高空滑移条件对化学非平衡粘性流动的影响

本文用数值方法计算了不同高度滑移边界条件对钝体绕流流场特性的影响。采用化学非平衡粘性激波层控制方程,边界条件含壁面滑移、激波滑移和无滑移条件。计算结果表明,考虑滑移条件后,激波层较厚,激波处的电子数密度为一有限值。文中给出了计算结果,并与其它文献的结果作了比较。     

三维化学非平衡粘性激波层流场数值模拟

本文通过引进主流贴体坐标 ,将粘性激波层概念推广到三维流场 ,得到了三维粘性激波层方程 ;应用空间推进与总体迭代相结合的求解方法 ,对三维化学非平衡粘性激波层流场进行了数值模拟     

激光引起的热激波的计算结果及激光脉冲宽度的影响

1.引言高能激光脉冲辐照金属材料时,烧蚀掉表面一薄层材料。汽化金属迅速喷出,由于动量守恒,在固态材料中引起一个热激波。热激波传播到自由表面,形成反射稀疏波。材料中的峰值负压强P_-可能达到材料的抗拉强度二而出现层裂破坏。我们提     

高超声速气动热化学非平衡效应数值分析研究

通过数值分析研究了化学非平衡效应对气动加热问题的影响.分别以量热完全气体、单组分热完全气体和5组分化学非平衡气体为气体模型,计算了圆柱钝头的绕流流场和壁面热流密度分布,比较并分析了高温化学非平衡效应对流场特性,尤其是气动加热特性的影响.结果分析表明,高温化学非平衡效应可使激波层变薄,激波层内温度大幅下降,从而会严重影响气动热环境特性,是影响高超声速飞行器热防护设计的重要因素.     

高能激光辐照固体材料时热激波效应的计算

1.引言固体材料受高能激光脉冲辐照时,激光能量沉积到它的表面,使一簿层材料烧蚀。汽化材料迅速膨胀,其反作用在固体材料中引起一个热激波。热激波传播到固体的自由表面之后,反射稀疏波中的负压强可能达到材料的抗拉强度,使其断裂而形成一个痂片,裂缝成为新的自由表面,可能再次形成新的痂片,这样使材料发生层裂破坏。     

侧壁激波诱导下凹腔燃烧室冷态流场实验观测

在单凹腔燃烧室中引入侧壁激波,为研究燃烧室内部流动特性,采用纳米粒子平面激光散射技术和粒子图像测速技术对全尺寸玻璃燃烧室模型进行流场观测,获得了冷态流场展向和法向的瞬态灰度图及平均速度场。实验结果表明:在远壁面区域,凹腔内部速度与密度都较低;引入侧壁激波后,近壁面区域凹腔与主流的质量与动量交换增强,速度与密度升高;受到侧壁激波影响,燃烧室底壁边界层不再均匀,凹腔中后部产生大规模低速区,具有明显三维特性。     

11 组元化学反应气体粘性激波层钝体绕流数值计算

本文采用１１组元化学模型对双曲体粘性激波层化学非平衡绕流流场进行了数值计算,给出了压力、温度,Ｎ＋２、Ｏ＋２、Ｎ＋、Ｏ＋和ＮＯ＋摩尔浓度及ｅ－数密度在驻点的分布,并与７组元、５组元的计算结果作了比较。     

流过泰氟隆烧蚀表面的化学非平衡粘性激波层数值研究

本文对有泰氟隆烧蚀的化学非平衡粘性激波层流场进行了数值模拟。应用空间推进与总体迭代相结合的求解方法，采用１９组元、２９种反应的空气—泰氟隆化学反应系统，对化学非平衡粘性激波层流场与泰氟隆壁面烧蚀传热过程进行耦合求解，研究了平衡催化壁和非催化壁条件对粘性激波层烧蚀流场的影响。     

不同抽吸孔布局的进气道数值模拟机理分析

采用标准k-ωSST湍流模型数值计算方法,针对2种不同抽吸孔布局的超声速进气道数值进行了模拟机理分析。结果表明:在抽吸孔前缘引起的膨胀波与唇口反射激波相交,马赫数增加;模型-1在抽吸孔内形成循环涡流,马赫数增加到3.6,并在抽吸孔内多次反射,在抽吸孔出口的马赫数降低;而模型-2由于在受到剪切层的影响,在抽吸孔内形成循环涡流变成亚声速区域;在抽吸孔后缘形成强压缩波,与进气道反射激波多次相交,模型-2的进气道上壁面下游的压力整体趋势大于模型-1的壁面压力。     

激波诱导可燃气体爆燃的数值模拟

运用化学流体力学基本理论 ,建立了一维激波诱导可燃气体爆燃的九化学反应模型 ,完成了CO气体爆燃过程的数值模拟 ,由CO气体密度的变化以及流场中压力和温度的相应变化 ,清楚地说明了激波诱导可燃气体爆燃的发生机制以及对灭火的重要影响     

Shock wave mitigation using zig-zag structures and cylindrical obstructions

The present study focuses on the mitigation of shock wave using novel geometric passages in the flow field. The strategy is to produce multiple shock reflections and diffractions in the passage with minimum flow obstruction, which in turn is expected to reduce the shock wave strength at the target location. In the present study the interaction of a plane shock front (generated from a shock tube) with various geometric designs such as, 1) zig-zag geometric passage, 2) staggered cylindrical obstructions and 3) zig-zag passage with cylindrical obstructions have been investigated using computational technique. It is seen from the numerical simulation that, among the various designs, the maximum shock attenuation is produced by the zig-zag passage with cylindrical obstructions which is then followed by zig-zag passage and staggered cylindrical obstructions. A comprehensive investigation on the shock wave reflection and diffraction phenomena happening in the proposed complex passages have also been carried out. In the new zig-zag design, the initial shock wave undergoes shock wave reflection and diffraction process which swaps alternatively as the shock front moves from one turn to the other turn. This cyclic shock reflection and diffraction process helps in diffusing the shock wave energy with practically no obstruction to the flow field. It is found that by combining the shock attenuation ability of zig-zag passage (using shock reflection and diffraction) with the shock attenuation ability of cylindrical blocks (by flow obstruction), a drastic attenuation in shock strength can be achieved with moderate level of flow blocking.     

两道同侧扫掠激波作用下形成的三维平板边界层

为探索一种减弱扫掠激波/边界层干扰强度的侧压方式,采用数值计算方法研究两道同侧扫掠激波作用下形成的三维平板边界层。对三维边界层的流动机理进行研究,并与相同气流偏转角的一道扫掠激波作用下形成的三维边界层进行定量比较。研究表明,存在两道同侧扫掠激波时,第一道扫掠激波使侧壁附近边界层变薄,进而使第二道扫掠激波与再附形成的边界层的相互作用减弱,从而总的效果是两道扫掠激波与边界层的相互作用强度比一道扫掠激波的弱;两道扫掠激波的气流总偏转角与一道扫掠激波的相同,相交后汇聚成的激波强度与一道扫掠激波的基本相同,之前被两道扫掠激波"扫"起来的边界层在汇聚激波作用下还呈现锥形流动,分离线和来流的夹角也与一道扫掠激波的基本相同。     

Experimental and numerical study of the blast wave decrease using sandwich panel by granular materials core

Among the intrinsic properties of some materials, e.g., foams, porous materials, and granular materials, are their ability to mitigate shock waves. This paper investigated shock wave mitigation by a sandwich panel with a granular core. Numerical simulations and experimental tests were performed using Autodyn hydro-code software and a shock tube, respectively. The smoothed particle hydrodynamics (SPH) method was used to model granular materials. Sawdust and pumice, whose properties were determined by several compression tests, were used as granular materials in the sandwich panel core. These granular materials possess many mechanisms, including compacting (e.g., sawdust) and crushing (e.g., pumice) that mitigate shock/blast wave. The results indicated the ineffectiveness of using a core with low thickness, yet it was demonstrated to be effective with high thickness. Low-thickness pumice yielded better results for wave mitigation. The use of these materials with a core with appropriate core reduces up to 88% of the shock wave. The results of the experiments and numerical simulations were compared, suggesting a good agreement between the two. This indicates the accuracy of simulation and the ability of the SPH method to modeling granular material under shock loading. The effects of grain size and the coefficient of friction between grains have also been investigated using simulation, implying that increasing the grain size and coefficient of friction between grains both reduce overpressure.     

Modeling of the whole process of shock wave overpressure of free-field air explosion

The waveform of the explosion shock wave under free-field air explosion is an extremely complex problem. It is generally considered that the waveform consists of overpressure peak, positive pressure zone and negative pressure zone. Most of current practice usually considers only the positive pressure. Many empirical relations are available to predict overpressure peak, the positive pressure action time and pressure decay law. However, there are few models that can predict the whole waveform. The whole process of explosion shock wave overpressure, which was expressed as the product of the three factor functions of peak, attenuation and oscillation, was proposed in the present work. According to the principle of explosion similarity, the scaled parameters were introduced and the empirical formula was absorbed to form a mathematical model of shock wave overpressure. Parametric numerical simulations of free-field air explosions were conducted. By experimental verification of the AUTODYN numerical method and comparing the analytical and simulated curves, the model is proved to be accurate to calculate the shock wave overpressure under free-field air explosion. In addition, through the model the shock wave overpressure at different time and distance can be displayed in three dimensions. The model makes the time needed for theoretical calculation much less than that for numerical simulation.     

A study on the surface overpressure distribution and formation of a double curvature liner under a two-point initiation

The formation mechanism of an EFP(explosively formed projectile) using a double curvature liner under the overpressure effect generated by a regular oblique reflection was investigated in this paper.Based on the detonation wave propagation theory,the change of the incident angle of the detonation wave collision at different positions and the distribution area of the overpressure on the surface of the liner were calculated.Three-dimensional numerical simulations of the formation process of the EFP with tail as well as the ability to penetrate 45# steel were performed using LS-DYNA software,and the EFP ve-locity,the penetration ability,and the forming were assessed via experiments and x-ray photographs.The experimental results coincides with those of the simulations.Results indicate that the collision of the detonation wave was controlled to be a regular oblique reflection acting on the liner by setting the di-mensions of the unit charge and maintaining the pressure at the collision point region at more than 2.4 times the CJ detonation when the incident angle approached the critical angle.The distance from the liner midline to the boundary of the area within which the pressure ratio of the regular oblique reflection pressure to the CJ detonation pressure was greater than 2.5,2,and 1.5was approximately 0.66 mm,1.32 mm,and 3.3 mm,respectively.It is noted that pressure gradient caused the liner to turn inside out in the middle to form the head of the EFP and close the two tails of the EFP at approximately 120μs.The penetration depth of the EFP into a 45# steel target exceeded 30 mm,and there was radial expansion between the head and tail of the EFE increasing the penetration resistance of the EFP.Therefore,the structural size of the unit charge and the liner can be further optimized to reduce resistance to increase the penetration ability of the EFP.     

Numerical study on the case effect of a bomb air explosion

When considering the bomb explosion damage effect, the air shock wave and high-speed fragments of the bomb case are two major threats. In experiments, the air shock wave was studied by the bare ex-plosives superseding the real cased bomb; in contrast, the bomb case influence was ignored to reduce risk. The air explosion simulations of the MK84 warhead with and without the case were conducted. The numerical simulation results showed that the bomb case significantly influenced the shock wave generated by the bomb: the spatial distribution of shock wave in the near field changed, and the peak value of shock wave was reduced. Breakage of the case and kinetic energy of the fragmentation consumed 3 and 38% of the explosion energy, respectively. The increasing factors of the peak over-pressure induced by the bare explosive on the ground and in the air were 1.43-3.04 and 1.37-1.57, respectively. Four typical stages of case breakage were defined. The mass distribution of the fragments follows the Mott distribution. The initial velocity distribution of the fragments agreed well with the Gurney equation.     

磁化等离子体对电磁波反射系数的计算分析

为了从理论上分析磁化等离子体对飞行器隐身的机理,采用等效输入阻抗方法计算金属平板前非均匀磁化等离子体层对垂直入射电磁波的功率反射系数,结果表明:电子数密度大小、入射波频率、等离子体碰撞频率和外磁场是功率反射系数的主要影响因素.电子数密度、等离子体碰撞频率取值必须合适,外加磁场才能明显降低等离子体对入射电磁波的功率反射系数.     

基于背衬影响的水下声隐身夹芯复合材料结构设计

在考虑背衬影响的前提下,建立了3种典型水下声隐身夹芯复合材料的结构模型;从水声波动方程出发,推导了3种模型的传递矩阵、声反射系数和吸声系数,并通过试验验证了传递矩阵法的有效性;考虑吸声层厚度、密度、损耗因子、水层厚度等对声隐身性能的影响,应用数值方法对水下夹芯复合材料声隐身结构形式进行了设计,分析了各层材料参数对隐身结构反射系数和吸声系数的影响规律;在吸声层中附加了一层复合材料,有效地抑制了隐身结构的谐振峰,并研究了附加层的匹配位置,使隐身结构在不改变吸声层厚度的情况下获得了更好的声学性能.     

Dynamic parameters of multi-cabin protective structure subjected to low-impact load – Numerical and experimental investigations

The dynamic response of a multi-cabin protective structure subjected to impact load directly affects the protective performance of materials; thus, studying the dynamic response and communication law of wave effect of the load plays an important role in the prediction of protective performance. In this study, the protection experiments of box-structure under air- and/or water-medium are conducted, the dynamic response of the structure subjected to low-impact load is analyzed, and the corresponding numerical simulations are analyzed using the theory of finite element method (FEM). Combined with experimental and FEM simulations, the shock strain distribution, acceleration attenuation, and signal energy in defensive materials are determined. Based on the results, the metal structure exhibits good absorption characteristics for shock vibration. Using the experimental data, we also show that the attenuation of shock wave in water medium should be significantly better than that in air medium, and the protective structure should be designed for a combination of water and air mediums. Meanwhile, the numerical simulation can provide a quantitative analysis process for dynamic analysis of defensive materials.