AERODYNAMICS AND MIXTURE FORMATION IN BURNERS WITH A MULTI-ROW JET FUEL SUPPLY SYSTEM


Keywords: CFD modeling, microjet burners, mixture formation of fuel and oxidizer, aerodynamics

Abstract

The purpose of the work is to establish the laws of isothermal flow and mixture formation of fuel and oxidizer in a new modification of microjet burners equipped with a three-row fuel jet system and oriented to operation at various values of the excess air coefficient. The proposed burners are designed to provide the ability to control the composition of the fuel mixture in the flame stabilization zone and, in general, high efficiency of fuel combustion under the conditions under consideration. As part of the work, the following tasks were to be solved: to establish the main characteristics of the flow and mixture formation in the these burners; to identify the effects of various factors on the structure of the flow and mixture formation in these burners; to determine the rational design parameters of the fuel gas supply system, which realize favorable conditions for the mixture formation of fuel and oxidizer in the flame stabilization zone of the proposed burners. Computer simulation using Fluent code was used as a research method.

The main features of aerodynamics and mixture formation of fuel and oxidizer in the considered burner devices are revealed. The dependences of the characteristics of the processes under study on a number of design and operating parameters have been established. In particular, a comparative analysis of the patterns of flow and mixture formation during the operation of burner devices was performed for various values of the excess air coefficient corresponding to the supply of fuel gas to various fuel supply sections. Data have been obtained to determine the values of the geometric parameters of the fuel supply system, under which the necessary conditions for mixture formation in the flame stabilization zone are realized.1548

References

1. Seyed Ehsan, Hosseini Mazlan, Abdul Wahid. Investigation of bluff-body micro-flameless combustion. Energy Conversion and Management. 2014. V. 88. P. 120-128. https://doi.org/10.1016/j.enconman.2014.08.023
2. Askarova A.S., Messerle V.E., Bolegenova S.A., Maksimov V.Yu. & Nugymanova A.O. Influence of the method of air-fuel mixture supply on the main characteristics of heat and mass transfer processes. Thermophysics and Aeromechanics. 2022. V. 29. P. 107–124 https://doi.org/10.1134/S0869864322010097
3. Fialko N.M., Prokopov V.G., Butovsky L.S., Sherenkovskii Ju.V., Aleshko S.O., Meranova N.O., Polozenko N.P. Peculiarities of the flow of fuel and oxidizer with an echeloned arrangement of flame stabilizers. Industrial heat engineering. 2011. No. 2. P. 59-64. (in rus.)
4. Fialko N.M., Prokopov V.G., Butovsky L.S., Sherenkovskii Ju.V., Meranova N.O., Aleshko S.O., Kokhanenko P.S., Polozenko N.P. Modeling of the flow structure of an isothermal stream in an echeloned lattice of flat flame stabilizers. Industrial heat engineering. 2010. No. 6. P. 28-36. (in rus.)
5. Fialko N.M., Sherenkovskii Ju.V., Prokopov V.G., Polozenko N.P., Meranova N.O., Aleshko S.A., Ivanenko G.V., Yurchuk V.L., Milko E.I., Olkhovskaya N.N. Modeling of the flow structure in echeloned grids of stabilizers by varying their displacement step. 2015. V.2. №8(74). P.29-34. DOI: 10.15587/1729-4061.2015.39193, http://journals.uran.ua/eejet/article/view/39193/37251(in rus.)
6. Fialko N.M., Sherenkovskiy Ju.V., Maison N.V., Meranova N.O., Butovsky L.S., Abdulin M.Z., Polozenko N.P., Klishch A.V., Strizheus S.N., Timoshchenko A.B. Intensification of transfer processes in a burner with a cylindrical flame stabilizer. Scientific Bulletin of NLTU of Ukraine. 2014. 24.5 P. 136-142. chrome-extension://efaidnbmnnnibpcajpcglclefindmkaj/ https://nv.nltu.edu.ua/Archive/2014/24_5/24.pdf (in rus.)
7. Fialko N.M., Sherenkovskiy Ju.V., Maison N.V., Meranova N.O., Butovsky L.S., Abdulin M.Z., Polozenko N.P., Klishch A.V., Strizheus S. N., Timoshchenko A.B. Mathematical modeling of flow and mixture formation processes in a cylindrical stabilizer burner. Eastern European Journal of Advanced Technologies. 2014. V.3. No. 8(69). P.40-44. (in rus.)
8. Fialko N.M., Prokopov V.G., Aleshko S.A., Abdulin M.Z., Rokitko K.V., Maletskaya O.E., Milko E.I., Olkhovskaya N.N., Regragi A., Evtushenko A.A. Computer simulation of flow in microjet burners with asymmetric fuel supply. Scientific Bulletin of NLTU of Ukraine. 2018. V.28. № 8. P. 117-121. https://doi.org/10.15421/40280823 (in rus.)
9. Fialko N.M., Prokopov V.G., Sherenkovskyi Ju.V., Alyoshko S.O., Meranova N.O., Rokitko K.V. CFD modeling of the temperature regimes of the combustion zone of stabilizer type burners with asymmetric fuel supply. Thermophysics and thermal power engineering. 2019. V. 41. №4. P.13-18. (in Ukr.)
10. Fialko N.M., Aleshko S.A., Rokitko K.V., Maletskaya O.E., Milko E.I., Kutnyak O.N., Olkhovskaya N.N., Regragui A., Donchak M.I., Evtushenko A.A. Regularities of mixture formation in the burners of the stabilizer type with one-sided fuel supply. Технологические системы. 2018. 3(38). С. 37-43.
11. Fialko N.M., Butovsky L.S., Prokopov V.G., Sherenkovskii Ju.V., Meranova N.O., Aleshko S.A., Polozenko N.P. Computer simulation of the mixture formation process in stabilizer-type burners with gas supply introduced into the blowing air flow. Industrial heat engineering. 2011. No.1. P. 51-56. (in rus.)
12. Fialko N.M., Butovsky L.S., Prokopov V.G., Granovskaya E.A., Sherenkovskii Ju.V., Aleshko S.A., Kokhanenko P.S. Features of the flow around flat stabilizers with a limited flow Prom heat engineering. 2010. No. 5. P. 26-33. (in rus.)
13. Fialko N.M., Prokopov V.G., Aleshko S.A., Sherenkovskii Ju.V., Meranova N.O., Timoshchenko A.B., Abdulin M.Z., Butovsky L.S. Efficiency of cooling systems for burners of jet-stabilizer type. Technological systems. 2012. № 1. P.52-57.
http://technological-systems.com/index.php/Home/article/view/309/316 (in rus.)
14. Fialko N.M., Prokopov V.G., Sherenkovskii Ju. V., Aleshko S.A., Meranova N.O., Yurchuk V.L., Hanzha M.V. Modeling of heat transfer processes in stabilizer burners with heat-resistant coatings.The development of technical sciences: problems and solutions: Conference Proceedings, April 27-28, 2018. Brno: Baltija Publishing. P.189-192.
15. Fialko N.M., Sherenkovskii Yu.V., Maison M.V., Abdulin. M.Z., Khomuk S.V., Enina A.A., Novitsky V.S., Timoshchenko A.B. Increasing the intensity of transfer processes in a cylindrical stabilizer burner by using rectangular annular niches. Collection of works "Problems of ecology and operation of power facilities" / Institute of industrial ecology. K.: IPTs ALKON NAS of Ukraine, 2014. P. 122-125. (in Ukr.)
16. Fialko N. M., Prokopov V. G., Sherenkovskii Ju. V., Aleshko S. A., Meranova N. O., Abdulin M. Z., Butovskii L. S., Mirgorodsky A. N. Computer modeling of transfer processes in cooling systems of stabilizer-type burners. Industrial heat engineering. 2012. V. 34. №1. P. 64-71. (in rus.)
17. Jones, W.P., Marquis, A.J., Wang, F. Large eddy simulation of a premixed propane turbulent bluff body flame using the Eulerian stochastic field method. Fuel. 2015. V. 140. P. 514-525. https://doi.org/10.1016/j.fuel.2014.06.050

Abstract views: 345
PDF Downloads: 289
Published
2023-06-11
How to Cite
Fialko, N., Prokopov, V., Sherenkovskyi, J., Meranova, N., & Aloshko, S. (2023). AERODYNAMICS AND MIXTURE FORMATION IN BURNERS WITH A MULTI-ROW JET FUEL SUPPLY SYSTEM. Thermophysics and Thermal Power Engineering, 45(2), 34-44. https://doi.org/https://doi.org/10.31472/ttpe.2.2023.4

Most read articles by the same author(s)

1 2 > >>