共查询到19条相似文献,搜索用时 796 毫秒
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针对等离子体流场的模拟准确性问题及其对高超声速磁流体控制的影响,通过数值求解三维非平衡Navier-Stokes流场控制方程和Maxwell电磁场控制方程,建立了三维低磁雷诺数磁流体数值模拟方法及程序,分析了不同空气组分化学反应模型和壁面有限催化效率等因素对高超声速磁流体控制的影响.研究表明:不同空气组分化学反应模型对高超声速磁流体流场结构、气动力/热特性控制的影响不容忽视;对于本文计算条件,Park化学反应模型在组分模型一致性、等离子体模拟准确性等方面具有一定优势;磁控热防护效果,受壁面有限催化复合系数影响较大,两者呈非线性关系,不同表面区域差异较大;磁场对磁阻力伞及其磁阻力特性影响,受壁面催化效应的影响相对较小. 相似文献
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吸气式高超声速飞行器气动力气动热的数值模拟方法及应用 总被引:1,自引:0,他引:1
对吸气式高超声速飞行器而言,物面热流和摩阻的准确预测对飞行器设计及安全十分关键.介绍采用CFD准确预测气动力和气动热的方法,包括流动的控制方程、湍流模型及湍流的先进壁面函数边界条件,介绍流动的数值求解方法.对典型超声速层流和湍流流动的摩擦阻力和热流进行详细的验证与确认,考察CFD工具在使用先进壁面函数边界条件后,湍流计算的法向网格无关性能力.对设计的一种吸气式高超声速飞行器的气动力和气动热进行数值模拟,为飞行器的气动设计及热防护提供了可靠的数据. 相似文献
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针对低超声速飞行器非稳态飞行条件下内外流固耦合一体化计算的复杂性,将飞行器外部流场的实时气动热转化为浮动的第三类边界条件进行解耦.以加速俯冲的超声速三维头锥体为例,分别采用浮动温差法和辐射平衡法提取表面对流换热系数进行解耦计算,并与直接耦合计算结果进行比较,验证两种解耦算法的可靠性.结果表明,将非稳态飞行过程离散为不同飞行状态点,通过提取对流换热系数解耦计算得到的不同状态点的锥体表面温度分布与直接耦合计算得到的结果吻合较好.两种解耦算法在计算效率方面均要优于耦合计算方法;在外界气动环境发生剧烈变化的过程中,最大相对误差均不超过2%. 相似文献
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高超声速飞行器周围的激波层内高温气体会发生剧烈的物理化学变化,伴随强烈的光辐射过程,直接影响红外导引头的光学成像效果。采用流体力学Navier-Stokes方程和热化学非平衡模型模拟高温非平衡流动,考虑电子跃迁和振转跃迁以窄带法求解气体辐射特性参数,基于有限体积法离散辐射传输方程,在分别验证流场解算、辐射参数求解和辐射传输计算的基础上,进行了飞行器高速飞行的流动和辐射模拟。数值求解得到了飞行器流场特征和粒子数空间分布。计算的选定波长范围内的气体辐射发射系数空间分布显示其与激波形状和波后气体温度分布相似。通过传输得到的飞行器光学窗口视线路径上的气体辐射噪声成轴对称分布,发现辐射噪声和飞行速度、气体成分等密切相关,马赫数增加时气体辐射噪声显著增强。 相似文献
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高超声速飞行器周围的激波层内高温气体会发生剧烈的物理化学变化,伴随强烈的光辐射过程,直接影响红外导引头的光学成像效果。采用流体力学Navier-Stokes方程和热化学非平衡模型模拟高温非平衡流动,考虑电子跃迁和振转跃迁以窄带法求解气体辐射特性参数,基于有限体积法离散辐射传输方程,在分别验证流场解算、辐射参数求解和辐射传输计算的基础上,进行了飞行器高速飞行的流动和辐射模拟。数值求解得到了飞行器流场特征和粒子数空间分布。计算的选定波长范围内的气体辐射发射系数空间分布显示其与激波形状和波后气体温度分布相似。通过传输得到的飞行器光学窗口视线路径上的气体辐射噪声成轴对称分布,发现辐射噪声和飞行速度、气体成分等密切相关,马赫数增加时气体辐射噪声显著增强。 相似文献
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Wei Huang Mohamed Pourkashanian Lin Ma Derek B. Ingham Shi Bin Luo Zhen Guo Wang 《显形杂志》2011,14(1):63-74
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As effective devices to extend the fuel residence time in supersonic flow and prolong the duration time for hypersonic vehicles cruising in the near-space with power, the backward-facing step and the cavity are widely employed in hypersonic airbreathing propulsive systems as flameholders. The two-dimensional coupled implicit RANS equations, the standard k-ε turbulence model, and the finite-rate/eddy-dissipation reaction model have been used to generate the flow field structures in the scramjet combustors with the backward-facing step and the cavity flameholders. The flameholding mechanism in the combustor has been investigated by comparing the flow field in the corner region of the backward-facing step with that around the cavity flameholder. The obtained results show that the numerical simulation results are in good agreement with the experimental data, and the different grid scales make only a slight difference to the numerical results. The vortices formed in the corner region of the backward-facing step, in the cavity and upstream of the fuel injector make a large difference to the enhancement of the mixing between the fuel and the free airstream, and they can prolong the residence time of the mixture and improve the combustion efficiency in the supersonic flow. The size of the recirculation zone in the scramjet combustor partially depends on the distance between the injection and the leading edge of the cavity. Further, the shock waves in the scramjet combustor with the cavity flameholder are much stronger than those that occur in the scramjet combustor with the backward-facing step, and this causes a large increase in the static pressure along the walls of the combustor. 相似文献12.
Effect of cavity location on combustion flow field of integrated hypersonic vehicle in near space 总被引:2,自引:0,他引:2
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The cavity has been widely employed as the flame holder to prolong the residence time of fuel in supersonic flows since it improves the combustion efficiency in the scramjet combustor, and also imposes additional drag on the engine. In this paper, the two-dimensional coupled implicit Reynolds Average Navier–Stokes equations, the RNG k–ε turbulence model and the finite-rate/eddy-dissipation reaction model have been employed to numerically simulate the combustion flow field of an integrated hypersonic vehicle. The effect of cavity location on the combustion flow field of the vehicle has been investigated, and the fuel, namely hydrogen, was injected upstream of the cavity on the walls of the first stage combustor. The obtained results show that the viscous lift force, drag force and pitching moment of the vehicle are nearly unchanged by varying the cavity location over the location range and designs considered in this article, namely the configurations with single cavity, double cavities in tandem and double cavities in parallel. The variation of the fuel injection strategy affects the separation of the boundary layer, and the viscous effect on the drag force of the vehicle is remarkable, but the viscous effects on the lift force and the pitching moment are both small and they can be neglected in the design process of hypersonic vehicles. In addition to varying the location of the cavities, three fuel injection configurations were considered. It was found that one particular case can restrict the inlet unstart for the scramjet engine. 相似文献13.
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横流效应显著影响高超声速飞行器的三维边界层转捩过程, 深化对该流动机制的认识有助于提升和改善飞行器气动性能及热力学环境. 针对HIFiRE5椭圆锥绕流问题, 采用大涡模拟方法计算分析了超声速边界层横流转捩特性, 并揭示其中的流动机理. 参考HIFiRE5风洞模型试验条件, 数值模拟中椭圆锥来流入口处施加人工速度扰动以激发边界层内不稳定扰动波, 进而预测了高超声速边界层流动横流失稳、转捩过程等基本流动特征, 并基于转捩热流分布形态对比, 获得了与试验数据基本吻合的计算结果. 研究发现, 椭圆锥中心线流动汇聚形成的流向涡结构非常容易失稳, 另外在中心线及侧缘之间的中部区域存在较强的横流不稳定性, 两种机制共同作用影响边界层转捩过程. 此外, 分析了来流扰动幅值对边界层横流失稳转捩的影响, 并发现静来流条件下, 横流区域出现两组独立的定常横流涡结构, 而强噪声来流条件下, 中心线主涡和中部横流涡均发生失稳转捩, 且在椭圆锥表面形成多峰状的转捩阵面. 最后, 深入分析流场的压力脉动动力学特性, 揭示了三维边界层发生失稳转捩的非线性演化机制. 相似文献
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涡轮-冲压组合发动机模态过渡段性能模拟和概念探讨 总被引:1,自引:0,他引:1
1概述涡轮-冲压组合发动机是可望用于天地往返运输系统和高超声速民航运输的吸气式发动机。在地面起飞和低速飞行阶段以涡轮发动机模态工作,在高空高速阶段以冲压发动机模态工作.涡轮模态和冲压模态的相互转换过程称为模态过渡段。在过渡段中两种发动机共同工作以联合循环方式运行。组合发动机以联合循环方式工作的性能,不仅与组成它的涡轮发动机和冲压发动机本身的型式和特征有关,而且受到两类发动机相互关系以及调节机构的影响。所以,涡轮冲压组合发动机模态过渡段稳态和瞬态过程的研究,是组合发动机性能研究的重要组成部分[1-… 相似文献
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Three-dimensional flow characteristics in a liquid fuel ramjet combustor were investigated using the PIV method. The combustor had two rectangular inlets that form a 90-degree angle with each other, with intake angles of 30 degrees. Three guide vanes were installed in each rectangular inlet to improve flow stability. The experiments were performed in a water tunnel test with the same Reynolds number as Mach 0.3 at the inlet. PIV software was developed to measure the characteristics of the flow field in the combustor. Accuracy of the developed PIV program was verified with a rotating disk experiment and standard data. The experimental results showed that the two main streams from the rectangular intakes collided near the plane of symmetry and generated two large longitudinal vortices, which was in agreement with three dimensional computational results. A large and complex threedimensional recirculating flow was measured behind the intakes. 相似文献