JP2005240154A - Method and equipment for continuously annealing steel plate - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a method and equipment for continuously annealing a steel plate in which an induction heating device is installed, the steel plate is adequately heated by the induction heating device, and a highly efficient operation is performed even when the tempering temperature of the steel plate exceeds 250°C. <P>SOLUTION: In the method for continuously annealing a steel plate by using the continuously annealing equipment having the cooling zone and the over-aging zone of the steel plate, an induction heating device to rapidly heat the steel plate is installed between the cooling zone and the over-aging zone, or at a first pass of the over-aging zone, and when the tempering temperature of the steel plate exceeds 250°C, the steel plate is heated by the induction heating device to a temperature of ≥80% of the in-furnace temperature at the over-aging zone. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to a method for continuously annealing a steel sheet using a continuous annealing facility having a steel sheet cooling zone and an overaging zone, and the continuous annealing facility.

  In order to stably feed the steel plate through a long line such as a continuous annealing facility, a taper shape or the like (crown) is given to the in-furnace transport roll (hearth roll) in the annealing furnace. A roll with a crown acts to center the steel plate at the taper. Therefore, when the steel plate deviates from the center of the roll due to meandering, the centering force works greatly on the meandering side and the steel plate returns to the center of the roll. The centering force of such a steel plate increases as the plate width increases and the taper angle of the roll crown increases.

  However, if the centering force is too strong for the rigidity of the steel plate, the steel plate will buckle (buckling), which may cause problems in product quality and may break from the buckled part. Will reduce the rate. For this reason, the crown of the in-furnace roll is determined from the meandering prevention of the steel sheet and the occurrence limit of buckling in consideration of the annealing temperature of the steel sheet, the material of the steel sheet, and the size of the steel sheet.

  However, in the heating zone, the temperature of the part where the in-furnace roll is not in contact with the steel plate rises due to radiation from the furnace, but in the region where the steel plate temperature near the heating zone entry side has not yet risen, Since the temperature of the portion in contact with the steel sheet is cooled by the steel sheet and approaches the temperature of the steel sheet, a temperature distribution is generated in the in-furnace roll, and a roll crown change (thermal crown) due to a difference in thermal expansion occurs. When the thermal crown is generated, the initial crown is not maintained, and the narrow material is likely to meander. Further, in the cooling zone, the furnace temperature is low, but the temperature of the steel plate is high, so that a thermal crown opposite to the heating zone is generated, and the crown becomes larger from the beginning.

Moreover, the temperature of the steel sheet is not constant. For example, when a liquid cooling zone is used to produce high-strength steel, the temperature of the steel sheet exiting the cooling zone is about 50 ° C, while when a water-cooled roll cooling zone is used to produce a soft material, The temperature of the steel plate that has come out of the strip is about 400 ° C., and when there are a plurality of such cooling means in the cooling zone of the steel plate, as a result, a difference occurs in the cooling end point temperature of the steel plate. It will reach over 300 ° C. And this temperature difference becomes a temperature difference of the steel plate which enters into the reheating furnace (overaging furnace or tempering furnace) which follows the cooling zone as it is, and a large difference is produced in the thermal crown formed on the in-furnace roll. As an example of this, in a metal plate continuous annealing facility that combines a liquid cooling zone and a cooling zone with an internal cooling roll, a rapid heating device is disposed between the cooling zone and the reheating zone, and heating is performed by this rapid heating device. A metal plate continuous annealing method is known in which the plate temperature of the plate is set within the range of the furnace temperature ± 200 ° C. at the inlet of the reheating zone (see, for example, Patent Document 1). Here, ± 200 ° C. is for preventing buckling and meandering of the steel sheet, and thereby it is possible to maintain the sheet feeding stability of the steel sheet in the reheating zone without changing the roll in the furnace. It is supposed to be.
JP-A-2-274823

  However, the above prior art has the following problems.

  In the method of Patent Document 1, a metal plate continuous annealing method is described in which the plate temperature of the plate heated by the rapid heating apparatus is set within the range of the furnace temperature ± 200 ° C. at the inlet of the reheating zone. For example, if the furnace temperature at the reheating zone inlet is about −100 ° C., the steel plate may be meandered. In other words, if the furnace temperature at the inlet of the reheating zone is 250 ° C., the steel plate is heated to about 150 ° C. by a rapid heating device disposed between the cooling zone and the reheating zone. It shows that the steel plate may meander when heated to 60% of the aging zone furnace temperature.

  Furthermore, recently, there has been an increasing need for a high-strength steel plate that has not been conventionally used and has a good workability. In order to manufacture such a steel sheet, the tempering temperature of the steel sheet rapidly cooled by liquid cooling or the like may need to be higher than 250 ° C. Conventionally, the tempering temperature of the steel sheet exceeds 250 ° C. No increase is made until the temperature is reached, and Patent Document 1 does not assume such a high temperature range.

  Therefore, even when the tempering temperature of the steel sheet exceeds 250 ° C., an object of the present invention is to install an induction heating device, and appropriately heat the temperature of the steel plate by the installed induction heating device so that high efficiency operation can be performed. An object of the present invention is to provide a steel plate continuous annealing method and a steel plate continuous annealing facility.

  The features of the present invention for achieving such an object are as follows.

  (1) A method of continuously annealing a steel sheet using a continuous annealing facility having a steel sheet cooling zone and an overaging zone, wherein the steel plate is placed between the cooling zone and the overaging zone or in the first pass of the overaging zone. When an induction heating device for rapid heating is installed and the tempering temperature of the steel sheet exceeds 250 ° C., the temperature of the steel sheet is heated to 80% or more of the overaging furnace temperature by the induction heating device. A method of continuous annealing of steel sheets characterized by

  (2) In a continuous annealing facility having a steel sheet cooling zone and an overaging zone, the cooling zone has a plurality of cooling means in which the difference in the cooling end point temperature of the steel plate is 300 ° C. or more, and the cooling zone and the overaging zone An induction heating apparatus for rapidly heating a steel plate having a heating capacity of 1500 kW or more is installed in the first pass of the overaging zone or between the steel plate and the continuous aging zone.

  According to the present invention, even when the tempering temperature of the steel sheet exceeds 250 ° C., the induction heating device for rapidly heating the steel sheet between the cooling zone and the overaging zone or in the first pass of the overaging zone is provided. Since it can be installed and the temperature of the steel sheet can be appropriately heated, meandering of the steel sheet does not occur even in high speed operation at a speed of 60 mpm or more, and the efficiency is improved.

  Drawing 1 is an explanatory view showing an example of the continuous annealing equipment of the steel plate of the present invention.

  The steel sheet continuous annealing facility shown in FIG. 1 has a steel sheet cooling zone 1 and an overaging zone 2. In addition, induction heating devices 3a and 3b for rapidly heating the steel plate are provided between the cooling zone 1 and the overaging zone 2 of the steel plate and in the first pass of the overaging zone.

  In the embodiment shown in FIG. 1, the induction heating device 3 is installed between the cooling zone 1 and the overaging zone 2 of the steel plate and in the first pass of the overaging zone, but the installation form is not limited to this. Instead, it may be installed between the cooling zone 1 of the steel plate and the overaging zone 2 or in the first pass of the overaging zone. That is, the induction heating device 3 may be installed so that the steel sheet cooled in the cooling zone 1 can be rapidly heated to a desired temperature before reaching the in-furnace roll on the downstream side of the first pass of the overaging zone.

When performing the continuous annealing of the steel sheet using the continuous annealing equipment for the steel sheet shown in FIG. Either or both of these are used to heat the steel sheet to 80% or more of the overaging zone furnace temperature. Here, the temperature in the overaging zone furnace is, for example, a temperature in a furnace thermometer installed at a substantially middle height position between the normal furnace rolls 4a and 4b.

  The cooling zone 1 is a zone for cooling the steel plate, and has a plurality of cooling means in which the difference in the cooling end point temperature of the steel plate in the cooling zone 1 is 300 ° C. or more. Here, examples of the plurality of cooling means include a combination of liquid cooling (water quenching), internal cooling type roll (roll cooling), gas jet cooling, air-water cooling, etc., but the present invention is limited to this. Any cooling means may be used. For example, as described above, it can be constituted by two cooling means, that is, an internal cooling roll (roll cooling) used at the time of manufacturing a general soft material and a liquid cooling (water quenching) used at the time of manufacturing high-tensile steel.

  The overaging zone 2 is also called a tempering zone, and is used to temper the steel sheet that has passed through the cooling zone 1 at a predetermined temperature. In the present invention, the tempering temperature of the steel sheet may be more than 250 ° C. in order to obtain a high-tensile steel sheet with good workability. The overaging zone 2 is provided with a plurality of in-furnace rolls 4a, 4b above and below it.

  The induction heating device 3 raises the steel sheet that has passed through the cooling zone 1 to a predetermined temperature by changing the energization amount. Thereafter, in the overaging zone 2, heating to a predetermined tempering temperature and holding at that temperature are performed.

  Next, FIG. 2 shows the steel plate speed (mpm) and the steel plate when the steel plate cooled to about 50 ° C. by water quenching according to the present invention is heated by the induction heating device 3 and the tempering temperature of the steel plate exceeds 250 ° C. It is a graph which shows an example of a relationship with temperature / temperature in an overaging zone furnace (%). As shown by the solid line in FIG. 2, when the steel sheet is heated by an induction heating device and the ratio between the steel sheet temperature after heating and the temperature inside the overaging furnace reaches 80% or more, the steel sheet speed can be increased to 60 mpm or more. The operation data was clearly divided such that the steel plate speed was less than 60 mpm when the ratio between the later steel plate temperature and the overaging zone furnace temperature was less than 80%. That is, when the steel sheet is heated by the induction heating device and the ratio of the heated steel plate temperature to the overaging zone furnace temperature becomes 80% or more, the steel plate does not meander, so the temperature of the steel plate is excessively increased by the induction heating device. It is necessary to heat to 80% or more of the aging zone furnace temperature. If meandering does not occur in the steel sheet, the steel sheet speed can achieve a high efficiency operation of about 60 mpm or more. On the other hand, when the steel sheet is heated by an induction heating device and the ratio between the steel sheet temperature after heating and the temperature inside the overaging zone is less than 80%, the steel plate particularly in the in-furnace roll downstream of the 1st pass of the overaging zone. If meandering occurs in the steel plate, and if meandering occurs in the steel plate, the steel plate speed becomes a low-efficiency operation suppressed to less than about 60 mpm.

  In FIG. 2, the upper limit value of the steel plate temperature / over-aging zone furnace temperature (%) is not particularly limited, but if the steel plate temperature / over-aging zone furnace temperature (%) is too high, an induction heating device is used. Since a large amount of power is required to be input to the power source, it is not preferable from the viewpoint of energy cost. Therefore, the steel sheet temperature / over-aging furnace temperature (%) is preferably 120% or less.

  Next, FIG. 3 shows the steel plate speed (mpm) and induction when the steel plate cooled to about 50 ° C. by the water quenching of the present invention is heated by the induction heating device 3 and the tempering temperature of the steel plate exceeds 250 ° C. It is a graph which shows an example of the relationship with the electric power used (kW) of a heating apparatus. As described above, if meandering does not occur in the steel plate, high-efficiency operation with a steel plate speed of about 60 mpm or more can be realized. Here, as shown in FIG. 2, in order to achieve a steel plate speed of 60 mpm or more, it is necessary to heat to 80% or more of the overaging zone furnace temperature. Therefore, in order to achieve a steel plate speed of 60 mpm or higher by heating the steel plate to an overaging zone furnace temperature of 80% or higher from FIG. 3, the heating capacity of the induction heating device is required to be 1500 kW or higher.

  As an example of the present invention, a steel sheet cooled to about 50 ° C. by water quenching when continuously annealing a high-strength steel plate with a tempering temperature of 300 ° C. using the steel sheet continuous annealing facility of the present invention shown in FIG. The steel plate temperature / over-aging furnace temperature (%) was adjusted within the range of 80 to 120% and heated by the induction heating device 3 having a heating capacity of 1500 kW or more. The production of the high-tensile steel sheet to be heated by the induction heating device 3 was made with 3 production chances, and the production chances were set as D, E, and F, respectively. The annealing amount per production chance was about 2000 tons.

  As a comparative example, using the continuous annealing equipment of the steel sheet of the present invention shown in FIG. 1, when a high-tensile steel sheet is continuously annealed at a tempering temperature of 300 ° C., a steel sheet cooled to about 50 ° C. is induced by water quenching. Heating was performed by adjusting the steel sheet temperature / over-aging furnace temperature (%) within the range of 50 to 80% by the heating device 3. The production of the high-tensile steel sheet that is heated by the induction heating device 3 was made with 3 production chances, and the production chances were set as A, B, and C, respectively.

  FIG. 4 shows the average steel sheet speed (mpm) for each chance in the manufacturing chances D, E, and F of the present invention example of the above-described high-tensile steel sheet and the manufacturing chances A, B, and C of the comparative example. In the production chances D, E, and F of the present invention example of the high-strength steel sheet in which the steel sheet temperature / over-aging zone furnace temperature (%) is 80% or more, there is no meandering of the steel sheet, and the average steel sheet speed (mpm) is High speed operation of 60 mpm or more was possible, and the efficiency was improved. On the other hand, in the production chances A, B, and C of the comparative example of the high-strength steel sheet in which the steel sheet temperature / over-aging zone furnace temperature (%) is less than 80%, the meandering occurs in the steel sheet in the over-aging zone in-furnace roll. The average steel plate speed (mpm) was reduced to less than 60 mpm.

Explanatory drawing which shows an example of the continuous annealing equipment of the steel plate of this invention The graph which shows an example of the relationship between a steel plate speed (mpm) and a steel plate temperature / overaging zone furnace temperature (%) when the tempering temperature of a steel plate exceeds 250 ° C. The graph which shows an example of the relationship between a steel plate speed (mpm) and the electric power used (kW) of an induction heating apparatus, when setting the tempering temperature of a steel plate to exceed 250 ° C. A graph showing the production chances D, E, F of the present invention example of the high-tensile steel sheet and the average steel sheet speed (mpm) for each chance in the production chances A, B, C of the comparative example.

Explanation of symbols

1 Cooling zone 2 Overaging zone
3, 3a, 3b Induction heating device 4, 4a, 4b In-furnace roll

Claims (2)

  A method of continuously annealing a steel sheet using a continuous annealing facility having a cooling zone and an overaging zone, and rapidly heating the steel plate between the cooling zone and the overaging zone or in the first pass of the overaging zone. When the induction heating device is installed and the tempering temperature of the steel sheet exceeds 250 ° C., the temperature of the steel sheet is heated to 80% or more of the overaging zone furnace temperature by the induction heating device. Continuous annealing method for steel sheet.   In continuous annealing equipment having a steel sheet cooling zone and an overaging zone, the cooling zone has a plurality of cooling means in which the difference in the cooling end point temperature of the steel plate is 300 ° C. or more, and between the cooling zone and the overaging zone Or in the 1st pass of an overaging zone, the induction heating apparatus for rapidly heating the steel plate which has a heating capacity of 1500 kW or more is installed, The continuous annealing equipment of the steel plate characterized by the above-mentioned.

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