Calculation of the burner liner wall temperature of the ramjet engine combustion chamber under the mist cooling
Authors: Andreev E.A., Kovalev K.E., Shostov A.K.
Published in issue: #2(134)/2023
DOI: 10.18698/2308-6033-2023-2-2251
Category: Aviation and Rocket-Space Engineering | Chapter: Thermal, Electric Jet Engines, and Power Plants of Aircrafts
Along with the turbojet engines, cruise missiles are using the ramjet engines, Features of the ramjet rockets use in most cases are characterized with the combustion chamber operating for significant time at the maximum heating, which makes it a rather heat-loaded unit that requires solving complex issues of the heat resistance. Therefore, calculations are relevant to determine thermal state of the combustion chamber elements, which makes the basis for making rational design decisions. This paper determines temperatures of the burner liner wall of the ramjet engine main combustion chamber affected by combustion products and cooling air. Certain similarity in the design of the burner liners of turbojet and ramjet engine on liquid fuel made it possible to adapt calculation methods worked out for a turbojet engine to the ramjet engine combustion chambers. Main sections of the combustion chamber and their characteristic features were identified. A system of non-linear heat transfer equations was solved using empirical coefficients for both cooled and uncooled sections. Graphs of temperature distribution in sections of the burner liner along the entire length of the combustion chamber were plotted. Qualitative analysis of the obtained results showed that the applied method could be used to determine the thermal state of the burner liner walls as the first approximation, without taking into account local design features, but using only the aerial vehicle flight conditions and the liquid fuel parameters.
References
[1] Kert B.E., Znamensky E.A., Kravtsov V.O., Panchenko A.V., Chubasov V.A. Raschetnaya otsenka ballisticheskih vozmozhnostey artilleriyskikh snaryadov s raketno-pryamotochnymi dvigatelyami [The estimated score of ballistic capabilities of artillery shells with rocket-thermally engines]. Izvestiya RARAN — Proceedings of the RARAS, 2019, no. 2 (107), pp. 125–133.
[2] Buzuluk V.I., Vasilyev R.P., Voevodenko N.V., Gubanov A.A., Gurevich B.I., Talyzin V.A., Chernyshev S.L. Issledovaniya kontseptsii vysokoskorostnykh grazhdanskikh samoletov v TsAGI [Research of high-speed civil aircraft concepts in TSAGI]. Obscherossiyskiy nauchno-tekhnicheskiy zhurnal “Polet” — All-Russian Scientific-Technical Journal “Polyot” (“Flight”), 2018, no. 11, pp. 37–49.
[3] Bakulev V.I., Golubev V.A., edited. Teoriya, raschet i proektirovanie aviatsionnykh dvigateley i energeticheskikh ustanovok [Theory, calculation and design of aircraft engines and power plants]. Moscow, MAI Publ., 2003, 688 p.
[4] Pchelkin Y.M. Kamery sgoraniya gazoturbinnykh dvigateley [Combustion chambers of the gas turbine engines]. Moscow, Mashinostroenie Publ., 1984, 280 p.
[5] Nechaev Y.N., Fedorov R.M. Teoriya aviatsionnykh gazoturbinnykh dvigateley. Ch. 2 [Theory of aviation gas turbine engines. Part 2]. Moscow, Mashinostroenie Publ., 1978, 336 p.
[6] Batenin I.A. Chislennoe modelirovanie raboty zharovoy truby v sisteme okhlazhdeniya kamery sgoraniya vozdushno-reaktivnogo dvigatelya [Numerical modeling of the flame tube operation in the cooling system of the air-jet engine combustion chamber]. Politekhnicheskiy molodezhnyi zhurnal — Politechnical Student Journal, 2019, no. 8 (37). DOI: 10.18698/2541-8009-2019-8-516
[7] Skibina N.P. Chislennoe issledovanie nestatsionarnogo techeniya gaza v kamere sgoraniya pryamotochnogo vozdushno-reaktivnogo dvigatelya s uchetom protsessa teploobmena [Computational study of unsteady gas flow in the combustion chamber of a ramjet engine with heat transfer]. Vychislitelnye tekhnologii — Computational Technologies, 2020, no. 6, pp. 50–61.
[8] Matveev S.G., Anisimov V.M., Zubrilin I.A., Kolomzarov O.V., Mironov N.S. Opredelenie teplovogo sostoyaniya i dovodka sistemy okhlazhdeniya stenok zharovoy truby s pomoschyu metodov trekhmernogo modelirovaniya [Determination of thermal state and modification of the flame tube cooling system with the help of three-dimensional modeling methods]. Vestnik Samarskogo universiteta. Aerokosmicheskaya tekhnika, tekhnologii i mashinostroenie — Vestnik of Samara University. Aerospace and mechanical engineering, 2015, no. 2, pp. 119–128.
[9] Avduevskiy V.S., Galitseyskiy V.M., edited. Osnovy teploperedachi v aviatsionnoy i raketno-kosmicheskoy tekhnike [Fundamentals of heat transfer in aviation, rocket and space technology]. Moscow, Mashinostroenie Publ., 1992, 528 p.
[10] Senyushkin N.S., Kharitonov V.F., Yalchibaeva L.N. Raschet teplovogo sostoyaniya stenok kamer sgoraniya VRD [Thermal state calculation for a combustion chamber of an air-breathing engine]. Vestnik Voronezhskogo gosudarstvennogo tekhnicheskogo universiteta — Bulletin of Voronezh State Technical University, 2012, no. 5, pp. 73–76.
[11] Lefebvre A.H. Gas Turbine Combustion. Taylor & Francis, 1983 [In Russ.: Lefevr A. Protsessy v kamerakh sgoraniya GTD. Moscow, Mir Publ., 1986, 566 p.].