KR101964959B1 - A Hybrid Type Exhaust Gas Treatment System for Automatic Control on Supply Mode of Scrubbing Solution Based on the Location Information and a Method thereof - Google Patents

Abstract

According to one embodiment of the present invention, an automatic control hybrid type exhaust gas treatment system of a position information-based cleaning liquid supply method of the present invention is an exhaust gas treatment system installed in a ship, the exhaust gas generated by combustion is introduced, An exhaust gas treatment device for injecting a cleaning liquid into the exhaust gas to remove harmful substances in the exhaust gas and to discharge the injected cleaning liquid; positioning means for positioning the vessel; and positioning means for positioning the vessel positioned by the positioning means (Open mode) in which an external cleaning liquid is supplied to the exhaust gas treatment apparatus to discharge the external cleaning liquid to the outside after use, or a closed mode in which the internal cleaning liquid is recycled, And control means for performing control so as to control the operation.

Description

Technical Field [0001] The present invention relates to a hybrid type exhaust gas treatment system, and more particularly to a hybrid type exhaust gas treatment system,

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a position information-based cleaning fluid supply system automatic control hybrid type exhaust gas treatment system and method, and more particularly to a system and method for supplying a cleaning fluid to an exhaust gas treatment apparatus of a ship, A position information-based cleaning liquid supply system for automatically controlling an open mode for discharging the exhaust gas after use and a closed mode for recycling the internal cleaning liquid, and a hybrid type exhaust gas treatment system and method .

Most modern ships are equipped with engines and boilers for their own power and heating. In order to drive the engine and the boiler, fuel must be burned. The exhaust gas generated in the combustion process includes harmful substances such as SOx, NOx, PM (Particular Matter, Particulate Material) have.

Sulfur oxides and nitrogen oxides can cause respiratory illness by acting on the mucous membranes of the human body, and they are pollutants designated by the International Agency for Research on Cancer (WHO) as a primary carcinogen. When the SOx and NOx are released into the air as they are, they react with water (H ₂ O) in the atmosphere and become sulfuric acid (H ₂ SO ₄ ) and nitric acid (HNO ₃ ), respectively.

PM is a form of small particles compared to gaseous pollutants. PM is emitted into the atmosphere as it is, and it can cause visibility disorder that reduces visibility, or fine particles can enter the human body through the lungs or respiratory tract and cause various diseases . In recent years, fine dust that is a problem in Korea is also caused by PM, which is considered to be the main cause of air pollution.

Therefore, it is necessary to prevent such harmful substances in the exhaust gas. In particular, in the case of a ship, it is known that the output of the engine is large, so that it emits exhaust gas of 130 times that of a passenger car. In order to prevent the emission of a large amount of harmful substances Specific and practical measures are required for the exhaust gas of the ship.

Therefore, the International Maritime Organization (IMO) has set up an Emission Control Area (ECA) to limit the emission of hazardous substances in the sea area. In particular, the SOx Emission Control Area (SECA) has been stricter than the ECA, which regulates other harmful substances such as NOx.

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

In addition to the ECA, legislation to regulate the SOx content in the exhaust gas to 3.5% or less in the waters around the world is scheduled to be implemented by 2020 from 0.5% at the IMO General Assembly held on October 28, 2016, The need for sulfuric acid management is growing even more.

In order to comply with such international regulations, LNG propellant lines, which use low sulfur or low sulfur oxides as fuel, are used, and scrubbers that reduce sulfur oxides are used. It is also used.

It is economically advantageous to perform the exhaust gas treatment process using a scrubber to satisfy the above-mentioned regulations even with a low-cost fuel having a relatively high sulfur content and to prevent environmental pollution. The scrubber ionizes the SOx with the cleaning liquid. When the sea water (pH 8.3) or the fresh water containing the alkaline additive is used as the cleaning liquid, the ionized sulfur oxide can be neutralized. In addition, the particulate matter may be agglomerated and discharged together with the cleaning liquid to prevent release into the atmosphere.

Conventionally, a method of supplying a scrubbing liquid to a scrubber of a ship is an open mode in which an external scrubbing liquid is supplied and discharged to the outside, and a closed mode in which an internal scrubbing liquid is recycled Respectively. In the open mode, seawater is supplied to the scrubbing liquid to be discharged to the sea after being used in the scrubber, and in the closed mode, fresh water containing the alkali additive is used as a scrubbing liquid to be continuously recirculated.

A scrubber with a hybrid type cleaning liquid supply method in which both of the open mode and the closed mode can be used is also presented. When the ship is operating within the above-mentioned emission control area, that is, in the ECA or SECA, It is preferable that the supply method is selected in the closed mode to prevent the sulfur oxides from being discharged to the outside. However, a technique for automatically controlling the cleaning liquid supply method of the hybrid type scrubber based on the position information of the ship has not yet been available.

The hybrid type scrubber requires a seawater pump for supplying external seawater in the open mode and a heat exchange medium for supplying the cooling medium to the heat exchanging part for lowering the temperature of the recirculating scrubbing liquid in the closed mode . However, in the conventional hybrid type scrubber, piping is inevitably complicated because these pumps are separated from each other and the space utilization is very low.

In addition, when the ship sails in a region where the sea water temperature is high, such as near the equator, the heat exchange efficiency of the sea water is lowered. However, in the conventional hybrid type scrubber, the capacity of the heat exchange pump for supplying the cooling medium to the heat exchanger is limited as compared with the seawater pump. Accordingly, when the scrubbing liquid is supplied to the scrubber in the closed mode when the temperature of the seawater is high, there is a problem that the cooling efficiency of the scrubbing liquid drops during the recycling of the scrubbing liquid

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

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems of the prior art,

SUMMARY OF THE INVENTION It is an object of the present invention to provide a position information-based cleaning liquid supply method automatic control hybrid type exhaust gas processing system and method which enables a cleaning liquid supply method of a ship's exhaust gas processing apparatus to be changed and controlled based on the position of a ship.

Another object of the present invention is to provide a position information-based cleaning liquid supply system for automatically controlling the supply of cleaning liquid in such a manner that a predetermined cleaning liquid is recycled to the exhaust gas processing apparatus when the position of the vessel is within ECA or SECA, Processing system and method.

It is a further object of the present invention to provide a position information-based cleaning liquid supply system that can maximize the space utilization of the ship by simplifying the piping while applying the cleaning liquid supply system to the exhaust gas processing apparatus of the ship. System.

A further object of the present invention is to provide a location information-based cleaning liquid supply system that supplies seawater as a washing liquid or a heat exchange medium, and enables the heat exchange to be smooth even if the supply capacity is sufficient and the sea water temperature is high. System.

It is still another object of the present invention to provide a position information-based cleaning liquid supply system automatic control system capable of efficiently removing harmful gas in the discharge cleaning liquid of an exhaust gas processing apparatus through an exhaust gas processing apparatus having improved space utilization and harmful substance removal efficiency And to provide a hybrid type exhaust gas processing system.

It is still another object of the present invention to provide a position information-based cleaning liquid supply system that can efficiently remove harmful substances including sulfur oxides (SOx) in the exhaust gas discharged from an engine or a boiler of the ship, Processing system.

In order to achieve the above object, the present invention is implemented by the following embodiments.

According to one embodiment of the present invention, an automatic control hybrid type exhaust gas treatment system of a position information-based cleaning liquid supply method of the present invention is an exhaust gas treatment system installed in a ship, the exhaust gas generated by combustion is introduced, An exhaust gas treatment device for injecting a cleaning liquid into the exhaust gas to remove harmful substances in the exhaust gas and to discharge the injected cleaning liquid; positioning means for positioning the vessel; and positioning means for positioning the vessel positioned by the positioning means (Open mode) in which an external cleaning liquid is supplied to the exhaust gas treatment apparatus to discharge the external cleaning liquid to the outside after use, or a closed mode in which the internal cleaning liquid is recycled, And control means for performing control so as to control the operation.

According to another embodiment of the present invention, there is provided an automatic control hybrid type exhaust gas treatment system for a position information-based cleaning liquid supply system according to the present invention, wherein the control means controls the position of the ship positioned by the positioning means according to an ECA (Emission Control Area) It is determined whether it is within the SECA (sulfur emission control area).

According to another embodiment of the present invention, the position information-based cleaning liquid supply method automatic control hybrid type exhaust gas processing system of the present invention is characterized in that the control means controls the position of the ECA or the SECA area, A certain area is derived as ECA or SECA.

According to another embodiment of the present invention, there is provided an automatic control hybrid type exhaust gas treatment system for a position information-based cleaning liquid supply system according to the present invention, wherein the control means controls the exhaust gas treatment device So that the cleaning liquid is supplied to the closed mode.

According to another embodiment of the present invention, there is provided an automatic control hybrid type exhaust gas processing system of a position information-based cleaning liquid supply method according to the present invention, comprising: an external cleaning liquid supply means for supplying an external cleaning liquid to the exhaust gas processing apparatus in the open mode And the external cleaning liquid supply means supplies the external cleaning liquid to the heat exchange medium to lower the temperature of the recirculated internal cleaning liquid in the closed mode.

According to another embodiment of the present invention, the position information-based cleaning liquid supply method automatic control hybrid type exhaust gas treatment system of the present invention is characterized in that the exhaust gas purifying apparatus includes: A first conduit disposed in the first conduit, a second conduit branching between the external cleaning fluid supply means and the first valve of the first conduit and connected to the heat exchange means, And a second valve disposed therein.

According to another embodiment of the present invention, there is provided an automatic control hybrid type exhaust gas treatment system for a position information-based cleaning liquid supply system according to the present invention, wherein the control means controls the first valve to open in the open mode, And controls the first valve and the second valve such that the first valve is closed and the second valve is opened in the closed mode.

According to another embodiment of the present invention, there is provided an automatic control hybrid type exhaust gas treatment system of a location information-based cleaning liquid supply system according to the present invention, wherein the harmful substance includes sulfur oxides (SOx), the external cleaning liquid is seawater, And the external cleaning liquid supply means includes a seawater pump for transporting seawater outside the ship.

According to another embodiment of the present invention, there is provided an automatic control hybrid type exhaust gas treatment system of a position information-based cleaning liquid supply method according to the present invention, wherein the exhaust gas treatment device is a device for selectively removing harmful substances from exhaust gas generated by combustion And a post-processor connected to the noxious gas removing unit to additionally remove harmful substances in the pretreatment gas, which is an exhaust gas whose noxious substances are primarily reduced by the pretreatment unit, wherein the pretreatment unit is configured to remove A preprocessor housing having an exhaust gas inlet portion for exhausting the exhaust gas and a pretreatment gas outlet portion for exhausting a pretreatment gas as an exhaust gas whose primary harmful substances are reduced in the pretreatment processor and forming a flow path of the exhaust gas therein; An agitating means for causing the exhaust gas on the exhaust gas to flow in a curved shape, A first pretreatment spraying means disposed between the gaseous inflow portion and the agitating means for spraying a cleaning liquid to the exhaust gas flowing through the exhaust gas inflow portion and a second pretreatment spraying means disposed between the agitating means and the pretreatment gas outflow portion, And a second pre-treatment injection means for injecting the cleaning liquid into the exhaust gas traveling in a curved shape through the flow path.

According to another embodiment of the present invention, there is provided a position information-based cleaning liquid supply system automatic control hybrid type exhaust gas treatment system according to the present invention, wherein the post-processor includes a pre-treatment gas inlet portion into which the pre- A post-treatment housing having a post-treatment gas outlet through which a process gas flows out after the harmful substance is additionally removed, and forms a flow path of the pre-treatment gas therein; And a numerical aperture blocking means for blocking the water flowed out to the outlet portion.

According to another embodiment of the present invention, there is provided a position information-based cleaning liquid supply system automatic control hybrid type exhaust gas treatment system according to the present invention, wherein the post-processor is provided at a lower portion of the water- A first post-treatment jetting unit disposed in the flow path of the pre-treatment gas to jet the cleaning liquid toward the pre-treatment gas, and a second post-treatment jetting unit configured to jet the cleaning liquid toward the pre- And a second post-processing injection means.

According to another embodiment of the present invention, there is provided an automatic control hybrid type exhaust gas treatment system for a position information-based cleaning liquid supply system according to the present invention, wherein the post-processor includes a first post- A packing disposed at a lower portion of the second post-treatment injection means, and a packing supporting means having a diffusion function for supporting the packing at the bottom and diffusing the pretreatment gas at a lower portion of the packing.

According to another embodiment of the present invention, there is provided a position information-based cleaning liquid supply system automatic control hybrid type exhaust gas treatment system according to the present invention, wherein the post-processor is disposed adjacent to the pretreatment gas inlet, And diffusing means for diffusing the pretreatment gas to be supplied to the gas.

According to another embodiment of the present invention, there is provided an automatic control hybrid type exhaust gas treatment system of a position-information-based cleaning liquid supply method of the present invention, wherein the exhaust gas treatment apparatus includes diffusion means, The exhaust gas flowing through the gas inlet including the gas diffuser is widely dispersed in the housing to enable an efficient cleaning operation and to prevent the pressure loss due to the falling cleaning liquid and the pressure loss due to the diffuser itself.

According to another embodiment of the present invention, there is provided an automatic control hybrid type exhaust gas treatment system according to the present invention, wherein the exhaust gas treatment apparatus further comprises a cleaning liquid injection means on the diffusion means, The spraying means includes a lateral spraying means for spraying the cleaning liquid to the side, so that the contact area between the exhaust gas dispersed in the diffusion means and the cleaning liquid is increased to improve the working efficiency, and the height of the housing is reduced to improve the space utilization .

According to another embodiment of the present invention, there is provided an automatic control hybrid type exhaust gas treatment system of a position information-based cleaning liquid supply method according to the present invention, wherein the exhaust gas treatment device further comprises a distributing means above the injecting means, The means includes a mesh structure including a plurality of small through holes and includes inclined portions in the form of an upwardly obliquely projected bulge which forms a large inflow hole on the lower side of the inclined portion so that the flow of exhaust gas deflected toward the inner wall surface And the treatment efficiency is improved by distributing evenly.

According to another embodiment of the present invention, there is provided an automatic control hybrid type exhaust gas treatment system of a position information-based cleaning liquid supply method according to the present invention, wherein the exhaust gas treatment device includes a first injection means, The first injection means, the second injection means, and the third injection means are arranged alternately up and down to enlarge the contact area with the exhaust gas, and the load of the engine or the boiler So that efficient operation is possible.

According to another embodiment of the present invention, there is provided an automatic control hybrid type exhaust gas treatment system according to the present invention, wherein the exhaust gas treatment device includes numerical separating means on the upper side of the multiple injection means, The number separating means includes at least one induction portion in which exhaust gas enters and a wing formed in the upper portion of the induction portion at the center thereof so that the helical flow of the exhaust gas from the induction portion is induced.

According to another embodiment of the present invention, there is provided an automatic control hybrid type exhaust gas treatment system according to the present invention, wherein the exhaust gas treatment device includes a water collecting part for collecting water bodies separated by the water separating part And means for preventing the release of harmful substances into the atmosphere.

According to another embodiment of the present invention, there is provided an automatic control hybrid type exhaust gas treatment system of a position information-based cleaning liquid supply method according to the present invention, wherein the exhaust gas treatment device comprises a water- And the water blocking means includes a blocking wall extending downward from one side of the slope so as to effectively block the water droplet that rises on the inner wall.

According to another embodiment of the present invention, there is provided a hybrid exhaust gas treatment method having improved space utilization of the present invention, comprising: a positioning step in which a positioning means determines a position of a ship; A method in which the cleaning liquid is injected into the exhaust gas to remove the noxious gas in the exhaust gas and the cleaning liquid is supplied to the exhaust gas processing device for discharging the sprayed cleaning liquid is detected by the position of the ship positioned by the positioning means A control method of controlling the cleaning liquid supply system to perform control so as to alternatively perform an open mode in which the external cleaning liquid is supplied to the outside and then discharged to the outside or a closed mode in which the internal cleaning liquid is recycled .

According to another embodiment of the present invention, there is provided a hybrid exhaust gas treatment method having improved space utilization according to the present invention, wherein in the control of the cleaning liquid supply method, when the position of the ship is within ECA or SECA, And the control is performed such that the cleaning liquid supply method to the gas processing apparatus becomes the closed mode.

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

The present invention provides an automatic control hybrid type exhaust gas treatment system and method based on positional information based on a positional information which enables a cleaning liquid supply method of a ship's exhaust gas treatment apparatus to be changed and controlled based on the position of a ship.

The present invention relates to a position information-based rinse solution supply system automatic control hybrid type exhaust gas processing system and method for allowing a rinse solution supply to proceed in such a manner that a certain rinse solution is recycled and supplied to the exhaust gas treatment apparatus when the position of the vessel is within ECA or SECA .

The present invention provides a position information-based cleaning liquid supply system automatic control hybrid type exhaust gas treatment system that maximizes space utilization of a ship by simplifying piping while applying a cleaning liquid supply system to a ship's exhaust gas treatment system. .

The present invention provides an automatic control hybrid type exhaust gas treatment system based on a position information based cleaning liquid supply system that supplies seawater as a cleaning liquid or a heat exchange medium and has a sufficient supply capacity to enable heat exchange even when the temperature of seawater is high. Lt; / RTI >

The present invention relates to a position information-based cleaning fluid supply system that enables efficient removal of noxious gases in the exhaust cleaning solution of an exhaust gas treatment device through an exhaust gas treatment device having improved space utilization and harmful substance removal efficiency. Hybrid type exhaust gas treatment System.

The present invention provides a location information-based cleaning liquid supply system automatic control hybrid type exhaust gas treatment system that enables efficient removal of harmful substances including sulfur oxides (SOx) in the exhaust gas discharged from an engine or a boiler of the ship Effect.

1 is a schematic diagram of an automatic control hybrid type exhaust gas treatment system based on a position information-based cleaning liquid supply system according to an embodiment of the present invention
Fig. 2 is a detailed view of the configuration excluding the positioning means and the control means in Fig. 1. Fig.
Fig. 3 is a view showing the flow of the external cleaning liquid in Fig. 2 in the open mode
Fig. 4 is a view showing the flow of the external cleaning liquid and the internal cleaning liquid in Fig.
5 is a perspective view of the exhaust gas processing apparatus according to the first embodiment.
6 is an exploded perspective view of the exhaust gas processing apparatus according to the first embodiment.
7 is a cross-sectional view taken along the line AA '
8 is a cross-sectional view of the exhaust gas treating apparatus according to the embodiment of the present invention,
9 is an exploded perspective view of a preprocessor of the exhaust gas processing apparatus according to the first embodiment.
10 is a sectional view taken along the line a1-a1 'in section A of Fig. 9
11 is a sectional view taken along the line a2-a2 'in the section A of Fig. 9
12 is a cross-sectional view taken along the line bb '
13 is a perspective view of the stirring means of the exhaust gas processing apparatus according to the first embodiment
14 is a cross-sectional view taken along the line c1-c1 '
Fig. 15 is a cross-sectional view taken along the line c2-c2 '
16 is an exploded perspective view of a post-processor of the exhaust gas processing apparatus according to the first embodiment
17 is a cross-sectional view taken along the line d1-d1 '
FIG. 18 is a cross-sectional view taken along the line d2-d2 '
19 is a perspective view of diffusion means of an exhaust gas processing apparatus according to the first embodiment;
20 is a perspective view of a packing supporting means of the exhaust gas treating apparatus according to the first embodiment;
FIG. 21 is a cross-sectional view taken along the line BB '
22 is a sectional view taken along the line e1-e1 '
23 is a sectional view taken along the line e2-e2 'in the section E of FIG.
FIG. 24 is a cross-sectional view taken along line ff '
25 is a view showing the cleaning process in Fig. 24
Fig. 26 is a cross-sectional perspective view of gg 'section of Fig. 16
Fig. 27 is a block diagram showing a numerical cut-off process in Fig.
28 is a perspective view of an exhaust gas processing apparatus according to the second embodiment
29 is an exploded perspective view of the exhaust gas processing apparatus according to the second embodiment.
30 is a sectional view of f1-f1 '
31 is an exploded perspective view showing diffusion means of the exhaust gas processing apparatus according to the second embodiment
32 is a sectional view taken along the line aa '
Fig. 33 is a sectional view taken along the line aa 'in section A of Fig. 29 showing a state in which the ship is inclined by rolling;
34 is a sectional view taken along the line aa 'in section A of Fig. 29 showing a state in which the exhaust gas flows
35 is a perspective view showing the injection means of the exhaust gas processing apparatus according to the second embodiment.
FIG. 36 is a cross-sectional view taken along the line b1-b1 '
37 is a cross-sectional view taken along line b2-b2 'of section B of Fig. 29
38 is a conceptual view showing a state in which the spraying means of the exhaust gas treating apparatus according to the second embodiment injects the cleaning liquid
39 is a perspective view showing the distributing means of the exhaust gas processing apparatus according to the second embodiment
FIG. 40 is a cross-sectional view taken along the line c1-c1 '
FIG. 41 is a cross-sectional view taken along the line c2-c2 '
Fig. 42 is a cross-sectional view taken along the line c1-c1 'of section A, B, and C of Fig. 29 showing how the exhaust gas flows
43 is a perspective view showing the multiple injection means of the exhaust gas processing apparatus according to the second embodiment
FIG. 44 is a cross-sectional view taken along the line d1-d1 '
45 and 46 are cross-sectional views taken along the line d2-d2 '
47 is an exploded perspective view showing the first type of water separating means of the exhaust gas treating apparatus according to the second embodiment;
Fig. 48 is a sectional view taken along the line e1-e1 'in section E of Fig.
49 is a sectional view taken along the line e2-e2 'in the section E of FIG. 29
50 is a perspective view showing a state in which exhaust gas flows by the first type of water separating means of the exhaust gas treating apparatus according to the second embodiment;
51 is an exploded perspective view showing a second type of water separating means of the exhaust gas treating apparatus according to the second embodiment;
Fig. 52 is a sectional view taken along the line e1-e1 'in section E of Fig.
Fig. 53 is a sectional view taken along the line e2-e2 'in the section E of Fig.
54 is a perspective view showing a state in which the exhaust gas flows by the second type of water separating means of the exhaust gas processing apparatus according to the second embodiment
Fig. 55 is a perspective view of sections E and D of Fig.
FIG. 56 is a sectional view taken along the line e1-e1 'of the section E and D of FIG. 29
57 is a partially cutaway perspective view showing the numerical cut-off means of the exhaust gas processing apparatus according to the second embodiment
58 is a sectional view taken along the line f1-f1 'in section F of Fig. 29
59 is a flow chart of a position information-based cleaning liquid supply method automatic control hybrid type exhaust gas treatment method according to an embodiment of the present invention

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a position information-based cleaning liquid supply method automatic control hybrid type exhaust gas treatment system and method according to the present invention will be described in detail with reference to the accompanying drawings. Unless defined otherwise, all terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs and, if conflict with the meaning of the terms used herein, It follows the definition used in the specification. Further, the detailed description of known functions and configurations that may unnecessarily obscure the subject matter of the present invention will be omitted.

In the present invention, exhaust gas means a gas generated in the process of burning a fuel to drive an engine, a boiler, etc., and harmful substances in the exhaust gas include sulfur oxides (SOx), nitrogen oxides (NOx), particulate matter (PM), and the like. The location information-based cleaning liquid supply system automatic control hybrid-type exhaust gas treatment system and method according to the present invention are mainly intended for treating exhaust gas in a ship, but are not limited in application to ships.

FIG. 1 is a block diagram of an automatic control hybrid type exhaust gas treatment system based on a location information-based cleaning liquid supply system according to an embodiment of the present invention. Referring to FIG. 1, the position information-based cleaning liquid supply method automatic control hybrid type exhaust gas processing system according to an embodiment of the present invention includes an exhaust gas processing device 1, an external cleaning liquid supply device 2, An inner cleaning liquid circulating means 4 and a heat exchanging means 5, a positioning means 6 and a control means 7. [

The positioning means 6 serves to determine the position of the ship when the position information-based cleaning liquid supply system automatic control hybrid type exhaust gas treatment system of the present invention is applied to the ship. The positioning means 6 may include a GPS device or the like.

The control means (7) controls the supply of the cleaning liquid to the exhaust gas processing apparatus (1) based on the position of the ship positioned by the positioning means (6) open mode) or a close mode in which the internal cleaning liquid is recycled.

The control means 7 includes a control module 71 for controlling valves and devices of the exhaust gas processing apparatus 1 and various pipes connected to the control means 7 and a control module 71 for controlling positional information of an emission control area (ECA) And a database 72 associated with the database.

The control module 71 compares the position of the ship with the position information of the ECA or SECA stored in the database 72 to determine whether the ship is located within the ECA or SECA.

When the control module 71 determines that the ship is located within the ECA or SECA, the control module 71 additionally determines whether the method of supplying the cleaning liquid to the exhaust gas processing device 1 is the open mode or the closed mode, The connection between the external cleaning liquid supply means 2 and the exhaust gas processing apparatus 1 is cut off and the internal cleaning liquid circulating means 3 So that the recirculation of the exhaust gas is continued.

If the control module 71 determines that the ship is not located within the ECA or SECA, if the method of supplying the cleaning liquid to the exhaust gas processing device 1 is a closed mode, have.

In this case, the control module 71 determines whether or not the ECA or SECA area has more than two (2) or more Coordinates of the points are connected to derive a certain area as ECA or SECA and it can be determined whether the ship is located in the ECA or SECA based on whether the position information of the ship exists in the corresponding area.

Through such automatic control of the control means 7, the operation of the ship's exhaust gas treatment system for satisfying the sulfur emission regulation in the ECA or SECA of the IMO can be naturally operated.

2 is a detailed view of the configuration except for the positioning means and the control means in FIG. 1. Referring to FIG. 2, the position information-based cleaning liquid supply method automatic control hybrid type exhaust gas processing system of the present invention includes an exhaust gas processing apparatus 1 The first to sixth conduits C1 to 6 and the first to fourth valves C1 to C4 and the second to sixth conduits C1 to C4 and the second to sixth conduits C1 to C4, V1 to V4).

The exhaust gas treatment apparatus 1 is an apparatus for injecting exhaust gas generated by combustion and injecting a cleaning liquid into the exhaust gas to remove harmful substances in the exhaust gas and to discharge the injected cleaning liquid. In the case where the present invention is applied to a ship, the toxic substance includes sulfur oxides (SOx), and the washing liquid is fresh water containing seawater or an alkali additive. The exhaust gas treatment device 1 dissolves sulfur oxides (SOx) in the exhaust gas by supplying fresh water containing seawater or an alkali additive as a cleaning liquid and discharges the toxic substances.

The exhaust gas treating apparatus 1 will be described below with reference to the first embodiment 1a and the second embodiment 1b. In the first embodiment 1a and the second embodiment 1b, the cleaning liquid flows in through the cleaning liquid inflow portions 1114, 1314, and 1714, and the cleaning liquid is discharged through the cleaning liquid outflow portions 1115, 1315, and 1715 .

A method of supplying the cleaning liquid to the exhaust gas processing apparatus 1 includes an open mode in which an external cleaning liquid is supplied and discharged after use, and a close mode in which the internal cleaning liquid is recycled and used continuously , Which are alternatively selected by the control means (7).

The external cleaning liquid aeration means 2 functions to supply the external cleaning liquid to the exhaust gas processing apparatus 1 in the open mode. In the case where the present invention is applied to a ship, the external washing liquid may be seawater outside the ship, and the external washing liquid supplying means 2 may be a seawater pump for supplying seawater.

In the closed mode, the external cleaning liquid aeration means (2) supplies the external cleaning liquid to the heat exchange medium to the heat exchange means (4) for lowering the temperature of the recirculated internal cleaning liquid. In the closed mode, the supply of the external cleaning liquid to the exhaust gas processing apparatus 1 is not required. Meanwhile, since the internal cleaning liquid recirculated in the closed mode is discharged in the exhaust gas treating apparatus 1 at a high temperature, generally 250 to 350 ° C, and is discharged in a state where the temperature is raised, It is necessary to lower the temperature to flow into the exhaust gas processing apparatus 1 again. In the closed mode, the external cleaning liquid supply means 2 supplies the external cleaning liquid to the heat exchange medium to the heat exchange means 4 which functions to lower the temperature of the internal cleaning liquid to be recycled. Since the external cleaning liquid has a lower temperature than the internal cleaning liquid to be recycled, it is suitable for use as a heat exchange medium for lowering the temperature of the internal cleaning liquid.

In the closed mode, the external cleaning liquid supply means 2 supplies the external cleaning liquid to the heat exchange means 4 as a heat exchange medium. Therefore, in the present invention, the heat exchange means 4 is provided separately for supplying the heat exchange medium The heat exchange medium supply means, that is, the heat exchange pump, need not be separately arranged. Therefore, the piping can be simplified and the space utilization can be improved.

In addition, when the seawater pump is used as the external cleaning liquid supply means 2, the capacity of the external cleaning liquid supply means 2 is larger than that of conventionally used heat exchange pumps, Even if the seawater is supplied to the heat exchange medium by the external cleaning liquid supply means 2 in the close mode, the heat exchange efficiency can be ensured through a sufficient supply capacity.

The inner rinsing liquid storage means 3 is a portion for storing the inner rinsing liquid recirculated when the inner rinsing liquid recirculates in the closed mode. The cleaning liquid storage means 3 serves as a buffer tank for recycling the internal cleaning liquid, and a cleaning liquid storage tank can be used. As the internal cleaning liquid, fresh water containing an alkali additive may be used as described above.

The internal cleaning liquid storage means 3 may be connected to internal cleaning liquid supply means (not shown) for replenishing the internal cleaning liquid, and may be supplemented with the internal cleaning liquid through the internal cleaning liquid supply means.

The internal rinsing liquid circulating means 4 is connected to the exhaust gas processing device 1 in the closed mode, that is, when the connection between the external rinsing liquid supply means 2 and the exhaust gas processing device 1 is cut off And re-circulates it. The inner rinse liquid circulating means 4 may be a circulation pump that supplies a pressure for recirculating the inner rinsing liquid.

The heat exchanging unit 5 serves to lower the temperature of the internal cleaning liquid recirculated when the internal cleaning liquid circulating unit 4 recirculates the internal cleaning liquid. The heat exchanging means 5 may be a heat exchanger or the like.

Since the temperature of the exhaust gas flowing into the exhaust gas treating apparatus 1 reaches 250 to 350 ° C, the temperature of the internal cleaning liquid injected from the exhaust gas treating apparatus 1 is raised. Therefore, in order to ensure a satisfactory circulation and cleaning efficiency of the internal washer fluid, the temperature of the discharged internal washer fluid must be lowered and reintroduced into the exhaust gas treatment device 1. The heat exchanging means (5) lowers the temperature of the internal washing liquid recirculated by the internal washing liquid circulating means (4) for this purpose.

As described above, in the present invention, the external cleaning liquid supply means 2 supplies the external cleaning liquid to the heat exchange means 5 as a heat exchange medium. As a result, it is not necessary to use a separate heat exchange medium supply means, that is, a heat exchange pump, for supplying the heat exchange medium to the heat exchange means 4, thereby simplifying the piping and improving the space utilization.

The specific arrangement and connection relationship of the exhaust gas processing apparatus 1, the external cleaning liquid supply means 2, the internal cleaning liquid storage means 3, the internal cleaning liquid circulation means 4, and the heat exchange means 5 will be described with reference to FIG. The following is an example.

The external cleaning liquid supply means 2 is connected to the first conduit C1 which connects the external cleaning liquid supply means 2 to the cleaning liquid inlet portions 1114, 1314 and 1714 of the exhaust gas processing apparatus 1 And a first valve (V1) is disposed in the first conduit (C1). The second conduit C2 is branched between the external cleaning liquid supply means 2 and the first valve V1 of the first conduit C1 and connected to the external rinse liquid inlet portion 53 of the heat exchange means 5 And a second valve V2 is disposed in the second conduit C2. The third conduit C3 has one end connected to the rinse solution inflow portions 1114, 1314, and 1714 of the exhaust gas processing apparatus 1 and the other end formed with a connection portion 11 ' One end of the first conduit C1 is connected to the external cleaning liquid supply means 2 and the other end is connected to the connection portion 11 'of the third conduit C3.

One end of the fourth conduit C4 is connected to the rinse solution outlet portions 1115, 1315 and 1715 of the exhaust gas processing apparatus 1 and the other end thereof is connected to the rinse solution inlet portion 31 of the internal rinse solution storage means 3, Respectively. A third valve (V3) is disposed in the fourth conduit (C4). The fifth conduit C5 is connected at one end to the inner rinsing liquid outlet 32 of the inner rinsing liquid storing means 3 and at the other end to the inner rinsing liquid inlet 51 of the heat exchanging means 5. [ And the internal cleaning liquid circulation means 4 and the fourth valve V4 are disposed in the fifth conduit C5. The sixth conduit C6 has one end connected to the inner rinse solution outlet 52 of the heat exchanging means 5 and the other end connected to the connecting portion 11 'of the third conduit C3.

The seventh conduit C7 is branched in the portion of the fourth conduit C4 where the third valve V3 is disposed and the outer conduit C5 of the fourth conduit C4 is branched in the outer rinsing liquid outlet portion 54 of the heat exchanging means 5. [ And a conduit C8 is connected.

3 shows the flow of the external cleaning liquid when the external cleaning liquid is supplied to the exhaust gas processing apparatus 1 in the open mode.

Referring to FIG. 3, in the open mode, the first valve V1 is opened, the second valve V2 is closed, and the third valve V3 is connected to the cleaning liquid And the cleaning liquid discharged through the outflow portions 1115, 1315, and 1715 is controlled to move to the seventh conduit C7. Further, the internal rinsing liquid circulating means 4 and the heat exchanging means 5 are not operated.

That is, the control module 71 of the control means 7 has the first valve V1 opened, the second valve V2 closed, the third valve V3, The first to third valves V1 to V3 are controlled so as to move the cleaning liquid discharged through the cleaning liquid outlet portions 1115, 1315, and 1715 of the first conduit 1 to the seventh conduit C7. Further, the internal cleaning liquid circulation means (4) and the heat exchange means (5) are controlled not to operate.

In this state, the external cleaning liquid supplied by the external cleaning liquid supply means 2 passes through the first conduit C1 and the third conduit C3 and flows into the rinsing liquid inflow portions 1114 and 1314 of the exhaust gas processing apparatus 1 And 1714 and is injected from the exhaust gas treatment apparatus 1 and then flows out to the rinse liquid outlet portions 1115, 1315 and 1715 of the exhaust gas processing apparatus 1, And is discharged to the outside through the seventh conduit C7.

Fig. 4 shows flows of the internal cleaning liquid and the external cleaning liquid when the internal cleaning liquid is supplied to the exhaust gas processing apparatus 1 in the closed mode.

Referring to FIG. 4, in the closed mode, the first valve V1 is closed, the second valve V2 is opened, and the third valve V3 is opened in the cleaning liquid The internal cleaning liquid discharged through the outflow portions 1115, 1315, and 1715 is controlled to move to the internal cleaning liquid inflow portion 31 of the cleaning liquid storage means 3. [ Further, the internal rinsing liquid circulation means (4) and the heat exchange means (5) operate. Therefore, the internal cleaning liquid is recirculated and supplied to the exhaust gas treating apparatus 1. [

That is, the control module 71 of the control means 7 is configured such that the first valve V1 is closed, the second valve V2 is opened, and the third valve V3 is closed, (V1 to V3) so as to move the cleaning liquid discharged through the cleaning liquid outlet portions 1115, 1315, and 1715 of the cleaning liquid container 1 to the inside cleaning liquid inlet portion 31 of the cleaning liquid storage means 3, . Further, the internal rinsing liquid circulation means (4) and the heat exchange means (5) are controlled to operate.

In this state, the external cleaning liquid supplied by the external cleaning liquid supply means 2 flows into the external cleaning liquid inflow portion 53 of the heat exchange means 5 via the second conduit C2, and the heat exchange means 5 The temperature of the inner cleaning liquid flowing in the inner cleaning liquid inflow portion 51 of the heat exchanging means 5 and flowing out to the inner cleaning liquid outlet portion 52 is lowered and then the temperature of the inner cleaning liquid flowing out to the outer rinse liquid outlet portion 54 of the heat exchanging means 5 Out. The external washing liquid flowing out through the external washing liquid outlet 54 is discharged to the outside through the eighth duct C8.

In the following, specific embodiments of the exhaust gas treating apparatus 1 applicable to the harmful gas removing system in the exhaust cleaning liquid of the exhaust gas treating apparatus of the present invention are described as the first embodiment 1a and the second embodiment 1b ).

Referring to Figs. 5 to 7, the exhaust gas processing apparatus 1a according to the first embodiment includes a preprocessor 11, a connection unit 12, and a post-processor 13. Fig.

Referring to FIG. 8, a process of treating the exhaust gas in the exhaust gas treating apparatus 1a will be briefly described below. In FIG. 8, a bold arrow indicates a flow of gas, a dotted line indicates a spraying liquid to be sprayed, and a thin arrow indicates a spraying liquid to be discharged.

When the exhaust gas generated by the combustion is introduced through the exhaust gas inlet 1112, the pre-processor 11 primarily produces harmful substances as a pretreatment gas and discharges the exhaust gas through the pretreatment gas outlet 1113. The connection part (12) moves the pretreatment gas to the post-processor (13). The post-processor 13 further removes harmful substances from the pre-treatment gas introduced through the pre-treatment gas inlet 1312 and discharges the post-treatment gas through the post-treatment gas outlet 1313.

In order to remove harmful substances in the exhaust gas in the preprocessor 11, the cleaning liquid introduced into the cleaning liquid inlet 1114 of the preprocessor 11 and the harmful substances of the pretreatment gas in the post- The cleaning liquid introduced into the cleaning liquid inflow portion 1314 of the post-processor 13 to remove the cleaning liquid is used as cleaning liquid outflow portions 1115 and 1315 formed in the lower portions of the preprocessor 11 and the post- ≪ / RTI >

When the present invention is applied to a ship, the washing liquid may be fresh water mixed with seawater or an alkali additive, and the exhaust gas may be generated in a combustion process of an engine or a boiler of the ship, (SOx) and PM.

The preprocessor 11 plays a role of primarily reducing harmful substances in the exhaust gas generated by the combustion. 6 to 9, the preprocessor 11 includes a preprocessor housing 111, a first pre-processing injection unit 112, a stirring unit 113, and a second pre-processing injection unit 114 .

The preprocessor housing 111 forms a contour of the preprocessor 11 and forms a flow path of the exhaust gas inside. 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. 5 to 9, in an embodiment of the present invention, the preprocessor housing 111 is formed as a cylindrical tower, and moves the introduced exhaust gas from the upper portion to the lower portion of the preprocessor housing 111, Forming a flow path through which harmful substances in the exhaust gas can be primarily removed.

The inner wall 1111 is a part forming the flow path of the exhaust gas inside the preprocessor housing 111. Referring to FIG. 6, in an embodiment of the present invention, the inner wall 1111 forms a flow path of the exhaust gas in the interior of the preprocessor housing 111 in a cylindrical shape.

The exhaust gas inlet 1112 is a portion into which the exhaust gas flows into the interior of the preprocessor housing 111. 6 to 9, the exhaust gas inlet 1112 is formed at the upper end of the preprocessor housing 111, and the exhaust gas flowing through the exhaust gas inlet 1112 flows through the exhaust gas inlet 1112, And moves downward along a cylindrical flow path formed by the inner wall 1111.

The pretreatment gas outlet 1113 is a portion through which the pretreatment gas, which is an exhaust gas from which harmful substances are primarily removed, is discharged from the pretreatment apparatus 11. 6 to 9, the pretreatment gas outlet 1113 is formed at a lower side of the pre-processor housing 111, and the pretreatment gas outlet 1113, which is discharged through the pretreatment gas outlet 1113, Processing unit 13 through the connection unit 12. The post-

The cleaning liquid inflow portion 1114 is a portion into which a cleaning liquid to be injected from the inside of the preprocessor 11 flows. 9, the cleaning liquid inflow portion 1114 is connected to or formed respectively with the first pre-treatment injection means 112 and the second pre-treatment injection means 114, which will be described later.

The cleaning liquid outlet 1115 is connected to the first pre-treatment injection unit 112 and the second pre-treatment unit 112 to remove harmful substances from the exhaust gas flowing into the interior of the preprocessor housing 111 through the exhaust gas inlet 1112. [ 2 is a portion where the cleaning liquid injected by the pre-treatment injection means 114 is discharged. 6 to 8, the rinse solution outlet 1114 is formed at the lower end of the pre-processor housing 111. The rinse solution outlet 1114 is connected to the first pre- The cleaning liquid injected by the second pre-treatment injection means 114 collects the harmful substances in the exhaust gas, moves to the lower end of the pre-processor housing 111, and is discharged to the outside. In order to smoothly discharge the cleaning liquid, it is preferable that the lower end of the pretreatment processor housing 111 is converged toward the cleaning liquid outlet 1114.

The first pretreatment injection means 112 is disposed in the vicinity of the exhaust gas inflow portion 1112 in the interior of the preprocessor housing 111 and injects the cleaning liquid into the exhaust gas flowing through the exhaust gas inflow portion 1112 . As described above, fresh water mixed with seawater and an alkali additive may be used as the washing liquid.

The first pre-treatment injector 112 cools the exhaust gas flowing through the exhaust gas inlet 1112. The exhaust gas flowing through the gas inlet 1112 generally has a temperature of 250 to 350 ° C. The temperature of the exhaust gas flowing through the gas inlet 1112 is reduced to 50 to 50 ° C. by the cleaning liquid injected by the first pre- And the volume is reduced.

In addition, the first pretreatment injection means 112 allows the PM to be primarily collected by the cleaning liquid, among the harmful substances in the exhaust gas. The exhaust gas in contact with the cleaning liquid injected by the first pre-treatment injection means 112 passes through the agitating means 113, the flow path thereof changes from a straight line to a spiral shape, and a second pre-treatment injection means 114 And comes into contact with the cleaning liquid to be sprayed. Accordingly, the cleaning liquid, which is sprayed by the first pre-treatment injection means 112 and collects toxic substances, increases in size, and is moved to the lower portion of the preprocessor housing 111 by gravity.

The first pretreatment injection means 112 injects the cleaning liquid in the form of a fine droplet compared with the second pretreatment injection means 114. [ Specifically, the first pretreatment spraying means 112 may spray the cleaning liquid in the form of droplets having a particle diameter of 100 to 200 mu m. Among the harmful substances of the exhaust gas, PM has a particle diameter of about 0.1 to 0.5 탆. When the cleaning liquid is sprayed in a droplet shape having a particle diameter of 100 to 200 탆, the PM is efficiently agglomerated and aggregated in the cleaning liquid .

10 and 11, in an embodiment of the present invention, the first pretreatment injection means 112 includes a rod-shaped injection body 1121, an injection port 1122 formed at one end of the injection body 1121, And the jetting body 1121 can receive the cleaning liquid and compressed air from the cleaning liquid supply unit (not shown) through the cleaning liquid inlet 1114. [ The injection body 1121 receives the cleaning liquid together with the compressed air and delivers the cleaning liquid to the injection port 1122. The injection port 1122 injects the cleaning liquid toward the exhaust gas.

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, And a plurality of protruding portions are disposed on the inner wall 1111 toward the center of the flow path at predetermined angular intervals. Through this arrangement, the cleaning liquid can be efficiently sprayed to the exhaust gas flowing into the exhaust gas inlet 1112 and proceeding toward the agitating means 113.

The specific shape and arrangement of the first pre-treatment injection means 112 may vary depending on the distribution amount of the first pre-treatment injection means 112 and the overall length design of the preprocessor 11. [

The agitating means 113 is disposed between the first pretreatment injecting means 112 and the second pretreatment injecting means 114 in the interior of the pretreatment housing 111 so that the exhaust gas on the flow path is curved, Preferably a helical flow. In one embodiment of the present invention, the preprocessor housing 111 forms an exhaust gas flow path vertically downward from the top to the bottom, wherein the agitator means 113 is connected to the inlet 1112 through the exhaust gas inlet 1112 So that the flow of the exhaust gas advancing straight downward is changed into a curved shape, preferably a spiral shape.

When the flow of the exhaust gas on the flow path is changed from a straight line to a curved line by the agitating means 113, the flow path becomes long, and as a result, the cleaning liquid injected by the second pre- The contact time of the contact surface is increased. Accordingly, the rate at which the harmful substances such as PM and SOx are trapped by the cleaning liquid in the exhaust gas becomes high. Therefore, it is preferable that the agitating means 113 is disposed adjacent to the exhaust gas inflow portion 1112.

Thus, the agitation means 113 can improve the removal time of harmful substances in the exhaust gas compared to the inner space of the preprocessor housing 111, and can increase the height of the preprocessor 11 without increasing the height thereof, The efficiency of removing harmful substances in the exhaust gas can be improved even if the height is reduced. As a result, it is possible to downsize the facility.

12 and 13, the stirring means 113 includes a central body 1131, a plurality of vanes 1132 and a space portion 1133, which are arranged to cover the flow path, Processor housing 111 by a flange portion 1334 coupled to the outer side of the front wall 1132. The front wall 1111 of the pre- The stirring means 113 may be arranged to be coupled to the inner wall 1111 of the preprocessor housing 111 through welding or the like.

The body 1131 is a center portion of the stirring means 113 and the wing 1132 is radially coupled to the body 1131 at a predetermined twist angle. The space portion 1133 is a portion formed between each of the vanes 1132 to form a space through which the exhaust gas can pass without colliding with the vanes 1132.

12, in the embodiment of the present invention, the agitating means 113 includes six blades 1132 that are twisted at an angle of 30 ° along the outer surface of the body 1131 And the space 1133 is formed between each of the vanes 1132.

When the agitating means 113 is configured as described above, the flow of the exhaust gas having passed through the agitating means 113 is formed in a spiral shape, and the flow of the exhaust gas formed by the inner wall 1111 of the pre- The first pre-treatment injection means 112 and the second pre-treatment injection means 114 can be formed symmetrically with respect to the moving direction center of the flow path, So that harmful substances in the trapped exhaust gas can flow down on the inner wall 1111 of the housing 111.

If the space portion 1132 does not appear between the vanes 1132, the exhaust gas flowing through the exhaust gas inlet portion 1112 is subjected to excessive pressure loss when passing through the agitation means 113 So that the flow of the exhaust gas is not preferable.

Further, it is preferable that the stirring means 113 is fixed without rotating. This is because the exhaust gas flowing through the exhaust gas inflow portion 1112 generally has a sufficient fluid supply speed toward the pretreatment gas outflow portion 1113 and therefore it is necessary to supply a separate linear energy to the exhaust gas on the flow path There is no.

The second pretreatment injection means 114 is disposed between the agitation means 113 and the pretreatment gas outflow 1113 in the interior of the preprocessor housing 111 and through the agitating means 113, And the cleaning liquid is sprayed on the exhaust gas proceeding spirally.

The second pretreatment injection means 114 is connected to the pretreatment gas outlet 1113 located at the lower portion of the preprocessor housing 111 through the agitation means 113. The second pretreatment injection means 114 is connected to the pre- The cleaning liquid is injected by the first pre-treatment injection means 112 to induce agglomeration of the cleaning liquid in a state of collecting harmful substances such as PM contained in the exhaust gas, thereby enlarging the size of the cleaning liquid, To flow down on the inner wall 1111 of the processor housing 111 or to fall down efficiently to the lower portion of the preprocessor housing 111.

In order to increase the size of the cleaning liquid injected by the first pretreatment injection means 112 and collecting harmful substances such as PM in the exhaust gas as described above, the second pre-treatment injection means 114, It is preferable to inject a cleaning liquid having a larger particle diameter than the cleaning liquid jetted by the jetting means 112. Specifically, it is preferable that the second pre-treatment injection means 114 injects the cleaning liquid in the form of a droplet having a particle diameter of 500 to 1,000 μm.

14 and 15, in an embodiment of the present invention, the second pretreatment injection means 114 includes a rod-shaped injection body 1141 and a plurality of branched water bodies 1141 branched from the injection body 1141 at regular intervals And a plurality of ejection openings 1143 formed at predetermined intervals in each of the ejection bores 1142. [ The jetting body 1141 can receive the cleaning liquid and the compressed air from the cleaning liquid supply unit (not shown) through the cleaning liquid inlet 1114. The jetting body 1141 receives the cleaning liquid together with the compressed air and delivers the jetted liquid to each of the jetting bases 1142. The jetting port 1143 injects the cleaning liquid toward the exhaust gas.

The second pretreatment injection means 114 forms a structure in which the injection ports 1143 for injecting the cleaning liquid are disposed more closely than the first pretreatment injection means 112, This is advantageous in uniformly spraying the cleaning liquid without a square area toward the exhaust gas flowing in the flow path spirally.

The specific shape and arrangement of the second pre-treatment injection means 114 and the like can be controlled in accordance with the distribution amount of the second pre-treatment injection means 114 and the distribution amount of the pre-processor 11 And the overall length design of the device.

The connection part 12 is a part for moving the pretreatment gas, which is an exhaust gas whose harmful substances are primarily reduced, in the preprocessor 11 to the post-processor 13. [ 6 to 8, one end of the connection part 12 is connected to the pretreatment gas outlet part 1113 of the preprocessor housing 111 and the other end is connected to the pretreatment gas inlet part 1312).

The post-processor 13 additionally removes harmful substances in the pretreatment gas, which is an exhaust gas whose toxic substances are primarily reduced by the preprocessor 11. 5 to 7 and 16, the post-processor 13 includes a post-processor housing 131, a diffusion unit 132, a packing 133, a packing support unit 134, a first post- 135, the second post-treatment injection means 136, the water separating means 137, the cleaning means 138, and the irrigation blocking means 139.

The post-processor housing 131 forms a contour of the post-processor 13 and forms a flow path of the pretreatment gas therein. The post-processor housing 131 includes an inner wall 1311, a pretreatment gas inlet 1312, a post-treatment gas outlet 1313, and a rinse solution outlet 1315. 6 and 16, in an embodiment of the present invention, the post-processor housing 131 is formed as a cylindrical tower, and moves the pre-treatment gas introduced through one side of the lower portion upward, Thereby forming a flow path through which harmful substances can be additionally removed.

The inner wall 1311 is a part forming the flow path of the pretreatment gas in the post-processor housing 131. Referring to FIGS. 6 and 16, the inner wall 1311 forms a flow path of the exhaust gas in the post-processor housing 131 in a cylindrical shape.

The pre-treatment gas inlet 1312 is a portion into which the pretreatment gas flows into the post-processor housing 131. As shown in FIGS. 6 to 8 and 16, the pretreatment gas inlet 1312 is formed at a lower side of the post-processor housing 131, and the pretreatment gas introduced through the pretreatment gas inlet 1312 Is moved upward along a cylindrical flow path formed by the inner wall 1311.

The post-treatment gas outlet 1313 is a portion through which the post-treatment gas, which is a pretreatment gas from which the harmful substances are further removed, is discharged from the post-processor 13. As shown in FIGS. 6 to 8 and 16, the post-treatment gas outlet 1313 is formed in the upper portion of the post-processor housing 131, and is discharged through the post-treatment gas outlet 1313 The process gas can be released to the atmosphere as the removal of harmful substances from the exhaust gas is performed by the pre-processor (11) and the post-processor (13).

The cleaning liquid inlet 1314 is a portion into which the cleaning liquid to be injected from the inside of the post-processor 13 flows. 6 and 16, the cleaning liquid inlet 1314 is connected to the first post-treatment injection unit 135, the second post-treatment injection unit 136, and the cleaning unit 138, which will be described later, Or formed.

The cleaning liquid outlet 1315 is connected to the first post-processing injection unit 135 or the second post-processing unit 135 to remove harmful substances in the pretreatment gas introduced into the post-processor housing 131 through the pre- And is a portion where the cleaning liquid injected by the second post-treatment injection means 136 is discharged. 6 to 8 and 16, the cleaning liquid outlet 1315 is formed at the lower end of the post-processor housing 131. The cleaning liquid outlet 1315 is connected to the cleaning liquid outlet 1315 through the cleaning liquid outlet 1315, The cleaning liquid injected by the processing injection means 135 and the second post-processing injection means 136 collects the harmful substances in the pretreatment gas and is moved to the lower end of the post-processor housing 131 to be discharged to the outside do. In order to smoothly discharge the cleaning liquid, the lower end of the post-treatment housing 131 is preferably formed to converge toward the cleaning liquid outlet 1315.

The diffusing means 132 diffuses the pre-treatment gas introduced through the pre-treatment gas inlet 1312 and disposed adjacent to the pre-treatment gas inlet 1312 in the post-processor housing 131. 17 to 19, the diffusing unit 132 is disposed in front of the pretreatment gas inlet 1312 and includes a body 1321 and a fastening unit 1322. [

The body 1321 is a member that covers the front of the pretreatment gas inlet 1312 and has a diffusion portion 1321a through which the pretreatment gas can pass. The body 1321 may be formed of a plate-like member. 18 and 19, the body 1321 is formed so as to vertically cover the front of the pretreatment gas inlet 1312. The upper and lower ends of the body 1321 are connected to the pre- And may be formed in an inclined or curved shape toward the inflow portion 1312 side.

The upper end of the body 1321 is formed to be inclined upward toward the pretreatment gas inlet 1312 and the lower end of the body 1321 is inclined downward toward the pretreatment gas inlet 1312 side Respectively. Through this shape of the body 1321, the pretreatment gas introduced through the pretreatment gas inlet 1312 can be uniformly diffused forward and upward and downward. The body 1321 may be formed not only in an upper portion and a lower portion in a shape that is inclined or curved, but also in a generally curved shape.

The diffusion portion 1321a may include a plurality of through holes, and the diffusion portion 1321a may be formed with a plurality of uniformly formed through holes. 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 size and shape of the body 1321 and the shape and the number of the diffusion portions 1321a may vary depending on the processing capacity of the post processor 13 and the like.

The fastening portion 1322 is a portion that is fastened to the fixing portion 1311b formed in the post-processor housing 131 so that the diffusion means 132 can be fixed inside the post-processor housing 131 . 17 and 18, the fastening portion 1322 is vertically extended or bent from the left and right ends of the body 1321 toward the pretreatment gas inlet 1312, To be fixed to the interior of the post-processor housing 131 by being fastened to the fixing portion 1311b formed in the post-processor housing 131. [

Since the flow path of the pretreatment gas, which is an exhaust gas whose reduction of harmful substances is primarily performed by the preprocessor 11, is changed by the agitating means 113 in a spiral manner, it flows out to the pretreatment gas outlet 1312 And flows into the pretreatment gas inlet 1312 via the connection portion 12, the gas has a certain amount of rotational energy. Accordingly, the flow of the air into the post-processor housing 131 is concentrated on the inner wall 1311 of the post-processor housing 131 toward the pretreatment gas inlet 1312, It is not uniformly dispersed in the flow path of the pretreatment gas formed in the reaction chamber.

The diffusing unit 132 functions as a nozzle by making the cross sectional area of the pre-treatment gas flow into the post-processor housing 131 to be narrower so that the pre-treatment gas flows into the post-processor housing 131 Thereby allowing uniform diffusion. So that the pretreatment gas can be uniformly dispersed on the flow path of the pretreatment gas formed in the post-treatment housing 131. That is, the pretreatment gas flowing into the packing 133 is uniformly dispersed through the diffusion unit 132, so that the absorption efficiency of the SOx of the pretreatment gas in the packing 133 can be increased, The efficiency can be improved.

As shown in FIGS. 17 and 18, two diffusion units 132 are disposed in front of the pre-treatment gas inlet 1312 so that the diffusion by the diffusion unit 132 can be performed more It can be made uniform.

The packing 133 is a portion for making a contact area between the cleaning liquid injected by the first post-treatment injection means 135 and the second post-treatment injection means 136 described later and the pretreatment gas large. The packing 133 is disposed on the flow path of the pretreatment gas in the upper portion of the diffusing means 132 in the post-processor housing 131 to increase the vapor / liquid contact area of the pretreatment gas and the cleaning liquid, Or the SOx which is a harmful substance in the pretreatment gas through the cleaning liquid composed of fresh water containing an alkali additive can be smoothly performed.

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

The packing support means 134 supports the packing 133 from below and diffuses the pretreatment gas. 20 and 21, the packing support means 134 covers the flow path of the pretreatment gas and has a step 1311a protruding inwardly in an inner wall 1311 of the post-processor housing 131, And supports the packing 133 placed on the upper part. In the present invention, the packing support means 134 has a diffusion function for diffusing the pretreatment gas from the lower portion of the packing 133.

The packing support means 134 includes a penetration portion 134a through which the pretreatment gas can pass and a support portion 134b for supporting the packing. Specifically, the supporting portion 134a is a strand having a cross structure, and the penetrating portion 134a is formed as a through hole formed by the supporting portion 134b. That is, the packing support means 134 forms the penetration portion 134a of the mesh structure by the support portion 134b having a cross structure. The pressure loss of the pretreatment gas can be reduced by lowering the resistance through the mesh structure.

The packing support means 134 increases the ratio of the diffusion portion 134a, that is, the ratio of the through holes of the mesh structure, thereby increasing the passage area of the pretreatment gas compared to a general mesh structure to minimize the pressure loss of the pretreatment gas Specifically, it is preferable that the area of the diffusion portion 134a and the vertical projection area of the support portion 134b are formed to be about 2 to 4: 1.

Meanwhile, as shown in FIG. 20, it is preferable that at least a part of the support part 134b has a twisted structure. If the support portion 134b has such a twisted structure, the pretreatment gas impinging on the support portion 134b among the pretreatment gases passing through the penetration portion 134a is changed in the traveling direction along the twisted direction. As a result, the pretreatment gas can be diffused more widely, and more uniform and active pretreatment gas can be dispersed and diffused.

In the present invention, the packing support means 134 does not merely support the packing 133, but also distributes the pretreatment gas introduced into the packing 133 evenly over the whole area of the lower portion of the packing 133 . As a result, the absorption efficiency of the SOx of the pretreatment gas in the packing 133 can be increased through the packing support means 134, and the collection efficiency of other harmful substances can be improved.

It is preferable that the packing support means 134 has a bending structure in which the hill portions 1341 and the valleys 1342 are continuously and continuously arranged. The continuous bending structure in parallel with each other improves the supporting force with respect to the cross sectional area, so that the packing 133 can be more stably supported by the hill 1341. Further, this structure allows the pressure of the pretreatment gas traveling toward the packing 133 to be uniformly dispersed in the packing support means 134, so that the pressure of the pretreatment gas flowing toward the packing 133 from the bottom of the packing 133 Thereby making the flowing pre-treatment gas uniformly diffuse to the lower portion of the packing 133 as a whole.

The first post-processing injection unit 135 is disposed on the flow path of the pre-processing gas among the interior of the post-processor housing 131 and injects the cleaning liquid toward the pre-processing gas. The first post-treatment injection means 135 is disposed on the upper portion of the packing 133 and injects the cleaning liquid toward the packing 133.

16, 22, and 23, in an embodiment of the present invention, the first post-processing injection unit 135 includes a rod-shaped injection body 1351, And a plurality of injection ports 1353 formed at predetermined intervals in the respective injection bosses 1352. The plurality of injection bosses 1352 are connected to the respective injection bosses 1352 through the injection body 1351, (Not shown) for supplying a cleaning liquid and compressed air to the cleaning liquid supply unit. The cleaning liquid and the compressed air supplied by the cleaning liquid supply unit (not shown) are supplied to the injection body 1351 through the cleaning liquid inlet 1314. The jetting body 1351 receives the cleaning liquid together with the compressed air and delivers the jetted liquid to each of the jetting bases 1352. The jetting port 1353 injects the cleaning liquid toward the exhaust gas.

The specific shape and arrangement of the first post-processing injection means 135 may vary depending on, for example, the distribution amount of the first post-processing injection means 135 and the overall length design of the post-processor 13.

The second post-processing injection unit 136 is disposed on the flow path of the pre-processing gas among the inside of the post-processor housing 131 to inject the cleaning liquid toward the pre-processing gas, And is operable independently. This independent operation can be performed by the control of the control unit C as shown in Fig. The controller C performs control so that the injections of the cleaning liquids of the first post-processing injection unit 135 and the second post-processing injection unit 136 can be independently performed.

16, 22, and 23, in an embodiment of the present invention, the second post-processing injection means 136 includes a rod-shaped injection body 1361, And a plurality of ejection openings 1363 formed at predetermined intervals in the respective ejection bosses 1362. The plurality of ejection bosses 1362 are formed through the ejection body 1361, (Not shown) for supplying a cleaning liquid and compressed air to the cleaning liquid supply unit. The cleaning liquid and the 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 jetting body 1361 receives the cleaning liquid together with the compressed air and delivers the cleaning liquid to each of the jetting bases 1362, and the jetting port 1363 ejects the cleaning liquid toward the exhaust gas.

The specific shape and arrangement of the second post-processing injection means 136 may be determined in accordance with the distribution amount of the second post-processing injection means 136 and the distribution amount of the second post-processing injection means 136, as described in connection with the first post- The overall length design of the processor 13, and the like.

The second post-processing injection means 136 independently operates with the first post-processing injection means 135 in that the second post-processing injection means 136 is connected to the first post-processing injection means 135, ≪ / RTI > or at the same time. Therefore, when the amount of the exhaust gas generated by the combustion and the amount of the pretreatment gas introduced from the preprocessor 11 changes according to the load of the engine, it is possible to spray the appropriate cleaning liquid correspondingly thereto, The economical operation of the processor 13 is achieved.

The second post-processing injection means 136 is disposed above the first post-processing injection means 135 at a predetermined interval. When the second post-processing injection means 136 and the first post-processing injection means 135 are disposed on the same horizontal plane of the flow path of the pretreatment gas, the resistance which interrupts the flow of the pretreatment gas becomes large, The second post-processing injection means 136 and the first post-processing injection means 135 are preferably arranged at different heights.

Further, the first post-processing injection means 135 and the second post-processing injection means 136 are disposed at different heights, and are disposed so as to cross each other when they are vertically projected on the flow path of the pretreatment gas Is more preferable. Through this arrangement, the cleaning liquid can be uniformly sprayed on the pretreatment gas on the pretreatment gas flow path without a rectangular area, and removal of toxic substances in the pretreatment gas can be performed more efficiently.

Hereinafter, the mechanism by which the harmful substances in the pretreatment gas are removed through the cleaning liquid injected by the first post-treatment injection means 135 and the second post-treatment injection means 136 will be described below.

The pretreatment gas includes harmful substances such as sulfur oxides (SOx) and PM, which are acidic substances. The first post-treatment injection means 135 and the second post-treatment injection means 136 neutralize The cleaning liquid is sprayed to coagulate and remove. In general, 0.1 ~ 0.5um of PM is first aggregated by fine droplets (100 ~ 200um) and becomes bigger. In addition, a basic cleaning solution is required to neutralize acidic sulfur oxides (SOx). 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). The neutralization reaction of sulfuric acid (SOx) by a cleaning liquid containing NaOH is as follows.

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

However, when the present invention is applied to a ship as described above, sea water, which is salt water, may be used as a cleaning liquid. In general, seawater contains salts such as sodium chloride (NaCl), magnesium chloride (MgCl ₂ ) and potassium chloride (KCl). PH is 7.8 ~ 8.3 due to the anions such as Cl ^- , SO ₄ ^2- and Br ^- And the like. Therefore, if such seawater is used as a cleaning liquid, there is an advantage that neutralization of sulfur oxides (SOx) can be performed without adding an additional alkaline additive.

At this time, the neutralization reaction formula by seawater is as follows. First, it is mixed with sulfur dioxide (SO ₂ ) in gaseous state.

SO _{2 (g)} + H ₂ O ₍₁₎ ↔ H ₂ SO _{3 (aq)}

Next, it reacts with the base in seawater.

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

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

That is, sulfur dioxide is absorbed in seawater and becomes a sulfate through the above reaction.

The odd water separating means 137 is disposed on the upper portion of the second post-processing injection means 136 among the inside of the post-processor housing 131 and is connected to the flow of the pretreatment gas via the second post- It is the part that performs the role of separating the micro liquid which flows in the path. The odd water separating means 137 is disposed in a manner such that a rim portion thereof is seated on a step 1311a protruding inwardly from the inner wall 1311 of the post processor housing 131.

The odd water separating unit 137 separates, filters and collects aerosol-type droplets or mist generated by the pretreatment gas and the cleaning liquid. The odd-numbered water separating unit 137 includes a blade May be arranged at a predetermined interval. In addition, the shape of the water separation unit 137 may vary depending on the design of the post-processor 13, temperature and chemical characteristics, and the like.

The cleaning means 138 is disposed on the upper portion of the second post-processing injection means 136 and the lower portion of the water separation means 137 among the interior of the post-processor housing 131, And a cleaning liquid is sprayed toward the cleaning liquid.

16, 24 and 25, in one embodiment of the present invention, the cleaning means 138 includes a bar-shaped injection body 1381 and a plurality of nozzles 1341 branched from the injection body 1381 at regular intervals And a plurality of ejection openings 1383 formed at predetermined intervals in each of the ejection bosses 1382. The ejection bosses 1382 are connected to the respective ejection bosses 1382 through a cleaning liquid and compressed air (Not shown) for supplying a cleaning liquid to the substrate. The cleaning liquid and the compressed air supplied by the cleaning liquid supply means (not shown) are supplied to the injection body 1381 through the cleaning liquid inlet portion 1314. The jetting body 1381 supplies the cleaning liquid together with the compressed air to each of the jetting bases 1382, and the jetting port 1383 ejects the cleaning liquid toward the jetting separating means 137.

The water separating means 136 may be contaminated or occluded during the process of separating, filtering and collecting fine droplets or mist in a state of collecting harmful substances such as PM in the pretreatment gas. The separation means 137 is cleaned by the cleaning liquid, thereby preventing contamination and clogging of the water separation means 136.

In addition, the cleaning means 138 may spray a cleaning liquid to increase the size of fine droplets or mist separated by the water separating means 137, so that droplets of fine droplets or mist that collect harmful substances become large droplets, It can efficiently fall down to the lower portion of the housing 131 or flow downward through the inner wall 1311 of the post-processor housing 131.

The numerical cutoff unit 139 is a part that functions to block the water flowed out through the inner wall 1311 of the post-processor housing 131 and flowing out to the post-process gas outlet 1313. 16, 26 and 27, the numerical blocking means 139 includes a blocking wall 1391. In addition, the water blocking means 139 forms a trapping space 1392 for trapping water in the vicinity of the after-treatment gas outlet 1313 to prevent water droplets from flowing out to the outside. The collection space 1392 is formed in such a form that the collected water drops can be dropped downward.

The post-processing gas outlet 1313 is formed on the upper portion of the post-processor housing 131 in an upward direction, and the numerical cutoff unit 139 is disposed below the post-processing gas outlet 1313 in a downward direction And includes an extended blocking wall 1391. The blocking wall 1391 forms a trapping space 1392 between upper end inner walls of the housing 131 of the post-processor. The upper end wall 1311 of the housing 131 of the post-processor is converged toward the post-process gas outlet and is formed in a sloping shape. The blocking wall 1391 effectively forms the trapping space 1392, It is preferable to extend vertically downward to efficiently block the external discharge of the enemy.

The pretreatment gas rises along the flow path of the pretreatment gas formed in the post-treatment unit 13, and is discharged as a post-treatment gas through the post-treatment gas outflow 1313 while the toxic substances are further removed. In this process, some of the number of cleaning liquids collected in the pretreatment gas is collected on the inner wall 1311 of the post-processor housing 131 and moved toward the post-processor outlet 1313.

The water droplets that have moved to the vicinity of the rim of the after-treatment gas outlet 1313 on the upper inner wall 1311 of the post-processor housing 131 are caught by the blocking wall 1391. A trapping space 1392 is formed between the blocking wall 1391 and the inner wall 1311 of the post-processor housing 131 around the post-processing gas outlet 1313 so that water droplets can cohere with each other. The number of particles in the trapping space 1392 coalesces and the size and weight of the particles accumulate in the trapping space 1392 and fall to the bottom of the post-processor housing 131.

Thus, the water blocking unit 139 prevents the water collected from the pre-treatment gas from collecting the harmful substances from being discharged to the outside through the post-processor outlet 1313, and is separated into the lower part of the post-processor housing 131 Let it fall.

Next, the exhaust gas processing apparatus 1b according to the second embodiment will be described.

Referring to FIG. 28, the exhaust gas from the engine or the boiler contains harmful substances such as SOx, NOx and Particulate Matter (PM), while the exhaust gas according to the second embodiment The exhaust gas treatment apparatus 1b according to the second embodiment may include a housing 171 in which a plurality of means for reducing the harmful substances are provided step by step.

29 and 30, the housing 171 may have various shapes in the form of a large barrel having an empty interior. In general, however, the housing 171 has a cylindrical housing 171, A gas inflow portion 1712 through which the exhaust gas enters and a cleaning liquid outlet portion 1715 through which the sprayed cleaning liquid escapes and a gas outlet portion 1713 through which the exhaust gas exits from the upper portion .

The inner wall surface 1711 may include a vertical surface 1711a which extends upward and downward and an inclined surface 1711b which is bent and extended from the vertical surface 1711a in the vicinity of the gas outflow portion 1713, The inner wall surface 1711 may have a function of rinsing the cleaning liquid introduced from the later-described injection means 173 or the like along the flow of the exhaust gas.

The gas inlet 1712 may include a gas inlet pipe 1712a that protrudes inward of the housing 171 and communicates with one side of a diffusion unit 172 which will be described later. Is formed as a hollow hollow cylinder having a function as a passage through which exhaust gas can flow.

The cleaning liquid outlet 1715 includes a cleaning liquid outlet pipe 1715a extending from a bottom surface of the housing 171 to a lower portion of the housing 171 by a predetermined length, In many cases, the inside is formed as a hollow hollow cylinder for discharging the cleaning liquid. In case of installing on a ship, it is possible to smoothly discharge the cleaning solution on one side according to the inclination of the ship without a separate bottom surface inclination due to a rolling phenomenon rolling the hull to the left and right and a pitching phenomenon to lean forward and backward.

The gas outflow portion 1713 is formed with a large hole in the exhaust gas treatment device 1b according to the second embodiment so that the clean gas from which harmful substances are removed is discharged to the atmosphere, And may communicate with the water cutoff means 178 to block the water droplets that rise on the inner wall surface 1711.

Next, referring to FIGS. 29 to 58, the exhaust gas flowing into the housing 171 of the exhaust gas processing apparatus 1b is cleaned in stages to remove sulfur oxides (SOx) and particulate matter (PM) I will explain various means of discharging cleaned gas.

29 and 30, the exhaust gas treatment apparatus 1b is provided with diffusion means 172 (see FIG. 29) for distributing the exhaust gas evenly inside the housing 171, A dispensing means 173 for spraying the cleaning liquid on the upper side thereof, a dispensing means 174 for spraying the exhaust gas on the upper side of the injection means 173, a multi-injection means 175), numeral separation means (176) for guiding the flow of the exhaust gas on the multiplying means (175), numeral collecting means (177) for collecting the numeral water separated from the lower portion of the numerical separating means (176) And a numerical aperture blocking means 178 for dropping the water droplets riding on the inner wall surface 1711 in the vicinity of the gas outlet portion 1713.

31 to 34, the diffusion means 172 has a function of uniformly dispersing the exhaust gas flowing in the gas inlet portion 1712 into the housing 171, A diffuser 1721 and an exhaust passage 1722 for exhausting the cleaning liquid, which is accumulated inside the gas diffuser 1721, without obstructing the flow of the exhaust gas.

31 and 32, the inside of the gas diffuser 1721 is formed into an empty thin-film-like narrow shape so that the inner surface 1721a and the outer surface 1721b and the boundary between the two surfaces 1721a and b And a blocking portion 11721d extending outwardly of the gas diffuser 1721 along the periphery of the outer side surface 1721b.

The outer side surface 1721b has a function that the exhaust gas flowing through the gas inlet portion 1712 rises and is widely dispersed inside the housing 171. [

In the prior art, gas diffusers are sometimes provided on the upper side of the gas inlet. However, the cleaning liquid having a lower narrowing width that becomes narrower toward the upper side flows down along the surface of the gas diffuser and obstructs the flow of the exhaust gas . Thereby, pressure loss of the exhaust gas is generated thereby to weaken the function of the entire exhaust gas processing apparatus. In addition, in many cases, the lower crucible has a triangular or conical shape. The exhaust gas introduced from the gas inlet part bypasses the lower side of the horn and spreads to the inside of the housing to form an upward flow. Causing a large pressure loss. Although the exhaust gas treatment apparatus is important in terms of how much pressure loss (mmAq / m) per unit height is quantified and used as an index for performance, the conventional art has a problem that the pressure loss It was a bar.

Accordingly, the gas diffuser 1721 according to the present invention includes a shape that widens toward the upper end, and the exhaust gas that has entered through the gas inlet 1712 is gradually widened along the outer surface 1721b of the gas diffuser 1721, The exhaust gas can be widely dispersed in the housing 171 without pressure loss. In particular, it is preferable that the gas diffuser 1721 in the shape of the upper limit of the light includes an inverted conical shape.

The inner side surface 1721a has a function of collecting the cleaning liquid sprayed from the spraying means 173 to be described later and collecting downwardly so as to collect downwardly. The flow of the gas is not disturbed and the pressure loss can be prevented.

The blocking portion 1721d is formed to extend outward along the periphery of the outer surface 1721b and is located below the edge 1721c. The blocking portion 1721d includes a first surface 172d-1 that is horizontally deployed, And a second surface 1721d-2.

Referring to FIG. 33, the exhaust gas treatment device 1b is used in a ship to confirm a pitching phenomenon in which a hull is tilted back and forth by a wave, and a rolling phenomenon in which a curve is tilted to the left and right . At this time, the housing 171 also tilts forward, backward, left and right. At this moment, when the gas diffuser 1721 is inclined so that the outer side surface 1721b extends beyond the vertical direction, the cleaning liquid jetted from the jetting means 173, 1712). If the cleaning liquid that has entered the gas inlet 1712 flows backward into the engine E or the boiler B, there is a possibility that a serious trouble such as a device failure occurs. Therefore, in order to prevent such a phenomenon, the blocking portion 1721d should be designed to have a size considering the size, rolling and pitching angle of the ship. More specifically, by varying the length of the first surface 1721d-1 and the length of the first surface 1721d-2, the degree of protrusion from the outer surface 1721b is adjusted so that even when the hull is tilted, And prevents backflow to the gas inlet 1712. At this time, the angle at which the outer surface 1721b is developed is preferably designed in consideration of rolling and pitching.

In addition, when the rolling and pitching occurs, the cleaning liquid accumulated in the blocking portion 1721d may be poured to the bottom of the housing 171 rather than the gas inflow portion 1712. For this, the development angle of the second surface 1721d-2 is designed in consideration of rolling and pitching.

The discharge passage 1722 has a function of discharging the cleaning liquid collected on the inner side surface 1721a of the gas diffuser 1721 to the bottom surface of the housing 171 to prevent overflow of the cleaning liquid, 1721 from the lower side to the inner side surface 1721a. At this time, the discharge passage 1722 is formed such that the gas inlet 1712 protrudes inside the housing 171 and extends to the inside of the extended gas inlet pipe 1712a. In order to discharge the cleaning liquid, the gas inlet pipe 1721a, And an outlet 1722a communicating with the inner surface of the base plate 1720. [ In this case, in order for the discharge port 1722a to be formed at one side of the gas inlet pipe 1712a, the discharge passage 1722 is formed in an inclined form from the lower side of the gas diffuser 1721 to the inner side of the gas inlet pipe 1712a As shown in Fig.

The cleaning liquid discharged from the discharge passage 1722 is accumulated on the bottom surface of the housing 171. The cleaning liquid collected therefrom is supplied to the cleaning liquid discharge portion 1715 extending from the bottom of the housing 171 downward at a predetermined angle To the outside of the exhaust gas treatment device 1b. At this time, even if the rinse solution outlet 1715 is biased to one side only and there is no separate inclined surface on the bottom surface of the housing 171, the pitching phenomenon and rotation The entire housing 171 is inclined by a rolling phenomenon in which the hull is inclined to the left and right due to the inclination of the hull, so that it is possible to smoothly discharge the cleaning liquid and prevent accumulation of excessively accumulated on the floor surface. The manner in which the housing 171 is lifted in this way can be seen in more detail in Fig.

34, the cleaning liquid collected on the inner surface 1721a of the gas diffuser 1721 is not affected by the flow of the exhaust gas passing through the gas inflow pipe 1712a, thereby preventing pressure loss (Dotted line), and the exhaust gas is naturally dispersed (indicated by a solid line) inside the housing 171 without pressure loss by the structure.

35 to 38, the spraying means 173 has a function of spraying a cleaning liquid from above the diffusion means 172 and cleaning the exhaust gas including sulfur oxides (SOx) and PM. In particular, Side injection means 1731 for injecting the exhaust gas in the direction of the flow direction of the exhaust gas.

Referring to FIG. 35, the lateral jetting means 1731 may include a jetting body 1731a and a jetting port 1731b, which are configured to jet a cleaning liquid onto the exhaust gas.

The injection body 1731a is connected to the inner wall surface 1711 of the housing 171 as a rod-shaped supply pipe for supplying the cleaning liquid. When the housing 171 is cylindrical, the injection body 1731a may also be circularly distributed Particularly, if it is located in the space formed by being inserted into the inner wall 1711 outwardly at a certain depth, the injection means 1731 itself prevents the flow of the exhaust gas and prevents the pressure loss due to the structure.

The jetting port 1731b is formed at one end of the jetting body 1731a to jet the cleaning liquid, and is formed toward the side surface to jet the cleaning liquid to the side surface.

The exhaust gas generated by the combustion in the engine E or the boiler B includes harmful substances such as sulfur oxides (SOx) and PM which are acidic substances. The injecting means 173 neutralizes or coheses these harmful substances Thereby spraying a cleaning liquid to be removed. In general, 0.1 ~ 0.5um of PM is first aggregated by fine droplets (100 ~ 200um) and becomes bigger. In order to neutralize acidic sulfur oxides (SOx), a basic cleaning liquid is required. In the case of using fresh water, a separate alkaline additive is added to induce a neutralization reaction.

Wherein the alkaline additive is capable of such as NaOH (sodium hydroxide), Na ₂ CO ₃ (sodium carbonate) or NaHCO ₃ (sodium bicarbonate). The neutralization reaction of sulfuric acid (SOx) by a cleaning liquid containing NaOH is as follows.

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

However, when the exhaust gas treatment device 1b is installed on a ship operated on the sea, sea water, which is salt water, may be used. In general, seawater contains salts such as sodium chloride (NaCl), magnesium chloride (MgCl ₂ ) and potassium chloride (KCl). PH is 7.8 ~ 8.3 due to the anions such as Cl ^- , SO ₄ ^2- and Br ^- And the like. Therefore, if such seawater is used as a cleaning liquid, there is an advantage that neutralization of sulfur oxides (SOx) can be performed without adding an additional alkaline additive.

At this time, the neutralization reaction by seawater is as follows, first mixed with gaseous sulfur dioxide (SO ₂ ) water.

SO _{2 (g)} + H ₂ O ₍₁₎ ↔ H ₂ SO _{3 (aq)}

Next, it reacts with the base in seawater.

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

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

That is, sulfur dioxide is absorbed in seawater and becomes a sulfate through the above reaction.

The spraying means may spray a dual fluid containing compressed air in addition to the washing liquid composed of seawater or fresh water to spread the washing liquid in the housing 171 to increase the area of contact with the exhaust gas to improve the washing efficiency.

Further, the cleaning liquid and the compressed air may have a function of cooling the harmful substances such as SOx or PM in the exhaust gas by lowering the temperature of the exhaust gas itself. Generally, the exhaust gas generated as a by-product of combustion in the engine E and the boiler B is a high-temperature gas having a temperature of about 250 to 300 degrees at the time when it flows into the housing 171. If such a high temperature exhaust gas is directly discharged into the atmosphere, many problems arise, and various structures in the housing 171 may cause heat injury, and the cleaning liquid may be rapidly evaporated, causing a trouble in the cleaning operation . Also, even when the cleaning liquid is sprayed at a high temperature, there is a possibility that the PM may pass without passing through the agglomerated state. Therefore, the injecting means 173 injects seawater or a two-fluid mixture of fresh water and compressed air into the exhaust gas of high temperature entered into the housing 171 through the gas inlet 1712 to cool the temperature to about 50 to 60 degrees .

The function of the above-described injection means 173 is more effective when the contact area with the exhaust gas and the contact time are increased. The spraying means of the conventional exhaust gas processing apparatus injects the cleaning liquid so as to coincide with the flow direction of the exhaust gas, And the contact time was short. Therefore, there has been a problem that the cleaning operation and the cooling operation can not be effectively performed.

In addition, the exhaust gas treatment apparatus for cleaning and cooling sulfur oxides (SOx) and PM has a very long shape such as exceeding 5 m in the vertical direction. When installed in a power plant on the ground, Due to the large volume, it limits the design of the ship and damages the aesthetics. However, the conventional injection means has a problem that the exhaust gas processing device itself can not be made longer in order to ensure a sufficient contact area by spraying the cleaning liquid in parallel with the exhaust gas flow direction.

In this case, the flow of the exhaust gas is disturbed to the front, resulting in a great pressure loss. As described above, since the degree of pressure loss of the exhaust gas treatment device is numerically expressed (mmAq / m unit), it is an important factor to be used as an index indicating the performance thereof.

35 to 37, the exhaust gas treatment apparatus 1b includes a lateral injection means 1731 inside the housing 171 to spray the cleaning liquid and the compressed air on the side of the flow of the exhaust gas, The sufficient contact area and contact time of the exhaust gas and the cleaning liquid can be ensured without increasing the length of the exhaust gas 171, so that the neutralization reaction of sulfur oxides (SOx), the agglomeration of PM, and the cooling reaction of the exhaust gas can be smoothly generated. Particularly, when installed on the lower side of the inclined portion 1741 of the distributing means 174 to be described later, the cleaning liquid is sprayed to the point where the vortex is generated, so that the exhaust gas and the cleaning liquid can be actively mixed. Moreover, when the temperature is lowered by the cooling, the air is shrunk and the volume is reduced, so that there is also an effect that the PM particles agglomerate and grow relatively. Further, since there is a force on the side surface, there is an advantage that no pressure loss is caused in the flow direction of the exhaust gas. Preferably, it is preferably injected perpendicularly to the flow direction of the exhaust gas.

In addition, referring to Fig. 38, it is possible to maximize the contact area with the exhaust gas and the contact time by distributing the two liquids of the cleaning liquid and the compressed air in a conical shape, thereby increasing the efficiency of the work.

39 to 42, the distributing means 174 is located on the upper side of the injection means 173, and is formed in a mesh structure including a plurality of through holes 174a, which are small holes, An inclined portion 1741 and a guide portion 1742 extending downward from the lower side of the inclined portion 1741. [

Referring to FIGS. 39 and 40, the inclined portion 1741 has an upward light-narrowing shape that becomes increasingly closer to the upper side, which draws the flow of the exhaust gas to the center and forms a swirling flow below the inclined portion 1741 To mix with the cleaning liquid.

The exhaust gas treatment device 1b is required to increase the contact area and contact time evenly dispersed inside the housing 171 for effective reaction between the cleaning liquid and the exhaust gas. It tends to rise toward the inner wall surface 1711 of the housing 171 due to the influence of the gas diffuser 1721 of the housing 171. Therefore, in order to return the upward flow of the exhaust gas deflected toward the inner wall surface 1711 toward the center, a large number of small through holes 174a are formed, and the exhaust gas is broadened toward the upper side as a whole. With this configuration, the exhaust gas deflected toward the inner wall surface 1711 of the housing 171 passes through the plurality of through holes 174a inclined downward toward the center, is refracted inward, and the flow is dispersed to the center. Also, the flow of some exhaust gas that has not risen through the through hole 174a collides with the lower surface of the inclined portion 1741 and forms a vortex flow (vortex) in the process of detouring downward, so that the mixture of the cleaning liquid and the exhaust gas The neutralization reaction of sulfur oxides (SOx) and the agglomeration reaction of PM actively occur, and the cleaning effect is further improved.

39 and 41, the guide portion 1742 includes an inlet hole 1742a, which is a large hole in the middle, and has a hollow shape so that exhaust gas can pass a large amount.

Mentioned inclined portion 1741 itself has a large effect of dragging the exhaust gas flow toward the center of the inner wall surface 1711 to the center but includes a large inflow hole 1742a at the center for performing a more reliable function. With this configuration, the exhaust gas whirled by the inclined portion 1741 is uniformly distributed to the center side to increase the cleaning efficiency. The vertically formed guide portion 1742 guides the flow of the exhaust gas so that such a distribution effect can be generated more effectively. The flow of such an exhaust gas can be seen in FIG.

43 to 46, the multiple injection means 175 is located on the upper side of the distribution means 174, and a plurality of injection means are arranged vertically.

Referring to FIG. 44, the multiple injection unit 175 may include a first injection unit 1751, a second injection unit 1752, and a third injection unit 1753.

45, the first injection means 1751 includes a rod-shaped injection body 1751a, a plurality of injection belts 1751b branching at a predetermined interval from the injection body 1751a, And a plurality of ejection openings 1751c formed at regular intervals on the base 1751b.

The jetting body 1751a is connected to the inner wall surface 1711 of the housing 171 as a supply pipe for supplying a cleaning liquid from the outside.

The jetting base 1751b is branched from the jetting body 1751a and is configured to jet the cleaning liquid into a wider space. The jetting base 1751b is disposed to be offset from the jetting base 1752b of the second jetting means 1752, The area can be maximized. In addition, it eliminates the dead zone of the exhaust gas and prevents the harmful substances from being released to the atmosphere as it is.

A plurality of jetting ports 1751c are formed at predetermined positions of the jetting base 1751b to jet a mixture of the cleaning liquid and the compressed air.

46, the second injection means 1752 similarly includes the injection body 1752a, the injection stage 1752b and the injection orifice 1752c, but the respective injection stages are arranged to be shifted in the same manner as described above. With this configuration, the contact area between the cleaning liquid and the exhaust gas injected by each of the injection means is maximized, so that the neutralization reaction of sulfur oxides (SOx) and the agglomeration reaction of PM can be effectively produced.

The first injecting means 1751 and the second injecting means 1752 can be selectively operated according to the operation states of the engine E, the boiler B, and the like. At this time, the controller 1754 may further include a controller 1754 for the selective injection to control the injection according to the driving state of the engine or the boiler.

Generally, the engine (E) used in ships changes its operation rate constantly, such as when the ship is accelerating or decelerating, when the drill for drilling the seabed is operated, or when the amount of power system used increases. Also, the boiler (B) is rarely used in hot summer days, but when it is cold winter, it is often used to maintain the temperature of the crew members and to control the temperature of the cargo. Thus, the running state of the engine E or the boiler B is continuously changed, which means that the amount of combustion of the fuel is changed. When the amount of combustion of the fuel changes, the amount of exhaust gas generated by combustion also varies. The amount of harmful substances such as sulfur oxides (SOx) and PM is also changed when the exhaust gas amount is changed.

However, even if the discharge amount of the exhaust gas is reduced, an unnecessary cleaning liquid is sprayed if the amount of the cleaning liquid sprayed from the discharge gas processing device 1b is constant. In order to inject the cleaning liquid, the pump must be operated. Since the pump is operated by electric power, unnecessary injection means waste of unnecessary electric power. In addition, unlike the case of spraying a washing solution using weak water with a pH of about 8.3, it is necessary to add an alkaline additive in case of making a washing solution using fresh water, and when an unnecessary washing solution is sprayed, the alkaline additive is also wasted. Therefore, there is a need to adjust the injection amount of the cleaning liquid corresponding to the exhaust amount of the exhaust gas, which varies depending on the operation state of the engine E or the boiler B.

The multiple injection means 175 of the exhaust gas processing apparatus 1b selectively operates the first injection means 1751 and the second injection means 1752 in accordance with the operation ratios of the engine E and the boiler B The above problems can be solved by spraying the cleaning liquid. With this configuration, when the amount of exhaust gas discharged is small, only a part of the injecting means is activated to inject the washer fluid, thereby preventing waste of electric power for operation of the pump and saving alkaline additive.

The multiple injection means 175 further includes a third injection means 1753 above the first injection means 1751 and the second injection means 1752 to enable efficient cleaning of harmful substances in the exhaust gas .

At this time, like the relation between the first injection means 1751 and the second injection means 1752, the third injection means 1753 is staggered with the second injection means 1752 to enlarge the contact area between the cleaning liquid and the exhaust gas It is possible to more effectively induce the neutralization reaction of sulfur oxides (SOx) and the coagulation action of PM.

The third injecting means 1753 is also selectively operated corresponding to the amount of exhaust gas discharged depending on the operation rate of the engine E or the boiler B to prevent waste of electric power of the pump for supplying the washing liquid, You can save.

The first spraying means 1751, the second spraying means 1752 and the third spraying means 1753 spray not only the cleaning liquid composed of seawater or fresh water but also the compressed air, So that the contact time and contact area between the sulfur oxides (SOx) and the cleaning liquid can be increased to facilitate the neutralization reaction. Also, the cooling action by the compressed air can be more effectively achieved.

47 to 54, the numerical separating means 176 is located on the upper side of the multiple injection means 175, and is roughly divided into two types.

Referring to FIG. 47, the first type includes an induction portion 1761 that is cleaned by a cleaning liquid and guides the flow of the exhaust gas that has been raised, and at least one horizontal blade that forms a spiral flow of the exhaust gas raised through the induction portion 1761. [ (1762a), a stopper (1764) for blocking the flow of exhaust gas in the upper and lower portions of the vane (1762a) and flowing in a predetermined direction, a first negative pressure preventing means (1763a) for preventing differential pressure from above the horizontal vane (1762a) ).

Referring to FIG. 51, the second type includes a guide portion 1761 for guiding the flow of the exhaust gas cleaned by the cleaning liquid and guided through the guide portion 1761, and a torsion blade 1762b for forming a helical flow of the exhaust gas raised through the guide portion 1761 And second negative pressure preventing means 1763b for preventing differential pressure on the upper side and the side surface of the torsion blade 1762b.

Referring to FIGS. 47, 48 and 51 and FIG. 52, the guiding portion 1761, which is a common configuration of the two types, includes a lower guiding plate 1761a narrowed toward the upper side, And a guide tube 1761b extending upwardly.

The induction plate 1761a preferably has a hollow truncated conical shape and has a function of guiding the exhaust gas raised via the multiple injection means 175 to the center. At this time, in order to send only one side without leaking exhaust gas, it is possible to construct airtightly to fit into the inner wall surface 1711 with a circumference corresponding to the end surface of the housing 171.

The induction pipe 1761b extends upward from the upper side of the induction plate 1761a and functions as a passageway for upwardly moving the exhaust gas led to the one side by the induction plate 1761a. As shown in FIG.

Referring to FIG. 48, one or more horizontal wings 1762a of the first type are provided on a lower plate 1764b to be described later, and are laid sideways with a constant curvature. The horizontal vanes 1762a are spaced apart from each other by a predetermined distance so that exhaust gas can pass through the horizontal vanes 1762a. The horizontal wing 1762a of this shape induces a radial flow in which the exhaust gas raised through the induction pipe 1761b flows in a spiral manner to the side.

The cleaning liquid jetted from the multiple jetting unit 175 exists in a small number of droplets in the exhaust gas, and includes many harmful substances such as SOx and PM. Accordingly, the vane 1762 forms a spiral flow of the exhaust gas, and the centrifugal force generated by the vane 1762 causes the relatively heavy water to be outwardly directed to the inner wall surface 1711, Thereby separating the exhaust gas from the water droplet.

In addition, all the horizontal blades 1762a may be configured as a stationary stator. When rotating like a compressor, the speed becomes excessively high, and the cleaning operation becomes inefficient because the contact time between the exhaust gas and the cleaning liquid is insufficient.

The stopper 1764 may include an upper plate 1764a and a lower plate 1764b that cover the upper and lower sides of the horizontal vane 1762a to prevent the exhaust gas from escaping up and down without forming a spiral flow . The upper plate 1764a and the lower plate 1764b may have the shape of a circular plate when the horizontal vanes 1762a are circularly distributed.

When the exhaust gas flows into the spiral by the vane 1762, a centrifugal force is applied and the fluid is concentrated to the inner wall surface 1711 and the center is relatively lowered in pressure. In this case, the spiral flow may not be formed properly due to the differential pressure, or the pressure may be lower than the air on the upper side, which may interfere with the upward movement. Therefore, there is a need to arrange the mass at the center of the spiral flow to prevent sound pressure.

Accordingly, the first negative pressure preventing means 1763a is located above the horizontal vane 1762a to prevent differential pressure due to the spiral flow of the exhaust gas, and preferably has a conical shape from above the upper plate 1764a. The flow of the exhaust gas by this can be seen in FIG.

51 and FIG. 53, the torsional wings 1762b are distributed along the outer surface of the induction pipe 1761b, and the inner wall surface 1711 of the housing 171, starting from the outer surface of the induction pipe 1761b, In a radial direction. At this time, an angle (stagger angle a) between the chord of the root surface contacting the outer surface of the induction pipe 1761b and the axis of the induction pipe 1761b; And an angle (stagger angle b) between the chord of the tip surface and the axis of the induction pipe 1761b; May be configured in a twisted fashion as a whole. Generally, b is formed larger than a. The twisted wing 1762b guides the oblique flow of the air that has passed through the guide tube 1761b and spirals downward. Preferably, the stagger angle continuously increases from the root to the tip, thereby inducing the flow of the exhaust gas more effectively.

Referring to FIG. 53, the twist wings 1762b are spaced apart from each other by an interval of 30 degrees so that a sufficient space is formed between the wings and the wings when viewed from above. Thereby minimizing the pressure loss of the exhaust gas exiting the induction pipe 1761b and creating a spiral bypass flow. Also, all of the torsional vanes 1762b may be composed of a stationary stator. If the torsion vane 1762b is rotated like a compressor, the speed becomes excessively high and the contact time between the exhaust gas and the cleaning liquid is not sufficient.

The second negative pressure preventing means 1763b extends to the lower portion of the torsional vibration damper 1762b so as to allow the exhaust gas raised through the induction pipe 1761b to pass downwardly, The pipe 1761b can be covered. As a result, when the number of the cleaning liquid including the harmful substances in the exhaust gas is separated by the centrifugal force, it can be effectively separated downward. The second negative pressure preventing means 1763b is in the form of a hollow cylinder for the flow of the exhaust gas, and preferably has a cylindrical shape to effectively prevent differential pressure. Or the first negative pressure preventing means 1763a on the upper side of the second negative pressure preventing means 1763b. The spiral bypass flow of the exhaust gas with such a configuration can be confirmed in more detail in Fig.

55 and 56, the water collecting means 177 collects the water separated from the exhaust gas at the bottom of the water separating means 176. The water collecting means 177 surrounds the induction pipe 1761b, A diaphragm 1772 having the same configuration as the diaphragm 1772, a diagonal plate 1772 having the same configuration as or parallel to the diaphragm 1772, a drop tube 1773 extending downward from one side of the diagonal plate 1772, And a collecting box 1774 located at the lower end of the tray 1773.

The numerical separator 176 separates the water in the exhaust gas, and uses the centrifugal force to deflect the cleaning liquid containing harmful substances such as SOx and PM toward the inner wall surface 1711 side. The separated water droplets are required to be dropped down before they rise again under the influence of the flow of the exhaust gas. At the same time, it is necessary to prevent the exhaust gas from rising up into the passage through which the water drops fall.

49, 53 and 55, the diaphragm 1771 includes a plurality of through-holes 1771a in the vicinity thereof to drop the water drops separated from the water separating means 176. [ At this time, if the exhaust gas treatment device 1b is installed on the ship, the water can be flowed into the through hole 1771a without any inclination of the diaphragm 1771 due to rolling and pitching of the hull.

The swash plate 1772 is extended to maintain a predetermined inclination so that the water drops away from the through holes 1771a of the partition plate 1771 can flow outwardly, and preferably has a conical shape. One or more drop holes 1772a are provided on one side for dropping the water droplets that have flowed out to the outside, preferably four in total, one for every 90 degrees.

The drop pipe 1773 is extended downward from the drop hole 1772a formed at one side of the swash plate 1772 to drop the water drop to the bottom of the housing 171. [ But it is preferable that the drop hole 1772a has a cross section coinciding with the drop hole 1772a. In the case of FIG. 29, the drop hole 1772a has a triangular shape, so that the drop pipe 1773 also has a triangular column shape.

55 and 56, the collecting cylinder 1774 is a cylinder for collecting the water droplets descended by the dropping tube 1773 so that the sprayed liquid below the third injecting means 1753 is always filled . When the dropping pipe 1773 extends to the inside of the collecting cylinder 1774 and is completely immersed in the washing liquid sprayed from the third injecting means 1753, the exhaust gas rises on the dropping pipe 1773, It is possible to prevent it from being discharged without going through.

57 and 58, the numerical blocking means 178 may include a first blocking means 1781 and a second blocking means 1782, each located above the numerical separating means 176, Some of the water drops separated from the gas are prevented from falling on the inner wall surface 1711 of the housing 171 under the influence of the flow of the exhaust gas without dropping, thereby preventing the water containing the harmful substances from being discharged into the atmosphere.

Since the cleaning liquid composed of the seawater or the fresh water injected from the injection means 173 and 175 has the function of neutralizing the sulfur oxides SOx and coagulating the PMs, the washing liquid water level present in the upper portion of the exhaust gas treatment device 1b is discharged It contains various harmful substances contained in gas. If the water droplets of the cleaning liquid are discharged together with the cleaned exhaust gas into the atmosphere, the exhaust gas treatment device 1b itself becomes meaningless, so that the atmospheric release of the water should be prevented.

To this end, the horizontal blade 1762a of the numerical separating means 176 induces a spiral flow of the exhaust gas including the washing liquid numerical value, and deflects the water droplet, which is relatively heavy liquid by the centrifugal force, toward the inner wall surface 1711 side of the housing 171 . Or the inclined wing 1762b of the numerical separating means 176 bypasses the exhaust gas and induces the spiral flow so that the numerical value is shifted to the lower side of the inner wall surface 1711 by the centrifugal force. The water droplets of the cleaning liquid leaning toward the inner wall surface 1711 drop downward under the action of gravity, are collected by the water collecting means 177, fall down to the bottom of the housing 171, and are prevented from being discharged into the atmosphere.

However, in spite of the water collecting means 177, a part of the washing liquid separated by the water separating means 176 rises by the pressure difference without falling after being struck on the inner wall surface 1711 of the housing 171 And flows upward on the inner wall surface 1711 toward the upper side of the housing 171 under the influence of the exhaust gas flow. There is a need to block the discharge of harmful substances by blocking the water droplets ascending from the inner wall surface 1711 to the upper side of the housing 171 and discharging it to the atmosphere.

57, the inner wall surface 1711 includes a vertical surface 1711a extending upwardly and downwardly, and an inclined surface 1711b extending from the vertical surface 1711a in the vicinity of the gas outflow portion 1713, ). The slope 1711b can cut off the water droplet that rises along the vertical surface 1711a due to the influence of the exhaust gas to some extent. However, when the exhaust gas meets the inclined surface 1711b, the inclined surface 1711b is bent and flows along the inclined surface, so that there is a concern that the numerical value affected by the exhaust gas also rises along the inclined surface 1711b and is released to the atmosphere.

In order to prevent this, the first blocking means 1781 may include a blocking wall 1781a extending downward from one side of the inclined surface 1711b. The blocking wall 1781 is distributed in the form of a thick band along the boundary of the gas outflow portion 1713. When the gas outflow portion 1713 is circular, the blocking wall 1781a has a hollow cylindrical shape. As a result, the number of pieces of water that have risen along the inner wall surface 1711 flows down along the blocking wall 1781a via the inclined surface 1711b and there is no surface to be lifted further at the lower end of the blocking wall 1781a. Falls. Preferably, the blocking wall 1781 is expanded in a direction in which gravity acts to further improve the blocking effect. This numerical flow can be seen in more detail in FIG.

The second blocking means 1782 is located below the first blocking means 1781 and may include a downward sloping surface 1782b and another blocking wall 1782a.

The lower inclined surface 1782b is bent toward the center at a predetermined angle from one side of the vertical surface 1711a of the housing 171. The downward inclined surface 1782b has a function of guiding a water drop rising on the vertical surface 1711a to the blocking wall 1782a . At this time, it is preferable that the angle is formed larger than 90 degrees and the inclined surface is inclined downward to smoothly guide the number.

The blocking wall 1782a extends downward from the end of the lower inclined surface 1782b, and is preferably developed in a direction in which gravity acts. The water drops falling down on the downward sloping surface 1782b meet the blocking wall 1782a and descend vertically and the surface of the blocking wall 1782a no longer rides on the end of the blocking wall 1782a and falls downward by gravity.

By the two blocking means 1781 and 1782, the water droplets of the cleaning liquid including the harmful substances such as SOx and PM can be prevented from being released to the atmosphere together with the clean gas.

Based on the above-described configuration, exhaust gas generated by combustion in an engine or a boiler passes through the exhaust gas treatment device 1b, and harmful substances such as SOx and particulate matter (PM) The process of converting into gas will be described with reference to FIGS. 29 and 30. FIG.

Referring to FIGS. 29 and 30, the exhaust gas enters the interior of the housing 171 through the gas inlet 1712. The mixture of the washing liquid and the compressed air injected from the injecting means 173 soon causes the PM in the exhaust gas to cohere with the diffusing means 172 on the upper side of the gas inlet pipe 1712a. At this time, the exhaust gas by the diffusion means 172 forms a flow deflected toward the inner wall surface 1712, passes through the distributing means 174 and is evenly distributed to the center. Neutralization of sulfur oxides (SOx) and agglomeration of PM are caused by the cleaning liquid jetted from the multiple injection means 175 and the spiral flow formed by the water separating means 176 Uses a centrifugal force to separate the water droplets outward. The separated water droplets fall by the water collecting means 177, and the exhaust gas turns helically and continues to rise. However, some of the water drops that can not fall due to the exhaust gas flow and rise along the inner wall surface 1711 are blocked by the blocking means 178 so as to be prevented from being released to the atmosphere.

Through the above-described structure and process, the exhaust gas separates harmful substances such as sulfur oxides (SOx) and particulate matter (PM), and is released into the atmosphere as a clean gas.

Hereinafter, a location information-based cleaning liquid supply method automatic control hybrid type exhaust gas treatment method of the present invention will be described.

FIG. 59 is a flow chart of a method of processing an automatic control hybrid type exhaust gas based on a position information-based cleaning liquid supply method according to an embodiment of the present invention. Referring to FIG. 1, a position information-based cleaning liquid supply method automatic control hybrid type exhaust gas treatment method according to an embodiment of the present invention includes a positioning step S1 and a cleaning liquid supply method control step S2.

The positioning step S1 is a step for the positioning means 6 to determine the position of the ship. As described above, the positioning means 6 serves to determine the position of the ship, and may include a GPS device or the like.

In the cleaning liquid supply system control step (S2), the exhaust gas generated by the combustion is introduced into the control means (7), the cleaning liquid is injected into the exhaust gas to remove the noxious gas in the exhaust gas, A mode in which the cleaning liquid is supplied to the exhaust gas processing apparatus 1 in an open mode or in an open mode in which an external cleaning liquid is supplied based on the position of the ship positioned by the positioning means 6, And performing a control so as to alternatively perform a closed mode in which the internal cleaning liquid is recycled.

The control method for controlling the cleaning liquid supply system (S2) includes a control method (7) for controlling the supply of the cleaning liquid to the exhaust gas processing device (1) when the position of the ship is within ECA or SECA ≪ / RTI > If the position of the vessel is not ECA or SECA but the cleaning liquid supply system to the exhaust gas treatment apparatus 1 is in the closed mode, the control means 7 can perform control to switch it to the open mode have. The concrete control embodiment of the control means 7 has been described above.

While the present invention has been described in connection with what is presently considered to be practical exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, Should be interpreted as falling within the scope of.

1, 1a, 1b: exhaust gas processing device
2: external cleaning liquid supply means
3: Internal cleaning liquid storage means
4: Internal cleaning liquid circulating means
5: Heat exchange means
11: preprocessor
111: Pre-processor housing
1111: inner wall 1112: exhaust gas inlet
1113: Pretreatment gas outlet 1114: Cleaning liquid inlet
1115:
112: first pretreatment injection means 113: stirring means
114: second pre-treatment injection means
12: Connection
13: Post-processor
131: Postprocessor housing
1311: inner wall 1312: pretreatment gas inlet
1313: post-treatment gas outlet part 1314: cleaning liquid inlet part
1315:
132: diffusion means 133: packing
134: Packing support means 135: First post-treatment injection means
136: second post-treatment injection means 137:
138: Cleaning means 139: Numerical blocking means
171: Housing
1711: inner wall surface 1712: gas inlet portion
1713: gas outflow part 1714: cleaning liquid inflow part
1712a: gas inlet pipe 1712b: gas inlet portion
1711a: vertical surface 1711b: inclined surface
1715:
172: diffusion means
1721: Gas diffuser 1722:
1721b: Outer side 1721d:
1721d-1: First surface 1721d-2: Second surface
1722a:
173: injection means 1731: side injection means
174: Distribution means 1741:
1742:
174a: Through hole 1742a: Inlet hole
175: Multiple injection means 176: Numerical separation means
1761: guide portion 1762: wing
1763: Means for preventing negative pressure 1764:
177: water collection means
1771: diaphragm 1772: swash plate
1773: Drop pipe 1774: Collection container
1771a: Through hole 1772a: Drop hole
178:
1781a: blocking wall 1782a: blocking wall
1782b: downward slope

Claims (22)

An exhaust gas treatment system installed on a ship,
An exhaust gas processing device for introducing exhaust gas generated by combustion and injecting a cleaning liquid into the exhaust gas to remove harmful substances in the exhaust gas and to discharge the injected cleaning liquid,
Positioning means for positioning the ship,
An open mode in which an external cleaning liquid is supplied to the exhaust gas processing device based on the position of the ship positioned by the positioning means and the external cleaning liquid is supplied to the outside and then discharged to the outside or the inside cleaning liquid is recirculated A control unit for automatically performing control so as to alternatively perform a close mode in which the control unit performs a control operation,
An external cleaning liquid supply means for supplying an external cleaning liquid to the exhaust gas processing apparatus in the open mode,
A conduit through which the cleaning liquid flows to the exhaust gas treatment device, one end connected to the external rinse solution supply device and the other end connected to the exhaust gas treatment device,
A first valve disposed on the conduit,
A conduit connected to an exhaust gas treatment device at one end and connected to a conduit through which the cleaning solution flows into the exhaust gas treatment device so as to flow the cleaning solution flowing out of the exhaust gas treatment device,
And a third valve disposed on the conduit through which the washing liquid flowing out from the exhaust gas treating apparatus flows, for discharging or discharging the washing liquid to the conduit in which the first valve is disposed,
Wherein,
And controls the first valve so as to stop the supply of the rinsing liquid from the external rinsing liquid supply means when the ship is located in the discharge regulating area based on the position of the ship received from the positioning means and controls the first valve so that the rinsing liquid discharged from the exhaust gas processing apparatus So that the cleaning liquid is recirculated by controlling the third valve so as to flow into the conduit in which the first valve is disposed,
Controls the first valve to receive the rinse solution from the external rinse solution supply means when the ship is located in an area other than the discharge regulation area based on the position of the ship received from the positioning means, The third valve is controlled so as to be discharged to the outside of the ship without flowing into the conduit in which the first valve is disposed so as to perform the open mode in which the washer fluid is discharged to the outside
Hybrid exhaust gas treatment system based on position information and automatic control of the supply of cleaning liquid.
The method according to claim 1,
Wherein the control means determines whether the position of the ship positioned by the positioning means is within an emission control area (ECA) or a sulfur emission control area (SECA). system.
3. The method of claim 2,
Wherein the control means derives a certain region as ECA or SECA based on the coordinate information on two or more points in the ECA or SECA region stored in the database.
3. The method of claim 2,
Wherein the control means controls the supply of the cleaning liquid to the exhaust gas processing device to be in the closed mode when the position of the ship is within the ECA or SECA. Processing system.


delete delete delete 5. The method of claim 4,
Wherein the harmful substance includes sulfur oxides (SOx), the external cleaning liquid is seawater, and the external cleaning liquid supply means includes a seawater pump for transporting seawater outside the ship. Controlled hybrid exhaust gas treatment system.
9. The method according to any one of claims 1 to 8,
The exhaust gas processing apparatus includes:
And a post-processor for additionally removing harmful substances in a pretreatment gas, which is an exhaust gas whose exhaust gas has been primarily reduced by the pretreatment unit, wherein the pre-
The pre-
And a pretreatment gas outlet through which the exhaust gas flowing in the exhaust gas flows and a pretreatment gas flowing out from the pretreater, which is an exhaust gas whose primary harmful substances have been reduced, A first agitating means disposed between the exhaust gas inlet and the agitating means for injecting the cleaning liquid into the exhaust gas flowing through the exhaust gas inlet, And a second pre-treatment spraying unit disposed between the agitating unit and the pre-treatment gas outflow unit for spraying the cleaning liquid into the exhaust gas flowing in a curved shape through the flow path through the agitating unit. Hybrid exhaust gas treatment system for automatic control of location information based cleaning liquid supply system.
10. The method of claim 9,
The post-
A pretreatment gas inlet for introducing the pretreatment gas and a post-treatment gas outlet for exhausting the post-treatment gas after the toxic substances are further removed by the post-processor, ,
And a numerical aperture blocking means for blocking the water flowing upward through the inner wall of the post-processor housing and flowing out to the post-process gas outlet portion.
11. The method of claim 10,
Wherein the post-processor is provided at a lower portion of the water-
A first post-treatment jetting unit disposed on a flow path of the pretreatment gas to jet a cleaning liquid toward the pretreatment gas,
Further comprising second post-treatment injection means disposed on a flow path of the pretreatment gas to spray a cleaning liquid toward the pretreatment gas and to operate independently of the first post-treatment injection means. Automated Hybrid Exhaust Gas Treatment System.
12. The method of claim 11,
The post-
A packing disposed at a lower portion of the first post-processing injection means and the second post-processing injection means in the post-processor housing,
And a packing supporting means for supporting the packing at a lower portion thereof and having a diffusion function for diffusing the pretreatment gas at a lower portion of the packing.
13. The method of claim 12,
The post-processor further includes diffusion means disposed adjacent to the pre-treatment gas inlet and diffusing the pre-treatment gas introduced through the pre-treatment gas inlet. system.
9. The method according to any one of claims 1 to 8,
Wherein the exhaust gas treating apparatus includes diffusion means,
The diffusing means includes a gas diffuser in the form of a supersonic lamp so that the exhaust gas flowing through the gas inlet is widely dispersed in the housing to enable an efficient cleaning operation and prevent the pressure loss due to the falling cleaning liquid and the pressure loss due to the diffuser itself Wherein the exhaust gas purifying system is a hybrid type exhaust gas purifying system.
15. The method of claim 14,
The exhaust gas treatment apparatus further comprises a cleaning liquid spraying means above the diffusion means,
Wherein the spraying means includes lateral spraying means for spraying the cleaning liquid to the side surface so that the contact area between the exhaust gas dispersed in the diffusion means and the cleaning liquid is widened to improve the working efficiency while reducing the height of the housing, Hybrid exhaust gas treatment system for automatic control of location information based cleaning liquid supply system.
16. The method of claim 15,
The exhaust gas treatment apparatus further comprises a distributing means above the injecting means,
Wherein the distributing means comprises a mesh structure including a plurality of small through holes and includes an inclined portion having a shape of a lowered light which is gradually increased toward the upper portion and a large inflow hole is formed below the inclined portion, Wherein the flow rate is uniformly distributed to improve the efficiency of the treatment.
17. The method of claim 16,
Wherein the exhaust gas processing apparatus includes a multi-injection means having a first injection means, a second injection means and a third injection means on the upper side of the distribution means,
Wherein the first injecting means, the second injecting means, and the third injecting means are arranged alternately up and down to enlarge the contact area with the exhaust gas, and selectively operate according to the load of the engine or the boiler, Information based cleaning liquid supply system automatic control Hybrid type exhaust gas treatment system.
18. The method of claim 17,
Wherein the exhaust gas processing device includes numerical separating means on the upper side of the multiple injection means,
Wherein the numerical separating means includes at least one induction portion for introducing an exhaust gas and a wing formed at an upper portion of the induction portion at the center thereof to induce a spiral flow of the exhaust gas from the induction portion, Hybrid type exhaust gas treatment system.
19. The method of claim 18,
Wherein the exhaust gas treatment apparatus includes a water collecting means for collecting the water droplets separated by the water separating means to prevent the release of harmful substances to the atmosphere. .
20. The method of claim 19,
Wherein said exhaust gas processing device includes numerical-value cut-off means for blocking an upwardly ascending numerical value on an inclined surface of said housing on the upper side of said numerical separating means,
Wherein the number blocking means includes a blocking wall extending downward from one side of the slope so as to effectively block the number ascending on the inner wall. .
Using the exhaust gas treatment system of claim 1,
A positioning step in which the positioning means determines the position of the ship,
The method in which the exhaust gas generated by the combustion means flows into the control means and the cleaning liquid is supplied to the exhaust gas processing device for removing the noxious gas in the exhaust gas by injecting the cleaning liquid into the exhaust gas and discharging the sprayed cleaning liquid And a closed mode in which an external washing liquid is supplied to the outside of the vessel, and a closed mode in which the inside washing liquid is recycled is used alternatively. And a cleaning liquid supply system control step of performing a control of the cleaning liquid supply system,
The cleaning liquid supply method control step includes:
And controls the first valve so as to stop the supply of the rinsing liquid from the external rinsing liquid supply means when the ship is located in the discharge regulating area based on the position of the ship received from the positioning means and controls the first valve so that the rinsing liquid discharged from the exhaust gas processing apparatus So that the cleaning liquid is recirculated by controlling the third valve so as to flow into the conduit in which the first valve is disposed,
Controls the first valve to receive the rinse solution from the external rinse solution supply means when the ship is located in an area other than the discharge regulation area based on the position of the ship received from the positioning means, The control unit controls the third valve so as not to flow into the conduit in which the first valve is disposed and to discharge the cleaning liquid to the outside so as to be discharged to the outside of the ship. .
22. The method of claim 21,
Wherein the control means controls the supply of the cleaning liquid to the exhaust gas processing device to be in the closed mode when the position of the ship is within the ECA or SECA. (Method for Automatic Treatment of Hybrid Exhaust Gas).

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