O. G. Glotov, “Condensed combustion products of aluminized propellants. IV. Effect of the nature of nitramines on aluminum agglomeration and combustion efficiency”, Fizika Goreniya i Vzryva, 42:4 (2006), 78–92; Combustion, Explosion and Shock Waves, 42:4 (2006), 436

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Fizika Goreniya i Vzryva, 2006, Volume 42, Issue 4, Pages 78–92 (Mi fgv1614)

This article is cited in 43 scientific papers (total in 43 papers)

Condensed combustion products of aluminized propellants. IV. Effect of the nature of nitramines on aluminum agglomeration and combustion efficiency

O. G. Glotov

Institute of Chemical Kinetics and Combustion, Siberian Division, Russian Academy of Sciences, Novosibirsk, 630090

Citations (43)

Abstract: The condensed combustion products of two model propellants consisting of ammonium perchlorate, aluminum, nitramine, and an energetic binder were studied by a sampling method. One of the propellants contained HMX with a particle size

D_{10} \approx 490

$D_{10}\approx490$

μ

$\mu$ m, and the other RDX with a particle size

D_{10} \approx 380

$D_{10}\approx380$

μ

$\mu$ m. The particle-size distribution and the content of metallic aluminum in particles of condensed combustion products with a particle size of

1.2

$1.2$

μ

$\mu$ m to the maximum particle size in the pressure range of

0.1

$0.1$ –

6.5

$6.5$ MPa were determined with variation in the particle quenching distance from the burning surface to

100

$100$ mm. For agglomerates, dependences of the incompleteness of aluminum combustion on the residence time in the propellant flame were obtained. The RDX-based propellant is characterized by more severe agglomeration than the HMX-based propellant – the agglomerate size and mass are larger and the aluminum burnout proceeds more slowly. The ratio of the mass of the oxide accumulated on the agglomerates to the total mass of the oxide formed is determined. The agglomerate size is shown to be the main physical factor that governs the accumulation of the oxide on the burning agglomerate.

Keywords: aluminized propellant, HMX, RDX, agglomeration, condensed combustion products, completeness of aluminum combustion, evolution of agglomerates.

Received: 05.07.2004
Accepted: 06.03.2006

English version:
Combustion, Explosion and Shock Waves, 2006, Volume 42, Issue 4, Pages 436–449
DOI: https://doi.org/10.1007/s10573-006-0073-z

Bibliographic databases:

Document Type: Article

UDC: 536.46

Language: Russian

Citation: O. G. Glotov, “Condensed combustion products of aluminized propellants. IV. Effect of the nature of nitramines on aluminum agglomeration and combustion efficiency”, Fizika Goreniya i Vzryva, 42:4 (2006), 78–92; Combustion, Explosion and Shock Waves, 42:4 (2006), 436–449

Citation in format AMSBIB

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\by O.~G.~Glotov

\paper Condensed combustion products of aluminized propellants. IV.~Effect of the nature of nitramines on aluminum agglomeration and combustion efficiency

\jour Fizika Goreniya i Vzryva

\yr 2006

\vol 42

\issue 4

\pages 78--92

\mathnet{http://mi.mathnet.ru/fgv1614}

\elib{https://elibrary.ru/item.asp?id=16542249}

\transl

\jour Combustion, Explosion and Shock Waves

\yr 2006

\vol 42

\issue 4

\pages 436--449

\crossref{https://doi.org/10.1007/s10573-006-0073-z}

Linking options:

https://www.mathnet.ru/eng/fgv1614

https://www.mathnet.ru/eng/fgv/v42/i4/p78

Cycle of papers

Condensed combustion products of aluminized propellants. 1. A technique for investigating the evolution of disperse-phase particles
O. G. Glotov, V. Ya. Zyryanov
Fizika Goreniya i Vzryva, 1995, 31:1, 74–80
Condensed combustion products of aluminized propellants. II. Evolution of particles with distance from the burning surface
O. G. Glotov
Fizika Goreniya i Vzryva, 2000, 36:4, 66–78
Condensed combustion products of aluminized propellants. III. Effect of an inert gaseous combustion environment
O. G. Glotov
Fizika Goreniya i Vzryva, 2002, 38:1, 105–113
Condensed combustion products of aluminized propellants. IV. Effect of the nature of nitramines on aluminum agglomeration and combustion efficiency
O. G. Glotov
Fizika Goreniya i Vzryva, 2006, 42:4, 78–92

This publication is cited in the following 43 articles:

Shipo LI, Gangchui ZHANG, Zhan WEN, Lu LIU, Xiang LV, Peijin LIU, Wen AO, “Role of AP–HMX mass ratio in combustion and agglomeration of NEPE propellant”, Chinese Journal of Aeronautics, 2025, 103470
Xueqin Liao, Jiangfeng Pei, Peini Xie, Yiwen Hu, Jianzhong Liu, “Aluminum particle agglomeration characteristics and suppression method during the combustion of aluminum‐based solid propellants: A review”, Propellants Explo Pyrotec, 49:1 (2024)
Dongliang Gou, Xiang Hu, Wen Ao, Peijin Liu, Guoqiang He, “Reduction of agglomeration effect by aluminum trihydride in solid propellant combustion”, Propellants Explo Pyrotec, 49:3 (2024)
Shipo Li, Zhan Wen, Lu Liu, Xiang Lv, Peijin Liu, Bo Yin, Larry K.B. Li, Wen Ao, “New discovery of aluminium agglomeration in composite solid propellants based on microscopic heating system”, Combustion and Flame, 263 (2024), 113342
Wenchao ZHANG, Zhimin FAN, Dongliang GOU, Yao SHU, Peijin LIU, Aimin PANG, Wen AO, “Elaborative collection of condensed combustion products of solid propellants: Towards a real Solid Rocket Motor (SRM) operational environment”, Chinese Journal of Aeronautics, 37:1 (2024), 77
N. S. Belousova, O. G. Glotov, A. V. Guskov, “Issledovanie vliyaniya dobavok-modifikatorov na kharakteristiki goreniya smesevogo topliva s alyuminiem”, Chelyab. fiz.-matem. zhurn., 9:2 (2024), 195–202
Hui Liu, Jifei Yuan, Xueqin Liao, Zhihao Sun, Jianzhong Liu, “Aluminum particle agglomeration mechanism and microscopic combustion characteristics of NEPE propellants”, J Therm Anal Calorim, 149:11 (2024), 5187
Huanhuan Gao, Fang Wang, Hui Liu, Yukun Chen, Jianzhong Liu, “Research progress and prospects on agglomeration models and simulation methods of aluminum particles in aluminum‐based composite propellants”, Propellants Explo Pyrotec, 2024
Chengyin Tu, Xiong Chen, Fan Chen, Yuqian Zhuang, Wenxiang Cai, Yingkun Li, Weixuan Li, Changsheng Zhou, Renjie Xie, “Effect of aluminum and ammonium perchlorate particle sizes on the condensed combustion products characteristics of aluminized NEPE propellants”, Sci Rep, 14:1 (2024)
Wei Le, Wanjun Zhao, Yanli Zhu, Ziting Wei, Zhigang Liu, Dazhi Liu, Qingjie Jiao, “Stable aluminum-lithium alloy fuels for solid propellants by facile surface modifying”, Chemical Engineering Journal, 497 (2024), 154451
O. G. Glotov, I. V. Sorokin, A. A. Cheremisin, “Pocket model of aluminum agglomeration with a tetrahedral cell for composite propellants”, Combustion, Explosion and Shock Waves, 59:6 (2023), 752–758
Dunhui Xu, Shengji Li, Xiao Jin, Xuefeng Huang, Heping Li, Fang Wang, “Comparison on the ignition and combustion characteristics of single Al-Li alloy and Al fuel microparticles in air”, Combustion and Flame, 258 (2023), 113114
Shipo Li, Xiang Lv, Lu Liu, Songchen Yue, Peijin Liu, Wen Ao, “Comparative study on aluminum agglomeration characteristics in HTPB and NEPE propellants: The critical effect of accumulation”, Combustion and Flame, 249 (2023), 112607
O.G. Glotov, “Screening of metal fuels for use in composite propellants for ramjets”, Progress in Aerospace Sciences, 143 (2023), 100954
O.G. Glotov, V.A. Poryazov, G.S. Surodin, I.V. Sorokin, D.A. Krainov, “Combustion features of boron-based composite solid propellants”, Acta Astronautica, 204 (2023), 11
Dongliang Gou, Zhimin Fan, Shixi Wu, Peijin Liu, Guoqiang He, Wen Ao, “The role of HMX particle size in the combustion and agglomeration of HTPB-based propellant”, Aerospace Science and Technology, 136 (2023), 108170
Xueqin Liao, Jianzhong Liu, Mengxia Sun, Hui Liu, Ziying Cheng, “Morphology and Size Distribution of Condensed Combustion Products of Aluminum-Based Propellants”, Combustion Science and Technology, 2023, 1
Cheng-yin Tu, Xiong Chen, Ying-kun Li, Bei-chen Zhang, Chang-sheng Zhou, “Experimental study of Al agglomeration on solid propellant burning surface and condensed combustion products”, Defence Technology, 26 (2023), 111
Wen Ao, Zhan Wen, Lu Liu, Yang Wang, Yu Zhang, Peijin Liu, Zhao Qin, Larry K.B. Li, “Combustion and agglomeration characteristics of aluminized propellants containing Al/CuO/PVDF metastable intermolecular composites: A highly adjustable functional catalyst”, Combustion and Flame, 241 (2022), 112110
Xue-Li Liu, Song-Qi Hu, Lin-Lin Liu, Yan Zhang, “Condensed Combustion Products Characteristics of HTPB/AP/Al Propellants under Solid Rocket Motor Conditions”, Aerospace, 9:11 (2022), 677

Citing articles in Google Scholar: Russian citations, English citations
Related articles in Google Scholar: Russian articles, English articles

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