圆盘旋转爆震燃烧室中爆震波传播模态

doi:10.13675/j.cnki.tjjs.200503

推进技术 ›› 2021, Vol. 42 ›› Issue (4): 865-873.DOI: 10.13675/j.cnki.tjjs.200503

圆盘旋转爆震燃烧室中爆震波传播模态

沈吴冰懿，黄玥，尤延铖，黄鸿涛

厦门大学航空航天学院，福建厦门 361102

出版日期:2021-04-15 发布日期:2021-04-15
作者简介:沈吴冰懿，博士生，研究领域为旋转爆震和超燃冲压发动机。E-mail：swby4444@gmail.com
基金资助:
国家自然科学基金（51876182；51406171；11972331）；中央高校基础研究基金（20720180058）。

Propagation Mode of Detonation Wave in a Plane-Radial Rotating Detonation Combustion Chamber

School of Aerospace Engineering，Xiamen University，Xiamen 361102，China

Online:2021-04-15 Published:2021-04-15

摘要/Abstract

摘要： 为了研究圆盘结构下旋转爆震波传播特性，通过求解14组分19步CH₄/O₂反应的欧拉方程，数值模拟了不同燃料喷射温度、压力、燃烧室内外直径比值和燃烧室径向长度并分析了其对旋转爆震波传播模态的影响。研究表明，只有预混气喷射温度为500~900K，喷射压力为0.5~3.5MPa的条件下能够在固定燃烧室内形成连续的旋转爆震波。受燃烧室结构影响，旋转爆震波的传播模态分为稳定模态和非稳定模态。整个非稳定传播模态根据爆震波对前周期的干涉又可以分为干涉阶段和不干涉阶段。在不干涉阶段，爆震波传播速度略高于C-J（Chapman-Jouguet）速度；在干涉阶段，爆震波传播速度低于C-J速度且爆震波被间断面分割成两部分。非稳定模态爆震波传播速度小于稳定模态，而爆震波夹角、燃烧室出口面积比则反之。

关键词: 径向长度;内外直径比值;传播模态;数值模拟;旋转爆震;燃烧室

Abstract: In order to study the propagation characteristics of the rotating detonation wave in a plane-radial rotating detonation combustor， Euler equation with 14 species-19 reactions methane/oxygen reaction mechanism were solved. Numerical simulations were conducted to study the effects of injection temperature，pressure，inlet and outer diameter ratio and radial length on the rotating detonation wave propagation mode. The results show that a continuous rotating detonation wave is formed in the fixed combustion chamber with the pre-mixed injection temperature of 500~900K and the injection pressure of 0.5~3.5MPa. With the effect of the combustor structure， propagation modes of rotating detonation waves are divided into stable mode and unstable mode. The entire unstable propagation mode can be divided into two stages based on the interference of the detonation wave to the previous period： the interference stage and the non-interference stage. In the non-interference stage， the propagation speed of the detonation wave is higher than the C-J （Chapman-Jouguet） speed. In the interference stage， the propagation speed of the detonation wave is lower than the C-J speed， and the detonation wave is divided into two parts by the discontinuous surface. The propagation speed of the detonation wave in the stable mode is higher than that in the unstable mode， while the angle of detonation wave and combustor outlet area ratio are reversed.

Key words: Radial length;Inlet and outer diameter ratio;Propagation mode;Numerical simulation;Rotating detonation;Combustion chamber

沈吴冰懿，黄玥，尤延铖，黄鸿涛. 圆盘旋转爆震燃烧室中爆震波传播模态[J]. 推进技术, 2021, 42(4): 865-873.

SHEN Wu-bing-yi, HUANG Yue, YOU Yan-cheng, HUANG Hong-tao. Propagation Mode of Detonation Wave in a Plane-Radial Rotating Detonation Combustion Chamber[J]. Journal of Propulsion Technology, 2021, 42(4): 865-873.

参考文献

[1] 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）.
[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] Nakagami S， Matsuoka K， Kasahara J， et al. Experimental Visualization of the Structure of Rotating Detonation Waves in a Disk-Shaped Combustor［J］. Journal of Propulsion and Power， 2016， 33（1）： 1-9.
[4] Nakagami S， Matsuoka K， Kasahara J， et al. Experimental Study of the Structure of Forward-Tilting Rotating Detonation Waves and Highly Maintained Combustion Chamber Pressure in a Disk-Shaped Combustor［J］. Proceedings of the Combustion Institute， 2016， 36（2）.
[5] Higashi J， Nakagami S， Matsuoka K， et al. Experimental Study of the Disk-Shaped Rotating Detonation Turbine Engine［C］. Grapevine： 55th AIAA Aerospace Sciences Meeting， 2017.
[6] 夏镇娟，周胜兵，马虎，等. 圆盘结构下旋转爆震波传播特性的实验研究［J］. 爆炸与冲击， 2018， 38（5）： 937-947.
[7] Xia Z， Ma H， Liu C， et al. Experimental Investigation on the Propagation Mode of Rotating Detonation Wave in Plane-Radial Combustor［J］. Experimental Thermal and Fluid Science， 2019， 103： 364-376.
[8] Scott A B. Flow Behavior in Radial Rotating Detonation Engines［D］ Ohio： Wright-Patterson Air Force Base， 2019.
[9] Scott A B， Marc D P， Riley H. et al. Experimental Flow Visualization in a Radial Rotating Detonation Engine［C］. San Diego： AIAA SciTech Forum， 2019.
[10] Huff R， Polanka M D， McClearn M J， et al. A Disk Rotating Detonation Engine Driven Auxiliary Power Unit［C］. Cincinnati： AIAA Propulsion and Energy Forum， 2018.
[11] McClearn M J， Schauer F R， Huff R， et al. A Disk Rotating Detonation Engine Part 2： Operation［C］. Kissimmee： AIAA Aerospace Sciences Meeting， 2018.
[12] Huff R， Polanka M D， McClearn M J， et al. A Disk Rotating Detonation Engine Part 1： Design and Buildup［C］. Kissimmee： AIAA Aerospace Sciences Meeting， 2018.
[13] 夏镇娟，马虎，葛高杨，等. 当量比对圆盘结构下旋转爆震波传播的影响［J］. 气体物理， 2019，（6）： 1-10.
[14] Xia Z， Ma H， Zhuo C， 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.
[15] Watanabe T， Jourdaine N H， Tsuboi N， et al. Three-dimensional Numerical Simulation of Disk Rotating Detonation Engine；Unsteady Flow Structure［C］. San Diego： AIAA Scitech 2019 Forum， 2019.
[16] 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.
[17] 夏镇娟，马虎，卓长飞，等. 圆盘结构下旋转爆震波的非稳定传播特性［J］. 航空学报， 2018， 39（2）.
[18] Ishiyama C， Miyazaki K， Nakagami S， et al. Experimental Study of Research of Centrifugal-Compressor-Radial-Turbine Type Rotating Detonation Engine［C］. Salt Lake： 52nd AIAA/SAE/ASEE Joint Propulsion Conference， 2016.
[19] Bykovskii F A， Zhdan S A， Vedernikov E F， et al. Detonation Combustion of Coal［J］. Combustion， Explosion and Shock Waves， 2012， 48（2）： 203-208.
[20] Bykovskii F A， Zhdan S A， Vedernikov E F， et al. Continuous Spin Detonation of a Coal-Air Mixture in a Flow-Type Plane-Radial Combustor［J］. Combustion， Explosion and Shock Waves， 2013， 49（6）： 705-711.
[21] 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.
[22] Bykovskii F A， Zhdan S A， Vedernikov E F， et al. Continuous and Pulsed Detonation of a Coal-Air Mixture［J］. Doklady Physics， 2010， 55（3）： 142-144.
[23] 王超. 吸气式连续旋转爆震波自持传播机制研究［D］. 长沙：国防科技大学， 2016.
[24] Dong G， Liu H， Chen Y. General， Nitrogen-Containing Semi-Detailed Chemical Kinetic Mechanism for Methane Laminar Premixed Flame［J］. Combustion Science and Technology， 2002，（8）： 44-48.
[25] 王健平，姚松柏. 连续爆轰发动机原理与技术［M］. 北京：科学出版社， 2018.

圆盘旋转爆震燃烧室中爆震波传播模态

Propagation Mode of Detonation Wave in a Plane-Radial Rotating Detonation Combustion Chamber

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