2020
DOI: 10.1016/j.jclepro.2020.120869
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Recovering lithium cobalt oxide, aluminium, and copper from spent lithium-ion battery via attrition scrubbing

Abstract: Highlights Attrition scrubbing is effective in selectively concentrating LiCoO2. Attrition scrubbing improves liberation efficiency from 34% to 77%. Attrition produces a precursor for hydrometallurgical processes. Electrostatic separator is used to recover copper and aluminium. AbstractIn this manuscript, the results show that the single-stage liberation by using a cutting mill is sub-optimum. From the analysis, that the size fraction of < 850 µ m only recovers 43.7 wt% LiCoO2. With the recovery of 9.0 wt%… Show more

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Cited by 42 publications
(16 citation statements)
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“…[108] A flowchart for black mass recovery was proposed by Widijatmoko. [109,110] Cells were shredded and sieving was applied to separate the components into different size fractions. An attrition scrubbing technology was used to liberate fine black mass from coarse foils.…”
Section: Mechanical Pre-treatmentmentioning
confidence: 99%
“…[108] A flowchart for black mass recovery was proposed by Widijatmoko. [109,110] Cells were shredded and sieving was applied to separate the components into different size fractions. An attrition scrubbing technology was used to liberate fine black mass from coarse foils.…”
Section: Mechanical Pre-treatmentmentioning
confidence: 99%
“…In order for the European recycling operators to meet the target recoveries outlined by the new Batteries Regulation, research concerning the mechanical preprocessing of battery waste is also necessary [1]. Currently, one substantial challenge in LIB recycling is selectively separating the electrode components into a fraction of their own prior to the chemical separation, in a manner that allows for a high throughput and recovery [13]. Since the electrode materials are considerably finer than the other LIB components, sieving is commonly applied to concentrate the electrodes in the underflow, while the current collector foils (Cu/Al) and other metallic components are mainly separated in the overflow.…”
Section: Introductionmentioning
confidence: 99%
“…This fraction was then milled with a centrifugal mill with a 0.25mm grid followed by subsequent sieving whereby the cathode recovery size fraction was <850μm. The results indicate that 43.7% wt, 8.8% wt and 10.3% wt of LiCoO 2 , Al and Co were recovered respectively ( Widijatmoko et al., 2020a ). The results still demonstrated low LiCoO 2 recovery thus, attrition scrubbing has been proposed as a second-stage liberation technique and is introduced in this paper as an advanced recovery technique.…”
Section: Physical Methodsmentioning
confidence: 99%
“…Attrition scrubbing is conventionally used in glass, mineral and water treatment industries to remove adhering sludge ( Cole et al., 1981 ; Valchev et al., 2011 ) and has recently been introduced as a secondary liberation technique to enhance single-stage liberation performed with a cutting mill in lithium recovery from spent LIBs. Single-stage liberation has resulted in the recovery of 43.7 wt % LiCoO 2 in the size fraction of <850 mm as well as 10.6 wt % and 9.0 wt % Cu and Al respectively in the size fraction >850mm ( Widijatmoko et al., 2020a ). The low recovery and lack of liberation is a result of the particles remaining adhered to the Al current collector therefore attrition scrubbing has been found to be an efficient solution.…”
Section: Physical Methodsmentioning
confidence: 99%