A Scalable Froth-Flotation Separation Process for Direct Recycling of Li-Ion Batteries and Its Technical Feasibility

Abstract: The increasing demand for Li-ion batteries (LIBs) in hybrid and electric vehicles had led to a significant increase in the volume of new and end-of-life LIBs. For this reason, recycling of spent LIBs has attracted significant attention in recent years for future sustainability. Different from existing recycling methods such as pyrometallurgical and hydrometallurgical methods, direct recycling method recovers cathode and anode active materials directly in reusable forms at a low cost. This process consists of t… Show more

“…2017)). 32 It has been suggested that the tension-dependent elastic strain in an R2R process can be modeled using Hooke's Law: 33 T = AEε [3] where A is the cross-sectional area; E is the elastic modulus; and ε is the tensile strain. Thus, for each component, a value of maximum allowable tension can be calculated from the experimental values of E and ε.…”

“…8,9,22 The feasibility of recovering electrode capacity though re-lithiation has already been demonstrated, [23][24][25][26][27][28][29] and preliminary work has suggested that reconditioned electrodes can be analytically indistinguishable from fresh electrodes. 22 To date, all known work with direct recycling has been done at the laboratory scale; 8,[26][27][28][29][30][31][32] as such, comprehensive process engineering optimization has yet to be performed to make this approach viable on an industrial scale.…”

“…Error bars represent the range of elastic moduli calculated at each strain rate from six samples. The elastic modulus of cycled components was obtained at a strain rate of 0.00082 s −1 (data from Wu et al (2017)) 32.…”

Characterization of Aged Li-Ion Battery Components for Direct Recycling Process Design

“…2017)). 32 It has been suggested that the tension-dependent elastic strain in an R2R process can be modeled using Hooke's Law: 33 T = AEε [3] where A is the cross-sectional area; E is the elastic modulus; and ε is the tensile strain. Thus, for each component, a value of maximum allowable tension can be calculated from the experimental values of E and ε.…”

“…8,9,22 The feasibility of recovering electrode capacity though re-lithiation has already been demonstrated, [23][24][25][26][27][28][29] and preliminary work has suggested that reconditioned electrodes can be analytically indistinguishable from fresh electrodes. 22 To date, all known work with direct recycling has been done at the laboratory scale; 8,[26][27][28][29][30][31][32] as such, comprehensive process engineering optimization has yet to be performed to make this approach viable on an industrial scale.…”

“…Error bars represent the range of elastic moduli calculated at each strain rate from six samples. The elastic modulus of cycled components was obtained at a strain rate of 0.00082 s −1 (data from Wu et al (2017)) 32.…”

Characterization of Aged Li-Ion Battery Components for Direct Recycling Process Design