KR101225412B1 - Appratus for refining sinter flue gas - Google Patents

Abstract

The present invention is connected to a plurality of exhaust duct member disposed in the lower portion of the sintered bed to which the sintered truck is ignited by the ignition furnace, and the exhaust gas is connected to some of the plurality of exhaust duct member and included in the exhaust gas A first exhaust gas discharge device for removing contaminants, and a second exhaust gas discharge device connected to the remaining portions of the plurality of exhaust duct members to discharge the exhaust gas and to remove the contaminants contained in the exhaust gas. The NOx material and the SOx material are separated into the first flue gas discharge device and the second flue gas discharge device to be treated and discharged.

Description

Apparatus for refining sinter flue gas

The present invention relates to an apparatus for treating sintered flue gas, and more particularly, to improve treatment efficiency by separating and treating contaminants contained in flue gas.

In general, sintered ore is prepared by mixing and charging iron ore, powdered coke, and subsidiary materials in a sintering furnace, followed by a sintering process.

In the sintering step, exhaust gas is generated by combustion.

An object of the present invention is to provide a sintered flue gas treatment device that improves the treatment efficiency by separating the SOx and NOx contained in the flue gas generated in the sintering process.

The object of the present invention is a plurality of exhaust duct member disposed in the lower portion of the sintered bed to be transported sintered trolley in the state ignited by the ignition furnace;

A first exhaust gas discharge device connected to a portion of the plurality of exhaust duct members to discharge exhaust gas and remove contaminants contained in the exhaust gas;

It is solved by providing a sintered flue gas treatment apparatus including a second flue gas discharge device connected to the other part of the plurality of exhaust duct members to discharge flue gas and remove contaminants contained in the flue gas.

The plurality of exhaust duct members are disposed from the inlet side of the sintered bed to the outlet side of the sintered bed, respectively, and are continuously disposed to inhale exhaust gas evenly in a section of the sintered bed where sintering is performed.

A plurality of exhaust duct members disposed within a certain distance from the inlet side of the sintered bed where the ignition is ignited by the ignition furnace are connected to a first exhaust gas discharge device, and a predetermined distance from the inlet side of the sintered bed where the ignition is ignited by the ignition furnace The plurality of exhaust duct members arranged thereafter are connected to the second exhaust gas exhaust device.

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The first exhaust gas discharge device is connected to the plurality of exhaust duct members and is connected to the first exhaust gas discharge part, and connected to the first exhaust gas discharge part and included in the exhaust gas discharged to the first exhaust gas discharge part. A first dust collecting unit for removing dust, a first main blowing unit mounted on the first exhaust gas discharge pipe unit, for sucking exhaust gas from the exhaust duct member into the first exhaust gas discharge pipe unit, and connected to the first exhaust gas discharge pipe unit And it characterized in that it comprises a NOx processing unit for removing the NOx component contained in the exhaust gas discharged from the first dust collector and discharge the exhaust gas.

The second exhaust gas discharge device is connected to the plurality of exhaust duct members and is connected to the second exhaust gas discharge pipe part, and is connected to the second exhaust gas discharge pipe part and included in the exhaust gas discharged to the second exhaust gas discharge pipe part. A second dust collecting part for removing dust, a second main blower mounted on the second exhaust gas discharge pipe part, for sucking exhaust gas from the exhaust duct member into the second exhaust gas discharge pipe part, and connected to the second exhaust gas discharge pipe part; And removing the SOx component included in the exhaust gas discharged from the second dust collecting unit and discharging the exhaust gas.

The SOx treatment unit may further include an absorbent supply unit for introducing an absorbent into the second exhaust gas discharge pipe unit.

The SOx treatment unit may include a recovery centrifuge for recovering the absorbent introduced from the absorbent supply unit into the second exhaust gas discharge pipe unit, and an absorbent reinsertion unit for introducing the absorbent recovered from the recovery centrifuge into the second exhaust gas discharge pipe unit. It further comprises.

The SOx treatment unit is connected to a concentration measuring sensor for measuring the concentration of SOx in the exhaust gas discharged from the recovery centrifuge, the concentration measuring sensor and the absorbent supply unit, and the absorbent according to the SOx concentration detected by the concentration measuring sensor. And a control unit for controlling the amount of absorbent introduced from the supply unit to the second exhaust gas discharge pipe unit.

The present invention has the effect of separating the exhaust gas generated in the sintering process to reduce the processing load generated during the removal of contaminants, and increase the treatment efficiency.

In particular, the present invention has the effect of separating the SOx and NOx of the pollutants contained in the exhaust gas to reduce the operating costs for each pollutant removal and to reduce the cost required for each pollutant treatment.

1 is a schematic diagram showing the structure of the present invention
Figure 2 is a graph showing the NOx concentration and SOx concentration at the sintering interval distance

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

As shown in FIG. 1, the sintering apparatus for producing sintered ore includes a sintered trolley 2 into which iron ore, powdered coke, and subsidiary materials are charged, and a sintered bed 1 for transferring the sintered trolley 2, and the sintered bed 1 of the sintered bed 1. The ignition furnace 3 which lights a fuel (powder coke) charged to the said sinter truck 2 at the inlet side is included.

In addition, the inlet side of the sintered bed 1 is provided with a hopper 4, a dream feeder 5, and the like, into which raw materials such as iron ore, powdered coke, and auxiliary materials and fuel are charged.

A plurality of exhaust ports through which exhaust gas is discharged is formed in the lower portion of the sintering bed 1, and an exhaust gas processing device is connected, and the exhaust gas processing device sucks air from the lower side of the sintering trolley 2 so that the sintering trolley 2 The exhaust gas generated in the sintering step in the outside) is discharged to the outside and the fire ignited on the upper part of the sintering cart 2 is continuously ignited to the lower side of the sintering cart 2 and charged in the entire interior of the sintering cart 2. The raw material is sintered evenly.

That is, the sintering process of the said sintering cart 2 is as follows.

At the inlet side of the sinter bed 1, a charge containing raw materials and fuel is charged into the sinter bogie 2 and the surface of the charge is ignited by the ignition furnace 3.

The sintered bogie 2 sinters raw materials while the internal fuel is combusted while being transferred from the inlet side to the outlet side of the sintering bed 1 along the sintering bed 1, and the exhaust gas treating apparatus is sintered. The exhaust gas is sucked from the lower part of the bogie 2 and processed.

In the sintering step, the exhaust gas is sucked into the lower portion of the sinter bogie 2 by the exhaust gas treatment device while transferring the sinter bogie 2 from the inlet side to the outlet side of the sinter bed 1, thereby By introducing air from the upper side into the interior, the fire ignited on the surface of the charge is transferred to the inside of the charge, and the charged fuel is burned evenly to sinter the raw material.

In addition, the sintered sintered body (for example, sintered ore) is withdrawn from the sintered trolley 2 on the outlet side of the sintered bed 1.

The sintered bogie 2 discharges the sintered sintered body from the outlet side of the sintered bed 1 and then moves to the inlet side of the sintered bed 1 again to repeat the sintering process as described above.

The exhaust gas treating apparatus of the present invention includes a plurality of exhaust duct members 10 disposed under the sintered bed 1.

The plurality of exhaust duct members 10 are continuously disposed from the inlet side of the sintering bed 1 to the outlet side of the sintering bed 1 to evenly distribute the exhaust gas in the section of the sintering bed 1 where sintering is performed. To inhale.

That is, each of the exhaust duct members 10 sucks and discharges the exhaust gas generated in the sintered trolley 2 in each section arranged and arranged sequentially from the inlet side to the outlet side of the sintered bed 1.

Some of the plurality of exhaust duct members 10 are connected to the first exhaust gas discharge device 20 for removing and discharging contaminants contained in the exhaust gas.

In addition, some of the plurality of exhaust duct members 10 that are not connected to the first exhaust gas discharge device 20 are connected to a second exhaust gas discharge device 30 that removes and discharges pollutants contained in the exhaust gas. .

On the other hand, the flue gas has a difference in the pollutant concentration of the flue gas for each section of the sintered bed (1).

As shown in FIG. 2, of the sintered bed 1 of the entire section 1L from the inlet side of the sintered bed 1 to the outlet side of the sintered bed 1 ignited by the ignition furnace 3. NOx concentration is higher than SOx concentration in the section (0.8L) within 80% at the inlet side.

In the remaining 20% section (0.2L) of the entire section from the inlet side of the sinter bed 1 to the outlet side of the sinter bed 1 ignited by the ignition furnace 3, the SOx concentration is the concentration of NOx. Occurs higher.

That is, the combustion is started in the sintering process, the amount of NOx generated until the beginning of the sintering process and the middle of the sintering process in which combustion is activated, and the amount of SOx generated at the end of the sintering process in which combustion is extinguished.

Therefore, when all the exhaust gas is discharged to one discharge line, it is necessary to simultaneously treat SOx and NOx, which are contaminants contained in the exhaust gas, which increases the load on the processing equipment, and is insufficient to completely process both, thereby improving the treatment efficiency. There is a problem that is degraded.

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The plurality of exhaust duct members 10 disposed within a predetermined distance, that is, within a predetermined distance, from the inlet side of the sintered bed 1 to be ignited by the ignition furnace 3 are connected to the first exhaust gas discharge device 20. , The plurality of exhaust duct members 10 disposed after a predetermined distance from the inlet side of the sintered bed 1 to be ignited by the ignition furnace 3 are connected to the second exhaust gas discharge device 30.

The first exhaust gas discharge device 20 includes: a first exhaust gas discharge pipe portion 21 connected to the plurality of exhaust duct members 10 and discharging the exhaust gas;

A first dust collecting part 22 connected to the first exhaust gas discharge pipe part 21 and removing dust contained in the exhaust gas discharged to the first exhaust gas discharge pipe part 21;

A first main blower (23) mounted to the first exhaust gas discharge pipe part (21) and configured to suck exhaust gas from the exhaust duct member (10) into the first exhaust gas discharge pipe part (21);

And a NOx treatment part 24 connected to the first exhaust gas discharge pipe part 21 to remove the NOx component included in the exhaust gas discharged from the first dust collecting part 22 and to discharge the exhaust gas.

Note that the NOx treatment unit 24 may be implemented in various modified examples including a selective reduction catalyst (CSR).

In addition, the second exhaust gas discharge device 30 is connected to the plurality of exhaust duct member 10 and the second exhaust gas discharge pipe portion 31 for discharging the exhaust gas;

A second dust collecting part 32 connected to the second exhaust gas discharge pipe part 31 and removing dust contained in the exhaust gas discharged to the second exhaust gas discharge pipe part 31;

A second main blower (33) mounted to the second exhaust gas discharge pipe part (31) for sucking exhaust gas from the exhaust duct member (10) into the second exhaust gas discharge pipe part (31);

And a SOx treatment part 34 connected to the second exhaust gas discharge pipe part 31 to remove the SOx component included in the exhaust gas discharged from the second dust collecting part 32 and to discharge the exhaust gas.

The SOx treatment part 34 further includes an absorbent supply part 34a for introducing an absorbent into the second exhaust gas discharge pipe part 31.

In addition, the SOx treatment part 34 is recovered by the recovery centrifuge 34b for recovering the absorbent introduced into the second exhaust gas discharge pipe 31 from the absorbent supply part 34a and the centrifuge 34b for recovery. It is preferable to further include an absorbent re-insertion unit 34c for introducing the absorbent into the second exhaust gas discharge pipe 31.

In addition, the SOx processing unit 34 is a concentration measuring sensor (34d) for measuring the concentration of SOx in the exhaust gas discharged from the recovery centrifuge (34b),

The concentration measuring sensor 34d is connected to the absorbent supply part 34a and is absorbed from the absorbent supply part 34a to the second exhaust gas discharge pipe part 31 according to the SOx concentration detected by the concentration measuring sensor 34d. It is preferable to further include a control part 34e for controlling the amount of absorbent added.

The control unit 34e determines the ratio of the input amount of the newly added absorbent and the recycled absorbent to be the concentration of SOx detected by the concentration measuring sensor 34d in order to prevent a decrease in efficiency according to the recycling rate of the absorbent. The amount of fresh absorbent introduced into the second exhaust gas discharge pipe 31 through the supply part 34a is controlled.

The SOx treatment unit 34 partially recovers and absorbs the absorbent introduced into the second exhaust gas discharge pipe 31 in the recovery centrifugal separator 34b, and in the dry SOx removal method of treating SOx by adding an excess absorbent. Recycling the absorbent improves the economics.

As described above, the pollutant discharged as described above separates and processes the exhaust gas generated in another section to individually remove the pollutant.

The present invention is to separate each treatment of the pollutants, in particular SOx, NOx to reduce the load generated in the treatment facility when removing the pollutants, reduce the operating cost and improve the treatment efficiency of each pollutant.

The present invention is not limited to the above-described embodiments, and various changes can be made without departing from the gist of the present invention, which is understood to be included in the configuration of the present invention.

1: sintered bed 2: sintered trolley
3: ignition furnace 10: cutting duct member
20: first exhaust gas discharge device 30: second exhaust gas discharge device

Claims (9)

A plurality of exhaust duct members disposed under the sintered bed to which the sintered truck in the ignited state is transported;
A first exhaust gas discharge device connected to a portion of the plurality of exhaust duct members to discharge exhaust gas and remove contaminants contained in the exhaust gas;
A second exhaust gas discharge device connected to the remaining part of the plurality of exhaust duct members to discharge the exhaust gas and to remove contaminants contained in the exhaust gas,
The second exhaust gas discharge device,
A second exhaust gas discharge pipe part connected to the plurality of exhaust duct members and configured to discharge exhaust gas;
A second dust collecting part connected to the second exhaust gas discharge pipe part and removing dust included in the exhaust gas discharged to the second exhaust gas discharge pipe part;
A second main blower mounted on the second exhaust gas discharge pipe and configured to suck exhaust gas from the exhaust duct member into the second exhaust gas discharge pipe;
A SOx treatment part connected to the second exhaust gas discharge pipe part and removing SOx components contained in the exhaust gas discharged from the second dust collecting part and discharging the exhaust gas;
The SOx processing unit,
An absorbent supply unit for introducing an absorbent into the second exhaust gas discharge pipe;
A recovery centrifuge for recovering the absorbent introduced from the absorbent supply unit into the second exhaust gas discharge pipe;
An absorbent re-insertion unit for introducing the absorbent recovered from the recovery centrifuge into the second exhaust gas discharge pipe;
A concentration measuring sensor for measuring a concentration of SOx in the exhaust gas discharged from the recovery centrifuge;
And a control unit connected to the concentration measuring sensor and the absorbent supply unit and controlling an amount of the absorbent supplied from the absorbent supply unit to the second exhaust gas discharge pipe unit according to the SOx concentration detected by the concentration measuring sensor. Sintering flue gas treatment device. The method according to claim 1,
The plurality of exhaust duct members are continuously disposed from the inlet side of the sintered bed to the outlet side of the sintered bed, the sintered exhaust gas treatment device, characterized in that to evenly suck the exhaust gas in the section of the sintering bed where sintering is performed. The method according to claim 1,
A plurality of exhaust duct members disposed within a predetermined distance from the inlet side of the sintered bed where the ignition is ignited by the ignition furnace is connected to the first exhaust gas discharge device,
And a plurality of exhaust duct members disposed after a predetermined distance from an inlet side of the sintered bed where ignition is performed by the ignition furnace is connected to a second exhaust gas discharge device. delete The method according to claim 1,
The first exhaust gas discharge device,
A first exhaust gas discharge pipe part connected to the plurality of exhaust duct members and configured to discharge exhaust gas;
A first dust collecting part connected to the first exhaust gas discharge pipe part and removing dust contained in the exhaust gas discharged to the first exhaust gas discharge pipe part;
A first main blower mounted on the first exhaust gas discharge pipe and configured to suck exhaust gas from the exhaust duct member into the first exhaust gas discharge pipe;
And a NOx treatment unit connected to the first exhaust gas discharge pipe unit and removing the NOx component contained in the exhaust gas discharged from the first dust collecting unit and discharging the exhaust gas. delete delete delete delete

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