Aerodynamic characteristics of co-flow jet wing with simple high-lift devices

Numerical investigations are conducted to explore the aerodynamic characteristics of three-dimensional Co-Flow Jet (CFJ) wing with simple high-lift devices during low-speed takeoff and landing. Effects of three crucial parameters of CFJ wing, i.e., angle of attack, jet momentum and swept angle, are comprehensively examined. Additionally, the aerodynamic characteristics of two CFJ configurations, i.e., using open and discrete slots for injection, are compared. The results show that applying CFJ technique to a wing with simple high-lift device is able to generate more lift, reduce drag and enlarge stall margin with lower energy expenditure due to the super-circulation effect. Increasing the jet intensity can reduce the drag significantly, which is mainly contributed by the reaction jet force. The Oswald efficiency factor is, in some circumstances, larger than one, which indicates the potential of CFJ in reducing induced drag. Compared with clean wing configuration, using CFJ technique allows the aerodynamic force variation less sensitive to the swept angle, and such phenomenon is better observed for small swept angle region. Eventually, it is interesting to know that the discrete slotted CFJ configuration demonstrates a promising enhancement in aerodynamic performance in terms of high lift, low drag and efficiency.     

低反力度跨声速转子的叶顶喷气扩稳数值研究

为进一步提高低反力度压气机的稳定工作范围，以某三级低反力度高负荷压气机首级跨声速转子为研究对象，借助三维数值模拟方法，进行了叶顶喷气扩稳研究，分析讨论了叶顶喷气提升低反力度压气机转子稳定性的机理，并探讨了不同喷气轴向位置对扩稳效果及气动性能的影响。结果表明：叶顶喷气通过削弱叶顶泄漏涡和通道激波的相互作用，抑制了转子近失速工况下泄漏涡的破碎，消除了叶顶通道的大面积堵塞，拓宽了转子的稳定工作边界；随着喷嘴的位置从叶顶前缘处沿轴向上游移动，转子的失速裕度提升量呈现出先增大后减小的趋势，综合扩稳效果和对压气机总性能参数的影响，最佳喷气轴向位置为叶顶前缘上游转子5%叶顶轴向弦长处；叶顶喷气改变了转子气动参数的径向分布，降低了转子上15%叶高范围内的负荷，同时也使得其它叶高区域的负荷提升。     

基于数字多波束星载多通道VDES设计

阐述了甚高频数据交换系统(VDES)系统产生背景,针对目前普遍存在的系统通信速率受限以及自动识别系统(AIS)时隙冲突问题,提出一种全双工射频通信频段设计方法和时隙冲突解决途径。通过采用多个射频通道以及多个波束合成,利用阵列天线和数字波束合成(DBF)技术,将卫星大覆盖范围划分为多个相互独立区域,缩小单个天线波束视场覆盖范围,减少单波束范围内船舶数量,能有效降低AIS信号时隙冲突。以600 km卫星轨道为例,介绍了8通道及8个波束DBF设计方法,对波束视场和天线增益等进行了仿真计算。结果表明:多波束可覆盖±42°视场角范围,单波束视场角最大为±14°。