JPH0491852A - Structure and method for cooling belt in twin belt type continuous casting apparatus - Google Patents
Structure and method for cooling belt in twin belt type continuous casting apparatusInfo
- Publication number
- JPH0491852A JPH0491852A JP20980190A JP20980190A JPH0491852A JP H0491852 A JPH0491852 A JP H0491852A JP 20980190 A JP20980190 A JP 20980190A JP 20980190 A JP20980190 A JP 20980190A JP H0491852 A JPH0491852 A JP H0491852A
- Authority
- JP
- Japan
- Prior art keywords
- belt
- cooling
- cooling water
- nozzle
- continuous casting
- 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.)
- Granted
Links
- 238000001816 cooling Methods 0.000 title claims abstract description 59
- 238000000034 method Methods 0.000 title claims abstract description 6
- 238000009749 continuous casting Methods 0.000 title claims description 17
- 239000000498 cooling water Substances 0.000 claims abstract description 37
- 238000005266 casting Methods 0.000 claims abstract description 21
- 230000002093 peripheral effect Effects 0.000 claims abstract description 3
- 239000002184 metal Substances 0.000 claims description 11
- 229910052751 metal Inorganic materials 0.000 claims description 11
- 238000002347 injection Methods 0.000 abstract description 3
- 239000007924 injection Substances 0.000 abstract description 3
- 238000010586 diagram Methods 0.000 description 4
- 230000007547 defect Effects 0.000 description 2
- 229910001018 Cast iron Inorganic materials 0.000 description 1
- 230000004323 axial length Effects 0.000 description 1
- 238000005516 engineering process Methods 0.000 description 1
- 230000017525 heat dissipation Effects 0.000 description 1
- 238000010438 heat treatment Methods 0.000 description 1
- 238000003780 insertion Methods 0.000 description 1
- 230000037431 insertion Effects 0.000 description 1
- 230000005855 radiation Effects 0.000 description 1
- 239000007921 spray Substances 0.000 description 1
- 238000005507 spraying Methods 0.000 description 1
- XLYOFNOQVPJJNP-UHFFFAOYSA-N water Substances O XLYOFNOQVPJJNP-UHFFFAOYSA-N 0.000 description 1
Landscapes
- Continuous Casting (AREA)
Abstract
Description
【発明の詳細な説明】
〔産業上の利用分野、1
本発明は、薄板の連続鋳造に用いら才する双ベルト式連
続鋳造装置のベルトの冷却構造と同冷却構造を使用する
冷却方法に関する。DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application, 1] The present invention relates to a belt cooling structure of a twin-belt continuous casting apparatus used for continuous casting of thin plates, and a cooling method using the same cooling structure.
一対のベルトによって鋳造する薄板の肉厚方向の鋳造空
間を形成し、注湯ノズルからの溶湯を連続的に供給して
連続鋳造する双ベルト式の連続鋳造装置が従来から利用
されている。第7図はこの双ベルト式の連続鋳込装置の
要部の概要を示すものである。BACKGROUND OF THE INVENTION Conventionally, a twin-belt type continuous casting apparatus has been used, in which a pair of belts forms a casting space in the thickness direction of a thin plate to be cast, and molten metal is continuously supplied from a pouring nozzle for continuous casting. FIG. 7 shows an outline of the main parts of this twin-belt type continuous casting device.
一文1の金属製のべtp ト50.51がそれぞれ駆動
プーリ52.53反びプーリ、う4に巻き付(〕られ、
はぼ垂直方向にバス−4゛る部分のベル)50.51の
間を鋳造空間どしでいる4、また、この鋳造空間に相当
する部分にはベル)50.51の裏面を受けてその変形
の抑制お冷却を兼ねたフィン℃】−ル55が配置さ才1
ている。そり、−(:、n−湯ノズル56が鋳造空間の
上端部に差[1,込」:れ、供給(また溶湯はベルト5
0.51の間で薄い11片Alなって下流側に排出され
る。The metal belts 50 and 51 of Sentence 1 are wound around drive pulleys 52 and 53, respectively, and around pulleys 4.
There is a casting space between the bell) 50.51 in the vertical direction, and a part corresponding to this casting space that receives the back side of the bell) 50.51. Fins that also serve as cooling and suppressing deformation are placed.
ing. -(:,n- The molten metal nozzle 56 is inserted into the upper end of the casting space, and the molten metal is supplied to the belt 5.
0.51, 11 thin pieces of Al are discharged to the downstream side.
注湯ノズル56からの溶湯1.゛よってベルト50.5
1は加熱さ才するため、これに冷却水を噴射し5て冷却
−イる冷却ノズル57が第8図のJうに設・けられる。Molten metal from pouring nozzle 56 1. Therefore, the belt is 50.5
1 is heated, so a cooling nozzle 57 is provided at J in FIG. 8 for injecting cooling water to the cooling nozzle 5 to cool it down.
この冷却ノズル57の組ろ込ろ構造は、たとえば時開B
E 60−152347号公報に開示されでいる。The loading structure of the cooling nozzle 57 is, for example, a time opening B.
It is disclosed in Japanese Patent No. E 60-152347.
冷却ノズル57(マベル)50.51の幅方向の全長に
1って複数配置I、たものでかつ鋳造方向1.−も複数
配置しまたもので、ぞれぞれから冷却水が図示のように
ベノ【、1・50.filが走る方向へ象1め(、冷却
水を噴射し、またり、またはベノL450.51の裏面
1.“垂11↑11、゛噴流を当て°こ冷却する。Cooling nozzles 57 (Mabel) 50. A plurality of cooling nozzles 57 (Mabel) are arranged along the entire length in the width direction of 51, and a plurality of cooling nozzles 57 (Mabel) are arranged in the casting direction 1. - are also arranged in multiple places, and the cooling water flows from each one as shown in the figure. Spray the cooling water in the direction in which the fil runs, or apply the jet to cool the back surface of the Beno L450.51.
〔発明が解決L2ようとづる課題〕
と、:/〕が、従来構造の冷却ノズル57では、第8図
の。ように冷却水の噴出端がプーリ54の中心、Jりも
1の1.=ベルにある1、このため、ベルト50を停止
[−さ七六ときには、プーリ54の周JIJから離れる
位置と冷却水が当たる位置までの距離1)の範囲は、冷
却されないままとなる。しまたがって、ベルト50苓停
止1シ、でいるαJJに注湯ノズル56を一点鎖線ご承
りように差し、込んてゆくと、この注湯ノズル56は予
熱されでいるのでその放熱によっで″A−玲却部分のの
ベルト50が加熱され、局所的な熱変形が件じてしまう
。なお、左側のベル)511ごおいても1様な問題が起
、こる。[Problems that the invention seeks to solve L2] and :/] are shown in FIG. 8 in the cooling nozzle 57 of the conventional structure. As shown, the cooling water spout end is at the center of the pulley 54, and the 1. = 1 at the bell, therefore, when the belt 50 is stopped, the range of distance 1) between the position away from the circumference JIJ of the pulley 54 and the position where the cooling water hits remains uncooled. Straddling the belt 50 and stopping the belt 50, insert the pouring nozzle 56 into the αJJ as indicated by the dashed line, and as you insert it, the pouring nozzle 56 has already been preheated, so its heat dissipation causes The belt 50 in the A-reduction portion is heated, causing local thermal deformation.A similar problem also occurs in the belt 511 on the left side.
この上う1こ、ベルト50.51のスター トロ存意て
は非冷却部分は注湯ノズル56の差し込みによっ”C5
ベルト50.51の部分的な変形が避けられない。ごの
たy)、鋳昌への表面品質に影響を与えるほか、ベルト
50.51の交換頻度も高くなって稼動率の低下を招く
一因ともな−、でいた。On top of this, the non-cooled part of the belt 50.
Partial deformation of the belt 50,51 is unavoidable. In addition to affecting the surface quality of the casting hole, the belts 50 and 51 also had to be replaced more frequently, which was one of the causes of lower operating rates.
本発明において解決づべき課題は、双ベルト式の連続鋳
造装置におけるベルトの非冷却部分を無<、Ltその変
形を防止するだめの冷却構造の完成にある。The problem to be solved by the present invention is to complete a cooling structure that prevents deformation of the uncooled portion of the belt in a twin-belt continuous casting machine.
[課題を解決4−るだ?l]の手段]1本発明の冷却構
造は、間隔をおいて設けた一対のプーリを回ってほぼ鉛
直方向に鋳造空間を造り出す一対のベルトと、前記プー
リの周面から離れて走行し、てゆく前記ベルトの裏りに
冷却水を噴射する冷却ノズルと4備え1.前記鋳造空間
の上端部に注湯ノズルを差し込んで溶湯を供給する双ベ
ルト式の連続鋳造装置であって、前記ベルトが前記プー
リの周面から離れる部分と前記冷却ノズルからの冷却水
が当たる部分との間に冷却水を噴出する冷却水噴出装置
を備、才でいることを特徴とする。[Solve the problem 4-Ruda? 1] The cooling structure of the present invention includes a pair of belts that rotate around a pair of pulleys spaced apart to create a casting space in a substantially vertical direction; a cooling nozzle for spraying cooling water onto the back side of the belt; A twin-belt continuous casting device that supplies molten metal by inserting a pouring nozzle into the upper end of the casting space, the part where the belt leaves the peripheral surface of the pulley and the part where the cooling water from the cooling nozzle hits. It is characterized by being equipped with a cooling water jetting device that jets cooling water between the
また、本発明のベルトの冷却方法は、前記冷却水噴出装
置からの冷却水の噴出を、前記注湯ノズルの前記鋳造空
間の」一端部へのIし込み過程から前記ベルトを走行駆
動するまでの開票J、の時間待なうことを特徴上する。In addition, the belt cooling method of the present invention is characterized in that the cooling water is jetted from the cooling water jetting device from the process of injecting the cooling water into one end of the casting space of the pouring nozzle until the belt is driven to run. It is characterized by waiting an amount of time for the vote counting J.
3
〔作用〕
冷却ノズルからの冷却水はベルトを走tJさゼるときに
噴出され、ベルトはその走行によって均一・に冷却され
なから注湯ノズルからの溶湯を受けてこれをr流に送り
出す。一方、ベルトを停止して鋳造態勢に入る前では、
タンデイツシュ等からの注湯ノズルがベルトの間に造ら
れた鋳造空間の」二端部1ご差し込まれる。この注湯ノ
ズルは予熱されているので、その差し込み時には放熱に
よってベルトが加熱される。これに対し、冷却水噴出装
置からは、注湯ノズルの差し込み過程からベルトの走行
開始までの開票上の時間継続して冷却水が噴出される。3 [Function] The cooling water from the cooling nozzle is ejected when the belt runs, and the belt is not uniformly cooled by the running, so it receives the molten metal from the pouring nozzle and sends it out in the flow. . On the other hand, before stopping the belt and entering the casting mode,
A pouring nozzle from a tundish or the like is inserted into the two ends 1 of the casting space created between the belts. Since this pouring nozzle is preheated, when it is inserted, the belt is heated by heat radiation. On the other hand, cooling water is continuously jetted from the cooling water jetting device for the time period from the insertion of the pouring nozzle to the start of running of the belt.
このた?l〕、冷却ノズルによっでは冷却が行なえなか
った注湯ノズル側に近いベルトの部分も冷却さね、操業
開始時点でのベルトの部分的な加熱が抑えられる。した
がって、ベルトは変形や熱歪等を生じることなく走行を
開始し、以降は冷却ノズルからの冷却水によって連続的
に冷却されながら作動4る、。others? l], the belt near the pouring nozzle side, which could not be cooled by the cooling nozzle, is also cooled, and partial heating of the belt at the start of operation can be suppressed. Therefore, the belt starts running without deformation or thermal distortion, and thereafter operates while being continuously cooled by cooling water from the cooling nozzle.
また、ベルトの移鮎速度が速い時、冷却水がかからない
範囲r)の通過時間が短くなり、冷却水を切ってもノズ
ルからの放熱てはベルトが変形や熱歪等を生じなくなる
。、
〔実施例〕
第1図は本発明の要部の構造苓示A縦断1iii図、第
2閏は第1図のI −、、、、、−1線矢視図、第3図
は双ベルト式連続鋳造装置の上端部の縦断…〕図である
。Furthermore, when the belt moves at a high speed, the time it takes to pass through the range r) where the cooling water is not applied becomes short, and even if the cooling water is turned off, the belt will not be deformed or thermally strained due to the heat dissipated from the nozzles. , [Example] Fig. 1 is a vertical cross-sectional view of the main part of the present invention shown in Fig. FIG. 2 is a vertical cross-section of the upper end of the belt-type continuous casting device.
第3図において、従来例でも説明し5たまうに金属製の
一対のベルト1,2がプーリ3,4に巻き付1)tられ
、これらのベルト1.2はそれぞれ駆動ブー・す(図示
せずン1ごよっで図中の矢11.1方向へ走行する。そ
して、垂直力向のバス部分にてきる隙間を鋳造空間とし
てこの中に注湯ノズノL5が差し2込まれでいる3、ま
た、プーリ3.4の1側にはベルト1,2の裏面を受け
て鋳造空間を整えるフィンロール6.7が糾み込まれで
いる。In FIG. 3, a pair of metal belts 1 and 2 are wound around pulleys 3 and 4, as described in the conventional example, and these belts 1 and 2 are connected to drive boots (not shown), respectively. Move in the direction of arrow 11.1 in the figure with the help of Zun 1. Then, the gap that comes to the bus part in the vertical force direction is used as a casting space, and the pouring nozzle L5 is inserted into this space 3. Furthermore, a fin roll 6.7 is embedded on the 1 side of the pulley 3.4 to receive the back surfaces of the belts 1 and 2 and prepare the casting space.
第1図に示すように、プーリ3.4の周りにはそのI!
l而J面りも凹んだ部分に配管3a苓設・げ、ぞの先端
には冷却ノズル8を取すイ・4けごいる。なお、第4図
及び第5図はべ刀ト・1の冷却ノズル・8の配列を示す
部分圧[開図N・び斜視図である。冷却ノズル8は、第
1図のようにベルト1の裏面に沿う姿勢に配置され、そ
のF端から冷却水をベルト1が辻る方向に沿わせて噴出
イる9、また、右側のベルト2に対する冷却ノズル8の
位置や姿勢も同様である。As shown in Figure 1, the I!
The piping 3a is installed in the concave part of the J surface, and the cooling nozzle 8 is installed at the tip of the pipe 3a. Note that FIGS. 4 and 5 are partial pressure views (open view N and perspective view) showing the arrangement of the cooling nozzles 8 of the blade 1. The cooling nozzle 8 is arranged along the back surface of the belt 1 as shown in FIG. The same applies to the position and attitude of the cooling nozzle 8 relative to the other.
ψ−に、冷却ノズル8の背部1、゛は、プーリ3.4の
軸線方向のほぼ全長に亘る冷却ヘッダ9を組み込む。こ
の冷却ヘッダ9がベルト1.2の裏面を向く面には噴出
孔971がその間1−’i]軸線を水平では少しJ−に
向1′jで開けられでいる。これらの噴出7+、;裡は
、第2図に示すように隣接する冷却ノズル8の間に設け
られ、冷却ノズル8の下端の噴出部よりも高い位置にあ
る。そして、冷却ヘッダ9の一端には第4図に示すよう
にインレットgbを設け、外部から適切な水圧の冷却水
をこのインレッhgbから供給し7で各噴出孔9aから
冷却水をベルト1,2の裏σtiに向j・ノて噴射4−
ろ、
以上の構成において、冷却ノズル8に」るベルト1,2
の冷却はぴ′来構造と同様であり、操業開始前からべ、
IIト1.2が走行している[続し、で冷却水を噴出し
てベル)1.2を冷却する。At ψ-, the back 1,'' of the cooling nozzle 8 incorporates a cooling header 9 over almost the entire axial length of the pulley 3.4. On the surface of the cooling header 9 facing the back side of the belt 1.2, jet holes 971 are opened in the direction 1'j, with the 1-'i] axis slightly parallel to J- in the horizontal direction. These jets 7+; are provided between adjacent cooling nozzles 8, as shown in FIG. 2, and are located at a higher position than the jets at the lower ends of the cooling nozzles 8. An inlet gb is provided at one end of the cooling header 9 as shown in FIG. Injection toward the back σti of 4-
In the above configuration, the belts 1 and 2 connected to the cooling nozzle 8
The cooling of the
II To cool down 1.2 while it is running (then blow out cooling water at bell).
また、操業開始の時点では冷却ノズル8に加λ7:玲却
−\ツダ9によっでもベルト1,2を冷却する。この冷
却パ\ツダ9からの冷却水の噴出は、注湯ノズル5を差
し込む過程からベル)1.2を走行させで連鋳作業を開
始する省、での開広」の時間行なう。これは、予熱され
た注湯ノズルを141図のよ・)に差し込むときイ、の
放熱によってベルト1゜2は高温となるので、これを冷
却へラダ9によ−。Further, at the start of operation, the belts 1 and 2 are also cooled by adding λ7 to the cooling nozzle 8 and applying it to the cooling nozzle 8. This spouting of cooling water from the cooling pad 9 is carried out during the time period from the process of inserting the pouring nozzle 5 to the time when the bell 1.2 is run to start continuous casting work. This is because when the preheated pouring nozzle is inserted into the hole shown in Figure 141, the belt 1゜2 becomes hot due to the heat dissipated in ①, so this is cooled down by the ladder 9.
て抑えるためである。ずなわぢ、冷却ノズル8によるだ
けでは、従来例で説明し、たまうに冷却ノズル8からの
冷却水が当たる部分より上側のベルト1.2が注湯ノズ
ル5によって加熱され、ベル11.2に変形を生じてい
た。これに対し、冷却ノズル8では冷却できない注湯ノ
ズル5側のベルト1.2の裏面を冷却ヘッダ9によって
冷却することによ。で、連続鋳造作業の開始時期でのベ
ルト1.2の変形4防止することができZ)。したがっ
て、冷却ノズル8にJ、って冷力■さ才γているベノ1
ト1.2の部分と同様jご、注湯、ノズル5からの放熱
に列シ、でもベルl−1,2の変形がなくなる。This is to suppress the However, if only the cooling nozzle 8 is used, as explained in the conventional example, the belt 1.2 above the part that is hit by the cooling water from the cooling nozzle 8 will be heated by the pouring nozzle 5, and the belt 11.2 will be heated by the pouring nozzle 5. deformation had occurred. In contrast, the cooling header 9 cools the back surface of the belt 1.2 on the pouring nozzle 5 side, which cannot be cooled by the cooling nozzle 8. Therefore, deformation of the belt 1.2 at the start of continuous casting work can be prevented. Therefore, the cooling nozzle 8 has a cooling power of 1.
Similar to the part 1.2, there is no deformation of the bells 1-1 and 2 even though the metal is poured and the heat is dissipated from the nozzle 5.
、−のように、ベルト1.2を停廿させている間にY熱
された注湯ノズル54鋳造空間の1″6部に厚し、込ん
でも、ベルト1.2の変形が生じない。このたy〕、従
来構造に比べる♂、ベルト1,2の変形部分が鋳造空間
をバスづる毎に生じていた語呂への品質欠陥がなくなる
。、また、ベルト〕、2自体も歪等を生じることなく稼
動し5、七の耐久性が向1.すると共に交換頻度も低く
なり稼動率の向上が図られる1、
〔発り」の効果〕
(1) ベルトの間の鋳造空間に注湯ノズルを差し2
込むときに、この注湯ノズルによ−、て加熱される部分
を冷却ノズルによる定常冷却とは別に冷却水噴出装置に
よって冷却するようにしている。このた綽、ベルトを走
行さゼる前に注湯ノズルからの熱によってベルトが部分
的に変形することがなくなリ、鋳造する鋳11゛の表面
品質4向土゛さセる、了、古ができる1゜
(2) ベア11−自体の変形だ1ノてなく運←、初
期にJ)(」る熱堵の発I+も抑(られるので、ベルト
の耐久付も向t= L、、−J交換らn度も従来構が1
、−比べると似、くなり、稼11率の向」二も達成され
る5、(:3)+79「I原人[IJ′よって生じてい
た変jイ〕部)ぐが鋳jZ空間を通、llめ°l−6毎
、Iツテじ″ていた品質欠陥も防止で6きる1、
4図面のP!7i申な説1[1
第1図は本発明の要部の構のを示づ縦ド11山1図、第
2し1は第1Mのl −T線矢視図、第:3図は双べ井
ト式の連続、鋳を装置のト端部の縦帽1面図、第41図
は冷ip ノズル及び冷却ヘッダの噴出イ1..の配置
を示1正1ffi図1.第5図はその棚、略斜視図、第
6図1は冷却ノズルよ冷却−・ラダとによるベルトの除
却状況を示r概略図、第7図は双ベルト式の連続訪iじ
一装置の概略図2第8図は従来の冷却ノズノl、のめる
一備λた要部の概略Vである。, -, even if the Y-heated pouring nozzle 54 thickens to 6 parts of the casting space while the belt 1.2 is stopped, the belt 1.2 will not be deformed. In this way, compared to the conventional structure, the quality defects that occur every time the deformed parts of the belts 1 and 2 pass through the casting space are eliminated.In addition, the belts 1 and 2 themselves also suffer from distortion, etc. It operates without any problems 5, 7, and durability is improved 1. At the same time, the frequency of replacement is reduced and the operating rate is improved. Insert 2
During pouring, the portion heated by the pouring nozzle is cooled by a cooling water jetting device, in addition to steady cooling by the cooling nozzle. This prevents the belt from being partially deformed by the heat from the pouring nozzle before running the belt, and improves the surface quality of the cast iron to be cast. 1゜(2) The deformation of the bear 11- itself ←, the initial J)(" heat release I+ is also suppressed, so the durability of the belt is also improved. , -J exchange, the conventional structure is 1
, - Comparing it, it becomes similar, and the direction of the 11 rate is also achieved. 1 and 4 of the drawings can be prevented by preventing quality defects that would otherwise occur during the entire process. 7i Simple theory 1 [1 Figure 1 shows the structure of the main part of the present invention. Figure 1 shows the structure of the main part of the present invention. Figure 2 shows the structure of the main part of the present invention. Figure 41 is a top view of the vertical cap at the end of the double-bottomed well type continuous casting equipment, and shows the cooling IP nozzle and cooling header jetting point 1. .. Figure 1 shows the arrangement of 1. Fig. 5 is a schematic perspective view of the shelf, Fig. 6 1 is a schematic diagram showing the state of belt removal by the cooling nozzle and cooling ladder, and Fig. 7 is a diagram of the double-belt type continuous visiting device. Schematic Diagram 2 FIG. 8 is a schematic diagram V of the main parts of a conventional cooling nozzle L and a fitting λ.
1、) ベルト・ I′1湯ノズル 冷去1]51ス°ル ;冷却1−\ツタ ・イ)1.・ノド 8 J: 4:プーリ 7:ノイソIコール 配管 噴出孔1.) Belt I'1 hot water nozzle Cooling 1] 51 degrees ;Cooling 1-\Ivy ・B)1.・Throat 8 J: 4: Pulley 7: Noiso I call Piping spout hole
Claims (1)
方向に鋳造空間を造り出す一対のベルトと、前記プーリ
の周面から離れて走行してゆく前記ベルトの裏面に冷却
水を噴射する冷却ノズルとを備え、前記鋳造空間の上端
部に注湯ノズルを差し込んで溶湯を供給する双ベルト式
の連続鋳造装置であって、前記ベルトが前記プーリの周
面から離れる部分と前記冷却ノズルからの冷却水が当た
る部分との間に冷却水を噴出する冷却水噴出装置を備え
てなる双ベルト式連続鋳造装置におけるベルトの冷却構
造。 2、間隔をおいて設けた一対のプーリを回ってほぼ鉛直
方向に鋳造空間を造り出す一対のベルトと、前記プーリ
の周面から離れて走行してゆく前記ベルトの裏面に冷却
水を噴射する冷却ノズルとを備え、前記鋳造空間の上端
部に注湯ノズルを差し込んで溶湯を供給する双ベルト式
の連続鋳造装置であって、前記ベルトが前記プーリの周
面から離れる部分と前記冷却ノズルからの冷却水が当た
る部分との間に冷却水を噴出する冷却水噴出装置を備え
てなる双ベルト式連続鋳造装置におけるベルトの冷却構
造において、冷却水噴出装置からの冷却水の噴出を、注
湯ノズルの鋳造空間の上端部への差し込み過程からベル
トを走行駆動するまでの間以上の時間行なう双ベルト式
連続鋳造装置におけるベルトの冷却方法。[Claims] 1. A pair of belts that rotate around a pair of pulleys spaced apart to create a casting space in a substantially vertical direction, and a back surface of the belt that runs away from the circumferential surface of the pulleys. A twin-belt continuous casting device comprising a cooling nozzle that injects cooling water and supplying molten metal by inserting a pouring nozzle into the upper end of the casting space, the part where the belt separates from the peripheral surface of the pulley. A cooling structure for a belt in a twin-belt continuous casting machine, comprising a cooling water jetting device that jets cooling water between the cooling water jetting device and a portion that is hit by the cooling water from the cooling nozzle. 2. A pair of belts that rotate around a pair of pulleys spaced apart to create a casting space in an almost vertical direction, and a cooling device that injects cooling water onto the back surface of the belt that runs away from the circumferential surface of the pulley. A twin-belt continuous casting device comprising: a pouring nozzle inserted into the upper end of the casting space to supply molten metal; In a belt cooling structure in a twin-belt continuous casting machine, which is equipped with a cooling water jetting device that jets cooling water between the parts that are hit by the cooling water, the jetting of cooling water from the cooling water jetting device is A method for cooling a belt in a twin-belt continuous casting machine, in which the belt is cooled for at least a period of time from the time the belt is inserted into the upper end of the casting space until the belt is driven to run.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
JP2209801A JPH0811276B2 (en) | 1990-08-07 | 1990-08-07 | Belt cooling structure and cooling method in twin belt type continuous casting apparatus |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
JP2209801A JPH0811276B2 (en) | 1990-08-07 | 1990-08-07 | Belt cooling structure and cooling method in twin belt type continuous casting apparatus |
Publications (2)
Publication Number | Publication Date |
---|---|
JPH0491852A true JPH0491852A (en) | 1992-03-25 |
JPH0811276B2 JPH0811276B2 (en) | 1996-02-07 |
Family
ID=16578823
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
JP2209801A Expired - Lifetime JPH0811276B2 (en) | 1990-08-07 | 1990-08-07 | Belt cooling structure and cooling method in twin belt type continuous casting apparatus |
Country Status (1)
Country | Link |
---|---|
JP (1) | JPH0811276B2 (en) |
Cited By (1)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US9476370B2 (en) | 2014-02-20 | 2016-10-25 | Generac Power Systems, Inc. | Single point engine control interface |
Citations (1)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
JPH0199754A (en) * | 1987-10-13 | 1989-04-18 | Sumitomo Metal Ind Ltd | Belt caster |
-
1990
- 1990-08-07 JP JP2209801A patent/JPH0811276B2/en not_active Expired - Lifetime
Patent Citations (1)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
JPH0199754A (en) * | 1987-10-13 | 1989-04-18 | Sumitomo Metal Ind Ltd | Belt caster |
Cited By (1)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US9476370B2 (en) | 2014-02-20 | 2016-10-25 | Generac Power Systems, Inc. | Single point engine control interface |
Also Published As
Publication number | Publication date |
---|---|
JPH0811276B2 (en) | 1996-02-07 |
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