KR20120114071A - Device for burning gas of annealing furnace - Google Patents

Abstract

PURPOSE: A waste gas combustion device of an annealing furnace is provided to minimize the time and effort for maintenance by automatically control detection and hydrogen ignition and to reduce the temperature deviation in an annealing furnace by maintaining flame at the exit side of the annealing furnace. CONSTITUTION: A waste gas combustion device of an annealing furnace comprises a mixing pipe(10), a wind shield(20), a hydrogen supply pipe(30), an ignition unit, and a flame detection sensor(50). The mixing pipe is arranged in the transverse direction in an annealing furnace and has a plurality of hole for spouting hydrogen in the longitudinal direction. The wind shield is installed lengthwise along the circumference of the mixing pipe and opens at the top to protect flame. The hydrogen supply pipe is connected to at least one end of the mixing pipe to supply hydrogen. The ignition unit is installed at one end of the wind shield to ignite hydrogen. The flame detection sensor is installed at one side of the wind shield to detect combustion flame.

Description

Waste gas combustion device of annealing furnace {DEVICE FOR BURNING GAS OF ANNEALING FURNACE}

The present invention relates to an annealing furnace using hydrogen gas as an atmospheric gas. More specifically, the present invention relates to a waste gas combustion apparatus of an annealing furnace for burning a small number contained in the waste gas when the waste gas is discharged.

In general, the annealing furnace for performing heat treatment of the steel sheet using the radiant heat is to heat the steel to recrystallize, grow the structure to remove the internal stress, and to make the structure with appropriate toughness.

The high temperature annealing furnace using hydrogen gas as an atmosphere gas, for example, heats a silicon steel sheet at a high temperature of about 850 ° C. in a hydrogen atmosphere.

The waste gas used as the atmosphere gas in the annealing furnace contains hydrogen, so when the waste gas is discharged as it is, the hydrogen escapes to the outside and causes a large explosion accident. Accordingly, when the waste gas is discharged from the annealing furnace, a combustion device is provided to prevent the hydrogen contained in the waste gas from being discharged to the outside, and the hydrogen is combusted and discharged.

Conventionally, it has a structure of burning hydrogen contained in waste gas by supplying combustion hydrogen to a combustion device connected to an annealing furnace and continuously igniting the combustion device. The hydrogen contained in the waste gas is burned through the combustion device in which the waste gas is ignited.

By the way, in the conventional structure described above, when the supply of hydrogen to the combustion device is cut off, the yanser device does not maintain the ignition state and the flame is turned off.

As such, when the flame of the combustion device is turned off, the hydrogen contained in the waste gas is not combusted and emitted to the outside.

Therefore, in the related art, the operator frequently checks whether the combustion apparatus maintains flames, and re-ignites the combustion apparatus in a non-ignition state due to the hydrogen cutoff, thus requiring a lot of time and effort for maintenance.

This provides a waste gas combustion device of the annealing furnace that can continuously maintain the flame for hydrogen combustion through the ignition check.

In addition, there is provided a waste gas combustion apparatus of an annealing furnace that is capable of reducing the occurrence of temperature deviation at the exit side of the annealing furnace.

To this end, the apparatus is provided with a mixing tube having a plurality of holes arranged in the width direction in the annealing furnace and ejecting hydrogen along the longitudinal direction, and installed in the longitudinal direction along the periphery of the mixing tube, the upper portion of which is open to protect the flame. A windshield, a hydrogen supply tube connected to at least one end of the mixing tube for supplying hydrogen, an igniter installed at one end of the windscreen to ignite hydrogen, and a flame detection sensor installed at one side of the windscreen to detect combustion flames It may include.

The apparatus may further include a controller connected to the flame detection sensor to calculate whether a flame is generated and to re-ignite hydrogen by operating the igniter in a non-ignition state.

The mixing tube may have a structure in which spiral protrusions are formed along an inner circumferential surface thereof.

The mixing pipe may have a structure in which hydrogen supply pipes are installed at both ends and a separation plate is installed at a central portion in a longitudinal direction to block the inside.

The apparatus may further include a pressure reducing pipe connected to the hydrogen supply pipe and formed in the mixing pipe and having a plurality of holes spaced apart from each other on the surface thereof to lower the supply pressure of hydrogen supplied from the hydrogen supply pipe to the mixing pipe. have.

The flame detection sensor may be an optical sensor for detecting the illuminance of the flame.

According to the apparatus as described above, by detecting the flame and maintaining the ignition state, it is possible to fundamentally prevent the hydrogen in the waste gas from being released to the atmosphere.

In addition, flame detection and hydrogen ignition are automatically controlled, minimizing time and effort for maintenance.

In addition, by maintaining the flame on the exit side of the annealing furnace, it is possible to reduce the temperature variation inside the annealing furnace and to improve the quality of the product.

1 is a schematic diagram showing a waste gas combustion device installed in an annealing furnace according to the present embodiment.
2 is a schematic cross-sectional view of the waste gas combustion apparatus of the annealing furnace according to the present embodiment.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings so that those skilled in the art can easily carry out the present invention. As can be easily understood by those skilled in the art, the following embodiments may be modified in various forms without departing from the spirit and scope of the present invention and the embodiments described herein. It is not limited to the example.

The drawings are schematic and illustrate that they are not drawn to scale. The relative dimensions and ratios of the parts in the figures have been exaggerated or reduced in size for clarity and convenience in the figures and any dimensions are merely exemplary and not limiting.

1 and 2 show the waste gas combustion apparatus of the annealing furnace according to the present embodiment.

As shown, the apparatus is provided along the periphery of the mixing tube 10 and the mixing tube 10, which is installed on one side of the annealing furnace 100 and has a hole 12 in which hydrogen is ejected on one side. It is installed in the longitudinal direction and the upper part is opened to protect the flame 20, the hydrogen supply pipe 30 for supplying hydrogen connected to the mixing pipe 10, the windshield 20 is installed at one end of the hydrogen An igniter 40 for ignition, and installed on one side of the windshield 20 includes a flame detection sensor 50 for detecting a combustion flame.

In addition, the apparatus further includes a controller 60 connected to the flame detection sensor 50 to calculate whether a flame is generated and to re-ignite hydrogen by operating the igniter 40 in a non-ignition state.

The mixing tube 10 is located at the exit side of the annealing furnace 100, and is disposed in the width direction of the annealing furnace 100 to extend for a long time. The mixing tube 10 is a hollow tube structure, a plurality of holes 12 are formed at intervals along the longitudinal direction at the top. The hydrogen supplied to the mixing tube 10 is ejected to the outside through the hole 12.

In this embodiment, both ends of the mixing tube 10 are respectively provided with hydrogen supply pipes 30, so that hydrogen is supplied through both ends of the mixing tube 10. In addition, a separation plate 14 for blocking the inside of the mixing tube 10 is installed at the central portion in the longitudinal direction of the mixing tube 10. The separating plate 14 maintains a constant sourcing pressure by balancing the hydrogen pressure inside the mixing pipe 10 even when the hydrogen supply pressure supplied from the hydrogen supply pipe 30 on the left and right sides of the mixing pipe 10 is different. do.

As shown in FIG. 1, the windshield 20 is installed along the upper end of the mixing tube 10 to surround the hole 12 formed at the upper end of the mixing tube 10. The windshield 20 is substantially open at the top to generate a combustion flame therein to release the flame to the top of the annealing furnace (100).

Thus, the hydrogen contained in the waste gas of the annealing furnace 100 is burned by the flame generated through the apparatus as described above. Here, since the apparatus is disposed at the exit side of the annealing furnace 100, the hydrogen gas of the waste gas is burned and the exit side of the annealing furnace 100 is heated by the flame to reduce the temperature variation in the annealing furnace 100.

In the present embodiment, both ends of the windscreen 20 are blocked, and an igniter 40 is installed at one end, and a flame detection sensor 50 for detecting a flame generated inside the windscreen 20 at the opposite end. Is installed.

The igniter 40 generates spark by receiving power and ignites hydrogen as a fuel. In this embodiment, the igniter 40 is configured to operate by receiving power in response to a signal from the controller 60.

In addition, in the present embodiment, the flame detection sensor 50 is made of an optical sensor for detecting the illuminance of the flame, and is not particularly limited if it is a structure capable of detecting the flame.

The controller 60 is provided with a calculation circuit for calculating the flame by receiving the detection signal of the flame detection sensor 50 therein, and has a structure for controlling the igniter 40 according to the flame.

On the other hand, the apparatus has a structure capable of lowering the supply pressure of hydrogen supplied from the hydrogen supply pipe 30 to the mixing pipe 10. To this end, the apparatus further includes a pressure reducing tube 32 connected to the hydrogen supply pipe 30 and positioned inside the mixing tube 10 and having a plurality of holes 34 formed on the surface thereof at intervals.

The pressure reducing tube 32 reduces the discharge pressure of the hydrogen discharged from the hydrogen supply pipe 30 by discharging hydrogen through a plurality of holes 34 formed in the surface. Hydrogen supplied from the hydrogen supply pipe 30 may damage the inside of the mixing tube 10 when directly ejected into the mixing tube 10 at a high pressure, and is ejected through the hole 12 of the mixing tube 10. The pressure may increase, making ignition difficult.

In addition, the apparatus primarily has a structure in which the mixing tube 10 has a spiral protrusion 16 formed along an inner circumferential surface in order to further reduce the pressure of hydrogen whose pressure is reduced through the pressure reducing tube 32. have. The spiral protrusion 16 is continuously formed along the longitudinal direction of the mixing tube 10. The protruding length of the protrusion 16 is not particularly limited.

Accordingly, the hydrogen supplied under reduced pressure through the decompression tube 32 passes helically along the protrusion 16 to the mixing tube 10, and the pressure is reduced again.

Hydrogen is heated by the mixing tube 10 while passing through the spiral protrusion 16 formed in the mixing tube 10 to increase the temperature. Therefore, the hydrogen supplied to the mixing tube 10 has a lower pressure and a higher temperature, thereby reducing the pressure and temperature variation of the hydrogen in the waste gas inside the annealing furnace 100.

Hereinafter, the operation of the apparatus will be described.

Hydrogen supplied to the hydrogen supply pipe 30 is supplied to the mixing pipe 10 via a pressure reducing pipe 32 installed at the tip of the hydrogen supply pipe 30. Hydrogen supplied to the decompression tube 32 is introduced into the mixing tube 10 through the hole 34 formed in the decompression tube 32. In this process, the high pressure hydrogen is sufficiently low in the discharge pressure. Hydrogen introduced into the mixing tube 10 through the hole 34 of the pressure reducing tube 32 is moved along the longitudinal direction of the mixing tube 10, and at this time, spirals along the protrusion 16 installed in the mixing tube 10. Is moved to form.

The hydrogen introduced into the excess mixing tube 10 has a lower pressure and a higher temperature through heat exchange with the mixing tube 10. Therefore, the temperature and pressure deviation between the hydrogen discharged from the mixing tube 10 and the hydrogen contained in the waste gas is reduced.

Hydrogen introduced into the mixing tube 10 is ejected upward through the hole 12 formed in the mixing tube 10. And it is ignited and burned in the windscreen 20 installed in the upper part of the mixing tube 10. The hydrogen is ignited through the igniter 40 installed in the windshield 20. Hydrogen ejected through the hole 12 of the mixing tube 10 is burned by ignition by the spark generated from the igniter 40 and its flame is introduced into the annealing furnace 100 through the open upper portion of the windshield 20. Squirt.

Thus, by forming a flame at the exit side of the annealing, it is possible to burn the hydrogen contained in the waste gas of the annealing discharged to the atmosphere.

On the other hand, the flame formed in the windshield 20 is continuously detected by the flame detection sensor 50. The flame detection sensor 50 applies the detected signal to the controller 60, and the controller 60 calculates the signal of the flame detection sensor 50 to check whether the flame continues.

In this state, if the flame in the windshield 20 is not detected, the flame detection sensor 50 sends this signal to the controller 60, and the controller 60 restarts the igniter 40. Thus, the igniter 40 ignites the hydrogen again to generate a combustion flame, thereby maintaining the flame.

While the illustrative embodiments of the present invention have been shown and described, various modifications and alternative embodiments may be made by those skilled in the art. Such variations and other embodiments will be considered and included in the appended claims, all without departing from the true spirit and scope of the invention.

10: mixing tube 12: hole
14: separating plate 16: protrusion
20: windshield 30: hydrogen supply pipe
32: pressure reducing tube 34: hole
40: igniter 50: flame detection sensor
60: controller

Claims (5)

A mixing tube disposed in the annealing furnace in the width direction and having a plurality of holes through which hydrogen is ejected along the longitudinal direction;
Windshield is installed in the longitudinal direction along the periphery of the mixing tube and the upper portion is open to protect the flame,
A hydrogen supply pipe connected to at least one end of the mixing pipe to supply hydrogen;
An igniter installed at one end of the windshield to ignite hydrogen;
Flame detection sensor is installed on one side of the windshield for detecting the combustion flame
Waste gas combustion apparatus of the annealing furnace comprising a. The method of claim 1,
And a controller connected to the flame detection sensor to calculate whether a flame is generated and to re-ignite hydrogen by operating the igniter in a non-ignition state. The method according to claim 1 or 2,
And a pressure reducing pipe connected to the hydrogen supply pipe and located inside the mixing pipe and having a plurality of holes formed on the surface thereof to lower the supply pressure of hydrogen. The method of claim 3, wherein
The mixing pipe is a waste gas combustion device of the annealing furnace formed with a spiral projection along the inner circumferential surface. The method of claim 4, wherein
The mixing pipe is a waste gas combustion device of the annealing furnace is installed hydrogen supply pipe at both ends and the separation plate is installed at the central portion in the longitudinal direction to block the inside.

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