KR101225262B1 - apparatus for preventing outer air inflow of heating furnace - Google Patents

Abstract

The present invention relates to an air inlet blocking device of a heating furnace, wherein gas injection nozzles 51 and 52 installed at the inlet and the outlet of the heating furnace 10 have an exhaust pipe 60 and an exhaust gas pipe 80 of the heating furnace 10. Is connected to, the suction fan 90 is installed in the exhaust gas pipe (80).
Therefore, the exhaust gas discharged from the heating furnace 10 is injected into the gas injection nozzles 51 and 52 to form the exhaust gas curtain C, thereby preventing heat loss and external air penetration into the heating furnace.
In particular, even if the flue gas forming the flue gas curtain is introduced into the furnace 10 according to the fluctuation of the internal pressure of the furnace 10, the oxygen concentration of the flue gas is almost similar to the atmosphere inside the furnace 10, so the slab oxidation is performed. The problem does not occur.

Description

Apparatus for preventing outer air inflow of heating furnace}

The present invention relates to an air inlet blocking device of a heating furnace, and more particularly, to an air inlet blocking device of a heating furnace capable of blocking the inflow of air through the inlet and the outlet of the heating furnace.

The hot rolling process, which is the basis of the rolling process, charges slabs manufactured by continuous casting into a heating furnace, reheats them to high temperature, cools them in a cooling facility through crude rolling, finishing rolling, etc., and produces them as final steel. will be.

The heating furnace is a device for heating a moving object (intermediate product), such as a slab, by itself, and heating the device, and is equipped with a plurality of working beams for moving after charging the heating object.

The walking beam moves the heating object from the inlet to the outlet of the heating furnace while repeating the up, forward, down, and backward movements by the hydraulic control.

In the moving process as described above, the heat of combustion of the burner is gradually heated to a heat source, thereby increasing the temperature to about 1200 ° C. which is a hot rolling temperature.

According to the present invention, although the air curtain is formed at the inlet and the outlet of the furnace to prevent the inflow of external air, the air forming the air curtain is sucked into the inside of the furnace according to the change in the internal pressure of the furnace. It is an object of the present invention to provide an air inlet blocking device of a heating furnace that can prevent generation of an oxidative scale on the surface of the furnace.

The present invention for achieving the above object,

Exhaust gas piping connected to the exhaust pipe of the furnace,

A gas injection nozzle connected to the exhaust gas pipe and installed close to the inlet and the outlet of the heating furnace, and receiving and injecting the exhaust gas of the heating furnace through the exhaust gas pipe to form an exhaust gas curtain;

Suction fan is installed in the exhaust gas pipe, the suction gas for sucking the exhaust gas of the exhaust pipe to blow high pressure to the gas injection nozzle

.

In addition, the controller is provided with a control unit for controlling the rotational speed of the suction fan by receiving the open and close signals of the doors installed at the inlet and the outlet of the heating furnace,

An oxygen sensor and an exhaust gas valve are installed at the rear end of the suction fan of the exhaust gas pipe,

COG pipe is connected to the front end of the oxygen sensor,

The COG pipe is provided with a COG valve,

The control unit controls the opening and closing of the exhaust gas valve and the COG valve in accordance with the oxygen concentration of the exhaust gas measured by the oxygen sensor.

In addition, the open and close signals of the door may be generated from a main computer controlling a heating furnace and a limit switch installed in the door.

The control unit may increase the rotational speed of the suction fan and open the exhaust gas valve when the door is opened.

The control unit may maintain the rotational speed of the suction fan at the minimum load state when the door is closed and close the exhaust gas valve.

The control unit may reduce the oxygen concentration of the exhaust gas by consuming oxygen in the exhaust gas by opening the COG valve and introducing COG into the exhaust gas pipe when the oxygen concentration of the exhaust gas measured by the oxygen sensor is greater than or equal to a set range. .

According to the present invention as described above,

By supplying the exhaust gas discharged from the heating furnace to the injection nozzles provided at the inlet and outlet of the heating furnace, by forming the exhaust gas curtain by high-pressure injection of the exhaust gas it is possible to block the outside air infiltration and internal heat release.

Therefore, the slab oxidation due to external air penetration and the deterioration of the slab due to the scale generation are prevented, and the heat loss is reduced to reduce the energy consumption of the furnace.

In particular, since the exhaust gas curtain is composed of the exhaust gas discharged from the furnace, there is an advantage that does not cause the slab oxidation problem even if some of the exhaust gas flows into the interior of the furnace according to the pressure fluctuations in the furnace.

In addition, when the oxygen concentration of the exhaust gas exceeds the allowable value, it is possible to lower the oxygen concentration by mixing coke oven gas (COG), so that even if the exhaust gas is introduced into the heating furnace, the slab oxidation problem does not occur.

1 is a block diagram of an external air blocking device of a heating furnace according to the present invention;
2 is a control flowchart of an external air shutoff device of a heating furnace according to the present invention.

Hereinafter, with reference to the accompanying drawings, the present invention will be described in detail.

The heating furnace 10 is configured in such a way that a housing for blocking the upper and lower portions of the transfer device 20 for transferring the slab S from the outside is enclosed.

The interior of the heating furnace 10 may be divided into a preheating zone 11, a heating table 12, a cracking table 13 according to the heating progress state of the slab (S), and the upper portion of the heating table 12 Burners 31, 32, and 33 are provided in the lower part and the crack zone 13, respectively, to supply heat generated during combustion of the fuel into the furnace 10.

On the other hand, the inlet and outlet of the heating furnace 10 to prevent heat loss and to prevent the inflow of external air, to reduce the energy cost and to suppress the generation of scale due to oxidation on the slab, each door 41, 42) is installed.

The present invention provides gas injection nozzles 51 and 52 at positions close to the inlet and the outlet of the heating furnace (for example, at the doors of the inlet and the outlet), and the gas injection nozzles 51 and 52 are connected to the heating furnace. (10) characterized in that connected to the exhaust pipe 60 through the exhaust gas pipe (80).

The exhaust pipe 60 is connected to the exhaust gas outlet of the front end (inlet side) of the furnace 10 and the stack 70 of the factory to discharge the high temperature exhaust gas generated by the combustion of the burner fuel in the furnace 10. It is a passage.

The exhaust gas pipe 80 is provided with a suction fan 90 for sucking the exhaust gas from the exhaust pipe 60 and forcibly blowing the gas to the gas injection nozzles 51 and 52.

The suction fan 90 is operated by the control unit 140 as a VVVF type.

The control unit 140 increases the number of rotations of the suction fan 90 when the doors 41 and 42 are opened, and draws a large amount of exhaust gas from the exhaust pipe 60 and blows them at high pressure to the gas injection nozzles 51 and 52. In addition, when the doors 41 and 42 are closed, the rotation speed of the suction fan 90 is reduced to minimize the exhaust gas suction and supply amount.

On the other hand, the exhaust gas pipe 80 is provided with an exhaust gas valve 100 for opening and closing the exhaust gas supply to the gas injection nozzles (51, 52).

In addition, an oxygen sensor 130 is installed at a previous part of the exhaust gas valve 100 of the exhaust gas pipe 80 (upstream of the exhaust gas flow), that is, at the rear end of the suction fan 90. The oxygen sensor 130 measures the amount of oxygen in the exhaust gas pipe 30 and delivers it to the controller 140.

Meanwhile, a COG pipe 110 (Cokes Oven Gas pipe) is connected to a portion before the oxygen sensor 130 of the exhaust gas pipe 80 (upstream of the exhaust gas flow), and the COG pipe 110 also opens and closes the COG pipe 110. The valve 120 is installed.

The exhaust gas valve 100 and the COG valve 120 is controlled by the control unit 140.

Meanwhile, the control unit 140 may receive the open and close signals of the doors 41 and 42 from the main computer controlling the heating furnace. In addition, the open and close signals of the doors 41 and 42 may also be transmitted from the limit switches 53 installed in the doors 41 and 42.

Now look at the effect of the present invention.

The doors 41 and 42 of the inlet and the outlet of the heating furnace are opened and closed as the heating object 10 enters and discharges a heating object, that is, an intermediate product such as the slab S.

The opening operation of the door is performed by a door open signal generated by the main computer of the heating process.

In addition, when the doors 41 and 42 are opened as described above, the limit switch 53 detects this and generates the detection signal.

The control unit 140 increases the rotation speed of the suction fan 90 and opens the exhaust gas valve 100 when the door open signal of the computer or the door open detection signal of the limit switch is transmitted.

Therefore, a large amount of hot exhaust gas flows from the exhaust pipe 60 through the exhaust gas pipe 80 and is supplied to the gas injection nozzles 51 and 52 and injected.

Therefore, the gas injection nozzle 51 forms a flue gas curtain (C; a name in contrast to a general air curtain) by high-pressure injection of hot exhaust gas.

Accordingly, the exhaust gas curtain basically blocks the inside and the outside of the heating furnace in the same way as a general air curtain, thereby preventing the air outside the heating furnace from penetrating into the heating furnace. In addition, the heat loss in the furnace is prevented from being released to the outside of the furnace.

On the other hand, since the exhaust gas curtain (C) was originally formed by the exhaust gas discharged from the heating furnace 10, the oxygen concentration does not have much difference with the conditions inside the heating furnace 10.

Therefore, when negative pressure is formed in the furnace by periodic pressure fluctuations inside the furnace, even if the flue gas forming the flue gas curtain is introduced into some of the furnaces, there is no problem of oxidizing the slab in the furnace. .

Therefore, since no scale is formed on the surface of the slab, the quality of the slab is improved.

On the other hand, in some cases the oxygen concentration of the exhaust gas may be higher than the appropriate value, the present invention can maintain the oxygen concentration of the exhaust gas curtain to an appropriate level by detecting this by using the oxygen sensor 130.

For example, the oxygen concentration of flue gas used to form flue gas curtains is maintained at 2-3%. This concentration is a safe concentration such that even if the exhaust gas is introduced into the furnace, hardly oxidizing the surface of the slab.

That is, the control unit 140 checks the oxygen concentration of the exhaust gas supplied to the gas injection nozzles 51 and 52 through the oxygen sensor 130 and if the oxygen contains more than the appropriate concentration range, the COG valve 120 Open).

Therefore, the COG flows into the exhaust gas pipe 80 from the COG pipe 110. The COG is used as a fuel gas to reduce the oxygen concentration of the exhaust gas supplied to the gas injection nozzles 51 and 52 by consuming oxygen while combining with oxygen in the exhaust gas to form a cool flame.

Therefore, only the exhaust gas having an oxygen concentration may be supplied to the gas injection nozzles 51 and 52, which may be introduced into the furnace, and when the doors 41 and 42 are opened and the exhaust gas curtain is formed, the pressure inside the furnace is formed. Even if a part of the flue gas constituting the flue gas curtain in accordance with the fluctuation does not oxidize the surface of the slab being heated, the scale is suppressed to improve the quality of the slab.

On the other hand, when the doors 41 and 42 are closed again in the open state, the control unit 140 recognizes the door closing signal of the main computer or the door closing detection signal of the limit switch 53, and thus the control unit 140. By reducing the rotational speed of the suction fan 90 to maintain the suction fan 90 to the minimum load state, by closing the exhaust gas valve 100 to block the exhaust gas supply to the gas injection nozzles (51, 52) Formation of the exhaust gas curtain C is stopped.

As described above, according to the present invention, whenever the door of the furnace is opened, the exhaust gas discharged from the furnace is supplied at a high pressure to a gas injection nozzle installed at the inlet and outlet of the furnace to form an exhaust gas curtain so that external air is introduced into the furnace. It prevents penetration and suppresses scale generation due to oxidation of the slab, and reduces heat loss by preventing the heat inside the furnace from escaping to the outside.

In addition, since the exhaust gas curtain is composed of the exhaust gas discharged from the furnace, even if the exhaust gas forming the exhaust gas curtain is introduced into the furnace according to the pressure fluctuations in the furnace, the slab does not oxidize the slab and thus does not cause any problem.

Or, even when the oxygen concentration of the flue gas itself is not suitable to allow the inflow into the furnace, COG is mixed to consume oxygen to form the flue gas curtain with only the flue gas having an allowable oxygen concentration, so that the flue gas is heated. The slab oxidation problem does not occur even if it is introduced into the furnace.

10: heating furnace 11: preheating table
12: heating zone 13: cracking zone
31,32,33: burner 41,42: door
51,52: gas injection nozzle 53: limit switch
60: exhaust pipe 70: stack
80: exhaust gas piping 90: suction fan
100: exhaust gas valve 110: COG piping
120: COG valve 130: oxygen sensor
140: control unit C: exhaust gas curtain

Claims (6)

delete Exhaust gas piping connected to the exhaust pipe of the furnace,
A gas injection nozzle connected to the exhaust gas pipe and installed close to the inlet and the outlet of the heating furnace, and receiving and injecting the exhaust gas of the heating furnace through the exhaust gas pipe to form an exhaust gas curtain;
Suction fan is installed in the exhaust gas pipe, the suction gas for sucking the exhaust gas of the exhaust pipe to blow high pressure to the gas injection nozzle
/ RTI >
A control unit is provided to control the rotational speed of the suction fan by receiving the open and close signals of the doors installed at the inlet and the outlet of the heating furnace.
An oxygen sensor and an exhaust gas valve are installed at the rear end of the suction fan of the exhaust gas pipe,
COG pipe is connected to the front end of the oxygen sensor,
The COG pipe is provided with a COG valve,
The control unit controls the opening and closing of the exhaust gas valve and the COG valve in accordance with the oxygen concentration of the exhaust gas measured by the oxygen sensor. The method according to claim 2,
The opening and closing signals of the door are generated from a main computer for controlling the heating furnace and a limit switch installed in the door. The method according to claim 2,
The control unit increases the rotational speed of the suction fan when the door is opened and the air inlet shutoff device, characterized in that for opening the exhaust gas valve. The method according to claim 2,
The control unit maintains the rotational speed of the suction fan at the minimum load state when the door is closed and closes the exhaust gas valve, characterized in that the exhaust gas valve. The method according to claim 2,
The control unit opens the COG valve when the oxygen concentration of the exhaust gas measured by the oxygen sensor is more than a set range to introduce COG into the exhaust gas pipe to consume oxygen in the exhaust gas, thereby reducing the oxygen concentration of the exhaust gas. Air inlet blocking device.

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