Abstract
The implementation of energy-efficiency measures as well as the integration of renewable energy systems, on the move towards the zero (or nearly zero)-energy building is certainly a challenging task. This is even more the case, when buildings are to operate in conditions with increased cooling demand, as it happens in the Eastern Mediterranean, the Middle East and North Africa. The aim of a zero-energy building cannot be achieved without a truly integrated energy design approach, by a combination of two major tools: (a) avoiding, postponing or reducing the generation of heating and cooling loads, by applying the basic principles of building physics and (b) using alternative, renewable sources and systems to produce the heating and refrigeration necessary.
Understanding the requirements of the user and providing adequate solutions remains the single most important prerequisite, if the design had to be successful and just a simple academic exercise. Targeted, interdisciplinary postgraduate courses are needed, with curricula focusing on the utilization of state-of-the-art technology, but also with the holistic approach in the core of their educational attitude, in order to provide architects and engineers with the expertise needed.
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References
Weiss W, Mauthner F (2012) Solar heat worldwide, Edition 2012, AEE INTEC, Austria
European Solar Thermal Industry Federation (2011) (2011) Solar thermal markets in Europe, trends and market statistics 2010. ESTIF
Steinbach J, Ragwitz M (2010)First consultation workshop on A common framework for a coordinated/harmonized policy on renewable heating, report part of the IEE project “Policy development for improving RES-H/C penetration in European Member States (RES-H Policy)”
Tsilingiridis G, Martinopoulos G (2010) Thirty years of domestic solar hot water systems use in Greece—energy and environmental benefits—future perspectives. Renew Energy 35:490–497
Drosou V, Karagiorgas M, Travasaros C (2011) The Greek solar thermal market and industrial applications, overview of the market situation. Proceedings of world sustainable energydays 2011, conference “Solar Process Heat”. Wels, Austria
Oxizidis S, Papadopoulos AM (2008) Solar air conditioning: a review of technological and market perspectives. Adv Build Energy Res 2:123–158
Eicker U, Schneider D, Schumacher J, Ge T, Dai Y (2010) Operational experiences with solar air collector driven desiccant cooling systems. Appl Energy 87:3735–3747
Sotiropoulos VA et al (1992) Final report on the evaluation of active solar systems of Solar Village 3, Aristotle University Thessaloniki, Thessaloniki, Greece
Papadopoulos MA et al (1992) Final report on the evaluation of passive solar systems of Solar Village 3, Aristotle University Thessaloniki, Thessaloniki, Greece
Tsilingiridis G, Sotiropoulos V (1998) Three-year measurements of ambient and indoor air temperatures in Solar Village, Athens, Greece. Energy Build 28:127–136
Tsekouras P, Drosou V, Antonopoulos K, Karytsas C (2012) An innovative high solar fraction heating and cooling plant in Athens—Control strategy and initial measurements, Proceedings of the ASME 2012 Summer Heat Transfer Conference HT2012, July 8–12, 2012, Puerto Rico, USA
Tsoutsos T, Karagiorgas M, Zidianakis G, Drosou V, Aidonis A, Gouskos Z, Moeses C (2009) Development of the applications of solar thermal cooling systems in Greece and Cyprus. Fresen Environ Bull 18(7b):1367–1380
EUROSTAT, Statistics on population unable to heat their homes adequately. Accessed 1 Apr 2014
Acknowledgment
The author wishes to acknowledge the European Commission for financing the Energy Efficiency, Renewable Energy and Environmental Impacts master study project ENERESE, JPCR 530194-2012, within the TEMPUS programme.
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Papadopoulos, A. (2016). Solar Thermal Systems for Zero-Energy Buildings: Perspectives and Challenges. In: Sayigh, A. (eds) Renewable Energy in the Service of Mankind Vol II. Springer, Cham. https://doi.org/10.1007/978-3-319-18215-5_72
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DOI: https://doi.org/10.1007/978-3-319-18215-5_72
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