KR102054865B1 - An Exhaust Gas Treatment System Having Backflow Prevention Means - Google Patents

Abstract

According to an embodiment of the present invention, in the exhaust gas treatment system having a backflow preventing means of the present invention, the exhaust gas generated by combustion is introduced, and the cleaning liquid is injected into the exhaust gas to remove harmful substances in the exhaust gas. An exhaust gas treatment device and a pipe part for transferring the exhaust gas to the exhaust gas treatment device from two or more combustion devices that generate exhaust gas by combustion, the pipe parts being exhausted when each of the combustion devices is stopped. And a backflow preventing means capable of preventing the backflow of the cleaning liquid from the gas treatment apparatus to the combustion apparatus in which the operation is stopped.

Description

An Exhaust Gas Treatment System Having Backflow Prevention Means

The present invention relates to an exhaust gas treatment system having a backflow preventing means, and more particularly, an exhaust gas generated by combustion is introduced, and an exhaust gas which removes harmful substances in the exhaust gas by injecting a cleaning liquid into the exhaust gas. A processing unit and a piping unit for transferring the exhaust gas to the exhaust gas processing apparatus from at least two combustion apparatuses that generate exhaust gas by combustion, wherein the piping unit is configured to stop the operation of each of the combustion apparatuses. The present invention relates to an exhaust gas treatment system having a backflow preventing means, comprising a backflow preventing means capable of preventing a backflow of the cleaning liquid from the suspended combustion apparatus to the combustion apparatus.

Most modern ships have engines and boilers for their own power and heating. In order to drive the engine and the boiler, fuel must be burned, and the exhaust gas generated during the combustion process includes harmful substances such as sulfur oxide (SOx), nitrogen oxide (NOx), and PM (particular matter, particulate matter). have.

Sulfur oxides and nitrogen oxides can act on the mucous membranes of the human body and cause respiratory diseases. They are also pollutants designated by the World Health Organization as a first-class carcinogen. In addition, when SOx or NOx is released into the air as it is, it reacts with moisture (H ₂ O) in the air to become sulfuric acid (H ₂ SO ₄ ) and nitric acid (HNO ₃ ), respectively, which may be a major cause of acid rain.

PM is a form of small particles compared to gaseous pollutants. When PM in exhaust gas is released into the air, it may cause visibility problems to reduce the visibility, or fine particles may enter the human body through the lungs or respiratory organs and cause various diseases. . Recently, the fine dust which is a problem in Korea is also caused by the PM and can be regarded as a major cause of air pollution.

Therefore, it is necessary to prevent the harmful substances in the exhaust gas. Especially in the case of ships, the engine output is huge, and it is known to emit 130 times the exhaust gas of a passenger car. Specific and practical measures for the exhaust gas of ships are required.

Accordingly, the International Maritime Organization (IMO) has established an emission control area (ECA) to limit the emissions of hazardous substances in the sea area. In particular, the SOx Emission Control Area (SECA) is more broadly regulated than the ECA, which also regulates other harmful substances such as NOx, and imposes strong sanctions.

Furthermore, from January 1, 2015, regulations were further tightened to limit the sulfur content of fuel that causes environmental pollution to 0.1% for all ships passing through the SECA (IMO 184 (59)). The SECA was extended from the Baltic Sea and the North Sea to North America through the amendment of the Marine Pollution Prevention Convention in August 2011. Sulfur oxide management will become more important.

In addition, legislation to reduce the SOx content in the exhaust gas to 3.5% or less in the world's waters other than the ECA was passed by the IMO General Assembly held on October 28, 2016 to 0.5%. Regardless, the need for sulfur oxide management is increasing.

In order to comply with such international regulations, LNG propulsion vessels using low sulphur or natural gas with low sulfur oxides are used. Fuel scrubbers that reduce sulfur oxides in exhaust gases are used. Also used.

When the exhaust gas treatment process is performed using a scrubber, it is economically advantageous to satisfy the above regulations and to prevent environmental pollution even with a low-cost fuel having a relatively high sulfur content. The scrubber ionizes SOx into the cleaning solution. At this time, using seawater or fresh water containing alkaline additives, which is about pH 8.3, can neutralize the ionized sulfur oxides. In addition, the particulate matter may be aggregated and discharged together in the cleaning liquid to prevent its release into the atmosphere.

In addition to the main engine, there are a number of combustion devices, including auxiliary engines and boilers. Therefore, the scrubber must deal with the exhaust gas generated from the plurality of combustion apparatuses. To this end, a multi inlet is formed at the exhaust gas inlet of the scrubber, and exhaust gases generated from a plurality of combustion devices such as a main engine and an auxiliary engine are introduced into the scrubber through the multi inlet.

In such a situation, when one of the plurality of combustion apparatuses needs to be restarted due to a failure or another reason, the pressure of the pipe connecting the combustion apparatus and the scrubber is lowered, so there is a risk of a backflow from the scrubber to the combustion apparatus. In this process, if the cleaning liquid injected from the scrubber is introduced into a combustion device such as an engine, it causes a serious problem in the function of the combustion device. Therefore, it is necessary to develop a technology for preventing backflow of the cleaning liquid from the scrubber in the inflow structure of the exhaust gas through the multi inlet to the scrubber.

US Patent No. 9,272,241 registered "COMBINED CLEANING SYSTEM AND METHOD FOR REDUCTION OF SOX AND NOX IN EXHAUST GASES FROM A COMBUSTION ENGINE", 2016. 03. 01.

The present invention is to solve the above problems of the prior art,

An object of the present invention is to prevent the backflow of the exhaust gas generated by combustion into the combustion apparatus in the exhaust gas treatment apparatus for removing harmful substances in the exhaust gas by injecting a cleaning liquid into the exhaust gas. It is to provide an exhaust gas treatment system having a.

Another object of the present invention is to provide a structure in which exhaust gases generated from two or more combustion apparatuses are introduced into one exhaust gas treatment apparatus, in which case one of the combustion apparatuses does not operate due to a failure or the like and requires a restart. It is an object of the present invention to provide an exhaust gas treating system having a non-return means for preventing backflow of exhaust gas or cleaning liquid from the exhaust gas treating apparatus to the combustion apparatus.

Still another object of the present invention includes a transfer conduit for connecting the combustion apparatus and the exhaust gas treating apparatus in a one-to-one correspondence, and transferring the exhaust gas to the exhaust gas treating apparatus in each of the combustion apparatuses. The backflow prevention means is disposed in each of the conveying conduits so as to cut off the connection between each of the combustion device and the exhaust gas treatment device, the exhaust having a backflow prevention means for efficiently blocking the backflow to each combustion device It is to provide a gas treatment system.

It is a further object of the present invention to provide an exhaust gas treatment system having a backflow preventing means for providing a bypass to the exhaust gas generated in each combustion device.

Still another object of the present invention is an exhaust gas treatment having a backflow prevention means for efficiently removing harmful gas in the exhaust cleaning liquid of the exhaust gas treatment apparatus through an exhaust gas treatment apparatus having improved space utilization and harmful substance removal efficiency. To provide a system.

Still another object of the present invention is to apply to a ship, the exhaust gas having a backflow prevention means for efficiently removing harmful substances including sulfur oxides (SOx) in the exhaust gas discharged from the engine, boiler, etc. of the vessel To provide a processing system.

The present invention is implemented by the embodiment having the following configuration to achieve the above object.

According to an embodiment of the present invention, in the exhaust gas treatment system having a backflow preventing means of the present invention, the exhaust gas generated by combustion is introduced, and the cleaning liquid is injected into the exhaust gas to remove harmful substances in the exhaust gas. An exhaust gas treatment device and a pipe part for transferring the exhaust gas to the exhaust gas treatment device from two or more combustion devices that generate exhaust gas by combustion, the pipe parts being exhausted when each of the combustion devices is stopped. And a backflow preventing means capable of preventing the backflow of the cleaning liquid from the gas treatment apparatus to the combustion apparatus in which the operation is stopped.

According to another embodiment of the present invention, in the exhaust gas treatment system having a non-return means of the present invention, the piping unit corresponding to each one of the combustion apparatus and the exhaust gas treatment unit in a one-to-one correspondence, in each of the combustion apparatus And a conveying conduit for transferring the exhaust gas to the exhaust gas treating apparatus, wherein the backflow preventing means is disposed in each of the conveying conduits so as to cut off the connection between the combustion apparatus and the exhaust gas treating apparatus. do.

According to another embodiment of the present invention, in the exhaust gas treatment system having a backflow prevention means of the present invention, the pipe portion is branched between each of the combustion device and each of the backflow prevention means of each of the transfer conduit, each combustion device It further comprises a bypass conduit for providing a bypass to the exhaust gas generated in.

According to another embodiment of the present invention, in the exhaust gas treatment system having a backflow preventing means of the present invention, the pipe portion is arranged in each of the bypass conduit is cut off blocking the bypass of the exhaust gas to the bypass conduit It further comprises a means.

According to another embodiment of the present invention, in the exhaust gas treatment system having a backflow prevention means of the present invention, the pipe portion is such that the exhaust gas moved through each of the transfer conduit can be introduced into the exhaust gas treatment device together It characterized in that it further comprises a manifold.

According to another embodiment of the present invention, the exhaust gas treatment system having a backflow prevention means of the present invention, the exhaust gas treatment system having the backflow prevention means is installed on a ship, the harmful substance is sulfur oxides (SOx) Characterized in that it comprises a.

According to another embodiment of the present invention, the exhaust gas treatment system having a backflow preventing means of the present invention, the exhaust gas treatment device, a pre-treatment that primarily reduces harmful substances in the exhaust gas generated by combustion, The pretreatment further includes a post-treatment unit to remove harmful substances in the pretreatment gas, which is firstly reduced harmful substances by the pretreatment, and is connected to the noxious gas removing unit, wherein the pre-treatment unit includes an exhaust gas inlet unit through which the exhaust gas is introduced. And a pretreatment gas outlet through which pretreatment gas, which is an exhaust gas of which harmful substances are first reduced, is discharged from the preprocessor, and a preprocessor housing which forms a flow path of the exhaust gas therein, and exhaust gas on the flow path are curved. Stirring means for flowing in a mold, the exhaust gas inlet and the stirring means A first pretreatment injection means arranged to spray cleaning liquid onto the exhaust gas introduced through the exhaust gas inlet, and between the agitating means and the pretreatment gas outlet to curve the flow path through the stirring means And a second pretreatment injection means for injecting the cleaning liquid into the exhaust gas.

According to another embodiment of the present invention, the exhaust gas treatment system having a backflow preventing means of the present invention, the after-treatment, the pre-treatment gas inlet and the post-treatment to which the pre-treatment gas is introduced, the harmful substances are additionally A post-treatment gas outlet having a post-treatment gas outlet through which the removed after-treatment gas flows out; It characterized in that it comprises a water droplet blocking means for blocking the.

According to another embodiment of the present invention, the exhaust gas treatment system having a backflow preventing means of the present invention, the post-processor is disposed on the flow path of the pre-treatment gas, the lower portion of the drop blocking means, the pre-treatment gas A first aftertreatment injection means for injecting a cleaning solution toward and a second aftertreatment injection means disposed on a flow path of the pretreatment gas and injecting the cleaning solution toward the pretreatment gas, the second posttreatment injection means operating independently of the first aftertreatment injection means It further comprises a means.

According to another embodiment of the present invention, in the exhaust gas treatment system having a backflow preventing means of the present invention, the aftertreatment, the first after-treatment injection means and the second after-treatment injection in the post-processor housing And a packing supporting means having a packing disposed at the bottom of the means and a diffusion function for supporting the packing at the bottom but diffusing the pretreatment gas at the bottom of the packing.

According to another embodiment of the present invention, in the exhaust gas treatment system having a backflow preventing means of the present invention, the aftertreatment is disposed adjacent to the pretreatment gas inlet to diffuse the pretreatment gas flowing through the pretreatment gas inlet It characterized in that it further comprises a diffusion means for letting.

The present invention has the following effects through the above-described configuration.

The present invention provides an exhaust gas having a backflow prevention means for preventing a backflow from the exhaust gas treatment apparatus for removing harmful substances in the exhaust gas by injecting exhaust gas generated by combustion and injecting a cleaning liquid into the exhaust gas. There is an effect to provide a gas treatment system.

The present invention has a structure in which the exhaust gas generated from two or more combustion apparatuses flows into one exhaust gas treatment apparatus, and the exhaust gas treatment is performed when one of the combustion apparatuses does not operate due to a failure or the like and requires restart. It has the effect of providing an exhaust gas treatment system having a backflow prevention means in which backflow of exhaust gas or cleaning liquid from the apparatus to the combustion apparatus does not occur.

The present invention includes a transfer conduit for connecting the combustion apparatus and the exhaust gas treating apparatus in a one-to-one correspondence, and for transferring the exhaust gas to the exhaust gas treating apparatus in each combustion apparatus, wherein the backflow preventing means includes: It is disposed in each of the conveying conduit so as to cut off the connection between the combustion device and the exhaust gas treatment device provides an exhaust gas treatment system having a backflow prevention means for efficiently blocking the back flow to each combustion device. It shows the effect.

The present invention has the effect of providing an exhaust gas treatment system having a backflow preventing means for providing a bypass to the exhaust gas generated in each combustion device.

The present invention has an effect of providing an exhaust gas treatment system having a backflow prevention means that can effectively remove the harmful gas in the exhaust cleaning liquid of the exhaust gas treatment apparatus through an exhaust gas treatment apparatus having improved space utilization and harmful substance removal efficiency. Gives.

The present invention is applied to a ship, to provide an exhaust gas treatment system having a backflow prevention means for efficiently removing harmful substances including sulfur oxides (SOx) in the exhaust gas discharged from the engine or boiler of the vessel, etc. Express the effect.

1 is a block diagram of an exhaust gas treatment system having a non-return means according to an embodiment of the present invention
Figure 2 is a block diagram of an exhaust gas treatment system having a backflow prevention means according to another embodiment of the present invention
3 is a perspective view of an exhaust gas treating apparatus;
4 is a cutaway perspective view of the exhaust gas treating apparatus;
5 is a cross-sectional view taken along line AA ′ of FIG. 1.
FIG. 6 is a reference diagram illustrating a process of treating exhaust gas in the cross section of FIG. 5.
7 is a cutaway perspective view of a preprocessor of the exhaust gas treating apparatus;
FIG. 8 is a1-a1 'cross-sectional view of section A of FIG.
FIG. 9 is a2-a2 'cross-sectional view of section A of FIG.
FIG. 10 is a cross-sectional view taken along line bb ′ of FIG. 7.
11 is a perspective view of a stirring means of the exhaust gas treating apparatus;
FIG. 12 is a cross-sectional view taken along the line C1-c1 'in section C of FIG.
FIG. 13 is a c2-c2 'cross-sectional view taken along the line C of FIG.
14 is a cutaway perspective view of a post-processor of an exhaust gas treating apparatus;
15 is a cross-sectional view taken along the line d1-d1 'of the section D of FIG.
16 is a cross-sectional view taken along the line d2-d2 'of the section D of FIG.
17 is a perspective view of a diffusion means of the exhaust gas treating apparatus;
18 is a perspective view of a packing supporting means of the exhaust gas treating apparatus;
19 is a cross-sectional view taken along line BB ′ of FIG. 18.
FIG. 20 is a cross-sectional view of section e1-e1 'of section E of FIG.
FIG. 21 is a cross-sectional view of section e2-e2 'in section E of FIG.
FIG. 22 is a cross-sectional view taken along line ff 'of FIG.
FIG. 23 is a reference diagram illustrating a washing process in FIG. 22.
24 is a sectional view taken along line gg 'of FIG. 14;
FIG. 25 is a reference diagram illustrating a water blocking process in FIG. 24.

Hereinafter, with reference to the accompanying drawings, an exhaust gas treatment system having a backflow preventing means according to the present invention will be described in detail. Unless otherwise defined, all terms in this specification are equivalent to the general meaning of the terms understood by those of ordinary skill in the art to which the present invention pertains and, if they conflict with the meanings of the terms used herein, Follow the definition used in the specification. In addition, detailed description of well-known functions and configurations that may unnecessarily obscure the subject matter of the present invention will be omitted.

Exhaust gas in the present invention refers to a gas generated in the process of burning fuel to drive an engine, a boiler, etc., the harmful substances in the exhaust gas is sulfur oxide (SOx), nitrogen oxide contained in the exhaust gas (NOx), PM (Particular Matter, particulate matter) and the like. The harmful gas removal system and method in the exhaust cleaning liquid of the exhaust gas treatment apparatus according to the present invention are mainly intended for the exhaust gas treatment on a ship, but the use is not limited to the ship.

Figure 1 is a block diagram of an exhaust gas treatment system having a backflow prevention means according to an embodiment of the present invention. Referring to Figure 1, the exhaust gas treatment system having a backflow prevention means of the present invention is the exhaust gas treatment device 1, the manifold (2), a plurality of combustion devices (3a, 3b, 3c) and the piping (4) It includes.

The exhaust gas treatment device 1 is a device for introducing exhaust gas generated by combustion, injecting a cleaning liquid into the exhaust gas to remove harmful substances in the exhaust gas, and discharging the injected cleaning liquid. When the present invention is applied to a vessel, the harmful substance may include sulfur oxides (SOx), the cleaning liquid may be characterized in that the fresh water containing sea water or alkali additives.

The exhaust gas treating apparatus 1 receives and sprays seawater or fresh water containing an alkali additive as a cleaning solution to dissolve sulfur oxides (SOx) in the exhaust gas, to remove toxic substances, and to discharge the particulate matter in the exhaust gas. It is also captured and discharged. Specific embodiments of the exhaust gas treating apparatus 1 will be described later.

The manifold 2 is a part that provides a multiple connection structure when the exhaust gas flows into the exhaust gas treatment apparatus 1 from a plurality of combustion apparatuses. Through the manifold 2, the exhaust gas can be smoothly introduced into the exhaust gas treatment device 1 from the plurality of combustion devices at the same time. That is, an efficient configuration of multi inlets may be achieved through the manifold 2.

The plurality of combustion devices 3a, 3b, 3c encompasses a device that generates exhaust gas by burning fuel, such as a main engine, one or more auxiliary engines, a boiler, and the like. In the case where the present invention is applied to a ship, a large ship includes not only a main engine but also a plurality of auxiliary engines, boilers, and the like.

The pipe 4 serves to transfer the exhaust gas from the two or more combustion devices 3a, 3b, and 3c to the exhaust gas treatment device 1. The pipe section 4 is a backflow prevention means that can prevent the flow of the cleaning liquid back from the exhaust gas treatment device 1 to the combustion device is stopped from operation when the combustion device (3a, 3b, 3c) is stopped 411, 421, and 431.

The pipe section 4 connects each of the combustion devices 3a, 3b, 3c and the exhaust gas treatment device 1 in a one-to-one correspondence, and each of the combustion devices 3a, 3b, 3c. Transport conduits (41, 42, 43) for conveying to the exhaust gas treatment device (1), wherein the backflow prevention means (411, 421, 431) is the combustion device (3a, 3b, 3c) and the It is arranged in each of the transfer conduits 41, 42, 43 so as to cut off the connection with the exhaust gas treatment device (1).

The non-return means 411, 421, and 431 may include a shutoff valve. Each of the combustion devices 3a, 3b, 3c is called a first combustion device 3a, a second combustion device 3b, and a third combustion device 3c, respectively, and each of the transfer conduits 41, 42, 43 When the first conveying conduit 41, the second conveying conduit 42 and the third conveying conduit 43, each of the backflow preventing means (411, 421, 431) is respectively the first backflow preventing means (411) , The second backflow preventing means 421 and the third backflow preventing means 431.

In the present invention, if the second combustion device (3b) is stopped due to failure or the like, when the restart is required, the second backflow prevention means (421) is the second combustion device (3b) and the exhaust gas treatment By disconnecting the device 1, the exhaust gas treatment device 1 is connected to the second combustion device 3b even when the first combustion device 3a and the third combustion device 3c are operating normally. The backflow of the exhaust gas or the cleaning liquid can be prevented.

The pipe 4 is branched between each of the combustion devices 3a, 3b, 3c and the backflow preventing means 411, 421, 431 of each of the transfer conduits 41, 42, 43. It may further include a bypass conduit (41b, 42b, 43b) for providing a bypass to the exhaust gas generated in (3a, 3b, 3c).

When each said transfer conduit 41, 42, 43 is called the 1st transfer conduit 41, the 2nd transfer conduit 42, and the 3rd transfer conduit 43, each said bypass conduit 41b, 42b, 43b ) Becomes a first bypass conduit 41b, a second bypass conduit 42b and a third bypass conduit 43b. Each of the bypass conduits 41b, 42b, 43b provides a bypass to the exhaust gases produced by each combustion device 3a, 3b, 3c.

For example, in the case where the first combustion device 3a is restarted after the operation is stopped, the first combustion device 3a may be used until the pressure of the exhaust gas generated in the first combustion device 3a reaches a predetermined level. The generated exhaust gas may be diverted through the first bypass conduit 41b while the first backflow preventing means 411 cuts off the connection between the first combustion device 3a and the exhaust gas treatment device 1. It becomes possible.

The pipe section 4 is disposed in each of the bypass conduits 41b, 42b, and 43b to block the bypass means 412, 422, 432 to block the bypass of the exhaust gas to the bypass conduits 41b, 42b, 43b. ) May be further included. When the bypass conduits 41b, 42b, 43b are referred to as a first bypass conduit 41b, a second bypass conduit 42b, and a third bypass conduit 43b, the blocking means 412, The 422 and 432 may be the first blocking means 412, the second blocking means 422, and the third blocking means 432, respectively, and they may include a blocking valve.

Looking at the specific example for the process of preventing backflow in the present invention.

If the first combustion device 3a is stopped due to failure or the like, and the second combustion device 3b and the third combustion device 3c are normally operated, the first backflow preventing means 411 The connection between the first combustion device 3a and the exhaust gas treatment device 1 is cut off.

In addition, even when the first combustion device 3a is restarted, the first backflow preventing means 411 may be configured until the pressure of the exhaust gas generated in the first combustion device 3a becomes a level capable of preventing backflow. The connection between the first combustion device 3a and the exhaust gas treatment device 1 is continuously interrupted, and the first blocking means 412 is open-controlled so that the exhaust gas generated in the first combustion device 3a is removed. 1 bypasses the bypass conduit 41b.

Furthermore, when the pressure of the exhaust gas generated in the first combustion device 3a reaches a level capable of preventing backflow, the first blocking means 412 is closed-controlled, and the first backflow preventing means 411 is opened. Controlled exhaust gas generated in the first combustion device 3a is introduced into the exhaust gas treatment device 1 through the first transfer conduit 41.

2 is a block diagram of an exhaust gas treatment system having a backflow preventing means according to another embodiment of the present invention, the exhaust gas treatment apparatus 1 will be described in detail.

2 to 5, the exhaust gas treating apparatus 1 includes a preprocessor 11, a connection part 12, and a post processor 13.

Referring to Figure 6, briefly look at the process of the exhaust gas proceeds in the exhaust gas treatment apparatus 1 as follows. In FIG. 6, the thick arrow indicates the flow of gas, the dotted line indicates the cleaning liquid to be injected, and the thin arrow indicates the cleaning liquid to be discharged.

When the exhaust gas generated by the combustion flows in through the exhaust gas inlet 1112, the pretreatment 11 makes the first harmful gas to be reduced pretreatment gas and discharges it through the pretreatment gas outlet 1113. The connection part 12 moves the pretreatment gas to the postprocessor 13. The aftertreatment unit 13 additionally removes harmful substances from the pretreatment gas introduced through the pretreatment gas inlet unit 1312 and discharges it through the aftertreatment gas outlet unit 1313.

In order to remove harmful substances in the exhaust gas from the pretreatment unit 11, the cleaning liquid used to flow into the cleaning liquid inlet 1114 of the pretreatment unit 11 and the harmful substances of the pretreatment gas in the post-treatment unit 13 are used. The cleaning solution introduced into the cleaning solution inlet 1314 of the aftertreatment 13 to remove the cleaning solution outlets 1115 and 1315 formed at the lower portion of the preprocessor 11 and the aftertreatment 13, respectively. Is discharged through.

When the present invention is applied to a ship, the cleaning liquid may be used as a fresh water, such as sea water or alkali additives, the exhaust gas is generated in the combustion process of the engine or boiler of the ship, the harmful substance is sulfur oxides (SOx) and PM.

The preprocessor 11 serves to primarily reduce harmful substances in the exhaust gas generated by combustion. As can be seen through FIGS. 4 to 7, the preprocessor 11 includes a preprocessor housing 111, a first pretreatment injection means 112, a stirring means 113, and a second pretreatment injection means 114. Include.

The preprocessor housing 111 forms an external shape of the preprocessor 11 and forms a flow path of the exhaust gas therein. The preprocessor housing 111 includes an inner wall 1111, an exhaust gas inlet 1112, a pretreatment gas outlet 1113, a cleaning liquid inlet 1114, and a cleaning liquid outlet 1115. 3 to 7, in one embodiment of the present invention, the preprocessor housing 111 is formed as a cylindrical tower, and moves the introduced exhaust gas from the top of the preprocessor housing 111 to the bottom thereof. It forms a flow path through which harmful substances in the exhaust gas can be removed first.

The inner wall 1111 is a portion that forms a flow path of the exhaust gas inside the preprocessor housing 111. Referring to FIG. 4, in one embodiment of the present invention, the inner wall 1111 has a cylindrical flow path of the exhaust gas inside the preprocessor housing 111.

The exhaust gas inlet 1112 is a portion into which the exhaust gas flows into the preprocessor housing 111. As can be seen through FIGS. 4 to 7, the exhaust gas inlet 1112 is formed at an upper end of the preprocessor housing 111, and the exhaust gas introduced through the exhaust gas inlet 1112 is The inner wall 1111 moves downward along the cylindrical flow path formed.

The pretreatment gas outlet 1113 is a portion from which the pretreatment gas, which is an exhaust gas from which harmful substances are first removed, is discharged from the preprocessor 11. As can be seen through FIGS. 4 to 7, the pretreatment gas outlet 1113 is formed at one lower side of the preprocessor housing 111, and is pretreated gas discharged through the pretreatment gas outlet 1113. Is moved to the post-processor 13 through the connection portion 12.

The cleaning liquid inlet 1114 is a portion into which the cleaning liquid for injection in the preprocessor 11 is introduced. As can be seen through FIG. 7, the cleaning solution inlet 1114 is connected or formed to the first pretreatment injection means 112 and the second pretreatment injection means 114, which will be described later.

The cleaning solution outlet 1115 may include the first pretreatment injection means 112 and the first agent to remove harmful substances from the exhaust gas introduced into the preprocessor housing 111 through the exhaust gas inlet 1112. 2 is a portion to which the cleaning liquid injected by the pretreatment injection means 114 is discharged. As shown in FIGS. 4 to 7, the cleaning solution outlet 1114 is formed at the lower end of the preprocessor housing 111, and the first pretreatment injection means 112 and the cleaning solution outlet 1114 are provided. The cleaning liquid injected by the second pretreatment injection means 114 may collect harmful substances in the exhaust gas and move to the lower end of the preprocessor housing 111 to be discharged to the outside. In order to smoothly discharge the cleaning liquid, the lower end of the pretreatment housing 111 may be formed in a shape that converges toward the cleaning liquid outlet 1114.

The first pretreatment injection means 112 is disposed near the exhaust gas inlet 1112 within the preprocessor housing 111 to inject a cleaning solution to the exhaust gas introduced through the exhaust gas inlet 1112. That's the part. As the cleaning solution, as described above, seawater, fresh water mixed with an alkali additive, and the like may be used.

The first pretreatment injection means 112 cools the exhaust gas introduced through the exhaust gas inlet 1112. The exhaust gas introduced through the gas inlet 1112 generally has a temperature of 250 ° C. to 350 ° C., and the temperature is lowered to 50 ° C. to 50 ° C. by the cleaning liquid injected by the first pretreatment injection means 112. The volume is reduced.

In addition, the first pretreatment injection means 112 allows PM to be collected primarily by the cleaning liquid, especially among the harmful substances in the exhaust gas. Exhaust gas in contact with the cleaning liquid injected by the first pretreatment injection means 112 passes through the stirring means 113, the flow path of which is changed from a straight line to a spiral, and the second pretreatment injection means 114 to be described later It comes in contact with the sprayed cleaning liquid. As a result, the cleaning solution in which the first pretreatment injection means 112 collects harmful substances is increased in size and moved to the lower portion of the preprocessor housing 111 by gravity.

Preferably, the first pretreatment injection means 112 sprays the cleaning liquid in the form of fine droplets as compared to the second pretreatment injection means 114. Specifically, the first pretreatment injection means 112 may be characterized in that to spray the cleaning liquid in the form of droplets having a particle size of 100 ~ 200㎛. Among the harmful substances of the exhaust gas, PM has a particle size of about 0.1 to 0.5 μm, and when the cleaning liquid is sprayed in the form of droplets having a particle size of 100 to 200 μm, it is effective to efficiently aggregate and aggregate the PM into the cleaning liquid. .

8 and 9, in one embodiment of the present invention, the first pretreatment injection means 112 includes a rod-shaped injection body 1121 and an injection hole 1122 formed at one end of the injection body 1121. It includes, and the injection body 1121 may be supplied with the cleaning liquid and compressed air from the cleaning liquid supply means (not shown) through the cleaning liquid inlet 1114. The injection body 1121 receives a cleaning liquid together with compressed air and delivers the cleaning liquid to the injection hole 1122, and the injection hole 1122 injects the cleaning liquid toward the exhaust gas.

On the other hand, the first pretreatment injection means 112 is disposed horizontally on a cross section perpendicular to the traveling direction of the exhaust gas on the flow path of the exhaust gas formed by the inner wall 1111 of the preprocessor housing 111, The inner wall 1111 is protruded toward the center of the flow path at regular angular intervals, and a plurality of the inner walls 1111 are disposed. Through such an arrangement, the cleaning liquid may be efficiently injected into the exhaust gas flowing into the exhaust gas inlet 1112 and traveling toward the stirring means 113.

The specific shape and arrangement of the first pretreatment injection means 112 may vary depending on the injection capacity of the first pretreatment injection means 112 and the overall length design of the preprocessor 11.

The stirring means 113 is disposed between the first pretreatment injection means 112 and the second pretreatment injection means 114 in the interior of the preprocessor housing 111 so that the exhaust gas on the flow path is curved, Preferably it is a part that serves to make the flow in a spiral. In one embodiment of the invention, the preprocessor housing 111 forms an exhaust gas flow path in the vertical direction from the top to the bottom, the stirring means 113 is introduced through the exhaust gas inlet 1112 The flow of exhaust gas which proceeds in a straight downward direction is thus converted into a curved, preferably spiral.

When the flow on the flow path of the exhaust gas is changed from a straight line to a curved line by the stirring means 113, the flow path is lengthened, and as a result, the washing liquid sprayed by the second pretreatment injection means 114 and Will increase the contact time. As a result, the proportion of harmful substances such as PM and SOx in the exhaust gas is increased by the cleaning liquid. Therefore, the stirring means 113 is preferably disposed adjacent to the exhaust gas inlet 1112.

In this way, the agitation means 113 can improve the removal time of harmful substances in the exhaust gas compared to the internal space of the preprocessor housing 111, without further increasing the height of the preprocessor 11 or further. Even if the height is reduced, the efficiency of removing harmful substances in the exhaust gas can be improved. As a result, the size of the equipment can be reduced.

10 and 11, the stirring means 113 is disposed covering the flow path, and includes a central body 1131, a plurality of wings 1132, and a space portion 1133. The flange portion 1334 coupled to the outside of the 1132 is seated on the stepped 1111a formed on the inner wall 1111 of the preprocessor housing 111. If necessary, the stirring means 113 may be arranged in the form of being coupled to the inner wall 1111 of the preprocessor housing 111 by welding or the like.

The body 1131 is a portion that is the center of the stirring means 113, the wing 1132 is radially coupled to the body 1131 with a predetermined torsion angle. In addition, the space portion 1133 is a portion that forms a space in which the exhaust gas can pass between the wings 1132 without hitting each of the wings 1132.

As shown in Figure 10, in one embodiment of the present invention, the stirring means 113, six wings 1132 are coupled at a predetermined angle twisted at an interval of 30 degrees along the outer surface of the body 1131 The space portion 1133 is formed between the wings 1132.

When the stirring means 113 is configured as described above, the flow of the exhaust gas passing through the stirring means 113 is helically formed, and the exhaust gas is formed by the inner wall 1111 of the preprocessor housing 111. It can be formed in a symmetrical form along the center of the flow direction of the flow path, the flow is smooth, by the cleaning liquid sprayed by the first pretreatment injection means 112 and the second pretreatment injection means 114 Hazardous substances in the trapped exhaust gas may flow down the inner wall 1111 of the housing 111.

On the other hand, when the space portion 1132 does not appear between the blades 1132, the exhaust gas introduced through the exhaust gas inlet 1112 receives excessive pressure loss when passing through the stirring means 113. Therefore, it is not preferable in view of the flow of the exhaust gas.

In addition, the stirring means 113 is preferably characterized in that it is fixed without rotation. This is because the exhaust gas flowing through the exhaust gas inlet 1112 generally has a sufficient fluid supply speed toward the pretreatment gas outlet 1113, so that it is necessary to supply a separate straight energy to the exhaust gas on the flow path. Because there is no.

The second pretreatment injection means 114 is disposed between the stirring means 113 and the pretreatment gas outlet 1113 in the preprocessor housing 111 and passes through the stirring means 113 through the flow path. It is a part that injects the cleaning liquid into the exhaust gas proceeding helically.

The second pretreatment injection means 114 is curved toward the pretreatment gas outlet 1113 located in the lower portion of the preprocessor housing 111 via the stirring means 113, preferably exhaust gas proceeding helically. By further spraying the cleaning solution on the surface, the first pretreatment injection means 112 is sprayed by the first pretreatment injection means 112 to induce aggregation of the cleaning solution in the state of collecting harmful substances such as PM contained in the exhaust gas, thereby making the size larger. The inner wall 1111 of the processor housing 111 flows down or falls to the lower portion of the preprocessor housing 111.

The second pretreatment injection means 114 is injected by the first pretreatment injection means 112 as described above to increase the size of the cleaning liquid in the state of collecting harmful substances such as PM in the exhaust gas. It is preferable to spray the cleaning liquid having a larger particle diameter than the cleaning liquid sprayed by the injection means 112. Specifically, the second pretreatment injection means 114 preferably sprays the cleaning liquid in the form of droplets having a particle diameter of 500 μm to 1,000 μm.

12 and 13, in one embodiment of the present invention, the second pretreatment injection means 114 is a rod-shaped injection body 1141 and a plurality of branches branched side by side at a predetermined interval from the injection body 1141. Jet nozzles 1142 and a plurality of jet holes 1143 formed at predetermined intervals in the jet nozzles 1142. The injection body 1141 may be supplied with a cleaning liquid and compressed air from the cleaning liquid supply means (not shown) through the cleaning liquid inlet 1114. The injection body 1141 receives the cleaning solution together with the compressed air and delivers the cleaning solution to each of the injection ports 1142, and the injection hole 1143 injects the cleaning solution toward the exhaust gas.

The second pretreatment injection means 114 has a structure in which the injection hole 1143 for injecting the cleaning liquid is more densely arranged than the first pretreatment injection means 112, which passes through the stirring means 113. This is because it is advantageous to evenly spray the cleaning liquid without the dead zone toward the exhaust gas which spirally flows through the flow path.

As described above with respect to the first pretreatment injection means 112, the specific shape and arrangement of the second pretreatment injection means 114 may also include the injection capacity of the second pretreatment injection means 114 and the preprocessor 11. ) May vary depending on the overall length of the design.

The connection part 12 is a part for moving the pretreatment gas, which is the exhaust gas of which the harmful substances are primarily reduced, from the preprocessor 11 to the aftertreatment 13. 4 to 6, one end of the connection part 12 communicates with a pretreatment gas outlet 1113 of the preprocessor housing 111, and the other end of the connection part 12 has a pretreatment gas inlet part of the postprocessor housing 131. 1312).

The aftertreatment 13 additionally removes harmful substances in the pretreatment gas, which is an exhaust gas in which the harmful substances are primarily reduced by the pretreatment 11. 3 to 5 and 14, the post processor 13 includes a post processor housing 131, a diffusion means 132, a packing 133, a packing support means 134, and a first post treatment injection means ( 135), the second after-treatment injection means 136, the water separation means 137, washing means 138, the water blocking means 139.

The aftertreatment housing 131 forms an external shape of the aftertreatment 13 and forms a flow path of the pretreatment gas therein. The aftertreatment housing 131 includes an inner wall 1311, a pretreatment gas inlet 1312, a posttreatment gas outlet 1313, and a cleaning solution outlet 1315. As shown in Figures 4 and 14, in one embodiment of the present invention, the post-processor housing 131 is formed as a cylindrical tower, and moves the pre-treatment gas introduced through the lower one in the upward direction and in the pre-treatment gas Form a flow path through which additional hazardous substances can be removed.

The inner wall 1311 is a portion that forms a flow path of the pretreatment gas inside the post-processor housing 131. 4 and 14, the inner wall 1311 has a cylindrical flow path of the exhaust gas inside the post-processor housing 131.

The pretreatment gas inlet 1312 is a portion into which the pretreatment gas flows into the postprocessor housing 131. As shown in FIGS. 4 to 6 and 14, the pretreatment gas inlet 1312 is formed at one lower side of the aftertreatment housing 131, and the pretreatment gas introduced through the pretreatment gas inlet 1312. Is moved upward along the cylindrical flow path formed by the inner wall 1311.

The aftertreatment gas outlet 1313 is a portion from which the aftertreatment gas, which is a pretreatment gas from which harmful substances are additionally removed, is discharged from the aftertreatment unit 13. As shown in FIGS. 4 to 6 and 14, the aftertreatment gas outlet 1313 is formed at an upper portion of the aftertreatment housing 131 and is discharged through the aftertreatment gas outlet 1313. The treatment gas may be discharged to the atmosphere by removing the harmful substances from the exhaust gas by the pretreatment 11 and the aftertreatment 13.

The cleaning solution inlet 1314 is a portion into which the cleaning solution for injection in the post processor 13 flows. As can be seen through FIGS. 4 and 14, the cleaning solution inlet 1314 is connected to the first aftertreatment injection means 135, the second aftertreatment injection means 136, and the cleaning means 138, which will be described later. Or formed.

The cleaning solution outlet 1315 is the first aftertreatment injection means 135 or the first to remove harmful substances in the pretreatment gas introduced into the aftertreatment housing 131 through the pretreatment gas inlet 1312. The cleaning liquid jetted by the second post-process injection means 136 is discharged. As can be seen through FIGS. 4 to 6 and 14, the cleaning solution outlet 1315 is formed at the lower end of the aftertreatment housing 131, and the first cleaning post through the cleaning solution outlet 1315 is performed. The cleaning liquid sprayed by the treatment injection means 135 and the second aftertreatment injection means 136 collects harmful substances in the pretreatment gas and moves to the lower end of the aftertreatment housing 131 to be discharged to the outside. do. In order to smoothly discharge the cleaning solution, the lower end of the post-processor housing 131 may be formed in a shape that converges toward the cleaning solution outlet 1315.

The diffusion means 132 is a portion which is disposed adjacent to the pretreatment gas inlet 1312 in the post processor housing 131 to diffuse the pretreatment gas introduced through the pretreatment gas inlet 1312. 15 to 17, the diffusion means 132 is disposed to be spaced apart in front of the pretreatment gas inlet 1312, and includes a body 1321 and a fastening part 1322.

The body 1321 is disposed to cover the front of the pretreatment gas inlet 1312 and has a diffuser 1321a through which the pretreatment gas can pass. The body 1321 may be formed of a plate member. As shown in FIGS. 16 and 17, the body 1321 is generally formed to vertically cover the front of the pretreatment gas inlet 1312, and the top and bottom of the body 1321 are the pretreatment gas. The inclined or curved paper toward the inlet portion 1312 may be formed in a shape.

In more detail, an upper end of the body 1321 is formed to be inclined upward toward the pretreatment gas inlet 1312, and a lower end of the body 1321 is inclined downward toward the pretreatment gas inlet 1312. Formed. Through the shape of the body 1321, the pretreatment gas introduced through the pretreatment gas inlet 1312 may be uniformly diffused forward and upper and lower portions. The body 1321 may be formed in the form of a curved sheet as a whole, not only inclined or curved sheets, the upper and lower ends.

The diffusion part 1321a may include a plurality of holes, and the diffusion part 1321a may be formed of a plurality of holes formed uniformly. However, the diffusion part 1321a is not limited to the through hole, and the diffusion part 1321a may be formed in the form of a slit or the like.

The area or shape of the body 1321, the size, shape, number, etc. of the diffusion part 1321a may vary depending on the processing capacity of the post processor 13.

The fastening part 1322 is a part which allows the diffusion means 132 to be fixed to the inside of the after processor housing 131 by being fastened to the fixing part 1311 b formed in the after processor housing 131. . 15 and 16, the fastening part 1322 is vertically extended or bent from the left and right ends of the body 1321 to the pretreatment gas inlet part 1312. By being fastened to the fixing part 1311b formed in the post processor housing 131, the diffusion means 132 may be fixed to the inside of the post processor housing 131.

The pretreatment gas, which is an exhaust gas of which the harmful substances are primarily reduced by the pretreatment 11, is discharged to the pretreatment gas outlet 1312 because the flow path is helically changed by the stirring means 113. Thus, even when flowing into the pretreatment gas inlet 1312 through the connecting portion 12, it has a certain amount of rotational energy. Accordingly, the flow is concentrated toward the pretreatment gas inlet 1312 of the inner wall 1311 of the postprocessor housing 131 while entering the inside of the postprocessor housing 131, and inside the postprocessor housing 131. It is not evenly distributed in the flow path of the pretreatment gas formed in the filter.

The diffusion means 132 narrows the cross-sectional area when the pretreatment gas flows into the aftertreatment housing 131 and serves as a nozzle so that the pretreatment gas flows into the aftertreatment housing 131. Allows to spread evenly. This allows the pretreatment gas to be evenly distributed on the flow path of the pretreatment gas formed inside the post-processor housing 131. That is, by evenly dispersing the pretreatment gas introduced into the packing 133 through the diffusion means 132, it is possible to increase the absorption efficiency of SOx of the pretreatment gas in the packing 133 and to collect other harmful substances. Efficiency can also be improved.

Meanwhile, as shown in FIGS. 15 and 16, two diffusion means 132 are disposed in front of the pretreatment gas inlet 1312 in succession, whereby diffusion by the diffusion means 132 is further increased. It can be made uniform.

The packing 133 is a portion for increasing the contact area between the cleaning liquid sprayed by the first aftertreatment injection means 135 and the second aftertreatment injection means 136 and the pretreatment gas, which will be described later. The packing 133 is disposed on the flow path of the pretreatment gas and the upper portion of the diffusion means 132 in the post-processor housing 131 to increase the gas / liquid contact area between the pretreatment gas and the cleaning liquid. Alternatively, it is possible to smoothly dissolve SOx, which is a harmful substance in the pretreatment gas, through a cleaning solution composed of fresh water or the like containing an alkali additive.

A plurality of fillers of the packing 133 is formed, and the filler may be made of steel, ceramic, plastic, or the like. In addition, the packing 133 may be formed of a random packing in which fillers are gathered and a structured packing having a predetermined pattern without a predetermined pattern. The packing 133 may vary in type and shape depending on the processing capacity and the length design of the post processor 13.

The packing supporting means 134 supports the packing 133 from the bottom, but diffuses the pretreatment gas. 18 and 19, the packing support means 134 covers the flow path of the pretreatment gas, the edge of the step 1311a protruding inward to the inner wall 1311 of the post-processor housing 131 The part rests and supports the packing 133 placed on the top. In the present invention, the packing support means 134 is characterized in that it has a diffusion function to diffuse the pretreatment gas in the lower portion of the packing 133.

The packing support means 134 includes a through part 134a formed to allow the pretreatment gas to pass therethrough and a support part 134b for supporting the packing. In detail, the support part 134a is a strand having a cross structure, and the through part 134a is formed by a through hole formed by the support part 134b. That is, the packing supporting means 134 forms the through portion 134a of the mesh structure by the supporting portion 134b having the cross structure. By reducing the resistance through such a mesh structure it is possible to reduce the pressure loss of the pretreatment gas.

The packing support means 134 increases the passage area of the pretreatment gas to minimize the pressure loss of the pretreatment gas by increasing the ratio of the diffusion part 134a, that is, the ratio of the perforation of the mesh structure, compared to the general mesh structure. Preferably, in detail, the area of the diffusion part 134a and the vertical projection area of the support part 134b are preferably about 2 to 4 to 1.

On the other hand, as shown in Figure 18, the support 134b is preferably characterized in that at least a portion has a twisted structure. When the support part 134b has the twisted structure as described above, the pretreatment gas that strikes the support part 134b of the pretreatment gas passing through the through part 134a is changed in its traveling direction along the twisted direction. As a result, the pretreatment gas can be diffused more widely, and more uniform and active dispersion and diffusion of the pretreatment gas is achieved.

In the present invention, the packing support means 134 does not merely support the packing 133, and evenly distributes the pretreatment gas introduced into the packing 133 in the entire lower area of the packing 133. . As a result, it is possible to increase the absorption efficiency of the SOx of the pretreatment gas in the packing 133 through the packing support means 134, and to improve the collection efficiency of other harmful substances.

On the other hand, the packing support means 134 preferably has a bent structure in which the peak portion (1341) and the valley portion (1342) are continuously connected side by side. Side by side successive bending structure improves the bearing capacity compared to the cross-sectional area allows the packing 133 can be more stably supported by the mountain (1341). Furthermore, such a structure allows the pressure of the pretreatment gas traveling toward the packing 133 to be uniformly distributed in the packing support means 134, and thus from the bottom of the packing 133 toward the packing 133. The flowing pretreatment gas is made to diffuse evenly to the bottom of the packing (133).

The first aftertreatment injection means 135 is a portion of the aftertreatment housing 131 disposed on the flow path of the pretreatment gas and spraying the cleaning liquid toward the pretreatment gas. The first aftertreatment injection means 135 is disposed on the packing 133 and sprays a cleaning solution toward the packing 133.

14, 20 and 21, in one embodiment of the present invention, the first post-process injection means 135 is a rod-shaped injection body (1351) and the injection body (1351) at regular intervals And a plurality of spraying rods 1352, which are branched side by side, and a plurality of spraying holes 1153 formed at predetermined intervals on each of the spraying rods 1352, and each of the spraying rods 1352 through the spraying body 1351. It may further include a cleaning liquid supply means (not shown) for supplying the cleaning liquid and compressed air. The cleaning liquid and compressed air supplied by the cleaning liquid supply means (not shown) are supplied to the injection body 1351 through the cleaning liquid inlet 1314. The injection body 1351 receives a cleaning liquid together with compressed air, and delivers the cleaning liquid to each of the spraying units 1352, and the injection hole 1353 injects the cleaning liquid toward the exhaust gas.

The specific shape and arrangement of the first aftertreatment injection means 135 may vary depending on the injection capacity of the first aftertreatment injection means 135 and the overall length of the aftertreatment 13.

The second aftertreatment injection means 136 is disposed on a flow path of the pretreatment gas in the interior of the aftertreatment housing 131 to inject a cleaning solution toward the pretreatment gas, but the first aftertreatment injection means 135 It is characterized in that it works independently. This independent operation can be made by the control of the controller C as shown in FIG. The controller C performs control so that the cleaning solution injection of the first after-treatment injection means 135 and the second after-treatment injection means 136 may be independently performed.

14, 20 and 21, in one embodiment of the present invention, the second after-treatment injection means 136 is a rod-shaped injection body 1361 and the injection body 1361 at regular intervals And a plurality of spraying rods 1362, which are branched side by side, and a plurality of spraying holes 1363 formed at predetermined intervals on each of the spraying rods 1362, and each of the spraying rods 1362 through the spraying body 1361. It may further include a cleaning liquid supply means (not shown) for supplying the cleaning liquid and compressed air. The cleaning liquid and compressed air supplied by the cleaning liquid supply means (not shown) are supplied to the injection body 1361 through the cleaning liquid inlet 1314. The injection body 1361 receives the cleaning liquid together with the compressed air and delivers the cleaning liquid to each of the injection rods 1362, and the injection hole 1363 injects the cleaning liquid toward the exhaust gas.

The specific shape, arrangement, and the like of the second aftertreatment injection means 136 are described in relation to the first aftertreatment injection means 135, and the injection capacity of the second aftertreatment injection means 136 and the post It may vary depending on the overall length design of the processor 13 and the like.

The second aftertreatment injection means 136 operates independently of the first aftertreatment injection means 135 so that the second aftertreatment injection means 136 is optional with the first aftertreatment injection means 135. This means that the cleaning liquid can be sprayed on or simultaneously. Therefore, when the amount of the exhaust gas generated by combustion and the amount of pretreatment gas flowing from the pretreatment 11 changes according to the load of the engine, it is possible to appropriately spray the cleaning liquid accordingly. Economical operation of the processor 13 is achieved.

The second aftertreatment injection means 136 is disposed above the first aftertreatment injection means 135 at regular intervals. When the second aftertreatment injection means 136 and the first aftertreatment injection means 135 are disposed on the same horizontal plane among the flow paths of the pretreatment gas, the resistance that hinders the flow of the pretreatment gas is increased. The second aftertreatment injection means 136 and the first aftertreatment injection means 135 are preferably arranged at different heights.

In addition, the first after-treatment injection means 135 and the second after-treatment injection means 136 are arranged at different heights, but are arranged to cross each other during vertical projection on the flow path of the pretreatment gas. More preferred. Through this arrangement, the cleaning liquid can be evenly sprayed on the pretreatment gas on the pretreatment gas flow path without a square area, and the removal of harmful substances in the pretreatment gas can be performed more efficiently.

Here, the mechanism of removing the harmful substances in the pretreatment gas through the cleaning liquid sprayed by the first aftertreatment injection means 135 and the second aftertreatment injection means 136 is as follows.

The pretreatment gas includes acidic substances such as sulfur oxides (SOx) and harmful substances such as PM, and the first aftertreatment injection means 135 and the second aftertreatment injection means 136 neutralize the harmful substances. The cleaning liquid is sprayed to agglomerate and remove. In general, 0.1 ~ 0.5um of PM is first agglomerated by fine water droplets (100 ~ 200um) increases in size. In addition, in order to neutralize the acidic sulfur oxides (SOx), a basic washing solution is required. When fresh water is used, a separate alkaline additive is added to induce a neutralization reaction.

At this time, the alkaline additive may be NaOH (sodium hydroxide), Na ₂ CO ₃ (sodium carbonate) or NaHCO ₃ (sodium bicarbonate). Neutralization reaction of sulfur oxide (SOx) by NaOH addition cleaning solution is as follows.

SO _{2 (g)} +2 NaOH _(aq) + (1/2) O _{2 (g)} → 2Na ⁺ + SO ₄ ^2- + H ₂ O

However, as described above, when the present invention is applied to a vessel, sea water, which is brine, may be used as a cleaning liquid. In general, water is sodium chloride (NaCl), magnesium chloride (MgCl _2), potassium chloride (KCl) containing a salt melt in which they occur Cl, such as ^-, SO ₄ ^2-, Br ^- the pH due to the negative ions, such as 7.8 ~ 8.3 degree Phosphorus weak basic. Therefore, if such seawater is used as a cleaning liquid, there is an advantage that neutralization of sulfur oxides (SOx) is possible without the addition of a separate alkaline additive.

At this time, the neutralization reaction by sea water is as follows, first, it is mixed with sulfur dioxide (SO ₂ ) water in the gas state.

SO _{2 (g)} + H ₂ O _(l) ↔ H ₂ SO _{3 (aq)}

It then reacts with the base in seawater, which is

_{2H 2 SO 3 (aq) +} OH - ↔ 2HSO 3 - (aq) + H + (aq) + H 2 O (aq)

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

In other words, sulfur dioxide is absorbed into seawater and undergoes the reaction to form sulfate.

The water separation means 137 is disposed above the second aftertreatment injection means 136 in the interior of the aftertreatment housing 131 to flow the pretreatment gas through the second aftertreatment injection means 136. It is the part that separates the microdroplets flowing through the path. The radiator separation means 137 is disposed in such a manner that the edge portion is seated on the stepped portion 1311a protruding inwardly into the inner wall 1311 of the post-processor housing 131.

The water separation means 137 serves to separate, filter, and recover an aerosol-type droplet or mist formed by the pretreatment gas and the cleaning liquid, and a vertical cross section is formed in a zigzag shape. ) May be arranged in a plurality arranged at regular intervals. In addition, the water separation means 137 may vary in a specific form according to the design, temperature and chemical characteristics of the post-processor 13, and the like.

The washing means 138 is disposed above the second aftertreatment injection means 136 and below the water separation means 137 in the interior of the aftertreatment housing 131 to separate the water separation means 137. It is the part which sprays a cleaning liquid toward.

14, 22 and 23, in one embodiment of the present invention, the cleaning means 138 is a rod-shaped injection body (1381), a plurality of branches branched side by side at regular intervals in the injection body (1381) And a plurality of injection holes 1383 formed at predetermined intervals on the injection rods 1382 and the injection rods 1382, and the cleaning liquid and the compressed air are supplied to the injection rods 1382 through the injection bodies 1381. It may further include a cleaning solution supply means for supplying (not shown). The cleaning liquid and the compressed air supplied by the cleaning liquid supply means (not shown) are supplied to the injection body 1341 through the cleaning liquid inlet 1314. The injection body 1381 receives the cleaning liquid together with the compressed air and delivers the cleaning liquid to each of the spray units 1382, and the injection hole 1383 injects the cleaning liquid toward the water separation means 137.

The water separation means 136 may be contaminated or blocked in the process of separating, filtering, and recovering fine droplets or mist in a state in which harmful substances such as PM and the like in the pretreatment gas are collected. By separating the separation means 137 by the cleaning solution to prevent contamination and blockage of the water separation means 136.

In addition, the cleaning means 138 by spraying the cleaning liquid to increase the size of the fine droplets or mist separated by the water separation means 137 to become a large droplet of fine droplets or mist trapping the harmful substances become the after-treatment Efficiently falls to the lower portion of the housing 131 or to flow down into the inner wall 1311 of the post-processor housing 131.

The drop blocking means 139 is a portion that rises through the inner wall 1311 of the after-treatment housing 131 and serves to block water droplets flowing out to the after-treatment gas outlet 1313. 14, 24 and 25, the drop blocking means 139 includes a blocking wall (1391). In addition, the water droplet blocking means 139 forms a collecting space (1392) for collecting the water droplets in the vicinity of the after-treatment gas outlet 1313 to prevent the water droplets outflow. The collection space 1392 is formed in a shape in which the collected drops can fall to the bottom.

The aftertreatment gas outlet 1313 is formed above the postprocessor housing 131 in an upward direction, and the water droplet blocking means 139 is downward from an edge of the aftertreatment gas outlet 1313. An extended barrier wall 1391 is included. The blocking wall (1391) forms a collecting space (1392) between the upper inner wall of the housing 131 of the post-processor. The upper inner wall 1311 of the housing 131 of the post-processor is converging toward the post-treatment gas outlet and is inclined, and the blocking wall 1391 is used to efficiently form the liquid and the collection space 1392. In order to effectively block the external discharge of the enemy is preferably characterized in that it is extended in the vertical direction.

The pretreatment gas rises along the flow path of the pretreatment gas formed in the aftertreatment 13 and becomes a posttreatment gas while additionally removing harmful substances, and is discharged to the outside through the aftertreatment gas outlet 1313. In this process, some of the water droplets consisting of the cleaning liquid which collects the harmful substances in the pretreatment gas are lifted on the inner wall 1311 of the aftertreatment housing 131 and moved toward the aftertreatment outlet 1313.

The water droplets moving to the vicinity of the edge of the aftertreatment gas outlet 1313 through the upper inner wall 1311 of the aftertreatment housing 131 are caught by the blocking wall 1391. In addition, a collection space (1392) is formed between the blocking wall (1391) and the inner wall (1311) of the after-treatment housing (131) around the after-treatment gas outlet (1313) to agglomerate the water droplets. Droplets aggregate in the collecting space (1392) to increase the size and weight of the droplets to fall to the bottom of the post-processor housing (131).

As such, the water droplet blocking means 139 blocks water droplets that collect harmful substances in the pretreatment gas from being discharged to the outside through the post processor outlet 1313, and is separated into a lower portion of the post processor housing 131. Let it fall

In the above, the Applicant has described various embodiments of the present invention, but these embodiments are merely one embodiment for implementing the technical idea of the present invention, and any changes or modifications may be made to the present invention as long as the technical idea of the present invention is implemented. It should be interpreted as falling within the scope of.

1: exhaust gas treatment system
2: manifold
3a, 3b, 3c: combustion device
4: piping
41: transfer conduit 41b: bypass conduit
411, 421, 431: backflow preventing means 412, 422, 432: blocking means
11: preprocessor
111: preprocessor housing
1111: inner wall 1112: exhaust gas inlet
1113: pretreatment gas outlet 1114: cleaning liquid inlet
1115: cleaning liquid outlet
112: first pretreatment injection means 113: stirring means
114: second pretreatment injection means
12: connection
13: Postprocessor
131: post-processor housing
1311: inner wall 1312: pretreatment gas inlet
1313: aftertreatment gas outlet 1314: cleaning liquid inlet
1315: cleaning liquid outlet
132: diffusion means 133: packing
134: packing support means 135: first post treatment injection means
136: second post treatment injection means 137: water separation means
138: washing means 139: water blocking means

Claims (11)

An exhaust gas processing device for introducing the exhaust gas generated by the combustion and injecting a cleaning liquid into the exhaust gas to remove harmful substances in the exhaust gas;
A piping portion for transferring the exhaust gas to the exhaust gas treating apparatus from at least two combustion apparatuses generating exhaust gas by combustion;
The piping unit connects each of the combustion apparatus and the exhaust gas treatment unit in a one-to-one correspondence, the transfer conduit for transferring the exhaust gas from the combustion apparatus to the exhaust gas treatment apparatus, and when the combustion apparatus is stopped. And a backflow preventing means capable of preventing the backflow of the cleaning liquid from the exhaust gas treatment device to the stopped combustion apparatus,
The backflow preventing means is disposed in each of the conveying conduits so as to block the connection between each of the combustion device and the exhaust gas treatment device.
The exhaust gas treating apparatus further includes a preprocessor which firstly reduces harmful substances in the exhaust gas generated by combustion, and additionally removes harmful substances in the pretreatment gas which is exhaust gas in which the harmful substances are firstly reduced by the preprocessor. Include a post processor connected through a connection,
The after-treatment unit has a pre-treatment gas inlet through which the pre-treatment gas is introduced, and a post-treatment gas outlet through which the after-treatment gas from which harmful substances are additionally removed by the after-treatment is discharged. Processor housing,
It is disposed adjacent to the pretreatment gas inlet comprises a diffusion means for diffusing the pretreatment gas flowing through the pretreatment gas inlet,
The diffusion means includes a body having a diffusion portion that is disposed to cover the front of the pre-treatment gas inlet in a state spaced in front of the pre-treatment gas inlet in the interior of the post-processor housing, the pre-treatment gas can pass through,
The body is formed in the form of vertically covering the front of the pretreatment gas inlet, the top and bottom are formed in the form of inclined or curved upward and downward, respectively, toward the pretreatment gas inlet side,
And the diffusion portion includes a plurality of through holes for minimizing pressure loss of the exhaust gas flowing through the diffusion means in the exhaust gas treatment apparatus.
delete The method of claim 1,
The pipe section further includes a bypass conduit branched between each of the combustion device and each of the backflow preventing means of each of the transfer conduits to provide a bypass to exhaust gas generated in each of the combustion devices. Exhaust gas treatment system.
The method of claim 3,
And the pipe portion further includes blocking means disposed in each of the bypass conduits to block bypass of the exhaust gas to the bypass conduit.
The method of claim 1,
The piping unit further comprises a manifold to allow the exhaust gas moved through each of the conveying conduit to be introduced into the exhaust gas treatment device, exhaust gas treatment system having a backflow prevention means.
The method of claim 1,
The exhaust gas treatment system having the backflow preventing means is installed on a ship, and the harmful substance includes sulfur oxides (SOx).
The method of claim 1, 3 to 6, wherein the preprocessor,
A pretreatment unit including an exhaust gas inlet unit through which the exhaust gas is introduced and a pretreatment gas outlet unit through which a pretreatment gas, which is an exhaust gas of which harmful substances are first reduced, is discharged from the preprocessor and forming a flow path of the exhaust gas therein; Aging means for making the exhaust gas on the flow path flows in a curved shape, and the cleaning liquid is injected between the exhaust gas inlet and the stirring means to spray the cleaning liquid to the exhaust gas introduced through the exhaust gas inlet And a second pretreatment injection means disposed between the pretreatment injection means and the agitating means and the pretreatment gas outlet, for injecting a cleaning liquid into the exhaust gas that curves the flow path via the stirring means. Exhaust gas treatment system having a backflow prevention means.
The method of claim 7, wherein
The aftertreatment further comprises a water drop blocking means for blocking the water drops flowing out through the inner wall of the after-treatment housing to the after-treatment gas outlet portion, the exhaust gas treatment system having a backflow preventing means.
The method of claim 8,
The post processor is located below the drop blocking means,
First post-treatment injection means disposed on a flow path of the pretreatment gas and spraying a cleaning liquid toward the pretreatment gas;
And a second aftertreatment injection means disposed on the flow path of the pretreatment gas, the second solution being sprayed toward the pretreatment gas and operating independently of the first aftertreatment injection means. Exhaust gas treatment system.
The method of claim 9,
The post processor,
A packing disposed under the first post-processing injection means and the second post-processing injection means in the post-processor housing;
And a packing support means for supporting the packing at the bottom but having a diffusion function to diffuse the pretreatment gas at the bottom of the packing.
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