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JPH042582B2 - - Google Patents
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JPH042582B2 - - Google Patents

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Publication number
JPH042582B2
JPH042582B2 JP58086567A JP8656783A JPH042582B2 JP H042582 B2 JPH042582 B2 JP H042582B2 JP 58086567 A JP58086567 A JP 58086567A JP 8656783 A JP8656783 A JP 8656783A JP H042582 B2 JPH042582 B2 JP H042582B2
Authority
JP
Japan
Prior art keywords
catalyst
arsenic
reaction
acid
methacrylic acid
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.)
Expired - Lifetime
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JP58086567A
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Japanese (ja)
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JPS59212445A (en
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Priority to JP58086567A priority Critical patent/JPS59212445A/en
Publication of JPS59212445A publication Critical patent/JPS59212445A/en
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    • 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

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  • Organic Low-Molecular-Weight Compounds And Preparation Thereof (AREA)
  • Low-Molecular Organic Synthesis Reactions Using Catalysts (AREA)

Description

【発明の詳細な説明】[Detailed description of the invention]

この発明は、改良された触媒の存在下に、アク
ロレイン、メタクロレインなどの不飽和アルデヒ
ドを分子状酸素と高温気相で反応させて、アクリ
ル酸、メタクリル酸などの不飽和酸を収率よく製
造する方法に関するものである。 従来不飽和アルデヒド、例えばアクロレイン、
メタクロレインなどを触媒の存在下に分子状酸素
と高温気相で反応させて、対応する不飽和酸、例
えばアクリル酸、メタクリル酸などを製造する方
法およびその際に使用する触媒は多数知られてい
るが、アクリル酸の製造とメタクリル酸の製造と
の両者の反応に有用であるとして提案されている
触媒でも、これをアクロレインの酸化に使用した
場合とメタクロレインの酸化に使用した場合とで
は、目的生成物である不飽和酸の収率に大差があ
り、アクリル酸の収率にくらべるとメタクリル酸
の収率は著しく低い。このようにメタクロレイン
を酸化してメタクリル酸を製造する場合、アクロ
レインを酸化してアクリル酸を製造する場合と同
様の結果が得られないのは、メタクロレインが反
応性に富み酸化されやすいメチル基を分岐として
有していることに一因があり、分岐のメチル基の
酸化をおさえて、アルデヒド基だけを選択的に酸
化することが困難なためである。また比較的メタ
クリル酸への選択性が高い触媒でもメタクロレイ
ンの反応率が高くなると、メタクリル酸への選択
性が低下し、結局メタクリル酸の収率は低いもの
となつてしまう。 従つて近年不飽和酸、特にメタクリル酸を高収
率で長期間にわたつて製造できる触媒の開発が強
く望まれている。 従来メタクリル酸の製造を主目的として提案さ
れている触媒、例えば特開昭50−82013号公報、
特開昭50−123619号公報、特開昭50−135020号公
報、特開昭51−65713号公報、特開昭51−115413
号公報、特開昭51−52120号公報、特開昭52−
57117号などにおいて提案されているモリブデン、
リン、アルカリ金属、バナジウムなどを含有する
触媒は、メタクリル酸の製造において比較的好ま
しい結果を与えるが、さらにメタクロレインの反
応率、メタクリル酸の選択率および収率、反応温
度(最適反応温度)などの面において改善する余
地が残されている。 そこでこの発明者らは、先にMo−P−V−
K/Cs−O系触媒を改良することができる触媒
としてMo−P−V−K/Cs−Ag/Te−O系触
媒(特開昭55−31006号公報)、また、Mo−P−
Ca−V−Cu−As−K(Cs)−Ta(B、Bi、Fe、
Sb)−O系触媒において調製時にオキシカルボン
酸類、グリコール類および糖類を混合した触媒
(特開昭58−6243号公報)を提案した。しかしな
がらこの触媒に満足することなく、さらにメタク
ロレインの反応率およびメタクリル酸の選択率を
ともに高い値に維持して、メタクリル酸を高収率
で工業的に製造できる実用的な触媒を開発するこ
とを目的として鋭意研究を行なつた。 その結果、リン、モリブデン、銅およびヒ素を
含有するヘテロポリ酸系の組成物とホウ素、アル
ミニウム、鉛、ビスマスおよびクロムよりなる群
から選ばれた元素のヒ酸塩および/または亜ヒ酸
塩とを混合した触媒によつて前記目的を達成する
ことが可能となり、低い反応温度でメタクロレイ
ンの反応率およびメタグリル酸の選択率の両者、
特にメタクリル酸の選択率を高い値に維持して、
高収率でメタクリル酸を製造できることを知り、
この発明に到つた。 この発明は、不飽和アルデヒドを触媒の存在下
に分子状酸素と高温気相で反応させて不飽和酸を
製造する方法において、触媒として (A) リン、モリブデン、銅およびヒ素を含有する
ヘテロポリ酸系の組成物と (B) ホウ素、アルミニウム、鉛、ビスマスおよび
クロムよりなる群から選ばれた元素のヒ酸塩お
よび/または亜ヒ酸塩 とからなる混合物を使用することを特徴とする不
飽和酸の製造法に関するものである。 この発明において(A)成分のリン、モリブデン、
銅、およびヒ素を含有するヘテロポリ酸系の組成
物は、式(1)で表わすことができる。 MoaPbCucAsdOe ……(1) 〔式中、Moはモリブデン、Pはリン、Cuは銅、
Asはヒ素、Oは酸素を示し、添字のa〜eは原
子数を示し、a=12とするとb=0.5〜5、好ま
しくは0.9〜3、c=0.005〜3、好ましくは0.01
〜1、dは0.0001〜2、好ましくは0.001〜1、
eは前記各元素の原子価によつておのずと定まる
値である。〕 式(1)で表わされるヘテロポリ酸系の組成物に
は、リン、モリブデン、銅およびヒ素を含有する
従来公知のヘテロポリ酸系の触媒に添加されてい
るタングステン、鉄、アンチモン、コバルト、亜
鉛、ジルコニウム、カルシウム、スズ、チタン、
パラジウム、タンタル、セリウム、バナジウム、
マグネシウム、銀などが少量含まれていてもさし
つかえない。 式(1)で表わされるヘテロポリ酸系の組成物の調
製には、従来公知のリン、モリブデン、銅および
ヒ素を含有するヘテロポリ酸系の触媒調製法が適
宜採用される。調製法の1例を次に示す。 各成分元素を含有する化合物を水の存在下に混
合して溶解または分散させ、得られる混合溶液ま
たはスラリを蒸発乾固し、乾固物を乾燥して式(1)
で表わされるヘテロポリ酸系の組成物にする。各
成分元素を含有する化合物の代表的なものとして
は、三酸化モリブデン、リンモリブデン酸、リン
酸などをはじめ、酸化銅、炭酸銅、硝酸銅、ヒ
酸、亜ヒ酸、酸化ヒ素などを挙げることができ
る。各成分元素を含有する化合物の混合順序は特
に制限はない。混合する際の温度は、一般には20
〜100℃が適当であり、混合時間は均一に混合で
きれば特に制限されないが混合後50〜100℃で1
〜20時間熟成するのが望ましい。乾固物は、100
℃前後の温度、一般には80〜130℃の温度で1〜
20時間乾燥するのが好適である。 またこの発明において、(B)成分のヒ酸塩、亜ヒ
酸塩などのヒ素化合物としては、一般にBAsO4
AlAsO4、Pb(AsO22、BiAsO4およびα−
CrAsO4が使用される。勿論、これらは複数種使
用してもよい。 これらのヒ素化合物は、ヒ素含有化合物例えば
ヒ酸あるいはヒ酸ナトリウムと、ホウ素、アルミ
ニウム、銅、鉛、ビスマスなどを含有する化合物
とを、上記化学式で表わされる原子比のヒ素化合
物が形成されるように原料の使用割合をかえ、水
を加え蒸発乾固あるいは生じた沈殿を過した
後、熱処理することによつて容易に調製すること
ができる。例えば、ホウ素とヒ素との原子比が
1:1のBAsO4で表わされるヒ酸ホウ素は、ヒ
酸と等モルのホウ酸に水を加え、十分撹拌しなが
ら蒸発乾固した後、400℃程度で焼成する方法、
ヒ酸水素二アンモニウムとホウ酸と400℃程度で
加熱する方法などで調製することができ、上記他
のヒ素化合物も同様の方法で調製することができ
る。 またこの発明において(A)成分のリン、モリブデ
ン、銅およびヒ素を含有するヘテロポリ酸系の組
成物と(B)成分のホウ素、アルミニウム、鉛、ビス
マスおよびクロムよりなる群から選ばれた元素の
ヒ酸塩および/または亜ヒ酸塩との混合割合は、
(B)のヒ素化合物の種類によつて若干異なるが、(A)
のモリブデン12グラム原子に対して(B)のヒ素化合
物が0.5〜0.0001モル、好ましくは0.3〜0.001モル
になるようにするのが、触媒活性の面からみて好
適である。また(A)と(B)は均一に混合できればどの
様な方法で混合してもよいが、一般には少量の
水、バインダーなどを加えて、または加えずに、
ニーダー、擂潰機などの混合機で機械的に混合す
る方法が採用され、適宜成形して使用に供され
る。 この発明において触媒はこれ単独で使用しても
担体と一緒に使用しても差支えない。担体として
は、従来アクリル酸、メタクリル酸などの製造用
触媒の担体として公知のものがいずれも使用で
き、例えばけいそう土、アルミナ、シリカ、酸化
チタン、シリカゾル、シリコンカーバイド、グラ
フアイトなどを挙げることができる。なお、担体
は触媒製造時に加えておいてもよい。触媒粒子の
形状および大きさなどは特に制限されることはな
く、使用状態(条件)に応じて適宜ペレツト状、
粒状など任意の大きさおよび形状に成形、整粒し
て一定の機械的強度をもたせて使用するのがよ
い。 この発明において、反応に使用する分子状酸素
としては、純酸素ガスでもよいが、特に高純度で
ある必要もないので、一般には空気を使用するの
が経済的で便利である。また反応においては分子
状酸素およびアクロレインまたはメタクロレイン
とともに希釈ガスを使用するのがよい。希釈ガス
としてはこの反応に悪影響を及ぼさないもの、例
えば窒素ガス、炭酸ガス、水蒸気などが使用で
き、なかでも水蒸気はアクリル酸やメタクリル酸
の選択率を向上させる作用があるだけでなく、触
媒活性を持続させる作用があるので、水蒸気を存
在させて反応を行なうのがよい。 また反応に使用すアクロレインまたはメタクロ
レインとしても分子状酸素と同様に特に高純度で
ある必要はなく、例えばプロピレンまたはイソブ
チレンの酸化反応によつて得られたものをそのま
ま使用してもよい。 この発明は、流動床、移動床、固定床などいず
れでも実施できるが、この発明で使用する触媒
は、比較的低い反応温度、短い接触時間でアクロ
レインまたはメタクロレインの反応率およびアク
リル酸またはメタクリル酸の選択率が高く、長期
間にわたつて触媒活性を持続させることができる
という利点があるので、一般には固定床で実施す
るのが有利である。 またこの発明において反応は、常圧、加圧、減
圧下などいずれで行なつてもよいが、一般には常
圧で行なうのが便利である。また反応温度は200
〜400℃、好ましくは250〜350℃、特に260〜320
℃が好適である。また接触時間は0.1〜10秒、好
ましくは0.5〜5秒が適当である。反応にはアク
ロレインまたはメタクロレインおよび分子状酸
素、一般には空気に、さらに水蒸気を加えた混合
ガスを使用するのが好適であり、混合ガスの組成
はアクロレインまたはメタクロレイン1モルに対
して、分子状酸素が0.5〜7モル、好ましくは1
〜5モルで、水蒸気が0.5〜30モル、好ましくは
1〜10モルであることが好適である。 また生成した目的生成物であるアクリル酸また
はメタクリル酸の回収には、従来一般に知られた
方法、例えば凝縮、溶剤抽出などの方法が適用さ
れる。 次に実施例および比較例を示す。例中の反応率
(%)、選択率(%)および収率(%)は次の定義
に従う。 反応率(%)=反応したアクロレインまたはメタクロ
レインのモル数/供給したアクロレインまたはメタクロ
レインのモル数×100 選択率(%)=生成したアクリル酸またはメタクリル
酸のモル数/反応したアクロレインまたはメタクロレイ
ンのモル数×100 収率(%)=生成したアクリル酸またはメタクリル酸
のモル数/供給したアクロレインまたはメタクロレイン
のモル数×100 実施例 1 三酸化モリブデン〔MoO3〕240g、85%リン
酸〔H3PO4〕16.0g、酸化銅〔CuO〕1.1gおよ
び60%ヒ酸〔H3AsO4〕水溶液19.8gを水1.5に
加えて溶解し、30℃で20時間熟成し、ドラム乾燥
機で蒸発乾固後、さらに120℃、20時間乾燥し、
組成物(A)〔Mo12P1Cu0.1As0.6〕(酸素などは省略)
を得た。 また、60%ヒ酸〔H3AsO4〕水溶液と等モルの
ホウ酸〔H3BO3〕に若干の水を加え、蒸発乾固
した。得られた固形物を空気中350℃で20時間熱
処理(焼成)し、ヒ酸ホウ素〔BAsO4〕を得た。 次いで組成物(A)100gとヒ酸ホウ素0.24gを擂
潰機で均一に混合した後、4mmφ×4mmHのペレ
ツトに成型して触媒を得た。 このようにして得られた触媒の触媒成分元素の
原子比(酸素などは省略以下同様)はMo:P:
Cu:As:B=12:1:0.1:0.63:0.03である。 このようにして調製した触媒10ml(14.6g)を
内径8mmφのガラス製U字型反応管に充填し、こ
れに容量でメタクロレイン5%、酸素10%、水蒸
気30%および窒素55%の混合ガスを400ml/min
の流量で流し280℃の温度で、接触反応を1時間
行つた。接触反応の結果は第1表に示す。 比較例 1 ヒ酸ホウ素を混合しないで、実施例1と同様の
組成物(A)を触媒として使用し、実施例1と同様の
反応条件で接触反応を行つた。接触反応の結果は
第1表に示す。 実施例 2 実施例1の組成物(A)とヒ酸ホウ素との混合割合
をかえたほかは、実施例1と同様にして触媒成分
元素の原子比がMo:P:Cu:As:B=12:
1:0.1:0.7:0.1の触媒を調製し、実施例1と同
様の反応条件で接触反応を行つた。接触反応の結
果は第1表に示す。 実施例 3〜4 実施例1と同様の方法で第1表に記載の組成物
(A)を調製した。 また、60%ヒ酸〔H3AsO4〕水溶液と等モルの
硝酸アルミニウム〔Al(NO33・9H2O〕とに若
干の水を加え蒸発乾固した後、得られた固形物を
空気中230℃で20時間熱処理(焼成)し、ヒ酸ア
ルミニウム〔AlAsO4〕を得た。次いで、実施例
1と同様に組成物(A)とヒ酸アルミ〔AlAsO4〕と
を混合して第1表に記載の組成の触媒を調製し
た。実施例1と同様の反応条件で接触反応を行つ
た結果を第1表に示す。 実施例 5〜6 実施例1と同様の方法で第1表に記載の組成物
(A)を調製した。 また60%ヒ酸〔H3AsO4〕水溶液にヒ素と鉛と
の原子比As:Pbが2:1になるように水酸化炭
酸鉛〔2PbCO3・Pb(OH)2〕を若干の水とともに
加えて混合した後、蒸発乾固し、得られた固形物
を空気中700℃で20時間熱処理(焼成)し、ヒ酸
鉛〔Pb(AsO22〕を得た。次いで実施例1と同
様に組成物(A)とヒ酸鉛〔Pb(AsO22〕とを混合
し第1表に記載の組成の触媒を調製した。実施例
1と同様の反応条件で接触反応を行つた結果を第
1表に示す。 実施例 7〜8 実施例1と同様の方法で第1表に記載の組成物
(A)を調製した。 また60%ヒ酸〔H3AsO4〕水溶液にヒ素とビス
マスとの原子比As:Biが1:1になるように硝
酸ビスマス〔4BiNO3(OH)2・BiO(OH)〕を若
干の水とともに加えて混合した後、蒸発乾固し、
得られた固形物を空気中400℃で20時間熱処理
(焼成)し、ヒ酸ビスマス〔BiAsO4〕を得た。次
いで実施例1と同様に組成物(A)とヒ酸ビスマス
〔BiAsO4〕とを混合し第1表に記載の組成の触媒
を調製した。実施例1と同様の反応条件で接触反
応を行つた結果を第1表に示す。 実施例 9〜10 実施例1と同様の方法で第1表に記載の組成物
(A)を調製した。また、60%ヒ酸〔H3AsO4〕水溶
液に等モル硝酸クロム〔Cr(NO33・9H2O〕水
溶液を加え、蒸発乾固した後、得られた固形物を
空気中400℃で20時間熱処理(焼成)し、α−
CrAsO4を得た。次いで実施例1と同様に組成物
(A)とヒ酸クロム〔α−CrAsO4〕とを混合し、第
1表に記載の組成の触媒を調製した。実施例1と
同様の反応条件で接触反応を行つた結果を第1表
に示す。 比較例 2〜7 実施例1の組成物(A)の調製法と同様の方法で、
三酸化モリブデン、リン酸、酸化銅およびヒ酸の
ほかにさらに、ホウ酸〔H3BO3〕、硝酸アルミニ
ウム〔Al(NO33・9H2O〕、水酸化炭酸鉛
〔2PbCO3・Pb(OH)2〕、硝酸ビスマス〔4BiNO3
(OH)2・BiO(OH)〕または硝酸クロム〔Cr
(NO33・9H2O〕を用い、(B)成分のヒ素化合物を
混合しないで、第2表に記載の組成の触媒を調製
した。実施例1と同様の反応条件で接触反応を行
つた結果を第2表に示す。 This invention produces unsaturated acids such as acrylic acid and methacrylic acid in high yield by reacting unsaturated aldehydes such as acrolein and methacrolein with molecular oxygen in the high-temperature gas phase in the presence of an improved catalyst. It's about how to do it. Conventionally unsaturated aldehydes, such as acrolein,
There are many known methods for producing corresponding unsaturated acids, such as acrylic acid and methacrylic acid, by reacting methacrolein with molecular oxygen in the presence of a catalyst in a high-temperature gas phase, and the catalysts used in this process. However, even though a catalyst has been proposed to be useful for both the production of acrylic acid and the production of methacrylic acid, there are There is a large difference in the yield of the target product, unsaturated acid, and the yield of methacrylic acid is significantly lower than that of acrylic acid. The reason why oxidizing methacrolein to produce methacrylic acid does not produce the same results as producing acrylic acid by oxidizing acrolein is that methacrolein has a highly reactive methyl group that is easily oxidized. This is partly due to the fact that it has a branched methyl group, and it is difficult to selectively oxidize only the aldehyde group while suppressing the oxidation of the methyl group of the branch. Furthermore, even if the catalyst has relatively high selectivity to methacrylic acid, when the reaction rate of methacrolein increases, the selectivity to methacrylic acid decreases, resulting in a low yield of methacrylic acid. Therefore, in recent years, there has been a strong desire to develop a catalyst that can produce unsaturated acids, particularly methacrylic acid, in high yield over a long period of time. Catalysts that have been proposed mainly for the production of methacrylic acid, such as JP-A No. 50-82013,
JP-A-50-123619, JP-A-50-135020, JP-A-51-65713, JP-A-51-115413
No. 52120, Japanese Patent Application Laid-open No. 52-52-
Molybdenum proposed in No. 57117 etc.
Catalysts containing phosphorus, alkali metals, vanadium, etc. give relatively favorable results in the production of methacrylic acid, but they also have problems such as the reaction rate of methacrolein, the selectivity and yield of methacrylic acid, the reaction temperature (optimal reaction temperature), etc. There is still room for improvement in this aspect. Therefore, the inventors first conducted Mo-P-V-
Mo-P-V-K/Cs-Ag/Te-O catalyst (Japanese Unexamined Patent Publication No. 55-31006) is used as a catalyst that can improve the K/Cs-O catalyst.
Ca-V-Cu-As-K(Cs)-Ta(B, Bi, Fe,
proposed a Sb)-O-based catalyst in which oxycarboxylic acids, glycols, and saccharides were mixed during preparation (Japanese Patent Application Laid-open No. 1983-6243). However, without being satisfied with this catalyst, we have developed a practical catalyst that can industrially produce methacrylic acid in high yield by maintaining both the methacrolein reaction rate and methacrylic acid selectivity at high values. He conducted intensive research with this aim. As a result, a heteropolyacid composition containing phosphorus, molybdenum, copper and arsenic and an arsenate and/or arsenite of an element selected from the group consisting of boron, aluminum, lead, bismuth and chromium are combined. The mixed catalyst makes it possible to achieve the above objectives, increasing both the conversion rate of methacrolein and the selectivity of methagrilic acid at low reaction temperatures.
In particular, by maintaining the selectivity of methacrylic acid at a high value,
Knowing that methacrylic acid can be produced with high yield,
I arrived at this invention. This invention relates to a method for producing an unsaturated acid by reacting an unsaturated aldehyde with molecular oxygen in the presence of a catalyst in a high-temperature gas phase. (B) an arsenate and/or arsenite of an element selected from the group consisting of boron, aluminium, lead, bismuth and chromium; It relates to a method for producing acids. In this invention, component (A) phosphorus, molybdenum,
A heteropolyacid composition containing copper and arsenic can be represented by formula (1). Mo a P b Cu c As d O e ...(1) [In the formula, Mo is molybdenum, P is phosphorus, Cu is copper,
As represents arsenic, O represents oxygen, and subscripts a to e represent the number of atoms, where a = 12, b = 0.5 to 5, preferably 0.9 to 3, and c = 0.005 to 3, preferably 0.01.
~1, d is 0.0001 to 2, preferably 0.001 to 1,
e is a value naturally determined by the valence of each element. ] The heteropolyacid composition represented by formula (1) includes tungsten, iron, antimony, cobalt, zinc, Zirconium, calcium, tin, titanium,
palladium, tantalum, cerium, vanadium,
There is no problem even if it contains small amounts of magnesium, silver, etc. For preparing the heteropolyacid composition represented by formula (1), a conventionally known method for preparing a heteropolyacid catalyst containing phosphorus, molybdenum, copper, and arsenic is appropriately employed. An example of the preparation method is shown below. Compounds containing each component element are mixed in the presence of water and dissolved or dispersed, the resulting mixed solution or slurry is evaporated to dryness, and the dried product is dried to form the formula (1).
A heteropolyacid composition represented by: Typical compounds containing each element include molybdenum trioxide, phosphomolybdic acid, phosphoric acid, copper oxide, copper carbonate, copper nitrate, arsenic acid, arsenite, arsenic oxide, etc. be able to. There is no particular restriction on the order of mixing the compounds containing each component element. The temperature for mixing is generally 20
~100℃ is appropriate, and the mixing time is not particularly limited as long as it can be mixed uniformly, but after mixing,
Aging is recommended for ~20 hours. Dry matter is 100
1 to 1 at a temperature around ℃, generally 80 to 130℃
Drying for 20 hours is preferred. In this invention, the arsenic compounds such as arsenate and arsenite as component (B) are generally BAsO 4 ,
AlAsO 4 , Pb(AsO 2 ) 2 , BiAsO 4 and α−
CrAsO4 is used. Of course, a plurality of these may be used. These arsenic compounds are produced by combining an arsenic-containing compound such as arsenic acid or sodium arsenate with a compound containing boron, aluminum, copper, lead, bismuth, etc., such that an arsenic compound having the atomic ratio represented by the above chemical formula is formed. It can be easily prepared by changing the ratio of raw materials used, adding water, evaporating to dryness or filtering the resulting precipitate, and then heat-treating. For example, boron arsenate, which is expressed as BAsO 4 with an atomic ratio of boron and arsenic of 1:1, is produced by adding water to boric acid in an equal molar amount to arsenic acid, evaporating to dryness with sufficient stirring, and then heating the mixture to about 400°C. How to fire with,
It can be prepared by heating diammonium hydrogen arsenate and boric acid at about 400°C, and the other arsenic compounds mentioned above can also be prepared by the same method. In addition, in this invention, a heteropolyacid composition containing phosphorus, molybdenum, copper and arsenic as the component (A) and an arsenic composition containing an element selected from the group consisting of boron, aluminum, lead, bismuth and chromium as the component (B). The mixing ratio with acid salt and/or arsenite is
Although it differs slightly depending on the type of arsenic compound in (B), (A)
From the viewpoint of catalytic activity, it is preferable that the amount of arsenic compound (B) be 0.5 to 0.0001 mol, preferably 0.3 to 0.001 mol, per 12 gram atoms of molybdenum. Also, (A) and (B) may be mixed in any way as long as they can be mixed uniformly, but generally, with or without adding a small amount of water, a binder, etc.
A method of mechanical mixing using a mixer such as a kneader or a crusher is adopted, and the mixture is appropriately shaped and used. In this invention, the catalyst may be used alone or together with a carrier. As the carrier, any carrier conventionally known as a carrier for catalysts for producing acrylic acid, methacrylic acid, etc. can be used, such as diatomaceous earth, alumina, silica, titanium oxide, silica sol, silicon carbide, graphite, etc. I can do it. Note that the carrier may be added at the time of catalyst production. There are no particular restrictions on the shape and size of the catalyst particles, and they may be shaped into pellets, etc. depending on the conditions of use.
It is preferable to use it by molding it into a desired size and shape, such as granules, and grading it to give it a certain mechanical strength. In this invention, the molecular oxygen used in the reaction may be pure oxygen gas, but it is not necessary to have particularly high purity, so it is generally economical and convenient to use air. It is also preferred to use a diluent gas in the reaction together with molecular oxygen and acrolein or methacrolein. As the diluent gas, any gas that does not have a negative effect on this reaction, such as nitrogen gas, carbon dioxide gas, or water vapor, can be used. Among them, water vapor not only has the effect of improving the selectivity of acrylic acid and methacrylic acid, but also improves the catalytic activity. It is best to carry out the reaction in the presence of water vapor, as this has the effect of sustaining the reaction. Further, the acrolein or methacrolein used in the reaction does not need to be of particularly high purity like molecular oxygen, and for example, those obtained by oxidation reaction of propylene or isobutylene may be used as they are. Although this invention can be carried out in any of fluidized bed, moving bed, fixed bed, etc., the catalyst used in this invention can improve the reaction rate of acrolein or methacrolein and acrylic acid or methacrylic acid at relatively low reaction temperature and short contact time. It is generally advantageous to carry out the process in a fixed bed because it has the advantage of having a high selectivity and being able to maintain catalyst activity over a long period of time. Further, in the present invention, the reaction may be carried out under normal pressure, increased pressure, reduced pressure, etc., but it is generally convenient to carry out the reaction under normal pressure. Also, the reaction temperature is 200
~400℃, preferably 250-350℃, especially 260-320
°C is preferred. Further, the appropriate contact time is 0.1 to 10 seconds, preferably 0.5 to 5 seconds. For the reaction, it is preferable to use a mixed gas of acrolein or methacrolein and molecular oxygen, generally air, further adding water vapor.The composition of the mixed gas is 1 mole of acrolein or methacrolein, 0.5 to 7 moles of oxygen, preferably 1
It is preferred that the amount of water vapor is between 0.5 and 30 mol, preferably between 1 and 10 mol. In addition, conventionally known methods such as condensation and solvent extraction can be used to recover the desired product, acrylic acid or methacrylic acid. Next, examples and comparative examples will be shown. The reaction rate (%), selectivity (%) and yield (%) in the examples follow the following definitions. Reaction rate (%) = Number of moles of acrolein or methacrolein reacted/Number of moles of acrolein or methacrolein supplied x 100 Selectivity (%) = Number of moles of acrylic acid or methacrylic acid produced/Number of moles of acrolein or methacrolein reacted Number of moles of x 100 Yield (%) = Number of moles of acrylic acid or methacrylic acid produced/Number of moles of acrolein or methacrolein supplied x 100 Example 1 Molybdenum trioxide [MoO 3 ] 240 g, 85% phosphoric acid [ 16.0 g of H 3 PO 4 ], 1.1 g of copper oxide [CuO], and 19.8 g of 60% arsenic acid [H 3 AsO 4 ] aqueous solution were dissolved in 1.5 g of water, aged at 30°C for 20 hours, and dried in a drum dryer. After evaporation to dryness, further drying at 120℃ for 20 hours,
Composition (A) [Mo 12 P 1 Cu 0.1 As 0.6 ] (Oxygen etc. are omitted)
I got it. Further, a small amount of water was added to a 60% arsenic acid [H 3 AsO 4 ] aqueous solution and an equimolar amount of boric acid [H 3 BO 3 ], and the mixture was evaporated to dryness. The obtained solid was heat-treated (calcined) in air at 350°C for 20 hours to obtain boron arsenate [BAsO 4 ]. Next, 100 g of composition (A) and 0.24 g of boron arsenate were mixed uniformly using a crusher, and the mixture was molded into pellets of 4 mmφ x 4 mmH to obtain a catalyst. The atomic ratio of the catalyst component elements of the catalyst thus obtained (oxygen etc. are omitted) is Mo:P:
Cu:As:B=12:1:0.1:0.63:0.03. 10 ml (14.6 g) of the catalyst prepared in this manner was filled into a glass U-shaped reaction tube with an inner diameter of 8 mm, and a mixed gas containing 5% methacrolein, 10% oxygen, 30% water vapor, and 55% nitrogen by volume 400ml/min
The contact reaction was carried out for 1 hour at a flow rate of 280°C. The results of the contact reaction are shown in Table 1. Comparative Example 1 A catalytic reaction was carried out under the same reaction conditions as in Example 1 using the same composition (A) as in Example 1 as a catalyst without mixing boron arsenate. The results of the contact reaction are shown in Table 1. Example 2 The atomic ratio of the catalyst component elements was Mo:P:Cu:As:B= 12:
A catalyst of 1:0.1:0.7:0.1 was prepared and a catalytic reaction was carried out under the same reaction conditions as in Example 1. The results of the contact reaction are shown in Table 1. Examples 3-4 Compositions listed in Table 1 in a similar manner to Example 1
(A) was prepared. In addition, a small amount of water was added to a 60% arsenic acid [H 3 AsO 4 ] aqueous solution and an equimolar amount of aluminum nitrate [Al( NO 3 ) 3.9H 2 O], and the resulting solid was evaporated to dryness. Heat treatment (calcination) was performed in air at 230°C for 20 hours to obtain aluminum arsenate [AlAsO 4 ]. Next, in the same manner as in Example 1, composition (A) and aluminum arsenate [AlAsO 4 ] were mixed to prepare catalysts having the compositions shown in Table 1. Table 1 shows the results of a catalytic reaction conducted under the same reaction conditions as in Example 1. Examples 5-6 Compositions listed in Table 1 in a similar manner to Example 1
(A) was prepared. In addition, lead hydroxide carbonate [2PbCO 3 Pb(OH) 2 ] was added to a 60% arsenic [H 3 AsO 4 ] aqueous solution with some water so that the atomic ratio of arsenic and lead was 2:1. After addition and mixing, the mixture was evaporated to dryness, and the resulting solid was heat-treated (calcined) in air at 700°C for 20 hours to obtain lead arsenate [Pb(AsO 2 ) 2 ]. Next, in the same manner as in Example 1, composition (A) and lead arsenate [Pb(AsO 2 ) 2 ] were mixed to prepare a catalyst having the composition shown in Table 1. Table 1 shows the results of a catalytic reaction conducted under the same reaction conditions as in Example 1. Examples 7-8 Compositions listed in Table 1 in a similar manner to Example 1
(A) was prepared. In addition, bismuth nitrate [4BiNO 3 (OH) 2・BiO (OH)] was added to a 60% arsenic [H 3 AsO 4 ] aqueous solution with some water so that the atomic ratio of arsenic and bismuth was 1:1. After adding and mixing, evaporate to dryness,
The obtained solid was heat-treated (calcined) in air at 400°C for 20 hours to obtain bismuth arsenate [BiAsO 4 ]. Next, in the same manner as in Example 1, composition (A) and bismuth arsenate [BiAsO 4 ] were mixed to prepare catalysts having the compositions shown in Table 1. Table 1 shows the results of a catalytic reaction conducted under the same reaction conditions as in Example 1. Examples 9-10 The compositions listed in Table 1 were prepared in the same manner as in Example 1.
(A) was prepared. In addition, an equimolar chromium nitrate [Cr(NO 3 ) 3.9H 2 O] aqueous solution was added to a 60% arsenic acid [H 3 AsO 4 ] aqueous solution, and after evaporating to dryness, the obtained solid was heated in air at 400°C. Heat treated (baked) for 20 hours at α-
CrAsO4 was obtained. Next, the composition was prepared in the same manner as in Example 1.
(A) and chromium arsenate [α-CrAsO 4 ] were mixed to prepare a catalyst having the composition shown in Table 1. Table 1 shows the results of a catalytic reaction conducted under the same reaction conditions as in Example 1. Comparative Examples 2 to 7 In the same manner as the preparation method of composition (A) of Example 1,
In addition to molybdenum trioxide, phosphoric acid, copper oxide, and arsenic acid, boric acid [H 3 BO 3 ], aluminum nitrate [Al(NO 3 ) 3・9H 2 O], and lead carbonate hydroxide [2PbCO 3・Pb (OH) 2 ], bismuth nitrate [4BiNO 3
(OH) 2・BiO(OH)] or chromium nitrate [Cr
(NO 3 ) 3 ·9H 2 O] and without mixing the arsenic compound as component (B), catalysts having the compositions shown in Table 2 were prepared. Table 2 shows the results of a catalytic reaction conducted under the same reaction conditions as in Example 1.

【表】【table】

【表】【table】

【表】 実施例 11 実施例1と同様の触媒10mlを内径8mmφのガラ
ス製U字型反応管に充填し、これに容量でアクロ
レイン6%、酸素10%、水蒸気30%および窒素54
%の混合ガスを400ml/minの流量で流し、280℃
の温度で接触反応を行つた。その結果、アクロレ
インの反応率は96.2%、アクリル酸の選択率は
93.7%、アクリル酸の収率は90.1%であつた。[Table] Example 11 10 ml of the same catalyst as in Example 1 was filled into a glass U-shaped reaction tube with an inner diameter of 8 mm, and the volume was filled with 6% acrolein, 10% oxygen, 30% water vapor, and 54% nitrogen.
% mixed gas at a flow rate of 400ml/min at 280℃
The catalytic reaction was carried out at a temperature of . As a result, the reaction rate of acrolein was 96.2%, and the selectivity of acrylic acid was
The yield of acrylic acid was 93.7% and 90.1%.

Claims (1)

【特許請求の範囲】 1 不飽和アルデヒドを触媒の存在下に分子状酸
素と高温気相で反応させて不飽和酸を製造する方
法において、触媒として (A) リン、モリブデン、銅およびヒ素を含有する
ヘテロポリ酸系の組成物と (B) ホウ素、アルミニウム、鉛、ビスマスおよび
クロムよりなる群から選ばれた元素のヒ酸塩お
よび/または亜ヒ酸塩 とからなる混合物を使用することを特徴とする不
飽和酸の製造法。[Claims] 1. A method for producing an unsaturated acid by reacting an unsaturated aldehyde with molecular oxygen in the presence of a catalyst in a high-temperature gas phase, which contains (A) phosphorus, molybdenum, copper and arsenic as a catalyst; and (B) an arsenate and/or arsenite of an element selected from the group consisting of boron, aluminum, lead, bismuth and chromium. A method for producing unsaturated acids.
JP58086567A 1983-05-19 1983-05-19 Production of unsaturated acid Granted JPS59212445A (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
JP58086567A JPS59212445A (en) 1983-05-19 1983-05-19 Production of unsaturated acid

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
JP58086567A JPS59212445A (en) 1983-05-19 1983-05-19 Production of unsaturated acid

Publications (2)

Publication Number Publication Date
JPS59212445A JPS59212445A (en) 1984-12-01
JPH042582B2 true JPH042582B2 (en) 1992-01-20

Family

ID=13890588

Family Applications (1)

Application Number Title Priority Date Filing Date
JP58086567A Granted JPS59212445A (en) 1983-05-19 1983-05-19 Production of unsaturated acid

Country Status (1)

Country Link
JP (1) JPS59212445A (en)

Also Published As

Publication number Publication date
JPS59212445A (en) 1984-12-01

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