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[1]杨尚荣,周晨初,王牧昕.同轴离心式喷嘴热声不稳定性递归网络分析[J].火箭推进,2021,47(01):36-42.
　YANG Shangrong,ZHOU Chenchu,WANG Muxin.Dynamic behavior of thermoacoustic instabilities of an coaxial swirl injector using recurrence network[J].Journal of Rocket Propulsion,2021,47(01):36-42.

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同轴离心式喷嘴热声不稳定性递归网络分析

《火箭推进》[ISSN:1672-9374/CN:CN 61-1436/V] 卷: 47 期数: 2021年01期页码: 36-42 栏目: 研究与设计出版日期: 2021-02-28

Title:: Dynamic behavior of thermoacoustic instabilities of an coaxial swirl injector using recurrence network

文章编号:: 1672-9374(2021)01-0036-07

作者:: 杨尚荣¹; 周晨初¹; 王牧昕²; (1.西安航天动力研究所液体火箭发动机技术重点实验室, 陕西西安 710100; 2.中国航天科工集团公司六院210所,陕西西安 710065)

Author(s):: YANG Shangrong¹; ZHOU Chenchu¹; WANG Muxin²; (1.Science and Technology on Liquid Rocket Engine Laboratory, Xi'an Aerospace Propulsion Institute, Xi'an 710100, China; 2. 210 Institute, The Sixth Academy of China Aerospace Science & Industry Corp., Xi'an 710065, China)

关键词:: 同轴离心式喷嘴; 热声不稳定; 递归网络; 网络测度; 阵发性

Keywords:: coaxial swirl injector; thermoacoustic instability; recurrence network; network measures; intermittency

分类号:: V453.1

文献标志码:: A

摘要:: 为获得同轴离心式喷嘴燃烧动力学特性,开展了喷注单元稳定性试验研究。试验中随着混合比的增加,系统依次经历了燃烧噪声状态、阵发状态和准周期振荡状态。采用递归网络方法对实验结果进行分析,获得了典型工况下的网络拓扑图。燃烧噪声状态体现出随机特征,阵发状态体现出中央聚集和极限环边界特征,准周期振荡状态体现出宽边界圆环特征。利用网络全局测度对系统动力学状态转变过程进行量化估计,发现聚类系数、特征路径长度、介数中心性、网络直径、全局有效性、同配性等均可作为同轴离心式喷嘴燃烧动力学转变过程的表征指标。

Abstract:: An experimental investigation of a laboratory-scale coaxial swirl injector in a cylindrical combustor was carried out. The dynamic behavior transits from combustion noise to quasiperiodic oscillations via intermittency with increasing mixture ratio. The topologies of recurrence networks constructed from the time series of acoustic pressure for three typical equivalence ratios were obtained. It is founded that the topologies show characteristics of random, central concentration and limit cycle boundary, and torus in the state of combustion noise, intermittency and quasiperiodic oscillation respectively. Topological measures of complex networks, namely clustering coefficient, characteristic path length, betweenness centrality, global efficiency, network diameter and assortativity were computed and used to distinguish different dynamical regimes in a turbulent combustor. It is found that these network properties capture the change in physical state of the system dynamics during the transition from combustion noise to combustion instability.

参考文献/References:

[1] KIM K T.Nonlinear interactions between the fundamental and higher harmonics of self—excited combustion instabilities[J].Combustion Science and Technology, 2017,189(7):1091-1106.
[2] MURUGESAN M,ZHU Y H,LI L K B.Complex network analysis of forced synchronization in a hydrodynamically self—excited jet[J].International Journal of Heat and Fluid Flow,2019,76: 14-25.
[3] MURAYAMA S,KINUGAWA H,TOKUDA I T,et al.Characterization and detection of thermoacoustic combustion oscillations based on statistical complexity and complex—network theory[J].Physical Review E,2018,97(2):022223.
[4] MURUGESAN M,SUJITH R I.Combustion noise is scale-free: transition from scale-free to order at the onset of thermoacoustic instability[J].Journal of Fluid Mechanics,2015,772: 225-245.
[5] 王金华,聂要辉,常敏,等.预混湍流火焰面褶皱结构网络拓扑研究[J].实验流体力学,2018,32(1):19-25.
[6] OKUNO Y,SMALL M,GOTODA H.Dynamics of self—excited thermoacoustic instability in a combustion system: Pseudo—periodic and high—dimensional nature[J].Chaos,2015,25(4):043107.
[7] GOTODA H,KINUGAWA H,TSUJIMOTO R,et al.Characterization of combustion dynamics,detection,and prevention of an unstable combustion state based on a complex—network theory[J].Physical Review Applied,2017,7(4):044027.
[8] MURUGESAN M,SUJITH R I.Detecting the onset of an impending thermoacoustic instability using complex networks[J].Journal of Propulsion and Power,2016,32(3):707-712.
[9] SINGH J,BELURVISHWANATH R,CHAUDHURI S,et al.Network structure of turbulent premixed flames[J].Chaos,2017,27(4):043107.
[10] GODAVARTHI V,UNNI V R,GOPALAKRISHNAN E A,et al.Recurrence networks to study dynamical transitions in a turbulent combustor[J].Chaos,2017,27(6):063113.
[11] MURAYAMA S,KAKU K,FUNATSU M,et al.Characterization of dynamic behavior of combustion noise and detection of blowout in a laboratory—scale gas—turbine model combustor[J].Proceedings of the Combustion Institute,2019,37(4):5271-5278.
[12] MILLER K,SISCO J,NUGENT N,et al.Combustion instability with a single—element swirl injector[J].Journal of Propulsion and Power,2007,23(5):1102-1112.
[13] WIERMAN M K,HALLUM W Z,ANDERSON W E.Stability characterization of a high pressure transverse combustor with discretely variable oxidizer post lengths[C]//50th AIAA/ASME/SAE/ASEE Joint Propulsion Conference.Reston,Virginia: AIAA,2014.
[14] 王枫,李龙飞,张贵田.液氧煤油补燃发动机喷注器高频燃烧不稳定性的试验研究[J].宇航学报,2012,33(2):260-264.
[15] 王延涛,薛帅杰,杨岸龙,等.同轴喷嘴自发激励高频燃烧不稳定性试验研究[J].宇航学报,2015,36(12):1414-1420.
[16] 王迪,聂万胜,周思引,等.单喷嘴模型发动机纵向高频燃烧不稳定性实验分析[J].实验流体力学,2018,32(2):18-23.
[17] 张蒙正,张志涛,李鳌,等.高频燃烧不稳定性单喷注器燃烧室模拟实验的研究[J].实验技术与管理,2008,25(3):28-32.
[18] 杨向明,杨尚荣,杨岸龙,等.同轴离心式喷嘴热声不稳定性递归分析[J].宇航学报,2020,41(5):608-616.
[19] KANTZ H,SCHREIBER T.Nonlinear time series analysis[M].Cambridge: Cambridge University Press,2003.
[20] DONNER R V,ZOU Y,DONGES J F,et al.Recurrence networks—a novel paradigm for nonlinear time series analysis[J].New Journal of Physics,2010,12(3):033025.
[21] ZOU Y,DONNER R V,MARWAN N,et al.Complex network approaches to nonlinear time series analysis[J].Physics Reports,2019,787: 1-97.

备注/Memo

收稿日期:2020-05-13
基金项目:国家自然科学基金(51606138)
作者简介:杨尚荣(1986—),男,博士,高级工程师,研究领域为液体火箭发动机喷雾燃烧。

更新日期/Last Update: 2021-02-20