KR20170091549A - Method and apparatus for manufacturing steel sheet having martensite phase - Google Patents

Abstract

The present invention relates to a method and apparatus to produce a martensite-containing steel sheet, comprising: a step of preparing, in a coil form, a steel sheet in which at least a part of austenite is transformed into martensite during a water cooling process; a step of heating a steel sheet coil such that at least a portion of a microstructure of the steel sheet turns into austenite; and a step of cooling the heated steel sheet coil at a cooling rate of 500 C/sec or more while transferring the steel sheet at a transfer speed of 300 mpm or more to transform at least a part of the austenite to martensite. Accordingly, the present invention aims to provide a method of more economically manufacturing a martensite-containing steel sheet which is less transformed through batch-type heating and continuous cooling.

Description

TECHNICAL FIELD [0001] The present invention relates to a method of manufacturing a martensite-containing steel sheet,

The present invention relates to a method and an apparatus for producing a martensite-containing steel sheet used for automotive structural steel, and more particularly, to a method and apparatus for producing a martensite-containing steel sheet by batchwise heating and cooling continuously.

Demand for high strength automotive structural steel is increasing to satisfy high fuel efficiency and strict safety regulations through light weight.

In general, an alloy element such as a non-ferrous metal or a rare earth is added to produce a high strength steel.

However, when alloying elements are added, there is a problem that the manufacturing cost is increased and the manufacturing efficiency and product processability (for example, weldability) are deteriorated.

For this reason, attempts have been made to improve the strength of steel by rapid cooling in a heat treatment process while minimizing the alloy component.

As an example of such a rapid cooling method, there is a method using quenching.

The quenching cooling method is generally a method in which the steel sheet can be cooled at a cooling rate of, for example, 1000 占 폚 per 1 mm of the steel sheet.

In the quenching and cooling process, a quenching cooling tank in which cooling water is stored is used.

The cooling bath may include a cooler for maintaining the cooling water at a constant temperature and a jet injector for increasing the cooling rate. As such, the steel strip passes through a cooling bath, which is a quenching device, to achieve a desired degree of cooling.

However, there is a problem that when the high-temperature steel sheet is quenched by the existing quenching-cooling apparatus, the shape of the steel sheet is deteriorated.

For example, in a heating zone, a steel sheet is heated to a temperature of 800 ° C or higher. When the steel sheet is quenched, the steel sheet rapidly cools to room temperature within one second, resulting in a large temperature difference in the longitudinal direction and the width direction.

To solve this problem, it is necessary to increase the tensile strength of the steel sheet in order to obtain a flat steel sheet in the quenching process, to adjust the water temperature of the cooling water, to lower the temperature of the steel sheet at the start of quenching and to add an alloy component to prevent ferrite transformation Various methods have been proposed.

However, there is a limit to obtaining a good flatness by quenching (quenching) a steel sheet at a high temperature through conventional techniques.

On the other hand, there are a batch type and a continuous type in the process of heat treating the steel sheet, and the batch type in which the steel sheet is heated and cooled in the coil state has a slow cooling rate. In the continuous type in which the steel sheet is heated and cooled while moving, There are big features.

In general, the continuous type is advantageous for mass production, and the batch type is advantageous for small-scale production as compared with the continuous type.

A preferred aspect of the present invention is to provide a method for economically manufacturing a martensite-containing steel sheet in which the martensite-containing steel sheet is deformed in a batch manner by heating and cooling continuously to provide a more economical method.

Another desirable aspect of the present invention is to provide a device for economically manufacturing a martensite-containing steel sheet which is heated batchwise and continuously cooled to reduce the shape deformation.

A preferred aspect of the present invention is a method for manufacturing a steel sheet, comprising: preparing a steel sheet in the form of a coil in which at least a portion of austenite is transformed into martensite under water cooling;

Heating the steel coil so that at least a part of the microstructure of the steel sheet becomes austenite; And

And cooling the steel sheet coil at a cooling rate of 500 DEG C / sec or more while transferring the steel sheet at a conveying speed of 300 mpm or more by loosening the heated steel sheet coil to transform at least a part of the austenite into martensite. ≪ / RTI >

The water-cooling termination temperature in water-cooling is preferably 150 ° C or higher, which is Ms (martensitic transformation start temperature) or lower.

Another preferred aspect of the present invention is a heating furnace for heating a steel sheet in the form of a coil; Phage prills releasing the heated coil; A cooling device for cooling a heated steel sheet unreeled from the coil; And a coil for winding a cooled steel sheet.

The cooling device may be configured to give a cooling rate of 500 DEG C / sec or more when cooling the steel sheet.

The cooling device may include a cooling bath in which a cooling liquid for cooling the heated steel plate is stored, and a cooling pad for jetting the cooling liquid toward the steel strip.

And a guide roller for guiding the steel sheet between the phage prill and the cooling device, and between the cooling device and the coil.

According to a preferred aspect of the present invention, it is possible to minimize the facility cost by satisfying the cooling rate necessary for manufacturing the mart steel while reducing the size of the equipment, and by separating the heating and cooling, the feeding speed of the steel strip in the cooling process is increased to 500 Even in the case of rapid cooling above 캜 / sec, the change in the longitudinal temperature gradient of the steel strip is minimized, thereby reducing the thermal stress and minimizing the shape deformation of the steel strip.

1 is a schematic view showing an example of an apparatus for producing a martensitic steel sheet according to the present invention

The present invention provides a method and an apparatus for manufacturing a martensite-containing steel sheet that is effective not only in facility investment and operation but also minimizes the shape deformation of the steel strip by dispersing and minimizing concentration of longitudinal thermal stress of the steel sheet during rapid cooling of the steel sheet .

According to a preferred aspect of the present invention, in order to produce a martensite-containing steel sheet, a steel sheet in which at least a part of austenite is transformed into martensite under water cooling is prepared in the form of a coil.

As the steel sheet, at least a part of the microstructure becomes austenite upon heating, and a steel sheet in which at least a part of austenite is transformed into martensite at the time of water cooling is sufficient, and is not particularly limited.

The steel sheet which can be preferably applied to the present invention includes a martensitic steel sheet, a dual phase steel sheet and a complex phase steel sheet.

Examples of the steel sheet include: 0.05 to 0.4% by weight of carbon, 2% by weight or less of silicon (excluding 0), manganese of 1 to 3% by weight, phosphorus of 0.05% 0), the balance Fe, and other impurities.

The steel sheet is not particularly limited, but may be, for example, a hot-rolled steel sheet or a cold-rolled steel sheet.

Next, the steel sheet coil prepared as described above is heated so that at least a part of the microstructure of the steel sheet becomes austenite.

The heating conditions of the steel sheet can be appropriately controlled according to the steel sheet to be produced.

For example, in order to transform the entire microstructure into martensite, it is sufficient to heat the microstructure of the steel sheet so that all of the microstructure becomes austenite.

When the steel sheet is heated, the heating temperature is preferably 700 to 900 占 폚, and the heating atmosphere is preferably a reducing atmosphere. The reducing atmosphere may be 90 to 98% by volume of nitrogen and 2 to 10% by volume of hydrogen . The heating method is not particularly limited, and examples thereof include radiant heating, radiant tube and muffle type heating furnace.

The heating time may be 20 to 80 hours, for example, when the coil width is 600 to 1400 mm.

The steel sheet coil thus heated is unwound, and water is cooled at a cooling rate of 500 DEG C / sec or more while feeding the steel sheet at a feeding speed of 300 mpm or more to transform at least a part of the austenite into martensite to produce a martensite-containing steel sheet.

When the steel sheet has a conveying speed of less than 300 mpm, there is a problem that the temperature gradient and the reduction of the thermal stress are insufficient compared to the conventional continuous annealing method and the effect of improving the shape is small.

The higher the feed rate of the steel sheet is, the faster it is. However, if the steel sheet is too fast, it may be difficult to control the slewing and facilities. Therefore, the upper limit is preferably limited to 800 mpm.

More preferably, the feed rate of the steel sheet is 400 to 600 mpm.

When the cooling rate of the steel sheet is less than 500 deg. C / sec, there is a problem that the cooling deviation increases in the film burning area and the shape of the steel sheet deteriorates.

On the other hand, if the cooling rate is too high, the temperature gradient and the thermal stress may be increased to deteriorate the shape of the steel sheet. Therefore, the upper limit is preferably limited to 2000 ° C / sec. The cooling rate of the steel sheet is more preferably 500 to 1500 DEG C / sec. The most preferable cooling rate of the steel sheet is 800 to 1200 DEG C / sec.

The water-cooling termination temperature in water-cooling is not particularly limited as long as it is not higher than Ms (martensitic transformation start temperature), and may be, for example, room temperature.

In the case of self-tempering, it is preferable that the water-cooling end temperature in water-cooling is 150 deg. C or lower which is Ms (martensitic transformation start temperature) or lower.

As described above, if the water-cooling termination temperature in water-cooling is Ms or less and 150 占 폚 or more, self-tempering can be performed to improve elongation without additional tempering process and evaporate residual water on the surface of the steel strip to prevent scale formation.

Hereinafter, an example of an apparatus for producing a martensite-containing steel sheet according to the present invention will be described with reference to Fig.

1, an apparatus 100 for producing a martensite-containing steel sheet according to the present invention comprises a heating furnace 1 for heating a steel sheet in the form of a coil 10; A phage prill 2 for releasing the heated coil 10; A cooling device (3) for cooling a heated steel sheet unloaded from the coil; And a coil 4 for winding the cooled steel sheet.

The cooling device 3 may include a cooling bath 31 in which a cooling liquid for cooling the heated steel plate is stored and a cooling base 32 for jetting the cooling liquid toward the steel strip.

The cooling device 3 may be configured to give a cooling rate of 500 DEG C / sec or more when cooling the steel sheet.

And guide rollers 5a and 5b for guiding the steel sheet between the phage prill 2 and the cooling device 3 and between the cooling device 3 and the coiler 4. [

In Fig. 1, reference numeral 6 denotes a conveyance truck, 11 denotes a heating-roller door, and 33 denotes a cooling roller.

A method for producing a martensite-containing steel sheet using the apparatus 100 for producing a martensite-containing steel sheet of Fig. 1 will be described.

 First, a steel plate coil 10 to be heated is placed on a conveying platform 6 with a crane or the like.

The conveyance truck 6 carrying the coil moves to the heating furnace 1. When the coil 10 is inserted into the printer pulley 2, the conveyance truck 6 comes out of the heating furnace 1.

Thereafter, the steel plate is connected to the guide roller 5a, the cooling roller 33, the guide roller 5b and the coil 4. Alternatively, the steel plate of the newly-installed coil 10 is welded to the already connected steel plate and connected to the phage prill 2.

Thereafter, the heating furnace door 11 is closed and the coil 10 is heated.

For example, the heating temperature is 700 to 900 占 폚, and the inside can be 90 to 98% by volume of nitrogen and 2 to 10% by volume of hydrogen in a reducing atmosphere.

The heating furnace 1 is not particularly limited, and a radiant tube or a muffle type heating furnace can be used as the radiant heating.

The heating time is 20 to 80 hours when the coil width is 600 to 1400 mm.

When the necessary temperature is reached up to the inside of the coil, the phage prill 2 and the coil 4 are operated so that the steel plate passes through the cooling bath 31 of the cooling device 3. The cooling bath 31 is filled with water as cooling medium for cooling. Further, a cooling base 32 for spraying a coolant on the front and rear surfaces of the steel strip is provided in the cooling bath to cool the steel plate at a rate of 500 ° C / sec or more.

The conveying speed of the steel sheet during cooling is 400 to 600 mpm, which is more than 300 mpm, preferably 2 to 3 times faster than the normal continuous annealing process conveying speed of 1.5 to 1.5 times faster than 200 mpm.

As a result, in a conventional continuous heat treatment process, for example, the steel strip temperature gradient during quenching and quenching is reduced to 300 ° C / meter, but in the present invention, 150 ° C to 100 ° C / meter. Numerical results show that the thermal stress decreases by one-third when the speed is doubled. Therefore, the steel sheet shape can be good even though the cooling rate is the same as the cooling rate of 1000 DEG C / sec in the ordinary continuous annealing for quenching process. On the other hand, since the steel strip feeding speed is fast during cooling, the time taken to cool the entire coil is as short as about 4 minutes.

1: heating furnace 2: phage prill 3: cooling device 4: coiler 5 (a) 5 (b): guide roller 31: cooling bath 32:

Claims (10)

Preparing a steel sheet in the form of a coil in which at least a part of austenite is transformed into martensite during water cooling;
Heating the steel coil so that at least a part of the microstructure of the steel sheet becomes austenite; And
Cooling the heated steel sheet coil at a cooling rate of 500 ° C / sec or more while transferring the steel sheet at a conveying speed of 400 to 600 mpm to transform at least a part of the austenite to martensite, Wherein the feed rate and the cooling rate of the steel sheet are controlled such that the temperature gradient of the steel sheet is 150 to 100 DEG C / meter.
The method for producing a martensite-containing steel sheet according to claim 1, wherein the water-cooling termination temperature in water cooling is Ms (martensitic transformation start temperature) or lower.
The method for producing a martensite-containing steel sheet according to claim 1, wherein the water-cooling termination temperature in water-cooling is 150 deg. C or higher, which is not higher than Ms (martensitic transformation start temperature).
The method for producing a martensite-containing steel sheet according to claim 1, wherein the cooling rate of the steel sheet is 800 to 1200 ° C / sec.
The method for producing a martensite-containing steel sheet according to claim 1, wherein the steel sheet is one of a martensite steel sheet, a dual phase steel sheet and a complex phase steel sheet.
The steel sheet according to claim 1, wherein the steel sheet contains 0.05 to 0.4% by weight of carbon, 2% by weight or less of silicon (excluding 0), manganese of 1 to 3% 0.02 wt% or less (including 0), the balance Fe and other impurities.
A heating furnace for heating the steel plate in the form of a coil; Phage prills releasing the heated coil; A cooling device for cooling a heated steel sheet unreeled from the coil; And a coiler for winding the cooled steel sheet. The conveying speed of the steel sheet fed by the paper prills and the cooling rate of the steel sheet cooled by the cooling device are set such that the temperature gradient of the steel sheet to be cooled is 150 to 100 DEG C / meter The steel sheet having the martensite-containing steel sheet.
8. The apparatus for manufacturing a martensite-containing steel sheet according to claim 7, wherein the cooling device is configured to give a cooling rate of 500 DEG C / sec or more when cooling the steel sheet.
The apparatus for manufacturing a martensite-containing steel sheet according to claim 7, wherein the cooling device comprises a cooling bath in which a cooling liquid for cooling a heated steel sheet is stored, and a cooling band for jetting the cooling liquid toward the steel strip .
The apparatus for manufacturing a martensite-containing steel sheet according to claim 7, wherein a guide roller for guiding the steel sheet is provided between the phage prill and the cooling device, and between the cooling device and the coil.

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