KR20190036240A - Continuation preheating device - Google Patents

Abstract

Disclosed is a continuous preheating apparatus for enabling continuous preheating of a coil. According to an aspect of the present invention, the continuous preheating apparatus comprises: a pair of heating units installed on one side and the other side of a base frame and generating heat; a discharge unit installed in the center of the upper end of the base frame, discharging combustion gas of the heating unit and dividing a space between the heating units into a first preheating space and a second preheating space; a movement unit movably installed in the base frame and configured to cover the first preheating space or the second preheating space in accordance with an operation; and a control unit for controlling the heating unit, the discharge unit and the movement unit.

Description

Continuation preheating device

The present invention relates to a continuous preheating apparatus, and more particularly, to a continuous preheating apparatus capable of continuously heating a martensitic stainless steel coil.

Generally, the entire martensitic stainless steel coil is used up to room temperature, for example, 40 DEG C in order to prevent plate breakage caused by coil cracks during cold rolling of the martensitic stainless steel coil.

In the preheating device for heating the coil to room temperature, one coil is housed in the preheating box, the coil is heated to a set temperature, and then the coil is taken out.

However, since only one coil can be housed in the existing preheating box, there is a problem in that a long time is required because the process of taking out the heated coil and storing another coil to be preheated is performed.

The continuous preheating apparatus according to the embodiment of the present invention preheats any one of the two coils disposed in the two preheating spaces and preheats the other coil when the preheated coil is drawn out, thereby continuously preheating the coils .

According to an aspect of the present invention, there is provided a heat exchanger comprising: a pair of heating units installed at one side and the other side of an upper end of a base frame to generate heat; A discharge unit installed at the upper center of the base frame for discharging the combustion gas of the heating unit and partitioning the pair of heating units into first and second preheating spaces; A moving unit movably installed in the base frame and adapted to surround the first preheating space or the second preheating space according to an operation; And a control unit for controlling the heating unit, the discharge unit, and the moving unit.

Each of the heating units may include a burner configured to receive the gas and air and burn the same; A heat supply tube connected to the burner to transfer the combustion gas to the discharge portion; And a partition wall accommodating the heat supply tube and installed in the base frame.

Further, the discharge unit may include an exhaust tube connected to the heat supply tube; A partition wall that houses the exhaust tube and is installed at the center of the base frame; And an exhaust device connected to the exhaust tube and forcibly discharging a combustion gas to be delivered to the exhaust tube.

The exhaust device may further include a first exhaust pipe connected to the exhaust pipe and a second exhaust pipe connected to the first exhaust pipe and having a cover having a predetermined storage space therein; A fan rotatably provided in the cover; A motor for generating power for driving the fan; And a power transmission unit for transmitting the rotational force of the motor to the fan.

The power transmission unit may include a drive pulley connected to the rotation shaft of the motor, a driven pulley installed in the fan to rotate together with the fan, and a belt connecting the drive pulley and the driven pulley.

The moving unit may include a moving cover provided to surround the first preheating space or the second preheating space; A wheel rotatably provided below the movable cover; And a driving unit connected to one end and the other end of the moving cover to generate a driving force for moving the moving cover.

The driving device may further include a pair of driving units provided on one side and the other side of the base frame, wherein each of the driving units includes: a driving motor for generating a driving force; A sprocket provided at both ends of a rotating shaft that receives the rotating force of the driving motor and rotates; And a connecting ring provided on both sides of the moving cover, wherein the sprocket and the connecting link of each driving unit can be connected through a chain.

The apparatus may further include a position sensor for sensing movement of the movable cover such that the movable cover moves to a specific position.

A guide rail for guiding the movement path of the wheel may be provided at an upper end of the base frame.

In addition, the coils are disposed in the first preheating space and the second preheating space, and the moving cover is moved to the second preheating space side after heating the coil in the first preheating space to have a predetermined temperature, The coil can be heated.

The upper end of the moving cover may be formed with a slot in the moving direction so as to avoid interference with the discharging unit when the moving cover moves.

In addition, the elongated hole may be provided with a blocking member to prevent the heat of the preheating space in the moving cover from being dissipated.

The blocking member is made of elastically deformable rubber material. The blocking member includes a center slit portion formed so as to be centered in the longitudinal direction of the elongated hole, and a unit slit portion that is cut at regular intervals on both sides along the center slit portion. .

The apparatus may further include a temperature sensing sensor for sensing a temperature of the first preheating space and the second preheating space.

The continuous preheating apparatus according to an embodiment of the present invention preheats any one of two coils disposed in two preheating spaces and then preheats the other coil when the preheated coil is drawn out, thereby continuously preheating the coils So that the preparation time for preheating the coil can be shortened.

In addition, any one of the coils may have a role of maintaining the temperature of the neighboring coils and a certain temperature due to the influence of the temperature generated at the time of preheating.

BRIEF DESCRIPTION OF THE DRAWINGS The present invention will be described in detail with reference to the following drawings, which illustrate preferred embodiments of the present invention, and thus the technical idea of the present invention should not be construed as being limited thereto.
1 is a perspective view schematically showing a continuous preheating apparatus according to an embodiment of the present invention.
2 is a partially cutaway perspective view showing a burner of a heating unit provided in a continuous preheating apparatus according to an embodiment of the present invention.
FIG. 3 is a view illustrating an exhaust unit of a discharge unit provided in the continuous preheating apparatus according to an embodiment of the present invention.
4 is a view illustrating a state in which a moving cover of a moving unit included in a continuous preheating apparatus according to an embodiment of the present invention is moved so as not to interfere with a discharging unit.
5 is a view illustrating a driving unit of a moving unit provided in the continuous preheating apparatus according to an embodiment of the present invention.
6 is a side view showing an operation state of the continuous preheating apparatus according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. The following embodiments are provided to fully convey the spirit of the present invention to a person having ordinary skill in the art to which the present invention belongs. The present invention is not limited to the embodiments shown herein but may be embodied in other forms. For the sake of clarity, the drawings are not drawn to scale, and the size of the elements may be slightly exaggerated to facilitate understanding.

FIG. 1 is a perspective view schematically showing a continuous preheating apparatus according to an embodiment of the present invention, FIG. 2 is a partial cutaway perspective view showing a burner of a heating unit provided in the continuous preheating apparatus, and FIG. 4 is a view showing a state in which the moving cover of the moving part provided in the continuous preheating device is moved so as not to interfere with the discharging part, and FIG. 5 is a view showing the moving FIG. 6 is a side view showing an operation state of the continuous preheating apparatus. FIG.

1 to 6, a continuous preheating apparatus 10 according to an aspect of the present invention includes a pair of heating units 210 and 220 installed at one side and the other side of an upper end of a base frame 100 to generate heat, A discharge unit 300 disposed at the center of the upper end of the base frame 100 to partition the space between the pair of heating units 210 and 220 into first and second preheating spaces 101 and 102, A moving part 400 installed movably in the frame 100 and adapted to surround the first preheating space 101 or the second preheating space 102 according to the operation and the heating part 210 and 220, And a control unit 500 for controlling the unit 300 and the moving unit 400.

The base frame 100 is provided in a plate shape having a predetermined width. A pedestal 104 for stably arranging the coil 4 is installed at the upper end of the base frame 100. The pedestal 104 is provided in the first preheating space 101 and the second preheating space 102, respectively, which will be described later. The base frame 100 is further provided with a position sensor 105 for sensing the movement of the movable cover 410 so that the movable cover 410 of the movable part 400 moving on the base frame 100 moves to a specific point, A guide rail 103 for guiding the movement path of the movable cover 410 is provided. The structure in which the movable cover 410 is moved to a specific point along the guide rail 103 will be described below again.

The pair of heating units 210 and 220 are installed on one side and the other side of the base frame 100, respectively. The pair of heating units 210 and 220 are divided into a first heating unit 210 installed at one side of the base frame 100 and a second heating unit 220 installed at the other side of the base frame 100.

The first and second heating units 210 and 220 have the same configuration. For example, the first and second heating units 210 and 220 include burners 211 and 221, heat supply tubes 217 and 227, and partition walls 218 and 228, respectively. The first heating unit 210 includes a first burner 211 configured to receive gas and air to be burned and a second burner 211 connected to the first burner 211 to transfer the combustion gas to the exhaust unit 300. [ And a first partition 218 accommodating the first heat supply tube 217 and the first heat supply tube 217 and installed at one side of the base frame 100. The second heating unit 220 is connected to the second burner 221 to transfer the combustion gas to the discharge unit 300. The second heating unit 220 includes a second burner 221, And a second partition wall 228 accommodating the tube 227 and the second heat supply tube 227 and installed on the other side of the base frame 100. That is, as described above, the first heating unit 210 and the second heating unit 220 have the same configuration, are controlled by the controller 500, and can be independently operated.

2, the first burner 211 of the first heating unit 210 is schematically shown. Since the first burner 211 and the second burner 221 have the same configuration as described above, the first burner 211 will be described below as a reference.

2, the first burner 211 includes a cylindrical body 212 having one open center, an air supply pipe 213 for supplying air into the body 212, A gas supply pipe 214 for supplying a combustion gas into the combustion chamber 212, and an ignition rod 215 for spark ignition. The air supply pipe 213 and the gas supply pipe 214 are installed in the body portion 212 to supply air and gas to the body portion 212. The ignition structure of the first burner 211 is generally used, and a detailed description thereof will be omitted.

Reference numeral 216 denotes a frame load for sensing heat generated by ignition of the first burner 211.

The first burner 211 and the second burner 221 are for heating the first preheating space 101 and the second preheating space 102 respectively and can be controlled by the controller 500 respectively. For example, when the first preheating space 101 or the second preheating space 102 is closed by the moving part 400 to be described later, only the burner for heating the closed preheating space is operated. The operating states of the heating units 210 and 200 according to the moving unit 400 will be described below again.

Referring again to FIGS. 1 to 6, the first heat supply tube 217 is provided in a zigzag fashion in the first partition 218. One end of the first heat supply tube 217 is connected to the first burner 211 and the other end of the first heat supply tube 217 is connected to the exhaust tube 310 of the discharge unit 300 to be described later. That is, the first heat supply tube 217 conveys the combustion gas resulting from the combustion of the first burner 211 to the discharge part 300, and raises the temperature of the first preheating space 101 through the heat generated at this time Role. Meanwhile, the exhaust tube 310 is connected to the first and second heat supply tubes 217 and 227, respectively.

The first partition 218 is installed on one side of the upper end of the base frame 100 to form a first preheating space 101 together with a partition wall 320 of a discharge unit 300 to be described later. That is, the coil 4 is accommodated in the space between the first partition 218 and the partition wall 320, and this space is formed as the first preheating space 101. The first partition 218 is provided to have a predetermined height so that the coil 4 is disposed in the first preheating space 101. The second partition 228 is disposed on the other side of the upper end of the base frame 100 to form the second preheating space 102 together with the partition walls 320.

The first partition 217 and the second partition 227 are provided with a temperature sensing sensor 230 for sensing the temperatures of the first preheating space 101 and the second preheating space 102, respectively. The temperature sensing sensor 230 senses the temperature in the first preheating space 101 or the second preheating space 102 to measure the preheating temperature of the coil 4, The control unit 500 determines whether the preheating operation is stopped or proceeded.

The exhaust unit 300 includes an exhaust tube 310 connected to the first and second heat supply tubes 217 and 227 and an exhaust tube 310 accommodating the exhaust tube 310, And an exhaust device 330 connected to the exhaust pipe 320 and the exhaust pipe 310 for forcibly discharging the combustion gas.

The exhaust tube 310 is provided so as to be zigzag bent in the partition wall 320. The exhaust tube 310 conveys the combustion gas delivered through the first and second heat supply tubes 217 and 227 and the heat generated by the heat tubes 210 and 220 together with the respective preheating spaces 101 , And 102).

The partition wall 320 is provided at the center of the upper end of the base frame 100 to partition the first preheating space 101 and the second preheating space 102 between the first partition wall 218 and the second partition wall 228 do.

3, the exhaust unit 330 includes a stack 331 connected to the exhaust pipe 310 and discharging combustion gas, a fan 333 installed in the stack 331, A motor 334 for driving the motor 333 and a power transmission unit 335 for transmitting the rotational force of the motor 334 to the fan 333. [

The stack 331 includes a first exhaust pipe 331a connected to the exhaust pipe 310 and a second exhaust pipe 331b formed with a cover 332 connected to the first exhaust pipe 331a and having a predetermined storage space therein. ). The first exhaust pipe 331a and the second exhaust pipe 331b may be integrally formed.

The fan 333 is rotatably installed in the cover 332. The fan 333 is installed to blow air in a direction in which the combustion gas is discharged to the outside through the stack 331 upon rotation according to the operation. By the operation of the fan 333, the combustion gas can be smoothly transported and forcedly discharged.

The power transmission unit 335 transmits the rotational force of the motor 334 to the fan 333 so that the fan 333 is rotated. The rotation transmitting portion 335 includes a driving pulley 336 coupled to the motor shaft of the motor 334 and rotated together with the driving pulley 336 and a driven pulley 337 mounted on the fan 333 to rotate together with the fan 333, And a belt 338 connecting the pulley 336 and the driven pulley 337. When the driving pulley 336 rotates according to the operation of the motor 334, the rotating force is transmitted to the driven pulley 337 through the belt 338 to rotate the fan 333. The discharging device 330 is controlled by the control unit 500.

The moving part 400 is provided to be movable in the base frame 100 and is adapted to surround the first preheating space 101 or the second preheating space 102 according to the operation. More specifically, the moving part 400 includes a moving cover 410 that is provided to enclose the first preheating space 101 or the second preheating space 102, And driving devices 440 and 450 connected to one end and the other end of the moving cover 410 to generate a driving force for moving the moving cover 410.

The moving cover 410 is provided to enclose either the first or second preheating space 101 or 102 so that the first preheating space 101 or the second preheating space 102 is not exposed to the outside. As shown, the moving cover 410 is formed to have a so-called 'P' shape having an upper surface and both side surfaces. When the moving cover 410 surrounds the first preheating space 101, the first partitioning wall 218 and the partitioning wall 320 are formed to be enclosed together with the first preheating space 101. In addition, when the movable cover 410 moves to cover the second preheating space 102, the second partition wall 228 and the partition wall 320 are enclosed together with the second preheating space 102. The moving cover 410 moves to one side and the other side of the base frame 100 with respect to the partitioning wall 320. The moving cover 410 is formed with a slot 411 in the moving direction so as to avoid interference with the discharging unit 300 when the moving cover 410 is moved. In other words, a slot 411 is formed so as to pass the stack 331 in order to avoid interference with the stack 331 protruded upward from the partition wall 320. Therefore, the movable cover 410 can be easily moved without being interfered with the stack 331.

The blocking member 420 is installed in the long hole 411 to block the heat of the preheating spaces 101 and 102 in the moving cover 410 from being radiated to the outside. The blocking member 420 is made of an elastically deformable rubber material. 4, the blocking member 420 includes a center slit portion 421 formed so as to be cut in the longitudinal direction of the long hole 411 and a center slit portion 421 formed at both sides of the center slit portion 421 at regular intervals An incised unit slit portion 422 is formed. The center slip part 421 serves to guide the stack 331 smoothly when the movable cover 410 moves. In addition, the unit slit portion 422 allows the blocking member 420 at the portion in contact with the stack 331 to be easily elastically deformed. That is, as the movable cover 410 moves, a part of the blocking member 420 which is in contact with the stack 331 is elastically deformed. The blocking member 420 elastically deformed by the stack 331 is elastically restored to its original state when the contact with the stack 331 is released and blocks the space between the preheating spaces 101 and 102 and the outside.

In order to easily move the moving cover 410, a wheel 430 is installed below the moving cover 410. The wheels 430 are rotatably mounted on both lower sides of the moving cover 410 so as to be movable on the base frame 100. At this time, the wheel 430 is provided to move stably along the guide rail 103 formed on the upper end of the base frame 100.

The driving units 440 and 450 include a pair of driving units 440 and 450 provided on one side and the other side of the base frame 100. The driving units 440 and 450 are connected to the moving cover 410 So as to operate the moving cover 410 according to the operation. The pair of driving units 440 and 450 may be divided into a first driving unit 440 provided on one side of the base frame 100 and a second driving unit 450 provided on the other side of the base frame 100. The first and second driving units 440 and 450 have the same configuration.

More specifically, the first drive unit 440 includes a first drive motor 441 for generating a drive force, and a second drive motor 442 provided at both ends of the first rotation shaft 445 that rotates upon receiving the rotational force of the first drive motor 441 And a first linking ring 447 provided on both sides of the first sprocket 446 and one end of the moving cover 410. The second driving unit 450 includes a second driving motor 451 for generating a driving force and a second driving motor 452 provided at both ends of the second rotating shaft 455 for receiving rotation of the second driving motor 451, And a second linking ring 457 provided on both sides of the other end of the moving cover 410 and the sprocket 446, respectively. That is, as described above, the first driving unit 440 and the second driving unit 450 have the same configuration, and are controlled by the controller 500 and can be operated independently of each other. In order to move the moving cover 410 according to the operation of the first driving unit 440 and the second driving unit 450, one end is connected to the first connecting ring 447 and the other end is connected to the first sprocket 446 and a second sprocket 456 to the second linking ring 457. The second linking ring 457 is connected to the second linking ring 457 via a chain 460.

In Fig. 5, a first drive unit 440 is schematically shown. Since the first drive unit 440 and the second drive unit 450 have the same configuration as described above, the first drive unit 440 will be described below.

5, the first drive unit 440 is coupled to the motor shaft of the first drive motor 441 to transmit the rotational force of the first drive motor 441 to the first sprocket 446 A first driven sprocket 443 and a first driven sprocket 442 provided on the first rotating shaft 445 so as to rotate together with the first rotating shaft 445 and a first driven sprocket 443 And a first chain 444 surrounding the first chain 444. Accordingly, as the first driving motor 441 operates, the rotational force is transmitted to the first rotational shaft 445 so that the first rotational shaft 445 rotates.

Reference numeral '106', which is not described, is a support portion provided on the base frame 100 to support the first rotation shaft 445 rotatably.

When the rotational force is transmitted to the first rotating shaft 445 through the first driving unit 440 as described above, the first sprocket 446 rotates to pull the chain 460. That is, since one end of the chain 460 is connected to the first linking ring 447 formed on the movable cover 410, the movable cover 410 is moved in one direction of the base frame 100 by the movement of the chain 460 To the first preheating space 101 side. The first drive unit 440 is controlled to be operated when the movable cover 410 is moved to the first preheating space 101. That is, the first drive unit 440 is controlled to be operated when the movable cover 410 is moved to the first preheating space 101. This is because the other end of the chain 460 is connected to the second linking ring 457 formed on the movable cover 410 and the second drive motor 451 of the second drive unit 450 The movable cover 410 is moved toward the second preheating space 102, which is the other side of the base frame 100, when the second sprocket 456 pulls the chain 460.

When the movable cover 410 is moved to the first preheating space 101 or the second preheating space 102, the movable cover 410 is moved to a specific position through the position detecting sensor 105 installed on the base frame 100 As shown in FIG. For example, the position sensor 105 may be provided at one side and near the center of the base frame 100, respectively. The position detection sensor 105 may be formed to face the first and second connection rings 447 and 457 formed on the moving cover 410. That is, the position sensor 105 provided at one side of the base frame 100 senses the movement of the movable cover 410 so that the second connection ring 457 is positioned at the opposite position, and transmits a signal to the controller 500 . That is, the specific position of the moving cover 410 is sensed through the detected signal, and the moving cover 410 can be positioned to surround the second preheating space 102. The position sensor 105 provided at the center of the base frame 100 senses the movement of the movable cover 410 to transmit the signal to the controller 500 so that the second connection ring 457 is opposed. That is, the movable cover 410 can be positioned to surround the first preheating space 101 through the detected signal.

As described above, the continuous preheater 10 according to one aspect of the present invention includes the first preheating space 101 and the second preheating space 102, and sequentially preheats each of the preheating spaces 101 and 102 The continuous preheating process can be rapidly performed.

More specifically, the coils 4 are disposed in the first preheating space 101 and the second preheating space 102, respectively. When the coil 4 is disposed in each of the preheating spaces 101 and 102, the movable cover 410 preheats the coil 4 positioned to surround the first preheating space 101 to a predetermined temperature. At this time, the moving cover 410 is moved to a specific position through the position detecting sensor 105. When it is detected that the moving cover 410 is located in the first preheating space 101, the first burner 211 And the temperature of the first preheating space 101 is raised by ignition. The temperature sensing sensor 230 provided in the first and second partitions 218 and 228 may be configured to operate only the warm sensing sensor 230 on the space side to be preheated, ) Is measured, and when the temperature rises to the set temperature, the preheating operation is stopped.

Then, the second drive unit 450 is operated to move the movable cover 410 to the second preheating space 102 side. When the movable cover 410 is positioned to surround the second preheating space 102, the second burner 221 is ignited to raise the temperature of the second preheating space 102. The preheated coil 4 in the first preheating space 101 together with the preheating operation in the second preheating space 102 is discharged to the outside through the lift 2 of the crane apparatus (see '1' Of course, another coil to be preheated is housed in the first preheating space 101 again.

That is, the coil 4 can be continuously preheated by repeating the above operations in sequence.

The combustion gas of each of the burners 211 and 221 is connected to the exhaust tube 310 of the exhaust unit 300 so that the exhaust gas is exhausted from the exhaust tube 310. [ 310 generate heat. That is, since the heat generated during the preheating of the second preheating space 102 after the preheating of the first preheating space 101 is continuously generated through the exhaust tube 310 located at the center, the heat of the neighboring coil 4 It is possible to perform a role of keeping a warming action.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. It will be understood that various modifications and changes may be made without departing from the scope of the appended claims.

10: Continuous preheating device 100: Base frame
105: position detecting sensor 210: first heating part
211: first burner 217: first heat supply tube
218: first partition 220: second heating part
221: second burner 227: second heat supply tube
228: second partition 230: temperature sensor
300: exhaust part 310: exhaust tube
320: partitioning partition wall 330: exhausting device
333: Fan 334: Motor
400: moving part 410: moving cover
420: blocking member 430: wheel
440: first driving unit 450: second driving unit
460: Chain 500: Control section

Claims (14)

A pair of heating units installed on one side and the other side of the upper end of the base frame to generate heat;
A discharge unit installed at the upper center of the base frame for discharging the combustion gas of the heating unit and partitioning the pair of heating units into first and second preheating spaces;
A moving unit movably installed in the base frame and adapted to surround the first preheating space or the second preheating space according to an operation; And
And a control unit for controlling the heating unit, the discharge unit, and the moving unit. The method according to claim 1,
Wherein each of the heating units comprises:
A burner configured to receive and burn the gas and air;
A heat supply tube connected to the burner to transfer the combustion gas to the discharge portion; And
And a partition wall accommodating the heat supply tube and installed in the base frame. 3. The method of claim 2,
The discharge portion
An exhaust tube connected to the heat supply tube;
A partition wall that houses the exhaust tube and is installed at the center of the base frame; And
And an exhaust device connected to the exhaust tube for forcibly discharging the combustion gas transferred to the exhaust tube. The method of claim 3,
In the exhaust device,
A first exhaust pipe communicating with the exhaust tube, and a second exhaust pipe connected to the first exhaust pipe and having a cover having a predetermined storage space therein;
A fan rotatably provided in the cover;
A motor for generating power for driving the fan; And
And a power transmission unit for transmitting the rotational force of the motor to the fan. 5. The method of claim 4,
Wherein the power transmission unit includes a drive pulley connected to a rotation shaft of the motor, a driven pulley installed in the fan to rotate together with the fan, and a belt connecting the drive pulley and the driven pulley. The method according to claim 1,
The moving unit includes:
A moving cover provided to surround the first preheating space or the second preheating space;
A wheel rotatably provided below the movable cover;
And a driving device connected to one end and the other end of the moving cover to generate a driving force for moving the moving cover. The method according to claim 6,
Wherein the driving device includes a pair of driving units so as to be provided on one side and the other side of the base frame,
Wherein each of the drive units includes:
A driving motor for generating a driving force;
A sprocket provided at both ends of a rotating shaft that receives the rotating force of the driving motor and rotates; And
And a connecting ring provided on both sides of the moving cover,
Wherein the sprocket and the linkage of each drive unit are connected through a chain. The method according to claim 6,
Further comprising a position sensing sensor for sensing movement of the moving cover such that the moving cover moves to a specific point. The method according to claim 6,
And a guide rail for guiding the movement path of the wheel is provided at an upper end of the base frame. The method according to claim 6,
Wherein the coil is disposed in the first preheating space and the second preheating space and the moving cover is moved to the second preheating space side after heating the coil in the first preheating space to have a predetermined temperature, Continuous preheating device for heating. The method according to claim 6,
Wherein a long hole is formed in the upper end of the moving cover in a moving direction so as to avoid interference with the discharging portion when the moving cover is moved. 12. The method of claim 11,
And wherein the elongated hole is provided with a blocking member to prevent heat of the preheating space in the moving cover from dissipating heat. 13. The method of claim 12,
Wherein the blocking member is made of a rubber material that is elastically deformable,
Wherein the blocking member has a center slit portion formed so as to be centered in the longitudinal direction of the elongated hole and a unit slit portion cut at regular intervals on both sides along the center slit portion. The method according to claim 1,
Further comprising a temperature sensing sensor for sensing a temperature of the first preheating space and the second preheating space.

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