Substantiation of the ratio of biofuel and kerosin in the mixture for its application as aviation fuel

Today, technologies for the production of alternative fuels and for the development of engines on different operating principles are actively developing, due to both the tightening of the environmental requirements of ICAO (International Civil Aviation Organization) for harmful emissions into the atmosphere and the depletion of non-renewable resources, and the interests of the oil importing countries. Strict requirements are imposed on the quality of aviation fuels related to ensuring the reliability of aviation technology and flight safety. Requirement toughening for quality indicators will inevitably lead to higher fuel prices, so today we can observe some concessions in domestic and foreign regulatory documents to certain quality indicators of aviation fuels, for example, to indicators of low-temperature properties. It follows that the use of petroleum fuels will sooner or later become inappropriate. Technologies to produce synthetic and biological fuels from various types of raw materials make it possible to obtain fuel with close quality indicators to traditional kerosene, but it has not yet been completely replaced. Therefore, today we are considering the use of alternative fuels in a mixture with petroleum kerosene in various proportions. The question remains open: in what proportion is it possible to use mixtures of alternative fuel with kerosene on the aircraft without any negative consequences for their operation. Based on the known dependencies, a mathematical model is proposed for calculating some operational indicators of fuel, engine and aircraft depending on the proportion of mixing alternative fuel and kerosene. In accordance with the calculations, the most rational ratio of petroleum kerosene and SPK fuel is substantiated both from the point of view of the necessary operational properties and from the point of view of economic feasibility.

1. Fedorov, E.P. and Frantsuzova, N.A. (2010). Development of synthetic jet fuel from bioraw materials. Ramjet WFD and Chemmotologi, in L.S. Yanovskii (Ed.). Proceedings of CIAM, no. 1340, pp. 107-116. (in Russian)

2. Glagoleva, O.F. and Belokon, T.N. (2019). Topliva dlya dvigateley vnutrennego sgoraniya i alternativnaya energetika [Fuels for internal combustion engines and alternative energy]. 55 let khimmotologii. Osnovnyye itogi i napravleniya razvitiya: tezisy dokladov Mezhvedomstvennoy nauchno-tekhnicheskoy konferentsii [Proceedings of the Interdepartmental scientific and technical conference «55 years of chemmotology. Main results and directions of development» reports], p. 49. (in Russian)

3. Nikolaykin, N.I., Melnikov, B.N. and Bolshunov, Yu.A. (2010). Transfer into alternative kinds of fuel as the way of transport power and ecological efficiency increase. Nauchnyy Vestnik MGTU GA, no. 162, pp. 12-21. (in Russian)

4. Glover, B.M. (2008). Boeing and the environment: our commitment to a better future: presentation of boeing management company, Seattle (USA): Boeing Management Company, 40 p.

5. Vasilev, A.Yu., Chelebyan, O.G. and Medvedev, R.S. (2013). Peculiarities of application of biofuel mixture in combustion chambers of modern gas turbine engines. Vestnik SGAU imeni Akademika S.P. Koroleva, no. 3 (41), pp. 57-62. (in Russian)

6. Schmidt, M., Paul, A., Cole, M. and Ploetner, K.O. (2016). Challenges for ground operation arising from aircraft concepts using alternative energy. Journal of Air Transport Management, vol. 56, part B, pp. 107-117. https://doi.org/10.1016/j.jairtraman.2016.04.023

7. Gryadunov, K.I., Kozlov, A.N., Samoilenko, V.M. and Ardeshiri, Sh. (2019). Comparative analysis of quality indicators of aviation kerosine, biofuels and their mixtures. Civil Aviation High Technologies, vol. 22, no. 5, pp. 67-75. https://doi.org/10.26467/2079-0619-2019-22-5-67-75. (in Russian)

8. Bashchenko, N.S., Adzhiev, A.Yu. and Shein, O.G. (2009). Vozmozhnosti polucheniya novogo aviatsionnogo topliva - ASKT [Opportunities for obtaining new aviation fuel-ASKT]. Exposition Oil & Gas, no. 5, pp. 40-41. (in Russian)

9. Ratner, S.V. (2018). Innovation in the aircraft industry: An analysis of results of research programs for developing alternative types of aviation fuel. National Interests: Priorities and Security, vol. 14, no. 3, pp. 492-506. https://doi.org/10.24891/ni.14.3.492. (in Russian)

10. Fu, J., Yang, C., Wu, J., Zhuang, J., Hou, Z. and Lu, X. (2015). Direct production of aviation fuels from microalgae lipids in water. Fuel, vol. 139, pp. 678-683. https://doi.org/10.1016/j.fuel.2014.09.025

11. Gishvarov, A.S. (2008). Ekspluatatsionnaya nadezhnost toplivnykh system vozdushnykh sudov: uchebnoye posobiye [Operational reliability of aircraft fuel systems: textbook. Allowance]. Ufa: UGATU, 298 p. (in Russian)

12. Polezhaev, Yu.V. (Ed.). (2006). Zakony goreniya [The laws of combustion]. Moscow: Energomash, 352 p. (in Russian)

13. Demskaya, I.A. and Raznoschikov, V.V. (2012). Metodika opredeleniya novykh sostavov alternativnykh topliv [Methodology for determining new compositions of alternative fuels]. Aerospace MAI Journal, vol. 19, no. 5, pp. 72-80. (in Russian)

14. Bratkov, A.A. (Ed.). (1985). Teoreticheskiye osnovy khimmotologii [Theoretical foundations of chemmotology]. Moscow: Khimiya, 320 p. (in Russian)

15. Piskunov, V.A. (1983). Himmotologiya v grazhdanskoy aviatsii: spravochnik [Chemmotology in civil aviation: directory]. Moscow: Transport, 248 p. (in Russian)

16. Litvinov, A.A. (1987). Osnovy primeneniya goryuche-smazochnykh materialov v grazhdanskoy aviatsii. Uchebnik dlya VUZ [Bases of fuels and lubricants application in civil aviation: Textbook for Universities]. Moscow: Transport, 308 p. (in Russian)

17. Dubovkin, N.F. (1962). Spravochnik po uglerodnym toplivam i ikh produktam sgoraniya [Handbook on the thermophysical properties of hydrocarbon fuels and their products of combustion]. Moscow-Leningrad: Gosenergoizdat, 288 p. (in Russian)

18. Dubovkin, N.F., Malanicheva, V.G., Massur, Yu.P. and Fedorov, E.P. (1985). Fizikokhimicheskiye i ekspluatatsionnyye svoystva reaktivnykh topliv: spravochnik [Physical and chemical and operational properties of jet fuels: directory]. Moscow: Khimiya, 240 p. (in Russian)

19. Seregin, E.P. (2018). Razvitiye himmotologii [Development of chemmotology]. Moscow: Pervyy tom, 880 p. (in Russian)

20. Khvorenkova, A.Zh. (2014). Teoriya goreniya i vzryva: sbornik zadach [Theory of combustion and explosion: collection. Task]. Yekaterinburg: Izdatelstvo UrGUPS, 80 p. (in Russian)

21. Kulchitskiy, A.R. (2009). Topliva dlya energoustanovok. Raschet termokhimicheskikh pokazateley: uchebnoye posobiye [Fuel for power plants. Calculation of thermochemical parameters: textbook]. Vladimir: Izdatelstvo Vladimirskogo gosudarstvennogo universiteta, 100 p. (in Russian)

22. Chishty, W.A., Chan, T., Canteenwalla, P., Davison, C.R. and Chalmers, J. (2017). Benchmarking data from the experience gained in engine performance and emissions testing on alternative fuels for aviation. Journal of the Global Power and Propulsion Society, pp. 195-210. https://doi.org/10.22261/S5WGLD