废旧镍氢电池的特性及回收工艺的初步经济评估。
Characterization of spent nickel-metal hydride batteries and a preliminary economic evaluation of the recovery processes.
作者信息
Lin Sheng-Lun, Huang Kuo-Lin, Wang I-Ching, Chou I-Cheng, Kuo Yi-Ming, Hung Chung-Hsien, Lin Chitsan
机构信息
a Department of Civil Engineering and Geomatics , Super Micro Mass Research and Technology Center, and Center for General Education, Cheng Shiu University , Kaohsiung City , Taiwan , Republic of China.
b Department of Environmental Engineering and Science , National Pingtung University of Science and Technology , Pingtung , Taiwan , Republic of China.
出版信息
J Air Waste Manag Assoc. 2016 Mar;66(3):296-306. doi: 10.1080/10962247.2015.1131206.
UNLABELLED
Valuable metal materials can be recovered from spent nickel-metal hydride (NiMH) batteries. However, little attention has been paid to the metal compositions of individual components of NiMH batteries, although this is important for the selection of the appropriate recycling process. In this study, NiMH batteries were manually disassembled to identify the components and to characterize the metals in each of these. A preliminary economic analysis was also conducted to evaluate the recovery of valuable metals from spent NiMH batteries using thermal melting versus simple mechanical separation. The results of this study show that metallic components account for more than 60% of battery weight. The contents of Ni, Fe, Co, and rare earth elements (REEs) (i.e., valuable metals of interest for recovery) in a single battery were 17.9%, 15.4%, 4.41%, and 17.3%, respectively. Most of the Fe was in the battery components of the steel cathode collector, cathode cap, and anode metal grid, while Ni (>90%) and Co (>90%) were mainly in the electrode active materials (anode and cathode metal powders). About 1.88 g of REEs (Ce, La, and Y) could be obtained from one spent NiMH battery. The estimated profits from recovering valuable metals from spent NiMH batteries by using thermal melting and mechanical processes are 2,329 and 2,531 USD/ton, respectively, when including a subsidy of 1,710 USD/ton. The findings of this study are very useful for further research related to technical and economic evaluations of the recovery of valuable metals from spent NiMH batteries.
IMPLICATIONS
The spent nickel-metal hydride (NiMH) batteries were manually disassembled and their components were identified. The metals account for more than 60% of battery weight, when Ni, Fe, Co, and rare earth elements (REEs) were 17.9%, 15.4%, 4.41%, and 17.3%, respectively, in a single battery. The estimated profits of recovering valuable metals from NiMH batteries by using thermal melting and mechanical processing are 2,329 and 2,531 USD/ton, respectively, when including a subsidy of 1,710 USD/ton. These findings are very useful to develop or select the recovery methods of valuable metals from spent NiMH batteries.
未标注
可以从废旧镍氢(NiMH)电池中回收有价值的金属材料。然而,尽管这对于选择合适的回收工艺很重要,但很少有人关注镍氢电池各个组件的金属成分。在本研究中,手动拆解镍氢电池以识别其组件并表征其中的金属。还进行了初步的经济分析,以评估采用热熔法与简单机械分离法从废旧镍氢电池中回收有价值金属的情况。本研究结果表明,金属组件占电池重量的60%以上。单个电池中镍、铁、钴和稀土元素(REEs)(即有回收价值的金属)的含量分别为17.9%、15.4%、4.41%和17.3%。大部分铁存在于钢质阴极集流体、阴极帽和阳极金属网格等电池组件中,而镍(>90%)和钴(>90%)主要存在于电极活性材料(阳极和阴极金属粉末)中。从一块废旧镍氢电池中可获得约1.88克稀土元素(铈、镧和钇)。当包含每吨1710美元的补贴时,采用热熔法和机械法从废旧镍氢电池中回收有价值金属的估计利润分别为每吨2329美元和2531美元。本研究结果对于进一步开展与从废旧镍氢电池中回收有价值金属的技术和经济评估相关的研究非常有用。
启示
手动拆解废旧镍氢(NiMH)电池并识别其组件。金属占电池重量的60%以上,单个电池中镍、铁、钴和稀土元素(REEs)的含量分别为17.9%、15.4%、4.41%和17.3%。当包含每吨1710美元的补贴时,采用热熔法和机械法从镍氢电池中回收有价值金属的估计利润分别为每吨2329美元和2531美元。这些结果对于开发或选择从废旧镍氢电池中回收有价值金属的方法非常有用。
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