{"title":"利用激光材料加工技术回收锂离子电池的新方法","authors":"James Chen, Ruby Zhang, Jian Li","doi":"10.1016/j.susmat.2024.e01095","DOIUrl":null,"url":null,"abstract":"<div><p>Efficient and cost-effective recycling of spent lithium-ion batteries is essential for the sustainable growth of the clean energy sector, conserves critical mineral resources, and contribute to environmental sustainability. The pyrometallurgy process, involving high-temperature smelting and solid-state reduction, plays a key role in the industrial-scale recycling of these batteries. Traditional smelting methods, however, face criticism for their substantial energy requirements and the loss of lithium in slag. In this study, an innovative laser-based in-situ pyrometallurgical process, hereinafter referred to as laser recycling, was developed to recycle Li-ion batterie materials without using slag, enabling the simultaneous recovery of Co, Ni, Mn, and Li. Lab-scale experiments were carried out to investigate the influences of laser power density and duration on the carbothermic reduction behavior of battery materials. The results showed that the maximum temperature reached approximately 1850 °C with a laser power between 1500 and 2000 W focused to an area of 20 mm in diameter within a few seconds. The laser recycling facilitates concurrent smelting and solid-state reduction, with carbothermic reduction completed in just 30 s due to rapid reaction kinetics, ultra-high temperatures, and the enhanced contact area resulting from surface tension-driven molten material flow under intense laser beam exposure. This laser recycling process reduced LiCoO<sub>2</sub> and LiNi<sub>0.33</sub>Mn<sub>0.33</sub>Co<sub>0.33</sub>O<sub>2</sub> to metallic Co or Co-Ni-Mn alloy, respectively, while Li was recovered as Li<sub>2</sub>CO<sub>3</sub>. The new process allowed for the near-total recovery of Co, Ni, and Mn in the alloy and virtually 100% Li recovery in the form of Li<sub>2</sub>CO<sub>3</sub> by a vapor phase capture system. Additionally, continuous laser recycling in the battery material powder bed showed potentials to scale up for industry battery recycling. A mechanism for the laser recycling process was proposed. A preliminary discussion on the techno-economic implications of laser recycling was also provided.</p></div>","PeriodicalId":22097,"journal":{"name":"Sustainable Materials and Technologies","volume":"41 ","pages":"Article e01095"},"PeriodicalIF":8.6000,"publicationDate":"2024-09-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"https://www.sciencedirect.com/science/article/pii/S2214993724002756/pdfft?md5=a7d7fd3b75fbb0ade658d40c095eb7a7&pid=1-s2.0-S2214993724002756-main.pdf","citationCount":"0","resultStr":"{\"title\":\"A new method to recycle Li-ion batteries with laser materials processing technology\",\"authors\":\"James Chen, Ruby Zhang, Jian Li\",\"doi\":\"10.1016/j.susmat.2024.e01095\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<div><p>Efficient and cost-effective recycling of spent lithium-ion batteries is essential for the sustainable growth of the clean energy sector, conserves critical mineral resources, and contribute to environmental sustainability. The pyrometallurgy process, involving high-temperature smelting and solid-state reduction, plays a key role in the industrial-scale recycling of these batteries. Traditional smelting methods, however, face criticism for their substantial energy requirements and the loss of lithium in slag. In this study, an innovative laser-based in-situ pyrometallurgical process, hereinafter referred to as laser recycling, was developed to recycle Li-ion batterie materials without using slag, enabling the simultaneous recovery of Co, Ni, Mn, and Li. Lab-scale experiments were carried out to investigate the influences of laser power density and duration on the carbothermic reduction behavior of battery materials. The results showed that the maximum temperature reached approximately 1850 °C with a laser power between 1500 and 2000 W focused to an area of 20 mm in diameter within a few seconds. The laser recycling facilitates concurrent smelting and solid-state reduction, with carbothermic reduction completed in just 30 s due to rapid reaction kinetics, ultra-high temperatures, and the enhanced contact area resulting from surface tension-driven molten material flow under intense laser beam exposure. This laser recycling process reduced LiCoO<sub>2</sub> and LiNi<sub>0.33</sub>Mn<sub>0.33</sub>Co<sub>0.33</sub>O<sub>2</sub> to metallic Co or Co-Ni-Mn alloy, respectively, while Li was recovered as Li<sub>2</sub>CO<sub>3</sub>. The new process allowed for the near-total recovery of Co, Ni, and Mn in the alloy and virtually 100% Li recovery in the form of Li<sub>2</sub>CO<sub>3</sub> by a vapor phase capture system. Additionally, continuous laser recycling in the battery material powder bed showed potentials to scale up for industry battery recycling. A mechanism for the laser recycling process was proposed. 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引用次数: 0
摘要
对废旧锂离子电池进行高效且具有成本效益的回收利用,对于清洁能源行业的可持续发展、保护重要的矿产资源以及促进环境的可持续发展至关重要。高温冶金工艺涉及高温熔炼和固态还原,在这些电池的工业规模回收利用中发挥着关键作用。然而,传统的熔炼方法因需要大量能源和熔渣中的锂损耗而受到批评。本研究开发了一种基于激光的创新型原位火法冶金工艺(以下简称激光回收),可在不使用熔渣的情况下回收锂离子电池材料,同时回收钴、镍、锰和锂。实验研究了激光功率密度和持续时间对电池材料碳热还原行为的影响。结果表明,激光功率在 1500 到 2000 W 之间时,在几秒钟内聚焦到直径为 20 mm 的区域,最高温度达到约 1850 ℃。由于反应动力学迅速、温度超高,以及在强激光束照射下表面张力驱动熔融材料流动所产生的接触面积增大,碳热还原在短短 30 秒内就完成了。这种激光回收工艺将 LiCoO2 和 LiNi0.33Mn0.33Co0.33O2 分别还原成金属 Co 或 Co-Ni-Mn 合金,而锂则以 Li2CO3 的形式回收。通过气相捕获系统,新工艺几乎完全回收了合金中的钴、镍和锰,并以 Li2CO3 的形式实现了 100% 的锂回收。此外,在电池材料粉末床中进行连续激光回收显示出了扩大工业电池回收规模的潜力。研究人员提出了激光回收工艺的机制。还对激光回收的技术经济影响进行了初步讨论。
A new method to recycle Li-ion batteries with laser materials processing technology
Efficient and cost-effective recycling of spent lithium-ion batteries is essential for the sustainable growth of the clean energy sector, conserves critical mineral resources, and contribute to environmental sustainability. The pyrometallurgy process, involving high-temperature smelting and solid-state reduction, plays a key role in the industrial-scale recycling of these batteries. Traditional smelting methods, however, face criticism for their substantial energy requirements and the loss of lithium in slag. In this study, an innovative laser-based in-situ pyrometallurgical process, hereinafter referred to as laser recycling, was developed to recycle Li-ion batterie materials without using slag, enabling the simultaneous recovery of Co, Ni, Mn, and Li. Lab-scale experiments were carried out to investigate the influences of laser power density and duration on the carbothermic reduction behavior of battery materials. The results showed that the maximum temperature reached approximately 1850 °C with a laser power between 1500 and 2000 W focused to an area of 20 mm in diameter within a few seconds. The laser recycling facilitates concurrent smelting and solid-state reduction, with carbothermic reduction completed in just 30 s due to rapid reaction kinetics, ultra-high temperatures, and the enhanced contact area resulting from surface tension-driven molten material flow under intense laser beam exposure. This laser recycling process reduced LiCoO2 and LiNi0.33Mn0.33Co0.33O2 to metallic Co or Co-Ni-Mn alloy, respectively, while Li was recovered as Li2CO3. The new process allowed for the near-total recovery of Co, Ni, and Mn in the alloy and virtually 100% Li recovery in the form of Li2CO3 by a vapor phase capture system. Additionally, continuous laser recycling in the battery material powder bed showed potentials to scale up for industry battery recycling. A mechanism for the laser recycling process was proposed. A preliminary discussion on the techno-economic implications of laser recycling was also provided.
期刊介绍:
Sustainable Materials and Technologies (SM&T), an international, cross-disciplinary, fully open access journal published by Elsevier, focuses on original full-length research articles and reviews. It covers applied or fundamental science of nano-, micro-, meso-, and macro-scale aspects of materials and technologies for sustainable development. SM&T gives special attention to contributions that bridge the knowledge gap between materials and system designs.