Research on Pulse Excitation in High-pressure Acoustic Chambers with Different Length-to-diameter Ratios

LI Ji; SHI Baolu; TANG Yong; LI Tao; LI Junwei; LI Xinyan; WANG Ningfei

doi:10.12382/bgxb.2025.0674

您当前的位置：

首页 >

文章列表页 >

Research on Pulse Excitation in High-pressure Acoustic Chambers with Different Length-to-diameter Ratios

更新时间：2026-05-06

- Research on Pulse Excitation in High-pressure Acoustic Chambers with Different Length-to-diameter Ratios
- Acta Armamentarii Vol. 47, Issue 4, Pages: 250674(2026)
- 作者机构：
  
  北京理工大学空天科学与技术学院，北京 100081
  北京理工大学重庆创新中心，重庆 401120
  北京理工大学（珠海）, 广东珠海 519088
  辽宁北方华丰特种化工有限公司，辽宁抚顺 113003
- 作者简介：
- 基金信息：
- DOI：10.12382/bgxb.2025.0674
  CLC： TK49
- Received：21 July 2025，
  
  Online First：10 February 2026，
  
  Published：2026-04
- 稿件说明：
移动端阅览
LI Ji, SHI Baolu, TANG Yong, et al. Research on Pulse Excitation in High-pressure Acoustic Chambers with Different Length-to-diameter Ratios[J]. Acta Armamentarii, 2026, 47(4): 250674.
DOI：

LI Ji, SHI Baolu, TANG Yong, et al. Research on Pulse Excitation in High-pressure Acoustic Chambers with Different Length-to-diameter Ratios[J]. Acta Armamentarii, 2026, 47(4): 250674. DOI： 10.12382/bgxb.2025.0674.

摘要

面向火箭发动机动态燃烧稳定性评定实验需求，设计了火药脉冲枪，研究脉冲激励下高压声腔的声学响应特性。在10MPa背压下对长径比0.6～5.1之间的5种声腔开展了轴向和径向脉冲激励实验，基于理想激波管理论建立初始激波幅值预测方法，并研究激励方向和声腔长径比对冲击幅值、声腔特征频率和1阶纵向模态（1L）衰减系数等的影响规律。研究结果表明：脉冲枪在10MPa背压下最高产生了1.63MPa的冲击幅值，且冲击幅值与声腔长径比相关；随着声腔长径比的减小，脉冲激励引起的主导振荡模式从纵向模态转变为切向和高频叠加模态；发展了基于互相关分析和能量守恒的两种平均声速识别和预估方法，并由反推出的温度计算了理论特征频率，与实验值偏差最大为6.24%；不同激励方向下1L衰减系数偏差不超过8.8%，轴向激励实验的1L衰减系数与每个声腔的1L特征频率近似呈线性关系。

Abstract

For the dynamic combustion stability assessment of rocket engines

a pulse gun is developed to investigate the acoustic response characteristics of high-pressure acoustic chamber under pulse excitation. Axial and radial pulse excitation experiments are conducted on five acoustic chambers (

L/D

ratios:0.6-5.1) under 10MPa back pressure. A prediction method for initial shock wave amplitude is established based on the theory of ideal shock tube. The effects of exci

tation direction and chamber

L/D

ratio on the shock amplitude

the eigenfrequency of acoustic chamber and the attenuation coefficient of the first-order longitudinal (1L) mode are also analyzed. The pulse gun produces a maximum shock amplitude of 1.63MPa under 10MPa back pressure

which is correlated with chamber

L/D

ratio. As the

L/D

ratio decreases

the dominant oscillation mode transitions from longitudinal mode to tangential and highfrequency superposition mode. Two average sound speed estimation methods are developed based on cross correlation analysis and energy conservation. The theoretical eigenfrequencies calculated from reversederived temperatures deviate by up to 6.24% from experimental values. The attenuation coefficient (

) deviations of 1L mode under different excitation directions are less than 8.8%

and

demonstrates a linear correlation with 1L eigenfrequency.

关键词

Keywords

references

URBANO A, SELLE L, STAFFELBACH G, et al. Exploration of combustion instability triggering using large eddy simulation of a multiple injector liquid rocket engine [J]. Combustion and Flame, 2016, 169:129-140.

哈杰D T，里尔登F H.液体推进剂火箭发动机不稳定燃烧[M].朱宁昌，张宝炯，译.北京：国防工业出版社，1980.

HARRJE D T, REARDON F H.Liquid propellant rocket combustion instability [M]. ZHU N C, ZHANG B J, translated. Beijing: National Defense Industry Press, 1980. (in Chinese)

D'ALESSANDRO S, FREZZOTTI M L, FAVINI B, et al. Driving mechanisms in low-order modeling of longitudinal combustion instability [J]. Journal of Propulsion and Power, 2023, 39 (5): 754-764.

ZOLLA P M, MONTANARI A, GROSSI M, et al. Low-order modeling of combustion instability:a comprehensive analysis of the BKD test case [C]∥Proceedings of AIAA SciTech Forum and Exposition. Orlando, FL, US:AIAA, 2024.

ZOLLA P M, MONTANARI A, D'ALESSANDRO S, et al. Loworder modeling approach for the prediction of transverse combustion instabilities in multi-injector engines [J]. CEAS Space Journal, 2024, 16 (6): 635-657.

ZHANG X, LIU Y, ZHONG M, et al. Prediction method for instability boundaries of self-excited oscillation combustion in a model combustor [J]. Combustion Science and Technology, 2025, 197 (5): 857-873.

LI X Y, XU B, LI X S, et al. Effects of multiplicative and additive colored noises on the stability of a simplified thermoacoustic combustor [J]. Combustion and Flame, 2023, 249:112413.

XU G Y, WANG B, JIN B N, et al. Numerical study of triggered thermoacoustic instability driven by linear and nonlinear combustion response in a solid rocket motor [J]. Physics of Fluids, 2024, 36 (3): 034110.

XIONG J T, MORGAN H, KRIEG J, et al. Nonlinear combustion instability in a multi-injector rocket engine [J]. AIAA Journal, 2020, 58 (1): 219-235.

REN Y J, GUO K K, FENG S J, et al. Experimental and numerical study of nonlinear growth process of self-excited combustion instability in a model rocket combustor [J]. Proceedings of the Combustion Institute, 2024, 40 (1-4): 105221.

REARDON F H. Guidelines for combustion stability specifications and verification procedures for liquid propellant rocket engines [R]. Baltimore, MD, US:Johns Hopkins University, 1973.

丁兆波，许晓勇，乔桂玉，等.氢氧火箭发动机动态燃烧稳定性评定技术研究[J].导弹与航天运载技术，2013（1）：38-41.

DING Z B, XU X Y, QIAO G Y, et al. Dynamic combustion stability rating of LOX/LH 2 rocket engine [J ] . Missiles and Space Vehicles, 2013 (1): 38-41. (in Chinese)

KIM H J, SEO S, LEE K J. Stability rating tests for the lengthoptimization of baffles in a liquid propellant combustion chamber using a pulse gun [J]. Aerospace Science and Technology, 2008, 12 (3): 214-222.

OSBORNE R J, HULKA J R, MCCAY T D. Development and testing of pulse guns for combustion instability testing [C]∥Proceedings of AIAA Propulsion and Energy Forum. Reston, VA, US:AIAA, 2021:3640.

曾佳进，李军伟，李强，等.触发激励下固体火箭发动机声腔特性实验[J].兵工学报，2025，46（2）：240162.

ZENG J J, LI J W, LI Q, et al. Experimental study on acoustic property of solid rocket motor under pulse triggering [J]. Acta Armamentarii, 2025, 46 (2): 240162. (in Chinese)

张文昊，李军伟，曾佳进，等.脉冲触发对固体火箭发动机内弹道压强抬升的影响[J].固体火箭技术，2024，47（3）：310-320.

ZHANG W H, LI J W, ZENG J J, et al. Effect of pulse triggering on internal ballistic pressure rise of solid rocket motor [J]. Journal of Solid Rocket Technology, 2024, 47 (3): 310 - 320. (in Chinese)

卢健程，李军伟，张文昊，等.脉冲触发对固体火箭发动机内弹道和瞬态流场特性的影响[J].兵工学报，2025，46（1）：240013.

LU J C, LI J W, ZHANG W H, et al. Effect of pulse triggering on internal ballistics and transient flow field characteristics of solid rocket motor [J]. Acta Armamentarii, 2025, 46 (1): 240013. (in Chinese)

金秉宁，刘佩进，魏祥庚，等.基于T型燃烧器的非线性不稳定参数分析[J].固体火箭技术，2016，39（3）：301-305.

JIN B N, LIU P J, WEI X G, et al. Parameter analysis of nonlinear combustion instability based on T-burner [J]. Journal of Solid Rocket Technology, 2016, 39 (3): 301-305. (in Chinese)

李娟，王占利，王栋，等.某型固体火箭发动机不稳定燃烧仿真分析与试验[J].固体火箭技术，2018，41（2）：151-155.

LI J, WANG Z L, WANG D, et al. Simulation analysis and experiment on discontinuous combustion of a solid rocket motor [J]. Journal of Solid Rocket Technology, 2018, 41 (2): 151-155. (in Chinese)

SWARNALATHA K V, RANI S L. Triggered longitudinal instabilities in a combustion chamber: role of acoustic and combustion nonlinearities [J]. Nonlinear Dynamics, 2025, 113 (1): 109-162.

COMBS L P, HOEHN F W, WEBB S R, et al. Combustion stability rating techniques, final report:AFRPL-TR-66-229[R]. Canoga Park, LA, CA, US:Rocketdyne, 1966.

BRODE H L. Blast wave from a spherical charge [J]. Physics of Fluids, 1959, 2 (2): 217-229.

张秋芳，王宁飞，田维平.小型固体火箭发动机尾部点火器设计方法[J].固体火箭技术，2006，29（5）：341-345.

ZHANG Q F, WANG N F, TIAN W P.Design method for aft-end igniter of small scale-solid rocket motor [J]. Journal of Solid Rocket Technology, 2006, 29 (5): 341-345. (in Chinese)

杨尚荣，尚帅，于涵.4种激励方式下声模态衰减率的识别[J].火箭推进，2025，51（1）：102-110.

YANG S R, SHANG S, YU H.Decay rate identification of acoustic modes under four different forms of excitation [J]. Journal of Rocket Propulsion, 2025, 51 (1): 102-110. (in Chinese)

苏万兴.大长径比固体火箭发动机不稳定燃烧预示及抑制方法研究[D].北京：北京理工大学，2015.

SU W X.Prediction and suppression methods of combustion instability in large aspect ratio solid rocket motors [D]. Beijing: Beijing Institute of Technology, 2015. (in Chinese)

谭智杰，李军伟，张文昊，等.大长径比固体火箭发动机一阶纵向不稳定燃烧判据[J].固体火箭技术，2023，46（1）：25-31.

TAN Z J, LI J W, ZHANG W H, et al. Design criterion of the firstorder longitudinal combustion instability for solid rocket motor with large aspect ratio [J]. Journal of Solid Rocket Technology, 2023, 46 (1): 25-31. (in Chinese)

杜功焕，朱哲民，龚秀芬.声学基础[M].南京：南京大学出版社，2001.

DU G H, ZHU Z M, GONG X F.Fundamentals of acoustics [M]. Nanjing: Nanjing University Press, 2001. (in Chinese)

Views

下载量

CNKI被引量

Alert me when the article has been cited

提交

Tools

Publicity Resources

Experimental Study on Acoustic Property of Solid Rocket Motor under Pulse Triggering

Reflection of Charge Explosion Shock Wave from Concrete Floor

Related Author

WANG Ningfei

LI Xinyan

LI Junwei

LI Tao

TANG Yong

SHI Baolu

LI Ji

Junwei LI

Related Institution

Beijing Institute of Technology

School of Aerospace Engineering, Beijing Institute of Technology

Postal code：100089
Tel：010-68963060/68962718 Fax：010-68963025 Email：bgxb@cos.org.cn
Technical support is provided by Beijing Founder electronics co., LTD 京ICP备05059581号-4 京公网安备11010802024360号
It is recommended to read the content of this site in Chrome&IE9+. Please switch to extreme mode in browser 360.
Cookies We use cookies to help provide and enhance our service and tailor content. By continuing, you agree to the use of cookies.
Total Visits：128316 Visits Today：432

⁰