«Previous Article|Table of Contents|Next Article»

《火箭推进》[ISSN:1672-9374/CN:CN 61-1436/V]

Issue:

2021年06期

Page:

101-110

Research Field:

专刊

Publishing date:

Info

Title:

Experimental study on propagation mode of detonation wave in annular channel

Author(s):

YUAN Xueqiang; JIANG Luxin; ZHANG Duo; LIU Shijie

(Science and Technology on Scramjet Laboratory,National University of Defense Technology,Changsha 410073,China)

Keywords:

rotating detonation engine annular channel propagation mode experimental study wave structure velocity distribution

PACS:

V439

DOI:

-

Abstract:

The design of the annular combustion chamber is a key factor affecting the performance of a rotating detonation engine. Studying the propagation process of the detonation wave through the annular channel can provide a powerful guide for the design of the combustion chamber. In order to systematically study this propagation process and its propagation mode,the flow field shadow observation method is used to experimentally observe the propagation of detonation wave through the annular channel,and the propagation mode is divided in detail based on the influence of the inner and outer walls of the channel.The formation mechanism and velocity characteristics of each propagation mode are analyzed. The research results indicate that the propagation mode of detonation wave can be divided into unstable and stable propagation modes according to whether the wave front is decoupled. While considering the change of the Mach-stem,the propagation mode can be subdivided into Mach-stem growing type,steady type and decaying type. In the unstable propagation mode,the wave velocity experiences obvious attenuation while the velocity is relatively steady in the stable propagation mode,the detonation wave front near the outer wall is overdriven,and the overdriven degree increases with the attenuation of the Mach-stem. With the increase of the initial pressure,the ability of the detonation wave in realizing stable propagation is enhanced,and the Mach-stem shows a growing-steady-decaying transition trend,while the increase of the ratio of the wall curvature radius to the channel width makes the Mach-stem present a decaying-steady-growing transition law.

References:

[1] 李自然,林志勇,韩旭. 超声速斜爆震发动机起爆过程研究综述[J].火箭推进,2013,39(3):1-8.
LI Z R,LIN Z Y,HAN X. Investigation for initiation process of supersonic oblique detonation engine[J].Journal of Rocket Propulsion,2013,39(3):1-8.
[2] 邱华,何有权,门凯. 流体喷管的脉冲爆震发动机出口过膨胀优化数值研究[J].火箭推进,2021,47(1):29-35.
QIU H,HE Y Q,MEN K. Numerical study on overexpansion optimization of pulse detonation engine with fluidic nozzle[J].Journal of Rocket Propulsion,2021,47(1):29-35.
[3] LIU S J,LIN Z Y,LIU W D,et al.Experimental and three-dimensional numerical investigations on H₂/air continuous rotating detonation wave[J].Proceedings of the Institution of Mechanical Engineers,Part G:Journal of Aerospace Engineering,2013,227(2):326-341.
[4] FROLOV S M,AKSENOV V S,IVANOV V S,et al.Large-scale hydrogen-air continuous detonation combustor[J].International Journal of Hydrogen Energy,2015,40(3):1616-1623.
[5] LIU Y,ZHOU W J,YANG Y J,et al.Numerical study on the instabilities in H₂-air rotating detonation engines[J].Physics of Fluids,2018,30(4):046106.
[6] LIU S J,HUANG S Y,PENG H Y,et al.Characteristics of methane-air continuous rotating detonation wave in hollow chambers with different diameters[J].Acta Astronautica,2021,183:1-10.
[7] THOMAS G O,WILLIAMS R L. Detonation interaction with wedges and bends[J].Shock Waves,2002,11(6):481-492.
[8] LEE S H,CHO D R,CHOI J Y. Effect of curvature on the detonation wave propagation characteristics in annular channels[C]//46th AIAA Aerospace Sciences Meeting and Exhibit.Reston,Virigina:AIAA,2008.
[9] KUDO Y,NAGURA Y,KASAHARA J,et al.Oblique detonation waves stabilized in rectangular-cross-section bent tubes[J].Proceedings of the Combustion Institute,2011,33(2):2319-2326.
[10] NAKAYAMA H,MORIYA T,KASAHARA J,et al.Front shock behavior of stable detonation waves propagating through rectangular cross-section curved channels[C]//50th AIAA Aerospace Sciences Meeting including the New Horizons Forum and Aerospace Exposition. Reston,Virginia:AIAA,2012.
[11] NAKAYAMA H,MORIYA T,KASAHARA J,et al.Stable detonation wave propagation in rectangular-cross-section curved channels[J].Combustion and Flame,2012,159(2):859-869.
[12] NAKAYAMA H,KASAHARA J,MATSUO A,et al.Front shock behavior of stable curved detonation waves in rectangular-cross-section curved channels[J].Proceedings of the Combustion Institute,2013,34(2):1939-1947.
[13] PAN Z H,CHEN K P,QI J,et al.The propagation characteristics of curved detonation wave:Experiments in helical channels[J].Proceedings of the Combustion Institute,2019,37(3):3585-3592.
[14] PAN Z H,QI J,PAN J F,et al.Fabrication of a helical detonation channel:Effect of initial pressure on the detonation propagation modes of ethylene/oxygen mixtures[J].Combustion and Flame,2018,192:1-9.
[15] SUGIYAMA Y,NAKAYAMA Y,MATSUO A,et al.Numerical investigations on detonation propagation in a two-dimensional curved channel[J].Combustion Science and Technology,2014,186(10/11):1662-1679.
[16] YUAN X Q,ZHOU J,LIN Z Y,et al.Adaptive simulations of detonation propagation in 90-degree bent tubes[J].International Journal of Hydrogen Energy,2016,41(40):18259-18272.
[17] SHORT M,CHIQUETE C,QUIRK J J. Propagation of a stable gaseous detonation in a circular arc configuration[J].Proceedings of the Combustion Institute,2019,37(3):3593-3600.
[18] XIA Z J,MA H,ZHUO C F,et al.Propagation process of H₂/air rotating detonation wave and influence factors in plane-radial structure[J].International Journal of Hydrogen Energy,2018,43(9):4609-4622.
[19] YUAN X Q,ZHOU J,MI X C,et al.Numerical study of cellular detonation wave reflection over a cylindrical concave wedge[J].Combustion and Flame,2019,202:179-194.
[20] LI J,REN H L,NING J G. Numerical application of additive Runge-Kutta methods on detonation interaction with pipe bends[J].International Journal of Hydrogen Energy,2013,38(21):9016-9027.
[21] YUAN X Q,ZHOU J,LIU S J,et al.Diffraction of cellular detonation wave over a cylindrical convex wall[J].Acta Astronautica,2020,169:94-107.

Memo

Memo:

-

Common functions

Last Update: 1900-01-01