Investigation on Design and Detonation Combustion Characteristics of Liquid-Fuel Initiator for Rotating Detonation Engine

doi:10.13675/j.cnki. tjjs. 180648

Journal of Propulsion Technology ›› 2019, Vol. 40 ›› Issue (9): 2067-2074.DOI: 10.13675/j.cnki. tjjs. 180648

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Investigation on Design and Detonation Combustion Characteristics of Liquid-Fuel Initiator for Rotating Detonation Engine

1.Key Laboratory of Aero-Engine Thermal Environment and Structure,Ministry of Industry and Information Technology,College of Energy and Power Engineering,Nanjing University of Aeronautics and Astronautics,Nanjing 210016，China;2.School of National Defense Engineering,The Army Engineering University of PLA,Nanjing 210007，China

Published:2021-08-15

旋转爆震发动机液态燃料预爆器设计及爆震燃烧特性研究

张开晨¹,李建中¹,金武¹,袁丽²,李夏飞¹

1.南京航空航天大学能源与动力学院，航空发动机热环境与热结构工业和信息化部重点实验室;2.陆军工程大学国防工程学院，江苏南京;210007

作者简介:张开晨，硕士生，研究领域为爆震燃烧技术。E-mail：kczhang1004@nuaa.edu.cn
基金资助:
国家自然科学基金 51476077国家自然科学基金（51476077）。

Abstract

Abstract: To solve difficulties of ignition and compact structure in liquid-fuel rotating detonation engine, an initiator with liquid aviation kerosene as fuel was designed. It includes centrifugal/pre-film composite fuel atomizing injector, ignition/transmission flame concave cavity and three-branches pipe initiator chamber. The atomization characteristic of the centrifugal/pre-film composite fuel atomizing injector and detonation combustion characteristic of the initiator were experimentally studied with liquid aviation kerosene and pure oxygen. The change rules of atomized particle sizes behind the centrifugal/pre-film composite fuel atomizing injector were obtained. The detonation combustion characteristics such as pressure and flame propagation speed in the initiator were gained. The results show that, the atomization effect improves with increases in fuel pressures and airflow rate. Near the exit of the initiator (location of PCB5), the peak pressure of the detonation waves exceeds 3.80MPa and the maximum velocity reaches 1800m/s. With the increase of equivalence ratio, the positions of the overdriven detonation waves in the initiator are advanced, which are beneficial to shorten the length of the initiator. The research results provide ideas for the design of the initiator using liquid fuel.

Key words: Rotating detonation engine;Initiator;Detonation combustion characteristics

摘要： 为了解决液态燃料旋转爆震发动机点火起爆困难和结构紧凑等问题，进行了以液态航空煤油为燃料的预爆器设计，包括离心/预膜复合燃油雾化喷嘴、点火/传焰凹腔、三枝管预爆室等结构。以液态航空煤油/氧气为工作介质，进行了离心/预膜复合燃油雾化喷嘴雾化特性和预爆器爆震燃烧特性试验研究，获得了离心/预膜复合燃油雾化喷嘴雾化粒径变化规律，以及预爆器内爆震波压力、传播速度等变化规律。研究表明：离心/预膜复合燃油雾化喷嘴的雾化效果随气流流量和油压增加而改善，预爆器接近出口位置（PCB5处）爆震波峰值压力可超过3.80MPa，爆震波传播速度可达1800m/s；随着当量比增加，预爆器内过驱爆震位置提前，有利于缩短预爆器的长度。

关键词: 旋转爆震发动机;预爆器;爆震燃烧特性

ZHANG Kai-chen¹,LI Jian-zhong¹,JIN Wu¹,YUAN Li²,LI Xia-fei¹. Investigation on Design and Detonation Combustion Characteristics of Liquid-Fuel Initiator for Rotating Detonation Engine[J]. Journal of Propulsion Technology, 2019, 40(9): 2067-2074.

张开晨,李建中,金武,袁丽,李夏飞. 旋转爆震发动机液态燃料预爆器设计及爆震燃烧特性研究[J]. 推进技术, 2019, 40(9): 2067-2074.

References

[1] Rui Z, Dan W， Wang J. Progress of Continuously Rotating Detonation Engines[J]. Chinese Journal of Aeronautics， 2016， 29(1): 15-29.
[2] Anand V， Gutmark E J. Rotating Detonations and Spinning Detonations: Similarities and Differences[J]. AIAA Journal， 2018， 56(5): 1717-1722.
[3] Voitsekhovskii B V， Mitrofanov V V， Topchiyan M E. Structure of the Detonation Front in Gases (Survey)[J]. Combustion， Explosion， and Shock Waves， 1969， 5(3):267-273.
[4] Voitsekhovskii B V. Stationary Spin Detonation[J]. Soviet Journal of Applied Mechanics and Technical Physics， 1960， 129(3): 157-164.
[5] Cullen R E， Nicholls J A， Ragland K W. Feasibility Studies of a Rotating Detonation Wave Rocket Motor. [J]. Journal of Spacecraft and Rockets， 1966， 3(6):893-898.
[6] Braun E， Dunn N， Lu F. Testing of a Continuous Detonation Wave Engine with Swirled Injection[C]. Florida:48th AIAA Aerospace Sciences Meeting， 2010.
[7] Kindracki J， Wolański P， Gut Z. Experimental Research on the Rotating Detonation in Gaseous Fuels-Oxygen Mixtures[J]. Shock Waves， 2011， 21(2): 75-84.
[8] 刘世杰. 连续旋转爆震波结构、传播模态及自持机理研究[D]. 长沙:国防科学技术大学， 2012.
[9] 彭磊，王栋，李飞，等. 点火方式对旋转爆震发动机工作特性的影响[J]. 推进技术， 2016， 37(11): 2193-2200.
[10] 刘宇思，王健平，石天一，等. 两种点火方式下的H₂/O₂连续爆轰实验研究[C]. 哈尔滨：中国力学大会2011暨钱学森诞辰100周年纪念大会， 2011.
[11] Wang Y， Le J， Wang C， et al. A Non-Premixed Rotating Detonation Engine Using Ethylene and Air[J]. Applied Thermal Engineering， 2018， 137: 749-757.
[12] Zhuang Ma， Shujie Zhang， Mingyi Luan， et al. Experimental Research on Ignition， Quenching， Reinitiation and the Stabilization Process in Rotating Detonation Engine[J]. International Journal of Hydrogen Energy， 2018， 43(39): 18521-19529.
[13] 严宇，张锋，洪流，等. 旋转爆震发动机中爆震波不稳定传播特性实验研究[J]. 推进技术， 2017， 38(12): 2797-2804.
[14] 王家骅，韩启祥. 脉冲爆震发动机技术[M]. 北京:国防工业出版社， 2013.
[15] Brophy C， Netzer D， Forster D. Detonation Studies of JP-10 with Oxygen and Air for Pulse Detonation Engine Development[C]. Cleveland： 34th AIAA/ASME/SEA/ASEE Joint Propulsion Conference and Exhibit， 1998.
[16] 范玮，严传俊，李强，等. 脉冲爆震火箭发动机试验[J]. 推进技术， 2006， 27(5): 385-389.
[17] 丁永强，范玮，李强，等. 当量比对脉冲爆震火箭发动机爆震特性影响的实验研究[J]. 机械科学与技术， 2005， 24(11): 1371-1373.
[18] 刘道坤. 液态燃料旋转爆震发动机起爆过程研究[D]. 南京：南京理工大学， 2017.

Investigation on Design and Detonation Combustion Characteristics of Liquid-Fuel Initiator for Rotating Detonation Engine

旋转爆震发动机液态燃料预爆器设计及爆震燃烧特性研究

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