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CN111994925A - Comprehensive utilization method of valuable resources in waste lithium batteries - Google Patents

Comprehensive utilization method of valuable resources in waste lithium batteries Download PDF

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Publication number
CN111994925A
CN111994925A CN202010882725.3A CN202010882725A CN111994925A CN 111994925 A CN111994925 A CN 111994925A CN 202010882725 A CN202010882725 A CN 202010882725A CN 111994925 A CN111994925 A CN 111994925A
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lithium
magnesium
manganese
leaching
nickel
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董雄文
彭天剑
姚金华
李军旗
苏向东
陈肖虎
杨恒
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Hunan Xinda New Materials Co ltd
Guizhou Dalong Huicheng New Material Co ltd
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Hunan Xinda New Materials Co ltd
Guizhou Dalong Huicheng New Material Co ltd
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    • CCHEMISTRY; METALLURGY
    • C01INORGANIC CHEMISTRY
    • C01DCOMPOUNDS OF ALKALI METALS, i.e. LITHIUM, SODIUM, POTASSIUM, RUBIDIUM, CAESIUM, OR FRANCIUM
    • C01D15/00Lithium compounds
    • C01D15/08Carbonates; Bicarbonates
    • CCHEMISTRY; METALLURGY
    • C01INORGANIC CHEMISTRY
    • C01GCOMPOUNDS CONTAINING METALS NOT COVERED BY SUBCLASSES C01D OR C01F
    • C01G53/00Compounds of nickel
    • C01G53/006Compounds containing, besides nickel, two or more other elements, with the exception of oxygen or hydrogen
    • CCHEMISTRY; METALLURGY
    • C01INORGANIC CHEMISTRY
    • C01GCOMPOUNDS CONTAINING METALS NOT COVERED BY SUBCLASSES C01D OR C01F
    • C01G53/00Compounds of nickel
    • C01G53/04Oxides; Hydroxides
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01MPROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
    • H01M10/00Secondary cells; Manufacture thereof
    • H01M10/54Reclaiming serviceable parts of waste accumulators
    • CCHEMISTRY; METALLURGY
    • C01INORGANIC CHEMISTRY
    • C01PINDEXING SCHEME RELATING TO STRUCTURAL AND PHYSICAL ASPECTS OF SOLID INORGANIC COMPOUNDS
    • C01P2006/00Physical properties of inorganic compounds
    • C01P2006/80Compositional purity
    • YGENERAL 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
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02WCLIMATE CHANGE MITIGATION TECHNOLOGIES RELATED TO WASTEWATER TREATMENT OR WASTE MANAGEMENT
    • Y02W30/00Technologies for solid waste management
    • Y02W30/50Reuse, recycling or recovery technologies
    • Y02W30/84Recycling of batteries or fuel cells

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  • Organic Chemistry (AREA)
  • Engineering & Computer Science (AREA)
  • Inorganic Chemistry (AREA)
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  • Electrochemistry (AREA)
  • General Chemical & Material Sciences (AREA)
  • Manufacture And Refinement Of Metals (AREA)

Abstract

The invention discloses a comprehensive utilization method of valuable resources in waste lithium batteries, which relates to the technical field of lithium battery recovery, and comprises the following steps: the method comprises the following steps of pretreatment, acid leaching, aluminum and iron removal, copper removal, calcium, magnesium and lithium removal, ternary precursor preparation, chlorination, iron removal, magnesium and calcium removal and lithium precipitation, wherein in the calcium, magnesium and lithium removal step, sodium fluoride is added, so that the purposes of calcium removal, magnesium removal and lithium removal can be achieved, and the separation of lithium ions from cobalt, nickel and manganese ions is realized; the method can be used for preparing pure ternary precursor and battery-grade lithium carbonate, has low cost and simple process, and is suitable for industrial production.

Description

Comprehensive utilization method of valuable resources in waste lithium batteries
Technical Field
The invention relates to the technical field of lithium battery recovery, in particular to a comprehensive utilization method of valuable resources in waste lithium batteries.
Background
Metal elements such as cobalt, manganese, nickel, lithium, etc. are widely used in the field of lithium batteries. Particularly, cobalt is an important strategic metal, but the cobalt mineral resources in China are seriously deficient, the consumption of the cobalt is increased year by year, and most of cobalt raw materials depend on import. The content of cobalt, nickel, manganese and lithium in the anode material of the waste lithium battery is relatively high, and the recovery value is high.
With the rapid development of the new energy automobile industry, the yield of the ternary lithium battery shows a rapid increase trend, the recycling of the waste lithium battery is a research hotspot, a wet recovery technology is mainly adopted at present, in the wet recovery technology, the waste lithium battery is subjected to the procedures of discharging disassembly, crushing and screening, acid leaching, purification and impurity removal and the like to obtain a mixed solution containing cobalt, nickel, manganese and lithium, and the mixed solution contains a large amount of impurity ions such as iron, magnesium, calcium, aluminum, copper and the like, so that the separation difficulty of cobalt, nickel, manganese and lithium elements is large, and the quality of the obtained product is low.
In the prior art, an ion exchange membrane is often adopted to separate solution ions, but the ion exchange membrane has the defects of poor mechanical property, low separation efficiency, easy pollution of an outer membrane and the like, and the defects cause the reduction of the service performance, the shortening of the service life and the high production cost of the ion exchange membrane. Therefore, how to recover valuable resources in the waste lithium batteries and improve the quality of products becomes a problem which needs to be solved urgently.
Disclosure of Invention
Aiming at the technical problems that in the prior art, a mixed solution containing cobalt, nickel, manganese and lithium contains a large amount of impurity ions such as iron, magnesium, calcium, aluminum and copper, so that the separation difficulty of cobalt, nickel, manganese and lithium elements is high and the quality of the obtained product is low, the invention aims to provide a comprehensive utilization method of valuable resources in waste lithium batteries with low cost and simple process, and pure ternary precursors and battery-grade lithium carbonate can be prepared by the method.
In order to achieve the purpose, the invention provides the following technical scheme:
the invention provides a comprehensive utilization method of valuable resources in waste lithium batteries, which comprises the following steps:
the method comprises the following steps of pretreatment, namely, carrying out acid leaching discharge, water washing, roasting, crushing and screening on waste lithium batteries in sequence, wherein oversize products comprise a steel shell, an aluminum foil and a copper sheet, and undersize products comprise powder containing nickel, cobalt, manganese and lithium;
acid leaching, namely putting powder containing nickel, cobalt, manganese and lithium into a leaching tank, and adding concentrated sulfuric acid and hydrogen peroxide into the leaching tank to perform discontinuous leaching to obtain a mixed solution containing cobalt, nickel, manganese and lithium;
removing aluminum and iron, namely adding sodium carbonate with a set proportion into a mixed solution containing cobalt, nickel, manganese and lithium to react, removing aluminum and iron ions in the solution, and performing solid-liquid separation to obtain a mixed solution after aluminum and iron removal;
a copper removing step, namely adding sodium sulfide in a stoichiometric ratio into the mixed solution after aluminum and iron removal, reacting to generate copper sulfide precipitate, and performing solid-liquid separation to obtain the mixed solution after copper removal;
removing calcium, magnesium and lithium, namely adding sodium fluoride into the mixed solution after copper removal to react to generate calcium fluoride, magnesium fluoride and lithium fluoride sediments, and performing solid-liquid separation to obtain a mixed solution containing cobalt, nickel and manganese;
a step of preparing a ternary precursor, which is to add sodium hydroxide into a mixed solution containing cobalt, nickel and manganese to react to obtain a nickel-cobalt-manganese hydroxide precipitate;
chlorination, namely adding calcium fluoride, magnesium fluoride and lithium fluoride sediments into hydrochloric acid for reaction, and performing solid-liquid separation to obtain a lithium-rich solution;
a step of removing iron, namely, passing the lithium-rich solution through a filter device filled with solid manganese dioxide to remove Fe2+Conversion to Fe3+Converting the lithium-rich solution into hydroxide precipitate, evaporating and concentrating, and carrying out solid-liquid separation to obtain a concentrated lithium-rich solution;
removing magnesium and calcium, namely adding sodium carbonate into the concentrated lithium-rich solution to remove most of magnesium and calcium ions, then adding a mixture of sodium hydroxide and sodium carbonate to further remove the rest of magnesium and calcium ions to obtain the lithium-rich solution after impurity removal;
and a lithium precipitation step, namely adding sodium carbonate into the lithium-rich solution after impurity removal, separating lithium carbonate crystals, carrying out solid-liquid separation, and then carrying out flash evaporation drying to obtain the battery-grade lithium carbonate.
In a preferred embodiment, the pretreatment step specifically comprises:
(1) primary acid leaching discharge: putting the waste lithium battery into dilute sulfuric acid for discharging, wherein the mass concentration of the dilute sulfuric acid is 5-20%, and the discharging time is 2-6 h;
(2) secondary acid leaching discharge: putting the waste lithium battery into dilute sulfuric acid for discharging, wherein the mass concentration of the dilute sulfuric acid is 10% -30%, and the discharging time is 2-6 h;
(3) washing with water: putting the waste lithium battery subjected to acid leaching discharge twice into a washing tank for washing;
(4) roasting: putting the washed waste lithium battery into a steel belt furnace for roasting, introducing the roasted dilute sulfuric acid waste gas into an acid mist absorption tower for treatment, and then discharging;
(5) crushing and screening: crushing the roasted waste lithium battery by a hammer crusher, screening by a vibrating screen after crushing, wherein oversize materials comprise a steel shell, an aluminum foil and a copper sheet, and undersize materials comprise powder containing nickel, cobalt, manganese and lithium.
In the preferable scheme, in the acid leaching step, the reaction temperature is 60-70 ℃, and the solid-to-solid ratio of a leaching solution is 3-4: 1, the concentration of initial sulfuric acid for leaching is 200-240 g/L, the pH value of a leaching end point is 1-2, and the leaching time is 6-10 h.
The powder containing nickel, cobalt, manganese and lithium is leached with concentrated sulfuric acid to form soluble sulfate which enters the solution, and the leaching of nickel, cobalt, manganese and lithium is promoted by adding hydrogen peroxide. The reaction equation mainly involved is as follows:
MeO+H2SO4→MeSO4+H2o (Me is Ni, Co, Mn, Cu, Ca, Mg, Fe, etc.)
2LiCoO2+3H2SO4+H2O2→Li2SO4+2CoSO4+O2↑+4H2O
2LiNiO2+3H2SO4+H2O2→Li2SO4+2NiSO4+O2↑+4H2O
2LiMnO2+3H2SO4+H2O2→Li2SO4+2MnSO4+O2↑+4H2O
2Fe2++H2O2+2H+→2Fe3++2H2O
In the preferable scheme, in the step of removing the aluminum and the iron, high-temperature steam is added, the reaction temperature is controlled to be higher than 90 ℃, and the reaction time is 1-4 hours.
In the step of removing aluminum and iron, sodium carbonate is added into a mixed solution containing cobalt, nickel, manganese and lithium for reaction, the pH value of the solution is controlled to be 4.5, so that aluminum and the sodium carbonate react to generate aluminum slag (aluminum carbonate is decomposed into aluminum hydroxide when meeting water), and Fe3+Hydrolyzing to generate iron hydride precipitate, and after solid-liquid separation by a filter press, the residual materials do not contain aluminum and iron any more, thus achieving the purposes of removing aluminum and iron. The reaction equation mainly involved is as follows:
2Al3++3Na2CO3=Al2(CO3)3+6Na+
Al2(CO3)3+3H2O=2Al(OH)3↓+3CO2
H2SO4+Na2CO3=Na2SO4+H2O+3CO2
Fe3++3H2O→Fe(OH)3↓+3H+
in the step of removing calcium, magnesium and lithium, the purposes of removing calcium, magnesium and lithium can be achieved by adding sodium fluoride, and the separation of lithium ions from cobalt, nickel and manganese ions is realized.
In the preferred scheme, in the chlorination step, hydrochloric acid is added into the calcium fluoride, magnesium fluoride and lithium fluoride sediments for reaction for 1-4 h, and the calcium fluoride and magnesium fluoride sediments do not react with the hydrochloric acid. The reaction equation mainly involved is as follows:
LiF+HCl=LiCl+HF(aq)
in the iron removal step, the manganese dioxide is Fe2+Conversion to Fe3+Good catalyst of (2), Fe produced3+Hydrolysis to Fe (OH)3The precipitate was immediately removed by filtration. The reaction equation mainly involved is as follows:
4H++2Fe2++MnO2→Mn2++2Fe3++2H2O
in the step of removing magnesium and calcium, stoichiometric sodium carbonate is added according to the amount of magnesium and calcium ions in the lithium-rich solution, and the precipitate is filtered after full reaction to remove most of magnesium and calcium ions; and adding a mixture of sodium hydroxide and sodium carbonate to adjust the pH value of the lithium-rich solution to 13, wherein the mass concentration of the sodium hydroxide is 10-20%, the mass concentration of the sodium carbonate is 40-60%, and further removing the residual magnesium and calcium ions. The reaction equation mainly involved is as follows:
CO3 2-+Ca2+→CaCO3
CO3 2-+Mg2+→MgCO3
2OH-+Mg2+→Mg(OH)2
due to LiCO3Solubility product KSPIs 8.15 multiplied by 10-4,CaCO3Solubility product of KSPIs 3.36 multiplied by 10-9,MgCO3Solubility product of KSPIs 6.82X 10-6Therefore, stoichiometric sodium carbonate is added into the lithium-rich solution, and no lithium carbonate is separated out; due to Mg (OH)2Solubility product of KSPIs 1.8X 10-11Thus adding sodium hydroxideDeeply removing magnesium ions.
In the preferable scheme, in the step of lithium precipitation, sodium carbonate is added into the lithium-rich solution after impurity removal, the reaction temperature is 45-60 ℃, and the reaction time is 1-4 h. The reaction equation mainly involved is as follows:
2LiCl+2NaCO3+2HF→Li2CO3↓+NaF+HCl+CO2
the preferable scheme comprises a flash evaporation drying step, wherein flash evaporation drying is carried out after lithium carbonate crystallization and filtration, the crystallization temperature of lithium carbonate is higher than 100 ℃, finally a lithium carbonate product is obtained, and the filtrate is sent to a sewage treatment station for treatment.
Compared with the prior art, the invention has the beneficial technical effects that:
the invention provides a comprehensive utilization method of valuable resources in waste lithium batteries, which can be used for preparing pure ternary precursors and battery-grade lithium carbonate, and is low in cost, simple in process and suitable for industrial production.
Drawings
In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings needed to be used in the description of the embodiments are briefly introduced below, and it is obvious that the drawings in the following description are some embodiments of the present invention, and it is obvious for those skilled in the art to obtain other drawings based on these drawings without creative efforts.
Fig. 1 is a process flow chart of the comprehensive utilization method of valuable resources in the waste lithium battery.
Detailed Description
The technical solutions in the embodiments of the present invention will be clearly and completely described below, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, rather than all embodiments, and all other embodiments obtained by those skilled in the art without any creative work based on the embodiments of the present invention belong to the protection scope of the present invention.
The experimental procedures described in the following examples are conventional unless otherwise specified, and the reagents and materials described therein are commercially available without further specification.
Example 1
The embodiment is a comprehensive utilization method of valuable resources in waste lithium batteries, and is characterized by comprising the following steps:
(1) the method comprises the following steps of sequentially carrying out acid leaching discharging, water washing, roasting, crushing and screening on a waste ternary nickel-cobalt-manganese 18650 lithium battery, wherein oversize products are a steel shell, an aluminum foil and a copper sheet, and undersize products are powder containing nickel-cobalt-manganese-lithium, and specifically comprises the following steps:
(1.1) primary acid leaching discharge: a monorail crane is used for throwing the titanium basket provided with the waste lithium battery into a dilute acid soaking pool (4 m) with the dilute sulfuric acid concentration of about 8 percent3) Acid leaching discharging for about 4 hours;
(1.2) secondary acid leaching discharge: a monorail crane is used for throwing the titanium basket provided with the waste lithium battery into a dilute acid soaking pool (4 m) with the dilute sulfuric acid concentration of about 14 percent3) Acid leaching discharging for about 4 hours;
(1.3) water washing: putting the waste lithium battery subjected to acid leaching discharge twice into a washing tank for washing;
(1.4) roasting: putting the washed waste lithium battery into a steel belt furnace for roasting, introducing the roasted dilute sulfuric acid waste gas into an acid mist absorption tower for treatment, and then discharging;
(1.5) crushing and screening: crushing the roasted waste lithium battery by a hammer crusher, and screening by a vibrating screen after crushing, wherein oversize materials are a steel shell, an aluminum foil and a copper sheet, and undersize materials are nickel-cobalt-manganese-lithium-containing powder;
(2) and acid leaching, namely putting the powder containing nickel, cobalt, manganese and lithium into a leaching tank, adding concentrated sulfuric acid and hydrogen peroxide into the leaching tank for intermittent leaching, wherein the reaction temperature is 60-70 ℃, and the solid-to-solid ratio of a leaching solution is 3: 1, leaching initial sulfuric acid concentration of 220g/L, leaching end-point pH value of 1.5, and leaching time of 8 hours to obtain a mixed solution containing cobalt, nickel, manganese and lithium;
(3) removing aluminum and iron, namely adding sodium carbonate into a mixed solution containing cobalt, nickel, manganese and lithium to react, controlling the pH value of the solution to be 4.5, adding 0.5MPa of new steam, controlling the reaction temperature to be more than 90 ℃, reacting for 2 hours, and performing solid-liquid separation to obtain a mixed solution after aluminum and iron removal;
(4) a copper removing step, namely adding sodium sulfide in a stoichiometric ratio into the mixed solution after aluminum and iron removal, reacting to generate copper sulfide precipitate, and performing solid-liquid separation to obtain the mixed solution after copper removal;
(5) removing calcium, magnesium and lithium, namely adding sodium fluoride into the mixed solution after copper removal to react to generate calcium fluoride, magnesium fluoride and lithium fluoride sediments, and performing solid-liquid separation to obtain a mixed solution containing cobalt, nickel and manganese; pure water is used as the slag washing water in the step, and the slag washing water is reused in the aluminum and iron removing process and is not discharged;
(6) a step of preparing a ternary precursor, which is to add sodium hydroxide into a mixed solution containing cobalt, nickel and manganese, react to obtain a nickel-cobalt-manganese hydroxide precipitate which can be directly used as a ternary precursor material;
(7) a chlorination step, namely adding calcium fluoride, magnesium fluoride and lithium fluoride sediments into hydrochloric acid to react for 2 hours, and performing solid-liquid separation to obtain a lithium-rich solution;
(8) a step of removing iron, namely, passing the lithium-rich solution through a filter device filled with solid manganese dioxide to remove Fe2+Conversion to Fe3+Converting the lithium-rich solution into hydroxide precipitate, evaporating and concentrating, and carrying out solid-liquid separation to obtain a concentrated lithium-rich solution;
(9) removing magnesium and calcium, namely adding a mixture of sodium hydroxide and sodium carbonate to adjust the pH value of the lithium-rich solution to 13, wherein the mass concentration of the sodium hydroxide is 15% and the mass concentration of the sodium carbonate is 50%, so as to obtain the lithium-rich solution after impurity removal;
(10) and a lithium precipitation step, namely adding sodium carbonate into the lithium-rich solution after impurity removal, reacting at the temperature of 50 ℃ for 2 hours, separating lithium carbonate crystals, carrying out solid-liquid separation, and then carrying out flash evaporation drying to obtain the battery-grade lithium carbonate.
In the lithium carbonate product obtained in example 1, the purity of the lithium carbonate product was 99.8 wt%, the content of magnesium was 0.004 wt%, the content of calcium was 0.002 wt%, the content of iron was 0.0006 wt%, the content of copper was 0.0002 wt%, and the content of aluminum was 0.0006 wt%.
Example 2
The embodiment is a comprehensive utilization method of valuable resources in waste lithium batteries, and is characterized by comprising the following steps:
(1) the method comprises the following steps of sequentially carrying out acid leaching discharging, water washing, roasting, crushing and screening on a waste ternary nickel-cobalt-manganese 18650 lithium battery, wherein oversize products are a steel shell, an aluminum foil and a copper sheet, and undersize products are powder containing nickel-cobalt-manganese-lithium, and specifically comprises the following steps:
(1.1) primary acid leaching discharge: a monorail crane is used for throwing the titanium basket provided with the waste lithium battery into a dilute acid soaking pool (4 m) with the dilute sulfuric acid concentration of about 6 percent3) Acid leaching discharging for about 5 hours;
(1.2) secondary acid leaching discharge: a monorail crane is used for throwing the titanium basket provided with the waste lithium battery into a dilute acid soaking pool (4 m) with the dilute sulfuric acid concentration of about 20 percent3) Acid leaching discharging for about 3 hours;
(1.3) water washing: putting the waste lithium battery subjected to acid leaching discharge twice into a washing tank for washing;
(1.4) roasting: putting the washed waste lithium battery into a steel belt furnace for roasting, introducing the roasted dilute sulfuric acid waste gas into an acid mist absorption tower for treatment, and then discharging;
(1.5) crushing and screening: crushing the roasted waste lithium battery by a hammer crusher, and screening by a vibrating screen after crushing, wherein oversize materials are a steel shell, an aluminum foil and a copper sheet, and undersize materials are nickel-cobalt-manganese-lithium-containing powder;
(2) and acid leaching, namely putting the powder containing nickel, cobalt, manganese and lithium into a leaching tank, adding concentrated sulfuric acid and hydrogen peroxide into the leaching tank for intermittent leaching, wherein the reaction temperature is 60-70 ℃, and the solid-to-solid ratio of a leaching solution is 4: 1, leaching initial sulfuric acid concentration of 240g/L, leaching end-point pH value of 1.5, and leaching time of 6h to obtain a mixed solution containing cobalt, nickel, manganese and lithium;
(3) removing aluminum and iron, namely adding sodium carbonate into a mixed solution containing cobalt, nickel, manganese and lithium to react, controlling the pH value of the solution to be 4.5, adding 0.5MPa of new steam, controlling the reaction temperature to be more than 90 ℃, reacting for 3 hours, and performing solid-liquid separation to obtain a mixed solution after aluminum and iron removal;
(4) a copper removing step, namely adding sodium sulfide in a stoichiometric ratio into the mixed solution after aluminum and iron removal, reacting to generate copper sulfide precipitate, and performing solid-liquid separation to obtain the mixed solution after copper removal;
(5) removing calcium, magnesium and lithium, namely adding sodium fluoride into the mixed solution after copper removal to react to generate calcium fluoride, magnesium fluoride and lithium fluoride sediments, and performing solid-liquid separation to obtain a mixed solution containing cobalt, nickel and manganese; pure water is used as the slag washing water in the step, and the slag washing water is reused in the aluminum and iron removing process and is not discharged;
(6) a step of preparing a ternary precursor, which is to add sodium hydroxide into a mixed solution containing cobalt, nickel and manganese, react to obtain a nickel-cobalt-manganese hydroxide precipitate which can be directly used as a ternary precursor material;
(7) a chlorination step, namely adding calcium fluoride, magnesium fluoride and lithium fluoride sediments into hydrochloric acid to react for 2 hours, and performing solid-liquid separation to obtain a lithium-rich solution;
(8) a step of removing iron, namely, passing the lithium-rich solution through a filter device filled with solid manganese dioxide to remove Fe2+Conversion to Fe3+Converting the lithium-rich solution into hydroxide precipitate, evaporating and concentrating, and carrying out solid-liquid separation to obtain a concentrated lithium-rich solution;
(9) removing magnesium and calcium, namely adding a mixture of sodium hydroxide and sodium carbonate to adjust the pH value of the lithium-rich solution to 13, wherein the mass concentration of the sodium hydroxide is 15% and the mass concentration of the sodium carbonate is 45%, so as to obtain the lithium-rich solution after impurity removal;
(10) and a lithium precipitation step, namely adding sodium carbonate into the lithium-rich solution after impurity removal, reacting at the temperature of 50 ℃ for 2 hours, separating lithium carbonate crystals, carrying out solid-liquid separation, and then carrying out flash evaporation drying to obtain the battery-grade lithium carbonate.
In the lithium carbonate product obtained in example 2, the purity of the lithium carbonate product was 99.7 wt%, the magnesium content was 0.005 wt%, the calcium content was 0.003 wt%, the iron content was 0.0008 wt%, the copper content was 0.0003 wt%, and the aluminum content was 0.0005 wt%.
The above description is only a preferred embodiment of the present invention, and the protection scope of the present invention is not limited to the above-described embodiments. Modifications and variations that may occur to those skilled in the art without departing from the spirit and scope of the invention are to be considered as within the scope of the invention.

Claims (10)

1. A comprehensive utilization method of valuable resources in waste lithium batteries is characterized by comprising the following steps:
the method comprises the following steps of pretreatment, namely, carrying out acid leaching discharge, water washing, roasting, crushing and screening on waste lithium batteries in sequence, wherein oversize products comprise a steel shell, an aluminum foil and a copper sheet, and undersize products comprise powder containing nickel, cobalt, manganese and lithium;
acid leaching, namely putting powder containing nickel, cobalt, manganese and lithium into a leaching tank, and adding concentrated sulfuric acid and hydrogen peroxide into the leaching tank to perform discontinuous leaching to obtain a mixed solution containing cobalt, nickel, manganese and lithium;
removing aluminum and iron, namely adding sodium carbonate with a set proportion into a mixed solution containing cobalt, nickel, manganese and lithium to react, removing aluminum and iron ions in the solution, and performing solid-liquid separation to obtain a mixed solution after aluminum and iron removal;
a copper removing step, namely adding sodium sulfide in a stoichiometric ratio into the mixed solution after aluminum and iron removal, reacting to generate copper sulfide precipitate, and performing solid-liquid separation to obtain the mixed solution after copper removal;
removing calcium, magnesium and lithium, namely adding sodium fluoride into the mixed solution after copper removal to react to generate calcium fluoride, magnesium fluoride and lithium fluoride sediments, and performing solid-liquid separation to obtain a mixed solution containing cobalt, nickel and manganese;
a step of preparing a ternary precursor, which is to add sodium hydroxide into a mixed solution containing cobalt, nickel and manganese to react to obtain a nickel-cobalt-manganese hydroxide precipitate;
chlorination, namely adding calcium fluoride, magnesium fluoride and lithium fluoride sediments into hydrochloric acid for reaction, and performing solid-liquid separation to obtain a lithium-rich solution;
a step of removing iron, namely, passing the lithium-rich solution through a filter device filled with solid manganese dioxide to remove Fe2+Conversion to Fe3+Converting the lithium-rich solution into hydroxide precipitate, evaporating and concentrating, and carrying out solid-liquid separation to obtain a concentrated lithium-rich solution;
removing magnesium and calcium, namely adding sodium carbonate into the concentrated lithium-rich solution to remove most of magnesium and calcium ions, then adding a mixture of sodium hydroxide and sodium carbonate to further remove the rest of magnesium and calcium ions to obtain the lithium-rich solution after impurity removal;
and a lithium precipitation step, namely adding sodium carbonate into the lithium-rich solution after impurity removal, separating lithium carbonate crystals, carrying out solid-liquid separation, and then carrying out flash evaporation drying to obtain the battery-grade lithium carbonate.
2. The method for comprehensively utilizing valuable resources in the waste lithium batteries as claimed in claim 1, wherein the pretreatment step specifically comprises:
(1) primary acid leaching discharge: putting the waste lithium battery into dilute sulfuric acid for discharging, wherein the mass concentration of the dilute sulfuric acid is 5-20%, and the discharging time is 2-6 h;
(2) secondary acid leaching discharge: putting the waste lithium battery into dilute sulfuric acid for discharging, wherein the mass concentration of the dilute sulfuric acid is 10% -30%, and the discharging time is 2-6 h;
(3) washing with water: putting the waste lithium battery subjected to acid leaching discharge twice into a washing tank for washing;
(4) roasting: putting the washed waste lithium battery into a steel belt furnace for roasting, introducing the roasted dilute sulfuric acid waste gas into an acid mist absorption tower for treatment, and then discharging;
(5) crushing and screening: crushing the roasted waste lithium battery by a hammer crusher, screening by a vibrating screen after crushing, wherein oversize materials comprise a steel shell, an aluminum foil and a copper sheet, and undersize materials comprise powder containing nickel, cobalt, manganese and lithium.
3. The method for comprehensively utilizing valuable resources in the waste lithium batteries according to claim 1, wherein in the acid leaching step, the reaction temperature is 60-70 ℃, and the solid-to-solid ratio of a leaching solution is 3-4: 1, the concentration of initial sulfuric acid for leaching is 200-240 g/L, the pH value of a leaching end point is 1-2, and the leaching time is 6-10 h.
4. The method for comprehensively utilizing valuable resources in the waste lithium batteries as claimed in claim 1, wherein in the step of removing aluminum and iron, high-temperature steam is added, the reaction temperature is controlled to be more than 90 ℃, and the reaction time is 1-4 h.
5. The method for comprehensively utilizing valuable resources in the waste lithium batteries as claimed in claim 1, wherein in the chlorination step, calcium fluoride, magnesium fluoride and lithium fluoride sediments are added into hydrochloric acid for reaction for 1-4 h.
6. The method for comprehensively utilizing valuable resources in the waste lithium batteries as claimed in claim 1, wherein in the step of removing magnesium and calcium, stoichiometric sodium carbonate is added according to the amount of magnesium and calcium ions in the lithium-rich solution, and after full reaction, the precipitate is filtered out to remove most of the magnesium and calcium ions; and adding a mixture of sodium hydroxide and sodium carbonate to adjust the pH value of the lithium-rich solution to 13, wherein the mass concentration of the sodium hydroxide is 10-20%, and the mass concentration of the sodium carbonate is 40-60%.
7. The comprehensive utilization method of valuable resources in the waste lithium batteries as claimed in claim 1, wherein in the step of depositing lithium, the reaction temperature is 45-60 ℃ and the reaction time is 1-4 h.
8. The method for comprehensively utilizing valuable resources in the waste lithium batteries as claimed in claim 1, wherein flash evaporation drying is performed after lithium carbonate crystallization and filtration, the crystallization temperature of lithium carbonate is greater than 100 ℃, finally a lithium carbonate product is obtained, and the filtrate is sent to a sewage treatment station for treatment.
9. A nickel cobalt manganese hydroxide product obtainable by the process of any one of claims 1 to 8.
10. A battery grade lithium carbonate product, characterised in that it is produced by the process of any one of claims 1 to 8.
CN202010882725.3A 2020-08-28 2020-08-28 Comprehensive utilization method of valuable resources in waste lithium batteries Pending CN111994925A (en)

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