Open Access
Issue |
E3S Web Conf.
Volume 264, 2021
International Scientific Conference “Construction Mechanics, Hydraulics and Water Resources Engineering” (CONMECHYDRO - 2021)
|
|
---|---|---|
Article Number | 01017 | |
Number of page(s) | 11 | |
Section | Ecology, Hydropower Engineering and Modeling of Physical Processes | |
DOI | https://doi.org/10.1051/e3sconf/202126401017 | |
Published online | 02 June 2021 |
- Vulis L.A., Ershin Sh.A., Yarin L.P. Fundamentals of the theory of a gas torch. - L: Energy, p 203. (1968) [Google Scholar]
- Pope S.B., Ten questions Concerning the Large-Eddy Simulation of Turbulent Flows, New Journal of Physics, 6 (35). (2004), [Google Scholar]
- Khuzhayev I.K. The development of mathematical models of diffusion combustion and gas transportation through the pipeline: Diss. Dr. tech. sciences. - Tashkent, p 336. (2009) [Google Scholar]
- Roach P. Computational hydromechanics. - M.: Mir, p 612. (1980). [Google Scholar]
- Samarsky A.A., Vabishchevich P.N. Computational heat transfer. - M.: URSS editorial., P 784. (2009). [Google Scholar]
- Zverev V.G., Goldin V.D. The difference scheme for solving convection-diffusion problems, Computational technology, 7 (6), pp. 24–37, (2002). [Google Scholar]
- Zh. Rui, G. Han, H. Zhang, S. Wang, H. Pu, and K. Ling, “A new model to evaluate two leak points in a gas pipeline,” Journal of Natural Gas Science and Engineering, 46, pp. 491–497, (2017). [Google Scholar]
- Gudich I.G., Zhukov V.T., Manukovsky K.V., Novikova N.D., Rykov Yu.G., Feodoritova O.B. Numerical simulation of a high-speed combustion chamber using the OpenFOAMpackage, KIAM Preprints named after M.V. Keldish. pp 10–32. doi: 10.209448/prepr-2016-10. (2016). [Google Scholar]
- Yakimov A.S. Mathematical modeling of thermal protection and some heat and mass transfer problems. - Tomsk: Publishing house of Tomsk University, p 214. (2015). [Google Scholar]
- Khujhayev I.K., Khamdamov M.M. A numerical method for solving the problem of an axisymmetric turbulent jet of a propane-butane mixture during diffusion burning, VViPM, Tashkent, p 4. (2018). [Google Scholar]
- Khuzhayev I.K., Bozorov O. Sh. Features of the diffusion torch of multicomponent gas in a turbulent flow, Uzbek Journal of Problems of Mechanics. - Tashkent., (4) pp. 1722. (1998). [Google Scholar]
- Khojaev I.K., Hamdamov M.M. Numerical Results Of Diffusion Combustion In Turbulent Flow Of Reacting Gases, International Journal of Advanced Science and Technology, 29 (9), pp. 2060–2074, (2020), [Google Scholar]
- Aliev F., Zhumaev Z. Sh. Jet currents of reacting gases. Tashkent: Fan., p 132. (1987). [Google Scholar]
- Khojaev I.K., Hamdamov M.M. Numerical Method for Calculating Axisymmetric Turbulent Jets of Reacting Gases During Diffusion Combustion. Jour of Adv Research in Dynamical and Control Systems, 07, (12), (2020). [Google Scholar]
- M. Hamdamov, I. Khujaev, O. Bazarov, K. Isabaev. Axisymmetric turbulent methane jet propagation in a wake air flow under combustion at a finite velocity. IPICSE. 1030(2021) 012163. Doi: 10.1088/1757-899X/1030/1/012163. (2021). [Google Scholar]
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