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The use of renewable sources in city centres

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Wybrane pełne teksty z tego czasopisma
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Warianty tytułu
PL
Wykorzystanie odnawialnych źródeł energii w centrach miejskich
Języki publikacji
EN
Abstrakty
EN
he Machu Pichu Charter of 1977 launched the idea of "cities and regions" being interdependent entities that tend to become one, "multifunctionality" rather than "zoning", "communication" as the key to human life, "architecture" as socially functional spaces to live in. However, above all it introduced the concept of "the quality of life and its integration with the natural environment... The impact of technological and mechanical developments have led to architecture often using artificial conditioning systems created to work with unnatural lighting and climates..." In other words, the basic principles of bio-climatic architecture are also used for work in city centres, whereby the architects who design the houses are expected to pay more attention to the microclimate and use local materials, rather than create identical buildings for all climates and latitudes using artificial conditioning/heating systems that cause pollution to ensure the comfort of indoor environments. The most cost-effective technological options for the civil sector to help reduce CO 2 emissions between now and 2020 in accordance with the Kyoto Protocol are passive solar systems, thermal insulation for buildings, high-efficiency heating systems, etc. A large number of "historical" buildings comprise materials with a high level of thermal inertia, internal courtyards and staircases that provide natural ventilation, windows orientated in accordance with the direction of winds that prevail in that particular microclimate and comfortable outdoor spaces such as porticos, etc. A large number of buildings lead to teleheating which consequently leads to large savings in primary energy, especially when combined with the co-generation of heat and electricity. The need to use traditional materials, to be aware of the techniques used to create "historical" buildings and to respect historical and artistic materials requires particular expertise and training courses to create the specialists. Even if the quality of life in large cities is not the best, cities still remain centres of cultural, social and economic activities.
PL
Podstawowe zasady, na jakich opiera się architektura bioklimatyczna, mogą być wykorzystane do projektowania miejsc pracy w centrach miejskich. Od architektów oczekuje się działań zmierzających do zapewnieniu odpowiedniego mikroklimatu oraz wykorzystania lokalnych materiałów. Nie należy projektować budynków, które niczym by się nie różniły w różnych strefach klimatycznych i przy różnym położeniu i byłyby wyposażone w klimatyzację lub sztuczne systemy grzewcze, zapewniające komfort w ich wnętrzu. Takie urządzenia przyczyniają się do zwiększenia zanieczyszczenia środowiska. Najtańszym rozwiązaniem technologicznym, pozwalającym zmniejszyć emisję dwutlenku węgla w ciągu najbliższych dwudziestu lat, jest pasywny system słoneczny: "historyczne" budynki są zbudowane z materiałów o dużym stopniu bezwładności termicznej, mają wewnętrzne dziedzińce itp.
Rocznik
Strony
10--15
Opis fizyczny
bibliogr. 23 poz.
Twórcy
autor
  • Responsible Bioclimatic Architecture at ENEA, ENEA-UDA, Lungotevere Thaon de Revel 76, 00196 Rome, Italy; Lecturer on Environmental Psycology, University of Camerino, Faculty of Architecture, Camerino (Macerata), Italy
Bibliografia
  • [1] A.A. V.V. Architecture and urban space, PLEA 91. Kiuwer Ac. Pub. Sevilie, Spain, 1991.
  • [2] AA.VV., The state of the art and future research on passive cooling in architecture, Proceedings of the International Meeting ENEA, Rome, 1994.
  • [3] CIANCIULLO A., GALLO C., Costruire con il sole, ISES Italia, 1995.
  • [4] Commission of the European Communities, Solar Energy in Architecture and Urban Planning, Foster N. and Partners (Eds.), Bruxelles, 1993.
  • [5] ALFSEN C. (Editor) et al., Urban Biosphere and Society, The New York Academy of Sciences, New York, N.Y., 2004.
  • [6] MEADOWS D.H., MEADOWS D.L., RANDERS J., BEHRENS W.W., III, The Limits to Growth, A Report for the Club of Rome’s Project on the Predicament of Mankind, Universe Books, New York, 1972.
  • [7] ENEA, Rapporto Energia Ambiente, 2004, gennaio 2005.
  • [8] ENEA, Progettazione sostenibile: tre casi studio-La normativa energetico-ambientale in Italia, Roma, 2001.
  • [9] European Commission, ExternE, Externalities of Energy, Vol. 9, Fuel Cycles for Emerging and End-Use Technologies, Transport and Waste, EUR 18887, ISBN 92-828-7084-7, European Commission, Luxembourg, 1999.
  • [10] FALCONI G. (a cura di), Solar Buildings, Gangemi Editore, Roma, 1997.
  • [11] GALLO C., General policies and specific strategies for the integration of renewable energies in historical centers, Perspective in Energy, Pion Limited, London, 1995.
  • [12] GALLO C., SALA M., SAYIGH A., Architecture, Comfort and Energy, Pergamon, London, 1998.
  • [13] GALLO C., Architecture for sustainable development, Science for Peace, UNESCO, 1999.
  • [14] GALLO C., Architettura Bioclimatica (libro, videocassetta e floppy), ENEA, Roma, 1996 – distribuito da DEI e libreria DEDALO di Roma.
  • [15] GALLO C. (a cura di), Architettura ed Energia (CD_ROM interattivo), Roma, 1997 – distribuito da libreria DEDALO di Roma.
  • [16] GALLO C., Qualità energetico ambientale nell’architettura sostenible, Sole 24 Ore, Milano, 2000.
  • [17] GALLO C., Il rendimento energetico dell’edificio, Il Sole 24 Ore, Milano, 2006.
  • [18] GIVONI B., Impact of pianted areas on urban environmental quality: a review, Atmospheric Environment, 1991, Vol. 25 B, No. 3, Pergamon.
  • [19] IZARD J.L., Architectures d’été, Edisud, France, 1993.
  • [20] LAVIGNE P., FERNANDEZ P., BREJON P.I, Archítecture climatique; une contributíon au développement durable, tome 1, Bases et approche physique, 1992.
  • [21] DE ASIAIN L.J. et al., Bioclimatic Design and Urban Landscaping, Plea and Cres. Athens, Greece, 1993.
  • [22] MARONI M., SEIFERT B., LINDVALL T., Indoor Air Quality, Elsevier, 1995.
  • [23] NIKOLOPOULOU M. (coordinator), Designing open spaces in the urban environment: a bioclimatic approach, CRES, Greece (5° Framework Programme co-financed by the European Union), 2004.
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-article-BPW8-0001-0013
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