Domestic hydrogen installation in Poland – technical and economic analysis

• Autorzy: Cholewiński M. , Tomków Ł.

Identyfikatory

DOI

10.1515/aee-2015-0016

• Języki publikacji: EN

Abstrakty

EN

The application of renewable energy sources poses the problems connected with output volatility. In order to decrease this effect the energy storage technologies can be applied, particularly fuel cells connected with hydrogen storage. In this paper the application of SOFC system for a household in Poland is proposed. Economic and technical analysis is performed. It was found that the proposed installation is profitable after 25 years of operation when compared with conventional solution - heat pumps and gas-fired boilers.

Słowa kluczowe

EN

hydrogen; fuel cells; energy storage

• Wydawca: Polish Academy of Sciences, Committee on Electrical Engineering
• Czasopismo: Archives of Electrical Engineering
• Rocznik: 2015
• Tom: Vol. 64, nr 2
• Strony: 189--196
• Opis fizyczny: Bibliogr. 22 poz., rys., wykr., wz.

Twórcy

autor

Cholewiński M.

• Wrocław University of Technology Faculty of Mechanical and Power Engineering Wybrzeże Wyspiańskiego 27, 50-370 Wrocław

autor

Tomków Ł.

• Wrocław University of Technology Faculty of Mechanical and Power Engineering Wybrzeże Wyspiańskiego 27, 50-370 Wrocław

Bibliografia

• [1] Carmo M., Fritz D.L., Mergel J., Stolten D. A comprehensive review on PEM water electrolysis. International Journal of Hydrogen Energy 38: 4901-4934 (2013).
• [2] Pater S., Magiera J., The evaluation of a residential building energy needs using two separate calculation programs (in Polish). Czasopismo Techniczne Chemia 10(108): 165-184 (2011).
• [3] Michalak P., Electrical energy needs in a household and the seasonal renewable energy sources output volatility (in Polish). Elektrotechnika i Elektronika 29(1-2): 8-13 (2010).
• [4] Aprea J.L. Two years experience in hydrogen production and use in Hope bay, Antarctica. International Journal of Hydrogen Energy 37: 14773-14780 (2012).
• [5] Marecki M., Basics of energy conversion (in Polish). WNT Warszawa (2007).
• [6] Kobayashi Y., Ando Y., Kabata T. et al. Extremely High-efficiency Thermal Power System-Solid Oxide Fuel Cell (SOFC) Triple Combined-cycle System. Mitsubishi Heavy Industries Technical Review 48(3): 9-15. (2011).
• [7] Hauch A., Ebbesen S.D., Jensen S.H., Morgensen M., Highly efficient temperature electrolysis. Journal of Materials Chemistry 18: 2331-2340 (2008).
• [8] Spendelow J., Marcinkoski J., Fuel Cell System Cost - 2012. DOE Fuel Cell Technologies Program Record (2012).
• [9] Weimar M., Chick L., Gotthold D., Whyatt G., Cost Study for Manufacturing of Solid Oxide Fuel Cell Power Systems. Pacific Northwest National Laboratory (2013).
• [10] Szymański B. Photovoltaic installations (in Polish). Wydanie III. GLOBenergia (2013).
• [11] Caduff M., Huijbregts M.A.J., Koehler A. et al. Scaling Relationships in Life Cycle Assessment. The Case of Heat Production from Biomass and Heat Pumps. Journal of Industrial Ecology 18(3): 393-406 (2014).
• [12] Wu R., Energy Efficiency Technologies - Air Source Heat Pump vs. Ground Source Heat Pump. Journal of Sustainable Development 2(2): 14-23 (2009).
• [13] Balta M.T., Exergetic cost analysis and sustainability assessment of various low exergy heating systems. Energy and Buildings 55: 721-727 (2012).
• [14] Fan R., Gao Y., Hua L. et al., Thermal performance and operation strategy optimization for a practical hybrid ground-source heat-pump system. Energy and Buildings 78: 238-247 (2014).
• [15] Kim Y-J., Woo N-S., Jang S-C., Choi J-J., Feasibility study of a hybrid renewable energy system with geothermal and solar heat sources for residential buildings in South Korea. Journal of Mechanical Science and Technology 27(8): 2513-2521 (2013).
• [16] Khorasaninejad E., Hajabdollahi H., Thermo-economic and environmental optimization of solar assisted heat pump by using multi-objective particle swam algorithm. Energy 72: 680-690 (2014).
• [17] Jiang X.S., Jing Z.X., Li Y.Z. et al., Modelling and operation optimization of an integrated energy based direct district water-heating system. Energy 64: 375-388 (2014).
• [18] Pensini A., Rasmussen C.N., Kampton W., Economic analysis of using excess renewable electricity to displace heating fuels. Applied Energy 131: 530-543 (2014).
• [19] Rees S., Curtis R., National Deployment of Domestic Geothermal Heat Pump Technology: Observations on the UK Experience 1995-2013. Energies 7: 5460-5499 (2014).
• [20] Li F., Zheng G., Tian Z., Optimal operation strategy of the hybrid heating system composed of centrifugal heat pumps and gas boilers. Energy and Buildings 58: 27-36 (2013).
• [21] Skowroński M., Pumping systems (in Polish). Oficyna Wydawniczna Politechniki Wrocławskiej (2009).
• [22] Paska J., Economy of electricity production (in Polish). Przegląd Elektrotechniczny 80(9): 894-900 (2004).