Materials recovery from end-of-life wind turbine magnets

被引：7

作者：

Pietrantonio, M. ^{[1
]}

Pucciarmati, S. ^{[1
]}

Sebastianelli, L. ^{[1
]}

Forte, F. ^{[1
]}

Fontana, D. ^{[1
]}

机构：

[1] Italian Natl Agcy New Technol Energy & Sustainabl, Dept Sustainabil, ENEA, Via Anguillarese 301, I-00123 Rome, Italy

来源：

INTERNATIONAL JOURNAL OF ENVIRONMENTAL SCIENCE AND TECHNOLOGY | 2022年 / 19卷 / 08期

关键词：

Hydrometallurgy; Rare earths; Secondary raw materials; Wind turbine permanent magnets; NDFEB MAGNETS; HYDROMETALLURGICAL RECOVERY; RARE-EARTHS; SCRAP; ND; EXTRACTION; ELEMENTS;

D O I：

10.1007/s13762-021-03546-1

中图分类号：

X [环境科学、安全科学];

学科分类号：

08 ; 0830 ;

摘要：

Neodymium-iron-boron permanent magnets are increasingly used in green energy technologies, such as wind turbines and electric vehicles. In the near future, an increasing amount of magnets will reach their end-of-life stage, andtherefore, it is imperative to develop proper recycling routes aimed at the valorization of this waste fraction. In this work, a room temperature hydrometallurgical process was developed aimed at the recovery of both iron and rare earths contained in end-of-life wind turbine magnets. The process is based on a leaching step with nitric acid, followed by two precipitation steps and calcination. Iron hydroxide(III) and rare earth oxide with purity grade equal to 98% and 99%, respectively, were obtained. Based on these results, a process flowsheet was proposed for industrial implementation.

引用

页码：8019 / 8026

页数：8

共 50 条

[41] Recovery and reuse of structural products from end-of-life buildings
Hopkinson, Peter
Chen, Han-Mei
Zhou, Kan
Wang, Yong
Lam, Dennis
[J]. PROCEEDINGS OF THE INSTITUTION OF CIVIL ENGINEERS-ENGINEERING SUSTAINABILITY, 2019, 172 (03) : 119 - 128
[42] Developing end-of-life materials for caregivers
Zir, A
Asuncion, D
Cheang, M
Braun, K
[J]. GERONTOLOGIST, 2002, 42 : 253 - 254
[43] State-of-the-art value chain roadmap for sustainable end-of-life wind turbine blades
Lund, K. W.
Madsen, E. S.
[J]. RENEWABLE & SUSTAINABLE ENERGY REVIEWS, 2024, 192
[44] Advances and challenges of green materials for electronics and energy storage applications: from design to end-of-life recovery
Gao, Mengyao
Shih, Chien-Chung
Pan, Shu-Yuan
Chueh, Chu-Chen
Chen, Wen-Chang
[J]. JOURNAL OF MATERIALS CHEMISTRY A, 2018, 6 (42) : 20546 - 20563
[45] A Life Cycle Assessment of a recovery process from End-of-Life Photovoltaic Panels
Ansanelli, G.
Fiorentino, G.
Tammaro, M.
Zucaro, A.
[J]. APPLIED ENERGY, 2021, 290
[46] Transdisciplinary End-of-Life Analysis of Wind Turbines
Harder P.
Dreßler D.
Böning C.
Stonis M.
[J]. ZWF Zeitschrift fuer Wirtschaftlichen Fabrikbetrieb, 2022, 117 (1-2): : 41 - 45
[47] A finite element model for 3D printed recycled parts from end-of-life wind turbine blades
Yan, Zhengshu
Rahimizadeh, Amirmohammad
Zhang, Yixue
Zhou, Yuheng
Lessard, Larry
[J]. COMPOSITE STRUCTURES, 2023, 320
[48] Wind Turbines' End-of-Life: Quantification and Characterisation of Future Waste Materials on a National Level
Andersen, Niklas
Eriksson, Ola
Hillman, Karl
Wallhagen, Marita
[J]. ENERGIES, 2016, 9 (12):
[49] Prediction and recovery of end-of-life vehicles of China
LI Yun-yan
WANG Li-hua
[J]. Ecological Economy, 2015, 11 (04) : 342 - 349
[50] Perspectives for the recovery of rare earths from end-of-life fluorescent lamps
Binnemans, K.
Jones, P. T.
[J]. JOURNAL OF RARE EARTHS, 2014, 32 (03) : 195 - 200

← 1 2 3 4 5 →