Life Cycle Assessment of Additively Manufactured Foundations for Ultratall Wind Turbine Towers
ABSTRACT Wind energy production is rapidly growing in the United States and is expected to continue increasing as more and larger wind turbines are installed. To support these taller and heavier onshore turbines, new foundations must be designed and manufactured. One proposed method of reducing the...
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Wiley
2024-11-01
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| Series: | Wind Energy |
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| Online Access: | https://doi.org/10.1002/we.2947 |
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| author | Kathryn E. S. Jones Mo Li |
| author_facet | Kathryn E. S. Jones Mo Li |
| author_sort | Kathryn E. S. Jones |
| collection | DOAJ |
| description | ABSTRACT Wind energy production is rapidly growing in the United States and is expected to continue increasing as more and larger wind turbines are installed. To support these taller and heavier onshore turbines, new foundations must be designed and manufactured. One proposed method of reducing the total amount of concrete and steel in spread foundations is to utilize additive manufacturing to enable more material‐efficient designs. To compare these additively manufacturing‐enabled designs to conventional foundation designs, this study performs a life cycle impact assessment of four ultra‐tall wind turbine foundations: two foundations using 78‐MPa 3D printed stay‐in‐place concrete formwork cast with 35‐MPa ready‐mix concrete with reinforcements, and two conventional foundations cast entirely out of 35‐MPa concrete with reinforcements. The life cycle assessment investigates the environmental impacts of four different stages, including materials production, transportation, construction, and end‐of‐life. The materials production stage is found to dominate the life cycle results, contributing over 97% of the total CO2 emissions and over 88% of the fossil fuel depletion for each foundation. Compared to the conventional designs, the Short Flat Ribbed Beam foundation with 3D printed formwork has 22.4% lower CO2 emissions and 28.3% lower fossil fuel depletion than the Circular foundation, and 2.0% higher CO2 and 5.9% lower fossil fuel depletion compared to the Tapered foundation. Parametric studies indicate that reducing cement content and increasing recycled content in printed concrete can significantly reduce the overall life cycle impacts of the foundations. |
| format | Article |
| id | doaj-art-e9bb3f82fc9449dab2d54d016d1727bb |
| institution | OA Journals |
| issn | 1095-4244 1099-1824 |
| language | English |
| publishDate | 2024-11-01 |
| publisher | Wiley |
| record_format | Article |
| series | Wind Energy |
| spelling | doaj-art-e9bb3f82fc9449dab2d54d016d1727bb2025-08-20T02:17:27ZengWileyWind Energy1095-42441099-18242024-11-0127111427144910.1002/we.2947Life Cycle Assessment of Additively Manufactured Foundations for Ultratall Wind Turbine TowersKathryn E. S. Jones0Mo Li1Department of Civil and Environmental Engineering University of California, Irvine Irvine California USADepartment of Civil and Environmental Engineering University of California, Irvine Irvine California USAABSTRACT Wind energy production is rapidly growing in the United States and is expected to continue increasing as more and larger wind turbines are installed. To support these taller and heavier onshore turbines, new foundations must be designed and manufactured. One proposed method of reducing the total amount of concrete and steel in spread foundations is to utilize additive manufacturing to enable more material‐efficient designs. To compare these additively manufacturing‐enabled designs to conventional foundation designs, this study performs a life cycle impact assessment of four ultra‐tall wind turbine foundations: two foundations using 78‐MPa 3D printed stay‐in‐place concrete formwork cast with 35‐MPa ready‐mix concrete with reinforcements, and two conventional foundations cast entirely out of 35‐MPa concrete with reinforcements. The life cycle assessment investigates the environmental impacts of four different stages, including materials production, transportation, construction, and end‐of‐life. The materials production stage is found to dominate the life cycle results, contributing over 97% of the total CO2 emissions and over 88% of the fossil fuel depletion for each foundation. Compared to the conventional designs, the Short Flat Ribbed Beam foundation with 3D printed formwork has 22.4% lower CO2 emissions and 28.3% lower fossil fuel depletion than the Circular foundation, and 2.0% higher CO2 and 5.9% lower fossil fuel depletion compared to the Tapered foundation. Parametric studies indicate that reducing cement content and increasing recycled content in printed concrete can significantly reduce the overall life cycle impacts of the foundations.https://doi.org/10.1002/we.29473D printingCO2 emissionsconcrete additive manufacturingconcrete foundationlife cycle assessmentwind turbines |
| spellingShingle | Kathryn E. S. Jones Mo Li Life Cycle Assessment of Additively Manufactured Foundations for Ultratall Wind Turbine Towers Wind Energy 3D printing CO2 emissions concrete additive manufacturing concrete foundation life cycle assessment wind turbines |
| title | Life Cycle Assessment of Additively Manufactured Foundations for Ultratall Wind Turbine Towers |
| title_full | Life Cycle Assessment of Additively Manufactured Foundations for Ultratall Wind Turbine Towers |
| title_fullStr | Life Cycle Assessment of Additively Manufactured Foundations for Ultratall Wind Turbine Towers |
| title_full_unstemmed | Life Cycle Assessment of Additively Manufactured Foundations for Ultratall Wind Turbine Towers |
| title_short | Life Cycle Assessment of Additively Manufactured Foundations for Ultratall Wind Turbine Towers |
| title_sort | life cycle assessment of additively manufactured foundations for ultratall wind turbine towers |
| topic | 3D printing CO2 emissions concrete additive manufacturing concrete foundation life cycle assessment wind turbines |
| url | https://doi.org/10.1002/we.2947 |
| work_keys_str_mv | AT kathrynesjones lifecycleassessmentofadditivelymanufacturedfoundationsforultratallwindturbinetowers AT moli lifecycleassessmentofadditivelymanufacturedfoundationsforultratallwindturbinetowers |