Investigation of the parameters influence of the oxy-fuel burner and the test bench parameters on the deviation of the model similarity criterions from the full-scale values
Vol 7, Issue 1, 2024
VIEWS - 209 (Abstract) 141 (PDF)
Abstract
The article presents the results of a study of the workflow parameters influence in the full-scale and model burners of the combustion chamber oxy-fuel combined cycle on the deviation of similarity criteria from full-scale values. The variable parameters are the pressure and velocity of the fluid under model conditions, as well as the power of model and full-scale burners. The supercritical parameters of the working fluid in the cylindrical sections of the combustion zone at a pressure of 30 MPa and a temperature of 1570 ℃ were taken as full-scale conditions. In this paper, the dependences of the deviations of hydrodynamic and thermophysical similarity criteria on the speed and pressure of the combustion products of an oxygen-fuel mixture with carbon dioxide in the working zone of the test bench for burners are obtained. The parameters of the working fluid and the power of model burners are obtained, at which the values of the criteria deviations are minimal.
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1. Boontek N, Theinnoi K, Sittichompoo S. The effects of combustion phasing induced by water injection on deNOx performance of GDI engine at MBT ignition timing. Applied Chemical Engineering 2023; 6(2): 2366. doi: 10.24294/ace.v6i2.2366
2. Tian MW, Abed AM, Chauhan BS, et al. Techno-economic case study of applying heat recovery and CO2 capture systems on a gas turbine power plant, 4E analysis. Case Studies in Thermal Engineering 2023; 49: 103330. doi: 10.1016/j.csite.2023.103330
3. Bui M, Adjiman CS, Bardow A, et al. Carbon capture and storage (CCS): The way forward. Energy & Environmental Science 2018; 11(5): 1062–1176. doi: 10.1039/c7ee02342a
4. Kosoi AS, Zeigarnik YuA, Popel’ OS, et al. The conceptual process arrangement of a steam—Gas power plant with fully capturing carbon dioxide from combustion products. Thermal Engineering 2018; 65(9): 597–605. doi: 10.1134/s0040601518090045
5. Fu X, Wu J, Sun Z, et al. Peak-Shaving of the oxy-fuel power plant coupled with liquid O2 storage. Journal of Thermal Science 2023; 32(5): 1722–1736. doi: 10.1007/s11630-023-1864-1
6. Rogalev A, Komarov I, Kindra V, Zlyvko O. Entrepreneurial assessment of sustainable development technologies for power energy sector. Entrepreneurship and Sustainability Issues 2018; 6(1): 429–445. doi: 10.9770/jesi.2018.6.1(26)
7. Fan JL, Xu M, Li F, et al. Carbon capture and storage (CCS) retrofit potential of coal-fired power plants in China: The technology lock-in and cost optimization perspective. Applied Energy 2018; 229: 326–334. doi: 10.1016/j.apenergy.2018.07.117
8. Allam R, Martin S, Forrest B, et al. Demonstration of the Allam cycle: An update on the development status of a high efficiency supercritical carbon dioxide power process employing full carbon capture. Energy Procedia 2017; 114: 5948–5966. doi: 10.1016/j.egypro.2017.03.1731
9. Komarov II, Kharlamova DM, Vegera AN, Naumov VY. Study on effect CO2 diluent on fuel cоmbustion in methane-oxygen combustion chambers (Russian). Vestnik IGEU 2021; (2): 14–22. doi: 10.17588/2072-2672.2021.2.014-022
10. Saanum I, Ditaranto M. Experimental study of oxy-fuel combustion under gas turbine conditions. Energy & Fuels 2017; 31(4): 4445–4451. doi: 10.1021/acs.energyfuels.6b03114
11. Chan W, Lei X, Chang F, Li H. Thermodynamic analysis and optimization of Allam cycle with a reheating configuration. Energy Conversion and Management 2020; 224: 113382. doi: 10.1016/j.enconman.2020.113382
12. Iwai Y, Itoh M, Morisawa Y, et al. Development approach to the combustor of gas turbine for oxy-fuel, supercritical CO2 cycle. In: Proceedings of the ASME Turbo Expo 2015: Turbine Technical Conference and Exposition; 15–19 June 2015; Montreal, Canada.
13. Goodwin DG, Moffat HK, Speth RL. Cantera: An object-oriented software toolkit for chemical kinetics, thermodynamics, and transport processes. Available online: http://www.cantera.org (accessed on XX).
14. Anderson R, Hustad C, Skutley P, Hollis R. Oxy-fuel turbo machinery development for energy intensive industrial applications. Energy Procedia 2014; 63: 511–523. doi: 10.1016/j.egypro.2014.11.056
15. Guo H, Jub Y, Maruta K, et al. Numerical investigation of CH4/CO2/Air and CH4/CO2/O2 counterflow premixed flames with radiation reabsorption. Combustion Science and Technology 1998; 135(1–6): 49–64. doi: 10.1080/00102209808924149
16. Guo H, Ju Y, Maruta K, et al. Radiation extinction limit of counterflow premixed lean methane-air flames. Combustion and Flame 1997; 109(4): 639–646. doi: 10.1016/s0010-2180(97)00050-3.
17. Zhukov VP, Sechenov VA, Starikovskii AY. Combustion, explosion, and shock waves. 2003; 39(5): 487–495. doi: 10.1023/a: 1026186231905.
18. Smith GP, Golden DM, Frenklach M, et al. GRI Mechanism 3.0. University of California, Berkeley. Accessed December 16, 2019. http://combustion.berkeley.edu/gri-mech/version30/ text30.html.URL: https://dspace.www1.vlsu.ru/bitstream/123456789/3062/1/00635.pdf
19. Zuev KI. Fundamentals of similarity theory: Lecture notes; 2011. p.51. URL: https://dspace.www1.vlsu.ru/bitstream/123456789/3062/1/00635.pdf
20. Norkin NN. On approximate fire modeling of stationary processes of gorenje gases (Russian). Georesources Engineering 1948; 64: 220–231.
21. Guryanov AI, Evdokimov OA, Guryanova MM, Veretennikov SV. Criterion analysis and experimental study of combustion mechanisms in a bidirectional swirling flow and their relationship with pollutants emission. International Journal of Energy Research 2021; 45(4): 5500–5516. doi: 10.1002/er.6178
22. Kindra V. O. et al. Parametric optimization of the semi-closed oxy-fuel combustion combined cycle Energy saving theory and practice; 2020 Oktober 19–23; Kursk. Kursk: Closed Joint Stock Company "University. doi: 10.1088/1742-6596/1683/5/052028
23. Calculation and design of combustion chambers for gas turbine and combined-cycle gas plants. Moscow: Ministry of Heavy Engineering under the Council of Ministers of the USSR; 1974. p. 126. URL: https://files.stroyinf.ru/Data2/1/4293764/4293764051.pdf
24. Electronic resource. Official website of Siemens. Available online: https://www.siemens-energy.com/global/en/home/products-services/product/sgt-800.html#/ (accessed on 31.12.2023).
DOI: https://doi.org/10.24294/ace.v7i1.2802
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