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Combustion Science and Technology Volume 190, 2018 - Issue 12
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Articles

Unsteady chemical kinetics behavior of AP/HTPB propellant with micro-scale model

Xiaochun XueSchool of Energy and Power Engineering, Nanjing University of Science and Technology, NanjingJiangsu, ChinaView further author information
,
Yonggang YuSchool of Energy and Power Engineering, Nanjing University of Science and Technology, NanjingJiangsu, ChinaCorrespondence[email protected]
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&
Rui YeChina Electronics Technology Group Corporation No.38 Research Institute, HefeiAnhui, ChinaView further author information
Pages 2164-2187 | Received 27 Nov 2017, Accepted 26 Jun 2018, Published online: 26 Jul 2018

References

  • A I, A., T L, B., P O, C. et al. 1999. Burning rate of solid propellant ingredients, part 1: pressure and initial temperature effects. Journal of Propulsion & Power., 15, (6), 740–747.
  • Arisawa, H., and Brill, T.B., 1996. Flash pyrolysis of hydroxyl-terminated polybutadiene (HTPB) I: analysis and implications of the gaseous products. Combustion & Flame., 106, (1). 131–143.
  • B T, C., and Brewster, M.Q., 2002. Combustion of solid propellant sandwiches: effect of binder oxygenation and finite peclet number. Int. J. Energetic Mater. Chem. Propulsion., 5, (1–6). 226–235.
  • Burning Characteristics, K.M., 2010. Thermochemical behavior of AP/HTPB composite propellant using coarse and fine AP particles. Propellants Explosives Pyrotechnics., 36, (1). 57–64.
  • Burning Rate, K.M., 2008. Characteristics of ammonium perchloarte-based composite propellant using bimodal ammonium perchlorate. Journal of Propulsion & Power., 24, (3). 499–506.
  • C A, B., and Price, E.W., 1998. Leading-edge flame detachment: effect on pressure-coupled combustion response. Journal of Propulsion & Power., 14, (2). 160–165.
  • C F, M., and Thynell, S.T., 2000. Line-of-sight variations of temperature and species in solid propellant flames. Journal of Propulsion & Power., 16, (3). 505–512.
  • D L, R., K R, K., M A, S. et al. 2011. Development of highly active titania-based nanoparticles for energetic materials. TheJournal Phys. Chem. C., 115, (21), 10412–10418.
  • Fujimura, K., and Miyake, A., 2010. The effect of specific surface area of TiO2, on the thermal decomposition of ammonium perchlorate. J Therm Anal Calorim., 99, (1). 27–31.
  • G M, K., and Brewster, M.Q., 2002. Modeling the combustion of propellant sandwiches. Combustion Sci. Technol., 174, (4). 61–90.
  • Galfetti, L., L T, D., Severini, F. et al. 2007. Pre and post-burning analysis of nano-aluminized solid rocket propellants. Aerospace Sci. Technol., 11, (1), 26–32.
  • Hagihara, Y. 1982. Grinding of ammonium perchlorate by vibration ball mill. Sci. Tech. Energetic Materials., 43, 70–74.
  • Hegab, A., T L, J., Buckmaster, J. et al. 2001. Nonsteady burning of periodic sandwich propellants with complete coupling between the solid and gas phases. Combustion & Flame., 125, (1–2), 1055–1070.
  • J A, S., M J, S., M N, S. et al. 2014. Iron nanoparticle additives as burning rate enhancers in AP/HTPB composite propellants. Propellants Explosives Pyrotechnics., 40, (2), 253–259.
  • Jayaraman, K., K V, A., S R, C. et al. 2009. Effect of nano-aluminium in plateau-burning and catalyzed composite solid propellant combustion. Combustion & Flame., 156, (8), 1662–1673.
  • K R A, K., and Lakshmisha, K.N., 2002. Dynamic combustion of solid propellants: effects of unsteady condensed phase degradation layer. Journal of Propulsion and Power., 18, (2). 312–321.
  • Knott, G., and Brewster, M., 2000. A Two-Dimensional Model of Composite Propellant Flame Structure and Burning Rate. The 36th AIAA Joint Propulsion Conference and Exhibit. Las Vegas., U.S. 24 July- 28 July.
  • Kreitz, K., Petersen, E., Reid, D. et al. 2012. Scale-Up effects of nanoparticle production on the burning rate of composite propellant. Combustion Sci. Technol., 184, (6), 750–766.
  • M A, S., E L, P., D L, R. et al. 2009. Nano additives and plateau burning rates of ammonium-perchlorate-based composite solid propellants. Journal of Propulsion & Power., 25, (5), 1068–1078.
  • Merkle, C., and Summerfield, M. 1969. Extinguishment of solid propellants by depressurization - effects of propellant parameters. The 7th Aerospace Sciences Meeting. New York, NY, U.S. 20-22 January.
  • O P, K., A A, C., I D, E. et al. 1990. Investigation of the kinetics and the chemical reaction mechanism in the flame of a mixed compound, based on ammonium perchlorate and polybutadiene rubber. Combustion, Explosion, and Shock Waves., 26, (3), 292–300.
  • O P, K., N E, E., A A, C. et al. 1992. Flame structure, kinetics and mechanism of chemical reactions in flames of mixed composition based on ammonium perchlorate and polybutadiene rubber. Combustion, Explosion, and Shock Waves., 28, (4), 366–371.
  • R W, B., Jia, X., J D, L. et al. 1996. Theoretical and experimental study of composite solid propellant combustion. Combustion Sci. Technol., 115, (1–3):1–39.
  • S T, L., E W, P., R K, S. et al. 1994. Effect of multidimensional flamelets in composite propellant combustion. Journal of Propulsion & Power., 10, (6), 717–728.
  • S T, S., and Krier, H., 2003. Computational models of combustion of nonmetallized heterogeneous propellant. High Temperature., 41, (1). 95–128.
  • Surzhikov, S., Murphy, J., and Krier, H. 2000. 2D Model for Unsteady Burning Heterogeneous AP/binder Solid Propellants. 36th AIAA/ASME/SAE/ASEE Joint Propulsion Conference and Exhibit, Joint Propulsion Conferences, Las Vegas.
  • T L, B., and Zurn, D.E., 1971. The deflagration of ammonium perchlorate-polymeric binder sandwich models. Combustion Sci. Technol., 4, (1). 279–292.
  • T L, J., Buckmaster, J., and Hegab, A., 2001. Periodic propellant flames and fluid-mechanical effects. Journal of Propulsion & Power., 17, (2). 371–379.
  • T P, P., and Hanson-Parr, D.M., 1996. Solid propellant diffusion flame structure. Symp. Combustion., 26, (2). 1981–1987.
  • T’Ien, J.S., 1972. Oscillatory burning of solid propellants including gas phase time lag[J]. Combustion Sci. Technol., 5, (1). 47–54.
  • Ye, R., Yu, Y., and Cao, Y., 2015. Experimental study of transient combustion characteristics of AP/HTPB base bleed propellant under rapid pressure drop. Combustion Sci. Technol., 187, (3). 445–457.
  • Yu, Y., Zhou, Y., Lu, C. et al. 2014. Study on unsteady combustion behaviors of AP/HTPB base‐bleed propellants under transient depressurization conditions. Propellants Explosives Pyrotechnics., 39, (4), 511–517.

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