KR102130840B1 - Wet flue gas desulfurization apparatus - Google Patents

Abstract

In the present invention, as the exhaust gas flowing into the absorption tower is firstly gas-liquid contacted with the absorbing solution sprayed by the spray, and flows into the absorbing tank by the guide portion, and secondly gas-liquid contact with the absorbing solution in the absorbing tank. Provided is a wet flue gas desulfurization device capable of secondary removal of the contained sulfur oxides, thereby increasing desulfurization efficiency.

Description

Wet Flue Gas Desulfurization Device {WET FLUE GAS DESULFURIZATION APPARATUS}

The present invention relates to a wet flue gas desulfurization device, and more particularly, to a wet flue gas desulfurization device capable of secondly removing sulfur oxides contained in exhaust gas, thereby increasing desulfurization efficiency.

When sulfur-containing fuels are burned, sulfur is released into the atmosphere in the form of sulfur dioxide (SO2), except that it adheres to the ash. This sulfur dioxide causes air pollution and causes acid rain on the earth, which has a detrimental effect on humans and animals as well as the environment.

To this end, in order to protect the environment, large-scale incineration facilities and power plants have typically been equipped with exhaust gas desulfurization devices, most of which are wet flue gas desulfurization devices.

In the wet desulfurization process, the exhaust gas is brought into gas-liquid contact with an absorbing fluid containing an alkali such as lime, whereby sulfur dioxide is absorbed and removed from the exhaust gas. At this time, although it is classified into various types according to the gas-liquid contacting method of the exhaust gas and the absorbing fluid, a lot of spray-type contacting methods are adopted worldwide.

As a result, the sulfur dioxide absorbed from the exhaust gas forms sulfite in the absorbing fluid, which is usually oxidized by blowing air into the absorbing fluid to form a by-product gypsum.

That is, the wet flue gas desulfurization device is a type of so-called oxidation tank, and when air is blown into the tank, the air in the tank comes into contact with an absorbing fluid having absorbed sulfur dioxide inside the tank.

Looking at the conventional wet flue gas desulfurization device disclosed in Korean Utility Model Publication No. 1998-0030926, exhaust gas is introduced into the absorption tower 1 through an inlet duct, and the absorption tower 1 is connected to a circulation pump 3 The absorption liquid containing calcium carbonate supplied by the spray is sprayed from the spray nozzle 2 to make gas-liquid contact between the absorption liquid and the exhaust gas. The absorbent liquid selectively absorbs sulfur dioxide in the exhaust gas to produce calcium sulfite, and calcium sulfite (CaSO3) in the absorbent liquid is oxidized by oxygen in the air supplied to the absorption tower circulation tank 4 by the air intake pipe 6 To form gypsum.

However, in the conventional wet flue gas desulfurization device, in the part where the injection region where the absorption liquid is injected by the wall surface or the spray nozzle 2 in the open spray type absorption tower 1 as described above is included in the exhaust gas. There is a problem that the obtained sulfur dioxide is not sufficiently removed or the desulfurization rate is not constant.

Republic of Korea Utility Model Publication No. 1998-0030926 (released on Aug. 17, 1998)

The present invention is to solve the above problems, and an object of the present invention is to provide a wet flue gas desulfurization device capable of secondary removal of sulfur oxides contained in exhaust gas, thereby increasing desulfurization efficiency.

The present invention for solving the above problems, an absorption tank containing an absorption solution containing an alkaline absorbent, an absorption tower extending to the top of the absorption tank, and an exhaust gas inlet duct provided on one side of the absorption tower, Exhaust gas outlet duct provided on the other side of the absorption tower, a spray provided in the absorption tower for spraying the absorption solution, a circulation pump for supplying the absorption solution in the absorption tank to the spray, and the absorption tank It provides a wet flue gas desulfurization device comprising an oxygen supply pipe for supplying an oxygen-containing gas and a guide portion for flowing the exhaust gas flowing into the absorption tower through the inlet duct and passing through the spray into the absorption liquid in the absorption tank. .

The absorption tower is divided into a first region and a second region respectively communicating with the absorption solution in the absorption tank by the guide portion, and the inlet duct and the outlet duct may be provided in the first and second regions, respectively. .

One end of the guide portion may extend into the absorption solution in the absorption tank.

The guide portion may include a separation plate for separating the interior of the absorption tower up and down, and a guide duct extending from the separation plate into the absorption liquid in the absorption tank.

The separation plate may be formed to have the same shape as the cross section of the absorption tower.

The separation plate may be formed to have a narrow cross-sectional area along a direction in which exhaust gas introduced through the inlet duct flows into the absorption solution in the absorption tank.

The guide duct may be formed at the center of the separation plate.

The guide duct may communicate the upper region of the separation plate and the absorption solution in the absorption tank.

Alternatively, the guide duct may be formed in plural.

The inlet duct may be provided on an upper portion of the absorption tower, and the outlet duct may be provided on a lower side of the absorption tower.

In addition, a booster fan for increasing the pressure of the exhaust gas flowing into the inlet duct may be further included.

Exhaust gas may flow into the absorption solution in the absorption tank through the guide portion and form bubbles.

In addition, it may further include a backflow prevention plate installed inside the absorption tower.

The backflow prevention plate may be provided between the inlet duct and the spray.

One end of the oxygen supply pipe may be disposed on the outlet side of the guide duct.

Alternatively, the oxygen supply pipe is formed to have a plurality of branch passages, and one end of each of the branch passages may be disposed at the outlet side of each guide duct.

The spray may spray the absorption solution in both directions up and down the absorption tower.

The exhaust gas introduced into the absorption tower through the inlet duct is in primary contact with the absorption liquid sprayed by the spray, and the exhaust gas that has passed through the spray is absorbed by the guide unit into the absorption liquid in the absorption tank 2 It may be discharged through the outlet duct after contact with the next liquid.

According to the present invention, as the exhaust gas flowing into the absorption tower is firstly gas-liquid contacted with the absorption solution sprayed by the spray, and flows into the absorption tank by the guide portion, and the second liquid-liquid contact with the absorption solution in the absorption tank is exhausted It is possible to remove the sulfur oxides contained in the gas secondary, thereby increasing the desulfurization efficiency.

In addition, dust may be removed while the exhaust gas passes through the absorption solution in the absorption tank.

In addition, the exhaust gas can be easily introduced into the absorption solution in the absorption tank by a booster fan to increase the pressure of the exhaust gas flowing into the absorption tower, and the absorption solution and high surface area are formed by the formation of bubbles. It is possible to contact.

It should be understood that the effects of the present invention are not limited to the above-described effects, and include all effects that can be deduced from the configuration of the invention described in the detailed description or claims of the present invention.

1 is a schematic diagram showing a wet flue gas desulfurization device according to a first embodiment of the present invention.
Figure 2 is a perspective view of the guide portion in Figure 1 separated.
Figure 3 is a schematic diagram showing a wet flue gas desulfurization device according to a second embodiment of the present invention.
Figure 4 is a perspective view of the guide portion in Figure 3 separated.

Hereinafter, a preferred embodiment of the wet flue gas desulfurization device of the present invention will be described with reference to FIGS.

In addition, terms to be described later are terms defined in consideration of functions in the present invention, which may vary according to a user's or operator's intention or practice, and the following examples do not limit the scope of the present invention, but rather the scope of the present invention. It is merely exemplary of the components presented in the claims.

In order to clearly describe the present invention, parts irrelevant to the description are omitted, and the same reference numerals are assigned to the same or similar elements throughout the specification. Throughout the specification, when a part “includes” a certain component, this means that other components may be further provided, not excluding other components, unless specifically stated to the contrary.

The wet flue gas desulfurization apparatus of the present invention is specifically intended to remove sulfur oxides, mostly sulfur dioxide (SO2), by wet desulfurization from exhaust gases such as boilers.

First, with reference to Figures 1 and 2 to look at with respect to the wet flue gas desulfurization device according to the first embodiment of the present invention.

The wet flue gas desulfurization device according to the first embodiment of the present invention is largely, the absorption tank 100, the absorption tower 200, the exhaust gas inlet duct 210, the exhaust gas outlet duct 220, the spray 230, circulation It may be made of a pump 240, an oxygen supply pipe 300, a guide portion 400 and a by-product discharge portion 500.

Looking specifically, the absorption tank 100 stores an absorbing solution containing an alkaline absorbent, and in this embodiment, limestone (CaCO3) is used as the alkaline absorbent. The absorption tank 100 may be formed to have various cross-sections such as a circular shape or a square shape, and this embodiment will be described based on a cylindrical absorption tank.

The absorption tower 200 extends to the upper portion of the absorption tank 100, and may be integrally formed with the absorption tank 100.

An exhaust gas inlet duct 210 for introducing exhaust gas is provided at one side of the absorption tower 200, and an exhaust gas outlet duct 220 for discharging purified exhaust gas at the other side of the absorption tower 200 is provided. Is provided. The outlet duct 220 is provided with a mist eliminator (222) to remove moisture present on the absorbent solution.

In this embodiment, the inlet duct 210 is provided on the upper side of the absorption tower 200 based on FIG. 1, and the outlet duct 220 is provided on the lower side of the absorption tower 200.

The positions of the inlet duct 210 and the outlet duct 220 are not limited to this, but after the exhaust gas flowing through the inlet duct 210 is contacted with the absorption solution injected by the spray 230 to be described later. It is preferably provided to be discharged through the outlet duct 220.

Moreover, the absorption tower 200 is divided into a first region 201 and a second region 202, each of which is in communication with the absorption solution in the absorption tank 100 by a guide portion 400 to be described later, and the first The inlet duct 210 and the outlet duct 220 are provided in the region 201 and the second region 202, respectively.

In this embodiment, the inside of the absorption tower 200 is formed on the upper portion, the first region 201 communicating with the absorption solution in the absorption tank 100, and formed in the lower absorption in the absorption tank 100 It is divided into a second region 202 in communication with a solution, the exhaust gas inlet duct 210 is provided in the first region 201, and the exhaust gas outlet duct 220 is provided in the second region 202. Is becoming. This will be explained in more detail below.

A spray 230 for spraying the absorption solution is installed in the absorption tower 200, and the circulation pump 240 recovers the absorption solution in the absorption tank 100 and supplies it to the spray 230 It is for.

In this embodiment, the spray 230 is installed in the first region 201 but is provided below the inlet duct 210, and exhaust gas flowing into the absorption tower 200 through the inlet duct 210. As it flows to the lower portion of the absorption tower, it passes through the spray 230.

The spray 230 may spray the absorbing solution in both the upper and lower directions of the absorption tower 200, and accordingly, the exhaust gas passes through the spray 230 and can contact the absorbing solution on both the upper and lower sides of the spray. Therefore, the effect of increasing the contact area and contact time can be obtained. However, the present invention is not limited thereto, and the spray may be sprayed only in one direction, and the spray may be installed in multiple stages in the absorption tower to spray absorption solutions in directions facing each other.

Accordingly, the absorption solution that is raised by the circulation pump 240 and sprayed through the spray 230 and the exhaust gas flowing through the inlet duct 210 come into gas-liquid contact, and the absorption solution is exhausted. It absorbs sulfur dioxide present in the gas.

Specifically, the following reaction is performed in the absorption tower 200.

(1) SO2 + H2O + CaCO3 → CaSO3 + H2O + CO2

At this time, the spray 230 is preferably formed uniformly at all positions in the cross section of the absorption tower 200 so that the exhaust gas passing through the absorption tower 200 does not come into contact with the absorption solution and does not pass therethrough. Do.

However, nevertheless, in the case of exhaust gas passing along the wall surface of the absorption tower 200 or exhaust gas passing through an area where the absorption solution is not sufficiently sprayed by the spray 230, sulfur dioxide contained in the exhaust gas If it is not sufficiently removed, the desulfurization rate may be lowered.

Accordingly, in order to prevent the desulfurization rate from being lowered as described above, the wet flue gas desulfurization device of the present invention flows into the absorption tower 200 through the inlet duct 210 and passes the exhaust gas passing through the spray 230. A guide portion 400 is provided for flowing into the absorption liquid in the absorption tank 100.

The guide portion 400 is for separating the absorption tower 200 into a first region 201 and a second region 202 as described above, in this embodiment, the absorption tower 200 The first region 201 is formed on the upper portion and the second region 202 is formed on the lower portion.

At this time, the first region 201 and the second region 202 are respectively in communication with the absorption solution in the absorption tank 100, and one end of the guide portion 400 is the absorption solution in the absorption tank 100 It can be extended inward.

Specifically, the guide part 400 extends from the separation plate 420 and the separation plate 420 for separating the inside of the absorption tower 200 up and down into the absorption solution in the absorption tank 100. It may include a guide duct 440.

In this embodiment, the guide duct 440 is formed in the center of the separation plate 420, and is absorbed in the first region 201 and the absorption tank 100 divided by the separation plate 420. The solution is communicating.

The separation plate 420 may be formed to have the same shape as a cross section of the absorption tower 200 so that the first region 201 and the second region 202 may not be in communication with each other, and the separation plate ( 420) may be fixedly coupled to the inside of the absorption tower 200 by welding or the like, or may be combined by a separate coupling unit.

In addition, the separation plate 420 may be formed to have a narrow cross-sectional area along a direction in which the exhaust gas flowing through the inlet duct 210 flows into the absorption solution in the absorption tank 100.

That is, in the present embodiment, as shown in FIG. 2, since the absorption tower 200 is formed in a cylindrical shape, the separation plate 420 is also formed as a circular plate, and the guide is provided at the outer circumference of the separation plate 420. The duct 440 may be formed to have a tapered surface inclined toward the lower side of the absorption tower toward the center where the duct 440 is formed, so that the exhaust gas of the first region 201 along the guide plate 420 along the separation plate 420 ( 440).

As described above, the exhaust gas flowing into the absorption tower 200 through the inlet duct 210 firstly comes into gas-liquid contact with the absorption solution sprayed by the spray 230, and exhaust gas passing through the spray 230 The gas flows into the absorption tank 100 by the guide part 400 to make a second gas-liquid contact with the absorbed solution stored therein, and thus it is possible to secondarily remove sulfur oxides contained in the exhaust gas, thereby increasing desulfurization efficiency. It works.

In addition, dust may be removed while the exhaust gas passes through the absorption solution in the absorption tank 100.

The exhaust gas from which sulfur dioxide has been removed through the second gas-liquid contact with the absorption solution exits the second region 202 and is discharged to the outside of the absorption tower through the outlet duct 220, the absorption solution absorbing sulfur dioxide Will remain inside the absorption tank (100).

At this time, sulfur dioxide is absorbed by the sulfur dioxide in the absorption solution generated, the present embodiment in order to oxidize CaSO3, the absorption tank 100, an oxygen-containing gas, in this embodiment an oxygen supply pipe 300 for supplying air is installed do.

In this embodiment, one end of the oxygen supply pipe 300 is disposed on the outlet side of the guide duct 440. Accordingly, the exhaust gas flowing into the absorption solution in the absorption tank 100 through the guide duct 440 and the air supplied by the oxygen supply pipe 300 collide with each other and can be divided into finer particles to absorb. The surface area of contact with the solution is widened. As a result, the efficiency of removing sulfur dioxide from the exhaust gas and the efficiency of using oxygen can be increased.

In addition, it may further include a stirrer (not shown) for stirring the absorption solution in the absorption tank 100.

As the air is supplied into the absorption solution of the absorption tank 100 by the oxygen supply pipe 300, the oxidation reaction of CaSO3 is performed in the absorption tank 100, and accordingly, gypsum (CaSO4·2H2O) is produced as a by-product. Is formed. The gypsum formed as described above is suspended in the absorption solution and sinks to the lower side of the absorption tank 100.

Hereinafter, the reaction in the absorption tank 100 is as follows.

(2) CaSO3 + 2H2O + 1/2 O2 -> CaSO4·2H2O

A lower part of the absorption tank 100 is provided with a by-product discharge part 500 for discharging the gypsum generated as described above. The by-product discharge unit 500 includes a discharge pump 520 and a solid-liquid separator 540, the absorption solution containing gypsum is recovered by the discharge pump 520, the solid-liquid separator 540 It can be introduced into, thereby separating the solid material gypsum and filtrate, the absorbed sulfur dioxide can be completely removed.

Moreover, the filtrate may be transferred to a filtration tank (not shown), mixed with lime, and then returned to the absorption tank 100 again.

In addition, a booster fan 600 for increasing the pressure of the exhaust gas flowing into the inlet duct 210 may be further included. The pressurized blower 600 may be installed at the front end of the wet flue gas desulfurization device of the present invention, or may be installed on the inlet duct 210.

As the pressure of the exhaust gas flowing into the absorption tower 200 through the inlet duct 210 by the pressurized blower 600 is operated under a condition higher than atmospheric pressure, the exhaust gas in the first region 201 is guided. It can be easily introduced into the absorption solution in the absorption tank 100 by the unit 400. That is, the exhaust gas of the first region 201 is not discharged again through the inflow duct 210 but flows toward the absorption tank 100 by the guide unit 400.

In addition, as the exhaust gas flows into the absorption solution in the absorption tank 100 and forms bubbles, it is possible to make contact with a higher surface area.

Moreover, it may further include a backflow prevention plate 250 installed inside the absorption tower, and the backflow prevention plate 250 flows into the first region 201 of the absorption tower through the inlet duct 210. Exhaust gas is not again discharged through the inlet duct 210.

In this embodiment, the backflow prevention plate 250 is installed between the inlet duct 210 and the spray 230 in the first region 201.

Next, with reference to Figures 3 and 4 to look at with respect to the wet flue gas desulfurization device according to a second embodiment of the present invention.

In the wet flue gas desulfurization device according to the second embodiment, only the structure of the wet flue gas desulfurization device according to the first embodiment described above and the oxygen supply pipe and the guide part are formed differently, and the rest are all formed identically, and only different parts are described Do it.

In the present embodiment, the guide unit 1400 separates the interior of the absorption tower 200 into a first region 201 and a second region 202, wherein the first region 201 is an upper portion of the absorption tower. In the above, the second region 202 is formed under the absorption tower.

Specifically, the guide portion 1400 extends from the separation plate 1420 and the separation plate 1420 for separating the inside of the absorption tower 200 up and down into the absorption solution in the absorption tank 100. It may include a plurality of guide ducts (1440).

The separation plate 1420 may be formed to have the same shape as a cross section of the absorption tower 200 so that the first region 201 and the second region 202 may not be in communication with each other, and the separation plate ( 1420) may be fixedly coupled to the inside of the absorption tower 200 by welding or the like, or may be combined by a separate coupling unit.

In this embodiment, the guide duct 1440 is made of a plurality, and the first region 201 divided by the separation plate 1420 communicates with the absorption solution in the absorption tank 100.

That is, in the present embodiment, as shown in FIG. 4, since the absorption tower 200 is formed in a cylindrical shape, the separation plate 1420 is also formed as a circular plate, and the separation plate 1420 includes a plurality of guide ducts ( 1440) is disposed to allow the exhaust gas of the first region 201 to flow into the absorption tank 100 through each duct.

At this time, the number of the plurality of guide ducts 1440 may be variously formed, and the plurality of guide ducts 1440 may be arranged side by side in a row, as in the present embodiment. It does not matter at any position.

Accordingly, the same effect as the first embodiment can be obtained, and furthermore, the exhaust gas in the first region 201 is introduced into the absorption solution in the absorption tank 100 through the plurality of guide ducts 1440. Therefore, it can be supplied uniformly to all areas of the absorption tank.

In addition, in this embodiment, one end of the oxygen supply pipe 1300 is disposed at the outlet side of the guide duct 1440. In this embodiment, since a plurality of guide ducts 1440 are provided, the oxygen supply pipe 1300 is provided. In addition, it is formed to have a plurality of branch passages so that an end of each branch passage may be disposed at the outlet end of each of the guide ducts 1440.

The present invention is not limited to the specific embodiments and descriptions described above, and various modifications can be carried out by anyone having ordinary knowledge in the technical field to which the present invention pertains without departing from the gist of the present invention as claimed in the claims. And such modifications are within the protection scope of the present invention.

100: absorption tank 200: absorption tower
201: first area 202: second area
210: entrance duct 220: exit duct
222: moisture remover 230: spray
240: circulation pump 250: backflow prevention plate
300, 1300: oxygen supply pipe 400, 1400: guide unit
420, 1420: separation plate 440, 1440: guide duct
500: by-product discharge unit 520: discharge pump
540: solid-liquid separator 600: pressurized blower

Claims (18)

An absorption tank in which an absorption solution containing an alkaline absorbent is stored;
An absorption tower extending to an upper portion of the absorption tank;
An exhaust gas inlet duct provided on one side of the absorption tower;
An exhaust gas outlet duct provided on the other side of the absorption tower;
A spray installed in the absorption tower to spray the absorption solution;
A circulation pump for supplying the absorption solution in the absorption tank to the spray;
An oxygen supply pipe supplying an oxygen-containing gas to the absorption tank;
A guide unit for introducing exhaust gas flowing into the absorption tower through the inlet duct and passing through the spray into the absorption solution in the absorption tank; And
A backflow prevention plate installed inside the absorption tower to prevent the exhaust gas in the absorption tower from flowing backward to the inlet duct side;
The wet flue gas desulfurization device comprising a. An absorption tank in which an absorption solution containing an alkaline absorbent is stored;
An absorption tower extending to an upper portion of the absorption tank;
An exhaust gas inlet duct provided on one side of the absorption tower;
An exhaust gas outlet duct provided on the other side of the absorption tower;
A spray installed in the absorption tower to spray the absorption solution;
A circulation pump for supplying the absorption solution in the absorption tank to the spray;
An oxygen supply pipe supplying an oxygen-containing gas to the absorption tank; And
It includes; a guide portion for flowing into the absorption tower through the inlet duct and passing the exhaust gas through the spray into the absorption solution in the absorption tank;
The guide portion,
Separation plate for separating the interior of the absorption tower up and down; And
Includes a guide duct extending from the separation plate into the absorption solution in the absorption tank,
One end of the oxygen supply pipe is disposed on the outlet side of the guide duct, wet flue gas desulfurization device. The method according to claim 1 or 2,
The absorption tower is divided into a first region and a second region, each of which is in communication with the absorption liquid in the absorption tank by the guide portion, and the first and second regions are provided with the inlet duct and the outlet duct, respectively. Flue gas desulfurization device. According to claim 1,
The guide portion,
Separation plate for separating the interior of the absorption tower up and down; And
A guide duct extending from the separation plate into the absorption solution in the absorption tank;
Including, wet flue gas desulfurization device. The method of claim 2 or 4,
The separation plate is formed to have the same shape as the cross section of the absorption tower, wet flue gas desulfurization device. The method of claim 2 or 4,
The separation plate is formed so that the cross-sectional area is narrowed along the direction in which the exhaust gas flowing through the inlet duct flows into the absorption solution in the absorption tank, wet flue gas desulfurization device. The method of claim 6,
The guide duct is formed in the center of the separation plate, wet flue gas desulfurization device. The method of claim 7,
The guide duct is a wet flue gas desulfurization device in communication with the upper region of the separator and the absorption solution in the absorption tank. The method of claim 2 or 4,
The guide duct is composed of a plurality, wet flue gas desulfurization device. The method according to claim 1 or 2,
The inlet duct is provided on the upper portion of the absorption tower, the outlet duct is provided on the lower side of the absorption tower, wet flue gas desulfurization device. The method according to claim 1 or 2,
A booster fan for increasing the pressure of the exhaust gas flowing into the inlet duct;
Further comprising, wet flue gas desulfurization device. The method of claim 11,
A wet flue gas desulfurization device in which exhaust gas flows into the absorption liquid in the absorption tank through the guide portion and forms bubbles. According to claim 2,
A backflow prevention plate installed inside the absorption tower;
Further comprising, a wet flue gas desulfurization device. The method of claim 1 or 13,
The backflow prevention plate is provided between the inlet duct and the spray, wet flue gas desulfurization device. According to claim 4,
One end of the oxygen supply pipe is disposed on the outlet side of the guide duct, wet flue gas desulfurization device. The method of claim 9,
The oxygen supply pipe is formed to have a plurality of branch passages, one end of each branch passage is disposed on the outlet side of each guide duct, wet flue gas desulfurization device. The method according to claim 1 or 2,
The spray is a wet flue gas desulfurization device for spraying the absorption solution in both directions of the absorption tower. The method according to claim 1 or 2,
The exhaust gas introduced into the absorption tower through the inlet duct is in primary contact with the absorption solution sprayed by the spray, and the exhaust gas that has passed through the spray is absorbed by the guide unit in the absorption tank and 2 The wet flue gas desulfurization device, which is discharged through the outlet duct after the contact with the next liquid.

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