CN107437626B - Method for preparing carbon-coated manganese phosphate from waste zinc-manganese battery - Google Patents

Method for preparing carbon-coated manganese phosphate from waste zinc-manganese battery Download PDF

Info

Publication number
CN107437626B
CN107437626B CN201710635745.9A CN201710635745A CN107437626B CN 107437626 B CN107437626 B CN 107437626B CN 201710635745 A CN201710635745 A CN 201710635745A CN 107437626 B CN107437626 B CN 107437626B
Authority
CN
China
Prior art keywords
manganese
solution
filtrate
acid
washing
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Active
Application number
CN201710635745.9A
Other languages
Chinese (zh)
Other versions
CN107437626A (en
Inventor
蒋央芳
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Individual
Original Assignee
Individual
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Individual filed Critical Individual
Priority to CN201710635745.9A priority Critical patent/CN107437626B/en
Publication of CN107437626A publication Critical patent/CN107437626A/en
Application granted granted Critical
Publication of CN107437626B publication Critical patent/CN107437626B/en
Active legal-status Critical Current
Anticipated expiration legal-status Critical

Links

Classifications

    • 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

Landscapes

  • Chemical & Material Sciences (AREA)
  • General Chemical & Material Sciences (AREA)
  • Electrochemistry (AREA)
  • Chemical Kinetics & Catalysis (AREA)
  • Inorganic Chemistry (AREA)
  • Composite Materials (AREA)
  • Organic Chemistry (AREA)
  • Catalysts (AREA)
  • Manufacturing & Machinery (AREA)
  • Engineering & Computer Science (AREA)
  • Sustainable Development (AREA)
  • Life Sciences & Earth Sciences (AREA)
  • Crystallography & Structural Chemistry (AREA)

Abstract

The invention discloses a method for preparing carbon-coated manganese phosphate from waste zinc-manganese batteries. The method comprises the steps of pretreating, crushing and sorting the waste zinc-manganese batteries to obtain manganese dioxide, purifying and purifying to obtain a pure manganese solution, extracting a saponification solution of di (2, 4-trimethylpentyl) phosphonic acid to obtain di (2, 4-trimethylpentyl) manganese phosphonate, and carrying out high-temperature oxidation catalytic decomposition to obtain the carbon-coated manganese phosphate. The method for preparing the carbon-coated manganese phosphate from the waste zinc-manganese battery realizes the cyclic utilization and high-end utilization of the waste zinc-manganese battery, recovers zinc in the waste zinc-manganese battery, has simple process and small waste water production amount, and the obtained manganese phosphate is the carbon-coated manganese phosphate, has low impurity content, is of a spherical structure, has high tap density and narrow particle size distribution, and can regulate and control the carbon content.

Description

Method for preparing carbon-coated manganese phosphate from waste zinc-manganese battery
Technical Field
The invention relates to a method for preparing carbon-coated manganese phosphate from waste zinc-manganese batteries, belonging to the field of new energy battery materials.
Background
The theoretical specific capacity of the lithium iron phosphate is 170mAh/g, the discharge platform is 3.4V, and the energy density of the material is 578Wh/kg; the theoretical specific capacity of the lithium manganese phosphate is 171mAh/g, the discharge platform is 4.1V, and the energy density of the material is 701Wh/kg, which is 21 percent higher than that of the material.
The lithium manganese iron phosphate has the same capacity as lithium iron phosphate theoretically, and is 170mAh/g, but the electrode potential of the lithium manganese iron phosphate relative to Li < + >/Li is 4.1V, which is much higher than 3.4V of the lithium iron phosphate, and the lithium manganese iron phosphate is positioned in a stable electrochemical window of an organic electrolyte system. The high potential of 4.1V provides the manganese lithium phosphate with the potential advantage of high energy density, which is the greatest advantage over lithium iron phosphate, and if the actual capacity of the manganese lithium phosphate is exerted to the same extent as that of the lithium iron phosphate, the energy density of the manganese lithium phosphate is increased by 35% as compared with that of the current lithium iron phosphate, and the energy density of the manganese lithium phosphate can be increased by more than 20% as compared with that of the lithium manganese phosphate with the same voltage. In addition, the lithium manganese phosphate has low raw material cost and is environment-friendly, so the battery and the material have wide market prospect.
As a precursor of lithium iron manganese phosphate or lithium manganese phosphate, manganese dioxide or the like is generally used, but manganese phosphate has received increasing attention as a precursor thereof. And the carbon-coated manganese phosphate has better conductivity, so that the prepared anode material has better performance.
Disclosure of Invention
In view of this, it is preferable that,the invention provides a method for preparing carbon-coated manganese phosphate from waste zinc-manganese batteries, which takes the waste zinc-manganese batteries as raw materials, realizes the cyclic utilization and high-end utilization of the waste zinc-manganese batteries, simultaneously recovers zinc in the waste zinc-manganese batteries, has simple process and less wastewater generation amount, obtains the manganese phosphate which is carbon-coated manganese phosphate, has low impurity content, spherical structure and high tap density, and has the specific surface of 10-15m 2 The grain diameter distribution is narrow, and the carbon content can be adjusted and controlled.
The invention solves the technical problems by the following technical means:
the invention discloses a method for preparing carbon-coated manganese phosphate from waste zinc-manganese batteries, which comprises the following steps:
(1) Pretreating, namely crushing the waste zinc-manganese battery until the particle size of the material is 0.1-1mm, sorting the material in integrated equipment of air separation and electrostatic sorting, adding pure water into the obtained black powder material for slurrying, adding sodium hydroxide solution into the slurried material, reacting for 3-4 hours at 90-95 ℃ in a sealed reaction kettle, simultaneously arranging an exhaust pipe, inserting the exhaust pipe into the pure water to obtain an ammonia water solution, after the reaction is finished, filtering and washing to obtain a first filtrate and a first filter residue;
(2) Purifying, adding acid solution into the first filter residue, adding crude manganese powder at the same time, maintaining the pH of the solution at 0.5-1.5, reacting at 70-85 ℃ for 5-6 hours, then continuously adding the crude manganese powder, adjusting the pH of the solution to 5.5-6, then introducing air, completely oxidizing ferrous ions into ferric iron and precipitating, then filtering to obtain second filtrate and second filter residue, adjusting the pH of the second filtrate to 2-2.5, adding ammonium sulfide, reacting at 45-65 ℃ for 2-3 hours, and adding ammonium sulfide with the mole number of Cu in the second filtrate 2+ 、Co 2+ 、Ni 2+ 、Pb 2+ 、Cd 2+ 、Zn 2+ 1.1-1.25 times of the total mole number, filtering to obtain a third filtrate and a third filter residue, mixing the third filtrate with a P507 extractant saponified by ammonia water, performing 5-7 levels of countercurrent extraction, 5-7 levels of countercurrent washing, 5-7 levels of primary countercurrent back extraction, 4-6 levels of secondary countercurrent back extraction and 1-2 levels of countercurrent water washing to obtain raffinate, primary back extraction liquid and secondary back extraction liquid, and P50 of the third filtrate and the saponified by ammonia water7, the volume flow ratio of the extracting agent, the washing liquid, the primary stripping liquid, the secondary stripping liquid and the washing water is (0.5-0.65): 0.2-0.25, washing with 0.5-1mol/L hydrochloric acid, 1-1.5mol/L hydrochloric acid as primary stripping solution, 1.5-2mol/L hydrochloric acid as secondary stripping solution, adding heavy metal scavenger into the primary stripping solution, reacting at pH2.5-3.5 for 2-3 hours, maintaining the temperature at 30-40 ℃, filtering, adding ammonium fluoride into the filtrate, reacting at 90-95 ℃ for 2-3 hours to make the calcium and magnesium ions in the filtrate lower than 5mg/L, and filtering to obtain pure manganese solution;
(3) Preparing a di (2, 4-trimethylpentyl) phosphonic acid saponification solution, and performing 10-12-stage countercurrent extraction, 8-10-stage countercurrent acid solution washing and 4-5-stage countercurrent pure water washing on the di (2, 4-trimethylpentyl) phosphonic acid saponification solution and a pure manganese solution to obtain an organic phase after water washing;
(4) Adding 1-bromo-2-methylpropane into the organic phase washed by water in the step (3), mixing and stirring for 0.5-1 hour at the temperature of 40-50 ℃, then standing while adding ultrasonic waves for layering, taking the upper organic phase, roasting for 2-3 hours at the temperature of 450-500 ℃, simultaneously adding a catalyst, and introducing CO in the roasting process 2 And O 2 Maintaining CO in the mixed gas 2 And O 2 The volume ratio of (2-2.5) is that after the materials are completely changed into black solids from liquid, the reaction is continued for 0.5-3 hours, the reaction is stopped, and the high-purity carbon-coated manganese phosphate is obtained after cooling.
The integrated equipment for winnowing and electrostatic separation comprises a spiral blanking machine, wherein the spiral blanking machine is connected with a storage bin, at least one layer of magnetic net is arranged in the storage bin, the aperture of the magnetic net is 1-1.5mm, the magnetic net is connected with an electromagnet, an electrostatic generator is arranged on one side of the middle of the storage bin, a first discharge port is arranged below the electrostatic generator, an air outlet is formed in one side of the lower portion of the storage bin, a second discharge port is formed below the air outlet, and a third discharge port is formed in the bottom of the storage bin.
In the step (1), the concentration of the sodium hydroxide solution is 2-3mol/L, the mass ratio of the black powder material to the sodium hydroxide is 1.5-0.6, the first filtrate is added with sulfuric acid to adjust the pH value of the solution to 7.5-8, so as to obtain zinc hydroxide precipitate, the zinc hydroxide precipitate is filtered, dissolved by adding sulfuric acid, and concentrated and crystallized to obtain zinc sulfate crystals.
In the step (2), the second filter residue is returned to be mixed with the first filter residue for acid dissolution continuously, the mass ratio of the rough manganese powder to the manganese dioxide in the first filter residue is 1 2+ 、Co 2+ 、Ni 2+ 、Pb 2+ 、Cd 2+ 、Zn 2+ 2-3 times of the total mass to finally obtain the pure Mn solution]0.7-0.75mol/L, zn less than 5Mg/L, ca/Mg less than 5Mg/L, and other metal ion content less than 2Mg/L.
Sampling and measuring the raffinate in the extraction process in the step (2), and controlling Mn in the raffinate 2+ When the content of manganese ions is less than 5mg/L, the flow rate of the third filtrate is increased, and when the content of manganese ions is more than 10mg/L, the flow rate of the third filtrate is reduced.
The preparation method of the bis (2, 4-trimethylpentyl) phosphonic acid saponified solution in the step (3) comprises the steps of uniformly mixing bis (2, 4-trimethylpentyl) phosphonic acid with No. 260 solvent oil, wherein the concentration of the bis (2, 4-trimethylpentyl) phosphonic acid is 0.5-0.6mol/L, then adding ammonia water for mixing reaction, mixing and reacting for 0.5-1 hour at normal temperature, standing for layering, wherein an organic phase is the bis (2, 4-trimethylpentyl) phosphonic acid saponified solution, the molar ratio of the bis (2, 4-trimethylpentyl) phosphonic acid to the ammonia water is 1.6-1.8, the volume flow ratio of an organic phase, an aqueous phase, an acid solution and pure water is 4-1.2-0.4.5-1, the acid solution is 0.5-0.8mol/L hydrochloric acid solution, the stirring speed is 200-300r/min, the mixing time is 2-5min, the time is 30-35min, the content of clear manganese ions in the aqueous phase is controlled and the raffinate is added into 100mg/L washing water for extraction, and the extraction is carried out together.
The volume ratio of the washed organic phase to the 1-bromo-2-methylpropane in the step (4) is 1-3-5, and the lower organic phase obtained after layering is distilled to separate the 1-bromo-2-methylpropane from the No. 260 solvent oil.
The catalyst in the step (4) is one of nitric acid, perchloric acid and hypochlorous acid, the molar ratio of the catalyst to the upper organic phase is 1.
The invention adopts waste zinc-manganese batteries as raw materials, and the waste zinc-manganese batteries comprise the following components:
index (I) Mn Zn Plastic material Ni
Numerical value 20-25% 15-20% 5-10% 1-2%
NH 4 Cl Co Ca Si Al
3-8% 0.5-2% 0.5-1% 0.5-1% 0.1-0.2%
Cr Cu Mg Fe Na
0.5-0.8% 0.5-2% 1-2% 5-10% 0.5-1%
From data, the components of the waste zinc-manganese battery are complex, the separation of zinc and manganese and the separation and purification of other impurities are complex, the cost is high, the waste water generation amount is large, generally speaking, the recovery value or the recovery yield is basically zero, and the waste water can be realized only by realizing high-end recycling.
The invention adopts the integrated equipment of air separation and electrostatic separation to carry out separation, the integrated equipment of air separation and electrostatic separation comprises a spiral blanking machine, the spiral blanking machine is connected with a storage bin, at least one layer of magnetic conduction net is arranged in the storage bin, the aperture of the magnetic conduction net is 1-1.5mm, the magnetic conduction net is connected with an electromagnet, one side of the middle part of the storage bin is provided with an electrostatic generator, the lower part of the electrostatic generator is provided with a first discharge hole, one side of the lower part of the storage bin is provided with an air outlet, the lower part of the air outlet is provided with a second discharge hole, the bottom of the storage bin is provided with a third discharge hole, the feeding can be automatically realized by adopting the spiral blanking machine, meanwhile, the magnetic conduction net is adopted and is connected with the electromagnet, the magnetic conduction net can suck magnetic materials and simultaneously slow down the falling speed of the materials, the electrostatic separation of materials such as plastics can be realized, the separation of materials such as manganese dioxide and zinc metal or iron metal can be realized by adopting air separation, and the enrichment and purification of manganese dioxide can be preliminarily realized.
Adding an acid solution into the first filter residue, simultaneously adding rough manganese powder, maintaining the pH value of the solution to be 0.5-1.5, reacting for 5-6 hours at 70-85 ℃, taking the rough manganese powder as a reducing agent, avoiding the introduction of impurities, leaching and reducing manganese dioxide to obtain manganese ions with a divalent state, continuously adding the rough manganese powder, adjusting the pH value of the solution to be 5.5-6, introducing air, completely oxidizing ferrous ions into ferric iron and precipitating, simultaneously removing metal ions such as Cr/Al/Si/Sn/Ti and the like, filtering to obtain a second filtrate and a second filter residue, wherein the second filter residue contains the manganese powder and unreacted manganese dioxide, and returning to continuously dissolving.
Adjusting the pH of the second filtrate to 2-2.5, adding ammonium sulfide, reacting at 45-65 deg.C for 2-3 hr, wherein the molar number of the added ammonium sulfide is Cu in the second filtrate 2+ 、Co 2+ 、Ni 2+ 、Pb 2+ 、Cd 2+ 、Zn 2+ 1.1-1.25 times of the total mole number, filtering to obtain a third filtrate and a third filter residue, wherein sulfide can effectively remove Cu 2+ 、Co 2+ 、Ni 2+ 、Pb 2+ 、Cd 2+ 、Zn 2+ The plasma is generated by the plasma of the metal ions,
mixing the third filtrate with the P507 extractant saponified by the ammonia water, and performing 5-7-stage countercurrent extraction, 5-7-stage countercurrent washing, 5-7-stage primary countercurrent back extraction, 4-6-stage secondary countercurrent back extraction and 1-2-stage countercurrent water washing to obtain raffinate, primary strip liquor and secondary strip liquor, wherein the volume flow ratio of the third filtrate, the P507 extractant saponified by the ammonia water, the washing solution, the primary strip liquor, the secondary strip liquor and the washing water is 0.1-0.15:0.2-0.25, washing with 0.5-1mol/L hydrochloric acid, 1-1.5mol/L hydrochloric acid as primary stripping solution, 1.5-2mol/L hydrochloric acid as secondary stripping solution, adding heavy metal scavenger into the primary stripping solution, reacting at pH2.5-3.5 for 2-3 hr, maintaining the temperature at 30-40 deg.C, filtering, adding ammonium fluoride into the filtrate, and reacting at 90-95 deg.C for 2-3 hr to obtain filtrateLess than 5mg/L of calcium and magnesium ions, filtering to obtain pure manganese solution, and preferentially extracting Fe according to the extraction sequence of the P507 extractant 3+ /Zn 2+ Extracting and re-extracting Ca 2+ /Mn 2+ /Cu 2+ Then extracting Mg again 2+ /Ni 2+ /Co 2+ The invention adopts an extracting agent to extract manganese ions into an organic phase, and because of the problem of the extraction sequence, ferric iron, zinc ions, calcium ions and part of copper ions can be extracted, thereby controlling Mn in the raffinate 2+ When the content of manganese ions is less than 5mg/L and the content of the manganese ions is more than 10mg/L, the flow of the third filtrate is increased, when the content of the manganese ions is more than 10mg/L, the flow of the third filtrate is reduced, a large amount of magnesium ions and cobalt nickel ions can be prevented from being extracted, the difficulty of subsequent purification is reduced, then two-stage back extraction is adopted, the manganese ions are back extracted by the first-stage back extraction, part of calcium ions and copper ions are back extracted, the zinc ions are back extracted and enriched by the second-stage back extraction, then heavy metals are precipitated by the back-extracted manganese solution through a heavy metal trapping agent, calcium and magnesium are removed by fluoride, and the manganese solution with high purity can be obtained.
Preparing a bis (2, 4-trimethylpentyl) phosphonic acid saponification solution, carrying out 10-12-stage countercurrent extraction on the bis (2, 4-trimethylpentyl) phosphonic acid saponification solution and a pure manganese solution, washing with an 8-10-stage countercurrent acid solution and washing with 4-5-stage countercurrent pure water to obtain an organic phase after washing with water, and extracting manganese ions by using the bis (2, 4-trimethylpentyl) phosphonic acid to obtain an organic phase of the bis (2, 4-trimethylpentyl) phosphonic acid manganese, and further separating from magnesium, sodium, cobalt, nickel and the like to further improve the purity of the organic phase.
Adding 1-bromo-2-methylpropane into the washed organic phase, mixing and stirring at 40-50 deg.C for 0.5-1 hr, standing while adding ultrasonic wave for layering, collecting the upper organic phase, calcining at 450-500 deg.C for 2-3 hr while adding catalyst, introducing CO during calcination 2 And O 2 Maintaining CO in the mixed gas 2 And O 2 The volume ratio of (1) is 2-2.5, in the reaction process, after the materials are completely changed into black solids from liquid, the reaction is continuously carried out for 0.5-3 hours, the reaction is stopped, and the high-purity carbon-coated manganese phosphate is obtained after cooling. With 1-bromine2-methyl propane which can be mutually soluble with the No. 260 solvent oil, and the manganese bis (2, 4-trimethylpentyl) phosphonate is independently in one phase to realize the separation with the No. 260 solvent oil, and the obtained No. 260 solvent oil can be returned for use after the 1-bromo-2-methyl propane and the No. 260 solvent oil are distilled and separated, the obtained manganese bis (2, 4-trimethylpentyl) phosphonate is catalytically decomposed at high temperature to decompose carbon chains in the manganese bis (2, 4-trimethylpentyl) phosphonate into carbon dioxide and water, and a certain atmosphere is maintained to avoid the complete combustion of carbon, so that the carbon is coated on manganese phosphate, the reaction time is controlled, and the coating amount of the carbon can be controlled.
Because the positive electrode materials of the lithium manganese phosphate or the lithium manganese iron phosphate and the lithium iron phosphate have certain problems, namely poor conductivity, the conductivity of the positive electrode materials is improved by generally reducing the granularity of the lithium iron phosphate and coating the conductive materials.
Meanwhile, the wastewater generated by liquid phase precipitation synthesis is avoided, the wastewater amount is greatly reduced, and the process flow is short.
The 260# solvent oil is recycled, and simultaneously, the ammonium chloride and the like in the waste zinc-manganese battery can be effectively utilized to recover the zinc in the waste zinc-manganese battery, so that the cost can be reduced.
The indexes of the finally obtained manganese phosphate are as follows:
the invention has the beneficial effects that:
1. the waste zinc-manganese battery is used for preparing the high-purity carbon-coated manganese phosphate, the cost is low, and the process is short.
2. The discharge amount of waste water is less, compared with liquid phase precipitation, the waste water amount is greatly reduced, about 80 tons of waste water is generated by each ton of manganese phosphate produced by liquid phase precipitation, and only 20-30 tons of waste water is generated by the method.
3. The method adopts catalytic oxidation decomposition to prepare the carbon-coated manganese phosphate, and the obtained carbon-coated manganese phosphate has high purity, narrow particle size distribution and high tap density.
Detailed Description
The invention will be described in detail with reference to specific embodiments, and the method for preparing carbon-coated manganese phosphate from waste zinc-manganese batteries of the embodiment comprises the following steps:
(1) Pretreating, namely crushing the waste zinc-manganese battery until the particle size of the material is 0.1-1mm, sorting the material in integrated equipment of air separation and electrostatic sorting, adding pure water into the obtained black powder material for slurrying, adding sodium hydroxide solution into the slurried material, reacting for 3-4 hours at 90-95 ℃ in a sealed reaction kettle, simultaneously arranging an exhaust pipe, inserting the exhaust pipe into the pure water to obtain an ammonia water solution, after the reaction is finished, filtering and washing to obtain a first filtrate and a first filter residue;
(2) Purifying, adding acid solution into the first filter residue, adding crude manganese powder, maintaining the pH of the solution at 0.5-1.5, reacting at 70-85 ℃ for 5-6 hours, continuously adding the crude manganese powder, adjusting the pH of the solution to 5.5-6, introducing air, completely oxidizing ferrous ions into ferric iron, precipitating, filtering to obtain second filtrate and second filter residue, adjusting the pH of the second filtrate to 2-2.5, adding ammonium sulfide, reacting at 45-65 ℃ for 2-3 hours, and adding ammonium sulfide with the molar number of the ammonium sulfide being Cu in the second filtrate 2+ 、Co 2+ 、Ni 2+ 、Pb 2+ 、Cd 2+ 、Zn 2+ 1.1-1.25 times of the total mole number, then filtering to obtain a third filtrate and a third filter residue, mixing the third filtrate with the P507 extractant after the ammonia water saponification, and performing 5-7 stages of countercurrent extraction, 5-7 stages of countercurrent washing, 5-7 stages of countercurrent back extraction, 4-6 stages of secondary countercurrent back extraction and 1-2 stages of countercurrent water washing to obtain raffinate, a primary strip solution and a secondary strip solution, wherein the volume flow ratio of the third filtrate, the P507 extractant after the ammonia water saponification, the washing solution, the primary strip solution, the secondary strip solution and the washing water is 0.5-0.65: 0.2-0.25, washing with 0.5-1mol/L hydrochloric acidAdding a heavy metal capture agent into the primary stripping solution, reacting at the pH value of 2.5-3.5 for 2-3 hours, maintaining the temperature at 30-40 ℃, filtering, adding ammonium fluoride into the filtrate, reacting at the temperature of 90-95 ℃ for 2-3 hours to ensure that calcium and magnesium ions in the filtrate are lower than 5mg/L, and filtering to obtain a pure manganese solution;
(3) Preparing a di (2, 4-trimethylpentyl) phosphonic acid saponification solution, and performing 10-12-stage countercurrent extraction, 8-10-stage countercurrent acid solution washing and 4-5-stage countercurrent pure water washing on the di (2, 4-trimethylpentyl) phosphonic acid saponification solution and a pure manganese solution to obtain a water-washed organic phase;
(4) Adding 1-bromo-2-methylpropane into the organic phase washed by water in the step (3), mixing and stirring for 0.5-1 hour at the temperature of 40-50 ℃, then standing while adding ultrasonic waves for layering, taking the upper organic phase, roasting for 2-3 hours at the temperature of 450-500 ℃, simultaneously adding a catalyst, and introducing CO in the roasting process 2 And O 2 Maintaining CO in the mixed gas 2 And O 2 The volume ratio of (2-2.5) is that after the materials are completely changed into black solids from liquid, the reaction is continued for 0.5-3 hours, the reaction is stopped, and the high-purity carbon-coated manganese phosphate is obtained after cooling.
Winnowing and electrostatic separation integrated equipment includes spiral blanking machine, spiral blanking machine is connected with the feed bin, is provided with at least one deck in the feed bin and leads the magnetic net, and the aperture of leading the magnetic net is 1-1.5mm, it is connected with the electro-magnet to lead the magnetic net, and middle part one side of feed bin is provided with electrostatic generator, and electrostatic generator's below is provided with first discharge gate, lower part one side air outlet of feed bin, and the below of air outlet is provided with the second discharge gate, and the bottom of feed bin is provided with the third discharge gate.
In the step (1), the concentration of the sodium hydroxide solution is 2-3mol/L, the mass ratio of the black powder material to the sodium hydroxide is 1.5-0.6, the pH value of the first filtrate is adjusted to 7.5-8 by adding sulfuric acid, so as to obtain zinc hydroxide precipitate, the zinc hydroxide precipitate is filtered, dissolved by adding sulfuric acid, and concentrated and crystallized to obtain zinc sulfate crystals.
In the step (2), the second filter residue is returned to be mixed with the first filter residue for continuous acid dissolution, and rough manganese powderThe mass ratio of the P507 extractant to manganese dioxide in the first filter residue is 1.7-0.8, the preparation method of the P507 extractant after ammonia water saponification comprises the steps of uniformly mixing the P507 extractant with No. 260 solvent oil, wherein the concentration of the P507 extractant is 0.5-0.6mol/L, then adding ammonia water for mixing reaction, mixing reaction for 0.5-1 hour at normal temperature, standing for layering, wherein an organic phase is the P507 extractant after ammonia water saponification, the molar ratio of the P507 extractant to the ammonia water is 1.6-1.8, a heavy metal catching agent is an organic sulfur compound, and the addition amount of the heavy metal catching agent is that the Cu in the primary back extraction solution is that the molar ratio of the P507 extractant to the ammonia water is 1 2+ 、Co 2+ 、Ni 2+ 、Pb 2+ 、Cd 2+ 、Zn 2+ 2-3 times of the total mass to finally obtain the pure Mn solution]0.7-0.75mol/L, zn less than 5Mg/L, ca/Mg less than 5Mg/L, and other metal ion content less than 2Mg/L.
Sampling and measuring the raffinate in the extraction process in the step (2), and controlling Mn in the raffinate 2+ When the content of manganese ions is less than 5mg/L, the flow rate of the third filtrate is increased, and when the content of manganese ions is more than 10mg/L, the flow rate of the third filtrate is reduced.
The preparation method of the bis (2, 4-trimethylpentyl) phosphonic acid saponified solution in the step (3) comprises the steps of uniformly mixing bis (2, 4-trimethylpentyl) phosphonic acid with No. 260 solvent oil, wherein the concentration of the bis (2, 4-trimethylpentyl) phosphonic acid is 0.5-0.6mol/L, then adding ammonia water for mixing reaction, mixing and reacting for 0.5-1 hour at normal temperature, standing for layering, wherein an organic phase is the bis (2, 4-trimethylpentyl) phosphonic acid saponified solution, the molar ratio of the bis (2, 4-trimethylpentyl) phosphonic acid to the ammonia water is 1.6-1.8, the volume flow ratio of an organic phase, an aqueous phase, an acid solution and pure water is 4-1.2-0.4.5-1, the acid solution is 0.5-0.8mol/L hydrochloric acid solution, the stirring speed is 200-300r/min, the mixing time is 2-5min, the time is 30-35min, the content of clear manganese ions in the aqueous phase is controlled and the raffinate is added into 100mg/L washing water for extraction, and the extraction is carried out together.
The volume ratio of the washed organic phase to the 1-bromo-2-methylpropane in the step (4) is 1-3-5, and the lower organic phase obtained after layering is distilled to separate the 1-bromo-2-methylpropane from the No. 260 solvent oil.
The catalyst in the step (4) is one of nitric acid, perchloric acid and hypochlorous acid, the molar ratio of the catalyst to the upper organic phase is 1.
Example 1
A method for preparing carbon-coated manganese phosphate from waste zinc-manganese batteries comprises the following steps:
(1) Pretreating, namely crushing the waste zinc-manganese battery until the particle size of the material is 0.6mm, sorting the material in integrated equipment of air separation and electrostatic sorting, adding pure water into the obtained black powder material for slurrying, adding the slurried material into a sodium hydroxide solution, reacting for 3.3 hours at 92.5 ℃ in a sealed reaction kettle, simultaneously arranging an exhaust pipe, inserting the exhaust pipe into the pure water to obtain an ammonia water solution, after the reaction is finished, filtering and washing to obtain a first filtrate and a first filter residue;
(2) Purifying, adding acid solution into the first filter residue, adding crude manganese powder at the same time, maintaining the pH value of the solution at 1.2, reacting for 5.5 hours at 82 ℃, further adding the crude manganese powder, adjusting the pH value of the solution to 5.8, introducing air, completely oxidizing ferrous ions into ferric iron and precipitating, filtering to obtain a second filtrate and a second filter residue, adjusting the pH value of the second filtrate to 2.3, adding ammonium sulfide, reacting for 2.5 hours at 55 ℃, and adding ammonium sulfide with the mol number of Cu in the second filtrate 2+ 、Co 2+ 、Ni 2+ 、Pb 2+ 、Cd 2+ 、Zn 2+ 1.21 times of the total mole number, then filtering to obtain a third filtrate and a third filter residue, mixing the third filtrate with a P507 extractant after ammonia water saponification, performing 6-stage countercurrent extraction, 6-stage countercurrent washing, 5-stage primary countercurrent back extraction, 5-stage secondary countercurrent back extraction and 2-stage countercurrent water washing to obtain a raffinate, a primary strip liquid and a secondary strip liquid, wherein the volume flow ratio of the third filtrate, the P507 extractant after ammonia water saponification, the washing liquid, the primary strip liquid, the secondary strip liquid and the washing water is 0.13:0.23, washing with 0.7mol/L hydrochloric acid, 1.35mol/L hydrochloric acid as primary stripping solution, and 1.8mol/L hydrochloric acid as secondary stripping solution, adding heavy metal scavenger into the primary stripping solution, reacting at pH3.1 for 2.5 hr, maintaining for a whileFiltering at 35 ℃, adding ammonium fluoride into the filtrate, reacting for 2.6 hours at 92.5 ℃ to ensure that calcium and magnesium ions in the filtrate are lower than 5mg/L, and filtering to obtain a pure manganese solution;
(3) Preparing a di (2, 4-trimethylpentyl) phosphonic acid saponification solution, and carrying out 11-stage countercurrent extraction, 8-stage countercurrent acid solution washing and 4-stage countercurrent pure water washing on the di (2, 4-trimethylpentyl) phosphonic acid saponification solution and a pure manganese solution to obtain an organic phase after water washing;
(4) Adding 1-bromo-2-methylpropane into the organic phase washed by water in the step (3), mixing and stirring for 0.8 hour at the temperature of 45 ℃, then standing while adding ultrasonic waves for layering, taking the upper organic phase, roasting for 2.5 hours at the temperature of 465 ℃, simultaneously adding a catalyst, introducing CO in the roasting process 2 And O 2 Maintaining CO in the mixed gas 2 And O 2 The volume ratio of (2.3) to (1), after the materials are completely changed into black solids from liquid, continuing to react for 1 hour, stopping the reaction, and cooling to obtain the high-purity carbon-coated manganese phosphate.
Selection by winnowing and electrostatic separation integration equipment includes spiral blanking machine, spiral blanking machine is connected with the feed bin, is provided with at least one deck in the feed bin and leads the magnetic net, and the aperture of leading the magnetic net is 1.4mm, it is connected with the electro-magnet to lead the magnetic net, and middle part one side of feed bin is provided with electrostatic generator, and electrostatic generator's below is provided with first discharge gate, lower part one side air outlet of feed bin, and the below of air outlet is provided with the second discharge gate, and the bottom of feed bin is provided with the third discharge gate.
In the step (1), the concentration of the sodium hydroxide solution is 2.3mol/L, the mass ratio of the black powder material to the sodium hydroxide is 1.
In the step (2), the second filter residue is returned to be mixed with the first filter residue for acid dissolution, the mass ratio of the crude manganese powder to the manganese dioxide in the first filter residue is 1Adding ammonia water for mixing reaction, mixing and reacting for 0.9 hour at normal temperature, standing for layering, wherein the organic phase is the P507 extracting agent obtained after the ammonia water is saponified, the molar ratio of the P507 extracting agent to the ammonia water is 1.7, the heavy metal trapping agent is an organic sulfur compound, and the addition amount of the heavy metal trapping agent is that the Cu in the primary stripping solution is added 2+ 、Co 2+ 、Ni 2+ 、Pb 2+ 、Cd 2+ 、Zn 2+ 2.5 times of the total mass, finally obtaining pure Mn solution]Is 0.73mol/L, zn is less than 5Mg/L, ca/Mg is less than 5Mg/L, and the content of other metal ions is less than 2Mg/L.
Sampling and measuring the raffinate in the extraction process in the step (2), and controlling Mn in the raffinate 2+ At 7mg/L.
The preparation method of the bis (2, 4-trimethylpentyl) phosphonic acid saponification solution in the step (3) comprises the steps of uniformly mixing bis (2, 4-trimethylpentyl) phosphonic acid with 260# solvent oil, wherein the concentration of bis (2, 4-trimethylpentyl) phosphonic acid is 0.55mol/L, then adding ammonia water for mixing reaction, mixing and reacting for 0.8 hour at normal temperature, standing for layering, wherein the organic phase is the bis (2, 4-trimethylpentyl) phosphonic acid saponification solution, the molar ratio of bis (2, 4-trimethylpentyl) phosphonic acid to ammonia water is 1.7, the volume flow ratio of the organic phase, the aqueous phase, the acid solution and the pure water is 4.25, 0.25, 0.7mol/L hydrochloric acid solution, the stirring speed is 250r/min, the mixing time is 4min, the settling time is 33min, the manganese ion content in the raffinate is controlled at 80mg/L, and the washing water is mixed with the acid solution for extraction together.
The volume ratio of the washed organic phase to the 1-bromo-2-methylpropane in the step (4) is 1.5, and the lower organic phase obtained after layering is distilled to separate the 1-bromo-2-methylpropane from the No. 260 solvent oil.
The catalyst in the step (4) is one of nitric acid, perchloric acid and hypochlorous acid, the molar ratio of the catalyst to the upper organic phase is 1.
The final product has the following indexes:
index (I) Manganese content Phosphorus content Tap density Carbon content Na
Numerical value 39.6% 14.95% 1.28g/mL 1.99% 1.2ppm
Cr Ca Mg Na Ni Co
0.18ppm 6ppm 3.5ppm 2.8ppm 1.95ppm 0.43ppm
Fe Zn Cu Ti Al Si
4.9ppm 8ppm 0.25ppm 0.35ppm 1.2ppm 1.2ppm
D10 D50 D90 BET Sulfate radical Chloride ion
0.77μm 1.35μm 2.0μm 13.8m 2 /g 4.2ppm 2.5ppm
Meanwhile, the final recovery rate of manganese is 97.8%, and the waste water produced by each ton of manganese phosphate is 25 tons.
Example 2
A method for preparing carbon-coated manganese phosphate from waste zinc-manganese batteries comprises the following steps:
(1) Pretreating, namely crushing the waste zinc-manganese battery until the particle size of the material is 0.6mm, sorting the material in integrated equipment of air separation and electrostatic sorting, adding pure water into the obtained black powder material for slurrying, adding the slurried material into a sodium hydroxide solution, reacting for 3.3 hours at 92.5 ℃ in a sealed reaction kettle, simultaneously arranging an exhaust pipe, inserting the exhaust pipe into the pure water to obtain an ammonia water solution, after the reaction is finished, filtering and washing to obtain a first filtrate and a first filter residue;
(2) Purifying, adding acid solution into the first filter residue, adding crude manganese powder at the same time, maintaining the pH value of the solution at 1.2, reacting for 5.5 hours at 83 ℃, further adding the crude manganese powder, adjusting the pH value of the solution to 5.8, introducing air, completely oxidizing ferrous ions into ferric iron and precipitating, filtering to obtain a second filtrate and a second filter residue, adjusting the pH value of the second filtrate to 2.3, adding ammonium sulfide, reacting for 2.5 hours at 55 ℃, and adding ammonium sulfide with the mol number of Cu in the second filtrate 2+ 、Co 2+ 、Ni 2+ 、Pb 2+ 、Cd 2+ 、Zn 2+ 1.21 times of the total mole number, then filtering to obtain a third filtrate and a third filter residue, mixing the third filtrate with a P507 extractant after ammonia water saponification, and performing 6-stage countercurrent extraction, 6-stage countercurrent washing, 5-stage primary countercurrent back extraction, 5-stage secondary countercurrent back extraction and 2-stage countercurrent water washing to obtain raffinate, a primary strip liquor and a secondary strip liquor, wherein the volume flow ratio of the third filtrate, the P507 extractant after ammonia water saponification, the washing solution, the primary strip liquor, the secondary strip liquor and the washing water is 0.62: 0.24, washing with 0.7mol/L hydrochloric acid, adding a heavy metal scavenger into the primary stripping solution which is 1.33mol/L hydrochloric acid, adding a heavy metal scavenger into the secondary stripping solution which is 1.8mol/L hydrochloric acid, reacting at the pH of 3.1 for 2.5 hours, maintaining the temperature at 35 ℃, filtering, adding ammonium fluoride into the filtrate, reacting at the temperature of 92.5 ℃ for 2.6 hours to ensure that calcium and magnesium ions in the filtrate are lower than 5mg/L, and filtering to obtain a pure manganese solution;
(3) Preparing a di (2, 4-trimethylpentyl) phosphonic acid saponification solution, and performing 10-stage countercurrent extraction, 8-stage countercurrent acid solution washing and 4-stage countercurrent pure water washing on the di (2, 4-trimethylpentyl) phosphonic acid saponification solution and a pure manganese solution to obtain an organic phase after water washing;
(4) Adding 1-bromo-2-methylpropane into the organic phase washed by water in the step (3), mixing and stirring for 0.8 hour at the temperature of 45 ℃, then standing while adding ultrasonic waves for layering, taking the upper organic phase, roasting for 2.9 hours at the temperature of 475 ℃, simultaneously adding a catalyst, introducing CO in the roasting process 2 And O 2 Maintaining CO in the mixed gas 2 And O 2 The volume ratio of (2.5) to (1), after the materials are completely changed into black solids from liquid, continuing to react for 1.5 hours, stopping the reaction, and cooling to obtain the high-purity carbon-coated manganese phosphate.
Selection by winnowing and electrostatic separation integration equipment includes the spiral blanking machine, the spiral blanking machine is connected with the feed bin, is provided with at least one deck in the feed bin and leads the magnetic net, and the aperture of leading the magnetic net is 1.4mm, it is connected with the electro-magnet to lead the magnetic net, and middle part one side of feed bin is provided with electrostatic generator, and electrostatic generator's below is provided with first discharge gate, lower part one side air outlet of feed bin, the below of air outlet are provided with the second discharge gate, and the bottom of feed bin is provided with the third discharge gate.
In the step (1), the concentration of the sodium hydroxide solution is 2.3mol/L, the mass ratio of the black powder material to the sodium hydroxide is 1.
In the step (2), the second filter residue is returned to be mixed with the first filter residue for acid dissolution, the mass ratio of the crude manganese powder to the manganese dioxide in the first filter residue is 1 2+ 、Co 2+ 、Ni 2+ 、Pb 2+ 、Cd 2+ 、Zn 2+ 2.5 times of the total mass to finally obtain the pure Mn in the manganese solution]0.72mol/L, zn < 5mg/L, ca-Mg is less than 5Mg/L, and the content of other metal ions is less than 2Mg/L.
Sampling and measuring the raffinate in the extraction process in the step (2), and controlling Mn in the raffinate 2+ At 6mg/L.
The preparation method of the bis (2, 4-trimethylpentyl) phosphonic acid saponification solution in the step (3) comprises the steps of uniformly mixing bis (2, 4-trimethylpentyl) phosphonic acid with 260# solvent oil, wherein the concentration of bis (2, 4-trimethylpentyl) phosphonic acid is 0.55mol/L, then adding ammonia water for mixing reaction, mixing and reacting for 0.8 hour at normal temperature, standing for layering, wherein the organic phase is the bis (2, 4-trimethylpentyl) phosphonic acid saponification solution, the molar ratio of bis (2, 4-trimethylpentyl) phosphonic acid to ammonia water is 1.7, the volume flow ratio of the organic phase, the aqueous phase, the acid solution and the pure water is 4.28: 0.25:0.55, the acid solution is 0.7mol/L hydrochloric acid solution, the stirring speed is 250r/min, the mixing time is 4min, the settling time is 33min, the manganese ion content in the raffinate is controlled at 70mg/L, and the washing water is mixed with the washing water phase for extraction together.
The volume ratio of the organic phase washed by water in the step (4) to the 1-bromo-2-methylpropane is 1.
The catalyst in the step (4) is one of nitric acid, perchloric acid and hypochlorous acid, the molar ratio of the catalyst to the upper organic phase is 1.
The final product index is as follows:
index (I) Manganese content Phosphorus content Tap density Carbon content Na
Numerical value 39.7% 14.99% 1.30g/mL 1.85% 1.2ppm
Cr Ca Mg Na Ni Co
0.18ppm 5.8ppm 3.5ppm 2.8ppm 1.95ppm 0.43ppm
Fe Zn Cu Ti Al Si
4.6ppm 7.2ppm 0.25ppm 0.33ppm 1.2ppm 1.2ppm
D10 D50 D90 BET Sulfate radical Chloride ion
0.78μm 1.42μm 2.05μm 13.2m 2 /g 4.1ppm 2.1ppm
Meanwhile, the final recovery rate of manganese is 98.1%, and the amount of wastewater generated by each ton of manganese phosphate is 24 tons.
Example 3
A method for preparing carbon-coated manganese phosphate from waste zinc-manganese batteries comprises the following steps:
(1) Pretreating, namely crushing the waste zinc-manganese battery until the particle size of the material is 0.6mm, sorting the material in integrated equipment of air separation and electrostatic sorting, adding pure water into the obtained black powder material for slurrying, adding the slurried material into a sodium hydroxide solution, reacting for 3.3 hours at 92.5 ℃ in a sealed reaction kettle, simultaneously arranging an exhaust pipe, inserting the exhaust pipe into the pure water to obtain an ammonia water solution, after the reaction is finished, filtering and washing to obtain a first filtrate and a first filter residue;
(2) Purifying, adding acid solution into the first filter residue, adding crude manganese powder at the same time, maintaining the pH value of the solution at 1.1, reacting at 85 ℃ for 5.5 hours, then continuously adding the crude manganese powder, adjusting the pH value of the solution to 5.8, then introducing air, completely oxidizing ferrous ions into ferric iron and precipitating, then filtering to obtain a second filtrate and a second filter residue, adjusting the pH value of the second filtrate to 2.3, adding ammonium sulfide, reacting at 55 ℃ for 2.5 hours, and adding ammonium sulfide with the mol number of Cu in the second filtrate 2+ 、Co 2+ 、Ni 2+ 、Pb 2+ 、Cd 2+ 、Zn 2+ 1.23 times of the total mole number, then filtering to obtain a third filtrate and a third filter residue, mixing the third filtrate with a P507 extractant saponified with ammonia water, and performing 6-stage countercurrent extraction, 6-stage countercurrent washing, 5-stage primary countercurrent back extraction, 5-stage secondary countercurrent back extraction and 1-stage countercurrent water washing to obtain a raffinate, a primary strip liquor and a secondary strip liquor, wherein the volume flow ratio of the third filtrate, the P507 extractant saponified with ammonia water, the washing solution, the primary strip liquor, the secondary strip liquor and the washing water is 0.13:0.25, washing with 0.7mol/L hydrochloric acid, adding a heavy metal scavenger into the primary stripping solution which is 1.25mol/L hydrochloric acid, adding a heavy metal scavenger into the secondary stripping solution which is 1.9mol/L hydrochloric acid, reacting at the pH of 3.1 for 2.5 hours, maintaining the temperature at 35 ℃, filtering, adding ammonium fluoride into the filtrate, reacting at the temperature of 92.5 ℃ for 2.8 hours to enable calcium and magnesium ions in the filtrate to be lower than 5mg/L, and filtering to obtain a pure manganese solution;
(3) Preparing a di (2, 4-trimethylpentyl) phosphonic acid saponification solution, and performing 12-stage countercurrent extraction, 8-stage countercurrent acid solution washing and 4-stage countercurrent pure water washing on the di (2, 4-trimethylpentyl) phosphonic acid saponification solution and a pure manganese solution to obtain a water-washed organic phase;
(4) Adding 1-bromo-2-methylpropane into the organic phase washed by water in the step (3), mixing and stirring for 0.8 hour at the temperature of 45 ℃, then standing while adding ultrasonic waves for layering, taking the upper organic phase, roasting for 2.8 hours at the temperature of 480 ℃, simultaneously adding a catalyst, introducing CO in the roasting process 2 And O 2 Maintaining CO in the mixed gas 2 And O 2 The volume ratio of (1) is 23And after 1.5 hours, stopping the reaction, and cooling to obtain the high-purity carbon-coated manganese phosphate.
Selection by winnowing and electrostatic separation integration equipment includes the spiral blanking machine, the spiral blanking machine is connected with the feed bin, is provided with at least one deck in the feed bin and leads the magnetic net, and the aperture of leading the magnetic net is 1.4mm, it is connected with the electro-magnet to lead the magnetic net, and middle part one side of feed bin is provided with electrostatic generator, and electrostatic generator's below is provided with first discharge gate, lower part one side air outlet of feed bin, the below of air outlet are provided with the second discharge gate, and the bottom of feed bin is provided with the third discharge gate.
In the step (1), the concentration of the sodium hydroxide solution is 2.3mol/L, the mass ratio of the black powder material to the sodium hydroxide is 1:0.56, the pH value of the first filtrate is adjusted to 7.7 by adding sulfuric acid, so as to obtain zinc hydroxide precipitate, the zinc hydroxide precipitate is filtered, dissolved by adding sulfuric acid, and concentrated and crystallized to obtain zinc sulfate crystals.
In the step (2), the second filter residue is returned to be mixed with the first filter residue for acid dissolution, the mass ratio of the crude manganese powder to the manganese dioxide in the first filter residue is 1,
the mol ratio of the P507 extractant to ammonia water is 1.65, the heavy metal trapping agent is an organic sulfur compound, and the addition amount of the heavy metal trapping agent is Cu in the primary stripping solution 2+ 、Co 2+ 、Ni 2+ 、Pb 2+ 、Cd 2+ 、Zn 2+ 2.5 times of the total mass to finally obtain the pure Mn in the manganese solution]0.71mol/L, zn less than 5Mg/L, ca/Mg less than 5Mg/L, and the content of other metal ions is less than 2Mg/L.
Sampling and measuring the raffinate in the extraction process in the step (2), and controlling Mn in the raffinate 2+ At 9mg/L.
The preparation method of the bis (2, 4-trimethylpentyl) phosphonic acid saponified solution in the step (3) comprises the steps of uniformly mixing bis (2, 4-trimethylpentyl) phosphonic acid and 260# solvent oil, wherein the concentration of the bis (2, 4-trimethylpentyl) phosphonic acid is 0.55mol/L, then adding ammonia water for mixing reaction, mixing and reacting for 0.8 hour at normal temperature, standing for layering, wherein an organic phase is the bis (2, 4-trimethylpentyl) phosphonic acid saponified solution, the molar ratio of the bis (2, 4-trimethylpentyl) phosphonic acid to the ammonia water is 1.7, in the extraction process, the volume flow ratio of the organic phase, the aqueous phase, the acid solution and the pure water is 4.1.3.
The volume ratio of the organic phase washed by water in the step (4) to the 1-bromo-2-methylpropane is 1.
The catalyst in the step (4) is one of nitric acid, perchloric acid and hypochlorous acid, the molar ratio of the catalyst to the upper organic phase is 1.
The final product index is as follows:
index (I) Manganese content Phosphorus content Tap density Carbon content Na
Numerical value 39.9% 14.94% 1.35g/mL 1.85% 1.2ppm
Cr Ca Mg Na Ni Co
0.11ppm 5ppm 3.5ppm 2.8ppm 1.90ppm 0.4ppm
Fe Zn Cu Ti Al Si
4.9ppm 9ppm 0.25ppm 0.35ppm 1.1ppm 1.1ppm
D10 D50 D90 BET Sulfate radical Chloride ion
0.80μm 1.39μm 2.0μm 13.58m 2 /g 4.0ppm 2.0ppm
Meanwhile, the final recovery rate of manganese is 97.5%, and the waste water produced by each ton of manganese phosphate is 28 tons.
Finally, the above embodiments are only for illustrating the technical solutions of the present invention and not for limiting, although the present invention has been described in detail with reference to the preferred embodiments, it should be understood by those skilled in the art that modifications or equivalent substitutions may be made to the technical solutions of the present invention without departing from the spirit and scope of the technical solutions of the present invention, and all of them should be covered in the claims of the present invention.

Claims (8)

1. A method for preparing carbon-coated manganese phosphate from waste zinc-manganese batteries is characterized by comprising the following steps:
(1) Pretreating, namely crushing the waste zinc-manganese battery until the particle size of the material is 0.1-1mm, sorting the material in integrated equipment of air separation and electrostatic sorting, adding pure water into the obtained black powder material for slurrying, adding sodium hydroxide solution into the slurried material, reacting for 3-4 hours at 90-95 ℃ in a sealed reaction kettle, simultaneously arranging an exhaust pipe, inserting the exhaust pipe into the pure water to obtain an ammonia water solution, after the reaction is finished, filtering and washing to obtain a first filtrate and a first filter residue;
(2) Purifying by filteringAdding acid solution into the residue, simultaneously adding crude manganese powder, maintaining the pH of the solution at 0.5-1.5, reacting at 70-85 deg.C for 5-6 hr, further adding crude manganese powder, adjusting the pH of the solution to 5.5-6, introducing air to completely oxidize ferrous ions into ferric iron and precipitate, filtering to obtain second filtrate and second filter residue, adjusting the pH of the second filtrate to 2-2.5, adding ammonium sulfide, reacting at 45-65 deg.C for 2-3 hr, and adding ammonium sulfide in a molar amount of Cu in the second filtrate 2+ 、Co 2+ 、Ni 2 + 、Pb 2+ 、Cd 2+ 、Zn 2+ 1.1-1.25 times of the total mole number, then filtering to obtain a third filtrate and a third filter residue, mixing the third filtrate with the P507 extractant after the ammonia water saponification, and performing 5-7 stages of countercurrent extraction, 5-7 stages of countercurrent washing, 5-7 stages of countercurrent back extraction, 4-6 stages of secondary countercurrent back extraction and 1-2 stages of countercurrent water washing to obtain raffinate, a primary strip solution and a secondary strip solution, wherein the volume flow ratio of the third filtrate, the P507 extractant after the ammonia water saponification, the washing solution, the primary strip solution, the secondary strip solution and the washing water is 0.5-0.65: 0.2-0.25, washing with 0.5-1mol/L hydrochloric acid, 1-1.5mol/L hydrochloric acid as primary stripping solution, 1.5-2mol/L hydrochloric acid as secondary stripping solution, adding heavy metal scavenger into the primary stripping solution, reacting at pH2.5-3.5 for 2-3 hours, maintaining the temperature at 30-40 ℃, filtering, adding ammonium fluoride into the filtrate, reacting at 90-95 ℃ for 2-3 hours to make the calcium and magnesium ions in the filtrate lower than 5mg/L, and filtering to obtain pure manganese solution;
(3) Preparing a di (2, 4-trimethylpentyl) phosphonic acid saponification solution, and performing 10-12-stage countercurrent extraction, 8-10-stage countercurrent acid solution washing and 4-5-stage countercurrent pure water washing on the di (2, 4-trimethylpentyl) phosphonic acid saponification solution and a pure manganese solution to obtain an organic phase after water washing;
(4) Adding 1-bromo-2-methylpropane into the organic phase washed by water in the step (3), mixing and stirring for 0.5-1 hour at the temperature of 40-50 ℃, then standing while adding ultrasonic waves for layering, taking the upper organic phase, roasting for 2-3 hours at the temperature of 450-500 ℃, simultaneously adding a catalyst, and introducing CO in the roasting process 2 And O 2 Maintaining CO in the mixed gas 2 And O 2 In a volume ratio of 2 to 2.51, after the materials are completely changed into black solids from liquid, continuing to react for 0.5 to 3 hours, stopping the reaction, and cooling to obtain the high-purity carbon-coated manganese phosphate.
2. The method for preparing carbon-coated manganese phosphate from waste zinc-manganese batteries according to claim 1, characterized by comprising the following steps: the integrated equipment for winnowing and electrostatic separation comprises a spiral blanking machine, wherein the spiral blanking machine is connected with a storage bin, at least one layer of magnetic net is arranged in the storage bin, the aperture of the magnetic net is 1-1.5mm, the magnetic net is connected with an electromagnet, an electrostatic generator is arranged on one side of the middle of the storage bin, a first discharge port is arranged below the electrostatic generator, an air outlet is formed in one side of the lower portion of the storage bin, a second discharge port is formed below the air outlet, and a third discharge port is formed in the bottom of the storage bin.
3. The method for preparing carbon-coated manganese phosphate from waste zinc-manganese batteries according to claim 1, characterized by comprising the following steps: in the step (1), the concentration of the sodium hydroxide solution is 2-3mol/L, the mass ratio of the black powder material to the sodium hydroxide is 1.5-0.6, the pH value of the first filtrate is adjusted to 7.5-8 by adding sulfuric acid, so as to obtain zinc hydroxide precipitate, the zinc hydroxide precipitate is filtered, dissolved by adding sulfuric acid, and concentrated and crystallized to obtain zinc sulfate crystals.
4. The method for preparing carbon-coated manganese phosphate from waste zinc-manganese batteries according to claim 1, characterized by comprising the following steps: in the step (2), the second filter residue is returned to be mixed with the first filter residue for acid dissolution, the mass ratio of the crude manganese powder to the manganese dioxide in the first filter residue is 1 2+ 、Co 2+ 、Ni 2+ 、Pb 2+ 、Cd 2+ 、Zn 2+ 2-3 times of the total mass to finally obtain the pure Mn solution]0.7-0.75mol/L, zn less than 5Mg/L, ca/Mg less than 5Mg/L, and other metal ion content less than 2Mg/L.
5. The method for preparing carbon-coated manganese phosphate from waste zinc-manganese batteries according to claim 1, characterized by comprising the following steps: sampling and measuring the raffinate in the extraction process in the step (2), and controlling Mn in the raffinate 2+ When the content of manganese ions is less than 5mg/L, the flow rate of the third filtrate is increased, and when the content of manganese ions is more than 10mg/L, the flow rate of the third filtrate is reduced.
6. The method for preparing carbon-coated manganese phosphate from waste zinc-manganese batteries according to claim 1, characterized by comprising the following steps: the preparation method of the bis (2, 4-trimethylpentyl) phosphonic acid saponified solution in the step (3) comprises the steps of uniformly mixing bis (2, 4-trimethylpentyl) phosphonic acid with No. 260 solvent oil, wherein the concentration of the bis (2, 4-trimethylpentyl) phosphonic acid is 0.5-0.6mol/L, then adding ammonia water for mixing reaction, mixing and reacting for 0.5-1 hour at normal temperature, standing for layering, wherein an organic phase is the bis (2, 4-trimethylpentyl) phosphonic acid saponified solution, the molar ratio of the bis (2, 4-trimethylpentyl) phosphonic acid to the ammonia water is 1.6-1.8, the volume flow ratio of an organic phase, an aqueous phase, an acid solution and pure water is 4-1.2-0.4.5-1, the acid solution is 0.5-0.8mol/L hydrochloric acid solution, the stirring speed is 200-300r/min, the mixing time is 2-5min, the time is 30-35min, the content of clear manganese ions in the aqueous phase is controlled and the raffinate is added into 100mg/L washing water for extraction, and the extraction is carried out together.
7. The method for preparing carbon-coated manganese phosphate from waste zinc-manganese batteries according to claim 1, characterized by comprising the following steps: the volume ratio of the washed organic phase to the 1-bromo-2-methylpropane in the step (4) is 1-3-5, and the lower organic phase obtained after layering is distilled to separate the 1-bromo-2-methylpropane from the No. 260 solvent oil.
8. The method for preparing carbon-coated manganese phosphate from waste zinc-manganese batteries according to claim 1, characterized by comprising the following steps: the catalyst in the step (4) is one of nitric acid, perchloric acid and hypochlorous acid, the molar ratio of the catalyst to the upper organic phase is 1-3-5, and the pressure is 1-3MPa.
CN201710635745.9A 2017-07-31 2017-07-31 Method for preparing carbon-coated manganese phosphate from waste zinc-manganese battery Active CN107437626B (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
CN201710635745.9A CN107437626B (en) 2017-07-31 2017-07-31 Method for preparing carbon-coated manganese phosphate from waste zinc-manganese battery

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
CN201710635745.9A CN107437626B (en) 2017-07-31 2017-07-31 Method for preparing carbon-coated manganese phosphate from waste zinc-manganese battery

Publications (2)

Publication Number Publication Date
CN107437626A CN107437626A (en) 2017-12-05
CN107437626B true CN107437626B (en) 2019-08-13

Family

ID=60460270

Family Applications (1)

Application Number Title Priority Date Filing Date
CN201710635745.9A Active CN107437626B (en) 2017-07-31 2017-07-31 Method for preparing carbon-coated manganese phosphate from waste zinc-manganese battery

Country Status (1)

Country Link
CN (1) CN107437626B (en)

Families Citing this family (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN108306003B (en) * 2018-01-29 2020-03-27 蒋央芳 Preparation method of ferromanganese phosphate
CN108400330B (en) * 2018-03-08 2020-07-14 蒋央芳 Preparation method of carbon-doped manganese (III) phosphate
CN108408745B (en) * 2018-04-02 2020-07-14 方嘉城 Method for preparing battery-grade lithium carbonate from waste lithium batteries
CN111333049B (en) * 2020-03-23 2021-07-06 蒋央芳 Preparation method of lithium iron manganese phosphate
CN115911248A (en) * 2022-11-11 2023-04-04 天津大学 Interface phase of manganese dioxide electrode of water-based zinc battery and preparation method thereof

Citations (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN201038237Y (en) * 2007-04-03 2008-03-19 深圳市格林美高新技术股份有限公司 Selective volatilization recovery system for waste zinc-manganese battery
CN104229898A (en) * 2013-06-06 2014-12-24 湖南邦普循环科技有限公司 Method for preparing high-purity manganese sulfate and zinc sulfate by using waste zinc-manganese batteries as raw materials

Family Cites Families (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CA2915371A1 (en) * 2015-12-15 2017-06-15 Institut National De La Recherche Scientifique (Inrs) Method for recycling valuable metals from spent batteries

Patent Citations (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN201038237Y (en) * 2007-04-03 2008-03-19 深圳市格林美高新技术股份有限公司 Selective volatilization recovery system for waste zinc-manganese battery
CN104229898A (en) * 2013-06-06 2014-12-24 湖南邦普循环科技有限公司 Method for preparing high-purity manganese sulfate and zinc sulfate by using waste zinc-manganese batteries as raw materials

Non-Patent Citations (1)

* Cited by examiner, † Cited by third party
Title
从废旧锌锰电池中回收锌和锰的工艺研究;高玉华等;《再生资源研究》;20060227;第2006年卷(第1期);第35-37页

Also Published As

Publication number Publication date
CN107437626A (en) 2017-12-05

Similar Documents

Publication Publication Date Title
CN107437626B (en) Method for preparing carbon-coated manganese phosphate from waste zinc-manganese battery
CN108002408B (en) Method for preparing nickel sulfate, manganese, lithium, cobalt and cobaltosic oxide from battery waste
US8945275B2 (en) Method for recovering valuable metals from lithium secondary battery wastes
CN103088215B (en) Method for separating nickel-cobalt and manganese in nickel-cobalt-manganese material with high manganese-cobalt ratio
CN101871048B (en) Method for recovering cobalt, nickel and manganese from waste lithium cells
CN108193050B (en) Metal material recovery method in a kind of waste and old ternary power battery
CN108408745B (en) Method for preparing battery-grade lithium carbonate from waste lithium batteries
EP3956487B1 (en) Process for the recovery of cathode materials in the recycling of batteries
JP5719792B2 (en) Method for producing chemical manganese dioxide from ternary positive electrode active material, chemical manganese dioxide produced by the production method, and secondary battery containing chemical manganese dioxide
CN102088124A (en) High-purity polymetallic-element solid mixed salt and preparation method and application thereof
KR20170061206A (en) Collection method of precursor material using disposed lithum-ion battery
CN109279665B (en) Treatment method of nickel cobalt lithium manganate ternary waste
CN108588425B (en) Treatment method of cobalt-nickel metallurgy wastewater slag
US11952289B2 (en) Method for preparing nickel sulfate from nickel-iron-copper alloy
CN104046776A (en) Process for recovering valuable metals from high-iron alloys
CN111455171B (en) Method for extracting valuable metals from seabed polymetallic nodules and co-producing lithium battery positive electrode material precursor and titanium-doped positive electrode material
WO2023029573A1 (en) Method for extracting lithium from waste lithium battery
US11695170B2 (en) Battery-level Ni—Co—Mn mixed solution and preparation method for battery-level Mn solution
CN111286605B (en) Method for recovering valuable metals of seabed polymetallic nodule and co-producing NCM precursor
CN110016547B (en) Comprehensive utilization method of jarosite slag
CN112342383A (en) Method for separating and recovering nickel, cobalt, manganese and lithium in ternary waste
CN105645475B (en) A kind of high-purity manganese source preparation method applied to lithium electricity positive electrode
CN103221557B (en) Method for producing nickel-ontaining acidic solution
CN113921932B (en) Precursor solution, preparation method thereof, positive electrode material and lithium ion battery
CN115784188A (en) Method for recycling and preparing battery-grade iron phosphate

Legal Events

Date Code Title Description
PB01 Publication
PB01 Publication
SE01 Entry into force of request for substantive examination
SE01 Entry into force of request for substantive examination
GR01 Patent grant
GR01 Patent grant