WO2008022508A1 - Technique de préparation de lithium fer phosphate par le biais d'un procédé par voie humide et lithium fer phosphate préparé selon cette technique - Google Patents

Technique de préparation de lithium fer phosphate par le biais d'un procédé par voie humide et lithium fer phosphate préparé selon cette technique Download PDF

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WO2008022508A1
WO2008022508A1 PCT/CN2007/000577 CN2007000577W WO2008022508A1 WO 2008022508 A1 WO2008022508 A1 WO 2008022508A1 CN 2007000577 W CN2007000577 W CN 2007000577W WO 2008022508 A1 WO2008022508 A1 WO 2008022508A1
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compound
lithium
powder
iron phosphate
suspension
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PCT/CN2007/000577
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English (en)
French (fr)
Inventor
Linzhi Zhao
Wenman Li
Rongfu Li
Chunsheng Li
Qingtao Chen
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Henan Huan Yu Group Co. Ltd
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Publication of WO2008022508A1 publication Critical patent/WO2008022508A1/zh

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    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01MPROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
    • H01M4/00Electrodes
    • H01M4/02Electrodes composed of, or comprising, active material
    • H01M4/36Selection of substances as active materials, active masses, active liquids
    • H01M4/58Selection of substances as active materials, active masses, active liquids of inorganic compounds other than oxides or hydroxides, e.g. sulfides, selenides, tellurides, halogenides or LiCoFy; of polyanionic structures, e.g. phosphates, silicates or borates
    • H01M4/5825Oxygenated metallic salts or polyanionic structures, e.g. borates, phosphates, silicates, olivines
    • CCHEMISTRY; METALLURGY
    • C01INORGANIC CHEMISTRY
    • C01BNON-METALLIC ELEMENTS; COMPOUNDS THEREOF; METALLOIDS OR COMPOUNDS THEREOF NOT COVERED BY SUBCLASS C01C
    • C01B25/00Phosphorus; Compounds thereof
    • C01B25/16Oxyacids of phosphorus; Salts thereof
    • C01B25/26Phosphates
    • C01B25/45Phosphates containing plural metal, or metal and ammonium
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01MPROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
    • H01M10/00Secondary cells; Manufacture thereof
    • H01M10/05Accumulators with non-aqueous electrolyte
    • H01M10/052Li-accumulators
    • H01M10/0525Rocking-chair batteries, i.e. batteries with lithium insertion or intercalation in both electrodes; Lithium-ion batteries
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02EREDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
    • Y02E60/00Enabling technologies; Technologies with a potential or indirect contribution to GHG emissions mitigation
    • Y02E60/10Energy storage using batteries

Definitions

  • the invention relates to a preparation method of a lithium ion battery cathode active lithium iron phosphate and a product thereof, in particular to a method for preparing a lithium iron phosphate by a wet method and a product thereof.
  • Lithium-ion secondary batteries are a new generation of green energy, with high energy density, high cycle performance, low self-discharge rate, no memory effect, wide operating temperature range, etc., and have been used in mobile phones, laptops, camcorders, power tools, etc. Widely used in the field, it is marching into the field of electric vehicles. However, the research and application of cathode materials for lithium ion batteries are mostly concentrated on
  • LiC. 0 2 LiNi0 2 and LiMn 2 0 4, and the like.
  • spinel LiMn 2 0 4 has low cost and good safety, but poor cycle performance and temperature performance
  • LiNi0 2 has lower cost and higher capacity, but preparation is difficult, material consistency and reproducibility are poor, and there are Serious safety issues
  • LiC. 0 2 Due to its excellent comprehensive performance, it is currently the only large-scale commercial production of lithium ion battery cathode materials, but it is expensive, has certain toxicity and has certain safety problems.
  • LiFeP0 4 with olivine structure has the function of inserting and removing lithium, which makes LiFeP0 4 materials widely concerned and actively researched and developed.
  • the raw material resources are abundant and easy to obtain, and the structures of LiFeP0 4 and FeP0 4 are stable below 40 CTC; the theoretical discharge specific capacity is 170 mA / g and most of them can be exploited and utilized, and the operating voltage is 3.0 V (high magnification) - 3.4 V (low Magnification), very stable, good compatibility with electrolyte, the volume is only reduced by 6.5% during charging, and it is matched with the micro-increased volume of carbon negative electrode charging, especially LiFeP0 4 is non-toxic, high temperature performance, good cycle performance and safety. Good sex, there is hope for the popularity of electric vehicles. Therefore, it is expected that LiFeP0 4 will revolutionize lithium-ion batteries, making lithium-ion batteries universally applicable in electric vehicles.
  • the actual preparation method of lithium iron phosphate is mostly a high temperature solid phase method.
  • the so-called solid phase method refers to the solid Li source, Fe source, P source compound, miscellaneous element compound and reducing conductive additive, and the solid raw material is proportioned in the ball mill for a long time (for example: 18-36 hours, there are also 18 -48 hours, etc.) Grind the mixture, then take the medium and high temperature sections one or two times.
  • This method has the following disadvantages:
  • the method for preparing lithium iron phosphate by the wet method has the advantages of simple process, suitable industrialized continuous production, uniform mixing of raw materials, consistent product performance, and stable quality of prepared lithium iron phosphate, thereby overcoming the current production of lithium iron phosphate. The problem.
  • the method for preparing the lithium iron phosphate by the wet method of the invention has the following steps:
  • n is the valence of the doping element M
  • m is the number of moles of the compound containing Li
  • (lm) /n is the number of moles of the compound containing the impurity element M
  • p and q are respectively containing Fe and P0
  • the molar ratio meets the requirements of the following formula:
  • the number of moles of solid compound (weight of compound X its content) / molar mass;
  • the water-soluble Li+-containing compound is one of lithium acetate, lithium hydroxide, lithium oxalate, lithium citrate, lithium dihydrogen phosphate, lithium chloride or lithium nitrate
  • Fe 2+ compound is ferrous acetate, ferrous lactate, ferrous citrate, ferrous ammonium citrate, ferrous chloride or ferrous nitrate
  • water soluble P0-compound is phosphoric acid, lithium dihydrogen phosphate, phosphoric acid One of dihydrogen ammonium, diammonium hydrogen phosphate or ammonium phosphate; in addition to producing the desired product, other by-products are all relevant compounds which are easily removed during the preparation process;
  • the compound containing the doping element M is selected from a compound containing a high-valent element having an ionic radius close to a Li + radius such as Mg 2+ , yttrium, Zr 4+ or Nb 5+ , and the compound containing the doping element M is a doping element M
  • a doping element M One of an oxide, a hydroxide, a chloride, a nitrate, an organic acid salt or a metal organic compound;
  • the concentration of each solution is determined to be related to the solubility of the raw material compound, and the solid-liquid ratio during spray drying is also considered to be within the appropriate range, which is determined by the type of spray drying equipment that is available.
  • the reducing conductive additive is added to the suspension while stirring at a rotation speed of 120 rpm, and stirring is further continued for 1-3 hours to uniformly mix the suspension; the reducing conductive additive is carbon or pyrolysis can be produced.
  • One of the carbon compounds or any group thereof, or the reduced conductive additive is one of carbon or pyrogenic carbon-generating compounds or any combination thereof and a fine inert metal powder or an inert metal compound which can be reduced to the metal in a subsequent process.
  • One; one or a combination of carbon or pyrogenic carbon-generating compounds is added in an amount of from 3 to 15% by weight of the intended product, and the amount of the fine inert metal-added powder is 1% by weight of the intended product, and the inert metal is added.
  • the content of the inert metal in the compound is 1% by weight of the estimated product; wherein the carbon is superconducting carbon black or ultrafine graphite; wherein the pyrogenic carbon-generating compound is an organic compound-sucrose or citric acid, a natural polymer compound-starch Or a synthetic polymer compound-one of a polyethylene powder or a polyvinyl alcohol; wherein the powder of the fine inert metal is a powder of Ag or Cu; Yi can be reduced to, hydroxide, nitrate, organic acid salt, or one oxide of Cu or Ag for the metal organic compound of a metal inert;
  • the above uniformly mixed suspension is sent to the top of the spray drying tower by a metering pump, atomized by a centrifugal nozzle rotating at a speed of 18000-24000 rpm, and mixed with 260-31 CTC hot air at the inlet of the spray drying tower for air drying and drying.
  • the powder is collected by a cyclone and a bag filter having an inlet temperature of 100 to 120 Torr to obtain a mixture powder of each reaction product and by-product;
  • the mixture powder collected by the bag filter is sent to a high temperature furnace, and is calcined at a temperature of 350-50 CTC for 5-20 hours in a non-oxidizing atmosphere, and then baked at 600-80 (TC constant temperature for 5-20 hours, and then cooled.
  • the lithium ion battery cathode active lithium iron phosphate crystal powder is obtained by pulverizing and passing through a 300 mesh sieve; or it is baked at a constant temperature of 350 to 500 ° C for 5-25 hours in a non-oxidizing atmosphere, and then cooled to room temperature.
  • the positive electrode active material of the lithium ion battery is obtained. Lithium iron phosphate powder.
  • the mixed reaction solution is a suspension after performing a sufficient deposition reaction, and refers to a solid phase in the mixed solution according to the formula (2).
  • the precipitation of the deposition reaction is insufficient or the product Li J um) / n FeP0 4 (or LiFeP0 4 ) is partially dissolved and hydrolyzed, the by-product is dissolved in water, and the reaction product and by-products together form a relatively complex suspension mixture.
  • the raw material component solution is quickly and concurrently added to the reactor and stirred vigorously to maintain a large degree of supersaturation, so that the nucleation rate of Li ra M( 1-m)/n FeP0 4 (or LiFeP0 4 ) is much faster than the grain growth rate.
  • the crystal grains can be kept in the nanometer range, and the aggregated particles are in the micron range.
  • the reduced conductive additive means that the carbon produced by the addition or pyrolysis is both a conductive agent and a Fe 3+ is reduced to Fe 2+ at a high temperature, and has the dual functions of reduction and conduction.
  • the spray drying results in a homogeneous mixture of the respective reaction products and by-products centered on the LiJd FeP0 4 (or LiFePO 4 ) crystal nucleus or crystallites, and the by-products can be completely removed during the subsequent calcination.
  • the high temperature furnace is one of a tubular furnace, a box furnace, a tunnel furnace or a vertical furnace, and the latter two may also be of a discontinuous or continuous type.
  • the non-oxidizing atmosphere is an oxygen-free N 2 atmosphere, an Ar atmosphere, a N 2 mixed gas atmosphere, or one of Ar and a mixed gas atmosphere.
  • the method for preparing lithium iron phosphate by the wet method of the invention has the advantages of simple process and continuous production; uniform mixing of raw materials and uniform product performance, which can avoid the disadvantages of uneven performance of the dry mixing method, so that Li+, Fe 2+ , P0 and Mn + are uniformly mixed at the ion (equivalent to atomic) level, and a preliminary deposition reaction of LiFeP0 4 nucleus or crystallite is carried out, followed by spray drying and calcination, thereby easily producing an electrochemically superior and uniform carbon. Cover LiJi crea- strict) /n FeP0 4 (or LiFeP0 4 ) products.
  • the lithium ion battery cathode active material lithium iron phosphate prepared by the wet preparation method of the present invention is nanometer-sized, and its agglomerated particle size is below ⁇ , from its X-ray diffraction. It can be seen that it is an olivine-type structure and has no heterogeneous peaks. From its scanning electron micrograph, it can be seen that the particles are relatively uniform and mostly ⁇ 10 ⁇ m, and its particle size distribution map further proves that the particle size is below ⁇ ⁇ ⁇
  • the lithium ion battery assembled by the present invention has higher capacity, better high rate discharge performance and cycle performance.
  • Example 1 is an X-ray diffraction spectrum of 1 ⁇ ? ⁇ 4 prepared as in Example 1.
  • LiFeP0 4 is a scanning electron micrograph of LiFeP0 4 prepared in accordance with Example 1.
  • Fig. 3 is a graph showing the particle size distribution of 1?? 0 4 prepared in accordance with Example 1.
  • Figure 4 is a charge and discharge curve of a 14500-500 mAh cylindrical lithium ion battery prepared according to the LiFePCU ⁇ positive electrode active material prepared in Example 1.
  • 5 is a graph showing the discharge rate of each of the 14500-500 mAh cylindrical lithium ion batteries prepared by the LiFePCM ⁇ positive active material prepared in Example 1.
  • Li + + Fe 2+ +P0 LiFeP0 4 (4)
  • the above powder mixture was transferred to a box type high temperature furnace and heated at 360 ⁇ 10 ° C for 20 hours under a mixed atmosphere of (90% Ar + 10% 3 ⁇ 4), and then heated to 710 ⁇ 15 Torr for 5 hours at a constant temperature. Then, it was cooled to room temperature, taken out, pulverized, and passed through a 300 mesh sieve to obtain a lithium iron phosphate powder product.
  • Figure 1 is an X-ray diffraction pattern of the LiFePO 4 active prepared in Example 1, which was confirmed to be an olivine structure and free of impurity phases.
  • 2 is a scanning electron micrograph of the LiFePO 4 active prepared in Example 1, and it can be seen that most of the particles are ⁇ 10 ⁇ .
  • Fig. 3 is a particle size distribution diagram of the LiFePCV product prepared in Example 1, and further confirmed that the particle size fraction is 10 m or less.
  • Figure 4 is a preparation of a positive electrode active material prepared by a skilled worker using the LiFePO 4 prepared in Example 1 according to a conventional production process.
  • FIG. 1 is the 1C charge / 1C discharge cycle life curve of the 14500-500mAh cylindrical lithium ion battery in the same figure (unfinished).
  • Example 1 138 130 129 125 125 123 114
  • Example 1 The data in Table 1 and Figure 6 demonstrate that the lithium iron phosphate material prepared in Example 1 not only has high specific capacity and charge and discharge efficiency, but also has excellent high rate discharge performance and cycle performance.
  • reaction product and the by-product together form a suspension
  • the above powder mixture is spread on a material plate, sent to a high-temperature tunnel furnace in a high-purity nitrogen atmosphere, and calcined at a constant temperature of 490 ⁇ 10 ° C for 25 hours, then cooled to room temperature and taken out, and ball milled and mixed. 90% N 2 +10%3 ⁇ 4) in a high-temperature tunnel furnace with mixed atmosphere, calcined at 700 ⁇ 10°C for 10 hours, then cooled to room temperature, taken out, crushed, and sieved through 300 mesh to obtain Mg-doped lithium iron phosphate. (Li ⁇ Mg ⁇ FePOj material.
  • Table 1 lists the high-rate discharge capacities of the 1C-charged 1450-500 mAh cylindrical lithium ion battery prepared by using the lithium iron phosphate prepared in Example 2 as a positive electrode active material and a graphite carbon negative electrode.
  • reaction product and the by-product together form a suspension
  • the above uniformly mixed suspension is sent to the top of the spray drying tower by a metering pump, atomized by a centrifugal nozzle rotating at a speed of 18000-24000 rpm, and mixed at 290-310 Torr hot air at the inlet of the spray drying tower for air drying.
  • the dried powder is collected by a cyclone and a bag filter having an inlet temperature of 100 to 120 ° C to obtain a mixture powder of each reaction product and by-product;
  • the powder mixture is transferred to a tube-type high-temperature furnace and calcined at 490 ⁇ 10 ° C for 5 hours under an argon atmosphere, and then heated to 610 ⁇ 10 ° C for 20 hours at a constant temperature, and then cooled to room temperature and taken out.
  • the zirconium-doped lithium iron phosphate powder product is pulverized and sieved through 300 mesh.
  • Table 1 lists the high-rate discharge capacities of the 1C-charged 1450-500 mAh cylindrical lithium ion battery prepared by using the lithium iron phosphate prepared in Example 3 as a positive electrode active material and a graphite carbon negative electrode.
  • the above uniformly mixed suspension is sent to the top of the spray drying tower by a metering pump, atomized by a centrifugal nozzle rotating at a speed of 18000-24000 rpm, and mixed with hot air at 280-310 °C at the inlet of the spray drying tower.
  • the air stream is dried, and the dried powder is collected by a cyclone and a bag filter having an inlet temperature of 100 to 120 ° C to obtain a mixture powder of each reaction product and by-product;
  • the above powder mixture is transferred to a high-temperature vertical furnace and calcined at 490 ⁇ 10 °C for 5 hours under high-purity nitrogen atmosphere, then cooled to room temperature and taken out. After ball milling for 1 hour, it is sent to a tunnel furnace. (90% N 2 +10%) 610 soil was mixed at a constant temperature of 10 ° C for 20 hours in a mixed atmosphere, then cooled to room temperature and taken out, crushed and sieved through 300 mesh to obtain lithium doped lanthanum silicate.
  • Table 1 lists the high-rate discharge capacities of the 1C-charged 1450-500 mAh cylindrical lithium ion battery prepared by using the lithium iron phosphate prepared in Example 4 as a positive electrode active material and a graphite carbon negative electrode.
  • Example 2 The operation was carried out as in Example 1, except that it was calcined at a constant temperature of 450 ⁇ 10 Torr for 10 hours in a box-type high-temperature furnace under Ar atmosphere, and calcined at 790 ⁇ 10 ° C for 5 hours.
  • Table 1 lists the high-rate discharge capacities of the 1C-charged 1450-500 mAh cylindrical lithium ion battery prepared by using the lithium iron phosphate prepared in Example 5 as a positive electrode active material and a graphite carbon negative electrode. 'Example 6 ⁇
  • Example 4 Operate exactly as in Example 4, except that in a high temperature vertical furnace, a high temperature nitrogen atmosphere is baked at a constant temperature of 360 ⁇ 10 ° C for 10 hours. At the time, the furnace was heated at 790 ⁇ 10 ° C for 5 hours in a mixed atmosphere of (90 ° + 10%).
  • Table 1 lists the high-rate discharge capacities of the 1C-charged 1450-500 mAh cylindrical lithium ion battery prepared by using the lithium iron phosphate prepared in Example 6 as a positive electrode active material and a graphite carbon negative electrode.
  • the method for preparing lithium iron phosphate by wet method has the advantages of simple process, suitable industrialized continuous production, uniform mixing of raw materials and uniform product performance, and the prepared lithium iron phosphate has stable quality, and the crystal grains thereof are nano-sized and agglomerated particle size. Below 10 ⁇ ⁇ .
  • the lithium ion battery assembled by the lithium iron phosphate prepared by the invention has higher capacity, better high rate discharge performance and cycle performance.

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Description

湿法制备磷酸亚铁锂的方法及其制备的磷酸亚铁锂 技术领域
本发明涉及一种锂离子电池正极活性物磷酸亚铁锂的制备方法及其产品, 尤其涉及一种 湿法制备磷酸亚铁锂的方法及其产品。 背景技术
锂离子二次电池是新一代绿色能源, 具有高能量密度、 高循环性能、 低自放电率、 无记 忆效应、 工作温度范围宽等优点, 已在移动电话、 手提电脑、 摄像机、 电动工具等诸多领域 广泛应用, 正在向电动车领域进军。 但目前锂离子电池正极材料的研究和应用, 多集中于
LiC。02、 LiNi02和 LiMn204等。 其中尖晶石 LiMn204成本低, 安全性较好, 但循环性能和髙 温性能差; LiNi02成本较低, 容量较高, 但制备困难, 材料一致性和重现性差, 且存在较严 重安全问题; LiC。02由于综合性能优良, 所以是目前唯一大规模商品化生产的锂离子电池正 极材料, 但价格昂贵, 有一定毒性且存在一定的安全问题。
1997 年 Padhi 和 Goodenoagh首次报导橄榄石结构的 LiFeP04具有插脱锂功能, 使 LiFeP04类材料受到广泛关注和积极研发。 其原料资源丰富易得, 且 LiFeP04、 FeP04结构在 40CTC以下都稳定; 理论放电比容量为 170mA /g且绝大部分可开发利用, 工作电压为 3.0 V (高倍率) 一 3.4V (低倍率), 非常平稳, 与电解液相容性好, 充电时体积仅减小 6.5%, 正 与碳负极充电时体积微增相匹配, 特别是 LiFeP04无毒、 高温性能、 循环性能好和安全性好, 使电动车普及有了希望。 因此人们期望 LiFeP04将使锂离子电池出现革命性的变化, 使锂离 子电池在电动车中普遍应用成为现实。
目前实际制备磷酸亚铁锂的方法, 多为高温固相法。 所谓固相法, 指将固态的 Li源、 Fe源、 P源化合物、 惨杂元素化合物以及还原导电添加剂, 按比例以固体原料在球磨机中长 时间 (例如: 有 18- 36小时的, 也有 18-48小时等) 研磨混合, 然后取中、 高两个温度段一 次或两次烧成。 此法有如下缺点:
1、 混合均匀的时间不易确定, 不能连续生产;
2、 为确保混合均匀宁肯延长研磨时间, 费时;
3、 容易发生各批次产品不均匀等。 发明内容 本发明的目的是提供一种湿法制备磷酸亚铁锂的方法及其制备的磷酸亚铁锂。 本发明湿 法制备磷酸亚铁锂的方法工艺简单、 适宜工业化连续化生产, 原料混合均匀、 产品性能均勾 一致, 所制备的磷酸亚铁锂质量稳定, 从而克服了目前生产磷酸亚铁锂存在的问题。
本发明湿法制备磷酸亚铁锂的方法, 其步骤如下:
1. 液相沉积制备含 Li J(1_„)/n FeP04化合物微晶或晶核的悬浊液
1 )悬浊液中含锂、 铁、 磷及掺杂元素 M的化合物符合下式:
[mLi+n(l-m)/nM]: pFe: qP04 = 1: 1: 1 (1)
(1)式中 n是掺杂元素 M的化合价, m是含 Li的化合物的摩尔数, (l-m) /n是含惨杂元 素 M的化合物的摩尔数, p、 q分别是含 Fe和 P04的化合物的摩尔数, 当(l_m) /n=0时, 含惨 杂元素 M的化合物的摩尔数为零, 即悬浊液中不含含掺杂元素的化合物, 则 Li: Fe: P的摩 尔比符合下式的要求:
mLi: pFe: qP04= l : 1: 1 (2)
固体化合物的摩尔数 = (化合物的重量 X其含量) /摩尔质量;
2)根据 (1)式分别计算并称取所需重量的可溶于水的含锂、 铁、 磷及掺杂元素 M的 各化合物, 然后分别溶解于水中, 制成各溶液; 含掺杂元素 M的化合物不溶于水的为粉末; 所述水可溶性含 Li+化合物是醋酸锂、氢氧化锂、 草酸锂、柠檬酸锂、磷酸二氢锂、 氯化 锂或硝酸锂之一; 水可溶性含 Fe2+化合物是醋酸亚铁、 乳酸亚铁、 柠檬酸亚铁、 柠檬酸亚铁 铵、 氯化亚铁或硝酸亚铁之一; 水可溶性含 P0—化合物是磷酸、 磷酸二氢锂、 磷酸二氢铵、 磷酸氢二铵或磷酸铵之一; 总之除生成期望的产物, 其它副产物为在制备过程中容易去除的 各有关化合物均可;
含掺杂元素 M的化合物选自含离子半径接近 Li+半径的高价元素如 Mg2+、 ΑΓ、 Zr4+或 Nb5+ 等的化合物, 含掺杂元素 M的化合物为含掺杂元素 M的氧化物, 氢氧化物, 氯化物, 硝酸盐、 有机酸盐或金属有机化合物之一; .
3)将上述各溶液并流加入反应器中, 在搅拌器 120转 /分转速条件下, 加入不溶于水 的含掺杂元素 M的化合物的粉末, 均匀混合, 进行液相沉积反应, 由于沉淀反应进行的不完 全且副产物溶于水,所以制得的是含沉积化合物 Li (1-m)/„ FeP04微晶或晶核及副产物溶液的悬 浊混合液;
由于液相沉积时, 大部分锂铁已同磷酸根联结, 大大减少了高温焙烧时锂的挥发, 所以 锂不必过量, 故有 [m + n (l-m) /n] = p = q并令其等于 1, 使得(3 ) 式成立:
mLi++ (l-m) /n Mn++ pFe2++ qPO— = LiJ«-mVn FeP04 (3) (1)式即由理想的沉积反应 (3)决定,不含掺杂元素 M时, (1)式变 (2):
mLi : pFe: qP= l : 1: 1 (2)
这时, m = p = q,沉积反应(3)变为反应 (4)
Li+ + Fe2+ + P04 3" - LiFeP04 (4)
配制各溶液的浓度, 既和原料化合物溶解度有关, 也要考虑喷雾干燥时的固液比在合适 的范围内, 这要根据所拥有的喷雾干燥设备类型经过调试决定。
2. 加入还原导电添加剂
在搅拌器 120转 /分转速条件下,边搅拌边向上述悬浊液中加入还原导电添加剂,再继续 搅拌 1-3小时, 使悬浊液均匀混合; 还原导电添加剂是炭或热解可产生碳的化合物之一或其 任意组 , 或者还原导电添加剂是炭或热解可产生碳的化合物之一或其任意组合和细惰性金 属的粉末或后续工艺中可以还原为该金属的惰性金属化合物之一; 加入炭或热解可产生碳的 化合物之一或其任意组合的量为预计产品重量的 3— 15%, 加入细惰性金属的粉末的量为预计 产品重量的 1%,加入的惰性金属化合物中惰性金属的含量为预计产品重量的 1%; 其中,炭为 超导炭黑或超细石墨; 其中热解可产生碳的化合物为有机化合物一蔗糖或柠檬酸、 天然高分 子化合物一淀粉或合成高分子化合物一聚乙烯粉末或聚乙烯醇之一; 其中细惰性金属的粉末 为 Ag或 Cu的粉末;在后续工艺中可以还原为该金属的惰性金属化合物为 Ag或 Cu的氧化物、 氢氧化物, 硝酸盐、 有机酸盐或金属有机化合物之一;
3. 喷雾干燥悬浊液
用计量泵将上述均匀混合的悬浊液送到喷雾干燥塔顶部, 经转速为 18000— 24000转 /分 的离心喷头雾化, 在喷雾干燥塔入口与 260— 31CTC热空气混合进行气流干燥, 干燥后的粉体 经旋风分离器和入口温度为 100— 120Ό的袋式收尘器收集, 得包含各反应产物和副产物的混 合物粉末;
4. 焙烧、 粉碎
将上述袋式收尘器收集的混合物粉末送入高温炉中,在非氧化气氛下于 350— 50CTC恒温 焙烧 5— 20小时后,再在 600— 80(TC恒温焙烧 5— 20小时,然后冷却至常温后取出,经粉碎、 过 300目筛即得锂离子电池正极活性物磷酸亚铁锂结晶粉末; 或在非氧化气氛下于 350— 500 °C恒温焙烧 5— 25小时, 然后冷却至常温后取出, 经研磨成粉末, 再送入高温炉中在非氧化 气氛中于 600— 80CTC恒温焙烧 5— 20小时, 冷却至常温后取出, 经粉碎、 过 300目筛即得锂 离子电池正极活性物磷酸亚铁锂粉末。
所述混合反应液进行充分沉积反应后为悬浊液, 是指在混合液中按 (2)式进行的固相 沉积反应沉淀不够充分或说产物 Li Ju-m)/n FeP04 (或 LiFeP04)有部分溶解和水解, 副产物溶 解于水, 反应产物和副产物一起形成组分较复杂的悬浊混合液。 各原料组分溶液快速并流加 入反应器并强力搅拌, 保持较大过饱和度, 使 LiraM(1-m)/n FeP04 (或 LiFeP04) 晶核生成速度远 大于晶粒成长速度, 可以保持晶粒在纳米级范围, 聚集的颗粒在微米级范围。
所述还原导电添加剂是指加入的或热解产生的碳既是导电剂又可在高温下还原 Fe3+为 Fe2+, 具有还原、 导电的双重作用。
喷雾干燥所得为以 LiJd FeP04 (或 LiFeP04) 晶核或微晶为中心的各反应产物和副产 物的均匀混合物粉末, 副产物在后续焙烧过程中可完全除去。
所述高温炉为管式炉、 箱式炉、 隧道炉或立式炉之一, 后二者还可以是间断式或连续式 两种。
所述的非氧化气氛为不含氧的 N2气氛、 Ar气氛、 N2与 混合气体气氛或 Ar与 混合气 体气氛之一。
本发明湿法制备磷酸亚铁锂的方法, 工艺简单、 可连续生产; 原料混合均匀、 产品性能 均匀一致, 可以避免干法混料不均匀使产品性能不均匀的弊端, 使得 Li+、 Fe2+、 P0 和 Mn+在 离子(相当于原子)水平上均匀混合, 并进行初步生成 LiFeP04晶核或微晶的沉积反应, 然后 喷雾干燥和焙烧, 容易制得电化学性能优良且较均匀的碳包覆 LiJi„-„)/n FeP04 (或 LiFeP04) 产品。
釆用本发明湿法制备磷酸亚铁锂的方法制备出的锂离子电池正极活性物磷酸亚铁锂的晶 粒为纳米级,其团聚的颗粒尺寸在 ΙΟ μ ηι以下,从其 X-射线衍射图可看出其为橄榄石型结构, 且无杂相峰; 从其扫描电镜照片可看出颗粒较均匀且大多 <10 μ ιη, 其粒径分布图, 进一步证 明粒径在 ΙΟ μ ηι以下; 釆用本发明组装的锂离子电池有较高容量、 有较好的高倍率放电性能 和循环性能。
本发明所需原料、 设备均有市售。 附图说明
图 1为按实施例 1所制备的 1^?^04的 X-射线衍射图谱。
图 2为按实施例 1所制备的 LiFeP04扫描电镜照片。
图 3为按实施例 1所制备的 1^?^04的粒径分布图。
图 4为按实施例 1所制备的 LiFePCU乍正极活性物制备的 14500- 500mAh圆柱锂离子电池 0. 2C充放电曲线。 图 5为按实施例 1所制备的 LiFePCM乍正极活性物制备的 14500- 500mAh圆柱锂离子电池 各倍率放电曲线。
图 6为按实施例 1所制备的 LiFeP04作正极活性物制备的 14500- 500mAh圆柱锂离子电池 1C/1C循环寿命曲线 (未完)。 具体实施方式
下面结合附图及实施例, 对本发明作进一步说明。
实施例 1
1.首先分别配制 ra = p = q = 126. 77 摩尔的含 Li, Fe , P 化合物的溶液, 即将 LiOH. H20 (99. 8%) 5. 33kg, Fe (CH3C00) 2.4H20 (99%) 31. 50kg , H3P04 (85%) 14. 62kg, 分别溶解于 40、 50、 30kg且温度为 50°C的水中制成溶液; 将上述三种溶液并流加入 240升反应器, 在 120转 /分搅拌速度下使其混合均匀并快速进行(4) 式的沉积反应-
Li++ Fe2++P0 = LiFeP04 (4)
主产物和各副产物一起形成悬浊液;
2. 在搅拌器 120转 /分转速条件下加入还原导电添加剂, 预计 LiFeP04产量 =126. 77 X 157. 76, 约 20kg; 边搅拌边向上述悬浊液中加入预计成品重量 15%- 3. 0 kg的热解可产生碳 的化合物和加入的惰性金属化合物中惰性金属的含量为预计产品重量的 1%-即 0. 51 kg惰性 金属化合物, 即柠檬酸 3. 0Kg及 CuC204. l/2 00. 51kg, 再继续搅拌 1-3小时, 使悬浊液均匀 混合;
3. 用计量泵将上述均匀混合的悬浊液送到喷雾干燥塔顶部,经转速为 18000—24000转 / 分的离心喷头雾化, 在喷雾干燥塔入口与 260— 280Ό热空气混合进行气流干燥, 干燥后的粉 体经旋风分离器和入口 100— 120Ό的袋式收尘器收集, 得包含各反应产物和副产物的混合物 粉末;
4.将上述粉状混合物, 移到箱式高温炉中于 (90%Ar+10%¾)混合气氛下在 360±10°C恒 温焙烧 20小时后, 升温到 710± 15Ό恒温焙烧 10小时, 然后冷却至常温后取出, 粉碎、 过 300目筛得磷酸亚铁锂粉末产品。
图 1为实施例 1所制备的 LiFeP04活性物的 X-射线衍射图谱, 证明其为橄榄石结构且无 杂质相。 图 2为实施例 1所制备的 LiFeP04活性物的扫描电镜照片, 可看出大部分颗粒 <10 μ πι。 图 3为实施例 1所制备的 LiFePCV 性物的粒径分布图, 进一步证明粒径分部在 10 m 以下。图 4为由熟练操作工人用实施例 1所制备的 LiFeP04作正极活性物按常规生产工艺制备 正极配石墨负极制备的 14500- 500mAh圆柱锂离子电池 0. 2C充放电曲线。 比容量 134mAhg, 放电平台电压大于 3. 2V且非常平稳。 图 5为同图 4的 14500-500mAh圆柱电池 0. 2C、 1. 0 C、 3. 0C、 5. 0 C、 7. 0 C、 10. 0 C放电曲线, 计算各倍率放电比容量汇总于表 1中。 图 6为同图 的 14500- 500mAh圆柱锂离子电池 1C充 /1C放循环寿命曲线 (未完)。
表 1、 实施例制备的磷酸亚铁锂各倍率放电比容量(mAh/g)
样品 0. 2C 0. 5C 1C 3C 5C 7C 10C
实施例 1 138 130 129 125 125 123 114
实施例 2 134 126 124 120 119 118 ―
实施例 3 133 124 122 119 113 111 ―
实施例 4 133 125 123 120 120 110
实施例 5 131 122 121 118 117 109 ―
实施例 6 132 123 120 119 117 111 一
表 1中的数据和图 6证明按实施例 1制备的磷酸亚铁锂材料不仅有高比容量和充放效率, 而且有很好的高倍率放电性能和循环性能。
实施例 2
1.首先分别配制 m= 124. 27摩尔, p=q= 126. 80摩尔的含 Li, Fe, P化合物的溶液, 即 将 124. 26摩尔的 LiCl (99. 6%) 5. 29kg, 126. 80摩尔的 FeCl2. 4H20 (99. 5%) 25. 34kg, 126. 80摩 尔的 (N ) 3P04. 3H20 (99. 5%) 25. 89kKg, 分别溶解于 15、 30、 80Kg且温度为 50°C的水中制成溶 液, 并把 1. 268摩尔的 MgCl2. 6 0 (98%) 263. 05g溶解于 FeCl2溶液中; 在 120转 /分搅拌速 度下分将上述三种溶液并流加入 240升反应器中, 使其混合均匀并快速进行 (31)式的沉积 反应:
0. 98Li++0.
Figure imgf000008_0001
(31 )
此时反应产物和副产物一起形成悬浊液;
2. 在搅拌器 120转 /分转速条件下加入还原导电添加剂, 预计 L Olg^Fe ?04产量约等 于 126. 8 X 157. 76, 即 20kg;边搅拌边向上述悬浊液中加入预计成品重量 3°/。- 0. 6kg炭和热解 可产生碳的化合物及预计成品重量的 1%_0. 2 kg惰性金属粉末, 即超导炭黑 0. 3kg和蔗糖 0. 3kg及 0. 2 kg超细银粉, 再继续搅拌 1-3小时, 使悬浊液均匀混合;
3. 用计量泵将上述均匀混合的悬浊液送到喷雾干燥塔顶部,经转速为 18000— 24000转 / 分的离心喷头雾化, 在喷雾干燥塔入口与 290— 31CTC热空气混合进行气流干燥, 干燥后的粉 体经旋风分离器和入口温度为 100— 120Ό的袋式收尘器收集, 得包含各反应产物和副产物的 混合物粉末;
4.将上述粉状混合物摊在料板上, 送入高纯氮气氛的高温隧道炉中, 于 490± 10°C恒温 焙烧 25小时, 然后冷却至常温后取出, 球磨研混后送入(90%N2+10%¾)混合气氛的高温隧道 炉中, 于 700± 10°C恒温焙烧 10小时, 然后冷却至常温后取出, 粉碎、过 300目筛得掺杂 Mg 的磷酸亚铁锂 (Li^Mg^FePOj材料。 ·
表 1 中列出了按实施例 2 所制备的磷酸亚铁锂作正极活性物和石墨碳负极制备的 1450-500mAh圆柱锂离子电池 1C充电的各高倍率放电容量。
实施例 3
1. 首先分别配制 m= 120. 96摩尔, q= p= 126. 00摩尔的含 Li, Fe, P化合物的溶液及 含 Zrl. 26摩尔溶液, 即将含 120. 96摩尔 Li和 P的 LiH2P04 (98. 8%) 12. 724kg和含磷 5. 0 摩 尔的(N ) H2P04 (99. 5%) 0. 583kg —起, 含 126. 00 摩尔 Fe 的 Fe (C3¾03) 2. 3 0 (含 Fe 18. 9%) 37. 23kg及含 1. 26摩尔 Zr的 Zr (N03) 4 · 5¾0 (99%) 0. 546. 5kg分别溶解于 60、 60、 5kg且温度为 50Ό的热水中制成溶液;在 120转 /分搅拌速度下将上述三种溶液并流方式加入 240升反应器中, 使其混合均匀并快速进行(32) 式的沉积反应: .
0. 96Li++0.
Figure imgf000009_0001
(32)
此时反应产物和副产物一起形成悬浊液;
2. 在搅拌器 120转 /分转速条件下加入还原导电添加剂, 预计 Li^Zr^FePO产量约为 ( 126 X 157. 76 ) 20Kg; 边搅拌边向上述悬浊液中加入预计成品重量 10%- 2. 0 Kg的炭和热解 可产生碳的化合物, 即 0. 4Kg淀粉及 1. 6Kg的聚乙烯粉末, 再继续搅拌 1-3小时, 使悬浊液 均匀混合;
3. 用计量泵将上述均匀混合的悬浊液送到喷雾干燥塔顶部,经转速为 18000— 24000转 / 分的离心喷头雾化, 在喷雾干燥塔入口与 290— 310Ό热空气混合进行气流干燥, 干燥后的粉 体经旋风分离器和入口温度为 100— 120°C的袋式收尘器收集, 得包含各反应产物和副产物的 混合物粉末;
4.将上述粉状混合物, 移到管式高温炉中于氩气氛下在 490± 10°C恒温焙烧 5小时后, 升温到 610± 10°C恒温焙烧 20小时, 然后冷却至常温后取出, 粉碎、 过 300目筛得掺杂锆的 磷酸亚铁锂粉末产品。
表 1 中列出了按实施例 3 所制备的磷酸亚铁锂作正极活性物和石墨碳负极制备的 1450-500mAh圆柱锂离子电池 1C充电的各高倍率放电容量。
实施例 4 1.首先分别配制 m= 120. 43摩尔, p=q= 126. 77摩尔的含 Li, Fe, P化合物的溶液, 即 将含 Li 120. 43摩尔的 Li (C¾C00) ·2Η20 (99. 8%) 12. 31kg,含 Fe 126. 77摩尔的 Fe (C6H607) (含 Fel6. 8%) 42. 14kg,含 P 126. 77摩尔的(NH4) 2HP04 (99. 5%) 16. 83kg, 分别溶解于 10, 70, 40kg、 且温度为 50°C的水中制成溶液; 在 120转 /分搅拌速度下将上述三种溶液并流加入 240升反 应器, 然后将 1. 2677摩尔 NbA (含量 99. 5%)粉末 338. 66g加入, 使其混合均勾并快速进行
( 33) 式的沉积反应:
0. 95 Li+ +0. 05 H+ + Fe2+ + P04 3— = Li。 5H。.。5FeP04 (33)
当高温焙烧时 Li。.95H。.。5FeP04中 0. 05H+被 0. 01Nb5+置换, 最终产物为 (Li^Nb^FePO , 此时反应产物和副产物一起形成悬浊液。
2. 在搅拌器 120转 /分转速条件下加入还原导电添加剂, 预计 Li^Nb^FePO产量约为 (126. 77 X 157. 76) 20kg, 边搅拌边向上述悬浊液中加入预计成品重量 10%- 2. 0 Kg的炭或热 解可产生碳的化合物, 即 0. 35Kg超细石墨及重量百分比浓度为 7. 5%的聚乙烯醇水溶液 22kg
(其中含聚乙烯醇 1. 65kg), 再继续搅拌 1-3小时, 使悬浊液均勾混合。
3. 用计量泵将上述均匀混合的悬浊液送到喷雾干燥塔顶部,经转速为 18000— 24000转 / 分的离心喷头雾化, 在喷雾干燥塔入口与 280— 310°C热空气混合进行气流干燥, 干燥后的粉 体经旋风分离器和入口温度为 100— 120°C的袋式收尘器收集, 得包含各反应产物和副产物的 混合物粉末;
4.将上述粉状混合物, 移到高温立式炉中于高纯氮气氛下在 490± 10°C恒温焙烧 5小时, 然后冷却至常温后取出, 球磨 1小时后送入髙温隧道炉在 (90%N2+10% )混合气氛下 610土 10°C恒温焙烧 20 小时, 然后冷却至常温后取出, 粉碎、 过 300 目筛得掺杂铌磷酸亚铁锂
(Li b„.01FeP04)粉末产品。
表 1 中列出了按实施例 4 所制备的磷酸亚铁锂作正极活性物和石墨碳负极制备的 1450-500mAh圆柱锂离子电池 1C充电的各高倍率放电容量。
实施例 5
完全按实施例 1操作, 除了在箱式高温炉中于 Ar气氛下在 450± 10Ό恒温焙烧 10小时, 790± 10°C恒温焙烧 5小时。
表 1 中列出了按实施例 5 所制备的磷酸亚铁锂作正极活性物和石墨碳负极制备的 1450-500mAh圆柱锂离子电池 1C充电的各高倍率放电容量。 ' 实施例 6 ·
完全按实施例 4操作, 除了在高温立式炉中于高纯氮气氛下在 360± 10°C恒温焙烧 10小 时, 在髙温隧道炉在(90° +10% )混合气氛下 790± 10°C恒温焙烧 5小时。
表 1 中列出了按实施例 6 所制备的磷酸亚铁锂作正极活性物和石墨碳负极制备的 1450-500mAh圆柱锂离子电池 1C充电的各高倍率放电容量。 工业实用性
本发明湿法制备磷酸亚铁锂的方法工艺简单、 适宜工业化连续化生产, 原料混合均匀、 产品性能均匀一致, 所制备的磷酸亚铁锂质量稳定, 其晶粒为纳米级, 团聚的颗粒尺寸在 10 μ ηι 以下。 采用本发明制备的磷酸亚铁锂组装的锂离子电池有较高容量、 有较好的高倍率放 电性能和循环性能。

Claims

权 利 要 求
1.一种湿法制备磷酸亚铁锂的方法, 其步骤如下:
1 ) 液相沉积制备含 Li «_»)/n FeP04化合物微晶或晶核的悬浊液
( 1 )悬浊液中含锂、 铁、 磷及掺杂元素 M符合下式:
[mLi+n(l-m)/n M]: pFe: qP04 = 1: 1 : 1 ( i )
( i )式中 n是掺杂元素 M的化合价, m是含 Li的化合物的摩尔数, (1-m) /n是含掺杂元素 M 的化合物的摩尔数, p、 q分别是含 Fe和 P04的化合物的摩尔数, 当(1- m) /n=0时, 含掺杂元 素 M的化合物的摩尔数为零, 即悬浊液中不含掺杂元素的化合物, 则 Li: Fe: P的摩尔比符 合下式的要求:
mLi: pFe: qP04= 1: 1: 1 ( ii )
(2)根据( i )式分别计算并称取所需重量的可溶于水的含锂、铁、 磷及掾杂元素 M的各化合物, 然后分别溶解于水中, 制成各溶液; 含掺杂元素 M的化合物不溶于水的为粉 末;
(3)将上述各溶液并流加入反应器中, 在搅拌器 120转 /分转速条件下, 加入不溶 于水的含掺杂元素 M的化合物的粉末, 均匀混合, 进行液相沉积反应, 制得含 Li (1-n)/n FeP04 化合物微晶或晶核的混合悬浊液;
2) 加入还原导电添加剂
在搅拌器 120转 /分转速条件下,边搅拌边向上述悬浊液中加入还原导电添加剂,再继续 搅拌 1-3小时, 使悬浊液均匀混合; 还原导电添加剂是炭或热解可产生碳的化合物之一或其 任意组合, 或者还原导电添加剂是炭或热解可产生碳的化合物之一或其任意组合和细惰性金 属的粉末或后续工艺中可以还原为该金属粉末的惰性金属化合物之一; 加入炭或热解可产生 碳的化合物之一或其任意组合的量为预计产品重量的 3— 15%, 加入细惰性金属的粉末的量为 预计产品重量的 1%, 加入的惰性金属化合物中惰性金属的含量为预计产品重量的 1%;
3) 喷雾干燥悬浊液
用计量泵将上述均匀混合的悬浊液送到喷雾干燥塔顶部, 经转速为 18000— 24000转 / 分的离心喷头雾化, 在喷雾干燥塔入口与 260— 310Ό热空气混合进行气流干燥, 干燥后的粉 体经旋风分离器和入口温度为 100—120°C的袋式收尘器收集, 得包含各反应产物和副产物的 混合物粉末; 4)焙烧、 粉碎
将上述收尘器收集的混合物粉末送入高温炉中,在非氧化气氛下于 350— 500Ό恒温焙烧 5—20小时后, 再在 600— 800Ό恒温焙烧 5— 20小时, 然后冷却至常温后取出, 经粉碎、 过 300目筛即得锂离子电池正极活性物磯酸亚铁锂结晶粉末; 或在非氧化气氛下于 350— 500'C 恒温焙烧 5— 25小时, 然后冷却至常温后取出, 经研混成粉末, 再送入高温炉中在非氧化气 氛中于 600— 800°C恒温焙烧 5— 20小时, 冷却至常温后取出, 经粉碎、 过 300目筛即得锂离 子电池正极活性物磷酸亚铁锂粉末。
2.如权利要求 1所述湿法制备磷酸亚铁锂的方法,其特征在于,所述水可溶性含 Li+化合 物是醋酸锂、 氢氧化锂、 草酸锂、 柠檬酸锂、 磷酸二氢锂、 氯化锂或硝酸锂之一; 水可溶性 含 Fe2+化合物是醋酸亚铁、 乳酸亚铁、 柠檬酸亚铁、 柠檬酸亚铁铵、 氯化亚铁或硝酸亚铁之 一; 水可溶性含 P0—化合物是磷酸、 磷酸二氢锂、 磷酸二氢铵、 磷酸氢二铵或磷酸铵之一; 含掺杂元素 M的化合物选自含离子半径接近 Li+半径的高价元素如 Mg2+、 ΑΓ、 Zr4+或 Nb5+的化 合物, 含掺杂元素 M的化合物为含掺杂元素 M的氧化物, 氢氧化物, 氯化物, 硝酸盐、 有机 酸盐或金属有机化合物之一。
3. 如权利要求 2所述湿法制备磷酸亚铁锂的方法,其特征在于,所述还原导电添加剂中 炭为超导炭黑或超细石墨; 所述热解可产生碳的化合物为有机化合物一蔗糖或柠檬酸、 天然 高分子化合物一淀粉或合成高分子化合物一聚乙烯粉末或聚乙烯醇之一; 所述细惰性金属的 粉末为 Ag或 Cu的粉末; 在后续工艺中可以还原为该金属的惰性金属化合物为 Ag或 Cu的氧 化物、 氢氧化物, 硝酸盐、 有机酸盐或金属有机化合物之一。
4. 如权利要求 3所述湿法制备磷酸亚铁锂的方法, 其特征在于, 所述高温炉为管式炉、 箱式炉、 隧道炉或立式炉之一, 其中險道炉或立式炉是间断式或连续式两种。
5. 如权利要求 4所述湿法制备磷酸亚铁锂的方法,其特征在于,所述的非氧化气氛为不 含氧的 N2气氛、 Ar气氛、 N2与 ¾混合气体气氛,或 Ar与 ¾混合气体气氛之一。
6. 如权利要求 1一 5之一所述湿法制备磷酸亚铁锂的方法制备的磷酸亚铁锂。
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