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Management of wind-turbine blade waste as high-content concrete addition: Mechanical performance evaluation and life cycle assessment

Javier Manso‐Morato, Nerea Hurtado‐Alonso, Víctor Revilla‐Cuesta, Vanesa Ortega‐López

2025Journal of Environmental Management25 citationsDOIOpen Access PDF

Abstract

The management of end-of-life wind-turbine blades in the coming years will be necessary, as a clear solution for their recycling is yet to be found due to their complex composition. The suitability of their mechanical recycling is therefore evaluated in this paper, obtaining Raw-Crushed Wind-Turbine Blade (RCWTB) for subsequent incorporation in high amounts of up to 10% vol. in concrete, replacing the aggregates to achieve Fiber-Reinforced Concrete (FRC). Compressive strength levels of 40 MPa were at all times reached, although with steadily decreasing elastic moduli, properties that could be precisely related by regression using a hardened-density correction. Besides, tensile splitting strength increased by 0.03 MPa per 1% RCWTB and Poisson's coefficient was reduced, while maintaining flexural strength levels. Finally, life cycle assessment showed lower global warming potential for mixes with RCWTB, even compared to other FRC mixes, as the contents related to high-emitting raw materials of FRC were reduced. The results were promising and reveal a path towards greater sustainability of the wind-energy sector in alliance with the concrete industry. • Raw-Crushed Wind-Turbine Blade (RCWTB) was added into Fiber-Reinforced Concrete. • Full 28-day mechanical characterization of concrete with 0–10% vol. RCWTB. • Enhanced tensile performance and ductility of mixes when incorporating RCWTB. • Life Cycle Analysis (LCA) yielded enhanced environmental performance when using RCWTB. • RCWTB was successfully added in high percentages towards mechanical testing and LCA.

Topics & Concepts

Life-cycle assessmentTurbineTurbine bladeBlade (archaeology)Environmental scienceEngineeringWaste managementMarine engineeringMechanical engineeringProduction (economics)MacroeconomicsEconomicsRecycled Aggregate Concrete PerformanceInnovative concrete reinforcement materialsInnovations in Concrete and Construction Materials
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