JP2015038233A - Method and installation for production of steel strip - Google Patents

Method and installation for production of steel strip Download PDF

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JP2015038233A
JP2015038233A JP2013169579A JP2013169579A JP2015038233A JP 2015038233 A JP2015038233 A JP 2015038233A JP 2013169579 A JP2013169579 A JP 2013169579A JP 2013169579 A JP2013169579 A JP 2013169579A JP 2015038233 A JP2015038233 A JP 2015038233A
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steel strip
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cooling
rapid cooling
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佐々木 成人
Shigeto Sasaki
成人 佐々木
玄太郎 武田
Gentaro Takeda
玄太郎 武田
高橋 秀行
Hideyuki Takahashi
秀行 高橋
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JFE Steel Corp
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Abstract

PROBLEM TO BE SOLVED: To provide a method and an installation for production of a steel strip which enable stable production a steel strip having intended characteristics without deterioration of productivity and quality.SOLUTION: A method of producing a steel strip by annealing a steel strip continuously comprises chilling a steel strip after heating in an annealing furnace quickly in a rapid cooling apparatus and then heating the quick-chilled steel strip in a rapid heating apparatus arranged on the outlet side of the rapid cooling apparatus so as to keep the surface temperature of the steel strip at the cooling stop temperature.

Description

本発明は、鋼帯の製造方法および製造設備に関する。具体的には、焼鈍した鋼帯を焼入れするために、水冷によって急速冷却する鋼帯の製造方法および製造設備に関する。   The present invention relates to a steel strip manufacturing method and manufacturing equipment. Specifically, the present invention relates to a steel strip manufacturing method and manufacturing equipment that are rapidly cooled by water cooling in order to quench the annealed steel strip.

鋼帯の連続焼鈍において、処理する鋼帯に所期の機械的特性を付与するためには、加熱および冷却という熱処理条件の制御が重要である。特に、近年、高張力鋼板の需要が増大しており、高張力鋼板の製造に有利な急速冷却技術の重要性が増している。急速冷却技術としては、水焼入れ法、ロール冷却法、気水混合(ミスト)冷却法やガスジェット冷却法があり、必要な材質を得るためにそれぞれの方法が適宜選択されている。これらの中で、冷却水に浸漬する水焼入れ法が最も冷却速度が速く、強度を高めるための合金元素の添加も少なくできることから、水焼入れ法は高張力鋼板の製造に適している。   In continuous annealing of a steel strip, it is important to control the heat treatment conditions of heating and cooling in order to impart the desired mechanical properties to the steel strip to be treated. In particular, in recent years, the demand for high-strength steel sheets has increased, and the importance of rapid cooling technology advantageous for the production of high-strength steel sheets has increased. As rapid cooling techniques, there are a water quenching method, a roll cooling method, an air-water mixing (mist) cooling method, and a gas jet cooling method, and each method is appropriately selected in order to obtain a necessary material. Among these, the water quenching method of immersing in cooling water has the fastest cooling rate, and the addition of alloy elements for increasing the strength can be reduced. Therefore, the water quenching method is suitable for manufacturing high-tensile steel sheets.

水焼入れ法は、加熱された鋼帯を水中に浸漬させると同時に、水中内に設けられたクエンチノズルにより冷却水を鋼帯に噴射し、急冷を行う方法が一般的である。しかし、水焼入れ法では、冷却速度が速いために、冷却停止温度を制御することが非常に難しく、鋼帯が浸漬槽内を通過する間に水温まで一気に冷却されてしまう。このため、急冷後の過時効処理において鋼帯を再加熱する際の加熱に大きな負荷をもたらす。一方、再加熱時の加熱の負荷を下げるために、冷却水の水温を上げることが考えられる。しかし、水温の上昇は冷却能力の低下をもたらすため、所定の材質が得られなくなる。   The water quenching method is generally a method in which a heated steel strip is immersed in water, and at the same time, cooling water is sprayed onto the steel strip by a quench nozzle provided in the water to perform rapid cooling. However, in the water quenching method, since the cooling rate is fast, it is very difficult to control the cooling stop temperature, and the steel strip is cooled to the water temperature at a stretch while passing through the immersion tank. For this reason, a big load is brought about to the heating at the time of reheating a steel strip in the overaging treatment after rapid cooling. On the other hand, in order to reduce the heating load during reheating, it is conceivable to increase the coolant temperature. However, an increase in water temperature causes a decrease in cooling capacity, and a predetermined material cannot be obtained.

水焼入れ法の速い冷却速度を維持しつつ、再加熱時の負荷を和らげる方法として、特許文献1が開示されている。特許文献1では、鋼帯を急冷するにあたり、有機酸を含む水溶液を空中でスプレーして冷却を行い、その直後に前記と同一の成分の水溶液中に浸漬させる。そして、浸漬槽内には複数の加熱ロールが設けられており、浸漬中において冷却と同時に加熱も行うことにより、浸漬槽出側における鋼帯の温度を高め、再加熱時の負荷の低減を図っている。また、特許文献2では、連続焼鈍炉におけるストリップの冷却方法として、冷却水と熱水のいずれも切替可能なノズルを設置し、鋼帯を所定の温度に停止させる方法が開示されている。また、特許文献2では、熱水を噴射する際に、ノズルから噴射された熱水のうち蒸気にならなかった液滴を下流側へ排水させないように、トレイを介して受水槽に捕集している。   Patent Document 1 is disclosed as a method for reducing the load during reheating while maintaining the high cooling rate of the water quenching method. In patent document 1, when quenching a steel strip, it cools by spraying the aqueous solution containing an organic acid in the air, and immediately after that, it is immersed in the aqueous solution of the same component as the above. In addition, a plurality of heating rolls are provided in the immersion tank, and heating is performed simultaneously with cooling during immersion, thereby increasing the temperature of the steel strip on the exit side of the immersion tank and reducing the load during reheating. ing. Patent Document 2 discloses a method of cooling a strip in a continuous annealing furnace by installing a nozzle capable of switching between both cooling water and hot water, and stopping the steel strip at a predetermined temperature. Moreover, in patent document 2, when injecting hot water, the droplet which did not become a vapor | steam among the hot water injected from the nozzle is collected to a receiving tank through a tray so that it may not drain | drain to the downstream side. ing.

特公平1−18974号公報Japanese Patent Publication No. 1-18974 特開昭61−183415号公報JP-A 61-183415

しかしながら、特許文献1で開示されている方法の場合、空中でのスプレー冷却と浸漬槽内での冷却により冷却速度を確保しているため、冷却長が長くなり、高張力鋼板に必要な冷却速度が得られないという問題がある。また、浸漬槽内の加熱ロールは浸漬槽内の水溶液中にある。このため、加熱ロール内部は加熱されているものの、加熱ロール表面は水溶液と接触しているため、ロール温度は非常に不安定であり、定常的な操業には不向きである。   However, in the case of the method disclosed in Patent Document 1, since the cooling rate is secured by spray cooling in the air and cooling in the immersion bath, the cooling length becomes long, and the cooling rate necessary for the high-tensile steel plate There is a problem that cannot be obtained. Moreover, the heating roll in the immersion tank is in the aqueous solution in the immersion tank. For this reason, although the inside of a heating roll is heated, since the heating roll surface is in contact with the aqueous solution, the roll temperature is very unstable and is not suitable for steady operation.

また、特許文献2に開示されている方法の場合、製品の種類により急冷用ノズルと熱水用ノズルの切替を実施することにより、異なる冷却速度、冷却停止温度にて熱処理を実施する必要がなくなり、パスラインを切り換える必要がなくなるが、熱処理後の再加熱能力の低減効果の有無については述べられておらず、特に急冷用のノズルを用いて冷却を実施した場合には、鋼帯は水温まで冷却されてしまうため、その後、鋼帯を再加熱する際の加熱の負荷を軽減させることは困難である。   In the case of the method disclosed in Patent Document 2, it is not necessary to perform heat treatment at different cooling rates and cooling stop temperatures by switching between the quenching nozzle and the hot water nozzle depending on the type of product. However, there is no need to switch the pass line, but there is no mention of the effect of reducing the reheating ability after heat treatment, especially when cooling is performed using a rapid cooling nozzle, the steel strip will reach the water temperature. Since it will be cooled, it is difficult to reduce the heating load when the steel strip is reheated thereafter.

本発明は、上記課題に鑑みてなされたものであって、生産性や品質を低下させることなく、所望の特性を有する高張力鋼板を安定的に製造することができる鋼帯の製造方法および製造設備を提供することを目的とする。   The present invention has been made in view of the above-described problems, and a steel strip manufacturing method and manufacturing capable of stably manufacturing a high-tensile steel sheet having desired characteristics without reducing productivity or quality. The purpose is to provide equipment.

本発明者らは、前記課題を解決するために鋭意検討した結果、鋼帯を連続焼鈍し、従来と同等の速い冷却速度で急速冷却し、次いで急速加熱装置で加熱することにより、冷却停止温度を従来法の冷却停止温度よりも高くするという方法を見出した。これにより、再加熱時の加熱の負荷を軽減し、生産性を高めることができる。本発明の要旨は以下のとおりである。
[1]鋼帯を連続焼鈍処理する鋼帯の製造方法において、
焼鈍炉での加熱後の鋼帯を急速冷却装置で急冷した後、
前記急速冷却装置の出側に配置される急速加熱装置で、急冷された前記鋼帯を加熱して鋼帯表面温度を冷却停止温度に保持することを特徴とする鋼帯の製造方法。
[2][1]に記載の鋼帯の製造方法において、前記急速冷却装置の入側に鋼帯表面温度を測定する温度計を配置し、前記急速冷却装置の入側で測定される鋼帯表面温度の測定値に基づき前記急速冷却装置の出側の鋼帯表面温度を算出し、該急速冷却装置の出側の鋼帯表面温度と前記急速加熱装置の出側の鋼帯表面温度の目標値とから、前記急速加熱装置の加熱量を制御することを特徴とする鋼帯の製造方法。
[3][1]に記載の鋼帯の製造方法において、前記急速加熱装置の出側に鋼帯表面温度を測定する温度計を配置し、前記急速加熱装置の出側で測定される鋼帯表面温度の測定値と前記急速加熱装置の出側の鋼帯表面温度の目標値とから、前記急速加熱装置の加熱量を制御することを特徴とする鋼帯の製造方法。
[4][1]〜[3]のいずれかに記載の鋼帯の製造方法において、
前記急速冷却装置の入側および出側にそれぞれ一対のロールを配置し、前記鋼帯表面に滞留する冷媒を除去することを特徴とする鋼帯の製造方法。
[5][1]〜[4]のいずれかに記載の鋼帯の製造方法において、
前記急速冷却装置は鋼帯が下方から上方に移動する縦パス中に配置されていることを特徴とする鋼帯の製造方法。
[6]鋼帯の製造設備において、鋼帯を連続焼鈍処理する連続焼鈍装置が、
焼鈍炉での加熱後の鋼帯を急冷する急速冷却装置と、
前記急速冷却装置の出側に配置されて、前記鋼帯を加熱して鋼帯表面温度を冷却停止温度に保持する急速加熱装置と
を備えることを特徴とする鋼帯の製造設備。
[7][6]に記載の鋼帯の製造設備において、
前記急速冷却装置の入側および前記急速加熱装置の出側に配置されて、鋼帯表面温度を測定する温度計を備えることを特徴とする鋼帯の製造設備。
[8][6]または[7]に記載の鋼帯の製造設備において、
前記急速冷却装置は冷媒を供給する冷却ノズルを有し、前記冷却ノズルは前記鋼帯の搬送方向と平行に複数配置されていることを特徴とする鋼帯の製造設備。
[9][6]〜[8]のいずれかに記載の鋼帯の製造設備において、
前記急速冷却装置の入側および出側に、一対のロールを備えることを特徴とする鋼帯の製造設備。
[10][6]〜[9]のいずれかに記載の鋼帯の製造設備において、
前記急速冷却装置は鋼帯が下方から上方に移動する縦パス中に配置されていることを特徴とする鋼帯の製造設備。
As a result of intensive studies to solve the above problems, the inventors of the present invention continuously annealed the steel strip, rapidly cooled at a fast cooling rate equivalent to the conventional one, and then heated with a rapid heating device, thereby stopping the cooling stop temperature. Has been found to be higher than the conventional cooling stop temperature. Thereby, the heating load at the time of reheating can be reduced and productivity can be improved. The gist of the present invention is as follows.
[1] In a method for manufacturing a steel strip in which a steel strip is continuously annealed,
After quenching the steel strip after heating in the annealing furnace with a rapid cooling device,
A method of manufacturing a steel strip, comprising: heating a rapidly cooled steel strip to maintain a steel strip surface temperature at a cooling stop temperature by a rapid heating device disposed on an outlet side of the rapid cooling device.
[2] In the method for manufacturing a steel strip according to [1], a steel strip is provided, wherein a thermometer for measuring the surface temperature of the steel strip is disposed on the entry side of the rapid cooling device, and the steel strip is measured on the entry side of the rapid cooling device. A steel strip surface temperature on the outlet side of the rapid cooling device is calculated based on a measured value of the surface temperature, and a steel strip surface temperature on the outlet side of the rapid cooling device and a steel strip surface temperature on the outlet side of the rapid heating device are calculated. A method of manufacturing a steel strip, wherein the heating amount of the rapid heating device is controlled from the value.
[3] In the method for manufacturing a steel strip according to [1], a thermometer for measuring a steel strip surface temperature is disposed on the exit side of the rapid heating device, and the steel strip is measured on the exit side of the rapid heating device. A method of manufacturing a steel strip, comprising: controlling a heating amount of the rapid heating device from a measured value of a surface temperature and a target value of a steel strip surface temperature on the outlet side of the rapid heating device.
[4] In the method for producing a steel strip according to any one of [1] to [3],
A steel strip manufacturing method, wherein a pair of rolls are arranged on the entry side and the exit side of the rapid cooling device, respectively, and the refrigerant staying on the steel strip surface is removed.
[5] In the method for producing a steel strip according to any one of [1] to [4],
The rapid cooling device is disposed in a vertical path in which the steel strip moves from below to above.
[6] In a steel strip manufacturing facility, a continuous annealing apparatus for continuously annealing a steel strip is provided.
A rapid cooling device for rapidly cooling the steel strip after heating in the annealing furnace;
A steel strip manufacturing facility, comprising: a rapid heating device that is disposed on the outlet side of the rapid cooling device and that heats the steel strip to maintain the steel strip surface temperature at a cooling stop temperature.
[7] In the steel strip manufacturing facility according to [6],
A steel strip production facility comprising thermometers arranged on the inlet side of the rapid cooling device and on the outlet side of the rapid heating device to measure the surface temperature of the steel strip.
[8] In the steel strip manufacturing facility according to [6] or [7],
The rapid cooling apparatus has a cooling nozzle for supplying a refrigerant, and a plurality of cooling nozzles are arranged in parallel with the conveying direction of the steel strip.
[9] In the steel strip manufacturing facility according to any one of [6] to [8],
A steel strip production facility comprising a pair of rolls on the entry side and the exit side of the rapid cooling apparatus.
[10] In the steel strip manufacturing facility according to any one of [6] to [9],
The rapid cooling device is disposed in a vertical path in which the steel strip moves from below to above.

本発明によれば、急速冷却と急速加熱を組み合わせることにより急冷後の冷却停止温度を鋼帯のサイズ変更が生じても高温でほぼ一定に保持することが可能となり、鋼帯の再加熱時の加熱の負荷を軽減することができるので、生産性を高めることができる。そして、品質を低下させることなく、所望の特性を有する鋼帯を安定的に製造することができる。   According to the present invention, the combination of rapid cooling and rapid heating makes it possible to keep the cooling stop temperature after rapid cooling substantially constant even at a high temperature even when the steel strip is resized. Since the heating load can be reduced, productivity can be increased. And the steel strip which has a desired characteristic can be manufactured stably, without reducing quality.

本発明の実施に供する鋼帯の連続焼鈍設備の一例を示す概略図である。It is the schematic which shows an example of the continuous annealing equipment of the steel strip with which implementation of this invention is provided. 本発明の実施に供する鋼帯の冷却設備の一例を示す概略図である。It is the schematic which shows an example of the cooling equipment of the steel strip with which it uses for implementation of this invention. 従来法における鋼帯の連続焼鈍設備の一例を示す概略図である。It is the schematic which shows an example of the continuous annealing equipment of the steel strip in a conventional method. 従来法における鋼帯の冷却設備の一例を示す概略図である。It is the schematic which shows an example of the cooling equipment of the steel strip in a conventional method. 従来法における鋼帯の温度履歴の一例を示す図である。It is a figure which shows an example of the temperature history of the steel strip in a conventional method. 本発明における鋼帯の温度履歴の一例を示す図である。It is a figure which shows an example of the temperature history of the steel strip in this invention. 本発明で用いた冷却ノズルの熱伝達係数と鋼帯表面温度との関係を表す図である。It is a figure showing the relationship between the heat transfer coefficient of the cooling nozzle used by this invention, and the steel strip surface temperature. 本発明を実施した際の鋼帯の温度履歴の一例を示す図である。It is a figure which shows an example of the temperature history of the steel strip at the time of implementing this invention. 本発明を実施した際の鋼帯の温度履歴の一例を示す図である。It is a figure which shows an example of the temperature history of the steel strip at the time of implementing this invention.

以下、本発明の実施の形態について詳細に説明する。   Hereinafter, embodiments of the present invention will be described in detail.

図1および図2は、本発明の実施に供する鋼帯の連続焼鈍設備および冷却設備の一例を示す概略図である。また、図3および図4は、従来の連続焼鈍設備および冷却設備の一例を示す概略図である。   FIG. 1 and FIG. 2 are schematic views showing an example of a continuous annealing equipment and a cooling equipment for a steel strip used for carrying out the present invention. 3 and 4 are schematic views showing examples of conventional continuous annealing equipment and cooling equipment.

図1に示すとおり、本発明の鋼帯の連続焼鈍設備は、連続して搬送される鋼帯1を連続加熱する加熱帯2、均熱帯3、ガスジェット冷却帯4、冷却設備5、過時効帯7とから構成されている。   As shown in FIG. 1, the continuous annealing equipment for steel strip of the present invention includes a heating zone 2, a soaking zone 3, a gas jet cooling zone 4, a cooling facility 5, and an overaging for continuously heating a steel strip 1 that is continuously conveyed. It is composed of a band 7.

図2に示すとおり、本発明の鋼帯の冷却設備5は、鋼帯1に冷媒(以下、単に冷却水と称することもある。)を噴射し急速冷却を行う急速冷却装置8と、急速冷却装置8の出側に配置される急速加熱装置9とから構成されている。急速冷却装置8は、鋼帯の表裏面に冷却水を噴射する複数の冷却ノズル(スリットノズル)から構成されている。冷却ノズルは鋼帯の搬送方向と平行に、複数列配置されている。急速冷却装置8の入側および急速加熱装置9の出側には、鋼帯の表面温度を測定する温度計11が配置されている。急速冷却装置8の入側および出側には、冷媒を除去するための一対のロール12が配置されている。急速冷却装置8の周囲には、鋼帯冷却後の水が周囲へ飛散するのを防止するために、遮蔽ボックス13が配置されている。また、急速冷却装置8の出側でロール12の手前には、水切りエアパージノズル14が配置されている。   As shown in FIG. 2, the steel strip cooling facility 5 of the present invention includes a quick cooling device 8 that performs rapid cooling by injecting a coolant (hereinafter also referred to simply as cooling water) to the steel strip 1, and quick cooling. It is comprised from the rapid heating apparatus 9 arrange | positioned at the exit side of the apparatus 8. FIG. The rapid cooling device 8 includes a plurality of cooling nozzles (slit nozzles) that inject cooling water onto the front and back surfaces of the steel strip. The cooling nozzles are arranged in a plurality of rows in parallel with the conveying direction of the steel strip. A thermometer 11 for measuring the surface temperature of the steel strip is disposed on the entry side of the rapid cooling device 8 and the exit side of the rapid heating device 9. A pair of rolls 12 for removing the refrigerant is disposed on the entry side and the exit side of the rapid cooling device 8. A shielding box 13 is disposed around the rapid cooling device 8 in order to prevent water after cooling the steel strip from scattering to the surroundings. Further, a draining air purge nozzle 14 is disposed on the exit side of the rapid cooling device 8 and in front of the roll 12.

従来の連続焼鈍設備では、図3、図4に示すように、冷却設備16において冷却された鋼帯1は、誘導加熱装置6により再加熱後、過時効帯7において過時効処理が施される。冷却設備16では、図4に示すとおり、加熱された鋼帯1を浸漬槽15内に浸漬させると同時に、浸漬槽15の水面下に配置されたクエンチノズル17から冷却水を鋼帯に噴射し、急冷を行う。なお、クエンチノズル17の入側の直上にはピンチロール18が配置され、クエンチノズル17の出側にはリンガーロール19とドライヤー20とが配置される。   In the conventional continuous annealing facility, as shown in FIGS. 3 and 4, the steel strip 1 cooled in the cooling facility 16 is reheated by the induction heating device 6 and then subjected to an overaging treatment in the overaging zone 7. . In the cooling facility 16, as shown in FIG. 4, the heated steel strip 1 is immersed in the immersion bath 15, and at the same time, cooling water is injected from the quench nozzle 17 disposed below the surface of the immersion bath 15 into the steel strip. , Perform rapid cooling. A pinch roll 18 is disposed immediately above the entry side of the quench nozzle 17, and a ringer roll 19 and a dryer 20 are disposed on the exit side of the quench nozzle 17.

図5は、従来の連続焼鈍設備における鋼帯の温度履歴の一例を示す図である。従来の冷却方法の場合、図5に示すように、鋼帯はクエンチノズル17および浸漬槽15内で冷却水温まで一気に冷却される。このため、例えば、浸漬槽内の水温が35℃の場合、誘導加熱装置6へ到達する時点で鋼帯の温度も35℃まで冷却されてしまうため、生産性を向上させようとする場合、誘導加熱装置6への負荷が大きくなってしまう。   FIG. 5 is a diagram showing an example of a temperature history of a steel strip in a conventional continuous annealing facility. In the case of the conventional cooling method, as shown in FIG. 5, the steel strip is cooled at once to the cooling water temperature in the quench nozzle 17 and the immersion bath 15. For this reason, for example, when the water temperature in the immersion tank is 35 ° C., the temperature of the steel strip is also cooled to 35 ° C. when reaching the induction heating device 6. The load on the heating device 6 is increased.

一方、本発明は、急速冷却装置8で鋼帯1を急冷した後、急速冷却装置8の出側に配置される急速加熱装置9で急冷された鋼帯を加熱し、鋼帯表面温度を冷却停止温度に保持することを特徴とする。図6は、本発明の連続焼鈍設備における鋼帯の温度履歴の一例を示す図である。本発明の場合、図6に示すように、急速冷却装置8での冷却後、急速冷却装置8の出側に配置される急速加熱装置9により、鋼帯を300℃程度の高温に保持する。鋼帯を300℃程度の高温に保持することにより、過時効帯7の入側の段階で再加熱する必要がなくなるため、従来の誘導加熱装置6が不要となる。そして、誘導加熱装置6による再加熱が不要であるため、ライン速度を容易に上げることができ、生産性が向上する。   On the other hand, in the present invention, after the steel strip 1 is rapidly cooled by the rapid cooling device 8, the steel strip quenched by the rapid heating device 9 disposed on the outlet side of the rapid cooling device 8 is heated to cool the surface temperature of the steel strip. It is characterized by maintaining the stop temperature. FIG. 6 is a diagram showing an example of the temperature history of the steel strip in the continuous annealing facility of the present invention. In the case of the present invention, as shown in FIG. 6, after cooling in the rapid cooling device 8, the steel strip is maintained at a high temperature of about 300 ° C. by the rapid heating device 9 disposed on the outlet side of the rapid cooling device 8. By maintaining the steel strip at a high temperature of about 300 ° C., it is not necessary to reheat at the entry side of the overaging zone 7, so that the conventional induction heating device 6 becomes unnecessary. And since the reheating by the induction heating apparatus 6 is unnecessary, a line speed can be raised easily and productivity improves.

本発明では、急速冷却装置8内において、鋼帯表面温度が水温に到達する途中の温度領域である300〜500℃で急冷を一旦停止するために、急速冷却装置は鋼帯が下方から上方に移動する縦パス中に設置する。鋼板が上方から下方へ移動する縦パスの場合、冷却後の水は重力の影響により下流側へ漏れ出しやすく、冷却装置出側に冷却水が滞留してしまった場合、その冷却水の影響により鋼板の表面が冷却されてしまい冷却停止温度が不安定となりやすい。一方、本発明では、鋼帯が下方から上方に移動する縦パス中に急速冷却装置を設置し、更に急速冷却装置出側に水切りロール12を設置することで、鋼板に付着した冷却水や鋼板上から離脱した飛散水が通板下流側(水切りロール12の上方側)に漏れることを防止しやすくなり、冷却停止精度が向上(冷却停止温度が安定)し、板幅方向温度分布も均一にできる。   In the present invention, in the rapid cooling device 8, the rapid cooling device temporarily stops the rapid cooling at 300 to 500 ° C., which is the temperature range in the middle of the steel strip surface temperature reaching the water temperature. Install in the moving vertical path. In the case of a vertical path where the steel plate moves from top to bottom, the water after cooling tends to leak to the downstream side due to the effect of gravity, and if the cooling water stays on the cooling device outlet side, The surface of the steel sheet is cooled and the cooling stop temperature tends to become unstable. On the other hand, in the present invention, the quick cooling device is installed in the vertical path in which the steel strip moves from the lower side to the upper side, and the water draining roll 12 is further installed on the outlet side of the quick cooling device, so that the cooling water and the steel plate adhered to the steel plate. It becomes easy to prevent the splashed water that has left from leaking to the downstream side of the plate (above the draining roll 12), improving the cooling stop accuracy (stable cooling stop temperature), and making the temperature distribution in the plate width direction uniform it can.

よって、本発明では、急速冷却装置で鋼帯表面温度が水温に到達する途中の300〜500℃で急冷を一旦停止するために、急速冷却装置8は鋼帯が下方から上方に移動する縦パス中に設置するようにし、水切り機構として、急速冷却装置8の下流に一対の水切りロール12を配置した。急速冷却装置8の入側および出側には、水切り用の一対のロール12を配置することが好ましい。急速冷却装置8の入り側にロールを設置しない場合、急速冷却装置8からの冷却水が下部へ流出し、冷却開始前の鋼帯が冷却されてしまうため、鋼帯の冷却開始温度が変動し品質低下を招くおそれがある。急速冷却装置8の入側へロール12を設置することにより、冷却水を下部へ流出するのを防止することが可能となり、冷却開始温度が一定に保持することが可能となる。また、急速冷却装置8の出側のロール12は、冷却後の鋼帯に冷却水が滞留するのを防止する役割を持つ。冷却後の冷却水が鋼帯表面へ滞留する場合、冷却水の蒸発により鋼帯が不均一に冷却され、材質不均一、形状不均一の原因となる。急速冷却装置8の出側にロール12を設置することにより鋼帯表面の冷却水を分離することが可能となり、鋼帯表面温度を均一に保持することが可能となる。   Therefore, in the present invention, in order to temporarily stop the rapid cooling at 300 to 500 ° C. while the steel strip surface temperature reaches the water temperature in the rapid cooling device, the rapid cooling device 8 has a vertical path in which the steel strip moves upward from below. As a draining mechanism, a pair of draining rolls 12 was disposed downstream of the rapid cooling device 8. It is preferable to arrange a pair of draining rolls 12 on the entry side and the exit side of the rapid cooling device 8. If no roll is installed on the entry side of the rapid cooling device 8, the cooling water from the rapid cooling device 8 flows out to the lower part, and the steel strip before the cooling starts is cooled, so the cooling start temperature of the steel strip varies. There is a risk of quality degradation. By installing the roll 12 on the entry side of the rapid cooling device 8, it becomes possible to prevent the cooling water from flowing out to the lower part, and the cooling start temperature can be kept constant. The roll 12 on the outlet side of the rapid cooling device 8 has a role of preventing cooling water from staying in the steel strip after cooling. When the cooling water after cooling stays on the surface of the steel strip, the steel strip is cooled non-uniformly due to evaporation of the cooling water, causing non-uniform materials and non-uniform shapes. By installing the roll 12 on the exit side of the rapid cooling device 8, it becomes possible to separate the cooling water on the surface of the steel strip, and to keep the steel strip surface temperature uniform.

さらに、急速冷却装置8の出側で、急速冷却装置8とロール12との間に、水切り用のエアパージノズル14を配置してもよい。図2に示すように、エアパージノズル14により、急速冷却装置8の出側に配置されるロール12の水切り性がさらに向上する。エアパージノズル14の先端は、水切り性向上のために鋼帯に対して斜め下方向に配置されればよい。また、急速冷却装置8で使用する冷却ノズルの段数を変更する場合、エアパージノズル14を用いることにより、使用していない冷却ノズルに対向する鋼帯表面の水をパージできるので、冷却停止時の温度の精度も向上するという効果がある。   Further, an air purge nozzle 14 for draining water may be disposed between the rapid cooling device 8 and the roll 12 on the exit side of the rapid cooling device 8. As shown in FIG. 2, the air purge nozzle 14 further improves the drainability of the roll 12 disposed on the exit side of the rapid cooling device 8. The tip of the air purge nozzle 14 may be disposed obliquely downward with respect to the steel strip in order to improve drainage. Further, when changing the number of cooling nozzles used in the rapid cooling device 8, the air purge nozzle 14 can be used to purge water on the surface of the steel strip facing the cooling nozzle that is not being used. This also has the effect of improving the accuracy.

なお、冷却水流出の防止方法としては、上記のようなロールに限定されるものではなく、例えば、ガスノズルからガスを噴射し、パージを行うことも可能である。   The method for preventing the cooling water outflow is not limited to the roll as described above, and for example, it is possible to perform a purge by injecting a gas from a gas nozzle.

また、鋼帯冷却後の水が周囲へ飛散するのを防止するために、急速冷却装置8の周囲に遮蔽ボックス13を配置することが好ましい。図2のように、鋼帯が鉛直方向の下方から上方に移動する縦パスの場合、急速冷却装置8に遮蔽ボックス13を配置することにより、鋼帯下部へ流出する冷却水を堰き止めることができる。その結果、冷却開始温度を一定に保持することが可能となる。   Moreover, in order to prevent the water after steel strip cooling from scattering around, it is preferable to arrange the shielding box 13 around the rapid cooling device 8. In the case of a vertical path in which the steel strip moves upward from below in the vertical direction as shown in FIG. 2, the cooling water flowing out to the bottom of the steel strip can be blocked by arranging the shielding box 13 in the rapid cooling device 8. it can. As a result, the cooling start temperature can be kept constant.

本発明の急速冷却装置8は、複数の冷却ノズル(以下、単にスリットノズルと称することもある。)から構成されていることが好ましい。図2に示すとおり、冷却ノズルは鋼帯の搬送方向と平行に、鋼帯の表裏面に複数配置されればよい。冷却ノズルの先端は鋼帯に向けられ、冷却ノズルから冷却水が鋼帯に向けて噴射される。複数の冷却ノズルについては、使用する冷却ノズル数(使用ゾーン数)を適宜変更することができる。これにより、板厚変更やライン速度の変更に伴う、急速冷却装置の冷却量を適宜制御することができる。   The rapid cooling device 8 of the present invention is preferably composed of a plurality of cooling nozzles (hereinafter sometimes simply referred to as slit nozzles). As shown in FIG. 2, a plurality of cooling nozzles may be disposed on the front and back surfaces of the steel strip in parallel with the steel strip conveyance direction. The tip of the cooling nozzle is directed to the steel strip, and cooling water is jetted from the cooling nozzle toward the steel strip. About several cooling nozzles, the number of cooling nozzles (number of use zones) to be used can be changed suitably. Thereby, it is possible to appropriately control the cooling amount of the rapid cooling device accompanying the change of the plate thickness or the change of the line speed.

また、急速冷却時の鋼帯の平均冷却速度は、冷却後の鋼帯の強度を確保するために700℃/s以上が好ましい。   The average cooling rate of the steel strip during rapid cooling is preferably 700 ° C./s or more in order to ensure the strength of the steel strip after cooling.

本発明の急速加熱装置9について、急速加熱する方式としては、誘導加熱方式、近赤外線加熱方式、高温ガスを鋼帯へ吹き付ける方式などが挙げられる。なお、鋼帯が急速加熱装置9を通過する際に所定の温度へ加熱可能であれば、いずれの方式を用いてもよい。急速加熱装置9の加熱量の制御は、誘導加熱方式を用いる場合には、加熱コイルを搬送方向に複数列配置し、加熱コイルの使用段数を制御し、近赤外線加熱方式を使用する場合には、加熱用のランプを長手方向に複数列配置し、ランプの使用段数を適宜制御すればよい。   Examples of the rapid heating system 9 of the present invention include an induction heating system, a near-infrared heating system, and a system in which high-temperature gas is blown onto the steel strip. Any method may be used as long as the steel strip can be heated to a predetermined temperature when passing through the rapid heating device 9. When the induction heating method is used, the heating amount of the rapid heating device 9 is controlled by arranging a plurality of heating coils in the conveying direction, controlling the number of stages used for the heating coil, and using the near infrared heating method. The heating lamps may be arranged in a plurality of rows in the longitudinal direction, and the number of lamps used may be appropriately controlled.

本発明では、急速冷却装置8入側、急速加熱装置9出側に温度計11を設置し、板厚、ライン速度、急速加熱装置出側目標温度、水冷熱伝達係数、急速冷却装置入側温度実績値、急速加熱装置出側温度実績値を入力値として演算装置21に入力し、1次元の温度計算を算出することで急速加熱装置出側目標温度となるように急速加熱装置9の加熱量を制御装置22を用いて制御している。   In the present invention, the thermometer 11 is installed on the inlet side of the rapid cooling device 8 and the outlet side of the rapid heating device 9, and the plate thickness, the line speed, the target temperature on the outlet side of the rapid heating device, the water cooling heat transfer coefficient, the inlet temperature of the rapid cooling device. The actual heating value and the rapid heating device outlet temperature actual value are input as input values to the arithmetic unit 21, and the heating amount of the rapid heating device 9 is set so that the rapid heating device outlet target temperature is obtained by calculating a one-dimensional temperature calculation. Is controlled using the control device 22.

一般的に、冷媒に水を用いて鋼帯を急速冷却する場合、鋼帯の表面温度が400〜500℃で遷移沸騰領域となり、鋼帯からの抜熱量が大きくなる。このため、冷却が不均一となりやすく、鋼帯が過冷却されやすくなる。本発明の急速冷却装置8の場合、鋼帯表面温度と熱伝達係数の関係は、図7のようになっており、500℃以下にて遷移沸騰領域となる。   Generally, when rapidly cooling a steel strip using water as a refrigerant, the surface temperature of the steel strip becomes a transition boiling region at 400 to 500 ° C., and the amount of heat removed from the steel strip increases. For this reason, the cooling is likely to be uneven, and the steel strip is likely to be supercooled. In the case of the rapid cooling device 8 of the present invention, the relationship between the steel strip surface temperature and the heat transfer coefficient is as shown in FIG. 7, and it becomes a transition boiling region at 500 ° C. or less.

そこで、急速冷却装置8の入側の鋼帯表面温度720℃、鋼帯の搬送速度115m/minとし、図7に示す冷却時の熱伝達係数を用い、上記の入力値を演算装置21に入力し、1次元の温度計算を行った。急速冷却装置8に使用したスリットノズルは100mmピッチで9段配置されており、スリットノズルを5段使用した。なお、鋼帯の温度履歴は、例えば板圧延の理論と実際(日本鉄鋼協会、1984年、p141−160)に記載されているように1次元の熱伝導方程式を既知の初期条件(冷却開始温度、板厚、ライン速度、冷却時間)と境界条件(水冷時の熱伝達係数)を用いて差分法を用いて解くことにより算出される。今回も1次元熱伝導方程式を差分法により急速冷却装置入側から急速冷却装置出側までの温度履歴を算出した。   Therefore, the steel strip surface temperature on the entry side of the rapid cooling device 8 is set to 720 ° C., the steel strip transport speed is set to 115 m / min, and the above input value is input to the computing device 21 using the heat transfer coefficient during cooling shown in FIG. A one-dimensional temperature calculation was performed. Nine stages of slit nozzles used in the rapid cooling apparatus 8 were arranged at a pitch of 100 mm, and five stages of slit nozzles were used. Note that the temperature history of the steel strip is obtained by, for example, converting a one-dimensional heat conduction equation to a known initial condition (cooling start temperature) as described in the theory and practice of plate rolling (Japan Steel Association, 1984, p141-160). , Plate thickness, line speed, cooling time) and boundary conditions (heat transfer coefficient during water cooling) are calculated by solving using a difference method. The temperature history from the rapid cooling device entry side to the rapid cooling device exit side was also calculated by the finite difference method using the one-dimensional heat conduction equation.

図8は、板厚1.6mmの鋼帯を冷却した際の温度履歴の図である。急速加熱装置9の出側の鋼帯表面目標温度を300℃とする場合、図8に示すような温度履歴となる。一方、板厚1.6mmの鋼帯の冷却処理と同様の条件で、板厚1.4mmの鋼帯を処理した場合、図9に示すような温度履歴となる。図9に示すように、急速加熱装置9を使用しない場合、急速加熱装置9の出側温度が220℃程度まで冷却されてしまい、過冷となってしまう。例えば、図9の場合、板厚を1.4mmに変更した際、急速加熱装置9の出側の鋼帯表面目標温度(300℃)に対して80℃分の加熱量が必要となる。   FIG. 8 is a diagram of temperature history when a steel strip having a thickness of 1.6 mm is cooled. When the steel strip surface target temperature on the exit side of the rapid heating device 9 is set to 300 ° C., a temperature history as shown in FIG. 8 is obtained. On the other hand, when a steel strip having a thickness of 1.4 mm is processed under the same conditions as those for cooling a steel strip having a thickness of 1.6 mm, a temperature history as shown in FIG. 9 is obtained. As shown in FIG. 9, when the rapid heating device 9 is not used, the outlet temperature of the rapid heating device 9 is cooled to about 220 ° C., resulting in overcooling. For example, in the case of FIG. 9, when the plate thickness is changed to 1.4 mm, a heating amount of 80 ° C. is required for the steel strip surface target temperature (300 ° C.) on the exit side of the rapid heating device 9.

そこで本発明では、サイズ変更に伴うライン速度の加減速を行うことなく高能率で操業するために、急速冷却装置8の入側および急速加熱装置9の出側に、鋼帯の表面温度を測定する温度計11を配置することが好ましい。この温度計11で鋼帯の表面温度を測定することにより、急速加熱装置9の加熱量を適宜制御することができる。なお、温度計11としては、例えば、放射温度計を用いればよい。   Therefore, in the present invention, the surface temperature of the steel strip is measured on the entry side of the rapid cooling device 8 and the exit side of the rapid heating device 9 in order to operate with high efficiency without performing acceleration / deceleration of the line speed accompanying the size change. It is preferable to arrange a thermometer 11 to be used. By measuring the surface temperature of the steel strip with this thermometer 11, the heating amount of the rapid heating device 9 can be controlled as appropriate. For example, a radiation thermometer may be used as the thermometer 11.

本発明では、急速冷却装置8の入側で測定される鋼帯表面温度の測定値、ライン速度、板厚に基づき急速冷却装置8の出側の鋼帯表面温度を演算装置21で算出し、該急速冷却装置8の出側の鋼帯表面温度と急速加熱装置9の出側の鋼帯表面温度の目標値とから、急速加熱装置9の加熱量を制御することができる。まず、急速冷却装置8の入側に配置される温度計11により、急速冷却装置8の入側の鋼帯表面温度を測定する。そして、この測定値(急速冷却装置8の入側の鋼帯表面温度の実測値)、ライン速度、板厚から、急速冷却装置8の出側の温度を演算装置21にて1次元の温度計算により算出する。   In the present invention, the steel strip surface temperature on the exit side of the rapid cooling device 8 is calculated by the computing device 21 based on the measured value, line speed, and plate thickness of the steel strip surface temperature measured on the entry side of the rapid cooling device 8, The heating amount of the rapid heating device 9 can be controlled from the steel strip surface temperature on the delivery side of the rapid cooling device 8 and the target value of the steel strip surface temperature on the delivery side of the rapid heating device 9. First, the steel strip surface temperature on the entry side of the rapid cooling device 8 is measured by the thermometer 11 disposed on the entry side of the rapid cooling device 8. Then, from this measured value (actually measured value of the steel strip surface temperature on the inlet side of the rapid cooling device 8), the line speed, and the plate thickness, the temperature on the outlet side of the rapid cooling device 8 is calculated one-dimensionally by the arithmetic unit 21. Calculated by

この算出した急速冷却装置8の出側の鋼帯表面温度と、急速加熱装置9の出側の鋼帯表面温度の目標値との温度差を演算装置21で算出する。この温度差が、急速加熱装置9での必要な加熱量となり、制御装置22を介して急速加熱装置にて鋼板を加熱する。   A temperature difference between the calculated steel strip surface temperature of the rapid cooling device 8 and the target value of the steel strip surface temperature of the rapid heating device 9 is calculated by the computing device 21. This temperature difference becomes a necessary heating amount in the rapid heating device 9, and the steel plate is heated by the rapid heating device via the control device 22.

その結果、急速加熱装置9の出側の鋼帯表面温度を一定値に保持することが可能となり、サイズ変更(板幅変更)に伴うライン速度の加減速を行うことなく高能率での操業が可能となる。なお、急速加熱装置9での必要な加熱量を求める際には、板厚変更時の冷却停止温度を演算装置21にてモデル計算で予め算出し、急速加熱装置出側の目標温度と急速冷却装置出側温度の計算値の差を算出し、急速加熱装置9での必要な加熱量を決定している。   As a result, the steel strip surface temperature on the exit side of the rapid heating device 9 can be maintained at a constant value, and high-efficiency operation can be achieved without accelerating or decelerating the line speed associated with the size change (plate width change). It becomes possible. When the required heating amount in the rapid heating device 9 is obtained, the cooling stop temperature at the time of changing the plate thickness is calculated in advance by model calculation in the computing device 21, and the target temperature and rapid cooling on the rapid heating device exit side are calculated. The difference between the calculated values of the apparatus outlet side temperature is calculated, and the necessary heating amount in the rapid heating apparatus 9 is determined.

また、本発明では、演算装置21に予め設定される急速加熱装置9出側の鋼板表面温度の目標値と急速加熱装置出側に設置した温度計11の測定値を入力値として与え、目標値と実績値との温度差を算出し、この温度差を急速加熱装置9での必要加熱量として制御装置22へ入力し、急速加熱装置9の加熱量を制御することができる。
その結果、急速加熱装置9の出側の鋼帯表面温度を一定値に保持することが可能となり、サイズ変更に伴うライン速度の加減速を行うことなく高能率での操業が可能となる。
Moreover, in this invention, the target value of the steel plate surface temperature by the side of the rapid heating apparatus 9 preset by the arithmetic unit 21 and the measured value of the thermometer 11 installed in the rapid heating apparatus exit side are given as an input value, and target value The temperature difference between the actual heating value and the actual value is calculated, and this temperature difference is input to the control device 22 as the required heating amount in the rapid heating device 9 so that the heating amount of the rapid heating device 9 can be controlled.
As a result, the steel strip surface temperature on the exit side of the rapid heating device 9 can be maintained at a constant value, and high-efficiency operation can be performed without accelerating or decelerating the line speed accompanying the size change.

鋼帯の強度は急冷時の冷却速度に依存し、冷却速度が遅いと強度不足となる。図3および図4に示すような、浸漬槽中で冷却水を噴射する従来の冷却方法では、単に鋼帯を水中に浸漬させるよりも速い冷却速度を達成させるために、噴流により鋼帯表面と浸漬槽の浸漬水との境界層を打ち破ることを利用していた。しかし、十分な水量をスリットノズルから噴射すれば、水中で噴射するのと同等の冷却能力が得られる。同一の鋼帯サイズの場合、冷却速度はノズルからの噴射流速および冷却水の水温に依存する。ノズルからの噴射流速が速いほど、冷却速度は増加するものの、ある程度以上の噴射流速になるとほぼ同じ冷却速度になる。一方、水温が高いほど冷却速度は低下する。したがって、速い冷却速度を保つためには、冷却水の水温は極力低い方が好ましい。本発明者らが鋭意検討した結果、材質との兼ね合いから水温は60℃以下が好ましいことがわかった。さらに、焼入れ開始温度、水温のばらつき、ライン速度の変動等を考慮すると、45℃以下の水温が好ましい。したがって、本発明の急速冷却装置においては、45℃以下の水温で鋼帯を製造することにより、より安定的な操業が可能となる。   The strength of the steel strip depends on the cooling rate at the time of rapid cooling, and if the cooling rate is slow, the strength becomes insufficient. In the conventional cooling method in which cooling water is jetted in the immersion bath as shown in FIGS. 3 and 4, in order to achieve a faster cooling rate than simply immersing the steel strip in water, It used to break the boundary layer with the immersion water in the immersion tank. However, if a sufficient amount of water is ejected from the slit nozzle, a cooling capacity equivalent to that in water can be obtained. In the case of the same steel strip size, the cooling rate depends on the jet flow rate from the nozzle and the coolant temperature. Although the cooling rate increases as the injection flow rate from the nozzle increases, the cooling rate becomes substantially the same when the injection flow rate exceeds a certain level. On the other hand, the cooling rate decreases as the water temperature increases. Therefore, in order to maintain a high cooling rate, it is preferable that the coolant temperature is as low as possible. As a result of intensive studies by the present inventors, it was found that the water temperature is preferably 60 ° C. or less in consideration of the material. Furthermore, in consideration of quenching start temperature, variation in water temperature, variation in line speed, etc., a water temperature of 45 ° C. or lower is preferable. Therefore, in the rapid cooling device of the present invention, a more stable operation can be performed by manufacturing the steel strip at a water temperature of 45 ° C. or less.

以上に述べたように、本発明では、品質と生産能率の向上の両立を実現するために、急速冷却装置8と急速加熱装置9とを配置することにより、急速冷却装置8での過冷却分を急速加熱装置9により再加熱する。これにより急速加熱装置9の出側における板温を高温で保持することができる。   As described above, in the present invention, by providing the rapid cooling device 8 and the rapid heating device 9 in order to realize both improvement in quality and production efficiency, the amount of supercooling in the rapid cooling device 8 can be achieved. Is reheated by the rapid heating device 9. Thereby, the plate | board temperature in the exit side of the rapid heating apparatus 9 can be hold | maintained at high temperature.

以下、本発明の実施例を従来方法の比較例と比較して説明する。   Hereinafter, examples of the present invention will be described in comparison with comparative examples of conventional methods.

本発明の製造方法と従来の製造方法でのライン速度について比較を行った。図1および図2に示した連続焼鈍ラインを用いて、焼入れ開始温度を720℃として、板厚1.6mm、板幅が1000mmである引張強度が980MPa級の高張力冷延鋼板を製造した。急速冷却装置8のスリットノズルは表裏面ともに9段とし、冷却長は900mmである。長手方向表裏1段あたりのスリットノズルからの噴射水量は、100トン/時間とした。急速加熱装置9については、誘導加熱方式を用い、搬送方向に鋼帯の表裏面に4段ずつ加熱コイルを設置した。また、温度計11を用いて、鋼帯表面温度を測定した。   A comparison was made on the line speed between the manufacturing method of the present invention and the conventional manufacturing method. Using the continuous annealing line shown in FIGS. 1 and 2, a quenching start temperature was set to 720 ° C., and a high-tensile cold-rolled steel sheet having a plate thickness of 1.6 mm and a plate width of 1000 mm and a tensile strength of 980 MPa was manufactured. The slit nozzle of the rapid cooling device 8 has 9 stages on both the front and back surfaces, and the cooling length is 900 mm. The amount of water sprayed from the slit nozzle per front and back in the longitudinal direction was 100 tons / hour. About the rapid heating apparatus 9, the induction heating system was used and the heating coil was installed in the conveyance direction on the front and back surfaces of the steel strip in four stages. Moreover, the steel strip surface temperature was measured using the thermometer 11.

本発明例では、急速冷却装置8の入側の鋼帯表面温度(測定値)、ライン速度、板厚から急速冷却装置8の出側の鋼帯表面温度を演算装置21にて1次元の温度計算を実施することにより算出し、さらに急速加熱装置9の出側の鋼帯表面目標温度との温度差を演算装置21にて算出することにより、急速加熱装置9の必要加熱量を算出した。そして、急速加熱装置9の出側の鋼帯表面温度の目標値が、300℃または250℃となるように調整した。   In the example of the present invention, the steel strip surface temperature on the inlet side of the rapid cooling device 8 (measured value), the line speed, and the sheet thickness are used to calculate the steel strip surface temperature on the outlet side of the rapid cooling device 8 with a one-dimensional temperature by the arithmetic unit 21. The necessary heating amount of the rapid heating device 9 was calculated by calculating the temperature difference from the steel strip surface target temperature on the delivery side of the rapid heating device 9 with the calculation device 21. And it adjusted so that the target value of the steel strip surface temperature of the exit side of the rapid heating apparatus 9 might be 300 degreeC or 250 degreeC.

比較例では、図3、図4に示す従来法により、本発明例と同一の高張力冷延鋼板を製造した。クエンチノズル17は浸漬槽15内に設置され、クエンチノズル17から噴射される冷却水および浸漬槽15内の水温は30℃とした。   In the comparative example, the same high-tensile cold-rolled steel sheet as that of the present invention was manufactured by the conventional method shown in FIGS. The quench nozzle 17 was installed in the immersion tank 15, and the cooling water sprayed from the quench nozzle 17 and the water temperature in the immersion tank 15 were 30 ° C.

結果を表1に示す。   The results are shown in Table 1.

Figure 2015038233
Figure 2015038233

本発明例の場合、急速加熱装置9の出側の鋼帯表面温度が300℃になるように急速加熱装置9の加熱量を調整した場合、ライン速度は115mpmとなった。また、鋼帯表面温度が250℃になるように急速加熱装置9の加熱量を調整した場合も、ライン速度は125mpmであった。なお、得られた鋼板について、機械特性等の品質検査も行ったところ、全く問題のないレベルであった。   In the case of the example of the present invention, when the heating amount of the rapid heating device 9 was adjusted so that the steel strip surface temperature of the rapid heating device 9 became 300 ° C., the line speed was 115 mpm. Further, when the heating amount of the rapid heating device 9 was adjusted so that the steel strip surface temperature was 250 ° C., the line speed was 125 mpm. The obtained steel sheet was subjected to quality inspections such as mechanical characteristics, and it was at a level with no problem at all.

比較例の場合、浸漬槽内で鋼板の温度が30℃まで冷却されてしまうため、再加熱時における誘導加熱装置6への負荷が高くなる。表1に示すとおり、比較例では、目標温度まで昇温させるためにライン速度を75mpmに減速せざるを得なかった。したがって、比較例に比べて、本発明例は、急速加熱装置の出側の鋼帯表面温度を高くすることにより、誘導加熱装置6を用いることなく、生産性を向上することができた。   In the case of the comparative example, since the temperature of the steel sheet is cooled to 30 ° C. in the immersion tank, the load on the induction heating device 6 during reheating increases. As shown in Table 1, in the comparative example, the line speed had to be reduced to 75 mpm in order to raise the temperature to the target temperature. Therefore, compared with the comparative example, the inventive example was able to improve productivity without using the induction heating device 6 by increasing the steel strip surface temperature on the exit side of the rapid heating device.

製造中に板厚が変化した際のライン速度について比較を行った。図1および図2に示した連続焼鈍ラインを用いて、焼入れ開始温度を720℃として、板幅が1000mmである引張強度が980MPa級の高張力冷延鋼板を製造した。急速冷却装置8のスリットノズルは表裏面ともに9段とし、冷却長は900mmである。長手方向表裏1段あたりのスリットノズルからの噴射水量は、100トン/時間とした。急速加熱装置9については、誘導加熱方式を用い、搬送方向に鋼帯の表裏面に4段ずつ加熱コイルを設置した。   A comparison was made of the line speed when the plate thickness changed during production. Using the continuous annealing line shown in FIGS. 1 and 2, a quenching start temperature was set to 720 ° C., and a high-tensile cold-rolled steel sheet having a plate width of 1000 mm and a tensile strength of 980 MPa was manufactured. The slit nozzle of the rapid cooling device 8 has 9 stages on both the front and back surfaces, and the cooling length is 900 mm. The amount of water sprayed from the slit nozzle per front and back in the longitudinal direction was 100 tons / hour. About the rapid heating apparatus 9, the induction heating system was used and the heating coil was installed in the conveyance direction on the front and back surfaces of the steel strip in four stages.

本発明例では、急速冷却装置8の入側の鋼帯表面温度(測定値)、ライン速度、板厚から演算装置21を用いて、1次元熱伝導方程式を差分法により解くことで、急速冷却装置8の出側の鋼帯表面温度を算出し、急速加熱装置9の出側の鋼帯表面目標温度との温度差を演算装置21にて算出することで、急速加熱装置9の必要加熱量を算出した。そして、急速加熱装置9の出側の鋼帯表面温度の目標値が300℃または250℃となるように調整した。   In the example of the present invention, rapid cooling is achieved by solving the one-dimensional heat conduction equation by the difference method using the computing device 21 from the steel strip surface temperature (measured value), the line speed, and the plate thickness of the rapid cooling device 8. The required heating amount of the rapid heating device 9 is calculated by calculating the steel strip surface temperature on the outlet side of the device 8 and calculating the temperature difference from the target steel strip surface temperature on the outlet side of the rapid heating device 9 with the arithmetic device 21. Was calculated. And it adjusted so that the target value of the steel strip surface temperature of the exit side of the rapid heating apparatus 9 might be 300 degreeC or 250 degreeC.

比較例として、図3および図4に示した連続焼鈍ラインを用いて本発明例と同一の高張力冷延鋼板を製造した。クエンチノズル17は浸漬槽15内に設置され、クエンチノズル17から噴射される冷却水および浸漬槽15内の水温は30℃とした。   As a comparative example, the same high-tensile cold-rolled steel sheet as that of the present invention was manufactured using the continuous annealing line shown in FIGS. 3 and 4. The quench nozzle 17 was installed in the immersion tank 15, and the cooling water sprayed from the quench nozzle 17 and the water temperature in the immersion tank 15 were 30 ° C.

表2に結果を示す。   Table 2 shows the results.

Figure 2015038233
Figure 2015038233

本発明例の場合、板厚の変化に伴い、急速加熱装置9の出側の鋼帯表面温度になるように急速加熱装置9の加熱量を調整した場合、速度変化をほぼ生じることなく製造することが可能となった。   In the case of the example of the present invention, when the heating amount of the rapid heating device 9 is adjusted so as to be the surface temperature of the steel strip on the exit side of the rapid heating device 9 with the change in the plate thickness, the speed is hardly changed. It became possible.

一方、比較例の場合、浸漬槽内で鋼板の温度が30℃まで冷却されてしまうため、再加熱時における誘導加熱装置6への負荷が高くなる。表2に示すとおり、比較例では、目標温度まで昇温させるため板厚変更前後において本発明例よりもライン速度が低くなった。したがって、比較例に比べて、本発明例は、急速加熱装置の出側の鋼帯表面温度を急速加熱装置により高温で保持することにより、板厚が変更した場合でも速度変動を生じさせることなく高生産性を実現することができた。   On the other hand, in the case of the comparative example, since the temperature of the steel sheet is cooled to 30 ° C. in the immersion bath, the load on the induction heating device 6 during reheating increases. As shown in Table 2, in the comparative example, in order to raise the temperature to the target temperature, the line speed was lower than that of the inventive example before and after the plate thickness change. Therefore, compared with the comparative example, the present invention example does not cause speed fluctuation even when the plate thickness is changed by maintaining the steel strip surface temperature on the exit side of the rapid heating device at a high temperature by the rapid heating device. High productivity was achieved.

鋼板のライン速度が変化した際の急速加熱装置の加熱量の制御の有無について、比較を行った。図1および図2に示した連続焼鈍ラインを用いて、焼入れ開始温度を720℃として、板厚1.6mm、板幅が1000mmである引張強度が980MPa級の高張力冷延鋼板を製造した。急速冷却装置8のスリットノズルは表裏面ともに9段とし、冷却長は900mmである。長手方向表裏1段あたりのスリットノズルからの噴射水量は、100トン/時間とした。急速加熱装置9については、誘導加熱方式を用い、搬送方向に鋼帯の表裏面に4段ずつ加熱コイルを設置した。   The presence or absence of control of the heating amount of the rapid heating device when the line speed of the steel plate was changed was compared. Using the continuous annealing line shown in FIGS. 1 and 2, a quenching start temperature was set to 720 ° C., and a high-tensile cold-rolled steel sheet having a plate thickness of 1.6 mm and a plate width of 1000 mm and a tensile strength of 980 MPa was manufactured. The slit nozzle of the rapid cooling device 8 has 9 stages on both the front and back surfaces, and the cooling length is 900 mm. The amount of water sprayed from the slit nozzle per front and back in the longitudinal direction was 100 tons / hour. About the rapid heating apparatus 9, the induction heating system was used and the heating coil was installed in the conveyance direction on the front and back surfaces of the steel strip in four stages.

結果を表3に示す。   The results are shown in Table 3.

Figure 2015038233
Figure 2015038233

鋼板のライン速度が変化した際に急速加熱装置の加熱量を制御した本発明例では、急速加熱装置出側の温度を測定することにより、目標温度との温度差を演算装置21にて算出し、その温度差を急速加熱装置での加熱量としてあたえ制御装置22を用いて急速加熱装置での加熱量を制御することにより、ライン速度が変化した場合でもほぼ一定に鋼板の温度を制御することが可能となった。   In the example of the present invention in which the heating amount of the rapid heating device is controlled when the line speed of the steel sheet changes, the temperature difference from the target temperature is calculated by the arithmetic unit 21 by measuring the temperature on the exit side of the rapid heating device. The temperature difference is given as the heating amount in the rapid heating device, and the heating amount in the rapid heating device is controlled by using the control device 22, so that the temperature of the steel sheet is controlled almost uniformly even when the line speed changes. Became possible.

一方、比較として急速加熱装置の加熱量を制御しない(急速加熱装置を使用しない)場合、ライン速度が低下した場合の速度変化に伴い、急速冷却装置の通過時間が長くなる。このため、急速加熱装置の加熱量を制御しない場合には、急速加熱装置出側の温度が目標温度に比べ50℃以上低下した。したがって、本発明例では、急速加熱装置9の出側の鋼帯表面温度を一定値に保持することが可能となる。   On the other hand, as a comparison, when the heating amount of the rapid heating device is not controlled (the rapid heating device is not used), the passage time of the rapid cooling device becomes longer along with the speed change when the line speed decreases. For this reason, when the heating amount of the rapid heating apparatus was not controlled, the temperature on the exit side of the rapid heating apparatus was lowered by 50 ° C. or more compared to the target temperature. Therefore, in the example of this invention, it becomes possible to hold | maintain the steel strip surface temperature of the exit side of the rapid heating apparatus 9 to a fixed value.

鋼板の板厚を1.2mm〜1.8mmの範囲で変更した際の急速冷却装置の冷却ノズルの使用段数の影響、および、冷却ノズルの使用段数を固定した場合のライン速度の比較を行った。図1および図2に示した連続焼鈍ラインを用いて、焼入れ開始温度を720℃として、板幅が1000mmである引張強度が980MPa級の高張力冷延鋼板を製造した。急速冷却装置8のスリットノズルは表裏面ともに9段とし、冷却長は900mmである。長手方向表裏1段あたりのスリットノズルからの噴射水量は、100トン/時間とした。急速加熱装置9については、誘導加熱方式を用い、搬送方向に鋼帯の表裏面に4段ずつ加熱コイルを設置した。結果を表4に示す。   The effect of the number of cooling nozzles used in the rapid cooling device when the plate thickness of the steel sheet was changed in the range of 1.2 mm to 1.8 mm, and the line speed when the number of cooling nozzles used was fixed were compared. . Using the continuous annealing line shown in FIGS. 1 and 2, a quenching start temperature was set to 720 ° C., and a high-tensile cold-rolled steel sheet having a plate width of 1000 mm and a tensile strength of 980 MPa was manufactured. The slit nozzle of the rapid cooling device 8 has 9 stages on both the front and back surfaces, and the cooling length is 900 mm. The amount of water sprayed from the slit nozzle per front and back in the longitudinal direction was 100 tons / hour. About the rapid heating apparatus 9, the induction heating system was used and the heating coil was installed in the conveyance direction on the front and back surfaces of the steel strip in four stages. The results are shown in Table 4.

Figure 2015038233
Figure 2015038233

本発明例では、急速冷却装置8の入側の鋼帯表面温度、ライン速度、板厚、急速加熱装置の出側目標温度から演算装置21を用いて、1次元の熱伝導方程式を差分法により解くことで急速加熱装置の出側目標温度となる急速冷却装置8でのノズル使用段数を予め算出し、制御装置22を介してノズル使用段数を制御することにより、過冷却を回避することが可能となり、各板厚条件にて目標温度での制御が可能となった。一方、急速冷却装置の冷却ノズル使用段数を固定した場合、過冷却が発生し、再加熱時の昇温負荷が拡大したためライン速度が低下し生産性が悪化した。   In the present invention example, the one-dimensional heat conduction equation is calculated by the difference method using the arithmetic unit 21 from the steel strip surface temperature, the line speed, the plate thickness, and the outlet side target temperature of the rapid heating device of the rapid cooling device 8. It is possible to avoid overcooling by calculating in advance the number of nozzles used in the rapid cooling device 8 that becomes the delivery target temperature of the rapid heating device and controlling the number of nozzles used via the controller 22. Thus, control at the target temperature was possible under each plate thickness condition. On the other hand, when the number of cooling nozzles used in the rapid cooling apparatus was fixed, supercooling occurred, and the temperature rising load during reheating increased, resulting in a decrease in line speed and deterioration in productivity.

1 鋼帯
2 加熱帯
3 均熱帯
4 ガスジェット冷却帯
5 冷却設備
6 誘導加熱装置
7 過時効帯
8 急速冷却装置
9 急速加熱装置
11 温度計
12 ロール
13 遮蔽ボックス
14 エアパージノズル
15 浸漬槽
16 冷却設備
17 クエンチノズル
18 ピンチロール
19 リンガーロール
20 ドライヤー
21 演算装置
22 制御装置
DESCRIPTION OF SYMBOLS 1 Steel strip 2 Heating zone 3 Soaking zone 4 Gas jet cooling zone 5 Cooling equipment 6 Induction heating device 7 Overaging zone 8 Rapid cooling device 9 Rapid heating device 11 Thermometer 12 Roll 13 Shielding box 14 Air purge nozzle 15 Immersion tank 16 Cooling equipment 17 Quench nozzle 18 Pinch roll 19 Ringer roll 20 Dryer 21 Arithmetic unit 22 Control unit

Claims (10)

鋼帯を連続焼鈍処理する鋼帯の製造方法において、
焼鈍炉での加熱後の鋼帯を急速冷却装置で急冷した後、
前記急速冷却装置の出側に配置される急速加熱装置で、急冷された前記鋼帯を加熱して鋼帯表面温度を冷却停止温度に保持することを特徴とする鋼帯の製造方法。
In the manufacturing method of the steel strip that continuously anneals the steel strip,
After quenching the steel strip after heating in the annealing furnace with a rapid cooling device,
A method of manufacturing a steel strip, comprising: heating a rapidly cooled steel strip to maintain a steel strip surface temperature at a cooling stop temperature by a rapid heating device disposed on an outlet side of the rapid cooling device.
請求項1に記載の鋼帯の製造方法において、前記急速冷却装置の入側に鋼帯表面温度を測定する温度計を配置し、前記急速冷却装置の入側で測定される鋼帯表面温度の測定値に基づき前記急速冷却装置の出側の鋼帯表面温度を算出し、該急速冷却装置の出側の鋼帯表面温度と前記急速加熱装置の出側の鋼帯表面温度の目標値とから、前記急速加熱装置の加熱量を制御することを特徴とする鋼帯の製造方法。   In the manufacturing method of the steel strip according to claim 1, a thermometer for measuring a steel strip surface temperature is disposed on the entry side of the rapid cooling device, and the steel strip surface temperature measured on the entry side of the rapid cooling device is measured. The steel strip surface temperature on the outlet side of the rapid cooling device is calculated based on the measured value, and the steel strip surface temperature on the outlet side of the rapid cooling device and the target value of the steel strip surface temperature on the outlet side of the rapid heating device are calculated. A method of manufacturing a steel strip, wherein the heating amount of the rapid heating device is controlled. 請求項1に記載の鋼帯の製造方法において、前記急速加熱装置の出側に鋼帯表面温度を測定する温度計を配置し、前記急速加熱装置の出側で測定される鋼帯表面温度の測定値と前記急速加熱装置の出側の鋼帯表面温度の目標値とから、前記急速加熱装置の加熱量を制御することを特徴とする鋼帯の製造方法。   In the manufacturing method of the steel strip according to claim 1, a thermometer for measuring a steel strip surface temperature is disposed on the exit side of the rapid heating device, and the steel strip surface temperature measured on the exit side of the rapid heating device is measured. A method of manufacturing a steel strip, comprising: controlling a heating amount of the rapid heating device from a measured value and a target value of a steel strip surface temperature on the outlet side of the rapid heating device. 請求項1〜3のいずれかに記載の鋼帯の製造方法において、
前記急速冷却装置の入側および出側にそれぞれ一対のロールを配置し、前記鋼帯表面に滞留する冷媒を除去することを特徴とする鋼帯の製造方法。
In the manufacturing method of the steel strip in any one of Claims 1-3,
A steel strip manufacturing method, wherein a pair of rolls are arranged on the entry side and the exit side of the rapid cooling device, respectively, and the refrigerant staying on the steel strip surface is removed.
請求項1〜4のいずれかに記載の鋼帯の製造方法において、
前記急速冷却装置は鋼帯が下方から上方に移動する縦パス中に配置されていることを特徴とする鋼帯の製造方法。
In the manufacturing method of the steel strip in any one of Claims 1-4,
The rapid cooling device is disposed in a vertical path in which the steel strip moves from below to above.
鋼帯の製造設備において、鋼帯を連続焼鈍処理する連続焼鈍装置が、
焼鈍炉での加熱後の鋼帯を急冷する急速冷却装置と、
前記急速冷却装置の出側に配置されて、前記鋼帯を加熱して鋼帯表面温度を冷却停止温度に保持する急速加熱装置と
を備えることを特徴とする鋼帯の製造設備。
In steel strip manufacturing equipment, a continuous annealing device for continuous annealing treatment of steel strip,
A rapid cooling device for rapidly cooling the steel strip after heating in the annealing furnace;
A steel strip manufacturing facility, comprising: a rapid heating device that is disposed on the outlet side of the rapid cooling device and that heats the steel strip to maintain the steel strip surface temperature at a cooling stop temperature.
請求項6に記載の鋼帯の製造設備において、
前記急速冷却装置の入側および前記急速加熱装置の出側に配置されて、鋼帯表面温度を測定する温度計を備えることを特徴とする鋼帯の製造設備。
In the steel strip manufacturing facility according to claim 6,
A steel strip production facility comprising thermometers arranged on the inlet side of the rapid cooling device and on the outlet side of the rapid heating device to measure the surface temperature of the steel strip.
請求項6または7に記載の鋼帯の製造設備において、
前記急速冷却装置は冷媒を供給する冷却ノズルを有し、前記冷却ノズルは前記鋼帯の搬送方向と平行に複数配置されていることを特徴とする鋼帯の製造設備。
In the steel strip manufacturing facility according to claim 6 or 7,
The rapid cooling apparatus has a cooling nozzle for supplying a refrigerant, and a plurality of cooling nozzles are arranged in parallel with the conveying direction of the steel strip.
請求項6〜8のいずれかに記載の鋼帯の製造設備において、
前記急速冷却装置の入側および出側に、一対のロールを備えることを特徴とする鋼帯の製造設備。
In the steel strip production facility according to any one of claims 6 to 8,
A steel strip production facility comprising a pair of rolls on the entry side and the exit side of the rapid cooling apparatus.
請求項6〜9のいずれかに記載の鋼帯の製造設備において、
前記急速冷却装置は鋼帯が下方から上方に移動する縦パス中に配置されていることを特徴とする鋼帯の製造設備。
In the steel strip manufacturing facility according to any one of claims 6 to 9,
The rapid cooling device is disposed in a vertical path in which the steel strip moves from below to above.
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Cited By (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN106350657A (en) * 2016-08-29 2017-01-25 首钢京唐钢铁联合有限责任公司 Buckling-proof alarm system applied to continuous vertical annealing furnace
CN113774203A (en) * 2021-08-09 2021-12-10 南通江勤美金属制品有限公司 Non-hydraulic plate quenching device and method for continuous quenching of steel strip

Families Citing this family (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
KR102698313B1 (en) 2019-09-30 2024-08-22 제이에프이 스틸 가부시키가이샤 Metal belt rapid cooling device and metal belt rapid cooling method and method for manufacturing metal belt products

Citations (8)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JPS5760030A (en) * 1980-09-29 1982-04-10 Nippon Steel Corp Method for controlling cooling
JPS5891130A (en) * 1981-11-24 1983-05-31 Nippon Kokan Kk <Nkk> Cooling method for strip in successive annealing
JPS61183415A (en) * 1985-02-07 1986-08-16 Nippon Kokan Kk <Nkk> Cooling method of strip in continuous heat treatment furnace
JPS63161125A (en) * 1986-12-23 1988-07-04 Sumitomo Metal Ind Ltd Continuous annealing method and continuous annealing furnace
JPH02274823A (en) * 1989-04-18 1990-11-09 Nkk Corp Equipment and method for continuously annealing metal sheet
JPH05271785A (en) * 1992-03-24 1993-10-19 Kawasaki Steel Corp Method for adjusting temperature of metal strip
JPH11246916A (en) * 1998-03-02 1999-09-14 Kawasaki Steel Corp Vertical type continuous water-cooling device
JP2008150685A (en) * 2006-12-19 2008-07-03 Sumitomo Metal Ind Ltd Manufacturing method and manufacturing apparatus of cold-rolled steel plate

Patent Citations (8)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JPS5760030A (en) * 1980-09-29 1982-04-10 Nippon Steel Corp Method for controlling cooling
JPS5891130A (en) * 1981-11-24 1983-05-31 Nippon Kokan Kk <Nkk> Cooling method for strip in successive annealing
JPS61183415A (en) * 1985-02-07 1986-08-16 Nippon Kokan Kk <Nkk> Cooling method of strip in continuous heat treatment furnace
JPS63161125A (en) * 1986-12-23 1988-07-04 Sumitomo Metal Ind Ltd Continuous annealing method and continuous annealing furnace
JPH02274823A (en) * 1989-04-18 1990-11-09 Nkk Corp Equipment and method for continuously annealing metal sheet
JPH05271785A (en) * 1992-03-24 1993-10-19 Kawasaki Steel Corp Method for adjusting temperature of metal strip
JPH11246916A (en) * 1998-03-02 1999-09-14 Kawasaki Steel Corp Vertical type continuous water-cooling device
JP2008150685A (en) * 2006-12-19 2008-07-03 Sumitomo Metal Ind Ltd Manufacturing method and manufacturing apparatus of cold-rolled steel plate

Cited By (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN106350657A (en) * 2016-08-29 2017-01-25 首钢京唐钢铁联合有限责任公司 Buckling-proof alarm system applied to continuous vertical annealing furnace
CN113774203A (en) * 2021-08-09 2021-12-10 南通江勤美金属制品有限公司 Non-hydraulic plate quenching device and method for continuous quenching of steel strip
CN113774203B (en) * 2021-08-09 2023-01-06 南通江勤美金属制品有限公司 Non-hydraulic plate quenching device and method for continuous quenching of steel strip

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