TY - JOUR
T1 - Manufacture and testing of biomass-derivable thermosets for wind blade recycling
AU - Clarke, Ryan W.
AU - Rognerud, Erik G.
AU - Puente-Urbina, Allen
AU - Barnes, David
AU - Murdy, Paul
AU - McGraw, Michael L.
AU - Newkirk, Jimmy M.
AU - Beach, Ryan
AU - Wrubel, Jacob A.
AU - Hamernik, Levi J.
AU - Chism, Katherine A.
AU - Baer, Andrea L.
AU - Beckham, Gregg T.
AU - Murray, Robynne E.
AU - Rorrer, Nicholas A.
PY - 2024/8/23
Y1 - 2024/8/23
N2 - Wind energy is helping to decarbonize the electrical grid, but wind blades are not recyclable, and current end-of-life management strategies are not sustainable. To address the material recyclability challenges in sustainable energy infrastructure, we introduce scalable biomass-derivable polyester covalent adaptable networks and corresponding fiber-reinforced composites for recyclable wind blade fabrication. Through experimental and computational studies, including vacuum-assisted resin-transfer molding of a 9-meter wind blade prototype, we demonstrate drop-in technological readiness of this material with existing manufacture techniques, superior properties relative to incumbent materials, and practical end-of-life chemical recyclability. Most notable is the counterintuitive creep suppression, outperforming industry state-of-the-art thermosets despite the dynamic cross-link topology. Overall, this report details the many facets of wind blade manufacture, encompassing chemistry, engineering, safety, mechanical analyses, weathering, and chemical recyclability, enabling a realistic path toward biomass-derivable, recyclable wind blades.
AB - Wind energy is helping to decarbonize the electrical grid, but wind blades are not recyclable, and current end-of-life management strategies are not sustainable. To address the material recyclability challenges in sustainable energy infrastructure, we introduce scalable biomass-derivable polyester covalent adaptable networks and corresponding fiber-reinforced composites for recyclable wind blade fabrication. Through experimental and computational studies, including vacuum-assisted resin-transfer molding of a 9-meter wind blade prototype, we demonstrate drop-in technological readiness of this material with existing manufacture techniques, superior properties relative to incumbent materials, and practical end-of-life chemical recyclability. Most notable is the counterintuitive creep suppression, outperforming industry state-of-the-art thermosets despite the dynamic cross-link topology. Overall, this report details the many facets of wind blade manufacture, encompassing chemistry, engineering, safety, mechanical analyses, weathering, and chemical recyclability, enabling a realistic path toward biomass-derivable, recyclable wind blades.
UR - http://www.scopus.com/inward/record.url?scp=85202007268&partnerID=8YFLogxK
U2 - 10.1126/science.adp5395
DO - 10.1126/science.adp5395
M3 - Artículo
C2 - 39172828
AN - SCOPUS:85202007268
SN - 1095-9203
VL - 385
SP - 854
EP - 860
JO - Science (New York, N.Y.)
JF - Science (New York, N.Y.)
IS - 6711
ER -