Influence of magnetic field on the properties of paraffin based fuel for hybrid rocket engines
Heading:
1Vergun, LYu., 1Chernyak, VYa., 2Orlovskaya, SG, 1Nedibalyuk, OA, 1Solomenko, ОV, 3Popov, SA 1Taras Shevchenko National University of Kyiv, Kyiv, Ukraine 2I.I. Mechnikov National University of Odessa, Odessa, Ukraine 3Taras Shevchenko National University of Kyiv, Institute of Geology, Kyiv, Ukraine |
Space Sci.&Technol. 2016, 22 ;(3):16-24 |
https://doi.org/10.15407/knit2016.03.016 |
Publication Language: Ukrainian |
Abstract: We consider the question of increasing of paraffin based fuel regression rate. The hypothesis about dependence of these
values from the change of chains conformation on surface of melt layer is advanced and use of magnetic field at the preparation of fuel charge is proposed. We conclude that a static magnetic field allows to stabilization of transfer droplets from paraffinic melt to combustions zone. |
Keywords: magnetic field, paraffin based fuel, regression rate coefficient |
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12. Loskutova Ju. V., Judina N. V., Pisareva S. I., et al. The rheological properties of high-viscosity oils and paraffin in a magnetic field. Mater. IV Int. confer. «Chemistry of Oil and Gas», Vol. 1, 474—478 (Tomsk, 2000) [in Russian].
13. Talantov A. V. Fundamentals of the theory of combustion, 249 p. (Rotaprint, Kazan', 1975) [in Russian].
14. Frenkel' Ja. I. Kinetic Theory of Liquids, 592 p. (Nauka, Leningrad, 1975) [in Russian].
15. Shahparonov M. I., Asheko A. A., Usacheva T. M. Kinetics dielectrically observed processes of thermal motion in liquid alkanes. Zhurn. fiz. himii, 58 (11), 2746—2749 (1984) [in Russian].
16. Bulavin L .A., Aktan O.Yu. , Zabashta Yu. F. Vacancies in folded polymer crystals. Polymer Sci. Ser. A, 44 (9), 980—985 (2002).
17. Bulavin L. A., Aktan O. Yu., Lazarenko M. M. The mechanism of melting of lamellar crystals with the branched chains. Ukr. J. Phys., N 9, 952—957 (2005).
18. Bulavin L. A., Aktan O. Yu., Zabashta Yu. F. The statistical theory of melting of folded crystals containing vacancies.Polymer Sci. Ser. A, 45 (10), 1007—1010 (2003).
19. Bulavin L. A., Aktan O. Yu., Zabashta Yu. F. Formation of a mesomorphic phase upon melting of folded crystals containing vacancies. Polymer Sci. Ser. B, 47 (3-4), 109—113 (2005).
20. de Gennes P.-G. Scaling Concepts in Polymer Physics, 368 p. (Cornell Univ. Press, Oxford, 1979).
21. Etkin V. Thermokinetics (Synthesis of Heat Engineering Theoretical Grounds), 334 p. (Haifa, 2010).
22. Karabeyoglu A., Zilliac G., Cantwell B. J., et al. Scale-Up Tests of High Regression Rate Paraffin-Based Hybrid Rocket Fuels. J. Propulsion and Power, 20 (6), 1037—1045 (2004).
https://doi.org/10.2514/1.3340
23. Nedybaliuk O. A., Chernyak V. Ya., Martish E. V., et al. Plasma assisted combustion of paraffin mixtures. Probls Atomic Sci. and Technology, 1 (83), 219—221 (2013).
24. Nedybaliuk O. A., Solomenko O. V., Chernyak V. Ya., et al. Peculiarities of Plasma Assisted Stearine Combustion. Phys. Rev. and Res. International, 3 (4), 522—529 (2013).
25. Sutton G., Biblaz O. Rocket Propulsion Elements, 7th Edition, 751 p. (John-Wiley & Sons, New York, 2001).
26. Watanabe K., et al. Cryogen-free hybrid magnet for magnetic levitation. Phys. C, N 386, 485—489 (2003).
https://doi.org/10.1016/s0921-4534(02)02232-3
27. Wunderlich B., Möller M., Grebowicz J., et al. Conformational motion and disorder in low and high molecular mass crystals, 121 p. (Springer-Verlag, Berlin, Heidelberg, 1988).
https://doi.org/10.1007/BFb0008607