JP2012089531A - Nonaqueous electrolyte secondary battery and carbon material for nonaqueous electrolyte secondary battery - Google Patents

Nonaqueous electrolyte secondary battery and carbon material for nonaqueous electrolyte secondary battery Download PDF

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JP2012089531A
JP2012089531A JP2012016172A JP2012016172A JP2012089531A JP 2012089531 A JP2012089531 A JP 2012089531A JP 2012016172 A JP2012016172 A JP 2012016172A JP 2012016172 A JP2012016172 A JP 2012016172A JP 2012089531 A JP2012089531 A JP 2012089531A
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secondary battery
electrolyte secondary
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JP5445797B2 (en
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Kotaro Satori
浩太郎 佐鳥
Akinori Kita
昭憲 北
Tokuo Komaru
篤雄 小丸
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Sony Corp
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Abstract

PROBLEM TO BE SOLVED: To obtain a lithium ion secondary battery having high capacity and high reliability by suppressing deterioration of the inside of the battery caused by thermal history.SOLUTION: A ratio RG(=Gs/Gb) of a graphitization degree Gs determined from surface-enhanced Raman spectral spectrum to a graphitization degree Gb determined from Raman spectral spectrum using argon laser light, which are structural parameters of a carbon material, is prescribed to 4.5 or higher, and a nonaqueous electrolyte secondary battery is constituted by using the material having the prescribed RG as a negative electrode. In the surface-enhanced Raman spectral spectrum using argon laser light, a nonaqueous electrolyte secondary battery is constituted by using a material having a peak in the range of 1360 cmor more as a negative electrode.

Description

本発明は、非水電解液二次電池と、非水電解液二次電池用炭素材料とに関する。   The present invention relates to a non-aqueous electrolyte secondary battery and a carbon material for a non-aqueous electrolyte secondary battery.

近年、携帯電話やノート型パソコンに代表されるように、電子機器の小型化、ポータブル化が急激に進み、二次電池の高エネルギー化への要求が高まってきている。   In recent years, as represented by mobile phones and notebook personal computers, electronic devices are rapidly becoming smaller and more portable, and demands for higher energy secondary batteries are increasing.

従来の二次電池としては、鉛電池、Ni−Cd電池、Ni−MH電池が挙げられるが、放電電圧が低く、また、エネルギー密度も十分に高くない。一方、金属リチウムやリチウム合金、或いは電気化学的にリチウムイオンを吸蔵し放出できる炭素材料を負極活物質に用い、種々の正極と組み合わせたリチウム二次電池が開発され、実用化されている。この種の電池は電池電圧が高く、上述した従来の電池に比べ重量、或いは体積当たりのエネルギー密度が大きい二次電池として期待されている電池である。   Examples of conventional secondary batteries include lead batteries, Ni-Cd batteries, and Ni-MH batteries, but the discharge voltage is low and the energy density is not sufficiently high. On the other hand, lithium secondary batteries in which metallic lithium, lithium alloy, or a carbon material capable of electrochemically absorbing and releasing lithium ions are used as a negative electrode active material and combined with various positive electrodes have been developed and put into practical use. This type of battery has a high battery voltage and is expected as a secondary battery having a higher energy density per weight or volume than the above-described conventional battery.

この種の二次電池は当初、負極に金属リチウム、或いはリチウム合金を用いた系で検討されていたが、金属リチウム、或いはリチウム合金を用いた負極は、充放電効率、デントライト等に問題があり、一部を除き、実用化に至ってないのが現状である。   This type of secondary battery was originally studied in a system using metallic lithium or a lithium alloy for the negative electrode, but the negative electrode using metallic lithium or a lithium alloy has problems in charge / discharge efficiency, dent light, and the like. Yes, with some exceptions, it has not been put into practical use.

そこで現在、リチウムイオンを電気化学的に吸蔵、放出できる炭素材料を負極に用いることが有力視され、且つ、実現されてきた。この種の材料を用いた負極は金属リチウム、或いはリチウム合金を用いた負極と比較し、充放電時に金属リチウムのデンドライト生成や合金の微紛化が起こらず、クーロン効率が高いため、充放電可逆性に優れたリチウム二次電池が構成できる。   Therefore, it has now been considered promising and realized to use a carbon material capable of electrochemically occluding and releasing lithium ions for the negative electrode. Compared with negative electrodes using metallic lithium or lithium alloys, negative electrodes using this type of material do not generate metal lithium dendrites or alloy fines during charging / discharging, and have high coulomb efficiency. A lithium secondary battery excellent in performance can be configured.

また、この種の材料を負極活物質に用いた電池では、その電池内に金属リチウムが析出することがなく、安全性の高いリチウム二次電池が構成でき、現在、リチウム含有複合酸化物からなる正極と組み合わされ、商品化されるに至っている。この電池は、いわゆるリチウムイオン電池と呼ばれ、負極に炭素材料、正極にLiCoO2 、電解液に非水溶媒からなる非水電解液をそれぞれ用いている。 In addition, in a battery using this type of material as a negative electrode active material, lithium metal is not deposited in the battery, and a highly safe lithium secondary battery can be configured, and is currently made of a lithium-containing composite oxide. Combined with the positive electrode, it has been commercialized. This battery is referred to as a so-called lithium ion battery, and uses a carbon material for the negative electrode, LiCoO 2 for the positive electrode, and a non-aqueous electrolyte composed of a non-aqueous solvent for the electrolyte.

負極となる炭素材料は、次のように大別される。すなわち、鉱石などでも産出され、今日では人工的に作ることが可能になった黒鉛材料、人工的な黒鉛材料の前駆体となる易黒鉛化性炭素材料、黒鉛が人工的に生成するような高温にさらしても黒鉛にならない難黒鉛化性炭素材料である。現在では、負極容量の点から、黒鉛材料と難黒鉛化性炭素材料が用いられている。   The carbon material used as a negative electrode is roughly classified as follows. In other words, graphite materials that have been produced in ores and are now able to be artificially produced, graphitizable carbon materials that are precursors of artificial graphite materials, and high temperatures at which graphite is artificially produced It is a non-graphitizable carbon material that does not become graphite when exposed to. At present, graphite materials and non-graphitizable carbon materials are used from the viewpoint of negative electrode capacity.

電子機器の発達により、前記リチウムイオン電池はその電源として注目され、特に小型軽量、且つ、高容量という特徴を生かしてノート型パソコンへの搭載が急速に進んだ。ノート型パソコンはその携帯性に特徴があり、そのため小型化、高性能化が必要である。ところで高性能化には内蔵するCPUの動作周波数を上げる必要がある。しかしながら、これに伴って消費電力が増大し、動作中に発生する発熱量も増加するものである。また、小型になるほど、パソコン本体内の空間は減少する。これにより、使用中に発生する熱が逃げにくくなり、パソコン本体内の温度が上昇することになる。   Due to the development of electronic devices, the lithium ion battery has been attracting attention as a power source thereof, and has been rapidly installed in notebook personal computers by taking advantage of its small size, light weight and high capacity. Notebook PCs are characterized by their portability, so they must be smaller and have higher performance. By the way, for higher performance, it is necessary to increase the operating frequency of the built-in CPU. However, this increases power consumption and increases the amount of heat generated during operation. Also, the smaller the size, the smaller the space inside the PC body. This makes it difficult for heat generated during use to escape and the temperature inside the PC body to rise.

上述したように電子機器内部の温度が上昇すると、電池への影響も大きくなる。即ち、電池が充電された状態でこの熱履歴を受けると、電池内で劣化反応が起こり、これによる電池容量の低下は回復できないものである。従って本発明の課題は熱履歴にさらされることによって生じる電池内部の劣化を抑制し、高容量で高信頼性の非水電解液二次電池を得ることを目的とし、さらにこのために、非水電解液二次電池用炭素材料を提供することにある。   As described above, when the temperature inside the electronic device rises, the influence on the battery also increases. That is, when this thermal history is received while the battery is charged, a deterioration reaction occurs in the battery, and the decrease in battery capacity due to this reaction cannot be recovered. Accordingly, an object of the present invention is to suppress deterioration inside the battery caused by exposure to a thermal history, and to obtain a high capacity and high reliability non-aqueous electrolyte secondary battery. The object is to provide a carbon material for an electrolyte secondary battery.

上述の課題を達成するために、発明者らが鋭意検討したところ、負極用炭素材料において、その構造パラメータを規定することにより、この材料を負極に用いた電池を高温中で保存された場合でも、容量劣化が小さく、高容量で高信頼性の非水電解液二次電池が得られることを見出すに至った。   In order to achieve the above-mentioned problems, the inventors have intensively studied, and in the carbon material for a negative electrode, by defining its structural parameters, even when a battery using this material as a negative electrode is stored at a high temperature. Thus, it has been found that a non-aqueous electrolyte secondary battery having a small capacity deterioration, a high capacity and a high reliability can be obtained.

まず、請求項1に記載の発明は、波長514.5nmのアルゴンレーザ光と波数分解能4cm-1の分光器を用い、炭素材料に厚さ10nmの銀を蒸着した場合の表面増大ラマン分光スペクトルにおいて、非結晶質の乱層構造に由来する振動モードとして1350cm-1〜1400cm-1の範囲に1365以上の強度のピークを有する炭素材料を負極に用いて非水電解液二次電池を構成するものである。 First, the invention according to claim 1 is a surface-enhanced Raman spectroscopic spectrum in the case where silver having a thickness of 10 nm is deposited on a carbon material using an argon laser beam having a wavelength of 514.5 nm and a spectroscope having a wave number resolution of 4 cm −1 . , constitutes a non-aqueous electrolyte secondary battery using a carbon material for the negative electrode having a peak of 1365 or more intensity in the range of 1350cm -1 ~1400cm -1 as a vibration mode derived from the turbostratic structure of amorphous It is.

また、請求項2に記載の発明は、請求項1に記載の発明の炭素材料を黒鉛とするものである。   In the invention according to claim 2, the carbon material of the invention according to claim 1 is graphite.

また、請求項3に記載の発明は、波長514.5nmのアルゴンレーザ光と波数分解能4cm-1の分光器を用い、銀を10nmの厚さで蒸着した場合の表面増大ラマン分光スペクトルにおいて、非結晶質の乱層構造に由来する振動モードとして1350cm-1〜1400cm-1の範囲に1365以上の強度のピークを有する非水電解液二次電池用炭素材料である。 The invention according to claim 3 is a surface-enhanced Raman spectroscopic spectrum obtained by depositing silver at a thickness of 10 nm using an argon laser beam having a wavelength of 514.5 nm and a spectroscope having a wave number resolution of 4 cm −1. a carbon material for a nonaqueous electrolyte secondary battery having a peak of 1365 or more intensity in the range of 1350cm -1 ~1400cm -1 as a vibration mode derived from the turbostratic crystalline.

また、請求項4に記載の発明は、請求項3に記載の発明の炭素材料を黒鉛とするものである。   In the invention according to claim 4, the carbon material of the invention according to claim 3 is graphite.

つぎに、本発明で用いる構造パラメータの測定する方法を説明する。
本発明で用いる構造パラメータはラマン分光法を応用して測定される。従来、炭素材料のラマンスペクトルは、黒鉛結晶質構造に由来する振動モードとして1580cm-1〜1620cm-1付近(Pba)と、非結晶質の乱層構造に由来する振動モードとして1350cm-1〜1400cm-1付近(Pbb)にピークを有する。黒鉛材料の構造の乱れが進行すると、ラマンスペクトル上では、Pba強度(高さHba)が低下し、Pbb強度(高さHbb)が増加する。Pba, Pbbの2つのピーク高さ比は、黒鉛化度を表わす。
Next, a method for measuring the structural parameters used in the present invention will be described.
The structural parameters used in the present invention are measured by applying Raman spectroscopy. Conventionally, Raman spectra of carbon materials have a vibration mode derived from a graphite crystalline structure in the vicinity of 1580 cm −1 to 1620 cm −1 (Pba) and a vibration mode derived from an amorphous turbulent structure from 1350 cm −1 to 1400 cm. It has a peak near -1 (Pbb). When the disorder of the structure of the graphite material proceeds, on the Raman spectrum, the Pba intensity (height Hba) decreases and the Pbb intensity (height Hbb) increases. The ratio of the two peak heights of Pba and Pbb represents the degree of graphitization.

表面増大ラマン分光法(SERS)は、試料表面に銀、金などの金属薄膜を成膜して測定する方法で、1974年、Fleischmann らにより発明され、数nmオーダーの最表面分析とラマン感度の増大を得ることができることを特徴としている。この方法で得られる黒鉛材料のラマンスペクトルは、分析深さは異なるが、通常のラマン分光と同様の振動モードが得られる。黒鉛結晶質構造に由来する振動モードとして1580cm-1〜1620cm-1(Psa)付近と、非結晶質の乱層構造に由来する振動モードとして1350cm-1〜1400cm-1(Psb)付近にピークが得られ、Psa強度(高さHsa)とPsb強度(高さHsb)との比は粒子最表面層部分の黒鉛化度を表わす。 Surface-enhanced Raman spectroscopy (SERS) is a method of measuring a thin metal film such as silver or gold on the surface of a sample, and was invented by Fleischmann et al. In 1974. It is characterized by an increase. The Raman spectrum of the graphite material obtained by this method is different in analysis depth, but the same vibration mode as in normal Raman spectroscopy can be obtained. And around 1580cm -1 ~1620cm -1 (Psa) as a vibration mode derived from a graphite crystalline structure, peak near 1350cm -1 ~1400cm -1 (Psb) as a vibration mode derived from the turbostratic non crystalline The ratio of the obtained Psa strength (height Hsa) to Psb strength (height Hsb) represents the degree of graphitization of the outermost surface layer portion of the particle.

本発明の非水電解液二次電池または非水電解液二次電池用炭素材料は、炭素材料について表面増大ラマン分光スペクトルのピークを有する範囲を規定し、この規定に合致した炭素材料を負極に用いているので高温環境における保存での電池容量の劣化を抑制する。   The non-aqueous electrolyte secondary battery or the non-aqueous electrolyte secondary battery carbon material of the present invention defines a range having a peak of a surface-enhanced Raman spectroscopic spectrum for the carbon material, and a carbon material conforming to this rule is used as a negative electrode. Since it is used, battery capacity degradation during storage in a high temperature environment is suppressed.

本発明によると、炭素材料表面近傍の構造パラメータを規定することにより、高温保存しても劣化が少なくて信頼性が高く、且つ、容量の大きな非水電解液二次電池または非水電解液二次電池用炭素材料を提供することが可能となる。   According to the present invention, by defining the structural parameters in the vicinity of the surface of the carbon material, the non-aqueous electrolyte secondary battery or the non-aqueous electrolyte 2 having a small capacity, high reliability and high capacity even when stored at a high temperature. It becomes possible to provide a carbon material for a secondary battery.

本発明に係わる、渦巻式電極を用いた円筒型非水電解液二次電池の断面図である。1 is a cross-sectional view of a cylindrical non-aqueous electrolyte secondary battery using a spiral electrode according to the present invention. 容量回復率とRGの関係を示す図である。It is a figure which shows the relationship between a capacity | capacitance recovery rate and RG. 容量回復率とPsbの関係を示す図である。It is a figure which shows the relationship between a capacity | capacitance recovery rate and Psb.

つぎに、発明の実施の形態について説明する。
本発明に使用する炭素材料は、上述した構造パラメータを満足すればいずれの材料も使用可能であるが、その中でも特に黒鉛材料が好ましい。黒鉛材料には鉱石などから産出される天然黒鉛と、有機物を原料とし、2000℃以上の高温で熱処理して得られる人造黒鉛とがある。
Next, embodiments of the invention will be described.
As the carbon material used in the present invention, any material can be used as long as it satisfies the structural parameters described above, and among these, a graphite material is particularly preferable. Graphite materials include natural graphite produced from ores and the like, and artificial graphite obtained by heat treatment at a high temperature of 2000 ° C. or higher using organic materials as raw materials.

上記人造黒鉛を生成するに際して出発原料となる有機材料としては、石炭やピッチが代表的なものである。ピッチとしては、コールタール、エチレンボトム油、原油等の高温熱分解で得られるタール類、アスファルトなどより蒸留(真空蒸留、常圧蒸留、スチーム蒸留)、熱重縮合、抽出、化学重縮合等の操作によって得られるものや、その他木材乾留時に生成するピッチ等もある。さらにピッチとなる出発原料としてはポリ塩化ビニル樹脂、ポリビニルアセテート、ポリビニルブチラート、3,5−ジメチルフェノール樹脂等がある。これら石炭、ピッチは、炭素化の途中最高400℃程度で液状で存在し、その温度で保持することで芳香環同士が縮合、多環化して積層配向した状態となり、その後500℃程度以上の温度になると固体の炭素前駆体則ちセミコークスを形成する。このような過程を液相炭素化過程と呼び、易黒鉛化炭素の典型的な生成過程である。   Typical examples of the organic material used as a starting material for producing the artificial graphite include coal and pitch. As pitch, tars obtained by high-temperature pyrolysis of coal tar, ethylene bottom oil, crude oil, etc., asphalt, etc. (vacuum distillation, atmospheric distillation, steam distillation), thermal polycondensation, extraction, chemical polycondensation, etc. There are also those obtained by operation and other pitches generated during dry distillation of wood. Furthermore, examples of the starting material for forming a pitch include polyvinyl chloride resin, polyvinyl acetate, polyvinyl butyrate, and 3,5-dimethylphenol resin. These coals and pitches are present in a liquid state at a maximum of about 400 ° C. during carbonization, and by maintaining at that temperature, the aromatic rings are condensed and polycyclic to form a laminated orientation, and then a temperature of about 500 ° C. or higher. Then, a solid carbon precursor, that is, semi-coke is formed. Such a process is called a liquid-phase carbonization process and is a typical process for producing graphitizable carbon.

その他、ナフタレン、フェナントレン、アントラセン、トリフェニレン、ピレン、ペリレン、ペンタフェン、ペンタセン等の縮合多環炭化水素化合物、その他誘導体(例えばこれらのカルボン酸、カルボン酸無水物、カルボン酸イミド等)、あるいは混合物、アセナフチレン、インドール、イソインドール、キノリン、イソキノリン、キノキサリン、フタラジン、カルバゾール、アクリジン、フェナジン、フェナントリジン等の縮合複素環化合物、さらにはその誘導体も原料として使用可能である。   Other condensed polycyclic hydrocarbon compounds such as naphthalene, phenanthrene, anthracene, triphenylene, pyrene, perylene, pentaphen, and pentacene, other derivatives (for example, carboxylic acids, carboxylic acid anhydrides, carboxylic acid imides, etc.) or mixtures, acenaphthylene Indole, isoindole, quinoline, isoquinoline, quinoxaline, phthalazine, carbazole, acridine, phenazine, phenanthridine and other condensed heterocyclic compounds, and derivatives thereof can also be used as raw materials.

以上の有機材料を出発原料として所望の人造黒鉛を生成するには、例えば、上記有機材料を窒素等の不活性ガス気流中、300〜700℃で炭化した後、不活性ガス気流中、昇温速度毎分1〜100℃、到達温度900〜1500℃、到達温度での保持時間0〜30時間程度の条件で仮焼し、さらに2000℃以上、好ましくは2500℃以上で熱処理されることによって得られる。勿論、場合によっては炭化や仮焼操作を省略しても良い。高温で熱処理された炭素材料、あるいは黒鉛材料は粉砕、分級して負極材料に供されるが、この粉砕は炭化、仮焼、高温熱処理の前に行うことが好ましい。   In order to produce desired artificial graphite using the above organic material as a starting material, for example, the organic material is carbonized at 300 to 700 ° C. in an inert gas stream such as nitrogen, and then heated in an inert gas stream. It is obtained by calcining at a speed of 1 to 100 ° C. per minute, an ultimate temperature of 900 to 1500 ° C., a holding time at the ultimate temperature of about 0 to 30 hours, and further heat-treated at 2000 ° C. or higher, preferably 2500 ° C. or higher. It is done. Of course, depending on the case, carbonization and calcination operations may be omitted. The carbon material or graphite material heat-treated at high temperature is pulverized and classified to be used as the negative electrode material. This pulverization is preferably performed before carbonization, calcination, and high-temperature heat treatment.

さらに、より実用的な性能を有する材料としては真密度2.1g/cm3 以上であり、且つ嵩比重が0.4g/cm3 以上の黒鉛材料を用いることが好ましい。黒鉛材料は真密度が高いので、これで負極を構成すると、電極充填性が高められ、電池のエネルギー密度が向上する。また、黒鉛材料のうち特に嵩比重が0.4g/cm3 以上の黒鉛材料を用いると、電極構造が良好なものとなって、サイクル特性が改善される。これは嵩比重が大きい黒鉛材料は負極合剤層中に比較的均一に分散されることができる等のためである。さらに、嵩比重が0.4g/cm3 以上であって、且つ平均形状パラメータxave が125以下である偏平度の低い材料を用いると、さらに電極構造が良好なものとなり、さらにサイクル特性が改善される。 Furthermore, as a material having more practical performance, it is preferable to use a graphite material having a true density of 2.1 g / cm 3 or more and a bulk specific gravity of 0.4 g / cm 3 or more. Since the graphite material has a high true density, when the negative electrode is formed with this, the electrode filling property is improved and the energy density of the battery is improved. In addition, when a graphite material having a bulk specific gravity of 0.4 g / cm 3 or more is used among the graphite materials, the electrode structure is improved and the cycle characteristics are improved. This is because the graphite material having a large bulk specific gravity can be relatively uniformly dispersed in the negative electrode mixture layer. Furthermore, when a material having a low specificity with a bulk specific gravity of 0.4 g / cm 3 or more and an average shape parameter xave of 125 or less is used, the electrode structure is further improved and the cycle characteristics are further improved. The

上述した黒鉛材料を得るには、炭素が成型体とされた状態で黒鉛化のための熱処理を行う方法が好ましく、この黒鉛化成型体を粉砕することによって、より嵩比重が高く、平均形状パラメータxave の小さい黒鉛材料が可能となる。また、黒鉛材料として嵩比重、平均形状パラメータxave が前記の範囲であって、比表面積が9m2 /g以下の黒鉛粉末を用いた場合、黒鉛粒子に付着したサブミクロンの微粒子が少なく、嵩比重が高くなり、電極構造が良好なものとなって、さらにサイクル特性が改善される。 In order to obtain the above-described graphite material, a method of performing a heat treatment for graphitization in a state where carbon is formed into a molded body is preferable. By crushing this graphitized molded body, the bulk specific gravity is higher, and the average shape parameter A graphite material with a small xave becomes possible. Further, when graphite powder having a bulk specific gravity and an average shape parameter xave within the above ranges and a specific surface area of 9 m 2 / g or less is used as the graphite material, there are few submicron fine particles adhering to the graphite particles, and the bulk specific gravity is low. Becomes higher, the electrode structure becomes better, and the cycle characteristics are further improved.

また、レーザ回折法により求められる粒度分布において、累積10%粒径が3μm以上であり、且つ累積50%粒径が10μm以上であり、且つ累積90%粒径が70μm以下である黒鉛粉末を用いることにより安全性、信頼性の高い非水電解液二次電池が得られる。   Further, a graphite powder having a cumulative 10% particle size of 3 μm or more, a cumulative 50% particle size of 10 μm or more, and a cumulative 90% particle size of 70 μm or less is used in the particle size distribution obtained by the laser diffraction method. Thus, a safe and reliable non-aqueous electrolyte secondary battery can be obtained.

粒度の小さい粒子は比表面積が大きくなるが、この含有率を制限することにより、比表面積の大きい粒子による過充電時などの異常発熱を抑制するとともに、粒度の大きい粒子の含有率を制限することにより、初充電時における粒子の膨張に伴う内部ショートを抑制することができ、高い安全性、信頼性を有する実用的な非水電解液二次電池が可能となる。   Particles with a small particle size have a large specific surface area, but by restricting this content rate, it is possible to suppress abnormal heat generation during overcharging due to particles with a large specific surface area and to limit the content rate of particles with a large particle size. As a result, an internal short circuit due to particle expansion during initial charging can be suppressed, and a practical non-aqueous electrolyte secondary battery having high safety and reliability can be achieved.

また、粒子の破壊強度の平均値が6.0kgf/mm2 以上である黒鉛粉末を用いることにより、電極中に電解液を含有させるための空孔を多く存在させることができ、負荷特性の良好な非水電解液二次電池が可能となる。 In addition, by using graphite powder having an average value of the breaking strength of particles of 6.0 kgf / mm 2 or more, it is possible to have many pores for containing the electrolyte in the electrode, and the load characteristics are excellent. A non-aqueous electrolyte secondary battery becomes possible.

つぎに、本発明で規定される炭素材料の製造方法を説明する。まず、人造黒鉛について説明する。前述したように、人造黒鉛の前駆体としては、石油や石炭から得られるピッチ類が原料として用いることができる。これを400〜500℃で熱処理し、得られた炭素前駆体を、不活性雰囲気中800〜1000℃で熱処理して得られる。この時点で、粉砕し粒度調整した後、反応性ガスを用いて適当な温度を選択し、粒子表面を僅かに酸化する。その後、さらに不活性雰囲気中で高温処理し黒鉛化することにより、本発明に規定される材料を得ることができる。   Below, the manufacturing method of the carbon material prescribed | regulated by this invention is demonstrated. First, artificial graphite will be described. As described above, pitches obtained from petroleum or coal can be used as a raw material as a precursor of artificial graphite. This is heat-processed at 400-500 degreeC, and the obtained carbon precursor is heat-processed at 800-1000 degreeC in inert atmosphere. At this point, after pulverization and particle size adjustment, an appropriate temperature is selected using a reactive gas, and the particle surface is slightly oxidized. Then, the material prescribed | regulated to this invention can be obtained by carrying out the high temperature process in an inert atmosphere, and graphitizing.

反応性ガスは炭素と反応するものであればいずれの化合物も使用可能であるが、その中でも酸素、オゾン、二酸化炭素、一酸化炭素、塩素、塩酸、二酸化硫黄、NOx 等が好ましい。反応温度は、使用するガスによって適宜選択可能であるが、室温〜500℃が好ましい。また、一度黒鉛化された粒子に対して、レーザ等の強力な光を照射し、その粒子表面の凹凸を取り去り、磨くことで本発明に規定される材料を得ることができる。 The reaction gas can be used any compound as long as it reacts with carbon, oxygen among them, ozone, carbon dioxide, carbon monoxide, chlorine, hydrochloric acid, sulfur dioxide, NO x, etc. are preferable. The reaction temperature can be appropriately selected depending on the gas used, but is preferably room temperature to 500 ° C. Moreover, the material prescribed | regulated to this invention can be obtained by irradiating powerful light, such as a laser, to the once graphitized particle, removing the unevenness | corrugation of the particle | grain surface, and polishing.

つぎに、天然黒鉛について述べる。天然黒鉛を適当な条件で粉砕すると、結晶構造中に菱面体構造が出現する。これを2000℃以上で熱処理することで本発明に規定される材料を得ることができる。菱面体構造の含有率はX線回折によって求めることができるが、その含有率は、1%以上、40%以下が好ましく、5%以上、30%以下がより好ましい。   Next, natural graphite will be described. When natural graphite is pulverized under appropriate conditions, a rhombohedral structure appears in the crystal structure. The material prescribed | regulated to this invention can be obtained by heat-processing this at 2000 degreeC or more. The content of the rhombohedral structure can be determined by X-ray diffraction, and the content is preferably 1% or more and 40% or less, and more preferably 5% or more and 30% or less.

一方、前記の負極材料からなる負極と組み合わせて用いられる正極材料は特に限定されないが、十分な量のLiを含んでいることが好ましく、例えば一般式LiMO2 (ただしMはCo、Ni、Mn、Fe、Al、V、Tiの中の少なくとも1種を表す。)で表されるリチウムと遷移金属からなる複合金属酸化物やLiを含んだ層間化合物等が好適である。 On the other hand, the positive electrode material used in combination with the negative electrode made of the negative electrode material is not particularly limited, but preferably contains a sufficient amount of Li. For example, the general formula LiMO 2 (where M is Co, Ni, Mn, A composite metal oxide composed of lithium and a transition metal represented by (1) represents at least one of Fe, Al, V, and Ti, and an intercalation compound containing Li are suitable.

本発明の非水電解液二次電池に用いる非水電解液は電解質が非水溶媒に溶解されてなる非水電解液が用いられる。電解質を溶解する非水溶媒としては、エチレンカーボネート(EC)等の比較的誘電率の高いものを主溶媒に用いることが前提となるが、本発明を完成させるにはさらに複数成分の低粘度溶媒を添加する必要がある。   As the non-aqueous electrolyte used in the non-aqueous electrolyte secondary battery of the present invention, a non-aqueous electrolyte obtained by dissolving an electrolyte in a non-aqueous solvent is used. As a non-aqueous solvent for dissolving the electrolyte, it is premised that a solvent having a relatively high dielectric constant such as ethylene carbonate (EC) is used as a main solvent. To complete the present invention, a multi-component low-viscosity solvent is used. Need to be added.

高誘電率溶媒としては、プロピレンカーボネート(PC)、ブチレンカーボネート、ビニレンカーボネート、スルホラン類、ブチロラクトン類、バレロラクトン類等が好適である。   As the high dielectric constant solvent, propylene carbonate (PC), butylene carbonate, vinylene carbonate, sulfolanes, butyrolactones, valerolactones and the like are suitable.

低粘度溶媒としては、ジエチルカーボネート、ジメチルカーボネート、メチルエチルカーボネート、メチルプロピルカーボネート等の対称、あるいは非対称の鎖状炭酸エステルが好適であり、さらに2種以上の低粘度溶媒を混合して用いても良好な結果が得られる。   As the low-viscosity solvent, a symmetric or asymmetric chain ester carbonate such as diethyl carbonate, dimethyl carbonate, methyl ethyl carbonate, methyl propyl carbonate or the like is preferable, and two or more kinds of low-viscosity solvents may be mixed and used. Good results are obtained.

特に負極に黒鉛材料を用いる場合、非水溶媒の主溶媒として好適なのはECがまず挙げられるが、ECの水素原子をハロゲン元素で置換した構造の化合物も好適である。また、PCのように黒鉛材料と反応性があるものの、主溶媒としてのECやECの水素原子をハロゲン元素で置換した構造の化合物等に対して、その一部を第2成分溶媒で置換することにより、良好な特性が得られる。   In particular, when a graphite material is used for the negative electrode, EC is first preferred as the main solvent of the nonaqueous solvent, but a compound having a structure in which the hydrogen atom of EC is substituted with a halogen element is also suitable. In addition, although it is reactive with graphite materials such as PC, a part of the EC or the compound having a structure in which the hydrogen atom of EC is substituted with a halogen element is substituted with a second component solvent. As a result, good characteristics can be obtained.

その第2成分溶媒としては、PC、ブチレンカーボネート, 1,2−ジメトキシエタン、1,2−ジエトキシメタン、γ−ブチロラクトン、バレロラクトン、テトラヒドロフラン、2−メチルテトラヒドロフラン、1,3−ジオキソラン、4−メチル−1,3−ジオキソラン、スルホラン、メチルスルホラン等が使用可能であり、その添加量としては10Vol %未満が好ましい。   As the second component solvent, PC, butylene carbonate, 1,2-dimethoxyethane, 1,2-diethoxymethane, γ-butyrolactone, valerolactone, tetrahydrofuran, 2-methyltetrahydrofuran, 1,3-dioxolane, 4- Methyl-1,3-dioxolane, sulfolane, methylsulfolane and the like can be used, and the addition amount is preferably less than 10 Vol%.

さらに本発明を完成させるには主溶媒に対して、あるいは主溶媒と第2成分溶媒の混合溶媒に対して、第3の溶媒を添加し導電率の向上、ECの分解抑制、低温特性の改善を図るとともにリチウム金属との反応性を低め、安全性を改善するようにしても良い。第3成分の溶媒としては、まずDEC(ジエチルカーボネート)やDMC(ジメチルカーボネート)等の鎖状炭酸エステルが好適である。また、MEC(メチルエチルカーボネート)やMPC(メチルプロピルカーボネート)等の非対称鎖状炭酸エステルが好適である。   To complete the present invention, a third solvent is added to the main solvent or to the mixed solvent of the main solvent and the second component solvent to improve conductivity, suppress EC decomposition, and improve low-temperature characteristics. In addition to reducing the reactivity with lithium metal, safety may be improved. As the solvent for the third component, first, a chain carbonate such as DEC (diethyl carbonate) or DMC (dimethyl carbonate) is suitable. Further, asymmetric chain carbonates such as MEC (methyl ethyl carbonate) and MPC (methyl propyl carbonate) are suitable.

主溶媒あるいは主溶媒と第2成分溶媒の混合溶媒に対する第3成分となる鎖状炭酸エステルの混合比(主溶媒または、主溶媒と第2成分溶媒の混合溶媒:第3成分溶媒)は、容量比で15:85から40:60が好ましく、18:82から35:65がさらに好ましい。さらに、第3成分の溶媒としてはMECとDMCとの混合溶媒であってもよい。MEC−DMC混合比率は、MEC容量をm、DMC容量をdとしたときに、1/9≦d/m≦8/2 で示される範囲とすることが好ましい。   The mixing ratio of the chain carbonate ester as the third component to the main solvent or the mixed solvent of the main solvent and the second component solvent (the main solvent or the mixed solvent of the main solvent and the second component solvent: the third component solvent) is the capacity. The ratio is preferably 15:85 to 40:60, more preferably 18:82 to 35:65. Further, the third component solvent may be a mixed solvent of MEC and DMC. The MEC-DMC mixing ratio is preferably in a range represented by 1/9 ≦ d / m ≦ 8/2, where m is the MEC capacity and d is the DMC capacity.

また、主溶媒あるいは主溶媒と第2成分溶媒の混合溶媒と第3成分の溶媒となるMEC−DMCの混合比率は、MEC容量をm、DMC容量をd、溶媒全量をTとしたときに、3/10≦(m+d)/T≦9/10 で示される範囲とすることが好ましく、5/10≦(m+d)/T≦8/10 で示される範囲とすることがさらに好ましい。   The mixing ratio of the main solvent or the mixed solvent of the main solvent and the second component solvent and the third component solvent is MEC-DMC, where the MEC capacity is m, the DMC capacity is d, and the total amount of the solvent is T. A range represented by 3/10 ≦ (m + d) / T ≦ 9/10 is preferable, and a range represented by 5/10 ≦ (m + d) / T ≦ 8/10 is more preferable.

このような非水溶媒に溶解する電解質としては、この主の電池に用いられるものであればいずれも1種以上混合し使用可能である。例えばLiPF6 が好適であるが、その他LiClO4 、LiAsF6 、LiBF4 、LiB(C6 5 4 、CH3 SO3 Li、CF3 SO3 Li、LiN(CF3 SO2 2 、LiC(CF3 SO2 3 、LiCl、LiBr等も使用可能である。 As the electrolyte dissolved in such a non-aqueous solvent, any one used in this main battery can be mixed and used. For example, LiPF 6 is preferable, but LiClO 4 , LiAsF 6 , LiBF 4 , LiB (C 6 H 5 ) 4 , CH 3 SO 3 Li, CF 3 SO 3 Li, LiN (CF 3 SO 2 ) 2 , LiC (CF 3 SO 2 ) 3 , LiCl, LiBr or the like can also be used.

以下に、本発明に係わる非水電解液二次電池について、図1を参照し、その実施例1〜実施例5、および、これと比較するための比較例1〜比較例4について説明する。尚、本発明はこれらの例に限定されるものではない。   Below, with reference to FIG. 1, the non-aqueous-electrolyte secondary battery concerning this invention is demonstrated about the Example 1- Example 5 and the comparative example 1- Comparative example 4 for comparing with this. The present invention is not limited to these examples.

<実施例1>
負極1はつぎのようにして作製した。石炭ピッチコークスに石油ピッチを添加して混合した後、加圧整形した。これを不活性雰囲気中500℃で熱処理し、その後、粉砕分級したのち、不活性雰囲気中1000℃にて熱処理し黒鉛前駆体を得た。この前駆体と酸素ガスを密閉し、200℃で20時間処理した。その後、これを不活性雰囲気中2950℃で1時間熱処理し、試料を得た。
<Example 1>
The negative electrode 1 was produced as follows. Petroleum pitch was added to coal pitch coke and mixed, and then pressed and shaped. This was heat-treated at 500 ° C. in an inert atmosphere, then pulverized and classified, and then heat-treated at 1000 ° C. in an inert atmosphere to obtain a graphite precursor. The precursor and oxygen gas were sealed and treated at 200 ° C. for 20 hours. Then, this was heat-processed in inert atmosphere at 2950 degreeC for 1 hour, and the sample was obtained.

このようにして得た炭素材料粉末を90重量部、結着剤としてポリフッ化ビニリデン(PVDF)10重量部を混合し、負極合剤を調製した。この負極合剤を、溶剤であるN−メチルピロリドンに分散させてスラリー(ペースト状)にした。負極集電体として厚さ10μmの帯状の銅箔を用い、この集電体の両面に負極合剤スラリーを塗布し、乾燥させた後圧縮成型して帯状の負極1を作製した。   90 parts by weight of the carbon material powder thus obtained and 10 parts by weight of polyvinylidene fluoride (PVDF) as a binder were mixed to prepare a negative electrode mixture. This negative electrode mixture was dispersed in N-methylpyrrolidone as a solvent to form a slurry (paste). A strip-shaped copper foil having a thickness of 10 μm was used as a negative electrode current collector. A negative electrode mixture slurry was applied to both surfaces of the current collector, dried, and then compression molded to prepare a strip-shaped negative electrode 1.

正極2はつぎのようにして作製した。
炭酸リチウム0.5モルと炭酸コバルト1モルを混合し、900℃の空気中で5時間焼成してLiCoO2 を得た。正極活物質としてこのLiCoO2 を91重量部、導電剤としてグラファイト6重量部、結着剤としてポリフッ化ビニリデン3重量部を混合し、正極合剤とした。この正極合剤をN−メチルピロリドンに分散させてスラリー(ペースト状)にした。正極集電体として厚さ20μmの帯状のアルミニウム箔を用い、この集電体の両面に均一に正極合剤スラリーを塗布し、乾燥させた後圧縮成型して帯状の正極2を作製した。
The positive electrode 2 was produced as follows.
Lithium carbonate 0.5 mol and cobalt carbonate 1 mol were mixed and calcined in air at 900 ° C. for 5 hours to obtain LiCoO 2 . 91 parts by weight of LiCoO 2 as a positive electrode active material, 6 parts by weight of graphite as a conductive agent, and 3 parts by weight of polyvinylidene fluoride as a binder were mixed to obtain a positive electrode mixture. This positive electrode mixture was dispersed in N-methylpyrrolidone to form a slurry (paste). A strip-shaped aluminum foil having a thickness of 20 μm was used as the positive electrode current collector, and the positive electrode mixture slurry was uniformly applied to both surfaces of the current collector, dried, and then compression molded to prepare a strip-shaped positive electrode 2.

上述したようにして作製した負極1および正極2を厚さ25μmの微多孔性ポリプロピレンフィルムからなるセパレータ3を負極1、セパレータ3、正極2、セパレータ3の順に積層し、これをセンターピン14を中心にして多数回巻回し、そのセパレータ3の最終端部をテープで固定して渦巻型の電極素子を作製した。   The negative electrode 1 and the positive electrode 2 produced as described above were laminated in the order of the negative electrode 1, the separator 3, the positive electrode 2, and the separator 3 in the order of the negative electrode 1, the separator 3, the positive electrode 2, and the separator 3. Then, the coil 3 was wound many times, and the final end portion of the separator 3 was fixed with a tape to produce a spiral electrode element.

このようにして作製した電極素子を電池缶5内に収納し、電極素子の上下両面には絶縁板4を配設する。絶縁テープを張った正極リード13を正極集電体11から導出して電池蓋7に導通する安全弁装置8に、また、負極リード12を負極集電体10から導出して電池缶5に溶接した。電池缶5は外径18mm(内径17.38mm、厚さ0.31mm)、高さ65mmの鉄製である。   The electrode element produced in this way is accommodated in the battery can 5, and insulating plates 4 are provided on both upper and lower surfaces of the electrode element. The positive electrode lead 13 with the insulating tape stretched out from the positive electrode current collector 11 and led to the safety valve device 8 which conducts to the battery lid 7, and the negative electrode lead 12 from the negative electrode current collector 10 and welded to the battery can 5. . The battery can 5 is made of iron having an outer diameter of 18 mm (inner diameter: 17.38 mm, thickness: 0.31 mm) and a height of 65 mm.

この電池缶5の中に、エチレンカーボネートとジメチルカーボネートとの等容量混合溶媒中にLiPF6 を1モル/リットルの割合で溶解した電解液を注入した。ついで、封口ガスケット6 を介して電池缶5をかしめることにより、電池蓋7を固定し、電池内の気密性を保持させて非水電解液二次電池を作成した。 In the battery can 5, an electrolytic solution in which LiPF 6 was dissolved at a ratio of 1 mol / liter in an equal volume mixed solvent of ethylene carbonate and dimethyl carbonate was injected. Next, the battery can 5 was caulked through the sealing gasket 6 to fix the battery lid 7 and to maintain the airtightness in the battery, thereby producing a non-aqueous electrolyte secondary battery.

<実施例2>
アセナフチレンピッチを原料に用い、400℃にて10kg/cm2 以上の高圧下で熱処理し、バルクメソフェースを成長させた。これを不活性雰囲気中500℃で熱処理し、その後、粉砕分級したのち、不活性雰囲気中1000℃で熱処理し黒鉛前駆体を得た。この黒鉛前駆体を不活性雰囲気中3050℃で1時間熱処理し、試料を得た。これを負極材料に用いる以外は、実施例1と同様に非水電解液二次電池を作成した。
<Example 2>
Using acenaphthylene pitch as a raw material, heat treatment was performed at 400 ° C. under a high pressure of 10 kg / cm 2 or more to grow a bulk mesoface. This was heat-treated at 500 ° C. in an inert atmosphere, then pulverized and classified, and then heat-treated at 1000 ° C. in an inert atmosphere to obtain a graphite precursor. This graphite precursor was heat-treated at 3050 ° C. for 1 hour in an inert atmosphere to obtain a sample. A nonaqueous electrolyte secondary battery was prepared in the same manner as in Example 1 except that this was used as the negative electrode material.

<実施例3>
アセナフチレンピッチに硫酸を少量添加して、これを400℃にて10kg/cm2 以上の高圧下で熱処理し、バルクメソフェースを成長させた。これを不活性雰囲気中500℃で熱処理し、その後、粉砕分級したのち、不活性雰囲気中1000℃にて熱処理し黒鉛前駆体を得た。この前駆体を不活性雰囲気中3050℃で1時間熱処理し、試料を得た。これを負極材料に用いる以外は、実施例1と同様に非水電解液二次電池を作成した。
<Example 3>
A small amount of sulfuric acid was added to acenaphthylene pitch, and this was heat-treated at 400 ° C. under a high pressure of 10 kg / cm 2 or more to grow a bulk mesophase. This was heat-treated at 500 ° C. in an inert atmosphere, then pulverized and classified, and then heat-treated at 1000 ° C. in an inert atmosphere to obtain a graphite precursor. This precursor was heat-treated at 3050 ° C. for 1 hour in an inert atmosphere to obtain a sample. A nonaqueous electrolyte secondary battery was prepared in the same manner as in Example 1 except that this was used as the negative electrode material.

<実施例4>
純度99%以上とした天然黒鉛を、ボールミルにて粉砕し、その後、分級した。これを流動させながら、大気中にてその表面にレーザ光を十分に照射し、その後、不活性雰囲気中2600℃で1時間熱処理し、試料を得た。これを負極材料に用いる以外は、実施例1と同様に非水電解液二次電池を作成した。
<Example 4>
Natural graphite having a purity of 99% or more was pulverized with a ball mill and then classified. While flowing this, the surface was sufficiently irradiated with laser light in the air, and then heat-treated at 2600 ° C. for 1 hour in an inert atmosphere to obtain a sample. A nonaqueous electrolyte secondary battery was prepared in the same manner as in Example 1 except that this was used as the negative electrode material.

<実施例5>
純度99%以上とした天然黒鉛を、ジェットミルにて粉砕しながら風力分級した。X線回折で測定したところ、菱面体構造が20%含有していることが判明した。これを不活性雰囲気中2700℃で1時間熱処理し、試料を得た。これを負極材料に用いる以外は、実施例1と同様に非水電解液二次電池を作成した。
<Example 5>
Natural graphite having a purity of 99% or more was subjected to air classification while being pulverized by a jet mill. Measurement by X-ray diffraction revealed that the rhombohedral structure contained 20%. This was heat-treated at 2700 ° C. for 1 hour in an inert atmosphere to obtain a sample. A nonaqueous electrolyte secondary battery was prepared in the same manner as in Example 1 except that this was used as the negative electrode material.

<比較例1>
石炭ピッチコークスに石油ピッチを添加して混合した後、加圧整形した。これを不活性雰囲気中500℃で熱処理し、その後、粉砕分級したのち、不活性雰囲気中1000℃で熱処理し黒鉛前駆体を得た。この黒鉛前駆体を不活性雰囲気中2950℃で1時間熱処理し、試料を得た。これを負極材料に用いる以外は、実施例1と同様に非水電解液二次電池を作成した。
<Comparative Example 1>
Petroleum pitch was added to coal pitch coke and mixed, and then pressed and shaped. This was heat-treated at 500 ° C. in an inert atmosphere, then pulverized and classified, and then heat-treated at 1000 ° C. in an inert atmosphere to obtain a graphite precursor. This graphite precursor was heat-treated at 2950 ° C. for 1 hour in an inert atmosphere to obtain a sample. A nonaqueous electrolyte secondary battery was prepared in the same manner as in Example 1 except that this was used as the negative electrode material.

<比較例2>
アセナフチレンピッチを原料に用いて、400℃にて熱処理し、メソフェース小球体の含有率が50%の時点で、マトリックスと小球体を分離させ、取り出した。これを不活性雰囲気中500℃で熱処理し、その後、粉砕分級したのち、不活性雰囲気中1000℃で熱処理し黒鉛前駆体を得た。この前駆体を不活性雰囲気中2900℃で1時間熱処理し、試料を得た。これを負極材料に用いる以外は、実施例1と同様に非水電解液二次電池を作成した。
<Comparative example 2>
Using acenaphthylene pitch as a raw material, heat treatment was performed at 400 ° C., and when the content of mesophase spherules was 50%, the matrix and the spherules were separated and taken out. This was heat-treated at 500 ° C. in an inert atmosphere, then pulverized and classified, and then heat-treated at 1000 ° C. in an inert atmosphere to obtain a graphite precursor. This precursor was heat-treated at 2900 ° C. for 1 hour in an inert atmosphere to obtain a sample. A nonaqueous electrolyte secondary battery was prepared in the same manner as in Example 1 except that this was used as the negative electrode material.

<比較例3>
純度99%以上とした天然黒鉛を、ボールミルにて粉砕し、その後、分級し、試料を得た。これを負極材料に用いる以外は、実施例1と同様に非水電解液二次電池を作成した。
<Comparative Example 3>
Natural graphite having a purity of 99% or more was pulverized with a ball mill and then classified to obtain a sample. A nonaqueous electrolyte secondary battery was prepared in the same manner as in Example 1 except that this was used as the negative electrode material.

<比較例4>
純度99%以上の天然黒鉛を、ジェットミルにて粉砕しながら風力分級して試料を得た。これを負極材料に用いる以外は、実施例1と同様に非水電解液二次電池を作成した。
<Comparative example 4>
Natural graphite having a purity of 99% or more was subjected to air classification while being pulverized by a jet mill to obtain a sample. A nonaqueous electrolyte secondary battery was prepared in the same manner as in Example 1 except that this was used as the negative electrode material.

上述したようにして作成した実施例1〜実施例5、および、比較例1〜比較例4の電池を、最大電圧4.2V、定電流1A、充電時間3時間の条件で充電し、これを用いて、45℃の雰囲気に1ヶ月間保存した。この45℃とは電子機器の内部温度を想定したものである。その後、放電して保存後の放電容量を測定し、再度前記条件で充電する。その後、1Aで放電してこの時の放電容量を測定し、回復容量を求めた。この回復容量を保存後の放電容量で除した値を容量回復率と定義する。これを表1に示す。   The batteries of Examples 1 to 5 and Comparative Examples 1 to 4 created as described above were charged under the conditions of a maximum voltage of 4.2 V, a constant current of 1 A, and a charging time of 3 hours. And stored in a 45 ° C. atmosphere for 1 month. This 45 ° C. assumes the internal temperature of the electronic device. Then, it discharges, the discharge capacity after a preservation | save is measured, and it charges again on the said conditions. Thereafter, the battery was discharged at 1 A, and the discharge capacity at this time was measured to obtain the recovery capacity. A value obtained by dividing the recovery capacity by the discharge capacity after storage is defined as a capacity recovery rate. This is shown in Table 1.

Figure 2012089531
Figure 2012089531

実施例1〜5、比較例1〜4の各試料について、波長514、5nmのアルゴンレーザを利用し、波数分解能4cm-1のラマン分光器で測定したラマンスペクトル、および、同様の測定条件で、銀を10nmの厚さに蒸着した試料のSERSスペクトルからRG、Pbb、Pba、Psb、Psaを求め、これも表1に示した。 For each sample of Examples 1 to 5 and Comparative Examples 1 to 4, using an argon laser with a wavelength of 514 and 5 nm, a Raman spectrum measured with a Raman spectrometer having a wave number resolution of 4 cm −1 , and the same measurement conditions, RG, Pbb, Pba, Psb, and Psa were determined from the SERS spectrum of a sample in which silver was deposited to a thickness of 10 nm, and these are also shown in Table 1.

これらのデータより、図2に容量回復率とRGの関係を示した。同図よりRGが高いほど容量回復率が高いことがわかる。特に、RG=4.5以上では、容量回復率は、85%以上に達しており、高温環境における保存時の容量劣化が低く抑えられることがわかる。   From these data, FIG. 2 shows the relationship between the capacity recovery rate and RG. It can be seen from the figure that the higher the RG, the higher the capacity recovery rate. In particular, when RG = 4.5 or more, the capacity recovery rate reaches 85% or more, and it can be seen that capacity degradation during storage in a high-temperature environment can be kept low.

また、図3に容量回復率とPsbの関係を示した。同図よりPsbが高いほど容量回復率が高いことがわかる。特に、Psb=1365以上では、容量回復率は85%以上に達しており、高温環境における保存時の容量劣化が低く抑えられることがわかる。   FIG. 3 shows the relationship between the capacity recovery rate and Psb. It can be seen from the figure that the capacity recovery rate is higher as Psb is higher. In particular, when Psb = 1365 or more, the capacity recovery rate reaches 85% or more, and it can be seen that capacity degradation during storage in a high-temperature environment can be kept low.

以上詳細に説明したように、炭素材料の構造パラメータである、アルゴンレーザ光を用いたラマン分光スペクトルから求められる黒鉛化度Gb と、表面増大ラマン分光スペクトルから求められる黒鉛化度Gsとの比率RG(=Gs/Gb)を4.5以上に規定することで、これを負極に用いた非水電解液二次電池の高温環境における保存時の容量劣化が抑制される。また、アルゴンレーザ光を用いた表面増大ラマン分光スペクトルにおいて、1365cm-1以上の範囲にピークを有する材料を負極に用いることで、同様に高温環境における保存時の容量劣化が抑制される。 As described above in detail, the ratio RG between the graphitization degree Gb obtained from the Raman spectroscopic spectrum using argon laser light and the graphitization degree Gs obtained from the surface enhanced Raman spectroscopic spectrum, which is a structural parameter of the carbon material. By defining (= Gs / Gb) to be 4.5 or more, capacity deterioration during storage in a high temperature environment of a non-aqueous electrolyte secondary battery using this as a negative electrode is suppressed. Moreover, in the surface-enhanced Raman spectroscopic spectrum using argon laser light, a material having a peak in the range of 1365 cm −1 or more is used for the negative electrode, so that capacity degradation during storage in a high-temperature environment is similarly suppressed.

1…負極、2…正極、3…セパレータ、4…絶縁板、5…電池缶、6…封口ガスケット、7…電池蓋、8…安全弁装置、10…負極集電体、11…正極集電体、12…負極リード、13…正極リード。 DESCRIPTION OF SYMBOLS 1 ... Negative electrode, 2 ... Positive electrode, 3 ... Separator, 4 ... Insulation board, 5 ... Battery can, 6 ... Sealing gasket, 7 ... Battery cover, 8 ... Safety valve apparatus, 10 ... Negative electrode collector, 11 ... Positive electrode collector , 12 ... negative electrode lead, 13 ... positive electrode lead.

Claims (4)

波長514.5nmのアルゴンレーザ光と波数分解能4cm-1の分光器を用い、炭素材料に銀を10nmの厚さで蒸着した場合の表面増大ラマン分光スペクトルにおいて、非結晶質の乱層構造に由来する振動モードとして1350cm-1〜1400cm-1の範囲に1365以上の強度のピークを有する炭素材料を負極に用いた、
非水電解液二次電池。
Derived from amorphous turbulent structure in a surface-enhanced Raman spectroscopic spectrum when silver was deposited on a carbon material with a thickness of 10 nm using an argon laser beam with a wavelength of 514.5 nm and a spectrometer with a wave number resolution of 4 cm −1. a carbon material having a peak of 1365 or more intensity in the range of 1350cm -1 ~1400cm -1 as a vibration mode used for the negative electrode,
Non-aqueous electrolyte secondary battery.
前記炭素材料は黒鉛である、
請求項1記載の非水電解液二次電池。
The carbon material is graphite;
The nonaqueous electrolyte secondary battery according to claim 1.
波長514.5nmのアルゴンレーザ光と波数分解能4cm-1の分光器を用い、銀を10nmの厚さで蒸着した場合の表面増大ラマン分光スペクトルにおいて、非結晶質の乱層構造に由来する振動モードとして1350cm-1〜1400cm-1の範囲に1365以上の強度のピークを有する、
非水電解液二次電池用炭素材料。
In a surface-enhanced Raman spectroscopic spectrum obtained by depositing silver at a thickness of 10 nm using an argon laser beam having a wavelength of 514.5 nm and a spectroscope having a wave number resolution of 4 cm −1 , a vibration mode derived from an amorphous turbulent structure Having a peak with an intensity of 1365 or more in the range of 1350 cm −1 to 1400 cm −1 ,
Carbon material for non-aqueous electrolyte secondary batteries.
黒鉛である、
請求項3記載の非水電解液二次電池用炭素材料。
Is graphite,
The carbon material for nonaqueous electrolyte secondary batteries according to claim 3.
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