JP3978801B2 - Graphite powder for lithium secondary battery and production method thereof - Google Patents

Description

【００６５】
表１からわかるように、閉塞構造の間隙面密度が同じグラファイト粉末を比較すると、黒鉛化温度が高いほどｄ002 が小さく、従って結晶性が向上することがわかる。また、黒鉛化温度が同じ場合には、間隙面密度が大きいほどｄ002 が小さくなる傾向があった。即ち、結晶性(d002)は、黒鉛化温度と間隙面密度の両方に依存する。そして、本発明の条件、即ち、間隙面の密度が 100〜1500個／μｍで、ｄ002 が0.33700 nm以下である条件を満たすグラファイト粉末は、放電容量が310 mAh/g 以上で、多くは330 mAh/g 以上になり、最高で364 mAh/g という理論容量にかなり近づいた放電容量を得ることができた。
【００６６】
(実施例２)
本実施例は、粉砕を炭素化前に行った、上記第２の方法を例示する。
石油ピッチから得られたバルクメソフェーズピッチを、実施例１と同じハンマーミルを使用いて、4500 rpmで５分間粉砕した。粉砕したバルクメソフェーズピッチを、次いでアルゴン雰囲気下1000℃に１時間加熱して炭素化し、そのままアルゴン雰囲気下、2800℃で30分間熱処理して黒鉛化することにより、グラファイト粉末を得た。得られたグラファイト粉末の断面を実施例１と同様に電子顕微鏡で観察した結果、ｃ面層の末端に閉塞構造を有していたが、間隙面密度は80個／μｍであった。炭素化および黒鉛化熱処理の条件は実施例１と同じであったので、粉砕を炭素化の前と後のいずれに実施しても、黒鉛化後に得られるグラファイト粉末の間隙面密度はほとんど同じであることがわかる。
【００６７】
このグラファイト粉末に対して、酸素雰囲気中、700 ℃で、30分間隔で最長３時間までの酸化熱処理を行い、次いでアルゴン雰囲気中1000℃で５時間の熱処理を行った。この場合にも、酸化熱処理により閉塞構造が一旦開放され、さらに不活性ガス中ので熱処理でｃ面層末端に短ピッチの閉塞構造が形成されたことが電子顕微鏡観察でわかった。
【００６８】
上記の熱処理後のグラファイト粉末のｄ002 と放電容量を実施例１と同様に調べた結果を、表２に、酸化熱処理時間と一緒に示す。
【００６９】
【表２】

【００７０】
粉砕が4500 rpmと比較的低速の場合でも、本発明の第２の方法に従って、黒鉛化熱処理後に酸化熱処理と不活性ガス中での熱処理を行うと、間隙面密度が大きく増大し、それに伴っていくらかｄ002 も低下 (結晶性が増大) することがわかる。その結果、粉砕が4500 rpmでも、例えば350 mAh/g といった高い放電容量を示すグラファイト粉末を得ることができた。
【００７１】
【発明の効果】
本発明によれば、グラファイト粉末の表面に現れるｃ面層末端の閉塞構造の間隙面密度を100 個／μｍ以上とし、ｄ002 が0.33700 nm以下と結晶性を高めることによって、非常に高い放電容量を示すリチウム二次電池の負極材料に適したグラファイト粉末が得られる。さらに、実施例に示したように、本発明の第１および第２の方法では、粉砕機の回転数、黒鉛化熱処理条件、およびその後の表面処理 (酸化熱処理＋不活性ガス熱処理) の条件によって、間隙面密度とｄ002 の値を制御することができるので、要求される放電容量の水準に応じたグラファイト粉末を製造することができ、製造されたグラファイト粉末の性能もこれらの条件からある程度予測が可能となる。
【図面の簡単な説明】
【図１】本発明にかかるグラファイト粉末表面に現れるｃ面層末端の閉塞構造を示す説明図である。
【図２】グラファイト粉末の閉塞構造を示す電子顕微鏡写真である。
【図３】図３(a) は、本発明にかかるグラファイト粉末のＸ線回折図の１例を示し、図３(b) はその一部の拡大図である。[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a graphite powder having a novel structure that can form a lithium secondary battery having a high discharge capacity and is suitable as a negative electrode material for a lithium secondary battery. The present invention also relates to a negative electrode material for a lithium secondary battery comprising the graphite powder.
[0002]
[Prior art]
Lithium secondary batteries use lithium as the negative electrode active material, transition metal oxides or chalcogenides (eg, sulfides, selenides) as the positive electrode active material, and an aprotic organic solvent (eg, alkylene or Dialkyl carbonates, ether solvents, sulfolanes, nitrile solvents, nitromethane, amide solvents, ester solvents, glycols, etc.) and inorganic or organic lithium salts (eg, LiClO _Four , LiBF _Four , LiCl, LiCF _Three SO _Three Is a type of non-aqueous secondary battery using a solution in which is dissolved.
[0003]
Since lithium is a very basic metal, a lithium secondary battery can easily extract a large voltage. For this reason, lithium secondary batteries have recently attracted attention as secondary batteries with high electromotive force and energy density, and can be used in a wide range of fields such as electronic devices, electric devices, electric vehicles, and power storage as distributed or portable batteries. Has been expected, and some have already been put into practical use.
[0004]
Early lithium secondary batteries used foil-like metallic lithium alone as a negative electrode active material. In this case, the charge / discharge reaction proceeds by dissolution (ionization) and precipitation of Li. However, in the Li + → Li reaction at the time of charging, metal Li tends to be deposited in a needle shape. Therefore, when charging and discharging are repeated, dendritic Li dendrites are deposited on the electrode surface. When this dendritic Li dendrite grows, it may penetrate the separator (partition), which causes a short circuit with the positive electrode, which shortens the life of the charge / discharge cycle. was there.
[0005]
In order to solve this problem, measures such as alloying Li (eg, Li / Al alloy) have been studied, but the most promising solution at present is to store lithium in carbon materials such as graphite. In this method, the prepared material is used as the negative electrode active material. In this case, the negative electrode material may be substantially only a carbon material, Li ions in the electrolyte solution are taken in between the layers of the carbon material during charging by doping, occlusion, insertion (intercalation), etc., and Li ions are discharged during discharging. Released from the carbon material into the electrolyte. In other words, charging and discharging (electrode reaction) occurs due to the uptake and release of Li ions. Therefore, this type of battery is also called a lithium ion secondary battery.
[0006]
As the carbon material, it is known to use pulverized natural graphite or artificial graphite, or mesophase spheroids having optical anisotropy generated in the heating process of pitch. An electrode produced by mixing such a powdery carbon material with a small amount of a binder (binder) and a solvent and molding is used for a negative electrode of a lithium secondary battery.
[0007]
The theoretical capacity of a lithium secondary battery using a metal Li simple substance as a negative electrode active material is as high as about 3800 mAh / g. On the other hand, the theoretical capacity of a lithium secondary battery composed of a negative electrode active material in which lithium is stored in a carbon material is an intercalation compound in which lithium is regularly and densely stored between graphite layers. ₆ When Li is used as the negative electrode active material, it is about 372 mAh / g.
[0008]
However, in the actual carbon material negative electrode, there are surface active sites that alienate the penetration of Li ions in the carbon material, and a dead region for storing Li ions, etc. ₆ Achieving 372 Ah / kg, which is the theoretical capacity of Li, is extremely difficult, and various proposals have been made for a method for producing a negative electrode carbon material in order to bring this theoretical capacity as close as possible.
[0009]
For example, in Japanese Patent Laid-Open No. 7-282812, the capacity of a lithium secondary battery is increased by increasing the regularity of the laminated arrangement of graphite layers of graphitized carbon fibers. In this publication, when the carbon fiber is pulverized, an undesirable structural defect different from the regularity of the stacking arrangement of the original carbon fiber graphite layer is introduced, and in order to increase the capacity of the lithium secondary battery, the stacking arrangement of the graphite layer It is described that it is advantageous to increase the regularity of However, even if the regularity of the graphite layer stacking arrangement is increased in this way, the discharge capacity of the lithium secondary battery is at most 316 mAh / g, and the graphite-based negative electrode carbon has a high capacity exceeding 330 mAh / g. You can't get the material.
[0010]
[Problems to be solved by the invention]
The present invention has no risk of short-circuiting or short-circuiting due to deposition of Li dendrite, and has a large storage capacity of Li ions, so that a lithium secondary battery having a high discharge capacity can be constructed. It is an object to provide a graphite powder suitable as a material and a method for producing the same. As a specific target of the present invention, the theoretical capacity of a lithium secondary battery using a carbon material as a negative electrode material, such as at least 310 mAh / g, preferably 330 mAh / g or more, and in some cases exceeding 360 mAh / g ( To achieve a discharge capacity approaching 372 mAh / g).
[0011]
[Means for Solving the Problems]
The present inventors systematically investigated the relationship between the microscopic structure of the graphite powder used as the negative electrode material of the lithium secondary battery and the charge / discharge characteristics, and as a result of conducting various analyzes by theoretical calculations, It has been found that by appropriate treatment, the graphite powder changes to a “closed structure” in which the end of the c-plane layer is closed in a loop shape. As schematically shown in FIG. 1, this closed structure is formed in units of several c-plane layers (more precisely, even layers), and the c-plane is opened at the interface between two adjacent unit closed structures. In addition, a “gap surface” is generated.
[0012]
This closed structure of the graphite powder can be actually confirmed by observing the vicinity of the surface of the powder cross-section obtained by cutting the graphite powder in a direction parallel to the c-axis with a high-resolution transmission electron microscope. An example of such an electron micrograph is shown in FIG.
[0013]
As a result of further investigations, the inventors of the present invention have found that the density of the gap surface in the graphite powder (that is, the density of the unit closed structure) and the c-axis (002) plane lattice spacing (d002) are charge / discharge of the lithium secondary battery. It has been found that it has a great influence on properties, and that these conditions can be controlled by pulverization before graphitization heat treatment, graphitization heat treatment conditions, and heat treatment under specific conditions thereafter.
[0014]
Here, the present invention is “graphite powder having a closed structure in which the end of the graphite c-plane layer is closed in a loop shape on the powder surface, and the density of the gap surface between the closed structures in the graphite c-axis direction is 200 It is ˜1500 / μm, and the c-axis (002) plane lattice spacing (d002) determined by the lattice constant precision measurement method by X-ray diffraction is 0.33700 nm or less. According to this invention, the negative electrode material for lithium secondary batteries which consists of this graphite powder is also provided.
[0015]
Graphite powder of the present invention Is Carbon material pulverized before and / or after carbonization (Excluding those crushed by disk crusher) Heat treatment at a temperature of 2500 ° C or higher and graphitize, then heat-treat under conditions that allow the surface of the obtained graphite to be scraped, and heat treatment at a temperature of 800 ° C or higher in an inert gas. It can be manufactured by the “characterized method”.
[0016]
DETAILED DESCRIPTION OF THE INVENTION
The graphite powder of the present invention has a closed structure (hereinafter also simply referred to as closed structure) in which the end of the graphite c-plane layer is closed in a loop shape on the surface thereof. In this closed structure, the end of the graphite c-plane layer (carbon network layer), which is ideally composed of a network structure in which carbon 6-membered rings are connected in a plane, is closed by overlapping multiple loops resembling fingerprints. It is a thing. The formation of such a closed structure on the surface of the graphite powder is more energetic when the ends of the two c-plane layers are bonded to each other and closed in a loop than when the ends of the c-plane layer remain cut. This is thought to be because of its stability.
[0017]
As shown in FIGS. 1 and 2, this closed structure is generally not a single layer loop but a laminated loop structure in which several layers of loops overlap. As shown in FIG. 1, each laminated loop structure formed by overlapping a plurality of loops is referred to as a “unit blocking structure” in the present invention. For the sake of simplicity, FIG. 1 shows only a unit block structure in which three loops (six c-plane layers) are stacked. However, the number of loop stacks varies for each unit block structure, for example, 10 or more. The number of stacked layers may be as described above. In FIG. 2, white stripes indicate the graphite c-plane layer, and arrows indicate the gap plane.
[0018]
As a result of investigating through the molecular orbital method, which portion of the occluding structure Li ions may pass through, the gap between two adjacent unit occluding structures shown in FIG. It was found that the gap surface) was the main passage site. At the entrance of the gap surface, the interaction between Li ions and carbon atoms is weak, and the barrier energy for penetration is low.
[0019]
If the end of the c-plane layer is not clogged in a loop and remains broken, not only Li ions but also electrolyte will enter the graphite and lithium will easily grow into dendritic dendrites during charging. The charge / discharge cycle characteristics are degraded. In addition, since the cut end is chemically unstable, it tends to be pulverized from this portion, and the cycle characteristics are also deteriorated. Accordingly, graphite having a loop-like closed structure that is chemically stable and difficult to infiltrate the electrolyte is more advantageous as an electrode material.
[0020]
It is considered that the penetration of Li ions into the negative electrode carbon material becomes easier as the number of Li ion penetration sites increases. Therefore, it is considered that as the density of the gap surface between the unit clogging structures of the graphite c-plane layer described above increases, Li ions easily enter the negative electrode material, and the amount of Li ions stored in the carbon material increases.
[0021]
In consideration of such a viewpoint, in the present invention, the density of the gap surface of the closed structure found on the surface of the graphite powder is defined to be a certain value or more, and the crystallinity of the graphite powder is also defined. This is because the discharge capacity also depends on the crystallinity.
[0022]
That is, the graphite powder of the present invention has a closed structure in which the end of the graphite c-plane layer is closed in a loop shape on the surface, and the density of the gap surface between the closed structures in the graphite c-axis direction is 100-1500. / Μm, and the c-axis (002) plane lattice spacing (d002) obtained by the lattice constant precision measurement method by X-ray diffraction is 0.33700 nm or less.
[0023]
Here, the graphite c-axis direction is a direction perpendicular to the c-plane layer (carbon network layer) as shown in FIG. Further, the c-axis (002) plane lattice spacing (d002) is a distance between adjacent c-plane layers indicated as d002 in FIG.
[0024]
In general, graphite powder is composed of several regions (corresponding to crystal grains of polycrystalline powder) having different c-axis directions, and each region (that is, a group of regions having the same c-axis direction) is called a crystallite. The length of this crystallite in the c-axis direction is called the crystallite diameter.
[0025]
In the graphite powder of the present invention, the end portion of the c-plane layer exposed on the surface of each crystallite has the above-described closed structure, but the entire surface does not need to have the above-described closed structure, and at least one of the surfaces. It suffices if this closed structure is seen in the part. However, it is preferable that this closed structure is formed on substantially the entire surface of the powder.
[0026]
The gap surface between the loop-like closed structure at the end of the c-plane layer of the graphite powder and the unit closed structure in the c-axis direction is a high-resolution transmission electron near the surface of the powder fragment obtained by cutting the graphite powder in a direction parallel to the c-axis. It can be seen by observing with a microscope. By measuring the length L (μm) in the c-axis direction and the total number N of gap surfaces appearing in this length from this electron micrograph, N / L is obtained. The density (pieces / μm) of the gap surface can be calculated (see FIG. 1).
[0027]
In the graphite powder of the present invention, the density of the gap surface of the loop-shaped block structure is set to 100 pieces / μm or more. Below this, the distance between the gap surfaces (that is, the length in the c-axis direction of the unit block structure) This is because the contribution to the increase of the Li ion penetration site is small. In fact, when the gap surface density is so low, it is impossible to achieve a high discharge capacity exceeding 330 mAh / g.
[0028]
The upper limit of the gap surface density of 1500 / μm is a closed structure in which all c-plane layers form a single-layer loop between two adjacent layers (that is, each unit closed structure consists of two c-plane layers) This is the maximum gap surface density theoretically predicted from the graphite crystal structure.
[0029]
The c-axis (002) plane lattice spacing (d002) is an index of crystallinity, and the smaller the spacing, the higher the crystallinity of the graphite powder. The crystallinity of the graphite powder depends on the graphitization heat treatment conditions, and the higher the heat treatment temperature and the longer the time, the higher the crystallinity of the graphite powder tends to be obtained.
[0030]
The lattice spacing of the crystal can generally be determined from the diffraction peak of the X-ray diffraction diagram. The Gakushin method has been most commonly used for determining the lattice spacing of carbon materials by X-ray diffraction. However, in the Gakushin method, only a large diffraction peak is measured and the midpoint of the width of 2/3 of the diffraction peak intensity is set as the peak position, so an accurate value is obtained due to the effect of the asymmetric component and the error of the optical system. I can't. In the present invention, as the value of d002, a more precise value obtained by a lattice constant precision measurement method using a least square method including a diffractometer error is adopted. In the precision measurement method, when all the peaks are used for calculation and the systematic error of the measurement system is small, unlike the Gakushin method, an internal standard sample is not required.
[0031]
If the value of d002 obtained by the lattice constant precision measurement method is larger than 0.33700 nm, the crystallinity of the graphite powder is insufficient and a discharge capacity as high as 330 mAh / g cannot be realized. The value of d002 is preferably 0.33650 nm or less.
[0032]
The graphite powder having the closed structure at the end of the c-plane layer and the d002 value according to the present invention can be produced by graphitizing a carbon material obtained by carbonization and pulverization at an appropriate temperature. Even if graphitization is performed in this way, a graphite powder that satisfies the conditions of the present invention can be produced if the crushing is carried out under high-speed conditions, and the density of the gap surface of the closed structure at the end of the c-plane layer is 100 / μm or more. Hereinafter, this manufacturing method is referred to as a first method. However, in the first method, the gap surface density of the obtained graphite powder is slightly higher than 100 pieces / μm (eg, 100 to 120 pieces / μm), for example, a very high gap of 200 pieces / μm or more. It is difficult to obtain an areal density.
[0033]
According to another production method (second method), the graphite powder obtained by graphitization as described above is heat-treated under conditions that allow the surface to be shaved (eg, oxidation at a temperature of 600 to 800 ° C.). Heat treatment) and further heat treatment in an inert gas at a temperature of 800 ° C. or higher. In this method, a very high gap surface density of 200 or more, for example, 500 to 1500 / μm can be obtained.
[0034]
In addition, the manufacturing method of the graphite powder concerning this invention is not limited to said 1st and 2nd method. The graphite powder according to the present invention may be produced by any method as long as a graphite powder having a clogging structure at the end of the c-plane layer and having a gap surface density of 100 / μm or more can be formed.
[0035]
The carbonaceous raw material used for carbonization is not particularly limited, and may be the same as that conventionally used for producing graphite powder. Specific examples of the carbonaceous raw material include coal tar pitch or petroleum pitch, mesophase spherules generated by heat treatment of these pitches, bulk mesophase that is a matrix of these spheroids, and various organic resins or organic substances (e.g., Polyacrylonitrile, rayon) and the like. Particularly preferred carbonaceous raw materials are mesophase microspheres and bulk mesophase.
[0036]
A carbonaceous material is pulverized and carbonized to obtain a carbon material. The clogging structure is formed during the graphitization heat treatment due to the atomic level irregularities (layer defects) on the powder surface caused by pulverization. Therefore, the pulverization is essential for obtaining a graphite powder having a high density of the clogging structure. In particular, in the first method, this pulverization condition greatly affects the shape and density of the closed structure of the graphite powder generated after the graphitization heat treatment.
[0037]
When pulverizing after graphitization heat treatment, layer defects occur in the c-plane layer of graphite produced by heat treatment, and the introduced blocking structure may be destroyed by pulverization. Is not desirable. Therefore, the pulverization performed before the heat treatment is preferably performed so that the final particle size required for the use of the graphite powder is obtained.
[0038]
For example, when used as a negative electrode material for a lithium secondary battery, it is known that if the average particle size is too large, the packing density decreases, and those having a particle size smaller than 1 μm degrade the initial charge / discharge characteristics. It is preferable that fine particles having a particle diameter in the range of 5 to 50 μm and less than 1 μm do not exist. However, mild pulverization for the purpose of crushing, classification for fine particle removal and adjustment of the average particle diameter may be carried out after the graphitization heat treatment or after the final heat treatment in the second method.
[0039]
Grinding may be performed before or after carbonization, and may be performed both before and after carbonization, but it is better to heat before carbonization than carbonization and graphitization. Can be continued and there is no waste of heat energy.
[0040]
The pulverization may be performed using a conventional pulverizer such as a hammer mill, a fine mill, an attrition mill, or a ball mill. A preferred pulverizer is an impact pulverizer, typically a hammer mill. As described above, particularly in the first method, the influence of the pulverization conditions on the crystal structure of the graphite powder is large, and high-speed pulverization is required to obtain a graphite powder having a closed structure with a gap surface density of 100 / μm or more. It is necessary to adopt. The specific pulverization conditions (eg, rotation speed, pulverization time) vary depending on the type of pulverizer used and the type of carbonaceous raw material, so that graphite powder having a pore surface density of 100 / μm or more after graphitization heat treatment is used. What is necessary is just to determine by experiment so that it may produce | generate and the powder of a desired particle size may be obtained.
[0041]
For example, when the bulk mesophase is pulverized with a hammer mill, if the rotational speed of the pulverizer is 5000 to 8000 rpm, a graphite powder having a closed structure with a gap surface density of 100 / μm or more is obtained after the graphitization heat treatment. be able to. If the rotational speed is lower than 5000 rpm, the density of the gap surface cannot be increased to 100 pieces / μm or more. If the rotational speed is higher than 8000 rpm, the specific surface area of the graphite powder after pulverization and graphitization heat treatment becomes large. As a result, a passive film is likely to be formed at the first charge in the Li ion secondary battery, and a highly efficient negative electrode cannot be obtained. However, this is only an example, and if the pulverizer or the type of raw material changes, the appropriate rotational speed also changes.
[0042]
Also in the case of the second method, such high speed pulverization may be performed, whereby a graphite powder having a very high density closed structure such that the density of the gap surface exceeds 1000 / μm can be obtained. . However, since the gap surface density is greatly increased by two heat treatments after the graphitization heat treatment, the pulverization by the second method does not need to be performed at high speed.
[0043]
Carbonization conditions for the pulverized carbonaceous raw material may be selected so that the raw material is decomposed and elements other than carbon contained in the raw material are almost completely removed. In order to prevent the oxidation (combustion) of carbon, the heat treatment is carried out in an inert atmosphere or vacuum. The heat treatment temperature for carbonization is usually in the range of 800 to 1500 ° C, and particularly preferably around 1000 ° C. The heat treatment time required for carbonization is about 30 minutes to 3 hours when the temperature is 1000 ° C., although it depends on the type of raw material, the amount of treatment, and the temperature.
[0044]
The powdery carbon material obtained by pulverization and carbonization is heat-treated and graphitized. This heat treatment temperature is carried out under conditions that cause graphitization (crystallization) and finally obtain graphite powder having a c-axis (002) plane lattice spacing d002 of 0.33700 nm or less. The graphitization temperature is usually 2500 ° C or higher, and an upper limit of about 3200 ° C is practical for current heating technology. However, since d002 greatly depends on the graphitization conditions, in the first method, the heat treatment conditions are set so that d002 becomes 0.33700 nm or less after graphitization. The heat treatment temperature for this is usually 2500 ° C. or higher, preferably 2800 ° C. or higher, more preferably 2900 ° C. or higher. In the second method, d002 is somewhat reduced by the oxidation heat treatment and inert gas heat treatment after graphitization, and therefore d002 after graphitization may slightly exceed 0.33700 nm. In this case, the graphitization heat treatment temperature is preferably 2700 ° C. or higher. However, the higher the heat treatment temperature is, the smaller d002 becomes and the discharge capacity is improved. Although the heat treatment time depends on the temperature and the treatment amount, it is generally 20 minutes or longer. The heat treatment atmosphere is a non-oxidizing atmosphere, preferably an inert gas atmosphere (eg, nitrogen, helium, argon, neon, carbon dioxide, etc.) or a vacuum.
[0045]
The graphite powder thus produced by the graphitization heat treatment generally has a closed structure in which the end of the c-plane layer is closed in a loop shape on the powder surface. However, if the pulverization before this heat treatment is performed under sufficiently high speed conditions, the gap surface density will be reduced. A graphite powder slightly exceeding 100 pieces / μm is obtained. That is, it is a graphite powder produced by the first method. Thus, even if the gap surface density is slightly higher than 100 / μm, the discharge capacity is remarkably improved as compared with the case where the density is lower than 100 / μm.
[0046]
In the second method, the graphite powder obtained by the graphitization heat treatment is further subjected to two heat treatments, namely an oxidation heat treatment (or heat treatment for scraping off other surfaces) and a heat treatment in an inert gas atmosphere, so Remarkably increase the surface density. Next, the heat treatment after graphitization in the second method will be described.
[0047]
The oxidation heat treatment first applied to the graphite powder is performed to scrape the powder surface by oxidation. As a result, the closed structure of the powder surface (c-plane layer end) generated by the graphitization heat treatment is cut and opened, and the end of the c-plane layer is flattened with almost the same length. A graphite powder with ends is obtained.
[0048]
The conditions for the oxidation heat treatment are not particularly limited as long as the closure structure is substantially opened by oxidation, but the heat treatment temperature is preferably in the range of 600 to 800 ° C. This is because the graphite powder having a closed structure has high oxidation resistance, so that it is difficult to oxidize when the temperature of the oxidation heat treatment is lower than 600 ° C., and the oxidation progresses rapidly at 800 ° C. or higher and the entire graphite powder deteriorates. The oxidation heat treatment time varies depending on the temperature and the amount of treatment, but is generally 1 to 10 hours. The heat treatment atmosphere is an oxygen-containing atmosphere, and may be a pure oxygen atmosphere or a mixed gas atmosphere of oxygen and an inert gas (eg, air).
[0049]
The opening of the closing structure is not limited to the oxidation heat treatment. Other methods can also be adopted as long as the c-plane layer ends can be obtained by opening the blocking structure by scraping the surface structure of the graphite powder. Examples of other methods include fluorination heat treatment and hydrogenation heat treatment. The heat treatment conditions in this case may be appropriately set by experiment so that the closed structure is opened.
[0050]
Thereafter, the graphite powder is further heat-treated in an inert gas atmosphere. By the heat treatment in the inert gas atmosphere, the end of the c-plane layer of the open structure is connected to the end of the other c-plane layer, and a closed loop structure is formed again at the end of the c-plane layer on the surface of the graphite powder. Is done.
[0051]
At the time of this loop connection at the end of the c-plane layer, since the end of the c-plane layer on the surface of the graphite powder is flattened by the oxidation heat treatment, it is extremely rare for two separate layers to be connected, as shown in FIG. Such a large closed structure in which a large number of connecting loops are laminated cannot be formed. The number of laminated loops is at most 5 layers, and most is about 1 to 3 layers. For this reason, the number of closed structures per length in the c-axis direction increases, and the density of the gap surfaces increases. As a result, in the first method, the gap surface density was slightly higher than 100 / μm. In the second method, the gap surface density was increased so as to exceed 500 / μm, for example. The pitch of the surface can be reduced.
[0052]
The inert gas atmosphere may be one or more of Ar, He, Ne, and the like, for example. The heat treatment temperature may be a temperature that causes a relatively large lattice vibration that can connect the ends of the c-plane layer. When the closed structure is connected to form a closed structure, the energy is low and the structure is stabilized. Therefore, when sufficient lattice vibration is generated by heat treatment in an inert gas atmosphere, the open ends of the c-plane layers are connected to each other. It is. For this purpose, a heat treatment temperature of 800 ° C. or higher is generally required. The upper limit is not particularly limited, but as described above, about 3200 ° C. is practical with the current heating technology. The heat treatment time is not limited as long as a closed structure is formed and varies greatly depending on the temperature and the amount of treatment, but is generally 1 to 10 hours. For example, at 1000 ° C., about 5 hours is a standard.
[0053]
The graphite powder having the closed structure of the present invention can be used for the same application as that of the conventional graphite powder. The c-plane layer of graphite powder forms a closed structure, and the closed structure in the c-axis direction, and hence the density of the gap surface is as high as 100-1500 / μm, and at the same time, d002 is 0.33700 nm or less and the crystallinity is Since it is high, the functions of the graphite powder such as doping, occlusion, and insertion, that is, the storage function of the substance between the c-plane layers are remarkably improved.
[0054]
The graphite powder of the present invention is particularly suitable as a negative electrode material for a lithium secondary battery. Because there are many gap surfaces and vacancy-type defects in the closed structure that is the penetration site of Li ions, Li ions can easily penetrate, and more Li ions reach the material storage area of the graphite powder, Li ion storage capacity increases. Therefore, a lithium secondary battery with improved discharge capacity can be created. In addition, since the c-plane layer of graphite powder has a closed structure, the electrolyte does not easily enter the graphite powder, and precipitation of Li dendritic dendrites during charging can be avoided. Long life.
[0055]
When the graphite powder of the present invention is used for this purpose, the production of an electrode of a lithium secondary battery using the graphite powder can be carried out in the same manner as before.
For example, after classification as necessary to adjust the particle size of graphite powder, this powder is mixed with a small amount of a binder and a solvent to form a paste or slurry. Examples of the binder are fluorine resin powders such as polyvinylidene fluoride and polytetrafluoroethylene, and water-soluble binders such as carboxymethyl cellulose. As the solvent, a polar organic solvent, water or the like can be used. The obtained paste or slurry is applied to a suitable metal current collector, dried and molded to obtain an electrode. The positive electrode, electrolyte solution, separator, and other configurations of the lithium secondary battery may be the same as the conventional product.
[0056]
【Example】
This example exemplifies the first and second methods in which pulverization is performed after carbonization.
[0057]
Bulk mesophase pitch obtained from petroleum pitch was coarsely pulverized and carbonized by heating to 1000 ° C. for 1 hour under an argon atmosphere to obtain a carbon material. This carbon material is pulverized at 4500 rpm or 7500 rpm for 5 minutes using a hammer mill (Fuji Paudal u-Mizer), and then the pulverized carbon material is measured in increments of 100 ° C. from 2700 ° C. to 3000 ° C. in an argon atmosphere. The graphite powder was obtained by heat-processing for 30 minutes at the selected predetermined temperature, and graphitizing.
[0058]
As a result of observing fragments of these graphite powders cut in the c-axis direction with a high-resolution transmission electron microscope, all of them had a clogging structure at the end of the surface c-plane layer. The gap surface density of the closed structure was determined from an electron micrograph (average of 10 fields of view). The gap surface density is 80 pieces / μm for all graphite powders with a rotation speed of 4500 rpm when pulverizing the carbon material, and 103 pieces / μm for all graphite powders with 7500 rpm, depending on the graphitization temperature. There was little effect. That is, it was found that the gap surface density is greatly affected by the pulverization conditions, and if the pulverization is performed at a high speed, a closed structure is generated at a high pitch exceeding the gap surface density of 100 / μm during the graphitization heat treatment. High speed grinding is necessary in the first method in which the gap surface density is 100 / μm or more only by grinding.
[0059]
For the graphite powder that was pulverized at 4500 rpm, in accordance with the second method described above, oxidation heat treatment of oxidation in an oxygen atmosphere at 650 ° C. × 2 hours or 700 ° C. × 3 hours, and then in an argon atmosphere, 1000 ° C. × 5 Heat treatment for hours was performed. When the graphite surface powder was subjected to oxidation heat treatment and heat treatment in an inert gas in the same manner as described above, the gap surface density was determined in the same manner as described above. In the case of time, it was 770 / μm, which was significantly increased compared with 103 / μm before the treatment. That is, the gap surface density could be greatly increased by the treatment after graphitization by the second method. In addition, as a result of observing the fragments of the graphite powder after the oxidation heat treatment with an electron microscope in the same manner as described above, the closed structure at the end of the c-plane layer generated by the graphitization heat treatment was cut off and opened after the oxidation heat treatment. It was observed that the ends were relatively uniform.
[0060]
The c-axis (002) plane lattice spacing (d002) of each of these graphite powders and the discharge capacity of the lithium secondary battery were measured as follows.
[0061]
d002 is an X-ray diffraction diagram of a graphite powder sample prepared using an X-ray diffractometer manufactured by Mac Science under the conditions of an acceleration voltage of 40 kV, a current of 150 mA, and a measurement range of 20 to 90 °. From the figure, it was calculated by the lattice constant precision measurement method (without using internal standard) by the least square method including the error of the diffractometer. An example of the produced X-ray diffraction diagram is shown in FIG. FIG. 3 (b) is an enlarged view of a part of FIG. 3 (a). To determine the lattice constant, all peak positions of the plane indices (002), (100), (101), (004), (110), (112), (006) indicated by arrows in Fig. 3 (b) Was used. The X-ray diffraction measurement was performed three times, and the weighted average of the obtained values was taken as the value of d002.
[0062]
In order to measure the discharge capacity, each graphite powder was sieved to 5 μm or more and 45 μm or less, and then used for production of an electrode. The average particle size of the graphite powder was about 15 μm. 90 parts by weight of graphite powder and 10 parts by weight of polyvinylidene fluoride powder were mixed in a solvent N-methylpyrrolidone and dried to form a paste. The obtained paste was applied to a uniform thickness on a 20 μm thick copper foil serving as a current collector using a doctor blade, and then dried at 80 ° C. 1cm area cut out from here ² The test piece was used as a negative electrode.
[0063]
The negative electrode characteristics were evaluated by a three-pole constant current charge / discharge test using metallic lithium as a counter electrode and a reference electrode. The electrolyte was LiClO at a concentration of 1 mol / l in a 1: 1 mixed solvent of ethylene carbonate and dimethyl carbonate. _Four What was dissolved was used. Discharge capacity is 0.3 mA / cm ² This was obtained by charging to 0.0 V at a current density of 1.5 V and then discharging to 1.5 V at the same current density.
The above test results are summarized in Table 1.
[0064]
[Table 1]

[0065]
As can be seen from Table 1, when graphite powders having the same gap surface density of the closed structure are compared, it can be seen that the higher the graphitization temperature, the smaller d002, and thus the higher the crystallinity. When the graphitization temperature is the same, d002 tends to decrease as the gap surface density increases. That is, the crystallinity (d002) depends on both the graphitization temperature and the gap surface density. The graphite powder satisfying the conditions of the present invention, that is, the density of the gap surface of 100-1500 pieces / μm and d002 of 0.33700 nm or less, has a discharge capacity of 310 mAh / g or more, most of which is 330 mAh. The discharge capacity was very close to the theoretical capacity of 364 mAh / g.
[0066]
(Example 2)
The present example illustrates the second method in which the pulverization was performed before carbonization.
Bulk mesophase pitch obtained from petroleum pitch was ground at 4500 rpm for 5 minutes using the same hammer mill as in Example 1. The pulverized bulk mesophase pitch was then carbonized by heating at 1000 ° C. for 1 hour under an argon atmosphere, and then graphitized by heat treatment at 2800 ° C. for 30 minutes under an argon atmosphere to obtain graphite powder. As a result of observing the cross section of the obtained graphite powder with an electron microscope in the same manner as in Example 1, it had a closed structure at the end of the c-plane layer, but the gap surface density was 80 / μm. Since the conditions for carbonization and graphitization heat treatment were the same as in Example 1, the gap surface density of the graphite powder obtained after graphitization was almost the same regardless of whether pulverization was performed before or after carbonization. I know that there is.
[0067]
The graphite powder was subjected to an oxidation heat treatment in an oxygen atmosphere at 700 ° C. at intervals of 30 minutes for a maximum of 3 hours, and then in an argon atmosphere at 1000 ° C. for 5 hours. Also in this case, it was found by observation with an electron microscope that the closed structure was once opened by the oxidation heat treatment, and that a short pitch closed structure was formed at the end of the c-plane layer by the heat treatment in the inert gas.
[0068]
The results of examining the d002 and discharge capacity of the graphite powder after the above heat treatment in the same manner as in Example 1 are shown in Table 2 together with the oxidation heat treatment time.
[0069]
[Table 2]

[0070]
Even when the pulverization is relatively low, such as 4500 rpm, if the oxidation heat treatment and the heat treatment in the inert gas are performed after the graphitization heat treatment according to the second method of the present invention, the gap surface density is greatly increased. It can be seen that d002 also decreases (crystallinity increases). As a result, it was possible to obtain a graphite powder having a high discharge capacity of, for example, 350 mAh / g even when pulverized at 4500 rpm.
[0071]
【The invention's effect】
According to the present invention, the gap surface density of the closed structure at the end of the c-plane layer appearing on the surface of the graphite powder is set to 100 pieces / μm or more, and d002 is 0.33700 nm or less to increase the crystallinity. The graphite powder suitable for the negative electrode material of the lithium secondary battery shown is obtained. Furthermore, as shown in the examples, in the first and second methods of the present invention, depending on the rotational speed of the pulverizer, the graphitization heat treatment conditions, and the subsequent surface treatment (oxidation heat treatment + inert gas heat treatment) conditions. Since the gap surface density and d002 value can be controlled, it is possible to produce graphite powder according to the required level of discharge capacity, and the performance of the produced graphite powder can be predicted to some extent from these conditions. It becomes possible.
[Brief description of the drawings]
BRIEF DESCRIPTION OF DRAWINGS FIG. 1 is an explanatory diagram showing a closed structure of a c-plane layer end appearing on the surface of a graphite powder according to the present invention.
FIG. 2 is an electron micrograph showing the closed structure of graphite powder.
FIG. 3 (a) shows an example of an X-ray diffraction pattern of the graphite powder according to the present invention, and FIG. 3 (b) is a partially enlarged view thereof.

Claims (3)

A graphite powder having a closed structure in which the end of the graphite c-plane layer is closed in a loop shape on the powder surface, and a density of gap surfaces between the closed structures in the graphite c-axis direction is 200 to 1500 / μm; Graphite powder characterized by having a c-axis (002) plane lattice spacing (d002) of 0.33700 nm or less determined by a precise method of measuring lattice constant by X-ray diffraction. After carbonizing the carbon material (excluding those pulverized by a disk crusher) before and / or after carbonization by heat treatment at a temperature of 2500 ° C. or higher, the surface of the resulting graphite is shaved. The method for producing a graphite powder according to claim 1, wherein the heat treatment is performed under a condition that the heat treatment can be performed, and the heat treatment is further performed in an inert gas at a temperature of 800 ° C or higher.   A negative electrode material for a lithium secondary battery comprising the graphite powder according to claim 1.

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