[논문]폐리튬인산철 양극재로부터 리튬의 선침출 및 인과 철의 개별적 분리 회수 연구

김희선; 김보람; 김대원

doi:10.7464/ksct.2024.30.1.28

폐리튬인산철 양극재로부터 리튬의 선침출 및 인과 철의 개별적 분리 회수 연구
Pre-leaching of Lithium and Individual Separation/Recovery of Phosphorus and Iron from Waste Lithium Iron Phosphate Cathode Materials 원문보기

청정기술 = Clean technology, v.30 no.1, 2024년, pp.28 - 36

김희선 (고등기술연구원 신소재공정센터) , 김보람 (고등기술연구원 신소재공정센터) , 김대원 (고등기술연구원 신소재공정센터)

초록
AI-Helper

전기차의 수요가 증가함에 따라 리튬이온전지의 시장 또한 급증하고 있다. 리튬이온전지의 배터리 수명은 제한되어 있으며, 수명을 다한 배터리의 교체 필연적이므로 폐리튬이온전지 배터리가 발생하게 된다. 이에 리튬이온전지 중 폐리튬인산철(LiFePO₄, 이하 LFP라고 함) 양극재 분말에서부터 리튬은 선택적으로 선침출하고 인산철(FePO₄) 분말을 회수하였다. 회수된 인산철 분말은 탄산나트륨(Na₂CO₃) 분말과 혼합하여 열처리하여 그 결정상을 확인하였다. 열처리 온도를 변수로 하였고, 이후 증류수를 이용하여 수침출 후 각 성분의 침출률 및 분말 특성을 비교하였다. 본 연구에서 리튬은 약 100% 침출률을 보였고 800 ℃에서 열처리한 분말의 경우 인이 약 99% 침출되었으며, 침출 잔사는 Fe₂O₃ 단일 결정상으로 확인되었다. 따라서 본 연구에서는 폐LFP 분말로부터 리튬, 인 그리고 철 성분을 개별적으로 분리 및 회수할 수 있었다.

Abstract ▼ AI-Helper

As demand for electric vehicles increases, the market for lithium-ion batteries is also rapidly increasing. The battery life of lithium-ion batteries is limited, so waste lithium-ion batteries are inevitably generated. Accordingly, lithium was selectively preleached from waste lithium iron phosphate (LiFePO4, hereafter referred to as the LFP) cathode material powder among lithium ion batteries, and iron phosphate (FePO4) powder was recovered. The recovered iron phosphate powder was mixed with alkaline sodium carbonate (Na2CO3) powder and heat treated to confirm its crystalline phase. The heat treatment temperature was set as a variable, and then the leaching rate and powder characteristics of each ingredient were compared after water leaching using Di-water. In this study, lithium showed a leaching rate of approximately 100%, and in the case of powder heat-treated at 800 ℃, phosphorus was leached by approximately 99%, and the leaching residue was confirmed to be a single crystal phase of Fe2O3. Therefore, in this study, lithium, phosphorus, and iron components were individually separated and recovered from waste LFP powder.

주제어

표/그림 (12)

표 Table 1. Different extraction methods of LFP battery
$Figure 1. (a) X-ray diffraction pattern and (b) ~ (c) SEM image of waste LiFePO4 powder.$ 그림 Figure 1. (a) X-ray diffraction pattern and (b) ~ (c) SEM image of waste LiFePO₄ powder.
그림 Figure 2. Experimental procedure for the Li separation/recovery of waste LiFePO₄ powder.
표 Table 2. Chemical composition of waste LiFePO₄ cathode powders and residue after leaching (%)
$Figure 3. X-ray diffraction pattern of wasted LFP powder and leaching residue.$ 그림 Figure 3. X-ray diffraction pattern of wasted LFP powder and leaching residue.
표 Table 3. Chemical composition of leaching solution and leaching efficiency (%)
그림 Figure 4. Gibbs free energy change according to various chemical reaction equations when mixing FePO₄ and Na₂CO₃ powders.
그림 Figure 5. TGA curves; (a) FePO₄, Na₂CO₃ and mixed powder, (b) detailed curve of mixed powder.
$Figure 6. X-ray diffraction pattern of FePO4 and Na2CO3 and their mixed powders (2:3 = FePO4:Na2CO3) mixed by ball milling.$ 그림 Figure 6. X-ray diffraction pattern of FePO₄ and Na₂CO₃ and their mixed powders (2:3 = FePO₄:Na₂CO₃) mixed by ball milling.
$Figure 7. X-ray diffraction pattern; (a) according to heat treatment temperature of mixed power, (b) residue after water leaching of heat-treated powder at each temperature.$ 그림 Figure 7. X-ray diffraction pattern; (a) according to heat treatment temperature of mixed power, (b) residue after water leaching of heat-treated powder at each temperature.
그림 Figure 8. Leaching efficiency of P and Fe according to heat-treatment temperature.
표 Table 4. ICP-OES data and leaching efficiency after water leaching according to heat-treatment temperature

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