KR20090104406A - Apparatus for discharging a billet of a heating furnace - Google Patents

Abstract

PURPOSE: A material extractor of a furnace is provided to prevent a skid mark on a heated material bottom surface by increase a temperature of a bottom surface of the heated material. CONSTITUTION: A material extractor of a furnace comprises an extraction roller(120), a drive unit(140) and a heating unit(160). A plurality of extraction rollers is arranged in the outlet site of a furnace(10). The furnace heats a heated material(50) inserted into the inside. The drive unit is connected to the extraction roller and reversely rotates the extraction roller. The heating unit is arranged in both sides of the extraction roller and settled in the extraction roller to prevent a skid mark on the bottom surface of the heated material. The heating unit heats the bottom surface of the heated material reciprocating.

Description

Apparatus for discharging a billet of a heating furnace}

The present invention relates to a skid mark formation preventing device for heating a billet, and more particularly, a material of a heating furnace installed in a heating furnace for heating a billet to prevent the formation of skid marks generated on the bottom of the billet. It relates to an extraction device.

In general, a heating furnace for heating a material such as a billet forms a preheating zone, a heating zone, and a cracking zone in the interior thereof, and after charging a billet or heating material therein, the heating materials are heated through a plurality of heating burners. do.

In addition, such a heating furnace includes a walking skid device having a fixed skid member and a movable skid member for moving the heating materials on the upper portion. The working beam apparatus gradually moves the heating material seated on the upper surface of the fixed skid member and the moving skid member from the furnace charging side to the extraction side, and is heated to the wire rollable temperature by the heating burner while the heating material is moved.

That is, the moving skid member of the working beam device gradually moves the heating material from the furnace charging side to the extraction side inside the furnace through a walking beam cycle process consisting of up-> forward-> down-> retreat.

In other words, the billet, that is, the heating material is seated on the upper surface of the fixed skid member and the moving skid member of the walking beam type, the contact portion (bottom) of the heating material in contact with the skid member is the upper surface of the heating material by heat transfer to the skid member And the temperature is lower than the side surface.

On the other hand, the billet heated to a high temperature, that is, the heating material is seated on the extraction roller before extraction to the outside of the heating furnace through the extraction roller has a wire rod work extraction waiting time.

By the way, the temperature of the heating material is usually extracted is 1000 ~ 1200 ℃, the extraction roller for extracting the heating material is usually managed to 100 ℃ or less in order to ensure wear resistance.

Therefore, when a high temperature heating material is seated on the extraction roller and has a waiting time, heat transfer occurs from the heating material heated to a high temperature to the extraction roller, and the bottom of the heating material which is in contact with the extraction roller is rapidly cooled and lower than the upper surface of the heating material. Temperature.

That is, a skid mark, which is lower in temperature than the upper and side surfaces of the heating material, is generated at the contact portion (bottom surface) of the heating material, which is a portion having a lower temperature than the non-contact area of the heating material, and thus a temperature deviation occurs on the heating material.

At this time, the temperature deviation of the skid mark portion, which is a non-contact portion and the contact portion of the heating material, is approximately 20 to 30 ° C., and the skid mark portion having such a large temperature deviation generates a difference in elongation of the rolled material in the rough rolling process of the wire rod rolling process. Let's do it.

Due to the difference in elongation of the rolled material, there is a problem that the precision of the size and discharge amount of the wire rolled material is lowered. In addition, there is a problem that the change of the rolling material loop-control between the rolling mill and the next rolling mill is serious, causing inlet guide breakage, which is a key component of wire rolling, and causing scratches on the surface of the rolled material due to breakage of the inlet guide.

In addition, the skid marks due to the temperature variation of the rolled material repeatedly increase the instantaneous load change of the rolling drive motor, which adversely affects the control characteristics of the drive motor, and also causes the deterioration of wire rolling workability and wire quality problems.

Therefore, conventionally, in order to reduce the temperature deviation in such a skid mark part, heating time was extended or heating furnace temperature was raised excessively. However, such an increase in the furnace temperature causes a problem of raising the production cost of the furnace operation due to excessive use of fuel.

In addition, overheating of the fuel causes the heating material to overheat, thereby increasing scale generation and lowering the error rate. In addition, the scale generated on the surface of the heating material is removed by the high-pressure water impact, there is a problem that the surface defect occurs in the material rolled by the scale not dropped off.

An object of the present invention is to provide a material extraction apparatus for a heating furnace that prevents the formation of skid marks generated by a low temperature extraction roller for extracting a heating material from the heating furnace to the outside.

The material extraction apparatus of the heating furnace according to the present invention is disposed on the exit side of the heating furnace for heating the heating material introduced into the inside, and rotates the heating material seated on the upper to the outside of the heating furnace or forward, reverse rotation A plurality of extraction rollers for reciprocating the heating material seated on the top repeatedly, a drive unit connected to the extraction roller for forward and reverse rotation of the extraction roller, and disposed on both sides of the extraction roller, the bottom surface of the heating material The heating unit includes a heating unit for heating the bottom surface of the heating material is reciprocating seated on the extraction roller to prevent the formation of the skid mark.

The drive unit is a drive source for generating a rotational force, the extraction roller is connected to the drive source and the extraction roller by the inertia force during the reciprocating motion of the heating material through the driving force generated from the drive source so that the heating material does not collide with the side wall of the heating furnace It may be provided with a drive member for forward and reverse rotation.

The heating unit is a heating member fixed to the outside of the heating furnace wall of the heating furnace, the heating member is mounted to the fixing member so as to pass through the heating furnace wall of the heating furnace and arranged to heat the bottom surface of the heating material on both sides of the extraction roller A burner may be provided.

The apparatus for extracting material of a heating furnace according to the present invention may further include a control unit provided with the driving source and connected to the motor to control the motor to generate a driving force for forward and reverse rotation of the extraction roller. .

The heating burner may be installed to be inclined to the heating wall to heat the bottom surface of the heating material.

According to the present invention, by heating the bottom of the heating material seated on the extraction roller reciprocating through the heating unit to increase the temperature of the bottom of the heating material to prevent the skid mark is formed on the bottom of the heating material. .

Hereinafter, a material extraction apparatus of a heating furnace according to the present invention will be described with reference to the drawings.

1 is a block diagram showing a material extraction apparatus of a heating furnace according to the present invention.

Referring to FIG. 1, the material extraction apparatus 100 of the heating furnace is disposed at the exit side of the heating furnace 10 through which the heating material 50 is discharged. That is, the material extraction apparatus 100 of the heating furnace is disposed on one side wall of the heating furnace 10, and the one side wall is connected to the heating furnace wall provided with the extraction port 12 through which the heating material 50 is discharged.

In addition, the material extraction apparatus 100 of the heating furnace includes an extraction roller 120, the drive unit 140, the heating unit 160, and the controller 180.

The extraction roller 120 is disposed such that one side thereof is adjacent to the inside of the heating furnace 10, that is, the end of the working beam device 20. That is, one side of the extraction roller 120 is installed to penetrate one side of the heating furnace (10). In addition, the extraction roller 120 is rotatably installed to move the heating material 50 seated on one side of the extraction roller 120.

Therefore, the heating material 50 seated on the extraction roller 120 by the working beam device 20 is moved on the upper surface of the extraction roller 120 in accordance with the forward and reverse rotation of the extraction roller 120. Through this, the heating material 50 is moved to the outside of the heating furnace or reciprocated while being seated on the extraction roller 120.

The driving unit 140 is connected to the extraction roller 120 to rotate the extraction roller 120 forward, reverse. That is, the driving unit 140 rotates the extraction roller 120 so that the heating material seated on the extraction roller 120 is moved.

Meanwhile, the driving unit 140 may include a driving source 142 and a driving member 144.

The driving source 142 is installed to be disposed outside the heating furnace 10 and generates a driving force for rotating the extraction roller 120. In addition, the driving source 142 is connected to the control unit 180 and is controlled by the control unit 180 to generate a driving force for forward and reverse rotation of the extraction roller 120.

In addition, the driving member 144 is connected to the drive source 142 and the extraction roller 120 to rotate the extraction roller 120 through the rotational force generated from the drive source 142.

The drive member 144 includes a drive sprocket 144a, a driven sprocket 144b, and a drive chain 144c. The driving sprocket 144a is connected to the driving source 142 to transmit the rotational force generated from the driving source 142.

Then, the driven sprocket 144b is fastened to the extraction roller 120 at the outside of the heating furnace 10, and the drive chain 144c moves in a caterpillar form to the driven sprocket 144b from the drive sprocket 144a, And it is fastened to transfer a driving force from the driven sprocket 144b to the driven sprocket 144b.

In the drawing, a case in which a plurality of drive chains 144c are provided to connect driven sprockets 144b coupled to extraction rollers 120 disposed adjacent to each other is provided. However, the driving chain 144c is not limited thereto. A driven sprocket 144b coupled to the extraction roller 120 may be connected.

Looking at the operation of the drive unit 140, a driving force is generated from the driving source 142, the generated driving force is transmitted to the driving sprocket 144a. When the drive sprocket 144a is rotated, the drive chain 144c installed in the drive sprocket 144a is moved in a caterpillar form, and the drive chain 144c rotates the driven sprocket 144b. Eventually, when the driven sprocket 144b is rotated, the extraction roller 120 also rotates with the driven sprocket 144b.

The driving force transmitted in this way reaches all the extraction rollers 120 through the driven sprocket 144b and the drive chain 144c.

The drawing illustrates the case where the driving member 144 is the driving sprocket 144a, the driven sprocket 144b, and the driving chain 144c. However, the present invention is not limited thereto, and the extraction roller is driven by the driving force generated from the driving source 142. Any configuration capable of rotating 120 may be employed.

In addition, the extraction roller 120 and the drive unit 140 is mounted on a mounting not shown, which is disposed outside the heating furnace 10 and the extraction roller 120 is rotatably mounted by the drive unit 140. Since the configuration in which the extraction roller 120 and the driving unit 140 are installed on the mounting table corresponds to a technique well known to those skilled in the art, a detailed description thereof will be omitted.

The heating unit 160 is provided with a plurality, heating the bottom surface of the heating material 50 is mounted on the extraction roller 120 to prevent the formation of the skid mark on the bottom surface of the heating material 50 to reciprocate.

In addition, the heating unit 160 may be connected to the controller 180. Detailed description of the heating unit 160 will be described below.

2 is a side view for explaining a heating unit according to the present invention.

1 and 2, the heating unit 160 includes a fixing member 162 and a heating burner 164.

The fixing member 162 is fixedly installed outside the heating wall of the heating furnace 10 to fix the heating burner 164. That is, the heating burner 164 is fixed to the fixing member 162 by mounting the flange 162a of the fixing member 162 to the fixing member 162 by the fixing bolt 162b.

The heating burner 164 is mounted to the fixing member 162 so as to penetrate the heating furnace wall of the heating furnace 10, and is arranged to heat the bottom surface of the heating material 50 on both sides of the extraction roller 120.

In addition, the heating burner 164 includes a gas inlet 164a and an oxygen inlet 164b through which gas and oxygen for generating a flame are introduced. In addition, the heating burner 164 has a mixing part in which the introduced oxygen and gas are mixed, although not shown therein.

That is, the gas inlet 164 is connected to the gas supply pipe 166a to which gas is supplied, and the oxygen inlet is connected to the oxygen supply pipe 166b to which oxygen is supplied.

The introduced gas and oxygen are mixed in the mixing section and then ignited by the ignition source. Then, the ignited flame is ejected through the end of the heating burner 164 disposed inside the heating furnace 10 to reach the bottom surface of the heating material 50.

On the other hand, the heating burner 164 is installed to have a predetermined slope on the heating furnace wall of the heating furnace 10, which is for the heating burner 164 to discharge the flame to the bottom of the heating material (50).

In addition, the end of the heating burner 164 is disposed to be adjacent to the extraction roller 120 to facilitate the discharge of the flame to the bottom of the heating material (50).

The controller 180 is connected to the driving unit 140 to control the forward and reverse rotation of the extraction roller 120. That is, the controller 180 is connected to the drive source 142 to control the drive source 142, thereby controlling the forward and reverse rotation of the extraction roller 120.

Detailed description of the controller 180 will be described below.

3 is an explanatory diagram for explaining the operation of the control unit according to the present invention.

1 and 3, the controller 180 controls the driving source 142 such that the extraction roller 120 rotates repeatedly in the forward and reverse directions only in the extraction standby mode of the heating material 50. To this end, the controller 180 includes a control disc 182, a detection rod 184, and first, second and third detection switches 186, 188 and 190.

That is, after the heating material 50 is seated on the upper portion of the extraction roller 120, when the signal of the extraction standby mode is applied to the control unit 180, the control disk 182 is rotated. Rotation of the control disc 182 continues until the third detection switch 190 is detected by the detection rod 184.

When the third detection switch 190 is detected by the detection rod 184, the controller 180 drives the driving source 142 to rotate the extraction roller 120 in the forward direction. Thereafter, the extraction roller 120 is rotated in the forward direction until the second detection switch 188 is detected by the detection rod 184.

When the second detection switch 188 is detected by the detection rod 184, the controller 180 controls the driving source 142 to rotate the extraction roller 120 in the reverse direction. Accordingly, the extraction roller 120 is rotated in the reverse direction.

The reverse rotation of the extraction roller 120 continues until the first detection switch 186 is detected by the detection rod 184.

When the first detection switch 186 is detected by the detection rod 184, the controller 180 controls the driving source 142 to rotate the extraction roller 120 in the forward direction again. Accordingly, the extraction roller 120 is rotated in the forward direction.

After that, the rotation disc 182 continues until the second detection switch 186 is detected by the detection rod 184, and the extraction roller 120 is rotated in the reverse direction.

The forward and reverse rotation of the extraction roller 120 is repeatedly performed in the above-described manner, and continues until the extraction signal of the heating material 50 from the heating furnace 10 is applied to the controller 180.

Accordingly, the heating material 50 seated on the extraction roller 120 is reciprocated by the extraction roller 120 in accordance with the forward and reverse rotation of the extraction roller 120.

In addition, the controller 180 controls the rotational speed of the extraction roller 120 to maintain the moving speed of the heating material 50 is 0.1 ~ 0.5m / s, which is 0.6 of the moving material 50 If the m / s or more because the inertia force caused by the movement of the heating material 50 may cause the risk that the heating material 50 collides with the wall surface of the heating furnace (10).

In addition, while the control unit 180 is connected to the heating unit 160 and controls the drive source 142 so that the extraction roller 120 is rotated repeatedly in the forward and reverse directions, by emitting a flame from the heating burner 164 to heat the material The bottom of 50 is heated.

With reference to the drawings will be described the operation of the material extraction apparatus of the heating furnace according to the present invention.

Figure 4 is an operation for explaining the operation of the material extraction apparatus of the heating furnace according to the present invention, Figure 5 is an operation diagram for explaining the operation of the material extraction apparatus of the heating furnace according to the present invention.

In other words, Figure 4 is an operation diagram showing a case in which the heating material 50 seated on the upper surface of the extraction roller 120 is moved in one direction, Figure 5 is a heating material seated on the upper surface of the extraction roller 120 It is an operation diagram showing a case in which 50 is moved in the other direction.

4 and 5, first, the heating material 50 is seated on the extraction roller 120 by the working beam device 20 installed inside the heating furnace 10. After the heating material 50 is seated on the extraction roller 120, when the extraction standby mode signal is applied to the controller 180, the controller 180 controls the driving source 142 to rotate the extraction roller 120 forward. . At the same time, the controller 180 allows the heating unit 160 to heat the bottom surface of the heating material 50.

That is, the controller 180 drives the driving source 142 to rotate the extraction roller 120 forward when a signal of the extraction standby mode is applied. When the driving source 142 is driven, the driving force is sequentially transmitted to the driving member 144 connected to the driving source 142, that is, the driving sprocket 144a, the driving chain 144c, and the driven sprocket 144b, and thus the extraction roller. 120 rotates in the forward direction.

When the extraction roller 120 rotates in the forward direction, the heating material 50 seated on the upper surface of the extraction roller 120 is moved in one direction by the extraction roller 120. At this time, the heating unit 160 heats the bottom of the heating material (50).

The forward rotation of the extraction roller 120 continues until the second detection switch 188 is detected by the detection rod 184 shown in FIG. Then, when the second detection switch 188 is detected by the detection rod 184, the controller 180 controls the driving source 142 to rotate the extraction roller 120 in the reverse direction.

In other words, the controller 180 controls the driving source 142 so that the driving source 142 generates the driving force in the reverse direction, and the driving member 144 connected to the driving source 142, that is, the driving sprocket 144a and the driving chain 144c. The driving force is sequentially transmitted to the driven sprocket 144b, and the driving sprocket 144a, the drive chain 144c, and the driven sprocket 144b are driven in the reverse direction of the driving direction to rotate the extraction roller 120 in the forward direction. do. Accordingly, the extraction roller 120 is rotated in the reverse direction.

Accordingly, the heating material 50 seated on the upper surface of the extraction roller 120 is moved in the other direction by the extraction roller 120. That is, the heating material 50 is moved in the direction opposite to the direction in which the extraction roller 120 is rotated in the forward direction. In addition, while the heating material 50 is moved in the other direction, the heating unit 160 continues to heat the bottom of the heating material (50).

On the other hand, the movement of the heating material 50 in the other direction, that is, reverse rotation of the extraction roller 120 continues until the first detection switch 186 is detected by the detection rod 184 shown in FIG. When the first detection switch 186 is detected by the detection rod 184, the controller 180 controls the driving source 142 to rotate the extraction roller 120 in the forward direction.

The extraction roller 120 rotates in the forward direction until the second detection switch 188 is detected by the detection rod 184, whereby the heating material 50 is moved in one direction.

This operation is continued until the extraction signal of the heating material 50 from the heating furnace 10 to the controller 180 is applied.

That is, the controller 180 controls the driving unit 120 as described above to reciprocate the heating material 50, and at the same time, heat the bottom surface of the heating material 50 through the heating unit 160. The formation of the skid mark on the bottom of 50 can be reduced.

In addition, when the moving speed of the heating material 50 is 0.6m / s or more may cause a risk that the heating material 50 collides with the wall surface of the heating furnace 10 by the inertial force due to the movement of the heating material 50. Since the controller 180 controls the drive source 142 to adjust the rotational speed of the extraction roller 120 so that the moving speed of the heating material 50 maintains the speed of 0.1 ~ 0.5m / s.

As described above, the material extraction apparatus 100 of the heating furnace controls the drive unit 140 to reciprocate the heating material 50 seated on the upper surface of the extraction roller 120 and at the same time through the heating unit 160. By heating the bottom of the heating material 50 evenly, it is possible to prevent the skid marks from being formed on the bottom of the heating material 50.

Through this, it is possible to prevent the occurrence of the difference in elongation of the rolled material in the rough rolling process of the wire rod rolling process later, and also to prevent the precision of the corgi and the discharge amount of the wire rolled material due to the difference in the elongation of the rolled material. .

In addition, the inlet guide can be prevented from being damaged to prevent the occurrence of scratches on the surface of the rolled material.

As a result, by preventing the formation of skid marks, the wire rolling workability can be improved, and the wire quality can be improved.

1 is a block diagram showing a material extraction apparatus of a heating furnace according to the present invention.

2 is a side view for explaining a heating unit according to the present invention.

3 is an explanatory diagram for explaining the operation of the control unit according to the present invention.

Figure 4 is an operation for explaining the operation of the material extraction apparatus of the heating furnace according to the present invention.

5 is an operation diagram for explaining the operation of the material extraction apparatus of the heating furnace according to the present invention.

<Explanation of symbols for the main parts of the drawings>

100: material extraction apparatus of the heating furnace

120: extraction roller

140: drive unit

160: heating unit

180: control unit

Claims (5)

It is disposed on the exit side of the heating furnace for heating the heating material introduced into the inside, and rotates the heating material seated on the upper to the outside of the heating furnace or reciprocating the heating material seated on the upper by repeating forward and reverse rotation Multiple extraction rollers; And A driving unit connected to the extraction roller to rotate the extraction roller forward and reverse; A heating unit disposed at both sides of the extraction roller to heat the bottom surface of the heating material reciprocated while being mounted on the extraction roller to prevent the formation of skid marks on the bottom surface of the heating material; Material extraction apparatus of the heating furnace comprising a. The method of claim 1, wherein the drive unit A drive source for generating a rotational force; A driving member connected to the driving source and the extraction roller to rotate the extraction roller forward and reverse so that the heating material does not collide with the side wall of the heating furnace by inertial force during the reciprocating motion of the heating material through the driving force generated from the driving source; Material extraction apparatus of the heating furnace characterized in that it comprises a. The method of claim 1, wherein the heating unit A fixing member fixedly installed outside the heating furnace wall of the heating furnace; And A heating burner mounted on the fixing member so as to penetrate the heating furnace wall of the heating furnace and arranged to heat the bottom surface of the heating material on both sides of the extraction roller; Material extraction apparatus of the heating furnace characterized in that it comprises a. The method of claim 2, wherein the drive source is provided by a motor, And a control unit connected to the motor to control the motor to generate a driving force for forward and reverse rotation of the extraction roller. The method of claim 3, wherein the heating burner The material extraction apparatus of the heating furnace, characterized in that the bottom surface of the heating material is installed to be inclined to the heating wall to the heating.

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