This paper presents an energy evaluation of a hybrid system composed of a photovoltaic farm, hydrogen consumption and solid oxide fuel cell, which simulation involves the electric demand of a household in the Western territory of Australia. Specifically, the study evidence a significant solar potential that provides 4659kWh/yr. However, there is an energy deficit in the period when the load energy is higher than the solar generation. As a result, the fuel cell integration solves the irregularities of solar availability, providing 4567kWh/year load demand and 477827kWh/year of energy delivered to the grid. Finally, the configuration of the system generates 50% more than the energy required, which allows enlarging the electric consumption and the possibility to append thermal energy.

G. Bourne, P. Scrock, and A. Stock. “Powering progress: States renewable energy race,” 16 Oct 2018. [Online]. Available: https://www.climatecouncil.org.au/resources/states-renewable-energy/. [Accessed 3 Jun 2019].

L. Brailsford, A. Stock, G. Bourne, and P. Stock. “Powering progress: States renewable energy race,” Climate Council of Australia, 2018.

e. a. t. (Australian Government Department of Resources, G. Australia and A. B. o. A. a. R. Economics, “Australian energy resource assessment,” 2010. [Online]. Available: https://d28rz98at9flks.cloudfront.net/70142/70142_complete.pdf. [Accessed 4 June 2019].

S. Bruce, M. Temminghoff, J. Hayward, E. Schmidt, C. Munnings, D. Palfreyman, and P. Hartley. “National Hydrogen Roadmap: Pathways to an economically sustainable hydrogen industry in Australia,” CSIRO, 2018.

Australian Energy Regulator. “Energy made easy- Understand and compare your home energy usage,” Australian Government, 24 April 2019. [Online]. Available: https://www.energymadeeasy.gov.au/benchmark. [Accessed 16 May 2019].

European Commission. “Photovoltaic geographical information system,” 21 Sept 2017. [Online]. Available: http://re.jrc.ec.europa.eu/pvg_tools/en/tools.html. [Accessed 19 May 2019].

S. Allende. “Energy analysis of a solid oxide fuel cell (Sofc) operated by PV system in the residential sector, in Highland,” M.A. thesis, GRIN Verlag, Munich, 2018.

F. Brihmat, and S. Mekhtoub, “PV cell temperature/ PV power output relationships homer methodology calculation,” National Superior Polytechnic School, Algeria, 2014.

M. Jeffrey, I. Kelly, T. Muneer, and I. Smith. “Evaluation of Solar Modelling Techniques Through Experiment on a 627 kWp Photovoltaic,” Journal of Renewable and Sustainable Energy, vol. 7, no. 3, 2105

Advanced Solar Photonics. “ASP-400GSM - smart moduletm series - high efficiency frameless monocrystalline solar modules,” 2012. [Online]. Available: https://www.enfsolar.com/Product/pdf/Crystalline/50bd9203a2fc0.pdf. . [Accessed 20 May 2019].

T. Muneer, R. Milligan, I. Smith, A. Doyle, M. Pozuelo, and M. Knez. “Energetic, environmental and economic performance of electric,” Edinburgh, Transportation Research Part D: Transport and Environment, 2015, pp. 40-61.

A. Kabza. “Fuel cell formulary,” 9 Nov 2016. [Online]. Available: http://www.pemfc.de/FCF_A4.pdf. [Accessed 21st May 2019].

D. Steward. “National renewable energy laboratory,” FCPower model simulation, 2013. [Online]. Available: https://www.nrel.gov/hydrogen/fuel-cell-power-model.html. [Accessed 5 May 2019].

A. El-Maaty. “Modelling and Simulation of a Photovoltaic Fuel Cell Hybrid System,” PhD. thesis, University of Kassel , Kassel, 2005.

Battelle Memorial Institute, “Manufacturing cost analysis of 100 and 250 kW fuel cell systems for primary power and combined heat and power applications,” U.S. Department of Energy, 2016.

T. Yuan, Q. Duan, X. Chen, X. Yuan, W. Cao, J. Hu, and Q. Zhu. “Coordinated control of a wind-Methanol-Fuel cell system with hydrogen storage,” MDPI, Basel, 2017.

S. Downes. “Perth electricity prices compared,” 7 Jan 2019. [Online]. Available: https://www.canstarblue.com.au/electricity/perth-electricity-prices/. [Accessed 1 Aug 2019].

D. Goos. “Feasibility Study of a Solar Charging Facility for Electric Vehicles in Munich,” M.A. thesis, Edinburgh, 2015.

L. Parry. “Greener Kirkcaldy,” 2015. [Online]. Available: http://www.greenerkirkcaldy.org.uk/how-much-energy-are-your-home-appliances-using/. [Accessed 13 May 2018].

ACS Chemistry for life. “The energy efficiency of heating water,” [Online]. Available: http://highschoolenergy.acs.org/content/hsef/en/how-can-energy-change/energy-efficiency-of-heating-water.html. [Accessed 17 June 2018].

E. Gago, S. Etxebarria, Y. Tham, Y. Aldali, and T. Muneer. “Inter-relationship between mean-daily irradiation and temperature, and decomposition models for hourly irradiation and temperature,” International Journal of Low-Carbon Technologies, vol. 6, no. 1, pp. 22-37, 2010.

A. Ganguly, D. Misra, and S. Ghosh. “Modeling and analysis of solar photovoltaic-electrolyzer-fuel cell hybrid power system integrated with a floriculture greenhouse,” Department of Mechanical Engineering, Bengal Engineering & Science University, Shibpur,, West Bengal, 2010.

K. Ro, and S. Rahman, “Battery or Fuel Cell Support for an Autonomous Photovoltaic Power System,” Renewable energy, vol. 13, no. 2, pp. 203-213.

J. Guan, N. Minh, B. Ramamurthi, J. Ruud, J.-K. Hong and P. Riley. “High Performance Flexible Reversible Solid Oxide Fuel Cell,” United States Department of Energy , Torrance, 2004.

W. Saeed, and G. Warkozek, “Modeling and analysis of renewable PEM fuel cell system,” International Conference on Technologies and Materials for Renewable Energy, Environment and sustainability, pp. 87-101, 2015.

G. Wu, K. Y.Lee, L. Sun, and Y. Xue. “Coordinated fuzzy logic control strategy for hybrid PV array with fuel-cell and ultra-capacitor in a Microgrid,” Department of Electrical and Computer Engineering, Bejing, 2017.

M. Hosseini, I. Dincer, and M. Rosen. “Investigation of renewable energy-Based integrated system for baseload power generation”, Progress in Sustainable Energy Technologies:, Generating Renewable Energy, pp. 21-46, 2014.

M. M. Elamari. “Optimisation of Photovoltaic Powered Electrolysis for Hydrogen Production for a Remote Area in Libya,” PhD, University of Manchester, Manchester, 2011.

Business Juice. “Business energy prices by region,” 2017. [Online]. Available: https://www.businessjuice.co.uk/energy-guides/energy-prices-by-region/. [Accessed 24 July 2018].

N. Hill, and R. Watson. “2016 government GHG conversion,” Department of Business Energy & Industrial Strategy (BEIS), London, 2016.

D. Steward, M. Penev, G. S. Becker, and W. Becker. “Modeling electricity, heat, and hydrogen generation from fuel cell-based distributed energy systems,” National Renewable Energy Laboratory, 2013.

Clean Energy Council. “Clean energy Australia,” 9 April 2018. [Online]. Available: https://assets.cleanenergycouncil.org.au/documents/resources/reports/clean-energy-australia/clean-energy-australia-report-2018.pdf. [Accessed 1st March 2019].

J. Lagorse, D. Paire, and A. Miraoui. “Sizing optimization of a stand-alone street lighting system powered by a hybrid system using fuel cell, PV and battery,” Renewable Energy, vol. 34 , no. 3, pp. 683-691, 2009.

M. Jamshidi, and A. Askarzadeh. “Techno-economic analysis and size optimization of an off-grid hybrid photovoltaic, fuel cell and diesel generator system,” Sustainable Cities and Society, vol. 4, pp. 310-320, 201.

M. Qandil, R. Amano, and A. Abbas, “A stand-alone hybrid photovoltaic, Fuel Cell and Battery System,” Proc. of the ASME 2018 12th International Conference on Energy Sustainability, pp. 24-28, 2018.

H. Rezkab, E. Taha, M. Al-Dhaifallahe, M.Obaidcf, A. Hashema, M.El-Sayedb, M. Ali, and G.Olabi. “Fuel cell as an effective energy storage in reverse osmosis desalination plant powered by photovoltaic system,” Energy, vol. 175, pp. 423-433, 2019.