CN103757389A - Leaching method of lithium cobaltate waste battery positive electrode material - Google Patents

Leaching method of lithium cobaltate waste battery positive electrode material Download PDF

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Publication number
CN103757389A
CN103757389A CN201310736589.7A CN201310736589A CN103757389A CN 103757389 A CN103757389 A CN 103757389A CN 201310736589 A CN201310736589 A CN 201310736589A CN 103757389 A CN103757389 A CN 103757389A
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China
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leaching
acid
positive electrode
sulfuric acid
nitric acid
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CN201310736589.7A
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Chinese (zh)
Inventor
龙炳清
张章
崔伟
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四川师范大学
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Priority to CN201310736589.7A priority Critical patent/CN103757389A/en
Publication of CN103757389A publication Critical patent/CN103757389A/en

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    • 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
    • Y02PCLIMATE CHANGE MITIGATION TECHNOLOGIES IN THE PRODUCTION OR PROCESSING OF GOODS
    • Y02P10/00Technologies related to metal processing
    • Y02P10/20Recycling

Abstract

The invention provides a leaching method of a lithium cobaltate waste battery positive electrode material, which comprises the following steps: adding a positive electrode material subjected to roasting pretreatment separated from lithium cobaltate waste batteries and cocoanut shell flour into a pressure-resistant sulfuric-acid/nitric-acid-corrosion-resistant reaction kettle, adding a sulfuric acid-nitric acid mixed solution, and carrying out agitation leaching under sealed conditions.

Description

The leaching method of anode material of waste LiCoO battery

Technical field

The present invention relates to a kind of leaching method of anode material of waste LiCoO battery.

Background technology

Cobalt acid lithium battery is the widely used battery of a class, and this battery will produce a large amount of refuse batteries after using and scrapping.Because this class battery contains plurality of heavy metal, if abandon into environment, will environment be produced to very large direct and potential hazard.Anode material of waste LiCoO battery is mainly containing cobalt, lithium, copper and aluminium, and wherein cobalt, lithium and copper three's total content is greater than 60%, has very much a recovery value.The technique that reclaims at present cobalt, lithium and copper from anode material of waste LiCoO battery mainly contains thermal process and wet processing.The product that thermal process obtains is alloy material, cobalt, lithium and copper that very difficult acquisition is purer.Wet processing becomes more readily available purer cobalt, lithium and copper.Leaching is a requisite process in wet processing.The leaching method of anode material of waste LiCoO battery mainly contains hydrochloric acid leaching process, sulfuric acid leaching, nitric acid lixiviation process and nitration mixture (sulfuric acid adds nitric acid) lixiviation process at present.Hydrochloric acid leaching process, equipment corrosion is large, the large and contaminate environment of acid mist generation.The reductive agent (as hydrogen peroxide etc.) that sulfuric acid leaching consumption is more expensive.The nitric acid consumption of nitric acid lixiviation process is large, and can produce a large amount of oxynitride, contaminate environment.All there is the problem that improves how economically leaching velocity, raising metal leaching rate, reduces acid consumption and other supplementary product onsumption in all wet processings.Although nitric acid processing industry pure oxygen lixiviation process and nitration mixture processing industry pure oxygen lixiviation process have solved the problems referred to above preferably, but leaching plant is more complicated, and the required industrial pure oxygen amount of refuse battery leaching is little, refuse battery is processed enterprise, and manufacture pure oxygen is personal uneconomical on the spot, and the storage of industrial pure oxygen, transportation and use are cumbersome.Development equipment corrosion is little, leaching velocity is fast, leaching yield is high, acid consumes and other supplementary product onsumption is low, easy to use, the leaching method of the anode material of waste LiCoO battery of basic non-environmental-pollution has larger practical value.

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Summary of the invention

The problem leaching for current anode material of waste LiCoO battery, the object of the invention is to find a kind of metal leaching rate high, leaching velocity is fast, leaching yield is high, acid consumption and other supplementary product onsumption are low, easy to use, need not expensive reductive agent, the leaching method of the anode material of waste LiCoO battery of basic non-environmental-pollution, it is characterized in that by positive electrode material isolated from waste LiCoO battery and that obtain through roasting pretreatment and≤coconut shell powder of 1.5mm adds withstand voltage, in the reactor of resistance to sulfuric acid and nitric acid corrosion, the mixing solutions that adds sulfuric acid and nitric acid, and carry out in confined conditions agitation leach.After leaching finishes, carry out liquid-solid separation, obtain required infusion solution.Temperature of reaction is 60 ℃~80 ℃, and the sulfuric acid starting point concentration of leaching is 1mol/L~4mol/L, and the starting point concentration of nitric acid is that 5g/L~10g/L extraction time is 2h~4h, and leaching process stirs, and stirring velocity is 30r/min~120r/min.Sulphuric acid is to add 110%~140% of sulfuric acid theoretical consumption that in the positive electrode material of reaction vessel, all metals leach.The add-on of coconut shell powder is counted LiCoO in positive electrode material with butt 290%~120% of quality.

The object of the present invention is achieved like this: airtight and have under the condition that coconut shell powder and nitric acid exists, (cobalt in material and lithium exist with cobalt acid lithium form the anode material of waste LiCoO battery of sulfuric acid leaching after roasting pretreatment, copper and aluminium are mainly metal oxide form) time, there is following main chemical reactions in leaching process:

CuO?+?H 2SO 4?=?CuSO 4?+?H 2O

Al 2O 3?+?3H 2SO 4?=?3Al 2(SO 4) 3?+?3H 2O

nC 6H 10O 5?+?nH 2SO 4?=n(C 5H 11O 5)HSO 4

n(C 5H 11O 5)HSO 4?+?nH 2O?=?nC 6H 12O 6?+?nH 2SO 4

C 6H 12O 6?+?8HNO 3?=?8NO?+?6CO 2?+?10H 2O

nC 6H 10O 5?+?8nHNO 3?=?8nNO?+?6nCO 2?+?9nH 2O

6LiCoO 2?+?9H 2SO 4?+?2NO?=?6CoSO 4?+?3Li 2SO 4?+?2HNO 3?+?8H 2O

The total reaction of cobalt acid lithium is:

24nLiCoO 2?+?nC 6H 10O 5?+?36nH 2SO 4?=?24nCoSO 4?+?12nLi 2SO 4?+?6nCO 2?+?41nH 2O

Other organism in coconut shell powder also generates NO, CO with nitric acid reaction 2and H 2o, the NO of generation and LiCoO 2and H 2sO 4by previous reaction, generate CoSO 4, Li 2sO 4, HNO 3and H 2o.

Because the speed of response of nitric acid and coconut shell powder is very fast, the NO of generation and LiCoO 2reaction also very fast, accelerate thus whole leaching process, and realize LiCoO 2leach more completely.NO can thoroughly destroy the laminate structure of high oxide in positive electrode material, improves the leaching yield of valuable metal.

With respect to existing method, outstanding advantages of the present invention is to adopt coconut shell powder to make reductive agent, and nitric acid is made to leach accelerator and leached anode material of waste LiCoO battery, speed of response is fast, such as reaction acidity is lower, and the consumption of sulfuric acid and reductive agent is little, and coconut shell powder is cheap; In positive electrode material, the laminate structure of high oxide is destroyed thoroughly, can improve metal leaching rate; In leach liquor subsequent disposal, do not need to neutralize a large amount of acid, cost is lower; The waste amount producing in leach liquor subsequent disposal is few, has reduced pollution abatement costs, has obvious economic benefit and environmental benefit; Process is carried out in confined conditions, the environmental pollution of having avoided NO to overflow and produce.

specific implementation method

embodiment 1: 100g anode material of waste LiCoO battery (is contained to cobalt 53.6%, lithium 5.3%, copper 8.2%, aluminium 3.4%) and≤to add volume be in the lining titanium pressure reaction still of 2L to 1.5mm coconut shell powder 30g, adding sulfuric acid concentration is the mixed acid solution 1180ml that 1.5mol/L, concentration of nitric acid are 5g/L, at 60 ℃~70 ℃, 4.0h is leached in airtight stirring (stirring velocity 80r/min), after leaching finishes, carry out liquid-solid separation, obtain 1150ml infusion solution (not containing leached mud washing water).The leaching yield of cobalt, lithium, copper and aluminium be respectively 99.1%, 99.2%, 99.0% and 98.6%(by entering cobalt in infusion solution and leached mud washings, lithium, copper and aluminium, calculate).

Embodiment 2: 500g anode material of waste LiCoO battery (is contained to cobalt 53.6%, lithium 5.3%, copper 8.2%, aluminium 3.4%) it is in the lining titanium pressure reaction still of 5L that≤1.5mm coconut shell powder 190g adds volume, adding sulfuric acid concentration is 3.0mol/L, concentration of nitric acid is the mixed acid solution 3500ml of 10g/L, at 70 ℃~80 ℃, 2h is leached in airtight stirring (stirring velocity 70r/min), after finishing, leaching carries out liquid-solid separation, obtain 3300ml infusion solution (not containing leached mud washing water), cobalt, lithium, the leaching yield of copper and aluminium is respectively 99.2%, 99.5%, 99.0% and 98.8%(by the cobalt entering in infusion solution and leached mud washings, lithium, copper and aluminium calculate).

Claims (1)

1. the leaching method of an anode material of waste LiCoO battery, it is characterized in that by positive electrode material isolated from waste LiCoO battery and that obtain through roasting pretreatment and≤coconut shell powder of 1.5mm adds withstand voltage, in the reactor of resistance to sulfuric acid and nitric acid corrosion, the mixing solutions that adds sulfuric acid and nitric acid, and carry out in confined conditions agitation leach, after finishing, leaching carries out liquid-solid separation, obtain required infusion solution, temperature of reaction is 60 ℃~80 ℃, the sulfuric acid starting point concentration leaching is 1mol/L~4mol/L, the starting point concentration of nitric acid is that 5g/L~10g/L extraction time is 2h~4h, leaching process stirs, stirring velocity is 30r/min~120r/min, sulphuric acid is to add 110%~140% of sulfuric acid theoretical consumption that in the positive electrode material of reaction vessel, all metals leach, the add-on of coconut shell powder is counted LiCoO in positive electrode material with butt 290%~120% of quality.
CN201310736589.7A 2013-12-29 2013-12-29 Leaching method of lithium cobaltate waste battery positive electrode material CN103757389A (en)

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Citations (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN101928831A (en) * 2009-06-23 2010-12-29 四川师范大学 Leaching method of anode material of lithium cobalt oxide waste battery
CN102030375A (en) * 2010-10-29 2011-04-27 北京矿冶研究总院 Method for preparing lithium cobaltate by directly using invalid lithium ion battery

Patent Citations (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN101928831A (en) * 2009-06-23 2010-12-29 四川师范大学 Leaching method of anode material of lithium cobalt oxide waste battery
CN102030375A (en) * 2010-10-29 2011-04-27 北京矿冶研究总院 Method for preparing lithium cobaltate by directly using invalid lithium ion battery

Non-Patent Citations (1)

* Cited by examiner, † Cited by third party
Title
李进中等: ""氧化锰矿还原浸出工艺技术研究进展"", 《中国锰业》, vol. 29, no. 4, 28 November 2011 (2011-11-28), pages 1 - 7 *

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