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Tytuł artykułu

Striving for sustainable architecture in the 21st century - main issues in the development of innovative office space concepts

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Warianty tytułu
Języki publikacji
EN
Abstrakty
EN
The knowledge on office building in the past and present, how the workspace evolved to incorporate contemporary technological breakthroughs, was in this paper combined with goals of sustainable building in a “smart” office building design in Belgrade, Serbia, taking local factors into consideration to create a comfortable space for the employees in a dense urban matrix with a minimal environmental footprint, and considering the workflow of contemporary office spaces, it’s multidirectional input and increasingly horizontal work hierarchy. Issues of proper inputs for building today in the 21st century are thoroughly considered in this paper and respective building’s design features as shown here: how to deal with location, position and orientation of the building, organization of both formal and informal areas, natural ventilation, green glazed surfaces, solar energy, wind turbines, rainwater utilization measures, surrounding vegetation, lighting and appliances, and piezoelectric paving.
Rocznik
Strony
35--43
Opis fizyczny
Bibliogr. 22 poz.
Twórcy
  • Full Professor, V-SPARC School of Architecture, VIT Vellore Institute of Technology, Vellore, Tamil Nadu, India
  • Master Engineer of Architecture, Design Architect, PhD Candidate, TUM Munich, Germany
  • Master student, Faculty of Architecture, University of Belgrade, Bulevar Kralja Aleksandra 73, 11000 Belgrade, Serbia
Bibliografia
  • [1] Andresen, I. and Ř. Aschehoug (2005). System analysis of smart facades. Conference “Glass in Buildings”, Bath (UK), 2005-04-07/08.
  • [2] Aschehoug, Ř, Hestnes, A.G., Matusiak, B., Lien, A.G., Stang, J. and Bell D. (2000). BP Amoco Solar Skin - A Double Façade with PV”. Proceedings. Eurosun 2000, Copenhagen June 2000.
  • [3] Bell, S., Morse S. (2008). Sustainability Indicators: Measuring the Immeasurable? 2nd ed. Earthscan, London.
  • [4] Hantula, R., Voege, D. (2010). How do solar panels work? Chelsea club publishers, New York. ISBN 978- 1-60413-472-8.
  • [5] Harding, S. P. (1997). What is Deep Ecology? Resurgence, 185, 14-17.
  • [6] Milošević, P. (2008). Intelligent Buildings, Innovative Technologies, Materials and Structures. Izgradnja - Monthly Review of Civil Engineering, Architecture and Town Planning Unions (Belgrade), 62(8-9), Vol. LXII, August-September, 355-362; CIP 624+71/72(05), ISSN 0350-5421, COBISS.SR-ID 55831; http://www.arhitektura.rs/konstrukcije/konstrukcije/700-inteligentne-zgrade
  • [7] Efe R., Cürebal, I., Gad, A., Tóth, B. (2001). Enviromental sustainability and landscape management. ISBN 978-954-07-4140-6.
  • [8] Group of authors (2003). The General Plan of Belgrade 2021. Official Gazette of Belgrade, number 27 of 15 October.
  • [9] Van Paassen A H C, et al. (1999). Natural ventilation for offices - NatVent a better way to work. Garston, Watford, UK: Building Research Establishment.
  • [10] Ministry of Environment, Mining and Spatial Planning (2008). National Sustainable Development Strategy. [Online], http://www.ekoplan.gov.rs/DNA/docs/strategija_rs.pdf
  • [11] Fisk, W. J. (2000). Health and Productivity Gains from Better Indoor Environments and Their Relationship with Building Energy Efficiency. Annual Review of Energy & the Environment. 25(2), 537-566.
  • [12] Hoekstra, A.Y. (2006). The Global Dimension of Water Governance: Nine Reasons for Global Arrangements in Order to cope with local Problems. Value of Water Research Report Series, No.2 UNESCO-IHE Institute for Water Education. [Online], http://doc.utwente.nl/58371/1/Report_20.pdf
  • [13] Stang, A, Hawthorne, C. (2005). The Green House, Princeton Architectural Press, New York.
  • [14] Wen Foo S., Yau Seng Mah D., Emily Ayu B. (2017). Modeling rainwater harvesting for commercial buildings. Water practice and technology. 12(3), IWA publishing 2017. DOI 10.2166 wpt 2017.077.
  • [15] Gajić, R. (2012). Aspects of Sustainable Use of Urban Land important for Energy Efficiency. IV Conference on Environmental Protection and Energy Efficiency, Association of Engineers of Belgrade, Belgrade. ISBN 978-86-915671-0-1.
  • [16] Montoya, A. P., Obando, F. A.,Morales, J. G., Vargas, G. (2017). Automatic aeroponic irrigation system based on Arduino’s platform. Universidad Nacional de Colombia, Medellin, Colombia. IOP Conf. Series: Journal of Physics: Conf. Series 850 (2017) 012003. DOI: 10.1088/1742 6596/850/1/012003, IOP Publishing.
  • [17] Group of authors (2007). Fourth Assessment Report of the Intergovernmental Panel on Climate Change. Cambridge University Press, Cambridge, and New York.
  • [18] Van Hinte, E, Neelen, M, Vink, J, Vollaard, P. (2003). Smart Architecture, 010 Publishers, Rotterdam.
  • [19] Bouzidy, F. Z. (2017). Footsteps: Renewed tiles. Al Akhawayn University in Ifrane. School of Science and Engineering.
  • [20] Lalović, B. (1982). Solar houses, BIGZ, Belgrade.
  • [21] Zlatanović-Tomašević, V. (2012). Regulations for Energy Efficiency of Buildings. IV Conference on Environmental Protection and Energy Efficiency, Association of Engineers of Belgrade, Belgrade, ISBN 978-86-915671-0-1.
  • [22] https://www.tesla.com/solarroof
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-a9cf9eac-32e1-4665-9579-f812e94022e4
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