Propulsive performance of pulse detonation engine with fluidically augmented nozzle

被引:0
作者
机构
[1] School of Power and Energy, Northwestern Polytechnical University
来源
Zheng, H.-L. (008zheng@163.com) | 1600年 / Journal of Propulsion Technology卷 / 35期
关键词
Constant volume cycle model; Fluidic nozzle; Generalized 1D flow model; Nozzle pressure ratio; Pulse detonation engine; Thrust coefficient;
D O I
10.13675/j.cnki.tjjs.2014.07.018
中图分类号
学科分类号
摘要
Both generalized 1-D flow model and constant volume cycle model are employed to investigate the performance of pulse detonation engine with a fluidic nozzle. Thrust coefficient of a fluidic nozzle in steady flow and average thrust coefficient of a pulse detonation engine with a fluidic nozzle during a pulse detonation cycle have been calculated. In the steady flow, fluidic nozzle shows a better performance than its baseline nozzle when nozzle pressure ratio is lower than a critical value. During a pulse detonation cycle, for a certain initial uniform combustion pressure, the fluidic nozzle with a continual second injection can augment the average thrust coefficient when the expansion ratio is higher than a critical value. Interrupted injection can improve the max average thrust coefficient for this initial uniform combustion pressure by 2.4% when initial uniform combustion pressure is 5MPa.
引用
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页码:1002 / 1008
页数:6
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