Scholarly record
ENVIRONMENTAL ASSESSMENT OF VENTILATION DUCTS IN AN EDUCATIONAL BUILDING: A ROMANIAN CASE STUDY
Abstract
Accounting for 40% of final energy consumption and 34% of emissions in the European Union, buildings have a significant role to play in achieving a carbon neutral Europe before 2050. But to make buildings more sustainable we need to assess and reduce carbon emissions at every stage of their life cycle, from construction materials to ongoing energy use. As heating, ventilation and air-conditioning (HVAC) systems are the primary energy consumers in buildings, they offer significant potential for energy saving and it is imperative to assess the environmental impact of the materials used in these systems. This study evaluates the environmental footprint of an HVAC system from an educational building in Romania, through the methodology of life cycle assessment using One Click LCA software, focusing on the impact of different types of ventilation ducts, namely rectangular and circular. Our initial analysis revealed that energy use and materials production were the primary contributors to global warming. Within the HVAC system, the air handling unit and the ventilation ducts had the most significant impacts, with emissions gradually decreasing as we transitioned from rectangular to circular ducts shapes. We also investigated how a country-s national energy mix and transportation distances affect the environmental impact of a circular ventilation duct. Due the lack of a comprehensive database of Environmental Product Declarations (EPDs) within the software, this analysis relied also on an EPD produced for Romania, which awaits verification. Our findings revealed that encouraging local sources materials and energy from renewable sources for ventilation ducts reduces the environmental impact of the whole HVAC system.
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References14
Greenhouse gas emissions from energy use in buildings in Europe https://www.eea.europa.eu/en/analysis/indicators/greenhouse-gas-emissions-from-energy [Accessed on 25 August 2024];
2050 long-term strategy https://climate.ec.europa.eu/eu-action/climate-strategies-targets/2050-long-term-strategy_en [Accessed on 25 August 2024];
Global Alliance for buildings and construction, 2021, Decarbonizing the building sector 10 key measures https://globalabc.org/sites/default/files/2021-08/Decarbonizing%20The%20Building%20Sector%20-%2010%20Key%20Measures.pdf [Accessed on 8 September 2024];
Ibn-Mohammed T., Greenough R., Taylor S., Ozawa-Meida L., Acquaye A., Operational vs. embodied emissions in buildings � A review of current trends, Energy and Buildings, vol. 66, pp 232-245, 2013; DOI: 10.1016/j.enbuild.2013.07.026
Ni Myint N., Shafique M., Embodied carbon emissions of buildings: Taking a step towards net zero buildings, Case Studies in Construction Materials, vol. 20, e03024, 2024; DOI: 10.1016/j.cscm.2024.e03024
Gonzalez-Torres M., Perez-Lombard L., Coronel Juan F., Maestre Ismael R., Yan Da, A review on buildings energy information: Trends, end-uses, fuels and drivers, Energy Reports, vol. 8, pp 626-637, 2022; DOI: 10.1016/j.egyr.2021.11.280
Bergsdal, H., Tonnesen J., Borg A., Solli C., Life cycle inventory library for embodied emissions in ventilation components, Building and Environment, vol. 262, 111854, 2024; DOI: 10.1016/j.buildenv.2024.111854
Fuchsl S., Rheude F., Roder H., Life cycle assessment (LCA) of thermal insulation materials: A critical review, Cleaner Materials, vol. 5, 100119, 2022; DOI: 10.1016/j.clema.2022.100119
Barahmand Z., Eikeland M. S., Life Cycle Assessment under Uncertainty: A Scoping Review, World, vol. 3, no. 3, 2022; DOI: 10.3390/world3030039
Kiamili C., Hollberg A., Habert G., Detailed Assessment of Embodied Carbon of HVAC Systems for a New Office Building Based on BIM, Sustainability, vol.12, 3372, 2020; DOI: 10.3390/su12083372
Palcan A., Wentz Dr. Blake, Holtzhower Dr. Lantz, HVAC dusctwork design and its impacts on life cycle analysis of a building, Sustainable ecological engineering design for society (SEEDS), Conference proceedings from the fourth international SEEDS conference, Dublin, pp 71-78, 2018;
Masoud Eris, Comparative Life Cycle Assessment of Tailor-Made Fabric, Glass Wool, and Galvanized Steel Ductwork for Ventilation Systems in a School and Office Building, MSc thesis, Aalborg, 2023;
One Click LCA software https://oneclicklca.com/software/design-construction/lca-for-construction [Accessed on August 2024];
Albu H., Beu D., Rus T., Moldovan R., Domnita F., Vilcekova S., Life cycle assessment of LED luminaire and impact on lighting installation � A case study, Alexandria Engineering Journal, vol. 80, pp 282-293, 2023; DOI: 10.1016/j.aej.2023.08.068
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