KR20150114402A - Wet-type desulfurization apparatus - Google Patents

Abstract

The present invention relates to a wet type desulfurization device which comprises: a reactor including an inlet formed in a center in which exhaust gas including sulfur oxide is introduced, an outlet formed in an upper side from which the exhaust gas flowed into the reactor discharges, and an absorption space formed in an upper part, and an sulfur oxide inside the exhaust gas is absorbed to an absorbent solution therein, wherein the absorbent solution to which a sulfur oxide is absorbed, and accommodated in a lower part and a product is generated from the absorbent solution; an absorbent solution recirculation module performing the recirculation of the absorbent solution inside the reacting space into the absorption space between the inlet and the outlet by being connected with the reactor, and spraying the absorbent solution to the exhaust gas flowing into the absorbent space, so that the absorbent solution may absorb the sulfur oxide in the exhaust gas; a pH control module injecting a pH material having a higher pH than that of the absorbent solution in the reacting space, so that the pH of the absorbent space is higher than the pH of the reacting space, thereby increasing an absorption rate of the sulfur oxide in the absorption space, and improving the quality of the product in the reacting space. Consequently, the absorption rate of the sulfur oxide and the quality (purity) of the product are enhanced at the same time, and more specifically, the absorption rate of the sulfur oxide is increased by having the pH of the absorption space, wherein the sulfur oxide inside the reactor is in contact with the absorbent solution, to be maintained to 6.0 or more; and the quality (purity) of the product is enhanced by having the pH of the reacting space, wherein the absorbent solution is accommodated inside the reactor, and the product is generated, to be maintained from 4.0 to 5.0.

Description

Wet-type desulfurization apparatus

The present invention relates to a wet desulfurization apparatus, and more particularly, to a wet desulfurization apparatus capable of improving the ability to absorb and remove sulfur oxides and, at the same time, .

Generally, a wet desulfurization system using limestone (CaCO ₃ ) is generally used as a method of treating sulfur oxides (SO _x ) and acid gases contained in the exhaust gas. In the wet desulfurization system, Although it is somewhat high, it is mainly used in large facilities because operation maintenance cost is low. In addition, limestone (CaCO ₃ ) is widely used in desulfurization facilities because it has a merit that it can be used at a low price unlike comparatively expensive products such as caustic soda (NaOH), which is an alkaline substance produced in Korea.

1 shows a prior art desulfurization apparatus in which acid gas is absorbed through gas-liquid contact in an absorption chamber 30 after an untreated gas is introduced into a desulfurizer. The absorbed acid gas is treated by the following reaction, and the slurry is supplied to the absorbing liquid spraying nozzle 63 by the recirculating pump 40 and re-injected to reabsorb the acidic gas in the gas.

SO ₂ (g) + H ₂ O → H ₂ SO ₃ (aq) (1)

H ₂ SO ₃ (aq) ↔ H ⁺ + HSO ₃ ^- ↔ 2H ⁺ + SO ₃ ^{2 -} (2)

Ca ^{2 +} + SO ₃ ^{2 -} ↔ CaSO ₃ (3)

A sulfur oxides (SO _x), go to produce gypsum reaction tank 10 is reproduced as gypsum (CaSO ₄ o 2H ₂ O) through a process as below.

O ₂ (g) O ₂ (aq) (4)

HSO ₃ ^- + O ₂ ^- H ⁺ + SO ₄ ^2- (5)

SO ₄ ^2- + O _{2 -} > SO ₄ ^2- (6)

CaCO ₃ (s) + 2H ^{+ -} & gt ^; Ca ₂ ⁺ + H ₂ O + CO ₂ (7)

Ca ²⁺ + SO ₃ ^2- + H ₂ O → CaCO ₃ H ₂ O (s) (8)

Ca ²⁺ + SO ₄ ^2- + 2H ₂ O → CaSO ₄揃 2H ₂ O (s) (9)

FIG. 2 is a graph showing the production rate of HSO ₃ ^- according to pH change, FIG. 3 is a graph showing the oxidation rate of HSO ₃ ^- which determines the purity of gypsum after formation of HSO ₃ ^- in FIG. 2, The graph shows the SO _x absorption rate with the change of the pH of the reactor together with the change in the pore size. The pH of the slurry inside the wet desulfurizer is improved in the range of 4.0 ~ 5.0, while the SO ₂ absorption rate is decreased. If it is maintained at 5.0 or more, it can be understood that the absorption rate of SO ₂ is improved but the quality of the gypsum can be lowered. Thus, it can be seen that SO _x absorption and gypsum quality can be maximized at different pHs.

However, since the conventional wet desulfurization apparatus has a structure that operates and maintains the same pH, it is possible to simultaneously satisfy both the conditions requiring a high pH for the absorption rate of sulfur oxides and the conditions requiring a low pH for the product quality There was no problem.

Korean Patent Publication No. 10-0906805

An object of the present invention is to provide a wet desulfurization apparatus capable of simultaneously satisfying the improvement of the absorption rate of sulfur oxides as well as the improvement of the quality of a product to be produced.

According to an aspect of the present invention, there is provided an exhaust gas purifier including an inlet port through which an exhaust gas containing sulfur oxides flows in a middle portion thereof, an outlet port through which the introduced exhaust gas is discharged to the outside, A reaction space in which an absorption space in which sulfur oxides in the gas is absorbed by the absorption liquid is formed and a reaction space in which a product is generated from the absorption liquid in which the absorption liquid absorbed by the sulfur oxides is absorbed is formed in the lower part; And an adsorption unit for adsorbing the absorption liquid in the absorption space to increase the absorption rate of the sulfur oxides in the absorption space and improve the quality of the product in the reaction space, and a pH adjustment module for introducing a high pH substance higher than the pH of the absorption liquid in the reaction space and introducing the high-pH substance into the absorption space so that the pH is higher than the pH of the absorption liquid in the reaction space.

According to another aspect of the present invention, there is provided an exhaust gas purifying apparatus for an internal combustion engine in which an inlet for introducing exhaust gas containing sulfur oxides is formed in a middle portion thereof, an outlet port through which the introduced exhaust gas is discharged to the outside, A reaction tank in which an absorption space in which sulfur oxides in the gas is absorbed by the absorption liquid is formed and a product is generated from the absorption liquid in which the sulfur oxides are absorbed and the sulfur oxides are absorbed; An absorption liquid connected to the reaction tank to recirculate an absorption liquid in the reaction space to the absorption space between the outlet and the inlet and to inject the absorption liquid into the exhaust gas so that the absorption liquid absorbs sulfur oxides in the exhaust gas A recirculation module; And the absorption space of the reaction space is adjusted so that the pH of the absorption liquid in the absorption space is higher than the pH of the absorption liquid in the reaction space so as to increase the absorption rate of the sulfur oxide in the absorption space and improve the quality of the product in the reaction space. And a pH adjustment module for introducing a high pH material into the absorption space higher than the pH of the wet desulfurization device.

The wet desulfurization apparatus according to the present invention provides the following effects.

First, the pH of the absorption space contacting with the sulfur oxide in the reaction vessel is maintained at 6.0 or more, so that the absorption rate of the sulfur oxide is improved, and the pH of the reaction space in which the absorption liquid is received and the product is produced is 4.0 to 5.0 So that it is possible to improve not only the absorption rate of sulfur oxides but also the quality (purity) of the product at the same time.

Second, the structure is simple, and the installation is easy and economical.

Third, the pH control module can be applied in various ways such as direct supply in accordance with the design or capacity of the reaction tank, or supply using a control chamber.

Fourth, the absorption rate of sulfur oxides can be maximized by injecting the absorption liquid supplied from the pH adjustment module at the upper part of the reaction tank.

Fifth, since the pH substance is supplied through the pH control module, the absorption space in the reaction tank and the pH of the reaction space can be easily controlled.

1 is a view showing the construction of a conventional wet desulfurization apparatus.
FIG. 2 is a graph showing the production rate of HSO ₃ ^- according to pH change in the wet desulfurization apparatus of FIG. 1; FIG.
3 is a graph showing the oxidation rate of HSO ₃ ^- after formation of HSO ₃ ^- in the wet desulfurization apparatus of FIG.
4 is a graph showing the SO _x absorption and three high purity according to the pH change of the reaction vessel in a wet desulfurization unit of Figure 1;
5 is a view showing the construction of a wet desulfurization apparatus according to an embodiment of the present invention.
6 is a view showing another embodiment of the pH adjustment module in the wet desulfurization apparatus of FIG.
7 is a view showing another embodiment of the pH adjustment module in the wet desulfurization apparatus of FIG.
8 is a view showing another embodiment of the pH adjustment module in the wet desulfurization apparatus of FIG.
9 and 10 are graphs showing the pH change of the wet desulfurizer of FIG.
11 is a view showing another embodiment of the pH adjustment module in the wet desulfurizer of FIG.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

5, a wet desulfurization apparatus 400 according to an embodiment of the present invention includes a reaction tank 100, an absorption liquid recirculation module 200, and a pH control module 300a.

In the reaction tank 100, an exhaust gas containing sulfur oxides flows in, and an alkaline absorption liquid for removing sulfur oxides in the exhaust gas is brought into vapor-liquid contact with the exhaust gas to absorb the sulfur oxides, A product in which an absorption liquid reacts with sulfur oxides is produced.

Wherein the absorption liquid is an alkaline absorbing solution for removing acid gases, acid gases such as a sulfur oxide (SO _x), hydrogen chloride (HCl) and hydrogen fluoride (HF) contained in the exhaust gas of limestone (CaCO ₃₎ aqueous solution of calcium hydroxide ( An alkaline substance such as Ca (OH) ₂ ) aqueous solution, ammonia (NH ₃ ) aqueous solution, caustic soda (NaOH) aqueous solution or magnesium carbonate (line CO ₃ ) may be used.

Referring to the reaction vessel 100, the reaction vessel 100 is provided with an inlet 101 through which an exhaust gas including sulfur oxides flows in the center thereof, and an outlet 101 through which the introduced exhaust gas is discharged to the outside The inlet port 101 and the outlet port 102 are preferably formed so that the time taken for the introduced exhaust gas to stay in the reaction tank 100 is long.

In addition, the reaction tank 100 has an absorption space 120 in which the absorption liquid and the exhaust gas are in vapor-liquid contact with each other to absorb sulfur oxides in the exhaust gas, and the absorption space 120 A reaction space 110 in which the alkali absorbing liquid absorbed by the sulfur oxides is absorbed and the sulfurous oxide absorbs the absorbed liquid to generate a product is formed, (Not shown).

The absorption liquid recycling module 200 recycles the absorption liquid in the reaction tank 100 to the absorption space 120 between the outlet 102 and the inlet 101 and supplies the circulation supplied absorption liquid to the reaction tank 100 so as to absorb sulfur oxides in the exhaust gas.

In detail, the absorption liquid recycling module 200 includes a circulation line 210, a circulation pump 220, and a spray nozzle unit 230. One side of the circulation line 210 is connected to the reaction space 110 of the reaction tank 100 and the other side is connected to the absorption space 120 of the reaction tank 100.

The circulation pump 220 is installed on the circulation line 210 to circulate and supply the absorption liquid of the reaction tank 100 to the absorption space 120 of the reaction tank 100.

The injection nozzle unit 230 injects the absorption liquid supplied to the circulation line 210 in the absorption space 120 of the reaction tank 100 into the absorption space 120.

The circulation line 210 and the injection nozzle unit 230 are arranged in parallel in a plurality of layers and are arranged in the absorption space 120 so as to be spaced apart from each other by a plurality of layers, It is preferable to make the gas-liquid contact uniform so as to improve the absorption of sulfur oxides. The number of layers of the circulation line 210 and the injection nozzle unit 230 can be variously applied according to the capacity and the design of the reaction vessel 100. Likewise, (Not shown).

Meanwhile, the reaction space 110 of the reaction tank 100 is maintained at a pH of 4.0 to 5.0 for the quality (purity) of a product formed by the reaction between the absorption liquid and the sulfur oxide, It is preferable that the space 120 is maintained at pH 6.0 or higher to improve the absorption rate of sulfuric acid in the absorption liquid. For this, the optimum pH can be maintained for each of the reaction space 110 and the absorption space 120 through the pH control module 300a.

The pH adjustment module 300a may be configured to adjust the pH of the absorption space 120 so that the absorption rate of the sulfur oxides in the absorption space 120 increases, The pH of the reaction space 110 is higher than the pH of the reaction space 110, so that the pH of the reaction space 110 is higher than the pH of the reaction space 110. Here, the high pH material is an alkaline material such as an aqueous solution of limestone (CaCO ₃ ). The pH of the absorbing liquid is increased when it is added, and the desired pH can be maintained by controlling the amount of the high pH material.

In detail, the pH control module 300a directly supplies the pH-adjusted substance to the circulation line 210 and is connected to the absorption space 120 of the reaction tank 100, To the absorption space (120). The first supply unit may include a first supply line 310a communicating with the absorption space 120 and a second supply line 310b provided on the first supply line 310a in the absorption space 120, A supply nozzle part 320a for spraying and supplying the high pH material, and a pump (not shown) connected to the first supply line 310a for forcibly supplying the high pH material.

In addition, the pH control module 300a may be configured to supply the high-pH substance to the absorption space 120 through the circulation line 210, The high pH material can be supplied.

Referring to FIG. 6, the pH control module 300b includes a second supply unit connected to the circulation line 210 to supply the pH-adjusted substance to the circulation line 210. The second supply unit may include a second supply line 310b communicating with the circulation line 210 to supply the high pH material, a pump connected to the second supply line 310b for forcibly supplying the high- (Not shown). Here, the detailed description of the first supply pipe portion and the second supply pipe portion is similar to that of a fluid supply device including a known supply line and a pump.

7, the pH control module 300c is a method of supplying a high pH substance to the absorption space 120 using the absorption liquid of the reaction tank 100, and the connection line 310c A pH adjustment chamber 320c, a supply line 330c, and an adjustment pump 340c.

The connection line 310c is spaced apart from and adjacent to the reaction tank 100 and connected to the reaction space 110 of the reaction tank 100 and the pH control chamber 320c, Thereby allowing the absorption liquid of the adsorbent 110 to flow into the pH control chamber 320c. It is preferable that the connection line 310c is formed so as to be downwardly directed to the pH control chamber 320c in the reaction tank 100 so that the absorption liquid in the reaction space 110 can be smoothly moved.

The pH control chamber 320c is connected to the connection line 310c to form an adjustment space in which the introduced absorption liquid is received. The pH control chamber 320c is adjusted such that the pH of the absorbing liquid in the regulating space is higher than the pH of the reaction space 110 by supplying the high pH substance from the inlet 321c formed at the upper side . It is preferable that the high-pH substance is introduced by mixing the high-pH substance with cold water at a temperature of 1 to 15 ° C, and then dissolving the high-pH substance more easily. It is preferable that the absorption rate of SO _x can be improved in a short time. Herein, the high pH material is adjusted so that the pH of the reaction tank 100 and the pH of the pH control chamber 320c are properly maintained.

Here, the absorbing solution contained in the reaction tank 100 is maintained at pH 4.0 to 5.0. This is to improve the amount and quality of gypsum produced in the reaction tank 100. It is desirable to appropriately adjust the amount of the high pH substance to be added to the pH control chamber 320c and to prevent The pH of the absorbent stored in the reaction tank 100 can be maintained at 4.0 to 5.0, for example, by appropriately feeding water into the reaction tank 100 as needed.

One side of the supply line d30c is connected to the pH control chamber 320c and the other side of the supply line d30c is connected to the absorption space 120 of the reaction tank 100, To the absorption space (120). The pH adjustment module 300c includes a plurality of injection nozzles installed in the supply line 330c in the absorption space 120 so as to inject the absorption liquid into the absorption space 120. [

Meanwhile, it is preferable that the supply line 330c is located above the recycling module on the upper side of the reaction tank 100. This is because the contact time between the sulfur oxide which flows in from the inlet 101 and flows upward and the absorption liquid sprayed through the pH adjustment module 300a and the absorption liquid recycling module 200 is maximized, .

The regulating pump 340c is installed on the supply line 330c to circulate and supply the absorbing liquid, and a detailed description thereof will be omitted because a known fluid pump can be applied.

8, the wet desulfurization device 700 has a structure in which the absorption liquid is circulated and supplied using only the pH control module 300d without installing the absorption liquid recirculation module 200 described above have. The wet desulfurization apparatus 700 includes a reaction tank 100 and a pH adjustment module 300d. Here, the description of the reaction vessel 100 is omitted since it has been described above, and the same reference numerals denote the same components.

The pH adjustment module 300d is connected to the reaction tank 100 to circulate and supply the absorption liquid in the reaction space 110 to the absorption space 120. In the absorption space 120, The absorption rate of the cargo is increased and the quality of the product in the reaction space 110 is improved.

In detail, the pH control module 300d may be configured to inject the high-pH substance to maintain the pH of the absorption liquid in the absorption space 120 higher than the pH of the absorption liquid in the reaction space 110, And includes a connection line 310d, a pH control chamber 320d, a supply line 330d, a regulating pump 340d, and a spray nozzle unit 350d. Here, the connection line 310d, the pH adjustment chamber 320d, the adjustment pump 340d, and the injection nozzle unit 350d are similar to the corresponding configurations of the pH adjustment module 300c of FIG. 7, Is omitted.

The pH adjusting module 300d is formed by dividing the supply line 330d into a plurality of layers in a height direction in the absorbing space 120 so that the absorbing liquid is injected widely in the absorbing space 120, So that the vapor-liquid contact efficiency of the sulfuric acid and the absorbing liquid can be improved. The other side of the supply line 330d is connected to the absorption space 120 of the reaction tank 100 so as to be connected to the pH adjustment chamber 320d, A plurality of supply pipes 331d branched from the absorption space 120 and arranged to be spaced from each other in the height direction in the absorption space 120 of the reaction tank 100 are included in the absorption space 120 And a plurality of spray nozzle units 350d are installed in the respective supply pipes 331d. Here, the reference numeral 321d denotes a charging port.

9 and 10 are graphs showing the pH change of the wet desulfurization apparatus 700 of FIG. 8 and the conventional wet desulfurization apparatus of FIG. 1, respectively. 9 is a graph showing the pH change of the absorption liquid in the reaction tank 100 of the wet desulfurization apparatus 700 of FIG. 8, (b) is a graph showing the pH change of the absorption liquid in the reaction tank 100 of the conventional wet desulfurization apparatus of FIG. (10). Fig.

Referring to the drawings, the wet desulfurization apparatus 700 of FIG. 6 (b) has a different pH of the absorption liquid in the upper absorption region and a lower absorption region in the lower reaction region, and more specifically, , And the lower reaction zone has a pH range that can increase the purity of the product (eg gypsum) produced. However, in the case of the conventional wet desulfurization apparatus of (a), except that the pH of the absorption liquid which is lowered from the absorption region to the reaction region is increased by the introduction of an alkaline substance such as limestone in the reaction region of the reaction tank 100, And the pH of the reaction zone are not different from each other.

That is, the wet desulfurization apparatus 700 can increase the absorption rate of sulfur oxides and, at the same time, improve the quality of the product. On the other hand, the conventional wet desulfurization apparatus (a) As a result, the pH of the absorbing liquid which can improve the absorption rate of sulfur oxides and the pH which can improve the purity of the product are different from each other, but they are maintained at the same pH. There is a problem that it is difficult to satisfy all the conditions for improving the purity.

10 is a graph showing the pH change in the entire cycle of the pH control module including the reaction tank 100, unlike the pH change of the absorption liquid in the reaction tank 100, as shown in FIG. to be. 1 (a) is a graph showing the pH change of the conventional wet desulfurizer of FIG. 1, and FIG. 1 (b) is a graph of pH change of the wet desulfurizer 700 of FIG. In the graph, region A represents the absorption region above the reaction tank 100, region B represents the reaction region below the reaction tank 100, and region C represents the region where the absorption liquid is recycled and the pH adjustment module region.

Referring to FIG. 1, in a cycle of the conventional wet desulfurization apparatus of FIG. 1 (a), the pH is maximized at the upper part of the reaction tank 10, that is, at the point where the absorption liquid is sprayed, It can be seen that it is held up and recycled to the absorption region. In this case, the absorption rate in the absorption region may be satisfied, but the purity of the gypsum product in the reaction region is lowered.

However, in the case of the wet desulfurization apparatus 700 of (b), the sulfuric acid absorption rate of the absorption liquid can be maximized because it can maintain a high pH of about pH 6.0 in the absorption region for absorption of sulfur oxides, In the reaction zone, a lower pH can be maintained, so that a product of high purity and high quality can be obtained.

As described above, the wet desulfurization apparatus 700 can maintain the pH corresponding to the absorption region where the absorption rate of sulfur oxides is to be increased and maintain the pH suitable for the reaction region where the product quality is to be improved Thereby improving the absorption rate of sulfur oxides as well as improving the quality of the resulting product.

FIG. 11 is a view showing another embodiment of the pH control module 300e in the wet desulfurization apparatus 700 of FIG. 8. Hereinafter, the configuration that is generally similar to FIG. 8 will be mainly described.

In the wet desulfurization apparatus 800, the pH adjustment module 300e includes circulation control lines 311e and 312e, circulation control pumps 321e and 322e, injection nozzle units 331e and 332e, and a supply unit 341e , 342e.

One side of the circulation control lines 311e and 312e is connected to the reaction space 110 of the reaction tank 100 so that the absorption liquid of the reaction space 110 flows and the other side of the circulation control line 311e and 312e And is connected to the absorption space 120 so that the absorption liquid flows into the absorption space 120.

The circulation control pumps 321e and 322e are installed on the circulation control lines 311e and 312e to perform the forced circulation of the absorption liquid in the reaction space 110 to the absorption space 120. [

A plurality of the injection nozzles 331e and 332e are provided on the circulation control lines 311e and 312e in the absorption space 120 so as to inject the supplied absorption liquid into the absorption space 120, The configuration of one jetting nozzle unit 331e and 332e is similar to a known fluid jetting nozzle, and therefore will not be described.

The supply units 341e and 342e are connected to the circulation control lines 311e and 312e at the front ends of the circulation control pumps 321e and 322e to feed the high pH material into the circulation control lines 311e and 312e .

The pH control module 300e is connected to the circulation control lines 311e and 312e and the circulation control pumps 321e and 322e and the injection nozzles 331e and 332e and the supply units 341e and 342e ), And the absorbing liquids supplied to the absorbing liquids may have different pHs.

In detail, the pH control module 300e includes a first pH control module and a second pH control module. The first pH control module and the second pH control module are respectively connected to the first Circulation control lines 311e and 312e, circulation control pumps 321e and 322e, injection nozzle units 331e and 332e and supply units 341e and 342e.

At this time, the injection nozzle unit 331e of the first pH adjustment module unit is positioned above the injection nozzle unit 332e of the second pH adjustment module unit. Then, the pH of the absorbing solution supplied through the first pH adjusting module is 6.5 to 7.0, and the pH of the absorbing solution supplied through the second pH adjusting module is maintained at 6.0 to 6.5, 120 so that the pH of the absorbing liquid injected to the upper portion of the adsorbent 120 is higher.

As described above, the wet desulfurization apparatuses 400, 500, 600, 700, and 800 are arranged in the reaction space 110 and the absorption space 120 of the reaction tank 100 through the pH control modules 300a, 300b, 300c, 300d, Can be easily adjusted through various methods.

In the wet desulfurization apparatuses 400, 500, 600, 700, and 800, the pH of the absorption space 120 contacting the sulfur oxides in the reaction tank 100 can be maintained at 6.0 or more, thereby improving the absorption rate of sulfur oxides , The pH of the reaction space 110 can be maintained at 4.0 to 5.0, thereby improving not only the absorption rate of sulfur oxides but also the quality (purity) of the product.

Although not shown, the wet desulfurization devices 400, 500, 600, 700, and 800 may include a pH sensing sensor installed in the absorption space 120 and the reaction space 110, respectively. The pH sensing sensor and the pH adjustment modules 300a, 300b, 300b, 300c, 300d, and 300e of the reaction chamber 100, the absorption space 120 in the reaction vessel 100 and the reaction space 300 in the reaction vessel 100 correspond to the types of oxides including sulfur oxides contained in the exhaust gas, It is also possible to monitor the pH of the adsorbent 110 and to control the pH in consideration of the absorption rate of sulfur oxides and the purity of the product.

While the present invention has been described with reference to exemplary embodiments, 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. Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims.

100 ... reactor 101 ... inlet
102 ... outlet 103 ... outlet
110 ... reaction space 120 ... absorption space
200 ... Absorbent liquid recirculation module 210 ... circulation line
220 ... circulation pump 230 ... injection nozzle part
300a, 300b, 300c, 300d, 300e ... pH adjustment module 310a ... first supply line
310b ... second supply line 310c ... connection line
320c ... pH adjustment chamber 321c ... inlet
330c, 330d ... supply line 340c ... regulating pump
320a ... supply nozzle portion
400,500,600,700,800 ... wet desulfurization unit

Claims (14)

An inlet port through which the exhaust gas containing sulfur oxides flows is formed in the middle portion, an outlet port through which the introduced exhaust gas is discharged to the outside is formed on the upper side, and an absorption port in which the sulfur oxide in the exhaust gas is absorbed into the absorption liquid A reaction tank in which a solution is absorbed by the sulfur oxides and a product is generated from the absorption liquid in which the sulfur oxides are absorbed;
An absorption liquid connected to the reaction tank to recirculate an absorption liquid in the reaction space to the absorption space between the outlet and the inlet and to inject the absorption liquid into the exhaust gas so that the absorption liquid absorbs sulfur oxides in the exhaust gas A recirculation module; And
Wherein the pH of the absorption liquid in the absorption space is higher than the pH of the absorption liquid in the reaction space so as to increase the absorption rate of the sulfur oxide in the absorption space and improve the quality of the product in the reaction space. and a pH regulating module for introducing a high pH substance higher than pH into the absorption space. The method according to claim 1,
The absorption liquid recirculation module comprises:
A circulation line connected at one side to the reaction space of the reaction tank and connected to the absorption space of the reaction tank at the other side,
A circulation pump installed on the circulation line for circulating and supplying the absorption liquid of the reaction tank to the absorption space of the reaction tank,
And a jet nozzle unit provided on the circulation line in the absorption space and jetting the supplied absorption liquid into the absorption space. The method of claim 2,
The pH adjustment module includes:
And a first supply unit connected to the circulation line to supply the high pH substance to the circulation line. The method according to claim 1,
The pH adjustment module includes:
And a second supply unit connected to the absorption space of the reaction tank so as to communicate with the high-pH material to supply the absorption space to the absorption space. The method according to claim 1,
The pH adjustment module includes:
A connection line connected to the reaction space of the reaction tank and connected to the absorption liquid,
A pH control chamber connected to the connection line and formed with a control space in which the introduced absorbing liquid is received and from which the high pH material is supplied,
A supply line connected to the pH adjusting chamber at one side and connected to the absorption space of the reaction tank at the other side to supply the absorption liquid of the pH adjustment chamber to the absorption space,
And a regulating pump installed on the supply line for circulating and supplying the absorbing liquid. The method of claim 5,
Wherein the supply line includes:
And the other side is located above the recycle module on the upper side of the reaction tank. An inlet port through which the exhaust gas containing sulfur oxides flows is formed in the middle portion, an outlet port through which the introduced exhaust gas is discharged to the outside is formed on the upper side, and an absorption port in which the sulfur oxide in the exhaust gas is absorbed into the absorption liquid And a reaction space in which a reaction space in which the absorption liquid absorbed by the sulfur oxides is contained and a product is generated from the absorption liquid in which the sulfur oxides are absorbed is formed; And
The absorption space of the absorption space in the absorption space is connected to the reaction vessel so as to circulate and supply the absorption liquid in the reaction space to the absorption space in order to increase the absorption rate of the sulfur oxides in the absorption space and improve the quality of the product in the reaction space, And a pH adjustment module for introducing a high pH substance higher than the pH of the absorption liquid in the reaction space into the absorption space so as to be higher than the pH of the absorption liquid in the reaction space. The method of claim 7,
The pH adjustment module includes:
A connection line connected to the reaction space of the reaction tank and connected to the absorption liquid,
A pH control chamber connected to the connection line and formed with a control space in which the introduced absorbing liquid is received and from which the high pH material is supplied,
A supply line connected to the pH adjusting chamber at one side and connected to the absorption space of the reaction tank at the other side to supply the absorption liquid of the pH adjustment chamber to the absorption space,
And a regulating pump installed on the supply line for circulating and supplying the absorbing liquid. The method of claim 7,
The pH adjustment module includes:
A connection line connected to the reaction space of the reaction tank and connected to the absorption liquid,
A pH control chamber connected to the connection line and formed with a control space in which the introduced absorbing liquid is received and from which the high pH material is supplied,
The pH adjustment chamber is connected to the pH adjustment chamber in one side and the other side is connected to the absorption space in the reaction tank to supply the absorption solution of the pH adjustment chamber to the absorption space, A supply portion including supply lines spaced apart from each other in the height direction in the absorption space,
And a regulating pump installed on the supply line for circulating and supplying the absorbing liquid. The method of claim 7,
The pH adjustment module includes:
One side of which is connected to the reaction space of the reaction tank and the other side of which is connected to the absorption space of the reaction tank,
A circulation control pump installed on the circulation control line for circulating and supplying the absorption liquid in the reaction space to the absorption space;
An absorption nozzle unit installed on the circulation control line in the absorption space and injecting the supplied absorption liquid into the absorption space;
And a supply unit connected to the circulation control line at a front end of the circulation control pump to input the high pH material. The method of claim 10,
The pH adjustment module includes:
A first pH control module unit including the circulation control line, the circulation control pump, the injection nozzle unit, and the supply unit;
And a second pH control module part including the circulation control line, the circulation control pump, the injection nozzle part, and the supply part, and being disposed apart from the first pH control module part,
Wherein the pH of the absorbing liquid supplied through the first pH adjusting module and the pH of the absorbing liquid supplied through the second pH adjusting module are different. The method of claim 11,
Wherein the injection nozzle portion of the first pH adjustment module portion is located above the injection nozzle portion of the second pH adjustment module portion,
Wherein the pH of the absorbing solution supplied through the first pH adjusting module is 6.5 to 7.0 and the pH of the absorbing solution supplied through the second pH adjusting module is 6.0 to 6.5. The method according to any one of claims 1 to 12,
The reaction space of the reaction tank is maintained at pH 4.0 to 5.0 for the quality of the product formed by the reaction of the absorbent with the sulfur oxide,
Wherein the absorption space of the reaction tank is maintained at a pH of 6.0 or more so as to improve an absorption rate of the absorption liquid. 14. The method of claim 13,
The high-
Wherein the wet desulfurization apparatus is one of an aqueous solution of limestone (CaCO ₃ ), an aqueous solution of calcium hydroxide (Ca (OH) ₂ ), an aqueous solution of ammonia (NH ₃ ), an aqueous solution of sodium hydroxide (NaOH) and an aqueous solution of magnesium carbonate (line CO ₃ ).

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