CN102437332B - Preparation method of manganese and barium activated lithium iron phosphate as cathode material - Google Patents
Preparation method of manganese and barium activated lithium iron phosphate as cathode material Download PDFInfo
- Publication number
- CN102437332B CN102437332B CN2011103359417A CN201110335941A CN102437332B CN 102437332 B CN102437332 B CN 102437332B CN 2011103359417 A CN2011103359417 A CN 2011103359417A CN 201110335941 A CN201110335941 A CN 201110335941A CN 102437332 B CN102437332 B CN 102437332B
- Authority
- CN
- China
- Prior art keywords
- manganese
- barium
- lithium
- source
- cathode material
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Active
Links
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
Abstract
The invention discloses a preparation method of manganese and barium activated lithium iron phosphate as a cathode material. The preparation method comprises the steps of: mixing raw materials including a lithium source, a manganese source, a barium source, an iron source and a phosphate source according to the proportion of 1mol:(0.00002-0.00005)mol:(0.0003)mol:1mol:1mol; then, performing high-speed ball milling at the rotation speed of 200r/min for 20h in an absolute ethyl alcohol medium; drying at 105-120 DEG C to obtain a precursor; placing the precursor obtained through drying in a high-temperature furnace; and calcinating for 24h at the high temperature of 500-750 DEG C in a common pure nitrogen atmosphere to obtain the manganese and barium activated lithium iron phosphate as the cathode material. Because a small amount of substitutive manganese and barium are doped, the shape and the particle size of a product are favorably controlled to obtain a stable lithium iron phosphate compound, of which the crystal lattice is activated, the lithium ion diffusion coefficient is increased, and the initial discharge capacity of the obtained cathode material reaches 160.52mAh/g; a charge-discharge platform of the cathode material is about 3.5V relative to a lithium electrode potential, the initial discharge capacity exceeds 168mAh/g, and the capacity is attenuated by about 1.2% after 100 times of charge-discharge cycles; and compared with a control embodiment, namely undoped LiFePO4, the cathode material is greatly improved in specific capacity and cyclic stability.
Description
Technical field
Manganese of the present invention, barium activation lithium iron phosphate positive material preparation method belong to a kind of anode material of lithium battery preparation method, particularly a kind of ferric phosphate lithium cell method for preparing anode material.
Background technology
At present, the research present situation of LiFePO4 doping vario-property: LiFePO4 LiFePO4 is because it is nontoxic, environmentally friendly, safe, abundant, high, the stable cycle performance, cheap of specific capacity in raw material source, steady discharge platform with theoretical capacity 3.5V of 170mAh/g, LiFePO 4 material has high energy density, cheap price, excellent security, is specially adapted to electrokinetic cell.But its resistivity is bigger.Because LiFePO4, under the normal temperature, the dynamics of LiFePO4 is bad, the high rate performance extreme difference, domestic and international research persons have used such as methods such as coating, doping, nanometers and have improved high rate performance, and basic idea improves conductivity exactly and shortens ion, electric transmission path.Doping is the important material modification method of a class.2002, reported first lithium position doping vario-properties such as Massachusetts science and engineering Chiang professor Yet-Ming can improve the LiFePO4 electronic conductivity greatly.They carry out the doping of high volence metal ion (Mg2+, Al3+, Ti4+, Zr4+, Nb5+ and W6+) solid solution in the lithium position, electronic conductivity has improved 8 orders of magnitude.Sample through above-mentioned doping has better electrochemical performance, and particularly high-rate performance discharges under the electric current of 21.5C (3225mA/g), still can obtain the capacity of 60mAh/g.Doping carbon: carbon has good electric conductivity and lower mass density, adds a spot of carbon of people, can improve the electric conductivity of material on the one hand, can reduce the particle diameter yardstick of material on the other hand.Xxx has studied different phase and has mixed people's carbon to the influence of material electrochemical performance.Shi Zhicong etc. " adopt solid phase reaction in conjunction with the high speed ball-milling method, synthetic positive electrode LiFePO4, experiment shows: LiFePO4 has the discharge voltage plateau of 3.4V, and discharge capacity only decays 9.5% after reaching 147mAh/g charge and discharge cycles 100 times first.LiFePO4/C composite material behind the carbon dope, the granule-morphology rule is the class sphere, and particle is little, and particle diameter distributes and all colludes.Carbon is scattered between the crystal grain, has strengthened the electrical conductance between the particle.LiFePO4 specific discharge capacity and cycle performance behind the carbon dope all significantly improve.Mix in the lithium position: the LiFePO4 crushed grain is assorted to be a kind of important method of improving chemical property.Mix and can improve the conductivity of LiFePO4 in the lithium position.Tan Xianyan etc. " " adopt the calcination method synthesizing lithium ionic cell positive pole material lithium iron phosphate, mix a spot of Mg2+ and have significantly improved conductivity of electrolyte materials, have improved the chemical property of LiFePO4.After the doping, LiFePO4 discharge capacity first reaches 135.52mAh/g; Unadulterated LiFePO4 discharge capacity first has only 116.25mAh/g.Conductivity after the doping has obtained certain raising.This is because doping little metal ion replaces the Li+ position, constitutes the p-type semiconductor, has increased the conductivity of material.The identical ^ of Liu adopts improved solid phase method to prepare LiFePO4 and the Li0 that particle is fine, particle diameter is evenly distributed, 98Mn, and the o.o2LiFePO4 compound, mixing is conducive to control pattern and the particle diameter of product on a small quantity, obtains stable LiFePO4 compound.Because Mn2+ octahedral coordination radius, can think that magnesium ion occupies the replacement lithium ion less than Fe2+.The result shows: the relative lithium electrode current potential of the charge and discharge platform of lithium ion is about 3.5V in the material, and initial discharge capacity surpasses 160mAh/g, and capacity only decays 5.5% after 50 charge and discharge cycles, shows that this method has improved specific energy and cyclical stability.The iron position is assorted disastrously: can improve conductivity of electrolyte materials though mix in the lithium position, because foreign atom can hinder the diffusion of lithium ion in the one dimension passage, thereby be unfavorable for improving the high-rate charge-discharge capability of material.And the doping of iron position can improve the rate charge-discharge performance of LiFePO4, improves cycle performance.^ such as Liu Fangling adopt parcel carbon to improve its surface electronic conductivity, and doped metal ion is to improve its body electronic conductivity.Having chosen ionic radius approaches and 4 different metal ion species Ca3+ of valence state, Ti5+, Ta5+, mix in the Fe position of MO6+, sample unit cell volume after the doping all has minimizing, electronic conductivity has improved 4-6 the order of magnitude than the electronic conductivity of LiFePO4, and its impedance in electrolyte solution is significantly reduced, and chemical property also obviously improves.^ such as Hu Huanyu adopt the synthetic tiny and uniform nanoscale positive electrode of the particle LiFePO4 of high-temperature solid phase reaction method, have good capacity cycle performance, but its high rate capability are poor.Mix a spot of manganese and can reduce the polarization of material, improve the high rate capability of material.This mainly is because the doping of manganese has increased the unit cell volume of LiFePO4, more be conducive to deviating from of lithium, the doping of manganese has caused sintering process to produce crystal structure defects in addition, has improved the electron conduction of material, thereby has made the high-rate charge-discharge capability of material make moderate progress.The phosphate potential crushed grain is assorted: P site doped is feasible in theory, but the doping of carrying out phosphate potential is separately seldom arranged.^ such as Zhang Yurong have studied olivine structural Li2+2xTi2-xCu2x (NbO) 2, and having obtained conductivity by Ti and Cu replacement P is that 1.26 * 10-6S/cm-adds, and initial discharge capacity is the positive electrode of 805.8mAh/g.Such material has higher conductivity, but owing to Fe is all replaced by Ti and Cu, ' guiding discharge voltage is lower, and cycle performance is poor.Though phosphate potential is feasible in theory, study less relatively.
By retrieval, put down in writing 1043 of relevant lithium battery applications for a patent for invention, 2181 of lithium ion battery applications for a patent for invention at present, wherein having a great deal of is relevant method of mixing.
Be confirmed to be the lithium position in theory, or the iron position, or phosphate potential obtains mixing and role, and relevant authoritative experts still have different separately brilliant idea, also constantly studying, exploring.
Present more consistent viewpoint is, LiFePO4 has that fail safe is good, pollution-free, stable cycle performance, specific capacity is high and advantage such as cheap, but also has poorly conductive and the lower shortcoming of tap density.Poorly conductive is to influence the biggest factor that LiFePO4 is used, and conductivity can be improved by mixing, and high-rate charge-discharge capability also improves, and has suppressed the effect of capacity attenuation to a certain extent.The doping approach can improve, improve the lithium ion anode material performance, has been a kind of feasible mode of generally acknowledging.
Summary of the invention
The objective of the invention is to: based on the structural limitations of the lithium iron phosphate positive material (LiFePO4) of prior art, there are its poorly conductive and the low deficiency of lithium ion diffusion coefficient, now propose manganese, barium activation lithium iron phosphate positive material preparation method that the activation of a kind of manganese, barium improves its performance.
The present invention has been a kind of feasible mode of generally acknowledging in view of the doping approach can improve, improve the lithium ion anode material performance.According to the chemical property of barium/lithium, electric property, crystal structure characteristic is the characteristics of akin element:
Barium is element the most active in the alkaline-earth metal, because it is very active, and oxidized easily, should be kept in kerosene and the atoleine.
5.212 electron-volts of ionization energy, the first ionization energy 502.9kJ/mol;
Crystal structure: structure cell is body centred cubic cell, and each structure cell contains 2 metallic atoms;
Brilliant bag parameter: a=502.8pm; B=502.8pm; C=502.8pm; α=90 °; β=90 °; γ=90 °.
Lithium, metallic element can react with a large amount of inorganic reagents and organic reagent.All can chemical combination with oxygen, nitrogen, sulphur etc., because easily oxidated and deepening, and density is littler than kerosene, so should deposit in the atoleine.
5.392 electron-volts of ionization energy, the first ionization energy 520.2kJ/mol;
Crystal structure: structure cell is body centred cubic cell, and each structure cell contains 2 metallic atoms;
Cell parameter: a=351pm; B=351pm; C=351pm; α=90 °; β=90 °; γ=90 °.
Think that barium should be to be easy to the doping effect of lithium position most.The present invention be mix by barium test, in the situation of mixing with barium, can add 1-2 other element again, constitute 2 yuan or 3 yuan of doping, with obtained performance anode material of lithium battery preferably.
Manganese of the present invention, barium activation lithium iron phosphate positive material, it is characterized in that: its chemical composition or chemical general formula can be expressed as: LiMnxBayFePO
4, x=0.00002-0.00005, y=0.0003; Wherein the mol of Li, Mn, Ba, Fe, P ratio is: 1mol Li: 0.00002-0.00005mol Mn: 0.0003mol Ba: 1 mol Fe: 1mol P.
Manganese of the present invention, barium activation lithium iron phosphate positive material preparation method, it is characterized in that: its lithium source, source of iron, the phosphoric acid root, the manganese source, the raw material in barium source, according to 1mol Li: 0.00002-0.00005mol Mn: 0.0003mol Ba: 1mol Fe: after 1mol P ratio is mixed, in ethanol medium, rotating speed 200-800r/min high speed ball milling 15-20h, with 105-120 ℃ of oven dry, obtain presoma, the presoma that oven dry is obtained places in the high temperature furnace, in nitrogen atmosphere, through 500-750 ℃ of high-temperature calcination 16-24h, namely get manganese of the present invention, barium activation lithium iron phosphate positive material.Its lithium source is one of lithium carbonate, lithium hydroxide, source of iron is ferrous oxalate, the phosphoric acid root is one of ammonium dihydrogen phosphate or diammonium hydrogen phosphate, the manganese source is one of the inferior manganese of carbonic acid, manganous hydroxide, manganese dioxide, and the barium source is one of brium carbonate, barium hydroxide, barium chloride, barium nitrate, barium monoxide, barium sulphide.
The present invention's beneficial effect compared with prior art: manganese of the present invention, barium activation lithium iron phosphate positive material preparation method, the gained material is perhaps because a small amount of manganese, barium of replacing that mixes, be conducive to control pattern and the particle diameter of product, obtain stable LiFePO4 compound, manganese, barium ions occupy the replacement lithium ion, its lattice has obtained activation, has improved the lithium ion diffusion coefficient; The doping ion though mixing, barium lithium position can improve conductivity of electrolyte materials, owing to can hinder the diffusion of lithium ion in the one dimension passage, thereby be unfavorable for improving the high-rate charge-discharge capability of material.Product unit cell volume after manganese mixes all has minimizing, and electronic conductivity improves than the electronic conductivity of LiFePO4, and its impedance in electrolyte solution is significantly reduced, and chemical property also obviously improves; Its first discharge capacity reach 160.52mAh/g; The relative lithium electrode current potential of its charge and discharge platform is about 3.5V, and initial discharge capacity surpasses 168mAh/g, and capacity decays about 1.2% approximately after 100 charge and discharge cycles; Specific capacity and cyclical stability and unadulterated LiFePO4 discharge capacity first have only 116.25mAh/g to compare, and are greatly improved.
Embodiment
The invention will be further described below in conjunction with embodiment, but embodiments of the present invention are not limited thereto.
Below adopt the calcination method synthetic method, to manganese of the present invention, barium activation lithium iron phosphate positive material preparation method, be illustrated.
Manganese of the present invention, barium activation lithium iron phosphate positive material preparation method, its lithium source can be used: lithium salts such as lithium carbonate, lithium hydroxide or lithium dihydrogen phosphate, source of iron can be used: ferrous oxalate etc., the phosphoric acid root can be used: ammonium dihydrogen phosphate or diammonium hydrogen phosphate etc., the manganese source is the inferior manganese MnCO3 of carbonic acid,, manganous hydroxide Mn (OH) 2, manganese dioxide MnO2 etc., the barium source can be used: barium salts such as brium carbonate, barium hydroxide, barium chloride, barium nitrate, barium monoxide, barium sulphide.
Select for use: lithium carbonate (Li2CO3) (99.73%), manganese dioxide (99.8%), brium carbonate (BaCO3) (99.8%), ferrous oxalate (FeC2O4.2H2O) (99.06%), diammonium hydrogen phosphate (NH4H2PO4) (98%) is raw material; According to 1mol Li: 0.00002-0.00005mol Mn: 0.0003mol Ba: 1mol Fe: after 1mol P ratio is mixed, in ethanol medium, rotating speed 200-800r/min high speed ball milling 15-20h, with 105-120 ℃ of oven dry, obtain presoma, the presoma that oven dry is obtained places in the high temperature furnace, in blanket of nitrogen, through 500-750 ℃ of high-temperature calcination 16-24h, namely get manganese of the present invention, barium activation lithium iron phosphate positive material.
Embodiment 1
Li2CO3 (99.73%), MnO2 (99.8%), BaCO3 (99.8%), FeC2O4.2H2O (99.06%), NH4H2PO4 (98%) raw material, according to 1mol Li: 0.00002molMn: 0.0003mol Ba: 1mol Fe: after 1mol P ratio is mixed, in absolute ethyl alcohol (AR) medium, high speed ball milling 20h (rotating speed 200r/min).After the 105-120 ℃ of oven dry, obtain presoma, the presoma that oven dry is obtained places in the high temperature furnace, in common purity nitrogen (>99.5%) atmosphere, and through 500-750 ℃, high-temperature calcination 24h.Namely get manganese of the present invention, barium activation lithium iron phosphate positive material.
Embodiment 2 (not mixing contrast)
With Li2CO3 (99.73%), FeC2O4.2H2O (99.06%), NH4H2PO4 (98%) raw material, according to 1mol Li: 1mol Fe: after 1mol P ratio is mixed, in absolute ethyl alcohol (AR) medium, high speed ball milling 20h (rotating speed 200r/mimn.After the 105-120 ℃ of oven dry, obtain presoma, the presoma that oven dry is obtained places in the high temperature furnace, in common purity nitrogen (>99.5%) atmosphere, and through 500-750 ℃, high-temperature calcination 24h.Namely get lithium ion anode material.
Adopt the testing equipment of prior art and the method for testing of prior art, to manganese, the barium activation lithium iron phosphate positive material of above embodiment 1, carry out test result with the comparative examples 2 of not mixing and be:
The manganese of the embodiment of the invention 1, barium activation lithium iron phosphate positive material, discharge capacity reaches more than the 155.52mAh/g first; Unadulterated LiFePO4 discharge capacity first has only in the 116.25mAh/g.
The barium activation lithium iron phosphate positive material of the embodiment of the invention 1, the relative lithium electrode current potential of its charge and discharge platform is about 3.5V, and initial discharge capacity surpasses 164mAh/g, and capacity decays about 3.0% approximately after 100 charge and discharge cycles.
Barium activation lithium iron phosphate positive material preparation method of the present invention, assorted after mixing, the raising of gained material specific capacity and cyclical stability, perhaps this be because a small amount of manganese, barium of replacing that mixes, be conducive to control pattern and the particle diameter of product, obtain stable LiFePO4 compound, barium ions occupies the replacement lithium ion, its lattice has obtained activation, has improved the lithium ion diffusion coefficient; The doping ion though mixing, barium lithium position can improve conductivity of electrolyte materials, owing to can hinder the diffusion of lithium ion in the one dimension passage, thereby be unfavorable for improving the high-rate charge-discharge capability of material.And the doping of iron position can improve the rate charge-discharge performance of LiFePO4, improves cycle performance.Product unit cell volume after manganese mixes all has minimizing, and electronic conductivity improves than the electronic conductivity of LiFePO4, and its impedance in electrolyte solution is significantly reduced, and chemical property also obviously improves; Its first discharge capacity reach 155.52mAh/g; The relative lithium electrode current potential of its charge and discharge platform is about 3.5V, and initial discharge capacity surpasses 164mAh/g, and capacity decays about 3.0% approximately after 100 charge and discharge cycles; Specific capacity and cyclical stability and unadulterated LiFePO4 discharge capacity first have only 116.25mAh/g to compare, and are greatly improved.Be to replace manganese, barium on a small quantity owing to mix, be conducive to control pattern and the particle diameter of product, obtain stable LiFePO4 compound, its lattice has obtained activation, has improved the result of lithium ion diffusion coefficient.
Claims (1)
1. manganese, barium activation lithium iron phosphate positive material preparation method, it is characterized in that: its lithium source, source of iron, the phosphoric acid root, the manganese source, the raw material in barium source, according to 1mol Li: 0.00002-0.00005mol Mn: 0.0003mol Ba: 1mol Fe: after 1mol P ratio is mixed, in ethanol medium, rotating speed 200-800r/min high speed ball milling 15-20h, with 105-120 ℃ of oven dry, obtain presoma, the presoma that oven dry is obtained places in the high temperature furnace, in nitrogen atmosphere, through 500-750 ℃ of high-temperature calcination 16-24h, namely get manganese, barium activation lithium iron phosphate positive material.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
CN2011103359417A CN102437332B (en) | 2011-10-26 | 2011-10-26 | Preparation method of manganese and barium activated lithium iron phosphate as cathode material |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
CN2011103359417A CN102437332B (en) | 2011-10-26 | 2011-10-26 | Preparation method of manganese and barium activated lithium iron phosphate as cathode material |
Publications (2)
Publication Number | Publication Date |
---|---|
CN102437332A CN102437332A (en) | 2012-05-02 |
CN102437332B true CN102437332B (en) | 2013-10-09 |
Family
ID=45985298
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
CN2011103359417A Active CN102437332B (en) | 2011-10-26 | 2011-10-26 | Preparation method of manganese and barium activated lithium iron phosphate as cathode material |
Country Status (1)
Country | Link |
---|---|
CN (1) | CN102437332B (en) |
Citations (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN101393982A (en) * | 2008-10-28 | 2009-03-25 | 南京海泰纳米材料有限公司 | Method for producing carbon coated nano stage lithium iron phosphate by precipitation |
CN101582498A (en) * | 2009-06-18 | 2009-11-18 | 东北师范大学 | Method for preparing nanometer ferrous phosphate lithium /carbon composite material |
Family Cites Families (1)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
JP4703985B2 (en) * | 2004-08-02 | 2011-06-15 | 住友大阪セメント株式会社 | Method for producing positive electrode active material for lithium battery |
-
2011
- 2011-10-26 CN CN2011103359417A patent/CN102437332B/en active Active
Patent Citations (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN101393982A (en) * | 2008-10-28 | 2009-03-25 | 南京海泰纳米材料有限公司 | Method for producing carbon coated nano stage lithium iron phosphate by precipitation |
CN101582498A (en) * | 2009-06-18 | 2009-11-18 | 东北师范大学 | Method for preparing nanometer ferrous phosphate lithium /carbon composite material |
Non-Patent Citations (1)
Title |
---|
JP特开2006-48991A 2006.02.16 |
Also Published As
Publication number | Publication date |
---|---|
CN102437332A (en) | 2012-05-02 |
Similar Documents
Publication | Publication Date | Title |
---|---|---|
CN102347486B (en) | Method for preparing barium-activated lithium iron phosphate cathode material | |
CN102376954A (en) | Lithium iron phosphate anode material with activating aluminum and barium | |
CN102376952B (en) | Preparing method for aluminium and barium activated lithium iron phosphate positive electrode material | |
CN102509796B (en) | Preparation method of boron and barium activated lithium iron phosphate anode material | |
CN102364734B (en) | Method for preparing antimony and barium activated lithium iron phosphate cathode material | |
CN102376953B (en) | Preparing method for calcium and barium activated lithium iron phosphate positive electrode material | |
CN102509798B (en) | Preparation method of copper-barium-activated lithium iron phosphate anode material | |
CN102386403B (en) | Preparation method for magnesium/barium-activated lithium iron phosphate cathode material | |
CN102437332B (en) | Preparation method of manganese and barium activated lithium iron phosphate as cathode material | |
CN102347491B (en) | Method for preparing cadmium-barium-activated lithium iron phosphate cathode material | |
CN102386402B (en) | Preparation method of cobalt/barium activated lithium iron phosphate anode material | |
CN102437328B (en) | Preparation method of germanium and barium activated lithium iron phosphate as cathode material | |
CN102361078B (en) | Method for preparing nickel and barium activated lithium iron phosphate cathode material | |
CN102354755B (en) | Preparation method of strontium and barium activated lithium iron phosphate positive pole material | |
CN102364735B (en) | Preparation method of beryllium and barium activated lithium iron phosphate positive electrode material | |
CN102386401B (en) | Method for preparing molybdenum barium activated lithium iron phosphate anode material | |
CN102437333B (en) | Preparation method of bismuth and barium activated lithium iron phosphate as cathode material | |
CN102361083B (en) | Method for preparing vanadium and barium activated lithium iron phosphate anode material | |
CN102437329B (en) | Preparation method of titanium and barium activated lithium iron phosphate as cathode material | |
CN102509793B (en) | Method for preparing zinc and barium activated lithium iron phosphate cathode material | |
CN102364733B (en) | Method for preparing antimony and barium activated lithium iron phosphate cathode material | |
CN102386406A (en) | Preparation method of selenium and barium activated lithium iron phosphate anode materials | |
CN102386399A (en) | Cobalt and barium activated lithium iron phosphate anode material | |
CN102347488A (en) | Manganese-barium-activated lithium iron phosphate cathode material | |
CN102361076A (en) | Titanium barium activated lithium iron phosphate cathode material |
Legal Events
Date | Code | Title | Description |
---|---|---|---|
C06 | Publication | ||
PB01 | Publication | ||
C10 | Entry into substantive examination | ||
SE01 | Entry into force of request for substantive examination | ||
C14 | Grant of patent or utility model | ||
GR01 | Patent grant | ||
TR01 | Transfer of patent right |
Effective date of registration: 20191107 Address after: No.678-15, Xinmin North Road, Wutong street, Tongxiang City, Jiaxing City, Zhejiang Province Patentee after: Tongxiang Levi new materials Co., Ltd. Address before: 542800 the Guangxi Zhuang Autonomous Region Hezhou City eight step District No. 40 West Lane Patentee before: Wei Gulin |
|
TR01 | Transfer of patent right |