Application of thermo-chemical technologies for conversion of associated gas in diesel-gas turbine installations for oil and gas floating units

Cherednichenko, Oleksandr; Serbin, Serhiy; Dzida, Marek

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Tytuł artykułu

Application of thermo-chemical technologies for conversion of associated gas in diesel-gas turbine installations for oil and gas floating units

Autorzy

Cherednichenko Oleksandr , Serbin Serhiy , Dzida Marek

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Abstrakty

The paper considers the issue of thermo-chemical recovery of engine’s waste heat and its further use for steam conversion of the associated gas for oil and gas floating units. The characteristics of the associated gas are presented, and problems of its application in dual-fuel medium-speed internal combustion engines are discussed. Various variants of combined diesel-gas turbine power plant with thermo-chemical heat recovery are analyzed. The heat of the gas turbine engine exhaust gas is utilized in a thermo-chemical reactor and a steam generator. The engines operate on synthesis gas, which is obtained as a result of steam conversion of the associated gas. Criteria for evaluating the effectiveness of the developed schemes are proposed. The results of mathematical modeling of processes in a 14.1 MW diesel-gas turbine power plant with waste heat recovery are presented. The effect of the steam/associated gas ratio on the efficiency criteria is analyzed. The obtained results indicate relatively high effectiveness of the scheme with separate high and low pressure thermo-chemical reactors for producing fuel gas for both gas turbine and internal combustion engines. The calculated efficiency of such a power plant for considered input parameters is 45.6%.

Słowa kluczowe

thermo-chemical heat recovery gas turbine engine diesel engine associated gas steam reforming efficiency methane number

Wydawca

Gdańsk University of Technology, Faculty of Ocean Engineering & Ship Technology

Czasopismo

Polish Maritime Research

Rocznik

2019

Tom

nr 3

Strony

181--187

Opis fizyczny

Bibliogr. 23 poz., rys., tab.

Twórcy

autor

Cherednichenko Oleksandr

cherednichenko.aleksandr65@gmail.com

Admiral Makarov National University of Shipbuilding Heroyiv Ukraine av. 9 54025 Mykolaiv Ukraine

autor

Serbin Serhiy

serbin1958@gmail.com

Admiral Makarov National University of Shipbuilding Heroyiv Ukraine av. 9 54025 Mykolaiv Ukraine

autor

Dzida Marek

dzida@pg.edu.pl

Gdańsk University of Technology 11/12 Gabriela Narutowicza Street 80-233 Gdańsk Poland

Bibliografia

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5. Szymaniak M. (2018): Steam Turbine Stage Modernisation in Front of the Extraction Point. Polish Maritime Research, No.2, Vol. 25, 116–122.
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7. Michael Farry (1998) Ethane from associated gas still the most economical. Retrieved from https://www.ogj. com/articles/print/volume-96/issue-23/in-this-issue/gasprocessing/ethane-from-associated-gas-still-the-mosteconomical.html , Accessed 20 May 2019.
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9. Nguyen T., Elmegaard B., Pierobon L., Haglind F., Breuhaus P. (2012): Modelling and analysis of offshore energy systems on North Sea oil and gas platforms. 53-rd International Conference of Scandinavian Simulation Society, SIMS 2012. Retrieved from https:// www.researchgate.net/publication/263973093_ Modelling_and_analysis_of_offshore_energy_ systems_on_North_Sea_oil_and_gas_platforms/ figures?lo=1.
10. Foss M. M. (2004): Interstate natural gas quality specifications & interchangeability. Center for Energy Economics. Retrieved from http://www.beg.utexas.edu/files/ energyecon/global-gas-and-lng/CEE_Interstate_Natural_ Gas_Quality_Specifications_and_Interchangeability.pdf.
11. Oil & Gas Industry Overview (2019): Crude Oil and Natural Gas: From Source to Final Products. Retrieved from https://www.ihrdc.com/els/po-demo/module01/ mod_001_02.htm.
12. WÄRTSILÄ(2019): Wärtsilä Methane number calculator. Retrieved from https://www.wartsila.com/products/ marine-oil-gas/gas-solutions/methane-number-calculator.
13. ISO/TR 22302:2014 (2014): Natural gas. Calculation of methane number.
14. WÄRTSILÄ(2015): Wärtsilä GasReformer. Retrieved from https://www.offshore-europe.co.uk/__novadocuments/31 687?v=635089663131000000.
15. Gatsenko NA., Serbin SI. (1995). Arc plasmatrons for burning fuel in industrial installations, Glass and Ceramics, vol. 51 (11-12), 383–386
16. Matveev I. B., Tropina A. A., Serbin S. I., Kostyuk V. Y. (2008): Arc modeling in a plasmatron channel. IEEE Trans. Plasma Sci., No.1, Vol. 36, part 2, 293–298.
17. Serbin SI, Matveev IB, Goncharova MA (2014). Plasma Assisted Reforming of Natural Gas for GTL. Part I, IEEE Trans. Plasma Sci., vol. 42, no. 12, pp. 3896-3900
18. Matveev I., Matveeva S., Serbin S. (2007): Design and Preliminary Result of the Plasma Assisted Tornado Combustor. Collection of Technical Papers - 43rd AIAA/ ASME/SAE/ASEE Joint Propulsion Conference, Cincinnati, OH, AIAA 2007-5628, Vol. 6, 6091-6098.
19. Matveev I., Serbin S. (2012): Investigation of a reverse-vortex plasma assisted combustion system. Proc. of the ASME 2012 Heat Transfer Summer Conf., Puerto Rico, USA, HT2012- 58037, 133-140.
20. Matveev I., Serbin S., (2006): Experimental and Numerical Definition of the Reverse Vortex Combustor Parameters. 44th AIAA Aerospace Sciences Meeting and Exhibit, Reno, Nevada, AIAA-2006-0551, 6662-6673.
21. Cherednichenko O., Serbin S. (2018): Analysis of Efficiency of the Ship Propulsion System with Thermochemical Recuperation of Waste Heat. J. Marine. Sci. Appl. No.1, Vol. 17, 122-130.
22. Serbin S.I. (2006): Features of liquid-fuel plasma-chemical gasification for diesel engines. IEEE Trans. Plasma Sci., 6, No.vol. 34, 2488-2496.
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Uwagi

Opracowanie rekordu w ramach umowy 509/P-DUN/2018 ze środków MNiSW przeznaczonych na działalność upowszechniającą naukę (2019).

Typ dokumentu

Bibliografia

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