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[1]张留欢,马化杰,周建平,等.氨解离度对无水肼ATR发动机性能影响研究[J].火箭推进,2019,45(02):16-19，52.
　ZHANG Liuhuan,MA Huajie,ZHOU Jianping,et al.Performance analysis of hydrazine ATR with different dissociated ratios of NH3different[J].Journal of Rocket Propulsion,2019,45(02):16-19，52.

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氨解离度对无水肼ATR发动机性能影响研究

《火箭推进》[ISSN:1672-9374/CN:CN 61-1436/V] 卷: 45 期数: 2019年02期页码: 16-19，52 栏目: 研究与设计出版日期: 2019-04-30

Title:: Performance analysis of hydrazine ATR with different dissociated ratios of NH₃different

文章编号:: 1672-9374(2019)02-0016-04

作者:: 张留欢; 马化杰; 周建平; 南向谊; 李光熙; (西安航天动力研究所,陕西西安 710100)

Author(s):: ZHANG Liuhuan; MA Huajie; ZHOU Jianping; NAN Xiangyi; LI Guangxi; (Xi'an Aerospace Propulsion Institute, Xi'an 710100, China)

关键词:: 无水肼; ATR发动机; 氨解离度

Keywords:: Hydrazine; ATR; dissociated ratio of NH₃

分类号:: V439

文献标志码:: A

摘要:: 基于无水肼ATR发动机,开展了氨解离度对涡轮前燃气及发动机总体性能的影响研究,对不同氨解离度时无水肼ATR发动机性能进行计算对比。结果显示,随着氨解离度x升高,无水肼分解燃气温度降低,H₂、N₂在分解混合气中的质量百分比升高,燃气比热比、气体常数数值升高; 在地面状态同一转速下,x越小,发动机比冲越高。在100%物理转速时,x=0.29对应的发动机比冲最高且为808 s,无水肼流量为0.999 kg/s,较x=0.8发动机比冲提高最大约7.3%,无水肼流量减小约7.33%; 同一高空条件100%转速下,x越小,发动机比冲越高。在22 km/3.5Ma条件下,x=0.29较x=0.8发动机比冲提高最大约14.6%,无水肼流量减小约8.2%。在同一ATR发动机、同一转速下,氨解离度越低,涡轮等熵功越大,无水肼流量越小,发动机比冲越高。

Abstract:: Based on hydrazine ATR, performance analysis of hydrazine ATR with different dissociated ratios of NH₃(x)was presented here.And the calculation and comparison about performance of ATR with different x were carried out.The results show that as x increases, temperature of gas decreases which is dissociated from hydrazine by catalysis, mass percentage of H₂, N₂ increases, and the value of specify heat ratio and gas constant goes up.On the ground state, the specify impulse of ATR increases as x decreases under the same rev.When the physical rev is 100% and x=0.29, the specify impulse reaches top 808s, which is 7.3% higher than that at x=0.8, and the mass flow rate of hydrazine is 0.999 kg/s, which is 7.33% lower than that at x=0.8.Under the condition of high altitude, the specify impulse of ATR increases as x decreases under the same rev.The specify impulse and mass flow rate, with x of 0.29, are 14.6% and 8.2% higher than that at x =0.8 when the flight condition is 22 km/3.5Ma respectively.With the same ATR engine and rev, as the dissociated ratio of NH₃ decreases, isentropic work of turbine increases, mass flow rate of hydrazine decreases and specify impulse of ATR increases.

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备注/Memo

收稿日期:2017-11-02; 修回日期:2018-01-02 基金项目:装备预研航天科技联合基金(6141B060626040) 作者简介:张留欢(1986—),男,硕士,工程师,研究领域为组合推进系统气动热力技术

更新日期/Last Update: 2019-04-30