Investigation of turbulent heat and mass transfer in combustion of the liquid fuel
DOI:
https://doi.org/10.26577/rcph-2019-i2-16Keywords:
inflammation, liquid fuel, pressure, computational, computational research, combustion chamberAbstract
Conducted research of inflammation of the hexadecane depending on the level of pressure in the combustion chamber under given primary conditions. In the process of work, pressure was increased till 200 bars for choosing optimum characteristics of combustion. In the result of work obtained schedules of distribution of the maximum temperature, maximum concentration of the carbon dioxide and water steam, time of inflammation from the pressure in the combustion chamber. Individually provided distribution of the temperature fields at the moment of inflammation and temperature at the moment of active fuel combustion depending on the pressure in the combustion chamber. Based on the obtained results and schedules, chosen optimum pressure equal to 170 bars, when noticed inflammation with the time of delay equal to 0.8 ms, temperature in the combustion chamber is reaching 2697 K, and also discharging relatively low concentration of the carbon dioxide 0.186 g/g.
References
2 International Energy Outlook, www.eia.gov/outlooks/ieo, 9 p. (2013).
3 V. Messerle, et al. High temperature, 53, 3, 445-452 (2015).
4 S. Bolegenova, et al., Bulgarian Chemical Communications, 48, 236, 236-241 (2016).
5 A.S. Askarova, et al., Thermophysics and aeromechanics, 21, 6, pp. 747-754 (2014).
6 V.S. Maximov, et al., J of Applied Fluid Mechanics, 9, 2, 699-709 (2016).
7 S. Bolegenova, High temperature, 5, 5, 751-757 (2015).
8 V.E. Messerle, et al., Thermophysics and aeromechanics, 23, 1, 125-13 (2016).
9 A.A. Amsden, P.J. O'Rourke, Butler T.D. KIVA-II: A computer program for chemically reactive flows with sprays, (Los Alamos. 1989), 160p.
10 S.A. Zajcev, V.R. Kuznecov, and G.M. Kuncev, Fizika gorenija i vzryva. Vsesojuznyj nauchno-teoreticheskij zhurnal, (Novosibirsk. Nauka. Sibirskoe otdelenie, 1991), g.s.45-52. (In Russ)
11 A.S. Askarova, et al., News of the National Academy of Sciences of the Republic of Kazakhstan, physico-mathematical series, 2, 57-60 (2012). (In Russ)
12 A.S. Askarova, et al., Izvestija NAN RK, serija fiziko-matematicheskaja, 5 (285), 8-11 (2012). (In Russ)
13 A.S. Askarova, et al., Bulgarian Chemical Communications, 48 E, 229-235 (2016).
14 A.S. Askarova, et al., Bulgarian Chemical Communications, 48 E, 272-277 (2016).
15 A.S. Askarova, et al., News of the National Academy of Sciences of the Republic of Kazakhstan, physico-mathematical series, 3 (295), 32-37 (2014).
16 A.S. Askarova, et al., News of the National Academy of Sciences of the Republic of Kazakhstan, physico-mathematical series, 3 (295), 22-26 (2014). (In Russ)
17 A.S. Askarova, et al., News of the National Academy of Sciences of the Republic of Kazakhstan, physico-mathematical series, 2 (300), 98-103 (2015).
18 I. Berezovskaya, et al., Proc. of the 2013 Intern. Conf. on Applied Mathematics and Computational Methods in Engineering AMCME), Rhodes Island, Greece, 1, 155-158 (2013).
19 M. Gorokhovski and R. Borghi, Transactions of SAE, 930075 (1993).
20 Spravochnik himika. Tom vtoroj. Pod red. B.N. Nikol'skogo, (Izd.: Himija, 1964), p.578-579 (In Russ).