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JPH0790164B2 - Apparatus and method for producing high-viscosity substance - Google Patents

Apparatus and method for producing high-viscosity substance

Info

Publication number
JPH0790164B2
JPH0790164B2 JP2021995A JP2199590A JPH0790164B2 JP H0790164 B2 JPH0790164 B2 JP H0790164B2 JP 2021995 A JP2021995 A JP 2021995A JP 2199590 A JP2199590 A JP 2199590A JP H0790164 B2 JPH0790164 B2 JP H0790164B2
Authority
JP
Japan
Prior art keywords
container
stirring
stirring blade
liquid
treated
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
Application number
JP2021995A
Other languages
Japanese (ja)
Other versions
JPH03188936A (en
Inventor
英和 中元
親生 小田
則男 仲里
盛久 丸子
一夫 井原
高年 木下
敬信 古川
健一 渡部
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.)
Hitachi Ltd
Original Assignee
Hitachi Ltd
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 Hitachi Ltd filed Critical Hitachi Ltd
Publication of JPH03188936A publication Critical patent/JPH03188936A/en
Publication of JPH0790164B2 publication Critical patent/JPH0790164B2/en
Anticipated expiration legal-status Critical
Expired - Lifetime legal-status Critical Current

Links

Classifications

    • BPERFORMING OPERATIONS; TRANSPORTING
    • B01PHYSICAL OR CHEMICAL PROCESSES OR APPARATUS IN GENERAL
    • B01JCHEMICAL OR PHYSICAL PROCESSES, e.g. CATALYSIS OR COLLOID CHEMISTRY; THEIR RELEVANT APPARATUS
    • B01J19/00Chemical, physical or physico-chemical processes in general; Their relevant apparatus
    • B01J19/18Stationary reactors having moving elements inside
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B01PHYSICAL OR CHEMICAL PROCESSES OR APPARATUS IN GENERAL
    • B01JCHEMICAL OR PHYSICAL PROCESSES, e.g. CATALYSIS OR COLLOID CHEMISTRY; THEIR RELEVANT APPARATUS
    • B01J2219/00Chemical, physical or physico-chemical processes in general; Their relevant apparatus
    • B01J2219/00049Controlling or regulating processes
    • B01J2219/00168Controlling or regulating processes controlling the viscosity
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B01PHYSICAL OR CHEMICAL PROCESSES OR APPARATUS IN GENERAL
    • B01JCHEMICAL OR PHYSICAL PROCESSES, e.g. CATALYSIS OR COLLOID CHEMISTRY; THEIR RELEVANT APPARATUS
    • B01J2219/00Chemical, physical or physico-chemical processes in general; Their relevant apparatus
    • B01J2219/18Details relating to the spatial orientation of the reactor
    • B01J2219/185Details relating to the spatial orientation of the reactor vertical

Landscapes

  • Chemical & Material Sciences (AREA)
  • Organic Chemistry (AREA)
  • Chemical Kinetics & Catalysis (AREA)
  • Mixers Of The Rotary Stirring Type (AREA)
  • Polymerisation Methods In General (AREA)
  • Physical Or Chemical Processes And Apparatus (AREA)
  • Polyamides (AREA)
  • Polyesters Or Polycarbonates (AREA)
  • Other Resins Obtained By Reactions Not Involving Carbon-To-Carbon Unsaturated Bonds (AREA)
  • Polyoxymethylene Polymers And Polymers With Carbon-To-Carbon Bonds (AREA)

Description

【発明の詳細な説明】 〔産業上の利用分野〕 本発明は高粘度液の撹拌混合処理に係り、特に例えば液
晶ポリマ(Liquid Crystal Plastics)、ポリアリレー
ト(Polyarylate)などの高機能エンジニアリングプラ
スチックの製造に好適な高粘性物質の製造に関するもの
である。
Description: TECHNICAL FIELD The present invention relates to a stirring and mixing treatment of a high-viscosity liquid, and particularly to the production of highly functional engineering plastics such as liquid crystal polymers (Liquid Crystal Plastics) and polyarylates. The present invention relates to the production of a highly viscous substance suitable for.

〔従来の技術〕[Conventional technology]

一般に、高粘性物質の混練、反応等の製造においては、
装置内での被処理液の付着、共廻りを少なくすると共
に、被処理液の滞溜部分を少なくして品質の劣化を防止
したものが種々考案されている。例えば日本特許公開公
報昭56−116721号及び文献(重合反応装置の基礎と解
析:村上泰弘著:P33〜P37)に示されているように、リ
ボン翼を配列し、容器内面をすべてかき取れる構造とし
たものがある。この構造を円筒状容器で具体化したもの
を第21図により説明する。図において、攪拌動力は駆動
源より回転動力伝達軸(以下、回転耳軸と呼ぶ)2を経
由し、攪拌槽本体1内の回転軸5に伝達される。該回転
軸5には水平方向に支持腕4a、4bが複数個とりつけら
れ、支持腕4a、4bの先端には攪拌槽本体1の内壁をくま
なく掻き取るようにらせん状にリボン翼3a、3bが取り付
けられている。攪拌槽本体1の上部には予備重合装置23
からの被処理液や添加剤の供給口6が、下部には被処理
液の排出口7が設けられている。本装置によって高粘度
液を攪拌混合処理する場合、被処理液の粘度が数百〜1k
Pa・s(数千〜1万ポアズ)までは良好に動作するが、
被処理液の粘度が数kPa・s(数万ポアズ)に達する
と、リボン翼3a、3bに被処理液が付着し共回り現象が起
る。また回転軸5の表面は表面の周速が遅いので、高粘
度液になると被処理液の付着共回りが起り、デットスペ
ースが発生し攪拌・混合性能が悪化する。従って、従来
装置では被処理液の粘度が1kPa・s(1万ポアズ)まで
となり、それ以上の高粘度になると攪拌に用する時間が
長くなり、さらにデッドスペースによる被処理物の品質
低下が生じる等の不具合があった。
Generally, in the production of kneading and reaction of highly viscous substances,
Various types of devices have been devised, in which the adhesion and co-rotation of the liquid to be treated in the apparatus are reduced and the accumulated portion of the liquid to be treated is reduced to prevent the deterioration of quality. For example, as shown in Japanese Patent Publication No. Sho 56-116721 and a document (Basic and Analysis of Polymerization Reactor: Yasuhiro Murakami: P33 to P37), ribbon blades are arranged so that the entire inner surface of the container can be scraped off. There is something. A concrete example of this structure with a cylindrical container will be described with reference to FIG. In the figure, stirring power is transmitted from a drive source to a rotary shaft 5 in a stirring tank main body 1 via a rotary power transmission shaft (hereinafter referred to as a rotary ear shaft) 2. A plurality of supporting arms 4a and 4b are horizontally attached to the rotary shaft 5, and ribbon blades 3a and 3b are spirally attached to the tips of the supporting arms 4a and 4b so as to scrape the inner wall of the agitation tank main body 1 thoroughly. Is attached. At the upper part of the stirring tank main body 1, a prepolymerization device 23
A supply port 6 for the liquid to be treated and the additive is provided, and a discharge port 7 for the liquid to be treated is provided in the lower part. When stirring and mixing high-viscosity liquid with this device, the viscosity of the liquid to be treated is several hundred to 1k.
Works well up to Pas (thousands to 10,000 poises),
When the viscosity of the liquid to be treated reaches several kPa · s (tens of thousands of poise), the liquid to be treated adheres to the ribbon blades 3a and 3b, and a co-rotation phenomenon occurs. Further, since the peripheral speed of the surface of the rotary shaft 5 is slow, when the liquid becomes a high viscosity liquid, co-rotation of the liquid to be treated occurs, a dead space is generated, and stirring / mixing performance is deteriorated. Therefore, in the conventional apparatus, the viscosity of the liquid to be treated is up to 1 kPa · s (10,000 poise), and if the viscosity is higher than that, the time for stirring becomes long, and further the quality of the substance to be treated deteriorates due to dead space. There was a problem such as.

また、従来の汎用プラスチック等の製造方法に関して
は、文献(重合反応装置の基礎と解析:村上泰弘著:P13
7〜P140)に述べられているような重合反応プロセスに
より製造されている。上述のプロセスにより高機能エン
ジニアリングプラスチックを製造する場合、以下の問題
点が発生する。プラスチックの高機能化とは例えば機械
強度の増加、耐熱温度の上昇、耐候・耐薬品性の向上等
があるが、一般的に高機能化するということは樹脂の重
合度を増加させる、つまり分子量を増大させることであ
る。樹脂は分子量を増大すれば、その樹脂の溶融粘度が
増加してくる。
Regarding conventional methods for producing general-purpose plastics, etc., refer to the literature (Basic and analysis of polymerization reactor: Yasuhiro Murakami: P13
It is manufactured by the polymerization reaction process as described in 7-P140). When manufacturing a high-performance engineering plastic by the above-mentioned process, the following problems occur. High-performance plastics include, for example, increase in mechanical strength, increase in heat resistance temperature, improvement in weather resistance and chemical resistance, but generally high-performance means increasing the degree of polymerization of the resin, that is, the molecular weight. Is to increase. As the molecular weight of the resin increases, the melt viscosity of the resin increases.

従来の製造プロセスで使用されている撹拌機の処理粘度
は1kPa・s(1万ポアズ)が限界となっている。そのた
めに高機能樹脂(スーパエンプラ)を製造するには第23
図に示すプロセスにより製造している。第23図により従
来プロセスを説明する。樹脂の原料となるモノマーと触
媒を加えて原料を調整し、さらに樹脂の溶剤を加えて低
粘度の液状の状態で攪拌槽内へ供給し、所定の反応温度
に保ったまま攪拌し、溶液重合を行う。この時に、反応
の進行により発生する重合副成物は随時除去して行く。
反応の進行と共に樹脂の分子量は増加するが溶剤中で攪
拌されているので溶液の粘度は上昇せず数百Pa・s(数
千ポアズ)程度に保たれている。反応が進み所定の重合
度に到達すると、次の工程として溶剤を回収するプロセ
スがある。この工程には、脱モノマー装置、脱水装置、
乾燥装置などが配置され、最終的には溶剤と分離された
最終重合物のみが得られる。
The processing viscosity of the stirrer used in the conventional manufacturing process is limited to 1 kPa · s (10,000 poise). Therefore, it is the 23rd to manufacture high-performance resin (super engineering plastic).
It is manufactured by the process shown in the figure. The conventional process will be described with reference to FIG. Prepare the raw material by adding the monomer and catalyst that are the raw materials for the resin, and then add the solvent for the resin and supply it to the stirring tank in a liquid state with low viscosity, and stir it while maintaining it at the prescribed reaction temperature to carry out solution polymerization. I do. At this time, polymerization by-products generated by the progress of the reaction are removed at any time.
Although the molecular weight of the resin increases with the progress of the reaction, the viscosity of the solution does not increase and is maintained at about several hundred Pa · s (several thousand poises) because it is stirred in the solvent. When the reaction progresses to reach a predetermined degree of polymerization, there is a process of recovering the solvent as the next step. In this process, a demonomerizer, dehydrator,
A drying device or the like is arranged so that only the final polymer separated from the solvent is finally obtained.

つぎに、高機能樹脂(スーパエンプラ)の他の製造方法
を第24図により説明する。このプロセスでは、樹脂の原
料であるモノマーに触媒を加えて調整し攪拌槽内へ供給
する。攪拌槽の所定の反応温度、雰囲気条件に保ち攪拌
混合する。この時に反応により発生する重合副成物を随
時除去して行くと、反応の進行にともなって樹脂の分子
量が増加し、攪拌処理液の粘度が上昇し、塊状状態にな
り塊状重合となる。さらに反応が進むと、処理液の粘度
は攪拌装置の処理限界粘度に到達する。この限界粘度に
達した中間重合物を攪拌槽外に排出し、処理液の温度を
融点以下に下げて固化し、チップ状にする。このチップ
状になった中間重合物を別種の攪拌装置内に供給し、所
定雰囲気条件を保ち攪拌すると重合反応がさらに進行し
ていく。この固相重合反応により最終重合物が製造され
る。
Next, another manufacturing method of the high-performance resin (super engineering plastic) will be described with reference to FIG. In this process, a catalyst is added to the monomer, which is the raw material of the resin, and the monomer is adjusted and supplied into the stirring tank. Stir and mix while maintaining the reaction temperature and atmospheric conditions in the stirring tank. At this time, if the polymerization by-products generated by the reaction are removed at any time, the molecular weight of the resin increases with the progress of the reaction, the viscosity of the stirring treatment liquid increases, and a bulk state is formed, resulting in bulk polymerization. When the reaction proceeds further, the viscosity of the treatment liquid reaches the treatment limit viscosity of the stirrer. The intermediate polymer having reached this critical viscosity is discharged to the outside of the stirring tank, and the temperature of the treatment liquid is lowered to the melting point or lower to solidify to form chips. When the chip-shaped intermediate polymer is supplied into another type of stirring device and stirred under a predetermined atmospheric condition, the polymerization reaction proceeds further. The final polymerized product is produced by this solid-state polymerization reaction.

また、従来の製造プロセスの溶液重合および塊状重合に
使用される攪拌装置は通常第21図に示すように、予備重
合装置23と重合装置25とで構成されている。予備重合装
置23には低粘度用の攪拌翼24が設置されている。この予
備重合装置23は原料と触媒の攪拌混合が主体で主に低粘
度の液を処理し、低粘度用攪拌翼24にはタービン翼ある
いはパドル翼等が使用されている。予備重合装置23によ
り重合の前処理を終えた処理液は重合装置25へ供給され
る。ここで所定の反応条件を設定し重合反応を進行させ
る。この重合装置25に使用される中粘度用攪拌翼3a、3b
は通常数百Pa・sから1kPa・s(数千ポアズから1万ポ
アズ)まで処理できるリボン翼が使用されている。重合
装置25により所定の重合まで処理された重合物は、前述
したプロセスに従って次工程へ送られる。なお、この種
の装置として関連するものには例えば特開昭62−95122
号や実公昭47−38289号などが挙げられる。
Further, as shown in FIG. 21, the stirring device used for the solution polymerization and bulk polymerization in the conventional manufacturing process is usually composed of a preliminary polymerization device 23 and a polymerization device 25. The prepolymerization device 23 is provided with a stirring blade 24 for low viscosity. This prepolymerization apparatus 23 mainly processes a low-viscosity liquid by stirring and mixing the raw material and the catalyst, and a turbine blade or a paddle blade is used as the low-viscosity stirring blade 24. The treatment liquid that has undergone the pretreatment for polymerization by the prepolymerization device 23 is supplied to the polymerization device 25. Here, predetermined reaction conditions are set and the polymerization reaction proceeds. Medium viscosity stirring blades 3a, 3b used in the polymerization apparatus 25
Usually uses a ribbon blade capable of processing several hundred Pa · s to 1 kPa · s (several thousand poises to 10,000 poises). The polymerized product that has been processed by the polymerization device 25 up to a predetermined polymerization is sent to the next step according to the above-described process. A device related to this type is disclosed in, for example, Japanese Patent Laid-Open No. 62-95122.
No. and Jitsuko Sho 38-38289.

〔発明が解決しようとする課題〕[Problems to be Solved by the Invention]

上記従来技術は高粘性物質の攪拌・混合処理に関して配
慮がされておらず、被処理液が高粘度になるにつれ付着
性が激しくなり、その結果、被処理液の流動は攪拌によ
って剪断作用の大きなリボン翼部のみで作用し、剪断力
のゆき届かない攪拌槽の中心部の流動がほとんどない状
態となる。さらに被処理液の粘度が高くなればリボン翼
表面に付着する被処理液の付着力が攪拌による剪断力よ
り大きくなり、被処理液はリボン翼表面に付着したまま
動かず共回り状態となる。その結果、攪拌・混合が悪く
なり、剪断力を受けにくい攪拌軸に被処理液が付着し、
その付着物が品質劣下し、その他の被処理物と攪拌・混
合し製品の品質低下を引き起すという欠点があった。さ
らに、従来装置では1kPa・s(1万ポアズ)程度までの
粘度しか処理できないので他の高粘度性物質の処理装置
を使わなければならず、高機能樹脂の製造プロセスが複
雑となり製造時間が長くなるという欠点があった。
The above-mentioned prior art does not take into consideration the stirring / mixing treatment of highly viscous substances, and as the liquid to be treated becomes more viscous, the adhesiveness becomes stronger, and as a result, the flow of the liquid to be treated has a large shearing action by stirring. It works only by the ribbon blades, and there is almost no flow in the center of the stirring tank where the shear force does not reach. Further, when the viscosity of the liquid to be treated becomes higher, the adhesive force of the liquid to be treated adhered to the surface of the ribbon blade becomes larger than the shearing force due to the stirring, and the liquid to be treated remains attached to the surface of the ribbon blade and does not move but corotates. As a result, stirring and mixing deteriorate, and the liquid to be treated adheres to the stirring shaft that is less susceptible to shearing force.
There is a drawback that the quality of the adhered matter deteriorates and the quality of the product is deteriorated by stirring and mixing with other processed objects. Furthermore, since the conventional equipment can only handle viscosities up to about 1 kPa · s (10,000 poise), it is necessary to use treatment equipment for other highly viscous substances, which complicates the manufacturing process for high-performance resins and lengthens the manufacturing time. There was a drawback that

本発明の目的は被処理液の滞留部分が少なく、品質向上
が図れる高粘性物質の製造装置を提供することにある。
It is an object of the present invention to provide an apparatus for producing a highly viscous substance, which has a small amount of retained liquid and can improve quality.

本発明の他の目的は高機能樹脂の製造に高粘度液まで処
理できる攪拌装置を使用することにより、製造プロセス
を簡略化することである。
Another object of the present invention is to simplify the manufacturing process by using a stirrer capable of processing even a high-viscosity liquid in the manufacture of a highly functional resin.

本発明の他の目的は高機能樹脂の製造装置を簡略化し、
装置価格を低減することにある。
Another object of the present invention is to simplify a high-performance resin manufacturing apparatus,
It is to reduce the equipment price.

さらに、本発明の他の目的は本発明の高粘性物質の製造
装置を用い、容器内の循環流れを促進させ、表面更新性
能を向上できる重縮合系高分子等の製造装置及び方法を
提供することにある。
Further, another object of the present invention is to provide an apparatus and method for producing a polycondensation polymer or the like, which uses the apparatus for producing a highly viscous substance of the present invention, promotes a circulating flow in a container, and can improve surface renewal performance. Especially.

さらに、本発明の他の目的は本発明の装置を用い、容器
内の伝熱作用を促進することにより、重合熱の除去効果
を高めた付加重合系高分子等の製造装置及び方法を提供
することにある。
Further, another object of the present invention is to provide an apparatus and a method for producing an addition-polymerized polymer or the like, which uses the apparatus of the present invention to promote the heat transfer action in the container to enhance the effect of removing the heat of polymerization. Especially.

〔課題を解決するための手段〕[Means for Solving the Problems]

上記目的を達成するために、回転軸をなくし、矩形状の
枠を連結して攪拌翼を構成したものである。
In order to achieve the above object, the stirring shaft is formed by eliminating the rotating shaft and connecting rectangular frames.

また、被処理液の循環流形成のために、矩形状の枠の水
平方向部材を回転方向にねじりを加えて矩形枠の側面部
材を傾斜させて複数個連結し、攪拌翼を構成したもので
ある。
Further, in order to form a circulating flow of the liquid to be treated, a horizontal blade of a rectangular frame is twisted in the rotational direction to incline the side members of the rectangular frame, and a plurality of them are connected to form a stirring blade. is there.

さらに、高粘性物質の排出作業改良のために、攪拌装置
に槽内加圧装置と被処理液の抜出し機構とを設ける構成
としたものである。
Further, in order to improve the discharge work of the highly viscous substance, the agitating device is provided with a tank pressurizing device and a liquid extraction mechanism for the liquid to be treated.

さらに、高粘性物質の排出作業改良のために、攪拌槽下
部の形状を円錐状(コーン状)としたものである。
Further, in order to improve the discharge work of the highly viscous substance, the lower part of the stirring tank has a conical shape.

さらに、高粘性物質の攪拌中に被処理液が槽上部へかき
上げられ滞留部分を形成するのを防止するために、槽上
部の攪拌翼の傾きを下部側の攪拌翼の傾きと逆向きにし
たものである。
Furthermore, in order to prevent the liquid to be treated from being lifted up to the upper part of the tank and forming a retention part while stirring the highly viscous substance, the inclination of the stirring blade on the upper part of the tank is set in the opposite direction to the inclination of the stirring blade on the lower side. It was done.

さらに、上記目的を達成するために重合反応装置に、矩
形状枠部材を連結した攪拌翼を具備する攪拌装置を使用
したものである。
Further, in order to achieve the above-mentioned object, a stirring device having stirring blades connected to a rectangular frame member is used as the polymerization reaction device.

さらに、上記目的達成のために重合反応、特に付加重合
系高分子の製造時に発生する重合熱の除去効果を高める
ように、攪拌翼部材中に熱媒を流通させる構造としたも
のである。
Further, in order to achieve the above object, a heating medium is circulated in the stirring blade member so as to enhance the effect of removing the polymerization heat generated during the polymerization reaction, particularly the addition polymerization type polymer.

〔作用〕[Action]

撹拌翼構造を回転軸のない矩形状枠の連結構造とするこ
とにより、被処理液が回転軸に付着するのを防止でき、
さらに、複数個連結する矩形状枠の水平方向の翼部材間
の取付角度を回転方向にねじって攪拌翼を構成すること
により、槽壁面を上昇し、槽中央部を下降する循環流を
容易に形成することができるので滞留部の少ない攪拌装
置を提供することができる。
By setting the stirring blade structure to a connecting structure of rectangular frames without a rotating shaft, it is possible to prevent the liquid to be treated from adhering to the rotating shaft,
Further, by constructing a stirring blade by twisting the mounting angle between the horizontal blade members of the rectangular frame connecting a plurality of them in the rotation direction, the circulation flow that rises the tank wall surface and descends the tank center part is facilitated. Since it can be formed, it is possible to provide a stirrer having a small retention portion.

さらに、高粘度液を処理する際に問題となる軸への処理
液の付着、共回り現象が起らないので高粘度の攪拌が可
能となる。このため、従来プロセスでは攪拌粘度を下げ
て処理するか、あるいは途中から別種の攪拌装置を使用
する必要があったが、本攪拌装置を使用すれば、高粘度
の最終重合物まで同一の攪拌装置で製造できるので製造
プロセスが簡略化できる。
Further, since the treatment liquid does not adhere to the shaft and the co-rotation phenomenon does not occur which is a problem when treating the high viscosity liquid, stirring with high viscosity can be performed. For this reason, in the conventional process, it was necessary to reduce the stirring viscosity for processing or use a stirring device of a different type from the middle, but if this stirring device is used, even the high-viscosity final polymerized product can be obtained with the same stirring device. Since it can be manufactured by, the manufacturing process can be simplified.

さらに、攪拌槽下部に設けた被処理液を抜き出す排出機
構と攪拌槽に設けた槽内を加圧する加圧機構とを併用す
ることにより、被処理液の排出時間が短縮できる。
Further, the discharge time of the liquid to be treated can be shortened by using the discharge mechanism for discharging the liquid to be treated provided in the lower part of the stirring tank and the pressurizing mechanism provided in the stirring tank for pressurizing the inside of the tank.

〔実施例〕〔Example〕

以下、本発明の一実施例を第1図、第2図により説明す
る。図において、攪拌槽本体1は円形断面を有する円筒
状の容器であり、図示はしないが外側は加熱冷却可能な
熱媒ジャケットを有している。攪拌翼は回転動力伝達軸
(以下、回転耳軸と呼ぶ)2および攪拌翼部材8a、8b、
8c、8d、9a、9b、9cを組み合せ連結して矩形状の枠を構
成し、この枠をθ度ずつずらし接続し一本の攪拌翼構成
要素(格子翼)を形成する。第2図に示したように本実
施例ではθが90度の場合について図示しているが、θの
値については任意の値を取っても良い。また、攪拌翼部
材8a、8b、8c、8dおよび9a、9b、9c、9d、9fは丸棒ある
いは板状部材等が使用される。
An embodiment of the present invention will be described below with reference to FIGS. 1 and 2. In the figure, the stirring tank main body 1 is a cylindrical container having a circular cross section, and although not shown, the outside has a heating medium jacket capable of heating and cooling. The stirring blade includes a rotary power transmission shaft (hereinafter, referred to as a rotating ear shaft) 2 and stirring blade members 8a, 8b,
8c, 8d, 9a, 9b and 9c are combined and connected to form a rectangular frame, and the frames are shifted by θ degrees and connected to form one stirring blade constituent element (lattice blade). As shown in FIG. 2, the present embodiment illustrates the case where θ is 90 degrees, but the value of θ may be any value. As the stirring blade members 8a, 8b, 8c, 8d and 9a, 9b, 9c, 9d, 9f, round rods or plate members are used.

以上の構成において、高粘性物質の攪拌作用について説
明する。回転耳軸2により攪拌翼部材8aに回転が伝えら
れる。攪拌翼部材8a、8b、9a、9dにより構成された矩形
状枠は攪拌槽本体1の内壁にそって回転し、被処理液を
攪拌・混合する。水平方向に設置された攪拌翼部材8a、
8b、8c、8dは槽内を水平方向に回転し、半径方向の攪拌
混合に寄与する。また垂直方向の攪拌翼部材9a、9d、9
b、9c、9e、9fは槽壁面を槽壁面をくまなく掻き取るの
で被処理液の滞留部分がなくなる。さらにこの矩形状の
攪拌翼要素と次の矩形状の攪拌翼要素とは取付角度θを
もって取付けられており、さらに次の矩形状の攪拌要素
も取付角度θをもって連続して構成されている。従って
水平方向の攪拌翼部材8a、8b、8c、8dおよび垂直方向の
部材9a、9b、9c、9d、9e、9fでそれぞれ高粘度液を攪拌
・混合した場合にそれぞれの翼部材の位置は槽内のそれ
ぞれの位置に分布しているので、攪拌によってできる被
処理液の形状は複雑な形となり、槽の容積に対する被処
理液の表面積の割合が増加する。このことは例えば、重
合反応操作においては揮発物の脱ガス性能の向上につな
がる。また回転軸が無いため高粘度の被処理物質の付着
滞留がなくなり良好な攪拌・混合性能が得られる。本実
施例では攪拌翼部材9a、9b、9c、9d、9e、9fに丸棒を用
いた場合を示しているが板状の部材等を使用しても同様
の効果が得られる。
The stirring action of the highly viscous substance in the above configuration will be described. Rotation is transmitted to the stirring blade member 8a by the rotating shaft 2. The rectangular frame constituted by the stirring blade members 8a, 8b, 9a, 9d rotates along the inner wall of the stirring tank main body 1 to stir and mix the liquid to be treated. A stirring blade member 8a installed in a horizontal direction,
8b, 8c, and 8d rotate horizontally in the tank and contribute to stirring and mixing in the radial direction. The vertical stirring blade members 9a, 9d, 9
In b, 9c, 9e, and 9f, since the tank wall surface is scraped all over the tank wall surface, there is no retained portion of the liquid to be treated. Further, the rectangular stirring blade element and the next rectangular stirring blade element are attached at an attachment angle θ, and the next rectangular stirring element is also continuously formed at the attachment angle θ. Therefore, when the high-viscosity liquid is stirred and mixed by the horizontal stirring blade members 8a, 8b, 8c, 8d and the vertical members 9a, 9b, 9c, 9d, 9e, 9f, the position of each blade member is the tank. Since the liquid is distributed to each position inside, the shape of the liquid to be treated formed by stirring becomes complicated, and the ratio of the surface area of the liquid to be treated to the volume of the tank increases. This leads, for example, to an improvement in the degassing performance of volatiles in the polymerization reaction operation. Further, since there is no rotary shaft, high-viscosity substances to be treated do not adhere and accumulate, and good stirring and mixing performance can be obtained. In this embodiment, the round blades are used for the stirring blade members 9a, 9b, 9c, 9d, 9e, 9f, but the same effect can be obtained by using plate members.

つぎに、本発明の他の実施例について第3図および第4
図により説明する。図において、攪拌槽本体1は円形断
面を有する円筒状の容器であり図示はしないが外側は加
熱冷却可能な熱媒ジャケットを有している。攪拌翼は回
転耳軸2および攪拌翼部材8a、8b、9a、9dを組合せて連
結し矩形状の枠を構成し一つの攪拌翼構成要素(格子
翼)を形成する。攪拌翼構成要素のうちで水平方向に設
置される攪拌翼部材8a、8bは槽中心部を回転中心として
θほど回転方向にねじった位置にあり、槽壁面をくま
なくかきとるように形成された垂直方向の攪拌翼部材9
a、9dとそれぞれ結合している。つぎの攪拌翼構成要素
も同様の形状となっており、水平方向の攪拌翼部材8bと
8eとは取付け角度θで結合されている。さらにつぎの
攪拌翼構成要素も同様の角度で取り付けられ一本の攪拌
翼を形成している。図示した形状は取付け角度θが90
度の場合を示しているが、θ、θは任意の角度を設
定してもよい。また攪拌翼部材8a、8b、8c、8d、8e、8f
および9a、9b、9c、9d、9e、9fは丸棒あるいは板状部材
等が使用される。以上の構成において、高粘性物質の攪
拌作用について説明する。回転耳軸2により攪拌翼部材
8aに回転が伝えられる。攪拌翼部材8a、8b、9a、9dによ
り構成された矩形状枠は攪拌槽本体1の内壁にそって回
転し、被処理液を攪拌・混合する。水平方向に設置され
た攪拌翼部材8a、8bは槽内を水平方向に回転し、半径方
向の攪拌・混合に寄与する。また槽内壁面にそって壁面
をかきとりながら回転する攪拌翼部材9a、9dは攪拌翼部
材8a、8bが回転方向に位相をθほど進めて取付けてい
るので回転によって槽壁面付近の被処理液を上方へかき
上げる力が作用する。従ってこの攪拌翼構成要素が回転
することにより槽周辺部の被処理液には上方への流れが
生じ、それにより槽中央部は下方への流れが発生する。
さらにこの攪拌翼構成要素は次の攪拌翼構成要素と取付
角度θを保って結合しており、さらに次の攪拌翼構成
要素も同様に結合して攪拌翼を形成する。従って、それ
ぞれの攪拌翼構成要素により槽内壁面付近には槽下部か
ら上方へ向う流れが発生し、槽中央部は槽上方から下方
へ向う流れができるので、槽全体に循環流ができ被処理
液の滞留部分が無くなり良好な攪拌・混合が得られる。
ここで本実施例の攪拌装置の槽壁面付近の被処理液の流
れについて第5図により説明する。本発明内容は特に被
処理液が数万ポアズのような高粘度の場合に適してい
る。第5図は第3図に示した装置の攪拌槽本体1の円筒
内周壁面を平面に展開した場合を示している。図におい
て、矩形枠の攪拌翼部材9a、9d、9b、9e、9f、9cはそれ
ぞれ回転位相角度θがあるので、攪拌翼の進行方向に
対して後方へ傾いた勾配を持っている。この状態で攪拌
翼を回転させると攪拌翼部材9aの前面に被処理液15のか
たまりが形成される。攪拌翼が回転するに従って被処理
液のかたまりは全体が上方に押し上げられて行く。
Next, another embodiment of the present invention will be described with reference to FIGS.
It will be described with reference to the drawings. In the figure, the stirring tank main body 1 is a cylindrical container having a circular cross section, and although not shown, the outside has a heating medium jacket capable of heating and cooling. The stirring blade forms a rectangular frame by combining and connecting the rotating shaft 2 and the stirring blade members 8a, 8b, 9a, 9d to form one stirring blade constituent element (lattice blade). Of the constituent elements of the stirring blade, the stirring blade members 8a and 8b installed horizontally are twisted in the direction of rotation by θ 2 with the center of the tank as the center of rotation, and are formed so as to scratch the wall surface of the tank. Vertical stirring blade member 9
It is connected to a and 9d respectively. The next stirring blade components also have the same shape, and the horizontal stirring blade member 8b and
It is connected to 8e at a mounting angle θ 1 . Further, the next stirring blade component is also attached at the same angle to form one stirring blade. The illustrated shape has a mounting angle θ 1 of 90.
Although the case of degrees is shown, θ 1 and θ 2 may be set to arbitrary angles. Also, the stirring blade members 8a, 8b, 8c, 8d, 8e, 8f
For 9a, 9b, 9c, 9d, 9e and 9f, a round bar or a plate-shaped member is used. The stirring action of the highly viscous substance in the above configuration will be described. Stirrer blade member by rotating shaft 2
The rotation is transmitted to 8a. The rectangular frame constituted by the stirring blade members 8a, 8b, 9a, 9d rotates along the inner wall of the stirring tank main body 1 to stir and mix the liquid to be treated. The stirring blade members 8a and 8b installed in the horizontal direction rotate horizontally in the tank and contribute to the radial stirring and mixing. The stirring blade members 9a and 9d, which rotate while scraping the wall surface along the inner wall surface of the tank, are attached by advancing the phase of the stirring blade members 8a and 8b by θ 2 in the rotation direction, so that the liquid to be treated near the wall surface of the tank is rotated. The force to lift the Therefore, the rotation of the stirring blade component causes an upward flow of the liquid to be treated in the peripheral portion of the tank, which causes a downward flow in the central portion of the tank.
Further, this stirring blade constituent element is connected to the next stirring blade constituent element while maintaining the mounting angle θ 1 , and the next stirring blade constituent element is also similarly connected to form the stirring blade. Therefore, each stirring blade component causes a flow upward from the lower part of the tank near the inner wall surface of the tank, and a flow from the upper part to the lower part of the tank in the center part of the tank. No stagnant portion of liquid is obtained, and good stirring and mixing can be obtained.
Here, the flow of the liquid to be treated in the vicinity of the wall surface of the stirring apparatus of this embodiment will be described with reference to FIG. The present invention is particularly suitable when the liquid to be treated has a high viscosity such as tens of thousands of poise. FIG. 5 shows a case where the cylindrical inner peripheral wall surface of the stirring tank main body 1 of the apparatus shown in FIG. In the figure, each of the stirring blade members 9a, 9d, 9b, 9e, 9f, 9c having a rectangular frame has a rotation phase angle θ 2 and therefore has a gradient inclined rearward with respect to the traveling direction of the stirring blade. When the stirring blade is rotated in this state, a mass of the liquid to be treated 15 is formed on the front surface of the stirring blade member 9a. As the stirring blade rotates, the entire mass of the liquid to be treated is pushed upward.

この時被処理液15は攪拌翼部材9aの前面で混合されてい
る。本実施例では攪拌翼部材9a、9d、9b、9e、9f、9cが
それぞれ分割されて槽内に分布している。従って、例え
ば攪拌翼部材9bによって混合されている被処理液の一部
は攪拌翼部材の上端および下端から後方へあふれ出てい
る。このあふれ出た被処理液の一部はあとから進んでく
る攪拌翼部材9aと9fによって攪拌・混合処理している被
処理液とそれぞれ合流して混合し、槽内全体の均一攪拌
・混合性能の向上に寄与する。また第22図に第21図に示
した従来装置のリボン翼を平面に展開した場合について
示す。従来の攪拌槽3a、3bはそれぞれ槽内に連続して設
置されている。従って従来の攪拌翼では被処理液は攪拌
翼部材3a、3bの前面のみで攪拌・混合しながら液全体が
上部側へ押し上げられ攪拌している。被処理液の粘度が
高くなると被処理液の付着力が増加し攪拌翼部3a、3bの
表面に付着し上部側への移動も少なくなり、被処理液が
共回りの状態となり攪拌・混合性能は低下する。前述の
第5図の方式では攪拌翼部材が分割しているので共回り
を起しにくい。また、攪拌翼部材は槽内全体に均一に分
布しているので、攪拌によってできる被処理液の形状は
複雑な形となり、槽の容積に対する液の表面積の割合が
増加し揮発物成分の脱ガス性能の向上につながり、重合
反応操作においては反応時間を短縮できる利点がある。
また回転軸が無いので高粘度処理物質の付着滞留が無く
なり良好な攪拌性能が得られる。本実施例では攪拌翼部
材に丸棒を用いた場合について示しているが、板状の部
材等を使用しても同様の効果が得られる。
At this time, the liquid to be treated 15 is mixed on the front surface of the stirring blade member 9a. In this embodiment, the stirring blade members 9a, 9d, 9b, 9e, 9f, 9c are divided and distributed in the tank. Therefore, for example, part of the liquid to be treated mixed by the stirring blade member 9b overflows rearward from the upper and lower ends of the stirring blade member. A part of this overflowed liquid to be processed merges and mixes with the liquid to be stirred and mixed by the stirring blade members 9a and 9f, which are advancing afterwards, and mixes to obtain uniform stirring and mixing performance in the entire tank. Contribute to the improvement of. Further, FIG. 22 shows a case where the ribbon blade of the conventional apparatus shown in FIG. 21 is developed on a plane. The conventional stirring tanks 3a and 3b are continuously installed in each tank. Therefore, in the conventional stirring blade, the liquid to be treated is pushed up and stirred with the whole liquid while stirring and mixing only the front surfaces of the stirring blade members 3a and 3b. When the viscosity of the liquid to be treated increases, the adhesive force of the liquid to be treated increases and adheres to the surfaces of the stirring blades 3a and 3b, and the movement to the upper side also decreases, and the liquid to be treated becomes a co-rotating state and the stirring / mixing performance Will fall. In the system shown in FIG. 5 described above, since the stirring blade member is divided, it is difficult to cause co-rotation. Further, since the stirring blade members are evenly distributed in the whole tank, the shape of the liquid to be treated by stirring becomes complicated, and the ratio of the surface area of the liquid to the tank volume increases to degas volatile components. This has the advantage of improving the performance and shortening the reaction time in the polymerization reaction operation.
In addition, since there is no rotating shaft, high-viscosity treated substances do not adhere and accumulate, and good stirring performance can be obtained. In this embodiment, a round bar is used as the stirring blade member, but the same effect can be obtained by using a plate member or the like.

つぎに本発明の他の実施例について第6図、第7図によ
り説明する。本実施例は基本的構成部材および動作につ
いては前述の実施例と同一であり同様の効果がある。本
実施例では特に攪拌翼構成要素の攪拌翼構成部材8aと8b
の取付位相θを90度とした場合を示す。さらに攪拌翼構
成部材9aと9dは板状のリボン翼とし、この攪拌翼構成要
素を取付角度θを90度で連結して攪拌翼としたもので
ある。攪拌翼構成部材にリボン翼を使用したことにより
処理液のかき上げ作用がさらに大きくなり槽全体の循環
流が強くなり良好な混合・攪拌効果が得られる。また、
リボン翼を槽壁面に断続的に配置しているので、リボン
翼を連続的に構成した場合より、攪拌翼に被処理液が付
着し滞留する量が減少し、攪拌・混合性能が向上する。
Next, another embodiment of the present invention will be described with reference to FIGS. This embodiment is the same as the above-mentioned embodiments in terms of basic components and operation, and has the same effect. In this embodiment, in particular, the stirring blade constituent members 8a and 8b of the stirring blade constituent elements.
The case where the mounting phase θ of is set to 90 degrees is shown. Further, the stirring blade constituent members 9a and 9d are plate-shaped ribbon blades, and the stirring blade constituent elements are connected at a mounting angle θ 1 of 90 degrees to form a stirring blade. By using the ribbon blade as the stirring blade constituent member, the scraping action of the treatment liquid is further increased, and the circulation flow in the entire tank is strengthened, so that good mixing and stirring effects can be obtained. Also,
Since the ribbon blades are intermittently arranged on the wall surface of the tank, the amount of the liquid to be treated adhering to and staying on the stirring blades is reduced as compared with the case where the ribbon blades are continuously configured, and the stirring / mixing performance is improved.

つぎに本発明の他の実施例について第8図、第9図によ
り説明する。本実施例は基本的構成部材および動作につ
いては前述の実施例と同一であり、同様の効果が得られ
る。本実施例では特に攪拌槽本体1の下部形状を円錐状
とし、この円錐状の槽壁にそうように矩形形状を形成し
たものである。本構造により被処理液の排出時に被処理
液の排出が容易となり短時間で排出できる効果がある。
Next, another embodiment of the present invention will be described with reference to FIGS. This embodiment is the same as the above-mentioned embodiment in terms of basic constituent members and operation, and similar effects can be obtained. In this embodiment, in particular, the lower part of the stirring tank main body 1 has a conical shape, and the rectangular shape is formed on the conical tank wall. With this structure, the liquid to be processed can be easily discharged when the liquid to be processed is discharged, and the liquid can be discharged in a short time.

また本実施例では攪拌槽本体1の下部形状を円錐状と
し、この円錐部頂点に排出装置10を備え、供給口上流側
に槽内を加圧できる加圧装置11を設けている。攪拌翼は
円錐状の槽壁にそうように矩形形状を形成している。ま
た攪拌翼部材8a、8bは槽中心部を回転中心としてθ
ど回転方向にねじった位置にあり、槽壁面をくまなくか
きとるように形成された垂直方向部材9a,9dとそれぞれ
結合している。つぎの攪拌翼構成要素も同様の形状とな
っており水平方向部材8bと8eは取付角度θで結合され
以下の攪拌翼構成要素も同様に結合して攪拌翼を形成し
ている。本実施例では攪拌あるいは反応操作終了後処理
液を排出する際、攪拌翼を反応操作の時と逆方向に回転
させると同時に排出装置10を運転させ、さらに加圧装置
11により槽内を加圧し排出処理を行う。本方式によれば
攪拌翼を逆転させるので被処理液は槽壁面下方へ押し下
げられ槽下部へ集中する。さらに槽内は加圧状態にある
ので排出装置10への供給が容易となり被処理液の排出時
間が短縮できる利点がある。
Further, in the present embodiment, the lower part of the stirring tank main body 1 has a conical shape, the discharging device 10 is provided at the apex of this conical portion, and the pressurizing device 11 capable of pressurizing the inside of the tank is provided on the upstream side of the supply port. The stirring blades thus form a rectangular shape on the conical vessel wall. The stirring blade members 8a and 8b are located at a position twisted in the direction of rotation by θ 2 with the center of the tank as the center of rotation, and are connected to vertical members 9a and 9d formed so as to scrape the wall surface of the tank, respectively. There is. The next stirring blade component has the same shape, and the horizontal members 8b and 8e are connected at an attachment angle θ 1 and the following stirring blade components are similarly connected to form a stirring blade. In this embodiment, when the processing liquid is discharged after completion of the stirring or reaction operation, the stirring blade is rotated in a direction opposite to that in the reaction operation, and at the same time, the discharging device 10 is operated, and the pressurizing device is further operated.
The inside of the tank is pressurized by 11 and discharge processing is performed. According to this method, the stirring blade is reversed, so that the liquid to be treated is pushed down below the wall surface of the tank and concentrated in the lower part of the tank. Further, since the inside of the tank is in a pressurized state, it is easy to supply it to the discharge device 10, and there is an advantage that the discharge time of the liquid to be treated can be shortened.

また本実施例では特に攪拌翼構成部材のうち槽壁面をか
き取る攪拌翼部材の両端(9a1、9a2、9d1、9d2、9b1、9
b2、9e1、9e2、9c1、9f1)を水平方向の攪拌翼部材との
結合部よりそれぞれ上方および下方へ伸ばして攪拌翼構
成要素を構成し、これらの攪拌翼構成要素を連結して攪
拌翼としている。本構成の立形攪拌装置の槽壁面付近の
被処理液の流れについて説明する。第10図は第8図に示
した装置の円筒円周壁面を平面に展開した場合を示して
いる。第10図は第5図で説明した内容とほとんど同一で
あるので詳細な説明は省略する。本実施例においては特
に攪拌翼部材9a、9d、9b、9e、9f、9cがそれぞれ分割さ
れて槽内に分布し、しかも攪拌翼部材端がおのおのの翼
の軌跡の内側へ入り込んでいるので、攪拌翼部材両端か
ら後方へあふれ出る被処理液と後方の攪拌翼部材前面の
被処理液との混合がさらに改善されるので槽内全体の均
一攪拌・混合性能の向上に寄与する。また、翼部材の端
部9a1、9d1の取付角度は9a、dの翼部材の傾きと逆向き
に形成すれば、処理液が槽上部へ付着滞留するのを防止
する効果もある。尚、本実例では排出装置10はスクリュ
ー式で図示したが、本発明はこれに限定されるものでは
ない。即ち、スクリューの先端部に吐出弁を設けて吐出
装置10を構成しても良い。
Further, particularly in this embodiment, both ends (9a 1 , 9a 2 , 9d 1 , 9d 2 , 9b 1 , 9b of the stirring blade member for scraping the tank wall surface among the stirring blade constituent members are used.
b 2 , 9e 1 , 9e 2 , 9c 1 , 9f 1 ) are extended upward and downward respectively from the joint with the horizontal stirring blade member to form a stirring blade constituent element, and these stirring blade constituent elements are connected. And then use it as a stirring blade. The flow of the liquid to be treated in the vicinity of the wall surface of the vertical stirrer of this configuration will be described. FIG. 10 shows a case where the cylindrical circumferential wall surface of the apparatus shown in FIG. 8 is developed on a plane. Since FIG. 10 is almost the same as the content described with reference to FIG. 5, detailed description will be omitted. In this embodiment, in particular, the stirring blade members 9a, 9d, 9b, 9e, 9f, 9c are each divided and distributed in the tank, and since the stirring blade member ends enter the inside of the trajectory of each blade, The mixing of the liquid to be treated overflowing rearward from both ends of the stirring blade member and the liquid to be treated on the front surface of the rear stirring blade member is further improved, which contributes to improvement of uniform stirring / mixing performance in the entire tank. Further, if the mounting angles of the end portions 9a 1 and 9d 1 of the blade members are formed in the direction opposite to the inclination of the blade members 9a and 9d, there is also an effect of preventing the processing liquid from adhering and accumulating on the upper part of the tank. Although the discharging device 10 is illustrated as a screw type in this example, the present invention is not limited to this. That is, the discharge device 10 may be configured by providing a discharge valve at the tip of the screw.

つぎに本発明の他の実施例について第11図により説明す
る。本実施例は基本的構成部材および動作については前
述の実施例と同一であり同様の効果が得られる。本実施
例では特に攪拌槽本体1の形状を円錐状(コーン状)と
し、それと共に攪拌翼形状も槽壁面に沿うように円錐状
としている。本実施例の形状にすることにより、被処理
液は攪拌中には槽壁面に沿って拡がり、円筒状の槽より
も上部の槽断面積が大きいので被処理液の容積当りの表
面積が増加して表面更新作用が改善される。高粘度液の
重合反応操作においては表面更新性能が反応時間の律速
となり、本性能の改善は反応時間の短縮に寄与する。
Next, another embodiment of the present invention will be described with reference to FIG. This embodiment is the same as the above-mentioned embodiments in terms of basic components and operation, and similar effects can be obtained. In this embodiment, in particular, the shape of the stirring tank body 1 is conical (conical), and the stirring blade shape is also conical so as to follow the wall surface of the tank. With the shape of this example, the liquid to be treated spreads along the wall surface of the tank during stirring, and the tank cross-sectional area at the upper part is larger than that of the cylindrical tank, so that the surface area per volume of the liquid to be processed increases. The surface renewal effect is improved. In the polymerization reaction operation of a high-viscosity liquid, the surface renewal performance is the rate-determining reaction time, and improvement of this performance contributes to shortening the reaction time.

つぎに本発明の他の実施例について第12図により説明す
る。本実施例は基本的構成部材および動作については前
述の実施例と同一であり同様の効果が得られる。本実施
例では特に攪拌翼構成要素の矩形状枠の内部へ垂直方向
に補強部材20a、20dをまた別の矩形状枠には20e、20bを
取り付け、おのおのの攪拌翼構成要素の剛性を強化した
ものである。本補強部材を取り付けることにより、攪拌
翼の強度向上と共に、矩形状枠内の攪拌・混合が改善で
き、攪拌・混合性能の向上に寄与する。
Next, another embodiment of the present invention will be described with reference to FIG. This embodiment is the same as the above-mentioned embodiments in terms of basic components and operation, and similar effects can be obtained. In this embodiment, in particular, reinforcing members 20a and 20d are attached vertically to the inside of the rectangular frame of the stirring blade constituents and 20e and 20b are attached to the other rectangular frames to enhance the rigidity of each stirring blade constituent. It is a thing. By attaching this reinforcing member, it is possible to improve the strength of the stirring blade and improve stirring / mixing in the rectangular frame, which contributes to improvement of stirring / mixing performance.

つぎに本発明の他の実施例について第13図、第14図によ
り説明する。本実施例は基本的構成部材および動作につ
いては前述の実施例と同一であり同様の効果が得られ
る。本実施例では特に攪拌翼構成要素のうち回転耳軸2
と連結する部分に攪拌翼構成要素を8a、9a、8b、9bと8
g、21b、8e、21aとの二組で連結して攪拌翼を構成す
る。本構成により攪拌動力の伝達部の部材の数が増える
ので攪拌翼の剛性が強化されるものである。また図示は
しないがさらに攪拌翼構成要素を8bと8cとの間を連結し
ても同様の効果が得られる。
Next, another embodiment of the present invention will be described with reference to FIGS. This embodiment is the same as the above-mentioned embodiments in terms of basic components and operation, and similar effects can be obtained. In the present embodiment, particularly, the rotating ear shaft 2 among the components of the stirring blade is used.
8a, 9a, 8b, 9b and 8
Two sets of g, 21b, 8e, and 21a are connected to form a stirring blade. With this configuration, the number of members of the stirring power transmission portion is increased, so that the rigidity of the stirring blade is enhanced. Although not shown, the same effect can be obtained by further connecting the stirring blade constituent elements between 8b and 8c.

つぎの本発明の他の実施例について第15図および第16図
により説明する。本実施例は基本的構成部材および動作
については前述の実施例と同一であり同様の効果が得ら
れる。とくに本実施例では攪拌・混合操作において、特
に数kPa・s(数万ポアズ)の被処理液を処理する際に
は槽壁面をかき上げた被処理液が槽上部に滞留し均一な
攪拌が困難となる現象を防止するため、攪拌翼上部の攪
拌翼構成要素のうち水平方向の攪拌翼部材8a、8bの取付
位相角度を回転方向と逆向きにθだけねじって攪拌翼
構成要素を形成する。本構成にすると攪拌槽壁面をかき
とる攪拌翼部材9a、9dの傾きは攪拌翼が運転方向に回転
すると槽壁面の処理液を下方へ押し下げるように作用す
る。従って下方の攪拌翼構成要素からは被処理液を槽壁
面にそって上方へ押し上げるように作用し、上部の攪拌
翼構成要素では被処理液を押し下げるので被処理液が槽
上部付近に滞留するのを防止でき、良好な攪拌・混合性
能が得られる。
Another embodiment of the present invention will be described below with reference to FIGS. 15 and 16. This embodiment is the same as the above-mentioned embodiments in terms of basic components and operation, and similar effects can be obtained. In particular, in the present example, in the stirring / mixing operation, particularly when treating a liquid to be treated of several kPa · s (tens of thousands of poise), the liquid to be treated, which has been scratched up from the wall surface of the tank, stays in the upper part of the tank and is uniformly stirred. In order to prevent a difficult phenomenon, the stirring blade constituent elements are formed by twisting the installation phase angle of the stirring blade members 8a and 8b in the horizontal direction of the stirring blade constituent elements above the stirring blade by θ 2 in the direction opposite to the rotation direction. To do. With this configuration, the inclination of the stirring blade members 9a and 9d that scrape the wall surface of the stirring tank acts so as to push down the processing liquid on the wall surface of the tank when the stirring blade rotates in the operating direction. Therefore, the lower stirring blade component acts to push the liquid to be treated upward along the wall surface of the tank, and the upper stirring blade component pushes down the liquid to be treated, so that the liquid to be treated stays near the upper portion of the tank. Can be prevented and good stirring / mixing performance can be obtained.

本発明の他の実施例について第17図、第18図により説明
する。本実施例は攪拌翼構成部材を中空に形成し、回転
耳軸2を二重管として回転耳軸2の上端にロータリージ
ョイント50を備えたものがある。本実施例ではロータリ
ージョイント50より攪拌翼構成部材8a、9a、8b、8e、9b
さらに9e、8e、8b、9bと内部に伝熱媒体を供給して流通
させることができるので、被処理液の加熱および冷却操
作が急速にでき、重合の処理時間が短縮できる。
Another embodiment of the present invention will be described with reference to FIGS. In the present embodiment, there is one in which the stirring blade constituting member is formed hollow and the rotary shaft 2 is a double tube and the rotary joint 50 is provided at the upper end of the rotary shaft 2. In this embodiment, the rotary joint 50 causes the stirring blade constituent members 8a, 9a, 8b, 8e, 9b.
Furthermore, since the heat transfer medium can be supplied to and circulated through 9e, 8e, 8b and 9b, the heating and cooling operations of the liquid to be treated can be performed rapidly, and the treatment time of the polymerization can be shortened.

また、処理液の排出時には、攪拌翼構成部材内部へ熱媒
を供給することにより、攪拌翼表面に付着する液量を減
少させることができる。
Further, at the time of discharging the treatment liquid, the amount of liquid adhering to the surface of the stirring blade can be reduced by supplying the heat medium to the inside of the stirring blade constituent member.

さらに他の実施例では、被処理液の粘度変化を回転耳軸
2の回転トルク検出により検知して、粘度に応じて回転
耳軸2の回転数を変えたものがある。本実施例では、被
処理液の粘度が低い時には回転数を高めて、強力な攪拌
ができ、粘度が高い時には回転数を下げてトルク過大が
防止できる。この場合、被処理液の粘度の検知は、回転
トルク以外に予備ノズル(図示せず)より一定時間毎に
サンプリングして直接測定することも可能である。
In still another embodiment, there is a method in which a change in the viscosity of the liquid to be treated is detected by detecting the rotation torque of the rotating shaft 2, and the rotation speed of the rotating shaft 2 is changed according to the viscosity. In this embodiment, when the viscosity of the liquid to be treated is low, the rotation speed can be increased to perform strong stirring, and when the viscosity is high, the rotation speed can be decreased to prevent excessive torque. In this case, the viscosity of the liquid to be treated can be directly measured by sampling from a preliminary nozzle (not shown) at regular intervals other than the rotation torque.

つぎに本装置を用いた高粘性物質の製造方法の他の実施
例を第8図及び第19図により説明する。第19図は本発明
の高機能樹脂(高粘性物質)の製造プロセスの概略フロ
ーを示す。高粘性物質の原料であるモノマーと触媒とを
混合し、付加重合反応あるいは縮重合反応により目的の
最終重合物を塊状重合で製造するものである。高機能樹
脂は重合度を増加させるので溶融粘度が増加し、最終重
合物の溶融粘度は数kPa・s(数万ポアズ)のまで上昇
する。通常の攪拌装置で数kPa・s(数万ポアズ)の液
を処理すると、混合・攪拌性能が悪いため、製品の重合
度分布が大きくばらつき、品質が大幅が低下してくる。
そこで第8図に示す高粘性物質の攪拌装置を用い、攪拌
性能を悪化させないで最終重合物まで処理する。第8
図、第9図に示した高粘性物質の攪拌装置の構成及び作
用は前述したので省略する。
Next, another embodiment of the method for producing a highly viscous substance using this apparatus will be described with reference to FIGS. 8 and 19. FIG. 19 shows a schematic flow of the manufacturing process of the high-performance resin (highly viscous substance) of the present invention. This is a method in which a monomer, which is a raw material of a highly viscous substance, and a catalyst are mixed, and an intended final polymer is produced by bulk polymerization by an addition polymerization reaction or a condensation polymerization reaction. Since the high-performance resin increases the degree of polymerization, the melt viscosity increases, and the melt viscosity of the final polymer rises to several kPa · s (tens of thousands of poise). When a liquid of several kPa · s (tens of thousands of poise) is treated with an ordinary stirring device, the mixing / stirring performance is poor, so that the degree of polymerization distribution of the product is largely varied and the quality is significantly deteriorated.
Therefore, the stirring apparatus for highly viscous substances shown in FIG. 8 is used to process the final polymer without deteriorating the stirring performance. 8th
The structure and operation of the agitator for highly viscous substances shown in FIGS.

本発明の枠状部材を形成する攪拌翼により処理液は槽全
体に循環流ができ、液の滞留部分が無くなり高粘度液の
良好な攪拌混合が得られる。従って本攪拌装置を用いて
重合反応を行えば均一な重合度をもった最終重合物が得
られる。さらに、重合反応の最初から一基の攪拌装置に
より最終重合物の製造を行うことができる。
By the stirring blades forming the frame-shaped member of the present invention, the treatment liquid can be circulated in the whole tank, and the stagnant portion of the liquid can be eliminated to obtain good stirring and mixing of the high-viscosity liquid. Therefore, when the polymerization reaction is carried out using the present stirring device, a final polymer having a uniform degree of polymerization can be obtained. Furthermore, the final polymerized product can be produced from the beginning of the polymerization reaction with a single stirrer.

つぎに、本発明の他の実施例について第20図により説明
する。本実施例は予備重合装置23と第8図あるいは第20
図により説明した攪拌装置18とを用いて高機能樹脂(高
粘性物質)を付加重合反応あるいは縮重合反応により目
的の最終重合物を塊状重合で製造するものである。本実
施例は重合反応の前段階の低粘液を従来の低粘度用攪拌
翼24を具備した予備重合装置23で処理し、中粘度から最
終の処理粘度を高粘度用攪拌翼19を具備した攪拌装置18
の攪拌槽1で処理するものである。高粘度用攪拌翼19は
第8図あるいは第20図で説明したものと同様の構成、作
用をもつものである。以上の構成により、高機能樹脂
(高粘性物質)を製造することにより、塊状重合プロセ
スのみで製造できるので、プロセスの簡略化が計れる。
Next, another embodiment of the present invention will be described with reference to FIG. In this embodiment, the prepolymerization device 23 and FIG. 8 or 20 are used.
A high-performance resin (highly viscous substance) is produced by addition polymerization reaction or polycondensation reaction using a stirring device 18 described with reference to the figure to produce an intended final polymer by bulk polymerization. In this example, the low-viscosity liquid at the pre-stage of the polymerization reaction was treated by the pre-polymerization device 23 equipped with the conventional low-viscosity stirring blade 24, and the stirring viscosity provided with the high-viscosity stirring blade 19 from the medium viscosity to the final processed viscosity Device 18
It is processed in the stirring tank 1 of 1. The high-viscosity stirring blade 19 has the same structure and operation as those described in FIG. 8 or FIG. With the above-described structure, the high-performance resin (highly viscous substance) can be manufactured by only the bulk polymerization process, so that the process can be simplified.

以上のように本実施例によれば、本体1内の被処理液の
循環速度が高められ、表面更新性能が向上できるので、
重縮合系高分子(ポリエチレンテレフタレート、ポリブ
チレンテレフタレートポリアミド、ポリアセタール、ポ
リカーボネート等)の重合速度が高められる。また、本
実施例によれば、被処理液の伝熱性能が高められるの
で、ポリスチレン等の付加重合系高分子の重合におい
て、被処理液の反応熱の除去が容易となり、安定した重
合操作ができる。
As described above, according to this embodiment, the circulation speed of the liquid to be treated in the main body 1 is increased, and the surface renewal performance can be improved.
The polymerization rate of polycondensation polymers (polyethylene terephthalate, polybutylene terephthalate polyamide, polyacetal, polycarbonate, etc.) can be increased. Further, according to the present example, since the heat transfer performance of the liquid to be treated is enhanced, it is easy to remove the reaction heat of the liquid to be treated in the polymerization of the addition polymerization type polymer such as polystyrene, and a stable polymerization operation can be performed. it can.

さらに、本実施例によれば、高粘度の被処理液での表面
更新性能及び本体の壁からの伝熱性能が高められるの
で、重合操作以外に、高分子からの脱モノマー操作、脱
溶媒操作に本発明の装置が適する。
Furthermore, according to this example, since the surface renewal performance and the heat transfer performance from the wall of the main body with the high-viscosity liquid to be treated can be improved, the demonomerization operation and the desolventization operation from the polymer can be performed in addition to the polymerization operation. The device of the present invention is suitable for.

さらに、本実施例によれば、粉粒体及び粘着性粉粒体の
揮発物除去操作においても、本体内での循環速度が高め
られるので、本発明の装置が適し、さらに、チップ状ポ
リエチレンテレフタレート、ポリブチレンテレフタレー
ト等の粉粒体形状高分子の固相重合にも好適である。
Furthermore, according to the present example, since the circulation speed in the main body can be increased even in the volatile matter removing operation of the powdery particles and the adhesive powdery particles, the device of the present invention is suitable, and further, the chip-shaped polyethylene terephthalate It is also suitable for solid-state polymerization of powder-shaped polymers such as polybutylene terephthalate.

〔発明の効果〕〔The invention's effect〕

本発明によれば、矩形状の枠部材によって槽内をくまな
くかきとる構成であるので滞留部分のない良好な攪拌・
混合性能が得られる。また被処理液の共回りを起す回転
軸がないので攪拌・混合による被処理液の品質低下を防
止できる効果がある。さらに、矩形状の枠部材に被処理
液のかきあげ作用を持たせると槽内に大きな循環流れが
発生し攪拌・混合性能が向上する。
According to the present invention, since the rectangular frame member is used to scrape the inside of the tank thoroughly, good stirring and no stagnant portion can be achieved.
Mixing performance is obtained. Further, since there is no rotating shaft that causes co-rotation of the liquid to be treated, it is possible to prevent deterioration of the quality of the liquid to be treated due to stirring and mixing. Further, when the rectangular frame member is provided with a scraping action for the liquid to be treated, a large circulating flow is generated in the tank, and stirring / mixing performance is improved.

また矩形状の枠部材を連結して回転させるため槽全体に
亘り攪拌された被処理液の形状が複雑になり、槽容積当
りの被処理液表面積の比が増加し表面更新作用が大きく
なり、蒸発成分の脱ガス性能が向上する効果がある。さ
らに、攪拌翼を逆回転させることにより、被処理液を槽
下部へ集中させて被処理液の排出時間を短縮できる効果
がある。
Further, since the rectangular frame members are connected and rotated, the shape of the liquid to be treated that is agitated over the entire tank becomes complicated, the ratio of the surface area of the liquid to be processed per tank volume increases, and the surface renewal action increases. This has the effect of improving the degassing performance of the vaporized components. Further, by rotating the stirring blade in the reverse direction, the liquid to be treated can be concentrated in the lower portion of the tank, and the discharge time of the liquid to be treated can be shortened.

さらに、本発明によれば、高機能樹脂(高粘性物質)の
製造を塊状重合のみでできるので製造プロセスが簡略化
できる。
Furthermore, according to the present invention, since the high-performance resin (high-viscosity substance) can be produced only by bulk polymerization, the production process can be simplified.

また、高機能樹脂の製造設備価格を下げる効果もある。
さらに、高機能樹脂の製造にかかる反応時間も短縮でき
る効果がある。
It also has the effect of lowering the cost of manufacturing equipment for high-performance resins.
Further, there is an effect that the reaction time required for producing the high-performance resin can be shortened.

【図面の簡単な説明】[Brief description of drawings]

第1図は本発明の一実施例の高粘性物質の製造装置の概
略図、第2図は第1図のI−I線断面図、第3図は本発
明の他の実施例の高粘性物質の製造装置の概略図、第4
図は第3図のII−II線断面図、第5図は第3図の円筒円
周壁面の展開図、第6図は本発明のさらに他の実施例の
高粘性物質の製造装置の概略図、第7図は第6図のIII
−III線断面図、第8図は本発明のさらに他の実施例の
高粘性物質の製造装置の概略図、第9図は第8図のIV−
IV線断面図、第10図は第8図の円筒円周壁面の展開図、
第11図は本発明のさらに他の実施例の高粘性物質の製造
装置の概略図、第12図は本発明のさらに他の実施例の高
粘性物質の製造装置の概略図、第13図は本発明のさらに
他の実施例の高粘性物質装置の概略図、第14図は第13図
のV−V線断面図、第15図は本発明のさらに他の実施例
の高粘性物質の製造装置の概略図、第16図は第15図のVI
−VI線断面図、第17図は本発明のさらに他の実施例の高
粘性物質の製造装置の概略図、第18図は第17図のVII−V
II線断面図、第19図は本発明の一実施例の製造プロセス
のフロー図、第20図は本発明の他の実施例の塊状重合装
置の概略説明図、第21図は従来の高粘性物質の製造装置
の概略説明図、第22図は第21図の円筒円周壁面の展開
図、第23図および第24図はそれぞれ従来の製造プロセス
に関するフロー図である。 1……攪拌槽本体、2……回転耳軸、6……供給口、7
……排出口、8a〜8d……攪拌翼部材、9a〜9f……攪拌翼
部材、10……排出装置、11……加圧装置、18……攪拌装
置、19……高粘度用攪拌翼、20a,20b,20e,20d……補強
部材、23……予備重合装置、24……低粘度用攪拌翼、25
……重合装置、31……翼接手部材
FIG. 1 is a schematic view of an apparatus for producing a highly viscous substance according to an embodiment of the present invention, FIG. 2 is a sectional view taken along the line I-I of FIG. 1, and FIG. 3 is a highly viscous material according to another embodiment of the present invention. Schematic of the manufacturing equipment of the substance, 4th
FIG. 5 is a sectional view taken along the line II-II of FIG. 3, FIG. 5 is a development view of the cylindrical circumferential wall surface of FIG. 3, and FIG. 6 is a schematic view of a highly viscous substance manufacturing apparatus according to still another embodiment of the present invention. Figures and 7 are III of Figure 6.
-III sectional view, FIG. 8 is a schematic view of a highly viscous substance producing apparatus according to still another embodiment of the present invention, and FIG. 9 is IV- of FIG.
IV line sectional view, FIG. 10 is a development view of the cylindrical circumferential wall surface of FIG. 8,
FIG. 11 is a schematic view of an apparatus for producing a highly viscous substance according to still another embodiment of the present invention, FIG. 12 is a schematic diagram of an apparatus for producing a highly viscous substance according to yet another embodiment of the present invention, and FIG. FIG. 14 is a schematic view of a highly viscous substance device according to still another embodiment of the present invention, FIG. 14 is a sectional view taken along the line VV of FIG. 13, and FIG. 15 is a process for producing a highly viscous substance according to still another embodiment of the present invention. Schematic of the device, Fig. 16 is VI of Fig. 15
-VI line sectional view, FIG. 17 is a schematic view of a highly viscous substance manufacturing apparatus according to still another embodiment of the present invention, and FIG. 18 is VII-V of FIG.
II sectional view, FIG. 19 is a flow chart of the manufacturing process of one embodiment of the present invention, FIG. 20 is a schematic explanatory view of a bulk polymerization apparatus of another embodiment of the present invention, FIG. 21 is a conventional high viscosity FIG. 22 is a schematic explanatory view of a material manufacturing apparatus, FIG. 22 is a development view of a cylindrical circumferential wall surface in FIG. 21, and FIGS. 23 and 24 are flow charts related to a conventional manufacturing process. 1 ... Agitation tank main body, 2 ... Rotating ear shaft, 6 ... Supply port, 7
...... Discharge port, 8a to 8d …… Stirring blade member, 9a to 9f …… Stirring blade member, 10 …… Discharging device, 11 …… Pressurizing device, 18 …… Stirring device, 19 …… High viscosity stirring blade , 20a, 20b, 20e, 20d …… Reinforcing member, 23 …… Prepolymerization device, 24 …… Stirrer for low viscosity, 25
...... Polymerizer, 31 ...... Wing joint member

フロントページの続き (72)発明者 丸子 盛久 茨城県土浦市神立町502番地 株式会社日 立製作所機械研究所内 (72)発明者 井原 一夫 山口県下松市大字東豊井794番地 株式会 社日立製作所笠戸工場内 (72)発明者 木下 高年 山口県下松市大字東豊井794番地 株式会 社日立製作所笠戸工場内 (72)発明者 古川 敬信 山口県下松市大字東豊井794番地 株式会 社日立製作所笠戸工場内 (72)発明者 渡部 健一 山口県下松市大字東豊井794番地 株式会 社日立製作所笠戸工場内Front Page Continuation (72) Inventor Maruko Moriku 502 Jinritsucho, Tsuchiura-shi, Ibaraki Machinery Research Institute, Hiritsu Manufacturing Co., Ltd. (72) Inventor Kazuo Ihara 794, Higashitoyoi, Kudamatsu City, Yamaguchi Prefecture Hitachi Kasado, Ltd. Inside the factory (72) Inventor Takashi Kinoshita 794 Azuma Higashitoyo, Shimomatsu City, Yamaguchi Prefecture Kasado Co., Ltd.Inside the factory (72) Keinobu Furukawa 794 Azuma Higashitoyo, Shimomatsu City, Yamaguchi Corporation Hitachi Kasa Co., Ltd. Inside the To Factory (72) Inventor Kenichi Watanabe 794 Azuma Toyoi, Kudamatsu City, Yamaguchi Prefecture Stock Company Hitachi Ltd. Inside the Kasado Factory

Claims (7)

【特許請求の範囲】[Claims] 【請求項1】垂直方向に設置された円筒状容器あるいは
該容器の下部が円錐状の容器内に2つの水平方向部材
(8a,8b)と容器壁面と微小な隙間を保って設置される
2つの垂直方向部材(9a,9b)とによって矩形枠を形成
し、さらに下側の水平方向部材(8b)を上側の水平方向
部材(8a)に対して回転方向に位相をθ度進ませて、
ねじられた枠形状に構成された枠構造物(8a,9a,8b,9
b)と、 この枠構造物と同様に形成された他の枠構造物(8e,9e,
8f,9b)とを垂直方向に重ね、 上記枠構造物の下側の水平方向部材(8b)と上記他の枠
構造物の上側の水平方向部材(8e)とを回転中心の位置
において回転方向に所定の角度θ度で交差させて連結
して撹拌翼としたことを特徴とする高粘性物質の製造装
置。
1. A vertically-arranged cylindrical container or a lower part of the container is installed in a conical container with two horizontal members (8a, 8b) and a wall surface of the container with a minute gap maintained. A rectangular frame is formed by the two vertical members (9a, 9b), and the lower horizontal member (8b) is advanced in phase by θ 2 degrees in the rotational direction with respect to the upper horizontal member (8a). ,
Frame structure (8a, 9a, 8b, 9
b) and other frame structures (8e, 9e,
8f, 9b) are vertically overlapped, and the lower horizontal member (8b) of the frame structure and the upper horizontal member (8e) of the other frame structure are rotated at the center of rotation. An apparatus for producing a highly viscous substance, characterized in that a stirring blade is formed by connecting the two to each other at a predetermined angle θ 1 degree and connecting them.
【請求項2】上記垂直方向部材の両端あるいは一端をこ
の垂直方向部材と連結される水平方向部材の位置より枠
外に突出させたことを特徴とする請求項1記載の高粘性
物質の製造装置。
2. The apparatus for producing a highly viscous substance according to claim 1, wherein both ends or one end of the vertical member is projected outside the frame from a position of a horizontal member connected to the vertical member.
【請求項3】上記容器の下部形状は逆円錐形状であり、
この逆円錐形状の頂部に被処理液を抜き出す排出機構と
上記容器の上部において連通し上記容器内の気相部を加
圧する加圧機構とが設けられ、 上記排出機構を運転して被処理液を排出する際、上記容
器の内壁に付着した付着物を掻き下げる方向に上記撹拌
翼を回転させると共に上記加圧機構により上記容器内を
加圧することを特徴とする請求項1または2記載の高粘
性物質の製造装置。
3. The lower shape of the container is an inverted conical shape,
A discharge mechanism for extracting the liquid to be treated and a pressurizing mechanism for communicating with the upper portion of the container to pressurize the vapor phase portion in the container are provided at the top of the inverted cone, and the liquid to be treated is operated by operating the discharge mechanism. The high pressure according to claim 1 or 2, characterized in that, when discharging, the stirring blade is rotated in a direction of scraping off the deposits adhering to the inner wall of the container, and the inside of the container is pressurized by the pressing mechanism. Equipment for producing viscous substances.
【請求項4】重合反応の初期段階から最終段階までを上
記容器内で一貫して行うことを特徴とする請求項1、2
または3記載の高粘性物質の製造装置。
4. The method according to claim 1, wherein the initial stage to the final stage of the polymerization reaction are carried out in the vessel in a consistent manner.
Or the apparatus for producing a highly viscous substance described in 3.
【請求項5】タービン翼あるいはパドル翼等の低粘度用
撹拌翼を具備した低粘度用撹拌装置と請求項1、2また
は3記載の高粘性物質の製造装置とを連結して、付加重
合系高分子あるいは縮重合系高分子の製造を塊状重合に
より行うことを特徴とする高粘性物質の製造方法。
5. An addition polymerization system by connecting a low-viscosity stirring apparatus equipped with a low-viscosity stirring blade such as a turbine blade or a paddle blade to the high-viscosity substance producing apparatus according to claim 1, 2 or 3. A method for producing a highly viscous substance, which comprises producing a polymer or a polycondensation polymer by bulk polymerization.
【請求項6】垂直方向に設置された円筒状容器あるいは
該容器の下部が円錐状の容器内に、 2つの水平方向部材(8a,8b)と容器壁面と微小な隙間
を保って設置される2つの垂直方向部材(9a,9d)とに
よって形成され、さらに下側の水平方向部材(8b)を上
側の水平方向部材(8a)に対して回転方向に位相をθ
度進ませて、ねじられた枠形状に構成された枠構造物
(8a,9a,8b,9d)と、 この枠構造物と同様に構成された他の枠構造物(8e,9e,
8f,9b)とを垂直方向に重ね、 上記枠構造物の下側の水平方向部材(8b)と上記他の枠
構造物の上側の水平方向部材(8e)とを回転中心の位置
において回転方向に所定の角度θ度で交差させて連結
してなる撹拌翼により重合反応操作を行うことを特徴と
する高粘性物質の製造方法。
6. A vertically-arranged cylindrical container or a container having a lower part of the container having a conical shape with two horizontal members (8a, 8b) and a wall surface of the container provided with a minute gap therebetween. It is formed by two vertical members (9a, 9d), and the lower horizontal member (8b) has a phase θ 2 in the rotational direction with respect to the upper horizontal member (8a).
The frame structure (8a, 9a, 8b, 9d) formed in a twisted frame shape by advancing, and other frame structures (8e, 9e, 8e, 9e,
8f, 9b) are vertically overlapped, and the lower horizontal member (8b) of the frame structure and the upper horizontal member (8e) of the other frame structure are rotated at the center of rotation. A method for producing a highly viscous substance, characterized in that a polymerization reaction operation is carried out by means of a stirring blade formed by intersecting and connecting at a predetermined angle θ 1 degree.
【請求項7】垂直方向に設置された円筒状容器あるいは
該容器の下部が円錐状の容器内に2つの水平方向部材
(8a,8b)と容器壁面と微小な隙間を保って設置される
2つの垂直方向部材(9a,9d)とによって矩形枠に構成
された枠構造物(8a,9a,8b,9d)と、 この枠構造物と同様に形成された他の枠構造物(8e,9e,
8f,9b)とを垂直方向に重ね、 上記枠構造物の下側の水平方向部材(8b)と上記他の枠
構造物の上側の水平方向部材(8e)とを回転中心の位置
において回転方向に所定の角度θ度で交差させて連結
して撹拌翼としたことを特徴とする高粘性物質の製造装
置。
7. A vertically-arranged cylindrical container or the lower part of the container is installed in a conical container with two horizontal members (8a, 8b) and a wall surface of the container with a minute gap maintained. A frame structure (8a, 9a, 8b, 9d) formed into a rectangular frame by two vertical members (9a, 9d), and another frame structure (8e, 9e) formed in the same manner as this frame structure. ,
8f, 9b) are vertically overlapped, and the lower horizontal member (8b) of the frame structure and the upper horizontal member (8e) of the other frame structure are rotated at the center of rotation. An apparatus for producing a highly viscous substance, characterized in that a stirring blade is formed by connecting the two to each other at a predetermined angle θ 1 degree and connecting them.
JP2021995A 1989-02-03 1990-02-02 Apparatus and method for producing high-viscosity substance Expired - Lifetime JPH0790164B2 (en)

Applications Claiming Priority (4)

Application Number Priority Date Filing Date Title
JP1-23878 1989-02-03
JP2387889 1989-02-03
JP1-231607 1989-09-08
JP23160789 1989-09-08

Related Child Applications (1)

Application Number Title Priority Date Filing Date
JP7096528A Division JP2853605B2 (en) 1989-02-03 1995-04-21 Method and apparatus for producing highly viscous substance

Publications (2)

Publication Number Publication Date
JPH03188936A JPH03188936A (en) 1991-08-16
JPH0790164B2 true JPH0790164B2 (en) 1995-10-04

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ID=26361310

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JP2021995A Expired - Lifetime JPH0790164B2 (en) 1989-02-03 1990-02-02 Apparatus and method for producing high-viscosity substance
JP7096528A Expired - Lifetime JP2853605B2 (en) 1989-02-03 1995-04-21 Method and apparatus for producing highly viscous substance
JP10056435A Pending JPH10218906A (en) 1989-02-03 1998-03-09 Process and apparatus for producing highly viscous substance
JP10233804A Pending JPH11140179A (en) 1989-02-03 1998-08-20 Process and apparatus for producing highly viscous substance

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JP10056435A Pending JPH10218906A (en) 1989-02-03 1998-03-09 Process and apparatus for producing highly viscous substance
JP10233804A Pending JPH11140179A (en) 1989-02-03 1998-08-20 Process and apparatus for producing highly viscous substance

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JPH0790164B2 (en) * 1989-02-03 1995-10-04 株式会社日立製作所 Apparatus and method for producing high-viscosity substance
JP2006142133A (en) * 2004-11-16 2006-06-08 Kazuhiko Kato Catalyst apparatus
WO2007065840A1 (en) * 2005-12-07 2007-06-14 Basf Se Method for the continuous mixing of polymer particles
JP4614913B2 (en) * 2006-05-26 2011-01-19 住友重機械プロセス機器株式会社 Stirring method using a vertical stirrer for high viscosity non-Newtonian fluids
KR100977147B1 (en) * 2007-12-31 2010-08-23 세메스 주식회사 Fluidizing bed apparatus for producting carbon nano tube and facility and method producting carbon nano tube
JP5304437B2 (en) * 2008-05-29 2013-10-02 三菱瓦斯化学株式会社 Method for producing polyamide
ES2724707T3 (en) * 2008-08-14 2019-09-13 Basf Se Batch procedure for the manufacture of polyamides
EP2627763B1 (en) * 2010-10-15 2016-05-04 Andritz Technology and Asset Management GmbH High solids enzyme reactor or mixer and method
MX2015017160A (en) * 2013-06-12 2016-09-22 Basf Se Device for synthesizing a polymer with reduced formation of deposits in the reaction chamber.
EP3007818B1 (en) * 2013-06-12 2017-08-09 Basf Se Method of polymerisation under separation of a gaseous substance
JP6869414B1 (en) * 2020-10-13 2021-05-12 岩井機械工業株式会社 Stirrer

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* Cited by examiner, † Cited by third party
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Also Published As

Publication number Publication date
JPH0871397A (en) 1996-03-19
JP2853605B2 (en) 1999-02-03
JPH11140179A (en) 1999-05-25
JPH10218906A (en) 1998-08-18
JPH03188936A (en) 1991-08-16

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