This study is about the recovery of carbon lithium and valuable material (Ni, Mn, Co) from the lithium-ion battery cathode active material for electric vehicles NCM (LiNiMnCoO2) and investigated the conditions of recovery of carbon lithium (Li2CO3) and valuable material by thermal reactions in lithi...
This study is about the recovery of carbon lithium and valuable material (Ni, Mn, Co) from the lithium-ion battery cathode active material for electric vehicles NCM (LiNiMnCoO2) and investigated the conditions of recovery of carbon lithium (Li2CO3) and valuable material by thermal reactions in lithium and valuable material in cathode active materia. To check the thermal behavior of NCM-type cathode active materia, a TGA (thermigravimetric analysis) analysis device was used and CO2 gas was supplied to simulate actual thermal reactions in an anode. cathode active materia was observed to vary in weight between 650 and 800°C, and it is believed that the increase in weight change was due to the super separation of carbon lithium and metal oxide CoO, MnO and NiO. Based on these results, Carbonation experiment was conducted in the temperature zone between 600 and 900°C, water penetration test for separating carbon lithium, and reduction heat treatment test for improving recovery rate of metal powder is as follows.
1. Carbonation test was conducted for phase separation from Li2CO3 and NiO, CoO, and MnO from NCM system acathode active material and confirmed that Li2CO3 and metal oxide NiO, MnO, and CoO are completely separated at 800 to 900°C. The temperature was maintained at 800°C for 2 hours and 2 hours.
2. To selectively recover carbon lithium from the electrolyte powder separated by Carbonation, water penetration was performed using the difference in solubility between carbon lithium and metal oxide. When the ratio of powder and distilled water was between 1:30 and 5 hours, the largest amount of carbon lithium was withdrawn and carbon lithium was recovered. In order to determine the amount of leachate Li from raw materials, the wet analysis method, Integrated Plasma (ICP), was used and approximately 89% lithium was recovered through water penetration.
3. The Monde process was used to selectively recover Ni from the remaining mixture (NiO, CoO, and MnO) after a water leak. Phase I of the process is a reduction phase, and hydrogen (H2) was supplied in the temperature zone (about 200°C) where only NiO can be reduced during the mixing powder. Stage II is the production of nickel carbonyl (Ni(CO)4(g)) so that the reduced Ni is easily separated from the mixture, and nickel carbonyl was produced by supplying CO gas to the mixture maintained at 80°C. Phase III was the final step in the selective recovery of Ni powder and (Ni(CO)4(g) was heat-dissolved at 180°C to obtain high purity Ni. The purity of the Ni powder recovered through the Mond process is approximately 97.99% and is sufficiently reusable for industrial use.
This study is about the recovery of carbon lithium and valuable material (Ni, Mn, Co) from the lithium-ion battery cathode active material for electric vehicles NCM (LiNiMnCoO2) and investigated the conditions of recovery of carbon lithium (Li2CO3) and valuable material by thermal reactions in lithium and valuable material in cathode active materia. To check the thermal behavior of NCM-type cathode active materia, a TGA (thermigravimetric analysis) analysis device was used and CO2 gas was supplied to simulate actual thermal reactions in an anode. cathode active materia was observed to vary in weight between 650 and 800°C, and it is believed that the increase in weight change was due to the super separation of carbon lithium and metal oxide CoO, MnO and NiO. Based on these results, Carbonation experiment was conducted in the temperature zone between 600 and 900°C, water penetration test for separating carbon lithium, and reduction heat treatment test for improving recovery rate of metal powder is as follows.
1. Carbonation test was conducted for phase separation from Li2CO3 and NiO, CoO, and MnO from NCM system acathode active material and confirmed that Li2CO3 and metal oxide NiO, MnO, and CoO are completely separated at 800 to 900°C. The temperature was maintained at 800°C for 2 hours and 2 hours.
2. To selectively recover carbon lithium from the electrolyte powder separated by Carbonation, water penetration was performed using the difference in solubility between carbon lithium and metal oxide. When the ratio of powder and distilled water was between 1:30 and 5 hours, the largest amount of carbon lithium was withdrawn and carbon lithium was recovered. In order to determine the amount of leachate Li from raw materials, the wet analysis method, Integrated Plasma (ICP), was used and approximately 89% lithium was recovered through water penetration.
3. The Monde process was used to selectively recover Ni from the remaining mixture (NiO, CoO, and MnO) after a water leak. Phase I of the process is a reduction phase, and hydrogen (H2) was supplied in the temperature zone (about 200°C) where only NiO can be reduced during the mixing powder. Stage II is the production of nickel carbonyl (Ni(CO)4(g)) so that the reduced Ni is easily separated from the mixture, and nickel carbonyl was produced by supplying CO gas to the mixture maintained at 80°C. Phase III was the final step in the selective recovery of Ni powder and (Ni(CO)4(g) was heat-dissolved at 180°C to obtain high purity Ni. The purity of the Ni powder recovered through the Mond process is approximately 97.99% and is sufficiently reusable for industrial use.
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