Lithium-ion batteries have greatly expanded along with the mobile phone market, and as the electric vehicle business is activated in earnest, they will attract many people's attention even afterwards. Until now, many people have attracted attention to the recovery of valuable metals inside lithium-ion batteries, but graphite, which is mainly used as an anode material, is also worth recycling. Therefore, in order to recover graphite with high purity and valuable metals, graphite that can be used as an anode material of a secondary battery may be generated again through a regeneration process of purifying and separating graphite from a waste lithium-ion battery and recovering electrical characteristics of graphite. This paper describes the process of converting waste graphite into regenerated graphite and the environmental and economic effects of regenerated graphite.

리튬이온 배터리는 휴대폰 시장과 함께 크게 확대되었고 전기 자동차 사업이 본격적으로 활성화됨에 따라, 이후에도 많은 사람의 관심을 끌게 될 분야이다. 지금까지는 리튬이온 배터리 내부에 있는 유가금속에 대한 회수에많은 사람이 관심을 끌고 있지만, 음극재로서 주로 활용되는 흑연 또한 재활용가치는 충분하다. 따라서 순도 높은흑연의 회수와 유가금속의 회수를 함께 하기 위해, 폐 리튬이온 배터리로부터 흑연의 정제 및 분리, 흑연의 전기적특성을 회복하는 재생과정을 통해 다시금 이차전지의 음극재로써 활용할 수 있는 흑연을 만들어 내는 과정을가지게 할 것이다. 본 논문에서는 폐 흑연을 재생 흑연으로 바꾸는 과정과 재생 흑연이 가져오는 경제적 효과를기술한다.

1 Zhang, G, "ecycling of electrode materials from spent lithium-ion battery by pyrolysis-assisted flotation" 9 (9): 106777-, 2021

2 Lai, X, "Turning waste into wealth : A systematic review on echelon utilization and material recycling of retired lithium-ion batteries" 40 : 96-123, 2021

3 Lin, J. H, "Thickness-controllable coating on graphite surface as anode materials using glucose-based suspending solutions for lithium-ion battery" 436 : 128270-, 2022

4 Badawy, S. M, "Synthesis of High-Quality Graphene Oxide From Spent Mobile Phone Batteries" 35 (35): 1485-1491, 2016

5 Li, L, "Sustainable Recovery of Cathode Materials from Spent Lithium-Ion Batteries Using Lactic Acid Leaching System" 5 (5): 5224-5233, 2017

6 Zhang, L, "Study on nano-graphitic carbon coating on Si mold insert for precision glass molding" 448 : 128893-, 2022

7 Du, Z, "Si alloy/graphite coating design as anode for Li-ion batteries with high volumetric energy density" 254 : 123-129, 2017

8 Mohammed, A, "Scanning electron microscope (SEM): A review" 7-9, 2018

9 Gao, Y, "Regenerating spent graphite from scrapped lithium-ion battery by high-temperature treatment" 189 : 493-502, 2022

10 Yang, K, "Recycling spent carbon cathode by a roasting method and its application in Li-ion batteries anodes" 261 : 121090-, 2020

11 Liu, C, "Recycling of spent lithium-ion batteries in view of lithium recovery : A critical review" 228 (228): 801-813, 2019

12 Tian, G, "Recycling of spent Lithium-ion Batteries: A comprehensive review for identification of main challenges and future research trends" 53 (53): 102447-, 2022

13 Lain, M. J, "Recycling of lithium ion cells and batteries" 97 : 736-738, 2001

14 Zhan, R, "Recovery of active cathode materials from lithium-ion batteries using froth flotation" 17 : e00062-, 2018

15 He, Y, "Recovery of LiCoO2 and graphite from spent lithium-ion batteries by Fenton reagentassisted flotation" 143 : 319-325, 2017

16 Ali, H, "Preprocessing of spent lithium-ion batteries for recycling: Need, methods, and trends" 168 : 112809-, 2022

17 Santana, I. L, "Photocatalytic properties of Co3O4/LiCoO2 recycled from spent lithium-ion batteries using citric acid as leaching agent" 190 : 38-44, 2017

18 Jung, H. S, "Optical Analysis of Graphene - Focusing on Raman Spectroscopy" 18 (18): 20-25, 2009

19 Xiao, J, "Novel Approach for in Situ Recovery of Lithium Carbonate from Spent Lithium Ion Batteries Using Vacuum Metallurgy" 51 (51): 11960-11966, 2017

20 Liu, K, "Innovative Electrochemical Strategy to Recovery of Cathode and Efficient Lithium Leaching from Spent Lithium-Ion Batteries" 3 (3): 4767-4776, 2020

21 Yun, J, "In-situ electrochemical coating of Ag nanoparticles onto graphite electrode with enhanced performance for Li-ion batteries" 155 : 396-401, 2015

22 Gao, Y, "Improvement of the electrochemical performance of spent graphite by asphalt coating" 24 : 101089-, 2021

23 Vieceli, N, "Hydrometallurgical recycling of EV lithium-ion batteries: Effects of incineration on the leaching efficiency of metals using sulfuric acid" 125 : 192-203, 2021

24 Yao, Y, "Hydrometallurgical Processes for Recycling Spent Lithium-Ion Batteries: A Critical Review" 6 (6): 13611-13627, 2018

25 Rothermel, S, "Graphite Recycling from Spent Lithium-Ion Batteries" 9 (9): 3473-3484, 2016

26 Liu, K, "From spent graphite to recycle graphite anode for high-performance lithium ion batteries and sodium ion batteries" 356 : 136856-, 2020

27 Liu, J, "Critical strategies for recycling process of graphite from spent lithium-ion batteries:A review" 816 : 151621-, 2021

28 Lai, X, "Critical review of life cycle assessment of lithium-ion batteries for electric vehicles: A lifespan perspective" 12 : 100169-, 2022

29 Winey, M, "Conventional transmission electronmicroscopy" 25 (25): 319-323, 2014

30 Meng, Y. F, "Concurrent recycling chemistry for cathode/anode in spent graphite/LiFePO4 batteries : Designing a unique cation/anionco-workable dual-ion battery" 64 : 166-171, 2022

31 Barrios, O. C, "Chlorination roasting of the cathode material contained in spent lithium-ion batteries to recover lithium, manganese, nickel and cobalt" 176 : 107321-, 2022

32 Hsieh, C. C, "Carbon-coated porous Si/C composite anode materials via two-step etching/coating processes for lithium-ion batteries" 46 (46): 26598-26607, 2020

33 Niu, B, "Advances and challenges in anode graphite recycling from spent lithium-ion batteries" 439 : 129678-, 2022

34 Zhu, X, "A promising regeneration of waste carbon residue from spent Lithium-ion batteries via low-temperature fluorination roasting and water leaching" 430 (430): 132703-, 2022

35 Ruan, D, "A low-cost silicon-graphite anode made from recycled graphite of spent lithiumion batteries" 884 : 115073-, 2021