CA2869154C - Magnetic separation of electrochemical cell materials - Google Patents
Magnetic separation of electrochemical cell materials Download PDFInfo
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- CA2869154C CA2869154C CA2869154A CA2869154A CA2869154C CA 2869154 C CA2869154 C CA 2869154C CA 2869154 A CA2869154 A CA 2869154A CA 2869154 A CA2869154 A CA 2869154A CA 2869154 C CA2869154 C CA 2869154C
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B03—SEPARATION OF SOLID MATERIALS USING LIQUIDS OR USING PNEUMATIC TABLES OR JIGS; MAGNETIC OR ELECTROSTATIC SEPARATION OF SOLID MATERIALS FROM SOLID MATERIALS OR FLUIDS; SEPARATION BY HIGH-VOLTAGE ELECTRIC FIELDS
- B03C—MAGNETIC OR ELECTROSTATIC SEPARATION OF SOLID MATERIALS FROM SOLID MATERIALS OR FLUIDS; SEPARATION BY HIGH-VOLTAGE ELECTRIC FIELDS
- B03C1/00—Magnetic separation
- B03C1/02—Magnetic separation acting directly on the substance being separated
- B03C1/28—Magnetic plugs and dipsticks
- B03C1/286—Magnetic plugs and dipsticks disposed at the inner circumference of a recipient, e.g. magnetic drain bolt
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B03—SEPARATION OF SOLID MATERIALS USING LIQUIDS OR USING PNEUMATIC TABLES OR JIGS; MAGNETIC OR ELECTROSTATIC SEPARATION OF SOLID MATERIALS FROM SOLID MATERIALS OR FLUIDS; SEPARATION BY HIGH-VOLTAGE ELECTRIC FIELDS
- B03C—MAGNETIC OR ELECTROSTATIC SEPARATION OF SOLID MATERIALS FROM SOLID MATERIALS OR FLUIDS; SEPARATION BY HIGH-VOLTAGE ELECTRIC FIELDS
- B03C1/00—Magnetic separation
- B03C1/02—Magnetic separation acting directly on the substance being separated
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B02—CRUSHING, PULVERISING, OR DISINTEGRATING; PREPARATORY TREATMENT OF GRAIN FOR MILLING
- B02C—CRUSHING, PULVERISING, OR DISINTEGRATING IN GENERAL; MILLING GRAIN
- B02C23/00—Auxiliary methods or auxiliary devices or accessories specially adapted for crushing or disintegrating not provided for in preceding groups or not specially adapted to apparatus covered by a single preceding group
- B02C23/08—Separating or sorting of material, associated with crushing or disintegrating
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B03—SEPARATION OF SOLID MATERIALS USING LIQUIDS OR USING PNEUMATIC TABLES OR JIGS; MAGNETIC OR ELECTROSTATIC SEPARATION OF SOLID MATERIALS FROM SOLID MATERIALS OR FLUIDS; SEPARATION BY HIGH-VOLTAGE ELECTRIC FIELDS
- B03C—MAGNETIC OR ELECTROSTATIC SEPARATION OF SOLID MATERIALS FROM SOLID MATERIALS OR FLUIDS; SEPARATION BY HIGH-VOLTAGE ELECTRIC FIELDS
- B03C1/00—Magnetic separation
- B03C1/02—Magnetic separation acting directly on the substance being separated
- B03C1/025—High gradient magnetic separators
- B03C1/031—Component parts; Auxiliary operations
- B03C1/032—Matrix cleaning systems
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B03—SEPARATION OF SOLID MATERIALS USING LIQUIDS OR USING PNEUMATIC TABLES OR JIGS; MAGNETIC OR ELECTROSTATIC SEPARATION OF SOLID MATERIALS FROM SOLID MATERIALS OR FLUIDS; SEPARATION BY HIGH-VOLTAGE ELECTRIC FIELDS
- B03C—MAGNETIC OR ELECTROSTATIC SEPARATION OF SOLID MATERIALS FROM SOLID MATERIALS OR FLUIDS; SEPARATION BY HIGH-VOLTAGE ELECTRIC FIELDS
- B03C1/00—Magnetic separation
- B03C1/02—Magnetic separation acting directly on the substance being separated
- B03C1/025—High gradient magnetic separators
- B03C1/031—Component parts; Auxiliary operations
- B03C1/033—Component parts; Auxiliary operations characterised by the magnetic circuit
- B03C1/0335—Component parts; Auxiliary operations characterised by the magnetic circuit using coils
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B03—SEPARATION OF SOLID MATERIALS USING LIQUIDS OR USING PNEUMATIC TABLES OR JIGS; MAGNETIC OR ELECTROSTATIC SEPARATION OF SOLID MATERIALS FROM SOLID MATERIALS OR FLUIDS; SEPARATION BY HIGH-VOLTAGE ELECTRIC FIELDS
- B03C—MAGNETIC OR ELECTROSTATIC SEPARATION OF SOLID MATERIALS FROM SOLID MATERIALS OR FLUIDS; SEPARATION BY HIGH-VOLTAGE ELECTRIC FIELDS
- B03C1/00—Magnetic separation
- B03C1/02—Magnetic separation acting directly on the substance being separated
- B03C1/025—High gradient magnetic separators
- B03C1/031—Component parts; Auxiliary operations
- B03C1/033—Component parts; Auxiliary operations characterised by the magnetic circuit
- B03C1/034—Component parts; Auxiliary operations characterised by the magnetic circuit characterised by the matrix elements
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B03—SEPARATION OF SOLID MATERIALS USING LIQUIDS OR USING PNEUMATIC TABLES OR JIGS; MAGNETIC OR ELECTROSTATIC SEPARATION OF SOLID MATERIALS FROM SOLID MATERIALS OR FLUIDS; SEPARATION BY HIGH-VOLTAGE ELECTRIC FIELDS
- B03C—MAGNETIC OR ELECTROSTATIC SEPARATION OF SOLID MATERIALS FROM SOLID MATERIALS OR FLUIDS; SEPARATION BY HIGH-VOLTAGE ELECTRIC FIELDS
- B03C1/00—Magnetic separation
- B03C1/32—Magnetic separation acting on the medium containing the substance being separated, e.g. magneto-gravimetric-, magnetohydrostatic-, or magnetohydrodynamic separation
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B07—SEPARATING SOLIDS FROM SOLIDS; SORTING
- B07B—SEPARATING SOLIDS FROM SOLIDS BY SIEVING, SCREENING, SIFTING OR BY USING GAS CURRENTS; SEPARATING BY OTHER DRY METHODS APPLICABLE TO BULK MATERIAL, e.g. LOOSE ARTICLES FIT TO BE HANDLED LIKE BULK MATERIAL
- B07B1/00—Sieving, screening, sifting, or sorting solid materials using networks, gratings, grids, or the like
- B07B1/46—Constructional details of screens in general; Cleaning or heating of screens
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01M—PROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
- H01M10/00—Secondary cells; Manufacture thereof
- H01M10/54—Reclaiming serviceable parts of waste accumulators
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B03—SEPARATION OF SOLID MATERIALS USING LIQUIDS OR USING PNEUMATIC TABLES OR JIGS; MAGNETIC OR ELECTROSTATIC SEPARATION OF SOLID MATERIALS FROM SOLID MATERIALS OR FLUIDS; SEPARATION BY HIGH-VOLTAGE ELECTRIC FIELDS
- B03C—MAGNETIC OR ELECTROSTATIC SEPARATION OF SOLID MATERIALS FROM SOLID MATERIALS OR FLUIDS; SEPARATION BY HIGH-VOLTAGE ELECTRIC FIELDS
- B03C2201/00—Details of magnetic or electrostatic separation
- B03C2201/18—Magnetic separation whereby the particles are suspended in a liquid
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B07—SEPARATING SOLIDS FROM SOLIDS; SORTING
- B07B—SEPARATING SOLIDS FROM SOLIDS BY SIEVING, SCREENING, SIFTING OR BY USING GAS CURRENTS; SEPARATING BY OTHER DRY METHODS APPLICABLE TO BULK MATERIAL, e.g. LOOSE ARTICLES FIT TO BE HANDLED LIKE BULK MATERIAL
- B07B1/00—Sieving, screening, sifting, or sorting solid materials using networks, gratings, grids, or the like
- B07B1/46—Constructional details of screens in general; Cleaning or heating of screens
- B07B1/4609—Constructional details of screens in general; Cleaning or heating of screens constructional details of screening surfaces or meshes
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B07—SEPARATING SOLIDS FROM SOLIDS; SORTING
- B07B—SEPARATING SOLIDS FROM SOLIDS BY SIEVING, SCREENING, SIFTING OR BY USING GAS CURRENTS; SEPARATING BY OTHER DRY METHODS APPLICABLE TO BULK MATERIAL, e.g. LOOSE ARTICLES FIT TO BE HANDLED LIKE BULK MATERIAL
- B07B1/00—Sieving, screening, sifting, or sorting solid materials using networks, gratings, grids, or the like
- B07B1/46—Constructional details of screens in general; Cleaning or heating of screens
- B07B1/4609—Constructional details of screens in general; Cleaning or heating of screens constructional details of screening surfaces or meshes
- B07B1/4645—Screening surfaces built up of modular elements
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02E—REDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
- Y02E60/00—Enabling technologies; Technologies with a potential or indirect contribution to GHG emissions mitigation
- Y02E60/10—Energy storage using batteries
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02W—CLIMATE CHANGE MITIGATION TECHNOLOGIES RELATED TO WASTEWATER TREATMENT OR WASTE MANAGEMENT
- Y02W30/00—Technologies for solid waste management
- Y02W30/50—Reuse, recycling or recovery technologies
- Y02W30/84—Recycling of batteries or fuel cells
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Abstract
Description
MAGNETIC SEPARATION OF ELECTROCHEMICAL CELL MATERIALS
INVENTORS
Timothy W. Ellis Joshua A. Montenegro TECHNICAL FIELD
[0001] This specification generally relates to the separation of recyclable electrode materials from electrochemical cell scrap. More specifically, this specification relates to the separation of recyclable electrode materials from electrochemical cell scrap to form recycled material concentrates that may be directly re-used in new electrochemical cell manufacturing.
BACKGROUND
Accordingly, the widespread use of batteries and other devices comprising electrochemical cells (e.g., electric double-layer capacitors, also known as supercapacitors or ultracapacitors) causes the generation of large scrap battery waste streams.
SUMMARY
A slurry is formed comprising the electrode active materials. The slurry comprises lithium metal compounds. The slurry is subjected to a magnetic field of sufficient magnetic field intensity to magnetize particles in the slurry. The magnetized particles comprise at least one lithium metal compound. The magnetized particles are separated from the slurry using magnetic force induced between the magnetized particles and an active magnetic surface in contact with the slurry.
The magnetized particles are separated from the slurry using magnetic force induced between the magnetized particles and an active magnetic surface in contact with the slurry. The separated particles comprise one of the two or more lithium metal compounds. The two or more lithium metal compounds are collected as separated electrode active material concentrates.
BRIEF DESCRIPTION OF THE DRAWINGS
separation system;
separation system comprising a recycle feature;
DESCRIPTION
Thus, the invention is not limited by the description of the various non-limiting and non-exhaustive embodiments disclosed in this specification. The features and characteristics described in connection with various embodiments may be combined with the features and characteristics of other embodiments. Such modifications and variations are intended to be included within the scope of this specification. As such, the claims may be amended to recite any features or characteristics expressly or inherently described in, or otherwise expressly or inherently supported by, this specification. Further, Applicant(s) reserve the right to amend the claims to affirmatively disclaim features or characteristics that may be present in the prior art.
Therefore, any such amendments comply with the requirements of 35 U.S.C.
112, first paragraph, and 35 U.S.C. 132(a). The various embodiments disclosed and described in this specification can comprise, consist of, or consist essentially of the features and characteristics as variously described herein.
For example, a range of "1.0 to 10.0" is intended to include all sub-ranges between (and including) the recited minimum value of 1.0 and the recited maximum value of 10.0, that is, having a minimum value equal to or greater than 1.0 and a maximum value equal to or less than 10.0, such as, for example, 2.4 to 7.6. Any maximum numerical limitation recited in this specification is intended to include all lower numerical limitations subsumed therein and any minimum numerical limitation recited in this specification is intended to include all higher numerical limitations subsumed therein. Accordingly, Applicant(s) reserve the right to amend this specification, including the claims, to expressly recite any sub-range subsumed within the ranges expressly recited herein. All such ranges are intended to be inherently described in this specification such that amending to expressly recite any such sub-ranges would comply with the requirements of 35 U.S.C. 112, first paragraph, and 35 U.S.C.
132(a).
An overview of the recycling of these battery systems is described in the following references:
= Stevenson, M., "Recycling: Lead-Acid Batteries: Overview," Encyclopedia of Electrochemical Power Sources, pp. 165-178, 2009, Elsevier B.V., Editor-in-Chief: Jurgen Garche.
= Sloop, S.E., Kotaich, K., Ellis, T.W., & Clarke, R., "Recycling:
Lead¨Acid Batteries: Electrochemical," Encyclopedia of Electrochemical Power Sources, pp. 179-187, 2009, Elsevier B.V., Editor-in-Chief: Jurgen Garche.
= Kotaich, K. & Sloop, S.E., "Recycling: Lithium and Nickel¨Metal Hydride Batteries," Encyclopedia of Electrocheinical Power Sources, pp. 188-198, 2009, Elsevier By., Editor-in-Chief: Jurgen Garche.
= Scott, K., "Recycling: Nickel¨Metal Hydride Batteries," Encyclopedia of Electrochemical Power Sources, pp. 199-208, 2009, Elsevier B.V., Editor-in-Chief: Jurgen Garche.
= Xu, J., Thomas H.R., Francis R.W., Lum, K.R., Wang, J., Liang, B., "A
review of processes and technologies for the recycling of lithium-ion secondary batteries," Journal of Power Sources, Volume 177, January 2008, pp. 512-527.
= S. M. Shin, N. H. Kim, J. S. Sohn, D. H. Yang, Y. H. Kim, "Development of a metal recovery process from Li-ion battery wastes," Hydrometallurgy, Volume 79, Issues 3-4, October 2005, pp. 172-181.
= Junmin Nan, Dongmei Han, Xiaoxi Zuo, "Recovery of metal values from spent lithium-ion batteries with chemical deposition and solvent extraction,"
Journal of Power Sources, Volume 152, 1 December 2005, Pages 278-284.
= Rong-Chi Wanga, Yu-Chuan Lina, She-Huang Wub, "A novel recovery process of metal values from the cathode active materials of the lithium-ion secondary batteries," Hydrometallurgy, Volume 99, Issues 3-4, November 2009, Pages 194-201.
= Y. Pranolo, W. Zhang, C.Y. Cheng, "Recovery of metals from spent lithium-ion battery leach solutions with a mixed solvent extractant system,"
Hydrometallurgy, Volume 102, Issues 1-4, April 2010, Pages 37-42.
= Baoping Xin, Di Zhang, Xian Zhang, Yunting Xia, Feng Wu, Shi Chen, Li Li, "Bioleaching mechanism of Co and Li from spent lithium-ion battery by the mixed culture of acidophilic sulfur-oxidizing and iron-oxidizing bacteria,"
Bioresource Technology, Volume 100, Issue 24, December 2009, Pages 6163-6169.
= Li L, Gc J, Wu F, Chen R, Chen S, Wu B, "Recovery of cobalt and lithium from spent lithium ion batteries using organic citric acid as leachant," J.
Hazard Mater., 176(1-3), Apr 15, 2010, pp. 288-93.
= M Contestabile, S Panero, B Scrosati, "A laboratory-scale lithium-ion battery recycling process," Journal of Power Sources, Volume 92, Issues 1-2, January 2001, Pages 65-69.
= Daniel Assumpcdo Bertuola, Andrea Moura Bemardesa, Jorge Alberto Soares Tenoriob, "Spent NiMH batteries: Characterization and metal recovery through mechanical processing," Journal of Power Sources, Volume 160, Issue 2, 6 October 2006, Pages 1465-1470.
= Kim, Y, Matsuda, M., Shibayama, A., Fujita, T., "Recovery of LiCo02 from Wasted Lithium Ion Batteries by using Mineral Processing Technology,"
Resources Processing, Volume 51, Issue 1, 2004, pp. 3-7.
= U.S. Patent No. 6,261,712, July 17, 2001.
= International Patent Application Publication No. WO 2008/022415 Al, February 28, 2008.
Industrial-scale processes for the reclamation and recycling of active electrochemical cell materials (i.e., the electrode active materials) generally fall into two categories: pyrometallurgical processes and hydrometallurgical processes.
Pyrometallurgical processes involve the high-temperature smelting of scrap electrochemical cells to produce various alloys, metallic oxides, carbon, and flue gases. Pyrometallurgical processes are very energy-intensive and produce large quantities of slag, dross, fly ash, and other waste materials that must be disposed of or further processed. Hydrometallurgical processes generally employ aggressive chemicals such as strong acids and/or strong bases to dissolve metals, alloys, and/or inorganic metal compounds, such as metal oxides, and extract or leach the active electrochemical cell materials from scrap electrochemical cells. To recover the extracted/leached materials, the ion-rich leach solutions that result from extraction treatment must be further processed by techniques such as counter-solvent extraction, chemical precipitation, chemical deposition, and/or electrowinning to recover the dissolved metals in a chemically reduced or other useful form. Hydrometallurgical processes rely on inorganic solution chemistry and solution post-processing and, therefore, may pose environmental or workplace health and safety concerns arising from solution waste streams.
Pyrometallurgical and hydrometallurgical processes both suffer from various additional disadvantages, particularly in the context of recycling electrode materials from lithium-ion batteries. In both types of recycling processes, the electrode active materials are recovered in structurally-modified and chemically-modified forms that cannot be directly re-used to manufacture electrodes for new electrochemical cells.
For example, during pyrometallurgical recycling of lithium-ion batteries, the cathode (i.e., positive electrode) active materials (e.g., LiCo02, LiMn204, LiFePO4, LiNi02, LiNiCoMn02, LiNi113Co1/A11/302, LiNi0.8Co0 202, LiNi00.833Coo.1702) are chemically converted into Co-Fe-Ni-Mn alloys, which are recovered as the smelting product, and lithium oxides, which are lost to slag, fly ash, and dross. Likewise, during hydrometallurgical recycling of lithium-ion batteries, the cathode active materials are chemically converted into various oxides, hydroxides, and oxyhydroxides of the constituent metals, which must undergo substantial post-processing, separation, purification, and chemical modification and synthesis to reconstitute cathode active materials. Analogous issues are associated with the pyrometallurgical and hydrometallurgical recycling of electrode active materials from nickel-metal hydride, lead-acid, and other electrochemical cell chemistries.
Alternatively, in various non-limiting embodiments, the processes and systems described in this specification may be used in combination with pyrometallurgical, hydrometallurgical, and other recycling processes and systems.
M = z H
wherein z is the magnetic susceptibility of the material. Magnetic susceptibility is a dimensionless proportionality constant that indicates the degree of magnetization of a material in response to an externally applied magnetic field. The magnetic susceptibility of a material is an intrinsic physical property. The magnetic susceptibility of a material provides a measure of how the material will react when placed in a magnetic field.
Materials that do not have any unpaired electron orbital spin or spin angular momentum are generally diamagnetic. Diamagnetic materials are repelled by an externally applied magnetic field. The magnetic susceptibility values of diamagnetic materials are negative values, which indicate the repulsion of the materials by externally applied magnetic fields.
Larger absolute values of the magnetic susceptibilities of diamagnetic materials correlate with larger induced magnetizations and larger repulsive magnetic forces between the diamagnetic materials and an externally applied magnetic field.
However, unlike paramagnetic materials, ferromagnetic materials exhibit a persistent magnetization in the absence of an externally applied magnetic field. Ferromagnetism arises from the intrinsic tendency of the unpaired electrons of these materials to orient parallel to each other (either co-parallel or anti-parallel, i.e., ferro- and fern-magnetism, respectively) to minimize their energy state. Ferromagnetic materials are characterized by a Curie point temperature above which a given ferromagnetic material loses its ferromagnetic properties because increased thermal motion within the material disrupts the alignment of the electron's intrinsic spin magnetic moments.
LiCo02 is the most common cathode active material in commercial and industrial lithium-ion electrochemical cells because this material exhibits reliable cathodic performance, high energy density, low self-discharge rate, long cycle time, and ease of manufacture.
6 C + x Li+ + x e 4C6Lix LiCo02 4 Li(l_x)Co02+ x Li + + x e-
Table 1 Component Range Example (Weight Percent) Composition (weight percent) Lithium metal compound 25-30 27.5 Steel/nickel 22-27 24.5 Cu/A1 12-17 14.5 Graphite 14-18 16.0 Electrolyte 2-6 3.5 Polymer/Plastics 12-16 14.0
refers to a compound comprising lithium, at least one additional metal or metal oxide, and an inorganic counter ion such as, for example, oxide (022-) or phosphate (P043-).
In various non-limiting embodiments, a lithium metal compound may be represented by the general formula:
LiMxNz wherein M is one or more metals selected from the group consisting of Co, Mn, Ni, Fe, and Al, wherein N is an inorganic counter ion selected from the group consisting of 022- and P043-, wherein x ranges from greater than zero to two (0 <x 2), and wherein z ranges from one to five (1 z 5). In various non-limiting embodiments, a lithium metal compound may comprise LiCo02, LiMn204, LiFePO4, LiNi02, LiNiCoMn02, LiNiv3Cou3A11/302, LiNi0.8Co0 202, or LiNi00.833Co0.17302. In some non-limiting embodiments, a lithium metal compound may comprise a compound of the formula:
LiNii_yCoy02 wherein y ranges from zero to 1 (0 y 1).
The lithium compound powder and the metal compound powders are, respectively, compounds that can produce corresponding oxides or phosphates by calcination of the powders. For example, mixtures of powdered oxides, hydroxides, carbonates, carbides, phosphates, and the like, of lithium, cobalt, manganese, nickel, iron, and aluminum, including mixed metal compounds, may be calcined to produce particulate lithium metal compound powders, which may be used to form the cathode active material coatings on current collecting plates or foils.
Examples of suitable lithium compounds include Li20, Li2C01, and the like.
Examples of suitable cobalt compounds include Co(OH)2, Co2(CO3)(OH)2, CO203, and the like.
Examples of suitable nickel compound include Ni(OH)2, Ni2(CO3)(OH)2, Ni203, and the like. Other suitable materials include various manganese, iron, and aluminum oxides, hydroxides, and the like.
For example, some lithium-ion electrochemical cells comprise tape-casted or painted electrodes comprising virgin (unprocessed) graphite particles having a D90 value of 14 micrometers, and virgin LiMn204 or LiNiCoMn02 having D90 values of 5.4 micrometers and 15.6 micrometers, respectively, wherein the D90 value is the particle size below which lies 90 percent of the volume of a particle sample.
This is accomplished in accordance with various embodiments described in this specification by utilizing the different magnetic susceptibilities of different lithium metal compounds, which are paramagnetic and, therefore, will exhibit different magnetization behavior when subjected to an externally applied magnetic field.
solvent or supercritical fluid extraction of electrolyte; pyrolysis or heat treatment to thermally degrade and remove plastics, electrolyte, and/or binder; crushing, milling, shredding, or otherwise comminuting electrochemical cells; and screening, sieving, or otherwise classifying comminuted electrochemical cell materials.
Examples of suitable comminution equipment include, but are not limited to, vertical cutting mills, hammer mills, knife mills, slitter mills, ball mills, pebble mills, and the like. The comminuted electrochemical cell components may then be classified and separated based on particle size to remove and separate plastic casing materials, steel or aluminum casing materials, plastic separator materials, circuit components, and other non-electrode materials from the particulate electrode materials. The size classification and separation of comminuted electrochemical cell materials may be performed, for example, using a screening or sieving operation. Such unit operations may be performed, for example, wing multiple differently-sized sieves, air tables, vibration screens, and like equipment.
Alternatively, or in addition, comminuted electrochemical cell components may be subjected to a preliminary magnetic separation operation to remove ferromagnetic and very highly paramagnetic materials such as, for example, steel casing and housing materials. It is understood that a preliminary magnetic separation operation to remove ferromagnetic and very highly paramagnetic materials from comminuted electrochemical cells before the formation of a slurry (see step 16 in Figure 1, described below) is different than the magnetic separation and concentration of electrode active materials (see steps 18-24 in Figure 1, described below).
particles may comprise one or more unit operations such as, for example, solvent wash treatment, water rinse treatment, froth flotation treatment, mechanical dispersion, and/or ultrasonic dispersion.
Patent Application Publication No. 2011-0272331 Al.
In various non-limiting embodiments, black mass comprising Pb(II) and Pb(IV) compounds may be suspended in water in a froth flotation vessel with a froth flotation agent and sparged with air to entrain hydrophobically-modified lead compound materials and float the lead-based materials out of the vessel, thereby removing the lead-based materials from the black mass.
For example, the magnetic field may magnetize particles comprising at least one lithium metal compound. The magnetization of particles comprising the slurry induces a magnetic force between the magnetized particles and an active magnetic surface in contact with the slurry at step 20. The attractive nature of the induced magnetic force separates the magnetized particles from the slurry at step 22, for example, by pinning the magnetized particles to the active magnetic surface in contact with the slurry, thereby overcoming the fluid drag forces of the slurry carrier fluid and retaining the magnetized particles as a magnetic fraction while eluting a non-magnetic fraction. By controlling the magnetic field intensity and/or gradient, and the nature of the active magnetic surface, predetermined electrode active materials separated from the slurry may be concentrated and purified to produce an electrode active material concentrate at step 24.
The particles retained in the magnetic flux-converging matrix 56 are flushed out of the separation box 54 by flowing clean carrier fluid from a clean carrier fluid feed 62 and through the separation box 54 after discontinuing the slurry flow from slurry feed 60 and after de-energizing the electromagnetic coils 52a and 52b. The flushed magnetic fraction is collected in collection vessel 68. The flow of slurry, clean carrier fluid, non-magnetic fractions, and flushed magnetic fractions may be controlled, for example, my manipulating valves 58a, 58b, 58c, and 58d, and other transport equipment such as pumps (not shown).
process or system comprising a high-intensity magnetic filter or a wet high-intensity magnetic separator may be operated in a batch or semi-batch manner. For example, a slurry comprising multiple different electrode active materials such as graphite and one or more lithium metal compounds may be fed to a high-intensity magnetic filter or a wet high-intensity magnetic separator operating at a magnetic field intensity sufficient to retain a paramagnetic electrode active material. The resulting magnetic fraction may comprise a lithium metal compound concentrate, for example, and the non-magnetic fraction may comprise graphite and lithium metal compounds possessing lower magnetic susceptibility values than the magnetically retained compound.
first non-magnetic fraction passes the first magnetic separator 105a and is fed to a second magnetic separator 105b where a second magnetic fraction is retained comprising the slurry constituent possessing the second largest magnetic susceptibility value. The second magnetic fraction is subsequently collected as a second electrode active material concentrate. A
second non-magnetic fraction passes the second magnetic separator 105b and is fed to a third magnetic separator 105c where a third magnetic fraction is retained comprising the slurry constituent possessing the third largest magnetic susceptibility value. The third magnetic fraction is subsequently collected as a third electrode active material concentrate. A
third non-magnetic fraction passes the third magnetic separator 105c and may comprise a non-magnetic electrode active material concentrate, such as, for example, a graphite concentrate, that may be collected. Alternatively, the third non-magnetic fraction may be fed to subsequent unit operations such as additional magnetic separation stages for further refinement.
As shown in Figure 5A, the tank drum separator 150a comprises a stationary magnet assembly 152a located within a rotating drum 156a positioned in a slurry tank 154a. The externally applied magnetic field from the magnet assembly 152a induces a magnetization in the drum surface 156a as it rotates past the magnet assembly 152a, which produces a zone 163a of high magnetic gradient. Paramagnetic particles passing through the high magnetic gradient zone 163a are also magnetized by the magnet assembly 152a, which induces an attractive magnetic force between the magnetized particles and the magnetized drum surface 156a when the surface is located adjacent to the magnet assembly 152a. The drum surface 156a functions as an active magnetic surface to which the magnetized particles may be pinned, thereby overcoming fluid drag forces of a slurry carrier fluid and retaining the magnetized particles on the drum surface 156a while the drum surface is located adjacent to the magnet assembly 152a. As the counterclockwise rotating drum surface 156a proceeds away from the magnet assembly 152a, the magnetic field weakens, the drum surface and pinned particles are de-magnetized, and the previously magnetized particles detach from the drum surface and elute as a magnetic fraction. The balance of the feed slurry elutes as a non-magnetic fraction. The counterclockwise rotation of the drum surface 156a is generally concurrent with the direction of slurry flow as indicated by arrows 165a.
Accordingly, the intensity of the magnetic field established in the high magnetic gradient zones 162a and 163b may be used to control the separation of electrode active materials comprising a slurry by retaining predetermined paramagnetic compounds, such as lithium metal compounds, while passing non-magnetic compounds such as graphite. This capability may be used to separate and concentrate the various electrode active materials comprising the feed slurry.
The resulting magnetic fraction may comprise a lithium metal compound concentrate, for example, and the non-magnetic fraction may comprise graphite and lithium metal compounds possessing lower magnetic susceptibility values than the magnetically retained compound.
Alternatively, the third non-magnetic fraction may be fed to subsequent unit operations such as additional drum separation stages for further refinement.
EAM1 is diamagnetic like graphite, for example. EAM2, EAM3, and EAM4 are paramagnetic like lithium metal compounds and nickel oxyhydroxide, for example, and each electrode active material possesses successively greater magnetic susceptibilities, i.e.
x, <
The slurry is successively fed to three magnetic separation stages, which may be implemented using any suitable combination of magnetic separation equipment.
The three successive stages utilize successively higher magnetic field intensities, i.e., H1 <H2 <H3.
The non-magnetic fraction from Stage-1 and Stage-2 are fed to Stage-2 and Stage-3, respectively. EAM4 (comprising the largest magnetic susceptibility value, x4) is separated and concentrated as the magnetic fraction at Stage-1 (comprising the smallest magnetic field intensity, Hl). EAM3 (comprising the second largest magnetic susceptibility value, Z3) is separated and concentrated as the magnetic fraction at Stage-2 (comprising the second smallest magnetic field intensity, H2). EAM2 and EAM1 (comprising the second lowest and the lowest magnetic susceptibility values, respectively, x2 and xi) are separated and concentrated at Stage-3 (comprising the largest magnetic field intensity H3).
EAM2 is concentrated in the magnetic fraction of Stage-3 and EAM1 is concentrated in the non-magnetic fraction of Stage-3.
EAM1 is diamagnetic like graphite, for example. EAM2, EAM3, and EAM4 are paramagnetic like lithium metal compounds and nickel oxyhydroxide, for example, and each electrode active material possesses successively greater magnetic susceptibilities, i.e., xi < x2 < x3 < x4.
The slurry is successively fed to three magnetic separation stages, which may be implemented using any suitable combination of magnetic separation equipment.
The three successive stages utilize successively lower magnetic field intensities, i.e., Hl > H2 > H3. The magnetic fraction from Stage-1 and Stage-2 are fed to Stage-2 and Stage-3, respectively.
EAM1 (comprising the lowest magnetic susceptibility value, x1) is separated and concentrated as the non-magnetic fraction at Stage-1 (comprising the largest magnetic field intensity, H1).
EAM2 (comprising the second lowest magnetic susceptibility value, Z2) is separated and concentrated as the non-magnetic fraction at Stage-2 (comprising the second largest magnetic field intensity, H2). EAM3 and EAM4 (comprising the second highest and the highest magnetic susceptibility values, respectively, x3 and x4) are separated and concentrated at Stage-3 (comprising the smallest magnetic field intensity H3). EAM4 is concentrated in the magnetic fraction of Stage-3 and EAM3 is concentrated in the non-magnetic fraction of Stage-3.
EXAMPLES
Example-1: Magnetic susceptibilities of select lithium metal compounds
Mm = Xm H
Table 2 Lithium metal compound 3 ___________________ Cyõ, [in /kg_I) ( xõ, [enzu/gm-Od ) LiFePO4 4.82 x 10-3 6.064 x 10-5 LiMn204 3.52 x 10-3 4.419 x 10-5 LiNiCoMn02 2.26 x 10-3 2.842 x 10-5 LiNi00.833Co0.17002 1.34 x 10-3 1.690 x 10-5 LiCo02 8.91 x 10-5 1.124x 10-6 As shown in Figure 12, the magnetic susceptibilities of each lithium metal compound are sufficiently different to facilitate the magnetic separation, isolation, and concentration of each individual lithium metal compound from a mixed black mass slurry comprising multiple different lithium metal compounds.
Example-2: Select lithium metal compound test separations
magnetic flux-converging matrix is positioned within the separation box to intensify the magnetic field gradient within the separation box and function as an active magnetic surface to which magnetized particles are pinned during a separation. The magnetic flux-converging matrix may comprise an expanded metal material similar to a steel wool material. The Eriez L-4-20 uses standard expanded metal flux-converging matrices such as, for example, coarse grid (1/2 inch #13 gauge) and medium grid (1/4 inch #18 gauge). Coarse grid will handle feeds with particle sizes as great as 20 mesh. Medium grid should be used with particles of 30 mesh or smaller particle sizes.
This capability was used to perform two test separations: (i) a separation of a mixture of reagent grade LiCo02 and reagent grade LiMn204; and (ii) a separation of a mixture of reagent grade LiCo02 and reagent grade LiFePO4.
LiMn204powder mixture and the LiCo02 ¨LiFePO4powder mixture were used to form aqueous slurries comprising the lithium metal compounds at a 5% solid content by mass by hand mixing under ambient conditions. The aqueous slurries were double-passed through the Eriez L-4-20 operating at 30%, 60%, and 90% of maximum magnetic field intensity, respectively. A #18 gauge medium grid expanded metal mesh was used as the magnetic flux-converging matrix for the test separations. The first passes separated the constituent particles into magnetic fractions (which were pinned to the magnetic flux-converging matrix) and non-magnetic fractions (which passed through with the slurry) at the predetermined magnetic field intensities. The non-magnetic fractions from the first passes were fed through the Eriez L-4-20 for second passes. After the second passes, the Eriez L-4-20 was de-energized and the magnetic fractions were collected with a water flush. A water flush was also used in between the first passes and the second passes (while the Eriez L-4-20 was energized) to ensure that any entrained non-magnetic particles were removed from the first pass magnetic fraction.
The results are reported in Tables 3 and 4 and Figures 13-20.
Table 3 Element weight percentage concentration and percentage increase/decrease relative to feed Mag Feed Sample Field Li +/- Li Co +/- Co Mn +/- Mn Fe +/- Fe Fraction Intensity Feed -- 7.00 -- 25.30 -- 42.00 -- -- --Mag , 90% , 5.45 , -22.19 , 12.72 , -49.72 , 59.22 , 41.01 -- . --.
Non-mag 90% 7.13 1.85 45.77 80.92 24.48 -41.72 -- --LiMn204 Feed -- 7.00 -- 25.30 -- 42.00 -- -- --Mag 60% 5.43 -28.87 15.25 -65.86 53.83 21.97 ----LiCo02 Non-mag 60% 7.65 9.24 57.30 126.48 16.77 -60.08 -- --Feed -- 7.00 -- 25.30 -- 42.00 -- -- --Mag 30% 5.60 -20.01 15.78 -37.62 56.11 33.59 Non-mag 30% 6.30 -10.01 38.85 53.54 23.60 -43.81 --, -- , Feed -- 6.45 -- 45.81 -- -- -- 8.46 --Mag 90% 7.26 12.65 44.88 -2.04 -- -- 16.15 90.74 Non-mag 90% 8.51 32.00 67.93 48.28 -- -- 5.63 , -33.48 , LiFcPO4 Feed 6.45 45.81 8.46 + Mag 60% 7.26 12.65 47.29 3.77 -- -- 13.77 62.71 LiCo02 Non-mag 60% 8.51 32.00 66.13 44.35 -- -- 5.53 -34.66 Feed -- 6.45 -- 45.81 -- -- -- 8.46 --Mag 30% 7.41 14.89 46.10 0.63 -- -- 15.46 82.60 Non-mag 30% 8.47 31.39 63.16 37.87 -- -- 6.15 -27.35 Table 4 Recovery (weight percentage) Feed Sample Fraction Mag Field Intensity Lilin204 LiCo02 LiFePO4 Feed -- 100.00 100.00 100.00 Mag 90% 74.43 25.06 --Non-mag 90% 7.45 74.94 --LiMn204 Feed -- 100.00 100.00 100.00 + Mag 60% 83.79 30.01 --LiCo02 Non-mag 60% 7.39 69.99 --Feed -- 100.00 100.00 100.00 Mag 30% 70.34 28.84 --Non-mag 30% 7.92 71.16 --Feed -- 100.00 100.00 100.00 Mag 90% -- 29.22 64.19 Non-mag 90% -- 70.78 35.81 LiFePO4 Feed -- 100.00 100.00 100.00 + Mag 60% -- 35.82 66.03 LiCo02 Non-mag 60% -- 64.18 33.97 Feed -- 100.00 100.00 100.00 Mag 30% -- 20.55 47.11 Non-mag 30% -- 79.45 52.89
Example-3: Battery electrode active material test separation
The anode comprised graphite on a copper current collecting plate. The electrolyte comprised an ethylene-carbonate based carrier fluid, which evaporated during disassembly.
The anodes and cathodes were peeled from the separator sheets, cut from the electrical leads, removed, and stored in separate containers.
Table 5 WHOLE (Average Values) Mass Dimensions (in) keigM VN,h .. aspth Pouch 491 8.5 5.4 0.55 DISASSEMBLED
xl Approx. # of Sheets Mass Proportion Dimensions On) Sheet per pouch*
HsiEht Anode 202.0 41.1% 7.025 5.875 9.5 21 Cathode 175_5 35.7% 7.75 5.875 5.7 25 Pouch and Separator 54.3 11.1%
Eiectrolyte Amnt Ca icd 5,2 12,1%
Cale Sum 451.0 100:0%
'Based on kkre-Plit
solids content slurry. The slurry was magnetically separated using the Eriez L-4-20 operating at 30%, 60%, and 90% of maximum magnetic field intensity (approximately 0.6 Tesla, 1.2 Tesla, and 1.8 Testa, respectively). A #18 gauge medium grid expanded metal mesh was used as the magnetic flux converging matrix for the test separation. The test separation was designed to sequentially separate the strongest to weakest magnetically susceptible particles.
In this manner, ferromagnetic materials would not obstruct the mesh and/or entrain non-magnetic particles in the magnetic fraction.
magnetic field intensity to pin any ferromagnetic and strongly paramagnetic particles to the magnetic flux converging matrix, thereby separating the magnetized particles from the slurry using the magnetic force between the magnetized particles and an active magnetic surface in contact with the slurry. The non-magnetic fraction passed through the separation box and was collected in a container. After thoroughly rinsing the pinned magnetic fraction with excess water, the collection container was changed, the coils de-energized, and the magnetic field removed. The pinned magnetic fraction captured by the 30% intensity field was washed out of the magnetic flux converging matrix and separation box with de-ionized water and the first magnetic fraction was saved for further analysis.
field intensity) pass was fed through the magnetic separator operating at 60%
magnetic field intensity, which resulted in a second magnetic fraction and a second non-magnetic fraction.
Again, in like manner, the non-magnetic fraction from the second (60% field intensity) pass was fed through the magnetic separator operating at 90% magnetic field intensity, which resulted in a third magnetic fraction and a third non-magnetic fraction.
Accordingly, the test separation produced a total of four test fractions: three magnetic fractions corresponding to 30%, 60%, and 90% field intensity, respectively, and a non-magnetic fraction corresponding to the third non-magnetic fraction that passed through the separator at 90%
field intensity.
The weight percentage recovery and concentration of the lithium, iron, phosphorus, and carbon was calculated for the four test fractions. The results are reported in Tables 6-8 and Figures 21-25 and showed a staged or cumulative separation and concentration of the anode and cathode active materials.
Table 6 Sample # Description Weight Amount Concentrations [wt%]
grams wt% Al Cu Fe Li P C
Anode: Cu-822 26.8 28.5 0.35 0.64 0.09 0.00 0.77 100.00 Carbon Cathode: Al -823 67.2 71.5 0.36 0.14 34.08 2.37 16.96 7.04 LiFePO4 Mixed Feed 94 100.0 0.36 0.28 24.39 1.70 12.34 33.54 824 30% Magnetic 9.2 9.82 0.34 0.17 34.64 2.70 17.41 7.80 825 60% Magnetic 18.3 19.53 0.44 0.18 30.28 1.99 15.26 8.37 826 90% Magnetic 25.8 27.53 0.47 0.18 34.20 2.52 17.10 10.59 827 Non-Magnetic 40.4 43.12 0.68 0.35 13.63 1.10 7.48 65.04 Calculated 93.7 100.00 0.54 0.25 24.61 1.82 12.62 33.36 Mixed Feed Table 7 Sample # Description Weight Amount Cumulative Amount [grams]
grams wt% Al Cu Fe Li P C
Anode: Cu -822 26.8 28.5 0.095 0.172 0.025 0.000 0.207 26.800 Carbon Cathode: Al -823 67.2 71.5 0.239 0.092 22.903 1.594 11.396 4.731 LiFePO4 Mixed Feed 94 100.0 0.334 0.264 22.928 1.594 11.602 31.531 824 30% Magnetic 9.2 9.82 0.031 0.015 3.187 0.249 1.602 0.717 825 60% Magnetic 18.3 19.53 0.111 0.048 8.729 0.613 4.394 2.250 826 90% Magnetic 25.8 27.53 0.233 0.093 17.552 1.262 8.807 4.983 827 Non-Magnetic 40.4 43.12 0.276 0.141 5.507 0.445 3.021 26.275 Calculated 93.7 100.00 0.510 0.234 23.059 1.708 11.827 31.258 Mixed Feed Table 8 Sample # Description Weight Amount Recovery [Wo]
-- grams wt% Al Cu Fe Li P C
Anode: Cu -822 26.8 28.5 -- -- -- -- -- --Carbon Cathode: Al - 67.2 71.5 -- -- -- -- -- --LiFePO4 Mixed Feed 94 100.0 152.72 88.88 100.57 107.13 101.94 99.13 824 30% Magnetic 9.2 9.82 9.30 5.78 13.90 15.59 13.80 2.28 825 60% Magnetic 18.3 19.53 33.25 18.06 38.07 38.48 37.87 7.14 826 90% Magnetic 25.8 27.53 69.89 35.32 76.55 79.19 75.90 15.80 827 Non-Magnetic 40.4 43.12 82.83 53.56 24.02 27.94 26.04 83.33 Calculated 93.7 100.00 100.00 100.00 100.00 100.00 100.00 100.00 Mixed Feed -- 30% Magnetic -- -- 6.09 6.50 13.82 14.55 13.54 2.30 -- 60% Magnetic -- -- 21.77 20.31 37.85 35.92 37.15 7.20 -- 90% Magnetic -- -- 45.77 39.74 76.12 73.92 74.46 15.94 -- Non-Magnetic -- --54.23 60.26 23.88 26.08 25.54 84.06
based on mass of phosphorus. Analogous recovery and concentration percentages were also observed based on the masses of lithium and iron.
Example-4: Lithium-ion electrochemical cell recycle processes
Example-5: Mixed secondary battery recycle process
The process and system 400 may also be modified, for example, to comprise various additional unit operations as described above, such as, for example, electrical discharge operations (e.g., resistive loading or soaking in an aqueous or non-aqueous salt solution, a preliminary magnetic separation operation to remove ferromagnetic and very highly paramagnetic materials such as, for example, steel casing and housing materials, a froth floatation treatment to remove lead and lead compounds from the black mass, and an ultrasonic dispersion operation to break-up particle agglomerates and further refine the particle size when forming black mass slurry.
*****
In comparison to hydrometallurgy, the cost savings can be found in the fact that the process and systems described in this specification do not require chemical extraction/leachant solutions and precipitation, deposition, or electrowinning operations. In comparison to pyrometallurgy, lower costs are realized by avoiding the use of energy intensive smelting operations to reduce the material to its base metals. In contrast to both hydrometallurgy and pyrometallurgy processes, the processes and systems described in this specification directly produce recycled electrode active material that can be directly re-used in new electrochemical cell manufacturing.
Claims (33)
comminuting electrochemical cells, the electrochemical cells comprising lithium-ion electrochemical cells;
screening the comminuted electrochemical cells to separate electrode active material particles from other electrochemical cell components, the electrode active material particles comprising two or more lithium metal compounds;
mixing the electrode active material particles with a carrier fluid to form a slurry;
subjecting the slurry to a magnetic field of sufficient magnetic field intensity to magnetize paramagnetic particles in the slurry;
separating the two or more lithium metal compounds from graphite and collecting a graphite concentrate;
separating the magnetized particles from the slurry using magnetic force induced between the magnetized particles and an active magnetic surface in contact with the slurry, the separated particles comprising one of the two or more lithium metal compounds; and collecting at least one of the two or more lithium metal compounds as separated electrode active material concentrates.
LiM x N z wherein M is one or more metals selected from the group consisting of Co, Mn, Ni, Fe, and Al, wherein N is an inorganic counter ion selected from the group consisting of O2 2- and PO4 3, wherein x ranges from greater than zero to two, and wherein z ranges from one to five.
LiNi1-y Coy O2 wherein y ranges from zero to 1.
removing electrode active materials from electrochemical cells, the electrochemical cells comprising lithium ion batteries;
forming a slurry comprising electrode active material particles, the particles comprising at least one lithium metal compound;
subjecting the slurry to a magnetic field of sufficient magnetic field intensity to magnetize particles in the slurry;
separating the at least one lithium metal compound from graphite and collecting a graphite concentrate; and separating the magnetized particles from the slurry using magnetic force induced between the magnetized particles and an active magnetic surface in contact with the slurry.
subjecting a slurry comprising electrode active lithium compound particles to a magnetic field of sufficient magnetic field strength to magnetize paramagnetic particles in the slurry;
separating the lithium compound particles from graphite and collecting a graphite concentrate; and separating the magnetized particles from the slurry using magnetic force between the magnetized particles and an active magnetic surface in contact with the slurry.
a plurality of magnetic separators connected in series, wherein each successive magnetic separator comprises a higher magnetic field intensity or a higher magnetic field gradient, and wherein each successive magnetic separator separates an electrode active lithium compounds comprising a lower magnetic susceptibility value from a slurry comprising graphite and collects a graphite concentrate.
a plurality of magnetic separators connected in series, wherein each successive magnetic separator comprises a lower magnetic field intensity or a lower magnetic field gradient, and wherein each successive magnetic separator separates ail electrode active lithium compounds comprising a higher magnetic susceptibility value from a slurry comprising graphite and collects a graphite concentrate.
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| US13/435,143 US9156038B2 (en) | 2012-03-30 | 2012-03-30 | Magnetic separation of electrochemical cell materials |
| PCT/US2013/034056 WO2013148809A1 (en) | 2012-03-30 | 2013-03-27 | Magnetic separation of electrochemical cell materials |
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| CA2869154A1 (en) | 2013-10-03 |
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| US20240198357A1 (en) | 2024-06-20 |
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| US10046334B2 (en) | 2018-08-14 |
| JP2015516653A (en) | 2015-06-11 |
| MX2014011735A (en) | 2015-01-22 |
| CN104394995A (en) | 2015-03-04 |
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