Numerical simulation of combustion processes for hydrogen-air mixture in a variable cross-section pipe
Authors: Korshunova M.R. | |
Published in issue: #9(14)/2017 | |
DOI: 10.18698/2541-8009-2017-9-165 | |
Category: Aviation and Rocket-Space Engineering | Chapter: Thermal, Electric Jet Engines, and Power Plants of Aircrafts |
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Keywords: combustion, hydrogen-air mixture, gas dynamic computation, simulation of combustion in a pipe, reactor-based approach |
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Published: 14.09.2017 |
We used mathematical models of different orders to investigate various mechanisms of hydrogen oxidation kinetics. We considered the models of a closed adiabatic reactor, and one- and two-dimensional flow reactors. We accordingly selected chemical kinetic mechanisms from the list of those integrated in our hydrocode. We simulated flow and combustion processes in a variable cross-section pipe. We studied the effect the geometric parameters of the flow duct have on the gas dynamics inside it. We used thermodynamic equilibrium methods to compute a one-dimensional flow in the pipe. The results show that various mechanisms of chemical kinetics affect the integral characteristics of the flow and heat transfer in a variable cross-section pipe. We detect certain features of gas dynamics that affect combustion and ignition processes. A comparison to the one-dimensional technique shows a satisfactory agreement of the integral parameters.
References
[1] Bedarev I.A., Fedorov A.V. Comparative analysis of three mathematical models of hydrogen ignition. Fizika goreniya i vzryva, 2006, vol. 42, no. 1, pp. 26–33. (Eng. version: Combustion, Explosion, and Shock Waves, 2006, vol. 42, no. 1, pp. 19–26).
[2] Avduevskiy V.S., Koshkin V.K. Osnovy teploperedachi v aviatsionnoy i raketno-kosmicheskoy tekhnike [Heat transport fundamentals in aerotechnics and rocket and space equipment]. Moscow, Mashinostroenie publ., 1992. 528 p.
[3] Shchetinkov E.S. Fizika goreniya gazov [Gas combustion physics]. Moscow, Nauka publ., 1965. 739 p.
[4] Nechaev Yu.N., Fedorov R.M. Teoriya aviatsionnykh gazoturbinnykh dvigateley. V 2 ch. [Theory of aeronautic gas-turbine engines]. Moscow, Mashinostroenie publ., 1977–1978. Pt. 1 – 312 p., pt. 2 – 335 p.
[5] Kryukov V.G., Naumov V.I. Reacting flotation mathematical simulation based on reactor approach. Fiziko-khimicheskaya kinetika v gazovoy dinamike [Physical-chemical kinetics in gas dynamics], 2004, no. 2. Available at: http://chemphys.edu.ru/issues/2004-2/articles/65/.
[6] Platonov I.M. Modeling Hydrogen combustion in a hypersonic flow using Ansys CFX. Trudy MAI, 2015, no. 82. Available at: http://trudymai.ru/eng/published.php?ID=58562.
[7] Deshko A.E. O On the selection of kinetic model for hydrogen burning in numerical simulation of supersonic non-equilibrium flow. Tekhnicheskaya mekhanika, 2014, no. 1, pp. 37–45.