the subsonic region becomes narrower with the increase of the length of the step.     

超声速横向气流中喷雾的数值模拟

对超声速横向气流中的喷雾过程进行了数值模拟,采用二维N-S方程计算气相,应用一次雾化模型和二次雾化模型模拟了喷雾雾化过程,并与实验测量结果进行了对比。研究了湍流度和附面层厚度对液雾穿透深度的影响,发现湍流度和附面层厚度并不是主要的影响因素,认为雾化模型是影响液雾穿透深度的关键因素。     

超声速进气道流场三维数值模拟

超声速进气道是固体火箭冲压发动机至关重要的部件之一,直接影响燃烧室的燃烧及发动机性能。基于N-S方程、标准k-ε双方程湍流模型,利用FLUENT软件对某型固体火箭冲压发动机楔形超声速进气道内外流场进行了三维数值模拟。计算得到了超声速进气道在飞行马赫数为Ma=3.5的情况下的流场性能。并在相同马赫数下,研究了等比压缩和攻角条件下的进气道流场的分布情况。模拟结果表明：进气道的总压恢复系数和流量系数等性能指标受到攻角的影响而发生变化。     

固体燃料冲压发动机火炬式点火器设计

对火炬式点火器工作原理进行了介绍,根据氧化剂、燃料的状态对火炬式点火器进行了分类,分析了各类点火器结构特点及热防护措施.设计出使用气氧、酒精的固体燃料冲压发动机地面试验用火炬式点火器,采用旋转液膜与酒精再生冷却相结合的办法,有效地加强了点火器的热防护.在冲压发动机试车台上,对该火炬式点火器进行了30余次单独试验,均取得了成功,可持续工作时间不少于20 s.     

凹腔超声速燃烧室氢气燃烧流场数值模拟

对带长深比为10的凹腔结构的燃烧室二维氢燃烧流场进行数值模拟,燃料喷注方式采用凹腔上游喷注加辅加凹腔前壁、底壁、后壁喷注。采用三阶MUSCL格式求解二维含组分守恒N-S方程组,湍流模型采用剪切修正的RNGk-ε湍流模型,对喷氢燃烧工况进行了计算研究,并分别分析了凹腔中不同燃料喷注方式对燃烧特性的影响。结果表明：凹腔是火焰驻留的主要区域;凹腔上游喷注氢,可以使燃料在凹腔中混合燃烧,辅加凹腔中喷氢的三种方式对燃烧状况产生一定的影响。在凹腔前壁、底面辅加喷氢,没有增强凹腔的稳焰特性,对整个燃烧状态影响不大;在凹腔后壁喷氢,能够增加凹腔中的燃料含量,加强了回流效果,对燃烧状态影响较大。三种喷注方式都没有从根本上改变凹腔燃烧流场的特性。     

Numerical investigation of the impact of asymmetric fuel injection on shock train characteristics

Numerical simulations are carried out to investigate the impact of asymmetric fuel injection on shock train characteristics using the commercial-code FLUENT. The asymmetry of fuel injection is examined by changing the fuel flow rates of the upper and lower wall fuel injectors. The numerical approach solves the two-dimensional Reynolds-averaged Navier–Stokes (RANS) equations, supplemented with a k-ω model of turbulence. As a result, different ways of fuel injections will always lead to shock train transitions, with the variations of shock train structure, strength and leading edge position. For symmetric fuel injection, the flowfield of the isolator is quite asymmetric with the boundary layer of the upper wall side developing much stronger than that of the lower wall, which is due to the heterogeneity of the incoming flow. Regarding to asymmetric fuel injection with more of lower wall side, though the pressures in the combustor are nearly the same, the first shock of the shock train converts between ‘Distinct symmetric X type shock’ and ‘Obscure and weaker asymmetric shock’ and the shock train leading edge moves upstream with the increase of the asymmetry level. With regard to asymmetric fuel injection with more of upper wall side, ‘incomplete asymmetric X type shock’ occurs and the shock train structures keep nearly the same with low level of fuel injection asymmetry. Unexpected results like unstart will happen when increasing the level of fuel injection asymmetry. And the isolator will come back to normal state by decreasing the differential of upper and lower wall sides fuel injections.     

燃气舵的舵间气动干扰分析

固体发动机地面试验燃气舵测力试验数据与习惯上的单独舵风洞测力试验存在着差异，多舵风洞测力试验表明：当喷流出口静压小于环境压力（ｐ＜１。０）燃气舵的气动性能重现了地面试验的结果，（ｐ＞１．０）；与单独舵的风洞试验结果相接近。分析得出ｐ＜１．０时燃气舵气动性能变差的原因是多舵使超音速喷流受堵，气流分离之故。     

Lift force acting on the cylinder in viscous liquid under vibration

The averaged lift force acting on a solid in viscous liquid in case of translational or rotary vibrations of a cavity is experimentally investigated. Experiments are performed with a heavy cylinder; different types of vibrations, translational and rotational, are investigated. It is found that the vibrations excite the mean lift force which could provide the suspension of solid even in gravity field. The repulsion lift force acts on the body near the walls of the vibrating cavity. It is caused by the viscous hydrodynamic interaction of oscillating body with the wall and is significant at a distance comparable with the thickness of Stokes layer. The intensification of vibration results in the excitation of tangential lift force, which is caused by the brake of the symmetry of the body's oscillations with respect to the cavity wall. In case of rotary vibrations the lift force of high intensity manifests itself in the bulk of the cavity due to the interaction of body with the oscillating shear flow. The mean dynamics of the solid body in a cavity under the rotary vibrations is determined by the combined action of two averaged vibrational effects—levitation of the body in the oscillating shear flow and hydrodynamic interaction of the body with the wall. In case of translational vibrations the dynamics of the solid is mainly determined by interaction with the walls. The experiments demonstrate that the vibrations have strong mean effect on the bodies in liquid; they could be used for efficient control of solid inclusions in microgravity and must be taken into account in space experiments and technologies.