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Interrelationship Between Solid Propellant Combustion and Materials Behavior

Published online by Cambridge University Press:  15 February 2011

Kenneth K. Kuo ,
Thomas A. Litzinger  and
Wen H. Hsieh
Kenneth K. Kuo
Affiliation:
Department of Mechanical Engineering, The Pennsylvania State University, University Park, Pennsylvania 16802, USA
Thomas A. Litzinger
Affiliation:
Department of Mechanical Engineering, The Pennsylvania State University, University Park, Pennsylvania 16802, USA
Wen H. Hsieh
Affiliation:
Department of Mechanical Engineering, The Pennsylvania State University, University Park, Pennsylvania 16802, USA
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Abstract

Thermochemical and physical processes which occur in various aspects of solid-propellant combustion including steady-state burning, ignition, transient burning, cook-off and crack propagation are presented in this paper. For each case, the various thermochemical and physical properties involved are summarized. In addition, the current direction of solidpropellant research is highlighted. The intent of this paper is to stimulate the interest of materials scientists and engineers in the field of solid propellants so that they will contribute their unique expertise to the advancement of current research. It is also the hope of the authors that the paper will serve as a useful summary of important relationships and parameters for scientists and engineers currently involved in solid-propellant research.

Type
Research Article
Information
MRS Online Proceedings Library (OPL) , Volume 296: Symposium Y – Structure and Properties of Energetic Materials , 1992 , 331
Copyright
Copyright © Materials Research Society 1993

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References

1 Kubota, N., “Combustion Characteristics of Rocket Propellants,” in Chapter 1 of Fundamentals of Solid Propellant Combustion, (Eds. Kuo, K.K. and Summerfield, M.), AIAA Progress in Astronautics and Aeronautics, Vol.90, pp. 1–52, 1984.Google Scholar
2 Kubota, N., “Combustion Mechanisms of Nitramine Composite Propellants,” Eighteenth International Symposium on Combustion, The Combustion Institute, Pittsburgh, PA 1981, p. 187.Google Scholar
3 Hsieh, W. H., Li, W. Y., and Yim, Y. J., “Combustion Behavior and Thermochemical Properties of RDX-Based Solid Propellants,” AIAA-92–3628, AIAA/SAE/ASME/ASEE 28th Joint Propulsion Conference and Exhibition, July 6–8, 1992, Nashville, TN.Google Scholar
4 Razdan, M. K. and Kuo, K. K., “Erosive Burning of Solid Propellants,” Chapter 10 of Fundamentals of Solid Propellant Combustion, (Eds., Kuo, K. K. and Summerfield, M.), Progress in Astronautic and Aeronautics, Vol.90, AIAA, New York, NY. 1984.Google Scholar
5 Hsieh, W. H. and Kuo, K. K., “Erosive and Strand Burning of Stick Propellant, Part II: Theoretical Modeling of Erosive-Burning Processes,” Journal of Propulsion and Power, Vol.6, No. 4, July-August 1990, pp. 400406.Google Scholar
6 Godon, J. C., Duterque, J., Lengelli, G., “Solid-Propellant Erosive Burning,” Journal of Propulsion and Power, Vol.8, No. 4, July-August 1992, pp. 741747.Google Scholar
7 Kuo, K. K., Hsieh, W. H., Hsieh, K. C., and Miller, M. S., “Modeling of Hot Fragment Conductive Ignition of Solid Propellants with Applications to Melting and Evaporation of Solids,” ASME Journal of Heat Transfer, Vol.110, August 1988, pp. 670679.Google Scholar
8 Ritchie, S. J., Hsieh, W. H., and Kuo, K. K., “Convective Ignition Phenomena of LOVA Propellants,” AIAA 90–2194 AIAA/SAE/ASME/ASEE 26th Joint Propulsion Conference, July 16–18, 1990, Orlando, FL. (Also accepted for publication in the Journal of Propulsion and Power.)Google Scholar
9 Cohen, A., Beyer, R.A., Newberry, J.E., and Bilyk, S.R., “Laser ignition of Solid Propellants: Comparison of Model Predictions with Pressure and Emission Predictions,” 29th JANNAF Combustion Meeting, NASA Langley Research Center, October 1992.Google Scholar
10 Parr, T. and Hanson-Parr, D., “Species and Temperature Profiles in Ignition and Deflagration of HMX,” Paper 87-8 Spring Meeting of the Western States Section of the Combustion Institute, April 1987.Google Scholar
11 Kuo, K.K., Kim, J-U., Fetherolf, B.L., and Torikai, T., “Pre-ignition Dynamics of RDX-based Energetic Materials under CO2 Laser Heating,” Combustion and Flame, in press.Google Scholar
12 Deluca, L., Ohlemiller, T.J., Caveny, L.H., and Summerfield, M., “ative Ignition of Double-base Propellants,” ALAA Journal, Vol 14, No.8, 1976, pp.11111117.Google Scholar
13 Ohlemiller, T. J., Caveny, L.H., Deluca, L.,and Summerfield, M.,“Dynamic Effect of Ignitability Limits of Solid Propellants Subjected to Radiative Heating,” 14th Symposium (International) on Combustion, Combustion Institute 1972.Google Scholar
14 Hermance, C.E., “Solid Propellant Ignition Theories and Experiments,” in Chapter 5 of Fundamentals of Solid Propellant Combustion, (Eds. Kuo, K.K. and Summerfield, M.), AIAA, Progress in Astronautics and Aeronautics, Vol.90, 1984, pp. 239304.Google Scholar
15 Kuo, K. K, Fundamentals of Combustion, Chapter 10, 1986, pp. 734–791.Google Scholar
16 Ritchie, S. J., Fetherolf, B. L., Hsieh, W. H., and Kuo, K. K., “A Comparative Analysis of the Convective and Radiative Ignition Processes of XM-39 Solid Propellant,” CPIA Pub. 573, Vol. 1, Oct. 1991, 28th JANNAF Combustion Subcommittee Meeting, pp. 453–461.Google Scholar
17 Covino, J. and Hudson, C. T., “Cook-off Mechanistic Understanding and Predictive Capabilities,” CPIA Publication 586, JANNAF Propulsion Systems Hazards Subcommittee Workshop, HSWC, Silver Spring, MD, April 27-May 1, 1992.Google Scholar
18 Oxley, J. C., “Cook-off Small-Scale Thermal Hazard Analysis,” CPIA Publication 586, JANNAF Propulsion Systems Hazards Subcommittee Workshop, April 27 -May 1, 1992, pp. 21–43.Google Scholar
19 Craig, B. and Butcher, A. G., “Intermediate and Full-Scale Cookoff Tests,” CPIA Publication 586, JANNAF Propulsion Systems Hazards Subcommittee Workshop, April 27 - May 1, 1992, pp. 5–20.Google Scholar
20 Kuo, K.K., Gore, J. P., and Summerfield, M., “Transient Burning of Solid Propellants” Chapter 11 of Fundamentals of Solid Propellant Combustion, Eds. by K.K. Kuo and M. Summerfield, Progress in Astronautics and Aeronautics, Vol.90, pp. 599–659.Google Scholar
21 Kumar, M. and Kuo, K. K., “Effect of Deformation on Flame Spreading and Combustion in Propellant Cracks,” AIAA Journal, Vol.19, No. 12, 1981, pp. 15801589.CrossRefGoogle Scholar
22 Kuo, K. K. and Kooker, D. E., “Coupling between Nonsteady Burning and Structural Mechanics of Solid Propellant Grains,” Chapter 13, Nonsteady Burning and Combustion Stability of Solid Propellants, AIAA Progress Series, Vol. 143, (Eds. De Luca, L., Price, E., and Summerfield, M.), pp. 465–517, 1992.Google Scholar
23 Siefert, J. G. and Kuo, K. K., “Crack Propagation in Burning Solid Propellant,” Dynamics of Shock Waves, Explosives, and Detonation. AIAA Progress Series, (Eds. Bowen, J.R., Manson, N., Oppenheim, A. K., and Soloukhin, R. J.), Vol.94, p. 575, 1985.Google Scholar
24 Wu, S. R., Lu, Y. C., Kuo, K. K., and Yang, V., “Crack Initiation and Propagation in Burning Metalized Propellants,” Eighteenth International Pyrotechnics Seminar, The International Pyrotechnics Society, Breckenridge, Colorado, 1992, pp. 9851003.Google Scholar
25 Belyaev, A. F., Korotkov, A. I., Sulimov, A. A., Sukoyan, M. K., and Obmenin, A. V., “Development of Combustion in an Isolated Pore,” Combustion, Explosion, and Shock Waves, Vol.5, 1969, pp. 49.Google Scholar
26 Jacobs, H. R., Hufferd, W. L., and Williams, M. L., “Further Studies of the Critical Nature of Cracks in Solid Propellant Grains,” AFRPL-TR-75-14, 1975.Google Scholar
27 Athavale, M. M., Hsieh, K. C., Hsieh, W. H., Char, J. M., and Kuo, K. K., “Interaction of Flame Spreading, Combustion, and Fracture of Single-Perforated Stick Propellants Under Dynamic Condition,” Dynamics of Reactive Systems, Part II: Modeling and Heterogeneous Combustion, AIAA Progress Series, Vol.105, (Eds. Bowen, J.R., Layer, J.-C., and Soloukhin, R. I.), 1986, pp. 267290.Google Scholar
28 Lu, Y.C., “Combustion-Induced Crack Propagation Process in a Solid-Propellant Crack Cavity,” Ph.D. Thesis, The Pennsylvania State University, December 1992.Google Scholar
29 Schapery, R. A., “A Theory of Crack Initiation and Growth in Viscoelastic Media, I: Theoretical Development,” International Journalo f Fracture Mechanics, Vol.11, 1975, pp. 141159.Google Scholar
30 Schapery, R. A., “Correspondence Principles and a Generalized J Integral for Large Deformation and Fracture Analysis of Viscoelastic Media,” International Journal of Fracture, Vol.25, 1984, pp. 195223.Google Scholar
31 Hufferd, W.L., Jacobs, H. R., and Laheru, K. L., “On the Fracture of Viscoelastic Materials,” CPIA 264, 1975, pp. 339356.Google Scholar