JP3506323B2 - Method for producing copolymer - Google Patents
Method for producing copolymerInfo
- Publication number
- JP3506323B2 JP3506323B2 JP02707399A JP2707399A JP3506323B2 JP 3506323 B2 JP3506323 B2 JP 3506323B2 JP 02707399 A JP02707399 A JP 02707399A JP 2707399 A JP2707399 A JP 2707399A JP 3506323 B2 JP3506323 B2 JP 3506323B2
- Authority
- JP
- Japan
- Prior art keywords
- polymerization
- weight
- vapor
- temperature
- monomer
- 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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Classifications
-
- C—CHEMISTRY; METALLURGY
- C08—ORGANIC MACROMOLECULAR COMPOUNDS; THEIR PREPARATION OR CHEMICAL WORKING-UP; COMPOSITIONS BASED THEREON
- C08F—MACROMOLECULAR COMPOUNDS OBTAINED BY REACTIONS ONLY INVOLVING CARBON-TO-CARBON UNSATURATED BONDS
- C08F212/00—Copolymers of compounds having one or more unsaturated aliphatic radicals, each having only one carbon-to-carbon double bond, and at least one being terminated by an aromatic carbocyclic ring
- C08F212/02—Monomers containing only one unsaturated aliphatic radical
- C08F212/04—Monomers containing only one unsaturated aliphatic radical containing one ring
- C08F212/06—Hydrocarbons
- C08F212/08—Styrene
- C08F212/10—Styrene with nitriles
Landscapes
- Chemical & Material Sciences (AREA)
- Health & Medical Sciences (AREA)
- Chemical Kinetics & Catalysis (AREA)
- Medicinal Chemistry (AREA)
- Polymers & Plastics (AREA)
- Organic Chemistry (AREA)
- Polymerisation Methods In General (AREA)
- Addition Polymer Or Copolymer, Post-Treatments, Or Chemical Modifications (AREA)
Description
【0001】[0001]
【発明の属する技術分野】本発明は芳香族ビニル−シア
ン化ビニル系共重合体の連続的製造法に関するものであ
り、重合装置におけるポリマースケールやポリマーブロ
ックの生成を低減させ、製品中へのゲル状ポリマーの混
入を低減させると共に、高い生産性を維持しつつ長時間
の連続運転を可能とする製造方法に関するものである。BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a continuous process for producing an aromatic vinyl-vinyl cyanide-based copolymer, which reduces the formation of polymer scale and polymer blocks in a polymerization apparatus and allows gels to be incorporated into products. TECHNICAL FIELD The present invention relates to a production method capable of reducing long-term polymer mixture and enabling continuous operation for a long time while maintaining high productivity.
【0002】[0002]
【従来の技術】芳香族ビニル−シアン化ビニル系共重合
体を製造する際に重合装置において生成するポリマース
ケールやポリマーブロックは、伝熱能力の低下、配管の
有効断面積の低下とそれに伴う圧力損失の上昇、さらに
は閉塞、製品中へのゲル状ポリマーの混入による製品外
観や力学物性の著しい低下など、様々な問題を引き起こ
す。そして、ポリマースケールやポリマーブロックが生
成すると操業を一旦停止してこれらを除去せねばなら
ず、このことが大きく生産性の低下をもたらすものであ
った。2. Description of the Related Art A polymer scale or polymer block produced in a polymerization apparatus when an aromatic vinyl-vinyl cyanide copolymer is produced has a reduced heat transfer capacity, a reduced effective cross-sectional area of a pipe, and a corresponding pressure. It causes various problems such as increased loss, plugging, and marked deterioration of product appearance and mechanical properties due to inclusion of gel polymer in the product. Then, when polymer scales and polymer blocks are formed, it is necessary to temporarily stop the operation and remove them, which causes a large decrease in productivity.
【0003】従来、重合装置におけるポリマースケール
の生成防止の方法としては、例えば特開昭57−253
10号公報のように原料中に含まれる水分を制御する方
法や特開昭60−260605号公報のようにアミド化
合物を添加して重合する方法などが提案されているが、
これらの方法では脱水操作や単量体を含む回収溶剤の組
成管理が煩雑であり、また、アミド化合物の製品への混
入に伴う光学物性その他、各種物性の低下などの課題が
残った。Conventionally, as a method for preventing the formation of polymer scale in a polymerization apparatus, for example, JP-A-57-253 has been used.
No. 10, a method of controlling the water content contained in the raw material, a method of adding an amide compound and polymerizing as in JP-A-60-260605 have been proposed.
In these methods, the dehydration operation and the composition control of the recovery solvent containing the monomer are complicated, and the problems such as the deterioration of various physical properties such as optical properties accompanying the incorporation of the amide compound into the product remain.
【0004】特公平7−5644号公報には、2基以上
の重合器を連結し、第1基目の重合器出口の重合転化率
を制御してゲル状ポリマーの生成を防止するという方法
も提案されているが、この方法では装置が複雑となり、
温度管理を始めとする生産管理が難しいという課題が残
る。Japanese Patent Publication No. 7-5644 discloses a method of connecting two or more polymerization vessels and controlling the polymerization conversion rate at the outlet of the first polymerization vessel to prevent the formation of gel polymer. Although proposed, this method complicates the device,
The problem remains that production control including temperature control is difficult.
【0005】また、特開平9−77806号公報には、
原料を重合缶上部の気相部器壁にスプレーして器壁を濡
らす方法も提案されているが、この方法ではスプレー液
が直接かからないところや配管にゲル状ポリマーが生成
しやすいという課題が残る。Further, in Japanese Patent Laid-Open No. 9-77806,
A method of wetting the vessel wall by spraying the raw material onto the vapor phase vessel wall above the polymerization vessel has also been proposed, but this method has the problem that a gel polymer is likely to be generated in places where the spray liquid does not directly come into contact and in the piping. .
【0006】さらに、特開平5−255448号公報に
は、各重合器内を120〜150℃以内で且つ単量体の
重合転化速度を30%/hr以内に保持させるという方
法が提案されているが、この方法では生産性において必
ずしも充分とはいえない。Further, Japanese Patent Laid-Open No. 5-255448 proposes a method of keeping the inside of each polymerization vessel within 120 to 150 ° C. and the polymerization conversion rate of monomers within 30% / hr. However, this method is not always sufficient in productivity.
【0007】[0007]
【発明が解決しようとする課題】本発明の目的は、芳香
族ビニル−シアン化ビニル系共重合体の連続的な製造に
際し、完全混合槽型重合器気相部の内壁面や配管、ノズ
ルなどにおけるポリマースケールやポリマーブロックの
生成を防止して伝熱能力の低下、配管の閉塞、あるいは
製品中へのゲル状ポリマーの混入による製品外観や力学
特性の低下などの問題を生じることなく、高い生産性を
維持しつつ長期間の安定的な生産を可能とする芳香族ビ
ニル−シアン化ビニル系共重合体の連続的製造方法を提
供することにある。The object of the present invention is to continuously produce an aromatic vinyl-vinyl cyanide copolymer, for example, the inner wall surface of the vapor phase part of the complete mixing tank type polymerization vessel, pipes, nozzles, etc. The production of polymer scale and polymer blocks in the product is prevented to reduce the heat transfer ability, blockage of piping, and the deterioration of product appearance and mechanical properties due to the inclusion of gel polymer in the product, resulting in high production. An object of the present invention is to provide a continuous production method of an aromatic vinyl-cyanide vinyl-based copolymer, which enables stable production for a long period of time while maintaining the properties.
【0008】[0008]
【課題を解決するための手段】本発明者らは、芳香族ビ
ニル−シアン化ビニル系共重合体を連続的に製造する方
法について鋭意検討した結果、重合時に、気相部蒸気を
引き抜いて冷却、凝縮させた液を再び気相部にスプレー
することにより該気相部における気液接触を活発にして
該気相部の温度を低下させることがポリマースケールや
ポリマーブロックの生成防止に顕著な効果があることを
見出し、本発明の完成に到った。本発明の製造方法は重
合液の単量体比を乱すことなく、また単量体重量/溶剤
重量比を乱すことも少なく従って操作上の変動をほとん
ど与えることがなく、しかも副次的に得られる気相部壁
の濡れ効果がポリマースケールやポリマーブロックの生
成防止に役立つ優れた製造方法である。Means for Solving the Problems The inventors of the present invention have made earnest studies on a method for continuously producing an aromatic vinyl-vinyl cyanide-based copolymer, and as a result, during the polymerization, the vapor phase vapor was extracted and cooled. , Re-spraying the condensed liquid on the gas phase part to activate the gas-liquid contact in the gas phase part to lower the temperature of the gas phase part is a remarkable effect in preventing formation of polymer scale or polymer block. Therefore, the present invention has been completed. The production method of the present invention does not disturb the monomer ratio of the polymerization liquid, and also does not disturb the monomer weight / solvent weight ratio so that there is almost no change in operation, and the secondary production is achieved. The wetting effect of the vapor phase wall is an excellent manufacturing method that helps prevent the formation of polymer scale and polymer blocks.
【0009】即ち、本発明は、溶剤の存在下に、芳香族
ビニル系単量体、シアン化ビニル系単量体及びこれらと
共重合可能なその他のビニル系単量体を含む原料混合液
を連続的に共重合させてなる共重合体の製造方法におい
て、芳香族ビニル系単量体50〜80重量%、シアン化
ビニル系単量体50〜20重量%及びこれらと共重合可
能なその他のビニル系単量体0〜30重量%の単量体混
合液100重量部と、溶剤10〜50重量部、重合開始
剤0〜1重量部及び分子量調節剤0〜1重量部とを、気
相部の蒸気を凝縮させるコンデンサーを備えた完全混合
槽型重合器(I)または該重合器(I)とこれに連結し
た重合器(II)を1基以上組み合わせた重合装置に連
続的に供給し、該重合器(I)の重合温度を120〜1
70℃とし、該重合器(I)のコンデンサーから還流す
る蒸気凝縮液を、大気圧における沸点が120℃以下で
ある凝縮液成分の濃度が合計65重量%以上になるよう
にその温度及び供給量を調整してこれを該重合器(I)
の気相部にスプレーすることを特徴とする該共重合体の
連続的製造方法に関する。That is, the present invention provides a raw material mixture containing an aromatic vinyl monomer, a vinyl cyanide monomer and other vinyl monomers copolymerizable with these in the presence of a solvent. In the method for producing a copolymer which is continuously copolymerized, 50 to 80% by weight of an aromatic vinyl-based monomer, 50 to 20% by weight of a vinyl cyanide-based monomer, and other copolymerizable with these. 100 parts by weight of a monomer mixture liquid of 0 to 30% by weight of a vinyl-based monomer, 10 to 50 parts by weight of a solvent, 0 to 1 part by weight of a polymerization initiator, and 0 to 1 part by weight of a molecular weight modifier are mixed in a gas phase. A continuous mixing tank type polymerization device (I) equipped with a condenser for condensing some vapors or a polymerization device in which at least one polymerization device (I) and a polymerization device (II) connected thereto are continuously supplied. , The polymerization temperature of the polymerization vessel (I) is 120 to 1
The temperature and supply amount of the vapor condensate refluxed from the condenser of the polymerizer (I) so that the total concentration of the condensate components having a boiling point of 120 ° C. or less at atmospheric pressure is 65% by weight or more. Of the polymerization vessel (I)
The present invention relates to a continuous process for producing the copolymer, which comprises spraying the gas phase part of
【0010】以下、本発明を詳細に説明する。本発明に
おける芳香族ビニル系単量体とは、分子内に芳香族基と
ビニル基とを有するラジカル重合可能な化合物であり、
例えばスチレン、α−メチルスチレン、p−メチルスチ
レン、3,5−ジメチルスチレン、2,4−ジメチルス
チレン、t−ブチルスチレン等のアルキル基置換スチレ
ン、α−ブロモスチレン、p−ブロモスチレン、o−ク
ロロスチレン、p−クロロスチレン等のハロゲン化スチ
レン等が挙げられる。これら芳香族ビニル系単量体は単
独で用いても、2種類以上混合して用いてもよい。The present invention will be described in detail below. The aromatic vinyl-based monomer in the present invention is a radically polymerizable compound having an aromatic group and a vinyl group in the molecule,
For example, styrene, α-methylstyrene, p-methylstyrene, 3,5-dimethylstyrene, 2,4-dimethylstyrene, alkyl group-substituted styrene such as t-butylstyrene, α-bromostyrene, p-bromostyrene, o- Examples thereof include halogenated styrene such as chlorostyrene and p-chlorostyrene. These aromatic vinyl monomers may be used alone or in combination of two or more.
【0011】芳香族ビニル系単量体の使用量は単量体の
合計量中50〜80重量%、好ましくは55〜80重量
%、さらに好ましくは60〜80重量%、最も好ましく
は65〜77重量%である。50重量%未満の場合は、
耐熱変色性が悪くなり、80重量%を超える場合は耐熱
性、力学特性が悪くなる。The amount of the aromatic vinyl monomer used is 50 to 80% by weight, preferably 55 to 80% by weight, more preferably 60 to 80% by weight, most preferably 65 to 77, based on the total amount of the monomers. % By weight. If less than 50% by weight,
If it exceeds 80% by weight, the heat resistance and mechanical properties will deteriorate.
【0012】本発明におけるシアン化ビニル系単量体と
は、分子内にニトリル基とビニル基とを有するラジカル
重合可能な化合物であり、例えばアクリロニトリル、メ
タクリロニトリル等が挙げられる。これらシアン化ビニ
ル系単量体は単独で用いても、2種類以上混合して用い
ても良い。The vinyl cyanide monomer in the present invention is a radically polymerizable compound having a nitrile group and a vinyl group in the molecule, and examples thereof include acrylonitrile and methacrylonitrile. These vinyl cyanide-based monomers may be used alone or in combination of two or more.
【0013】シアン化ビニル系単量体の使用量は単量体
の合計量中50〜20重量%、好ましく45〜20重量
%、最も好ましくは35〜23重量%である。50重量
%を超える場合は、耐熱変色性が悪くなり、20重量%
未満の場合は耐熱性、力学特性が悪くなる。The vinyl cyanide monomer is used in an amount of 50 to 20% by weight, preferably 45 to 20% by weight, and most preferably 35 to 23% by weight, based on the total amount of the monomers. When it exceeds 50% by weight, the heat discoloration resistance is deteriorated, and 20% by weight
If it is less than 1, heat resistance and mechanical properties are deteriorated.
【0014】また、本発明において必要に応じて加える
ことのできる、芳香族ビニル系単量体またはシアン化ビ
ニル系単量体と共重合可能なビニル系単量体とは、分子
内にビニル基を有するラジカル重合可能な化合物であ
り、例えばメタクリル酸メチル、メタクリル酸エチル、
アクリル酸メチル、アクリル酸エチル等の(メタ)アク
リル酸エステル、アクリル酸、メタクリル酸等の不飽和
酸、無水マレイン酸等の不飽和酸無水物、N−メチルマ
レイミド、N−フェニルマレイミド、N−シクロヘキシ
ルマレイミド等のマレイミド系単量体等が挙げられる。
これらのビニル系単量体は単独で用いても、2種類以上
混合して用いてもよい。In the present invention, the vinyl-based monomer copolymerizable with the aromatic vinyl-based monomer or the vinyl cyanide-based monomer, which can be added as necessary, is a vinyl group in the molecule. A radically polymerizable compound having, for example, methyl methacrylate, ethyl methacrylate,
(Meth) acrylic acid esters such as methyl acrylate and ethyl acrylate, unsaturated acids such as acrylic acid and methacrylic acid, unsaturated acid anhydrides such as maleic anhydride, N-methylmaleimide, N-phenylmaleimide, N- Examples thereof include maleimide-based monomers such as cyclohexylmaleimide.
These vinyl-based monomers may be used alone or in combination of two or more.
【0015】これらのビニル系単量体の使用量は単量体
の合計量中30重量%以下、好ましくは10重量%以下
である。The amount of these vinyl monomers used is 30% by weight or less, preferably 10% by weight or less based on the total amount of the monomers.
【0016】本発明で用いる溶剤とは、通常ラジカル重
合で使用される不活性な重合溶剤であり、例えばエチル
ベンゼン、トルエン、キシレン、o−キシレン、m−キ
シレン、p−キシレン、クメン、n−プロピルベンゼ
ン、イソプロピルベンゼン等の芳香族炭化水素、2−ブ
タノン、メチルイソブチルケトン等のケトン類、N,N
−ジメチルホルムアミド、N,N−ジメチルアセトアミ
ド、N−メチルピロリドン等のアミド化合物が挙げられ
る。これら溶剤のうち、芳香族炭化水素以外の溶剤は芳
香族炭化水素との併用が好ましい。例えば2−ブタノン
を単独で用いた場合、重合時に撹拌によって飛び跳ねて
気相部内壁に付着した芳香族ビニル−シアン化ビニル系
共重合体のうち、シアン化ビニル系重合体を多く含有す
る成分のみが溶け残り、これがゲル状ポリマーとなりや
すい。The solvent used in the present invention is an inert polymerization solvent which is usually used in radical polymerization, for example, ethylbenzene, toluene, xylene, o-xylene, m-xylene, p-xylene, cumene, n-propyl. Aromatic hydrocarbons such as benzene and isopropylbenzene, ketones such as 2-butanone and methyl isobutyl ketone, N, N
Examples include amide compounds such as dimethylformamide, N, N-dimethylacetamide and N-methylpyrrolidone. Among these solvents, solvents other than aromatic hydrocarbons are preferably used in combination with aromatic hydrocarbons. For example, when 2-butanone is used alone, only a component containing a large amount of a vinyl cyanide-based polymer among the aromatic vinyl-vinyl cyanide-based copolymers that jumped by stirring during polymerization and adhered to the inner wall of the gas phase part Remain undissolved, and this easily becomes a gel polymer.
【0017】溶剤の使用量は単量体混合液100重量部
に対して10〜50重量部、好ましくは17〜45重量
部、最も好ましくは24〜35重量部である。10重量
部未満の場合は、完全混合槽型重合器での重合液の粘度
が高くなり、撹拌に要する所要動力が大きくなり過ぎる
と共に混合不良に伴う除熱不良が生じて温度調節が困難
となり、また、ポリマースケールやポリマーブロックの
生成が多くなる。一方、50重量部を超えた場合には、
脱揮予熱器の負荷が増大して生産効率が低下すると共に
分子量も低下し、芳香族ビニル−シアン化ビニル系共重
合体あるいはそれを用いたABS樹脂としての必要な力
学特性が得られないばかりでなく、必要な流動特性をも
得られなくなる。The amount of the solvent used is 10 to 50 parts by weight, preferably 17 to 45 parts by weight, and most preferably 24 to 35 parts by weight, based on 100 parts by weight of the monomer mixture. If the amount is less than 10 parts by weight, the viscosity of the polymerization liquid in the complete mixing tank type polymerization vessel becomes high, the required power required for stirring becomes too large, and heat removal failure due to poor mixing occurs and temperature control becomes difficult, Moreover, the production of polymer scales and polymer blocks increases. On the other hand, if it exceeds 50 parts by weight,
The load on the devolatilization preheater increases, the production efficiency decreases, and the molecular weight also decreases, so that the mechanical properties required for an aromatic vinyl-vinyl cyanide copolymer or an ABS resin using the same cannot be obtained. In addition, the required flow characteristics cannot be obtained.
【0018】本発明において必要に応じて添加する重合
開始剤には、公知の重合開始剤が使用でき、例えばメチ
ルエチルケトンパーオキサイド等のケトンパーオキサイ
ド類、1,1−ビス(t−ブチルパーオキシ)3,3,
5−トリメチルシクロヘキサン、2,2−ビス(4,4
−ジ−t−ブチルパーオキシシクロヘキシル)プロパン
等のパーオキシケタール類、クメンハイドロパーオキサ
イド等のハイドロパーオキサイド類、ジクミルパーオキ
サイド等のジアルキルパーオキサイド類、ベンゾイルパ
ーオキサイド等のジアシルパーオキサイド類、ジイソプ
ロピルパーオキシジカーボネート等のパーオキシジカー
ボネート類、t−ブチルパーオキシイソプロピルカーボ
ネート等のパーオキシエステル類、2,2’−アゾビス
イソブチロニトリル、1,1’−アゾビス(シクロヘキ
サン−1−カルボニトリル)等のアゾニトリル類、t−
ブチルパーオキシアリルカーボネート、t−ブチルトリ
メチルシリルパーオキサイド、3,3’,4,4’−テ
トラ(t−ブチルパーオキシカルボニル)ベンゾフェノ
ン等の有機過酸化物等が挙げられる。これら重合開始剤
のうち、10時間半減期を示す温度が60〜120℃の
ものがとくに好ましい。これら重合開始剤は単独で用い
ても、2種類以上混合して用いてもよい。In the present invention, known polymerization initiators can be used as the polymerization initiator to be added as required. For example, ketone peroxides such as methyl ethyl ketone peroxide, 1,1-bis (t-butylperoxy). 3,3
5-trimethylcyclohexane, 2,2-bis (4,4
-Peroxyketals such as di-t-butylperoxycyclohexyl) propane, hydroperoxides such as cumene hydroperoxide, dialkyl peroxides such as dicumyl peroxide, diacyl peroxides such as benzoyl peroxide, Peroxydicarbonates such as diisopropyl peroxydicarbonate, peroxyesters such as t-butyl peroxyisopropyl carbonate, 2,2′-azobisisobutyronitrile, 1,1′-azobis (cyclohexane-1- Azonitriles such as carbonitrile), t-
Examples thereof include butyl peroxyallyl carbonate, t-butyl trimethyl silyl peroxide, and organic peroxides such as 3,3 ′, 4,4′-tetra (t-butyl peroxy carbonyl) benzophenone. Among these polymerization initiators, those having a temperature showing a 10-hour half-life of 60 to 120 ° C. are particularly preferable. These polymerization initiators may be used alone or in combination of two or more.
【0019】重合開始剤の使用量は重合装置における反
応熱の除去が制御可能な範囲であれば量が多いほうが反
応速度を上げられ有利である。実用的な使用量は単量体
の合計量100重量部に対して0〜1重量部、好ましく
は0を超えて1重量部である。It is advantageous that the amount of the polymerization initiator used is large so that the reaction rate can be increased so long as the removal of the reaction heat in the polymerization apparatus can be controlled. The practical amount used is 0 to 1 part by weight, preferably more than 0 and 1 part by weight, based on 100 parts by weight of the total amount of the monomers.
【0020】本発明において必要に応じて添加する分子
量調節剤とは、通常ラジカル重合で使用される分子量調
節剤であり、n−ドデシルメルカプタン、t−ドデシル
メルカプタン、シクロヘキシルメルカプタン等の直鎖、
分岐あるいは環式構造を有すアルキルメルカプタン類、
ブテニルメルカプタン等の不飽和結合を有すメルカプタ
ン類、1,2−エタンジチオール等の多価チオール類、
チオフェノール、2−メルカプトトルエン等の芳香族チ
オール類、1,3−ジメルカプト−2−プロパノール等
のヒドロキシ基を有するメルカプタン類、ドデシル3−
メルカプトプロピオネート等のエステル基を有するメル
カプタン類、1−メチル−4−イソプロピリデニルシク
ロヘキサン等のテルペン類、2,4−ジフェニル−4−
メチル−1−ペンテン等が挙げられる。これら分子量調
節剤は単独で用いても、2種類以上混合して用いてもよ
い。In the present invention, the molecular weight regulator added as necessary is a molecular weight regulator usually used in radical polymerization, and is a linear chain such as n-dodecyl mercaptan, t-dodecyl mercaptan or cyclohexyl mercaptan.
Alkyl mercaptans having a branched or cyclic structure,
Mercaptans having an unsaturated bond such as butenyl mercaptan, polyvalent thiols such as 1,2-ethanedithiol,
Aromatic thiols such as thiophenol and 2-mercaptotoluene, mercaptans having a hydroxy group such as 1,3-dimercapto-2-propanol, and dodecyl 3-
Mercaptans having an ester group such as mercaptopropionate, terpenes such as 1-methyl-4-isopropylidenylcyclohexane, 2,4-diphenyl-4-
Methyl-1-pentene and the like can be mentioned. These molecular weight modifiers may be used alone or in combination of two or more.
【0021】分子量調節剤の使用量は単量体の合計量1
00重量部に対して1重量部以下、好ましくは0を超え
1重量部以下、さらに好ましくは0.01〜0.5重量
部である。1重量部を超えた場合は製品である芳香族ビ
ニル−シアン化ビニル系共重合体の分子量が小さくなり
すぎて、とくに芳香族ビニル−シアン化ビニル系共重合
体をABS樹脂の原料として使用したときABS樹脂の
強度が低下する。The total amount of the monomers used is 1
The amount is 1 part by weight or less, preferably more than 0 and 1 part by weight or less, and more preferably 0.01 to 0.5 part by weight, relative to 00 parts by weight. When the amount exceeds 1 part by weight, the molecular weight of the product aromatic vinyl-cyanide-based copolymer becomes too small. Particularly, the aromatic vinyl-vinyl cyanide-based copolymer is used as a raw material for the ABS resin. At this time, the strength of the ABS resin decreases.
【0022】本発明で使用する重合装置は、気相部の蒸
気を凝縮させるコンデンサーを備えた完全混合槽型重合
器(I)または該重合器(I)とこれに連結した重合器
(II)を1基以上とからなる。重合器(II)は完全
混合槽型重合器、管型重合器、押出機型重合器またはニ
ーダー型重合器等を用いることができる。The polymerization apparatus used in the present invention is a complete mixing tank type polymerization vessel (I) equipped with a condenser for condensing vapor in the gas phase, or the polymerization vessel (I) and a polymerization vessel (II) connected thereto. Consists of one or more units. As the polymerization vessel (II), a complete mixing tank type polymerization vessel, a tube type polymerization vessel, an extruder type polymerization vessel, a kneader type polymerization vessel or the like can be used.
【0023】重合器(I)における重合液を実質的に均
一とするための実施形態については特に限定しないが、
ヘリカルリボン翼等のリボン型撹拌翼、タービン型撹拌
翼、スクリュー型撹拌翼、アンカー翼、傾斜パドル翼や
平パドル翼等のパドル翼、フルゾーン翼(商品名)、マ
ックスブレンド翼(商品名)、またはサンメラー翼(商
品名)等による攪拌混合のほか、たとえばこれに重合器
(I)の外部に設けたポンプ等による循環混合を組み合
わせて行うこともできる。The embodiment for making the polymerization liquid in the polymerization vessel (I) substantially uniform is not particularly limited,
Ribbon type stirring blades such as helical ribbon blades, turbine type stirring blades, screw type stirring blades, anchor blades, paddle blades such as inclined paddle blades and flat paddle blades, full zone blades (trade name), Maxblend blades (trade name), Alternatively, in addition to stirring and mixing with a sun-merer blade (trade name) or the like, circulation mixing with a pump or the like provided outside the polymerization vessel (I) may be combined therewith.
【0024】重合器(I)を撹拌混合する場合、気相部
における撹拌軸へのポリマー付着をなくすために、重合
器の下部に撹拌翼駆動部を置く下部撹拌式が優れる。When the polymerization vessel (I) is agitated and mixed, a lower agitation system in which a stirring blade driving section is provided at the bottom of the polymerization vessel is excellent in order to prevent the adhesion of the polymer to the agitation shaft in the gas phase section.
【0025】本発明において重合器(I)の気相部に接
する重合器壁の外側部の温度(以降、気相部の「外温」
と記す)は、気相部の温度よりも低いことが望ましい。
気相部外温は0〜120℃、好ましくは0〜100℃、
さらに好ましくは20〜100℃、最も好ましくは60
〜80℃である。0℃未満では、攪拌時に飛び跳ねて気
相部内壁表面に付着した重合液が高粘度となり過ぎるた
め長時間滞留してゲル状ポリマーとなり、これが重合液
中に混入して製品中へのゲル状ポリマー混入の原因とな
る。一方、120℃を超えた場合は重合液から発生した
蒸気が気相部内壁表面で凝縮したまま重合してゲル状ポ
リマーとなり、これが重合液中に混入して製品中へのゲ
ル状ポリマー混入の原因となる。In the present invention, the temperature of the outer portion of the wall of the polymerization vessel which is in contact with the gas phase portion of the polymerization vessel (I) (hereinafter, "outside temperature" of the gas phase portion)
Is preferably lower than the temperature of the vapor phase part.
The outside temperature of the gas phase is 0 to 120 ° C, preferably 0 to 100 ° C,
More preferably 20 to 100 ° C., most preferably 60.
~ 80 ° C. If the temperature is lower than 0 ° C, the polymer solution that jumps up at the time of stirring and adheres to the surface of the inner wall of the gas phase portion becomes too viscous, and stays for a long time to form a gel-like polymer. It may cause contamination. On the other hand, when the temperature exceeds 120 ° C, the vapor generated from the polymerization liquid is polymerized while condensing on the inner wall surface of the gas phase portion to form a gel-like polymer, which is mixed in the polymerization liquid and mixed with the gel-like polymer in the product. Cause.
【0026】重合器(I)の気相部の外温を気相部温度
よりも低くする方法は、重合器壁の外側に設けた外套に
冷水や冷媒を通す方法が一般的であるが、外套を設けず
に重合器に散水する方法でもよく、公知の方法を適宜採
用できる。重合器(I)に外套を設ける場合は気相部と
液相部で分割した外套とし、気相部と液相部それぞれ独
立に温度調節できることが最も好ましい。なお、本発明
で、気相部の外温は前記に説明したとおりであるが、外
套付きの重合器(I)の場合直接その温度を測定するこ
とが難しいので、便宜上、外套の入口及び出口における
冷媒(熱媒)温度の算術平均値をいう。A general method for lowering the outside temperature of the gas phase portion of the polymerization vessel (I) below the temperature of the gas phase portion is to pass cold water or a refrigerant through a jacket provided outside the polymerization vessel wall. A method of sprinkling water on the polymerization vessel without providing a jacket may be used, and a known method can be appropriately adopted. When the jacket is provided in the polymerization vessel (I), it is most preferable that the jacket is divided into the gas phase portion and the liquid phase portion, and the temperature can be controlled independently for each of the gas phase portion and the liquid phase portion. In the present invention, the external temperature of the gas phase part is as described above, but it is difficult to directly measure the temperature in the case of the polymerization vessel (I) with an overcoat, and therefore, for convenience, the inlet and outlet of the overcoat are used. The arithmetic mean value of the temperature of the refrigerant (heating medium) in.
【0027】また、本発明における蒸気凝縮液とは、重
合器(I)で発生した蒸気を重合器(I)に直接または
ガス配管を経由して接続したコンデンサーで凝縮させた
凝縮液であり、使用するコンデンサーとしては、例えば
スプレーコンデンサー、シェル&チューブ型コンデンサ
ーなどが挙げられる。そしてこの蒸気凝縮液を、大気圧
における沸点が120℃以下、好ましくは100℃以
下、さらに好ましくは90℃以下である成分の濃度の合
計が65重量%以上、好ましくは65〜95重量%、さ
らに好ましくは70〜90重量%となるように調整す
る。大気圧における沸点が120℃以下である成分の濃
度の合計が65重量%未満では重合器(I)の気相部温
度が高くなりすぎて重合器(I)に接続したノズルや配
管において、そこで凝縮した凝縮液が重合してゲル状ポ
リマーとなり、これが重合液中に混入して製品中へのゲ
ル状ポリマー混入の原因となる。The vapor condensate in the present invention is a condensate obtained by condensing the vapor generated in the polymerization vessel (I) with a condenser connected to the polymerization vessel (I) directly or via a gas pipe. Examples of the condenser to be used include a spray condenser and a shell & tube condenser. The vapor condensate has a boiling point of 120 ° C. or less at atmospheric pressure, preferably 100 ° C. or less, more preferably 90% or less, and the total concentration of the components is 65% by weight or more, preferably 65 to 95% by weight, and further It is preferably adjusted to 70 to 90% by weight. If the total concentration of the components having a boiling point of 120 ° C. or less at atmospheric pressure is less than 65% by weight, the gas phase temperature of the polymerization vessel (I) becomes too high, and the nozzle or pipe connected to the polymerization vessel (I) may have The condensed condensate is polymerized into a gelled polymer, which is mixed in the polymerized liquid and causes gelled polymer to be mixed in the product.
【0028】大気圧における沸点が120℃以下である
成分としては、例えば沸点がこの範囲にあるシアン化ビ
ニル系単量体等やトルエン溶剤などが該当するが、芳香
族ビニル−シアン化ビニル系共重合体に対する溶解力の
高さからシアン化ビニル系単量体が好ましく、とくにア
クリロニトリルが好ましい成分である。As the component having a boiling point of 120 ° C. or less at atmospheric pressure, for example, vinyl cyanide-based monomers having a boiling point in this range, toluene solvent and the like are applicable. Vinyl cyanide-based monomers are preferred because of their high solubility in polymers, and acrylonitrile is a particularly preferred component.
【0029】蒸気凝縮液中の大気圧における沸点が12
0℃以下である成分の濃度の合計を調整する方法とし
て、例えば重合器(I)の気相部にスプレーする蒸気凝
縮液の温度及び供給量の調節によって行う。The boiling point of the vapor condensate at atmospheric pressure is 12
As a method for adjusting the total concentration of components having a temperature of 0 ° C. or lower, for example, the temperature and supply amount of the vapor condensate sprayed on the gas phase part of the polymerization vessel (I) are adjusted.
【0030】重合器(I)の気相部にスプレーする蒸気
凝縮液の温度は、例えば重合器(I)に接続したコンデ
ンサーの冷媒流量や冷媒温度を調節することによって行
う。また、重合器(I)の気相部にスプレーする蒸気凝
縮液の供給量は、コントロールバルブ等を用いて調節
し、余剰の蒸気凝縮液は直接重合器液相部に戻すことが
好ましい。またスプレー流量を安定させ、蒸気凝縮液中
の大気圧における沸点が120℃未満である成分の濃度
の合計を65重量%以上に維持するとともに、流量低下
時にノズル内で蒸気凝縮液が重合してスプレーノズルが
閉塞することを防ぐために、重合器(I)に接続したコ
ンデンサーで凝縮した蒸気凝縮液をバッファータンクを
経由して重合器(I)に戻すことが好ましい。その際、
必要に応じてポンプ等を用いてバッファータンクから重
合器(I)に蒸気凝縮液を戻してもよい。なお、蒸気凝
縮液中の大気圧における沸点が120℃以下である成分
の濃度の合計が65重量%未満となった場合に、原料中
のシアン化ビニル系単量体を蒸気凝縮液に混合して濃度
を65重量%以上としこれを重合器(I)の気相部にス
プレーすることは、製造される芳香族ビニル−シアン化
ビニル系共重合体に組成むらが生じて透明性が失われる
ので好ましくない。The temperature of the vapor condensate sprayed on the gas phase of the polymerizer (I) is controlled by, for example, adjusting the refrigerant flow rate or the refrigerant temperature of the condenser connected to the polymerizer (I). Further, it is preferable that the supply amount of the vapor condensate sprayed to the gas phase part of the polymerizer (I) is adjusted by using a control valve or the like, and the surplus vapor condensate is directly returned to the liquid phase part of the polymerizer. In addition, the spray flow rate is stabilized, the total concentration of components having a boiling point of less than 120 ° C. at atmospheric pressure in the vapor condensate is maintained at 65 wt% or more, and the vapor condensate polymerizes in the nozzle when the flow rate decreases. In order to prevent the spray nozzle from being blocked, it is preferable to return the vapor condensate condensed by the condenser connected to the polymerizer (I) to the polymerizer (I) via the buffer tank. that time,
If necessary, the vapor condensate may be returned from the buffer tank to the polymerization vessel (I) using a pump or the like. When the total concentration of the components in the vapor condensate having a boiling point of 120 ° C. or less at atmospheric pressure is less than 65% by weight, the vinyl cyanide-based monomer in the raw material is mixed with the vapor condensate. When the concentration is adjusted to 65% by weight or more and the composition is sprayed on the gas phase part of the polymerization vessel (I), composition unevenness occurs in the produced aromatic vinyl-vinyl cyanide copolymer, resulting in loss of transparency. It is not preferable.
【0031】重合器(II)としてコンデンサーを備え
た重合器を用いる場合は、重合器(I)に接続したコン
デンサーで凝縮した蒸気凝縮液に重合器(II)に接続
したコンデンサーで凝縮した蒸気凝縮液を合わせてから
重合器(I)及び重合器(II)に分配して戻しても良
い。ただし重合器(I)内の単量体重量/溶剤重量比を
大きく変動させないことがよい。When a polymerizer equipped with a condenser is used as the polymerizer (II), the vapor condensate condensed by the condenser connected to the polymerizer (I) is condensed by the vapor condensate condensed by the condenser connected to the polymerizer (II). The liquids may be combined and then distributed and returned to the polymerization vessel (I) and the polymerization vessel (II). However, it is preferable that the monomer weight / solvent weight ratio in the polymerization vessel (I) is not largely changed.
【0032】ところで、本発明で使用するスプレーノズ
ルの形式は、例えば充円錐ノズル、空円錐ノズルまたは
扇型ノズル等が挙げられる。スプレーノズルの適正な孔
径は、ノズル数とスプレー液の流量、および重合器
(I)の寸法等により異なり一概には決まらないが、実
験的にこれらを勘案して求めることができる。スプレー
は気相部になされる。スプレーによる気液間の熱交換を
活発に生じさせるためには液滴は細かいほど好ましい。
スプレーは重合器(I)の気相部内壁、スプレー配管及
び攪拌翼等に向けられる。これらにスプレー液が掛かる
ことはポリマースケール、ポリマーブロックの生成防止
のためには好ましいが、スプレーによる濡れの効果は副
次的なものであり、必ずしもこの限りではない。また、
重合液表面に向けたスプレーを加えてもよい。The type of spray nozzle used in the present invention may be, for example, a full-cone nozzle, an empty-cone nozzle or a fan-shaped nozzle. The proper hole diameter of the spray nozzle varies depending on the number of nozzles, the flow rate of the spray liquid, the size of the polymerization vessel (I), etc., and is not unconditionally determined, but can be determined experimentally in consideration of these. The spray is applied to the vapor phase. Finer droplets are preferable in order to actively generate heat exchange between gas and liquid by spraying.
The spray is directed to the inner wall of the vapor phase portion of the polymerizer (I), the spray pipe, the stirring blade, and the like. It is preferable that the spray liquid is sprayed on these, in order to prevent the formation of polymer scale and polymer block, but the effect of wetting by spraying is secondary and is not necessarily limited to this. Also,
A spray directed to the surface of the polymer solution may be added.
【0033】本発明で、重合器(I)への供給液は単量
体を主体とする原料液そのものか、あるいは重合器(I
I)を重合器(I)の前段に連結した重合装置において
は重合器(II)で単量体が部分的に予備重合された供
給液であるが、供給液の重合転化率は供給される単量体
重量に対して30重量%以下が好ましく、さらに好まし
くは10重量%以下、最も好ましくは0重量%である。
これが30重量%を超えると重合器(I)における重合
熱の発生量が限定されて重合器(I)内の蒸発量が不足
しスプレーに用いる蒸気凝縮液を充分に確保できなくな
ることがある。In the present invention, the liquid to be supplied to the polymerization vessel (I) is the raw material solution itself mainly composed of the monomer, or the polymerization vessel (I).
In the polymerization apparatus in which I) is connected to the previous stage of the polymerization vessel (I), the monomer is partially prepolymerized in the polymerization vessel (II), but the polymerization conversion rate of the supply fluid is supplied. The amount is preferably 30% by weight or less, more preferably 10% by weight or less, and most preferably 0% by weight, based on the weight of the monomer.
If this content exceeds 30% by weight, the amount of heat of polymerization generated in the polymerization vessel (I) is limited, and the amount of evaporation in the polymerization vessel (I) becomes insufficient, so that the vapor condensate used for spraying may not be sufficiently secured.
【0034】本発明で、重合器(I)における重合転化
速度は、供給される単量体重量に対して30重量%/h
rを超える重合転化速度とする。また、重合器(I)の
出口における重合転化率は50〜90重量%とすること
が好ましく、さらに好ましくは60〜90重量%、最も
好ましくは70〜90重量%である。重合転化速度が3
0重量%/hr以下、或いは重合転化率が50重量%未
満であると、重合器(I)における重合熱の発生量が限
定されて重合器(I)内の蒸発量が不足しスプレーに用
いる蒸気凝縮液を充分確保できなくなるばかりでなく、
生産能力の低下をもきたす。重合転化速度は所定の重合
温度においては主に重合開始剤量で調節する。In the present invention, the polymerization conversion rate in the polymerization vessel (I) is 30% by weight / h based on the weight of the monomer fed.
The polymerization conversion rate exceeds r. The polymerization conversion rate at the outlet of the polymerization vessel (I) is preferably 50 to 90% by weight, more preferably 60 to 90% by weight, and most preferably 70 to 90% by weight. Polymerization conversion rate is 3
When the content is 0% by weight / hr or less or the polymerization conversion rate is less than 50% by weight, the amount of heat of polymerization generated in the polymerization vessel (I) is limited and the amount of evaporation in the polymerization vessel (I) is insufficient, which is used for spraying. Not only will it not be possible to secure sufficient vapor condensate,
It also causes a decline in production capacity. The polymerization conversion rate is mainly controlled by the amount of the polymerization initiator at a predetermined polymerization temperature.
【0035】本発明で、重合器(I)における重合温度
は120〜170℃、好ましくは125〜160℃、さ
らに好ましくは130〜155℃である。この温度範囲
では所定のスプレー流量を確保しやすく、30重量%/
hr以上の重合転化速度を達成しやすい。In the present invention, the polymerization temperature in the polymerization vessel (I) is 120 to 170 ° C, preferably 125 to 160 ° C, more preferably 130 to 155 ° C. In this temperature range, it is easy to secure a predetermined spray flow rate, and 30 wt% /
It is easy to achieve a polymerization conversion rate of at least hr.
【0036】尚、本発明における重合器(I)における
重合転化速度(単位:重量%/hr)とは、重合器
(I)における重合転化率の増加分(単位:重量%)
を、重合器(I)における滞留時間(単位:hr)で除
して求めた値である。そして、滞留時間は重合器(I)
の液相部の容積(単位:m3)を原料液の供給速度(単
位:m3/hr)で除して求めた値である。The polymerization conversion rate (unit:% by weight / hr) in the polymerization vessel (I) in the present invention means the increment of the polymerization conversion rate (unit:% by weight) in the polymerization vessel (I).
Is a value obtained by dividing by the residence time (unit: hr) in the polymerization vessel (I). The residence time is the polymerization vessel (I).
It is a value obtained by dividing the volume (unit: m 3 ) of the liquid phase part of the above by the supply rate (unit: m 3 / hr) of the raw material liquid.
【0037】重合転化率は具体的には、以下のとおり測
定して求めた。重合液または供給液を約2g精秤し、ア
セトンで希釈して30mlとし、これを撹拌下にメタノ
ール450mlに注いで析出させた析出物を濾別し、常
圧下、80℃で4時間乾燥した後にその重量を精秤し
た。そしてこの析出物の重量の測定値をアセトンで希釈
する前の重合液の重量の測定値で除し、100重量%を
乗じて重合液の樹脂濃度を算出した。この値を重合装置
に供給された原料中の仕込み単量体濃度で除して各重合
転化率を求めた。The polymerization conversion rate was specifically determined by measuring as follows. About 2 g of the polymerization liquid or the feed liquid was precisely weighed, diluted with acetone to 30 ml, poured into 450 ml of methanol with stirring, and the deposited precipitate was separated by filtration and dried at 80 ° C. for 4 hours under normal pressure. After that, the weight was precisely weighed. Then, the measured value of the weight of the precipitate was divided by the measured value of the weight of the polymerization liquid before being diluted with acetone, and multiplied by 100% by weight to calculate the resin concentration of the polymerization liquid. This value was divided by the concentration of the charged monomer in the raw material supplied to the polymerization apparatus to determine each polymerization conversion rate.
【0038】本発明において、最終的に排出される重合
液は重合転化率65重量%以上、好ましくは70重量%
以上、さらに好ましくは80重量%を超えたところまで
上げて重合を完結させた後、溶剤及び未反応単量体を分
離・除去して共重合体を得る。本発明におけるこれら分
離・除去の実施形態についてはとくに限定はないが、例
えば重合を終えた液を熱交換器に通して予熱しこれを減
圧に保ったタンクに導入して溶剤及び未反応単量体を気
化させて分離・除去する方法が挙げられる。In the present invention, the finally discharged polymerization liquid has a polymerization conversion rate of 65% by weight or more, preferably 70% by weight.
As described above, more preferably, the content is raised to a level exceeding 80% by weight to complete the polymerization, and then the solvent and the unreacted monomer are separated and removed to obtain a copolymer. The embodiment of separation / removal in the present invention is not particularly limited, but for example, the liquid after polymerization is passed through a heat exchanger to be preheated and introduced into a tank kept under reduced pressure to remove solvent and unreacted unit amount. Examples include a method of vaporizing the body to separate and remove it.
【0039】前記の最終的に排出される重合液から共重
合体を得るに際して、その溶剤及び未反応単量体の分離
・除去操作の前段階で、もしくは操作中の段階で、また
は操作後の段階で、フェノール系やリン系等の酸化安定
剤、ベンゾトリアゾール系やヒンダードアミン系等の光
安定剤、ステアリルアルコールやエチレンビスステアロ
アマイド等の滑剤、アンスラキノン系等のブルーイング
剤、その他の添加剤を混合することもできる。When the copolymer is obtained from the finally discharged polymerization liquid, it is before the operation of separating and removing the solvent and unreacted monomer, or during the operation, or after the operation. At the stage, oxidation stabilizers such as phenol type and phosphorus type, light stabilizers such as benzotriazole type and hindered amine type, lubricants such as stearyl alcohol and ethylene bis stearoamide, bluing agents such as anthraquinone type, and other additions The agents can also be mixed.
【0040】以下、本発明を図面に示す重合装置の一例
に基づいて更に詳細に説明する。図1は本発明の実施に
用いる重合装置の一例を示す概念図である。1は重合器
(I)であり、混合を良くするために液相部内壁に邪魔
板が付いても良く、2は原料または重合液と余剰の蒸気
凝縮液とを重合器(I)に供給するための供給液供給ラ
イン、3は重合器(I)気相部のスプレー、4はスプレ
ーに蒸気凝縮液を供給するためのスプレー液供給ライ
ン、5はスプレーする蒸気凝縮液の流量計、6はスプレ
ーする蒸気凝縮液の流量を調節するコントロールバル
ブ、7は原料がスプレーに混入することを防ぐための逆
止弁、8は気相部の蒸気をコンデンサーに導くためのベ
ーパーライン、9は蒸気を凝縮させて蒸気凝縮液とする
ためのコンデンサー、10は蒸気凝縮液のバッファータ
ンク、11はバッファータンクから蒸気凝縮液を抜き出
すための蒸気凝縮液抜き出しポンプ、12はバッファー
タンクの液面計、13はバッファータンクの液レベルを
一定に保つためのコントロールバルブ、14はバッファ
ータンクの液温計、15は重合液表面、16は気相部、
17は液相部、18はジャケット分割位置、19は気相
部ジャケット、20は液相部ジャケット、21は攪拌
翼、22は攪拌機モーター、23は気相部の温度計、2
4はノズルサイズ15Aの圧力計、25はノズルサイズ
50Aの圧力計、26は重合液を抜き出す重合液抜き出
しポンプ、27、28はストップ弁を示す。Hereinafter, the present invention will be described in more detail based on an example of a polymerization apparatus shown in the drawings. FIG. 1 is a conceptual diagram showing an example of a polymerization apparatus used for carrying out the present invention. Reference numeral 1 is a polymerization vessel (I), and a baffle plate may be attached to the inner wall of the liquid phase portion to improve mixing, and 2 is a raw material or a polymerization fluid and an excess vapor condensate are supplied to the polymerization vessel (I). A liquid supply line for spraying, 3 is a spray in the vapor phase part of the polymerizer (I), 4 is a spray liquid supply line for supplying a vapor condensate to the spray, 5 is a flow meter of the vapor condensate to be sprayed, 6 Is a control valve for adjusting the flow rate of the vapor condensate to be sprayed, 7 is a check valve for preventing the raw material from being mixed in the spray, 8 is a vapor line for guiding the vapor in the vapor phase to the condenser, and 9 is vapor. A condenser for condensing the vapor condensate into a vapor condensate, 10 is a vapor condensate buffer tank, 11 is a vapor condensate extraction pump for extracting the vapor condensate from the buffer tank, and 12 is a buffer tank fluid. Meter, 13 a control valve for keeping the liquid level in the buffer tank constant, 14 a buffer tank of liquid temperature meter, 15 the polymerization solution surface, 16 the gas phase,
17 is a liquid phase part, 18 is a jacket division position, 19 is a gas phase part jacket, 20 is a liquid phase part jacket, 21 is a stirring blade, 22 is a stirrer motor, 23 is a gas phase thermometer, 2
4 is a pressure gauge with a nozzle size of 15A, 25 is a pressure gauge with a nozzle size of 50A, 26 is a polymerization liquid extraction pump for extracting the polymerization liquid, and 27 and 28 are stop valves.
【0041】温度計23と圧力計24の設置された重合
器(I)1の気相部16の蒸気はベーパーライン8を経
由してコンデンサー9に入り、そこで凝縮して蒸気凝縮
液となる。この蒸気凝縮液は一旦、液温計14の設置さ
れたバッファータンク10に蓄えられ、蒸気凝縮液抜き
出しポンプ11によって重合器(I)1に戻されるが、
その戻す量は液面計12とコントロールバルブ13との
組み合わせによってバッファータンク10の液レベルが
一定となるように調節される。蒸気凝縮液抜き出しポン
プ13を出た蒸気凝縮液は、スプレー液供給ライン4を
経由して重合器(I)1の気相部16にスプレー3より
スプレーされるが、そのスプレーされる量は流量計5と
コントロールバルブ6との組み合わせによって調節され
る。重合器(I)1はジャケットを有しているが、その
ジャケットは気相部16と液相部17との界面である液
面15の位置に合わせられたジャケット分割位置18で
分割されて気相部ジャケット19と液相部ジャケット2
0よりなる。重合器(I)1の攪拌はその下部に設置さ
れた攪拌機モーター22による攪拌翼21の回転によっ
て行われる。重合器(I)で重合された重合液は重合液
抜き出しポンプ26によって抜き出される。The vapor in the vapor phase section 16 of the polymerization vessel (I) 1 in which the thermometer 23 and the pressure gauge 24 are installed enters the condenser 9 via the vapor line 8 and is condensed there to become a vapor condensate. This vapor condensate is temporarily stored in the buffer tank 10 in which the liquid thermometer 14 is installed, and returned to the polymerizer (I) 1 by the vapor condensate extraction pump 11,
The amount to be returned is adjusted by the combination of the liquid level gauge 12 and the control valve 13 so that the liquid level in the buffer tank 10 becomes constant. The vapor condensate discharged from the vapor condensate extraction pump 13 is sprayed from the spray 3 to the gas phase portion 16 of the polymerizer (I) 1 via the spray liquid supply line 4, and the sprayed amount is the flow rate. It is adjusted by the combination of the total 5 and the control valve 6. The polymerizer (I) 1 has a jacket, and the jacket is divided by a jacket dividing position 18 aligned with the position of the liquid surface 15 which is the interface between the gas phase portion 16 and the liquid phase portion 17. Phase jacket 19 and Liquid phase jacket 2
It consists of zero. Stirring of the polymerizer (I) 1 is performed by rotation of the stirring blade 21 by a stirrer motor 22 installed in the lower part thereof. The polymerization liquid polymerized in the polymerization vessel (I) is extracted by the polymerization liquid extraction pump 26.
【0042】重合器(I)1の気相部16の気相部温度
は温度計23で測定されるが、この気相部温度を調節す
るためには流量計5とコントロールバルブ6との組み合
わせに対して設定する値を調節してスプレーされる蒸気
凝縮液の量を調節する方法、あるいはコンデンサー9の
冷媒流量や冷媒温度を調節することによって液温計14
で測定される蒸気凝縮液の温度を調節する方法等が挙げ
られる。これらの調節によって、重合器(I)1の気相
部16において蒸気とスプレーされた蒸気凝縮液との間
の気液平衡の状況が調節され、蒸気凝縮液中のシアン化
ビニル系単量体の濃度が調整されると共に温度計23で
測定される気相部温度も調節される。この気相部温度の
調節により、シアン化ビニル系単量体や芳香族系単量体
等の単量体が熱重合することによる付着物の生成が防止
される。The vapor phase temperature of the vapor phase section 16 of the polymerizer (I) 1 is measured by a thermometer 23. In order to adjust the vapor phase temperature, a combination of a flow meter 5 and a control valve 6 is used. Liquid thermometer 14 by adjusting the value to be set to adjust the amount of vapor condensate sprayed, or by adjusting the refrigerant flow rate and the refrigerant temperature of the condenser 9.
And a method of adjusting the temperature of the vapor condensate measured in 1. By these adjustments, the vapor-liquid equilibrium state between the vapor and the sprayed vapor condensate in the vapor phase section 16 of the polymerizer (I) 1 is adjusted, and the vinyl cyanide-based monomer in the vapor condensate is adjusted. Is adjusted, and the gas phase temperature measured by the thermometer 23 is also adjusted. By adjusting the temperature of the vapor phase portion, formation of deposits due to thermal polymerization of monomers such as vinyl cyanide-based monomers and aromatic-based monomers is prevented.
【0043】また、この気液平衡によって、液面15か
ら蒸発した直後の過熱蒸気は蒸気凝縮液のスプレーによ
って飽和蒸気となり、気相部ジャケット19のみならず
温度計23や圧力計24などのスプレーの直接かからな
い部分でも凝縮するようになり、その凝縮液が各種器壁
を洗い流す効果が現れる。これにより、スプレーによる
直接的な洗浄だけでなく、スプレーのかからない部分の
洗浄をも生じる。Further, due to this vapor-liquid equilibrium, the superheated vapor immediately after evaporating from the liquid surface 15 becomes saturated vapor due to the spray of the vapor condensate, and not only the vapor phase jacket 19 but also the thermometer 23 and the pressure gauge 24 are sprayed. Condensation will begin to occur even on the parts that are not directly applied, and the condensate will have the effect of washing off various vessel walls. As a result, not only the direct cleaning by spraying but also the cleaning of the non-sprayed part occurs.
【0044】[0044]
【実施例】以下、実施例及び比較例により本発明を詳細
に説明する。最初に本発明において用いた分析または評
価方法について説明する。EXAMPLES The present invention will be described in detail below with reference to examples and comparative examples. First, the analysis or evaluation method used in the present invention will be described.
【0045】蒸気凝縮液の組成分析
装置 :ガスクロマトグラフGC−8AIF(島津製作
所製)
カラム:PEG20M+TCEP(15+5%/UNIPOR
TB60/80M)、SUS3φmm×3m、温度115℃、キャ
リヤー流速30ml/min
検出器:FID
異物の評価
製造した共重合体中へのゲル状ポリマーや不透明となっ
た樹脂などの異物の有無の確認は、長さ約3mm、直径
約3mmの共重合体ペレットをランダムに100g採取
して各ペレットを個別に検体として目視による観察で行
った。つぎに、長さ4cm×4cm×厚さ1mm、2m
m及び3mmの3部分からなる三段プレートを5枚成形
して検体とし、これに含まれる異物の有無を目視にて観
察した。いずれも、検体中に異物が認められなかった場
合に「異物なし」と評価した。Composition analyzer for vapor condensate: Gas chromatograph GC-8AIF (manufactured by Shimadzu Corporation) Column: PEG20M + TCEP (15 + 5% / UNIPOR)
TB60 / 80M), SUS3φmm × 3m, temperature 115 ° C, carrier flow rate 30ml / min Detector: FID Evaluation of foreign matter Check the presence of foreign matter such as gel polymer or opaque resin in the manufactured copolymer. , 100 g of a copolymer pellet having a length of about 3 mm and a diameter of about 3 mm was randomly sampled, and each pellet was individually observed as a specimen by visual observation. Next, length 4 cm x 4 cm x thickness 1 mm, 2 m
Five three-stage plates composed of three parts of m and 3 mm were molded to obtain a sample, and the presence or absence of foreign matter contained in the sample was visually observed. In each case, when no foreign matter was found in the sample, it was evaluated as “no foreign matter”.
【0046】実施例1
攪拌翼をマックスブレンド翼とし、全容量438リット
ル、液相部容量190リットルである図1に示した構造
の重合装置を使用した。重合装置は図1に示した重合器
(I)1からなり、この重合装置に原料を供給し表1に
記載の条件で重合させて得られた重合液を、重合液抜き
出しポンプ26で抜き出した後、多管式熱交換器で温度
230℃まで昇温してから絶対圧4kPaに減圧したタ
ンクにフラッシュさせて溶剤及び未反応モノマーを分
離、除去し、共重合体を製造した。表1に示す条件で5
日間、連続的に共重合体の製造を行い、1日おきにサン
プリングして観察・評価したところ、製造した共重合体
中にはゲル状ポリマーや不透明となった樹脂などの異物
は見られなかった。また、5日間の製造終了後、洗缶せ
ずに重合器(I)1を開放点検したところ、気相部16
の器壁だけでなく、温度計23のノズル、圧力計24の
ノズル及びベーパーライン8等にも樹脂等の付着物は全
く見られなかった。なお、得られた運転結果を表1にま
とめた。(以下の実施例、比較例も同様である)。Example 1 A polymerization apparatus having a structure shown in FIG. 1 with a total capacity of 438 liters and a liquid phase capacity of 190 liters was used with a stirring blade as a Maxblend blade. The polymerization apparatus consisted of the polymerization vessel (I) 1 shown in FIG. 1. The polymerization solution obtained by supplying the raw materials to the polymerization apparatus and polymerizing under the conditions shown in Table 1 was extracted by the polymerization solution extraction pump 26. After that, the temperature was raised to 230 ° C. in a multi-tube heat exchanger and then flushed in a tank whose pressure was reduced to 4 kPa in absolute pressure to separate and remove the solvent and unreacted monomers to produce a copolymer. 5 under the conditions shown in Table 1.
When the copolymer was continuously produced for a day and sampled every other day for observation and evaluation, no foreign matter such as gel polymer or opaque resin was found in the produced copolymer. It was Further, after completion of the production for 5 days, the polymerization vessel (I) 1 was opened and inspected without washing, and the gas phase portion 16
No deposits such as resin were found on the nozzle of the thermometer 23, the nozzle of the pressure gauge 24, the vapor line 8 and the like, in addition to the vessel wall. The obtained operation results are summarized in Table 1. (The same applies to the following examples and comparative examples).
【0047】実施例2
重合装置の重合器を2基とし、図1に示した重合器
(I)1の後段にジャケットを有す容積140リットル
の満液型の完全混合槽型重合器(II)を設置した。こ
の重合装置に原料を供給して得られた重合液は、図1に
示す重合液抜き出しポンプ26で抜き出された後、重合
器(II)でさらに重合してから重合器(II)の出口
に設置した重合液抜き出しポンプで抜き出され、多管式
熱交換器で230℃まで昇温してから絶対圧4kPaに
減圧したタンクにフラッシュさせて溶剤及び未反応モノ
マーを分離、除去し、共重合体を製造した。その他の条
件は表1に示す条件として5日間、連続的に共重合体の
製造を行い、1日おきにサンプリングして評価したとこ
ろ、製造した共重合体のペレット及び三段プレート中に
はゲル状ポリマーや不透明となった樹脂などの異物は見
られなかった。また、5日間の製造終了後、洗缶せずに
重合器(I)1を開放点検したところ、気相部16の器
壁だけでなく、温度計23のノズル、圧力計24のノズ
ル及びベーパーライン8等にも樹脂等の付着物は全く見
られなかった。Example 2 A polymerization vessel (I) shown in FIG. 1 having two polymerization vessels and a jacket at the rear stage of the polymerization vessel (I) 1 and having a volume of 140 liters was a liquid-filled complete mixing tank type polymerization vessel (II). ) Was installed. The polymerization solution obtained by supplying the raw materials to this polymerization apparatus is withdrawn by the polymerization solution withdrawing pump 26 shown in FIG. 1 and then further polymerized in the polymerization vessel (II) before the outlet of the polymerization vessel (II). It is extracted by the polymerization liquid extraction pump installed in the column, heated to 230 ° C in a multi-tube heat exchanger, and flushed in a tank whose absolute pressure is reduced to 4 kPa to separate and remove the solvent and unreacted monomers. A polymer was produced. The other conditions were as shown in Table 1, where the copolymer was continuously produced for 5 days and sampled every other day for evaluation. The produced pellets of the copolymer and the gel in the three-stage plate were evaluated. No foreign matter such as a polymer or an opaque resin was found. Further, after the completion of production for 5 days, the polymerization vessel (I) 1 was opened and inspected without washing. No deposit such as resin was found on the line 8 or the like.
【0048】比較例1
表1に示す条件で実施例1と同様にして連続的に共重合
体の製造を行い、1日おきにサンプリングして評価した
ところ、製造開始から2日が経過した時点で製造した共
重合体のペレット中に不透明となった樹脂の異物が見ら
れるようになり、三段プレート中にはゲル状ポリマーも
見られるようになった。また、製造開始から3日が経過
した時点で圧力計24の指示値が圧力計25の指示値と
一致しなくなり、しかも圧力計25の指示値が変動して
も圧力計24の指示値は変動しなくなってしまった。製
造開始から5日間の製造終了後、洗缶せずに重合器
(I)1を開放点検したところ、圧力計24のノズルが
樹脂で閉塞していた。また、温度計23のノズル、圧力
計25のノズル及びベーパーライン8等に樹脂の付着物
が見られ、しかもこれらの閉塞物や付着物は溶剤として
用いたエチルベンゼンだけでなく、正常に製造した共重
合体を容易に溶解するN,N−ジメチルホルムアミドや
アセトン等の有機溶剤にも不溶であった。Comparative Example 1 A copolymer was continuously produced under the conditions shown in Table 1 in the same manner as in Example 1 and sampled every other day for evaluation. When 2 days passed from the start of production, An opaque resinous foreign material became to be seen in the pellets of the copolymer produced in 1., and a gel polymer also came to be seen in the three-stage plate. In addition, the indication value of the pressure gauge 24 does not match the indication value of the pressure gauge 25 when 3 days have passed since the start of manufacturing, and the indication value of the pressure gauge 24 changes even if the indication value of the pressure gauge 25 changes. I have stopped doing it. After the completion of the production for 5 days from the start of the production, when the polymerization vessel (I) 1 was opened and inspected without washing the can, the nozzle of the pressure gauge 24 was clogged with the resin. Further, resin deposits were found on the nozzle of the thermometer 23, the nozzle of the pressure gauge 25, the vapor line 8 and the like. Moreover, these plugged substances and deposits were not only ethylbenzene used as a solvent but also those produced normally. It was also insoluble in organic solvents such as N, N-dimethylformamide and acetone which easily dissolve the polymer.
【0049】比較例2
重合缶(I)1の気相部16にスプレーする液を原料の
一部のみとし、蒸気凝縮液を全量、供給液供給ラインに
合流させた。その他の条件は表1に示す条件として実施
例1と同様にして連続的に共重合体の製造を行い、1日
おきにサンプリングして評価したところ、製造した共重
合体のペレット及び三段プレート中にはゲル状ポリマー
や不透明となった樹脂などの異物は見られなかった。し
かし、製造開始から5日間の製造終了後、洗缶せずに重
合器(I)1を開放点検したところ、温度計23のノズ
ル、圧力計24のノズル及びベーパーライン8等に樹脂
の付着物が見られ、しかもこれらの付着物は溶剤として
用いたエチルベンゼンに対してだけでなく、正常に製造
した共重合体を容易に溶解するN,N−ジメチルホルム
アミドやアセトン等の有機溶剤にも不溶であった。Comparative Example 2 The liquid to be sprayed on the gas phase portion 16 of the polymerization can (I) 1 was only a part of the raw material, and the entire vapor condensate was joined to the feed liquid supply line. The other conditions were as shown in Table 1, and the copolymer was continuously produced in the same manner as in Example 1, and the samples were evaluated every other day. The pellets and the three-stage plate of the produced copolymer were evaluated. No foreign matter such as gel polymer or opaque resin was found inside. However, after the completion of the production for 5 days from the start of the production, when the polymerization vessel (I) 1 was opened and inspected without washing it, resin deposits on the nozzle of the thermometer 23, the nozzle of the pressure gauge 24, the vapor line 8 and the like. Moreover, these deposits are insoluble not only in ethylbenzene used as a solvent but also in an organic solvent such as N, N-dimethylformamide or acetone which easily dissolves a normally produced copolymer. there were.
【0050】[0050]
【表1】 [Table 1]
【0051】[0051]
【発明の効果】以上の結果から明かなように、本発明の
芳香族ビニル−シアン化ビニル系共重合体の連続的な製
造方法は、単に完全混合槽型重合器の気相部内壁を洗浄
してポリマースケールやポリマーブロックの生成を防止
するだけのものではなく、完全混合槽型重合器に接続し
たノズルや配管で凝縮した凝縮液の重合をも防止し、伝
熱能力の低下、配管の有効断面積の低下とそれに伴う圧
力損失の上昇、さらには閉塞、製品中へのゲル状ポリマ
ーの混入による製品外観や力学物性の低下などの問題が
生じることなく、高い生産性を維持しつつ長期間の安定
的な生産が可能である方法であり、極めて有益である。As is apparent from the above results, the continuous method for producing an aromatic vinyl-cyanide vinyl copolymer of the present invention simply involves cleaning the inner wall of the gas phase of a complete mixing tank type polymerization vessel. Not only to prevent the formation of polymer scales and polymer blocks, but also to prevent the polymerization of the condensate condensed by the nozzles and pipes connected to the complete mixing tank type polymerizer, which lowers the heat transfer capacity and reduces the High productivity is maintained while maintaining high productivity without causing problems such as a decrease in effective area and increase in pressure loss due to it, blockage, and deterioration of product appearance and mechanical properties due to gel polymer inclusion in the product. This is a method that enables stable production for a certain period and is extremely beneficial.
【図1】本発明の共重合体の製造方法における重合器
(I)の一例を示す説明図である。FIG. 1 is an explanatory view showing an example of a polymerization vessel (I) in the method for producing a copolymer of the present invention.
1:重合器(I) 2:供給液供給ライン 3:スプレー 4:蒸気凝縮液供給ライン 5:流量計 6:コントロールバルブ 7:逆止弁 8:ベーパーライン 9:コンデンサー 10:バッファータンク 11:蒸気凝縮液抜き出しポンプ 12:液面計 13:コントロールバルブ 14:液温計 15:液面 16:気相部 17:液相部 18:ジャケット分割位置 19:気相部ジャケット 20:液相部ジャケット 21:攪拌翼 22:攪拌機モーター 23:温度計 24:圧力計(ノズルサイズ15A) 25:圧力計(ノズルサイズ50A) 26:重合液抜き出しポンプ 27:ストップ弁 28:ストップ弁 1: Polymerizer (I) 2: Supply liquid supply line 3: Spray 4: Steam condensate supply line 5: Flow meter 6: Control valve 7: Check valve 8: Vapor line 9: Condenser 10: Buffer tank 11: Steam condensate extraction pump 12: Level gauge 13: Control valve 14: Liquid thermometer 15: Liquid level 16: Gas phase section 17: Liquid phase part 18: Jacket division position 19: Gas phase jacket 20: Liquid phase jacket 21: Stirrer 22: Stirrer motor 23: Thermometer 24: Pressure gauge (nozzle size 15A) 25: Pressure gauge (nozzle size 50A) 26: Polymerization liquid extraction pump 27: Stop valve 28: Stop valve
───────────────────────────────────────────────────── フロントページの続き (58)調査した分野(Int.Cl.7,DB名) C08F 212/10 C08F 2/00 - 2/60 C08F 220/44 ─────────────────────────────────────────────────── ─── Continuation of the front page (58) Fields surveyed (Int.Cl. 7 , DB name) C08F 212/10 C08F 2/00-2/60 C08F 220/44
Claims (5)
体、シアン化ビニル系単量体及びこれらと共重合可能な
その他のビニル系単量体を含む原料混合液を連続的に共
重合させてなる共重合体の製造方法において、 芳香族ビニル系単量体50〜80重量%、シアン化ビニ
ル系単量体50〜20重量%及びこれらと共重合可能な
その他のビニル系単量体0〜30重量%の単量体混合液
100重量部と、溶剤10〜50重量部、重合開始剤0
〜1重量部及び分子量調節剤0〜1重量部とを、気相部
の蒸気を凝縮させるコンデンサーを備えた完全混合槽型
重合器(I)または該重合器(I)とこれに連結した重
合器(II)を1基以上組み合わせた重合装置に連続的
に供給し、該重合器(I)の重合温度を120〜170
℃とし、該重合器(I)のコンデンサーから還流する蒸
気凝縮液を、大気圧における沸点が120℃以下である
凝縮液成分の濃度が合計65重量%以上になるようにそ
の温度及び供給量を調整してこれを該重合器(I)の気
相部にスプレーすることを特徴とする該共重合体の連続
的製造方法。1. A raw material mixed solution containing an aromatic vinyl-based monomer, a vinyl cyanide-based monomer, and another vinyl-based monomer copolymerizable with these is continuously co-polymerized in the presence of a solvent. In the method for producing a copolymer obtained by polymerizing, 50 to 80% by weight of an aromatic vinyl monomer, 50 to 20% by weight of a vinyl cyanide monomer, and other vinyl-based monomer copolymerizable therewith 100 parts by weight of monomer mixture liquid of 0 to 30% by weight, 10 to 50 parts by weight of solvent, and 0 polymerization initiator
-1 part by weight and 0 to 1 part by weight of a molecular weight regulator, a complete mixing tank type polymerization device (I) equipped with a condenser for condensing vapor in the gas phase part or a polymerization device (I) and a polymerization connected thereto. The polymerization temperature of the polymerization vessel (I) is set to 120 to 170 by continuously supplying it to a polymerization apparatus in which at least one vessel (II) is combined.
C., and the temperature and supply amount of the vapor condensate refluxed from the condenser of the polymerizer (I) are adjusted so that the total concentration of the condensate components having a boiling point of 120 ° C. or less at atmospheric pressure is 65% by weight or more. A continuous process for producing the copolymer, which is prepared and sprayed on the gas phase of the polymerization vessel (I).
重合器壁の外側部の温度が気相部温度より低く、かつ0
〜120℃に調整されていることを特徴とする請求項1
記載の共重合体の連続的製造方法。2. In the polymerizer (I), the temperature of the outer portion of the wall of the polymerizer which is in contact with the gas phase portion is lower than the temperature of the gas phase portion and is 0.
The temperature is adjusted to ~ 120 ° C.
A method for continuously producing the copolymer described.
ける重合転化率が30重量%未満である供給液を重合転
化速度30重量%/hrを超える速度で共重合させ、か
つ該重合器(I)の出口における重合転化率を50〜9
0重量%とすることを特徴とする請求項1または請求項
2に記載の共重合体の連続的製造方法。3. In the polymerization vessel (I), a feed liquid having a polymerization conversion rate of less than 30% by weight at its inlet is copolymerized at a polymerization conversion rate of more than 30% by weight / hr, and the polymerization vessel (I) ), The polymerization conversion rate at the outlet is 50 to 9
The continuous production method of the copolymer according to claim 1 or 2, wherein the content is 0% by weight.
り、シアン化ビニル系単量体がアクリロニトリルである
ことを特徴とする請求項1〜3のいずれか1項に記載の
共重合体の連続的製造方法。4. The copolymer according to claim 1, wherein the aromatic vinyl monomer is styrene and the vinyl cyanide monomer is acrylonitrile. Continuous manufacturing method.
凝縮した蒸気凝縮液をバッファータンクを経由して重合
器(I)に戻すことを特徴とする請求項1〜4のいずれ
か1項に記載の共重合体の連続的製造方法。5. The vapor condensate condensed by a condenser connected to the polymerizer (I) is returned to the polymerizer (I) via a buffer tank, according to any one of claims 1 to 4. A method for continuously producing the copolymer described.
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JP02707399A JP3506323B2 (en) | 1999-02-04 | 1999-02-04 | Method for producing copolymer |
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JP02707399A JP3506323B2 (en) | 1999-02-04 | 1999-02-04 | Method for producing copolymer |
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JP3506323B2 true JP3506323B2 (en) | 2004-03-15 |
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JP4242267B2 (en) * | 2003-12-24 | 2009-03-25 | 三菱レイヨン株式会社 | Method for producing vinyl polymer composition |
JP5309660B2 (en) * | 2008-04-02 | 2013-10-09 | Jsr株式会社 | Method for producing polymer for photoresist |
EP2308902B1 (en) * | 2008-07-08 | 2013-09-11 | Toray Industries, Inc. | Method for manufacturing thermoplastic copolymers |
JP2014095030A (en) * | 2012-11-09 | 2014-05-22 | Nippon A&L Inc | Aromatic vinyl copolymer, thermoplastic resin composition and manufacturing method of aromatic vinyl copolymer |
KR102435545B1 (en) | 2018-12-18 | 2022-08-24 | 주식회사 엘지화학 | Method and apparatus for preparing aromatic vinyl compound-vinylcyan compound copolymer |
KR102706277B1 (en) * | 2019-12-04 | 2024-09-13 | 주식회사 엘지화학 | Method and apparatus for preparing aromatic vinyl based copolymer |
CN117083310A (en) | 2021-04-08 | 2023-11-17 | 电化株式会社 | Copolymer, resin composition for injection molding, molded article, and method for producing copolymer |
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