Application analysis of a hybrid solid oxide fuel cell-gas turbine system for marine power plants

References

• Baldi F, Moret S, Tammi K, Marechal F. 2020. The role of solid oxide fuel cells in future ship energy systems. Energy. 194(1):1–22.
   Google Scholar
• Capstone Turbine Corporation. 2020. https://www.capstoneturbine.com.
   Google Scholar
• Cheddie DF. 2010. Integration of a solid oxide fuel cell into a 10 MW gas turbine power plant. Energies. 3:754–769. doi:https://doi.org/10.3390/en3040754.
   Web of Science ®Google Scholar
• Chen D, Xu Y, Hu B, Yan C, Lu L. 2018. Investigation of proper external air flow path for tubular fuel cell stacks with an anode support feature. Energy Convers Manage. 171:807–814. doi:https://doi.org/10.1016/j.enconman.2018.06.036.
   Google Scholar
• Chen D, Xu Y, Tade MO, Shao Z. 2017. General regulation of air flow distribution characteristics within planar solid oxide fuel cell Stacks. ACS Energy Letters. 2:319–326. doi:https://doi.org/10.1021/acsenergylett.6b00548.
   Google Scholar
• Cherednichenko O, Serbin S. 2018. Analysis of efficiency of the ship propulsion system with thermochemical recuperation of waste heat. J Mar Sci Appl. 17(1):122–130. doi:https://doi.org/10.1007/s11804-018-0012-x.
   Google Scholar
• 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. Pol Marit Res. 26(103):181–187. doi:https://doi.org/10.2478/pomr-2019-0059.
   Google Scholar
• Díaz-de-Baldasano MC, Mateos FJ, Núñez-Rivas LR, Leo TJ. 2014. Conceptual design of offshore platform supply vessel based on hybrid diesel generator-fuel cell power plant. Appl Energy. 116:91–100.
   Web of Science ®Google Scholar
• Fernandes A, Brabandt J, Posdziech O, Saadabadi A, Recalde M, Fan L, Promes EO, Liu M, Woudstra T, Aravind PV. 2018. Design, construction, and testing of a gasifier-specific solid oxide fuel cell system. Energies. 11:1–17.
   Web of Science ®Google Scholar
• Fuentes DI, Pérez HL. 2015. Fuel-cell integration on board surface ships. Ship Sci Technol. 8(16):19–28.
   Google Scholar
• Gatsenko NA, Serbin SI. 1995. Arc plasmatrons for burning fuel in industrial installations. Glass Ceram. 51(11–12):383–386. doi:https://doi.org/10.1007/BF00679821.
   Google Scholar
• Gimelli A, Sannino R. 2017. Thermodynamic model validation of Capstone C30 micro gs turbine. Energy Procedia. 126(201709):955–962.
   Google Scholar
• Han J, Charpentier JF, Tang T. 2015. State of the art of fuel cells for ship applications. HAL-01073612. https://hal.archives-ouvertes.fr/hal-01073612, doi:https://doi.org/10.1109/ISIE.2012.6237306.
   Google Scholar
• Kwaśniewski T, Piwowarski M. 2020. Design analysis of hybrid gas turbine-fuel cell power plant in stationary and marine application. Pol Marit Res. 27(106):107–119. http://www.bg.pg.gda.pl/pmr/pdf/PMRes_2020_2.pdf.
   Google Scholar
• Langfeldt L. 2018. Maritime fuel cell applications. Technologies and ongoing developments. https://www.jterc.or.jp/koku/koku_semina/pdf/180221_presentation-01.pdf.
   Google Scholar
• Lemański M, Topolski J, Badur J. 2004. Analysis strategies for gas turbine-solid oxide fuel cell hybrid cycles. In: Domachowski Z, editor. Technical, economic, and environmental aspects of combined cycle power plants. Gdańsk: TU Press; p. 213–220.
   Google Scholar
• Lingstädt T, Grimm F, Krummrein T, Bücheler S, Aigner M. 2018. Experimental investigation of an SOFC off-gas combustor for hybrid power plant usage with low heating values realised by natural gas addition. In: GPPS Forum 18 Global Power and Propulsion Society, Montreal, 1–8. https://doi.org/https://doi.org/10.5281/zenodo.1342414.
   Google Scholar
• Matveev I, Matveeva S, Serbin S. 2007a. Design and preliminary result of the plasma assisted Tornado combustor. In: 43rd AIAA/ASME/SAE/ASEE Joint Propulsion Conference, Cincinnati, OH, AIAA 2007-5628.6:6091–6098.
   Google Scholar
• Matveev I, Serbin S. 2006. Experimental and numerical definition of the reverse vortex combustor parameters. In: 44th AIAA Aerospace Sciences Meeting and Exhibit, Reno, Nevada, AIAA-2006-0551, 6662–6673.
   Google Scholar
• Matveev I, Serbin S. 2012. Investigation of a reverse-vortex plasma assisted combustion system. In: ASME 2012 Heat Transfer Summer Conf., Puerto Rico, USA, HT2012-58037. 2012:133(140. https://doi.org/https://doi.org/10.1115/HT2012-58037.
   Google Scholar
• Matveev I, Serbin S, Mostipanenko A. 2007b. Numerical optimization of the “Tornado” combustor aerodynamic parameters. In: 45th AIAA Aerospace Sciences Meeting, Reno, Nevada, AIAA 2007-391.7, 4744–4755.
   Google Scholar
• Matveev IB, Serbin SI, Vilkul VV, Goncharova NA. 2015. Synthesis gas afterburner based on an injector type plasma-assisted combustion system. IEEE Trans Plasma Sci. 43(12):3974–3978. doi:https://doi.org/10.1109/TPS.2015.2475125.
   Google Scholar
• McPhail SJ, Leto L, Boigues-Muñoz C. 2012. The Yellow Pages of SOFC Technology, International Status of SOFC Deployment 2012-2013. IEA Implementing Agreement Advanced Fuel Cells, Annex 24 – SOFC, https://www.researchgate.net/publication/311869822_The_Yellow_Pages_of_SOFC_Technology_International_Status_of_SOFC_deployment_2012-2013.
   Google Scholar
• Minnehan JJ, Pratt JW. 2017. Practical application limits of fuel cells and batteries for zero emission vessels. SANDIA Report: SAND2017-12665.
   Google Scholar
• National Fuel Cell Research Center. 2010. Hybrid fuel cell / gas turbine systems. Analyses of hybrid fuel cell gas turbine systems. http://www.nfcrc.uci.edu/PDF_Research_Summaries/HYBRIDfuelCELL_GASturbineSystems-AnalysesHybridFuelCellGasTurbineSystems.pdf.
   Google Scholar
• Nguyen TV, Elmegaard B, Pierobon L, Haglind F, Breuhaus P. 2012. Modelling and analysis of offshore energy systems on North Sea oil and gas platforms. Proceedings of the 53rd SIMS conference on Simulation and Modelling. https://backend.orbit.dtu.dk/ws/portalfiles/portal/38487211/content.pdf.
   Google Scholar
• Pratt JW, Chan SH. 2017. Maritime fuel cell generator project. SANDIA Report: SAND2017-5751.
   Google Scholar
• Saisirirat P. 2015. The solid oxide fuel cell (SOFC) and gas turbine (GT) hybrid system numerical model. Energy Procedia. 79:845–850. doi:https://doi.org/10.1016/j.egypro.2015.11.576.
   Google Scholar
• Sanusi YS, Mokheimer EMA. 2019. Performance analysis of a membrane-based reformer-combustor reactor for hydrogen generation. Int J Energy Res. 43:189–203. doi:https://doi.org/10.1002/er.4250.
   Google Scholar
• Schumacher E. 2018. Alternative fuels and fuel cells in ships – Status of the e4ships. Project Cluster, NOW GmbH. https://www.altenergy.info/wp-content/uploads/2018/10/2-Erik-Schumacher-e4ships-Project-Cluster.pdf.
   Google Scholar
• Serbin SI. 1998. Modeling and experimental study of operation process in a gas turbine combustor with a plasma-chemical element. Combust Sci Technol. 139:137–158. doi:https://doi.org/10.1080/00102209808952084.
   Web of Science ®Google Scholar
• Serbin SI. 2006. Features of liquid-fuel plasma-chemical gasification for diesel engines. IEEE Trans Plasma Sci. 34(6):2488–2496. doi:https://doi.org/10.1109/TPS.2006.876422.
   Google Scholar
• Serbin S, Goncharova N. 2017. Investigations of a gas turbine low-emission combustor operating on the synthesis gas. Int J Chem Eng. 2017:1–14. doi:https://doi.org/10.1155/2017/6146984.
   Google Scholar
• Serbin SI, Matveev IB, Goncharova NA. 2014. Plasma assisted reforming of natural gas for GTL. Part I. IEEE Trans Plasma Sci. 42(12):3896–3900. doi:https://doi.org/10.1109/TPS.2014.2353042.
   Google Scholar
• Serbin SI, Matveev IB, Mostipanenko GB. 2011. Investigations of the working process in a “lean-burn” gas turbine combustor with plasma assistance. IEEE Trans Plasma Sci. 39(12):3331–3335. doi:https://doi.org/10.1155/2017/6146984.
   Google Scholar
• Serbin SI, Washchilenko NV, Cherednichenko OK, Chen D, Zonming Y. 2020. Hybrid power plant on fuel elements. Decision on the issuance of a declaratory patent for invention application 2019 11476 (Ukraine) from November 27, 2019.
   Google Scholar
• Sun J, Stebe J, Kennell C. 2010. Feasibility and design implications of fuel cell power for sealift ships. Nav Eng J. 122(3):87–102. doi:https://doi.org/10.1111/j.1559-3584.2010.00274.x.
   Google Scholar
• Tunca F, Kaya N. 2017. Thermodynamic analysis of gas turbine–solid oxide fuel cell (GT-SOFC) aircraft auxiliary power unit (APU). Int J Adv Mech Auto Eng. 4(1):10–14.
   Google Scholar
• U.S. Dept. of Energy, Office of Fossil Energy. 2004. Fuel Cell Handbook, 7th Edition. National Energy Technology Laboratory, Morgantown, West Virginia: EG&G Technical Services, Inc.
   Google Scholar
• van Biert L, Godjevac M, Visser K, Aravind PV. 2016. A review of fuel cell systems for maritime applications. J Power Sources. 327:345–364. doi:https://doi.org/10.1016/j.jpowsour.2016.07.007.
   Web of Science ®Google Scholar
• Vogler F, Würsig G. 2010. Fuel cells in maritime applications. Challenges, chances and experience. http://conference.ing.unipi.it/ichs2011/papers/158.pdf.
   Google Scholar
• Welaya YMA, Ammar NR. 2013. Thermodynamic analysis of a combined gas turbine power plant with a solid oxide fuel cell for marine applications. Int J Naval Architect Ocean Eng. 5(4):529–545. doi:https://doi.org/10.2478/IJNAOE-2013-0151.
   Web of Science ®Google Scholar
• Zaccaria V, Tucker D, Traverso A. 2017. Gas turbine advanced power systems to improve solid oxide fuel cell economic viability. J Global Power Propul Soc. 1:28–40.
   Google Scholar