圆盘结构下旋转爆震波的不稳定传播特性

doi:10.7527/S1000-6893.2017.121438

流体力学与飞行力学

本期目录 | 过刊浏览 | 高级检索

前一篇 | 后一篇

圆盘结构下旋转爆震波的不稳定传播特性

夏镇娟, 马虎, 卓长飞, 周长省

南京理工大学机械工程学院, 南京 210094

收稿日期:2017-05-19 修回日期:2017-07-07 出版日期:2018-02-15 发布日期:2018-02-11
通讯作者: 马虎,E-mail:154552879@qq.com E-mail:mahuokok@163.com
基金资助:
国家自然科学基金（51606100）；江苏省自然科学基金（BK20150782）；中央高校基本科研业务费专项资金（30915118836）

Characteristics of unstable propagation of rotating detonation wave in plane-radial structure

XIA Zhenjuan, MA Hu, ZHUO Changfei, ZHOU Changsheng

School of Mechanical Engineering, Nanjing University of Science and Technology, Nanjing 210094, China

Received:2017-05-19 Revised:2017-07-07 Online:2018-02-15 Published:2018-02-11
Supported by:
National Natural Science Foundation of China (51606100); Natural Science Foundation of Jiangsu Province (BK20150782); the Fundamental Research Funds for the Central Universities (30915118836)

摘要/Abstract

摘要： 为研究圆盘结构下旋转爆震波的不稳定传播特性，以2H₂+O₂+3.76N₂为反应混合物，开展该结构下的二维数值研究。详细分析了旋转爆震波不稳定传播模态的流场特征，以及爆震波参数、出口流场参数和增压比的变化。结果表明，不稳定传播模态下，旋转爆震波重复进行"解耦—再起爆"过程，内圆扩张曲面的发散作用，使出口附近的爆震波首先解耦，解耦区域逐渐往流场内部扩张；反射激波与前导激波的碰撞产生局部热点，促使爆震波重新起爆；爆震波的压力、温度以及传播速度皆随爆震波的解耦及再起爆过程发生变化；旋转爆震波的不稳定传播对出口速度分量及马赫数的影响很小；出口增压比受不稳定传播的影响较大，随时间呈周期性变化，变化幅值较高且不稳定。出口增压比的循环周期与爆震波"解耦—再起爆"的周期一致，稳定后两者的循环频率约为21.6 kHz。

关键词: 旋转爆震波, 数值模拟, 圆盘结构, 不稳定传播, 爆震参数

Abstract: To reveal the characteristics of unstable propagation of the rotating detonation wave in the plane-radial structure, a two-dimensional numerical simulation of the structure was conducted with 2H₂+O₂+3.76N₂ being the reaction mixture. The flow field structure under the unstable propagation mode was analyzed, as well as variation of detonation parameters, flow parameters and the pressure amplification ratio at the exit. Results indicate that decoupling and re-initiation of the rotating detonation wave occur repeatedly under the unstable propagation mode. The diffraction of the inner circle geometry weakens the intensity of the detonation wave. The detonation wave decouples first near the exit, and then the decoupling region expands to the interior flow field gradually. The collision of the reflected wave and the leading shock wave urges the formation of the hot spot in the flow field, initiating the detonation wave again. The detonation pressure, temperature and propagating velocity vary with the "decoupling and re-initiation" process of the detonation wave. The unstable propagation of the rotating detonation wave has only a small effect on the velocity components and Mach number in the exit, but a significant effect on the exit pressure amplification ratio. The pressure amplification ratio varies periodically with time, and the amplitude is high and unsteady. The cycle period of the pressure amplifying ratio is consistent with the period of "decoupling and re-initiation" process, and the cycle frequency is about 21.6 kHz after dynamic stability.

Key words: rotating detonation wave, numerical simulation, plane-radial structure, unstable propagation, detonation parameter

中图分类号:

V235.22

夏镇娟, 马虎, 卓长飞, 周长省. 圆盘结构下旋转爆震波的不稳定传播特性[J]. 航空学报, 2018, 39(2): 121438-121438.

XIA Zhenjuan, MA Hu, ZHUO Changfei, ZHOU Changsheng. Characteristics of unstable propagation of rotating detonation wave in plane-radial structure[J]. ACTA AERONAUTICAET ASTRONAUTICA SINICA, 2018, 39(2): 121438-121438.

参考文献

[1] VOITSEKHOVSKⅡ B V, MITROFANOV V V, TOPCHIYAN M E. Structure of the detonation front in gases[J]. Combustion, Explosion, and Shock Waves, 1969, 5(3):385-395(in Russian).[2] BYKOVSKⅡ F A, ZHDAN S A, VEDERNIKOV E F. Continuous spin detonations[J]. Journal of Propulsion and Power, 2006, 22(6):1204-1216.[3] BYKOVSKⅡ F A, ZHDAN S A, VEDERNIKOV E F. Continuous detonation of syngas-air mixtures in an annular flow-type cylindrical combustor[C]//24th International Colloquium on the Dynamics of Explosions and Reactive Systems, 2013:1-4.[4] ANAND V, GEORGE A S, DRISCOLL R, et al. Characterization of instabilities in a rotating detonation combustor[J]. International Journal of Hydrogen Energy, 2015, 40(46):16649-16659.[5] ANAND V, GEORGE A S, DRISCOLL R, et al. Longitudinal pulsed detonation instability in a rotating detonation combustor[J]. Experimental Thermal and Fluid Science, 2016, 77:212-225.[6] RANKIN B A, RICHARDSON D R, CASWELL A W, et al. Chemiluminescence imaging of an optically accessible non-premixed rotating detonation engine[J]. Combustion and Flame, 2017, 176(1):12-22.[7] ZHANG H L, LIU W D, LIU S J. Experimental investigations on H₂/air rotating detonation wave in the hollow chamber with Laval nozzle[J]. International Journal of Hydrogen Energy, 2017, 42(5):3363-3370.[8] 刘世杰, 林志勇, 孙明波, 等. 旋转爆震波发动机二维数值模拟[J]. 推进技术, 2010, 31(5):634-640. LIU S J, LIN Z Y, SUN M B, et al. Two-dimensional numerical simulation of rotating detonation wave engine[J]. Journal of Propulsion Technology, 2010, 31(5):634-640(in Chinese).[9] 刘世杰, 覃慧, 林志勇, 等. 连续旋转爆震波细致结构及自持机理[J]. 推进技术, 2011, 32(3):431-436. LIU S J, QIN H, LIN Z Y, et al. Detailed structure and propagating mechanism research on continuous rotating detonation wave[J]. Journal of Propulsion Technology, 2011, 32(3):431-436(in Chinese).[10] MANABU H, FUJIWARA T, PIOTR W. Fundamentals of rotating detonations[J]. Shock Waves, 2009, 19(1):1-10.[11] EUDE Y, DAVIDENKO D M, GÖKALP I, et al. Use of the adaptive mesh refinement for 3D simulations of a CDWRE (Continuous Detonation Wave Rocket Engine):AIAA-2011-2236[R]. Reston, VA:AIAA, 2011.[12] FROLOV S M, DUBROVSKⅡ A V, IVANOV V S. Three-dimensional numerical simulation of the operation of a rotating-detonation chamber with separate supply of fuel and oxidizer[J]. Russian Journal of Physical Chemistry B, 2013, 7(1):35-43.[13] TANG X M, WANG J P, SHAO Y T. Three-dimensional numerical investigations of the rotating detonation engine with a hollow combustor[J]. Combustion and Flame, 2015, 162(4):997-1008.[14] LI J, NING J G, ZHAO H, et al. Numerical investigation on the propagation mechanism of steady cellular detonations in curved channels[J]. Chinese Physics Letters, 2015, 32(4):144-147.[15] BYKOVSKⅡ F A, ZHDAN S A, VEDERNIKOV E F, et al. Detonation of a coal-air mixture with addition of hydrogen in plane-radial vortex chambers[J]. Combustion, Explosion, and Shock Waves, 2011, 47(4):473-482.[16] NAKAGAMI S, MATSUOKA K, KASAHARA J, et al. Visualization of rotating detonation waves in a plane combustor with a cylindrical wall injector:AIAA-2015-0878[R]. Reston, VA:AIAA, 2015.[17] ISHIYAMA C, MIYAZAKI K, NAKAGAMI S, et al. Experimental study of research of centrifugal-compressor-radial-turbine type rotating detonation engine:AIAA-2016-5103[R]. Reston, VA:AIAA, 2016.[18] HIGASHI J, ISHIYAMA C, NAKAGAMI S, et al. Experimental study of disk-shaped rotating detonation turbine engine:AIAA-2017-1286[R]. Reston, VA:AIAA, 2017.[19] 卓长飞, 武晓松, 封锋. 底部排气弹三维湍流燃烧的数值模拟[J].固体火箭技术, 2013, 36(6):720-726. ZHUO C F, WU X S, FENG F. Numerical simulation of three-dimensional turbulent combustion of the base bleed projectile[J]. Journal of Solid Rocket Technology, 2013, 36(6):720-726(in Chinese).[20] 卓长飞, 武晓松, 封峰. 超声速流动中底部排气减阻的数值研究[J].兵工学报, 2014, 35(1):18-26. ZHUO C F, WU X S, FENG F. Numerical research on drag reduction of base bleed in supersonic flow[J]. Acta Armamentarii, 2014, 35(1):18-26(in Chinese).[21] 马虎, 武晓松, 王栋, 等. 旋转爆震发动机数值研究[J]. 推进技术, 2012, 33(5):820-825. MA H, WU X S, WANG D, et al. Numerical investigation for rotating detonation engine[J]. Journal of Propulsion Technology, 2012, 33(5):820-825(in Chinese).[22] 夏镇娟, 武晓松, 马虎, 等. 圆盘结构下旋转爆震波的二维数值研究[J]. 推进技术, 2017, 38(6):1409-1418. XIA Z J, WU X S, MA H, et al. Two-dimensional numerical simulation of rotating detonation wave in plane-radial structure[J]. Journal of Propulsion Technology, 2017, 38(6):1409-1418(in Chinese).

E-mail：hkxb@buaa.edu.cn

关于我们

期刊社服务

专业学科

封面文章

友情链接

主管单位：中国科学技术协会主办单位：中国航空学会北京航空航天大学

圆盘结构下旋转爆震波的不稳定传播特性

Characteristics of unstable propagation of rotating detonation wave in plane-radial structure

PDF (PC)

可视化

摘要/Abstract

引用本文

使用本文

参考文献

相关文章 15

编辑推荐

Metrics

本文评价

[1]	夏侯唐凡, 陈江涛, 邵志栋, 吴晓军, 刘宇. 随机和认知不确定性框架下的CFD模型确认度量综述[J]. 航空学报, 2022, 43(8): 25716-025716.
[2]	杨建凯, 顾冬冬, 葛庆, 檀晨晨, 文雨. 铝合金激光增材制造支撑布局及精确成形机制[J]. 航空学报, 2022, 43(4): 525331-525331.
[3]	姜有旭, 李杰, 杨钊. 某层流机翼验证机风洞试验数据修正方法[J]. 航空学报, 2022, 43(11): 526814-526814.
[4]	段俊亦, 童福林, 李新亮, 刘洪伟. 压缩-膨胀湍流边界层平均摩阻分解[J]. 航空学报, 2022, 43(1): 625915-625915.
[5]	刘朋欣, 袁先旭, 孙东, 傅亚陆, 李辰. 高温化学非平衡湍流边界层直接数值模拟[J]. 航空学报, 2022, 43(1): 124877-124877.
[6]	沈鹏飞, 刘朋欣, 孙东, 袁先旭. 马赫6柱-裙构型激波/湍流边界层干扰摩阻统计特性[J]. 航空学报, 2022, 43(1): 626005-626005.
[7]	刘朋欣, 袁先旭, 梁飞, 李辰, 孙东. 高温化学非平衡湍流边界层脉动量象限分析[J]. 航空学报, 2021, 42(S1): 726338-726338.
[8]	鲍俊, 王瑜, 牛潜, 朱锡冬, 程建杰. 喷雾液滴撞击液膜影响参数及流动机理分析[J]. 航空学报, 2021, 42(S1): 726360-726360.
[9]	陈崇沛, 梁剑寒, 关清帝, 高天运. 守恒型可压缩一维湍流方法及其在超声速标量混合层中的应用[J]. 航空学报, 2021, 42(S1): 726364-726364.
[10]	李青, 涂国华, 余钊圣, 林昭武, 李婷婷, 袁先旭. 惯性颗粒在非均匀加速流中的输运问题[J]. 航空学报, 2021, 42(S1): 726390-726390.
[11]	李成成, 李芳, 杨斌, 王莹. 等离子体激励抑制喷管分离流动数值模拟[J]. 航空学报, 2021, 42(7): 124547-124547.
[12]	刘宗兴, 刘军, 李维娜. 爆炸冲击载荷下典型机身结构动响应及破坏[J]. 航空学报, 2021, 42(2): 224252-224252.
[13]	孙东, 刘朋欣, 沈鹏飞, 童福林, 郭启龙. 马赫数6柱-裙激波/边界层干扰直接模拟[J]. 航空学报, 2021, 42(12): 124681-124681.
[14]	王方, 王煜栋, 姜胜利, 陈军, 唐军, 徐华胜, 李象远, 邢竞文, 高东硕, 金捷. AECSC-JASMIN湍流燃烧仿真软件研发和检验[J]. 航空学报, 2021, 42(12): 625003-625003.
[15]	崔笑蕾, 詹梅, 高鹏飞, 李锐, 王贤贤, 雷煜东, 马飞, 张洪瑞. 虑及板坯几何和性能波动的薄壁件塑性成形数值模拟研究进展[J]. 航空学报, 2021, 42(10): 525145-525145.