KR101789515B1 - Quenching heating apparatus for continuous heat treatment coil steel plate - Google Patents

Abstract

The present invention relates to a quenching heating apparatus for a continuous annealing apparatus for a coil steel plate,
An LF type primary induction heater for heating a coil steel sheet supplied from an uncoiler to a temperature not higher than the magnetic transformation point temperature of 650-750 占 폚; An insulating guide duct installed between the primary induction heating furnace and the temperature maintaining furnace to prevent the coil steel plate, which is heated through the primary induction furnace and then moves toward the temperature holding furnace, from being exposed to the atmosphere; And a TF type second induction heater installed in the insulating guide duct to heat the coil steel plate to a quenching temperature of 850-950 ° C.
The coil steel sheet can be stably heated, so that the quenching heat treatment can be performed smoothly.

Description

TECHNICAL FIELD [0001] The present invention relates to a quenching heating apparatus for continuously heating a coil steel plate,

The present invention relates to a quenching heating apparatus for a continuous steel heating system for a coil steel plate, and more particularly, to a quenching heating apparatus for a quenching heating apparatus of a coil steel plate, in which a heat insulating guide duct is provided between a primary induction heating furnace and a quenching tempering furnace, .

In general, a steel sheet having a thickness of 0.6 to 3.2 mm, which is generally used for automobile parts, is cut to a size suitable for a press die, and is manufactured as an automotive part through press molding.

After completion of the press-molding, the automotive parts are subjected to heat treatment for quenching and tempering to satisfy mechanical properties such as strength, hardness, abrasion resistance, impact resistance, workability, and magnetic properties required for the automotive parts.

The term " heat treatment " refers to a heating and cooling operation for heating a metal material to a temperature below the melting point and selectively increasing or decreasing the cooling rate to obtain a desired structure and properties. The quenching, tempering, .

In this heat treatment, quenching and quenching are repeatedly performed and then tempering is performed. However, such an intermittent heat treatment process is disadvantageous in that productivity is greatly reduced.

In addition, there is a problem in that a part to be molded by a press is charged into a heat treatment furnace and then heated, and the heated part is dipped and cooled, which makes it difficult to correct due to deformation and various costs and time Which causes a problem of loss.

Patent Document 1 below discloses a continuous heat treatment apparatus for a steel plate or a steel plate for use in high strength and high strength steel plates for use in ships, general and welded structures, boilers and pressure vessels, line pipes, weatherproofing and corrosion resistant steel .

In the continuous heat treatment apparatus of the thick plate of Patent Document 1, the thick plate is applied through the continuous induction heating furnace, and the heated thick plate is cooled and quenched. Then, the heated plate is charged into the continuous induction heating tempering furnace through the conveying apparatus, Tempering improves the productivity by continuous heat treatment of the thick plate, improves the good texture and mechanical properties through uniform heating, prevents deformation through the upper / lower transport rollers, It is also possible to perform continuous heat treatment work such as called process and annealing process by heating.

However, the continuous heat treatment apparatus of the thick plate of Patent Document 1 is for heat treatment of a thick plate having a thickness of 6 mm or more and a length of 25 m, and does not prevent or correct deformation caused by continuous quenching and tempering.

In addition, a magnetic field is generated by applying a current to the induction heating coil, and an induction current is generated in the thick plate by a magnetic field, and the heating is performed by the joule heat, so that a temperature deviation occurs between the skin layer and the inner center.

Korean Registered Patent No. 10-0694559 (registered on Mar. 07, 2007)

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems of the prior art, and it is an object of the present invention to quench a coil steel sheet in a continuous heat treatment facility in which quenched and tempered coil steel plates of a thin plate having a thickness of 0.6 to 3.2 mm are continuously subjected to quenching and tempering. And to provide a quenching heating apparatus for continuous heating of a coil steel plate which can be heated at a high temperature.

In order to achieve the above-mentioned object, a quenching heating apparatus for a continuous annealing apparatus for a coil steel plate according to the present invention comprises: an LF type 1 heating apparatus for heating a coil steel sheet fed from an uncoiler to a temperature not higher than a magnetic transformation point temperature of 650-750 ° C. Car induction heating; An insulating guide duct installed between the primary induction heating furnace and the temperature maintaining furnace to prevent the coil steel plate, which is heated through the primary induction furnace and then moves toward the temperature holding furnace, from being exposed to the atmosphere; And a TF type secondary induction heater installed in the heat insulating guide duct to heat the coil steel sheet to a quenching temperature of 850 - 950 캜.

The quenching heating apparatus of the continuous steel heat treatment apparatus for a coil steel sheet according to the present invention is characterized in that the heat insulating guide duct comprises an inner heat insulating wall forming a coil steel plate passing space having a rectangular cross section; An outer heat insulating wall in the form of a rectangular cross section provided on the outer periphery of the inner heat insulating wall; And a first heat-resistant fiber member filled in a space between the inner heat-insulating wall and the outer heat-insulating wall to block heat of the inner heat-insulating wall from being transferred to the outer heat-insulating wall.

The quenching heating apparatus of the continuous steel heat treatment apparatus for a coil steel according to the present invention includes a second heat resistant fiber member installed at a lower end of the coil steel plate passing space to prevent direct contact of the coil steel plate with the inner heat insulating wall .

The quenching heating apparatus of the continuous steel heat treatment apparatus for a coil steel sheet according to the present invention is characterized in that the coil steel sheet passing space is maintained in a vacuum state or a nitrogen atmosphere gas is charged.

The quenching heating apparatus of the continuous steel heating system for a coil steel plate according to the present invention is characterized in that the secondary induction furnace is movable in the forward and backward directions and can be separated from the heat insulating guide duct.

According to the quenching heating apparatus of the continuous annealing apparatus for a coil steel plate according to the present invention, after the coil steel sheet is heated to a magnetic transformation point or lower through primary induction heating of the LF type, the secondary induction furnace of the TF type is heated to a quenching temperature, It is possible to stably heat the coil steel plate, so that the quenching heat treatment can be performed smoothly.

According to the quenching heating apparatus of the continuous annealing apparatus for a coil steel plate according to the present invention, the coil steel plate which is heated by the primary induction furnace and then moves toward the quenching temperature holding furnace is guided through the heat insulating guide duct to minimize the heat loss of the coil steel plate It is possible to reduce the energy and to prevent the oxidation of the coil steel sheet, so that a high-quality heat-treated product can be obtained.

According to the quenching heating apparatus of the continuous steel heat treatment apparatus for a coil steel sheet according to the present invention, the secondary induction heater can be separated from the heat insulating guide duct to facilitate the inspection, adjustment, and repair of the secondary induction heater and the heat insulating guide duct .

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is an overall layout view of a continuous steel plate annealing apparatus to which a quenching heating apparatus of a continuous annealing apparatus for a coil steel plate according to a preferred embodiment of the present invention is applied;
2 is a front view of a quenching and heating apparatus of a continuous annealing equipment for a coil steel plate according to a preferred embodiment of the present invention
FIGS. 3A and 3B are a plan view of a quenching heating apparatus of a continuous annealing equipment for a coil steel plate according to the presently preferred embodiment,
Fig. 4 is a conceptual view of LF induction heating,
5 and 6 are longitudinal cross-sectional views of a heat insulating guide duct of a quenching heating apparatus of a continuous steel heat treating apparatus for a steel coil according to the present invention,
7 is a conceptual view of the TF induction heating.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will now be described in detail with reference to the accompanying drawings.

In the following, the terms "upward", "downward", "forward" and "rearward" and other directional terms are defined with reference to the states shown in the drawings.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is an overall layout diagram of a continuous steel plate annealing apparatus to which a quenching heating apparatus of a continuous annealing apparatus for a coil steel plate according to a preferred embodiment of the present invention is applied.

The present invention relates to a continuous annealing apparatus for a coil steel plate, which comprises: a coil steel plate (1) having a thickness of 0.6 to 3.2 mm is uncoiled from an uncoiler (10) to perform heat treatment for quenching and tempering, And rewinds the steel plate 1 back to the recoiler 80. [

As shown in FIG. 1, the continuous steel heat treatment system for a coil steel plate is a quench-hardening apparatus for performing quenching between an uncoiler 10 for supplying a coil steel plate 1 and a recoiler 80 for rewinding a heat-treated coil steel plate 1 And a tempering section for performing heating and tempering is provided.

The continuous annealing equipment for a coil steel plate includes an uncoiler 10, a quenching tension adjusting device 20, a quenching heating device 100, a quenching temperature holding furnace 30, a quenching device 40, a tempering device 200, The holding furnace 50, the air cooler 60, the tempering tension adjusting device 70, and the recoiler 80 are arranged in this order.

In FIG. 1, reference numeral 91 denotes a cutter, 92 denotes a welder, 93 denotes a tension pad for uncoiler, and 94 denotes a heat-treated finished product cutter.

FIG. 2 is a front view of a quenching heating apparatus for a continuous annealing apparatus for a coil steel plate according to a preferred embodiment of the present invention, and FIGS. 3a and 3b are plan views of a quenching heating apparatus for a continuous annealing apparatus for a coil steel plate according to the preferred embodiment of the present invention.

The quenching heating apparatus 100 of the continuous steel annealing apparatus for a coil steel sheet according to the preferred embodiment of the present invention includes a primary induction furnace 110, a heat insulating guide duct 120, and a secondary induction furnace 130.

The primary induction heater 110 heats the coil steel plate 1 supplied from the uncoiler 10 to a temperature equal to or lower than the magnetic transformation point temperature of about 650 to 750 ° C.

In general, the heating of the metal plate in the heat treatment furnace is carried out by indirect heating mainly using a radiant tube. However, this indirect heating is not limited to the fact that the difference in temperature between the metal plate and the furnace temperature is small, So that the productivity is restricted. In indirect heating using a radiant tube, it is difficult to realize high-temperature annealing because of rapid heating in the vicinity of a transformation point at which a heat endothermic reaction occurs or restriction of heat resistance of a radiant tube, for example, The degree of freedom in selecting the heat treatment conditions of the steel sheet is restricted.

On the contrary, the induction heating for heating the metal plate with a high-frequency current can freely control the heating rate and the heating temperature, and is a heating method recently attracting attention because of its high degree of freedom in terms of heat treatment operation and development of metal plate products.

There are two types of induction heating. One is to cause a high frequency current to flow through the induction coil surrounding the metal plate to allow the magnetic flux to pass through the end face in the longitudinal direction (traveling direction) of the metal plate and generate an induction current circulating in the width direction section of the metal plate perpendicular to this flux (Longitudinal flux, longitudinal magnetic field heating method) for heating the metal plate.

Another method is to arrange an inductor (good magnetic body) wound with a primary coil across a metal plate, pass a magnetic flux generated by passing an electric current through the primary coil through the in-plane surface of the metal plate, It is a TF system (Transverse Flux, vertical magnetic field heating system) in which induction current is generated on the plate surface to heat the metal plate.

In the induction heating of the LF type in which the induction current is circulated in the plate section, the relationship [delta (mm) = 5.03105 (p / mu rf), p And the induced current generated in the front and back of the metal plate is deeper than the thickness of the steel plate, the induced current does not occur on the end face of the metal plate.

For example, in the case of a nonmagnetic metal plate or a metal plate whose magnetic property exceeds the Curie temperature, the penetration depth delta of the current is deepened, and therefore, if the thickness of the metal plate is small, no induction current is generated. Even if the magnetic material is a magnetic material, even if the plate thickness is too thin compared to the penetration depth, the induction current does not occur in the cross section of the steel sheet in the LF method.

On the other hand, in the induction heating by the TF method, since the magnetic flux passes through the plate surface of the metal plate, the metal plate can be heated independently of the plate thickness and without discrimination between magnetic and nonmagnetic. Or may not be able to be heated completely. Further, excessive heating is likely to occur at the end portion of the metal plate (see, for example, Japanese Patent Application Laid-Open No. 62-281291).

If the magnetic metal plate is not located at the center of the opposing inductor, it may be pulled close to one of the inductors, so that the magnetic flux locally concentrates and the temperature difference of the metal plate becomes large. In addition, since the inductor shape can not be easily changed in the induction heating by the normal TF method, there is a problem that it is difficult to cope with the change of the plate width of the metal plate.

For this reason, for example, Japanese Patent Laid-Open Publication No. 2008-186589 discloses a magnetic recording medium which includes a magnetic pole segment which is arranged to be opposed to a thin plate in parallel in the plate width direction of the thin plate and which is independently movable in the thickness direction of the thin plate, And a movable shield plate of a non-magnetic metal for adjusting the magnetic field caused by the magnetic pole segments so as to protrude and retract in the plate width direction.

4 is a conceptual diagram of LF induction heating.

The primary induction heater 110 heats the coil steel plate 1 by an LF method (longitudinal magnetic flux heating method) in which the coil steel plate 1 passes inside the heating coil 112 of the closed curve.

The LF method is a method in which a magnetic field is generated and heated in the longitudinal direction (vertical axis) of the heating target as described above, and the induction current is wrapped around the material outer surface and rotated.

In the LF method, when the ferromagnetic material is heated, the ferromagnetic metal absorbs the magnetic field in the heating coil to improve the heating efficiency. When the nonmagnetic material is heated, the magnetic field in the heating coil is not absorbed by the metal to be heated.

The primary induction heater 110 is of the LF type in which a pair of heating coils 112 in the form of a closed curve are arranged in the left and right direction around the passage of the coil steel 1 in the casing 111, In the heater 110, the coil steel plate 1 is heated in the process of passing the space inside the heating coil 112 in the form of a closed curve in the left-right direction.

5 and 6 are vertical cross-sectional views of a heat insulating guide duct of a quenching heating apparatus in a continuous steel heat treating apparatus for a steel coil according to the present preferred embodiment.

The heat insulating guide duct 120 suppresses the heat loss of the coil steel plate 1 which is heated to the quenching temperature holding furnace 30 after being heated in the primary induction heater 110 and the coil steel plate 1 is exposed to the air And is provided between the primary induction heater 110 and the temperature maintaining furnace 30 in order to prevent oxidation from being promoted.

The heat insulating guide duct 120 includes an inner heat insulating wall 121, an outer heat insulating wall 122, a first heat resistant fiber member 123 and a second heat resistant fiber member 124.

The inner heat insulating wall 121 constitutes a coil steel sheet passing space S having a rectangular cross section by using a heat resistant board exhibiting a heat insulating effect at a high temperature of 1100 캜 or higher.

It is preferable that the coil steel plate passing space S provided inside the inner heat insulating wall 121 is kept in a vacuum state or filled with a nitrogen atmosphere gas.

The outer heat insulating wall 122 is in the form of a rectangular cross section provided on the outer periphery of the inner heat insulating wall 121.

The external heat insulating wall 122 is preferably made of an electrically insulating material such as graphite, which has excellent heat resistance and can withstand high temperatures.

The first heat resistant fiber member 123 is filled in the space between the inner heat insulating wall 121 and the outer heat insulating wall 122 and blocks the heat of the inner heat insulating wall 121 from being transmitted to the outer heat insulating wall 122 .

The first heat-resistant fiber member 123 is preferably made of a fiber material capable of exerting an adiabatic effect at a high temperature of 900 ° C or higher.

The second heat resistant fiber member 123 is installed at the lower end of the coil steel plate passage space S and is heated by the primary induction heater 110 and the secondary induction heater 130 to heat the coil steel plate 1 Thereby blocking transmission to the inner heat insulating wall 121.

The second heat resistant fiber member 123 is formed such that the coil steel plate 1 passing through the coil steel plate passing space 1 is lowered by gravity down to contact the inner heat insulating wall 121, So that it does not occur.

The second heat-resistant fiber member 123 is preferably made of a fiber material exhibiting an adiabatic effect at a high temperature of 1100 ° C or higher.

The secondary induction heater 130 heats the coil steel sheet 1 heated to a temperature below the magnetic transformation point temperature through the primary induction heater 110 to a quenching temperature of about 850 to 950 ° C.

The secondary induction heater 130 is installed in the heat insulating guide duct 120 installed between the primary induction furnace 110 and the temperature maintaining furnace 30 so as to be movable in the forward and backward directions.

7 is a conceptual view of the TF induction heating.

The secondary induction heater 130 heats the coiled steel plate 1 with a TF system (Transverse Flux, vertical magnetic field heating system) in which the heating coil 132 is provided on the upper and lower portions of the coiled steel plate 1.

The TF method is a method in which a magnetic field is generated and heated in the vertical direction (normal direction) of the target to be heated, as described above, and the induced current is rotated on one side of the workpiece.

In the TF method, the magnetic field in the heating coil is not absorbed by the metal to be heated, so that the magnetic field is pressed in the plane direction of the material to be heated to increase the magnetic field coupling coefficient.

The secondary induction heater 130 has a pair of upper casing 131a spaced in the left and right direction and a pair of lower casing 131b spaced in the left and right direction.

The secondary induction heater 130 is movable in the forward and backward direction through the caster 134 provided at the lower end of the casing supporting frame 133.

The forward and backward conveying structure of the secondary induction heater 130 may be a known linear device including a linear motor and a conveying rail, or a conveying cylinder type.

The quenching heating apparatus 100 of the continuous annealing apparatus for a coil steel sheet according to the preferred embodiment of the present invention heats the coil steel plate 1 to a temperature not higher than the magnetic transformation point through the LF type primary induction furnace 110, Type induction heating furnace 130 to the quenching temperature.

That is, in the continuous heat treatment facility, the coil steel plate 1 of the uncoiler 10 is moved toward the recoiler 80, and in the process of passing through the quenching heater 100 disposed on the moving path of the coil steel plate 1 And is heated to a quenching temperature.

During the quenching and heating process, the coil steel plate 1 is introduced into the primary induction furnace 110 and passes through the inside of the pair of heating coils 112 in the form of a closed curve, And is moved to the quenching temperature holding furnace 30 through the heat insulating guide duct 120. [

The heat insulating guide duct 120 prevents the coil steel plate 1 from being cooled during the movement of the coil steel sheet 1 heated by the primary induction heater 110 to the quenching temperature holding furnace 30, The steel sheet 1 is prevented from being exposed to the air, thereby preventing the oxidation of the coil steel sheet 1.

The secondary induction heater 130 of the TF type installed in the heat insulating guide duct 120 is formed by winding a coil steel plate 1 through a pair of heating coils 122 located at the top and bottom of the coil steel plate 1, 950 < [deg.] ≫ C.

In the quenching heating apparatus 100 of the continuous annealing apparatus for a coil steel plate according to the preferred embodiment of the present invention, the secondary induction heater 130 is installed to be movable in the front-rear direction.

Accordingly, it is possible to check the secondary induction heater 130, adjust the position of the heating coil 132 of the secondary induction heater 130, check the state of the heat insulating guide duct 120, or repair the heat insulating guide duct 120 The secondary induction heater 130 can be moved backward and separated from the heat insulating guide duct 120 as shown in FIG. 3B.

Although the present invention has been described in detail with reference to the above embodiments, it is needless to say that the present invention is not limited to the above-described embodiments, and various modifications may be made without departing from the spirit of the present invention.

100: quenching heating device
110: Primary induction heating
112: Heating coil
120: Insulation guide duct
130: Secondary induction heater
132: Heating coil

Claims (5)

The coil steel plate 1 having a thickness of 0.6 to 3.2 mm is uncoiled in the uncoiler 10 to perform quenching and tempering heat treatment and then the heat treated coil steel plate 1 is re- The quenching heating apparatus of the continuous steel heating system for a coil steel plate,
An LF type primary induction heater 110 for heating the coil steel plate 1 supplied from the uncoiler 10 to a temperature not higher than the magnetic transformation point temperature of 650-750 占 폚;
The coil steel plate 1 installed between the primary induction furnace 110 and the temperature maintaining furnace 30 and heated by the primary induction furnace 110 and moving toward the temperature maintaining furnace 30 is placed in the atmosphere An insulation guide duct (120) for preventing exposure;
And a TF type secondary induction heater (130) installed in the heat insulating guide duct (120) and heating the coil steel plate (1) to a quenching temperature of 850 - 950 캜. Quenching heating device. The method according to claim 1,
The insulation guide duct (120)
An inner heat insulating wall 121 forming a coil steel plate passage space S having a rectangular cross section;
An outer heat insulating wall 122 in the form of a rectangular cross section provided on the outer periphery of the inner heat insulating wall 121;
A first heat resistant fiber member 123 filled in a space between the inner heat insulating wall 121 and the outer heat insulating wall 122 to block the heat of the inner heat insulating wall 121 from being transmitted to the outer heat insulating wall 122; Wherein the heating device is a heating device for a quenching heating of a continuous steel plate annealing system. 3. The method of claim 2,
The insulation guide duct (120)
And a second heat resistant fiber member (124) provided at a lower end of the coil steel plate passing space (S) to prevent the coil steel plate (1) from coming into direct contact with the inner heat insulating wall (121) A quenching heating apparatus for a heat treatment plant. The method according to claim 2 or 3,
Wherein the coil steel plate passage space (S) is maintained in a vacuum state or is filled with a nitrogen atmosphere gas. The method according to claim 1,
Wherein the secondary induction heater (130) is installed movably in the forward and backward directions and can be separated from the heat insulating guide duct (120).

Images