A multi-attribute assessment using WASPAS for choosing an optimal indoor environment

• Autorzy: Zavadskas E. K. , Kalibatas D. , Kalibatiene D.

Identyfikatory

DOI

10.1016/j.acme.2015.10.002

• Języki publikacji: EN

Abstrakty

EN

The majority of present-day dwelling houses were constructed in the previous century, when energy efficiency was not as important as now. Therefore, there is a necessity to assess existing dwelling houses and refurbish them to satisfy energy efficient requirement and humans’ needs. To cover the first part, authors of this paper continue their discussion on optimal leaving place started previously. In this paper based on concepts “passive house” and “active house”, standards of European Union (EU) and Lithuania, the concept “optimal environment” is refined and defined. According to the presented concept of optimal environment, the MADM-opt method, which is based on the concept of optimal alternative, is refined in the paper also. It is applied for the WASPAS method to assess an indoor environment of six apartments in similar brick houses. The results show that MADM-opt can be used for the assessment of alternatives and their evaluation according to the optimal alternative. Moreover, it allows determining deviation of the assessed alternatives from the optimal alternative.

Słowa kluczowe

EN

multi-attribute assessment; indoor environment; WASPAS; passive house; active house

PL

dom energooszczędny; efektywność energetyczna; jakość środowiska wewnętrznego

• Wydawca: Springer ; Wrocław University of Science and Technology
• Czasopismo: Archives of Civil and Mechanical Engineering
• Rocznik: 2016
• Tom: Vol. 16, no. 1
• Strony: 76--85
• Opis fizyczny: Bibliogr. 46 poz., rys., tab., wykr.

Twórcy

autor

Zavadskas E. K.

• Department of Construction Technology and Management, Faculty of Civil Engineering, Vilnius Gediminas Technical University, Saulėtekio al. 11, Vilnius LT-10223, Lithuania

autor

Kalibatas D.

• Department of Construction Technology and Management, Faculty of Civil Engineering, Vilnius Gediminas Technical University, Saulėtekio al. 11, Vilnius LT-10223, Lithuania

autor

Kalibatiene D.

• Department of Information Systems, Faculty of Fundamental Sciences, Vilnius Gediminas Technical University, Sauletekio al. 11, Vilnius LT-10223, Lithuania

Bibliografia

• [1] Energy Efficiency Plan 2011, Communication from the Commission to the European Parliament, the Council, the European Economic and Social Committee and the Committee of the Regions, European Commission, 2011.
• [2] M. Economidou, Europe's Buildings under the Microscope, Buildings Performance Institute Europe (BPIE), 2011 http:// www.europeanclimate.org/documents/LR_%20CbC_study. pdf.
• [3] EU, Directive 2010/31/EU of 19 May 2010 on the Energy Performance of Buildings, EU, Brussels, 2010.
• [4] M. Gröndahl, G. Gates, The Secrets of a Passive House, The New York Times Website, 2010.
• [5] M. Sachs, Passive House VS Active House: Two Competing Visions for the Future of Homes. Inside the Housing Revolution, 2010 http://www.insidethehousingevolution. com/housing-designs/passive-house-vs-active-house-two- competing-visions-for-the-future-of-homes/.
• [6] W. Pan, H. Garmston, Building regulations in energy efficiency: compliance in England and Wales, Energy Policy 45 (2012) 594–605.
• [7] D. Kalibatas, E.K. Zavadskas, D. Kalibatiene, The concept of the ideal indoor environment in multi-attribute assessment of dwelling-houses, Archives of Civil and Mechanical Engineering 11 (1) (2011) 89–101.
• [8] D. Kalibatas, E.K. Zavadskas, D. Kalibatiene, A method of multi-attribute assessment using ideal alternative: choosing an apartment with optimal indoor environment, International Journal of Strategic Property Management 16 (3) (2012) 338–353.
• [9] Five performance Criteria for Passive House Standard, NuTech Renewables, 2011 http://nutechrenewables.com/ architect/five-design-criteria-for-designing-passive-houses. html.
• [10] N. Venckus, R. Bliūdžius, A. Endriukaityte, J. Parasonis, Research of low energy house design and construction opportunities in Lithuania, Technological and Economic Development of Economy 6 (3) (2010) 541–554.
• [11] M.K. Kuzman, P. Grošelj, N. Ayrilmis, M. Zbašnik-Senegačnik, Comparison of passive house construction types using analytic hierarchy process, Energy and Buildings 64 (2013) 258–263.
• [12] M. Praznik, V. Butala, M. Zbašnik Senegačnik, Simplified evaluation method for energy efficiency in single-family houses using key quality parameters, Energy and Buildings 67 (2013) 489–499.
• [13] B. Risholt, B. Time, A.G. Hestnes, Sustainability assessment of nearly zero energy renovation of dwellings based on energy, economy and home quality indicators, Energy and Buildings 60 (2013) 217–224.
• [14] P. Rohdin, A. Molin, B. Moshfegh, Experiences from nine passive houses in Sweden – indoor thermal environment and energy use, Building and Environment 71 (2014) 176–185.
• [15] E. Siozinyte, J. Antucheviciene, Solving the problems of daylighting and tradition continuity in a reconstructed vernacular building, Journal of Civil Engineering and Management 19 (6) (2013) 873–882.
• [16] B. Vodopivec, R. Zarnic, J. Tamosaitiene, M. Lazauskas, J. Selih, Renovation priority ranking by multi-criteria assessment of architectural heritage: the case of castles, International Journal of Strategic Property Management 18 (1) (2014) 88–100.
• [17] M. Derbez, B. Berthineau, V. Cochet, M. Lethrosne, C. Pignon, J. Riberon, S. Kirchner, Indoor air quality and comfort in seven newly built, energy-efficient houses in France, Building and Environment 72 (February) (2014) 173–187.
• [18] Indoor Environment Quality, Sustainable Design Assessment in the Planning Process (SDAPP), City of Port Phillip, 2012 http://www.portphillip.vic.gov.au/ SDAPP_01_Indoor_Environment_Quality.pdf.
• [19] An Office Building Occupant's Guide to Indoor Air Quality, EPA, EPA-402-K-97-003, Washington, 1997 http://www.epa. gov/iaq/pdfs/occupants_guide.pdf.
• [20] Enhance Indoor Environmental Quality (IEQ), WBDG Sustainable Committee, 2013 http://www.wbdg.org/design/ieq.php.
• [21] Who Guidelines for Indoor Air Quality – Selected pollutants, World Health Organisation (WHO), Europe, 2010 http://www. euro.who.int/__data/assets/pdf_file/0009/128169/e94535.pdf.
• [22] O.C.G. Adan, J. Ng-A-Tham, W. Hanke, T. Sigsgaard, P. van den Hazel, F. Wu, In search of a common European approach to a healthy indoor environment, Environmental Health Perspectives 115 (6) (2007) 983–988.
• [23] Indoor and Outdoor Environmental Quality, Federation of European Heating, Ventilation and Air-conditioning Associations, REHVA, 2013 http://www.rehva.eu/ eu-regulations/indoor-environmental-quality-standards/.
• [24] R. Niemelä, V. Hongisto, H. Koskela, E. Sandberg, A virtual indoor environment model – a useful tool for design, Scandinavian Journal of Work, Environment & Health (Suppl. 4) (2008) 39–42.
• [25] Indoor Air Quality, Canadian Centre for Occupational Health and Safety, 2013 http://www.ccohs.ca/oshanswers/chemicals/ iaq_intro.html.
• [26] HN 98:2000, Natural and artificial lighting of workplaces, Limit values and general requirements for their measuring. Lithuanian hygienic norm. Zin., 2000 Nr. 277 (in Lithuanian).
• [27] STR 2.02.01:2004, Residential buildings, Zin., 2003 Nr. 23-721 (in Lithuanian).
• [28] HN 42:2009, Microclimate of residential and administrative buildings, Lithuanian hygienic norm, Zin., 2009 Nr. 159-7219 (in Lithuanian).
• [29] STR 2.09.02:2005, Heating, ventilation and air exchange, Zin., 2005 Nr. 75-2729 (in Lithuanian).
• [30] STR 2.01.07:2003, Noise protection of inside and outside environment, Zin., 2003 Nr. 79-3614 (in Lithuanian).
• [31] HN 35:2007, Maximum chemicals (pollutants) indoor concentration in living areas, Lithuanian hygienic norm, Zin., 2007 Nr. 55-2162 (in Lithuanian).
• [32] E. Triantaphyllou, Multi-criteria Decision Making Methods: A Comparative Study, Springer, 2000.
• [33] B. Roy, R. Słowinski, Questions guiding the choice of a multicriteria decision aiding method, EURO Journal on Decision Processes 1 (1/2) (2013) 69–97.
• [34] P. Liu, Z. Han, A fuzzy multi-attribute decision-making method under risk with unknown attribute weights, Technological and Economic Development of Economy 17 (2) (2011) 246–258.
• [35] D. Stanujkic, N. Magdalinovic, S. Stojanovic, R. Jovanovic, Extension of ratio system part of MOORA method for solving decision-making problems with interval data, Informatica 23 (1) (2012) 141–154.
• [36] G. Kou, Y. Lu, Y. Peng, Y. Shi, Evaluation of classification algorithms using MCDM and rank correlation, International Journal of Information Technology & Decision Making 11 (01) (2012) 197–225.
• [37] R. Simanaviciene, L. Ustinovicius, A new approach to assessing the biases of decisions based on multiple attribute decision making methods, Electronics and Electrical Engineering (1) (2012) 29–32.
• [38] E.K. Zavadskas, Z. Turskis, R. Volvaciovas, S. Kildiene, Multi- criteria assessment model of technologies, Studies in Informatics and Control 22 (4) (2013) 249–258.
• [39] A. Ruzgys, R. Volvaciovas, C. Ignatavicius, Z. Turskis, Integrated evaluation of external wall insulation in residential buildings using SWARA-TODIM MCDM method, Journal of Civil Engineering and Management 20 (1) (2014) 103–110.
• [40] E.K. Zavadskas, Z. Turskis, J. Antucheviciene, A. Zakarevicius, Optimization of weighted aggregated sum product assessment, Electronics and Electrical Engineering (6) (2012) 3–6.
• [41] M.G. Kendall, Rank Correlation Methods, fourth ed., Griffin, London, 1970.
• [42] O. Seppanen, M. Vuolle, Cost effectiveness of some remedial measures to control summer time temperatures in an office building, in: Proc of Sixth International Conference ‘‘Healthy Buildings 2000’’, Finland, vol. 1, 2000, 665–670.
• [43] What is a Passive House? Passive House Institute, 2010 http://www.passivehouse.us/passiveHouse/ PassiveHouseInfo.html.
• [44] C. Ludeman, Passive House (Passivhaus) Standard for Energy Efficient Design, 2008 http://www.100khouse.com/2008/04/ 10/passive-house-passivhaus-standard-for-energy-efficient- design/.
• [45] EN 15251, Indoor environmental input parameters for design and assessment of energy performance of buildings addressing indoor air quality, thermal environment, lighting and acoustics, 2006/07/31, 2006 http://www.cres.gr/ greenbuilding/PDF/prend/set4/WI_31_Pre-FV_version_ prEN_15251_Indoor_Environment.pdf.
• [46] STR 2.01.09:2012, Energy performance of buildings. Energy performance certification. Zin., 2012 Nr. D1-674 (in Lithuanian).

Uwagi

PL

Opracowanie ze środków MNiSW w ramach umowy 812/P-DUN/2016 na działalność upowszechniającą naukę