Abstract
Population growth and technological development in recent decades have made human activities largely responsible for structural changes in the built environment at regional and global levels. Civil construction, as an integral part of the chain of industrial activities, is also one of the segments responsible for energy consumption and potential greenhouse gas emissions throughout its life cycle. The building materials and their systems have a direct influence on energy consumption and impact assessment, both in the pre-operational, use and end-of-life and disposal phases. In this context, Hot Water Building Systems (HWBS) are included. The variability of possibilities available with regard to the choice of energy sources, water reserve and distribution systems and the selection of materials used in these building systems allows empowering the decision-making in the designing phase. The definition of the type of installation to be used in a building is defined by technical and/or economic requirements. However, the spectrum of possibilities should consider resource consumption and generation of environmental impacts throughout the life cycle. This research proposes a novel application of an environmental management method to empower the decision-making process and encourage the selection course of HWBS. This work insights a Life Cycle Assessment (LCA) methodology to compare a specific the environmental performance of two distinct HWBS (i.e. Natural Gas Heating System and Solar Heating System) for multi-family residential developments.
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References
Meyer, W.B., Turner, B.L.: Human population growth and global land-use/cover change. Annu. Rev. Ecol. Syst. 23(1), 39–61 (1992)
Harte, J.P.: Human population as a dynamic factor in environmental degradation. Popul. Environ. 28(4–5), 223–226 (2007)
Riahi, K., Rao, S., Krey, V., Cho, C., Chirkov, V., Fischer, G., Kindermann, G., Nakicenovic, N., Rafaj, P.: RCP 8.5—A Scenario of Comparatively High Greenhouse Gas Emissions. Clim. Change Clim. Change 109, 33 (2011)
Fumo, N., Mago, P., Luck, R.: Methodology to estimate building energy consumption using EnergyPlus Becnhmark Models. Energy Build. 42(1), 2331–2337 (2010)
Constantinos, A.B., Droutsa, K., Dascalaki, E., Kontoyiannidis, S.: Heating energy consumption and resulting environmental impact of European apartment buildings. Energy Build. 37(5), 429–442 (2005). https://doi.org/10.1016/j.enbuild.2004.08.003
Valdehi, A.D., Ralegaonkar, R.V., Mandavgane, S.: Improving environmental performance of building through increased energy efficiency: a review. Sustain. Urban Areas 1(4), 211–218 (2011). https://doi.org/10.1016/j.scs.2011.07.007
Martinopoulos, G., Papakostasa, K.T., Papadopoulos, M.: A comparative review of heating systems in EU countries, based on efficiency and fuel cost. Renew. Sustain. 90(1), 687–699 (2018). https://doi.org/10.1016/j.rser.2018.03.060
Najjar, M., Figueiredo, K., Hammad, A.W.A., Haddad, A.: Integrated optimization with building information modeling and life cycle assessment for generating energy efficient buildings. Appl. Energy 250, 1366–1382 (2019)
Glick, S., Guggemos, A.A.: Life-cycle assessment and life-cycle cost as collaborative tools in residential heating system selection. J. Green Build. 5(3), 107–115 (2010)
Randi, H.B., Marc, A.E.: A review of the sustainability of residential hot water infrastructure: public health, environmental impacts, and consumer drivers. J. Green Build. Fall 6(4), 77–95 (2011)
Moore, C.C.S., Rego, E.E., Kulay, L.: The Brazilian electricity supply for 2030: a projection based on economic, environmental and technical criteria. Environ. Nat. Resour. Res. 7(4), 17–29 (2017). https://doi.org/10.5539/enrr.v7n4p17
Klöpffer, W.: Introducing life cycle assessment and its presentation in ‘LCA Compendium’. In: Klöpffer, W. (ed.) Background and Future Prospects in Life Cycle Assessment. LCA Compendium – The Complete World of Life Cycle Assessment. Springer, Dordrecht, pp. 39–84 (2014)
UNEP: Avaliação de Políticas Públicas para Redução da Emissão de Gases de Efeito Estufa em Edificações. São Paulo (2012). Disponível em: http://www.cbcs.org.br/userfiles/comitestematicos/outrosemsustentabilidade/UNEP_capa-miolo-rev.pdf
De Souza, C.G., Barbastefano, R.G., Teixeira, R.C.: Life cycle assessment research in Brazil: characteristics, interdisciplinarity, and applications. Int. J. Life Cycle Assess. 22(1), 266–276 (2017). ISSN: 09483349
Coelho Filho, O., Saccaro Jr, N.L., Luedemann, G.: A avaliação de ciclo d vida cmo ferramenta para a formulação de políticas públicas no Brasil. Brasília: Ipea (2016)
Meex, E., Hollberg, A., Knapen, E., Hildebrand, L., Verbeeck, G.: Requirements for applying LCA-based environmental impact assessment tools in the early stages of building design. Build. Environ. 133(1), 228–236 (2018)
Ochsendorf, J., et al.: Methods, Impacts, and Opportunities in the Concrete Building Life Cycle. Cambridge (2011). Disponível em: https://www.greenconcrete.info/downloads/MITBuildingsLCAreport.pdf
Da Silva, G.A. et al.: Avaliação do ciclo de vida: ontologia terminológica. Instituto Brasileiro de Informação em Ciência e Tecnologia – Ibict, 72p (2014)
ISO—International Organization for Standardization: ISO 14040. Environmental Management—Life Cycle Assessment—Principles and Framework. Geneva: ISO, 20p (2006a)
ISO—International Organization for Standardization: ISO 14044. Environmental Management—Life Cycle Assessment—Requirements and Guidelines. Geneva: ISO, 46p (2006b)
Stranddorf, H.K., Hoffmann, L.: Update on impact categories, normalization and weighting in LCA-Selected EDIP97-data. Danish Environmental Protection Agency, pp. 995, 290 (2005a)
Najjar, M. et al.: Integration of BIM and LCA: evaluating the environmental impacts of building materials at an early stage of designing a typical office building. J. Build. Eng. 14(1), 115–126 (2017)
Najjar, M.K., Figueiredo, K., Evangelista, A.C.J., Hammad, A.W.A., Tam, V.W.Y., Haddad, A.: Life cycle assessment methodology integrated with BIM as a decision-making tool at early-stages of building design. Int. J. Construct. Manage. 1–15 (2019b)
Crespo, N.M., Bueno, C., Ometto, A.R.: Avaliação de Impacto do Ciclo de Vida: revisão dos principais métodos Palavras-chave. Production, no x (2013)
Machado, G.: Aprenda como funciona a gestão de Stakeholders na Construção Civil. Halo Notoriedade Empresarial (2017). Disponível em: http://halonotoriedade.com.br/aprenda-como-funciona-a-gestao-de-stakeholders-na-construcao-civil/. Acesso em: 07/abr./19
Oyarzo, J., Peuportier, B.: Life cycle assessment model applied to housing in Chile. J. Clean. Prod. 69(1), 109–116 (2014). ISSN: 0959-6526
Inaba, A. et al.: Chapter 4: Data documentation, review, and management. In: Global Guidance Principles for Life Cycle Assessment Databases: A Basis for Greener Processes and Products, pp. 85–95 (2011). ISBN: 978-92-807-3174-3
Bare, J.C., Hofstetter, P., Pennington, D.W., Udo de Haes, H.: Int. J. LCA 5(319) (2000)
Acero, A.P., Rodríguez, C., Ciroth, A.: LCIA Methods: Impact assessment methods in Life Cycle Assessment and Their Impact Categories. Greendelta, 23p. (2015)
RIVM. LCIA: The ReCiPe Model (2018) Disponível em: https://www.rivm.nl/en/life-cycle-assessment-lca/recip
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Silva, A.B., Najjar, M.K., Hammad, A.W.A., Haddad, A.N., Vazquez, E.G. (2021). A Proposed Methodology of Life Cycle Assessment for Hot Water Building Systems. In: M.C.F. Cunha, V., Rezazadeh, M., Gowda, C. (eds) Proceedings of the 3rd RILEM Spring Convention and Conference (RSCC 2020). RSCC 2020. RILEM Bookseries, vol 35. Springer, Cham. https://doi.org/10.1007/978-3-030-76543-9_19
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