CN1681145A - Negative electrode active material and use of secondary lithium battery - Google Patents
Negative electrode active material and use of secondary lithium battery Download PDFInfo
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- CN1681145A CN1681145A CNA200410030990XA CN200410030990A CN1681145A CN 1681145 A CN1681145 A CN 1681145A CN A200410030990X A CNA200410030990X A CN A200410030990XA CN 200410030990 A CN200410030990 A CN 200410030990A CN 1681145 A CN1681145 A CN 1681145A
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- active material
- lithium battery
- battery cathode
- secondary lithium
- cathode active
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Classifications
-
- Y—GENERAL 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
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02E—REDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
- Y02E60/00—Enabling technologies; Technologies with a potential or indirect contribution to GHG emissions mitigation
- Y02E60/10—Energy storage using batteries
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- Battery Electrode And Active Subsutance (AREA)
Abstract
The invention has a grain structure with an outer shell and several inner cores. The grain size is from 100 nanometers to 100 microns. The inner cores are compound grain that includes active substance and conducting additive. The outer shell is a carbon layer. The active substance takes 20-95wt% of total cathode active material, and is mixture of one or several transition metallic compound selected from silicon and lithium storage whose thermodynamic equilibrium potential is less than 1.5v. The cathode material can be made by using mechanical process or thermal method, and can be directly used as cathode material or used with other existing cathode material.
Description
Technical field
The present invention relates to a kind of negative material of lithium battery, particularly relate to a kind of secondary lithium battery cathode active material and purposes of being used for.
Background technology
In the secondary lithium battery cathode active material, the theoretical specific capacity of lithium metal is 3830mAh/g, and is therefore the highest as the serondary lithium battery energy density of negative active core-shell material with lithium metal.But dendritic growth appears in metal serondary lithium battery negative pole in charge and discharge process, make internal short-circuit of battery, causes battery burning even blast.In order to improve its fail safe, arrive late nineteen eighties at early seventies, lithium alloys such as lithium aluminium, lithium silicon, lithium lead, lithium tin, lithium cadmium once were used to the substituted metal lithium and made negative active core-shell material, though this has been avoided the dendritic growth problem to a certain extent, but these alloys are meeting efflorescence gradually in the repeated charge process, it is the dimension instability, cause the variation that electrically contacts between alloy particle and the collector and between the alloy particle, cause battery performance to degenerate even lost efficacy (document [1]: A Bolahanmu, electrochemistry communication, 138 volumes, 1233 pages, 1993).
In 1980, Armand (M.Armand) proposes serondary lithium battery can adopt " rocking chair type " battery system (" lithium ion " battery afterwards was otherwise known as), be that the both positive and negative polarity active material all adopts embedding compound (intercalationcompounds), this compounds can be reversible storage and exchange lithium ion, thereby avoid using lithium metal or lithium alloy.Typical negative material such as LiWO
2And Li
6Fe
2O
3Deng, but its energy density greatly reduces.Through the effort in 10 years, in March, 1989, Japanese Sony Corporation applied for that employing carbon makes negative active core-shell material, LiCoO
2Make the patent of the serondary lithium battery of positive electrode active materials, and in 1992 at first with its commercialization (document [2]: Bu Lunuo, electrochemistry can will, 139 volumes, 2776 pages, 1992).
From then on, serondary lithium battery begins to develop rapidly.The material with carbon element of various ways such as petroleum coke, carbon fiber, RESEARCH OF PYROCARBON, native graphite, Delanium extensively is elected to be the secondary lithium battery cathode active material.But carbon is 372mAh/g as the theoretical specific capacity of negative active core-shell material, still can not satisfy the further pursuit of people to the high-energy density secondary battery.
Have been found that some transition metal oxide, sulfide, fluoride, for example cuprous oxide and cupric oxide (Cu
2O, CuO), cobalt oxide (CoO, Co
3O
4), iron oxide (Fe
2O
3), nickel oxide (NiO), ruthenium-oxide (RuO
2), cobalt sulfide (CoS
0.89), titanium fluoride (TiF
3), vanadium fluoride (VF
3) can reversible lithium storage, and the reversible lithium storage capacity is up to 400-1000mAh/g (document [3]: P.Poizot, S.Laruelle, S.Grugeon, L.Dupont, J.M.Tarascon, Nature, 407,496 (2000); And document [4]: H.Li, G.Richter, J.Maier, Adv.Mater., 15,736 (2003)).
But show through experiment and Theoretical Calculation, the thermodynamical equilibrium current potential of these material storage lithiums generally is higher than 1.5V, because electrochemical polarization, the actual lithium current potential platform that takes off often is higher than 2 volts, these materials are as the negative material of lithium ion battery, when arranging in pairs or groups with positive electrode, the integral energy density of battery does not significantly improve.Discover the transition metal oxide of having reported, sulfide in addition, the cycle performance of fluoride or nitride is relatively poor, mainly is that the change in volume of active material particle is bigger because the embedding lithium takes off in the lithium process, along with charge and discharge cycles, electrically contact variation gradually between the active material.And the passivating film of particle surface in cyclic process repeatedly the growth come off, this crosses title can consume lithium, causes the battery reversible capacity to descend gradually.In addition, these transition metal oxides, first all efficiency for charge-discharges of fluoride and silicon are all less than 70%.
As document [5]: Li Hong, yellow-study outstanding person, Chen Liquan, a kind of with the serondary lithium battery of the nano silicon-based composite material of disperse phase as active material of positive electrode, disclosed nano silicon-based composite negative pole material among the CN98117759.X, this material forms composite material with nano-silicon and conductive additive physical dispersion, has very high reversible lithium storage capacity (1700mAh/g), but cyclicity and first all coulombic efficiencies relatively poor (65%), main cause is similar to above-mentioned transistion metal compound, and is bigger owing to change in volume in charge and discharge process, with the variation gradually that contacts of conductive additive, and because silicon directly contacts the poor stability of surface passivated membrane in this composite material with electrolyte.
Also the someone proposes by CVD carbon directly to be coated on silicon face recently, the cyclicity of this material and first all coulombic efficiencies are improved really, but the reversible capacity of this material is 800mAh/g, with the theoretical capacity of this composite material (document [6]: M.Yoshio that greatly differs from each other (3200mAh/g), H.Wang, K.Fukud, T.Umeno, N.Dimov, Z.Ogumib, J.Electrochem.Soc, 149, A1598 (2002)).This capacity that shows the silicon of some does not discharge, its main cause is in charge and discharge process, be coated on inner silicon grain efflorescence gradually, electrically contact variation between the silicon grain, so the silicon grain of considerable part is because polarization and do not demonstrate due electro-chemical activity.
Summary of the invention
The objective of the invention is to overcome the defective of existing negative active core-shell material; The cycle performance that overcomes some negative active core-shell material is poor, some is that reversible capacity is low, some is to take off lithium current potential height or the low defective of coulombic efficiency; Thereby provide a kind of can be so that serondary lithium battery has higher charge/discharge capacity and cycle characteristics preferably, and fail safe be used for secondary lithium battery cathode active material and purposes.
The objective of the invention is to realize by the following technical solutions:
The invention provides a kind of secondary lithium battery cathode active material that is used for, it is one to have the particle of " nucleocapsid " structure (be similar to China food " Lantern Festival "), its particle diameter is 100 nanometers~100 micron, and wherein: described " nucleocapsid " structure comprises a kernel and shell; Its kernel is made up of inner composite particles, comprises active material and conductive additive two components, and shell is a carbon-coating.
Described active material accounts for 20~95wt% of the total weight of negative active core-shell material; it is that the thermodynamical equilibrium current potential that is selected from silicon and storage lithium is lower than one or more the mixture in the transistion metal compound of 1.5V; particle diameter is 10 nanometers to 50 micron, and it is the particle of irregular, spheric granules or almost spherical.
The storage lithium mechanism of transistion metal compound is as follows:
The thermodynamical equilibrium current potential of the storage lithium of transistion metal compound is:
E=-(j*Δ
fG(Li
nX)-Δ
fG(M
iX
j)/njF
The transistion metal compound that described storage lithium thermodynamical equilibrium current potential is lower than 1.5V comprises TiO, VO, V
2O
3, VO
2, CrO, Cr
2O
3, Cr
3O
4, Mn
2O
3, MnO, NbO, NbO
2, Nb
2O
5
Described conductive additive is 1~20wt% of the weight of active material, comprises graphite powder, conductive black, acetylene black, carbon nano-tube (Single Walled Carbon Nanotube, multi-walled carbon nano-tubes), carbon fiber, metal powder and metallic fiber; The particle diameter of described graphite powder, conductive black, acetylene black and metal powder is 1 nanometer to 20 micron; The length of described carbon nano-tube, carbon fiber and metallic fiber is 10 nanometers to 20 micron, and diameter is that 10 nanometers are to 500 nanometers.
Described shell carbon-coating be one or more layers, equally distributed continuous carbon film, or carbon granule layer.
The secondary lithium battery cathode active material that is used for provided by the invention can adopt (I) Mechanical Method or (II) Hydrothermal Preparation.
(I) use Mechanical Method to prepare the secondary lithium battery cathode active material that is used for of the present invention, comprise following step:
(1) the inside composite particles of preparation active material and conductive additive even dispersion: the active material (commercially available industrial products) and the conductive additive of the drying of required proportioning are made by one of following method:
With after conductive additive mixes, mechanical ball milling makes a with active material;
B is dispersed in active material and conductive additive in water or the organic solvent (as ethanol) and evenly disperses the back sedimentation by mechanical agitation or ultrasonic agitation, filters, and makes after the oven dry;
C puts into active material in the tube furnace of inert gas (as argon gas, hydrogen, nitrogen) protection and carbon source gas (as ethylene gas, acetylene gas, toluene vapor, benzene vapour etc.), (300~1200 ℃) at a certain temperature, heated 0.5~72 hour, (hereinafter to be referred as CVD) makes by chemical vapour deposition (CVD);
D is dispersed in active material in the emulsion (as the electrically conductive graphite breast) that contains conductive additive, stirs the back filtration drying and makes;
Can obtain active material and the mixed uniformly inner composite particles of conductive additive by said method or other conventional method, or the active material surface is used as the even inside composite particles that covers of CVD carbon-coating of conductive additive.
(2) inner composite particles is dispersed in the presoma of RESEARCH OF PYROCARBON: the inside composite particles that step (1) is made and the organic precursor of carbon containings such as sucrose, starch, glucose, cyclodextrin or yellow starch gum according to a certain ratio (10~0.1: 1) make by one of following method:
A dry grinding: with inner composite particles with directly make after presoma mixes by mechanical lapping;
B wet-milling: in grinding pot, add distilled water or ethanol, or after other can dissolve the organic solvent of above-mentioned presoma, inner composite particles and presoma were used mechanical lapping again;
C is dispersed in inner composite particles in solution, emulsion or the slurries that contain above-mentioned presoma, and solvent evaporated makes;
D or other conventional method;
(3) form pyrolytic carbon layer on inner composite particles surface:
The mixture that step (2) is obtained is (300~1200 ℃) heat treatment 0.5~72 hour in certain temperature range under inert atmosphere (as argon gas, hydrogen, nitrogen), the organic precursor of above-mentioned carbon containing will be converted into RESEARCH OF PYROCARBON, and the surface that is coated on inner composite particles forms pyrolytic carbon layer, obtains the secondary lithium battery cathode active material that is used for of the present invention.It is pointed out that according to the difference of presoma, the weight of the presoma of above-mentioned carbon containing is generally 10~25% of original weight through pyrolysis step.
Use Mechanical Method to prepare the secondary lithium battery cathode active material that is used for of the present invention, also can comprise step (4):
(4) at composite particles surface coverage CVD carbon-coating:
The coating that step (3) is obtained the inside composite particles of pyrolytic carbon layer put into the tube furnace of inert gas (as argon gas, hydrogen, nitrogen) protection and carbon source gas (as organic gass such as methane, ethene, acetylene, benzene or toluene); (300~1200 ℃) at a certain temperature; heated 0.5~72 hour; utilize chemical vapour deposition (CVD) to coat one or more layers CVD carbon-coating again on the surface of the inside composite particles that has coated pyrolytic carbon layer, obtain the secondary lithium battery cathode active material that is used for of the present invention.
After step (3) is handled, what obtain is used for the secondary lithium battery cathode active material, the pattern of the pyrolytic carbon layer of its surface coverage is relevant with the geometric shape of treatment conditions and inner composite particles, it may be the skin covering of the surface that one deck evenly coats, also may be island or certain fluctuating carbon granule layer arranged, its coverage is not very high, and specific area is bigger.Through the further processing of step (4), can form equally distributed continuous carbon film on its surface, covered inner composite particles fully, reduce the specific area of whole composite particles.
Use Mechanical Method to prepare the secondary lithium battery cathode active material that is used for of the present invention, also can be without step (2) (3), directly by step (4), at inner composite particles surface coverage one deck CVD carbon-coating.
It is pointed out that preparation process that is used for the secondary lithium battery cathode active material and preparation method with above-mentioned The Nomenclature Composition and Structure of Complexes feature are not limited to said method.
That uses the preparation of above-mentioned Mechanical Method is used for the secondary lithium battery cathode active material, and the geometry appearance of its active material is irregular amorphous, though the negative active core-shell material that makes thus can directly use, but its bulk density or tap density are not very high.In order further to optimize geometry and control surface composition, it is above-mentioned when being used for the secondary lithium battery cathode active material to use Mechanical Method to prepare, and also comprises step (1-1) before in step (1):
Utilize conventional liquid-phase precipitation method, active material is prepared into sphere or subglobular particle;
Or also comprise step (2-1) afterwards in step (2):
Mechanical again wet-milling obtains subglobose particle after the mixture drying with step (2);
Or also comprise step (3-1) afterwards in step (3):
Composite particles machinery wet-milling with the coating pyrolytic carbon layer of step (3) obtains subglobose particle.
(II) use the Hydrothermal Preparation secondary lithium battery cathode active material that is used for of the present invention, comprise following step:
(1) the inside composite particles of preparation active material and conductive additive even dispersion:
Identical with the step (1) in the Mechanical Method;
(2) at inner composite particles surface hydro-thermal carbon coated layer:
The inside composite particles that step (1) is obtained places a sealed pressure vessel, and insert the aqueous solution of the presoma (as be selected from sucrose, water soluble starch, cyclodextrin, yellow starch gum and the glucose one or more) of carbon containing, the compactedness of this container is 20~95v%, the weight ratio of the inside composite particles that adds and the presoma of carbon containing is 10-0.1: 1, seal this container, be heated to 100~500 ℃, obtain coating the inside composite particles of carbon-coating;
(3) form pyrolytic carbon layer on inner composite particles surface:
Identical with the step (3) in the Mechanical Method; Obtain the secondary lithium battery cathode active material that is used for of the present invention.
Use the Hydrothermal Preparation secondary lithium battery cathode active material that is used for of the present invention, also can comprise step (4):
(4) at composite particles surface coverage CVD carbon-coating: identical with the step (4) in the Mechanical Method.
It is pointed out that preparation process that is used for the secondary lithium battery cathode active material and preparation method with above-mentioned The Nomenclature Composition and Structure of Complexes feature are not limited to said method.
That uses above-mentioned Hydrothermal Preparation is used for the secondary lithium battery cathode active material, because organic precursor charing step in solution is subjected to capillary the influence, form the spherical geometry appearance of approximate circle, therefore need not further to optimize geometry, this also is to use one of above-mentioned advantage that is used for the secondary lithium battery cathode active material of Hydrothermal Preparation.
The invention provides a kind of above-mentioned purposes that is used for the secondary lithium battery cathode active material, this can be used for the secondary lithium battery cathode active material and be directly used in the secondary lithium battery cathode material.
The invention provides the another kind of above-mentioned purposes that is used for the secondary lithium battery cathode active material, this is used for the secondary lithium battery cathode active material mixes with other existing negative material (as graphite) and be used for the secondary lithium battery cathode material, describedly be used for 3~98wt% that the secondary lithium battery cathode active material accounts for total negative material weight.
Provided by the invention have " Lantern Festival " structure be used for the secondary lithium battery cathode active material, the change in volume of inner active material in charge and discharge process is subjected to the inhibition of outer shell pyrolytic carbon layer and CVD carbon-coating, and the buffering of inner conductive additive.And, even crucial part also is active material efflorescence in charge and discharge process, also can keep good electrical contact with the inner conductive additive all the time.In addition, because inner active material is wrapped up by carbon-coating, the growth of surface passivated membrane is only relevant with the carbon of outer shell, and the specific area of this layer significantly reduces owing to covered fine and close CVD carbon-coating, the benefit of bringing like this is growth and the decomposition that passivating film has been avoided on inner active material surface, the passivating film of outer surface can stable growth, and the lithium that consumes is few.Because remarkable change in volume and bigger irreversible capacity loss that inner active material causes all are able to remarkable reduction.By our a large amount of experimental results show that, the above-mentioned secondary lithium battery cathode active material that is used for structure on Lantern Festival has made full use of and has brought into play the big advantage of inner active material lithium storage content, solved the problem of change in volume, solved surface passivated membrane growth problem of unstable, so cyclicity and efficiency for charge-discharge significantly improve.In addition, the material of the inner active material of the conduct that the present invention adopts has the low characteristics of current potential that discharge and recharge, and therefore adopts material of the present invention also to have the high advantage of energy density as the serondary lithium battery of negative active core-shell material preparation.
Provided by the invention when being used for the secondary lithium battery cathode active material and being directly used in the secondary lithium battery cathode material, it is very high to have a reversible capacity, and cyclicity is good, and the high advantage of efficiency for charge-discharge.Mix when being used for the secondary lithium battery cathode material with other existing negative material (as graphite), also can improve the electrochemical properties of this mixing negative material.For example the lithium storage content of graphite is 300~370mAh/g, the reversible capacity of a kind of silica-based composite particles negative material provided by the invention is 2300mAh/g, if these two kinds of materials are simply mixed, when silica-based composite particles negative material accounted for mixing negative material 20wt%, the reversible capacity of this mixing negative material can reach 700mAh/g; When silica-based composite particles negative material accounts for when mixing negative material 5wt%, this reversible capacity that mixes negative material is still up to 450mAh/g, all apparently higher than the lithium storage content of graphite.
Adopt provided by the inventionly when being used for the secondary lithium battery cathode active material, adopt the preparation method of existing general lithium ion battery negative as the secondary lithium battery cathode active material.For example, be used for the secondary lithium battery cathode active material and (its granularity is 1~1000nm as the powder body material of conductive additive with provided by the invention, comprise acetylene black, carbon black, graphite powder etc.) mechanical mixture, the weight ratio that this conductive additive accounts for total electrode material is 0~15wt%, again with general bonding agent, nmp solution as 5% Kynoar, mix at normal temperatures and pressures and make the composite material slurries, it is coated in paper tinsel as the various conductions of collector uniformly, net, porous body, on the carrier of foams or corpus fibrosum material (as Copper Foil, nickel screen, nickel foam, carbon felt etc.).The gained film thickness makes it 100~150 ℃ of oven dry down at 2~20um then, is 0.2~20Mpa/cm at pressure
2Under compress, continue to be cut into different shape by the prepared cell specification and to be negative pole 100~150 ℃ of bakings 12 hours, the preparation method of above-mentioned negative electrode can not be confined to this technology.
The positive electrode active materials of serondary lithium battery of the present invention is the existing positive electrode that is used for serondary lithium battery, can reversibly embed and deviate from the transistion metal compound that contains lithium of lithium, and is typical in LiCoO
2, LiNiO
2, LiMn
2O
4, LiFePO
4, LiNi
1-xCo
xMnO
2Deng, and be not limited to this.Anodal method for making is similar to negative pole, with positive electrode active materials, conductive additive (as acetylene black), binding agent (as the cyclohexane solution of 5% Kynoar), mix to form the composite material slurries in 85: 10: 5 by weight percentage at normal temperatures and pressures, it is coated on the aluminium foil as collector uniformly, the gained film thickness is at 5~40um, 100~150 ℃ of oven dry down, be 0.2~20Mpa/cm then at pressure
2Under compress, continue after the oven dry gained film to be cut into different shape by the prepared cell specification and to be positive pole 100~150 ℃ of bakings 12 hours.
The organic electrolyte solution of serondary lithium battery of the present invention can be added one or more solvable lithium salts by the mixed solvent that a kind of organic solvent or several organic solvent are formed and form.Typical organic solvent is vinyl carbonate (EC:ethylene carbonate) for example, propylene carbonate (PC:propylene carbonate), diethyl carbonate (DEC:diethyl carbonate), dimethyl carbonate (DME:dimethyl carbonate), ethyl-methyl carbonic ester (EMC:ethyl methyl carbonate), dimethoxy-ethane (DME:dimethoxy-ethane) etc., typical solvable lithium salts such as LiClO
4, LiBF
4, LiPF
6, LiCF
3SO
3, LiAsF
6Deng.Typical system such as 1MLiPF
6(EC-DEC volume ratio 1: 1), 1M LiPF
6(EC-DMC volume ratio 3: 7) etc. can also add various functional form additives in above-mentioned electrolyte, biphenyl for example, vinyl carbonic ester (VEC) etc.The selection of electrolyte also can be not limited to this.
The polymer dielectric of serondary lithium battery of the present invention adopts existing serondary lithium battery polymer dielectric, as polyethylene nitrile, LiClO
4, propylene carbonate and vinyl carbonate be with weight ratio 20: 5: 45: 30 mixtures of forming, or the mixture of the copolymer of Kynoar and hexafluoropropylene and lithium hexafluoro phosphate, and be not limited to this.
The barrier film that the barrier film of serondary lithium battery of the present invention is used for existing general serondary lithium battery, as the porous polypropylene barrier film, nonwoven fabrics, and be not limited to this.
The invention provides a kind of serondary lithium battery, its basic structure by contain provided by the invention have " structure on Lantern Festival " be used for the negative pole of secondary lithium battery cathode active material as negative active core-shell material, contain the positive pole of the compound of lithium as positive electrode active materials, organic electrolyte solution or polymer dielectric, barrier film, collector, battery case, compositions such as lead-in wire.Wherein, separate by the barrier film that has soaked organic electrolyte solution or by polymer dielectric between positive pole and the negative pole, positive pole is burn-on respectively to go between with an end of negative pole and is linked to each other with the battery case two ends of mutually insulated.The profile of this serondary lithium battery can make button (individual layer) respectively, column type (multilaminate coiled), and square (multilayer folding), chewing gum type (multilayer folding) etc., and be not limited to this.
Serondary lithium battery of the present invention is applicable to that various mobile electronic devices maybe need the equipment of mobile driven by energy, mobile phone for example, notebook computer, portable video recorder, electronic toy, electric tool, electric automobile, hybrid vehicle, fields such as electric topedo, and be not limited to this.
Compare with the negative material of existing battery, the advantage that is used for the secondary lithium battery cathode active material provided by the invention is: the composite anode active material that the present invention adopts has used the silicon of high lithium storage content or transistion metal compound as the core active material, and adopted special " Lantern Festival " structure, thereby during as secondary lithium battery cathode, it is low to have the current potential of discharging and recharging, the reversible capacity height, and cyclicity is good, safe and reliable, the high remarkable advantage of first all coulombic efficiencies.
Description of drawings
Fig. 1 is the schematic diagram that is used for secondary lithium battery cathode active material " Lantern Festival " structure of the present invention;
Fig. 2 is the charging and discharging curve of the embodiment of the invention 1 simulated battery;
Fig. 3 is the cyclicity curve of the embodiment of the invention 1 simulated battery;
Fig. 4 is the charging and discharging curve of the embodiment of the invention 5 simulated batteries;
Wherein, 1 inner active material 2 inner conductive additives 3 pyrolytic carbon layer 4CVD carbon-coatings.
Embodiment
(1) with the commodity Cr of drying
2O
3(irregular geometric shape, granularity are 100 nanometers to 20 micron) mixes by 10: 1 weight ratio with carbon black (average grain diameter is 40 nanometers) as conductive additive, and mechanical ball milling (rotating speed is 500 rev/mins, 6 hours) obtains inner composite particles; (2) should the inside composite particles and sucrose by 1: 1 weight ratio machinery mix grinding (rotating speed is 150 rev/mins, 1 hour), obtain finely dispersed mixture; (3) with this mixture, pyrolysis under high pure nitrogen, the step of pyrolysis is: be warmed up to 400 ℃ with 4 hours from room temperature earlier, be warmed up to 700 ℃ with 10 hours from 400 ℃ again, after 12 hours, drop to room temperature with 2 hours at 700 ℃ of constant temperature at last then, obtained coating the inside composite particles of pyrolytic carbon layer; This composite particles is mixed (the 20g composite particles is mixed in the 80ml ethanol) wet-milling 2 hours (rotating speed is 300 rev/mins) with ethanol, take out the back drying and remove ethanol, get 600 orders after the screening to the powder between 300 orders; (4) (volume ratio is 1: 4 under the mist that contains toluene and high pure nitrogen, flow is 200ml/ minute, the tube furnace volume is 0.02 cubic metre), with the 800 ℃ of pyrolysis in tube furnace of this composite particles (being raised to 800 ℃ with 5 hours from room temperature earlier) 800 ℃ of constant temperature 2 hours, again with dropping to room temperature in 2 hours, obtain the secondary lithium battery cathode active material I that is used for of the present invention, this negative active core-shell material has " Lantern Festival " structure, and outer dia is 50 microns, and active material Cr is contained in its inside
2O
3With the transition metal oxide composite particles that conductive black is formed, its outside has coated the carbon granule layer from the sucrose pyrolysis, and outermost layer has coated and utilized the carbon-coating of CVD from the toluene pyrolysis, and the weight ratio of its each several part is listed in table 1.
In order to study the chemical property of serondary lithium battery of the present invention, adopt an Experimental cell to study.Experimental cell is at H
2Assemble in the argon filling glove box of O content<1.0ppm.
The electrolyte of Experimental cell is 1M LiPF
6Be dissolved in the mixed solvent of vinyl carbonate and dimethyl carbonate (volume ratio is 1: 1).
The preparation of the negative pole of Experimental cell: will contain Cr
2O
3Be used for secondary lithium battery cathode active material I and conductive black, the cyclohexane solution of 5%PVDF (Kynoar) mixes formation slurry (weight ratio of drying the latter two is 90: 5: 5) at normal temperatures and pressures, evenly be coated on the Copper Foil substrate as the negative pole coating, obtain about 2~50 microns film of thickness; With this film at 150 ℃ down after the oven dry, at 20Kg/cm
2Under compress, continue 150 ℃ of oven dry 12 hours down, then film being cut to area is 1cm
2Thin rounded flakes as the negative pole of Experimental cell.
The preparation of the positive pole of Experimental cell: with LiMn
2O
4Powder and conductive black, the cyclohexane solution of 5%PVDF mix and form slurry (weight ratio after three's oven dry is 85: 10: 5), evenly are coated on the aluminum substrates as anodal coating, obtain thickness and be 5~40 microns film; With this film at 150 ℃ down after the oven dry, at 20Kg/cm
2Under compress, continue 150 ℃ of oven dry 12 hours down, after this film is cut to area is 1cm
2Thin rounded flakes as the positive pole of Experimental cell.
With other basic building block except that electrolyte or solid electrolyte of Experimental cell, as negative pole, positive pole, barrier film, dryings such as collector, battery case, lead-in wire back is assembled into Experimental cell according to a conventional method in the argon filling glove box.
Use is subjected to computer-controlled auto charge and discharge instrument to carry out charge and discharge cycles to test, and the current density of test is 0.4mA/cm
2, the charging cut-ff voltage is 4.3V, and discharge cut-off voltage is 2V, and test result is listed in table 1.
Use is by Cr
2O
3The simulated battery of composite negative pole and lithium assembling is studied Cr of the present invention
2O
3Composite negative pole material is with respect to the discharge characteristics of lithium metal, the just very metallic lithium foil of simulated battery, and the current density of charge and discharge cycles test is 0.4mA/cm
2, the charging cut-ff voltage is 3V, discharge cut-off voltage is 0.0V.The charging and discharging curve of simulated battery as shown in Figure 2, the cyclicity curve of simulated battery as shown in Figure 3, test result is listed in table 1.
(1) the manganese oxide MnO (average grain diameter is 10 microns) with drying mixes by 5: 1 weight ratio with the acetylene black (average grain diameter is 10 nanometers) as conductive additive, (rotating speed is 500 rev/mins behind the mechanical ball milling, 6 hours), with the heat treatment under high pure nitrogen of this mixture, heat treated step is: be warmed up to 600 ℃ with 2 hours from room temperature earlier, after 1 hour, drop to room temperature with 2 hours at 600 ℃ of constant temperature again, obtain the inside composite particles of surface coverage carbon-coating; (2) should put into an autoclave by the inside composite particles, in autoclave, add 20% aqueous sucrose solution in advance, compactedness is 80v%, the weight ratio of sucrose and inner composite particles is 2: 1, reactor was heated 48 hours at 180 ℃, the black composite particles that produces is filtered, obtain coating the inside composite particles of carbon-coating; (3) (volume ratio is 1: 4 under the mist that contains toluene and high pure nitrogen, flow is 200ml/ minute, the tube furnace volume is 0.02 cubic metre), 700 ℃ of pyrolysis (were raised to 700 ℃ with 3 hours from room temperature earlier in tube furnace, 700 ℃ of constant temperature 5 hours, again with dropping to room temperature in 2 hours), obtain the secondary lithium battery cathode active material II that is used for of the present invention, this negative active core-shell material has " Lantern Festival " structure, outside average diameter is 20 microns, and active material MnO and conductive black are contained in its inside, and the outside has coated the carbon granule layer from the sucrose pyrolysis, outermost layer has coated and has utilized the carbon-coating of CVD from the toluene pyrolysis, and the weight ratio of its each several part is listed in table 1.
The preparation of the negative pole of Experimental cell: the secondary lithium battery cathode active material II that is used for that will contain MnO mixes the formation slurry at normal temperatures and pressures with the cyclohexane solution of 5%PVDF (Kynoar), evenly be coated on the Copper Foil substrate as the negative pole coating, obtain about 2~20 microns film of thickness; With this film at 150 ℃ down after the oven dry, at 20Kg/cm
2Under compress, continue 150 ℃ of oven dry 12 hours down, then film being cut to area is 1cm
2Thin rounded flakes as the negative pole of Experimental cell.
Anodal preparation, Experimental cell assembling and method of testing are with embodiment 1, and the assembling of simulated battery and test are with embodiment 1, and its test result is listed in table 1.
(1) with the V of drying
2O
3(average grain diameter is 50 microns) mixes by 20: 1 weight ratio with graphite powder (granularity is 20 microns) as conductive additive, and mechanical ball milling (rotating speed is 500 rev/mins, 6 hours) obtains inner composite particles; (2) should the inside composite particles and water soluble starch by 20: 0.25 weight ratio machinery mix grindings (add a spot of water during ball milling, rotating speed is 150 rev/mins, 2 hours), the mixture drying that mixes is anhydrated; (3) with this mixture, pyrolysis under high-purity argon gas, the step of pyrolysis is: be warmed up to 300 ℃ with 2 hours from room temperature earlier, be warmed up to 500 ℃ with 10 hours from 300 ℃ again, after 8 hours, drop to room temperature with 2 hours at 500 ℃ of constant temperature at last then, obtained coating the inside composite particles of pyrolytic carbon layer; This composite particles is mixed (the 20g composite particles is mixed in the 80ml ethanol) wet-milling 2 hours (rotating speed is 300 rev/mins) with ethanol, take out the back drying and remove ethanol, screening back classification; Obtain the secondary lithium battery cathode active material III that is used for of the present invention, this negative active core-shell material has " Lantern Festival " structure, and active material V is contained in (outer dia is 100 microns) its inside
2O
3With the transition metal oxide composite particles that the superfine graphite powder is formed, its outside has coated the carbon granule layer from the starch pyrolysis, and the weight ratio of its each several part is listed in table 1.
The preparation of the negative pole of Experimental cell: will contain V
2O
3The secondary lithium battery cathode active material III that is used for mix the formation slurry at normal temperatures and pressures with the cyclohexane solution of 5%PVDF (Kynoar), evenly be coated on the Copper Foil substrate as the negative pole coating, obtain about 2~20 microns film of thickness; With this film at 150 ℃ down after the oven dry, at 20Kg/cm
2Under compress, continue 150 ℃ of oven dry 12 hours down, then film being cut to area is 1cm
2Thin rounded flakes as the negative pole of Experimental cell.
Anodal preparation, Experimental cell assembling and method of testing are with embodiment 1, and the assembling of simulated battery and test are with embodiment 1, and its test result is listed in table 1.
(1) with commodity NbO (the irregular geometric shape of drying, granularity is 500 nanometers to 50 micron) (draw ratio is 100: 1 with multi-walled carbon nano-tubes as conductive additive, length is 20 microns, wall thickness 5 nanometers) mix by 20: 1 weight ratio, (rotating speed is 500 rev/mins to mechanical ball milling, 6 hours), obtain inner composite particles; (2) should the inside composite particles and glucose by the wet-milling (add a spot of distilled water, rotating speed is 150 rev/mins, 1 hour) of 1: 1 weight ratio machinery, obtain finely dispersed mixture; (3) with this mixture, (volume ratio is 1: 4 under the mist that contains ethene and high pure nitrogen, flow is 200ml/ minute, the tube furnace volume is 0.02 cubic metre), 700 ℃ of pyrolysis (were raised to 700 ℃ with 7 hours from room temperature earlier in tube furnace, 700 ℃ of constant temperature 72 hours, again with dropping to room temperature in 2 hours), obtain the secondary lithium battery cathode active material IV that is used for of the present invention, this negative active core-shell material has " Lantern Festival " structure, the transition metal oxide composite particles of active material NbO and multi-walled carbon nano-tubes composition is contained in its inside, its outside has coated the carbon granule layer from the glucose pyrolysis, outermost layer has coated and has utilized the carbon-coating of CVD from ethylene pyrolysis, and outer dia is 50 microns, and the weight ratio of its each several part is listed in table 1.
The preparation of the negative pole of Experimental cell: the secondary lithium battery cathode active material IV that is used for that will contain NbO mixes the formation slurry at normal temperatures and pressures with the cyclohexane solution of 5%PVDF (Kynoar), evenly be coated on the Copper Foil substrate as the negative pole coating, obtain about 2~20 microns film of thickness; With this film at 150 ℃ down after the oven dry, at 20Kg/cm
2Under compress, continue 150 ℃ of oven dry 12 hours down, then film being cut to area is 1cm
2Thin rounded flakes as the negative pole of Experimental cell.
Anodal preparation, Experimental cell assembling and method of testing are with embodiment 1, and the assembling of simulated battery and test are with embodiment 1, and its test result is listed in table 1.
Embodiment 5, the preparation of use Mechanical Method contain the negative active core-shell material V of silicon
(1) with commodity silica flour (the irregular geometric shape of drying, granularity is 1 micron to 20 microns) mix by 20: 1 weight ratio with carbon black (average grain diameter is 10 nanometers) as conductive additive, mechanical ball milling (rotating speed is 500 rev/mins, 6 hours) obtains inner composite particles; (2) should the inside composite particles and cyclodextrin by 1: 1 weight ratio machinery mix grinding (rotating speed is 150 rev/mins, 1 hour), obtain finely dispersed mixture; (3) with this mixture, pyrolysis under high pure nitrogen, the step of pyrolysis is: be warmed up to 400 ℃ with 4 hours from room temperature earlier, be warmed up to 1200 ℃ with 10 hours from 400 ℃ again, then at 1200 ℃ of constant temperature after 12 hours, drop to room temperature with 2 hours at last, obtained coating the inside composite particles of pyrolytic carbon layer; This composite particles is mixed (the 20g composite particles is mixed in the 80ml ethanol) wet-milling 2 hours (rotating speed is 300 rev/mins) with ethanol, take out the back drying and remove ethanol, get 600 orders after the screening to the powder between 300 orders; (4) (volume ratio is 1: 2 under the mist that contains acetylene and high pure nitrogen, flow is 100ml/ minute, the tube furnace volume for O.02 the cubic meter), 1200 ℃ of pyrolysis (were raised to 1200 ℃ with 2 hours from room temperature earlier in tube furnace, 1200 ℃ of constant temperature 1 hour, again with dropping to room temperature in 2 hours), obtain the secondary lithium battery cathode active material V that is used for of the present invention, this negative active core-shell material has " Lantern Festival " structure, the transition metal oxide composite particles of active material silicon and conductive black composition is contained in its inside, its outside has coated the carbon granule layer from the cyclodextrin pyrolysis, outermost layer has coated and has utilized the carbon-coating of CVD from the acetylene pyrolysis, outer dia is 10 microns, and the weight ratio of its each several part is listed in table 1.
The preparation of the negative pole of Experimental cell: what will contain silicon is used for secondary lithium battery cathode active material V and conductive carbon black, the cyclohexane solution of 5%PVDF (Kynoar) mixes formation slurry (weight ratio after three's oven dry is 85: 10: 5) at normal temperatures and pressures, evenly be coated on the Copper Foil substrate as the negative pole coating, obtain about 2~20 microns film of thickness; With this film at 150 ℃ down after the oven dry, at 20Kg/cm
2Under compress, continue 150 ℃ of oven dry 12 hours down, then film being cut to area is 1cm
2Thin rounded flakes as the negative pole of Experimental cell.
Anodal preparation, Experimental cell assembling and method of testing are with embodiment 1, and the assembling of simulated battery and test are with embodiment 1, and its test result is listed in table 1.
Embodiment 6, the preparation of use Mechanical Method contain the negative active core-shell material VI of VO
The preparation method who is used for secondary lithium battery cathode active material VI who contains VO (average grain diameter is 10 microns) is similar to the preparation method of embodiment 1, just the raw material of step (2) RESEARCH OF PYROCARBON is industrial yellow starch gum, obtain the secondary lithium battery cathode active material VI that is used for of the present invention at last, this negative active core-shell material has " Lantern Festival " structure, the transition metal oxide composite particles of active material VO and conductive black composition is contained in its inside, its outside has coated the carbon granule layer from the yellow starch gum pyrolysis, outermost layer has coated and has utilized the carbon-coating of CVD from the toluene pyrolysis, outer dia is 50 microns, and the weight ratio of its each several part is listed in table 1.
The preparation of the negative pole of Experimental cell: what will contain VO is used for secondary lithium battery cathode active material VI and conductive carbon black, the cyclohexane solution of 5%PVDF (Kynoar) mixes formation slurry (weight ratio after three's oven dry is 85: 10: 5) at normal temperatures and pressures, evenly be coated on the Copper Foil substrate as the negative pole coating, obtain about 2~20 microns film of thickness; With this film at 150 ℃ down after the oven dry, at 20Kg/cm
2Under compress, continue 150 ℃ of oven dry 12 hours down, then film being cut to area is 1cm
2Thin rounded flakes as the negative pole of Experimental cell.
Anodal preparation, Experimental cell assembling and method of testing are with embodiment one, and the assembling of simulated battery and test are identical with embodiment one, and it discharges and recharges and the results are shown in subordinate list 1.
Embodiment 7, the preparation of use Mechanical Method contain VO
2Negative active core-shell material VII
Contain VO
2The preparation method who is used for secondary lithium battery cathode active material VII be similar to the preparation method of embodiment 1, just step (1) conductive additive is that (length is 10 nanometers to Single Walled Carbon Nanotube, diameter is 1 nanometer), obtain the secondary lithium battery cathode active material VII that is used for of the present invention at last, this negative active core-shell material has " Lantern Festival " structure, and active material VO is contained in its inside
2With the transition metal oxide composite particles that Single Walled Carbon Nanotube is formed, its outside has coated the carbon granule layer from the sucrose pyrolysis, and outermost layer has coated and utilized the carbon-coating of CVD from the toluene pyrolysis, and the weight ratio of its each several part is listed in table 1.
The preparation of the negative pole of Experimental cell: will contain VO
2Be used for secondary lithium battery cathode active material VII and conductive carbon black, the cyclohexane solution of 5%PVDF (Kynoar) mixes formation slurry (weight ratio after three's oven dry is 90: 5: 5) at normal temperatures and pressures, evenly be coated on the Copper Foil substrate as the negative pole coating, obtain about 2~20 microns film of thickness; With this film at 150 ℃ down after the oven dry, at 20Kg/cm
2Under compress, continue 150 ℃ of oven dry 12 hours down, then film being cut to area is 1cm
2Thin rounded flakes as the negative pole of Experimental cell.
Anodal preparation, Experimental cell assembling and method of testing are with embodiment 1, and the assembling of simulated battery and test are with embodiment 1, and its test result is listed in table 1.
Embodiment 8, the preparation of use Mechanical Method contain the negative active core-shell material VIII of CrO
The preparation method who is used for secondary lithium battery cathode active material VIII who contains CrO is similar to the preparation method of embodiment 1, just step (1) conductive additive is that (length of this fiber is 20 microns to carbon nano-fiber, diameter is 500 nanometers), obtain the secondary lithium battery cathode active material VIII that is used for of the present invention at last, this negative active core-shell material has " Lantern Festival " structure, the transition metal oxide composite particles of active material CrO and carbon nano-fiber composition is contained in its inside, its outside has coated the carbon granule layer from the sucrose pyrolysis, outermost layer has coated and has utilized the carbon-coating of CVD from the toluene pyrolysis, and the weight ratio of its each several part is listed in table 1.
The preparation of the negative pole of Experimental cell: what will contain CrO is used for secondary lithium battery cathode active material VIII and conductive carbon black, the cyclohexane solution of 5%PVDF (Kynoar) mixes formation slurry (weight ratio after three's oven dry is 90: 5: 5) at normal temperatures and pressures, evenly be coated on the Copper Foil substrate as the negative pole coating, obtain about 2~20 microns film of thickness; With this film at 150 ℃ down after the oven dry, at 20Kg/cm
2Under compress, continue 150 ℃ of oven dry 12 hours down, then film being cut to area is 1cm
2Thin rounded flakes as the negative pole of Experimental cell.
Anodal preparation, Experimental cell assembling and method of testing are with embodiment 1, and the assembling of simulated battery and test are with embodiment 1, and its test result is listed in table 1.
Embodiment 9, use Hydrothermal Preparation contain Cr
3O
4Negative active core-shell material IX
(1) with the chromium oxide Cr of drying
3O
4(50 nanometer) mixes by 5: 1 weight ratio with the acetylene black (diameter is 10 nanometers) as conductive additive, (rotating speed is 500 rev/mins behind the mechanical ball milling, 6 hours), with the heat treatment under high pure nitrogen of this mixture, heat treated step is: be warmed up to 600 ℃ with 2 hours from room temperature earlier, after 1 hour, drop to room temperature with 2 hours at 600 ℃ of constant temperature again, obtain the inside composite particles of surface coverage carbon-coating; (2) should put into an autoclave by the inside composite particles, in autoclave, add 50% amidin in advance, compactedness is 95%, the weight ratio of starch and inner composite particles is 1: 2, reactor was heated 72 hours at 250 ℃, the black composite particles that produces is filtered, obtain coating the inside composite particles of carbon-coating; (3) will coat the inside composite particles of carbon-coating, pyrolysis under high pure nitrogen, the step of pyrolysis is: be warmed up to 300 ℃ with 4 hours from room temperature earlier, be warmed up to 750 ℃ with 5 hours from 300 ℃ again, then at 750 ℃ of constant temperature after 12 hours, drop to room temperature with 2 hours at last, obtained coating the inside composite particles of pyrolytic carbon layer; (4) (volume ratio is 1: 1 under the mist that contains benzene and high pure nitrogen, flow is 100ml/ minute, the tube furnace volume is 0.02 cubic metre), 700 ℃ of CVD pyrolysis (were raised to 700 ℃ with 3 hours from room temperature earlier in tube furnace, 700 ℃ of constant temperature 5 hours, again with dropping to room temperature in 2 hours), obtain the secondary lithium battery cathode active material IX that is used for of the present invention, this negative active core-shell material has " Lantern Festival " structure, and active material VO is contained in its inside
2And acetylene black, the outside has coated the carbon granule layer from the starch pyrolysis, and outermost layer has coated and has utilized the carbon-coating of CVD from the benzene pyrolysis, and outer dia is 100 nanometers, and the weight ratio of its each several part is listed in table 1.
The preparation of the negative pole of Experimental cell: will contain Cr
3O
4Be used for secondary lithium battery cathode active material IX and conductive carbon black, the cyclohexane solution of 5%PVDF (Kynoar) mixes formation slurry (weight ratio after three's oven dry is 90: 5: 5) at normal temperatures and pressures, evenly be coated on the Copper Foil substrate as the negative pole coating, obtain about 2~20 microns film of thickness; With this film at 150 ℃ down after the oven dry, at 20Kg/cm
2Under compress, continue 150 ℃ of oven dry 12 hours down, then film being cut to area is 1cm
2Thin rounded flakes as the negative pole of Experimental cell.
Anodal preparation, Experimental cell assembling and method of testing are with embodiment 1, and the assembling of simulated battery and test are with embodiment 1, and its test result is listed in table 1.
Embodiment 10, use Hydrothermal Preparation contain Mn
2O
3Negative active core-shell material X
(1) manganese oxide (50 nanometer) with drying mixes by 5: 1 weight ratio with the acetylene black (average grain diameter is 10 nanometers) as conductive additive, and (rotating speed is 500 rev/mins, 6 hours) obtains inner composite particles behind the mechanical ball milling; (2) should put into an autoclave by the inside composite particles, in autoclave, add 40% the yellow starch gum aqueous solution in advance, compactedness is 20%, the weight ratio of yellow starch gum and inner composite particles is 10: 1, reactor was heated 24 hours at 190 ℃, after the black composite particles filtration that produces, obtain coating the inside composite particles of carbon-coating; (3) will coat the inside composite particles of carbon-coating, pyrolysis under high pure nitrogen, the step of pyrolysis is: be warmed up to 300 ℃ with 4 hours from room temperature earlier, be warmed up to 600 ℃ with 5 hours from 300 ℃ again, after 5 hours, drop to room temperature with 2 hours at 600 ℃ of constant temperature at last then, obtain the secondary lithium battery cathode active material X that is used for of the present invention, this negative active core-shell material has " Lantern Festival " structure, and active material Mn is contained in its inside
2O
3And acetylene black, the outside has coated the carbon granule layer from the yellow starch gum pyrolysis, and outer dia is 500 nanometers, and the weight ratio of its each several part is listed in table 1.
The preparation of the negative pole of Experimental cell: will contain Mn
2O
3Be used for secondary lithium battery cathode active material X and conductive carbon black, the cyclohexane solution of 5%PVDF (Kynoar) mixes formation slurry (weight ratio after three's oven dry is 85: 10: 5) at normal temperatures and pressures, evenly be coated on the Copper Foil substrate as the negative pole coating, obtain about 2~20 microns film of thickness; With this film at 150 ℃ down after the oven dry, at 20Kg/cm
2Under compress, continue 150 ℃ of oven dry 12 hours down, then film being cut to area is 1cm
2Thin rounded flakes as the negative pole of Experimental cell.
Anodal preparation, Experimental cell assembling and method of testing are with embodiment 1, and the assembling of simulated battery and test are with embodiment 1, and its test result is listed in table 1.
Embodiment 11, the preparation of use Mechanical Method contain NbO
2Negative active core-shell material XI
Contain NbO
2The preparation method who is used for secondary lithium battery cathode active material XI of (average grain diameter is 30 microns) is similar to the preparation method of embodiment 1, just step (1) conductive additive is acetylene black (average grain diameter is 50 nanometers), obtain the secondary lithium battery cathode active material XI that is used for of the present invention at last, this negative active core-shell material has " Lantern Festival " structure, and active material NbO is contained in its inside
2With the transition metal oxide composite particles that acetylene black is formed, its outside has coated the carbon granule layer from the sucrose pyrolysis, and outermost layer has coated and utilized the carbon-coating of CVD from the toluene pyrolysis, and outer dia is 1 micron, and the weight ratio of its each several part is listed in table 1.
The preparation of the negative pole of Experimental cell: will contain NbO
2Be used for secondary lithium battery cathode active material XI and conductive carbon black, the cyclohexane solution of 5%PVDF (Kynoar) mixes formation slurry (weight ratio after three's oven dry is 85: 10: 5) at normal temperatures and pressures, evenly be coated on the Copper Foil substrate as the negative pole coating, obtain about 2~20 microns film of thickness; With this film at 150 ℃ down after the oven dry, at 20Kg/cm
2Under compress, continue 150 ℃ of oven dry 12 hours down, then film being cut to area is 1cm
2Thin rounded flakes as the negative pole of Experimental cell.
Anodal preparation, Experimental cell assembling and method of testing are with embodiment 1, and the assembling of simulated battery and test are with embodiment 1, and its test result is listed in table 1.
Embodiment 12, use Hydrothermal Preparation contain Nb
2O
5Negative active core-shell material XII
Contain Nb
2O
5The preparation method who is used for secondary lithium battery cathode active material XI be similar to the preparation method of embodiment 4, just step (1) conductive additive is an acetylene black, obtain the secondary lithium battery cathode active material XII that is used for of the present invention at last, this negative active core-shell material has " Lantern Festival " structure, and active material Nb is contained in its inside
2O
5With the transition metal oxide composite particles that acetylene black is formed, its outside has coated the carbon granule layer from the glucose pyrolysis, and outermost layer has coated and utilized the carbon-coating of CVD from ethylene pyrolysis, and outer dia is 20 microns, and the weight ratio of its each several part is listed in table 1.
The preparation of the negative pole of Experimental cell: will contain Nb
2O
5Be used for secondary lithium battery cathode active material XII and conductive carbon black, the cyclohexane solution of 5%PVDF (Kynoar) mixes formation slurry (weight ratio after three's oven dry is 85: 10: 5) at normal temperatures and pressures, evenly be coated on the Copper Foil substrate as the negative pole coating, obtain about 2~20 microns film of thickness; With this film at 150 ℃ down after the oven dry, at 20Kg/cm
2Under compress, continue 150 ℃ of oven dry 12 hours down, then film being cut to area is 1cm
2Thin rounded flakes as the negative pole of Experimental cell.
Anodal preparation, Experimental cell assembling and method of testing are with embodiment 1, and the assembling of simulated battery and test are with embodiment 1, and its test result is listed in table 1.
Embodiment 13, the preparation of use Mechanical Method contain the negative active core-shell material XIII of silicon
The preparation method who is used for secondary lithium battery cathode active material XIII who contains silicon is similar to the preparation method of embodiment 1, obtain the secondary lithium battery cathode active material XIII that is used for of the present invention at last, this negative active core-shell material has " Lantern Festival " structure, the composite particles of active material silicon and conductive black composition is contained in its inside, its outside has coated the carbon granule layer from the sucrose pyrolysis, outermost layer has coated and has utilized the carbon-coating of CVD from the toluene pyrolysis, and the weight ratio of its each several part is listed in table 1.
The preparation of the negative pole of Experimental cell: what will contain silicon is used for secondary lithium battery cathode active material XIII and native graphite with 3: 92 ratio mechanical mixture of weight ratio, this mixture and the cyclohexane solution of 5%PVDF (Kynoar) are mixed formation slurry (weight ratio that is used for secondary lithium battery cathode active material XIII, native graphite and PVDF that contains silicon is 3: 92: 5) at normal temperatures and pressures, evenly be coated on the Copper Foil substrate as the negative pole coating, obtain about 2~20 microns film of thickness; With this film at 150 ℃ down after the oven dry, at 20Kg/cm
2Under compress, continue 150 ℃ of oven dry 12 hours down, then film being cut to area is 1cm
2Thin rounded flakes as the negative pole of Experimental cell.
Anodal preparation, Experimental cell assembling and method of testing are with embodiment 1, and the assembling of simulated battery and test are with embodiment 1, and its test result is listed in table 1.
Embodiment 14, the preparation of use Mechanical Method contain the negative active core-shell material XIV of silicon/chromium oxide
The preparation method who is used for secondary lithium battery cathode active material XIV who contains silicon/chromium oxide is similar to the preparation method of embodiment 1, be with silicon and chromium oxide in step (1), after conductive black is mixed together ball milling, again with the sucrose mixed pyrolysis, obtain the secondary lithium battery cathode active material XIV that is used for of the present invention at last, this negative active core-shell material has " Lantern Festival " structure, active material silicon and chromium oxide are contained in its inside, and the transition metal oxide composite particles of conductive black composition, its outside has coated the carbon granule layer from the sucrose pyrolysis, outermost layer has coated and has utilized the carbon-coating of CVD from the toluene pyrolysis, and the weight ratio of its each several part is listed in table 1.
The preparation of the negative pole of Experimental cell: what will contain silicon/chromium oxide is used for secondary lithium battery cathode active material XIV and graphitization mesocarbon bead with 50: 45 ratio mechanical mixture of weight ratio, this mixture and the cyclohexane solution of 5%PVDF (Kynoar) are mixed formation slurry (weight ratio that is used for secondary lithium battery cathode active material XIV, graphitization mesocarbon bead and PVDF that contains silicon/chromium oxide is 50: 45: 5) at normal temperatures and pressures, evenly be coated on the Copper Foil substrate as the negative pole coating, obtain about 2~20 microns film of thickness; With this film at 150 ℃ down after the oven dry, at 20Kg/cm
2Under compress, continue 150 ℃ of oven dry 12 hours down, then film being cut to area is 1cm
2Thin rounded flakes as the negative pole of Experimental cell.
Anodal preparation, Experimental cell assembling and method of testing are with embodiment 1, and the assembling of simulated battery and test are with embodiment 1, and its test result is listed in table 1.
Embodiment 15, the preparation of use Mechanical Method contain the negative active core-shell material XV of silicon
The preparation method who is used for secondary lithium battery cathode active material XV who contains silicon is similar to the preparation method of embodiment 1, obtain the secondary lithium battery cathode active material XV that is used for of the present invention at last, this negative active core-shell material has " Lantern Festival " structure, the composite particles of active material silicon and conductive black composition is contained in its inside, its outside has coated the carbon granule layer from the sucrose pyrolysis, outermost layer has coated and has utilized the carbon-coating of CVD from the toluene pyrolysis, and the weight ratio of its each several part is listed in table 1.
The preparation of the negative pole of Experimental cell: what will contain silicon is used for secondary lithium battery cathode active material XV and hard carbon ball with 65: 30 ratio mechanical mixture of weight ratio, this mixture and the cyclohexane solution of 5%PVDF (Kynoar) are mixed formation slurry (weight ratio that is used for secondary lithium battery cathode active material XV, hard carbon ball and PVDF that contains silicon is 65: 30: 5) at normal temperatures and pressures, evenly be coated on the Copper Foil substrate as the negative pole coating, obtain about 2~20 microns film of thickness; With this film at 150 ℃ down after the oven dry, at 20Kg/cm
2Under compress, continue 150 ℃ of oven dry 12 hours down, then film being cut to area is 1cm
2Thin rounded flakes as the negative pole of Experimental cell.
Anodal preparation, Experimental cell assembling and method of testing are with embodiment 1, and the assembling of simulated battery and test are with embodiment 1, and its test result is listed in table 1.
Embodiment 16, the preparation of use Mechanical Method contain Cr
2O
3Negative active core-shell material XVI
Contain Cr
2O
3The preparation method who is used for secondary lithium battery cathode active material XVI be similar to the preparation method of embodiment 1, just step (1) conductive additive is the superfine graphite powder, obtain the secondary lithium battery cathode active material XVI that is used for of the present invention at last, this negative active core-shell material has " Lantern Festival " structure, and active material Cr is contained in its inside
2O
3With the transition metal oxide composite particles that the superfine graphite powder is formed, its outside has coated the carbon granule layer from the sucrose pyrolysis, and outermost layer has coated and utilized the carbon-coating of CVD from the toluene pyrolysis, and the weight ratio of its each several part is listed in table 1.
The preparation of the negative pole of Experimental cell: will contain Cr
2O
3Be used for secondary lithium battery cathode active material XVI and the cyclohexane solution of 5%PVDF (Kynoar) mix at normal temperatures and pressures and form slurry and (contain Cr
2O
3The weight ratio that is used for secondary lithium battery cathode active material XVI and PVDF be 98: 2), evenly be coated on the Copper Foil substrate as the negative pole coating, obtain about 2~20 microns film of thickness; With this film at 150 ℃ down after the oven dry, at 20Kg/cm
2Under compress, continue 150 ℃ of oven dry 12 hours down, then film being cut to area is 1cm
2Thin rounded flakes as the negative pole of Experimental cell.
Anodal preparation, Experimental cell assembling and method of testing are with embodiment 1, and the assembling of simulated battery and test are with embodiment 1, and its test result is listed in table 1.
Embodiment 17, the preparation of use Mechanical Method contain Cr
3O
4Negative active core-shell material XVII
Contain Cr
3O
4The preparation method who is used for secondary lithium battery cathode active material XVII be similar to the preparation method of embodiment 3, just step (1) conductive additive is a conductive carbon black, obtain the secondary lithium battery cathode active material XVII that is used for of the present invention at last, this negative active core-shell material has " Lantern Festival " structure, and active material Cr is contained in its inside
3O
4With the transition metal oxide composite particles that conductive carbon black is formed, its outside has coated the carbon granule layer from the sucrose pyrolysis, and outermost layer has coated and utilized the carbon-coating of CVD from the toluene pyrolysis, and the weight ratio of its each several part is listed in table 1.
The preparation of the negative pole of Experimental cell: will contain Cr
3O
4Be used for secondary lithium battery cathode active material XVII and the cyclohexane solution of 5%PVDF (Kynoar) mix at normal temperatures and pressures and form slurry and (contain Cr
3O
4The weight ratio that is used for secondary lithium battery cathode active material XVII and PVDF be 95: 5), evenly be coated on the Copper Foil substrate as the negative pole coating, obtain about 2~20 microns film of thickness; With this film at 150 ℃ down after the oven dry, at 20Kg/cm
2Under compress, continue 150 ℃ of oven dry 12 hours down, then film being cut to area is 1cm
2Thin rounded flakes as the negative pole of Experimental cell.
Anodal preparation, Experimental cell assembling and method of testing are with embodiment 1, and the assembling of simulated battery and test are with embodiment 1, and its test result is listed in table 1.
Embodiment 18, the preparation of use Mechanical Method contain the negative active core-shell material XVIII of silicon
The preparation method who is used for secondary lithium battery cathode active material XVIII who contains silicon is similar to the preparation method of embodiment 1, different is that the silicon raw material adopts the nano-silicon (commodity next by the induced with laser vapour deposition, particle mean size is 10 nanometers) obtain the secondary lithium battery cathode active material XVIII that is used for of the present invention at last, this negative active core-shell material has " Lantern Festival " structure, the composite particles of active material silicon and conductive black composition is contained in its inside, its outside has coated the carbon granule layer from the sucrose pyrolysis, outermost layer has coated and has utilized the carbon-coating of CVD from the toluene pyrolysis, its outside diameter is 200 nanometers, and the weight ratio of each several part is listed in table 1.
The preparation of the negative pole of Experimental cell: what will contain silicon is used for secondary lithium battery cathode active material XVIII and conductive black, with 5: 1 mixed of weight ratio, this mixture and the cyclohexane solution of 5%PVDF (Kynoar) are mixed formation slurry (weight ratio that is used for secondary lithium battery cathode active material XVIII, conductive black and PVDF that contains nano-silicon is 5: 1: 0.3) at normal temperatures and pressures, evenly be coated on the Copper Foil substrate as the negative pole coating, obtain about 2~20 microns film of thickness; With this film at 150 ℃ down after the oven dry, at 20Kg/cm
2Under compress, continue 150 ℃ of oven dry 12 hours down, then film being cut to area is 1cm
2Thin rounded flakes as the negative pole of Experimental cell.
Anodal preparation, Experimental cell assembling and method of testing are with embodiment 1, and the assembling of simulated battery and test are with embodiment 1, and its test result is listed in table 1.
The composition of the negative active core-shell material of table 1, embodiment 1~18 and simulated battery thereof discharge and recharge data
Embodiment | Negative active core-shell material is formed (weight portion) | Negative pole is formed (weight portion) | Electrochemical properties | |||||||||
Active material | Conductive additive | Outer shell | Negative active core-shell material | Other negative active core-shell material | Conductive additive | Binding agent | Reversible capacity (MAH/gram) | Average charging tension (volt) | Coulombic efficiency | |||
Kind | Weight | Pyrolytic carbon layer | The CVD carbon-coating | |||||||||
1 | Cr 2O 3 | 10 | 1 | 2 | 0.5 | 90 | 0 | 5 | 5 | 750 | 1.5 | 74 |
2 | MnO | 5 | 1 | 2.4 | 1 | 95 | 0 | 0 | 5 | 480 | 1.6 | 78 |
3 | V 2O 3 | 20 | 1 | 0.05 | 0 | 95 | 0 | 0 | 5 | 650 | 1.5 | 77 |
4 | NbO | 20 | 1 | 5 | 0 | 95 | 0 | 0 | 5 | 450 | 1.4 | 77 |
5 | Si | 20 | 1 | 5 | 0.2 | 85 | 0 | 10 | 5 | 2300 | 0.6 | 85 |
6 | VO | 100 | 1 | 49 | 1 | 90 | 0 | 5 | 5 | 460 | 1.2 | 77 |
7 | VO 2 | 100 | 5 | 20 | 5 | 90 | 0 | 5 | 5 | 520 | 1.8 | 77 |
8 | CrO | 20 | 5 | 5 | 0.2 | 90 | 0 | 5 | 5 | 470 | 1.4 | 78 |
9 | Cr 3O 4 | 20 | 4 | 5 | 0.1 | 90 | 0 | 5 | 5 | 700 | 1.7 | 77 |
10 | Mn 2O 3 | 20 | 1 | 2 | 0 | 85 | 0 | 10 | 5 | 600 | 1.8 | 79 |
11 | NbO 2 | 20 | 1 | 5 | 1 | 85 | 0 | 10 | 5 | 620 | 1.5 | 78 |
12 | Nb 2O 5 | 10 | 1 | 5 | 1 | 85 | 0 | 10 | 5 | 460 | 1.5 | 78 |
13 | Si | 10 | 1 | 1 | 1 | 3 | 92 | 0 | 5 | 450 | 0.4 | 85 |
14 | Si/Cr 2O 3 | 10 | 2 | 2 | 1 | 50 | 45 | 0 | 5 | 1000 | 1.0 | 78 |
15 | Si | 20 | 10 | 65 | 5 | 65 | 30 | 0 | 5 | 1500 | 0.5 | 84 |
16 | Cr 2O 3 | 30 | 60 | 5 | 5 | 98 | 0 | 0 | 2 | 500 | 1.3 | 80 |
17 | Cr 3O 4 | 90 | 9.9 | 0.1 | 0 | 95 | 0 | 0 | 5 | 700 | 1.6 | 78 |
18 | Si | 20 | 1 | 5 | 0.2 | 79 | 0 | 15 | 6 | 2000 | 0.5 | 76 |
Claims (10)
1, a kind of secondary lithium battery cathode active material that is used for, it is one to have the particle of " nucleocapsid " structure, its particle diameter is 100 nanometers~100 micron; Wherein:
Described " nucleocapsid " structure comprises a kernel and shell; Its kernel is made up of inner composite particles, comprise active material and conductive additive, described active material accounts for 20~95wt% of the total weight of negative active core-shell material, and it is that the thermodynamical equilibrium current potential that is selected from silicon and storage lithium is lower than one or more the mixture in the transistion metal compound of 1.5V; Described conductive additive is 1~200wt% of the weight of active material;
Described shell is a carbon-coating.
2, the secondary lithium battery cathode active material that is used for as claimed in claim 1 is characterized in that, the transistion metal compound that described storage lithium thermodynamical equilibrium current potential is lower than 1.5V comprises VO, V
2O
3, VO
2, CrO, Cr
2O
3, Cr
3O
4, Mn
2O
3, MnO, NbO, NbO
2, Nb
2O
5
3, the secondary lithium battery cathode active material that is used for as claimed in claim 1 is characterized in that, described active material is a spheric granules.
4, the secondary lithium battery cathode active material that is used for as claimed in claim 1 is characterized in that, the particle diameter of described active material is 10 nanometers to 50 micron.
5, the secondary lithium battery cathode active material that is used for as claimed in claim 1 is characterized in that, described conductive additive is graphite powder, conductive black, acetylene black, carbon nano-tube, carbon fiber, metal powder or metallic fiber.
6, the secondary lithium battery cathode active material that is used for as claimed in claim 5 is characterized in that, the particle diameter of described graphite powder, conductive black, acetylene black and metal powder is 10 nanometers to 20 micron.
7, the secondary lithium battery cathode active material that is used for as claimed in claim 5 is characterized in that, the length of described carbon nano-tube, carbon fiber and metallic fiber is 10 nanometers to 20 micron, and diameter is that 1 nanometer is to 500 nanometers.
8, the secondary lithium battery cathode active material that is used for as claimed in claim 1 is characterized in that, described shell carbon-coating be one or more layers, equally distributed continuous carbon film, or carbon granule layer.
9, the described purposes that is used for the negative pole of secondary lithium battery cathode active material making serondary lithium battery of a kind of claim 1.
10, the described secondary lithium battery cathode active material that is used for of a kind of claim 1 mixes the purposes that is used for the secondary lithium battery cathode material with other existing negative material, describedly is used for 3~98wt% that the secondary lithium battery cathode active material accounts for total negative material weight.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
CNB200410030990XA CN1328805C (en) | 2004-04-05 | 2004-04-05 | Negative electrode active material and use of secondary lithium battery |
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