KR101182805B1 - Absorption tower having multi-absorption chamber - Google Patents

Abstract

The present invention relates to a wet absorption tower having multiple absorption chambers. It includes an absorbent liquid tank containing an alkaline absorbent liquid for neutralizing the oxide in the acidic harmful gas; A plurality of absorption chambers disposed above the absorbent liquid tank and passing acidic harmful gas to be treated therein, the gas inlet for receiving the acidic harmful gas at a lower side thereof and a gas outlet at the upper side thereof; A gas transfer duct for communicating a gas outlet of one absorption chamber and a gas inlet of a neighboring absorption chamber so as to communicate internal spaces of the absorption chamber; A plurality of nozzles provided in each of the absorption chambers and for ejecting the absorption liquid supplied from the outside into the absorption chamber; And an absorbent liquid supplying means for supplying the absorbent liquid in the absorbent liquid tank to the nozzle.
The wet absorption tower having the multiple absorption chambers of the present invention as described above includes a plurality of absorption chambers through which the exhaust gas passes through and in contact with the absorption liquid, thereby extending the contact time between the exhaust gas and the absorption liquid to the maximum. In addition, since the removal efficiency of the oxide in the exhaust gas is high and there is no fear of leakage of the absorbent liquid, it is not easy to maintain the device or cost for sealing.

Description

Absorption tower having multi-absorption chamber

The present invention relates to a wet absorption tower having multiple absorption chambers.

Acidic components such as hydrogen chloride (HCl), sulfur oxides (SOx), or hydrogen fluoride (HF) in the exhaust gases generated during the combustion of materials in large-scale incineration plants, boilers or steel mills, etc., are very harmful to humans and cause air pollution. As a substance, it is removed through various methods.

As a method for removing acidic components in the exhaust gas, exhaust gas is introduced into the absorption tower, and an alkaline solution (such as slaked lime, Ca (OH) 2) or slurry as an absorption liquid is injected into the absorption tower to obtain a high temperature. By allowing the exhaust gas of to come into contact with the alkaline substance, there is a method of absorbing and neutralizing the acidic substance in the gas with the alkaline substance. The alkaline solution contacts the gas in the absorption tower in a particulate state and undergoes a reaction process of absorbing acidic substances in the gas. The removal efficiency of the acidic material depends on the contact time and the contact area between the acidic material and the absorbent liquid and the pH of the absorbent liquid.

1 illustrates a conventional wet absorption tower for the neutralization reaction.

As shown in the drawing, the conventional wet absorption tower 11 includes a reaction tank 35 which receives exhaust gas through the exhaust gas inlet 13, has a processing gas outlet 15 thereon, and accommodates the absorbent liquid 17. In addition, a plurality of nozzles 31 arranged in an upper portion of the reaction tank 35, an absorbent liquid discharge pipe 23 for supplying the absorbent liquid 17 to the nozzle 31, a pump 25, and an absorbent liquid supply pipe 29 ). The absorbing liquid 17 is a slurry in which water and slaked lime or limestone are mixed, or a solution in which caustic soda or magnesium hydroxide is mixed.

In addition, an agitator 19 is installed at the side of the reaction tank 35. The stirrer 19 prevents the solids from sinking and sticking inside the absorbent liquid 17. The stirrer 19 has a motor 19a and a stirring blade 19b that is rotated by the motor 19a. The shaft for transmitting the rotational force of the motor (19a) to the stirring blade (19b) extends through the side wall of the reaction tank 35 into the reaction tank (35).

Reference numeral 27 is a discharge line. The discharge line is a passage for sending a portion of the absorbing liquid 17 to an external solution discharge tank (not shown).

In the conventional absorption tower 11 having the above structure, the exhaust gas flowing into the processing space 33 through the exhaust gas inlet 13 moves upwardly toward the processing gas outlet 15 and moves from the nozzle 31. It comes in contact with the absorbing liquid 17 injected downward. As the exhaust gas comes into contact with the absorbent liquid 17, the oxide inside the exhaust gas reacts with the absorbent liquid 17 to be neutralized, and the gas from which the oxide is removed is discharged to the outside through the process gas outlet 15.

However, the conventional absorption tower 11 has a limit in absorbing acid gas of the absorbent liquid, and the contact time between the absorbent liquid and the exhaust gas is short. For example, when a high concentration of SOx-containing gas of 2000 ppm or more flows in, the treatment efficiency of the oxide is increased. The disadvantage is that it is not good.

That is, the time that the exhaust gas can come into contact with the absorbing liquid is while the exhaust gas stays in the processing space 33, and the exhaust gas that enters through the exhaust gas inlet 13 due to the structure of the tower is subsequently pushed by the incoming exhaust gas and the processing gas. Since it exits directly to the outlet 15, the amount of time the residence time in the processing space 33 is short, and even if the processing time is sufficient, the amount of acidic substances that can be absorbed by the absorbent liquid itself in contact with the exhaust gas is limited. It is not possible to process high concentrations of exhaust gases at once.

In addition, in the conventional absorption tower 11, since the stirrer 19 is located at the side of the reaction tank 35, a sealing device is required to surround the shaft of the stirrer penetrating the side wall of the reaction tank 35. The sealing device is to prevent leakage of the absorbent liquid 17 to the outside of the reaction tank 35 and requires continuous maintenance.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and includes a plurality of absorption chambers that allow high concentration acid exhaust gas to pass therein and come into contact with an absorbing liquid, thereby extending the contact time between the exhaust gas and the absorbing liquid to the maximum, and thereby exhaust gas. It is an object of the present invention to provide a wet absorption tower having a multi-absorption chamber that is easy to maintain due to high removal efficiency of oxides and no fear of leakage of absorbent liquid, and thus no device or cost for sealing is required.

Wet absorption tower having a multiple absorption chamber of the present invention for achieving the above object, the absorption liquid tank for containing an alkaline absorption liquid for neutralizing the oxide in the acidic harmful gas; A plurality of absorption chambers disposed above the absorbent liquid tank and passing acidic harmful gas to be treated therein, the gas inlet for receiving the acidic harmful gas at a lower side thereof and a gas outlet at the upper side thereof; A gas transfer duct for communicating a gas outlet of one absorption chamber and a gas inlet of a neighboring absorption chamber so as to communicate internal spaces of the absorption chamber; A plurality of nozzles provided in each of the absorption chambers and for ejecting the absorption liquid supplied from the outside into the absorption chamber; And an absorbent liquid supplying means for supplying the absorbent liquid in the absorbent liquid tank to the nozzle.

In addition, the absorption chamber is opened to the lower portion as a cylindrical casing, the lower end portion is characterized in that it extends to the lower liquid level of the absorbent liquid.

In addition, the absorbent tank is further provided with a stirrer for stirring the absorbent liquid in the absorbent liquid tank, the stirrer; And a motor connected to the driving shaft of the absorbent liquid tank, the shaft connected to the driving shaft of the motor, and extending into the absorbent liquid tank, and a stirring blade provided at an extended end of the shaft to be immersed in the absorbent liquid.

In addition, the motor is disposed in the upper center of the absorbent liquid tank, the absorption chamber is characterized in that the symmetrical arrangement around the motor.

The wet absorption tower having the multiple absorption chambers of the present invention as described above includes a plurality of absorption chambers through which the exhaust gas passes through and in contact with the absorption liquid, thereby extending the contact time between the exhaust gas and the absorption liquid to the maximum. In addition, even high concentration exhaust gas can be treated at one time, so the processing efficiency is good, and there is no fear of leakage of absorbent liquid, so there is no need for sealing device or cost, so maintenance is easy, facilities are simple, and economical operation is possible. Do.

1 is a view showing a conventional wet absorption tower.
2 is a perspective view schematically showing a wet absorption tower having multiple absorption chambers according to an embodiment of the present invention.
3 is a view for explaining the operation of the absorption tower shown in FIG.

Hereinafter, one embodiment according to the present invention will be described in detail with reference to the accompanying drawings.

FIG. 2 is a perspective view partially illustrating a wet absorption tower having multiple absorption chambers according to an embodiment of the present invention, and FIG. 3 is a view schematically illustrating the operation of the absorption tower illustrated in FIG. 2. .

The same reference numerals as the above reference numerals denote the same members having the same function.

As shown, the wet absorption tower 41 having the multiple absorption chambers according to the present embodiment includes an absorbent liquid tank 43 containing the absorbent liquid 17 and four disposed above the absorbent liquid tank 43. The absorption chamber 45, the transfer duct 47 which communicates the said absorption chamber 45, and the stirrer for stirring the said absorption liquid 17 are included.

The absorbent liquid tank 43 has an air inlet 55 on one side as a container for accommodating the absorbent liquid 17 therein. The air inlet 55 is a passage for guiding outside air into the absorbent liquid tank 43. Air injected through the air inlet 55 oxidizes calcium sulfite in the absorbent liquid 17 to gypsum.

In addition, the pump 25 is provided outside the absorbent liquid tank 43. The pump 25 sucks the absorbent liquid in the absorbent liquid tank 43 through the absorbent liquid discharge pipe 23 and pumps it to the nozzle 31 through the absorbent liquid supply pipe 29. As a result, the absorbent liquid 17 is discharged to the outside of the absorbent liquid tank 43 by the pump 25 and then sent to the nozzle 31 and sprayed through the nozzle 31 to the internal space 43a of the absorbent liquid tank 43. Come back. As described above, the lime as much as the absorbent liquid discharged through the discharge line 27 is replenished into the absorbent liquid tank 43 through a separate supply line.

The stirrer may include a motor 49 disposed at an upper center of the absorbent liquid tank 43 and a shaft connected to a drive shaft of the motor 49 and extending vertically downward and being axially rotated by the driving of the motor 49 ( 53 and a stirring blade 51 fixed to an extended end of the shaft 53 and immersed in the absorbent liquid 17.

The shaft 53 penetrates the ceiling wall of the absorbent liquid tank 43, but since the absorbent liquid 17 is maintained at a level within a predetermined range inside the absorbent liquid tank 43, there is no fear that the absorbent liquid 17 will leak to the outside. . The function of the stirrer is the same as the stirrer 19 described through FIG.

On the other hand, the absorption chamber 45 is a cylindrical case having a constant diameter and height, the lower portion thereof is opened to communicate with the internal space 43a of the absorbent liquid tank 43. The absorption chamber 45 is disposed symmetrically around the motor 49. In particular, the lower end portion of the absorption chamber 45 extends downward into the absorption liquid tank 43 and is locked under the liquid surface of the absorption liquid 17. Therefore, the absorbent liquid injected from the nozzle 31 can be returned to the absorbent liquid tank 43, and the gas passing through the absorbing chamber 45 passes through the transfer duct 47 in sequence without leaking to the outside.

In addition, each absorption chamber 45 is provided with a gas inlet 45a and a gas outlet 45b. The gas inlet 45a is a passage located below the outer circumferential surface (of the portion located above the absorption tank 43) of the absorption chamber 45, and guides the gas to be processed into the absorption chamber 45. In addition, the gas outlet 45b is a passage formed in the upper portion of the outer circumferential surface of the absorption chamber 45 and is a hole for discharging the processing gas processed in the absorption chamber 45 to the outside.

Each of the absorption chambers 45 communicates with each other through the transfer duct 47. The transfer duct 47 is a conduit for moving the gas passing through the absorption chamber 45 to the next absorption chamber 45.

One end of the transfer duct 47 is connected to the gas outlet 45b of the arbitrary absorption chamber 45 and the other end is connected to the gas inlet 45a of the neighboring absorption chamber 45. Therefore, as shown in FIG. 3, the four absorption chambers 45 communicate in series through the transfer duct 47, and the exhaust gas flows upward through the lower portions of the absorption chambers 45 and flows upward. I'm going.

In addition, a plurality of nozzles 31 are installed in each of the absorption chambers 45. The nozzle 31 ejects the absorbent liquid supplied through the absorbent liquid supply pipe 29 downward into the processing space 33. The absorbing liquid injected from the nozzle 31 comes into contact with the exhaust gas flowing upward in the absorption chamber 45 and returns to the absorbing liquid tank 43 in the state of absorbing the oxide in the exhaust gas.

Reference numeral 57 is a blower. The blower 57 is connected to the gas outlet 45b of the first absorption chamber 45 on the right side of FIG. 3, and serves to extract the processed gas to the outside.

Operation of the wet absorption tower 41 of the present embodiment having the above configuration is made as follows.

First, the pump 25 is driven to spray the absorbing liquid 17 through the nozzles 31 inside the absorbing chambers 45. The absorbing liquid injected from the nozzle 31 passes through the processing space 33 and falls into the absorbing liquid tank 43. At the same time, the motor 49 is driven to continuously agitate the absorbent liquid 17 inside the absorbent liquid tank 43 so as to prevent gypsum from solidifying inside the absorbent liquid 17. In addition, by supplying air into the absorbent liquid 17 through the air inlet 55, for example, calcium sulfite mixed into the absorbent liquid is oxidized.

While the absorbing liquid 17 is being injected, the exhaust gas to be treated is injected through the gas inlet 45a of the first absorption chamber 45 on the left side of the drawing. The exhaust gas injected through the gas inlet 45a flows up the processing space 33 and then exits the gas outlet 45b to the next absorption chamber 45 through the transfer duct 47.

It goes without saying that the exhaust gas comes into contact with the absorbing liquid injected from the nozzle 31 during the upward flow of the processing space 33. The absorbent liquid falls in the state in which the oxide in the exhaust gas is absorbed and is collected in the absorbent liquid tank 43.

As described above, the exhaust gas passing through the left first absorption chamber 45 and the transfer duct 47 passes through the second absorption chamber 45, the third absorption chamber, and the fourth absorption chamber, and comes into contact with the absorption liquid. The number of the absorption chambers is, of course, can be adjusted according to the acid concentration in the exhaust gas. In particular, the treatment efficiency of the acidic gas can be adjusted according to the number of absorption chambers participating in the treatment.

The exhaust gas which has passed through the fourth last absorption chamber 45 is exhausted to the outside through the blower 57 as the treated gas. The absorption chamber depends on the acid concentration in the exhaust gas.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims.

11: Absorption tower 13: Exhaust gas inlet 15: Treatment gas outlet
17: Absorption liquid 19: Agitator 19a: Motor
19b: stirring blade 23: absorption liquid discharge pipe 25: pump
27: discharge line 29: absorption liquid supply pipe 31: nozzle
33: treatment space 35: reaction tank 41: absorption tower
43: absorbing liquid tank 43a: inner space 45: absorption chamber
45a: gas inlet 45b: gas outlet 47: transfer duct
49: motor 51: stirring wing 53: shaft
55: air inlet 57: blower

Claims (4)

An absorbent liquid tank containing an alkaline absorbent liquid for neutralizing oxides in acidic harmful gases;
A plurality of absorption chambers disposed above the absorbent liquid tank and passing acidic harmful gas to be treated therein, the gas inlet for receiving the acidic harmful gas at a lower side thereof and a gas outlet at the upper side thereof;
A gas transfer duct for communicating a gas outlet of one absorption chamber and a gas inlet of a neighboring absorption chamber so as to communicate internal spaces of the absorption chamber;
A plurality of nozzles provided in each of the absorption chambers and for ejecting the absorption liquid supplied from the outside into the absorption chamber;
Absorbent liquid supply means for supplying the absorbent liquid in the absorbent liquid tank to the nozzle;
The absorbent liquid tank includes a stirrer for stirring the absorbent liquid in the absorbent liquid tank,
The stirrer;
A multiple absorption chamber comprising a motor installed outside the absorption liquid tank, a shaft connected to the drive shaft of the motor and extending into the absorption liquid tank, and a stirring blade provided at an extended end of the shaft to be immersed in the absorption liquid. Wet absorption tower having a. The method of claim 1,
And the absorption chamber is opened downwardly as a cylindrical casing, the lower end of which is extended below the liquid level of the absorption liquid. delete The method of claim 1,
The motor is disposed in the upper center of the absorbent tank,
The absorption chamber is a wet absorption tower having a multiple absorption chamber, characterized in that arranged symmetrically around the motor.

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