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VERIFYING THE ADVANTAGES OF CONCRETE ROAD PAVEMENT BASED ON FLY ASH USING THROUGH THE LCA METHOD
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STN EN ISO 14044: Environmental management. Life cycle assessment. Requirements and guidelines, 2007.
Estokova A., Porhincak M., Ruzbacky R. Minimization of CO2 emisions and primal energy by building materials´ environmental evaluation and optimalization. Chemical Engineering Transactions, vol. 25, pp. 1-6, 2011.
Hoffman L., Astrup J. A., Møller T. B., Schmidt A. Life Cycle Assessment (LCA) - A guide to approaches, experiences and information sources. Environmental issues report No 6. European Environment Agency, p. 116, 1998.
Azapagic A., Emsley A., Hamerton I. Polymers, the environment and sustainable development. UK: John Wiley & Sons, Ltd., p. 235, 2003.
EUROPEAN COMMISSION: Making sustainable consumption and production a reality. Luxembourg: Publications Office of the European Union, p. 29, 2010.
Vilcekova S. & Kridlova B. E. Multi-criteria analysis of building assessment regarding energy performance using a life-cycle approach. International Journal of Energy and Environmental Engineering, 2014. [cited 28 April 2014]
Benoit C. et al. Guidelines for social life cycle assessment of products: a social and socio-economic LCA code of practice complementing environmental LCA and Life Cycle Costing, contributing to the full assessment of goods and services within the context of sustainable development. Paris: United Nations Environment Programme, p. 103, 2009.
Junk J. & Stevulova N. Effective utilization of the industrial wastes in concrete production. In: Design, technology, refurbishment and management of buildings: 37th IAHS World Congress on Houusing, Santander, Spain, pp. 1-7, 2010.
Junak J . & Stevulova N. Coal fly ash processing for its utilization in building materials preparing, Zeszyty naukowe Politechniki Rzeszowskiej, v ol. 265, no. 53, pp. 73-78, 2009.
Sjunnesson J. Life Cycle Assessment of Concrete. Master's Dissertation in Environmental Engineering. Lund: Lunds Tekniska Högskola, p. 61, 2005.
Berge B. The Ecology of Building Materials. Second edition. UK: Elsevier Ltd., p.447, 2009.
Hodkova J., Lupisek, A., Mancik, S., Vochoc L., Zdara T. Envimat.cz - Online Database of Environmental Profiles of Building Materials and Structures. In Environmental Software Systems. Frameworks of eEnvironment. Berlin: Springer Science+Business Media, pp. 272-279, 2011.
CML-IA Characterisation Factors [online]. Nederlands: Universiteit Leiden, Institute of Environmental Sciences (CML). [cited 28 April 2014].
Meciarova, L. Findings of environmental impact of concretes prepared with a share of fly ash in terms of assessing basic factors of their life cycle, Diploma thesis, Slovakia, Kosice: TUKE, p. 73 (in Slovak), 2013.
STN EN ISO 14044: Environmental management. Life cycle assessment. Requirements and guidelines, 2007.
Estokova A., Porhincak M., Ruzbacky R. Minimization of CO2 emisions and primal energy by building materials´ environmental evaluation and optimalization. Chemical Engineering Transactions, vol. 25, pp. 1-6, 2011.
Hoffman L., Astrup J. A., Møller T. B., Schmidt A. Life Cycle Assessment (LCA) - A guide to approaches, experiences and information sources. Environmental issues report No 6. European Environment Agency, p. 116, 1998.
Azapagic A., Emsley A., Hamerton I. Polymers, the environment and sustainable development. UK: John Wiley & Sons, Ltd., p. 235, 2003.
EUROPEAN COMMISSION: Making sustainable consumption and production a reality. Luxembourg: Publications Office of the European Union, p. 29, 2010.
Vilcekova S. & Kridlova B. E. Multi-criteria analysis of building assessment regarding energy performance using a life-cycle approach. International Journal of Energy and Environmental Engineering, 2014. [cited 28 April 2014]
Benoit C. et al. Guidelines for social life cycle assessment of products: a social and socio-economic LCA code of practice complementing environmental LCA and Life Cycle Costing, contributing to the full assessment of goods and services within the context of sustainable development. Paris: United Nations Environment Programme, p. 103, 2009.
Junk J. & Stevulova N. Effective utilization of the industrial wastes in concrete production. In: Design, technology, refurbishment and management of buildings: 37th IAHS World Congress on Houusing, Santander, Spain, pp. 1-7, 2010.
Junak J . & Stevulova N. Coal fly ash processing for its utilization in building materials preparing, Zeszyty naukowe Politechniki Rzeszowskiej, v ol. 265, no. 53, pp. 73-78, 2009.
Sjunnesson J. Life Cycle Assessment of Concrete. Master's Dissertation in Environmental Engineering. Lund: Lunds Tekniska Högskola, p. 61, 2005.
Berge B. The Ecology of Building Materials. Second edition. UK: Elsevier Ltd., p.447, 2009.
Hodkova J., Lupisek, A., Mancik, S., Vochoc L., Zdara T. Envimat.cz - Online Database of Environmental Profiles of Building Materials and Structures. In Environmental Software Systems. Frameworks of eEnvironment. Berlin: Springer Science+Business Media, pp. 272-279, 2011.
CML-IA Characterisation Factors [online]. Nederlands: Universiteit Leiden, Institute of Environmental Sciences (CML). [cited 28 April 2014].
Meciarova, L. Findings of environmental impact of concretes prepared with a share of fly ash in terms of assessing basic factors of their life cycle, Diploma thesis, Slovakia, Kosice: TUKE, p. 73 (in Slovak), 2013.
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