CN109461928A - A kind of high-energy density polynary positive pole material and preparation method thereof - Google Patents

Abstract

The present invention provides a kind of high-energy density polynary positive pole material and preparation method thereof, and it is Li that the positive electrode, which is by chemical formula,_1+a[(Ni_1‑2x Co _x Mn _x )_1‑y M _y ]_1‑zM′ _z O₂Matrix and be coated on the Li on described matrix surface₈ZrO₆With lithium ion conductor Li _u M″ _v O _w Composition, wherein -0.5≤a≤0.3, M and M ' are at least one of La, Cr, Mo, Ca, Fe, Hf, Ti, Zn, Y, Zr, Si, W, Nb, Sm, V, Mg, B, Al element, M " is at least one of Zr, Ti, Al, Si, Mn, Sn element；Composite oxides coat 0.01~3% that total amount is matrix mole.Positive electrode of the invention energy density with higher and cyclical stability, can be used for lithium-ion-power cell.The preparation method simple process and low cost of the material is suitable for large-scale production.

Description

A kind of high-energy density polynary positive pole material and preparation method thereof

Technical field

The present invention relates to a kind of high-energy density polynary positive pole material and preparation methods, belong to lithium ion battery technology neck Domain.

Background technique

High-energy is developed in raising along with people to demands such as electronic product cruise duration, electric car course continuation mileages The lithium ion battery of density becomes the urgent need of Vehicles Collected from Market.In lithium ion battery, the superiority and inferiority of positive electrode performance is determined The characteristics of performance of battery entirety, wherein multicomponent material is due to high voltage, height ratio capacity is considered most promising One of anode material of lithium battery.With the increase of nickel content, the nonactive remaining lithium on surface gradually increases multicomponent material, seriously Influence the performances such as capacity, the multiplying power of multicomponent material；Particle internal fissure, material dusting etc. are easy to happen in high voltage charge and discharge process Problem causes its cycle performance to reduce rapidly.Boundary can be effectively reduced by constructing lithium ion conductor clad on the surface of the material Face impedance increases lithium ion tunnel, inhibits to improve the chemical properties such as capacity, multiplying power, circulation with the side reaction between electrolyte. However, lithium ion conductor usually requires to synthesize in advance as clad in previous research and patent report, on the one hand prepared Journey is more complicated, on the other hand can not solve the problems, such as that the nonactive remaining lithium of material surface reduces material capacity, high rate performance.

Chinese patent CN107706390A discloses the lithium ion of a kind of fast-ionic conductor and the dual modification of conducting polymer The preparation method of battery polynary positive pole material, oxide is first passed through in patent or acid reacts generation fast-ionic conductor with hydroxide Then product is mixed simultaneously high-temperature calcination by finished product with ternary material again, obtain the multicomponent material of fast-ionic conductor cladding.The party Method preparation process is complicated, and required sintering temperature is higher.

Chinese patent CN105789565A discloses a kind of Li₂ZrO₃And Li₄ZrO₄Coated lithium ion battery is lithium-rich manganese-based just The preparation method of pole material.By Zr (OC in patent₄H₉)₄ZrO is obtained using hydro-thermal method after mixing with positive electrode material precursor₂Packet Then it is obtained Li with lithium salts mixed sintering by the anode material precursor covered₂ZrO₃And Li₄ZrO₄The positive electrode of cladding leads to The cladding of peroxychromic acid lithium effectively improves the cycle performance of sample.But the yield of hydro-thermal method is lower, the requirement to equipment is high, and The source organic matter Zr higher cost used in the patent, therefore can not large-scale application.

Summary of the invention

For above-mentioned problems of the prior art, the present invention provides a kind of high-energy density nickel-cobalt-manganese multi anode material There is the Li with electro-chemical activity in material and preparation method, nickel-cobalt-manganese multi material surface clad provided by the invention₈ZrO₆, And other lithium ion conductors.Wherein Li₈ZrO₆It is all hexagonal crystal system with nickel-cobalt-manganese multi positive electrode, is being higher than 4.0V voltage Lower there are the deintercalations of lithium ion, and when occurring two lithium ion deintercalations in molecule, charging and discharging capacity can achieve 220mAh/ g；Interface impedance of the battery in charge and discharge process can be effectively reduced in other lithium ion conductors in clad, constructs lithium ion Channel, the ingredient in above-mentioned clad can make material have preferable high rate performance and higher energy density.

The present invention also provides the preparation method of above-mentioned metal hydroxides presoma and positive electrode, simple process, processes It is easy stability contorting, production cost is low, is suitable for large-scale industrial production.

To achieve the goals above, the invention adopts the following technical scheme:

High-energy density polynary positive pole material provided by the invention, including matrix and the combined oxidation for being coated on described matrix surface Object clad；The chemical formula of described matrix is Li_1+a[(Ni_1-2x Co _x Mn _x )_1-y M _y ]_1-zM′ _z O₂, wherein -0.5≤a≤1.3,0.05 ≤x≤ 0.3,0≤y≤ 0.01,0≤z≤ 0.01, the clad includes Li₈ZrO₆It is Li with chemical formula _u M″ _v O _w Composite oxygen Compound, wherein 0≤u≤ 8,1≤v≤ 5,2≤w≤ 12, M and M ' be La, Cr, Mo, Ca, Fe, Hf, Ti, Zn, Y, Zr, Si, W, At least one of Nb, Sm, V, Mg, B, Al element, M " are at least one of Zr, Ti, Al, Si, Mn, Sn, W element；

The composite oxides clad is fine and close or un-densified；The amount of the substance of clad accounts for the 0.01~3% of matrix.

The average grain diameter D of the high-energy density polynary positive pole material₅₀It is 5~20 μm.

Preferably, the Li _u M″ _v O _w For LiAl₅O₈、LiAlO₂、Li₅AlO₄、Li₂SiO₃、Li₂Si₂O₅、Li₄SiO₄、 Li₂SnO₃、Li₂TiO₃、Li₄TiO₄、Li₄Ti₅O₁₂、Li₂ZrO₃、Li₆Zr₂O₇、Li₈ZrO₆、Li₄ZrO₄At least one of.

The present invention also provides the preparation methods of above-mentioned high-energy density polynary positive pole material, comprising the following steps:

(1) salt solution of nickel, cobalt, manganese and doped chemical is obtained into the mixing salt solution of 1~3mol/L；By sodium hydroxide It is dissolved into the aqueous slkali that concentration is 4~10mol/L；The enveloping agent solution for being 2~10mol/L at concentration by ammonia solvent.It will mix Closing salting liquid, aqueous slkali, enveloping agent solution, cocurrent is added in reaction kettle and is reacted together, is kept stirring in the process, simultaneously Control pH value in reaction and reaction temperature, precursor pulp obtained obtain spherical shape after separation of solid and liquid, washing, drying, screening Nickel cobalt manganese hydroxide (Ni_1-2x Co _x Mn _x )_1-y M _y (OH)₂；

(2) (the Ni for obtaining step (1)_1-2x Co _x Mn _x )_1-y M _y (OH)₂Be uniformly mixed with the oxide of lithium salts, M ', in air or In oxygen atmosphere, 4~20h is calcined at 600~1000 DEG C, by broken, screening, obtains anode material for lithium ion battery base Body Li_1+a[(Ni_1-2x Co _x Mn _x )_1-y M _y ]_1-zM′ _z O₂；

(3) by ZrO₂, the oxide of M ", lithium salts and the positive electrode matrix carry out mechanical mixture, then mixture is put into In Muffle furnace, it is heat-treated 0.5~12h in 450~800 DEG C of temperature ranges, is made by Li₈ZrO₆And lithium ion conductor Li _u M″ _v O _w The polynary positive pole material of composite oxides cladding；

- 0.5≤a≤1.3,0.05≤x≤ 0.3,0≤y≤ 0.01,0≤z≤ 0.01,0≤u≤ 8,1≤v≤ 5,2≤w ≤ 12, M and M ' are that at least one of La, Cr, Mo, Ca, Fe, Hf, Ti, Zn, Y, Zr, Si, W, Nb, Sm, V, Mg, B, Al are first Element, M " are at least one of Zr, Ti, Al, Si, Mn, Sn, W element.

Preferably, the oxide of the M ', M " oxide particle average grain diameter D₅₀For 1~50nm, specific surface area is greater than 10m²/g。

Preferably, the oxide of the M ', M " oxide be HfO₂、TiO₂、Y₂O₃、ZrO₂、SiO₂、W₂O₃、Nb₂O₅、 Sm₂O₃、V₂O₅、MgO、Al₂O₃At least one of.

Preferably, step (1) the reaction pH range is 10~13, and temperature is 50~70 DEG C.

Preferably, step (2), (3) described lithium salts are one or both of lithium carbonate, lithium hydroxide.

Preferably, the additional amount of step (2) described lithium salts is molar ratio=0.95~1.3 of Li/ (Ni+Co+Mn+M+M ').

Preferably, step (3) the mixed equipment is ball grinder, Ball-stirring mill, colter mixer, V-type batch mixer, high speed One of mixing machine.

Preferably, step (3) heat-treating atmosphere is air or oxygen, and heat treatment temperature is 500~750 DEG C, the time For 4~10h.

Present invention has the advantage that

(1) the high-energy density nickel-cobalt-manganese multi positive electrode that the present invention obtains has preferable structure in charge and discharge process Stability, cycle performance are excellent.

(2) the high-energy density nickel-cobalt-manganese multi positive electrode that the present invention obtains, after Overheating Treatment, the packet of surface formation Coating contains Li₈ZrO₆, Li₈ZrO₆In the case where being higher than 4.0V voltage with the electro-chemical activity of lithium ion deintercalation, to be obviously improved The capacity of product.

(3) the high-energy density nickel-cobalt-manganese multi positive electrode that the present invention obtains, it is effective by the cladding of composite oxides Reduce the residual non-reactive lithium content and interface impedance of positive electrode particle surface, hence it is evident that improve the forthright again of positive electrode Energy.

(4) preparation method simple process of the present invention, pollution-free.Doped chemical and clad incorporation way are simple, and dosage is few, Heat-treating atmosphere is without particular/special requirement.

Detailed description of the invention

In order to illustrate the technical solution of the embodiments of the present invention more clearly, required use in being described below to embodiment Attached drawing be briefly described, it should be apparent that, drawings in the following description are only some embodiments of the invention, for this For the those of ordinary skill in field, without creative efforts, it can also be obtained according to these attached drawings other Attached drawing.

Fig. 1 is the scanning electron microscope (SEM) photograph of nickel-cobalt-manganese multi positive electrode matrix prepared by comparative example 1.

Fig. 2 is the scanning electron microscope (SEM) photograph of high-energy density nickel-cobalt-manganese multi positive electrode prepared by embodiment 1.

Fig. 3 is the XRD spectrum that comparative example 1, embodiment 1 and embodiment 4 prepare sample.

Fig. 4 is charging and discharging curve figure of the half-cell of comparative example 1, embodiment 1 and the preparation of embodiment 4 at 0.1C.

Fig. 5 is specific discharge capacity figure of the half-cell of comparative example 1, embodiment 1 and the preparation of embodiment 4 under different multiplying.

Fig. 6 is cycle performance figure of the half-cell of comparative example 1, embodiment 1 and the preparation of embodiment 4 at 1C.

Fig. 7 is half-cell AC impedance figure prepared by comparative example 1, embodiment 1 and embodiment 4.

Specific embodiment

With reference to the attached drawing in the embodiment of the present invention, technical solution in the embodiment of the present invention carries out clear, complete Ground description, it is clear that described embodiments are only a part of the embodiments of the present invention, instead of all the embodiments.Based on this The embodiment of invention, every other implementation obtained by those of ordinary skill in the art without making creative efforts Example, belongs to protection scope of the present invention.

Comparative example 1

Step 1: dissolving nickel sulfate, cobaltous sulfate, manganese sulfate to obtain the mixed of 2mol/L according to the ratio of metal molar ratio 3:1:1 Salting liquid is closed, sodium hydroxide is dissolved into the aqueous slkali that concentration is 8mol/L；The complexing for being 6mol/L at concentration by ammonia solvent Agent solution.100L mixing salt solution, aqueous slkali, enveloping agent solution together cocurrent are added in reaction kettle and reacted, process It is constant to be kept stirring revolving speed 120rpm, control pH is 11.5~11.7, and temperature is 60 DEG C, when reaction completion, keeps temperature, stirring Revolving speed is constant, continues to stir 20min, is then separated by solid-liquid separation nickel cobalt manganese hydroxide slurry obtained, washs, filter cake It is sieved after 105 DEG C of drying 5h, obtains spherical nickel cobalt manganese hydroxide.

Step 2: the spherical nickel cobalt manganese hydroxide that step 1 obtains is uniformly mixed with lithium carbonate, wherein lithium carbonate is pressed It is added according to molar ratio Li/ (Ni+Co+Mn)=1.03.Then mixture is calcined 10 hours at 850 DEG C, after broken, screening Obtain average grain diameter D₅₀For 13 μm of nickel-cobalt-manganese multi positive electrode matrix Li_1.03Ni_0.6Co_0.2Mn_0.2O₂.Surface is carried out to it Remaining lithium titration, surface residual lithium content accounts for the 0.2% of matrix as the result is shown.

Step 3: by ZrO₂The positive electrode matrix obtained with step 2 according to 0.2:100 the mass ratio of the material and meanwhile put Enter and carry out dry mixed in ball milling mixing tank, is then placed in Muffle furnace and is heat-treated, 800 DEG C of heating under oxygen atmosphere 10h obtains the nickel-cobalt-manganese multi material of lithium Zirconium oxide cladding.

As shown in Figure 1, the nickel-cobalt-manganese multi positive electrode matrix microscopic appearance prepared in this comparative example is near-spherical particle.

As shown in figure 3, except multicomponent material main phase is special in the nickel-cobalt-manganese multi positive electrode XRD spectrum prepared in this comparative example It levies without other dephasign peaks outside peak, this is because material surface can be with ZrO₂The remaining lithium of reaction is less, the lithium zirconium oxygen of formation Compound content is low, and XRD can not be detected.

Material is assembled into half-cell and carries out electrochemical property test, the electric discharge ratio under 3.0~4.5V, 0.1C multiplying power Capacity is 201.3mAh/g, energy density 905.8Wh/kg.

Comparative example 2

Step 1 and step 2 are consistent with 1 preparation step of comparative example.

Step 3: by ZrO₂, the obtained positive electrode matrix of lithium hydroxide and step 2 according to 0.3:2.2:100 substance Amount ratio simultaneously be put into high speed mixer, mix 15min under the revolving speed of 800rpm, be then placed in Muffle furnace and carry out hot place Reason, 400 DEG C of heating 10h, obtain the nickel-cobalt-manganese multi material of zirconium cladding after being sieved in air atmosphere.

Since heat treatment temperature is lower, the ingredient of positive electrode clad is mainly ZrO₂.Material is assembled into half Battery carries out electrochemical property test, and the specific discharge capacity under 3.0~4.5V, 0.1C multiplying power is 198.7 mAh/g, energy Density is 894.2Wh/kg.

Embodiment 1

Step 1 and step 2 are consistent with 1 preparation step of comparative example.

Step 3: by ZrO₂, the obtained positive electrode matrix of lithium hydroxide and step 2 according to 0.5:3.8:100 substance Amount ratio simultaneously be put into high speed mixer, mix 10min under the revolving speed of 1200rpm, be then placed in Muffle furnace carry out heat Processing, 600 DEG C of heating 8h, obtain average grain diameter D in air atmosphere₅₀For 10 μm, clad main component be Li₈ZrO₆Nickel Cobalt-manganese multi material.

As shown in Fig. 2, the positive electrode second particle surface prepared in the present embodiment is uniformly attached with tiny cladding Grain, forms un-densified clad.

As shown in figure 3, except multicomponent material main phase is special in the nickel-cobalt-manganese multi positive electrode XRD spectrum prepared in the present embodiment There is also Li outside sign peak₈ZrO₆Characteristic peak, show there is Li on the surface of the material₈ZrO₆Phase.

As shown in figure 4, the nickel-cobalt-manganese multi positive electrode prepared in the present embodiment, which is assembled into half-cell, carries out electrochemistry Can test, specific discharge capacity under 3.0~4.5V, 0.1C multiplying power is 206.1mAh/g, energy density 927.5Wh/kg, 11.7Wh/kg is improved than 1 sample of comparative example.This is because Li₈ZrO₆It is all hexagonal crystal system with nickel-cobalt-manganese multi positive electrode, In the case where being higher than 4.0V voltage, there are the deintercalations of lithium ion, therefore can significantly improve the discharge capacity and energy density of material.

As shown in figure 5, the nickel-cobalt-manganese multi positive electrode prepared in the present embodiment putting under 3.0~4.5V, 1C multiplying power Electric specific capacity is 192.6mAh/g, improves 9.0mAh/g than 1 sample of comparative example.

As shown in fig. 6, the nickel-cobalt-manganese multi positive electrode prepared in the present embodiment, which is assembled into half-cell, carries out electrochemistry It can test, specific discharge capacity reaches 175.9mAh/g after recycling under 3.0~4.5V, 1C multiplying power 100 weeks, relative to comparative example 1 improves 5.9mAh/g.

As shown in fig. 7, half circular diameter of the nickel-cobalt-manganese multi positive electrode medium-high frequency part prepared in the present embodiment is less than The positive electrode prepared in comparative example 1, this illustrates Li₈ZrO₆Cladding significantly reduces the interface impedance of material.

Embodiment 2

Step 1: nickel sulfate, cobaltous sulfate, manganese sulfate are dissolved to obtain 1.5mol/L's according to the ratio of metal molar ratio 2:1:1 Aluminum sulfate and sodium hydroxide are obtained the aluminium of aluminium ion concentration 0.2mol/L according to molar ratio 1:10 mixed preparing by mixing salt solution Solution；Sodium hydroxide is dissolved into the aqueous slkali that concentration is 5mol/L；Ammonia solvent is molten at the complexing agent that concentration is 2mol/L Liquid.Mixing salt solution, aluminum solutions, aqueous slkali, enveloping agent solution together cocurrent are added in reaction kettle and reacted, process is protected It is constant to hold speed of agitator 115rpm, control pH is 11.8~12.0, and temperature is 55 DEG C, when reaction completion, temperature, stirring is kept to turn Speed is constant, continues to stir 20min, is then separated by solid-liquid separation nickel cobalt manganese aluminium hydroxide slurry obtained, washs, filter cake It is sieved after 110 DEG C of drying 3h, obtains the spherical nickel cobalt manganese hydroxide materials of aluminium element Uniform Doped.

Step 2: the spherical nickel cobalt manganese hydroxide materials for the aluminium element Uniform Doped that step 1 obtains are mixed with lithium carbonate It closes uniformly, wherein lithium carbonate is added according to molar ratio Li/ (Ni+Co+Mn+Al)=0.95.In air atmosphere, 900 DEG C of sintering 8h obtains anode material for lithium ion battery matrix Li by broken, screening_0.95(Ni_0.5Co_0.25Mn_0.25)_0.995Al_0.005O₂。

Step 3: by ZrO₂、TiO₂, the obtained positive electrode matrix of lithium hydroxide and step 2 is according to 0.3:0.2::1.3: 100 the mass ratio of the material is put into high speed mixer simultaneously, is mixed 10min under the revolving speed of 1200rpm, is then placed in Muffle furnace In be heat-treated, 500 DEG C of heating 10h, obtain average grain diameter D in air atmosphere₅₀It is 6 μm, cladding composition of layer contains Li₂ZrO₃、Li₈ZrO₆、Li₄Ti₅O₁₂Nickel-cobalt-manganese multi material.

The nickel-cobalt-manganese multi positive electrode prepared in the present embodiment is assembled into half-cell and carries out electrochemical property test, Specific discharge capacity under 3.0~4.5V, 0.1C multiplying power reaches 180.4mAh/g, energy density 811.8Wh/kg.Under 1C multiplying power Capacity retention ratio after recycling 80 weeks reaches 94.6%.

Embodiment 3

Step 1: nickel sulfate, cobaltous sulfate, manganese sulfate are dissolved to obtain 2.5mol/L's according to the ratio of metal molar ratio 8:1:1 Sodium hydroxide is dissolved into the aqueous slkali that concentration is 6mol/L, the network for being 6mol/L at concentration by ammonia solvent by mixing salt solution Mixture solution.Mixing salt solution, aqueous slkali, enveloping agent solution together cocurrent are added in reaction kettle and reacted, process is protected It is constant to hold speed of agitator 125rpm, control pH is 11.9~12.1, and temperature is 65 DEG C, when reaction completion, temperature, stirring is kept to turn Speed is constant, continues to stir 20min, is then separated by solid-liquid separation nickel cobalt manganese hydroxide slurry obtained, washs, filter cake 120 DEG C drying 4h after sieve, obtain spherical nickel cobalt manganese hydroxide materials.

Step 2: the spherical nickel cobalt manganese hydroxide materials that step 1 is obtained and Nano-sized Alumina Powder, nano-silica Change titanium powder to mix according to the ratio of molar ratio (Ni+Co+Mn): Al: Ti=99:0.4:0.6.By above-mentioned mixture again with Lithium hydroxide is uniformly mixed, and wherein lithium hydroxide is added according to molar ratio Li/ (Ni+Co+Mn+Al+Ti)=1.25.In oxygen gas In atmosphere, 750 DEG C of sintering 16h obtain anode material for lithium ion battery matrix Li by broken, screening_1.25 (Ni_0.8Co_0.1Mn_0.1)_0.99Al_0.004Ti_0.006O₂。

Step 3: by ZrO₂, the obtained positive electrode matrix of lithium hydroxide and step 2 according to 0.2:1.4:100 mole Than simultaneously be put into high speed mixer, mix 15min under the revolving speed of 1000rpm, be then placed in Muffle furnace and be heat-treated, The lower 700 DEG C of heating 1h of oxygen atmosphere, obtains average grain diameter D₅₀Contain Li for 15 μm, clad₈ZrO₆、Li₆Zr₂O₇Compound nickel Cobalt-manganese multi material.

The compound nickel-cobalt-manganese multi positive electrode prepared in the present embodiment is assembled into half-cell and carries out electrochemical property test, Its specific discharge capacity under 3.0~4.5V, 0.1C multiplying power reaches 220.3mAh/g, energy density 991.3Wh/kg.

Embodiment 4

Step 1 is consistent with 1 preparation step of comparative example.

Step 2: the spherical nickel cobalt manganese hydroxide materials that step 1 is obtained and nano oxidized hafnium powder, nano oxidized Zirconium powder is mixed according to the ratio of molar ratio (Ni+Co+Mn): Hf:Zr=99:0.4:0.6.By above-mentioned mixture again with carbonic acid It is uniformly mixed, wherein lithium hydroxide is added according to molar ratio Li/ (Ni+Co+Mn+Hf+Zr)=1.03.In oxygen atmosphere, 750 DEG C sintering 16h obtains anode material for lithium ion battery matrix Li by broken, screening_1.03(Ni_0.6Co_0.2Mn_0.2)_0.99Hf_0.004Zr_0.006O₂。

Step 3: by ZrO₂, the obtained positive electrode matrix of lithium hydroxide and step 2 it is same according to the molar ratio of 1:3:100 When be put into dry ball mill mixing tank, ball milling mixing 4 hours under the revolving speed of 100rpm are then placed in Muffle furnace and carry out hot place It manages, heats 10h at 750 DEG C in air atmosphere, obtain average grain diameter D₅₀It is 13 μm, clad contains Li₈ZrO₆、Li₆Zr₂O₇'s Nickel-cobalt-manganese multi material.

As shown in figure 3, except ternary material main phase is special in the nickel-cobalt-manganese multi positive electrode XRD spectrum prepared in the present embodiment There is also Li outside sign peak₈ZrO₆、Li₆Zr₂O₇、Li₂ZrO₃Characteristic peak, show there is Li on the surface of the material₈ZrO₆、Li₆Zr₂O₇、 Li₂ZrO₃Etc. phases.

As shown in figure 4, the nickel-cobalt-manganese multi positive electrode prepared in the present embodiment, which is assembled into half-cell, carries out electrochemistry It can test, the specific discharge capacity under 3.0~4.5V, 0.1C multiplying power is 204.2mAh/g, and energy density reaches 918.9Wh/ kg.One side Li₈ZrO₆Be higher than 4.0V voltage under there are the deintercalations of lithium ion, therefore can be improved material discharge capacity and Energy density；Another aspect Li₆Zr₂O₇、Li₂ZrO₃The interface resistance in battery charge and discharge process is significantly reduced as lithium ion conductor It is anti-, the polarization of material is reduced, and then improve discharge capacity.

As shown in figure 5, the nickel-cobalt-manganese multi positive electrode prepared in the present embodiment putting under 3.0~4.5V, 1C multiplying power Electric specific capacity is 187.8mAh/g, improves 4.2mAh/g than 1 sample of comparative example.

As shown in fig. 6, the nickel-cobalt-manganese multi positive electrode prepared in the present embodiment, which is assembled into half-cell, carries out electrochemistry It can test, specific discharge capacity reaches 180.6mAh/g after recycling under 3.0~4.5V, 1C multiplying power 100 weeks, relative to comparative example 1 improves 10.8 mAh/g, and capacity retention ratio improves 3.7%.Higher heat treatment temperature can make material surface gradient occur Doping, stabilizes the structure of material, and then improve its capacity retention ratio.

As shown in fig. 7, half circular diameter of the nickel-cobalt-manganese multi positive electrode medium-high frequency part prepared in the present embodiment is less than The positive electrode prepared in comparative example 1, this illustrates Li₈ZrO₆、Li₆Zr₂O₇、Li₂ZrO₃Cladding significantly reduces the interface of material Impedance.

The surface residual lithium content of material carries out titration test by potentiometric titrimeter in above-mentioned comparative example.

The microscopic appearance of material passes through scanning electron microscopy measurement in above-described embodiment and comparative example.

The electrochemical AC impedance of material is measured by electrochemical workstation in above-described embodiment and comparative example.

Positive active material in above-described embodiment and comparative example has carried out electric property assessment to it by the following method.

The assembling of button cell:

Firstly, by the compound nickel-cobalt-manganese multi positive active material of non-aqueous electrolyte secondary battery, acetylene black and gathering inclined difluoro Ethylene (PVDF) is mixed according to mass ratio 95%:2.5%:2.5%, coated on aluminium foil and drying and processing is carried out, uses 100Mpa Pressure punch forming be diameter 12mm, thick 120 μm of anode pole piece, then anode pole piece is put into 120 in vacuum drying box DEG C drying 12h.

Cathode is 17mm using diameter, with a thickness of the Li sheet metal of 1mm；The polyethylene porous that diaphragm uses with a thickness of 25 μm Film；Electrolyte uses the LiPF of 1mol/L₆, ethylene carbonate (EC) and diethyl carbonate (DEC) equivalent mixed liquor.

Anode pole piece, diaphragm, cathode pole piece and electrolyte are respectively less than to the Ar gas gloves of 5ppm in water content and oxygen content 2025 type button cells are assembled into case, using battery at this time as unactivated battery.

It is placed for 24 hours after production button cell, after open-circuit voltage is stablized, cut-off electricity is charged to using the current density of 20mA/g 4.3V is pressed, in 4.3V constant-voltage charge to cut-off current 0.024mA.Blanking voltage is then discharged to same current density 3.0V is repeated in a manner described once, using battery at this time as active cell.

The performance evaluation of button cell is as follows:

(1) high rate performance test: 25 DEG C of temperature, using active cell, in the voltage range of 3.0~4.5V, respectively with 0.1C, The current density of 0.2C, 1C, 2C, 5C recycle the high rate performance of 1 investigation material.

(2) cycle performance is tested: 25 DEG C of temperature, using active cell, in the voltage zone of 3.0~4.4V, 3.0~4.5V Between, the cycle performance of material is investigated under the current density of 1C.

(3) unactivated battery, within the scope of 0.1Hz~100kHz test frequency, 5mV AC impedance performance test: are used Ac impedance measurement is carried out under amplitude.

The foregoing is only a preferred embodiment of the present invention, but scope of protection of the present invention is not limited thereto, Within the technical scope of the present disclosure, any changes or substitutions that can be easily thought of by anyone skilled in the art, It should be covered by the protection scope of the present invention.Therefore, protection scope of the present invention should be with the protection model of claims Subject to enclosing.

Claims (10)

1. a kind of high-energy density polynary positive pole material, it is characterised in that: including matrix and be coated on answering for described matrix surface Close oxide cladding layers；The chemical formula of described matrix is Li_1+a[(Ni_1-2x Co _x Mn _x )_1-y M _y ]_1-zM′ _z O₂, wherein -0.5≤a≤ 0.3, 0.05≤x≤ 0.3,0≤y≤ 0.01,0≤z≤ 0.01, the clad includes Li₈ZrO₆It is Li with chemical formula _u M″ _v O _w Composite oxides, wherein 0≤u≤ 8,1≤v≤ 5,2≤w≤ 12, M and M ' be La, Cr, Mo, Ca, Fe, Hf, Ti, Zn, Y, At least one of Zr, Si, W, Nb, Sm, V, Mg, B, Al element, M " are at least one of Zr, Ti, Al, Si, Mn, Sn, W member Element；

High-energy density polynary positive pole material according to claim 1, it is characterised in that: the composite oxides clad It is fine and close or un-densified；The amount of the substance of clad accounts for the 0.01~3% of matrix.

2. high-energy density polynary positive pole material according to claim 1, it is characterised in that: the high-energy density is polynary The average grain diameter D of positive electrode₅₀It is 5~20 μm.

3. high-energy density polynary positive pole material according to claim 1, it is characterised in that: the Li _u M″ _v O _w For LiAl₅O₈、LiAlO₂、Li₅AlO₄、Li₂SiO₃、Li₂Si₂O₅、Li₄SiO₄、Li₂SnO₃、Li₂TiO₃、Li₄TiO₄、Li₄Ti₅O₁₂、 Li₂ZrO₃、Li₆Zr₂O₇、Li₈ZrO₆、Li₄ZrO₄At least one of.

4. a kind of preparation method of high-energy density polynary positive pole material, it is characterised in that the following steps are included:

(1) salt solution of nickel, cobalt, manganese and doped chemical is obtained into the mixing salt solution of 1~3mol/L；By sodium hydroxide It is dissolved into the aqueous slkali that concentration is 4~10mol/L；The enveloping agent solution for being 2~10mol/L at concentration by ammonia solvent.

It reacts 5. mixing salt solution, aqueous slkali, enveloping agent solution together cocurrent are added in reaction kettle, keeps in the process Stirring, while pH value in reaction and reaction temperature are controlled, precursor pulp obtained is by separation of solid and liquid, washing, drying, screening Afterwards, spherical nickel cobalt manganese hydroxide (Ni is obtained_1-2x Co _x Mn _x )_1-y M _y (OH)₂；

(2) (the Ni for obtaining step (1)_1-2x Co _x Mn _x )_1-y M _y (OH)₂Be uniformly mixed with the oxide of lithium salts, M ', in air or In oxygen atmosphere, 4~20h is calcined at 600~1000 DEG C, by broken, screening, obtains anode material for lithium ion battery matrix Li_1+a[(Ni_1-2x Co _x Mn _x )_1-y M _y ]_1-zM′ _z O₂；

(3) by ZrO₂, the oxide of M ", lithium salts and the positive electrode matrix carry out mechanical mixture, mixture is then put into horse Not in furnace, it is heat-treated 0.5~12h in 450~800 DEG C of temperature ranges, is made by Li₈ZrO₆And lithium ion conductor Li _u M″ _v O _w It is multiple Close the polynary positive pole material of oxide cladding；

- 0.5≤a≤1.3,0.05≤x≤ 0.3,0≤y≤ 0.01,0≤z≤ 0.01,0≤u≤ 8,1≤v≤ 5,2≤w ≤ 12, M and M ' are that at least one of La, Cr, Mo, Ca, Fe, Hf, Ti, Zn, Y, Zr, Si, W, Nb, Sm, V, Mg, B, Al are first Element, M " are at least one of Zr, Ti, Al, Si, Mn, Sn, W element.

6. the preparation method of high-energy density polynary positive pole material according to claim 5, it is characterised in that: the M's ' Oxide, M " oxide particle average grain diameter D₅₀For 1~50nm, specific surface area is greater than 10m²/g。

7. the preparation method of high-energy density polynary positive pole material according to claim 5, it is characterised in that: the M's ' Oxide, M " oxide be HfO₂、TiO₂、Y₂O₃、ZrO₂、SiO₂、W₂O₃、Nb₂O₅、Sm₂O₃、V₂O₅、MgO、Al₂O₃In extremely Few one kind.

8. the preparation method of high-energy density polynary positive pole material according to claim 5, it is characterised in that: the reaction PH range is 10~13, and temperature is 50~70 DEG C.

9. the preparation method of high-energy density polynary positive pole material according to claim 5, it is characterised in that: step (2) The additional amount of the lithium salts is molar ratio=0.95~1.3 of Li/ (Ni+Co+Mn+M+M ').

10. the preparation method of high-energy density polynary positive pole material according to claim 5, it is characterised in that: step (3) The heat-treating atmosphere is air or oxygen, and heat treatment temperature is 500~750 DEG C, and the time is 4~10h.