JP2015150515A - Catalyst for synthesis of carbon nanotube - Google Patents
Catalyst for synthesis of carbon nanotube Download PDFInfo
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- JP2015150515A JP2015150515A JP2014027130A JP2014027130A JP2015150515A JP 2015150515 A JP2015150515 A JP 2015150515A JP 2014027130 A JP2014027130 A JP 2014027130A JP 2014027130 A JP2014027130 A JP 2014027130A JP 2015150515 A JP2015150515 A JP 2015150515A
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- 229910021393 carbon nanotube Inorganic materials 0.000 title claims abstract description 174
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Abstract
Description
本発明はカーボンナノチューブ合成用触媒に関する。更に詳しくは、カーボンナノチューブ合成用触媒と、それを用いて製造されるカーボンナノチューブに関する。 The present invention relates to a catalyst for carbon nanotube synthesis. More specifically, the present invention relates to a carbon nanotube synthesis catalyst and a carbon nanotube produced using the catalyst.
直径が1μm以下のカーボンナノチューブは、例えば樹脂へ配合され、導電性や強度等の特性を付与するフィラーとして、種々の検討がなされている。そして、このようなカーボンナノチューブは、従来、主にアーク放電法、レーザー蒸着法、気相成長法などで製造されていた。 Carbon nanotubes having a diameter of 1 μm or less are variously studied as fillers that are blended into, for example, a resin and impart properties such as conductivity and strength. Such carbon nanotubes have heretofore been produced mainly by arc discharge method, laser vapor deposition method, vapor phase growth method and the like.
その中でも、気相成長法は、アーク放電法やレーザー蒸着法に比べて効率良く不純物の少ないカーボンナノチューブが得られるという利点がある。また、気体状態の原料を使用することによって、連続反応が可能であり、更には原料ガスとなる炭化水素や一酸化炭素等の炭素を含むガスが安価に入手できるので、カーボンナノチューブの量産化に適した技術といえる。 Among them, the vapor phase growth method has an advantage that carbon nanotubes with less impurities can be obtained more efficiently than the arc discharge method or the laser vapor deposition method. In addition, by using a raw material in a gaseous state, a continuous reaction is possible, and further, gas containing carbon such as hydrocarbon and carbon monoxide, which is a raw material gas, can be obtained at low cost. This is a suitable technology.
気相成長法によりカーボンナノチューブを得る際に使用される触媒(以下、カーボンナノチューブ合成用触媒と称する)は、例えばシリカ、アルミナ、マグネシア、ゼオライト等の担持成分に、鉄、コバルト、ニッケル等の活性成分の金属を担持させたもの等が提案されている(例えば特許文献1参照)。 Catalysts used to obtain carbon nanotubes by vapor phase growth (hereinafter referred to as carbon nanotube synthesis catalyst) include, for example, supported components such as silica, alumina, magnesia, and zeolite, and activities such as iron, cobalt, and nickel. The thing etc. which carry | supported the metal of the component are proposed (for example, refer patent document 1).
このようにして製造される微粒子状の触媒を用いて炭素繊維を気相成長させた場合、炭素繊維は曲がりくねって互いに絡み合った状態で成長する。カーボンナノチューブを樹脂中に分散させることにより絶縁性の樹脂に導電性を付与させることができることが一般に知られているが、このようにして得られる炭素繊維の絡まり凝集体は樹脂中での分散が悪く、その結果、所望の導電性を得るためには多量の炭素繊維を混入させる必要が生じることが多い。また、分散性の悪い多量の炭素繊維の絡まり凝集体を樹脂に混入させると、樹脂の強度劣化を引き起こすという課題を有していた。 When carbon fibers are vapor-phase-grown using the particulate catalyst thus produced, the carbon fibers are twisted and grow in a state where they are intertwined with each other. In general, it is known that conductivity can be imparted to an insulating resin by dispersing carbon nanotubes in a resin, but the entangled aggregates of carbon fibers obtained in this way are dispersed in the resin. Unfortunately, as a result, it is often necessary to mix a large amount of carbon fiber in order to obtain the desired conductivity. Further, when a large amount of entangled aggregates of carbon fibers having poor dispersibility is mixed in the resin, there is a problem that the strength of the resin is deteriorated.
また、このように強固に凝集した炭素繊維の分散性を改良するために、粉砕等の後処理によって微細化を行う方法が提案されている(特許文献2)。しかしながら、粉砕処理はコスト増加及び炭素繊維の切断等を招く可能性がある。 Moreover, in order to improve the dispersibility of the carbon fibers that have been tightly aggregated in this way, a method of miniaturization by post-treatment such as pulverization has been proposed (Patent Document 2). However, the pulverization treatment may lead to an increase in cost and cutting of carbon fibers.
これに対して、炭素繊維が1本1本独立しているか、或いは複数本が寄り集まって束状に集合したものであれば、樹脂への分散性が良く、少ない分散量で導電性に優れた樹脂成形体を供給することができると紹介されている(特許文献3)。 On the other hand, if the carbon fibers are independent one by one or if a plurality of carbon fibers are gathered together to form a bundle, the dispersibility in the resin is good, and the conductivity is excellent with a small amount of dispersion. It has been introduced that a molded resin product can be supplied (Patent Document 3).
一方で、気相成長法により束状に集合した炭素繊維を製造する従来の方法としては、基盤法による方法が知られている。即ち、基盤の表面に触媒をスパッタ等で添着し、この基盤面から炭素繊維を直線状に成長させるという方法である。このような基盤法により、長さが2.5mmで1ないし2層の炭素繊維のチューブ壁を形成した、カーボンナノチューブを製造した実施例が開示されている(非特許文献1)。同様にシリコンもしくは石英基盤に触媒成分をパターン化添着して行う実施例も開示されている(特許文献4)。しかし、これらの方法では、成長点となる触媒の面積が絶対的に少なく、そこを基盤として成長するカーボンナノチューブの量も少ないことから産業的な量産には不向きである。 On the other hand, as a conventional method for producing carbon fibers assembled in a bundle by a vapor phase growth method, a method based on a base method is known. That is, a catalyst is attached to the surface of the substrate by sputtering or the like, and carbon fibers are grown linearly from this substrate surface. An example in which a carbon nanotube is manufactured by forming a tube wall of one or two layers of carbon fibers having a length of 2.5 mm by such a base method is disclosed (Non-patent Document 1). Similarly, an embodiment in which a catalyst component is patterned and applied to a silicon or quartz substrate is also disclosed (Patent Document 4). However, these methods are unsuitable for industrial mass production because the area of the catalyst that serves as a growth point is absolutely small and the amount of carbon nanotubes that grow on this basis is also small.
これに対して、Co、Ni及びFeより選ばれる1種以上の金属を含む金属化合物と、Al及びMgより選ばれる1種以上の金属を含む金属化合物を、分解温度が300℃以下の有機化合物の存在下で焼成することで、表面に平面を有する金属含有材料から成る粉体を得る方法が提案されている。しかしながら、この方法では、多量の有機化合物を使用するため触媒焼成の際に高温になりやすく、焼結が進行してしまい、その結果、カーボンナノチューブの析出効率が低く、生成したカーボンナノチューブ中に触媒由来の不純物が多量に残留し、カーボンナノチューブの生産性が著しく低くなってしまうという問題があった。さらに、有機化合物が触媒焼成の際に灰分として残りやすいため、カーボンナノチューブ中に不純物として灰分が混入しやすいという問題があった(特許文献5)。 On the other hand, a metal compound containing one or more metals selected from Co, Ni, and Fe and a metal compound containing one or more metals selected from Al and Mg are organic compounds having a decomposition temperature of 300 ° C. or lower. There has been proposed a method of obtaining a powder made of a metal-containing material having a flat surface by firing in the presence of. However, in this method, since a large amount of organic compound is used, the catalyst is likely to be heated at a high temperature and sintering proceeds. As a result, the deposition efficiency of carbon nanotubes is low, and the catalyst is contained in the generated carbon nanotubes. There has been a problem that a large amount of impurities derived from the material remains, and the productivity of carbon nanotubes is significantly reduced. Furthermore, since an organic compound tends to remain as ash during catalyst firing, there is a problem that ash is easily mixed as an impurity in the carbon nanotube (Patent Document 5).
本発明が解決しようとする課題は、上記諸問題を解決できる、樹脂への分散が容易で、樹脂中での高い導電性を示すカーボンナノチューブと、それを製造するためのカーボンナノチューブ合成用触媒およびその製造方法を提供することである。 The problem to be solved by the present invention is to solve the above-mentioned problems, easily disperse in a resin, exhibit high conductivity in the resin, a carbon nanotube synthesis catalyst for producing the carbon nanotube, and The manufacturing method is provided.
本発明者らは、上記課題を解決すべく、鋭意検討の結果、本発明を完成するに至った。すなわち本発明の実施態様は、水酸化コバルトを含むカーボンナノチューブ合成用触媒前駆体を焼成することを特徴とするカーボンナノチューブ合成用触媒の製造方法に関する。 As a result of intensive studies to solve the above problems, the present inventors have completed the present invention. That is, an embodiment of the present invention relates to a method for producing a carbon nanotube synthesis catalyst, comprising calcining a carbon nanotube synthesis catalyst precursor containing cobalt hydroxide.
また、本発明の実施態様は、カーボンナノチューブ合成用触媒前駆体中の水酸化コバルトの含有率が、40モル%以上であることを特徴とする前記カーボンナノチューブ合成用触媒の製造方法に関する。 An embodiment of the present invention also relates to a method for producing a catalyst for carbon nanotube synthesis, wherein the content of cobalt hydroxide in the catalyst precursor for carbon nanotube synthesis is 40 mol% or more.
また、本発明の実施態様は、カーボンナノチューブ合成用触媒前駆体が、さらにマンガン化合物を含むことを特徴とする前記カーボンナノチューブ合成用触媒の製造方法に関する。 An embodiment of the present invention also relates to a method for producing a catalyst for carbon nanotube synthesis, wherein the catalyst precursor for carbon nanotube synthesis further contains a manganese compound.
また、本発明の実施態様は、下記の工程(1)および(2)を順次行うことを特徴とする前記カーボンナノチューブ合成用触媒の製造方法に関する。
(1)水酸化コバルトと、担持成分としてのマグネシウムおよびアルミニウムからなる群より選ばれる少なくとも1種の元素を含む金属塩(B)とを混合し、カーボンナノチューブ合成用触媒前駆体を得る工程。
(2)カーボンナノチューブ触媒前駆体を、焼成してカーボンナノチューブ合成用触媒を得る工程。
An embodiment of the present invention also relates to a method for producing the carbon nanotube synthesis catalyst, wherein the following steps (1) and (2) are sequentially performed.
(1) A step of mixing cobalt hydroxide and a metal salt (B) containing at least one element selected from the group consisting of magnesium and aluminum as a supporting component to obtain a catalyst precursor for carbon nanotube synthesis.
(2) A step of firing a carbon nanotube catalyst precursor to obtain a carbon nanotube synthesis catalyst.
また、本発明の実施態様は、前記方法により得られてなるカーボンナノチューブ合成用触媒に関する。 An embodiment of the present invention also relates to a carbon nanotube synthesis catalyst obtained by the above method.
また、本発明の実施態様は、前記触媒の表面が、0.2〜10μm2の平面面積を有することを特徴とする前記カーボンナノチューブ合成用触媒に関する。 An embodiment of the present invention also relates to the above-mentioned catalyst for carbon nanotube synthesis, wherein the surface of the catalyst has a planar area of 0.2 to 10 μm 2 .
また、本発明の実施態様は、平均粒径が5〜10nmの範囲であることを特徴とする前記カーボンナノチューブ合成用触媒に関する。 An embodiment of the present invention also relates to the carbon nanotube synthesis catalyst, wherein the average particle size is in the range of 5 to 10 nm.
また、本発明の実施態様は、カーボンナノチューブ合成用触媒中において、活性成分として、少なくともコバルトを含有し、かつ鉄、コバルトおよびニッケルからなる群より選ばれる少なくとも1種の元素と、担持成分として、マグネシウムおよびアルミニウムからなる群より選ばれる少なくとも1種の元素との合計100モル%に対する、活性成分の含有割合が、40〜80モル%であることを特徴とする前記カーボンナノチューブ合成用触媒に関する。 In addition, in the catalyst for carbon nanotube synthesis, the embodiment of the present invention contains at least one element selected from the group consisting of iron, cobalt, and nickel as an active component, and as a supporting component. The present invention relates to the above-mentioned catalyst for synthesizing carbon nanotubes, wherein the active ingredient content is 40 to 80 mol% with respect to 100 mol% in total with at least one element selected from the group consisting of magnesium and aluminum.
また、本発明の実施態様は、前記カーボンナノチューブ合成用触媒と、炭化水素および/またはアルコールを含んでなる炭素源とを接触反応させることを特徴とするカーボンナノチューブの製造方法に関する。 An embodiment of the present invention also relates to a method for producing carbon nanotubes, wherein the catalyst for carbon nanotube synthesis and a carbon source containing a hydrocarbon and / or alcohol are contacted and reacted.
また、本発明の実施態様は、前記方法により得られてなるカーボンナノチューブに関する。 An embodiment of the present invention also relates to a carbon nanotube obtained by the above method.
また、本発明の実施態様は、前記カーボンナノチューブと、樹脂とを含有してなるカーボンナノチューブ分散体に関する。 An embodiment of the present invention also relates to a carbon nanotube dispersion comprising the carbon nanotube and a resin.
本発明のカーボンナノチューブ合成用触媒を用いることにより、樹脂への分散性及び導電性に優れたカーボンナノチューブを効率的に製造することができるようになった。よって、少ない配合量で、樹脂成形体における導電性発現性にも優れ、従って、樹脂の成型性や樹脂成形体の機械的特性を損なうことなく、優れた導電性樹脂成形体を実現することができる。この導電性樹脂成形体は、帯電防止用電子部材、静電塗装用樹脂成形体、導電性透明樹脂組成物等への応用が可能である。また、本発明のカーボンナノチューブは成形体以外にも、シート、テープ、透明フィルム、インキ、導電塗料などの樹脂組成物へ適用することができる。 By using the carbon nanotube synthesis catalyst of the present invention, it has become possible to efficiently produce carbon nanotubes excellent in dispersibility in resin and conductivity. Therefore, it is possible to realize an excellent conductive resin molded body without impairing the moldability of the resin and the mechanical properties of the resin molded body with a small blending amount, and thus excellent in the electrical conductivity in the resin molded body. it can. This conductive resin molding can be applied to an electronic member for antistatic, a resin molding for electrostatic coating, a conductive transparent resin composition, and the like. Moreover, the carbon nanotubes of the present invention can be applied to resin compositions such as sheets, tapes, transparent films, inks and conductive paints in addition to molded articles.
以下に本発明の実施の態様を詳細に説明する。 Hereinafter, embodiments of the present invention will be described in detail.
(カーボンナノチューブ合成用触媒とその製造方法)
まず、本発明のカーボンナノチューブ合成用触媒とその前駆体について説明する。
(Carbon nanotube synthesis catalyst and its production method)
First, the carbon nanotube synthesis catalyst and its precursor of the present invention will be described.
本発明の触媒は、水酸化コバルトを含むカーボンナノチューブ合成用触媒前駆体を焼成して得ることができる。本明細書でいうカーボンナノチューブ合成用触媒前駆体とは、水酸化コバルトを主成分として含有する金属、金属酸化物、金属窒化物、金属ハロゲン化物、金属水酸化物、金属塩、およびそれらの混合物であり、焼成によってカーボンナノチューブ合成用触媒として機能するものであれば、特に限定されない。 The catalyst of the present invention can be obtained by calcining a carbon nanotube synthesis catalyst precursor containing cobalt hydroxide. The catalyst precursor for carbon nanotube synthesis referred to in this specification means a metal, metal oxide, metal nitride, metal halide, metal hydroxide, metal salt, and a mixture thereof containing cobalt hydroxide as a main component. If it functions as a catalyst for carbon nanotube synthesis by firing, it is not particularly limited.
カーボンナノチューブ合成用触媒前駆体の一成分である水酸化コバルトは、2、3または4価コバルトの水酸化物と複合水酸化物が知られており、焼成によってカーボンナノチューブ合成用触媒の活性成分として機能する。具体的には、水酸化コバルト(II)、水酸化コバルト(IV)コバルト(II)、水酸化コバルト(III)、炭酸コバルト(II)(塩基性)(2CoCO3・3Co(OH)2)等が挙げられるが、これに限定されない。 Cobalt hydroxide, which is a component of a catalyst precursor for carbon nanotube synthesis, is known to be a hydroxide, a composite hydroxide, or a compound of 2, 3 or 4 valent cobalt. Function. Specifically, cobalt hydroxide (II), cobalt hydroxide (IV) cobalt (II), cobalt hydroxide (III), cobalt carbonate (II) (basic) (2CoCO 3 .3Co (OH) 2 ), etc. However, it is not limited to this.
上記水酸化コバルトの内、水酸化コバルト(II)が好ましい。その理由として、焼成によってカーボンナノチューブ合成用触媒とした際に、表面が平面構造を有する触媒が得られやすく、そのような触媒を用いて製造されるカーボンナノチューブは、樹脂等への分散性や導電性が良好な束状のカーボンナノチューブが得られやすいことが挙げられる。 Of the above cobalt hydroxide, cobalt (II) hydroxide is preferred. The reason is that when a catalyst for carbon nanotube synthesis is obtained by firing, a catalyst having a planar structure on the surface is easily obtained, and carbon nanotubes produced using such a catalyst have dispersibility in resins and conductive properties. It is easy to obtain a bundle of carbon nanotubes with good properties.
カーボンナノチューブ合成用触媒前駆体中の水酸化コバルトの含有率は、50質量%以上であることが好ましい。その理由として、表面が平面構造を有する触媒が得られやすく、また、触媒表面の平面構造の占める割合が大きくなることが挙げられる。 The content of cobalt hydroxide in the carbon nanotube synthesis catalyst precursor is preferably 50% by mass or more. The reason for this is that a catalyst having a planar structure on the surface is easily obtained, and the proportion of the planar structure on the catalyst surface is increased.
本発明の態様の一つとして、水酸化コバルトの他に、さらに、マンガン化合物を含むカーボンナノチューブ合成用触媒前駆体を焼成してカーボンナノチューブ合成用触媒を製造することが好ましい。マンガン化合物としては、金属マンガンおよびその酸化物、ハロゲン化物、塩ならびにそれらの水和物および混合物が挙げられ、具体的には、金属マンガン、酢酸マンガン、炭酸マンガン、硝酸マンガン、二酸化マンガン等が挙げられる。 As one aspect of the present invention, it is preferable to produce a carbon nanotube synthesis catalyst by calcining a carbon nanotube synthesis catalyst precursor containing a manganese compound in addition to cobalt hydroxide. Examples of the manganese compound include manganese metal and its oxides, halides, salts, and hydrates and mixtures thereof. Specific examples include manganese metal, manganese acetate, manganese carbonate, manganese nitrate, and manganese dioxide. It is done.
また、本発明の態様の一つとして、触媒の担持成分として、マグネシウムおよび/または、アルミニウムおよび/または、タングステンおよび/または、ケイ素の酸化物を含んでも良い。これら担持成分の前駆体としては、マグネシウムおよびアルミニウム、タングステン、ケイ素の少なくともいずれか1つ以上の金属元素を含む金属塩(B)が挙げられ、具体的には、酢酸マグネシウム、水酸化マグネシウム、水酸化アルミニウム、タングステン酸コバルト(II)、ケイ酸ナトリウム等が挙げられる。 Further, as one aspect of the present invention, magnesium and / or aluminum and / or tungsten and / or silicon oxide may be included as a catalyst supporting component. Examples of precursors of these supported components include metal salts (B) containing at least one metal element of magnesium and aluminum, tungsten, and silicon. Specifically, magnesium acetate, magnesium hydroxide, water Examples include aluminum oxide, cobalt (II) tungstate, and sodium silicate.
本発明のカーボンナノチューブ合成用触媒は、表面に平面を有するものが好ましい。その平面の平坦さの程度は、本発明のカーボンナノチューブが得られる程度であれば任意である。尚、ここでいう「平面」とは、数学における厳密な平面のことではなく、巨視的な視点で見た時の、平面が平らな状態を有する面のことを指す。 The carbon nanotube synthesis catalyst of the present invention preferably has a flat surface. The flatness of the plane is arbitrary as long as the carbon nanotube of the present invention is obtained. The “plane” here is not a strict plane in mathematics, but a plane having a flat plane when viewed from a macroscopic viewpoint.
触媒のXY平面面積(平面方向、「表面面積」ともいう)は、0.2〜10μm2であることが好ましく、Z軸(厚み方向)は100nm以下であることが好ましい。上記範囲内であれば、触媒が平面となり、かつ効率的に原料が触媒に接触できるため、束状カーボンナノチューブの生産効率が向上するため好ましい。 The XY plane area (planar direction, also referred to as “surface area”) of the catalyst is preferably 0.2 to 10 μm 2 , and the Z axis (thickness direction) is preferably 100 nm or less. If it is in the said range, since a catalyst becomes a plane and a raw material can contact a catalyst efficiently, since the production efficiency of a bundle-like carbon nanotube improves, it is preferable.
また、カーボンナノチューブ合成用触媒は、平均粒径が5〜10nmの範囲であることが好ましい。平均粒径が10nmより小さいと、アモルファス成分が少なくなり、良好な分散性を有するカーボンナノチューブが得られ易いため好ましい。また、平均粒径が5nmより大きいと、容易にシンタリングが起きにくくなり、触媒の機能が低下しづらくなるため好ましい。 The carbon nanotube synthesis catalyst preferably has an average particle diameter in the range of 5 to 10 nm. An average particle size of less than 10 nm is preferred because the amorphous component is reduced and carbon nanotubes having good dispersibility are easily obtained. Further, it is preferable that the average particle diameter is larger than 5 nm because sintering is not easily caused and the function of the catalyst is hardly lowered.
ここで、本明細書でいうカーボンナノチューブ合成用触媒の平均粒径は、走査透過電子顕微鏡測定によるもので、任意に選択した約100個の一次粒子について、その径の長さを計測し、その数平均値より平均粒径(μm)を求めたものである。 Here, the average particle diameter of the carbon nanotube synthesis catalyst referred to in the present specification is measured by scanning transmission electron microscope, and the length of the diameter of about 100 primary particles arbitrarily selected is measured. The average particle diameter (μm) is obtained from the number average value.
カーボンナノチューブ合成用触媒中の活性成分の元素としては、鉄、コバルトおよびニッケルからなる群より選ばれる少なくとも1種の元素が挙げられるが、本発明においては、これら活性成分の内、コバルトは必須成分である。また、カーボンナノチューブ合成用触媒中の担持成分の元素としては、マグネシウム、アルミニウム、タングステンおよびケイ素からなる群より選ばれる少なくとも1種の元素が挙げられる。本発明の実施態様の一つとして、上記活性成分と担持成分との合計100モル%に対する活性成分の含有割合(以下、この割合を単に「活性成分含有率」と称す)は、40〜80モル%であることが好ましく、50〜80モル%であることがより好ましく、50〜60モル%であることがさらに好ましい。 The active component element in the carbon nanotube synthesis catalyst includes at least one element selected from the group consisting of iron, cobalt, and nickel. In the present invention, cobalt is an essential component. It is. Examples of the element of the supported component in the carbon nanotube synthesis catalyst include at least one element selected from the group consisting of magnesium, aluminum, tungsten, and silicon. As one embodiment of the present invention, the content ratio of the active ingredient to the total of 100 mol% of the active ingredient and the supporting component (hereinafter, this ratio is simply referred to as “active ingredient content”) is 40 to 80 mol. %, More preferably 50 to 80 mol%, still more preferably 50 to 60 mol%.
触媒中の活性成分含有率が80%モルより小さいと、触媒活性が高く、カーボンナノチューブの生産効率が高くなり、活性成分含有率が40%より大きいと、活性成分の割合が大きくなるため、生産効率が向上するため好ましい。 If the active component content in the catalyst is less than 80% mol, the catalytic activity is high and the production efficiency of carbon nanotubes is high, and if the active component content is greater than 40%, the proportion of the active component is increased. It is preferable because efficiency is improved.
水酸化コバルトの他に、さらに、マンガン化合物を含むカーボンナノチューブ合成用触媒前駆体を焼成して得られるカーボンナノチューブ合成用触媒の場合、前記活性成分と前記担持成分との合計100モル部に対して、マンガン元素が好ましくは2〜30モル部、より好ましくは2〜10モル部含まれていることが好ましい。マンガン金属元素を含む化合物の含有割合が30モル部より小さいほうが、カーボンナノチューブ製造の際に成長阻害物質になりにくく、またマンガン金属元素を含む化合物の含有割合が2モル部より大きいほうが、活性成分金属の粒子をより小さく制御しやすいため好ましい。 In addition to cobalt hydroxide, in the case of a carbon nanotube synthesis catalyst obtained by calcining a carbon nanotube synthesis catalyst precursor containing a manganese compound, the total amount of the active component and the supported component is 100 mol parts. The manganese element is preferably contained in an amount of 2 to 30 mol parts, more preferably 2 to 10 mol parts. When the content ratio of the compound containing manganese metal element is smaller than 30 mole parts, it is less likely to become a growth inhibiting substance during the production of carbon nanotubes, and the content ratio of the compound containing manganese metal element is larger than 2 mole parts as the active ingredient The metal particles are preferred because they are smaller and easier to control.
本発明のカーボンナノチューブ製造用触媒は、下記の工程(1)および(2)を順次行い製造することが好ましい。
(1)水酸化コバルトと、担持成分としてのマグネシウム、アルミニウム、タングステン及びケイ素の少なくともいずれか1種以上の元素を含む金属塩(B)とを混合し、カーボンナノチューブ合成用触媒前駆体を得る工程。
(2)カーボンナノチューブ触媒前駆体を、焼成してカーボンナノチューブ合成用触媒を得る工程。
The carbon nanotube production catalyst of the present invention is preferably produced by sequentially performing the following steps (1) and (2).
(1) A step of mixing cobalt hydroxide and a metal salt (B) containing at least one element of magnesium, aluminum, tungsten and silicon as a supporting component to obtain a catalyst precursor for carbon nanotube synthesis .
(2) A step of firing a carbon nanotube catalyst precursor to obtain a carbon nanotube synthesis catalyst.
まず、工程(1)について説明する。工程(1)は、カーボンナノチューブ合成用触媒中の活性成分の前駆体である水酸化コバルトと、前記担持成分の前駆体である金属塩(B)とを混合し、カーボンナノチューブ合成用触媒前駆体を得る工程である。ここで、活性成分の前駆体としては、水酸化コバルト以外に、鉄、コバルトおよびニッケルからなる群より選ばれる少なくとも1種の元素を含有する金属、金属酸化物、金属窒化物、金属ハロゲン化物、金属水酸化物、金属塩、およびそれらの混合物を含んでいてもよい。一方、担持成分の前駆体としては、上記のとおり、マグネシウムおよびアルミニウムの少なくともいずれか1つ以上の金属元素を含む金属塩(B)が挙げられる。 First, step (1) will be described. In step (1), cobalt hydroxide, which is a precursor of the active component in the catalyst for carbon nanotube synthesis, and a metal salt (B), which is a precursor of the supported component, are mixed, and a catalyst precursor for carbon nanotube synthesis It is the process of obtaining. Here, as the precursor of the active component, in addition to cobalt hydroxide, a metal, metal oxide, metal nitride, metal halide containing at least one element selected from the group consisting of iron, cobalt and nickel, Metal hydroxides, metal salts, and mixtures thereof may be included. On the other hand, examples of the precursor of the supporting component include a metal salt (B) containing at least one metal element of magnesium and aluminum as described above.
「混合」は、ミキサー等を使用して乾式で行ってもよく、湿式で行っても良い。湿式で混合する場合、上記前駆体を混合した後、水等の溶媒に溶解および/または分散させてもよく、また、予め各々の前駆体を水等の溶媒に溶解させた後に混合してもよい。また、水等の溶媒に溶解させる場合には加熱してもよい。湿式で混合する場合、上記で得られる溶液および/または分散液は、乾燥させることによりカーボンナノチューブ合成用触媒前駆体を得ることができる。乾燥させる際の雰囲気は、空気あるいは、窒素、アルゴン等の不活性ガス下のいずれでもよい。また、乾燥温度は、特に限定されるものではないが、溶媒として水を使用する場合、150〜200℃が好ましく、さらに好ましくは180〜200℃がさらに好ましい。 “Mixing” may be performed dry using a mixer or the like, or may be performed wet. When mixing in a wet manner, the above precursors may be mixed and then dissolved and / or dispersed in a solvent such as water, or may be mixed after each precursor is previously dissolved in a solvent such as water. Good. Moreover, when dissolving in solvents, such as water, you may heat. When mixing in a wet manner, the solution and / or dispersion obtained above can be dried to obtain a catalyst precursor for carbon nanotube synthesis. The atmosphere at the time of drying may be either air or an inert gas such as nitrogen or argon. Moreover, although drying temperature is not specifically limited, When using water as a solvent, 150-200 degreeC is preferable, More preferably, 180-200 degreeC is further more preferable.
上記の如く乾式または湿式により得られるカーボンナノチューブ合成用触媒前駆体は、さらに粉砕機等を用いて粉砕して微細化処理を行なうのが好ましい。微細化処理することにより、適度な空隙を含むことになるため、後述の工程(2)において、触媒前駆体を焼成する際に、粒径を小さく均一に制御できるようになるためである。 The catalyst precursor for synthesizing carbon nanotubes obtained by the dry or wet method as described above is preferably further pulverized by a pulverizer or the like and subjected to a fine treatment. This is because the fine voids contain appropriate voids, so that the particle size can be controlled to be small and uniform when the catalyst precursor is calcined in the step (2) described later.
次に、工程(2)について説明する。工程(2)は、カーボンナノチューブ触媒前駆体を、焼成してカーボンナノチューブ合成用触媒を得る工程である。 Next, process (2) is demonstrated. Step (2) is a step of obtaining a carbon nanotube synthesis catalyst by firing a carbon nanotube catalyst precursor.
触媒前駆体を焼成するとき、焼成する際の雰囲気は、酸素の存在下であれば良いが、空気あるいは、空気と窒素との混合ガスであることが好ましい。また、焼成温度は、450〜550℃の範囲であることが好ましい。焼成温度が450〜550℃の範囲であれば、過度の焼結が起きにくいため一次粒子が大きくなりにくく、また、炭素質不純物が触媒中に残りにくいため好ましい。 When firing the catalyst precursor, the atmosphere during firing may be in the presence of oxygen, but is preferably air or a mixed gas of air and nitrogen. Moreover, it is preferable that a calcination temperature is the range of 450-550 degreeC. If the firing temperature is in the range of 450 to 550 ° C., excessive sintering is unlikely to occur, so primary particles are difficult to increase, and carbonaceous impurities are not likely to remain in the catalyst.
上記で得られた焼成物は、さらに微細化処理を行なうのが好ましい。焼成物を粉砕する場合、カーボンナノチューブ合成用触媒と、炭化水素および/またはアルコールを含んでなる炭素源とを接触させて、カーボンナノチューブを合成する際に、カーボンナノチューブ製造用触媒に炭素源が十分に接触することが出来るため好ましい。 It is preferable that the fired product obtained above is further refined. When the fired product is pulverized, when the carbon nanotube synthesis catalyst is brought into contact with a carbon source containing hydrocarbons and / or alcohol to synthesize the carbon nanotube, the carbon nanotube production catalyst has sufficient carbon source. It is preferable because it can be contacted.
微粉化処理する手段は、特に制限はないが、少量の場合は乳鉢を用いて、一度に多量を処理する場合は、ピンミル、ハンマーミル、パルペライザー、ジェットミル等を用いることができる。 The means for pulverizing treatment is not particularly limited, but a mortar can be used for a small amount, and a pin mill, a hammer mill, a pulverizer, a jet mill or the like can be used for treating a large amount at once.
本発明のカーボンナノチューブ合成用触媒の好ましい平均粒径は、走査透過電子顕微鏡による測定で20nm以下、より好ましくは5〜10nmである。 The average particle diameter of the carbon nanotube synthesis catalyst of the present invention is preferably 20 nm or less, more preferably 5 to 10 nm as measured by a scanning transmission electron microscope.
(カーボンナノチューブとその製造方法)
次に、本発明のカーボンナノチューブ合成用触媒を用いたカーボンナノチューブの製造方法について説明する。
(Carbon nanotube and its manufacturing method)
Next, a method for producing carbon nanotubes using the carbon nanotube synthesis catalyst of the present invention will be described.
本発明のカーボンナノチューブを製造するためには、触媒として前記カーボンナノチューブ合成用触媒を用いて、炭素源としての原料ガスを加熱下、この触媒に接触反応させて、カーボンナノチューブを製造する。 In order to produce the carbon nanotube of the present invention, the carbon nanotube synthesis catalyst is used as a catalyst, and a raw material gas as a carbon source is heated and contacted with the catalyst to produce a carbon nanotube.
炭素源としての原料ガスとしては、従来公知の任意のものを使用でき、例えば、炭素を含むガスとしてメタンやエチレン、プロパン、ブタン、アセチレンなどの炭化水素や、一酸化炭素、アルコールなどを用いることが出来るが、特に使い易さの理由により、炭化水素および/またはアルコールが好ましい。 As the source gas as the carbon source, any conventionally known gas can be used. For example, as the gas containing carbon, hydrocarbons such as methane, ethylene, propane, butane, and acetylene, carbon monoxide, alcohol, and the like are used. However, hydrocarbons and / or alcohols are particularly preferred for ease of use.
また、必要に応じて、還元雰囲気下で触媒を活性化した後、又は還元性ガスと共にカーボンナノチューブ原料ガスと接触させて製造することが好ましい。活性化時における還元性ガスは、水素、アンモニア等を用いることができるが、水素が好ましく、その濃度は、原料ガス濃度100体積%に対して0.1〜100体積%が好ましく、1〜100体積%であることがより好ましい。1〜100体積%の範囲であれば、還元性ガスとしての効果が期待でき、かつ原料ガスのも適切な濃度となり、カーボンナノチューブが効率よく回収できるため好ましい。 If necessary, it is preferable to produce the catalyst after activating the catalyst in a reducing atmosphere or by bringing it into contact with the carbon nanotube raw material gas together with the reducing gas. As the reducing gas at the time of activation, hydrogen, ammonia or the like can be used, but hydrogen is preferable, and its concentration is preferably 0.1 to 100% by volume with respect to 100% by volume of the raw material gas, and 1 to 100%. More preferably, it is volume%. If it is in the range of 1 to 100% by volume, the effect as a reducing gas can be expected, the raw material gas also has an appropriate concentration, and carbon nanotubes can be efficiently recovered, which is preferable.
製造時の温度や原料ガスの供給量は、従来公知の任意の値から、適宜選択し決定すれば良いが、本発明の触媒においては、600〜850℃、特に650〜750℃が好ましく、反応圧力は大気圧以上40kPa以下、特に常圧以上30kPa以下とすることが好ましい。反応時間は反応温度や触媒と原料ガスとの触媒比率に応じて任意に設定されるが、通常0.5〜6時間程度である。本発明での反応速度は反応開始から約20分で最大となり、その後、徐々に失速して反応開始から5〜5.5時間で停止する。従って、反応時間は0.5〜6時間の範囲で管理することが好ましい。 The temperature at the time of production and the supply amount of the raw material gas may be appropriately selected and determined from any conventionally known values. However, in the catalyst of the present invention, 600 to 850 ° C., particularly 650 to 750 ° C. is preferable. The pressure is preferably from atmospheric pressure to 40 kPa, particularly from normal pressure to 30 kPa. Although reaction time is arbitrarily set according to reaction temperature and the catalyst ratio of a catalyst and raw material gas, it is about 0.5 to 6 hours normally. In the present invention, the reaction rate reaches its maximum at about 20 minutes from the start of the reaction, and then gradually slows down and stops at 5 to 5.5 hours from the start of the reaction. Therefore, the reaction time is preferably managed in the range of 0.5 to 6 hours.
反応終了後の原料ガス置換には、アルゴンガスや窒素等の不活性ガスを用いることが好ましい。 It is preferable to use an inert gas such as argon gas or nitrogen for the replacement of the raw material gas after completion of the reaction.
このような本発明のカーボンナノチューブ製造用触媒を用いるカーボンナノチューブの製造方法によれば、担持部分に均一に担持された微粒子の酸化鉄、酸化コバルト、および、酸化ニッケル部分を核として、触媒の平面部分よりカーボンナノチューブが析出、成長し配向性を有したバンドル状カーボンナノチューブが得られる。 According to the carbon nanotube production method using the catalyst for producing carbon nanotubes of the present invention, the planar surface of the catalyst with the iron oxide, cobalt oxide, and nickel oxide portions of the fine particles uniformly supported on the support portions as nuclei. Carbon nanotubes are precipitated and grown from the portion, and bundled carbon nanotubes having orientation are obtained.
以下に実施例を挙げて、本発明をさらに具体的に説明するが、本発明はその要旨を超えない限り、以下の実施例に限定されるものではない。例中、特に断わりのない限り、「部」とは「質量部」、「%」とは「質量%」をそれぞれ意味する。また、「カーボンナノチューブ」を「CNT」と略記することがある。 EXAMPLES The present invention will be described more specifically with reference to the following examples. However, the present invention is not limited to the following examples unless it exceeds the gist. In the examples, “part” means “part by mass” and “%” means “% by mass” unless otherwise specified. Further, “carbon nanotube” may be abbreviated as “CNT”.
なお、以下の実施例および比較例で用いた触媒は、次のように製造した。 The catalysts used in the following examples and comparative examples were produced as follows.
(実施例1)[触媒(a)の製造]
水酸化コバルト(II)75部、酢酸マグネシウム・四水和物172部を耐熱性容器に秤取り、電気オーブンを用いて、雰囲気温度180±5℃の温度で1時間乾燥させた後、80メッシュを通して粒径を整えて、触媒(a)の前駆体を得た。得られた触媒(a)の前駆体50部を耐熱容器に秤取り、マッフル炉にて、空気雰囲気下、450℃±5℃にて30分間焼成した後、乳鉢で粉砕して触媒(a)を得た。
(Example 1) [Production of catalyst (a)]
75 parts of cobalt hydroxide (II) and 172 parts of magnesium acetate tetrahydrate are weighed in a heat-resistant container, dried using an electric oven at an ambient temperature of 180 ± 5 ° C. for 1 hour, and then 80 mesh. Then, the particle size was adjusted to obtain a precursor of the catalyst (a). 50 parts of the catalyst (a) precursor obtained was weighed in a heat-resistant container, calcined in a muffle furnace in an air atmosphere at 450 ° C. ± 5 ° C. for 30 minutes, and then pulverized in a mortar to obtain catalyst (a). Got.
(実施例2)[触媒(b)の製造]
表1に記載した原料と仕込み量に変更した以外は、実施例1と同様にして触媒(b)を得た。
(Example 2) [Production of catalyst (b)]
A catalyst (b) was obtained in the same manner as in Example 1 except that the raw materials and preparation amounts described in Table 1 were changed.
(実施例3)[触媒(c)の製造]
水酸化コバルト(II)75部、酢酸マグネシウム・四水和物172部、酢酸マンガン・四水和物20部を耐熱性容器に秤取り、電気オーブンを用いて、雰囲気温度180±5℃の温度で1時間乾燥させた後、80メッシュを通して粒径を整えて、触媒(c)の前駆体を得た。得られた触媒(c)の前駆体50部を耐熱容器に秤取り、マッフル炉にて、空気雰囲気下、450℃±5℃にて30分間焼成した後、乳鉢で粉砕して触媒(c)を得た。
(Example 3) [Production of catalyst (c)]
75 parts of cobalt hydroxide (II), 172 parts of magnesium acetate tetrahydrate and 20 parts of manganese acetate tetrahydrate are weighed in a heat-resistant container, and the temperature of the atmosphere is 180 ± 5 ° C. using an electric oven. Then, the particle size was adjusted through 80 mesh to obtain a precursor of catalyst (c). 50 parts of the catalyst (c) precursor obtained was weighed in a heat-resistant container, calcined in a muffle furnace in an air atmosphere at 450 ° C. ± 5 ° C. for 30 minutes, and then pulverized in a mortar to obtain catalyst (c). Got.
(比較例1)[触媒(d)の製造]
硝酸コバルト・六水和物175g、硝酸アルミニウム九水和物525g、L−グルタミン酸89gを秤量し、混合して乳鉢で均一になるまですりつぶした。この混合物を耐熱性容器に入れ、マッフル炉にて空気雰囲気下、450℃±5℃にて1.5時間焼成し、触媒(d)を得た。
(Comparative Example 1) [Production of catalyst (d)]
Cobalt nitrate hexahydrate 175 g, aluminum nitrate nonahydrate 525 g, and L-glutamic acid 89 g were weighed, mixed and ground in a mortar until uniform. This mixture was placed in a heat-resistant container and calcined at 450 ° C. ± 5 ° C. for 1.5 hours in an air atmosphere in a muffle furnace to obtain a catalyst (d).
(比較例2)[触媒(e)の製造]
表1に記載した原料と仕込み量に変更した以外は、実施例1と同様にして触媒(e)を得た。
(Comparative Example 2) [Production of catalyst (e)]
A catalyst (e) was obtained in the same manner as in Example 1 except that the raw materials and preparation amounts described in Table 1 were changed.
<カーボンナノチューブの製造>
(実施例4)
加圧可能で、外部ヒーターで加熱可能な、内容積が10リットルの横型反応管の中央部に、カーボンナノチューブ合成用触媒(a)1gを散布した石英ガラス製耐熱皿を設置した。アルゴンガスを注入しながら排気を行い、反応管内の空気をアルゴンガスで置換し、横型反応管中の雰囲気を酸素濃度1体積%以下にした。次いで、外部ヒーターにて、横型反応管内の中心部温度が700℃になるまで加熱した。700℃に到達した後、毎分0.1リットルの流速で1分間、水素ガスを反応管内に導入し、触媒を活性化処理した。その後、炭素源としてエタノールを毎分1リットルの流速で反応管内に導入し、4時間接触反応させた。反応終了後、反応管内のガスをアルゴンガスで置換し、反応管内の温度を100℃以下になるまで冷却し、得られたカーボンナノチューブを採取した。得られたカーボンナノチューブは、導電性、分散性を比較するため、80メッシュの金網で粉砕ろ過した。
<Manufacture of carbon nanotubes>
Example 4
A quartz glass bakeware sprinkled with 1 g of carbon nanotube synthesis catalyst (a) was placed in the center of a horizontal reaction tube that can be pressurized and heated with an external heater and has an internal volume of 10 liters. Exhaust was performed while injecting argon gas, the air in the reaction tube was replaced with argon gas, and the atmosphere in the horizontal reaction tube was reduced to an oxygen concentration of 1% by volume or less. Subsequently, it heated with the external heater until the center part temperature in a horizontal type reaction tube became 700 degreeC. After reaching 700 ° C., hydrogen gas was introduced into the reaction tube at a flow rate of 0.1 liter per minute for 1 minute to activate the catalyst. Thereafter, ethanol as a carbon source was introduced into the reaction tube at a flow rate of 1 liter per minute, and contact reaction was performed for 4 hours. After completion of the reaction, the gas in the reaction tube was replaced with argon gas, the reaction tube was cooled to a temperature of 100 ° C. or less, and the resulting carbon nanotubes were collected. The obtained carbon nanotubes were pulverized and filtered with an 80 mesh wire mesh in order to compare conductivity and dispersibility.
(実施例5〜8および比較例3、4)
表2に記載した触媒と合成条件にそれぞれ変更した以外は、実施例4と同様な方法により、それぞれカーボンナノチューブを得た。
(Examples 5 to 8 and Comparative Examples 3 and 4)
Carbon nanotubes were obtained in the same manner as in Example 4 except that the catalysts and synthesis conditions described in Table 2 were changed.
<物性の測定方法>
カーボンナノチューブ合成用触媒およびカーボンナノチューブの物性は、以下の方法により測定した。
<Method of measuring physical properties>
The properties of the carbon nanotube synthesis catalyst and the carbon nanotubes were measured by the following methods.
<走査型電子顕微鏡による観察と平均粒径>
走査型電子顕微鏡(日本電子(JEOL)社製、JSM−6700M))によって、カーボンナノチューブ合成用触媒またはカーボンナノチューブの形態観察を実施した。観察は、カーボンナノチューブ合成用触媒またはカーボンナノチューブをカーボンペーパー上にそのままの状態で散布して実施した。100個のカーボンナノチューブ合成用触媒またはカーボンナノチューブ100個の短軸と長軸の径の長さを計測し、その数平均値をもってカーボンナノチューブ合成用触媒またはカーボンナノチューブの平均径(nm)とした。また束状のカーボンナノチューブについては、100本の束中のカーボンナノチューブの本数、束の長さを計測し、その数平均値をもってカーボンナノチューブの束中の平均本数(本)、束の長さ(μm)とした。
<Observation by scanning electron microscope and average particle size>
Using a scanning electron microscope (manufactured by JEOL (JEOL), JSM-6700M), the carbon nanotube synthesis catalyst or the morphology of the carbon nanotubes was observed. The observation was carried out by spraying the carbon nanotube synthesis catalyst or the carbon nanotubes as they were on the carbon paper. The lengths of the diameters of the short axis and the long axis of 100 carbon nanotube synthesis catalysts or 100 carbon nanotubes were measured, and the number average value thereof was taken as the average diameter (nm) of the carbon nanotube synthesis catalyst or carbon nanotubes. For the bundled carbon nanotubes, the number of carbon nanotubes in 100 bundles and the length of the bundles are measured, and the average number (number) in the bundle of carbon nanotubes, the length of the bundle ( μm).
さらに、カーボンナノチューブ合成用触媒について、走査型電子顕微鏡(株式会社エリオニクス社製ERA―9000)による三次元解析を行い、10個のカーボンナノチューブ合成用触媒について、平板状の平面の横軸に対してX軸、Y軸、高さ方向に対してY軸を測定し、その平均値をそれぞれX軸平均(μm)、Y軸平均(μm)、Z軸平均(μm)を求めた。またX軸平均(μm)、Y軸平均(μm)の面積を、XY平面面積(μm)として求めた。 Further, the carbon nanotube synthesis catalyst was subjected to a three-dimensional analysis using a scanning electron microscope (ERA-9000, manufactured by Elionix Co., Ltd.), and 10 carbon nanotube synthesis catalysts were plotted against the horizontal axis of the flat plate. The Y axis was measured with respect to the X axis, the Y axis, and the height direction, and the average values were obtained as the X axis average (μm), the Y axis average (μm), and the Z axis average (μm), respectively. Moreover, the area of X-axis average (micrometer) and Y-axis average (micrometer) was calculated | required as XY plane area (micrometer).
表3に触媒の形状、X軸平均(μm)、Y軸平均(μm)、Z軸平均(μm)、XY平面面積(μm)を示す。 Table 3 shows the shape of the catalyst, the X-axis average (μm), the Y-axis average (μm), the Z-axis average (μm), and the XY plane area (μm).
表3より、実施例1〜3の水酸化コバルトより作製した触媒(a)〜(c)は表面に平面を有することが明らかとなった。比較例1の従来方法により作製した触媒(d)は表面に平面を有するが、XY平面面積が大きいことが明らかとなった。また、比較例2の従来方法により作製した触媒(e)は、球状の微細な不定形かたまり構造を有することが明らかとなった。 From Table 3, it became clear that the catalyst (a)-(c) produced from the cobalt hydroxide of Examples 1-3 has a flat surface. Although the catalyst (d) produced by the conventional method of Comparative Example 1 has a flat surface, it was revealed that the XY plane area was large. Moreover, it became clear that the catalyst (e) produced by the conventional method of Comparative Example 2 has a spherical fine amorphous block structure.
(生産効率)
カーボンナノチューブは、合成時に使用した触媒と混合した形で得られるため、触媒効率の指標として、生産効率によって比較した。生産効率は、式(1)によって算出した。
生産効率=(合成で得られたカーボンナノチューブ重量−仕込み触媒重量)÷(仕込み触媒量)・・・・・・式(1)
(Production efficiency)
Since carbon nanotubes are obtained in a mixed form with the catalyst used at the time of synthesis, they were compared by production efficiency as an index of catalyst efficiency. The production efficiency was calculated by equation (1).
Production efficiency = (weight of carbon nanotube obtained by synthesis-weight of charged catalyst) ÷ (amount of charged catalyst) ··· Formula (1)
<体積抵抗率>
粉体抵抗率測定装置((株)三菱化学アナリテック社製:ロレスターGP粉体低効率測定システムMCP−PD−51)を用い、試料重量1.2gとし、粉体用プローブユニット(四探針・リング電極、電極間隔5.0mm、電極半径1.0mm、試料半径12.5mm)により、印加電圧リミッタを90Vとして、種々加圧下のカーボンナノチューブの体積抵抗率を測定した。密度1.0g/mLにおける値をカーボンナノチューブの体積抵抗率(Ω・cm)とした。
<Volume resistivity>
Using a powder resistivity measuring device (manufactured by Mitsubishi Chemical Analytech Co., Ltd .: Lorester GP powder low-efficiency measurement system MCP-PD-51), the sample weight is 1.2 g, and a probe unit for powder (four probes) The volume resistivity of the carbon nanotubes under various pressures was measured using a ring electrode, an electrode interval of 5.0 mm, an electrode radius of 1.0 mm, and a sample radius of 12.5 mm, with an applied voltage limiter of 90V. The value at a density of 1.0 g / mL was defined as the volume resistivity (Ω · cm) of the carbon nanotube.
<カーボンナノチューブ含有塗膜の表面抵抗とカーボンナノチューブの導電性評価>
カーボンナノチューブの導電性を評価するために、カーボンナノチューブを分散した塗膜を作成し、その表面抵抗を測定することにより導電性評価を行った。
三菱化学社製エポキシ樹脂グレード1256を、ブチルカルビトールアセテートに溶解して、固形分40%のエポキシ樹脂溶液を作製し、エポキシ樹脂溶液の固形分15gに対して、評価用のカーボンナノチューブ0.789gを混合し、フーバーマーラーで150lb、100回転の条件でそれぞれ1〜3回練り、評価用のカーボンナノチューブ分散体を得た。その後、東洋紡績社製PETフィルムに、アプリケーターを用いて、乾燥後の塗膜厚さが10±1μmとなるように塗工後、電気オーブン中で150±5℃にて60分間乾燥させて、カーボンナノチューブを含有する塗膜を得た。(株)三菱化学アナリテック社製:ロレスターGP粉体低効率測定システムMCP−PD−51を用いて、上記塗膜の表面抵抗(W/□)を測定した。
<Surface resistance of carbon nanotube-containing coating film and conductivity evaluation of carbon nanotube>
In order to evaluate the conductivity of the carbon nanotube, a coating film in which the carbon nanotube was dispersed was prepared, and the conductivity was evaluated by measuring the surface resistance.
An epoxy resin grade 1256 manufactured by Mitsubishi Chemical Corporation is dissolved in butyl carbitol acetate to prepare an epoxy resin solution having a solid content of 40%, and 0.789 g of carbon nanotubes for evaluation with respect to a solid content of 15 g of the epoxy resin solution. Were mixed and kneaded 1 to 3 times at 150 lb and 100 revolutions with a Hoover Muller to obtain a carbon nanotube dispersion for evaluation. Then, on the PET film manufactured by Toyobo Co., Ltd., using an applicator, after coating so that the coating thickness after drying is 10 ± 1 μm, it is dried in an electric oven at 150 ± 5 ° C. for 60 minutes, A coating film containing carbon nanotubes was obtained. (Mitsubishi Chemical Analytech Co., Ltd.) The surface resistance (W / □) of the coating film was measured using a Lorester GP powder low-efficiency measurement system MCP-PD-51.
カーボンナノチューブの導電性の評価基準は、上記3回練りの塗膜の表面抵抗が、101(W/□)以下の場合を○(良)、101(W/□)を超える場合を×(不良)とした。 The evaluation criteria for the conductivity of carbon nanotubes are: when the surface resistance of the above-mentioned three-time kneaded coating is 10 1 (W / □) or less, ○ (good), 10 1 (W / □) (Defect).
カーボンナノチューブの分散性の評価基準は、式(2)から求めた値で、2以下の場合を〇(良)、2(W/□)を超える場合を×(不良)とした。
分散性=(樹脂分散体積抵抗率3回練り(Ω・cm)÷(樹脂分散体積抵抗率1回練り(Ω・cm)・・・・・・式(2)
The evaluation standard of the dispersibility of the carbon nanotube was a value obtained from the formula (2). When the value was 2 or less, ○ (good) and 2 (W / □) were evaluated as x (bad).
Dispersibility = (resin dispersion volume resistivity kneaded 3 times (Ω · cm) ÷ (resin dispersion volume resistivity kneaded once (Ω · cm) ··· formula (2)
表4に、実施例4〜8、比較例3〜4で得られたカーボンナノチューブの形状、平均径(nm)、平均本数(本)、束の長さ(μm)を示す。 Table 4 shows the shape, average diameter (nm), average number (number), and bundle length (μm) of the carbon nanotubes obtained in Examples 4 to 8 and Comparative Examples 3 to 4.
表5に、実施例5〜8、比較例3、4で得られたカーボンナノチューブの評価結果を示す。 Table 5 shows the evaluation results of the carbon nanotubes obtained in Examples 5 to 8 and Comparative Examples 3 and 4.
表3及び表4から、本発明のカーボンナノチューブ合成用触媒は、比較例の触媒よりも、触媒の平均粒径(nm)が小さく、それ故、カーボンナノチューブの平均径(nm)が小さい束状構造を有するカーボンナノチューブが得られることが明らかとなった。 From Tables 3 and 4, the carbon nanotube synthesis catalyst of the present invention has a bundle shape in which the average particle diameter (nm) of the catalyst is smaller than that of the catalyst of the comparative example, and therefore the average diameter (nm) of the carbon nanotubes is small. It was revealed that a carbon nanotube having a structure can be obtained.
また、同表より、本発明のカーボンナノチューブ合成用触媒は、特別な微細化処理を施すことなく、比較例の触媒と比較してX軸、Y軸、Z軸が小さく、つまり厚みが小さくコンパクトな平面触媒となっているため、カーボンナノチューブの生産効率が優れていることが明らかとなった。 In addition, from the table, the carbon nanotube synthesis catalyst of the present invention has a smaller X-axis, Y-axis, and Z-axis, that is, a smaller thickness and a smaller size, compared to the catalyst of the comparative example, without any special refinement treatment. It has become clear that the production efficiency of carbon nanotubes is excellent because it is a flat catalyst.
表5より、本発明の束状を形成しているカーボンナノチューブは、比較例のカーボンナノチューブと比較して、優れた体積抵抗率を有していることが明らかとなった。また、本発明の束状を形成しているカーボンナノチューブを含有する樹脂は、比較例の従来製法で作製した束状構造または球状構造を有するカーボンナノチューブを含有する樹脂と比較して、高い導電性を有することが明らかとなった。 From Table 5, it was revealed that the carbon nanotubes forming the bundle of the present invention have an excellent volume resistivity as compared with the carbon nanotubes of the comparative examples. In addition, the resin containing carbon nanotubes forming the bundle of the present invention has higher conductivity than the resin containing carbon nanotubes having a bundle structure or a spherical structure prepared by the conventional manufacturing method of the comparative example. It became clear to have.
表5より、本発明の束状を形成しているカーボンナノチューブを含有する樹脂は、比較例の従来製法で作製した束状構造または球状構造を有するカーボンナノチューブを含有する樹脂と比較して、試行回数(練り回数)の少ない状態からそのカーボンナノチューブの性能を引き出した導電性を有しており、高い分散性を有することが明らかとなった。 From Table 5, the resin containing the carbon nanotubes forming the bundle of the present invention was compared with the resin containing the carbon nanotubes having a bundle structure or a spherical structure prepared by the conventional manufacturing method of the comparative example. It has been revealed that the carbon nanotube has the conductivity that draws out the performance of the carbon nanotube from the state where the number of times (the number of times of kneading) is small, and has high dispersibility.
従来の束状を形成しているカーボンナノチューブは、樹脂にカーボンナノチューブを分散させた場合、カーボンナノチューブの平均径(nm)が大きいため、低添加の場合、分散体の導電性の要因となるカーボンナノチューブマトリックスが作りにくい。しかし、本発明のバンドル状を形成しているカーボンナノチューブは、平均径(nm)が小さいため、易分散で導電性が発揮できることが可能になったと推測される。 Conventional carbon nanotubes forming a bundle shape have a large average diameter (nm) of carbon nanotubes when carbon nanotubes are dispersed in a resin. Nanotube matrix is difficult to make. However, since the carbon nanotubes forming the bundle shape of the present invention have a small average diameter (nm), it is presumed that the conductivity can be exhibited with easy dispersion.
すなわち、本発明の製造方法により得られるカーボンナノチューブ合成用触媒を用いることにより、分散性に優れ、高い導電性を有する材料を提供できるカーボンナノチューブを効率的に製造できることが明らかとなった。 That is, it has been clarified that by using the carbon nanotube synthesis catalyst obtained by the production method of the present invention, it is possible to efficiently produce carbon nanotubes that can provide a material having excellent dispersibility and high conductivity.
以上、本発明を特定の態様に沿って説明したが、当業者に自明の変形や改良は本発明の範囲に含まれる。 As mentioned above, although this invention was demonstrated along the specific aspect, the deformation | transformation and improvement obvious to those skilled in the art are included in the scope of the present invention.
Claims (11)
(1)水酸化コバルトと、担持成分としてのマグネシウムおよびアルミニウムからなる群より選ばれる少なくとも1種の元素を含む金属塩(B)とを混合し、カーボンナノチューブ合成用触媒前駆体を得る工程。
(2)カーボンナノチューブ触媒前駆体を、焼成してカーボンナノチューブ合成用触媒を得る工程。 The method for producing a carbon nanotube synthesis catalyst according to any one of claims 1 to 3, wherein the following steps (1) and (2) are sequentially performed.
(1) A step of mixing cobalt hydroxide and a metal salt (B) containing at least one element selected from the group consisting of magnesium and aluminum as a supporting component to obtain a catalyst precursor for carbon nanotube synthesis.
(2) A step of firing a carbon nanotube catalyst precursor to obtain a carbon nanotube synthesis catalyst.
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