KR101793983B1 - Equipment for automatically removing impurities of absorber in flue gas desulferization system and driving method thereof - Google Patents

Abstract

The present invention provides a facility to automatically remove impurities of an absorption tower for a desulfurizing facility. The automatic impurity removal facility includes: an absorption tower taking exhaust gas and oxidized air; a gas inflow part taking the exhaust gas, including sulfur oxides, into the absorption tower; an oxidized air inflow part taking the oxidized air into the absorption tower; an absorbent supply part supplying an absorbent to the absorption tower; a slurry discharge part moving along a transfer route to discharge plaster slurry generated after the desulfurization of the absorption tower; and a discharge control part connected with the slurry discharge part, measuring concentration values of impurities in the plaster slurry in a plurality of spots on the transfer route, and separating the plaster slurry along different routes in accordance with the concentration values of the impurities to extract plaster and discharge wastewater from the extracted plaster.

Description

Technical Field [0001] The present invention relates to an automatic absorber removal system for desulfurization equipment and a method for operating the same,

More particularly, the present invention relates to an apparatus for automatically removing an absorber impurity from a solid gypsum slurry during slurry-type waste transfer by a flue gas desulfurization process, The wastewater according to the concentration value of the impurities is discharged to dehydrate the gypsum and the wastewater having different impurity concentration values is stirred to recover the wastewater so as to achieve the set average impurity concentration value, To an automatic absorber tower impurity automatic removal system for desulfurization equipment capable of automatically controlling to discharge only the waste water of a desulfurization apparatus and its operation method.

Normally, desulfurization is to remove sulfur or sulfur compounds contained in a material, and there are three types of desulfurization processes.

These three types of desulfurization processes include the desulfurization process of petroleum products, the desulfurization process of gas, and flue gas desulfurization.

In the case of thermal power plants, this desulfurization process is essential because many sulfur dioxide are contained in the flue gas.

Sulfur dioxide is contained in the flue gas of a thermal power plant or a large boiler such as a factory which burns heavy sulfur oil or coal in large quantities.

Since these flue gases are a cause of pollution, a method of blowing lime into the combustion chamber of a boiler to form sulfur dioxide in the form of gypsum or adsorbing flue gas on activated carbon or active manganese has been adopted.

There is also a method of absorbing the flue gas into an aqueous solution of potassium sulfite or the like.

Wet flue gas desulfurization is a method in which flue gas is washed and absorbed by water or alkali solution, and the primary product is made into solution or slurry form. Since SO2 is mixed with liquid reactant, the reaction rate is fast and SO2 removal rate is high. It is compact and easy to secure site.

However, since the temperature of the gas discharged from the process is low, reheating is required for the upward force in the stack, and a large amount of wastewater is generated depending on the process.

Accordingly, at least 90% of the sulfur content is removed by a process using lime / limestone.

Gypsum (CaSO42H2O) is produced as a by-product in the forced oxidation, and this solid waste can be used as a gypsum board for reclamation or construction and can recover sulfur or sulfuric acid with high commercial value.

These solid wastes contain large amounts of sulfur oxides, sulfides and chloride components and are mostly discharged in the form of slurries. Such solid wastes in the form of slurries can cause severe wear and corrosion in the transport pipe that transports them.

Accordingly, if the inner wall of the conveyance pipe is easily broken and the solid waste in the interior flows out, there is a problem that damage to existing facilities and serious environmental pollution may occur.

Conventionally, a lining member for protecting the inner wall of the conveyance pipe is formed inside the conveyance pipe made of a metal material, and the above problem is solved. However, the life or damage of the lining member can be detected in real time There is a problem that it is difficult to efficiently carry out the foreign matter process control.

A prior art related to the present invention is Korean Patent Laid-Open Publication No. 10-2005-0068381 (published on July 5, 2005).

An object of the present invention is to provide a method and apparatus for measuring the concentration value of impurities contained in a solid gypsum slurry in real time while discharging a solid waste having a slurry form according to a flue gas desulfurization process and discharging wastewater according to the concentration value of the impurities, And an automatic absorption tower impurity automatic for desulfurization equipment which can automatically control the waste water to be collected so as to obtain the set average impurity concentration value and to discharge only the remaining wastewater by stirring the wastewater having different impurity concentration values And a method of operating the same.

It is another object of the present invention to provide an apparatus and method for monitoring gypsum slurry in real time during the transfer of gypsum slurry through a transfer tube and monitoring the internal state of the transfer tube in real time, And to solve the problem of the occurrence of a process stop due to the interruption of the conveyance through the conveyance path, and an operation method thereof.

It is a further object of the present invention to provide a gypsum slurry in which the gypsum slurry is physically agitated within the tube and the vibration set in the tube to be transported, effectively solving the problems such as hardening during transportation, To an apparatus for automatically removing an absorber impurity for a desulfurization apparatus and a method of operating the same.

In order to accomplish the above object, the present invention provides an automatic absorber removal system for desulfurization equipment.

The absorption tower impurity auto-removal system for the desulfurization system includes: an absorption tower into which exhaust gas and oxidation air flow; A gas inlet for introducing the exhaust gas containing sulfur oxide into the absorption tower; An oxidation air inflow part for introducing the oxidation air into the absorption tower; An absorbent supply part for supplying an absorbent to the absorption tower; A slurry discharge unit for transferring the generated gypsum slurry after the desulfurization in the absorption tower to the outside along the transfer path; And separating the gypsum slurry from the gypsum slurry along different paths depending on the concentration value of the impurities, the gypsum slurry being separated from the gypsum slurry at different positions on the transfer path of the gypsum slurry, And a discharge control unit for extracting the gypsum and discharging the wastewater separated from the extracted gypsum to the outside.

The slurry discharging unit includes a transfer pipe connected to the absorption tower and formed with a vortex-like groove in an inner periphery thereof, the gypsum slurry being introduced and transferred, and a control unit installed on the transfer pipe to receive a control signal from the discharge control unit And a pump for pumping the gypsum slurry to be transferred to the outside.

Wherein the discharge control unit includes a concentration sensor provided in the transfer pipe and measuring a concentration value of impurities contained in the gypsum slurry to be transferred, a plurality of discharge pipes branched from an end of the transfer pipe, A plurality of gypsum extractors connected to the plurality of discharge pipes for separating the gypsum and waste water from the gypsum slurry transferred through each of the plurality of discharge pipes and extracting the gypsum; A drainage unit connected to the plurality of gypsum extractors for draining the separated wastewater to the outside, and a controller for controlling the opening and closing of the gypsum slurry in accordance with the concentration value of the impurities measured from the concentration sensor And a controller for discharging the exhaust gas to each of the plurality of exhaust pipes.

The transfer tube includes an outer tube, an inner tube rotatably installed on the outer tube, and an inner tube having a plurality of blades having an oblique slope on an inner surface thereof.

The outer periphery of the inner tube is preferably connected to the rotary gear under the control of the controller, and the inner tube is preferably capable of varying the rotational speed by rotation of the rotary gear.

Particularly, the drainage section includes a plurality of first drain pipes connected to each of the plurality of gypsum extractors, a stirrer connected to the other ends of the plurality of drain pipes, a second drain pipe connected to the stirrer, An auxiliary gypsum extractor connected to the second drain pipe, a third drain pipe connected to the auxiliary gypsum extractor, and a return pipe communicating with the front end of the auxiliary gypsum extractor and the transfer pipe.

Here, the wastewater separated from the gypsum slurry having different impurity concentration values is transferred to each of the plurality of first water pipes, stirred with each other through the stirrer, and the wastewater, which has been stirred, passes through the second water pipe The impurity concentration value is measured by the auxiliary concentration sensor of the wastewater which has been conveyed and conveyed.

Wherein the controller calculates an average concentration value by averaging the different impurity concentration values and, when the impurity concentration value measured by the auxiliary concentration sensor is equal to or greater than the calculated average concentration value, .

Any one of the outer pipe and the inner pipe may be connected to the vibration generators for generating the set vibration value in response to the control signal from the controller.

In the controller, the vibration value may be variably set to be proportional to the impurity concentration value.

The conveyance pipe is further provided with an auxiliary conveyance pipe connected to the plurality of discharge pipes.

At both ends of the auxiliary conveyance pipe, there are further provided valves for opening and closing a part of the conveyance pipe and a flow path for the plurality of discharge pipes.

The conveyance pipe is further provided with a pressure sensor for measuring a pressure value inside the conveyance pipe.

In the controller, a reference pressure value is set.

Wherein the controller determines that the gypsum slurry is broken and determines that the gypsum slurry is transferred to the plurality of discharge pipes through the auxiliary transfer pipe by controlling opening and closing operations of the valves when the measured pressure value is less than the reference pressure value, can do.

In another embodiment, the present invention also provides a method for operating an automatic absorber tower impurity automatic equipment for desulfurization equipment, which automatically removes wastewater using the absorber tower impurity auto-removal facility for the desulfurization equipment.

The present invention relates to a method and apparatus for measuring a concentration value of an impurity contained in a solid gypsum slurry in real time while discharging solid waste having a slurry form according to a flue gas desulfurization process and discharging wastewater according to the impurity concentration value, The wastewater having different impurity concentration values is agitated so that the wastewater is collected so as to achieve the set average impurity concentration value and the remaining wastewater is discharged automatically.

The present invention also provides a method for monitoring gypsum slurry in real time during the transfer of gypsum slurry through a transfer tube and monitoring the internal state of the transfer tube in real time. When problems occur in transferring gypsum slurry in the transfer tube, It is possible to solve the problem that the transfer is stopped through the path to cause the process stoppage.

In addition, the present invention provides a gypsum slurry in which the gypsum slurry is physically agitated in the tube and the vibration set in the tube, effectively solving the problems such as hardening during transportation and the like, It is possible to prevent breakage of the transfer pipe itself.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a block diagram showing the construction of an absorber tower impurity auto-removal system for a desulfurization system of the present invention.
2 is a block diagram showing the construction of an automatic absorber tower impurity removal system for a desulfurization system according to the present invention.
FIG. 3 is a schematic diagram showing a construction for extracting gypsum and discharging wastewater according to different impurity concentration values according to the present invention.
4 is a configuration diagram showing another example of the structure of the absorber tower for automatically removing the absorber for the desulfurization equipment of the present invention.
5 and 6 are flowcharts illustrating a method of operating an automatic absorber removal apparatus for desulfurization equipment according to the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings so that those skilled in the art can easily carry out the present invention.

The present invention may be embodied in many different forms and is not limited to the embodiments described herein.

In order to clearly illustrate the present invention, parts not related to the description are omitted, and the same or similar components are denoted by the same reference numerals throughout the specification.

Hereinafter, the term "an upper (or lower)" or a "top (or lower)" of the substrate means that any structure is disposed or arranged in any manner, as long as any structure is provided or disposed in contact with the upper surface .

Furthermore, the present invention is not limited to a configuration that does not include any other configuration between the substrate and any configuration provided or disposed on (or under) the substrate.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Reference will now be made in detail to embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like reference numerals refer to like elements throughout.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a block diagram showing the construction of an absorber tower impurity auto-removal system for a desulfurization system of the present invention. 2 is a block diagram showing the construction of an automatic absorber tower impurity removal system for a desulfurization system of the present invention. FIG. 3 is a schematic diagram showing a construction for extracting gypsum and draining wastewater according to different impurity concentration values according to the present invention.

1 to 3, the apparatus for automatically removing an absorber impurity for a desulfurization apparatus according to the present invention comprises an absorber 100 into which exhaust gas and oxidation air are introduced, An oxidizing air inflow part 300 for introducing the oxidation air into the absorption tower 100 and an absorbent supply part 300 for supplying an absorbent to the absorption tower 100, A slurry discharging part 500 for transferring the gypsum slurry generated after the desulfurization in the absorber to the outside to discharge the slurry to the outside and a slurry discharging part 500 connected to the slurry discharging part 500, The concentration of the impurities contained in the gypsum slurry at a plurality of positions on the transfer path is measured and the gypsum slurry is separated along different paths depending on the concentration value of the impurities to separate the gypsum from the extracted gypsum It has an emission controller 600 for discharging waste water to the outside.

The slurry discharge unit 500 includes a transfer pipe 510 connected to the absorber 100 and formed with a vortex-like groove (not shown) on its inner periphery, And a pump 520 installed on the drum 510 to pump the gypsum slurry to the outside in response to a control signal from the discharge control unit 600.

The discharge control unit 600 includes a concentration sensor 610 installed in the transfer pipe 510 for measuring a concentration value of impurities contained in the gypsum slurry to be transferred, A plurality of discharge pipes 620 and a plurality of opening and closing valves 630 installed in the plurality of discharge pipes 620 for opening and closing the flow paths and a plurality of discharge pipes 620 connected to the plurality of discharge pipes 620, A plurality of gypsum extractors 640 for separating the gypsum slurry transferred through each of the gypsum slurry and the gypsum and extracting the gypsum from the gypsum slurry and a plurality of gypsum extractors 640 for discharging the separated wastewater to the outside The gypsum slurry is controlled to open and close each of the plurality of open / close valves 630 according to the concentration value of the impurities measured from the concentration sensor 610, and to each of the plurality of discharge tubes 620 Control to discharge It is composed of 660.

Here, the concentration sensor described above may be a chloride ion concentration meter for measuring the concentration of chloride ions contained in the gypsum slurry and / or an electric conductivity meter for measuring the electric conductivity of the gypsum slurry.

Although not shown in the drawing, the transfer pipe 510 includes an outer pipe, an inner pipe rotatably installed on the outer pipe, and an inner pipe having a plurality of blades having an oblique slope on an inner surface thereof.

The outer periphery of the inner tube is preferably connected to the rotary gear under the control of the controller, and the inner tube is preferably capable of varying the rotational speed by rotation of the rotary gear.

4 is a configuration diagram showing another example of the structure of the absorber tower for automatically removing the absorber for the desulfurization equipment of the present invention.

4, the drainage unit 650 includes a plurality of first drain pipes 651 connected to each of the plurality of gypsum extractors 620 and a plurality of second drain pipes 651 connected to the other ends of the first drain pipes 651 A second drain pipe 653 connected to the stirrer 652, an auxiliary concentration sensor 654 installed in the second drain pipe 653 and a second drain pipe 653 connected to the second drain pipe 653, A third drain pipe 656 connected to the auxiliary gypsum extractor 655 and a drain pipe 657 communicating with the front ends of the auxiliary gypsum extractor 655 and the transfer pipe 510, ).

The wastewater separated from the gypsum slurry having different impurity concentration values is transferred to each of the plurality of first water pipes 651 and stirred with each other through the agitator 652, The impurity concentration value is measured by the auxiliary concentration sensor 654 in the agitated wastewater conveyed through the second drain pipe 653 and conveyed.

The controller 660 averages the different impurity concentration values to calculate an average concentration value. When the impurity concentration value measured by the auxiliary concentration sensor 654 is equal to or greater than the calculated average concentration value, And is returned to the transfer pipe (510) through the pipe (657).

The controller 660 calculates an average concentration value by averaging the different impurity concentration values and when the impurity concentration value measured by the auxiliary concentration sensor 654 is equal to or less than the calculated average concentration value, The gypsum is transferred to the auxiliary gypsum extractor 655 side to further extract gypsum, and the generated wastewater can be discharged to the outside.

Also, although not shown in the drawing, any one of the outer pipe and the inner pipe may be connected to the vibration generators that generate the set vibration value in response to the control signal from the controller 660.

In the controller, the vibration value may be variably set to be proportional to the impurity concentration value.

The transfer pipe 510 is further provided with an auxiliary transfer pipe 511 connected to the plurality of discharge pipes 620.

The auxiliary transfer pipe 511 is further provided at both ends thereof with a part of the transfer pipe 510 and valves 512 for opening and closing the flow path with the plurality of discharge pipes 620.

The transfer pipe 510 is further provided with a pressure sensor 513 for measuring a pressure value inside the transfer pipe 510.

In the controller 660, a reference pressure value is set.

When the measured pressure value is less than the reference pressure value, the controller 660 determines that the gypsum slurry is broken and controls the opening / closing operation of the valves 512, so that the gypsum slurry flows to the auxiliary transfer pipe 511, To the plurality of discharge pipes.

Next, a method of operating the automatic absorber impurity removing apparatus for desulfurization equipment of the present invention having the above-described configuration will be described.

5 and 6 are flowcharts illustrating a method of operating an automatic absorber removal apparatus for desulfurization equipment according to the present invention.

Referring to FIGS. 1 to 5, the gas inflow part 200 generated in the absorption tower inflows exhaust gas and oxidation air.

The oxidation air inflow part 300 introduces the oxidation air into the absorption tower 100 and the absorption agent supply part 400 supplies the absorption agent to the absorption tower 100.

Then, the slurry discharging unit 500 transfers the generated gypsum slurry after the desulfurization in the absorber 100 to the outside along the conveying path.

The discharge control unit 500 according to the present invention measures the concentration of impurities contained in the gypsum slurry at a plurality of positions on the transfer path of the gypsum slurry while being connected to the slurry discharge unit 500, The gypsum slurry is separated along different paths depending on the concentration value of the impurities, and the gypsum is extracted and the wastewater separated from the extracted gypsum is discharged to the outside.

The slurry discharging unit 500 includes a transfer pipe 510 connected to the absorber 100 and formed with a vortex-like groove (not shown) on the inner circumference thereof and through which the gypsum slurry is introduced and transferred, And a pump 520 installed on the transfer pipe 510 for receiving the control signal from the discharge control unit 600 and pumping the gypsum slurry to be transferred to the outside.

Particularly, in the present invention, the drainage unit 650 includes a plurality of first drain pipes 651 connected to each of the plurality of gypsum extractors 620, and an agitator (not shown) connected to the other end of the plurality of first drain pipes 651 A second water pipe 653 connected to the agitator 652, an auxiliary concentration sensor 654 installed in the second water pipe 653, an auxiliary plaster 654 connected to the second water pipe 653, A third drain pipe 656 connected to the auxiliary gypsum extractor 655 and a return pipe 657 communicating with the front end of the auxiliary gypsum extractor 655 and the transfer pipe 510 The wastewater separated from the gypsum slurry having different impurity concentration values is transferred to each of the plurality of first water pipes 651.

Then, they are stirred together through the stirrer 652.

Subsequently, the agitated wastewater is conveyed through the second water pipe 653.

Then, the impurity concentration value can be measured by the auxiliary concentration sensor 654 on the conveyed wastewater to be conveyed.

Here, the controller 660 calculates the average concentration value by averaging the different impurity concentration values, and when the impurity concentration value measured by the auxiliary concentration sensor 654 is equal to or more than the calculated average concentration value, And may be recovered to the transfer pipe 510 through the recovery pipe 657.

The controller 660 calculates an average concentration value by averaging the different impurity concentration values and when the impurity concentration value measured by the auxiliary concentration sensor 654 is equal to or less than the calculated average concentration value, The gypsum is transferred to the auxiliary gypsum extractor 655 side to further extract gypsum, and the generated wastewater can be discharged to the outside.

In addition, the conveyance pipe 510 according to the present invention is further provided with an auxiliary conveyance pipe 511 connected to the plurality of discharge pipes 620. The auxiliary transfer pipe 511 is further provided at both ends thereof with a part of the transfer pipe 510 and valves 512 for opening and closing the flow path with the plurality of discharge pipes 620. The transfer pipe 510 is further provided with a pressure sensor 513 for measuring a pressure value inside the transfer pipe 510.

In this case, the reference pressure value is set in the controller 660, and when the measured pressure value is less than the reference pressure value, the controller 660 determines that the valve 512 is broken, The gypsum slurry may be controlled to be transferred to the plurality of discharge pipes through the auxiliary transfer pipe 511 by controlling the drive.

According to the above-described structure and operation, in the embodiment of the present invention, the concentration value of the impurity contained in the solid gypsum slurry is measured in real time during the transfer of the solid waste having the slurry form according to the flue gas desulfurization process, The wastewater according to the concentration value is discharged to dehydrate the gypsum and the wastewater having different impurity concentration values is stirred to automatically recover the wastewater so as to achieve the set average impurity concentration value and to discharge only the remaining wastewater .

In addition, in the embodiment of the present invention, when the gypsum slurry is conveyed through the conveyance pipe, the internal state of the conveyance pipe is monitored in real time, and when a problem occurs in the conveyance of the gypsum slurry in the conveyance pipe, It is possible to solve the problem that the feed is immediately stopped through the auxiliary feed path to cause the process stoppage.

In addition, the embodiment of the present invention allows the gypsum slurry to be physically agitated in the tube and the vibration set in the tube to which the gypsum slurry is transferred, thereby effectively solving the problems such as hardening during transportation, It is possible to prevent breakage of the conveyance pipe itself due to a problem.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it will be understood by those skilled in the art that various changes and modifications may be made without departing from the scope of the present invention.

Therefore, the scope of the present invention should not be limited to the above-described embodiments, but should be determined by the scope of the appended claims and equivalents thereof.

It is to be understood that the foregoing embodiments are illustrative and not restrictive in all respects and that the scope of the present invention is indicated by the appended claims rather than the foregoing description, It is intended that all changes and modifications derived from the equivalent concept be included within the scope of the present invention.

100: Absorption tower
200: gas inlet
300: oxidation air inflow part
400: absorbent supply part
500:
600:

Claims (5)

An absorption tower into which exhaust gas and oxidation air are introduced;
A gas inlet for introducing the exhaust gas containing sulfur oxide into the absorption tower;
An oxidation air inflow part for introducing the oxidation air into the absorption tower;
An absorbent supply unit for supplying the absorbent to the absorption tower;
A slurry discharge unit for transferring the generated gypsum slurry after the desulfurization in the absorption tower to the outside along the transfer path; And
The concentration of the impurities contained in the gypsum slurry at a plurality of positions on the conveyance path of the gypsum slurry is measured and the gypsum slurry is separated along different paths depending on the concentration value of the impurities, And a discharge control unit for extracting gypsum and discharging wastewater separated from the extracted gypsum to the outside,
The slurry discharging unit includes a transfer pipe connected to the absorption tower and formed with a vortex-like groove in an inner periphery thereof, the gypsum slurry being introduced and transferred, and a control unit installed on the transfer pipe to receive a control signal from the discharge control unit And a pump for pumping the gypsum slurry to be transferred to the outside,
Wherein the discharge control unit includes a concentration sensor provided in the transfer pipe and measuring a concentration value of impurities contained in the gypsum slurry to be transferred, a plurality of discharge pipes branched from an end of the transfer pipe, A plurality of gypsum extractors connected to the plurality of discharge pipes to separate the gypsum and waste water from the gypsum slurry transferred through each of the plurality of discharge pipes and to extract the gypsum; A drainage unit connected to the plurality of gypsum extractors for draining the separated wastewater to the outside, and a controller for controlling the opening and closing of the gypsum slurry in accordance with the concentration value of the impurities measured from the concentration sensor And a controller for discharging the gas to each of the plurality of discharge pipes,
The conveying pipe
An outer tube,
And an inner tube rotatably installed on the outer tube and having a plurality of blades having an inclined slope on an inner surface thereof,
A part of the outer tube is gear-connected to the rotary gear under the control of the controller,
Wherein the rotation speed of the inner pipe is adjusted by varying the rotation speed of the rotary gear.
delete delete delete A method for operating an automatic absorber impurity removing apparatus for desulfurization equipment, which automatically removes wastewater by using an automatic absorber removal apparatus for desulfurization equipment according to claim 1.

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