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Abstrakty
Over the past 50 years the use of air conditioning in non-domestic buildings has become a norm and an indicator of status. Today the rediscovering of the natural ventilation is a part of rediscovering the buildings’ energy efficiency, or maybe even a part of a wider approach, which is a desire to be closer to nature. The main task of all ventilation systems is to maintain an appropriate indoor air quality and to improve the indoor environment. Natural ventilation systems could do the above using less energy than mechanical systems. However, it requires also the implementation of other passive measures. The most important of them are: the reduction of the harmful air contaminants, the control of heat gains, the exposition of the building’s thermal mass and utilisation of the night cooling. Because of energy efficiency and thermal comfort reasons, in temperate climate ventilation systems have to work according to at least three scenarios: spring/autumn, winter and summer. The thermal comfort parameters in naturally ventilated buildings are usually more variable than in air-conditioned ones, what does not mean that the occupants will experience thermal discomfort. Therefore, thermal comfort in passively ventilated buildings should be evaluated according to the adaptive comfort standard, appropriated for the naturally ventilated buildings. The natural ventilation has its limits and probably not all buildings can be ventilated naturally. From the energy efficiency and thermal comfort reasons, implementing the mixed mode systems is sometimes more feasible. However, the real reason why the full potential of natural ventilation could not be explored is very often the lack of confidence in relying exclusively on it.
Czasopismo
Rocznik
Tom
Strony
935--947
Opis fizyczny
Bibliogr. 14 poz.
Twórcy
autor
- Warsaw University of Technology Faculty of Architecture ul.Koszykowa 55, PL 00-659 Warszawa
Bibliografia
- Auer, T., Sauerbruch M. (2011). Ein rekordverdächtiges Energiekonzept. Detail Green vol.1, pp.32-35.
- Carbon Trust (2013). www.en.wikipedia.org/wiki/Carbon_Trust - accessed 16.11.216.
- Environmental design CIBSE Guide A (2015). London: The Chartered Institution of Building Services Engineers.
- Gonçalves J., Bode K. (2010) “Up in the air”, CIBSE Journal December.
- Halliday S. (2008). Sustainable Construction. Oxford: Butterworth-Heinenmann.
- Hegger, M. (2008). Energy Manual Sustainable Architecture. Basel, Boston, Berlin: Birkhäuser.
- Natural ventilation in non-domestic buildings CIBSE Application Manual AM10 (2005). The Chartered Institution of Building Services Engineers.
- New Practice Case Study 102, The Queens Building De Montfort University - feedback for designers and clients, Energy Efficiency Best Practice Programme (1997). www.iesd. dmu.ac.uk/msc/EEBPP_NPCS_102.pdf accessed 25.02.2016.
- Passe U., Battaglia F. (2015). Designing Spaces for Natural Ventilation. New York: Routledge Taylor&Francis Group.
- Sanierung zweier Fakultätsgebäude Innsbruck (2015). Detail Green vol.2, pp.44-51.
- Sick building syndrome (2016). www.en.wikipedia.org/wiki/Sick_building_syndrome - accessed 13.11.2016.
- The limits of thermal comfort: Avoiding overheating in European buildings CIBSE Technical Memorandum 52 (2013). London: The Chartered Institution of Building Services Engineers.
- Verwaltungsgebäude in Frankfurt (2011). Detail Green vol.1, pp.26-29.
- Wood A., Salib R. (2014). Natural Ventilation in High-Rise Office Buildings, CTBUH Technical Guide. New York, London: Routledge.
Uwagi
Opracowanie ze środków MNiSW w ramach umowy 812/P-DUN/2016 na działalność upowszechniającą naukę (zadania 2017).
Typ dokumentu
Bibliografia
Identyfikator YADDA
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