KR20150043003A - Reductant supply system - Google Patents

Abstract

An embodiment of the present invention relates to a reductant supplying system comprising: a reductant supplying pipe for supplying a reductant to be used in a selective catalyst reduction reaction; a urea decomposition chamber installed on the reductant supplying pipe, provided with a urea solution containing urea, decomposing the urea, and providing generated ammonia to a lower stream portion of the reductant supplying pipe; a spraying nozzle for spraying a urea solution to the urea decomposition chamber; and a urea supplying line having a urea heat exchanging unit wound in the lower stream portion of the reductant supplying pipe and a urea supplying unit connecting the urea heat exchanging unit with the spraying nozzle, and supplying the urea solution to the spraying nozzle.

Description

REDUCTANT SUPPLY SYSTEM [0002]

An embodiment of the present invention relates to a reducing agent supply system, and more particularly, to a reducing agent supply system that generates and supplies ammonia used as a reducing agent to reduce nitrogen oxides contained in exhaust gas.

The selective catalytic reduction (SCR) system is a system for reducing nitrogen oxides contained in exhaust gas generated from diesel engines, boilers, and incinerators.

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 urea directly as a reducing agent to reduce nitrogen oxides or by spraying ammonia (NH ₃ ) generated by decomposing urea.

Generally, the urea decomposition apparatus generates urea by injecting urea into the urea decomposition chamber, and decomposing the injected urea by thermal energy inside the urea decomposition chamber.

The ammonia thus produced is mixed with the exhaust gas and passes through the catalyst to reduce the nitrogen oxides by reducing reaction with the nitrogen oxides contained in the exhaust gas.

Ammonia is formed by decomposition when high temperature is applied to urea. When the temperature at which urea is decomposed is low, by-products such as biuret, cyanuric acid, melamine, and ammeline together with ammonia (NH ₃ ) .

Therefore, in order to effectively decompose the urea, it is advantageous that the urea aqueous solution containing urea is supplied to the chamber for decomposing the urea at a predetermined temperature or higher.

However, when the urea aqueous solution is heated to 60 deg. C or more, problems such as stones occur. Therefore, there is a problem that the temperature of the urea aqueous solution should be limited to less than 60 deg. C until the urea is supplied to the chamber for decomposing the urea.

An embodiment of the present invention provides a reducing agent supply system capable of effectively controlling the temperature of an aqueous urea solution containing urea.

According to an embodiment of the present invention, a reducing agent supply system includes a reducing agent supply pipe for supplying a reducing agent to be used in a selective catalytic reduction reaction, ammonia produced by decomposing urea supplied in a urea aqueous solution containing urea, A urea decomposition chamber provided downstream of the reducing agent supply pipe, a spray nozzle for spraying the urea aqueous solution into the urea decomposition chamber, and a urea heat exchange unit wound on the downstream side of the reducing agent supply pipe, And a urea supply line having a urea supply part for supplying the urea aqueous solution to the injection nozzle.

The reductant supply system includes a urea reservoir for storing a urea aqueous solution, a urea transfer pump for transferring the urea aqueous solution stored in the urea storage portion along the urea supply line, and a urea supply portion and a urea storage portion And a connecting urea recovery line.

The reductant supply system may include a control valve provided in the urea recovery line, a plurality of temperature sensors provided in the urea heat exchanger of the urea supply line, and a control valve, And a control unit for controlling at least one of the pumps.

Wherein the control unit opens the control valve to recover a part of the urea aqueous solution supplied to the injection nozzle to the urea storage unit through the urea recovery line when the temperature of the urea aqueous solution measured by the plurality of temperature sensors is 60 캜 or more have.

The control unit may control the operation of the urea transfer pump to increase the flow rate of the urea aqueous solution flowing through the urea supply line when the temperature of the urea aqueous solution measured by the plurality of temperature sensors is 60 캜 or more.

The reducing agent supply system may further include a heat insulating member surrounding the urea heat exchanging unit of the urea supply line.

The reducing agent supply system may further include a compressed air supply line for supplying compressed air to the injection nozzle. The compressed air supply line includes a compressed air heat exchanger that is wound on the downstream side of the reductant supply pipe in an alternating manner with the urea heat exchanger of the urea supply line and a compressed air supply unit that connects the compressed air heat exchanger and the spray nozzle can do.

According to the embodiment of the present invention, the reducing agent supply system not only effectively controls the temperature of the urea aqueous solution containing urea but also reduces the overall cost of the selective catalytic reduction reaction by supplying the thermal energy required for urea decomposition in advance .

1 is a configuration diagram of a reducing agent supply system according to an embodiment of the present invention.
Fig. 2 is an enlarged view of the main configuration of Fig. 1. Fig.

Hereinafter, 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 shown 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 decomposes urea to produce ammonia (NH ₃ ) used as a reducing agent for reducing nitrogen oxides (NOx) contained in the exhaust gas.

The ammonia (NH ₃ ) generated and supplied by the reducing agent supply system 101 is mixed with the exhaust gas and reacts with the nitrogen oxide (NOx) of the exhaust gas through the catalyst. At this time, the catalyst may be made of various materials known to those skilled in the art, such as zeolite, vanadium, and platinum.

1, a reducing agent supply system 101 according to an embodiment of the present invention includes a reducing agent supply line 300, a urea decomposition chamber 200, a spray nozzle 400, and a urea supply line 510 .

The reducing agent supply system 101 according to an embodiment of the present invention may further include a urea storage unit 580, a urea transfer pump 550, and a urea recovery line 570.

The reducing agent supply system 101 according to an embodiment of the present invention further includes a control valve 575, a plurality of temperature sensors 750 (shown in FIG. 2), and a controller 700 (shown in FIG. 2) .

The reducing agent supply system 101 according to an embodiment of the present invention may further include a heating apparatus 350, a compressed air supply line 610, a compressed air supply unit 650, and a heat insulating member 900 (shown in FIG. 2) As shown in FIG.

The reducing agent supply pipe 300 supplies a reducing agent to be used for the selective catalytic reduction reaction.

The urea decomposition chamber 200 is installed on the reducing agent supply pipe 300. The urea decomposition chamber 200 decomposes urea (CO (NH ₂ ) ₂ ) to produce ammonia (NH ₃ ) which is used as a reducing agent for reducing nitrogen oxides (NOx).

In one embodiment of the present invention, the urea decomposition chamber 200 flows from the front end 201 to the rear end 209 with a fluid having thermal energy. That is, the front end portion 201 and the rear end portion 209 of the urea decomposition chamber 200 are connected to the upstream side and the downstream side of the reducing agent supply pipe, respectively. And the fluid flowing inside the urea decomposition chamber is supplied from the upstream side of the reducing agent supply pipe.

The fluid flowing along the urea decomposition chamber 200 may be an exhaust gas containing nitrogen oxide to be mixed with ammonia used as a reducing agent. However, an embodiment of the present invention is not limited to this, and exhaust gas discharged from air or other equipment other than the exhaust gas containing nitrogen oxide may be supplied to the urea decomposition chamber 200 from the upstream side of the reducing agent supply pipe .

Further, the fluid flowing in the urea decomposition chamber 200 has heat energy capable of decomposing the urea.

In the urea decomposition chamber 200, the urea is decomposed by the thermal energy of the fluid, and the ammonia generated by decomposition of the urea is supplied to the downstream side of the reducing agent supply pipe 300.

Also, although not shown, a mixer may be installed in the urea decomposition chamber 200. The mixer mixes the ammonia produced in the urea decomposition chamber 200 with the fluid flowing inside the urea decomposition chamber 200.

The injection nozzle 400 injects urea aqueous solution containing urea into the urea decomposition chamber 200.

In addition, the injection nozzle 400 can inject compressed air together with the urea aqueous solution. The compressed air helps spread the urea aqueous solution.

The urea contained in the urea aqueous solution injected from the injection nozzle 400 is decomposed by the thermal energy of the fluid flowing inside the urea decomposition chamber 200 to produce ammonia (NH ₃ ).

The heating device 350 is provided on the upstream side of the reducing agent supply pipe 300 relative to the urea decomposition chamber 200 to provide thermal energy to the fluid supplied to the urea decomposition chamber 200 by the reducing agent supply pipe 300. Thus, the thermal energy provided to the fluid is used to decompose the urea.

For example, the heating device 350 may be one of an oil burner or a plasma burner. That is, the heating device 350 can increase the temperature of the fluid flowing on the upstream side of the reducing agent supply pipe 300 with the heat energy generated by burning the fuel.

The urea storage part 580 stores an aqueous urea solution, and the urea supply line 510 connects the urea storage part 580 and the injection nozzle 400. The urea transfer pump 550 transfers the urea aqueous solution stored in the urea storage part 580 along the urea supply line 510 and supplies the urea aqueous solution to the injection nozzle 400.

2, the urea supply line 510 includes a urea heat exchanger 515 wound on the downstream side of the reducing agent supply pipe 300, a urea heat exchanger 515, And a urea supply unit 511 for connecting the nozzles 400.

The urea heat exchange portion 515 of the urea supply line 510 is formed to wind the downstream side of the reducing agent supply pipe 300 plural times. The urea heat exchanger 515 can heat-exchange the fluid flowing downstream of the reducing agent supply pipe 300 to raise the temperature of the urea aqueous solution flowing through the urea heat exchanger 515. The fluid flowing downstream of the reducing agent supply pipe 300 is used for decomposing urea among the thermal energy supplied from the heating device 350 and has residual heat energy.

The compressed air supply line 610 supplies compressed air to the injection nozzle 400.

The compressed air supply line 610 is also connected to the downstream side of the reducing agent supply pipe 300 by a compressed air heat exchanger 615 wound alternately with the urea heat exchanger 515 of the urea supply line 510, And a compressed air supply unit 611 for connecting the spray nozzle 600 and the spray nozzle 400.

The heat insulating member 900 surrounds the urea heat exchanger 515 of the urea supply line 510 and the compressed air heat exchanger 615 of the compressed air supply line 610. That is, the heat insulating member 900 helps the urea heat exchanging unit 515 and the compressed air heat exchanging unit 615, which surround the downstream side of the reducing agent supply pipe 300, effectively receive the heat energy, and the heat energy is discharged to the outside Can be suppressed.

The urea recovery line 570 connects the urea supply portion 511 of the urea supply line 510 and the urea storage portion 580. That is, the urea recovery line 570 can recover the urea aqueous solution into the urea storage portion 580 before the urea aqueous solution passing through the urea heat exchange portion 515 of the urea supply line 510 is supplied to the injection nozzle 400 .

The control valve 575 is installed on the urea recovery line 570 to control the flow rate of the urea aqueous solution passing through the urea recovery line 570.

The plurality of temperature sensors 750 are provided in the urea heat exchanging part 515 of the urea supply line 510 wound around the downstream side of the reducing agent supply pipe 300 a plurality of times to adjust the temperature of the urea aqueous solution passing through the urea heat exchanging part 515 Measure in real time.

The plurality of temperature sensors 750 can accurately and accurately measure the temperature even if the flow rate of the urea aqueous solution flowing through the urea heat exchanger 515 changes.

The control unit 700 controls at least one of the control valve 575 or the urea transfer pump 550 according to the information provided by the plurality of temperature sensors 750. In this embodiment,

More specifically, when the temperature of the urea aqueous solution measured by the plurality of temperature sensors 750 is 60 degrees Celsius or more, the control unit 700 opens the control valve 575 to store a part of the urea aqueous solution supplied to the injection nozzle 400 into the urea storage (580). ≪ / RTI >

When the temperature of the urea aqueous solution measured by the plurality of temperature sensors 750 is 60 degrees Celsius or more, the controller 700 controls the operation of the urea transfer pump 550 to control the flow rate of the urea aqueous solution flowing through the urea supply line 510 Can be increased.

With this configuration, the reducing agent supply system 101 according to the embodiment of the present invention can effectively control the temperature of the urea aqueous solution containing urea.

Therefore, it is possible to prevent the formation of stones by increasing the temperature of the urea aqueous solution.

Hereinafter, the control operation of the controller 700 will be described in detail in the reducing agent supply system 101 according to an embodiment of the present invention.

When the temperature of the urea aqueous solution flowing through the urea supply line 510 becomes 60 degrees Celsius or more due to excessive thermal energy supplied from the urea heat exchanger 515 of the urea supply line 510, A part of the urea aqueous solution supplied to the injection nozzle 400 is recovered to the urea storage part 580 through the urea recovery line 570 in order to minimize and suppress the supply of the urea aqueous solution containing the urea aqueous solution to the injection nozzle 400.

The control unit 700 controls the operation of the urea transfer pump 550 to increase the flow rate of the urea aqueous solution flowing through the urea supply line 510. Thus, the urea transfer pump 550 can replenish the amount of urea aqueous solution recovered through the urea recovery line 570.

In addition, if the urea transfer pump 550 increases the flow rate of the urea aqueous solution flowing through the urea supply line 510, the heat exchange in the urea heat exchanger 515 of the urea supply line 510 is relatively small, 400 is lowered.

That is, the control unit 700 recovers a portion of the urea aqueous solution having a temperature of 60 degrees Celsius or more through the urea heat exchanging unit 515 of the urea supply line 510 to the urea storage unit 580, And cooled.

The control unit 700 controls the operation of the urea transfer pump 550 to increase the flow rate of the urea aqueous solution flowing through the urea supply line 510 to replenish the urea aqueous solution recovered by the urea recovery line 570. At this time, the urea aqueous solution having passed through the urea heat exchanging part 515 of the urea supply line 510 at a relatively fast flow rate has a relatively low temperature. Therefore, the urea aqueous solution having a relatively low temperature, Aqueous solution can be supplied.

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.

101: Reducing agent supply system 200: Urea decomposition chamber
300: Reducing agent supply pipe 350: Heating device
400: injection nozzle 510: urea supply line
511: Urea supply part 515: Urea heat exchange part
550: urea transfer pump 570: urea recovery line
575: Control valve 580: Urea reservoir
610: compressed air supply line 611: compressed air supply line
615: Compressed air heat exchanger 700:
750: Temperature sensor 900: Heat insulating member

Claims (7)

A reducing agent supply pipe for supplying a reducing agent to be used for the selective catalytic reduction reaction;
A urea decomposition chamber installed on the reducing agent supply pipe and supplied with a urea aqueous solution containing urea to provide ammonia produced by decomposing urea to the downstream side of the reducing agent supply pipe;
A spray nozzle for spraying the urea aqueous solution into the urea decomposition chamber; And
A urea heat exchanging unit wound on the downstream side of the reducing agent supply pipe, a urea supplying unit connecting the urea heat exchanging unit and the injection nozzle, and a urea supply line
And a reducing agent supply system. The method of claim 1,
A urea storage part for storing an aqueous urea solution;
A urea transfer pump for transferring the urea aqueous solution stored in the urea storage portion along the urea supply line; And
A urea recovery line connecting the urea supply section of the urea supply line and the urea storage section
The reducing agent supply system. 3. The method of claim 2,
A control valve provided in the urea recovery line;
A plurality of temperature sensors provided in the urea heat exchanger of the urea supply line; And
A control unit for controlling at least one of the control valve and the urea transfer pump in accordance with information provided by the plurality of temperature sensors;
Further comprising a reducing agent supply system. 4. The method of claim 3,
Wherein the control unit opens the control valve to return a portion of the urea aqueous solution supplied to the injection nozzle to the urea storage unit through the urea recovery line when the temperature of the urea aqueous solution measured by the plurality of temperature sensors is 60 캜 or more, Supply system. 5. The method of claim 4,
Wherein the control unit controls the operation of the urea transfer pump to increase the flow rate of the urea aqueous solution flowing through the urea supply line when the temperature of the urea aqueous solution measured by the plurality of temperature sensors is 60 캜 or more. The method of claim 1,
And a heat insulating member surrounding the urea heat exchanging portion of the urea supply line. 7. The method according to any one of claims 1 to 6,
Further comprising a compressed air supply line for supplying compressed air to the injection nozzle,
The compressed air supply line includes:
A compressed air heat exchanger which is wound on the downstream side of the reducing agent supply pipe in an alternating manner with the urea heat exchanger of the urea supply line;
A compressed air supply unit for connecting the compressed air heat exchanger and the injection nozzle,
≪ / RTI >

Images