Investigating Various Ways of Cooling Cryogenic Fuel Tanks of Aerospace Equipment
| Authors: Yuranev O.A. | Published: 14.06.2018 |
| Published in issue: #3(120)/2018 | |
| Category: Aviation and Rocket-Space Engineering | Chapter: Innovation Technologies of Aerospace Engineering | |
| Keywords: cryogenic fuel tanks, cooling, liquid nitrogen, liquid hydrogen, liquid oxygen, gaseous helium, liquid oxygen | |
Contemporary rocket engineering trends involve using liquid methane and hydrogen as propellant components. Traditional cryogenic fuel tank cooling methods used in aerospace equipment do not simulate realistically either service temperature or the effect of the column of liquid on the structure, which means that finding new cooling technologies capable of solving these problems is a pressing issue. The study considers various cryogenic fuel tank cooling methods, lists their advantages and disadvantages, and determines the most promising techniques
References
[1] Gusev Y., Kolozezny A., Panichkin N. Choice of materials and design of propellant tanks and adjacent structures for future launchers, including RLV. 59th International Astronautical Congress, 2008. P. 5297–5306.
[2] Kolozeznyy A.E. Conceptual fundamentals for developing experimental technologies for cryogenic propellant tank thermal strength assurance of future competitive launch vehicles. Kosmonavtika i raketostroenie [Cosmonautics and Rocket Engineering], 2012, no. 2 (67), pp. 62–69 (in Russ.).
[3] Vasyukova D.A., Kolozeznyy A.E., Yuranev O.A. Effective method for qualification testing future cryogenic tanks of launch vehicles. Aviakosmicheskaya tekhnika i tekhnologiya, 2013, no. 1, pp. 23–25 (in Russ.).
[4] Panichkin N.G., ed. TsNIImash. Tsentr issledovaniy prochnosti. Istoriya razvitiya [TsNIImash. Strength research center. History of development]. Korolev, TsNIIMash Publ., 2001. 342 p.
[5] Gorbachev S.P., Popov V.P., Slavin M.V. Calculation of cooldown time for cryogenic tank. Izvestiya vuzov. Mashinostroenie [Proceedings of Higher Educational Institutions. Маchine Building], 2006, no. 5, pp. 43–53 (in Russ.).
[6] Vasyukova D.A., Kolozeznyy A.E., Yuranev O.A. Qualification of method for prediction of gas free convection cooling of the full-scaled test article of a launcher cryogenic tank. Polet [Flight], 2015, no. 7, pp. 18–24 (in Russ.).
[7] Matsekh A.M., Pavlenko A.N. Heat transfer and crisis phenomena in the falling films of cryogenic liquid. Teplofizika i aeromekhanika [Thermophysics and Aeromechanics], 2005, vol. 12, no. 1, pp. 99–112 (in Russ.).
[8] Vasyukova D.A., Kolozeznyy A.E., Yuranev O.A. Use of cryogenic helium system for operation temperature simulation in structural tests. Kosmonavtika i raketostroenie [Cosmonautics and Rocket Engineering], 2012, no. 2 (67), pp. 179–186 (in Russ.).
[9] Vasyukova D.A., Kolozeznyy A.E., Yuranev O.A. [Calculating justification of using the cryogenic helium installation for operational temperatures simulation at structural tests of the cryogenic spacecraft fuel tanks]. Innovatsionnyy arsenal molodezhi: trudy Tretyey nauchno-tekhnicheskoy konferentsii FGUP «KB «Arsenal» [Innovative Arsenal of Youth: Proc. 3d Sci.-Tech. Conf. of FGUP "KB "Arsenal"]. Sankt-Petersburg, BGTU Voenmekh Publ., 2012. P. 280–282.
[10] Arkharov A.M., Belyakov V.P., Mikulin E.I., et al. Kriogennye sistemy [Cryogenic systems]. Moscow, Mashinostroenie Publ., 1987. 536 p.
