爆ばく轰

爆ばく轰（Detonation）是これ火ひ釋放しゃくほう能のう量りょう的てき兩りょう種たね之の一いち。^[1]爆ばく轰是超ちょう声こえ速そく的てき急きゅう烈れつ燃もえ烧，当とう超ちょう声こえ速そく的てき放ひ热锋加速かそく通どおり过介质并形成けいせい冲击波は锋。超ちょう音速おんそく的てき爆ばく炸亦また屬ぞく爆ばく轟とどろき。^[1]火ひ另一いち種しゅ釋放しゃくほう能のう量りょう的てき方式ほうしき稱しょう緩なる燃もえ，兩りょう種たね方式ほうしき都と有ゆう俗稱ぞくしょう「爆ばく燃もえ」造成ぞうせい混淆こんこう。

爆ばく轰可以发生せい在ざい固体こたい和わ液体えきたい爆ばく炸，也可以发生せい在ざい活性かっせい气体。在ざい固体こたい和わ液体えきたい中ちゅう的てき爆ばく轰比气体中ちゅう的てき爆ばく轰速度そくど高だか得とく多た，使つかい得とく波は可か以被更さら细致地ち观测。许多种类的てき燃料ねんりょう处于气态、液えき滴しずく雾态或ある悬浮尘可发生爆ばく轰。氧化剂包括ほうかつ卤素、臭におい氧、过氧化か氢和氮氧化物ばけもの。气态爆ばく轰通常会じょうかい发生在ざい燃料ねんりょう和わ氧化剂的混合こんごう比例ひれい略りゃく低てい于通常つうじょう的てき燃もえ点てん。乙おつ炔、臭におい氧、过氧化か氢，可か在ざい没ぼつ有ゆう氧气的てき情じょう况下发生爆ばく轰。

爆ばく轰于1881年ねん由ゆかり两组法ほう国こく科学かがく家かMarcellin Berthelot, P. Vieille ^[2] 和かず Ernest-François Mallard, Henry Louis Le Chatelier ^[3] 分ぶん别发现。数学すうがく上じょう，David Chapman ^[4] 于1899预言了りょう这一传播现象，其后Émile Jouguet ^[5] ^[6]^[7] 在ざい20世せい纪初也进行ぎょう了りょう相しょう关的研究けんきゅう。在ざい20世せい纪四十じゅう年代ねんだい，Zeldovich，von Neumann和わDoering对爆轰现象ぞう的てき进一步理解作出了重要的贡献。

理り论

19世せい纪末20世せい纪初，Chapman和わJouguet分ぶん别对爆ばく轰现象ぞう进行了りょう研究けんきゅう，他た们的理り论是描述气体中ちゅう的てき爆ばく轰现象ぞう最さい简单的てき理り论，通常つうじょう被ひ称しょう为Chapman-Jouguet理り论。他た们用一いち组简单的代数だいすう方かた程ほど来らい描述爆ばく轰过程ほど放ひ热锋与冲击波は的てき传播。Zeldovich ^[8]，von Neumann ^[9] 和かずDoering ^[10] 在ざい第だい二次世界大战期间分别提出了更复杂的爆轰理论，也被称しょう为ZND理り论。

这两种理论都描述了りょう一维稳态波锋，20世せい纪六ろく十じゅう年代ねんだい，实验发现气相爆ばく轰通常つうじょう是ぜ不ふ稳定的てき且具有ぐゆう三さん维结构，只ただ在ざい平均へいきん的てき意い义下可か以被这些一维稳态理论所描述。Wood-Kirkwood爆ばく轰理论从一些方面可以弥补这些限制^[11]。

目前もくぜん尚なお无理论能描述这些结构是ぜ如何いか形成けいせい和わ持じ续的。

应用

在ざい爆ばく炸仪器き中ちゅう，爆ばく轰对周しゅう围区域くいき带来的てき损伤主要しゅよう来き源みなもと超ちょう音速おんそく的てき冲击波は。与あずか爆ばく燃もえ的てき亚音速そく热锋和わ较小的てき最大さいだい压强，爆ばく轰通常つうじょう更さら具ぐ破やぶ坏性，而爆燃もえ则更多用たよう于武器き发射。然しか而爆轰也有ゆう一些其他不那么具有破坏性的应用，比ひ如表面めん清きよし洁和镀膜，爆ばく轰焊接せっ等とう。爆ばく轰脉冲也可用かよう于航天てん器き推进 ^[12] ^[13]。

引擎和わ火器かき

在ざい使用しよう爆ばく燃もえ过程的てき设备中ちゅう，意外いがい的てき爆ばく轰过程ほど会かい引发一いち些问题。在ざい内燃ないねん机つくえ中ちゅう，这一现象通常称为爆震或敲缸，这会使し得とく引擎动力输出减少、过热甚至部ぶ件けん损坏。在ざい火器かき中ちゅう，爆ばく轰可能かのう导致致命ちめい的てき灾难和わ危险。

参考さんこう文献ぶんけん

^ ^1.0 ^1.1 Detonation and Deflagration: What Is The Difference?. Safetell Security, U.K. （原始げんし内容ないよう存そん档于2020-06-11）. DETONATION is a quick and explosive form of fire. [...] DEFLAGRATION is a slow catching fire. Ordinary fire and most explosions are instances of deflagration. Deflagration fires are usually controllable and can be harnessed.[...] Combustion takes different forms. When a decomposition reaction or combination reaction releases a lot of energy in a very short span of time, an explosion may occur. Deflagration and detonation are two ways energy may be released. If the combustion process propagates outward at subsonic speeds, it’s a deflagration. If the explosion moves outward at supersonic speeds, it’s a detonation."
^ M. Berthelot and P. Vieille, “On the velocity of propagation of explosive processes in gases,” Comp. Rend. Hebd. Séances Acad. Sci., Vol. 93, pp. 18-21, 1881
^ E. Mallard and H. L. Le Chatelier, “On the propagation velocity of burning in gaseous explosive mixtures,” Comp. Rend. Hebd. Séances Acad. Sci., Vol. 93, pp. 145-148, 1881
^ Chapman, D. L. (1899). VI. On the rate of explosion in gases. The London, Edinburgh, and Dublin Philosophical Magazine and Journal of Science, 47(284), 90-104.
^ Jouguet, E. (1905). On the propagation of chemical reactions in gases. J. de mathematiques Pures et Appliquees, 1(347-425), 2.
^ Jouguet, E. J. (1906). Mathem. Pures Appl. 1. 1905. P. 347-425. And 2.
^ Jouguet, É. (1917). L'œuvre scientifique de Pierre Duhem. Doin.
^ Zel'dovich; Kompaneets. Theory of Detonation. New York: Academic Press. 1960. ASIN B000WB4XGE. OCLC 974679.
^ von Neumann, John. Progress report on "Theory of Detonation Waves" (报告). 1942 [2019-11-13]. OSRD Report No. 549. Ascension number ADB967734. （原始げんし内容ないよう存そん档于2011-07-17）.
^ Doring, W. Über den Detonationsvorgang in Gasen. Annalen der Physik. 1943, 43 (6–7): 421–436. Bibcode:1943AnP...435..421D. doi:10.1002/andp.19434350605.
^ Glaesemann, Kurt R.; Fried, Laurence E. Improved wood–kirkwood detonation chemical kinetics. Theoretical Chemistry Accounts. 2007, 120 (1–3): 37–43 [2019-11-13]. doi:10.1007/s00214-007-0303-9. （原始げんし内容ないよう存そん档于2021-03-06）.
^ Kailasanath, K. Review of Propulsion Applications of Detonation Waves. AIAA Journal. 2000, 39 (9): 1698–1708. Bibcode:2000AIAAJ..38.1698K. doi:10.2514/2.1156.
^ Norris, G. Pulse Power: Pulse Detonation Engine-powered Flight Demonstration Marks Milestone in Mojave. Aviation Week & Space Technology. 2008, 168 (7): 60 [2019-11-13]. （原始げんし内容ないよう存そん档于2019-04-01）.

[safetell-1] 1.0 ^1.1 Detonation and Deflagration: What Is The Difference?. Safetell Security, U.K. （原始げんし内容ないよう存そん档于2020-06-11）. DETONATION is a quick and explosive form of fire. [...] DEFLAGRATION is a slow catching fire. Ordinary fire and most explosions are instances of deflagration. Deflagration fires are usually controllable and can be harnessed.[...] Combustion takes different forms. When a decomposition reaction or combination reaction releases a lot of energy in a very short span of time, an explosion may occur. Deflagration and detonation are two ways energy may be released. If the combustion process propagates outward at subsonic speeds, it’s a deflagration. If the explosion moves outward at supersonic speeds, it’s a detonation."

[2] M. Berthelot and P. Vieille, “On the velocity of propagation of explosive processes in gases,” Comp. Rend. Hebd. Séances Acad. Sci., Vol. 93, pp. 18-21, 1881

[3] E. Mallard and H. L. Le Chatelier, “On the propagation velocity of burning in gaseous explosive mixtures,” Comp. Rend. Hebd. Séances Acad. Sci., Vol. 93, pp. 145-148, 1881

[4] Chapman, D. L. (1899). VI. On the rate of explosion in gases. The London, Edinburgh, and Dublin Philosophical Magazine and Journal of Science, 47(284), 90-104.

[5] Jouguet, E. (1905). On the propagation of chemical reactions in gases. J. de mathematiques Pures et Appliquees, 1(347-425), 2.

[6] Jouguet, E. J. (1906). Mathem. Pures Appl. 1. 1905. P. 347-425. And 2.

[7] Jouguet, É. (1917). L'œuvre scientifique de Pierre Duhem. Doin.

[8] Zel'dovich; Kompaneets. Theory of Detonation. New York: Academic Press. 1960. ASIN B000WB4XGE. OCLC 974679.

[9] von Neumann, John. Progress report on "Theory of Detonation Waves" (报告). 1942 [2019-11-13]. OSRD Report No. 549. Ascension number ADB967734. （原始げんし内容ないよう存そん档于2011-07-17）.

[10] Doring, W. Über den Detonationsvorgang in Gasen. Annalen der Physik. 1943, 43 (6–7): 421–436. Bibcode:1943AnP...435..421D. doi:10.1002/andp.19434350605.

[11] Glaesemann, Kurt R.; Fried, Laurence E. Improved wood–kirkwood detonation chemical kinetics. Theoretical Chemistry Accounts. 2007, 120 (1–3): 37–43 [2019-11-13]. doi:10.1007/s00214-007-0303-9. （原始げんし内容ないよう存そん档于2021-03-06）.

[12] Kailasanath, K. Review of Propulsion Applications of Detonation Waves. AIAA Journal. 2000, 39 (9): 1698–1708. Bibcode:2000AIAAJ..38.1698K. doi:10.2514/2.1156.

[13] Norris, G. Pulse Power: Pulse Detonation Engine-powered Flight Demonstration Marks Milestone in Mojave. Aviation Week & Space Technology. 2008, 168 (7): 60 [2019-11-13]. （原始げんし内容ないよう存そん档于2019-04-01）.

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理り论

应用

引擎和わ火器かき

相關そうかん條目じょうもく

参考さんこう文献ぶんけん