气相爆轰物理的若干研究进展

姜宗林; 滕宏辉; 刘云峰

doi:10.6052/1000-0992-2012-2-20120202

气相爆轰物理的若干研究进展

doi: 10.6052/1000-0992-2012-2-20120202

中国科学院力学研究所, 高温气体动力学国家重点实验室, 北京100190

基金项目: 国家自然科学基金项目(90916028)资助

详细信息

通讯作者:
姜宗林

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出版历程
- 收稿日期: 2011-06-08
- 修回日期: 2011-07-11
- 刊出日期: 2012-03-25

SOME RESEARCH PROGRESS ON GASEOUS DETONATION PHYSICS

State Key lab of high temperature gas dynamics, Institute of Mechanics, Chinese Academy of Sciences, Beijing 100190, China

Funds: The project was supported by the National Natural Science Foundation of China (90916028).

More Information

Corresponding author: JIANG Zonglin

摘要

摘要: 爆轰现象的研究已经有一百多年的历史了,爆轰物理的研究取得了许多重要进展.本文从爆轰波的经典理论、胞格爆轰波的多波结构、气相爆轰波形成机理、气相爆轰波传播机制等方面综述了相关的若干研究进展,评述了这些进展的科学性与局限性,并探讨了将来可能的研究方向.这些研究进展主要包括:CJ(Chapman-Jouguet)理论和ZND(Zel'dovich,von Neumann,Döring)模型、爆轰波多波结构、爆轰胞格特征、直接起爆和爆燃转爆轰过程、热点起爆机制、爆轰波稳定性、扰动爆轰波的传播等.爆轰波是以超声速传播的自持燃烧现象,涉及了激波相互作用、燃烧化学反应、湍流扩散和流动不稳定性等复杂的气动物理过程,相关研究具有重要的学科理论意义.另外,爆轰燃烧具有高效的热化学能释放特点,在先进的热力推进技术方面有着重要的应用背景,因此相关研究也具有重要的工程应用价值.
- 气相爆轰波 /
- 爆轰波形成 /
- 爆轰波传播 /
- 热点起爆 /
- 胞格结构 /
- 稳定性
Abstract: Research on the detonation phenomena has been conducted for over one hundred years, and many important progresses in the detonation physics have been achieved. In this paper, the classic detonation theories and the multi-wave structure of cellular detonation are reviewed as well as the mechanism of detonation initiation and propagation. Then scientific meaning and limitation are commented and potential future research directions are pointed out. These progresses include the CJ theory and ZND model, detonation multi-wave structure, characteristics of the detonation cell, direct initiation and DDT, hot spot initiation mechanism, detonation stability, the propagation of the disturbed detonation, et al. Gaseous detonations are self-sustained supersonic combustion phenomena, involving shock wave interaction, combustion chemical reactions, turbulence, and hydrodynamic instability. Therefore they are very complicated and have also meaningful theoretical importance. On the other hand, the detonation achieves very efficient heat release and has potential applications in the advanced thermal propulsion technology, which constitutes important engineering background for related studies.
- gaseous detonation /
- detonation initiation /
- detonation propagation /
- hot spot initiation /
- cellular structure /
- instability

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参考文献(86)

1 Kailasanath K. Recent developments in the research on pulse detonation engines. AIAA Journal, 2003, 41(2):145-159

2 Roy G E, Frolov S M, Borisov A A, et al. Pulse detonation propulsion: challenges, current status, and future perspective. Prog Energy Combust Sci, 2004, 30(6): 545-672

3 Viguier C, Gourara A, Desbordes D. There-dimensional structure of stabilization of oblique detonation wave in hypersonic flow. Proceedings of the Combustion Institute,1998, 27(2): 2207-2214

4 Kasahara J, Fujiwara T, Endo T, et al. Chapman-Jouguet oblique detonation structure around hypersonic projectiles. AIAA Journal, 2001, 39(8): 1553-1561

5 Bykovskii F A, Zhdam S A, Vedernikov E F. Realization and modeling of continuous spin detonation of a hydrogenoxygen mixture in flow-type combustors. Combustion, Explosion and Shock Waves, 2009, 45(6): 716-728

6 Wolanski P, Kindracki J, Fujiwara T. An experimental study of small rotating detonation engine. In: Roy G, Frolov S, Sinibaldi J. eds. Pulsed and Continuous Detonations. Moscow: Torus Press, 2006. 332-338

7 Hishida M, Fujiwara T, Wolanski P. Fundamentals of rotating detonations. Shock Waves, 2009, 19(1): 1-10

8 俞鸿儒, 李斌, 陈宏. 激波管氢氧爆轰驱动技术的发展进程. 力学进展, 2005, 35(3): 315-322

9 Jiang Z, Zhao W, Yu H R. Demonstration of some concepts for developing long-test duration shock tunnels. In: Proceedings of 28th Symp on Shock Waves, July 16-23,2011

10 Hillebrandt W, Niemeyer J C. Type Ia supernova explosion models. Annu. Rev. Astron. Astrophys., 2000,38(1): 191-230

11 Berthelot M, Vieille E. On the velocity of propagation of explosive processes in gases. C. R. Hebd. Sceances Acad. Sci., 1881, 93: 18-21

12 Chapman D L. On the rate of explosion in gases. Philos. Mag., 1899, 47: 90-104

13 Jouguet E. On the propagation of chemical reactions in gases. J. De Mathematiques Pures et Appliqquees, 1905,1: 347-425

14 Zel’dovich Y B. On the theory of the propagation of detonation in gaseous systems. Journal of experimental and theoretical physics, 1940, 10: 543-568

15 von Neumann J. Theory of detonation waves. In: John von Neumann. Collected Works. Vol.6, ed. A.J. Taub. New York: Macmillam, 1942

16 Döring W. On detonation processes in gases. Ann. Phys.,1943, 43: 421-436

17 White D R. Turbulent structure in gaseous detonations. Phys. Fluids, 1961, 4: 465-480

18 Soloukhin R. Multi-headed structure of gaseous detonation. Combust. Flame, 1965, 9: 51-58

19 Wang C, Jiang Z, Gao Y. Half -cell law of regular cellular detonation. Chinese Physics Letters, 2008, 25(10):3704-3707

20 Liu Y, Jiang Z. Reconsideration on the role of the specific heat ratio in Arrhenius law applications. Acta Mechanic Sinica, 2008, 24(1): 261-266

21 Lee J H S. Initiation of gaseous detonation. Ann. Rev. Phys. Chem, 1977, 28: 75-104

22 Zel’dovich Y B, Librovich V B, Makhviladze G M, et al. On the development of detonation in a non-uniformly preheated gas. Astronautica Acta, 1970, 15: 312-321

23 Lee J H S, Lee B H K, Knystautas R. Direct initiation of cylindrical gaseous detonations. Phys. Fluids, 1966, 9:221-222

24 Lee J H S. Dynamic parameters of gaseous detonations. Ann. Rev. Fluid Mech., 1984, 16: 311-336

25 Lee J H S, Knystautas R, Frieman A. High-speed turbulent deflagration and transition to detonation in H2-Air mixtures. Combust. Flame, 1984, 56: 227-239

26 Urtiew P, Oppenheim A K. Experimental observation of the transition to detonation in an explosive gas. Proc. Roy. Soc. A, 1966, 295: 13-28

27 Lee J H S, Higgins A J. Comments on criteria for direct initiation of detonation. Phil. Trans. R. Soc. Lond. A,1999, 357: 3503-3521

28 Radulescu M I, Higgins A J, Murray S B. An experimental investigation of the direction initiation of cylindrical detonations. J. Fluid Mech., 2003, 480(1): 1-24

29 Lee J H S, Knystautas R, Yoshikawa N. Photochemical initiation of gaseous detonations. Acta Astronautica, 1978,5:971-982

30 Thomas G O, Jones A. Some observations of the jet initiation of detonation. Combust. Flame, 2000, 120: 392-398

31 Khokhlov A M, Oran E S. Numerical simulation of detonation initiation in a flame brush: the role of hot spots. Combust. Flame, 1999, 119: 400-416

32 Bartenev A M, Gelfand B E. Spontaneous initiation of detonations. Progress in Energy and Combustion Science,2002, 26: 29-55

33 Montgomery C J, Khokhlov A M, Oran E S. The effect of mixing irregularities on mixed-region critical length for deflagration-to-detonation transition. Combust. Flame,1998, 115: 38-50

34 Sharpe G J, Short M. Detonation ignition from a temperature gradient for a two-step chain-branching kinetics model. J. Fluid Mech., 2003, 476: 267-292

35 Ng H D, Lee J H S. Direct initiation of detonation with a multi-step reaction scheme. J. Fluid Mech., 2003, 476(1):179-211

36 Gu X J, Emerson D R, Bradley D. Modes of reaction front propagation from hot spots. Combust. Flame, 2003, 133:63-74

37 Teng H, Jiang Z. Gasdynamics characteristics of toroidal shock and detonation waves focusing. Science in China Series G-Physics and Astronomy, 2005, 48(6): 739-749

38 王春, 张德良, 姜宗林. 多障碍物通道中激波诱导气相爆轰的数值研究. 力学学报, 2006, 38(5): 586-592

39 Oran E S, Gamezo V N. Origins of the deflagration-todetonation transition in gas-phase combustion. Combust. Flame, 2007, 148: 4-47, 586-592

40 Brailovsky I, Sivashinsky G. Hydraulic resistance as a mechanism for deflagrationto-detonation transition. Combust. Flame, 2000, 122: 492-499

41 Kagan L, Sivashinsky G. The transition from deflagration to detonation in thin channels. Combust. Flame, 2003,134: 389-397

42 Kaneshige K, Shepherd J E. Detonation database, explosion dynamics laboratory report FM97-8. California Institute of Technology, Pasadena, CA, September, 1999

43 Gavrikov A I, Efimenko A A, Dorofeev S B. A model for detonation cell size prediction from chemical kinetics. Combust. Flame, 2000, 120: 19-33

44 Oran E S, Weber J W, Stefaniw E I, et al. A numerical study of a two-dimensional H₂-O₂-Ar detonation using a detailed chemical reaction model. Combust. Flame, 1998,113: 147-163

45 Gamezo V N, Desbordes D, Oran E S. Two-dimensional reactive flow dynamics in cellular detonation waves. Shock Waves, 1999, 9: 11-17

46 Gamezo V N, Desbordes D, Oran E S. Formation and evolution of two-dimensional cellular detonations. Combust. Flame, 1999, 116: 154-165

47 Radulescu M I, Lee J H S. The failure mechanism of gaseous detonations: experiments in porous wall tubes. Combust. Flame, 2002, 131: 29-46

48 Sharpe G J. Transverse waves in numerical simulations of cellular detonations. J. Fluid Mech., 2001, 447(1): 31-51

49 Pintgen F, Eckett C A, Austin J M, et al. Direct observations of reaction zone structure in propagating detonations. Combust. Flame, 2003, 133: 211-229

50 Mass L, Austin J M, Jackson T L. Triple-point shear layers in gaseous detonation waves. J. Fluid Mech., 2007,586(2): 205-248

51 Jiang Z, Han G, Wang C, et al. Self-organized generation of transverse waves in diverging cylindrical detonations. Combust. Flame, 2009, 156(8): 1653-1661

52 Williams D N, Bauwens L, Oran E S. Detailed structure and propagation of three-dimensional detonations. Proceedings of the Combustion Institute, 1996, 26(2): 2991-2998

53 Tsuboi N, Katoh S, Hayashi A K. Three-dimensional numerical simulation for hydrogen/air detonation: rectangular and diagonal structures. Proceedings of the Combustion Institute, 2002, 29(2): 2783-2788

54 Tsuboi N, Eto K, Hayashi A K. Detailed structure of spinning detonation in a circular tube. Combust. Flame, 2007,149: 144-161

55 Tsuboi N, Daimon Y, Hayashi A K. Three-demensional numerical simulation of detonations in coaxial tubes. Shock Waves, 2008, 18(5): 379-392

56 Li C, Kailasanath K, Oran E S. Detonation structures behind oblique shocks. Physics of Fluids, 1994, 6(4): 1600-1611

57 Choi J Y, Kim D W, Jeung I S. Cell-like structure of unstable oblique detonation wave from high-resolution numerical simulation. Proceedings of the Combustion Institute,2007, 31(2): 2473-2480

58 董刚, 范宝春, 李鸿志. 圆锥激波诱导的爆燃和爆轰不稳定性研究. 兵工学报, 2010, 31(4): 401-408

59 Bykovskii F A, Zhdan S A, Vedernikov E F. Continuous spin detonations. Journal of Propulsion and Power, 2006,22(6) : 1204-1216

60 张旭东, 范宝春, 归明月, 等. 旋转爆轰的三维结构和侧向稀疏波的影响. 爆炸与冲击, 2010, 30(4): 338-341

61 邵业涛, 王健平, 唐新猛, 等. 连续旋转爆轰发动机流场三维数值模拟. 航空动力学报, 2010, 25(8): 1717-1722

62 Erpenbeck J J. Stability of idealized one-reaction detonations. Phys. Fluids, 1964, 7: 684-696

63 Erpenbeck J J. Nonlinear theory of two-dimensional detonations. Phys. Fluids, 1970, 13: 2007-2026

64 He L, Lee J H S. The dynamical limit of one-dimensional detonations. Phys. Fluids, 1995, 7(5): 1151-1158

65 Sharpe G J, Falle S A E G. One-dimensional numerical simulations of idealized detonations. Proc. R. Soc. Lond. A, 1999, 455: 1203-1214

66 Ng H D, Radulescu M I, Higgins A J, et al. Numerical investigation of the instability for one-dimensional Chapman-Jouguet detonations with chain-branching kinetics. Combustion Theory and Modelling, 2005, 9: 385-401

67 Short M, Quirk J J. On the nonlinear stability and detonability limit of a detonation wave for a model three-step chain-branching reaction. J. Fluid Mech., 1997, 339(1):89-119

68 Watt S D, Sharpe G J. Linear and nonlinear dynamics of cylindrically and spherically expanding detonation waves. J. Fluid Mech., 2005, 522: 329-356

69 Clavin P, He L, Willams F A. Multidimensional stability analysis of overdriven gaseous detonations. Phys. Fluids,1997, 9 (12): 3764-3785

70 Clavin P, Denet B. Diamond patterns in the cellular front of an overdriven detonation. Physical Review Letters,2002, 88: 044502

71 Yao J, Stewart D S. On the dynamics of multi-dimensional detonation waves. J. Fluid Mech., 1996, 309: 225-275

72 Stewart D S. The shock dynamics of multidimensional condensed and gas-phase detonations. Proceedings of the Combustion Institute, 1998, 27(2): 2189-2205

73 Ohyagi S, Obara T, Hoshi S, et al. Diffraction and reinitiation of detonations behind a backward-facing step. Shock Waves, 2002, 12: 221-226

74 Jones D A, Kemister G, Tonello N A, et al. Numerical simulation of detonation reignition in H2-O2 mixtures in area expansions. Shock Waves, 2000, 10: 33-41

75 Arient M, Shepherd J E. A numerical study of detonation diffraction. J. Fluid Mech., 2005, 529: 117-146

76 李辉煌, 朱雨建, 杨基明. 爆轰波通过扩张喷管的双曝光全息实验和数值研究. 爆炸与冲击, 2005, 25(5): 445-450

77 邓博, 胡宗民, 滕宏辉, 等. 变截面管道中爆轰胞格演变机制的数值模拟研究. 中国科学G 辑: 物理学力学天文学,2008, 38(2): 206-216

78 Li H, Ben-Dor G. A modified CCW theory for detonation waves. Combust. Flame, 1998, 113(1): 1-12

79 Thomas G O, Williams R L. Detonation interaction with wedges and bends. Shock Waves, 2002, 11: 481-492

80 Guo C M, Zhang D L, Xie W. The mach reflection of a detonation based on soot track measurements. Combust. Flame, 2001, 127: 2051-2058

81 胡宗民, 高云亮, 张德良, 等. 爆轰波在楔面上反射数值分析. 力学学报, 2004, 7(4): 385-392

82 Hu Z, Jiang Z. Wave dynamic processes in cellular detonation reflection from wedges. Acta Mechanica Sinica,2007, 23(1): 33-41

83 Chao J, Lee J H S. The propagation mechanism of high speed turbulent deflagrations. Shock Waves, 2003, 12:277-289

84 朱雨建, 杨基明, Lee J H S. 两种不同气体中的高速爆燃波及其向爆轰的转变. 实验力学, 2008, 23(2): 110-117

85 Wang C J, Xu S L, Guo C M. Gaseous detonation propagation in a bifurcated tube. J. Fluid Mech., 2008, 599(1):81-110

86 王昌建, 徐胜利, 费立森, 等. 弯管内爆轰波传播的流场显示和数值模拟. 力学学报, 2006, 38(1): 9-15

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气相爆轰物理的若干研究进展

doi: 10.6052/1000-0992-2012-2-20120202

通讯作者:
姜宗林

计量

SOME RESEARCH PROGRESS ON GASEOUS DETONATION PHYSICS

Corresponding author: JIANG Zonglin

计量

目录

留言板

气相爆轰物理的若干研究进展

doi: 10.6052/1000-0992-2012-2-20120202

通讯作者: 姜宗林

计量

出版历程

SOME RESEARCH PROGRESS ON GASEOUS DETONATION PHYSICS

Corresponding author: JIANG Zonglin

计量

出版历程

目录

通讯作者:
姜宗林