Removal of iron and aluminum from hydrometallurgical NMC-LFP recycling process through precipitation

• Published in: Minerals engineering Vol. 218; p. 109037
• Main Authors: Zou, Yuanmin, Chernyaev, Alexander, Seisko, Sipi, Sainio, Jani, Lundström, Mari
• Format: Journal Article
• Language: English
• Published: Elsevier Ltd 01.11.2024
• Subjects: Black mass; Cathode active material; Copper; Fluorine removal; Lithium-ion battery; Phosphate; Black mass; Lithium-ion battery; Fluorine removal; Cathode active material; Copper; Phosphate
• ISSN: 0892-6875
• DOI: 10.1016/j.mineng.2024.109037

[Display omitted] •The presence of LFP in battery waste changes Fe and Al removal.•At pH 2 iron can be precipitated with 0.7 wt% Ni and ≤ 0.4 wt% Mn, Co, Al, and Li.•Iron precipitates as iron phosphate (FePO4) and iron fluoride (FeF3)•91% of Al precipitates at pH 4.5 as AlOOH, Al-F complex keeps minor Al soluble.•Selective Fe removal or combined Fe-Al removal can be conducted with pH adjustment. There is a need to develop removal strategies for typical battery impurities–iron and aluminum–from actual hydrometallurgical recycling solutions. In this work, the investigated solution originated from lithium nickel manganese cobalt oxide (NMC) rich black mass, while iron phosphate (LFP) was used as an in situ reductant. It was found that the presence of phosphate ions supported selective iron precipitation already at pH = 2.0 (T = 60 °C, t = 3 h, NaOH), with nearly complete iron removal (97.8 %). The precipitate was rich in iron (21.5 wt%) and phosphorus (13.4 wt%); it also contained 0.7 wt% Ni and 0.3–0.4 wt% Mn, Co, Al, and Li. It is suggested that the presence of phosphate in minor amounts may cause this co-precipitation of battery metals. With the aim of combined precipitation of iron (100 %) and aluminum (91.0 %), the pH was increased up to 4.5. Although 90.8 % of fluoride precipitated, the remaining fluorides may have kept the aluminum partially in soluble form as Al-F complexes. The formed precipitate had lower iron (18.4 wt%) and phosphorus (11.4 wt%) content, whereas the impurity contents and thus the battery metals losses were slightly higher: Ni, Mn, Co, Al, and Cu were each between 1.1–1.9 wt% and Li and F < 1 wt%. In the precipitates investigated, iron was found predominantly as iron phosphate (FePO4), whereas a minor fraction also precipitated as iron fluoride (FeF3). The precipitated aluminum existed mainly as AlOOH. The results presented here will help to build iron and aluminum removal strategies for industrial battery recycling solutions, and also provide insights into the dominant iron and aluminum phases forming the precipitates.