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JPH10194703A - Catalyst for producing synthesis gas and production of synthesis gas - Google Patents

Catalyst for producing synthesis gas and production of synthesis gas

Info

Publication number
JPH10194703A
JPH10194703A JP9001895A JP189597A JPH10194703A JP H10194703 A JPH10194703 A JP H10194703A JP 9001895 A JP9001895 A JP 9001895A JP 189597 A JP189597 A JP 189597A JP H10194703 A JPH10194703 A JP H10194703A
Authority
JP
Japan
Prior art keywords
catalyst
titanium
alkaline earth
synthesis gas
earth metal
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Granted
Application number
JP9001895A
Other languages
Japanese (ja)
Other versions
JP3086867B2 (en
Inventor
Takashi Hayakawa
孝 早川
Katsuomi Takehira
勝臣 竹平
Kunio Suzuki
邦夫 鈴木
Masao Shimizu
政男 清水
Satoshi Hamakawa
聡 浜川
Ryuji Shiozaki
竜二 塩崎
Shu Suzuki
周 鈴木
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
National Institute of Advanced Industrial Science and Technology AIST
Original Assignee
Agency of Industrial Science and Technology
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Agency of Industrial Science and Technology filed Critical Agency of Industrial Science and Technology
Priority to JP09001895A priority Critical patent/JP3086867B2/en
Publication of JPH10194703A publication Critical patent/JPH10194703A/en
Application granted granted Critical
Publication of JP3086867B2 publication Critical patent/JP3086867B2/en
Anticipated expiration legal-status Critical
Expired - Lifetime legal-status Critical Current

Links

Classifications

    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02PCLIMATE CHANGE MITIGATION TECHNOLOGIES IN THE PRODUCTION OR PROCESSING OF GOODS
    • Y02P20/00Technologies relating to chemical industry
    • Y02P20/50Improvements relating to the production of bulk chemicals
    • Y02P20/52Improvements relating to the production of bulk chemicals using catalysts, e.g. selective catalysts

Landscapes

  • Catalysts (AREA)
  • Hydrogen, Water And Hydrids (AREA)

Abstract

PROBLEM TO BE SOLVED: To obtain a catalyst capable of producing a small amount of carbon in a catalyst for producing a synthesis gas according to an oxidizing reaction of a lower hydrocarbon with carbon dioxide as an oxidizing agent and to provide a method for producing the synthesis gas using the catalyst. SOLUTION: A catalyst comprising a compound metallic oxide, containing an alkaline earth metal, titanium and nickel at substantially 1/1 atomic ratio of the alkaline earth metal to the titanium in which the alkaline earth metal and titanium form a perovskite structure is used in a method for producing a synthesis gas according to an oxidizing reaction of a lower saturated hydrocarbon with carbon dioxide. The catalyst for producing the synthesis gas according to the oxidizing reaction of the lower saturated hydrocarbon with the carbon dioxide as the oxidizing agent comprises the compound metallic oxide containing the alkaline earth metal, titanium and nickel at substantially 1/1 atomic ratio of the alkaline earth metal to the titanium in which the alkaline earth metal and the titanium form the perovskite structure.

Description

【発明の詳細な説明】DETAILED DESCRIPTION OF THE INVENTION

【0001】[0001]

【発明の属する技術分野】本発明は、天然ガスの主成分
である低級飽和炭化水素、とりわけメタンを二酸化炭素
で酸化することにより、合成ガス(一酸化炭素と水素の
混合ガス)を製造する方法及びそれに用いる触媒に関す
る。さらに詳しくは、低級飽和炭化水素と炭酸ガスの混
合ガスを高温下、触媒上に流通させて合成ガスを製造す
る際に、触媒上への炭素の析出を抑制して活性を長時間
持続できる方法及びそれに用いる触媒に関するものであ
る。
BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for producing a synthesis gas (mixed gas of carbon monoxide and hydrogen) by oxidizing lower saturated hydrocarbons, particularly methane, which is a main component of natural gas, with carbon dioxide. And a catalyst used therefor. More specifically, when producing a synthesis gas by flowing a mixed gas of lower saturated hydrocarbon and carbon dioxide gas at a high temperature over a catalyst, a method capable of suppressing the deposition of carbon on the catalyst and maintaining the activity for a long time. And a catalyst used therefor.

【0002】[0002]

【従来の技術】反応性に乏しいために工業的な利用が難
しい天然ガスの主成分である低級飽和炭化水素、とりわ
けメタンから、化学的変換によって工業原料を効率よく
製造できる技術の開発は、石油由来製品の原料を天然ガ
スに転換することが可能となるので、極めて重要であ
る。炭酸ガスは、利用価値がないために環境中に排出さ
れ地球温暖化の元凶物質となっているので、これの再利
用技術は地球環境対策として極めて重要な技術となる。
メタンを酸化して化学工業原料に利用可能な化合物に変
換する方法としては、主に次の3つが知られている。 (1)メタンと酸素の混合ガスを温度700℃以上の触
媒上に流通して、酸化カップリング反応によりエタンと
エチレンを製造する方法。この反応の触媒としては、金
属酸化物のいくつかの組み合わせからなる数多くの種類
の触媒が見いだされている(ソコロヴスキーら、Cat
al.Today;14,415(1992))。しか
し、エタンとエチレンの収率を上げることは難しく、こ
れまでに得られているエタンとエチレンの最大収率は2
5%程度であり、実用化の域には達していない。 (2)メタンと酸素の混合ガスからメタノールを製造す
る方法。例えば圧力50Kg/cm2、温度350℃の
反応条件下に混合ガスを流すと、無触媒反応が進行して
収率9%程度でメタノールが得られる(ゲッサーら、A
ppl.Catal.,57,45(1990))。し
かし、この方法は、高温、加圧下で行うために、極めて
危険性が大きいという問題点がある。また常圧の触媒反
応では、メタノール収率はさらに低い。 (3)メタンと酸素、メタンと水蒸気及びメタンと二酸
化炭素の混合ガスから合成ガスを製造する方法。これら
の反応をそれぞれ式で示すと、以下の通りである。 CH4+H2O→CO+3H2 (1) CH4+CO2→2CO+2H2 (2) CH4+1/2O2→CO+2H2 (3) 合成ガスは、アンモニア、メタノールあるいは酢酸の原
料として、さらに石油精製や燃料電池の燃料に用られ
る。また、合成ガスはフィッシャ−トロプシュ法によっ
てガソリンに変換できる。
2. Description of the Related Art The development of a technology for efficiently producing industrial raw materials by chemical conversion from lower saturated hydrocarbons, particularly methane, which is a main component of natural gas which is difficult to use industrially due to poor reactivity, has been developed by petroleum. This is extremely important because it allows the raw material of the derived product to be converted to natural gas. Since carbon dioxide gas has no utility value and is emitted into the environment and is a cause of global warming, its reuse technology is an extremely important technology as a measure against the global environment.
As a method for converting methane to a compound usable as a raw material for chemical industry, the following three methods are mainly known. (1) A method in which a mixed gas of methane and oxygen is passed over a catalyst having a temperature of 700 ° C. or higher to produce ethane and ethylene by an oxidative coupling reaction. Numerous types of catalysts comprising several combinations of metal oxides have been found as catalysts for this reaction (Sokolovsky et al., Cat.
al. Today; 14,415 (1992)). However, it is difficult to increase the yields of ethane and ethylene, and the maximum yields of ethane and ethylene obtained to date are 2
It is about 5%, which has not reached the level of practical use. (2) A method for producing methanol from a mixed gas of methane and oxygen. For example, when a mixed gas is flowed under the reaction conditions of a pressure of 50 kg / cm 2 and a temperature of 350 ° C., a non-catalytic reaction proceeds and methanol is obtained at a yield of about 9% (Gesser et al., A
ppl. Catal. , 57, 45 (1990)). However, this method has a problem that it is extremely dangerous because it is performed under high temperature and pressure. In a catalytic reaction under normal pressure, the methanol yield is even lower. (3) A method for producing a synthesis gas from a mixed gas of methane and oxygen, methane and steam, and methane and carbon dioxide. These reactions are represented by the following formulas. CH 4 + H 2 O → CO + 3H 2 (1) CH 4 + CO 2 → 2CO + 2H 2 (2) CH 4 + 1 / 2O 2 → CO + 2H 2 (3) The synthesis gas is used as a raw material for ammonia, methanol or acetic acid, and is used for petroleum refining and Used for fuel in fuel cells. Syngas can also be converted to gasoline by the Fischer-Tropsch process.

【0003】現在工業的に実施されている合成ガスの製
造法は、主にアルミナ担持ニッケル触媒上で進行する前
記式(1)のスチームリフォーミング反応によってい
る。しかし、この反応を行うためには、多量の水蒸気を
発生させる装置をプラント内に設置しなければならない
ので、プラントが大型になるという問題点がある。これ
に対し前記式(2)の反応は、水蒸気を必要としないの
でプラントが小型化できる利点がある。この反応に触媒
を用いると、反応温度800℃以下でも反応が進行する
ことが知られているが、高価な貴金属が触媒の必須成分
として必要であるという問題点がある(アシュクロフト
ら、NATURE,352,225(1991))。安
価なアルミナ担持ニッケル触媒でも前記式(2)の反応
に有効であるが、触媒上に炭素が析出して活性が低下す
るために、長時間にわたる使用ができないという問題点
がある(アシュクロフトら、NATURE,352,2
25(1991))。
[0003] The method of producing synthesis gas that is currently practiced industrially mainly depends on the steam reforming reaction of the above formula (1), which proceeds on a nickel catalyst supported on alumina. However, in order to carry out this reaction, a device for generating a large amount of water vapor must be installed in the plant, so that there is a problem that the plant becomes large. On the other hand, the reaction of the formula (2) does not require steam, and thus has an advantage that the plant can be downsized. It is known that if a catalyst is used in this reaction, the reaction proceeds even at a reaction temperature of 800 ° C. or lower, but there is a problem that an expensive noble metal is required as an essential component of the catalyst (Ashcroft et al., NATURE, 352 , 225 (1991)). Although an inexpensive nickel-supported alumina catalyst is effective for the reaction of the above formula (2), there is a problem that it cannot be used for a long time because carbon is deposited on the catalyst and the activity is reduced (Ashcroft et al.). , NATURE, 352 , 2
25 (1991)).

【0004】[0004]

【発明が解決しようとする課題】本発明は、低級炭化水
素と二酸化炭素との酸化反応による合成ガスの製造用触
媒において、炭素析出量の少ない触媒を提供するととも
に、それを用いた合成ガスの製造方法を提供することを
その課題とする。
DISCLOSURE OF THE INVENTION The present invention provides a catalyst for producing a synthesis gas by an oxidation reaction of a lower hydrocarbon and carbon dioxide, which provides a catalyst having a small carbon deposition amount and a synthesis gas using the same. It is an object to provide a manufacturing method.

【0005】[0005]

【課題を解決するための手段】本発明者らは、前記課題
を解決すべく鋭意研究を重ねた結果、本発明を完成する
に至った。即ち、本発明によれば、低級炭化水素と二酸
化炭素との酸化反応による合成ガスの製造方法におい
て、アルカリ土類金属とチタンとニッケルを含有し、ア
ルカリ土類金属とチタンとの原子比が実質的に1/1で
あり、且つ該アルカリ土類金属とチタンはペロブスカイ
ト構造を形成している複合金属酸化物からなる触媒を用
いることを特徴とする合成ガスの製造方法が提供され
る。また、本発明によれば、アルカリ土類金属とチタン
とニッケルを含有し、アルカリ土類金属とチタンとの原
子比が実質的に1/1であり、且つ該アルカリ土類金属
とチタンはペロブスカイト構造を形成している複合金属
酸化物からなることを特徴とする低級炭化水素と二酸化
炭素との酸化反応による合成ガスの製造用触媒が提供さ
れる。
Means for Solving the Problems The present inventors have conducted intensive studies to solve the above-mentioned problems, and as a result, have completed the present invention. That is, according to the present invention, in a method for producing a synthesis gas by an oxidation reaction between a lower hydrocarbon and carbon dioxide, an alkaline earth metal, titanium and nickel are contained, and the atomic ratio of the alkaline earth metal to titanium is substantially In particular, the present invention provides a method for producing a synthesis gas, characterized in that a catalyst comprising a composite metal oxide in which the alkaline earth metal and titanium form a perovskite structure is used. Further, according to the present invention, an alkaline earth metal, titanium and nickel are contained, the atomic ratio of the alkaline earth metal to titanium is substantially 1/1, and the alkaline earth metal and titanium are perovskite. There is provided a catalyst for producing a synthesis gas by an oxidation reaction between a lower hydrocarbon and carbon dioxide, characterized by being composed of a composite metal oxide having a structure.

【0006】[0006]

【発明の実施の形態】本発明のアルカリ土類金属とチタ
ンとニッケルを含有する複合酸化物からなる触媒におい
て、アルカリ土類金属とチタンとの原子比が実質的に1
/1であることが必要であり、これによって炭素析出の
減少された触媒を得ることができる。ニッケルの使用量
は特に制約されないが、通常、チタンに対する原子比で
0.05〜1、好ましくは0.01〜0.04である。
アルカリ土類金属としては、マグネシウム、カルシウ
ム、ストロンチウム、バリウムが挙げられ、好ましいア
ルカリ土類金属はバリウム、ストロンチウム又はカルシ
ウム、あるいはそれらの組み合わせである。本発明の触
媒において、アルカリ土類金属とチタンはペロブスカイ
ト型酸化物(MTiO3、M:アルカリ土類金属)を形
成し、ニッケルはそのペロブスカイト型酸化物の表面部
又は内部に存在する。この場合のニッケルは酸化ニッケ
ル(NiO)等のニッケル化合物であることができる
が、好ましくは金属ニッケルである。
BEST MODE FOR CARRYING OUT THE INVENTION In the catalyst of the present invention comprising a composite oxide containing an alkaline earth metal, titanium and nickel, the atomic ratio of the alkaline earth metal to titanium is substantially 1
/ 1 so that a catalyst with reduced carbon deposition can be obtained. The amount of nickel used is not particularly limited, but is generally 0.05 to 1, preferably 0.01 to 0.04 in atomic ratio to titanium.
Alkaline earth metals include magnesium, calcium, strontium, barium, with preferred alkaline earth metals being barium, strontium or calcium, or combinations thereof. In the catalyst of the present invention, the alkaline earth metal and titanium form a perovskite oxide (MTiO 3 , M: alkaline earth metal), and nickel is present on the surface or inside of the perovskite oxide. Nickel in this case can be a nickel compound such as nickel oxide (NiO), but is preferably metallic nickel.

【0007】本発明の触媒を好ましく調製するには、先
ず、クエン酸とエチレングリコールを含んだ水溶液にア
ルカリ土類金属、チタン及びニッケルをそれぞれ溶解し
た溶液を調製して、これらを原液とする。これらの原液
を所定量採取して混合し、ロータリエバポレーター中で
加温しながら濃縮する。濃縮液をビーカーに移してホッ
トプレート上で乾固する。このものを空気中300℃に
加熱して有機物を分解飛散させ、さらに500℃で焼成
して残存有機物を総て除去する。ここで得られた固形物
を粉末にした後、再度電気炉に入れて、空気中850℃
で焼成し、複合酸化物とする。また、上記手順でアルカ
リ土類金属とチタンから成るペロブスカイト型酸化物を
先ず調製して、これに所定量のニッケル原液をロータリ
ーエバポレーター中で含浸させた後、上記と同じ手順で
触媒を調製する。これらの複合金属酸化物のX線回折図
は、アルカリ土類金属とチタンから成るペロブスカイト
型酸化物、および酸化ニッケルに帰属される回折パター
ンを示す。
In order to preferably prepare the catalyst of the present invention, first, a solution is prepared by dissolving an alkaline earth metal, titanium and nickel in an aqueous solution containing citric acid and ethylene glycol, and these are used as stock solutions. A predetermined amount of these stock solutions is collected and mixed, and concentrated while heating in a rotary evaporator. Transfer the concentrate to a beaker and dry on a hot plate. This material is heated to 300 ° C. in the air to decompose and scatter organic substances, and then calcined at 500 ° C. to remove all remaining organic substances. After the solid obtained here is turned into a powder, it is put into an electric furnace again, and 850 ° C. in air.
To form a composite oxide. Further, a perovskite-type oxide composed of an alkaline earth metal and titanium is first prepared by the above procedure, and this is impregnated with a predetermined amount of a nickel stock solution in a rotary evaporator, and then a catalyst is prepared by the same procedure as above. The X-ray diffraction patterns of these composite metal oxides show the diffraction patterns attributed to perovskite-type oxides composed of an alkaline earth metal and titanium, and nickel oxide.

【0008】本発明において、複合金属酸化物を無機担
体に担持して、原料混合ガスとの接触面積を大きくする
こともできる。担体としては、シリカ、アルミナ、チタ
ニア、マグネシア等の多孔性物質が挙げられる。担持方
法は、複合金属酸化物の原料原液の混合液を用いて、通
常行われる混練や含浸で行えばよい。
In the present invention, the composite metal oxide can be supported on an inorganic carrier to increase the contact area with the raw material mixed gas. Examples of the carrier include porous substances such as silica, alumina, titania, and magnesia. The supporting method may be performed by a usual kneading or impregnation using a mixed solution of the raw material solution of the composite metal oxide.

【0009】本発明の触媒を用いて合成ガスを製造する
には、低級炭化水素と二酸化炭素との混合ガスを触媒と
接触させる。この場合、混合ガスを触媒に接触させる前
に触媒をメタンや水素で予め触媒上のニッケル成分を金
属状態のニッケルに保持するのが好ましい。また、この
ニッケル成分の還元は、混合ガスの温度を750℃以上
に保持し、これを触媒と接触させることによっても行う
ことができる。本発明の合成ガスの製造反応は次式によ
り表される
In order to produce a synthesis gas using the catalyst of the present invention, a mixed gas of a lower hydrocarbon and carbon dioxide is brought into contact with the catalyst. In this case, it is preferable that the nickel component on the catalyst is previously held in metallic nickel with methane or hydrogen before the mixed gas is brought into contact with the catalyst. Further, the reduction of the nickel component can also be performed by maintaining the temperature of the mixed gas at 750 ° C. or higher and bringing the mixed gas into contact with a catalyst. The synthesis gas production reaction of the present invention is represented by the following formula:

【化1】 Cm2m+2+mCO2→2mCO+(m+1)H2 (4) (式中、mは1〜4の数を表す)Embedded image C m H 2m + 2 + mCO 2 → 2mCO + (m + 1) H 2 (4) (where m represents a number of 1 to 4)

【0010】低級飽和炭化水素としては、炭素数1〜4
のもの、例えば、メタン、エタン、プロパン又はブタン
等が挙げられる。これらの低級飽和炭化水素は単独又は
混合物の形態で用いられる。二酸化炭素の使用割合は、
任意で行うことができるが、原料炭化水素がメタンの場
合にはメタン1モルに対して、1モル以上にするのがよ
い。反応温度は650〜1500℃、好ましくは750
〜1000℃である。反応圧力は常圧又は加圧であって
も良い。反応方式は固定床及び流動床等のいずれの方式
も採用することができる。
[0010] Lower saturated hydrocarbons include those having 1 to 4 carbon atoms.
, For example, methane, ethane, propane or butane. These lower saturated hydrocarbons are used alone or in the form of a mixture. The percentage of carbon dioxide used is
Although it can be carried out arbitrarily, when the raw material hydrocarbon is methane, the amount is preferably 1 mol or more per 1 mol of methane. The reaction temperature is 650-1500 ° C., preferably 750
10001000 ° C. The reaction pressure may be normal pressure or pressurization. As a reaction system, any system such as a fixed bed and a fluidized bed can be adopted.

【0011】[0011]

【実施例】次に本発明を、実施例によってさらに詳細に
説明するが、本発明はこれらの例により何等限定される
ものではない。
Next, the present invention will be described in more detail with reference to examples, but the present invention is not limited to these examples.

【0012】実施例1 先ず、触媒成分の原液を以下の手順で調製した。クエン
酸63gとエチレングリコール56mlを約350ml
の水に溶かし、この水溶液に炭酸カルシウム10gを徐
々に溶解後、全量を水で500mlとした溶液をカルシ
ウム原液とした。クエン酸105gとエチレングリコー
ル112mlを約350mlの水に溶かし、この水溶液
にオルトチタン酸テトライソプロピル28.4gを加え
る。溶液を激しく撹拌すると、生じた白色沈殿は徐々に
溶解して透明な溶液となる。これに水を加えて全量を5
00mlとしたものをチタン原液とした。クエン酸42
gとエチレングリコール56mlを約250mlの水に
溶かし、これに硝酸ニッケル6水和物29.1gを加え
て、ロータリーエバポレーター中90℃で撹拌する。数
時間後黄褐色のガスが発生し、このガスの発生が止まっ
た時点で、液体に水を加えて全量を250mlとし、こ
れをニッケル原液とした。
Example 1 First, a stock solution of a catalyst component was prepared by the following procedure. About 350 ml of citric acid 63 g and ethylene glycol 56 ml
Was dissolved in water, and 10 g of calcium carbonate was gradually dissolved in this aqueous solution, and the total volume was adjusted to 500 ml with water to obtain a calcium stock solution. 105 g of citric acid and 112 ml of ethylene glycol are dissolved in about 350 ml of water, and 28.4 g of tetraisopropyl orthotitanate is added to this aqueous solution. When the solution is stirred vigorously, the resulting white precipitate slowly dissolves into a clear solution. Add water and add 5
The solution having a volume of 00 ml was used as a titanium stock solution. Citric acid 42
g and 56 ml of ethylene glycol are dissolved in about 250 ml of water, 29.1 g of nickel nitrate hexahydrate is added thereto, and the mixture is stirred at 90 ° C. in a rotary evaporator. After several hours, a yellow-brown gas was generated. When the generation of this gas stopped, water was added to the liquid to make the total volume 250 ml, which was used as a nickel stock solution.

【0013】かくして得られた原液から次の手順で触媒
を調製した。カルシウム原液50ml、チタン原液50
ml及びニッケル原液5mlを混合し、ロータリエバポ
レーターで濃縮した後にホットプレート上で乾固する。
これを電気炉に入れて空気中500℃に加熱して、5時
間焼成する。ここで得られた固形物を乳鉢で粉末にし、
良く混合する。再度空気中850℃で5時間焼成し、得
られた複合酸化物を触媒として反応に供した。この複合
金属酸化物中の金属は、次の組成式で表されるもので、
カルシウムとチタンとはペロブスカイト型酸化物を形成
していることが確認された。 Ca1.0Ti1.0Ni0.2
From the stock solution thus obtained, a catalyst was prepared by the following procedure. Calcium stock solution 50ml, titanium stock solution 50
Then, 5 ml of the nickel solution and 5 ml of the nickel stock solution are mixed, concentrated on a rotary evaporator, and then dried on a hot plate.
This is placed in an electric furnace, heated to 500 ° C. in air, and fired for 5 hours. The solid obtained here is powdered in a mortar,
Mix well. The mixture was calcined again at 850 ° C. for 5 hours in the air, and the obtained composite oxide was used as a catalyst for the reaction. The metal in this composite metal oxide is represented by the following composition formula,
It was confirmed that calcium and titanium formed a perovskite oxide. Ca 1.0 Ti 1.0 Ni 0.2

【0014】反応は、触媒0.15gを充填した石英反
応管に、窒素を1.4リットル/時間の流速で流しなが
ら昇温し、850℃に達した時点でメタンを1.0リッ
トル/時間の流速で窒素ガスに加え、1時間経過の後さ
らに二酸化炭素を1.0リットル/時間で加えた時点を
反応の開始時間とした。反応開始6時間経過後の反応管
出口ガスを採取してガスクロマトグラフィーにかけた。
生成物は一酸化炭素と水素が大部分で、他は少量の水で
あった。この分析から窒素を内部標準にして反応成績を
計算して表1に示した。表中の、一酸化炭素の収率及び
水素の収率は次の式から計算した。
In the reaction, the temperature was raised while flowing nitrogen at a flow rate of 1.4 liter / hour into a quartz reaction tube filled with 0.15 g of the catalyst. When the temperature reached 850 ° C., methane was added at 1.0 liter / hour. The reaction start time was defined as the time point at which the nitrogen gas was added at a flow rate of 1 hour, and after 1 hour, carbon dioxide was further added at 1.0 liter / hour. Six hours after the start of the reaction, the gas at the outlet of the reaction tube was collected and subjected to gas chromatography.
The product was mostly carbon monoxide and hydrogen, the others were small amounts of water. From this analysis, the reaction results were calculated using nitrogen as an internal standard and are shown in Table 1. In the table, the yield of carbon monoxide and the yield of hydrogen were calculated from the following equations.

【数1】 (Equation 1)

【数2】 (Equation 2)

【0015】反応後、メタンと二酸化炭素を止めて窒素
のみを流しながら触媒を室温まで冷却した後、再度窒素
を空気に切り替えて温度を2.5℃/分の速度で上昇さ
せた。25℃毎に反応管出口ガス中の二酸化炭素を分析
し、この二酸化炭素が検出されなくなるまで温度を上昇
させた。この分析結果から、触媒上に蓄積した触媒重量
当たりの炭素量を計算して表1に示した。
After the reaction, the catalyst was cooled to room temperature while stopping methane and carbon dioxide and flowing only nitrogen, and then nitrogen was switched to air again to increase the temperature at a rate of 2.5 ° C./min. The carbon dioxide in the gas at the outlet of the reaction tube was analyzed every 25 ° C., and the temperature was increased until no more carbon dioxide was detected. From this analysis result, the amount of carbon per catalyst weight accumulated on the catalyst was calculated and shown in Table 1.

【0016】実施例2 実施例1の炭酸カルシウム10gを炭酸ストロンチウム
14.8gに変えた以外はすべて実施例1と同じ方法で
実験を行った結果を表1に示した。
Example 2 Table 1 shows the results of experiments conducted in the same manner as in Example 1 except that 10 g of calcium carbonate in Example 1 was changed to 14.8 g of strontium carbonate.

【0017】実施例3 実施例1の炭酸カルシウム10gを炭酸バリウム19.
3gに変えた以外はすべて実施例1と同じ方法で実験を
行った結果を表1に示した。
Example 3 10 g of the calcium carbonate of Example 1 was replaced with barium carbonate.
Table 1 shows the results of experiments conducted in the same manner as in Example 1 except that the amount was changed to 3 g.

【0018】実施例4 実施例1のカルシウム原液50mlを同カルシウム原液
40mlと実施例2のストロンチウム原液10mlの混
合溶液に変えた以外はすべて実施例1と同じ方法で実験
を行った結果を表1に示した。
Example 4 The results of an experiment conducted in the same manner as in Example 1 except that 50 ml of the undiluted calcium solution of Example 1 was changed to a mixed solution of 40 ml of the undiluted calcium solution and 10 ml of the undiluted strontium solution of Example 2 are shown in Table 1. It was shown to.

【0019】比較例1 実施例1のニッケル原液25mlにα−アルミナ5.1
gを加え、これをホットプレート上で良く撹拌しながら
蒸発乾固させ、以降の焼成手順は実施例1と同じ方法で
調製した触媒を用いて、実施例1と同じ方法で反応を行
った。その結果を表1に示した。
Comparative Example 1 α-alumina 5.1 was added to 25 ml of the nickel stock solution of Example 1.
g was added and the mixture was evaporated to dryness with good stirring on a hot plate. The subsequent calcination procedure was carried out in the same manner as in Example 1 using the catalyst prepared in the same manner as in Example 1. The results are shown in Table 1.

【0020】比較例2 酸化カルシウム2.2g、酸化ストロンチウム1g、酸
化チタン4g、酸化ニッケル0.8gを乳鉢で良く混合
した後、850℃で10時間焼成した。この複合酸化物
のX線回折図は、非常に弱いペロブスカイト型酸化物の
パターンと、原料酸化物に帰属される複雑なパターンを
示した。これを用いて実施例1と同じ操作で反応を行っ
た。結果を表1に示した。
Comparative Example 2 2.2 g of calcium oxide, 1 g of strontium oxide, 4 g of titanium oxide and 0.8 g of nickel oxide were mixed well in a mortar, and then fired at 850 ° C. for 10 hours. The X-ray diffraction pattern of this composite oxide showed a very weak perovskite oxide pattern and a complicated pattern attributed to the raw material oxide. Using this, a reaction was carried out in the same manner as in Example 1. The results are shown in Table 1.

【0021】比較例3 実施例4と同じ方法で、ニッケル原液を用いないで触媒
を調製し、実施例1と同じ方法で反応を行った。結果を
表1に示した。
Comparative Example 3 A catalyst was prepared in the same manner as in Example 4 without using a nickel stock solution, and reacted in the same manner as in Example 1. The results are shown in Table 1.

【0022】[0022]

【表1】 [Table 1]

【0023】実施例5〜8 実施例4で調製した触媒300mgを用いた以外は実施
例1と同じ反応条件で、20、50、100および15
0時間反応した結果を表2に示した。
Examples 5 to 8, 20, 50, 100 and 15 under the same reaction conditions as in Example 1 except that 300 mg of the catalyst prepared in Example 4 was used.
The result of the reaction for 0 hours is shown in Table 2.

【0024】[0024]

【表2】 [Table 2]

【0025】実施例9 実施例4で調製した触媒150mgを用い、ガス流速が
それぞれメタン1.5l/時間、二酸化炭素1.5l/
時間および窒素2.1l/時間の混合原料ガスを流しな
がら実施例1と同じ方法で反応を行った。結果を表3に
示した。
Example 9 Using 150 mg of the catalyst prepared in Example 4, the gas flow rate was 1.5 l / h for methane and 1.5 l / h for carbon dioxide.
The reaction was carried out in the same manner as in Example 1 while flowing a mixed raw material gas of 2.1 l / h with time. The results are shown in Table 3.

【0026】実施例10 実施例9のガス流速をそれぞれメタン3l/時間、二酸
化炭素3l/時間および窒素4.2l/時間に変えた以
外は、実施例9と同じ方法で反応を行い結果を表3に示
した。
Example 10 A reaction was carried out in the same manner as in Example 9 except that the gas flow rate in Example 9 was changed to 3 l / hour of methane, 3 l / hour of carbon dioxide, and 4.2 l / hour of nitrogen, respectively, and the results are shown in Table 9. 3 is shown.

【0027】[0027]

【表3】 [Table 3]

【0028】[0028]

【発明の効果】本発明により以下の効果を得ることがで
きる。 (1)スチームリフォーミングに比較して、プラントを
小型化できる。 (2)触媒上への炭素の析出が抑制されて、触媒活性が
長時間持続できる。 (3)触媒コストが低い。
According to the present invention, the following effects can be obtained. (1) The plant can be reduced in size as compared with steam reforming. (2) Precipitation of carbon on the catalyst is suppressed, and the catalyst activity can be maintained for a long time. (3) The catalyst cost is low.

───────────────────────────────────────────────────── フロントページの続き (72)発明者 清水 政男 茨城県つくば市東1丁目1番 工業技術院 物質工学工業技術研究所内 (72)発明者 浜川 聡 茨城県つくば市東1丁目1番 工業技術院 物質工学工業技術研究所内 (72)発明者 塩崎 竜二 茨城県つくば市東1丁目1番 工業技術院 物質工学工業技術研究所内 (72)発明者 鈴木 周 茨城県つくば市東1丁目1番 工業技術院 物質工学工業技術研究所内 ──────────────────────────────────────────────────続 き Continued on the front page (72) Inventor Masao Shimizu 1-1-1, Higashi, Tsukuba, Ibaraki Pref., National Institute of Advanced Industrial Science and Technology (72) Inventor Satoshi Hamakawa 1-1-1, Higashi, Tsukuba, Ibaraki, Japan Inside the R & D Institute (72) Inventor Ryuji Shiozaki 1-1-1, Higashi, Tsukuba, Ibaraki Pref.Institute of Materials Science and Technology (72) Inventor Shu Suzuki 1-1-1, Higashi, Tsukuba, Ibaraki Pref. Inside the Technical Research Institute

Claims (2)

【特許請求の範囲】[Claims] 【請求項1】 低級飽和炭化水素と二酸化炭素との酸化
反応による合成ガスの製造方法において、アルカリ土類
金属とチタンとニッケルを含有し、アルカリ土類金属と
チタンとの原子比が実質的に1/1であり、且つ該アル
カリ土類金属とチタンはペロブスカイト構造を形成して
いる複合金属酸化物からなる触媒を用いることを特徴と
する合成ガスの製造方法。
1. A method for producing a synthesis gas by an oxidation reaction between a lower saturated hydrocarbon and carbon dioxide, comprising an alkaline earth metal, titanium and nickel, wherein the atomic ratio of the alkaline earth metal to titanium is substantially A method for producing a synthesis gas, characterized in that a catalyst comprising a composite metal oxide in which the alkaline earth metal and titanium form a perovskite structure is used.
【請求項2】 アルカリ土類金属とチタンとニッケルを
含有し、アルカリ土類金属とチタンとの原子比が実質的
に1/1であり、且つ該アルカリ土類金属とチタンはペ
ロブスカイト構造を形成している複合金属酸化物からな
ることを特徴とする低級飽和炭化水素と二酸化炭素との
酸化反応による合成ガス製造用触媒。
2. An alkaline earth metal, titanium and nickel are contained, the atomic ratio of the alkaline earth metal and titanium is substantially 1/1, and the alkaline earth metal and titanium form a perovskite structure. A catalyst for producing a synthesis gas by an oxidation reaction between a lower saturated hydrocarbon and carbon dioxide, comprising a mixed metal oxide.
JP09001895A 1997-01-09 1997-01-09 Catalyst for syngas production and method for syngas production Expired - Lifetime JP3086867B2 (en)

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JP2010015860A (en) * 2008-07-04 2010-01-21 Murata Mfg Co Ltd Reformer for fuel cell
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