Life Cycle Assessment of road construction: A case study of the E39 Betna-Hestnes road project in Norway
Master thesis
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https://hdl.handle.net/11250/3080236Utgivelsesdato
2023Metadata
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Sammendrag
This master thesis assesses the environmental impacts caused by constructing E39 Betna-HestnesRoad Project in Trøndelag County, Norway, by using LCA methodology. additionally, this thesis seeksto identify potential measures that can be implemented to mitigate the project's environmentalimpacts.
Norway has made a commitment to reduce greenhouse gas emissions by 50% by the year 2030. Thisthesis is important for Bertelsen and Garpestad who are actively working towards achieving moreenvironmentally friendly road construction. Furthermore, it also serves as a valuable resource fororganizations, administrations, and stakeholders involved in the road construction sector, as itprovides insights and strategies for effectively mitigating the impacts and emissions in their roadprojects.
The construction phase of the entire E39 Betna-Hestnes project results in a total of 19,900 tons ofCO2 equivalent and had a total water consumption of approximately 118,500 m3. The totalterrestrial acidification resulting from constructing the E39 Betna-Hestnes road project is calculatedto be 85.2 tons of SO2 equivalent and terrestrial ecotoxicity is calculated to be 65654,3 ton1,4dichlorobenzene. In general, the main contributors to these emissions are Concrete(B45),reinforcement rebar steel, asphalt, and prefabricated beams.
1.2 million liters of fuel consumed by just construction machinery and mass transport is remarkablyhigh and huge. The material consumption activities have the biggest overall emissions related to(GWP, water use, and terrestrial acidification & ecotoxicity). The fossil-free construction site andmachinery in E39 Betna-Hestnes will significantly mitigate carbon dioxide emissions duringconstruction.
It becomes apparent that the use of timber instead of concrete in bridges could have more favorableenvironmental outcomes. This is primarily due to the quantities of cement and rebar steel required inconcrete bridge structures, which leads to higher raw-materials demand and higher energy demandduring the production phase from non-renewable sources.