多机并联火箭羽流流场及其底部热环境分析

For the problem that the plume flow field structure of a multi engine parallel rocket is complicated and the bottom thermal environment is extremely harsh, which may cause the failure of the engine structural components, the plume flow field and thermal environment at different altitudes are studied through numerical simulation. The result is compared with the measured results in flight which shows that when the rocket is flying at a low altitude, the plume of the engines do not interfere with each other. As the flight altitude increases, the plumes gradually expand and begin to interfere with each other, and finally there is an obvious backflow at the bottom of the rocket. The maximum heat flux at the moment of take off is basically the same as the measured value in flight. Before the backflow occurs, the heat flux mainly consists of radiant heat, the convective heat flow increases as the flight altitude grows, but it is also much smaller than the peak heat flow at takeoff. The result has certain guiding significance for the optimal design of engine structure thermal protection.     

液液同轴离心式喷嘴喷雾过程研究进展

内部流动主要研究了流量系数、液膜厚度和气核半径,分析了内部流场,少量研究涉及内外喷嘴液膜互击、液膜表面波振幅和频率等方面。液液喷嘴外部液膜流动及喷雾特性的研究开展较多,观测了不同工况、结构参数下内外液膜流动形态,少数学者使用理论方法分析了液膜破碎机理。对喷雾特性的研究主要是获得了喷雾锥角、破碎长度、液膜振荡频率等的变化规律,并进一步研究了SMD、液滴速度、混合特性等的变化规律。