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。     

一种计算任意形状封闭区域面积的新方法

在图像模式识别中 ,面积是很重要的特征。提出一种计算面积的新方法 ,利用Freeman链码矢量分析 ,对边界像素标注综合处理 ,再进行边界像素坐标加权求和计算 ,求得目标面积 ;该方法与原有计算面积的方法相比 ,该方法实现简单 ,计算量小 ,结果准确     

云模型和混合Petri网相结合的系统可靠性评价

针对复杂系统可靠性评价中工作环境可变的情形,提出基于云模型和混合Petri网相结合的可靠性评价方法。首先采用云模型描述系统的环境适应能力指数,并将其作为混合Petri模型中连续库所的托肯值来控制该模型中变迁的变迁率,然后采用基于Petri网的蒙特卡罗方法对不同环境下的系统可靠性进行仿真求解,得到系统在不同时刻下的失效率。最后以一个C4ISR系统为例,验证了该方法在解决可变工作环境下的系统可靠性评估是可行的。     

不同环境条件油气爆炸极限测试模拟实验系统

针对不同环境条件油气爆炸极限测试的特殊需要,研制了相应的测试实验台架和关键参数测试系统。对标准20L球形爆炸装置进行了改进,使之适用于不同环境条件油气爆炸极限的测定与分析,设计并构建了能够配制不同浓度油气的油气雾化循环配气系统、瞬态压力测试单元、温湿度测试单元和气体组分测试单元等。实验验证与分析结果表明：该模拟实验系统能够满足不同环境条件油气爆炸极限测试分析的需要,也可供其他相似可燃气体（液体蒸气）测试使用。     

非标准气象条件下火炮外弹道仿真

针对目前弹道仿真均建立在标准气象条件下,无法反映弹道真实情况这一问题,以非标准条件弹道模型为基础针对非标准气象条件改进了气温气压模型并建立了风场模型,应用Matlab/Simulink仿真工具构建对应的仿真模型,最后对某型火炮进行仿真验证并通过对仿真结果分析得出各种气象条件对弹道诸元的影响规律,揭示了气象因素与射击误差的关系,为新型火炮非标准气象条件下弹道研究、火炮模拟器弹道仿真开发以及部队实弹射击提供了参考依据。     

界面热阻对金刚石/银复合材料导热率的影响

研究了金刚石／银复合材料的导热率与金刚石的含量、粒度等之间的关系,着重讨论了界面热阻对复合材料导热率的影响。并阐述了金刚石表面镀钛,能有效改善金刚石对银的润湿性,降低界面热阻,从而提高金刚石／银复合材料的导热率。     

舰船水下静态电场深度换算的格林函数法

为从有限深度、有限范围内的舰船水下静态电场数据获知实际舰船更大深度上的场分布特征,在对深海环境中舰船静态电场满足的拉普拉斯方程进行求解的基础上,提出静态电场深度换算的格林函数法,推导出了换算公式的边界积分表达式,给出了实际应用中换算公式的近似计算方法。以舰船静态电场的基本模拟体——单个水平电偶极子的场为例,采用数值仿真的方法对换算公式进行了验证,并对近似计算方法进行了讨论。研究结果表明:该方法可直接通过对测量平面上离散场量进行二重求和来实现静态电场的各类深度换算;与文献中已有的换算方法相比,其换算过程更为快捷。     

管道热边界层理论的研究

研究了高粘性液体管道流动的热边界层理论。利用圆柱坐标粘性流运动基本微分方程,提出了管道热边界层方程,推导出边界层中的温度分布以及层流和紊流时热边界层厚度的常微分方程和解析解计算表达式,并通过Matlab编程实例,给出了热边界层厚度解析解与数值解的比较。计算结果表明:1)粘性的影响将使得热边界层的发展加快,随着粘性和流量的增大,其影响将更加显著;2)紊流时热边界层的发展比层流时要慢。     

An efficient SPH methodology for modelling mechanical characteristics of particulate composites

Particulate composites are one of the widely used materials in producing numerous state-of-the-art components in biomedical, automobile, aerospace including defence technology. Variety of modelling techniques have been adopted in the past to model mechanical behaviour of particulate composites. Due to their favourable properties, particle-based methods provide a convenient platform to model failure or fracture of these composites. Smooth particle hydrodynamics (SPH) is one of such methods which demonstrate excellent potential for modelling failure or fracture of particulate composites in a Lagrangian setting. One of the major challenges in using SPH method for modelling composite materials depends on accurate and efficient way to treat interface and boundary conditions. In this paper, a master-slave method based multi-freedom constraints is proposed to impose essential boundary conditions and interfacial displacement constraints in modelling mechanical behaviour of composite materials using SPH method. The proposed methodology enforces the above constraints more accurately and requires only smaller condition number for system stiffness matrix than the procedures based on typical penalty function approach. A minimum cut-off value-based error criteria is employed to improve the compu-tational efficiency of the proposed methodology. In addition, the proposed method is further enhanced by adopting a modified numerical interpolation scheme along the boundary to increase the accuracy and computational efficiency. The numerical examples demonstrate that the proposed master-slave approach yields better accuracy in enforcing displacement constraints and requires approximately the same computational time as that of penalty method.     

On vibration analysis of functionally graded carbon nanotube reinforced magneto-electro-elastic plates with different electro-magnetic conditions using higher order finite element methods

This article deals with evaluating the frequency response of functionally graded carbon nanotube rein-forced magneto-electro-elastic (FG-CNTMEE) plates subjected to open and closed electro-magnetic cir-cuit conditions. In this regard finite element formulation has been derived. The plate kinematics adjudged via higher order shear deformation theory (HSDT) is considered for evaluation. The equations of motion are obtained with the help of Hamilton's principle and solved using condensation technique. It is found that the convergence and accuracy of the present FE formulation is very good to address the vibration problem of FG-CNTMEE plate. For the first time, frequency response analysis of FG-CNTMEE plates considering the effect of various circuit conditions associated with parameters such as CNT dis-tributions, volume fraction, skew angle, aspect ratio, length-to-thickness ratio and coupling fields has been carried out. The results of this article can serve as benchmark for future development and analysis of smart structures.