Investigation of the Combustion Processes in the Gas Turbine Module of an FPSO Operating on Associated Gas Conversion Products

1. Organization for Economic Co-operation and Development (2014): Offshore Vessel, Mobile Offshore Drilling Unit & Floating Production Unit Market Review. Retrieved from http://www.oecd.org/officialdocuments/publicdisplaydocumentpdf/?cote=c/wp6(2014)13/final&doclanguage=en. Search in Google Scholar

2. Visiongain (2012): The Mobile Offshore Drilling Units (MODU) Market 2012–2022. Retrieved from https://www.marketresearch.com/product/sample-6889468.pdf. Search in Google Scholar

3. Stena Drilling (2018): Stena Drill MAX. Retrieved from http://stenadrillingmediabank.s3-eu-west-1.amazonaws.com/stena/wp-content/uploads/2018/04/11110204/Stena-DrillMAX_Technical-Specification_APR2018.pdf. Search in Google Scholar

4. Stena Drilling (2018): Stena Don. Retrieved from https://www.stena-drilling.com/stena/wp-content/uploads/2017/08/80845_Stena_DON_Brochure_A4_FINAL_LO.pdf. Search in Google Scholar

5. OCYAN (2017): FPSO Pioneiro de Libra. Retrieved from http://www.ocyansa.com/en/fleet/fpso-pioneiro-de-libra. Search in Google Scholar

6. Offshore Magazine (2018): OTC 2018: FPSO Market Recovery Under Way, Says EMA Report. Retrieved from https://www.offshore-mag.com/production/article/16804111/otc-2018-fpso-market-recovery-under-way-says-ema-report. Search in Google Scholar

7. Offshore Technology (2018): Report: 55 FPSOs to Start Operations by 2022. Retrieved from https://www.offshore-technology.com/news/report-55-fpsos-start-operations-2022/. Search in Google Scholar

8. Offshore Magazine (2002): Leadon FPSO Delivered on Time, Complete, Within Budget. Retrieved from https://www.offshore-mag.com/production/article/16759844/leadon-fpso-delivered-on-time-complete-within-budget. Search in Google Scholar

9. ENI (2016): Block 15-06 East Hub Development Project. Retrieved from https://www.eni.com/docs/en_IT/enicom/publications-archive/publications/brochures-booklets/countries/brochure_eni_angola_ese_web.pdf. Search in Google Scholar

10. Aker Floating Production (2009): FPSO Dhirubhai-1. Retrieved from http://www.akerfloatingproduction.com/s.cfm/3-12/FPSO-Dhirubhai-1-Operation. Search in Google Scholar

11. OCYAN (2017): FPSO Pioneiro de Libra. Retrieved from http://www.ocyansa.com/en/fleet/fpso-pioneiro-de-libra. Search in Google Scholar

12. OCYAN (2017): FPSO Cidade de Itajaí. Retrieved from https://api.ocyan-sa.com/sites/default/files/2018-09/cidade_do_itajai_0.pdf. Search in Google Scholar

13. Offshore Technology (2018): Triton Oil Field, North Sea Central. Retrieved from https://www.offshore-technology.com/projects/triton/. Search in Google Scholar

14. MAN Diesel & Turbo (2013): Offshore Power Module. Retrieved from https://marine.man-es.com/docs/default-source/shopwaredocumentsarchive/offshore-power-module.pdf?sfvrsn=c2dd9a8_4. Search in Google Scholar

15. Caterpillar Global Petroleum (2013): Offshore Power Generation Module. Retrieved from https://s7d2.scene7.com/is/content/Caterpillar/C10340375. Search in Google Scholar

16. Siemens (2019): We Power the World with Innovative Gas Turbines: Siemens Gas Turbine Portfolio. Retrieved from https://new.siemens.com/global/en/products/energy/power-generation/gas-turbines.html. Search in Google Scholar

17. Olszewski W., Dzida M. (2018): Selected Combined Power Systems Consisted of Self-Ignition Engine and Steam Turbine. Polish Maritime Research, No.1, Vol. 25, 198–203.10.2478/pomr-2018-0042 Search in Google Scholar

18. Domachowski Z., Dzida M. (2019): Applicability of Inlet Air Fogging to Marine Gas Turbine. Polish Maritime Research, Vol. 26, No.1, 15-19.10.2478/pomr-2019-0002 Search in Google Scholar

19. Mazzetti M.J., Nekså P., Walnum H.T., Hemmingsen A.K. (2014): Energy-Efficient Technologies for Reduction of Offshore CO₂ Emissions. Oil and Gas Facilities, Vol. 3, No. 1, 8996.10.2118/169811-PA Search in Google Scholar

20. Tarelko W. (2018): Application of Redundancy in Ship Power Plants of Offshore Vessels. New Trends in Production Engineering, Vol. 1, No. 1, 443-452.10.2478/ntpe-2018-0055 Search in Google Scholar

21. Tarelko W. (2018): Redundancy as a Way Increasing Reliability of Ship Power Plants. New Trends in Production Engineering. Vol. 1, No. 1, 515-522.10.2478/ntpe-2018-0064 Search in Google Scholar

22. The UK Oil and Gas Industry Association Ltd. (2015): Offshore Gas Turbines and Dry Low NOx Burners. An Analysis of the Performance Improvement. Retrieved from https://oilandgasuk.co.uk/wp-content/uploads/2015/05/producys-cayrgory.pdf. Search in Google Scholar

23. Cherednichenko O., Serbin S. (2018): Analysis of Efficiency of the Ship Propulsion System with Thermochemical Recuperation of Waste Heat. Journal of Marine Science and Application, Vol. 17, No.1, 122-130.10.1007/s11804-018-0012-x Search in Google Scholar

24. Cherednichenko O. (2015): Analysis of Efficiency of Diesel-Gas Turbine Power Plant with Thermo-Chemical Heat Recovery. MOTROL: Commission of Motorization and Energetics in Agriculture. Vol.17, No. 2, 25-28. Search in Google Scholar

25. Cherednichenko O. (2019): Efficiency Analysis of Methanol Usage for Marine Turbine Power Plant Operation Based on Waste Heat Chemical Regeneration. Problemele Energeticii Regionale, No.1, 102-111. Search in Google Scholar

26. Cherednichenko O., Serbin S., Dzida M. (2019): Application of Thermo-Chemical Technologies for Conversion of Associated Gas in Diesel-Gas Turbine Installations for Oil and Gas Floating Units. Polish Maritime Research, 3(103), Vol. 26, 181187.10.2478/pomr-2019-0059 Search in Google Scholar

27. Dzida M., Girtler J. (2016). Operation Evaluation Method for Marine Turbine Combustion Engines in Terms of Energetics. Polish Maritime Research, 4(92), Vol. 23, 6772.10.1515/pomr-2016-0071 Search in Google Scholar

28. Farry M. (1998): Ethane from Associated Gas Still the Most Economical. Retrieved from https://www.ogj.com/articles/print/volume-96/issue-23/in-this-issue/gas-processing/ethane-from-associated-gas-still-the-most-economical.html. Search in Google Scholar

29. Budanova N.А., Vantsovskiy V.G., Кorotich E.V. (2004): Development of the Low-Emission Combustion Chambers for the Gas Turbine Engines DN70, DN80, DB90. Marine and Energetic Gas Turbine Building, Vol. 1, GTR&PC “Zorya-Mashproekt”, Nikolaev, 31-35. Search in Google Scholar

30. Serbin S. I., Matveev I. B., Mostipanenko G. B. (2011): Investigations of the Working Process in a “Lean-Burn” Gas Turbine Combustor With Plasma Assistance. IEEE Transactions on Plasma Science, Vol. 39, No. 12, 3331-3335.10.1109/TPS.2011.2166811 Search in Google Scholar

31. Launder B.E., Spalding D.B. (1972): Lectures in Mathematical Models of Turbulence. Academic Press, London. Search in Google Scholar

32. Choudhury D. (1993): Introduction to the Renormalization Group Method and Turbulence Modeling. Fluent Inc. Technical Memorandum TM-107, 1993. Search in Google Scholar

33. Serbin S.I. (1998): Modeling and Experimental Study of Operation Process in a Gas Turbine Combustor with a Plasma-Chemical Element. Combustion Science and Technology, Vol. 139, 137-158.10.1080/00102209808952084 Search in Google Scholar

34. Serbin S.I. (2006): Features of Liquid-Fuel Plasma-Chemical Gasification for Diesel Engines. IEEE Transactions on Plasma Science, Vol. 34, No. 6, 2488-2496.10.1109/TPS.2006.876422 Search in Google Scholar

35. Matveev I., Serbin S., Mostipanenko A. (2007): Numerical Optimization of the „Tornado” Combustor Aerodynamic Parameters. Collection of Technical Papers - 45th AIAA Aerospace Sciences Meeting, Reno, Nevada, AIAA 2007-391, Vol. 7, 4744-4755.10.2514/6.2007-391 Search in Google Scholar

36. Serbin S., Goncharova N. (2017): Investigations of a Gas Turbine Low-Emission Combustor Operating on the Synthesis Gas. International Journal of Chemical Engineering, Vol. 4, 1-14.10.1155/2017/6146984 Search in Google Scholar

37. Serbin S.I., Matveev I.B., Goncharova N.A. (2014): Plasma Assisted Reforming of Natural Gas for GTL. Part I. IEEE Transactions on Plasma Science, Vol. 42, No. 12, 3896-3900.10.1109/TPS.2014.2353042 Search in Google Scholar

38. Matveev I.B., Serbin S.I., Vilkul V.V., Goncharova N.A. (2015): Synthesis Gas Afterburner Based on an Injector Type Plasma-Assisted Combustion System. IEEE Transactions on Plasma Science, Vol. 43, No. 12, 3974-3978.10.1109/TPS.2015.2475125 Search in Google Scholar

39. Gatsenko N.A., Serbin S.I. (1995): Arc Plasmatrons for Burning Fuel in Industrial Installations. Glass and Ceramics, Vol. 51(11-12), 383-386.10.1007/BF00679821 Search in Google Scholar