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第 46 卷潘传鱼，等：非冲击点火质量惯性约束装药燃烧反应演化模型研究第 2 期

10.11943/CJEM2018339.
SHANG H L, YANG J, LI T, et al. Experimental study on burning evolution in confined HMX-based PBX cracks [J]. Chinese
Journal of Energetic Materials, 2019, 27(12): 1056–1061. DOI: 10.11943/CJEM2018339.
[13] 尚海林, 马骁, 程赋, 等. 炸药燃烧产物驱动裂纹动态扩展耦合特性 [J]. 含能材料, 2019, 27(10): 819–823. DOI:
10.11943/CJEM2019136.
SHANG H L, MA X, CHENG F, et al. Coupling properties of crack penetration driven by explosive burning products [J].
Chinese Journal of Energetic Materials, 2019, 27(10): 819–823. DOI: 10.11943/CJEM2019136.
[14] SMILOWITZ L, HENSON B F, ROMERO J J, et al. Direct observation of the phenomenology of a solid thermal explosion
using time-resolved proton radiography [J]. Physical Review Letters, 2008, 100(22): 228301. DOI: 10.1103/PhysRevLett.
100.228301.
[15] SMILOWITZ L, HENSON B F, ROMERO J J, et al. Thermal decomposition of energetic materials viewed via dynamic x-ray
radiography [J]. Applied Physics Letters, 2014, 104(2): 024107. DOI: 10.1063/1.4858965.
[16] SMILOWITZ L, HENSON B F, OSCHWALD D, et al. Internal sub-sonic burning during an explosion viewed via dynamic
X-ray radiography [J]. Applied Physics Letters, 2017, 111(18): 184103. DOI: 10.1063/1.5004424.
[17] SMILOWITZ L, HENSON B F, ROMERO J J, et al. The evolution of solid density within a thermal explosion. I. proton
radiography of pre-ignition expansion, material motion, and chemical decomposition [J]. Journal of Applied Physics, 2012,
111(10): 103515. DOI: 10.1063/1.4711071.
[18] SMILOWITZ L, HENSON B F, ROMERO J J, et al. The evolution of solid density within a thermal explosion. II. dynamic
proton radiography of cracking and solid consumption by burning [J]. Journal of Applied Physics, 2012, 111(10): 103516.
DOI: 10.1063/1.4711072.
[19] SWANSON S R. Application of Schapery’s theory of viscoelastic fracture to solid propellant [J]. Journal of Spacecraft and
Rockets, 1976, 13(9): 528–533. DOI: 10.2514/3.27925.
[20] BENNETT J G, HABERMAN K S, JOHNSON J N, et al. A constitutive model for the non-shock ignition and mechanical
response of high explosives [J]. Journal of the Mechanics and Physics of Solids, 1998, 46(12): 2303–2322. DOI: 10.1016/
S0022-5096(98)00011-8.
[21] HILL L G. Burning crack networks and combustion bootstrapping in cookoff explosions [J]. AIP Conference Proceedings,
2006, 845(1): 531–534. DOI: 10.1063/1.2263377.
[22] 段卓平, 白志玲, 白孟璟, 等. 强约束固体炸药燃烧裂纹网络反应演化模型 [J]. 兵工学报, 2021, 42(11): 2291–2299. DOI:
10.3969/j.issn.1000-1093.2021.11.001.
DUAN Z P, BAI Z L, BAI M J, et al. Burning-crack networks model for combustion reaction growth of solid explosives with
strong confinement [J]. Acta Armamentarii, 2021, 42(11): 2291–2299. DOI: 10.3969/j.issn.1000-1093.2021.11.001.
[23] 白志玲, 段卓平, 李治, 等. 热刺激约束 DNAN 基不敏感熔铸炸药装药点火后反应演化调控模型 [J]. 含能材料, 2023,
31(10): 1004–1012. DOI: 10.11943/CJEM2023160.
BAI Z L, DUAN Z P, LI Z, et al. Regulation model for reaction evolution of confined DNAN-based cast explosives after
ignition under thermal stimulation [J]. Chinese Journal of Energetic Materials, 2023, 31(10): 1004–1012. DOI: 10.11943/
CJEM2023160.
[24] GRAHAM K J. Mitigation of fuel fire threat to large rocket motors by venting [C]//Insensitive Munitions & Energetic
Materials Symposium Munich. Munich: Air Force Research Laboratory, 2010.
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