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JPH01270982A - Air separator - Google Patents

Air separator

Info

Publication number
JPH01270982A
JPH01270982A JP9823888A JP9823888A JPH01270982A JP H01270982 A JPH01270982 A JP H01270982A JP 9823888 A JP9823888 A JP 9823888A JP 9823888 A JP9823888 A JP 9823888A JP H01270982 A JPH01270982 A JP H01270982A
Authority
JP
Japan
Prior art keywords
classification
fine powder
discharge port
powder discharge
diameter
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.)
Pending
Application number
JP9823888A
Other languages
Japanese (ja)
Inventor
Takuya Takayama
卓也 高山
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.)
Ube Corp
Original Assignee
Ube Industries 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 Ube Industries Ltd filed Critical Ube Industries Ltd
Priority to JP9823888A priority Critical patent/JPH01270982A/en
Publication of JPH01270982A publication Critical patent/JPH01270982A/en
Pending legal-status Critical Current

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  • Combined Means For Separation Of Solids (AREA)

Abstract

PURPOSE:To markedly reduce the mixing amount of coarse particles on a fine powder side by setting the inner diameter of a fine powder discharge port to a length having a specific ratio with respect to the max. diameter of a rotary blade wheel and providing an annular member having a specific length from the fine powder discharge port toward a vertical lower part. CONSTITUTION:A vertical drive shaft 7 supported in a rotatable manner and a rotary blade wheel 8' having a large number of integrally rotating classifying blades 8 provided to the periphery thereof are provided at the center of a classifying chamber 1. The fine powder discharge port 9 communicating with the interior of the rotary blade wheel are arranged above said blade wheel 8' and guide members 6 provided with a large number of slit like perforations for imparting revolution to classifying air are fixed to the outer periphery of the blade wheels on a concentric circle at a proper interval. A cone-shape member 10 reduced in its diameter downwardly is provided so as to be connected to the guide members 6. The inner diameter of the fine powder discharge port 9 is set to 30-70 of the max. diameter of the rotary blade wheel 8' and an annular member 12 having a length 5-20% of the height of the vent part of the classifying blades 8 is arranged from the fine powder discharge port 9 toward the vertical lower part.

Description

【発明の詳細な説明】 [産業上の利用分野] 本発明は、粉砕機および粉砕部において粉砕されたセメ
ント原料、タリン力、高炉スラグ、石灰石、化学品など
の被分級物(以下分級原料と記す)を気流によって微粉
と粗粉に分離するエアセパレ、−夕に関するものである
Detailed Description of the Invention [Industrial Application Field] The present invention is applicable to materials to be classified (hereinafter referred to as classified raw materials) such as cement raw materials, talin powder, blast furnace slag, limestone, and chemicals that are crushed in a crusher and a crushing section. This relates to an air separator that separates powder (described below) into fine powder and coarse powder using an air flow.

[従来の技術] エアーセパレータは、粉砕機および粉砕部において粉砕
された粉体から、気流によって所要粒度の粉体を取出し
、製品とすることを目的とする分級装置でおり、その分
級原理は、大きく分けると、粉体に作用する流体抗力と
粉体に働り重力の差を利用する重力分級、気流の方向を
急変することで粉体に働く流体抗力と慣性力との差を利
用する慣性力分級、および、流体抗力と気流を旋回させ
ることで粉体に働く遠心力との差を利用する遠心力分級
の3つに分類することができる。
[Prior Art] An air separator is a classification device whose purpose is to extract powder of a desired particle size from the powder crushed in a crusher and a crushing section using an air flow to produce a product.The classification principle is as follows. Broadly speaking, gravitational classification uses the difference between fluid drag acting on the powder and gravity acting on the powder, and inertia classification uses the difference between the fluid drag and inertia force acting on the powder by suddenly changing the direction of airflow. It can be classified into three types: force classification and centrifugal force classification that utilizes the difference between fluid drag and centrifugal force acting on the powder by swirling airflow.

この内、−殻内に、大量の分級原料を処理する場合には
、遠心力分級の原理を利用した分級装置が用いられてお
り、分級室の形状を渦巻状にすることで気流を旋回させ
る自由渦式のもの、分級室内に設けられた回転羽根によ
って気流を強制的に旋回させる強制渦式のもの、および
、これらを組合せて自由渦と強制渦の2つを利用する形
式としたものがある。
Among these, when processing a large amount of classified raw materials in a shell, a classification device that utilizes the principle of centrifugal force classification is used, and the shape of the classification chamber is spiral-shaped to swirl the airflow. There are free vortex types, forced vortex types in which the airflow is forcibly swirled by rotating blades installed in the classification chamber, and types that combine these to utilize both free vortices and forced vortices. be.

第7図に、従来技術のエアセパレータの1例を示す。FIG. 7 shows an example of a conventional air separator.

これは、自由渦と強制渦の2つを組合せた形式%式% 分級原料は、原料供給口3aから送入され、高速回転す
る分散盤4aおよび衝突板20を経由して分散状態で分
級用空気中に投入される。分級用空気は分級用空気取込
口5aから渦巻状のケーシング内壁に沿って接線方向に
流入し、案内部材6aを経由して一次旋回気流を形成し
、次いで、回転する回転羽根車8aによって二次旋回気
流を形成する。
This is a type of % formula that combines free vortex and forced vortex % The classified raw material is fed from the raw material supply port 3a, passes through the dispersion plate 4a rotating at high speed and the collision plate 20, and is used for classification in a dispersed state. thrown into the air. Classifying air flows tangentially from the classifying air intake 5a along the spiral inner wall of the casing, passes through the guide member 6a, forms a primary swirling airflow, and is then rotated by the rotating rotary impeller 8a. Next, a swirling airflow is formed.

分級は、最初−次旋回気流で行なわれ、次いで、二次旋
回気流において、遠心力と内向に流れる空気による抗力
とのバランスで行なわれ、所要粒度の微粒子は、微粉排
出口9aを経由して微粉として系外へ取出される。
Classification is performed in the first and second swirling airflows, and then in the secondary swirling airflow, by balancing the centrifugal force and the drag force due to the inwardly flowing air. It is taken out of the system as a fine powder.

一方、所用粒度より大きい粗粒子および所用粒度より細
かい微粒子の凝集体は、二次旋回気流による遠心力を受
は回転羽根車8aの外周方向に跳飛された後、案内部材
6aの内側に沿って下降する間に、案内部材6aを経由
して侵入してくる分級用空気に晒されて微粒子の凝集体
は分散作用を受けるが、粗粒子はざらに粗粉排出口11
に向かって落下を続ける。そして、分散した微粒子は、
再び分級用空気とともに二次旋回気流中に運ばれ分級さ
れる。
On the other hand, aggregates of coarse particles larger than the required particle size and fine particles smaller than the required particle size are bounced off toward the outer circumference of the rotary impeller 8a by the centrifugal force caused by the secondary swirling airflow, and then flowed along the inside of the guide member 6a. While descending, the aggregates of fine particles are exposed to the classification air that enters through the guide member 6a and are subjected to a dispersion effect, but the coarse particles are roughly dispersed through the coarse powder outlet 11.
Continue falling towards. Then, the dispersed fine particles are
It is transported again to the secondary swirling airflow together with the classification air and classified.

[発明が解決しようとする課題] しかし、遠心力分級においては、流体の抗力と遠心力の
バランスで分級が行なわれるという確固たる理論が成立
しているにもかかわらず、従来技術においては、微細な
粒子のみを微粉として取出すことは難しく、微粉側へ粗
粒子が混入するケースが多々発生していた。
[Problem to be solved by the invention] However, in centrifugal force classification, although there is a solid theory that classification is performed by the balance between fluid drag and centrifugal force, conventional technology It is difficult to extract only the particles as fine powder, and there have been many cases where coarse particles are mixed into the fine powder side.

理論と実際の差異に関しては、理論では単一粒子を取扱
っているのに対して、実際に分級しようとする粉体は単
一の粒子ではなく、粒子同志の衝突が発生したり、分級
羽根と粒子が衝突するといったことが起こっていること
に原因があると考えられている。
Regarding the difference between theory and reality, the theory deals with single particles, whereas the powder to be actually classified is not a single particle, but particles collide with each other or collide with the classification blade. It is thought that the cause is that particles collide.

これにより、従来から、粗粒子の微粉側への混入を防止
するために、所要粒度の微粉を得るのに必要とされる理
論上の分級羽根の回転数以上に実際の回転数を高速に設
定したり、回転羽根車の外周側に羽根車と一体に回転す
る粗粒子混入防止の部材を取付けるといった対策が採ら
れてきた。
As a result, in order to prevent coarse particles from entering the fine powder side, the actual rotation speed of the classification blade is set higher than the theoretical rotation speed required to obtain fine powder of the required particle size. Measures have also been taken, such as installing a member on the outer periphery of the rotary impeller that rotates together with the impeller to prevent coarse particles from entering.

したがって、回転羽根車の回転数の増加や、羽根車の外
周部の重量の増加に伴って、回転羽根車を駆動するため
の電力が過大なものになるという問題があった。
Therefore, as the rotational speed of the rotary impeller increases and the weight of the outer peripheral portion of the impeller increases, there is a problem in that the electric power required to drive the rotary impeller becomes excessive.

本発明は、粉砕機および粉砕部において粉砕された粉体
から、気流によって所要粒度の微粉を取出すことに関し
て、消費電力の増加を抑えるとともに微粉側に混入する
粗粒子を減少することが可能なエアセパレータを提供す
ることを目的とするものである。
The present invention provides an air flow system that can suppress an increase in power consumption and reduce coarse particles mixed into the fine powder side with respect to extracting fine powder of a required particle size from the powder crushed in a crusher and a crushing section using an air flow. The purpose is to provide a separator.

[課題を解決するための手段] 分級室の中心に、回転可能に支持された垂直な駆動軸と
その周囲に一体的に回転する多数の分級羽根を取付けた
回転羽根車を有し、該羽根車上方には回転羽根車内部と
連通する微粉排出口を配し、回転羽根車外周に分級用気
流に旋回を与えるための多数のスリット状開孔を具備す
る案内部材を同心円上に適当間隔離間して固設し、該案
内部材に連結して下方縮径のコーン状部材を備えたエア
セパレータにおいて、前記微粉排出口の内径φdを回転
羽根車の最大径φDに対して30%〜70%とし、かつ
、該微粉排出口から垂直下方に向けて前記分級羽根の通
風部分の高さHに対して5%〜50%の長ざhの環状部
材を設けたものである。
[Means for Solving the Problems] A rotary impeller is provided in the center of the classification chamber and has a rotatably supported vertical drive shaft and a number of classification blades that integrally rotate around the drive shaft. A fine powder discharge port communicating with the inside of the rotary impeller is arranged above the vehicle, and a guide member having a large number of slit-shaped holes for giving swirl to the airflow for classification is placed on the outer circumference of the rotary impeller, spaced apart at an appropriate distance on a concentric circle. In the air separator, the inner diameter φd of the fine powder discharge port is 30% to 70% of the maximum diameter φD of the rotary impeller. Further, an annular member having a length h of 5% to 50% of the height H of the ventilation portion of the classification blade is provided vertically downward from the fine powder discharge port.

微粉排出口の内径φdは、回転羽根車の外径φDに対し
て、30%の大きざより小ざくすると分級用空気の排出
口通過速度が上昇し過ぎるためセパレータ差圧が増加し
て排気ファンの消費電力の増加を招き、また、70%を
超える大きさにすると分級羽根の幅に制限を与え効果的
な分級が行なわれなくなるという不具合が生じる。
If the inner diameter φd of the fine powder outlet is made smaller than 30% of the outer diameter φD of the rotary impeller, the velocity of the classification air passing through the outlet will increase too much, and the separator differential pressure will increase, causing the exhaust fan to In addition, if the size exceeds 70%, the width of the classification blade is restricted and effective classification cannot be performed.

また、環状部材の長ざhは、分級羽根の通風部分の高さ
Hに対して、5%の長さより短くすると本発明によると
ころの分級の効果が小さくなり、50%の長さを超えて
長くすると分級用空気が分級羽根の下方に集中して通過
するため効率の良い分級が行なわれなくなる。
In addition, if the length h of the annular member is shorter than 5% of the height H of the ventilation part of the classification blade, the classification effect according to the present invention will be reduced, and if the length h exceeds 50%. If it is made too long, the classification air will concentrate under the classification blade and pass through, making it impossible to perform efficient classification.

[作 −用・] 案内部材によって一次旋回気流が形成され、回転羽根車
によって二次旋回気流が形成される。また、分級原料は
、−次旋回気流と二次旋回気流において、遠心力と内向
に流れる空気による抗力とのバランスで分級されるとい
う作用については従来と同じものである。
[Operation] A primary swirling airflow is formed by the guide member, and a secondary swirling airflow is formed by the rotary impeller. Furthermore, the classified raw material is classified in the secondary swirling airflow and the secondary swirling airflow with the balance between centrifugal force and drag force due to inwardly flowing air, which is the same as in the conventional method.

ここで、分級の行なわれる空間について考えると、従来
のエアセパレータでは、−次分級は案内部材と分級羽根
で囲まれた空間で行なわれ、二次分級は分級羽根の幅に
相当する空間かあるいはその近辺で行なわれるとされて
いた。
Now, considering the space in which classification is performed, in conventional air separators, -order classification is performed in a space surrounded by a guide member and classification blades, and secondary classification is performed in a space corresponding to the width of the classification blades or It was said that the event would take place in the vicinity.

しかし、本発明は、二次分級を分級羽根からざらに中心
寄りの空間でも行なうことが可能という本発明者の発見
によりなされたものであり、微粉排出口の内径を適当な
大きざに設定し、かつ、微粉排出口の周囲に垂直下方に
環状部材を設けることによって、分級羽根内側から環状
部材を下方に延長した位置に至る空間においても有効な
旋回気流を形成することが可能となるため、分級原料が
旋回気流中に滞留する時間が長くなりシャープな分級が
行なわれるようになる。
However, the present invention was made based on the inventor's discovery that secondary classification can be performed even in a space roughly in the center of the classification blade, and the inner diameter of the fine powder outlet is set to an appropriate size. In addition, by providing the annular member vertically downward around the fine powder discharge port, it is possible to form an effective swirling airflow even in the space from the inside of the classification blade to the position where the annular member is extended downward. The residence time of the classified raw material in the swirling air current becomes longer, and sharp classification is performed.

このため、微粉側へ混入する粗粒子の量を著しく減少さ
せることができるようになるというものである。
Therefore, the amount of coarse particles mixed into the fine powder side can be significantly reduced.

[実 施 例] 以下図面とともに本発明について詳細に説明する。[Example] The present invention will be described in detail below with reference to the drawings.

第1図は、本発明の1実施例である。該セパレータは円
筒状の分級室1と下方縮径の分級室2の内部に構成され
たもので、分級室1の中心に、回転可能に支持された垂
直な駆動軸7とその周囲に一体的に回転する多数の分級
羽根8を取付けた回転羽根車8−を有し、該羽根車8−
の上方には回転羽根8−の内部と連通する微粉排出口9
を配している。回転羽根車8′の外周には、分級用空気
に旋回を与えるための多数のスリット状開孔を具備する
案内部材6を同心円状に適当間隔離間して固設し、該案
内部材6に連結して下方縮径のコーン状部材10を備え
ている。
FIG. 1 shows one embodiment of the invention. The separator is constructed inside a cylindrical classification chamber 1 and a downward diameter-reduced classification chamber 2, and includes a vertical drive shaft 7 that is rotatably supported in the center of the classification chamber 1, and a vertical drive shaft 7 that is integrally mounted around the shaft. The impeller 8- has a rotary impeller 8- to which a large number of classification blades 8 are attached.
Above is a fine powder discharge port 9 that communicates with the inside of the rotating blade 8-.
are arranged. On the outer periphery of the rotary impeller 8', a guide member 6 having a large number of slit-like openings for giving swirl to the classified air is fixed concentrically at appropriate intervals and connected to the guide member 6. It is provided with a cone-shaped member 10 whose diameter is reduced downward.

分散′g、2の内部には、回転羽根車8−の下方部分の
駆動軸7に分散盤4を設け、分級原料供給口3から供給
される分級原料が、分級室1で分級され案内部材6およ
びコーン状部材10の内壁を沿って落下してくる微粒子
の凝集体とともに、分級用空気取込口か5からスリット
5′を経由して侵入してくる分級用空気の中に投入され
分散する構造としたものである。
Inside the dispersion 'g, 2, a dispersion disk 4 is provided on the drive shaft 7 in the lower part of the rotary impeller 8-, and the classified raw material supplied from the classified raw material supply port 3 is classified in the classification chamber 1 and is passed through the guide member. 6 and the aggregates of fine particles falling along the inner wall of the cone-shaped member 10 are thrown into the classification air that enters from the classification air intake port 5 via the slit 5' and dispersed. It has a structure that allows

ここで、前記微粉排出口9の内径を回転羽根車8′の最
大径φDに対して30%〜70%φdとし、かつ、該微
粉排出口9から垂直下方に向けて前記分級羽根8の通風
部分の高さHに対して5%〜50%の長ざhに相当する
環状部材12を設けていることが本発明の特徴となって
いる。
Here, the inner diameter of the fine powder discharge port 9 is set to 30% to 70% φd with respect to the maximum diameter φD of the rotary impeller 8', and the ventilation of the classification blade 8 is directed vertically downward from the fine powder discharge port 9. A feature of the present invention is that the annular member 12 is provided with a length h corresponding to 5% to 50% of the height H of the portion.

第2図は、本発明の他の実施例でおり、第1図のエアセ
パレータの分級室に相当する部分を竪型ローラミルに適
用したものでおる。゛該セパレータ各部材の構成は前記
セパレータと同等である。
FIG. 2 shows another embodiment of the present invention, in which a portion corresponding to the classification chamber of the air separator shown in FIG. 1 is applied to a vertical roller mill. ``The structure of each member of the separator is the same as that of the separator described above.

第5図および第6図は、本発明のエアセパレータを用い
、分級を行って得られたサンプルから、部分分級効率を
求めたものを示したものである。
FIGS. 5 and 6 show partial classification efficiency determined from samples obtained by classification using the air separator of the present invention.

第5図の分級実験は、同一のエアセパレータを用いて微
粉排出口に環状部材を設けた場合と設けていない場合の
2つの条件について実施し、微粉排出口の内径および回
転羽根車の回転数、分級用空気の量、分級原料の供給量
といったセパレータの運転条件は一定とした。分級原料
には普通ポルトランドセメントを使用した。
The classification experiment shown in Figure 5 was conducted under two conditions: with and without an annular member provided at the fine powder discharge port using the same air separator, and by determining the inner diameter of the fine powder discharge port and the rotation speed of the rotary impeller. The operating conditions of the separator, such as the amount of air for classification, and the amount of supplied raw material for classification, were kept constant. Ordinary Portland cement was used as the raw material for classification.

この図を見ると、セパレータの運転条件が一定であって
も、微粉排出口に環状部材を設けることにより、粗粉側
へ回収される粗粒子の割合が増加、つまり、微粉側で回
収される粗粒子の徂が減少し、ざらに、分級点が小ざく
なっていることがよく分かる。
Looking at this figure, even if the operating conditions of the separator are constant, by providing an annular member at the fine powder outlet, the proportion of coarse particles collected on the coarse powder side increases.In other words, the proportion of coarse particles collected on the fine powder side increases. It is clearly seen that the area of coarse particles has decreased and the classification point has become smaller.

第6図の分級実験は、同一のエアセパレータを用いて微
粉排出口に環状部材を設けた場合と設けていない場合の
2つの条件について実施し、微粉排出口の内径および回
転羽根車の回転数を一定とし、分級原料の供給量および
分級用空気の量は、環状部材を設けていない場合を10
0%とすると、環状部材を設けた場合には150%まで
増加したものである。
The classification experiment shown in Figure 6 was conducted using the same air separator under two conditions: with and without an annular member provided at the fine powder outlet. is constant, and the amount of supplied raw material for classification and the amount of air for classification are 10 when no annular member is provided.
If it is 0%, it increases to 150% when an annular member is provided.

この図を見ると、環状部材を設けることにより、分級用
空気の量を増加しても環状部材がない場合と同等の分級
が行われることが分かり、ざらに、原料の処理量を増加
することも可能となることが分かる。
Looking at this figure, it can be seen that by providing an annular member, even if the amount of classification air is increased, classification is performed equivalent to that without the annular member, and roughly speaking, the throughput of raw materials can be increased. It turns out that this is also possible.

[発明の効果コ 以上の説明で明らかなように、本発明によれば次のよう
な優れた効果を発揮する。
[Effects of the Invention] As is clear from the above description, the present invention provides the following excellent effects.

(1)回転羽根内側から環状部材を下方に延長した位置
に至る空間においても有効な旋回気流を形成することが
可能となり、分級原料が旋回気流中に滞留する時間を長
くすることができるようになるためシャープな分級が行
われる。
(1) It is now possible to form an effective swirling airflow even in the space from the inside of the rotating blade to the position where the annular member is extended downward, and the time that the classified raw material stays in the swirling airflow can be extended. As a result, sharp classification is performed.

このため、微粉側へ混入する粗粒子の量を著しく減少す
ることが可能となる。
Therefore, it is possible to significantly reduce the amount of coarse particles mixed into the fine powder side.

(2)また、分級点をより小さくすることが可能となり
、分級原料から微細な粒子を微粉として取出すことがで
きるようになる。
(2) Furthermore, it becomes possible to make the classification point smaller, and it becomes possible to take out fine particles as fine powder from the classified raw material.

(3)分級用空気の量を増加しても従来に変わらない分
級を行うことができるため、時間当りに処理できる分級
原料の量が増加できる。
(3) Even if the amount of classification air is increased, the same classification as before can be performed, so the amount of classified raw materials that can be processed per hour can be increased.

【図面の簡単な説明】[Brief explanation of the drawing]

第1図は、本発明によるエアセパレータの概略断面図、
第2図は、本発明による他のエアセパレータを表す図、
第3図は、第1図または第2図の■〜■断面を表す図、
第4図は、第1図に表したエアセパレータの分散室ケー
シングを取除いた図。 第5図および第6図は、本発明によるエアセパレータに
よる分級実験結果から部分分級効率を求めた図、第7図
は、従来のエアセパレータを表す図。 1・・・分@至、1′・・・分散室ケーシング、2・・
・分散室、2−・・・分散室ケーシング、3,3a・・
・分級原料供給口、3−・・・粉砕原料供給口、4,4
a・・・分散盤、5,5a・・・分級用空気取込口、5
 ′−スリット、6,6a・・・案内部材、6−・・・
スリット状開孔、7,7a・・・駆動軸、8・・・分級
羽根、8”、8a・・・回転羽根車、9,9a・・・微
粉排出口、10・・・コーン状部材、11・・・粗粉排
出口、12・・・環状部材、20・・・衝突板、30・
・・減速機、31・・・粉砕テーブル、32・・・加圧
シリンダ、33・・・ローラ支持部材、34・・・粉砕
ローラ、50・・・気流 特許出願人   宇部興産株式会社 第1Cg 第2図 第3図 第4図 第5図 第6r5r1 粒子径〈μm) 第7図
FIG. 1 is a schematic cross-sectional view of an air separator according to the present invention;
FIG. 2 is a diagram representing another air separator according to the invention;
FIG. 3 is a cross-sectional view from ■ to ■ of FIG. 1 or 2;
FIG. 4 is a diagram with the dispersion chamber casing of the air separator shown in FIG. 1 removed. 5 and 6 are diagrams showing partial classification efficiency determined from the results of classification experiments using the air separator according to the present invention, and FIG. 7 is a diagram showing a conventional air separator. 1...minute @to, 1'...dispersion chamber casing, 2...
・Dispersion chamber, 2-... Dispersion chamber casing, 3, 3a...
・Classified raw material supply port, 3-...Crushed raw material supply port, 4,4
a... Dispersion plate, 5, 5a... Air intake for classification, 5
'-Slit, 6, 6a...Guide member, 6-...
Slit-shaped opening, 7, 7a... Drive shaft, 8... Classifying blade, 8", 8a... Rotating impeller, 9, 9a... Fine powder discharge port, 10... Cone-shaped member, DESCRIPTION OF SYMBOLS 11... Coarse powder discharge port, 12... Annular member, 20... Collision plate, 30...
... Reduction gear, 31... Grinding table, 32... Pressure cylinder, 33... Roller support member, 34... Grinding roller, 50... Airflow patent applicant Ube Industries Co., Ltd. No. 1 Cg Figure 2 Figure 3 Figure 4 Figure 5 Figure 6r5r1 Particle diameter <μm) Figure 7

Claims (1)

【特許請求の範囲】[Claims]  分級室の中心に、回転可能に支持された垂直な駆動軸
とその周囲に一体的に回転する多数の分級羽根を取付け
た回転羽根車を有し、該羽根車上方には回転羽根車内部
と連通する微粉排出口を配し、回転羽根車外周に分級用
空気に旋回を与えるための多数のスリット状開孔を具備
する案内部材を同心円上に適当間隔離間して固設し、該
案内部材に連結して下方縮径のコーン状部材を備えたエ
アセパレータにおいて、前記微粉排出口の内径を回転羽
根車の最大径に対して30〜70%とし、かつ、該微粉
排出口から垂直下方に向けて前記分級羽根の通風部分の
高さに対して5%〜50%の長さの環状部材を設けたこ
とを特徴とするエアセパレータ。
At the center of the classification chamber, there is a rotary impeller with a rotatably supported vertical drive shaft and a number of classification blades that rotate integrally around the shaft. A guide member having a communicating fine powder discharge port and a large number of slit-like openings for giving swirl to the classification air around the outer periphery of the rotary impeller is fixedly installed on a concentric circle with an appropriate distance between the guide members. In the air separator, the inner diameter of the fine powder discharge port is set to 30 to 70% of the maximum diameter of the rotary impeller, and the inner diameter of the fine powder discharge port is set to be 30 to 70% of the maximum diameter of the rotary impeller. An air separator characterized in that an annular member is provided with a length of 5% to 50% of the height of the ventilation portion of the classification blade.
JP9823888A 1988-04-22 1988-04-22 Air separator Pending JPH01270982A (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
JP9823888A JPH01270982A (en) 1988-04-22 1988-04-22 Air separator

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
JP9823888A JPH01270982A (en) 1988-04-22 1988-04-22 Air separator

Publications (1)

Publication Number Publication Date
JPH01270982A true JPH01270982A (en) 1989-10-30

Family

ID=14214381

Family Applications (1)

Application Number Title Priority Date Filing Date
JP9823888A Pending JPH01270982A (en) 1988-04-22 1988-04-22 Air separator

Country Status (1)

Country Link
JP (1) JPH01270982A (en)

Cited By (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
WO1994022599A1 (en) * 1993-03-31 1994-10-13 Onoda Cement Co., Ltd. Vortex type air classifier
WO2010101270A1 (en) * 2009-03-03 2010-09-10 Ricoh Company, Ltd. Classifying apparatus, classifying method, and method for producing toner
WO2015151187A1 (en) * 2014-03-31 2015-10-08 ホソカワミクロン株式会社 Classifier

Citations (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JPS6339666A (en) * 1986-08-05 1988-02-20 宇部興産株式会社 Air separator

Patent Citations (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JPS6339666A (en) * 1986-08-05 1988-02-20 宇部興産株式会社 Air separator

Cited By (7)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
WO1994022599A1 (en) * 1993-03-31 1994-10-13 Onoda Cement Co., Ltd. Vortex type air classifier
US5533629A (en) * 1993-03-31 1996-07-09 Onodo Cement Co., Ltd Vortex pneumatic classifier
WO2010101270A1 (en) * 2009-03-03 2010-09-10 Ricoh Company, Ltd. Classifying apparatus, classifying method, and method for producing toner
JP2010227924A (en) * 2009-03-03 2010-10-14 Ricoh Co Ltd Classifier and classifying method
US9004285B2 (en) 2009-03-03 2015-04-14 Ricoh Company, Ltd. Classifying apparatus, classifying method, and method for producing toner
WO2015151187A1 (en) * 2014-03-31 2015-10-08 ホソカワミクロン株式会社 Classifier
JPWO2015151187A1 (en) * 2014-03-31 2017-04-13 ホソカワミクロン株式会社 Classifier

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