KR101516625B1 - Gas handling device for recycling tower - Google Patents

Abstract

The present invention relates to a gas processing apparatus for a regeneration tower, comprising: a supply pipe connected to a regeneration tower for supplying a supply gas; an exhaust pipe connected to the regeneration column for discharging exhaust gas at a flow rate equal to the flow rate of the supply gas supplied from the supply pipe; A gas processing unit connected to the exhaust pipe and processing the exhaust gas to extract sulfur oxides, a storage pipe connected to the gas treating unit to discharge the sulfur oxide, and a storage unit connected to the storage pipe and storing sulfur oxides, , And the harmful gas discharged from the activated carbon can be recycled.

Description

[0001] GAS HANDLING DEVICE FOR RECYCLING TOWER [0002]

TECHNICAL FIELD The present invention relates to a gas treatment apparatus for a regeneration tower, and more particularly, to a regeneration tower gas treatment apparatus capable of stably recovering sulfur oxides discharged from activated carbon.

Typical steelmaking consists of a steelmaking process to produce molten iron, a steelmaking process to remove impurities from molten iron, a casting process to solidify the liquid iron, and a rolling process to make iron steel or wire.

The sintering process can be carried out by a blast furnace. The sintering process is carried out by charging the coke and sintered raw materials, which have been dried in the coke oven, into a sintering furnace, thereby producing sintered ores.

Exhaust gas discharged from the coke oven passes through an exhaust gas treatment device for sintering machine using activated carbon as an adsorbent to remove foreign substances such as SOx and NOx, and the activated carbon adsorbing the foreign substances is heated while passing through the regenerator, and then recycled.

BACKGROUND ART [0002] The background art of the present invention is disclosed in Korean Patent Laid-Open Publication No. 2011-0022306 (published on Mar. 07, 2011, entitled "Method for regeneration using flue gas in sintering process").

An object of the present invention is to provide a regeneration tower gas treatment apparatus capable of stably recovering sulfur oxides while removing foreign substances discharged from activated carbon.

A gas processing apparatus for a regeneration tower according to the present invention includes: a supply tube connected to a regeneration tower to supply a supply gas; A discharge pipe connected to the regeneration tower for discharging exhaust gas at a flow rate equal to a flow rate of the feed gas supplied from the supply pipe; A gas treatment unit connected to the discharge pipe and treating the exhaust gas to extract sulfur oxides; A storage tube connected to the gas processing unit to discharge sulfur oxides; And a storage unit connected to the storage tube and storing sulfur oxides.

The gas processing unit includes: an inlet connected to the exhaust pipe to process the exhaust gas; An outlet connected to the storage tube to discharge sulfur oxides; And a foreign matter removing part connected to the inlet part and the lower part of the outlet part and discharging the foreign substances contained in the exhaust gas.

Wherein the inlet portion includes: an inlet pipe connected to an upper end portion of the discharge pipe portion and connected to the lower end portion of the foreign matter removing portion; And an inlet nozzle installed in the inlet pipe and injecting treated water into the outlet gas flowing into the inlet pipe.

Wherein the outlet portion includes: an outlet pipe connected to an upper end portion of the storage tube portion and connected to the lower end portion of the foreign matter removing portion; And an outlet nozzle installed in the outlet pipe and spraying the treated water to the sulfur oxide discharged from the outlet pipe.

The foreign matter removing unit may include: a water reservoir connected to the inlet and the outlet; A water supply pipe connected to the water storage tank to supply water; And a drain pipe connected to the water storage tank for discharging water.

The foreign material removing unit may further include: an agitator mounted on the water storage tank and stirring the stored water to prevent foreign matter from being precipitated.

In the gas treatment apparatus for a regeneration tower according to the present invention, since the exhaust gas is discharged from the regeneration tower in correspondence with the supply amount of the supply gas supplied to the regeneration tower, the inside of the regeneration tower is stabilized.

The gas treating apparatus for a regeneration tower according to the present invention has the effect of extracting sulfur oxides from the gas treating section and recycling them.

The gas treatment apparatus for a regeneration tower according to the present invention has an effect that the gas treatment section cools sulfur oxides to improve the storage stability of the extracted sulfur oxides.

In the gas treatment apparatus for a regeneration tower according to the present invention, the foreign matter removing unit continuously discharges foreign matter to the outside, thereby preventing sedimentation of foreign matter.

1 is a view schematically showing a gas processing apparatus for a regeneration tower according to an embodiment of the present invention.
2 is a view schematically showing a gas processing unit in a gas processing apparatus for a regeneration tower according to an embodiment of the present invention.

Hereinafter, an embodiment of a gas treatment apparatus for a regeneration tower according to the present invention will be described with reference to the accompanying drawings. In this process, the thicknesses of the lines and the sizes of the components shown in the drawings may be exaggerated for clarity and convenience of explanation. In addition, the terms described below are terms defined in consideration of the functions of the present invention, which may vary depending on the intention or custom of the user, the operator. Therefore, definitions of these terms should be made based on the contents throughout this specification.

FIG. 1 is a view schematically showing a gas processing apparatus for a regeneration tower according to an embodiment of the present invention, and FIG. 2 is a view schematically showing a gas processing section in a regeneration gas processing apparatus according to an embodiment of the present invention.

Referring to FIG. 1, a gas processing apparatus 1 for a regeneration tower according to an embodiment of the present invention includes a supply tube 10, a discharge tube 20, a gas processing unit 30, a storage tube 40, , And a storage unit (50).

The activated carbon passes through the adsorbing portion through which the coke oven gas passes and adsorbs foreign substances such as SOx and NOx contained in the coke oven gas and the activated carbon discharged from the adsorbing portion is stored in the input storage 130 and then supplied to the regeneration tower 110 do.

The regeneration tower 110 includes a heating unit 112 for heating the activated carbon while passing hot air supplied from the burner 150 and a cooling unit 114 for cooling the activated carbon passing through the heating unit 112 do.

When the high temperature air supplied from the burner 150 heats the activated carbon, the foreign matter and the harmful gas adsorbed on the activated carbon are desorbed from the activated carbon.

The activated carbon desorbed foreign matter and noxious gas is stored in the discharge reservoir 132 and then circulated to the adsorption unit.

The hot air supplied to the inside of the regeneration tower 110 by the burner 150 is exhausted to the outside of the regeneration tower 110 after heating the activated carbon.

The cooling part 114 cools the activated carbon while the outside air supplied from the charging tube 116 passes. The external air passing through the cooling section 114 is preheated by the activated carbon and supplied to the burner 150, so that the heating performance of the burner 150 is improved.

The supply pipe section 10 is connected to the regeneration tower 110 to supply the feed gas into the regeneration tower 110. For example, the supply pipe portion 10 is equipped with a valve for supplying a predetermined amount of supply gas. Nitrogen is used as the feed gas.

The discharge tube 20 is connected to the regeneration tower 110 to discharge the exhaust gas present inside the regeneration tower 110. At this time, the discharge pipe portion 20 discharges the exhaust gas at the same flow rate as the flow rate of the supply gas supplied from the supply pipe portion 10. [

That is, the gas processing unit 30 connected to the discharge tube 20, the discharge tube 20 and guiding the discharge gas, and the storage tube unit 40 are not provided with a blowing fan for forcibly transferring the discharge gas.

Therefore, the flow rate of the exhaust gas discharged to the discharge tube portion 20 corresponds to the flow rate of the supply gas supplied to the regenerator 110. At this time, the exhaust gas includes sulfur oxides and foreign substances discharged from activated carbon.

The gas treatment section 30 is connected to the exhaust pipe section 20 and processes the exhaust gas to extract sulfur oxides.

The storage tube portion 40 is connected to the gas processing portion 30 to discharge sulfur oxides and the storage portion 50 is connected to the storage tube portion 40 to store sulfur oxides.

1 and 2, the gas processing unit 30 according to an embodiment of the present invention includes an inlet 31, an outlet 32, and a foreign material removing unit 33. As shown in FIG.

The inlet 31 is connected to the outlet tube 20 to process the incoming exhaust gas and the outlet 32 is connected to the storage tube 40 to deliver the sulfur oxides extracted from the exhaust gas to the storage tube 40 Guide.

The foreign material removing unit 33 is connected to the lower part of the inlet part 31 and the outlet part 32, and discharges the foreign substances contained in the exhaust gas to the outside.

The inlet 31 according to an embodiment of the present invention includes an inlet tube 311 and an inlet nozzle 312.

The upper end of the inlet pipe 311 is connected to the discharge pipe portion 20 and the lower end of the inlet pipe 311 is connected to the upper end of the foreign matter removing portion 33.

The inlet nozzle 312 is formed on the upper portion of the inlet pipe 311 and injects the treatment water into the exhaust gas flowing into the inlet pipe. For example, the inlet nozzle 312 is disposed evenly along the inner circumferential surface of the inlet tube 311 so that the exhaust gas passing through the inlet tube 311 reacts with the treated water.

The treated water jetted from the inlet nozzle 312 falls in contact with foreign matter such as dust contained in the exhaust gas.

In addition, the treated water injected from the inlet nozzle 312 reacts with sulfur trioxide in sulfur oxides contained in the exhaust gas, and then falls into sulfuric acid.

In addition, the treatment water injected from the inlet nozzle 312 cools the exhaust gas. As a result, sulfur dioxide remains in the exhaust gas that has passed through the treated water of the inlet nozzle 312.

The outlet portion 32 according to one embodiment of the present invention includes an outlet tube 321 and an outlet nozzle 322.

The upper end of the outlet pipe 321 is connected to the storage tube portion 40 and the lower end of the outlet pipe 321 is connected to the upper end of the foreign matter removing portion 33.

The outlet nozzle 322 is formed in the upper portion of the outlet pipe 321 and injects the treatment water into the discharged sulfur oxide. For example, the outlet nozzle 322 is disposed evenly along the inner circumferential surface of the outlet tube 321 to allow the sulfur oxides passing through the outlet tube 321 to react with the treated water.

The treated water jetted from the outlet nozzle 322 drops in contact with foreign matter such as dust contained in the sulfur oxides.

In addition, the treated water injected from the outlet nozzle 312 reacts with sulfur trioxide in the sulfur oxides contained in the exhaust gas, and then falls into sulfuric acid.

In addition, the treated water injected from the outlet nozzle 322 cools the sulfur oxides. For example, the sulfur oxides passing through the treatment water jetted from the outlet nozzle 322 are cooled.

The foreign matter removing unit 33 according to an embodiment of the present invention includes a water storage tank 331, a water supply pipe 332, and a water discharge pipe 333. [

The water storage tank 331 is connected to the inlet 31 and the outlet 32. For example, the water reservoir 331 is seated on a fixture such as a ground, an inlet pipe 311 is connected to the upper left side, and an outlet pipe 321 is connected to the upper right side.

In the water storage tank 331, a certain level of water is stored. The water stored in the water storage tank 331 cools the sulfur oxides and blocks floating of the falling foreign matter.

Water is stored in the water storage tank 331 so as to reach the middle height of the water storage tank 331, and the sulfur oxide is passed through the upper portion of the water storage tank 331.

The water supply pipe 332 is connected to the water storage tank 331 to supply water and the water discharge pipe 333 is connected to the water storage tank 331 to discharge the water stored in the water storage tank 331 to the outside.

The amount of water supplied through the water supply pipe 332 is the same as the amount of water discharged through the water discharge pipe 333, so that the water stored in the water storage tank 331 maintains a certain water level.

When the water in the water storage tank 331 is continuously changed, cooling of the sulfur oxide is smoothly performed, and the precipitated foreign matter can be discharged to the outside without being fixed.

The foreign matter removing unit 33 according to an embodiment of the present invention further includes an agitator 334. The stirrer 334 is mounted on the water storage tank 331 and stirs the water stored in the water storage tank 331 to prevent foreign matter from being deposited on the water storage tank 331.

The operation and effect of the gas treatment apparatus for a regeneration tower according to an embodiment of the present invention having the above structure will be described as follows.

The activated carbon passes through the heating unit 112, discharges the exhaust gas containing the harmful gas and foreign matter, and then is cooled while passing through the cooling unit 114.

The outside air supplied to the cooling unit 114 is preheated by heat exchange with the activated carbon and then heated by the burner 150 and passes through the heating unit 112.

On the other hand, the supply pipe portion 10 connected to the regeneration tower 110 supplies nitrogen into the regeneration tower.

When nitrogen is supplied to the inside of the regeneration tower 110, generation of hot spots inside the regeneration tower 110 is suppressed, and the inside of the regeneration tower 110 is stabilized.

Thus, the temperature deviation of the inside of the regeneration tower 110 is reduced, so that the activated carbon can be smoothly removed and the outside air can be prevented from flowing into the regeneration tower 110 due to the damage of the regeneration tower 110.

When nitrogen is continuously supplied into the regeneration tower 110 in the above-described state, the exhaust gas discharged from the activated carbon is discharged from the regeneration tower 110 by the amount of nitrogen supplied into the regeneration tower 110, .

At this time, since the discharged gas is discharged corresponding to the supplied nitrogen, a negative pressure deviation is reduced inside the regenerator 110 to maintain a uniform pressure.

When the exhaust gas that has passed through the discharge pipe portion 20 flows into the inlet pipe 311, the process water is injected from the inlet nozzle 312.

The treated water injected from the inlet nozzle 312 falls into the water storage tank 331 together with foreign matters such as dust contained in the exhaust gas to cool the discharged gas.

At this time, sulfur oxide is contained in the exhaust gas. Of the sulfur oxides, sulfur trioxide reacts with the treated water to become sulfuric acid, and then falls into the water storage tank 331.

Water is stored in the water storage tank 331 and foreign substances which have not been removed by the treated water of the inlet nozzle 312 among the sulfur oxides passing through the upper portion of the water storage tank 331 are dropped by the load and settled in the water storage tank 331.

The sulfur oxides passing through the upper part of the water storage tank 331 are cooled by the water stored in the water storage tank 331.

The sulfur oxides passing through the upper part of the water storage tank 331 are discharged to the outlet pipe 321. The residual water and the sulfur trioxide are removed by the treated water sprayed from the outlet nozzle 322.

The sulfur oxides passing through the outlet nozzle 322 become sulfur dioxide of less than 100 degrees centigrade, stored in the storage section 50, and then reused.

Since the discharge gas is discharged from the regeneration tower 110 in accordance with the supply amount of the supply gas supplied to the regeneration tower 110, The inside can be stabilized.

In the gas treatment apparatus 1 for a regeneration tower according to an embodiment of the present invention, the gas processing unit 30 can extract sulfur oxides and recycle them.

In the gas treatment apparatus 1 for a regeneration tower according to the embodiment of the present invention, the gas treatment unit 30 cools sulfur oxides, and the storage stability of the extracted sulfur oxides is improved.

In the gas treatment apparatus 1 for a regeneration tower according to the embodiment of the present invention, the foreign matter removing unit 33 continuously discharges the foreign matter to the outside, thereby preventing the foreign matter from being settled.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it will be understood by those of ordinary skill in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. I will understand.

Accordingly, the true scope of protection of the present invention should be defined by the following claims.

10: supply pipe 20: exhaust pipe
30: gas treatment part 31: inlet part
32: outlet part 33: foreign matter removal
40: storage tube part 50: storage part
110: regeneration tower 311: inlet tube
312: inlet nozzle 321: outlet tube
322: outlet nozzle 331: reservoir
332: water pipe 333: water pipe

Claims (6)

A supply pipe connected to the regeneration tower to supply the supply gas;
A discharge pipe connected to the regeneration tower for discharging exhaust gas at a flow rate equal to a flow rate of the feed gas supplied from the supply pipe;
A gas treatment unit connected to the discharge pipe and treating the exhaust gas to extract sulfur oxides;
A storage tube connected to the gas processing unit to discharge sulfur oxides; And
And a storage portion connected to the storage tube portion and storing sulfur oxides,
The gas processing unit
An inlet portion connected to the exhaust pipe portion to process the exhaust gas introduced therein;
An outlet connected to the storage tube to discharge sulfur oxides; And
And a foreign matter removing part connected to the inlet part and the lower part of the outlet part and discharging the foreign substances contained in the exhaust gas,
The inlet
An inlet pipe connected to an upper end portion of the discharge pipe portion and connected to a lower end portion of the foreign matter removing portion; And
And an inlet nozzle provided in the inlet pipe for discharging treated water to an outlet gas flowing into the inlet pipe.
delete delete 2. The apparatus of claim 1, wherein the outlet
An outlet pipe connected to an upper end portion of the storage tube portion and connected to a lower end portion of the foreign matter removing portion; And
And an outlet nozzle provided in the outlet pipe for spraying the treated water to the sulfur oxide discharged from the outlet pipe.
The image forming apparatus according to claim 1,
A reservoir connected to the inlet and the outlet;
A water supply pipe connected to the water storage tank to supply water; And
And a water discharge pipe connected to the water storage tank and discharging water.
6. The apparatus according to claim 5, wherein the foreign substance removing unit
Further comprising an agitator mounted on the water reservoir and stirring the stored water to prevent foreign matter precipitation.

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