CN105914366A - Method for preparing spinel lithium-rich lithium manganate coated with boron oxide - Google Patents

Method for preparing spinel lithium-rich lithium manganate coated with boron oxide Download PDF

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CN105914366A
CN105914366A CN201610523419.4A CN201610523419A CN105914366A CN 105914366 A CN105914366 A CN 105914366A CN 201610523419 A CN201610523419 A CN 201610523419A CN 105914366 A CN105914366 A CN 105914366A
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lithium
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童庆松
郭可可
赵南南
游帅帅
王蕾
彭建明
张贵萍
王彤
李秀华
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Fujian Normal University
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    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01MPROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
    • H01M4/00Electrodes
    • H01M4/02Electrodes composed of, or comprising, active material
    • H01M4/36Selection of substances as active materials, active masses, active liquids
    • H01M4/48Selection of substances as active materials, active masses, active liquids of inorganic oxides or hydroxides
    • H01M4/50Selection of substances as active materials, active masses, active liquids of inorganic oxides or hydroxides of manganese
    • H01M4/505Selection of substances as active materials, active masses, active liquids of inorganic oxides or hydroxides of manganese of mixed oxides or hydroxides containing manganese for inserting or intercalating light metals, e.g. LiMn2O4 or LiMn2OxFy
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01MPROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
    • H01M10/00Secondary cells; Manufacture thereof
    • H01M10/05Accumulators with non-aqueous electrolyte
    • H01M10/052Li-accumulators
    • H01M10/0525Rocking-chair batteries, i.e. batteries with lithium insertion or intercalation in both electrodes; Lithium-ion batteries
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01MPROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
    • H01M4/00Electrodes
    • H01M4/02Electrodes composed of, or comprising, active material
    • H01M4/13Electrodes for accumulators with non-aqueous electrolyte, e.g. for lithium-accumulators; Processes of manufacture thereof
    • H01M4/139Processes of manufacture
    • H01M4/1391Processes of manufacture of electrodes based on mixed oxides or hydroxides, or on mixtures of oxides or hydroxides, e.g. LiCoOx
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01MPROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
    • H01M4/00Electrodes
    • H01M4/02Electrodes composed of, or comprising, active material
    • H01M4/36Selection of substances as active materials, active masses, active liquids
    • H01M4/362Composites
    • H01M4/366Composites as layered products
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01MPROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
    • H01M4/00Electrodes
    • H01M4/02Electrodes composed of, or comprising, active material
    • H01M4/36Selection of substances as active materials, active masses, active liquids
    • H01M4/48Selection of substances as active materials, active masses, active liquids of inorganic oxides or hydroxides
    • H01M4/483Selection of substances as active materials, active masses, active liquids of inorganic oxides or hydroxides for non-aqueous cells
    • 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
    • Y02EREDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
    • Y02E60/00Enabling technologies; Technologies with a potential or indirect contribution to GHG emissions mitigation
    • Y02E60/10Energy storage using batteries

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  • Chemical Kinetics & Catalysis (AREA)
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  • General Chemical & Material Sciences (AREA)
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Abstract

The invention relates to a method for preparing spinel lithium-rich lithium manganate coated with boron oxide. The method comprises the following steps: mixing spinel lithium-rich lithium manganate with a chemical formula of LixMnyOz with diboron trioxide or boric acid according to a weight ratio of 1:0.001 to 0.01, and preparing a precursor by wet grinding and drying steps; sintering the precursor in a temperature interval of 350-390 DEG C to prepare the spinel lithium-rich lithium manganate coated with the boron oxide. According to the invention, the costs of the raw materials are relatively low, and the prepared electrode material has excellent high current discharge performance at high temperature and storage conditions, thereby laying a good foundation for industrialization.

Description

The preparation method of the spinel lithium-rich LiMn2O4 of the oxide of Boron Coated
Technical field
The invention belongs to technical field prepared by battery electrode material, relate to one can be used for lithium battery, lithium ion battery, In polymer battery and ultracapacitor, the preparation method of the spinel lithium-rich LiMn2O4 of the oxide of Boron Coated.
Technical background
Lithium ion battery have cell voltage height, energy density height, memory-less effect, have extended cycle life, self discharge is low Advantage, the performance of positive electrode plays a part decision to the performance of lithium ion battery.
The advantages such as it is low that manganese-based anode material has price, green non-pollution, are the research emphasis of lithium ion battery.At manganio In positive electrode, that studies more has spinelle LiMn2O4, stratiform LiMnO2With layed solid-solution positive electrode.Wherein, layer Shape LiMnO2The less stable of structure when discharge and recharge, studies seldom at present.Spinelle LiMn2O4Can be 4V and 3V two Voltage range plays a role.The voltage platform correspondence lithium ion in the 4V district embedding in the tetrahedron 8a position of spinel structure and de- Go out;The embedding in the octahedra 16c position of spinel structure of the voltage platform correspondence lithium ion in 3V district and abjection.Lithium ion is at point The tetrahedral site of spinel structure embeds and deviates from not result in the significant change of structure.But, when depth of discharge is excessive, sample The structure of product can occur John-Teller to distort, and embeds and deviates from lithium ion structure can be caused by cube becoming in octahedron Four directions, discharge capacity rapid decay.Therefore, suppression spinelle LiMn2O4The John-Teller distortion of structure is to improve its charge and discharge The key of electrical property.Additionally, LiMn2O4Middle manganese is dissolved in electrolyte, and during high voltage discharge and recharge, the decomposition of electrolyte is also shadow Ring the key reason of electrode material cycle performance.
At Li4Mn5O12Charge and discharge process in, the deintercalation of lithium ion reaction mainly occurs in 3V district, and its theoretical discharge holds Amount is up to 163mAh/g.With spinelle LiMn2O4The theoretical capacity ratio of 148mAh/g be significantly improved, have that to become 3V district excellent The probability of elegant positive electrode.This material structure cell expansion rate in charge and discharge process is less, has the advantages such as cycle performance is outstanding. But, Li4Mn5O12Heat stability bad.Li under high temperature1+yMn2-yO4(y < 0.33) is easily decomposed to LiMn2O4With Li2MnO3[Manthiram A., et al., Ceram.Trans, 1998,92:291-302.], makes Li4Mn5O12It is difficult to Prepare with conventional method.Have studied multiple synthetic method, it is intended to obtain more preferably preparation method.Including solid-phase sintering Method, sol-gal process, hydro-thermal method and microwave sintering method etc..
Solid sintering technology is the compound mixing of the compound by lithium and manganese, sintering preparation under aerobic or oxygen free condition. Takada etc. [Takada T., J. Solid State Chem., 1997,130:74-80.] are by lithium salts (LiNO3、 Li2CO3、Li(CH3) and manganese compound (MnCO COO)3、Mn(NO3)2、Mn2O3And MnO2) mixing, 500 DEG C of-800 DEG C of humidity provinces Between prepare Li4Mn5O12.Kang etc. [Kang S. H., et al., Electrochem. Solid-State Lett., 2000,3 (12): 536-639.] and Fumio etc. [Fumio S., et al., J. Power Sources, 1997,68 (2): 609-612.] LiOH H first it is dried2O and Mn (Ac)2·4H2The mixed solution of O, prepares Li then at 500 DEG C of sintering [LiyMn2-y]O4.Li [the Li that they prepareyMn2-y]O4The sample discharge capacity in 3V district is 115-126mAh/g.At oxygen gas In atmosphere, Takada etc. [Takada T., et al., J. Power Sources, 1997,68:613-617.] finds, 500 DEG C of sintering CH3COOLi and Mn (NO3)2Fused mass prepare product the 1st circulation discharge capacity be 135mAh/g. Shin etc. [Shin Y., et al., Electrochim. Acta, 2003,48 (24): 3,583 3592.] think sintering When temperature is less than 500 DEG C, Mn3+Amount increase make discharge capacity increase.[Kajiyama A., the et al., J. such as Kajiyama Japan Soc. Powder & Powder Metallurgy, 2000,47 (11): 1139-1143; Nakamura T. Et al., Solid State Ionics, 1999,25:167-168.] by LiOH H2O and γ-Mn2O3Mixing, they Find, the Li of preparation in oxygen atmosphere4Mn5O12Chemical property better than prepare at air atmosphere.[the Xu such as Xu Meihua M. H., et al., J. Phys. Chem, 2010,114 (39): 16,143 16147.] and Tian etc. [Tian Y., Et al., Chem. Commun., 2007:2072 2074.] by MnSO4Add LiNO3And NaNO3Fuse salt in, 470 DEG C of-480 DEG C of temperature ranges can prepare nanometer Li4Mn5O12.Tian etc. [Tian Y., et al., Chem. Commun., 2007:2072 2074.] the nano wire Li for preparing4Mn5O12Putting that (under 0.2C multiplying power electric current) the 1st circulation and the 30th circulate Capacitance is respectively 154.3mAh/g and 140mAh/g.Thackeray etc. [Thackeray M. M, et al., J. Solid State Chem., 1996,125:274-277.;Michael M., et al., American Ceram. Soc. Bull, 1999,82 (12): 3347-3354.] by LiOH H2O and γ-MnO2Mixing, 600 DEG C of sintering can prepare Li4Mn5O12.Yang etc. [Yang X., et al., J. Solid State Chem., 2000,10:1903-1909.] By γ-MnO2Or β-MnO2Or barium manganese ore or acid birnessite and melted LiNO3Mixing, prepares at 400 DEG C Li1.33Mn1.67O4.Liu Cong [Liu Cong. the synthesis of lithium ion battery mangaic acid lithium cathode material and performance [D]. Guangdong: south China is pedagogical University, 2009.] first by LiOH H2O and electrolysis MnO2Dehydrated alcohol mixes, in 450 DEG C of sintering in air atmosphere, then Ball milling obtains sample in ethanol.The high discharge capacity of the sample that they prepare is 161.1mAh/g, the electric discharge of the 30th circulation Capacity is higher than 120mAh/g.
Kim etc. [Kim J., et al., J. Electrochem. Soc, 1998,145 (4): 53-55.] exist LiOH and Mn (CH3COO)2Mixed solution in add Li2O2, first prepare LixMnyOz·nH2O, then filter, wash, be dried Li is prepared with solid-phase sintering4Mn5O12.They find, the initial discharge capacity of the sample of 500 DEG C of preparations is 153mAh/g, and 40 follow The capacity attenuation rate of ring is 2%.Manthiram etc. [Manthiram A., et al., J. Chem. Mater, 1998,10 (10): 2895-2909.] research shows, in LiOH solution, and Li2O2Initial oxidation [Mn (H2O)6]2+, then through 400 DEG C of sintering, The Li of preparation4Mn5O12Discharge capacity in the 1st circulation is 160mAh/g.
In order to improve the process conditions of solid-phase sintering, double sintering method is used for preparation process.[the Li righteous army such as Li righteous army Deng, non-ferrous metal, 2007,59 (3): 25-29.] by LiOH, Mn (C2O4)2And H2C2O4Mixture be placed in air atmosphere In, prepare micron Li at 350 DEG C and 500 DEG C of sintering respectively4Mn5O12.The sample of preparation in the discharge capacity of the 1st circulation is 151mAh/g.Gao etc. [Gao J., et al., Appl. Phys. Lett., 1995,66 (19): 2487-2489.; Gao J., et al., J. Electrochem. Soc., 1996,143 (6): 1783-1788.] use two step heatings It is prepared for spinelle Li1+xMn2-xO4x(0<x≤0.2).[Robertson A. D., et al., the J. such as Robertson Power Sources, 2001,97-97:332-335.] at Mn (CH3COO)2·4H2O solution is mixed into Li2CO3, it is dried and obtains Obtain precursor.It is prepared for Li respectively at 250 DEG C and 300-395 DEG C of sintering4Mn5O12.Sample the 1st circulation and the electric discharge of the 50th circulation Capacity is respectively 175mAh/g and 120mAh/g.Wang etc. [Wang G. X., et al., J. Power Sources, 1998,74 (2): 198-201.] Li has been synthesized at 380 DEG C4Mn5O12.Xia [Xia Y. Y., et al., J. Power Sources, 1996,63 (1): 97-102.] etc. by injection method, sample is prepared at 260 DEG C of direct sinterings.At C/3 electric current Under, the discharge capacity first of this sample is 80mAh/g.
More than research shows, solid sintering technology prepares Li4Mn5O12Need to be at pure O2Or air atmosphere is carried out.This method Shortcoming includes that the composition of synthetic product and particle size distribution are relatively big, and the capacity attenuation rate of charge and discharge cycles is high, heavy-current discharge performance The best, high temperature cyclic performance is more undesirable.
In order to improve the uniformity of sample, reducing the granularity of sample particle, sol-gal process is used for preparing Li4Mn5O12 [Hao Y. J., et al., J. Solid State Electrochem., 2009,13:905 912;Meng Lili etc., Inorganic chemicals industry, 2009,46 (5): 37-39;Chu H. Y., et al., J. Appl. Electrochem, 2009, 39: 2007-2013.].Can feelings etc. [can feelings etc., battery, 2004,34 (3): 176-177.] by LiOH 2H2O、Mn (CH3COO)2·4H2The mixture of O and citric acid prepares micron spinelle Li at 300 DEG C and 500 DEG C sintering respectively4Mn5O12
In order to improve the uniformity of sample, reducing the granularity of sample particle, reduce sintering temperature, hydro-thermal method is also used for system Standby process.Zhang [Zhang Y. C., et al., Mater. Res. Bull., 2002,37 (8): 1411-1417.; Zhang Yongcai. hydro-thermal studies [D] with solvent-thermal process metastable phase functional material. Beijing: Beijing University of Technology, 2003.; Zhang Y. C., et al., J. Solid State Ionics, 2003,158 (1): 113-117.] etc. first by H2O2、 LiOH and Mn (NO3)2Mixed solution reaction prepare threadiness presoma LixMnyOz·nH2O, then with LiOH solution low-temperature hydrothermal Reaction prepares nanometer Li4Mn5O12.Generation superfine [generation is superfine. a kind of synthesis Li4Mn5O12The method [P] of sub-micrometer rod. CN 201010033605.2, applying date 2010.01.04.] and by MnSO4·H2O、KMnO4With mixing of cetyl trimethylammonium bromide Compound prepares submicron MnOOH 140 DEG C-180 DEG C temperature range hydro-thermal reactions, is blended into LiOH H2O, finally in 500 DEG C- 900 DEG C of prepared Li4Mn5O12.Sun Shuying etc. [Sun Shuying etc., inorganic material Leader, 2010,25 (6): 626-630.] pass through Hydro-thermal reaction, by MnSO4·H2O and (NH4)2S2O8Prepare nanometer β-MnO2, it is mixed into LiNO3After again by low-temperature solid-phase method reaction system Obtain Li4Mn5O12
Due to microwave sintering method, to have sintering velocity fast, the advantages such as sintering process is easy, and microwave sintering method or solid-phase sintering- The method that microwave sintering combines is used for synthesizing LiMn2O4.[Ahniyaz A., et al., the J. Eng. such as Ahniyaz Mater. Technol., 2004,264-268:133-136.] by γ-MnOOH, LiOH and H2O2Mixture pass through microwave Sintering process has synthesized LiMn2O4.Tong Qingsong seminar is with LiOH and Mn (CH3COO)2For raw material [woods element English etc., Fujian chemical industry, 2004,2:1-4.;Tong Qingsong etc., electrochemistry, 2005,11 (4): 435-439.] or with LiOH and MnC2O4[virgin for raw material Celebrating pine etc., Fujian Normal University's journal, 2006,22 (1): 60-63.], with disodium EDTA (EDTA) and lemon Lemon acid is chelating agent, uses microwave-solid phase double sintering method, is prepared for spinelle Li at 380 DEG C3.22Na0.569Mn5.78O12Sample Product or Li4Mn5O12Positive electrode.Research shows, at 4.5-2.5V voltage range, the Li of preparation3.22Na0.569Mn5.78O12Sample Discharge capacity in the 1st circulation is 132mAh/g, and the capacity attenuation rate of 100 circulations is 6.8%.Through 4 months deposit, this sample Product initial discharge capacity is 122mAh/g, and the capacity attenuation rate of 100 circulations is 17.4%.
Guo Junming etc. [Guo Junming etc., functional material, 2006,37:485-488.] with lithium nitrate and manganese nitrate (or with Lithium acetate and manganese acetate) it is raw material, make fuel with carbamide, use liquid-phase combustion legal system to obtain Li4Mn5O12.They find, acetate The Li of system synthesis4Mn5O12The height that synthesizes compared with nitrate system of thing phase purity.Kim etc. [Kim H. U., et al., Phys. Scr, 2010,139:1-6.] find, with by liquid phase synthesis approach in the samples of 400 DEG C of sintering with trace Mn2O3.Under 1C multiplying power electric current, the discharge capacity of sample the 1st circulation is 44.2mAh/g.Zhao etc. [Zhao Y., et al., Electrochem. Solid-State Lett., 2010,14:1509 1513.] use the synthesis of water-in-oil microemulsion method Nano spinel Li4Mn5O12
Spinel lithium-rich Li prepared due to said method4Mn5O12The structural stability of charge and discharge process is the highest, exists low The problems such as temperature discharge performance, high temperature cyclic performance and heavy-current discharge performance are poor.Used Surface coating, add high polymer, The method of Doped anions or cation is modified.
In order to improve Li4Mn5O12Cycle performance, Liu Cong [Liu Cong, the synthesis of lithium ion battery mangaic acid lithium cathode material and Performance, South China Normal University's academic dissertation, 2009.] predecessor of polyvinylpyrrolidonesolution solution with 450 DEG C of preparations is mixed, Respectively through hydro-thermal K cryogenic treatment, application of vacuum, it is dried and oxygen atmosphere process at 100 DEG C, prepares Li4Mn5O12.Research table Bright, under 0.5C multiplying power electric current, sample is respectively 137mAh/g and 126mAh/ in the discharge capacity of the 1st circulation and the 50th circulation g。
In order to improve spinelle Li further4Mn5O12Performance, used cation and anion doped method to improve sample The performance of product.Such as, Zhang etc. [Zhang D. B., et al., J. Power Sources, 1998,76:81- 90.] with CrO2.65、Li(OH)·H2O and MnO2For raw material, respectively at 300 DEG C and 450 DEG C sintering in oxygen atmosphere, it is prepared for Li4CryMn5-yO12(y=0,0.3,0.9,1.5,2.1).Research shows, at 0.25mA/cm2Under electric current, Li4Cr1.5Mn3.5O12Sample Product are respectively 170mAh/g and 152Ah/g in the discharge capacity of the 1st circulation and the 100th circulation.[the Robertson such as Robertson A. D., et al., J. Power Sources, 2001,97-97:332-335.] at Mn (CH3COO)2·4H2O and Co (CH3COO)2·4H2O mixed solution is initially charged Li2CO3, prepare precursor, after drying respectively at 250 DEG C and 430-440 DEG C of burning Knot, prepares Li4-xMn5-2xCo3xO12Sample.This sample the 1st circulation and the 50th circulation discharge capacity be respectively 175mAh/g and 120mAh/g.With Li4Mn5O12Compare, during charge and discharge cycles, Li4-xMn5-2xCo3xO12Structure more stable.Wherein, Li3.75Mn4.5Co0.075O12Discharge capacity in the 1st circulation is 150mAh/g, and the capacity attenuation rate of 50 circulations is close to 0%.Choi etc. [Choi W., et al., Solid State Ionics, 2007,178:1541-1545.] is by LiOH, LiF and Mn (OH)2Mixing, prepares Li respectively at 500 DEG C and 600 DEG C of double sinterings in air atmosphere4Mn5O12−ηFη(0≤η≤0.2).Its In, under 0.2C multiplying power electric current, the Li of 500 DEG C of preparations4Mn5O11.85F0.1Discharge capacity in the 1st circulation is 158mAh/g.? At 25 DEG C and 60 DEG C after discharge and recharge 50 circulation, the capacity attenuation rate of this sample is respectively 2.9% and 3.9%, illustrates at high temperature and low Initial discharge capacity and the cycle performance of the lower fluorine doped sample of temperature are improved.In recent years, Tong Qingsong seminar is at doping rich lithium point Spar Li4Mn5O12Series of studies work has been carried out in field, uses slurry mixing, is dried, prepares in conjunction with double sintering technical process Mix nickel richness lithium-spinel Li4Mn5O12(patent of invention 201310618022X), mix the rich lithium-spinel of tetravalence rare earth ion Li4Mn5O12(patent of invention 201310624811.4), mix gadolinium richness lithium-spinel Li4Mn5O12(patent of invention 2013106246161.1), mix yttrium richness lithium-spinel Li4Mn5O12(patent of invention 201310624942.2), to mix zirconium richness lithium point brilliant Stone Li4Mn5O12(patent of invention 201310624867.X), mix the rich lithium-spinel Li of monovalent ion4Mn5O12(patent of invention 201310617973.5), mix the rich lithium-spinel Li of bivalent cation4Mn5O12(patent of invention 201310618294.X), mix The rich lithium-spinel Li of titanic ion4Mn5O12(patent of invention 2013106246195), mix the rich lithium-spinel of vanadium Li4Mn5O12(patent of invention 201310617989.6), mix the rich lithium-spinel Li of stannum4Mn5O12(patent of invention 201310618248.X) etc. series of patents.These patented methods significantly improve the heavy-current discharge of rich lithium-spinel LiMn2O4 The voltage platform that performance or the cycle performance of sample or sample are discharged, improves the chemical property of sample in different aspects.
Although above-mentioned preparation method can improve the chemical property of sample, but, the spinelle Li of preparation at present4Mn5O12 When discharge and recharge, the stability of structure is the most bad, has that discharge performance under the conditions of low temperature and heavy-current discharge is poor, high temperature circulation The problems such as performance substantially decay.To this end, the present invention uses the method at spinel lithium-rich lithium manganate particle Surface coating insoluble matter, Stop contacting of electrolyte and spinel lithium-rich LiMn2O4 sample particle to a certain extent, improve sample and at high temperature and deposit bar Charge-discharge performance under part.The method that in document, the most useful cladding improves battery material performance.But, put down as a kind of voltage Platform is positioned at the lithium ion battery material in 3V district, lithium ion embed in the structure of lithium ion battery material and the passage deviate from not With.Knowable to industry general knowledge: the performance of anode material for lithium-ion batteries is by its structure, the process conditions that form and prepare certainly Fixed.Lithium ion battery is dependent on lithium ion and moves work between a positive electrode and a negative electrode.In charge and discharge process, Li+At positive pole Middle embedding and abjection.The positive electrode of different structure, lithium ion embeds different with the passage deviate from the structure, therefore, different The positive electrode of structure is diverse positive electrode (even if its chemical composition, as identical in chemistry skeleton symbol), by cladding side Method is improved the performance tool of the lithium ion battery material in 3V district and is had an unexpected effect, and making originally cannot be in field of lithium ion battery The battery material of application is possibly realized application.And compared with other battery material, this battery material has wide material sources, preparation The sintering temperature of the more usual lithium ion battery material of temperature is much lower, and the battery material of preparation is for preparing the painting blade technolgy of battery core Simply wait remarkable advantage.
Summary of the invention
For avoiding the deficiencies in the prior art, the present invention by being coated with on the surface of spinel lithium-rich lithium manganate particle, Improve sample charge-discharge performance under high temperature and storage condition.Be the technical scheme is that by realizing the purpose of the present invention
Li will be consisted ofxMnyOzSpinel lithium-rich LiMn2O4 powder and covering powder according to weight ratio 1:0.001~0.01 Mixing, adds 1 times of wet grinding media to 25 times of volumes of total solid capacity, mixes 3 hours~15 hours with wet milling device wet grinding, Prepare predecessor 1.By predecessor 1 constant pressure and dry, be vacuum dried or be spray-dried preparation be dried predecessor 2.By forerunner Thing 2 is placed in air, oxygen-enriched air or pure oxygen atmosphere, 350 DEG C~390 DEG C temperature ranges arbitrary temperature sinter 3 hours~ 24 hours, naturally cool to room temperature, prepare the spinel lithium-rich LiMn2O4 of the oxide of Boron Coated.
Here x, y and z meets relationship below simultaneously: 3.8≤x≤4.3,4.8≤y≤5.3, z=(x + 4y)/2。
Described covering is diboron trioxide or boric acid;The D50 particle diameter of described covering granule is in 1~200 nanometers In the range of.
Described constant pressure and dry is arbitrary temperature that predecessor 1 is placed in 140 DEG C~230 DEG C temperature ranges, at 1 air Pressure is dried, and prepares predecessor 2.Described vacuum drying is arbitrary temperature that predecessor 1 is placed in 80 DEG C~230 DEG C temperature ranges Degree, is dried under arbitrary pressure of 10Pa~10132Pa pressure range, prepares predecessor 2.Described spray drying is Predecessor 1 is placed in arbitrary temperature of 130 DEG C~230 DEG C temperature ranges, is dried with spray dryer, prepare predecessor 2.
Described wet grinding media is deionized water or distilled water.
Described oxygen-enriched air is that oxygen volume content more than 21% and is less than the air between 100%.
Described wet milling device includes general milling machine, super ball mill or wet milk.The industry conventional wisdom indicate that, D50 table The cumulative particle sizes percentile of sample product reaches particle diameter corresponding when 50%.Its physical significance be particle diameter be more than D50 Grain accounts for 50%, and the granule less than D50 also accounts for 50%, and D50 is also meso-position radius or median particle diameter.D50 is commonly used to represent the average of powder body Granularity.
Compared with other inventive method, the cost of material of the present invention is relatively low, and raw material sources are extensive, and preparation process is simple, system Standby electrode material composition uniformly, improves sample at high temperature and the charge-discharge performance under depositing, lays for industrialization good Basis.
Accompanying drawing explanation
Fig. 1 is the XRD diffraction pattern of the JCPDS card of the sample prepared by the embodiment of the present invention 1 and correspondence.Fig. 2 is this Sample prepared by bright embodiment 1 is at the graph of relation of 300mA/g electric current discharge capacity Yu period.Fig. 3 is the present invention Sample prepared by embodiment 1 is the discharge curve of the 1st circulation under 300mA/g electric current.
Detailed description of the invention
Below in conjunction with embodiment, the present invention is further detailed.Embodiment is only supplementing further the present invention With explanation rather than the restriction to invention.
Embodiment 1
It is Li by chemical composition4Mn5O12The diboron trioxide that spinel lithium-rich LiMn2O4 powder and D50 particle diameter are 100 nanometers Powder is mixed with mixture according to weight ratio 1:0.03, adds the distilled water of 18 times of volumes of the total solid capacity of mixture, Mix 9 hours with super ball mill wet grinding, prepare predecessor 1.Predecessor 1 is placed in 190 DEG C and 900 Pa vacuum under pressure are done Dry, prepare predecessor 2.Predecessor 2 is placed in the oxygen-enriched air atmosphere of oxygen volume content 50%, sinters 9 hours at 390 DEG C, Naturally cool to room temperature, prepare the spinel lithium-rich LiMn2O4 of the oxide of Boron Coated.
Compared with other inventive method, preparation process of the present invention is simple, and the sample of preparation has outstanding charge and discharge cycles Performance and storing performance, lay a good foundation for industrialization.
Embodiment 2
It is Li by chemical composition4.3Mn5.3O12.75Spinel lithium-rich LiMn2O4 powder and D50 particle diameter are 1 nanometer three oxidations two Boron powder is that 1:0.06 is mixed with mixture according to weight ratio, adds the distillation of 25 times of volumes of the total solid capacity of mixture Water, mixes 15 hours with wet milk wet grinding, prepares predecessor 1.Predecessor 1 is dried at 80 DEG C and 10Pa vacuum under pressure, system Standby predecessor 2.Predecessor 2 is placed in the oxygen-enriched air atmosphere of oxygen volume content 99%, sinters 24 hours at 360 DEG C, natural It is cooled to room temperature, prepares the spinel lithium-rich LiMn2O4 of the oxide of Boron Coated.
Compared with other inventive method, preparation process of the present invention is simple, and the sample of preparation has outstanding charge and discharge cycles Performance and storing performance, lay a good foundation for industrialization.
Embodiment 3
It is Li by chemical composition3.8Mn4.8O11.5Spinel lithium-rich LiMn2O4 powder and D50 particle diameter are 10 nanometers three oxidations two Boron powder is that 1:0.001 is mixed with mixture according to weight ratio, add the total solid capacity of mixture 1 times of volume go from Sub-water, mixes 3 hours with general milling machine wet grinding, prepares predecessor 1.By predecessor 1 under 230 DEG C and 10132Pa pressure true Empty dry, prepare predecessor 2.Predecessor 2 is placed in the oxygen-enriched air atmosphere of oxygen volume content 22%, sinters 3 at 350 DEG C Hour, naturally cool to room temperature, prepare the spinel lithium-rich LiMn2O4 of the oxide of Boron Coated.
Compared with other inventive method, preparation process of the present invention is simple, and the sample of preparation has outstanding charge and discharge cycles Performance and storing performance, lay a good foundation for industrialization.
Embodiment 4
It is Li by chemical composition3.8Mn5.3O12.5Spinel lithium-rich LiMn2O4 powder and D50 particle diameter are 50 nanometers three oxidations two Boron powder is that 1:0.005 is mixed with mixture, going of 25 times of volumes of the total solid capacity of addition mixture according to weight ratio Ionized water, mixes 3 hours with super ball mill wet grinding, prepares predecessor 1.Predecessor 1 is placed at 130 DEG C, with spray drying Machine is dried, and prepares predecessor 2.Predecessor 2 is placed in the oxygen-enriched air atmosphere that oxygen volume content is 99%, at 385 DEG C Sinter 24 hours, naturally cool to room temperature, prepare the spinel lithium-rich LiMn2O4 of the oxide of Boron Coated.
Compared with other inventive method, the preparation process of the present invention is simple, and the electrode material of preparation has outstanding charge and discharge Electricity cycle performance and storing performance, lay a good foundation for industrialization.
Embodiment 5
It is Li by chemical composition4Mn5O12The boric acid powder that spinel lithium-rich LiMn2O4 powder and D50 particle diameter are 70 nanometers according to Weight ratio 1:0.01 is mixed with mixture, adds the deionized water of 5 times of volumes of the total solid capacity of mixture, uses wet milk Wet grinding mixes 8 hours, prepares predecessor 1.Predecessor 1 is placed at 230 DEG C, is dried with spray dryer, prepare predecessor 2. Predecessor 2 is placed in air atmosphere, sinters 3 hours at 380 DEG C, naturally cool to room temperature, prepare the oxide of Boron Coated Spinel lithium-rich LiMn2O4.
Compared with other inventive method, preparation process of the present invention is simple, and the electrode material of preparation has outstanding discharge and recharge Cycle performance and storing performance, lay a good foundation for industrialization.
Embodiment 6
It is Li by chemical composition3.8Mn5O11.975The boric acid powder that spinel lithium-rich LiMn2O4 powder and D50 particle diameter are 100 nanometers End is that 1:0.01 is mixed with mixture according to weight ratio, adds the deionization of 18 times of volumes of the total solid capacity of mixture Water, mixes 15 hours with general milling machine wet grinding, prepares predecessor 1.Predecessor 1 normal pressure under 140 DEG C and 1 atmospheric pressure is done Dry, prepare predecessor 2.Predecessor 2 is placed in pure oxygen atmosphere, sinters 24 hours at 380 DEG C, naturally cool to room temperature, prepare The spinel lithium-rich LiMn2O4 of the oxide of Boron Coated.
Compared with other inventive method, preparation process of the present invention is simple, and the electrode material of preparation has outstanding discharge and recharge Cycle performance and storing performance, lay a good foundation for industrialization.
Embodiment 7
It is Li by chemical composition4Mn5.1O12.2The boric acid powder that spinel lithium-rich LiMn2O4 powder and D50 particle diameter are 1 nanometer by It is that 1:0.009 is mixed with mixture according to weight ratio, adds the distilled water of 2 times of volumes of the total solid capacity of mixture, with super Ball mill wet grinding can mix 3 hours, prepare predecessor 1.Predecessor 1 is placed in constant pressure and dry under 200 DEG C and 1 atmospheric pressure, system Standby predecessor 2.Predecessor 2 is placed in the oxygen-enriched air atmosphere of oxygen volume content 70%, sinters 3 hours at 350 DEG C, natural It is cooled to room temperature, prepares the spinel lithium-rich LiMn2O4 of the oxide of Boron Coated.
Compared with other inventive method, preparation process of the present invention is simple, and the electrode material of preparation has outstanding discharge and recharge Cycle performance and storing performance, lay a good foundation for industrialization.

Claims (5)

1. the preparation method of the spinel lithium-rich LiMn2O4 of the oxide of Boron Coated, it is characterised in that preparation process is by following steps Composition: Li will be consisted ofxMnyOzSpinel lithium-rich LiMn2O4 powder and covering powder according to weight ratio 1:0.001~0.01 Mixing, adds 1 times of wet grinding media to 25 times of volumes of total solid capacity, mixes 3 hours~15 hours with wet milling device wet grinding, Prepare predecessor 1;By predecessor 1 constant pressure and dry, be vacuum dried or be spray-dried preparation be dried predecessor 2;By forerunner Thing 2 is placed in air, oxygen-enriched air or pure oxygen atmosphere, 350 DEG C~390 DEG C temperature ranges arbitrary temperature sinter 3 hours~ 24 hours, naturally cool to room temperature, prepare the spinel lithium-rich LiMn2O4 of the oxide of Boron Coated;
Here x, y and z meets relationship below simultaneously: 3.8≤x≤4.3,4.8≤y≤5.3, and z=(x+ 4y)/2;
Described covering is diboron trioxide or boric acid.
The preparation method of the spinel lithium-rich LiMn2O4 of the oxide of Boron Coated the most according to claim 1, its feature exists It is arbitrary temperature that predecessor 1 is placed in 140 DEG C~230 DEG C temperature ranges in described constant pressure and dry, does at 1 atmosphere pressure Dry, prepare predecessor 2;Described vacuum drying is arbitrary temperature that predecessor 1 is placed in 80 DEG C~230 DEG C temperature ranges, It is dried under arbitrary pressure of 10Pa~10132Pa pressure range, prepares predecessor 2;Described spray drying is by front Drive thing 1 and be placed in arbitrary temperature of 130 DEG C~230 DEG C temperature ranges, be dried with spray dryer, prepare predecessor 2.
The preparation method of the spinel lithium-rich LiMn2O4 of the oxide of Boron Coated the most according to claim 1, its feature exists It is deionized water or distilled water in described wet grinding media;The D50 particle diameter of described covering granule is in 1~200 nanometer range In.
The preparation method of the spinel lithium-rich LiMn2O4 of the oxide of Boron Coated the most according to claim 1, its feature exists It is that oxygen volume content more than 21% and is less than the air between 100% in described oxygen-enriched air.
The preparation method of the spinel lithium-rich LiMn2O4 of the oxide of Boron Coated the most according to claim 1, its feature exists General milling machine, super ball mill or wet milk is included in described wet milling device.
CN201610523419.4A 2016-07-06 2016-07-06 Method for preparing spinel lithium-rich lithium manganate coated with boron oxide Pending CN105914366A (en)

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