WO2016192542A1

WO2016192542A1 - Method for manufacturing modified graphite negative electrode material

Info

Publication number: WO2016192542A1
Application number: PCT/CN2016/082871
Authority: WO
Inventors: 田东
Original assignee: 田东
Priority date: 2015-06-05
Filing date: 2016-05-20
Publication date: 2016-12-08
Also published as: CN104868159A

Abstract

Disclosed is a method for manufacturing a modified graphite negative electrode material. The method comprises the following steps: (1) precursor slurry manufacturing; (2) precursor drying; and (3) heat treatment. The graphite negative electrode material manufactured in the present invention has a high specific capacity; by modifying the material, the conductivity of the material is effectively improved, and the cycling stability of the material is improved; therefore, when the negative electrode material is used in a lithium ion battery, a high energy density and good cycling stability are achieved.

Description

一种改性石墨负极材料的制备方法Preparation method of modified graphite anode material

技术领域Technical field

本发明涉及一种改性石墨负极材料的制备方法，具体涉及一种掺有金属镍和金属硅，并通过包覆处理的石墨负极材料的制备方法。The invention relates to a preparation method of a modified graphite anode material, in particular to a preparation method of a graphite anode material doped with metal nickel and metal silicon and treated by coating.

背景技术Background technique

锂离子电池具有体积小，及长时间使用下仍维持高储电量与高放电量等优点，因而被广泛地被运用在通讯、电子等设备中。“石墨材”基于其安全性与成本考量，已然成为锂离子电池负极材料的原料主流；而各式以石墨材为原料的锂离子电池负极材料，以及相关的制备方法，也逐渐被开发出来。Lithium-ion batteries are widely used in communication and electronic equipment because of their small size and high storage capacity and high discharge capacity for long-term use. "Graphite" has become the mainstream of lithium ion battery anode materials based on its safety and cost considerations; and various lithium ion battery anode materials using graphite materials as raw materials, and related preparation methods, have also been gradually developed.

目前商业化锂离子电池负极材料采用的是石墨类碳材料，具有较低的锂嵌入/脱嵌电位、合适的可逆容量且资源丰富、价格低廉等优点，是比较理想的锂离子电池负极材料。但其理论比容量只有372mAh/g，因而限制了锂离子电池比能量的进一步提高，不能满足日益发展的高能量便携式移动电源的需求。同时，石墨作为负极材料时，在首次充放电过程中在其表面形成一层固体电解质膜(SEI)。固体电解质膜是电解液、负极材料和锂离子等相互反应形成，不可逆地消耗锂离子，是形成不可逆容量的一个主要的因素；其二是在锂离子嵌入的过程中，电解质容易与其共嵌在迁出的过程中，电解液被还原，生成的气体产物导致石墨片层剥落，尤其在含有PC的电解液中，石墨片层脱落将形成新界面，导致进一步SEI形成，不可逆容量增加，同时循环稳定性下降。而树脂类聚合物热解后形成的无定形碳的有序度低，结构比较松散，锂离子能相对自由地在其中嵌入和脱出而不会对其结构产生大的影响。At present, the commercial lithium ion battery anode material is made of graphite-based carbon material, has low lithium insertion/deintercalation potential, suitable reversible capacity, rich resources, and low price, and is an ideal anode material for lithium ion batteries. However, its theoretical specific capacity is only 372 mAh/g, which limits the further improvement of the specific energy of lithium-ion batteries and cannot meet the needs of the increasingly high-energy portable mobile power sources. At the same time, when graphite is used as a negative electrode material, a solid electrolyte membrane (SEI) is formed on the surface during the first charge and discharge process. The solid electrolyte membrane is formed by reacting an electrolyte, a negative electrode material, and lithium ions, and irreversibly consuming lithium ions, which is a major factor in forming an irreversible capacity. The second is that the electrolyte is easily embedded in the lithium ion intercalation process. During the process of eviction, the electrolyte is reduced, and the resulting gas product causes the graphite sheet to peel off. Especially in the electrolyte containing PC, the graphite sheet peels off and a new interface is formed, resulting in further SEI formation, irreversible capacity increase, and circulation. The stability is degraded. The order of the amorphous carbon formed by pyrolysis of the resin polymer The degree is low and the structure is relatively loose, and lithium ions can be relatively freely embedded and extracted therein without a large influence on the structure thereof.

由于石墨负极材料的局限性，因此对新型负极材料的开发非常必要。新型的负极材料有合金材料、硅基氧化物材料等。合金材料虽然能提供较高的可逆容量，但其循环性能不够理想。硅基氧化物材料虽然具有较高的可逆容量和较好的循环性能，但它的缺点是首次循环不可逆容量损失较大(常大于50％)。研究发现，金属镍及其氧化物作为锂离子电池的负极材料时，具有较高的比容量，此外金属镍具的延展性好，可使电极材料在锂的嵌脱过程中膨胀率大大降低。但是氧化镍的导电率低，影响了电池的充放电性能。Due to the limitations of graphite anode materials, the development of new anode materials is necessary. The new negative electrode materials are alloy materials, silicon-based oxide materials, and the like. Although the alloy material can provide a high reversible capacity, its cycle performance is not ideal. Although the silicon-based oxide material has a high reversible capacity and good cycle performance, it has the disadvantage that the irreversible capacity loss of the first cycle is large (usually greater than 50%). It has been found that metallic nickel and its oxides have higher specific capacity when used as a negative electrode material for lithium ion batteries. In addition, the ductility of metallic nickel is good, which can greatly reduce the expansion rate of electrode materials during lithium insertion and removal. However, the conductivity of nickel oxide is low, which affects the charge and discharge performance of the battery.

硅是一种最有希望取代碳材料的负极材料，这是因为硅具有高达4200mAh/g的最高容量；并且具有类似于石墨的平稳的放电平台。但与其它高容量金属相似，硅的循环性能非常差，不能进行正常的充放电循环。硅作为负极材料使用时，在充放电循环过程中，Li2Si合金的可逆生成与分解伴随着巨大的体积变化，会引起合金的机械***(产生裂缝与粉化)，导致材料结构的崩塌和电极材料的剥落而使电极材料失去电接触，从而造成电极的循环性能急剧下降，最后导致电极失效，因此在锂离子蓄电池中很难实际应用。研究表明，小粒径的硅或其合金无论在容量上还是在循环性能上都有很大的提高，当合金材料的颗粒达到纳米级时，充放电过程中的体积膨胀会大大减轻，性能也会有所提高，但是纳米材料具有较大的表面能，容易发生团聚，反而会使充放电效率降低并加快容量的衰减，从而抵消了纳米颗粒的优点；采用各种沉积方法制备的硅膜能够在一定程度上延长材料的循环寿命，却不能消除其较高的首次不可逆容量，从而制约了这种材料的实用化。另外一种改善硅负极性能的研究趋势就是制备硅与其它材料的复合材料或合金，其中，结合碳材料的稳定性和硅的高比容量特性而制备的硅/碳复合材料显示了巨大的应用前景。Silicon is one of the most promising anode materials for carbon materials because silicon has the highest capacity of up to 4200 mAh/g and has a smooth discharge platform similar to graphite. However, similar to other high-capacity metals, silicon has very poor cycle performance and cannot perform normal charge and discharge cycles. When silicon is used as a negative electrode material, the reversible formation and decomposition of Li2Si alloy is accompanied by a large volume change during the charge-discharge cycle, which causes mechanical splitting (cracking and chalking) of the alloy, resulting in collapse of the material structure and electrode material. The peeling off causes the electrode material to lose electrical contact, thereby causing a sharp drop in the cycle performance of the electrode, and finally causing electrode failure, so that it is difficult to practically apply in a lithium ion battery. Studies have shown that small-diameter silicon or its alloys have a great improvement in both capacity and cycle performance. When the particles of the alloy material reach the nano-scale, the volume expansion during charging and discharging will be greatly reduced, and the performance will be greatly reduced. It will improve, but nanomaterials have a large surface energy and are prone to agglomeration, which in turn will reduce the charge and discharge efficiency and accelerate the attenuation of the capacity, thus offsetting the superiority of the nanoparticles. The silicon film prepared by various deposition methods can prolong the cycle life of the material to a certain extent, but can not eliminate its high first irreversible capacity, thus restricting the practical use of the material. Another research trend to improve the performance of silicon anodes is to prepare composites or alloys of silicon and other materials. Among them, silicon/carbon composites prepared by combining the stability of carbon materials and the high specific capacity of silicon have shown great application. prospect.

发明内容Summary of the invention

为了克服现有技术的不足，本发明提供一种改性石墨负极材料的制备方法，使用该方法制备的负极材料，在拥有高容量的情况下，还具有良好的电化学循环稳定性。In order to overcome the deficiencies of the prior art, the present invention provides a method for preparing a modified graphite anode material, and the anode material prepared by the method has good electrochemical cycle stability even in the case of having a high capacity.

为了实现上述目的，本发明提供一种改性石墨负极材料的制备方法，包括如下步骤：In order to achieve the above object, the present invention provides a method for preparing a modified graphite anode material, comprising the following steps:

1)前驱体浆料制备：按照石墨∶树脂∶镍粉∶硅粉＝100∶3～10∶3～5∶1～5的重量比例，称取各组分分散于有机溶剂乙醇中，调节固含量至20％～40％，加入研磨球，进行球磨混合；1) Precursor slurry preparation: According to the weight ratio of graphite:resin:nickel powder:silica powder=100:3～10:3～5:1～5, the components are weighed and dispersed in the organic solvent ethanol to adjust the solid. The content is up to 20% to 40%, and the grinding ball is added for ball milling and mixing;

2)前驱体干燥：将球磨完毕后的浆料在30～40℃温度下进行干燥，得到粉体；2) drying of the precursor: the slurry after the ball milling is completed is dried at a temperature of 30 to 40 ° C to obtain a powder;

3)热处理：将步骤2)中所得到的粉体在惰性气体的保护下，以5～20℃/min的速度升温至800～1000℃，再保温3～10h，自然降温，冷却后经过粉碎、筛分即得到本发明所述的石墨负极材料。3) Heat treatment: the powder obtained in the step 2) is heated to a temperature of 5 to 20 ° C / min to 800 to 1000 ° C under the protection of an inert gas, and then kept for 3 to 10 hours, naturally cooled, and pulverized after cooling. The graphite negative electrode material of the present invention is obtained by sieving.

进一步，步骤1)中所述的石墨为人造石墨或者天然石墨中的一种或两者的混合。 Further, the graphite described in the step 1) is a mixture of one or both of artificial graphite or natural graphite.

进一步，步骤1)中所述树脂为酚醛树脂、环氧树脂、醇酸树脂、水溶性聚酯树脂、丙烯酸树脂、聚丁二烯树脂中的一种或两种以上的混合物。Further, the resin in the step 1) is one or a mixture of two or more of a phenol resin, an epoxy resin, an alkyd resin, a water-soluble polyester resin, an acrylic resin, and a polybutadiene resin.

进一步，步骤1)中所述的硅粉和镍粉的粒径≤100nm。Further, the particle diameter of the silicon powder and the nickel powder described in the step 1) is ≤100 nm.

进一步，步骤1)中研磨球采用的是非金属材质的氧化锆求、陶瓷球、聚氨酯球中的一种。Further, in the step 1), the grinding ball is one of a non-metallic zirconia, a ceramic ball, and a polyurethane ball.

进一步，步骤1)中球磨混合的时间为8～24h。Further, the time of ball milling mixing in step 1) is 8 to 24 hours.

进一步，步骤2)中浆料干燥是在真空负压状态下进行的，其压力≤-0.1Mpa。Further, the slurry drying in the step 2) is carried out under a vacuum negative pressure, and the pressure is ≤ -0.1 MPa.

进一步，步骤3)中惰性气体为氮气、氩气、氦气中的一种。Further, the inert gas in the step 3) is one of nitrogen gas, argon gas and helium gas.

本发明的有益效果如下：The beneficial effects of the present invention are as follows:

1、本发明通过选用纳米粉体，避免了金属硅粉因粒径较大而在充放电时产生的体积效应，保证了材料的在充放电过程中的稳定性，同时和石墨进行复合处理，解决了单一石墨负极材料容量偏低等缺点；1. The invention adopts the nano powder, thereby avoiding the volume effect of the metal silicon powder due to the large particle size during charging and discharging, ensuring the stability of the material during charging and discharging, and simultaneously compounding with graphite. Solved the shortcomings such as low capacity of single graphite anode material;

2、本发明采用真空低温负压进行浆料干燥，不仅可避免粉体在高温状态下干燥产生团聚，同时可对有机溶剂进行回收利用，起到节能环保的作用；2. The invention adopts vacuum low-temperature negative pressure to carry out slurry drying, which can not only avoid the agglomeration of the powder in the high temperature state, but also can recycle the organic solvent, thereby playing the role of energy saving and environmental protection;

3、通过在石墨表面包覆一层无定形碳，能有效提高石墨抗电解液的共嵌性能，同时树脂在热处理过程中，树脂内的小分子过多，在溢出过程中会造成包覆后材料的表面产生过多的空隙，这些空隙可以起到缓冲硅粉的体积效应，保证材料体系的稳定。 3. By coating a layer of amorphous carbon on the surface of the graphite, the co-intercalation performance of the graphite anti-electrolyte can be effectively improved, and at the same time, the resin has too many small molecules in the resin during the heat treatment, which will cause coating after the overflow process. Excessive voids are created on the surface of the material, which serve to cushion the volume of the silicon powder and ensure the stability of the material system.

本发明制备的石墨负极材料具备较高的比容量，通过对材料进行改性，有效提高了材料的导电性，改善了材料的循环稳定性。因此使得该负极材料在用于锂离子电池时，具有较高的能量密度和良好的循环稳定性。The graphite anode material prepared by the invention has high specific capacity, and the material is modified to effectively improve the conductivity of the material and improve the cycle stability of the material. Therefore, the anode material has high energy density and good cycle stability when used for a lithium ion battery.

具体实施方式detailed description

实施例1Example 1

按照石墨∶树脂∶镍粉∶硅粉＝100∶10∶3∶3的比例，称取1000g人造石墨、100g酚醛树脂、30g镍粉、30g硅粉，按照固含量为30％的比例，称取2706g的乙醇溶剂中，采用氧化锆研磨球，球磨12h，得到均匀浆料；再将浆料在-0.1Mpa、30℃的条件下，干燥10h，得到粉体；再将粉体在惰性气体的保护下，以10℃/min的速度升温至1000℃，再保温3h，自然降温，冷却后过筛即得到本发明石墨负极材料。According to the ratio of graphite:resin:nickel powder:silica powder=100:10:3:3, 1000 g of artificial graphite, 100 g of phenolic resin, 30 g of nickel powder, and 30 g of silicon powder were weighed and weighed according to a solid content of 30%. 2706g of ethanol solvent, using zirconia grinding ball, ball milling for 12h, to obtain a uniform slurry; then drying the slurry at -0.1Mpa, 30 ° C conditions, drying for 10h, to obtain powder; then the powder in an inert gas Under the protection, the temperature is raised to 1000 ° C at a rate of 10 ° C / min, and then kept for 3 h, and the temperature is naturally lowered. After cooling, the graphite anode material of the present invention is obtained by sieving.

实施例2Example 2

按照石墨∶树脂∶镍粉∶硅粉＝100∶5∶5∶1的比例，称取1000g天然石墨、50g环氧树脂、50g镍粉、10g硅粉，按照固含量为40％的比例，称取1665g的乙醇溶剂中，采用氧化锆研磨球，球磨12h，得到均匀浆料；再将浆料在-0.1Mpa、40℃的条件下，干燥80h，得到粉体；再将粉体在惰性气体的保护下，以20℃/min的速度升温至800℃，再保温10h，自然降温，冷却后过筛即得到本发明石墨负极材料。According to the ratio of graphite:resin:nickel powder:silica powder=100:5:5:1, weigh 1000g of natural graphite, 50g of epoxy resin, 50g of nickel powder, 10g of silicon powder, according to the ratio of solid content of 40%, weigh Taking 1665 g of ethanol solvent, using zirconia grinding balls, ball milling for 12 h, to obtain a uniform slurry; then drying the slurry at -0.1 MPa, 40 ° C for 80 h to obtain a powder; then the powder in an inert gas Under the protection, the temperature is raised to 800 ° C at a rate of 20 ° C / min, and then kept for 10 h, and the temperature is naturally lowered. After cooling, the graphite anode material of the present invention is obtained by sieving.

实施例3 Example 3

按照石墨∶树脂∶镍粉∶硅粉＝100∶8∶4∶3的比例，称取1000g人造石墨、80g酚醛树脂、40g镍粉、30g硅粉，按照固含量为30％的比例，称取2683g的乙醇溶剂中，采用陶瓷研磨球，球磨12h，得到均匀浆料；再将浆料在-0.1Mpa、35℃的条件下，干燥9h，得到粉体；再将粉体在惰性气体的保护下，以10℃/min的速度升温至850℃，再保温14h，自然降温，冷却后过筛即得到本发明石墨负极材料。According to the ratio of graphite:resin:nickel powder:silica powder=100:8:4:3, 1000 g of artificial graphite, 80 g of phenolic resin, 40 g of nickel powder, and 30 g of silicon powder were weighed and weighed according to a solid content of 30%. 2683g of ethanol solvent, using ceramic grinding balls, ball milling for 12h, to obtain a uniform slurry; then drying the slurry at -0.1Mpa, 35 ° C, drying for 9h, to obtain powder; then the powder in the protection of inert gas Next, the temperature was raised to 850 ° C at a rate of 10 ° C / min, and then kept for 14 h, and the temperature was naturally lowered. After cooling, the graphite anode material of the present invention was obtained by sieving.

对比例1Comparative example 1

实施例1中的人造石墨。Artificial graphite in Example 1.

对比例2Comparative example 2

实施例2中的天然石墨。Natural graphite in Example 2.

电化学性能测试Electrochemical performance test

为检验本发明方法制备的改性锂离子电池石墨负极材料的性能，用半电池测试方法进行测试，用以上实施例和比较例的负极材料∶乙炔黑∶PVDF(聚偏氟乙烯)＝93∶3∶4(重量比)，加适量NMP(N-甲基吡咯烷酮)调成浆状，涂布于铜箔上，经真空110℃干燥8小时制成负极片；以金属锂片为对电极，电解液为1mol/L LiPF6/EC+DEC+DMC＝1∶1∶1，聚丙烯微孔膜为隔膜，组装成电池。充放电电压为1.0～2.5V，充放电速率为0.5C，对电池性能进行能测试，测试结果见表1。In order to test the properties of the modified lithium ion battery graphite anode material prepared by the method of the present invention, the half cell test method was used to test, and the anode materials of the above examples and comparative examples were used: acetylene black: PVDF (polyvinylidene fluoride) = 93: 3:4 (weight ratio), add appropriate amount of NMP (N-methylpyrrolidone) to make a slurry, apply on copper foil, dry at 110 ° C for 8 hours to make a negative electrode sheet; use lithium metal sheet as the counter electrode, The electrolyte was 1 mol/L LiPF6/EC+DEC+DMC=1:1:1, and the polypropylene microporous membrane was a separator, which was assembled into a battery. The charge-discharge voltage is 1.0-2.5V, and the charge-discharge rate is 0.5C. The battery performance can be tested. The test results are shown in Table 1.

表1为不同实施例和比较例中负极材料的性能比较 Table 1 compares the performance of negative electrode materials in different examples and comparative examples.

[根据细则26改正28.07.2016]　

[Correct according to Rule 26 28.07.2016]

以上显示和描述了本发明的基本原理、主要特征及本发明的优点。本行业的技术人员应该了解，本发明不受上述实施例的限制，上述实施例和说明书中描述的只是说明本发明的原理，在不脱离本发明精神和范围的前提下，本发明还会有各种变化和改进，这些变化和改进都落入要求保护的本发明范围内。本发明的要求保护范围由所附的权利要求书及其等效物界定。 The basic principles, main features, and advantages of the present invention are shown and described above. It should be understood by those skilled in the art that the present invention is not limited by the foregoing embodiments, and that the present invention is only described in the foregoing description and the description of the present invention, without departing from the spirit and scope of the invention. Various changes and modifications are intended to be included within the scope of the invention as claimed. The scope of the invention is defined by the appended claims and their equivalents.

Claims

一种改性石墨负极材料的制备方法，包括如下步骤：A preparation method of a modified graphite anode material comprises the following steps:

1)前驱体浆料制备：按照石墨∶树脂∶镍粉∶硅粉＝100∶3～10∶3～5∶1～5的重量比例，称取各组分分散于有机溶剂乙醇中，调节固含量至20％～40％，加入研磨球，进行球磨混合；1) Precursor slurry preparation: According to the weight ratio of graphite:resin:nickel powder:silica powder=100:3～10:3～5:1～5, the components are weighed and dispersed in the organic solvent ethanol to adjust the solid. The content is up to 20% to 40%, and the grinding ball is added for ball milling and mixing;

2)前驱体干燥：将球磨完毕后的浆料在30～40℃温度下进行干燥，得到粉体；2) drying of the precursor: the slurry after the ball milling is completed is dried at a temperature of 30 to 40 ° C to obtain a powder;

3)热处理：将步骤2)中所得到的粉体在惰性气体的保护下，以5～20℃/min的速度升温至800～1000℃，再保温3～10h，自然降温，冷却后经过粉碎、筛分即得到本发明所述的石墨负极材料。3) Heat treatment: the powder obtained in the step 2) is heated to a temperature of 5 to 20 ° C / min to 800 to 1000 ° C under the protection of an inert gas, and then kept for 3 to 10 hours, naturally cooled, and pulverized after cooling. The graphite negative electrode material of the present invention is obtained by sieving.
根据权利要求1所述的一种改性石墨负极材料的制备方法，其特征在于，步骤1)中所述的石墨为人造石墨或者天然石墨中的一种或两者的混合。The method for preparing a modified graphite anode material according to claim 1, wherein the graphite in the step 1) is a mixture of one or both of artificial graphite or natural graphite.
根据权利要求1所述的一种改性石墨负极材料的制备方法，其特征在于，步骤1)中所述树脂为酚醛树脂、环氧树脂、醇酸树脂、水溶性聚酯树脂、丙烯酸树脂、聚丁二烯树脂中的一种或两种以上的混合物。The method for preparing a modified graphite anode material according to claim 1, wherein the resin in the step 1) is a phenol resin, an epoxy resin, an alkyd resin, a water-soluble polyester resin, an acrylic resin, One or a mixture of two or more of polybutadiene resins.
根据权利要求1所述的一种改性石墨负极材料的制备方法，其特征在于，步骤1)中所述的硅粉和镍粉的粒径≤100nm。The method for preparing a modified graphite anode material according to claim 1, wherein the silicon powder and the nickel powder in the step 1) have a particle diameter of ≤ 100 nm.
根据权利要求1所述的一种改性石墨负极材料的制备方法，其特征在于，步骤1)中研磨球采用的是非金属材质的氧化锆求、陶瓷球、聚氨酯球中的一种。 The method for preparing a modified graphite anode material according to claim 1, wherein in the step 1), the grinding ball is made of a non-metallic zirconia, a ceramic ball or a polyurethane ball.
根据权利要求1所述的一种改性石墨负极材料的制备方法，其特征在于，步骤1)中球磨混合的时间为8～24h。The method for preparing a modified graphite anode material according to claim 1, wherein the ball milling mixing time in the step 1) is 8 to 24 hours.
根据权利要求1所述的一种改性石墨负极材料的制备方法，其特征在于，步骤2)中浆料干燥是在真空负压状态下进行的，其压力≤-0.1Mpa。The method for preparing a modified graphite anode material according to claim 1, wherein the slurry drying in the step 2) is carried out under a vacuum negative pressure, and the pressure is ≤ -0.1 MPa.
根据权利要求1所述的一种改性石墨负极材料的制备方法，其特征在于，步骤3)中惰性气体为氮气、氩气、氦气中的一种。 The method for preparing a modified graphite anode material according to claim 1, wherein the inert gas in the step 3) is one of nitrogen gas, argon gas and helium gas.