KR20150133990A - Reductant supply system and method for managing the same - Google Patents

Abstract

The present invention relates to a reductant supply system and a method for operating the same. According to an embodiment of the present invention, the reductant supply system comprises: a spray nozzle for spraying a reductant; a reductant storage unit for storing a reductant to be supplied to the spray nozzle; a reductant supply line for connecting the reductant storage unit and the spray nozzle; a first valve installed on the reductant supply line; a water supply unit for supplying water to the spray nozzle; a first purge line for connecting the reductant supply line between the first valve and the spray nozzle to the water supply unit; a second valve installed on the first purge line; an air supply unit for supplying compressed air to the spray nozzle; an air supply line for connecting the spray nozzle and the air supply unit; a third valve installed on the air supply line; a second purge line for connecting the air supply line between the third valve and the air supply line to the reductant supply line between the first valve and the spray nozzle; a fourth valve installed on the second purge line; a drain line branched from the reductant supply line at a merge point between the spray nozzle and the second purge line and connected to the reductant storage unit; and a fifth valve installed on the drain line.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a reducing agent supply system,

The present invention relates to a reducing agent supply system and a method of operating the same, and more particularly, to a reducing agent supply system for supplying a reducing agent used in a selective catalytic reduction reaction for reducing nitrogen oxides contained in exhaust gas, will be.

Generally, a selective catalytic reduction (SCR) system is a system for reducing nitrogen oxides by purifying exhaust gas generated from a diesel engine, a boiler, and an incinerator.

The selective catalytic reduction system reacts the nitrogen oxides contained in the exhaust gas with the reducing agent while passing the exhaust gas and the reducing agent together in the reactor equipped with the catalyst, thereby reducing the nitrogen and the water vapor.

The selective catalytic reduction system uses ammonia (NH ₃ ) generated by directly spraying urea as a reducing agent to reduce nitrogen oxides or by hydrolyzing urea.

The reducing agent is supplied and injected through a reducing agent supply system.

In the conventional reductant supply system, during operation for reducing nitrogen oxides, a reducing agent and compressed air are supplied to the injection nozzle to supply the reducing agent with the atomized nozzle into the high-temperature gas.

When the operation of the selective catalytic reduction system is stopped, water is supplied to the reducing agent supply line, the remaining reducing agent is injected into the high temperature gas through the injection nozzle, and air is again supplied to supply the remaining reducing agent and water to the injection nozzle And then removed.

However, when the purge operation using water and air is performed to remove the reducing agent remaining in the reducing agent supply line, there is a problem that an excessive amount of the reducing agent is injected instantaneously through the injection nozzle at an early stage.

Accordingly, there is a fear that a clogging phenomenon occurs in the injection nozzle or a deposit is formed in the chamber where the reducing agent is decomposed.

Further, when the operation of the selective catalytic reduction system is to be stopped, further selective catalytic reduction system operation is required for the decomposition of the residual reducing agent removed from the reducing agent supply line.

In addition, when the reducing agent remaining in the reducing agent supply line is not completely removed, the reducing agent is crystallized in the reducing agent supply line, causing various valves and a mass flow controller (MFC) installed in the reducing agent supply line to malfunction.

An embodiment of the present invention provides a reducing agent supply system and an operation method thereof capable of effectively removing a reducing agent remaining in a supply pipe at the time of shutdown.

According to an embodiment of the present invention, the reducing agent supply system supplies a reducing agent to be used in a selective catalytic reduction reaction for reducing nitrogen oxides (NOx) contained in the exhaust gas. The reducing agent supply system may further include a reducing agent storage unit for storing the reducing agent to be supplied to the injection nozzle, a reducing agent supply line for connecting the reducing agent storage unit and the injection nozzle, A first purge line connecting the reducing agent supply line between the first valve and the injection nozzle to the water supply unit; and a second purge line connected to the first purge line, An air supply line connecting the injection nozzle and the air supply unit, a third valve provided on the air supply line, and a third valve disposed on the air supply line. And the air supply line between the first valve and the air supply unit is connected to the reducing agent supply line between the first valve and the injection nozzle A fourth valve disposed on the second purge line; a drain line branched from the reducing agent supply line between the injection nozzle and the second purge line confluence point and connected to the reducing agent storage part; And a fifth valve installed on the line.

In addition, the reducing agent supply system may further include a supply pump installed on the reducing agent supply line.

The reducing agent supply system may further include a recovery line branched from the reducing agent supply line between the first valve and the reducing agent storage unit and connected to the reducing agent storage unit.

The reducing agent supply system may further include a mass flow controller provided on the reducing agent supply line between the first valve and the injection nozzle.

According to an embodiment of the present invention, the method of operating the reducing agent supply system may include opening the first valve and the third valve, closing the second valve, the fourth valve, and the fifth valve, A reducing agent injection step of injecting the reducing agent stored in the first valve and the compressed air supplied by the air supply unit through the injection nozzle, and a reducing agent injection step of opening the third valve and the fifth valve, The fourth valve is closed and the reducing agent remaining in the reducing agent supply line is moved to the reducing agent storage part through the drain line to remove the first reducing agent, and the second valve and the third valve are opened, The fourth valve and the fifth valve are closed to inject the water supplied by the water supply unit to the injection nozzle, The second valve and the fourth valve are closed and the first valve and the second valve and the fifth valve are closed so that the air supplied by the air supply unit And thirdly removing the reducing agent and the water present in the reducing agent supply line while injecting the water with the injection nozzle.

The method of operating the reducing agent supply system may further include closing the first valve, the second valve, the third valve, the fourth valve, and the fifth valve to stop the injection of the injection nozzle .

According to the embodiment of the present invention, the reducing agent supply system and the operating method thereof can effectively remove the reducing agent remaining in the supply pipe at the time of shutdown.

FIG. 1 is a configuration diagram illustrating a reducing agent supply system according to an embodiment of the present invention.
FIGS. 2 to 5 are schematic views sequentially illustrating the operation of the reducing agent supply system of FIG. 1. FIG.
6 is a graph showing the operating logic of the reducing agent supply system of FIG.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings, which will be readily apparent to those skilled in the art to which the present invention pertains. The present invention may be embodied in many different forms and is not limited to the embodiments described herein.

The drawings are schematic and illustrate that they are not drawn to scale. The relative dimensions and ratios of the parts in the figures are exaggerated or reduced in size for clarity and convenience in the figures, and any dimensions are merely illustrative and not restrictive. And to the same structure, element or component appearing in more than one drawing, the same reference numerals are used to denote similar features.

The embodiments of the present invention specifically illustrate ideal embodiments of the present invention. As a result, various variations of the illustration are expected. Thus, the embodiment is not limited to any particular form of the depicted area, but includes modifications of the form, for example, by manufacture.

Hereinafter, a reducing agent supply system 101 according to an embodiment of the present invention will be described with reference to FIG.

The reducing agent supply system 101 according to an embodiment of the present invention is used in a selective catalytic reduction (SCR) system for reducing nitrogen oxides (NOx) contained in the exhaust gas, Supply.

For example, the selective catalytic reduction system removes nitrogen oxides (NOx) contained in the exhaust gas discharged from the engine through a reduction reaction, thereby reducing the nitrogen oxide content of the exhaust gas. Here, the engine may be a low speed or medium speed diesel engine used in ships.

However, the selective catalytic reduction system is not limited to the exhaust gas discharged from the engine, and can be used in various fields such as a plant.

In addition, the reducing agent supply system 101 according to the embodiment of the present invention injects the reducing agent into the reducing agent decomposition chamber 100, but the embodiment of the present invention is not limited thereto. That is, the reducing agent supply system 101 according to an embodiment of the present invention may inject the reducing agent directly into the exhaust gas flow path of the exhaust gas or the selective catalytic reduction reactor, not the reducing agent decomposition chamber 100.

The reducing agent decomposition chamber 100 generates ammonia (NH ₃ ) used as a reducing agent for decomposing urea (CO (NH ₂ ) ₂ ), which is a reducing agent injected by the reducing agent supply system, to reduce nitrogen oxides do.

When urea, CO (NH ₂ ) ₂ ) is decomposed in the reducing agent decomposition chamber 100, isocyanic acid (HNCO) is produced together with ammonia (NH ₃ ). And isocyanate is decomposed again and becomes ammonia. That is, the urea is decomposed and finally ammonia can be produced.

1, a reducing agent supply system 101 according to an embodiment of the present invention includes an injection nozzle 700, a reducing agent storage unit 200, a reducing agent supply line 610, a first valve 510, The first purge line 620, the second valve 520, the air supply unit 300, the air supply line 630, the third valve 530, the second purge line 640, 4 valve 540, a drain line 650, and a fifth valve 550.

Also, the reducing agent supply system 101 according to an embodiment of the present invention may further include a supply pump 280, a recovery line 690, and a mass flow controller 800.

The injection nozzle 700 is installed at a location where the reducing agent decomposition chamber 100 or other location for spraying the reducing agent injects the reducing agent. The injection nozzle 700 receives the reducing agent and the compressed air together and injects the atomized reducing agent into the high-temperature gas.

The reducing agent storage unit 200 stores a reducing agent to be supplied to the injection nozzle 700. The reducing agent supply line 610 connects the reducing agent storage unit 200 and the injection nozzle 700.

The first valve 510 is provided on the reducing agent supply line 610 to control on-off the supply of the reducing agent from the reducing agent storage unit 200 to the injection nozzle 700.

The supply pump 280 is installed on the reducing agent supply line 610 to supply the reducing agent of the reducing agent storage unit 200 to the injection nozzle 700.

When the atomized reducing agent is injected into the injection nozzle 700 during the operation of the selective catalytic reduction system, the first valve 510 and the third valve 530 to be described later are opened and the remaining valves 520, 540, 550 Is closed.

The water supply unit 400 supplies water to the injection nozzle 700. The water supplied by the water supply unit 400 is used to remove the reducing agent remaining in the reducing agent supply line 610 after the supply of the reducing agent from the reducing agent storage unit 200 to the injection nozzle 700 is stopped.

The first purge line 620 connects the reducing agent supply line 610 between the first valve 510 and the injection nozzle 700 to the water supply unit 400. That is, after the first valve 510 is closed and the supply of the reducing agent from the reducing agent storage unit 200 to the injection nozzle 700 is stopped, water is supplied from the water supply unit 400 by the first purge line 620, The residual reducing agent in the supply line 610 can be removed.

The second valve 520 is installed on the first purge line 620 to allow water to be supplied to the reducing agent supply line 610 via the first purge line 620 by the water supply unit 400, off.

When the residual reducing agent in the reducing agent supply line 610 is removed by the water supplied by the water supply unit 400, the second valve 520 and the third valve 530 are opened and the remaining valves 510, 540 and 550 are closed.

The air supply unit 300 supplies compressed air to the injection nozzle 700. At this time, the air supply unit 300 can supply the compressed air to the injection nozzle 700 through the air supply line 630, and if necessary, the reducing agent supply line 610 through the second purge line 640 The compressed air can be supplied to the injection nozzle 700 through the nozzle.

Specifically, the compressed air supplied to the injection nozzle 700 via the air supply line 630 is injected together with the reducing agent supplied to the injection nozzle 700 via the reducing agent supply line 610 to spray the atomized reducing agent .

The third valve 530 is provided on the air supply line 630 to enable the compressed air supplied by the air supply unit 300 to be supplied to the injection nozzle 700 through the air supply line 630 on- ).

The second purge line 640 is connected to the reducing agent supply line 610 between the first valve 510 and the spray nozzle 700 and the air supply line 630 between the third valve 530 and the air supply unit 300, Connect. The compressed air supplied by the air supply unit 300 through the second purge line 640 is supplied to the spray nozzle 700 through the first purge line 620 in the water supply unit 400, Is used to remove the reducing agent and water remaining in the reducing agent supply line (610).

In addition, in the embodiment of the present invention, the confluence point of the first purge line 620 and the reducing agent supply line 610 may be the same as the confluence point of the second purge line 640 and the reducing agent supply line 610, One section of the first purge line 620 and the second section of the second purge line 640 may overlap.

The fourth valve 540 is installed in the second purge line 640 and controls the compressed air supplied by the air supply unit 300 to be supplied to the reducing agent supply line 540 through the second purge line 640.

When the residual reducing agent and water in the reducing agent supply line 610 are removed by the compressed air supplied by the air supply unit 300, the third valve 530 and the fourth valve 540 are opened and the remaining valves (510, 520, 550) are closed.

The drain line 650 branches from the reducing agent supply line 610 between the injection nozzle 700 and the second purge line 640 and is connected to the reducing agent storage unit 200.

After the first valve 510 is closed and the reducing agent in the reducing agent storage part 200 is stopped from moving to the injection nozzle 700 via the reducing agent supply line 610, the drain line 650 is closed by the water supply part 400 The reducing agent remaining in the reducing agent supply line 610 is drained to the reducing agent storage unit 200 before water is supplied and the remaining reducing agent in the reducing agent supply line 610 is pushed out to the injection nozzle 700 .

At this time, the drain of the reducing agent through the drain line 650 flows from the reducing agent storage unit 200, the reducing agent supply line 610, and the spray nozzle 700 to the air supply unit 300, A portion of the compressed air supplied to the injection nozzle 700 through the reducing agent supply line 610 flows backward along the reducing agent supply line 610 and pushes the remaining reducing agent of the reducing agent supply line 610 to the drain line 650.

Also, since the drain line 650 does not simply remove the residual reducing agent in the reducing agent supply line 610 but also returns it to the reducing agent storage unit 200, the residual reducing agent can be recycled in one embodiment of the present invention.

The fifth valve 550 is installed in the drain line 650 to control the drain of the reducing agent to the reducing agent storage 200 through the drain line 650.

When the residual reducing agent in the reducing agent supply line 610 is drained through the drain line 650, the third valve 530 and the fifth valve 550 are opened and the remaining valves 510, 520 and 540 are opened Lt; / RTI >

The recovery line 690 branches from the reducing agent supply line 610 between the first valve 510 and the reducing agent storage part 200 and is connected to the reducing agent storage part 200.

The supply pump 280 may also be installed in the reducing agent supply line 610 between the first valve 510 and the reducing agent storage 200.

When the first valve 510 is closed, the reducing agent remaining in the reducing agent supply line 610 between the first valve 510 and the reducing agent storage unit 200 is returned to the reducing agent storage unit 200 through the recovery line 690 Can be recovered.

The mass flow controller 800 is installed in the reducing agent supply line 610 to help precisely control the flow rate of the reducing agent supplied to the injection nozzle 700 via the reducing agent supply line 610. That is, the amount of the reducing agent required for the selective catalytic reduction system can be precisely controlled by the mass flow controller 800 and the generation of ammonia slip can be minimized by suppressing the injection of the reducing agent more than necessary.

According to this configuration, the reducing agent supply system 101 according to an embodiment of the present invention can effectively remove the reducing agent remaining in the supply pipe, that is, the reducing agent supply line 610 at the time of shutdown.

The reducing agent remaining in the reducing agent supply line 610 is not completely removed and the reducing agent is crystallized in the reducing agent supply line 610 and the first valve 510 provided in the reducing agent supply line 610 and the mass flow controller MFC, 800 can be prevented from malfunctioning.

Hereinafter, a method of operating the reducing agent supply system 101 according to an embodiment of the present invention will be described in detail with reference to FIGS. 1 to 6. FIG.

The method of operating the reducing agent supply system 101 according to an embodiment of the present invention can be divided into a reducing agent injection operation, a reducing agent drain and recovery operation, a reducing agent removing operation using water, and a reducing agent removing operation using compressed air.

First, as shown in FIGS. 1 and 6, the reducing agent injection operation opens the first valve 510 and the third valve 530, and the second valve 520 and the fourth valve 540, The valve 550 is closed.

The reducing agent stored in the reducing agent storage unit 200 and the compressed air supplied from the air supply unit 300 are injected through the injection nozzle 700 and the atomized reducing agent is injected into the reducing agent decomposition chamber 100.

2 and 6, the reducing agent drain and the recovering operation are performed by opening the third valve 530 and the fifth valve 550 and opening the first valve 510 and the second valve 520, 4 valve 540 closes.

Accordingly, the reducing agent remaining in the reducing agent supply line 610 is moved to the reducing agent storage unit 200 through the drain line 650 and is primarily removed. In addition, according to one embodiment of the present invention, the reducing agent remaining in the reducing agent supply line 610 can be recovered to the reducing agent storage unit 200 and recycled.

Next, as shown in FIGS. 3 and 6, the reducing agent removing operation using water opens the second valve 520 and the third valve 530, and the first valve 510 and the fourth valve 540, The fifth valve 550 is closed.

Accordingly, the reducing agent remaining in the reducing agent supply line 610 can be removed secondarily while spraying the water supplied by the water supplying part 400 to the spraying nozzle 700. [

4 and 6, the reducing agent removing operation using compressed air is performed by opening the third valve 530 and the fourth valve 540 and opening the first valve 510 and the second valve 520 ) And closes the fifth valve (550).

Accordingly, the reducing agent and the water present in the reducing agent supply line 610 can be removed in a tertiary manner while the air supplied from the air supplying unit 300 is sprayed to the spraying nozzle 700.

5 and 6, when all of the remaining reducing agent in the reducing agent supply line 610 is removed, the first valve 510, the second valve 520, the third valve 530, The first valve 540, and the fifth valve 550 may be all closed to completely stop the operation of the reducing agent supply system 101.

According to the method of operating the reducing agent supply system 101 according to the embodiment of the present invention, the reducing agent supply system 101 effectively removes the reducing agent remaining in the supply pipe, that is, the reducing agent supply line 610, can do.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is evident that many alternatives, modifications and variations will be apparent to those skilled in the art. will be.

It is therefore to be understood that the embodiments described above are to be considered in all respects only as illustrative and not restrictive, the scope of the invention being indicated by the appended claims, It is intended that all changes and modifications derived from the equivalent concept be included within the scope of the present invention.

100: Reducing agent decomposition chamber 101: Reducing agent supply system
200: reducing agent storage unit 280: feed pump
300: air supply part 400: water supply part
510: first valve 520: second valve
530: third valve 540: fourth valve
550: fifth valve 610: reducing agent supply line
620: first purge line 630: air supply line
640: second purge line 650: drain line
690: return line 700: injection nozzle
800: mass flow controller

Claims (6)

A reducing agent supply system for supplying a reducing agent to be used in a selective catalytic reduction reaction for reducing nitrogen oxides (NOx) contained in an exhaust gas,
A spray nozzle for spraying a reducing agent;
A reducing agent storage unit for storing a reducing agent to be supplied to the injection nozzle;
A reducing agent supply line connecting the reducing agent storage unit and the injection nozzle;
A first valve disposed on the reducing agent supply line;
A water supply unit for supplying water to the spray nozzle;
A first purge line connecting the reducing agent supply line between the first valve and the injection nozzle to the water supply unit;
A second valve disposed in the first purge line;
An air supply unit for supplying compressed air to the injection nozzle;
An air supply line connecting the injection nozzle and the air supply unit;
A third valve disposed on the air supply line;
A second purge line connecting the air supply line between the third valve and the air supply unit to the reducing agent supply line between the first valve and the injection nozzle;
A fourth valve disposed on the second purge line;
A drain line branched from the reducing agent supply line between the injection nozzle and the second purge line confluence point and connected to the reducing agent storage unit; And
A fifth valve disposed on the drain line,
≪ / RTI > The method of claim 1,
And a supply pump installed on the reductant supply line. The method of claim 1,
And a recovery line branched from the reducing agent supply line between the first valve and the reducing agent storage unit and connected to the reducing agent storage unit. 4. The method according to any one of claims 1 to 3,
And a mass flow controller provided on the reducing agent supply line between the first valve and the injection nozzle. The method for operating the reducing agent supply system of claim 1,
Wherein the first valve and the third valve are opened, and the second valve, the fourth valve and the fifth valve are closed, and the reducing agent stored in the reducing agent storage unit and the compressed air supplied from the air supplying unit are supplied to the spray nozzle A reducing agent spraying step of spraying the reducing agent through the nozzle;
The third valve and the fifth valve are opened and the first valve, the second valve and the fourth valve are closed to transfer the reducing agent remaining in the reducing agent supply line to the reducing agent storage through the drain line ≪ / RTI >
The second valve and the third valve are opened and the first valve, the fourth valve and the fifth valve are closed so that water supplied to the water supply unit is sprayed to the injection nozzle while remaining in the reducing agent supply line Secondarily removing the reducing agent; And
The third valve and the fourth valve are opened and the first valve, the second valve, and the fifth valve are closed so that the air supplied by the air supply unit is injected into the injection nozzle while being present in the reducing agent supply line The third step of removing the reducing agent and the water
Wherein the reducing agent supply system comprises: The method of claim 5,
Further comprising closing the first valve, the second valve, the third valve, the fourth valve, and the fifth valve to stop the injection of the injection nozzle.

Images