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JPH0336868B2 - - Google Patents
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JPH0336868B2 - - Google Patents

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Publication number
JPH0336868B2
JPH0336868B2 JP15180585A JP15180585A JPH0336868B2 JP H0336868 B2 JPH0336868 B2 JP H0336868B2 JP 15180585 A JP15180585 A JP 15180585A JP 15180585 A JP15180585 A JP 15180585A JP H0336868 B2 JPH0336868 B2 JP H0336868B2
Authority
JP
Japan
Prior art keywords
coal
coke oven
carbonization chamber
coke
charged
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
Application number
JP15180585A
Other languages
Japanese (ja)
Other versions
JPS6211794A (en
Inventor
Motofumi Kurahashi
Takumi Muramatsu
Tsutomu Matsubara
Kunihito Onochi
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.)
Nippon Steel Corp
Original Assignee
Nippon Steel Corp
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 Nippon Steel Corp filed Critical Nippon Steel Corp
Priority to JP15180585A priority Critical patent/JPS6211794A/en
Publication of JPS6211794A publication Critical patent/JPS6211794A/en
Publication of JPH0336868B2 publication Critical patent/JPH0336868B2/ja
Granted legal-status Critical Current

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  • Coke Industry (AREA)

Description

【発明の詳細な説明】 (産業上の利用分野) 本発明はコークス炉炭化室内へ装入された粉炭
を加振圧密する装置に関するものである。
DETAILED DESCRIPTION OF THE INVENTION (Field of Industrial Application) The present invention relates to an apparatus for vibrating and compacting pulverized coal charged into a coke oven carbonization chamber.

(従来の技術) 工業用大型コークス炉設備の概要は第4図およ
び第5図に示される如くであり、コークス炉炭化
室Aは一室の大きさが、一例をあげれば幅0.4な
いし0.5m、高さ5ないし6m、裏側から表側迄
の長さ14ないし15mあり、表側裏側にはそれぞれ
開閉扉1,2を備えるとともに上部には4ないし
5個の粉炭装入口3が設けられている。かかるコ
ークス炉炭化室Aは間に燃焼室Bを配置して80室
ないし100室が並置されて炉団を構成し、該炉団
の上部を炭化室Aの粉炭装入口3に対応する数の
粉炭ホツパー4を有する粉炭装入車Cが炭化室A
の幅方向に走行し、各炭化室Aに粉炭を装入する
ようになされている。粉炭は炭化室A内にその高
さの約80%まで供給装入されるが、粉炭の安息角
(36゜ないし40゜)に従つて各装入口3の直下に頂
部をもつた凹凸面5を形成する。
(Prior art) The outline of large-scale industrial coke oven equipment is as shown in Figures 4 and 5, and the coke oven carbonization chamber A has a width of 0.4 to 0.5 m, for example. It has a height of 5 to 6 m, and a length from the back side to the front side of 14 to 15 m, and is provided with opening/closing doors 1 and 2 on the front and back sides, respectively, and four or five pulverized coal charging inlets 3 are provided at the top. In this coke oven carbonization chamber A, combustion chambers B are disposed between them, and 80 to 100 chambers are arranged side by side to form a furnace group, and the upper part of the furnace group is connected to the number corresponding to the pulverized coal charging inlets 3 of the coke oven A. A pulverized coal charging vehicle C having a pulverized coal hopper 4 is placed in the carbonization chamber A.
It runs in the width direction of the carbonization chamber A and charges powdered coal into each carbonization chamber A. Powdered coal is charged into the carbonization chamber A up to about 80% of its height, and an uneven surface 5 with a top is formed directly below each charging port 3 according to the angle of repose of the powdered coal (36° to 40°). form.

コークス炉団の裏側には装入粉炭の上記凹凸面
5を水平にならすためのレベラーDおよび生成コ
ークスを炭化室Aから押出すための押出機Eを搭
載した走行台車Fが配設されている。すなわちレ
ベラーDは、押出機Eの上部レベルにあつて粉炭
装入後数回炭化室Aの裏側から表側まで前進後退
を繰り返すことにより、装入粉炭の前記凹凸面5
を均等にならし発生ガス道6を確保させるもので
あり、その一例について説明すると、第6図に示
すように炭化室Aの全長にわたつて進入しかつ退
出可能な長さを有し、二枚の側板9,9とこれら
両側板間に所要のピツチをもつて取付けられた仕
切板10,10からなるビーム本体8と、該ビー
ム本体8をほぼ水平に支持案内するための数組の
ガイドローラー11と、前記ビーム本体8を炭化
室Aの裏扉2の上部に設けた小扉口7を通して前
進後退させるためのビーム駆動手段12とを備え
たものである。ビーム駆動手段12は走行台車F
上に設置した駆動用ドラム13、前後の固定案内
シーブ14,14およびこれらに巻付けられたエ
ンドレスロープ15からなり、該エンドレスロー
プ15はクリツプ16によりビーム本体8の後方
箇所に結着されている。したがつて駆動用ドラム
13を正逆転せしめることによりビーム本体8は
炭化室Aの全長にわたり進入退出することがで
き、仕切板10が粉炭の凹凸面5を掻きならして
レベリングを行なうものである。
On the back side of the coke oven group, there is disposed a traveling trolley F equipped with a leveler D for leveling the uneven surface 5 of the charged pulverized coal and an extruder E for pushing the produced coke out of the carbonization chamber A. . That is, the leveler D is located at the upper level of the extruder E and moves forward and backward several times from the back side to the front side of the carbonization chamber A after charging the pulverized coal, thereby improving the uneven surface 5 of the charged pulverized coal.
To explain one example of this, as shown in Fig. 6, it has a length that allows entry and exit over the entire length of the carbonization chamber A, and two A beam body 8 consisting of two side plates 9, 9 and partition plates 10, 10 installed with a required pitch between these side plates, and several sets of guides for supporting and guiding the beam body 8 almost horizontally. It is equipped with a roller 11 and a beam driving means 12 for moving the beam main body 8 forward and backward through a small door opening 7 provided at the upper part of the back door 2 of the carbonization chamber A. The beam driving means 12 is a traveling trolley F.
It consists of a driving drum 13 installed above, front and rear fixed guide sheaves 14, 14, and an endless rope 15 wrapped around these, and the endless rope 15 is tied to the rear part of the beam body 8 with a clip 16. . Therefore, by rotating the driving drum 13 in the forward and reverse directions, the beam body 8 can move in and out over the entire length of the carbonization chamber A, and the partition plate 10 scrapes the uneven surface 5 of the powdered coal to perform leveling. .

レベラーDの下位レベルに配設されている押出
機Eはコークス生成後、炭化室Aの表裏扉1,2
をあけ、その押出しラム17を炭化室A内に押進
め、生成コークスを表扉1側のコークスガイド車
Gを経て消火車Hへ押出し放出する。
The extruder E installed at the lower level of the leveler D uses the front and back doors 1 and 2 of the carbonization chamber A after producing coke.
is opened, the extrusion ram 17 is pushed into the carbonization chamber A, and the generated coke is pushed out and discharged to the fire extinguisher H through the coke guide car G on the front door 1 side.

以上はコークス炉設備の概要であるが、かかる
コークス炉で生成された乾留コークスの強度は、
装入粉炭の装入嵩密度を大きくすることにより改
善される。このことは嵩密度が大きい程粉炭粒子
間距離が小さくなることから、理論的にも、また
経験的にも知られている。すなわち粉炭粒度3mm
アンダー85%、含有水分8%の粉炭を実験資料と
して装入口から落下高さを変え堆積深さ(m)と
嵩密度(ton/m3)との関係をみると、第7図a
に示すように落下高さが大きい程また堆積深さが
大きい程嵩密度が大きくなり、試験炉で生成され
たコークスの冷間強度指数DI150 15(%)と装入深さ
(m)との関係、或は装入嵩密度(ton/m3)と冷
間強度指数DI150 15(%)との関係をみるとそれぞれ
第7図bおよび第7図cに示すようになり装入粉
炭の嵩密度が大きい程生成コークスの強度も大と
なることが判る。
The above is an overview of coke oven equipment, but the strength of carbonized coke produced in such a coke oven is
This can be improved by increasing the bulk density of the charged pulverized coal. This is known both theoretically and empirically because the larger the bulk density, the smaller the distance between powdered coal particles. In other words, the particle size of powdered coal is 3 mm.
Figure 7a shows the relationship between the deposition depth (m) and the bulk density (ton/m 3 ) by varying the height of drop from the charging port using powdered coal with 85% undercoat and 8% moisture content as experimental materials.
As shown in Figure 2 , the larger the falling height and the larger the deposition depth , the larger the bulk density. The relationship between the charging bulk density (ton/m 3 ) and the cold strength index DI 150 15 (%) is shown in Figures 7b and 7c, respectively. It can be seen that the greater the bulk density of coke, the greater the strength of the produced coke.

従来からコークス炉炭化室への粉炭装入は、前
記したように炉の上部から自然落下により行なわ
れており、炭化室の下部では落下高さが大きいこ
とおよび堆積自重による圧密作用が大きいことに
よつて嵩密度は大きくなるが、上部にゆく程嵩密
度は小さい。このような嵩密度の炉内分布では、
生成コークスの強度、品質が不均一であり、生産
性の向上は望めず、特に弱粘結炭使用の場合には
壊裂強度の低いコークスとなり銃鉄製造に還元剤
として高炉に装入した場合粉化率の増大による通
気性、通液性の保持が困難となり、生産性の低下
など高炉操業に支障を来たす原因にもなるもので
ある。このようなコークス炉炭化室内装入炭表層
部の低嵩密度に起因する生成コークスの強度、品
質の不均一を解消するための従来技術としては、
例えば特公昭59−18434号公報に示されるように、
レベラービームの先端に加振部材を設け、該加振
部材により、装入炭を加圧、加振することを特徴
とする加振充填装置がある。
Conventionally, pulverized coal has been charged into the coke oven carbonization chamber by falling naturally from the top of the furnace, as described above. Therefore, the bulk density increases, but the higher it goes to the top, the lower the bulk density becomes. With such a bulk density distribution in the furnace,
The strength and quality of the produced coke is uneven, and no improvement in productivity can be expected, especially when weakly coking coal is used, resulting in coke with low bursting strength when charged into a blast furnace as a reducing agent for gun iron production. Due to the increased pulverization rate, it becomes difficult to maintain air permeability and liquid permeability, which may cause problems in blast furnace operation such as decreased productivity. Conventional techniques for solving the non-uniformity in strength and quality of coke produced due to the low bulk density of the surface layer of coal input into the coke oven carbonization chamber include:
For example, as shown in Japanese Patent Publication No. 59-18434,
There is a vibratory filling device that is characterized in that a vibrating member is provided at the tip of a leveler beam, and the charged coal is pressurized and vibrated by the vibrating member.

(発明が解決しようとする問題点) 前記レベラービーム先端に加振部材を設け、装
入炭を加圧、加振する装置には、コークス炉操業
(生産性)を損なうことなく加圧、加振作業が終
了することが要求される。そのためには、振動源
からの発生振動力を高めるなどして短時間の作業
で高い圧密効果が得られなければならない。しか
しその反面、単に振動力を高めるなどの手段で
は、レベラービームの異常振動、特に横振動の発
生源因となり、コークス炉壁倒壊等が懸念される
問題を抱えていた。本発明は上記コークス炉壁の
安全性を保持しつつ、かつ高い装入炭圧密効果が
得られる装入炭加振圧密装置を提供するものであ
る。
(Problems to be Solved by the Invention) A device for pressurizing and vibrating charged coal by providing a vibrating member at the tip of the leveler beam is capable of pressurizing and vibrating the charged coal without impairing coke oven operation (productivity). The shaking operation is required to be completed. To achieve this, it is necessary to obtain a high compaction effect in a short time by increasing the vibration force generated from the vibration source. However, on the other hand, simply increasing the vibration force causes problems such as abnormal vibrations of the leveler beam, especially lateral vibrations, which may cause the coke oven wall to collapse. The present invention provides a charged coal vibratory compaction device that can obtain a high charged coal compaction effect while maintaining the safety of the coke oven wall.

(問題点を解決するための手段) すなわち、本発明の装置によれば、物理的な力
として、加圧力と振動力を装入粉炭のレベリング
された上面に与えることによつて、粉炭の嵩密度
を炭化室の上下および幅方向で均一に高めること
ができ、これによつて生産性の向上および壊裂強
度の高いコークスの製造を可能とするもので、そ
の構成の要旨とするところは、コークス炉炭化室
内へ装入後レベリングされた粉炭上面に接して炭
化室の全長にわたり進入退出可能に設けられたビ
ーム本体と、該ビーム本体の少なくとも先端に、
軸心上偏心質量を有するウエイトを複数個直列に
設け、これらのウエイトが互いに逆回転する加
圧、加振手段を備えたことを特徴とするものであ
る。本発明装置は装入炭のレベラービーム自体に
加圧、加振部材を設けても有効な手段となるもの
である。
(Means for Solving the Problems) That is, according to the device of the present invention, by applying pressing force and vibration force as physical forces to the leveled upper surface of the charged pulverized coal, the bulk of the pulverized coal can be increased. The density can be increased uniformly in the top, bottom, and width directions of the carbonization chamber, thereby making it possible to improve productivity and produce coke with high bursting strength. A beam body that is provided in contact with the upper surface of the pulverized coal that has been leveled after being charged into the coke oven carbonization chamber so as to be able to enter and exit over the entire length of the carbonization chamber, and at least at the tip of the beam body,
The present invention is characterized in that a plurality of weights each having an axially eccentric mass are provided in series, and that these weights are provided with pressurizing and vibrating means that rotate in opposite directions. The device of the present invention is an effective means even if a pressurizing and vibrating member is provided on the leveler beam itself of the charged coal.

(実施例) 次に実施例によつて本発明装置を詳細に説明す
る。本実施例は装入炭のレベラービームをビーム
本体として構成したもので第1図において8は、
2枚の長尺の側板9,9と長手方向に所要のピツ
チに取付けられている仕切板10,10とで多数
の底抜け区画が構成されているビーム本体で、該
ビーム本体8の先端部には屈折起伏自在に加振部
材18がその後端下部において枢着軸19により
ビーム本体8に枢着されている。該加振部18は
粉炭に対する加圧、加振面をなす底板20と長孔
21を有する引起し腕22とを有し、底板20の
上面にはその軸心長手方向に偏心質量を有するウ
エイト23が軸受33によつて回転可能なように
支持されている。また2つのウエイトの中間部に
は該ウエイトの軸に平歯車29が取り付けられ、
互いに逆方向に回転する構造となつている。ビー
ム本体8の後端部分には加振部材18の引起し駆
動用のシリンダー24が装着され、該シリンダー
24により引作動される牽引ロツド25の先端に
設けたピン26を前記引起し腕22の長孔21に
挿通してある。前記シリンダー24は、電磁弁2
7を介して供給される油圧等により作動され、牽
引ロツド25をストローク運動させることにより
加振部材18をビーム本体8と一線をなすように
引起し、或いは引起し腕22の長孔21の範囲内
で屈折降下させることができる。また、同じくビ
ーム本体8の後端部分には、ビーム先端の加振部
材18の内部に設置された偏心質量を有するウエ
イト23を駆動する速度可変電動モータ32が取
り付けられ、ビーム本体8の内部には、これを伝
達する長尺駆動軸31が慣通している。該長尺駆
動軸31の先端と、加振部材内部の偏心質量を有
するウエイト23の軸端とはボールジヨイント3
0によつて接続され、先端の加振部材18がビー
ム本体8に対して任意の角度で屈折しているとき
も速度可変電動モータ32の駆動力は伝達可能と
なる。
(Example) Next, the apparatus of the present invention will be explained in detail with reference to an example. In this embodiment, the leveler beam for charging coal is used as the beam main body, and 8 in FIG.
The beam body has a large number of hollow sections formed by two long side plates 9, 9 and partition plates 10, 10 attached at required pitches in the longitudinal direction. A vibrating member 18 is pivotally connected to the beam body 8 by a pivot shaft 19 at the lower rear end thereof so as to be able to bend and rise freely. The vibrating unit 18 has a bottom plate 20 that serves as a pressurizing and vibrating surface for powdered coal, and a lifting arm 22 having a long hole 21. A weight having an eccentric mass in the longitudinal direction of the axis is mounted on the top surface of the bottom plate 20. 23 is rotatably supported by a bearing 33. Further, a spur gear 29 is attached to the shaft of the two weights in the middle part thereof,
They are designed to rotate in opposite directions. A cylinder 24 for raising and driving the vibrating member 18 is attached to the rear end portion of the beam body 8, and a pin 26 provided at the tip of a pulling rod 25 that is pulled by the cylinder 24 is connected to the raising arm 22. It is inserted into the elongated hole 21. The cylinder 24 is a solenoid valve 2
It is actuated by hydraulic pressure or the like supplied through 7, and by making a stroke movement of the traction rod 25, the excitation member 18 is raised to be in line with the beam body 8, or within the range of the elongated hole 21 of the lifting arm 22. It can be refracted and lowered within. Similarly, a variable speed electric motor 32 is attached to the rear end portion of the beam body 8 to drive a weight 23 having an eccentric mass installed inside the vibrating member 18 at the tip of the beam. A long drive shaft 31 that transmits this is commonly used. The tip of the elongated drive shaft 31 and the shaft end of the weight 23 having an eccentric mass inside the vibrating member are connected to a ball joint 3.
0, and the driving force of the variable speed electric motor 32 can be transmitted even when the vibrating member 18 at the tip is bent at an arbitrary angle with respect to the beam body 8.

加振部材18は偏心質量を有するウエイト2
3、平歯車29並び軸受33を収納した密閉容器
体とすることができ、第1図に示すものはビーム
本体8の先端部区画内に加振部材18を収納可能
にした実施例であるが、あるいはビーム本体8の
先端部分をそのまま加振部材としてもよい。
The vibration member 18 is a weight 2 having an eccentric mass.
3. It can be made into a closed container housing the spur gear 29 and bearing 33, and the one shown in FIG. Alternatively, the tip portion of the beam body 8 may be used as the vibrating member.

加振部材18は牽引ロツド25による牽引を解
き、かつビーム本体8の後端部分に設置された電
動モータにより、長尺駆動軸31を介して加振部
材18内部の偏心質量を有するウエイト23に回
転運動を行なわせることにより、コークス炉炭化
室A内におけるレベリングされた粉炭上面に底板
板20を介して所要の加圧力並びに振動を付与す
ることができる。
The vibrating member 18 is released from the traction by the traction rod 25, and is driven by an electric motor installed at the rear end of the beam body 8 to a weight 23 having an eccentric mass inside the vibrating member 18 via a long drive shaft 31. By performing the rotational movement, the required pressing force and vibration can be applied to the leveled upper surface of the pulverized coal in the coke oven carbonization chamber A via the bottom plate 20.

なお石炭は第2図に示すように10〜20Hzの振動
周波数域での圧密効果が高く、速度可変電動モー
タ32は石炭の湿分、粒度分布で決定される最適
振動数を設定して最も効果的な加振圧密をするこ
とができる。
As shown in Figure 2, coal has a high consolidation effect in the vibration frequency range of 10 to 20Hz, and the variable speed electric motor 32 is set at the optimum vibration frequency determined by the moisture content and particle size distribution of the coal to achieve the most effect. It is possible to perform vibrational consolidation.

また、第3図に2つの偏心質量を有するウエイ
ト23の運動の状態を示す。ウエイト23aには
電動モータ32からの回転運動が伝達され、ウエ
イト23bは平歯車29により逆方向に回転され
る。このウエイトを回転させた場合その遠心力
は、ウエイト軸の軸芯から重心に向かつてその直
線上に発生するが、2つのウエイト23a,23
bを互いに逆方向に回転させるため、その合成力
を考えた場合、2つのウエイトが360゜回転する如
何なる場合でも、横向きの力は相殺され上向き或
いは下向きの力のみが残ることになる。したがつ
て、加振部材18は、コークス炭化室Aの炉壁に
危害を及ぼす横方向の力を発生することなく、装
入炭圧密に作用する上下方向の力のみを持つて、
装入炭表層に加圧、加振を付与することが可能と
なる。
Further, FIG. 3 shows the state of movement of the weight 23 having two eccentric masses. Rotational motion from the electric motor 32 is transmitted to the weight 23a, and the weight 23b is rotated by the spur gear 29 in the opposite direction. When this weight is rotated, the centrifugal force is generated in a straight line from the axis of the weight shaft toward the center of gravity, but when the two weights 23a, 23
Since b is rotated in opposite directions, considering the resultant force, even if the two weights rotate 360 degrees, the lateral forces will cancel out and only the upward or downward force will remain. Therefore, the vibrating member 18 has only a vertical force that acts on the compaction of the charged coal, without generating a lateral force that would harm the furnace wall of the coke carbonization chamber A.
It becomes possible to apply pressure and vibration to the surface layer of charged coal.

またビーム本体8は長尺であるため固有振動数
が低く加振周波数帯で共振して、ビームの異常振
動とコークス炉壁の破壊が懸念されるが、速度可
変電動モータ32の回転数の設定により共振点を
回避し、もしくは回転数を常時変化させることに
より共振現象を抑制することができる。
Furthermore, since the beam main body 8 is long, its natural frequency is low and it resonates in the excitation frequency band, causing concerns about abnormal vibration of the beam and destruction of the coke oven wall. The resonance phenomenon can be suppressed by avoiding the resonance point or by constantly changing the rotation speed.

このような装置で32m3のコークス炉炭化室にお
いて、加振部材の振動数15Hz、加圧力560Kg、
加振時間3secで圧密作業を行なつたところ、炭化
室内の粉炭上層部から深さ1m以内のところでは
装入炭の嵩密度を1.0m3当り0.1ton増して、刻部
におけるコークス強度DI150 15が2.7%向上した。
In a coke oven carbonization chamber of 32 m 3 with such equipment, the vibration frequency of the vibrating member is 15 Hz, the pressing force is 560 kg,
When consolidation work was performed with an excitation time of 3 seconds, the bulk density of the charged coal was increased by 0.1 ton per 1.0 m 3 within a depth of 1 m from the upper layer of powdered coal in the coking chamber, and the coke strength at the carved part was DI 150. 15 improved by 2.7%.

(発明の効果) 以上説明した如く、本発明の装入炭加振圧密装
置によれば、生成コークスの壊裂強度が高く、か
つほぼ均一なコークスを製造することが可能とな
り、コークス炉操業の生産性の向上が図られ、さ
らに高炉の操業に当り粉化率の少ない還元剤とな
り、高炉の操業、生産性の向上に寄与するところ
が極めて大きい。
(Effects of the Invention) As explained above, according to the charged coal vibratory compaction device of the present invention, it is possible to produce coke with high bursting strength and substantially uniform coke, which improves coke oven operation. Productivity is improved, and it also serves as a reducing agent with a low pulverization rate during blast furnace operation, making an extremely large contribution to improving blast furnace operation and productivity.

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

第1図は本発明実施例装置要部の側面図、第2
図は加振周波数と石炭圧代の関係図、第3図a,
b,cは先端加振部材内部に設置される2つの偏
心質量を有するウエイトの運動を示す略図、第4
図および第5図はコークス炉設備の概要を示す側
面図および平面図、第6図はレベラーの一例を示
す側面図、第7図はa,b,cは粉炭および生成
コークスの冷間モデルテスト結果を示す図表であ
る。 A……コークス炉炭化室、B……燃焼室、C…
…粉炭装入車、D……レベラー、E……押出機、
F……走行台車、G……コークガイド車、H……
消火車、1……表扉、2……裏扉、3……粉炭装
入口、4……粉炭ホツパー、5……凹凸面、6…
…発生ガス道、7……小扉口、8……ビーム本
体、9……側板、10……仕切板、11……ガイ
ドローラー、12……ビーム駆動手段、13……
駆動用ドラム、14……固定案内シーブ、15…
…エンドレスロープ、16……クリツプ、17…
…押出しラム、18……加振部材、19……枢着
軸、20……底板、21……長孔、22……引起
し腕、23……偏心質量を有するウエイト、24
……引起し駆動用シリンダ、25……牽引ロツ
ド、26……ピン、27……電磁弁、28……ギ
ヤーボツクス、29……平歯車、30……ボール
ジヨイント、31……長尺駆動軸、32……電動
モータ、33……軸受。
Fig. 1 is a side view of the main parts of the device according to the embodiment of the present invention;
The figure shows the relationship between excitation frequency and coal pressure, Figure 3a,
b, c are schematic diagrams showing the movement of a weight having two eccentric masses installed inside the tip excitation member;
Figure 5 and Figure 5 are a side view and plan view showing an overview of the coke oven equipment, Figure 6 is a side view showing an example of a leveler, Figure 7 is a, b, and c, a cold model test of pulverized coal and produced coke. This is a chart showing the results. A...Coke oven carbonization chamber, B...Combustion chamber, C...
...Powdered coal charging car, D...Leveler, E...Extruder,
F...Traveling trolley, G...Coke guide car, H...
Fire engine, 1... Front door, 2... Back door, 3... Powdered coal loading inlet, 4... Powdered coal hopper, 5... Uneven surface, 6...
... Generated gas path, 7 ... Small door opening, 8 ... Beam main body, 9 ... Side plate, 10 ... Partition plate, 11 ... Guide roller, 12 ... Beam driving means, 13 ...
Drive drum, 14...Fixed guide sheave, 15...
...Endless rope, 16...Clip, 17...
... Extrusion ram, 18 ... Vibrating member, 19 ... Pivoting shaft, 20 ... Bottom plate, 21 ... Elongated hole, 22 ... Lifting arm, 23 ... Weight having eccentric mass, 24
... Cylinder for lifting drive, 25 ... Traction rod, 26 ... Pin, 27 ... Solenoid valve, 28 ... Gearbox, 29 ... Spur gear, 30 ... Ball joint, 31 ... Long drive Shaft, 32... electric motor, 33... bearing.

Claims (1)

【特許請求の範囲】 1 コークス炉炭化室内へ装入後レベリングされ
た粉炭上面に接して炭化室の全長にわたり進入退
出可能に設けられたビーム本体と、該ビーム本体
の少なくとも先端に、軸心上偏心質量を有するウ
エイトを複数個直列に設け、これらのウエイトが
互いに逆回転する加圧、加振手段を備えたことを
特徴とするコークス炉内装入炭加振圧密装置。 2 ウエイトの回転速度を可変自在としたことを
特徴とする特許請求の範囲第1項に記載のコーク
ス炉内装入炭加振圧密装置。 3 ビーム本体としてレベラービームを用い、該
レベラービームの先端部に屈折可能に枢着された
枠状区画を設け、該枠状区画内に前記加圧、加振
部材を収納し得るように設けたことを特徴とする
特許請求の範囲第1項に記載のコークス炉内装入
炭加振圧密装置。
[Scope of Claims] 1. A beam body that is provided in contact with the upper surface of the pulverized coal that has been leveled after being charged into the coke oven carbonization chamber so as to be able to enter and exit over the entire length of the carbonization chamber, and at least a tip of the beam body that 1. A vibratory compaction device for coal in a coke oven, characterized in that a plurality of weights each having an eccentric mass are arranged in series, and the weights are pressurized and vibrated to rotate in opposite directions. 2. The coke oven coal charging vibration consolidation apparatus according to claim 1, characterized in that the rotational speed of the weight is variable. 3. A leveler beam is used as the beam main body, and a frame-shaped section is provided at the tip of the leveler beam so that it can be bent and pivoted, and the pressurizing and vibrating member is provided within the frame-shaped section. The apparatus for vibratory consolidation of coal in a coke oven according to claim 1.
JP15180585A 1985-07-10 1985-07-10 Device for vibrating and consolidating coal to be fed to coke oven Granted JPS6211794A (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
JP15180585A JPS6211794A (en) 1985-07-10 1985-07-10 Device for vibrating and consolidating coal to be fed to coke oven

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
JP15180585A JPS6211794A (en) 1985-07-10 1985-07-10 Device for vibrating and consolidating coal to be fed to coke oven

Publications (2)

Publication Number Publication Date
JPS6211794A JPS6211794A (en) 1987-01-20
JPH0336868B2 true JPH0336868B2 (en) 1991-06-03

Family

ID=15526687

Family Applications (1)

Application Number Title Priority Date Filing Date
JP15180585A Granted JPS6211794A (en) 1985-07-10 1985-07-10 Device for vibrating and consolidating coal to be fed to coke oven

Country Status (1)

Country Link
JP (1) JPS6211794A (en)

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