The goal of this work is to evaluate and to give evidence to innovative and sustainable technologies applied in the construction industry to carry out self-sufficient energy and to use the surplus energy for the production of hydrogen vector. An architectural integration design along with high technological systems is performed. The intermittency of renewable energy sources along with climatic conditions dependency imposes to store the energy produced, since it is clean and having a big calorific value: the hydrogen vector is currently the better energy carrier. The energy to obtain hydrogen by dissociation of water is supplied by a photovoltaic (PV) system. Through the computations of the annual energy balance between building’s demand and supply energy, it is shown that the extra energy produced by the solar generation system is used also for the hydrogen sustainable mobility. The renewable systems, model’s design and case study are tackled for the bigger one of the Dodecanese islands in the South Aegean Sea: Rhodes (Rodos). The Zero energy building’s integrative design-based approach, applied to the Hotel Buildings type industry is targeted to have new hotels buildings, in the Mediterranean typical warm climate, with zero energy consumption. The designers, authors of this work, have studied a real case or pilot project of an hotel, in the resort formula, suitable to the Greek landscape, showcasing technologies and innovations supporting environmental sustainability, energy efficiency, use of renewable energy, electricity storage by fuel cells that are tools particularly applicable to hotel facility [1]. The feasibility of this case study or pilot project is aligned jointly to the target of Zero Emission and Energy Efficiency EU Policy, as imposed by EU Directives. The strategic position of Rhodes in a geographical point full of sun and wind renewable energy power, enables to ensure the clean energy production, the current interesting development of the hydrogen as energy vector in the buildings [2] and also to satisfy the demand of tourists’ accommodation by having at the same time zero energy costs. Moreover, the presence in the island of the best example worldwide of ancient and sustainable built environment (UNESCO World Heritage site), represents also the best motivation to give witness there of a zero impact environmental urban development through the adoption of these achieved scientific results for a major success of Zero Energy Buildings.
References
[1]
Lamacchia, F.P. and Perfetto, G. (2015) Sustainable and Competitive Hotels through Energy Innovation. Capital Matera Zero Energy Resort, Nearly Zero Energy Hotels 2015 Conference, Acropolis Nice (France), 24th June.
[2]
Lamacchia, F.P. and Perfetto, G. (2015) Hydrogen for Energy and Sustainable Development (HFORE & SD) (Il vettoreIdrogeno per l’Energia e lo SviluppoSostenibile)—European Energy Day by EU during Sustainable Energy Mounth of June 2015. EUSEW, Workshop on Energy Related-Issues Targeted to Professional Engineers, Architects and Technicians, (Workshop tematico per tecniciprofessionistiingegneri, architetti, geometri e periti), Held in Matera, Italy, 11th June2015.
[3]
Lamacchia, F.P. and Perfetto, G. (2014) Nearly Zero Energy Buildings (nZEB)’s Design in South Europe— Mediterranean Climate, European Energy Day by EU during Sustainable Energy Week, 23-27th June 2014. EUSEW, Workshop on Energy Related-Issues Targeted to Professional Engineers, Architects and Technicians (Workshop tematico per tecniciprofessionistiingegneri, architetti, geometri e periti), Held in Matera, Italy, 27th June 2014.
[4]
Tsoutsos, T., Tournaki, S., de Santos, C.A. and Vercellotti, R. (2013) Nearly Zero Energy Buildings Application in Mediterranean Hotels. Energy Procedia, 42, 230-238. http://dx.doi.org/10.1016/j.egypro.2013.11.023
[5]
Farrou, I., Kolokotroni, M. and Santamouris, M. (2012) A Method for Energy Classification of Hotels: A Case-Study of Greece. Energy and Buildings, 55, 553-562. http://dx.doi.org/10.1016/j.enbuild.2012.08.010
[6]
European Commission (2012) Commission Delegated Regulation (EU) No 244/2012 of 16 January 2012 Supplementing Directive 2010/31/EU on the Energy Performance of Buildings. Official Journal, L081.
[7]
European Commission (2011) A Roadmap for Moving to a Competitive Low Carbon Economy in 2050. COM(2011) 112 final.
[8]
IEA (2013) Energy Efficiency Requirements in Building Codes: Energy Efficiency Policies for New Buildings. Assessed January. http://www.iea.org/publications/freepublications/publication/Building_Codes-1.pdf%20
[9]
Zografakis, N., Gillas, K., Pollaki, A., Profylienou, M., Bounialetou, F. and Tsagarakis, K. (2011) Assessment of Practices and Technologies of Energy Saving and Renewable Energy Sources in Hotels in Crete. Renewable Energy, 36, 1323-1328. http://dx.doi.org/10.1016/j.renene.2010.10.015
[10]
European Commission (2010) Directive 2010/31/EU of 19 May 2010 on the Energy Performance of Buildings (Recast). Official Journal, L153/13.
[11]
Perfetto, G. (2010) BIPV Building Integration Photovoltaics Systems: Technical & Architectural Issues. The Master Builder n. 10.
[12]
(2006) Sistemi Fotovoltaici e Termici–Strumenti per il Progettista”/“Photovoltaic and Solar Thermal Systems. Designer’s Handbook, AAVV-CELID—Torino.
[13]
(2003) I Sistemi Solari Fotovoltaici: Caratteristiche, Dimensionamento e Integrazione Architettonica/Photovoltaics Solar Systems: Requirements, Design and Building Integration: Lecture to the Laboratory of TechnologicalInnovation (F0T1). G. Perfetto - Politecnico di Torino, AA 2003-6.
[14]
(2010) Hydrogen and Fuel Cells: Fundamentals, Technologies and Applications. Edited by Detlef Stolten, WILEY- VCH.
[15]
Karagiorgas, M., Tsoutsos, T. and Moiá-Pol, A. (2007) Analysis, Simulation and Monitoring of Energy Consumption in Mediterranean Hotels. Application in Greece. Energy and Buildings, 39, 416-426.
http://dx.doi.org/10.1016/j.enbuild.2006.07.008
[16]
Karagiorgas, M., Tsoutsos, T., Drosou, V., Pouffary, S., Pagano, S., Lara, G.L. and Mendes, J.M. (2006) HOTRES: Renewable Energies in the Hotels. An Extensive Technical Support for the Hotel Industry. Renewable and Sustainable Energy Reviews, 10, 198-224. http://dx.doi.org/10.1016/j.rser.2004.09.012
[17]
Tsoutsos, T., Anagnostou, J., Pritchard, C., Karagiorgas, M. and Agoris, D. (2003) Solar Cooling Technologies in Greece. Applied Thermal Engineering, 23, 1427-1439. http://dx.doi.org/10.1016/S1359-4311(03)00089-9
[18]
CRES (1998) A Strategy for Energy Efficiency and Use of RES in the Mediterranean Hotel Sector. STR 0489-95-GR Thermie Final Report, DG 17th.
