Od konvencionalne do niskoenergetske kuće u srbiji. perspektiva životnog ciklusa
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Jul 13, 2019
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Conventional family buildings in Serbia consume excessive amounts of energy in the course of their entire life cycles. Study investigates energy performance improvement of a case study conventional family building in Serbia with the aim of reaching low energy building standard. Improvement process comprises energy-saving measures with the aims of heat loss reduction and energy production from renewable sources. Particular focus of the paper is on determining the relation between recurrent embodied and operating energy expressed in final energy units per year of building – ™s predicted residual service life. Recurrent embodied energy refers to the life cycle phases from the extraction of raw materials from the natural environment to the completion of the building material, component or system production process; transportation and assembly on the construction site. Operating energy of a building refers to utilisation of the building i.e energy demand for heating, cooling, hot water preparation, use of electrical appliances and lighting. Operating energy and energy produced by renewable energy systems are evaluated by the application of appropriate energy simulation software.
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Kako citirati
SLAVKOVIĆ, Katarina; KRSTIĆ FURUNDŽIĆ, Aleksandra.
Od konvencionalne do niskoenergetske kuće u srbiji. perspektiva životnog ciklusa.
Zbornik Međunarodnog kongresa i izložbe o KGH, [S.l.], v. 45, n. 1, p. 1-8, july 2019.
Dostupno na: <https://izdanja.smeits.rs/index.php/kghk/article/view/4907>. Datum pristupa: 19 apr. 2026
Sekcija
Ukupne osobine ponašanja zgrada i inteligencija
Reference
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[3] BPIE Buildings Performance Institute Europe (2011) Europe's buildings under a microscope. A coun-try-by-country review of the energy performance of buildings. Available at: http://www.bpie.eu/eu_buildings_under_microscope.html#.U9oOJvmSyI8 [Accessed 27 July 2014]
[4] European Commission (2012) Consultation paper. Financial support for energy efficiency in buildings. Available at: http://ec.europa.eu/energy/efficiency/consultations/20120518_eeb_financial_support_en.html [Accessed 27 July 2014]
[5] ***, Law on efficient use of energy, in Serbian: Zakon o efikasnom koriščenju energije, Official Gazette of Republic of Serbia 25/2013
[6] ***, Rulebook on energy efficiency of buildings, in Serbian: Pravilnik o energetskoj efikasnosti zgrada, Official Gazette of Republic of Serbia 61/2011
[7] ***, Regulations on conditions, content and method of issuing energy performance certificates, in Ser-bian: Pravilnik o uslovima, sadržini i načinu izdavanja sertifikata o energetskim svojstvima zgrada, Official Gazzete of Republic of Serbia 61/2011
[8] ***, Law on planning and construction, in Serbian: Zakon o planiranju i izgradnji, Official Gazette of Republic of Serbia 72/2009
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[10] ***, Directive 2010/31/EU of the European Parliament and of the Council of 19 May 2010 on the energy performance of buildings (recast), Official Journal of the European Communities, L 153/13-35
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[13] Slavković, K., Radivojević, A. (2014) Evaluation of energy embodied in the external wall of single-family buildings in the process of energy performance optimisation. Energy Efficiency. In publication. DOI 10.1007/s12053-014-9285-3
[14] Citherlet, S., Defaux, T. (2007). Energy and environmental comparison of three variants of a family house during its whole life span. Building and Environment, 42, 591-598
[15] Dixit, M. K., Fernandez-Solis, J. L., Lavy, S., Culp, C. H. (2010). Identification of parameters for embodied energy measurement: A literature review. Energy and buildings, 42, 1238-1247
[16] Beney, J. F., Attia, S., Andersen, M., Application of the Cradle to Cradle paradigm to a housing unit in Switzerland: Findings from a prototype design. PLEA, Sustainable Architecture for Renewable Future, Munich, Germany, 2013
[17] Dahlstrørm, O., Sørnes, K., Eriksen, S. T., Hertwich, E. (2012) Life cycle assessment of a single-family residence built to either conventional- or passive house standard. Energy and Buildings. 54, 470-479
[18] Dadoo, A., Gustavson, L., Sathre, R. (2010) Life cycle primary energy implication of retrofitting a wood-framed apartment building to passive house standard. Resource, Conservation and Recycling, 54, 1152-1160
[19] Hernandez, P., Kenny, P., Life Cycle Energy Performance: Exploring the limits of passive low energy building, World Sustainable building Conference, 2008
[20] Hernandez, P., Kenny, P. (2010) From net energy to zero energy buildings: Defining life cycle zero energy buildings (LC-ZEB). Energy and Buildings, 42, 815-821
[21] Hammond, G., Jones, C. (2011). Inventory of Carbon and Energy (ICE), Version 2.0. Summary Tables. Bath: University of Bath.
[22] Jovanović Popović, M. et al. (2012). Atlas of Family Housing in Serbia. Belgrade: Faculty of Architec-ture, University of Belgrade, GIZ Deutsche Gesellschaft
[23] Meteonorm. http://meteonorm.com/ [Last revised: October 2014]
[2] European Commission (2011) Communication from the commision to the European Paliament, the council, The European economicand social Committee and the committee of the regions. A Roadmap for moving to a competitive low carbon economy in 2050. Available at: http://ec.europa.eu/clima/policies/roadmap/documentation_en.htm [Accessed 25 July 2014]
[3] BPIE Buildings Performance Institute Europe (2011) Europe's buildings under a microscope. A coun-try-by-country review of the energy performance of buildings. Available at: http://www.bpie.eu/eu_buildings_under_microscope.html#.U9oOJvmSyI8 [Accessed 27 July 2014]
[4] European Commission (2012) Consultation paper. Financial support for energy efficiency in buildings. Available at: http://ec.europa.eu/energy/efficiency/consultations/20120518_eeb_financial_support_en.html [Accessed 27 July 2014]
[5] ***, Law on efficient use of energy, in Serbian: Zakon o efikasnom koriščenju energije, Official Gazette of Republic of Serbia 25/2013
[6] ***, Rulebook on energy efficiency of buildings, in Serbian: Pravilnik o energetskoj efikasnosti zgrada, Official Gazette of Republic of Serbia 61/2011
[7] ***, Regulations on conditions, content and method of issuing energy performance certificates, in Ser-bian: Pravilnik o uslovima, sadržini i načinu izdavanja sertifikata o energetskim svojstvima zgrada, Official Gazzete of Republic of Serbia 61/2011
[8] ***, Law on planning and construction, in Serbian: Zakon o planiranju i izgradnji, Official Gazette of Republic of Serbia 72/2009
[9] Sartori, I., Hestnes, A. G. (2007) Energy use in the life cycle of conventional and low energy buildings: A review article. Energy and Buildings. 39. pp. 249-257
[10] ***, Directive 2010/31/EU of the European Parliament and of the Council of 19 May 2010 on the energy performance of buildings (recast), Official Journal of the European Communities, L 153/13-35
[11] Slavković, K., Low energy buildings: Concepts of energy performance optimization of family houses. Places and Technologies, Faculty of Architecture, University of Belgrade, Belgrade, Serbia, 2014
[12] Marszal, A.J. et al. 2011. Zero energy buildings – a review of definitions and calculation methodologies, Energy and Buildings, 43: 971-979
[13] Slavković, K., Radivojević, A. (2014) Evaluation of energy embodied in the external wall of single-family buildings in the process of energy performance optimisation. Energy Efficiency. In publication. DOI 10.1007/s12053-014-9285-3
[14] Citherlet, S., Defaux, T. (2007). Energy and environmental comparison of three variants of a family house during its whole life span. Building and Environment, 42, 591-598
[15] Dixit, M. K., Fernandez-Solis, J. L., Lavy, S., Culp, C. H. (2010). Identification of parameters for embodied energy measurement: A literature review. Energy and buildings, 42, 1238-1247
[16] Beney, J. F., Attia, S., Andersen, M., Application of the Cradle to Cradle paradigm to a housing unit in Switzerland: Findings from a prototype design. PLEA, Sustainable Architecture for Renewable Future, Munich, Germany, 2013
[17] Dahlstrørm, O., Sørnes, K., Eriksen, S. T., Hertwich, E. (2012) Life cycle assessment of a single-family residence built to either conventional- or passive house standard. Energy and Buildings. 54, 470-479
[18] Dadoo, A., Gustavson, L., Sathre, R. (2010) Life cycle primary energy implication of retrofitting a wood-framed apartment building to passive house standard. Resource, Conservation and Recycling, 54, 1152-1160
[19] Hernandez, P., Kenny, P., Life Cycle Energy Performance: Exploring the limits of passive low energy building, World Sustainable building Conference, 2008
[20] Hernandez, P., Kenny, P. (2010) From net energy to zero energy buildings: Defining life cycle zero energy buildings (LC-ZEB). Energy and Buildings, 42, 815-821
[21] Hammond, G., Jones, C. (2011). Inventory of Carbon and Energy (ICE), Version 2.0. Summary Tables. Bath: University of Bath.
[22] Jovanović Popović, M. et al. (2012). Atlas of Family Housing in Serbia. Belgrade: Faculty of Architec-ture, University of Belgrade, GIZ Deutsche Gesellschaft
[23] Meteonorm. http://meteonorm.com/ [Last revised: October 2014]