KR20200140567A - SCR Exhaust Gas Denitration Device With Bypass Line - Google Patents

Abstract

The present invention relates to an SCR exhaust gas denitration apparatus with a bypass line and, more specifically, to an SCR exhaust gas denitration apparatus with a bypass line, in which the bypass line is installed in a holding space within a housing unit in which a catalyst layer is embedded such that the bypass line of the exhaust gas denitration apparatus can be easily formed in a narrow space within a ship, and an exit of a reactor line discharging an exhaust gas to the outside and an exit of the bypass line are independently formed without being connected to each other, thereby preventing contamination of the catalyst layer since a foreign substance, generated from the exhaust gas moving through the bypass line, goes into the housing unit through the reactor line when the exit of the reactor line is connected to the exit of the bypass line.

Description

SCR exhaust gas denitration device with bypass line {SCR Exhaust Gas Denitration Device With Bypass Line}

The present invention relates to an SCR flue gas denitration device having a bypass line, and more particularly, a bypass line is installed in a receiving space inside a housing part containing a catalyst layer, thereby bypassing the flue gas denitration device in a narrow space within a ship. The pass line can be easily configured, and the outlet of the reactor line and the outlet of the bypass line that discharge exhaust gas to the outside are not connected to each other and are configured independently, so that the outlet of the reactor line and the outlet of the bypass line When is connected, it relates to an SCR flue gas denitration apparatus having a bypass line, which prevents foreign matter generated from exhaust gas moving through the bypass line from entering the housing portion through the reactor line and contaminating the catalyst layer.

Nitrogen Oxides (NO _X ) among the exhaust gases emitted from ships is a representative air pollutant that is regulated by the International Maritime Organization (IMO), an affiliate of the United Nations (UN).

About 5 million tons of nitrogen oxides emitted from ships each year account for 7% of the world's emissions, and about 70% of nitrogen oxides emitted from ships are generated within 400km from the coast. In the (Emission Control Area, ECA), emissions of nitrogen oxides are more strictly regulated.

IMO categorizes the regulation of nitrogen oxides into Tier Ⅰ, Ⅱ, and Ⅲ according to the shipbuilding period and location of the sea area. Ships built from 2011 must meet Tier Ⅱ standards in all sea areas. Satisfaction of Tier Ⅱ standards in sea areas and Tier Ⅲ standards in emission control areas (ECA) is required.

These nitrogen oxide reduction methods are divided into a pretreatment method that controls the combustion method and a post-treatment method that treats and reduces exhaust gas. The post-treatment devices are SCR (Selective Catalyst Reduction) and SNCR (Selective Noncatalytic Reduction). Reduction, selective non-catalytic reduction).

SCR flue gas denitration system is to change and remove nitrogen oxide into nitrogen and water by passing the exhaust gas between 200℃~450℃ together with a reducing agent, whereas the SNCR device directly injects a reducing agent into the exhaust gas of 800℃ or higher. As a technology for removing nitrogen oxides, since the exhaust gas temperature of the ship is discharged between 300°C and 450°C, the SCR flue gas denitration device is mainly used as a nitrogen oxide reduction device.

1 is a view showing a conventional SCR flue gas denitration device 90, which is disclosed in Korean Utility Model Publication No. 20-2013-0004157 (2013.07.08.).

Referring to FIG. 1, a conventional SCR flue gas denitration device 90 includes a housing unit 91 accommodating a plurality of reactors 911 with a built-in catalyst, and exhaust gas is introduced into the housing unit 91. A reactor line 93 that allows nitrogen oxides of exhaust gas to undergo a selective catalytic reduction reaction with the catalyst and exhaust gas with reduced nitrogen oxides out of the housing 91, and an area other than the emission control sea area (ECA) In, a bypass line 95 is configured to allow exhaust gas to be discharged without passing through the reactor 911 of the housing unit 91.

However, in the case of the conventional SCR flue gas denitration device 90, as shown in FIG. 1, the bypass line 95 had to be configured outside the housing part 91, and the piping work had to be performed separately. There was a lot of hassle, and there is not enough space because various facilities are installed on the ship. When attempting to install a large-volume bypass line 95 as shown in FIG. 1 in such a space inside the ship, such installation space is required. Even preparing it can be difficult.

In addition, even if a space enough to install the bypass line 95 is provided, a sufficient working space is not secured, so the process of installing the bypass line 95 near the housing unit 91 by the operator Many problems can arise from For example, there may be a case where a relatively long piping material does not enter the vessel from the process of bringing in piping material to the vicinity of the housing unit 91, and the surrounding area in the process of moving piping material or changing its position or direction. Interference or collision with equipment may occur.

As a result, the conventional SCR flue gas denitration device 90 has a problem in that it does not consider the narrow space inside the ship at all.

In addition, as shown in FIG. 1, the bypass line 95 is branched from the reactor line 93 at the front end of the housing unit 91, and the bypass line is branched at the rear end of the housing unit 91. The pass line 95 is recombined with the reactor line 93. In this process, various foreign substances are separated from the exhaust gas that has moved through the bypass line 95 and the reactor in the housing unit 91 ( 911), and in this process, there was a problem that the catalyst in the reactor 911 was contaminated by the foreign material.

For this reason, the removal of nitrogen oxides in the exhaust gas through the reactor 911 was not efficiently performed, and the life of the reactor 911 was shortened, so that frequent replacement was required.

In addition, as the foreign matter accumulates on the pipe wall at the outlet end where the reactor line 93 and the bypass line 95 meet, the inside of the pipe at the outlet end is gradually clogged. As a result, back pressure is formed, whereby the bypass Not only the exhaust gas through the line 95 but also the exhaust gas through the reactor line 93 could not be properly discharged.

Therefore, the related industry considers a narrow space inside the ship, prevents the catalyst in the reactor from being contaminated by the exhaust gas that has moved through the bypass line, and prevents the formation of back pressure. The situation is demanding development.

(Utility Model Document 1) Korean Utility Model Publication No. 20-2013-0004157 (2013.07.08.)

The present invention was devised to solve the above problems,

An object of the present invention is to provide a bypass line that allows a bypass line to be installed in a receiving space inside a housing unit containing a catalyst layer, so that a bypass line of a flue gas denitration device can be easily configured in a narrow space within a ship. Branch is to provide an SCR flue gas denitration device.

Another object of the present invention is to configure the bypass line to pass through the inside of the housing unit, so that even if there is not enough space around the housing unit, it is possible to install the bypass line of the flue gas denitration device, SCR flue gas denitration having a bypass line. To provide a device.

Another object of the present invention is that the outlet of the reactor line and the outlet of the bypass line that discharge exhaust gas to the outside are not connected to each other, but are configured independently, so that the outlet of the reactor line and the outlet of the bypass line are connected. At this time, it is to provide an SCR flue gas denitration apparatus having a bypass line, which prevents foreign matter generated from exhaust gas moving through the bypass line from entering the housing portion through the reactor line and contaminating the catalyst layer.

Another object of the present invention is, when the reactor line and the bypass line share an exhaust gas outlet, foreign matter accumulates on the pipe wall at the outlet end from the exhaust gas discharged through the bypass line, and the inside of the pipe at the outlet end is It is to provide an SCR flue gas denitration device having a bypass line in which back pressure is prevented in advance by separating the outlet of the reactor line and the bypass line because it is gradually clogged and the back pressure can be formed.

Another object of the present invention is to configure an accommodation space inside the housing part and a catalyst layer in the accommodation space so that the exhaust gas that has entered the housing part passes through the catalyst layer, so that nitrogen oxides can be removed in accordance with the IMO regulatory conditions. It is to provide an SCR flue gas denitration device having a bypass line.

Another object of the present invention is to configure a reactor line on one side of the housing unit and the other side of the housing unit, so that exhaust gas is introduced into the housing unit through one side of the housing unit so that the introduced exhaust gas passes through the catalyst layer installed inside the housing unit, and the catalyst layer It is to provide an SCR flue gas denitration apparatus having a bypass line so that the exhaust gas that has passed through is discharged to the outside of the housing unit through the other side of the housing unit.

Another object of the present invention is to configure the bypass line to penetrate from one side of the housing unit to the other side, so that the bypass line can be accommodated inside the housing unit, but the exhaust gas discharged through the reactor line and the bypass line It is to provide an SCR flue gas denitration apparatus having a bypass line to prevent the exhaust gas discharged through the mixture from being mixed with each other.

Another object of the present invention is to prevent the flow space of the bypass line and the accommodation space of the housing part from communicating with each other, so that when exhaust gas is to be discharged to the outside without passing through the catalyst layer through the bypass line, the inside of the bypass line It is to provide an SCR exhaust gas denitration device having a bypass line to prevent the exhaust gas from flowing into the accommodation space of the housing.

Another object of the present invention is to configure an inner space on the reactor line and communicate the inner space with the receiving space of the housing unit, so that exhaust gas can flow into the receiving space of the housing unit through the reactor line, and into the receiving space. The introduced exhaust gas is to provide an SCR flue gas denitration apparatus having a bypass line that allows nitrogen oxides to be removed by passing through a catalyst layer formed on the receiving space.

Another object of the present invention is to configure an inlet part on one side of the housing part, and an outlet part on the other side of the housing part, to introduce exhaust gas into the housing part through the inlet part, and exhaust gas to the outside of the housing part through the outlet part. It is to provide an SCR flue gas denitration device having a bypass line to discharge.

Another object of the present invention is to provide a receiving part that includes a bypass line inside the housing part, an inlet part positioned at the front end of the receiving part and exposed to the outside of the housing part, and an inlet part located at the rear end of the receiving part and exposed to the outside of the housing part. It is to provide an SCR flue gas denitration apparatus having a bypass line, in which most of the bypass line is accommodated in the housing unit, but only at least a portion is located outside the housing unit by configuring the outlet unit.

Another object of the present invention is to connect the inlet of the bypass line with the inlet of the reactor line, so that the exhaust gas generated from the engine of the ship can move through a single transfer pipe and then diverge from the front end of the housing part. , To provide an SCR flue gas denitration device having a bypass line.

Another object of the present invention is to prevent the receiving part of the bypass line located on the receiving space of the housing from interfering with the catalyst layer installed on the receiving space, so that the bypass line can be easily configured to avoid the catalyst layer inside the housing part. It is to provide an SCR flue gas denitration device having a bypass line, which prevents a gap between the bypass line and the catalyst layer from flowing out of the housing part of the exhaust gas without nitrogen oxides removed. .

Another object of the present invention is to configure a first damper part in the inlet part of the reactor line, and configure a second damper part in the inlet part of the bypass line to open the first damper part in the discharge control sea area and close the second damper part. By doing so, the exhaust gas from which nitrogen oxides are removed is discharged through the reactor line, and the first damper part is closed and the second damper part is opened to discharge the exhaust gas through the bypass line in areas other than the emission control sea area. It is to provide an SCR flue gas denitration device having a line.

Another object of the present invention is to configure a third damper part in the outlet part of the reactor line, and configure a fourth damper part in the outlet part of the bypass line, so that when the first damper part is opened, the third damper part is opened, and the second It is to provide an SCR flue gas denitration apparatus having a bypass line to open the fourth damper part when the damper part is opened.

Another object of the present invention is to close the third damper part when the fourth damper part is opened, so that foreign substances contained in the exhaust gas fall by gravity in the process of discharging the exhaust gas through the bypass line, and the housing through the outlet part. It is to provide an SCR flue gas denitration device having a bypass line that blocks the problem of entering the inside of the unit and contaminating the catalyst layer.

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

According to an embodiment of the present invention, the present invention provides a housing part in which an accommodation space is formed inside the housing part and a catalyst layer is embedded in the accommodation space, and exhaust gas is introduced into the housing part through one side of the housing part. Reactor lines formed on one side and the other side of the housing part so that the exhaust gas passes through the catalyst layer and the exhaust gas that has passed through the catalyst layer flows out of the housing part through the other side of the housing part, and the other side from one side of the housing part. It characterized in that it comprises a bypass line formed to penetrate.

According to another embodiment of the present invention, the bypass line is characterized in that it passes through the accommodation space.

According to another embodiment of the present invention, the bypass line includes a flow space in which exhaust gas moves, and the flow space does not communicate with the accommodation space.

According to another embodiment of the present invention, the bypass line is not connected to the reactor line at the other side of the housing unit and independently discharges exhaust gas to the outside of the housing unit.

According to another embodiment of the present invention, the reactor line includes an inner space in communication with the accommodation space, and is connected to one side of the housing part to introduce exhaust gas into the housing part. And, an outlet part connected to the other side of the housing part to allow exhaust gas to flow out of the housing part.

According to another embodiment of the present invention, the bypass line includes a receiving portion accommodated in the housing portion, an inlet portion positioned at a front end of the receiving portion and exposed to the outside of the housing portion, and the It is located at the rear end of the receiving portion and characterized in that it comprises an outlet portion exposed to the outside of the housing.

According to another embodiment of the present invention, in the present invention, the outlet portion is not connected to the outlet portion.

According to another embodiment of the present invention, the inlet portion is characterized in that it is connected to the inlet portion.

According to another embodiment of the present invention, the inlet portion is characterized in that an end of the inlet portion is connected to the inlet portion, so that the flow space of the inlet portion and the inner space of the inlet portion communicate with each other.

According to another embodiment of the present invention, the receiving portion is characterized in that it does not interfere with the catalyst layer.

According to another embodiment of the present invention, the inlet part further includes a first damper part for controlling the flow of exhaust gas, and the inlet part adds a second damper part for controlling the flow of exhaust gas Including a furnace, the second damper part is closed when the first damper part is opened, and the second damper part is opened when the first damper part is closed.

According to another embodiment of the present invention, the outlet unit further includes a third damper unit for controlling the flow of exhaust gas, and the outlet unit adds a fourth damper unit for controlling the flow of exhaust gas Including a furnace, the third damper part is opened when the first damper part is opened, and the fourth damper part is opened when the second damper part is opened.

According to another embodiment of the present invention, the third damper part is closed when the fourth damper part is opened.

The present invention can obtain the following effects by the configuration, combination, and use relationship that will be described below with the present embodiment.

The present invention allows the bypass line to be installed in the accommodation space inside the housing unit containing the catalyst layer, so that the bypass line of the flue gas denitration device can be easily configured in a narrow space within a ship, and has a bypass line. It has the effect of providing a flue gas denitration device.

The present invention provides an SCR flue gas denitration device having a bypass line by configuring the bypass line to pass through the inside of the housing part, so that even if there is not enough space around the housing part, the bypass line of the flue gas denitration device can be installed. To produce the effect.

In the present invention, the outlet of the reactor line for discharging exhaust gas to the outside and the outlet of the bypass line are not connected to each other and are configured independently, so that when the outlet of the reactor line and the outlet of the bypass line are connected, the bypass There is an effect of providing an SCR flue gas denitration apparatus having a bypass line, which prevents foreign matter generated from exhaust gas moving through the line from entering the housing portion through the reactor line and contaminating the catalyst layer.

In the present invention, when the reactor line and the bypass line share the exhaust gas outlet, foreign matter accumulates on the pipe wall at the outlet end from the exhaust gas discharged through the bypass line, thereby gradually clogging the inside of the pipe at the outlet end. As can be formed, it has the effect of providing an SCR flue gas denitration device having a bypass line in which the generation of back pressure is prevented by separating the outlet of the reactor line and the bypass line.

The present invention constitutes an accommodation space inside a housing part, and a catalyst layer is formed in the accommodation space, so that the exhaust gas entering the housing part passes through the catalyst layer, so that nitrogen oxides can be removed in accordance with IMO regulation conditions, It derives the effect of providing an SCR flue gas denitration device having a bypass line.

In the present invention, by configuring reactor lines on one side of the housing unit and the other side, exhaust gas is introduced into the housing unit through one side of the housing unit, so that the introduced exhaust gas passes through the catalyst layer installed inside the housing unit, and the exhaust through the catalyst layer There is an effect of providing an SCR flue gas denitration apparatus having a bypass line to allow gas to flow out of the housing through the other side of the housing.

In the present invention, the bypass line is configured to penetrate from one side of the housing unit to the other side, so that the bypass line can be accommodated inside the housing unit, but exhaust gas discharged through the reactor line and exhaust gas discharged through the bypass line It has the effect of providing an SCR flue gas denitration device having a bypass line so that exhaust gases are not mixed with each other.

In the present invention, by preventing the flow space of the bypass line and the accommodation space of the housing part from communicating with each other, when exhaust gas is to be discharged to the outside without passing through the catalyst layer through the bypass line, the exhaust gas inside the bypass line is It derives the effect of providing an SCR flue gas denitration device having a bypass line that does not flow into the housing part.

The present invention constitutes an internal space on the reactor line, and communicates the internal space with the accommodation space of the housing part, so that exhaust gas can be introduced into the accommodation space of the housing part through the reactor line, and the exhaust gas introduced into the accommodation space There is an effect of providing an SCR flue gas denitration apparatus having a bypass line that allows nitrogen oxides to be removed by passing through the catalyst layer formed on the receiving space.

The present invention comprises an inlet portion on one side of the housing portion, and an outlet portion on the other side of the housing portion to inflow exhaust gas into the housing portion through the inlet portion, and to discharge exhaust gas to the outside of the housing portion through the outlet portion, It has the effect of providing an SCR flue gas denitration device having a bypass line.

In the present invention, the bypass line comprises a receiving portion accommodated inside the housing portion, an inlet portion positioned at the front end of the receiving portion and exposed to the outside of the housing portion, and an outlet portion positioned at the rear end of the receiving portion and exposed to the outside of the housing portion. , It results in the effect of providing an SCR flue gas denitration device having a bypass line in which most of the bypass line is accommodated in the housing part, but only a minimum part is located outside the housing part.

The present invention is a bypass line that connects the inlet of the bypass line to the inlet of the reactor line, so that the exhaust gas generated from the engine of the ship can move through a single conveying pipe and then diverge from the front end of the housing. There is an effect of providing an SCR flue gas denitration device having.

In the present invention, by preventing the receiving part of the bypass line located on the receiving space of the housing part from interfering with the catalyst layer installed on the receiving space, the bypass line can be easily configured to avoid the catalyst layer inside the housing part, It has an effect of providing an SCR flue gas denitration apparatus having a bypass line, which prevents a gap between the bypass line and the catalyst layer so that the exhaust gas from which nitrogen oxide has not been removed flows out of the housing.

In the present invention, the reactor line is closed by configuring the first damper part in the inlet part of the reactor line and the second damper part in the inlet part of the bypass line, opening the first damper part in the discharge control sea area and closing the second damper part. SCR with a bypass line that allows exhaust gas from which nitrogen oxides have been removed through and discharges exhaust gas through the bypass line by closing the first damper part and opening the second damper part in areas other than the emission control sea area It derives the effect of providing a flue gas denitration device.

In the present invention, a third damper part is configured in the outlet part of the reactor line, and a fourth damper part is configured in the outlet part of the bypass line, so that the third damper part is opened when the first damper part is opened, and when the second damper part is opened. There is an effect of providing an SCR flue gas denitration device having a bypass line to open the fourth damper part.

In the present invention, when the fourth damper part is opened, the third damper part is closed, so that foreign substances contained in the exhaust gas fall by gravity in the process of discharging the exhaust gas through the bypass line and enter the housing part through the outlet part. It has the effect of providing an SCR flue gas denitration apparatus having a bypass line, which blocks the problem of contaminating the catalyst layer.

1 is a view showing a conventional SCR flue gas denitration apparatus.
2 is a perspective view of an SCR flue gas denitration apparatus having a bypass line according to an embodiment of the present invention.
Figure 3 is a front view of Figure 2;
4 is a cross-sectional view taken along AA′ of FIG. 2.
5 is a cross-sectional view taken along BB' of FIG. 2.
Figure 6 is a bottom view of Figure 2;
7 is a view showing that the inlet portion and the inlet portion are connected.
Figure 8 is a plan view of Figure 2;
9 is a view showing an SCR flue gas denitration apparatus having a bypass line according to another embodiment of the present invention.
Figure 10 is a state of use of the present invention.

Hereinafter, preferred embodiments of an SCR flue gas denitration apparatus having a bypass line according to the present invention will be described in detail with reference to the accompanying drawings. In the following description of the present invention, if it is determined that a detailed description of a known function or configuration may unnecessarily obscure the subject matter of the present invention, a detailed description thereof will be omitted. Unless otherwise defined, all terms in this specification are the same as the general meanings of the terms understood by those of ordinary skill in the art to which the present invention belongs, and in case of conflict with the meanings of terms used in the present specification, the present disclosure According to the definitions used in the specification.

The SCR flue gas denitration apparatus 1 having a bypass line according to the present invention allows the bypass line to be installed in the accommodation space inside the housing part containing the catalyst layer, thereby facilitating the bypass line of the flue gas denitration system in a narrow space inside the ship. When the outlet of the reactor line and the outlet of the bypass line are connected to each other, the outlet of the reactor line that discharges exhaust gas to the outside and the outlet of the bypass line are not connected to each other but are independently configured. It is characterized in that it prevents foreign matter generated from the exhaust gas that has moved through the bypass line from entering the housing unit through the reactor line and contaminating the catalyst layer.

2 is a perspective view of an SCR flue gas denitration apparatus 1 having a bypass line according to an embodiment of the present invention, and FIG. 3 is a front view of FIG. 2, and referring to FIGS. 2 and 3, the bypass line is The branch SCR flue gas denitration apparatus 1 includes a housing part 10, a reactor line 30, and a bypass line 50.

The housing unit 10 refers to a configuration in which the receiving space 101 is formed inside and the catalyst layer 11 is embedded in the receiving space 101. The receiving space 101 is formed inside the housing part 10, and the catalyst layer 11 is formed in the receiving space 101, so that the exhaust gas entering the housing part 10 is transferred to the catalyst layer 11 ), it is possible to remove nitrogen oxides. The shapes shown in FIGS. 2 and 3 illustrate an example of the housing unit 10, and the housing unit 10 is not limited to this shape. However, the housing unit 10 accommodates the catalyst layer 11 therein, and an accommodation space 101 inside the housing unit 10 so that the exhaust gas introduced into the housing unit 10 can pass through the catalyst layer 11 It should be formed, and it is preferable to be configured in a hollow shape.

The catalyst layer 11 transfers nitrogen oxides (NO _X ) to the human body through a chemical reaction with a reducing agent in the exhaust gas introduced onto the housing 10 through a selective catalyst reduction (SCR) method. It refers to the composition to be discharged after decomposition into harmless water (H ₂ 0) and nitrogen (N ₂ ). In order to increase this effect, the catalyst layer 11 may be formed in plural as shown in FIG. 4 in the receiving space 101 of the housing part 10.

The reactor line 30 flows exhaust gas into the housing 10 through one side of the housing 10 so that the introduced exhaust gas passes through the catalyst layer 11 and the catalyst layer ( 11) refers to a configuration formed on one side and the other side of the housing unit 10 so that the exhaust gas that has passed through it is discharged to the outside of the housing unit 10 through the other side of the housing unit 10. That is, by configuring the reactor line 30 on one side and the other side of the housing unit 10, exhaust gas is introduced into the interior of the housing unit 10 through one side of the housing unit 10 The gas passes through the catalyst layer 11 installed inside the housing unit 10, and the exhaust gas that has passed through the catalyst layer 11 passes through the other side of the housing unit 10 to the outside of the housing unit 10. You can let it spill.

The reactor line 30 includes an internal space 301 in communication with the accommodation space 101, and exhaust gas into the accommodation space 101 of the housing unit 10 through the reactor line 30. And nitrogen oxides may be removed while the exhaust gas introduced into the receiving space 101 passes through the catalyst layer 11 formed on the receiving space 101. As shown in FIG. 2, the reactor line 30 is illustrated in the form of a pipe having a circular cross section in which one side and the other side are open, but the shape of the reactor line 30 is not limited thereto. It can be configured in various forms.

FIG. 4 is a cross-sectional view taken along line A-A' of FIG. 2. Referring to FIG. 4, the reactor line 30 includes an inlet portion 31 and an outlet portion 33.

The inlet part 31 is connected to one side of the housing part 10 to introduce exhaust gas into the housing part 10. Referring to FIG. 4, the inlet portion 31 includes an inner space 301 inside, and the inner space 301 is configured to communicate with the receiving space 101 of the housing unit 10, Exhaust gas that has entered through the inner space 301 of the inlet unit 31 is passed through the receiving space 101 of the housing unit 10 and exits through the inner space 301 of the outlet unit 33 to be described later. . As shown in FIG. 4, the inlet part 31 may be configured not to be connected to the inlet part 53 of the bypass line 50 to be described later, and unlike that shown in FIG. 4, the inlet The portion 31 and the inlet portion 53 to be described later may be configured to communicate with each other.

The outlet part 33 is connected to the other side of the housing part 10 to allow exhaust gas to flow out of the housing part 10. The outlet part 33, like the inlet part 31, includes an inner space 301 inside, and the inner space 301 is configured to communicate with the receiving space 101 of the housing part 10 do. Therefore, only the exhaust gas that has entered the receiving space 101 of the housing unit 10 through the inlet unit 31 and has passed through the catalyst layer 11 passes through the outlet unit 33 to the housing unit 10 Can be discharged to the outside. As will be described later, in order to prevent contamination of the catalyst layer 11, the outlet portion 33 is not connected to the outlet portion 55 of the bypass line 50 to be described later, but independently discharges exhaust gas. It is preferably configured as shown in.

The bypass line 50 may be configured to penetrate from one side of the housing 10 to the other side, and the bypass line 50 may be configured to pass through the accommodation space 101. Through this, even if there is not enough space around the housing part 10, the installation of the bypass line 50 of the flue gas denitration apparatus 1 can be facilitated.

The bypass line 50 includes a flow space 501 through which exhaust gas moves, and the flow space 501 is configured not to communicate with the accommodation space 101, and the bypass line When exhaust gas is to be discharged to the outside without passing through the catalyst layer 11 through 50, the exhaust gas inside the bypass line 50 flows into the accommodation space 101 of the housing unit 10 It will not be. That is, the bypass line 50 is configured to penetrate from one side of the housing unit 10 to the other side, so that the bypass line 50 can be accommodated inside the housing unit 10, but the The exhaust gas discharged through the reactor line 30 and the exhaust gas discharged through the bypass line 50 may not be mixed with each other.

Preferably, the bypass line 50 is not connected to the reactor line 30 at the other side of the housing unit 10 and is configured to independently discharge exhaust gas to the outside of the housing unit 10 Can be. Accordingly, the outlet of the reactor line 30 and the outlet of the bypass line 50 for discharging the exhaust gas to the outside are not connected to each other and are configured independently, so that the outlet of the reactor line 30 and the bypass line When the outlet of the line 50 is connected, foreign matter generated from the exhaust gas that has moved through the bypass line 50 enters the housing part 10 through the reactor line 30 and enters the catalyst layer 11 Can be prevented from contaminating.

In addition, when the reactor line 30 and the bypass line 50 share the exhaust gas outlet, foreign matter accumulates on the pipe wall at the outlet end from the exhaust gas discharged through the bypass line 50. , Since the inside of the pipe at the outlet end may be gradually blocked, the back pressure may be formed. By separating the outlet of the reactor line 30 and the bypass line 50, the generation of back pressure may be prevented in advance.

4 is a cross-sectional view taken along line A-A' of FIG. 2, and referring to FIG. 4, the bypass line 50 may be divided into a receiving portion 51, an inlet portion 53, and an outlet portion 55.

The receiving part 51 is a part accommodated inside the housing part 10, and accommodates the receiving part 51, which occupies most of the bypass line 50, in the housing part 10, Only a minimum portion may be positioned outside the housing 10. FIG. 5 is a cross-sectional view taken along BB′ of FIG. 2, and referring to FIG. 5, the receiving part 51 is configured so as not to interfere with the catalyst layer 11, and the catalyst layer inside the housing part 10 ( 11) so that the bypass line 50 can be easily configured. In addition, as shown in FIG. 5, the exhaust gas from which nitrogen oxides are not removed flows out of the housing unit 10 by configuring so that there is no gap between the bypass line 50 and the catalyst layer 11 It is desirable to block the problem that becomes.

The inlet part 53 is positioned at a front end of the receiving part 51 to be exposed to the outside of the housing part 10, and the inlet part 53 is connected to the inlet part 31 To do. The connection between the inlet part 53 and the inlet part 31 is such that one end of the inlet part 53 is directly connected to the inlet part 31 so that the flow space 501 of the inlet part 53 and the inlet part are connected. The inner space 301 of the part 31 may be communicated with each other, and as shown in FIG. 6, the inlet part 53 and the inlet part 31 are configured to be separated, but as shown in FIG. Likewise, it may be indirectly connected through a connection with a branched pipe. However, in any case, it is determined whether the exhaust gas generated from the engine of the ship, etc., enters the interior of the housing 10 or the bypass line 50 at the front end of the housing 10. It is the same in points.

The outlet part 55 is located at the rear end of the receiving part 51 and is exposed to the outside of the housing part 10. 8 is a plan view of FIG. 2, and referring to FIG. 8, it is preferable that the outlet part 55 is configured not to be connected to the outlet part 33 as shown in FIG. 8. When the outlet portion 33 of the reactor line 30 and the outlet portion 55 of the bypass line 50 are connected to each other, foreign matter contained in the exhaust gas that has moved through the bypass line 50 This is because the catalyst layer 11 located on the receiving space 101 may be contaminated by entering the receiving space 101 inside the housing part 10 through the outlet part 33 of the reactor line 30. to be.

FIG. 9 is a view showing an SCR flue gas denitration apparatus having a bypass line according to another embodiment of the present invention. In FIG. 9, a damper part is added in the embodiments shown in FIGS. 2 to 8 above. In order to avoid overlapping description, hereinafter, only the newly added damper part will be described.

The inlet part 31 further includes a first damper part 311 for controlling the flow of exhaust gas, and the inlet part 53 is a second damper part 531 for controlling the flow of exhaust gas It may further include. Preferably, the first damper part 311 is on the inlet part 31 as shown in FIG. 9, and the second damper part 531 is the inlet part 53 as shown in FIG. It can be formed on. More preferably, when the first damper part 311 is opened, the second damper part 531 is closed, and when the first damper part 311 is closed, the second damper part 531 is opened. , In the emission control sea area (ECA), the exhaust gas from which nitrogen oxides are removed is discharged through the reactor line 30 by opening the first damper part 311 and closing the second damper part 531, In an area other than the emission control sea area (ECA), the first damper part 311 may be closed and the second damper part 531 may be opened to allow exhaust gas to be discharged through the bypass line 50.

The outlet unit 33 further includes a third damper unit 331 for controlling the flow of exhaust gas, and the outlet unit 55 is a fourth damper unit 551 for controlling the flow of exhaust gas It may further include. Preferably, the third damper part 331 may be formed on the outlet part 33 as shown in FIG. 9, and the fourth damper part 551 is discharged as shown in FIG. It may be formed on the portion 55. In addition, for smooth exhaust gas discharge, when the first damper part 311 is opened, the third damper part 331 is opened, and when the second damper part 531 is opened, the fourth damper part 551 ) Can be opened. More preferably, the third damper part 331 is configured to be closed when the fourth damper part 551 is opened, and exhaust gas in the process of discharging the exhaust gas through the bypass line 50 It is possible to block a problem in that a foreign material contained in the catalyst layer 11 may be contaminated by entering the housing unit 10 through the outlet unit 33 of the reactor line 30 while falling by gravity.

FIG. 10 is a state diagram of use of the present invention. Referring to FIG. 10, exhaust gas generated from an engine or the like on a ship is moved to the SCR flue gas denitration device 1 through a single conveying pipe. The transfer pipe is branched at the front end of the housing part 10, and when the ship is in the emission control sea area (ECA), the exhaust gas is moved toward the reactor line 30 to pass through the housing part 10. To discharge, and when the ship is not located in the emission control sea area (ECA), the exhaust gas is moved toward the bypass line 50 so that the exhaust gas is not passed through the catalyst layer 11 through the bypass line 50. By discharging, the efficient operation of the device can be achieved. Above all, as shown in Fig. 10, the outlet of the reactor line 30 and the outlet of the bypass line 50 are formed separately, respectively, the outlet of the reactor line 30 and the bypass line ( When the outlet of 50) is connected, foreign matter generated from the exhaust gas that has moved through the bypass line 50 enters the housing part 10 through the reactor line 30 and contaminates the catalyst layer 11 Can be prevented.

The detailed description above is illustrative of the present invention. In addition, the above description shows and describes preferred embodiments of the present invention, and the present invention can be used in various other combinations, modifications and environments. That is, changes or modifications may be made within the scope of the concept of the invention disclosed in the present specification, the scope equivalent to the disclosed contents, and/or the skill or knowledge of the art. The above-described embodiments describe the best state for implementing the technical idea of the present invention, and various changes required in the specific application fields and uses of the present invention are possible. Therefore, the detailed description of the invention is not intended to limit the invention to the disclosed embodiment. In addition, the appended claims should be construed as including other embodiments.

1: SCR flue gas denitration device with bypass line
10: housing part
101: accommodation space
11: catalyst bed
30: reactor line
301: internal space
31: inlet
311: first damper part
33: outlet unit
331: third damper part
50: bypass line
501: flow space
51: receiving part
53: inlet
531: second damper part
55: outlet
551: fourth damper part

Claims (13)

A housing part in which a receiving space is formed inside and a catalyst layer is embedded in the receiving space,
The exhaust gas is introduced into the housing unit through one side of the housing unit so that the introduced exhaust gas passes through the catalyst layer, and the exhaust gas that has passed through the catalyst layer is discharged to the outside of the housing unit through the other side of the housing unit. Reactor lines formed on one side and the other side of the housing,
SCR flue gas denitration apparatus having a bypass line, characterized in that it comprises a bypass line formed so as to penetrate from one side of the housing portion to the other side. The method of claim 1,
The bypass line, characterized in that passing through the accommodation space, SCR flue gas denitration apparatus having a bypass line. The method of claim 2,
The bypass line includes a flow space in which the exhaust gas moves,
The flow space, characterized in that not in communication with the receiving space, SCR flue gas denitration apparatus having a bypass line. The method of claim 3,
The bypass line is an SCR flue gas denitration apparatus having a bypass line, characterized in that the exhaust gas is not connected to the reactor line from the other side of the housing unit and independently discharges exhaust gas to the outside of the housing unit. The method of claim 4,
The reactor line includes an inner space in communication with the accommodation space, an inlet part connected to one side of the housing part to introduce exhaust gas into the housing part, and an inlet part connected to the other side of the housing part to an outside of the housing part. SCR flue gas denitration apparatus having a bypass line, characterized in that it comprises an outlet for outflowing exhaust gas. The method of claim 5,
The bypass line includes a receiving portion accommodated inside the housing portion, an inlet portion positioned at a front end of the receiving portion and exposed to the outside of the housing portion, and an outlet portion positioned at a rear end of the receiving portion and exposed to the outside of the housing portion. SCR flue gas denitration apparatus having a bypass line, characterized in that it comprises a unit. The method of claim 6,
The outlet portion, the SCR flue gas denitration apparatus having a bypass line, characterized in that not connected to the outlet portion. The method of claim 6,
The inlet portion, characterized in that connected to the inlet portion, SCR flue gas denitration apparatus having a bypass line. The method of claim 8,
The inlet portion, an end portion of the inlet portion is connected to the inlet portion, characterized in that the flow space of the inlet portion and the inner space of the inlet portion communicate with each other, SCR flue gas denitration apparatus having a bypass line. The method of claim 6,
The accommodating part, the SCR flue gas denitration apparatus having a bypass line, characterized in that it does not interfere with the catalyst layer. The method of claim 6,
The inlet part further includes a first damper part for controlling the flow of exhaust gas, and the inlet part further includes a second damper part for controlling the flow of exhaust gas, and when the first damper part is opened, the second SCR flue gas denitration apparatus having a bypass line, characterized in that the damper part is closed, and the second damper part is opened when the first damper part is closed. The method of claim 11,
The outlet unit further includes a third damper unit for controlling the flow of exhaust gas, and the outlet unit further includes a fourth damper unit for controlling the flow of exhaust gas, and when the first damper unit is opened, the third SCR flue gas denitration apparatus having a bypass line, characterized in that the damper part is opened, and the fourth damper part is opened when the second damper part is opened. The method of claim 12,
The third damper portion, characterized in that closed when the fourth damper portion is opened, SCR flue gas denitration apparatus having a bypass line.

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