KR101489794B1 - A Reducing Agent Supply Device for SCR System and Method thereof - Google Patents

Abstract

The present invention relates to a reducing agent supplying apparatus for supplying a reducing agent into a denitration system for denitration of exhaust gas, and more particularly, to a reducing agent supplying apparatus for supplying a reducing agent to a denitration system for denitration of exhaust gas, Way check valve provided on a line connecting the dosing unit and the spraying unit to increase the efficiency of maintenance and maintenance, and the one-way check valve A water branch line serving as a passage through which water is discharged from the dosing section, an air branch line for spraying which is a passage through which the spraying air is discharged from the dosing section, and air for cleaning from the dosing section, In addition to being installed in each of the cleaning air branch lines, Way check valves are installed at a position immediately before the reductant branch line, the water branch line, the atomizing air branch line, and the cleaning air branch line are integrated into one line from the rear end of the jetting portion, And more particularly, to a reducing agent supplying device and a reducing agent supplying method of a denitration system capable of minimizing an inflow of a residual reducing agent into an engine.

Description

Technical Field [0001] The present invention relates to a reducing agent supplying apparatus and a reducing agent supplying method for a denitration system,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a reducing agent supplying device and a reducing agent supplying method for supplying a reducing agent into a denitration system for denitration of an exhaust gas. More particularly, the present invention relates to a reducing agent- Way check valve provided on a line connecting the dosing unit and the spraying unit without providing a separate control panel between the spraying unit and the spraying unit to increase the efficiency of maintenance and maintenance, Wherein the one-way check valve is connected to a reducing agent branch line which is a passage through which the reducing agent is discharged from the dosing section, a water branch line which is a passage through which the water is discharged from the dosing section, a spray air branch line which is a passage through which the spraying air is discharged from the dosing section, In each of the cleaning air branch lines which are the passages for the cleaning air Way check valve is installed at a position immediately before the reducing agent branch line, the water branch line, the spraying air branch line, and the cleaning air branch line are integrated into one line at the rear end of the jetting part, The present invention relates to a reducing agent supplying device and a reducing agent supplying method in a denitration system capable of minimizing an inflow of a residual reducing agent into an engine by minimizing an interval between a spraying part and a spraying part.

Exhaust gas emitted by thermal power plants using fossil fuels as energy sources contains a large amount of nitrogen oxides (NOx), which are known to cause acid rain and respiratory diseases. Accordingly, various techniques for removing nitrogen oxides contained in the exhaust gas have been developed.

1 is a configuration diagram of a conventional exhaust gas denitration system using selective catalytic reduction (SCR), which is most widely used for removing nitrogen oxides. Referring to FIG. 1, exhaust gas discharged from an engine 91 A reducing agent used for denitrifying nitrogen oxides (NOx) in the gas, that is, urea water (which becomes ammonia when urea water is vaporized) is injected into the mixing chamber 93 through the injection nozzle 951 to mix the exhaust gas and the reducing agent The mixed gas is introduced into the reactor 94 containing the SCR catalyst 944 so that the mixed gas of the exhaust gas and the reducing agent mixed in the reactor 94 passes through the SCR catalyst 944, (NOx) component is denitrified (denitrification reaction) to obtain an optimum denitrification efficiency and effectively prevents environmental pollution caused by nitrogen oxide (NOx) component and ammonia. 2, in the process of injecting the urea water into the mixing chamber 93 through the injection nozzle 951, the number of elements moving in the injection nozzle 951 or the injection nozzle 951 is shifted There is a possibility that remaining elements are not discharged into the mixing chamber 93 and the remaining urea water becomes solidified to block the injection nozzle 951 or the urea water passage on the furnace, The number of urea water lines 953 branched from the dosing unit 952 for controlling the supply of urea water and the washing water, in the structure for removing the solidified urea water remaining in the injection nozzle 951 or the urea water passage, A separate purge panel 956 is provided at a portion where the compressed air line 954 and the wash water line 955 are converged at the downstream end of the injection nozzle 951 and is controlled through the purge panel 956 Supply of urea water or water by washing water Is selectively control or manage the cleaning of the nozzle 951 or elements can move.

However, in such a conventional structure, in addition to the conventional dosing unit 952, a separate purge panel 956 must be installed at the downstream end of the injection nozzle 951, so that a separate panel or control line 957 Since the purge panel 956 is responsible for electrical control of various control valves and the like contained in the purge panel 956, the same configuration as the control line 957 used in the purge panel 956 can be provided. There arises a problem that the cost increases due to the facilities and the maintenance are complicated, and the frequency of occurrence of the failure also increases.

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

It is an object of the present invention to provide a spraying apparatus and a spraying method for spraying a spraying liquid on a line connecting the dosing unit and the spraying unit without separately providing a separate control panel between the dosing unit and the spraying unit, The present invention provides a reducing agent supplying device and a reducing agent supplying method for a denitrification system that can be controlled through a one-way check valve installed in a denitration system to reduce costs and improve maintenance efficiency.

It is another object of the present invention to provide a method of controlling an air conditioner, comprising: a one-way check valve which is connected to a reducing agent branch line as a passage through which the reducing agent is discharged from the dosing section, a water branch line as a passage through which water is discharged from the dosing section, And the washing air branch line, which is a passage through which the washing air is discharged from the dosing unit, as well as the reducing agent branch line, the water branch line, the spray air branch line, and the washing air branch line, Way check valve is provided at a position immediately before the introduction of the reducing agent into the line of the unidirectional check valves and the spraying part to minimize the inflow of the residual reducing agent into the engine, Supply method.

It is a further object of the present invention to provide a control panel in which a separate control panel is additionally provided between the dosing unit and the spraying unit through control for connecting the on / off valves in the one-way check valve and dosing unit installed on each line It is an object of the present invention to provide a reducing agent supplying device and a reducing agent supplying method for a denitrifying system which can solve the problem of maintenance burdens due to an increase in costs and troubles caused by configurations such as a separate control line installed in a control panel .

It is still another object of the present invention to provide an exhaust gas analyzer which is capable of measuring the amount of reducing agent injected from each denitration system through an outlet analyzer sequentially measuring the amount of nitrogen oxides contained in exhaust gas discharged through each exhaust pipe through a denitration process in a plurality of denitration systems The present invention provides a method of supplying a reducing agent to a plurality of denitrification systems using one outlet analyzer that can be controlled.

The reducing agent supplying device and the reducing agent supplying method of the denitration system for achieving the object of the present invention include the following arrangement.

The reducing agent supply device for supplying the reducing agent into the mixing chamber of the denitration system according to an embodiment of the present invention includes a spraying part for spraying a reducing agent or water into the mixing chamber by selectively controlling the reducing agent supply line, A reducing agent or water can be selectively supplied to the reducing agent; And a unidirectional check valve installed on a line connecting the dosing unit and the jetting unit.

According to another embodiment of the present invention, in the reducing agent supply device of the denitration system according to the present invention, the one-way check valve includes a reducing agent branch line as a passage through which the reducing agent is discharged from the dosing section, Line, a spraying air branch line which is a passage through which the spraying air is discharged from the dosing portion, and a cleaning air branching line which is a passage through which the washing air is discharged from the dosing portion.

According to another embodiment of the present invention, in the reducing agent supply device of the denitration system according to the present invention, the reducing agent branch line, the water branch line, the spray air branch line, And the one-way check valve installed in each of the reducing agent branch line, the water branch line, the spraying air branch line and the cleaning air branch line is installed at a position immediately before the respective lines are integrated with other lines.

The reducing agent supplying method for supplying the reducing agent into the mixing chamber of the denitration system according to an embodiment of the present invention includes a reducing agent branching line and a spraying air branching line to control the reducing agent branching line and the one- A reducing agent spraying step in which the reducing agent is sprayed through the spraying part together with the spraying air; A reducing agent injection stopping step of controlling the reducing agent branching line and the spraying air branching line so that the reducing agent remains in the section from the spraying part to the reducing agent branching line and the one-way check valve on the atomizing air branching line when the reducing agent injection is stopped; A reducing agent removing step of controlling the dosing addition line and the cleaning air branch line to remove the reducing agent remaining in the cleaning water together with the cleaning water through the one-way check valve on the water branch line and the cleaning air branch line; .

According to another embodiment of the present invention, in the reducing agent supplying method according to the present invention, the reducing agent injecting step may include a first on / off valve opening for opening the on / off valve on the reducing agent branch line and the spraying air branch line, And a first one-way check valve opening step in which the reducing agent is injected through the injection part together with the atomizing air through the reducing agent branching line and the one-way check valve on the atomizing air branching line after the first on / off valve opening step, The reducing agent injection stop step may include an on / off valve closing step of closing the on / off valve on the reducing agent branch line and the spraying air branch line, and a reducing agent branch line and spraying line on the downstream side of the injection / One-way check valve located immediately before the air branch line is integrated, Wherein the reducing agent removing step includes a second on / off valve opening step of opening the on / off valve on the dosing branch line and the cleaning air branch line, and the one-way check valve closing step in which the reducing agent is left And a second one-way check valve releasing step of removing the reducing agent remaining after the washing water is sprayed together with the washing air through the one-way check valve on the water branch line and the washing air branch line after the on / off valve opening step .

The present invention can obtain the following effects by the above-described embodiment, the constitution described below, the combination, and the use relationship.

The present invention is characterized in that a separate control panel is not additionally provided between the dosing portion and the jetting portion in the configuration for cleaning the jetting portion or the line on which the reducing agent remains, It is possible to control through the installed one-way check valve, thereby reducing the cost and improving the efficiency of maintenance.

A one-way check valve includes a reducing agent branch line serving as a passage through which the reducing agent is discharged from the dosing section, a water branch line serving as a passage through which water is discharged from the dosing section, an air branching line for spraying which is a passage through which the spraying air is discharged from the dosing section, The water reducing branch line, the water branching line, the spraying air branching line, and the cleaning air branching line are arranged in a single line from the downstream end of the spraying section, It is possible to minimize the inflow of the residual reducing agent into the engine by minimizing the interval between the one-way check valves and the jetting part by providing each one-way check valve at the immediately preceding position to be integrated.

The present invention eliminates the need to additionally provide a separate control panel between the dosing unit and the jetting unit through the control of linking the ON / OFF valves in the one-way check valve and the dosing unit installed on each line, It is possible to solve the problem of maintenance burden due to an increase in cost and troubles caused by configurations such as a separate control line installed in the panel.

The present invention can control the reducing agent injection amount of each denitration system through one outlet analyzer sequentially measuring the amount of nitrogen oxide contained in the exhaust gas finally exhausted through each exhaust pipe through a denitration process in a plurality of denitration systems Effect.

1 is a schematic view showing the structure of a conventional SCR denitration system
Fig. 2 is a schematic view showing a structure in which a reducing agent is supplied in Fig. 1
3 is a schematic view showing the structure of a reducing agent supply apparatus according to an embodiment of the present invention.
FIG. 4 is a view showing a process of injecting a reducing agent in FIG.
FIG. 5 is a view showing a section where the reducing agent remains when the reducing agent injection is stopped in FIG.
FIG. 6 is a view showing the process of spraying water to remove the residual reducing agent in FIG.
7 is a block diagram of a reducing agent supplying method according to an embodiment of the present invention
8 is a schematic view showing a structure of a conventional SCR denitration system
9 is a schematic view showing a structure of a plurality of denitration systems using one outlet analyzer according to another embodiment of the present invention
10 is a block diagram of a method for controlling a plurality of denitration systems using one outlet analyzer according to another embodiment of the present invention
11 is a graph showing the relationship between the amount
12 is a graph showing the relationship between the amount of reducing agent
13 is a block diagram of a method for controlling a plurality of denitration systems using one outlet analyzer according to another embodiment of the present invention

Hereinafter, preferred embodiments of the reducing agent supplying apparatus and the reducing agent supplying method of the denitration system according to the present invention will be described in detail with reference to the accompanying drawings. DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

3 to 6, the reducing agent supply device of the denitration system according to an embodiment of the present invention selectively controls the reducing agent supply line 563, the water supply line 564, and the compressed air supply line 565, A dosing part 562 for selectively supplying a reducing agent or water to the jetting part 561 for jetting a reducing agent or (washing) water into the chamber 54; And a one-way check valve 560 installed on a line connecting the dosing unit 562 and the jetting unit 561.

As described in the prior art, the selective catalytic reduction (SCR) denitrification system using nitrogen as a reducing agent, especially for the removal of nitrogen oxides (NOx) from the exhaust gas, That is, urea water (which becomes ammonia when urea water is vaporized) into the mixing chamber 93 through which the exhaust gas flows to denit nitrogen oxide (NOx) in the exhaust gas discharged from the engine 91 is supplied to the injection nozzle 951, The mixed gas is introduced into the reactor 94 containing the SCR catalyst 944 so that the exhaust gas and the reducing agent are introduced into the reactor 94 (NOx) contained in the exhaust gas is denitrified (denitrified) by passing the mixed gas through the SCR catalyst 944 to obtain an optimum denitrification efficiency and to obtain a nitrogen oxide (NOx) component and ammonia The exhaust pipe 52, the mixing chamber 54, the reactor 55, and the exhaust pipe 52 of the present invention, which are the same in the denitration system of the present invention, And the SCR catalyst 551 are omitted)

Particularly, in the conventional SCR denitration system, in the process of injecting urea water into the mixing chamber 93 through the injection nozzle 951, the number of urea water in the injection nozzle 951 or the injection nozzle 951 There is a problem in that the number of remaining elements does not always discharge into the mixing chamber 93 on the moving path and the remaining number of the element becomes solidified to block the injection nozzle 951 or the elliptical water passage. As shown in Fig. 2, a structure for removing the solidified urea water remaining in the injection nozzle 951 or the urea water passage is branched from the dosing unit 952 for controlling the supply of the urea water and the washing water A separate purge panel 956 is provided at a portion where the ellipse number line 953, the compressed air line 954 and the wash water line 955 converge to the rear end of the injection nozzle 951, and the purge panel 956 ) To control the number of elements A separate purge panel 956 is additionally provided in addition to the conventional dosing unit 952 under such a conventional structure. However, in the conventional structure, the purge nozzle 951 or the ellipsoidal transfer path is selectively controlled Since it is required to install the spray nozzle at the rear stage of the spray nozzle 951, the cost and the maintenance of the equipment such as the separate panel or the control line 957 are complicated, do.

Therefore, in order to solve the above-mentioned conventional problems, the reducing agent supplying apparatus of the denitration system according to the present invention includes a dosing unit 562 in which each line is branched and controlled so that a reducing agent or water can be selectively supplied, (The dosing unit 952) and the jetting unit (jetting nozzle 951) via a one-way check valve 560 provided on each line connecting the jetting unit 562 and the jetting unit 561, ) And the one-way check valve (560) without additional additional control panel (i.e., the same configuration as the purge panel (956) Thereby increasing the efficiency of the system.

The dosing unit 562 selectively controls the opening and closing of the lines to connect the reducing agent supply line 563, the water supply line 564, and the compressed air supply line 565 to the dosing unit 562, A reducing agent branch line 566 (a passage through which the reducing agent is discharged) branching from the dosing section 562, a water branch line 567 (a passage through which the washing water is discharged), Way check valve (not shown) installed in each of the spraying air branch line 568 (which is the passage through which the spraying air for discharging water is discharged) and the cleaning air branch line 569 560 in order to selectively supply a reducing agent or cleaning water to the jetting section 561. The reducing agent supply line 563 to which the reducing agent is supplied from the reducing agent storage tank is branched to the reducing agent branch line 566 after being connected to the dosing unit 562 and is supplied with water from the water tank The water supply line 564 is branched to the water branch line 567 after being connected to the dosing unit 562 and the compressed air supply line 565 to which the compressed air is supplied is connected to the dosing unit 562 The water branch line 566 and the spray air branch line 569 are branched into the spraying air branch line 568 and the cleaning air branch line 569. In the dosing section 562, the reducing agent branch line 566, the water branch line 567, An on / off valve 5621, which is a kind of control valve for turning on / off each line, is connected to the cleaning air branch line 568 and the cleaning air branch line 569, Selecting the opening and closing of each line for supply to As shown in FIG.

As shown in FIG. 3, the one-way check valve 560 controls the amount of flow of the water in only one direction on each line. The one-way check valve 560 includes the reducing agent branch line 566 branched from the dosing part 562, The branch line 567, the spraying air branch line 568, and the cleaning air branch line 569, respectively. 3, the reducing agent branching line 566, the water branching line 567, the spraying air branching line 568, and the cleaning air branching line 569 are all connected to the jetting portion 561 and 562 are integrated into one line at a position as close as possible to the jetting section 561 and connected to the jetting section 561. The reducing agent branching line 566, the water branching line 567, Way check valves 560 installed in each of the one-way check valves 560 and 568 and the cleaning air branch lines 569 are installed at positions immediately before the respective lines are integrated with other lines, 560 and the jetting section 561 to reduce the amount of the reducing agent remaining on the line connected to the jetting section 561 and the jetting section 561, And a repetition of the reducing agent remaining on the line connected to the jetting section 561 A reducing agent for cleaning is introduced into the engine 51 through the exhaust pipe 52 makes it possible to reduce as much as possible to give an adverse effect to the engine 51. The

4 to 6, in the process of injecting the reducing agent into the mixing chamber 54 through the jetting section 561, the reducing agent is supplied from the dosing section 562, An on / off valve 5621 installed in the reducing agent branch line 566 for supplying the air and an on / off valve 5621 installed in the atomizing air branch line 568 for supplying the air necessary for atomizing the reducing agent together Off valve 5621 of the cleaning water branch line 569 is closed), the reducing agent that moves along the reducing agent branch line 566 is returned to the reducing agent branch Directional check valve 560 installed at a portion of the line 566 which is joined to the spraying air branch line 568 and the spraying portion 561 together with the compressed air injected through the spraying air branch line 568 Into the mixing chamber 54 It is. In this case, when the supply of the reducing agent through the jetting unit 561 is stopped, the dosing unit 562 is provided with the on / off valve 5621 and the spraying air branch line 568 of the reducing agent branch line 566, The on / off valve 5621 of the reducing agent branch line 566 is closed and the minimum interval between the one-way check valve 560 of the reducing agent branch line 566 in the jetting section 561 as shown in FIG. 5 'Ⓐ'), a reducing agent that is not completely sprayed remains. Thereafter, the reducing agent remaining in the minimum interval between the one-way check valves 560 of the reducing agent branch line 566 (see 'a' of FIG. 5) in the jetting section 561 is washed (to prevent solidification) 6, the dosing unit 562 is provided with an on / off valve 5621 provided in the water branch line 567 for supplying the water for washing, and compressed air required for washing with water Off valve 5621 provided in the cleaning air branch line 569 for supplying the cleaning water to the water branch line 567 and the cleaning water moving along the water branch line 567 is discharged to the outside of the water branch line 567 (566) to the reducing agent branch line (566) through the one-way check valve (560) installed at the portion where the reducing agent branch line (566) The one-way check valve 560 of FIG. And discharged through the jetting section 561. [ As described above, a part of the residual reducing agent discharged through the jetting section 561 may flow into the engine 51 through the exhaust pipe 52 to adversely affect the engine 51. However, in the present invention, The gap between the one-way check valve 560 of the branch line 566 and the jetting section 561 is minimized so that the reducing agent branching line 566 connected to the jetting section 561 and the jetting section 561 The amount of the reducing agent remaining in the exhaust pipe 52 can be reduced so as to minimize the adverse effect of the reducing agent flowing into the engine 51 through the exhaust pipe 52 and the adverse effect on the engine 51 when the reducing agent is repeatedly washed.

As described above, in the reducing agent supply device of the denitration system according to the present invention, in the configuration for cleaning the spray part 561 and the line on which the reducing agent remains, a separate control panel is additionally provided between the dosing part and the spray part Therefore, the cost increase and maintenance are complicated due to various facilities such as a separate control panel (the 'purge panel 956' in FIG. 2) or a control line, Way check valve 560 installed on each line connecting the dosing unit 562 and the jetting unit 561. As a result, unlike the prior art, cost reduction and maintenance Thereby improving the efficiency of the apparatus.

Hereinafter, a method of supplying a reducing agent using the reducing agent supplying apparatus of the present invention will be described.

7, the reducing agent supply method of the denitrification system according to an embodiment of the present invention includes the reducing agent branching line 566 and the spraying air branching line 568 to control the reducing agent branching line 566, And a reducing agent spraying step (S1) in which the reducing agent is sprayed through the spraying part (561) together with the spraying air through the one-way check valve (560) on the atomizing air branch line (568); The dosing portion 562 controls the reducing agent branching line 566 and the atomizing air branching line 568 to cause the reducing agent branching line 566 and the spraying air branching line 568 A reducing agent injection stop step S2 in which the reducing agent remains in the section until the one-way check valve 560; The dosing section 562 controls the water branch line 567 and the cleaning air branch line 569 to be connected to the water branch line 567 and the cleaning air branch line 569 via the one- And a reducing agent removing step (S3) for removing the reducing agent remaining in the water together with the washing water.

The reducing agent injection step S1 more particularly includes a first on / off valve opening 562 for opening the on / off valve 5621 on the reducing agent branch line 566 and the atomizing air branch line 568, And the reducing agent is supplied to the spraying unit 511 through the one-way check valve 560 on the reducing agent branch line 566 and the spraying air branch line 568 after the first on-off valve opening step S11, And a first one-way check valve opening step (S12) through which the air is injected through the first one-way check valve opening step (561).

4, in the process of injecting the reducing agent into the mixing chamber 54 through the jetting section 561, the reducing agent is supplied from the dosing section 562 to the mixing chamber 54, An on / off valve 5621 installed in the reducing agent branch line 566 for supplying the air and an on / off valve 5621 installed in the atomizing air branch line 568 for supplying the air necessary for atomizing the reducing agent together (At this time, the water branch line 567 and the on / off valve 5621 of the cleaning air branch line 569 are closed)

In the first one-way check valve opening step S12, the reducing agent that moves along the reducing agent branch line 566 after the first on / off valve opening step S11 is supplied to the atomizing air branch line 566 of the reducing agent branch line 566, Way check valve 560 installed at a portion where the air is injected into the mixing chamber 54 through the jet portion 561 together with the compressed air injected through the atomizing air branch line 568 .

More specifically, the reducing agent injection stopping step (S2) includes an on / off valve closing step of closing the on / off valve 5621 on the reducing agent branch line 566 and the spraying air branch line 568 Way check valve (S21) positioned immediately before the reducing agent branch line (566) and the spraying air branch line (568) are integrated at the downstream end of the jetting section (561) after the on / off valve closing step (S21) Way check valve closing step S22 in which the reducing agent remains only in the section from the jetting section 561 to the one-way check valve 560 by the one-way check valve 560.

The on / off valve closing step S21 is a step in which the on / off valve 5621 of the reducing agent branch line 566 in the dosing unit 562 and the on / off valve 5621 of the reducing agent branch line 566 in the case of stopping the supply of the reducing agent into the mixing chamber 54 And closing the on / off valve 5621 of the atomizing air branch line 568.

The one-way check valve closing step S22 is performed between the ejector 561 and the one-way check valve 560 of the reducing agent branch line 566, as shown in FIG. 5, after the on / off valve closing step S21 (See ' a ' in FIG. 5) of the remainder.

More specifically, the reducing agent removing step (S3) includes a second on / off valve (562) for opening the on / off valve (5621) on the water branch line (567) And the one-way check valve 560 on the water branch line 567 and the cleaning air branch line 569 after the second on / off valve opening step S31, And a second one-way check valve opening step (S32) for removing the remaining reducing agent while being sprayed together with the air.

The second on / off valve opening step S31 may be performed after the unidirectional check valve closing step S22 and after the minimum interval between the one-way check valve 560 of the reducing agent branch line 566 in the jetting section 561 (See FIG. 5), the dosing portion 562 may be connected to the water branch line (not shown) for supplying the washing water as shown in FIG. 6 to wash the remaining reducing agent (to prevent solidification) Off valve 5621 provided in the cleaning air branch line 569 to supply the compressed air required for cleaning using water and the on / off valve 5621 provided in the cleaning air branch line 569 .

The second one-way check valve opening step S32 is a step in which the washing water traveling along the water branch line 567 after the second on / off valve opening step S31 is supplied to the water reducing line 567, The reducing agent branch line 566 in the jetting section 561 together with the compressed air injected through the washing air branch line 569 through the one-way check valve 560 provided at the site where the branching line 566 is merged with the branch line 566, Way check valve 560 of the control unit 560 and discharges the reducing agent through the jetting unit 561.

9-12, a method of reducing agent injection (control) in a plurality of Selective Catalytic Reduction (SCR) denitrification systems using one outlet analyzer according to another embodiment of the present invention includes a plurality of The amount of nitrogen oxides (NOx) contained in the exhaust gas finally discharged from each exhaust pipe 62 at the time of trial operation of the denitration system is sequentially measured by using one outlet analyzer 69, A first step (S1) of setting a reducing agent injection amount according to a ratio; The amount of nitrogen oxide (NOx) contained in the exhaust gas finally exhausted from each exhaust pipe 62 during the actual operation of the plurality of denitration systems is sequentially measured by using one outlet analyzer 69, And a second step (S2) of correcting the reducing agent injection amount for each denitration system set in the first step (S1) through comparison with the discharge reference value of the denitration system. In the above control method, the first step (S1), the second step (S2), and the third step (S3) to be described later are performed through the control unit (68) for overall control of the denitration system operation.

8, in the conventional SCR denitration system, even when a plurality of denitration systems are arranged in parallel, the exhaust gas 92 (hereinafter, referred to as " exhaust gas " And an outlet analyzer 98 for measuring the amount of nitrogen oxide contained in the exhaust gas finally discharged on the pipe of the exhaust gas purifier 100. The exhaust gas analyzer 98 checks whether or not the amount of nitrogen oxide contained in the final exhaust gas is within a reference value, The outlet analyzer 98 is installed in each of the plurality of denitration systems to control the amount of the reducing agent injected from each denitration system. In the case where the outlet analyzer 98 is connected to the final exhaust pipe 92 of the plurality of denitration systems and used, The fluctuation value of the nitrogen oxide in each denitration system can not be fed back in real time due to the interval occurring in the course of the sequential measurement of the stoneware 98 with respect to each exhaust pipe 92 of various denitrification systems , The outlet analyzer 98 determines the amount of nitrogen oxides in the exhaust pipe 92 of the other denitrification system based on the specific denitrification system, It is impossible to feed back the fluctuation value of the nitrogen oxides in the exhaust gas in real time). As a result, instantaneous and accurate real-time control due to changes in the load of the engine for each denitration system becomes slow. Therefore, even when a single outlet analyzer 98 is connected to a plurality of denitration systems in the past, this is merely for monitoring the value of nitrogen oxides discharged from each denitration system, It will not be used to control the real-time variation of the amount of reducing agent injected into the denitration system.

Therefore, in order to solve the above-mentioned conventional problems, in the method of reducing agent injection (control) in a plurality of denitration systems using one outlet analyzer according to the present invention, at the start of each of the denitration systems, The control unit 68 calculates the ratio of the engine load (NOx) in each denitration system to the NOx concentration in the NOx removal system, based on the value obtained by sequentially measuring the amount of NOx contained in the discharged exhaust gas by using one outlet analyzer 69 (Refer to FIGS. 11 and 12), and then, through the use of one outlet analyzer 69, the amount of nitrogen contained in the exhaust gas finally discharged from each exhaust pipe 62 during the actual operation of the plurality of denitration systems It is possible to control and correct the reducing agent injection amount control in a plurality of denitrification systems in real time in spite of the interval in the sequential measurement of the amount of the oxides The lock.

First, the first step (S1) of presetting a reducing agent injection quantity in accordance with each engine load ratio at the time of commissioning for each denitration system is as follows. As shown in FIG. 9, the final exhaust gas, Under the structure in which one outlet analyzer 69 is connected to each of the exhaust pipes 62 to be discharged, the outlet analyzer 69 is operated to perform the trial operation of each of the denitration systems (preliminary test operation before entering the actual full operation) (The engine load refers to the amount of fuel injected by each engine as the maximum fuel amount of the corresponding engine (hereinafter, referred to as " engine load ") for each denitration system through the maximum minimum setting module 6811 for each section of the injection amount setting module 681, And the amount of the reducing agent injected into the exhaust gas is divided into a predetermined section as shown in FIGS. 11 and 12, and the amount of reducing agent injected into each section (S11) through the injection amount calculation module 6812 of the injection amount setting module 681, a first step (S11) of setting a minimum value and a maximum value with respect to the engine load ratio and the amount of the reducing agent, ) Is calculated by multiplying the engine load ratio by a value obtained by dividing the difference between the maximum value and the minimum value of the reducing agent amount by the difference between the maximum value and the minimum value of the engine load ratio set in the denominator (S12) of setting the amount of reducing agent to the amount of exhaust gas.

In the first step (S11), the amount of nitrogen oxide contained in the exhaust gas that is finally discharged into the exhaust pipe (62) of each denitration system through the outlet analyzer (69) during the entire commissioning process of each denitration system And determines the amount of the reducing agent injected into the exhaust gas according to the change of the engine load for each denitration system through the maximum minimum setting module 6811 for each section of the injection amount setting module 681 based on the change of the measured value , The minimum and maximum values of the amount of the engine load and the amount of the reducing agent are set for each section by dividing the amount of nitrogen oxide that is derived when the amount of nitrogen oxide is adjusted to the range as shown in FIGS. 11 and 12 . For example, referring to FIG. 12, the amount of reducing agent injected is set at a minimum of 0 kg / hr to a maximum of 6 kg / hr in an engine load ratio range of 0% to 15% The amount of the reducing agent injected is set at a minimum of 6 kg / hr to a maximum of 12 kg / hr, and the amount of the reducing agent injected is set to be at least 12 kg / hr to a maximum of 19 kg / hr, and the amount of reducing agent injected is set at a minimum of 19 kg / hr to a maximum of 28 kg / hr at an engine load ratio of 50% to 75% The minimum and maximum values for the engine load ratio and the amount of the reducing agent for each of the five sections are set such that the amount of the reducing agent injected is set to a minimum of 28 kg / hr and a maximum of 38 kg / hr, You can see an example.

In the first step S12, the injection amount calculation module 6812 of the injection amount setting module 681 calculates a difference between a maximum value and a minimum value of the engine load ratio of the specific section set in the step 1-1) And the function calculated by multiplying the engine load ratio by a value obtained by dividing the difference between the maximum value and the minimum value of the amount of reducing agent in the corresponding section set in the step 1-1 in the denominator by a denominator The amount of the reducing agent is set to the amount of the exhaust gas to be introduced. 12, if the real-time measured engine load ratio is 10%, the corresponding engine load ratio (10%) corresponds to the predetermined table in FIG. 12 (15-0 = 15), which is the difference between the maximum value and the minimum value of the engine load ratio in the range of 0% to 15%, is denoted as denominator, and the difference between the maximum value and the minimum value of the reducing agent amount in the corresponding interval is 6 (6/15) * 10 = 4) calculated by multiplying the measured value by the real time engine load ratio 10 multiplied by the numerical value If the real-time measured engine load ratio is 40%, the corresponding engine load ratio (40%) is set in advance in FIG. 12 as the injection amount of the reducing agent injected into the exhaust gas The ratio of the engine load in the section belonging to the set table (the section where the engine load ratio is within 30% to 50%) (I.e., 19-12 = 7), which is the difference between the maximum value and the minimum value of the amount of reducing agent in the corresponding section, which is the difference between the maximum value and the minimum value of 20 (i.e., 50-30 = 20) (I.e., (7/20) * 40 = 14) calculated by multiplying the measured real-time engine load ratio 40 by 40 is calculated as the injection amount of the reducing agent injected into the exhaust gas at the present time, It is set through step S12. Accordingly, by using the table set in the first step S11 and the calculated function values set in the first and second step S12 for each of the denitration systems through such a flow, It is possible to inject and control the amount of the reducing agent required in real time in accordance with the change in the engine load ratio of each denitration system measured in real time.

Also, in actual operation for each denitration system, the deviation generated in the reducing agent injection amount for each denitration system set in the first step (S1) is corrected through the injection amount correction module 682 so that real-time feedback is performed according to the engine load change The second step S2 of measuring the amount of nitrogen oxides contained in the exhaust gas discharged from each of the exhaust pipes 62 during the actual operation of the plurality of denitration systems is carried out by using the outlet analyzer 69 A second step S21 of calculating a correction value by the correction value calculating module 6821 of the injection amount correcting module 682 through comparison of the value with the emission reference value of the nitrogen oxide, A second-2 step of correcting the reducing agent injection amount by multiplying the reducing agent injection amount set in the first-second step (S12) by the correction value calculated in the second-first step (S21) through the correction operation module 6822 of the second- S22).

In the second step (S21), the outlet analyzer 69 sequentially measures the amount of nitrogen oxide contained in the exhaust gas discharged from each of the exhaust pipes 62 during the actual operation of the plurality of denitration systems The correction value calculation module 6821 of the injection quantity correction module 682 compares the obtained measured value and the nitrogen oxide emission reference value with the correction value calculated by setting the difference between the measurement value and the emission reference value from 0.8 to 1.2 It is the process of calculating the value. That is, for example, when the measurement value of the nitrogen oxide measured in the specific denitrification system among the quantities of nitrogen oxide obtained by successively measuring using the outlet analyzer 69 is 15 and the emission standard value 10 of the nitrogen oxide is over 50% If the measured value of the measured nitrogen oxide is 12.5, it is determined that the amount of nitrogen (NOx) in the exhaust gas is equal to or greater than the amount of nitrogen In the case where the exhaust reference value 10 of the oxide exceeds 25%, an additional correction value for the injection amount of the reducing agent injected for the denitration of the exhaust gas in the step 2-1 (S21) is set to 1.05, The degree of difference between the measurement value measured through the outlet analyzer 69 and the discharge reference value is calculated as a proportional control form between a minimum of 0.8 and a maximum of 1.2. The limitation of the minimum and maximum of the correction values calculated in the step 2-1 (S21) to between 0.8 and 1.2 is to prevent a sharp increase or decrease in the amount of the reducing agent injected by the correction, So that problems such as increased pollution can be prevented.

In the second-2 step S22, the reducing agent injection amount set in the first-second step S12 through the correction computation module 6822 of the injection amount correction module 682 is updated in the second-first step S21 And correcting the reducing agent injection amount by multiplying the calculated correction value. That is, although the reducing agent is injected in the specific denitration system according to the reducing agent injection amount set in the step 1-2, the exhaust gas is actually included in the finally discharged exhaust gas in the corresponding denitration system actually measured in the outlet analyzer 69 If the amount of nitrogen oxides present in the second step S21 is different from the discharge reference value, the correction value for the reducing agent injection amount set in the step S12 is calculated in the second step S21, In step 2-2 (S22), the reducing agent injection amount set in the first-second step S12 is multiplied by the correction value calculated in the second-first step (S21) By controlling (controlling) the injection amount, it becomes possible to control so that the amount of nitrogen oxide discharged in real time can meet the discharge reference value. That is, in the present invention, during the commissioning of the plurality of denitration systems through the first step (S1), the reducing agent injection amount according to the amount of change in the engine load for each denitration system is set based on the measured value through the outlet analyzer 69 The reducing agent injection amount is controlled in real time according to the reducing agent injection amount set in the step 1-2 of the operation of each of the denitration systems, and in the actual operation of each of the denitration systems, through the outlet analyzer 69 By controlling (controlling) the reducing agent injection amount by precise correction of the amount of the reducing agent injected through the second step (S2) based on the sequentially measured values of the amounts of nitrogen oxides finally discharged from the respective denitration systems, In the process of sequentially measuring the amount of nitrogen oxide contained in the final exhaust gas of the plurality of denitration systems through the analyzer 69, Despite it will have a characteristic that can be a reducing agent injection amount control in a plurality of denitration system in real time.

13, in a reducing agent injection (control) method in a plurality of SCR denitrification systems using one outlet analyzer of the present invention, the reducing agent spraying (control) method is connected to each denitration system through a warning module 683 of the control unit 68 And a third step (S3) of generating and transmitting a warning signal when the engine load ratio calculated by dividing the amount of fuel injected into the engine 61 by the maximum fuel amount is 15% or less.

In the third step S3, an alarm signal is transmitted to the engine 61 when the engine load ratio falls below a specific reference level in the control method of the denitration system according to the present invention, If the amount of fuel currently injected in the engine having the maximum fuel amount of 7,110 kg / hr is 711 kg / hr, the engine load ratio is 10 % ((711/7110) * 9 = 10%). When the engine load ratio of the specific engine 61 is 15% or less, the concentration of the exhaust gas and the toxic substances contained therein is also increased drastically due to incomplete combustion or the like. Therefore, 683 to prevent a significant increase in the load on the SCR denitration system of the exhaust gas.

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

51: engine 52: exhaust pipe
54: mixing chamber 55: reactor
551: SCR catalyst 561:
562: Dosage part 5621: On / off valve
563: Reducing agent supply line 564: Water supply line
565: compressed air supply line 566: reducing agent branch line
567: Water branch line 568: Spray air branch line
569: Cleaning air branch line 560: One-way check valve
61: engine 62: exhaust pipe
64: mixing chamber 65: reactor
651: SCR catalyst 661: injection nozzle
69: Outlet analyzer 68:
681: Injection amount setting module 6811: Maximum minimum setting module per section
6812: injection quantity calculation module 682: injection quantity correction module
6821: correction value calculation module 6822: correction calculation module
683: Warning module
* Prior art related codes
91: engine 92: exhaust pipe
93: mixing chamber 94: reactor
944: SCR catalyst 951: injection nozzle
952: Dosing unit 953: Element number line
954: compressed air line 955: wash water line
956: Purge panel 957: Control line
98: Outlet Analyzer

Claims (6)

delete A reducing agent supply apparatus for supplying a reducing agent into a mixing chamber of a denitration system,
A dosing unit selectively controlling a reducing agent supply line, a water supply line, and a compressed air supply line so that a reducing agent or water can be selectively supplied to a jetting unit for jetting a reducing agent or water into the mixing chamber;
And a unidirectional check valve installed on a line connecting the dosing unit and the jetting unit,
Wherein the one-way check valve comprises a reducing agent branch line as a passage through which the reducing agent is discharged from the dosing section, a water branch line as a passage through which the water is discharged from the dosing section, a spray air branch line as a passage through which the spraying air is discharged from the dosing section, Wherein the cleaning agent is installed in each of the cleaning air branch lines which are the passage through which the cleaning air is discharged. 3. The method of claim 2,
The reducing agent branch line, the water branch line, the spraying air branch line, and the cleaning air branch line are integrated into a single line at the downstream end of the jetting section,
Wherein the one-way check valve installed in each of the reducing agent branch line, the water branch line, the spraying air branch line, and the cleaning air branch line is installed at a position immediately before the respective lines are integrated with other lines. Device. The method of claim 3,
Wherein the dosing unit includes an on / off valve in each of the reducing agent branch line, the water branch line, the spraying air branch line, and the cleaning air branch line in the dosing unit. A reducing agent supplying method for supplying a reducing agent into a mixing chamber of a denitration system,
A reducing agent injection step of controlling the reducing agent branch line and the atomizing air branch line so that the reducing agent is injected through the injection part together with the atomizing air through the reducing agent branch line and the one-way check valve on the atomizing air branch line;
A reducing agent injection stopping step of controlling the reducing agent branching line and the spraying air branching line so that the reducing agent remains in the section from the spraying part to the reducing agent branching line and the one-way check valve on the atomizing air branching line when the reducing agent injection is stopped;
A reducing agent removing step of controlling the dosing addition line and the cleaning air branch line to remove the reducing agent remaining in the cleaning water together with the cleaning water through the one-way check valve on the water branch line and the cleaning air branch line; And a reducing agent supply unit for supplying the reducing agent to the denitration system. 6. The method of claim 5,
The reducing agent injection step may include a first on / off valve opening step of opening the on / off valve on the reducing agent branch line and the atomizing air branch line, and the reducing agent branch line and the spraying line after the first on / off valve opening step. And a first one-way check valve opening step in which the reducing agent is injected through the injection part together with the atomizing air through the one-way check valve on the air branch line,
The reducing agent injection stop step may include an on / off valve closing step of closing the on / off valve on the reducing agent branch line and the spraying air branch line, and a reducing agent branch line on the downstream side of the injection part after the on / Way check valve in which the reducing agent remains only in a section from the spraying portion to the one-way check valve by each one-way check valve positioned immediately before the spraying air branch line is integrated,
The reducing agent removing step may include a second on / off valve opening step of opening the on / off valve on the dosing branch line and the cleaning air branch line for cleaning, and a second on / off valve opening step after the on / And a second one-way check valve opening step of removing the remaining reducing agent while the cleaning water is sprayed together with the cleaning air through the one-way check valve on the air branch line.

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