March 3, 2026Open Access

Oxygen-assisted pyrolysis recovery of glass fibers from end-of-life wind turbine blades and their reutilization

Key Points

The oxygen-assisted pyrolysis method improves the recovery of glass fibers, achieving stretching strength at 72.6% of commercial standards.
It shows that introducing oxygen accelerates the low-temperature oxidative cleavage of epoxy resin, aiding recovery while preserving fiber integrity.
This observational analysis supports enhanced fiber surface properties with retained polar silanol groups, improving composite material strength.
Significantly, this method shows promise for sustainable wind energy practices, promoting efficient recycling and reducing environmental impact.

Abstract

退役风电叶片回收与循环利用是推动风电产业绿色闭环发展的关键挑战。热解是最具工业化应用潜力的退役风电叶片回收技术之一，但存在流程复杂、树脂解聚与纤维力学性能保持难以协同等问题。为此，本研究提出一种氧辅助热解短程回收玻璃纤维的新策略，通过在热解过程中引入适量氧气，利用其产生的氧自由基调控树脂解聚路径，协同实现树脂高效去除与纤维性能保持。实验结果证实，氧辅助热解过程中，氧气能够加速环氧树脂的低温解聚，并可强化重质低聚物的氧化裂解，抑制其脱氢缩聚成炭，实现了纤维的短程直接回收，同时，有效减轻了纤维表面的热损伤，避免了集中缺陷的出现，回收纤维的拉伸强度和杨氏模量分别达到商用纤维的72.6%和95.6%，显著优于常规热解回收。并且，氧辅助热解还可在纤维表面保留大量极性硅羟基，有效改善其界面结合性能，因此，所制备复合材料的拉伸与弯曲强度分别达到商用纤维制备复合材料的94.9%和90.2%，具有优异的循环利用潜力。本研究提出的氧辅助热解方法在兼顾回收效率与纤维本体及界面性能方面具有明显优势，为退役风电叶片高效回收与循环利用提供了可行的技术路径与理论依据，对推动风电产业可持续发展具有重要意义。

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Oxygen-assisted pyrolysis recovery of glass fibers from end-of-life wind turbine blades and their reutilization

Key Points

Abstract

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