KR102150227B1 - Catalyst Integrated Dust Collector with Ammonia Injection - Google Patents

Abstract

The present invention relates to a catalyst-integrated dust collector embedded with an ammonia spray device, which receives exhaust gas, removes dust from the received gas, and outputs the dust-free gas. According to the present invention, the catalyst-integrated dust collector comprises: a dust collection case having a dust inlet and an air outlet formed therein; a bag filter installed inside the dust collection case to filter dust from exhaust gas discharged to the outside; a catalyst module disposed on the upper part of the bag filter and including at least one catalyst to receive the exhaust gas passing through the bag filter and perform a denitrification reaction; and an ammonia spray device spraying ammonia gas in a space between the upper part of the bag filter and the catalyst module to promote the denitrification reaction of the catalyst. The catalyst comprises: a partition of a predetermined length formed in a direction from one side to the other side of a side surface; an inlet unit formed on one side of a lower part; and an outlet unit formed on one side of an upper part, wherein the exhaust gas is introduced in the inlet unit, flows toward the other side in accordance with guidance of the partition, and flows again toward the outlet unit. Accordingly, such a catalyst-integrated dust collector can be installed in a worksite where it is difficult to install denitrification equipment due to a narrow installation space and includes the catalyst and the ammonia spray device installed on the upper part of the bag filter to perform denitrification.

Description

Catalyst Integrated Dust Collector with Ammonia Injection}

The present invention relates to a catalyst-integrated dust collector in which an ammonia injection device is inserted, and can be installed in a workplace where it is difficult to provide a denitrification facility due to a narrow installation space. Ammonia for denitrification by installing a catalyst and ammonia injection device on a bag filter. It relates to a catalyst-integrated dust collector with an injection device inserted.

In general, exhaust gases from factories or automobiles contain large amounts of harmful substances that damage the natural environment. In particular, nitrogen oxides (NOX) and sulfur oxides (SOX) contained in exhaust gas directly damage the respiratory system of the human body, but are recognized as the main cause of acid rain, a type of air pollution.

Therefore, regulations on exhaust gas are being implemented internationally, and are increasingly demanded in terms of increasing energy efficiency and preventing environmental pollution.

As a result, there is a further need for a technology that effectively and economically treats pollutants generated from pollution sources such as thermal power plants, incinerators, and various industrial processes. Pollutants discharged from the pollution source are mainly classified into dust, sulfur oxides, nitrogen oxides, chlorides, and heavy metals.

A brief look at the entire process of exhaust gas treatment is as follows.

In general, the exhaust gas treatment process undergoes a process of removing dust using a dust collector for exhaust gas discharged from a boiler, and then a process of providing an appropriate reaction temperature. After the above process, a process of removing sulfur oxide and a process of removing nitrogen oxide are performed. And clean air is discharged to the outside atmosphere through the chimney. Of course, the order of the entire process for treating exhaust gas differs by industry, and the dust collector for removing dust may use both an electric dust collector or a filter dust collector, but it is irrelevant to select only one.

During the above process, a denitration facility is used to remove nitrogen oxides.

Likewise, the denitration facility is separately installed to remove nitrogen oxides in exhaust gas, and generally, methods for removing nitrogen oxides include a selective catalytic reduction method and a selective non-catalytic reduction method.

The selective catalytic reduction method is a method of decomposing nitrogen oxides in the exhaust gas into nitrogen and water vapor by injecting ammonia as a reducing agent into exhaust gas and contacting the exhaust gas injected with the reducing agent with the catalyst.

A brief look at a method of removing nitrogen oxides through the selective catalytic reduction method is as follows.

Noble metal substances are platinum, palladium, and rhodium. Transition metals are vanadium, iron, cobalt, copper, and the like. The catalyst material is prepared by reacting at least one of titanium dioxide, vanadium oxide, alumina, and zeolite with at least one of platinum, palladium, rhodium, vanadium, iron, cobalt, and copper.

In addition, the catalyst is bonded to a substrate such as a highly durable honeycomb-type cordierite, and loaded in several stages in a reaction tower. After that, ammonia or ammonia water, which is a reducing agent, is sprayed onto the catalyst heated to a high temperature to reduce nitrogen oxides, thereby converting it into steam and nitrogen gas.

At this time, the reaction mechanism is as follows.

4 NO + O2 + 4NH3 -> 4N2 + 6H20

When the exhaust gas flows into the catalyst having the structure as shown in FIG. 1, it reacts as shown in FIG. 2 in the catalyst, and a reduction reaction occurs with nitrogen gas and water as shown in the above reaction equation to remove nitrogen oxides.

The selective catalytic reduction method is referred to as a selective catalytic reduction method in the sense of preferentially reducing nitrogen oxides in exhaust gas.

On the other hand, nitrogen oxide (Nox), the main culprit of fine dust and air pollution, is becoming a social issue, and the government announced that it will greatly strengthen the emission standards of nitrogen oxides from 2020. For reference, before the government announcement, the regulation on the concentration of nitrogen oxides was loose.

Accordingly, domestic business sites are reviewing various technologies in order to comply with the reinforced emission standards, and there are the following problems.

We tried to apply the “SCR using the HONEY-COMB type catalyst”, which is the most widely applied so far, but there is a problem that unnecessary additional energy costs are burdensome and the installation space is insufficient because temperature rise is required due to the characteristics of the facility.

As described above, in the conventional combustion process, nitrogen in the combustion air and nitrogen contained in solid fuel are oxidized to produce nitrogen oxides (mainly composed of nitrogen monoxide (NO) and nitrogen dioxide (NO2)). The first reduction in SNCR Nitrogen oxide is reduced and discharged below the emission standard by the catalyst of the denitrification facility (SCR). Here, the reducing agent is ammonia water (NH3) and urea water (CO(NH2)2).

However, conventionally, when the temperature is too high, the oxidation reaction has a problem of regenerating nitrogen oxides (NOx).

In addition, if the temperature is too low or the residence time is insufficient in the reaction between ammonia and nitrogen oxides, the nitrogen oxide reduction efficiency may decrease and untreated ammonia emissions may increase (ammonia slip, chemical excess).

As such, the main factors affecting the denitration performance include proper mixing of the exhaust gas and the reactant, temperature, residence time, and the like.

In order to compensate for the above shortcomings, the recent foreign-made PELLET TYPE catalyst is applied, and the characteristic of this TYPE is that it exhibits denitrification efficiency even at low temperature (150°C), so there is no burden of additional energy cost. In addition, the installation space required is more compact than the HONEY COMB TYPE.

On the other hand, in some workplaces, installation of denitrification facilities may be difficult due to the narrow installation space.

On the other hand, in the related art, ammonia is sometimes supplied to the front end of the dust collector to further promote the action of the catalyst.

However, in this case, activated carbon and slaked lime adsorb ammonia gas at the front end of the bag filter, thereby reducing the denitration efficiency.

In addition, there is a problem that the bag filter made of a nonwoven fabric is damaged by ammonia.

On the other hand, referring to FIG. 3, in the structure of the dust collector, there is a door at the top, and there is a certain space between the bag filter and the door.

The problem to be achieved by the present invention is to solve such a problem, and by installing a catalyst on the bag filter and injecting ammonia gas into the clean section between the bag filter and the catalyst, the reaction between nitrogen oxides and ammonia in the exhaust gas is prevented. It is to provide a catalyst-integrated dust collector with a maximum ammonia injection device inserted.

In addition, the object of the present invention is to solve such a problem, by installing a catalyst on the top of the bag filter and injecting ammonia gas into the clean section between the bag filter and the catalyst, It is to provide a catalyst-integrated dust collector in which an ammonia injection device is inserted so as not to damage.

In addition, the problem to be achieved by the present invention is to solve such a problem, and can be installed in a workplace where it is difficult to provide a denitrification facility due to a narrow installation space, and an ammonia injection device for denitrification by installing a catalyst on the top of the bag filter. It is to provide an inserted catalyst-integrated dust collector.

In addition, the object of the present invention is to solve such a problem, and the present invention delays the residence time after the exhaust gas flows into the catalyst to increase the time for mixing the exhaust gas and the reactant to increase the denitration efficiency. It is to provide a catalyst-integrated dust collector in which an injection device is inserted.

In addition, the problem to be achieved by the present invention is to solve such a problem.After the exhaust gas flows into the inlet of the catalyst, it descends downward according to the induction of the partition wall, then rises again and reacts with the exhaust gas while exiting the outlet. It is to provide a catalyst-integrated dust collector in which an ammonia injection device is inserted to increase the denitration efficiency by increasing the mixing time of the agent.

In addition, the problem to be achieved by the present invention is to solve such a problem, and after the exhaust gas flows into the inlet of the catalyst and goes out through the outlet while drawing an E letter, it increases the time for mixing the exhaust gas and the reactant to increase the denitration efficiency. It is to provide a catalyst-integrated dust collector in which an ammonia injection device is inserted to increase the

In order to achieve the above object, the catalyst-integrated dust collector into which the ammonia injection device according to the features of the present invention is inserted,

It is a catalyst-integrated dust collector with an ammonia injection device inserted into the exhaust gas to perform dedusting and output,

A dust collecting case having a dust inlet and an air outlet;

A bag filter installed inside the dust collecting case to filter dust of exhaust gas discharged to the outside;

A catalyst module located above the bag filter and including at least one catalyst for performing a denitrification reaction after the exhaust gas passing through the bag filter is introduced;

Including an injection device for accelerating the denitrification reaction of the catalyst by injecting ammonia gas into the space between the upper bag filter and the catalyst module,

The catalyst,

An inlet part is formed on one side of the lower part, an outlet part is formed in the other side of the upper part,

After the exhaust gas flows into the inlet, it moves in an S-shaped curve and exits the outlet.

The injection device is characterized in that the ammonia gas is injected in the direction of the inlet.

In order to achieve the above object, the catalyst-integrated dust collector into which the ammonia injection device according to the features of the present invention is inserted,

It is a catalyst-integrated dust collector with an ammonia injection device inserted into the exhaust gas to perform dedusting and output,

A dust collecting case having a dust inlet and an air outlet;

A bag filter installed inside the dust collecting case to filter dust of exhaust gas discharged to the outside;

A catalyst module located above the bag filter and including at least one catalyst for performing a denitrification reaction after the exhaust gas passing through the bag filter is introduced;

Including an injection device for accelerating the denitrification reaction of the catalyst by injecting ammonia gas into the space between the upper bag filter and the catalyst module,

The catalyst,

A partition wall of a predetermined length is formed from one side to the other side,

An inlet part is formed on one side of the lower part, an outlet part is formed in one side of the upper part,

After the exhaust gas flows into the inlet, it goes to the other side according to the guidance of the partition wall, and then flows out to the outlet again.

A compressed gas tank storing compressed gas and supplying compressed gas by opening and closing a valve;

An injector that injects the compressed gas to remove dust adhered to the bag filter;

It further comprises a compressed gas line for supplying the compressed gas of the compressed gas tank to the injector.

A door or a double door is formed above the dust collecting case.

The injection device,

It is characterized in that ammonia gas is supplied from a vaporizer that converts ammonia into gas in the ammonia tank.

According to the above-described configuration, the present invention inserts an ammonia injection device that maximizes the reaction between nitrogen oxides and ammonia in exhaust gas by installing a catalyst on the bag filter and injecting ammonia gas into the clean section between the bag filter and the catalyst. A catalyst integrated dust collector can be provided.

In addition, the present invention is a catalyst in which a catalyst is installed on the bag filter, and ammonia gas is injected into the clean section between the bag filter and the catalyst, so that the ammonia does not damage the nonwoven bag filter. An integrated dust collector can be provided.

In addition, the present invention can be installed in a workplace where it is difficult to provide a denitrification facility due to a narrow installation space, and a catalyst-integrated dust collector in which an ammonia injection device for denitrification by installing a catalyst is installed on a bag filter.

In addition, the present invention can provide a catalyst-integrated dust collector in which an ammonia injection device is inserted to increase the denitration efficiency by delaying the residence time after the exhaust gas flows into the catalyst to increase the mixing time between the exhaust gas and the reactant.

In addition, the present invention sprays ammonia to increase the denitration efficiency by increasing the time for mixing the exhaust gas and the reactant while the exhaust gas flows into the inlet of the catalyst and then goes down and rises again according to the induction of the partition wall. It is possible to provide a catalyst-integrated dust collector in which the device is inserted.

In addition, the present invention provides a catalyst-integrated dust collector in which an ammonia injection device is inserted to increase the denitration efficiency by increasing the time for mixing the exhaust gas and the reactant while drawing an S character after the exhaust gas flows into the inlet of the catalyst and goes out through the outlet. can do.

In addition, the present invention detects the differential pressure between the front and rear ends of the bag filter and determines that the function of the catalyst is not smooth when the pressure is higher than the standard differential pressure, and thus, an ammonia injection device is inserted to inject compressed gas to the catalyst to perform dedusting. A dust collector can be provided.

1 is a view showing the configuration of a low-temperature catalyst according to the prior art.
2 is a diagram showing the principle of a general denitrification action.
3 is a view showing a general dust collector.
4 is a view showing the configuration of a catalyst-integrated dust collector in which an ammonia injection device according to the first embodiment of the present invention is inserted.
5 is a view showing the configuration of a catalyst-integrated dust collector into which an ammonia injection device according to a second embodiment of the present invention is inserted.
6 is a view showing a front view of a hybrid injector applied to a catalyst-integrated dust collector in which an ammonia injection device is inserted according to an embodiment of the present invention.
7 is a side view of a hybrid injector.
8 is a diagram showing a plan view of a hybrid injector.
9 is a view showing the front of the hybrid injector separated.
10 is a view showing the inside of the upper cover by separating the hybrid injector.
11 is a view showing the U-bolt of the hybrid injector.
12 is a view showing a compressed gas line of a hybrid injector.
13 is a view showing the flow of compressed gas and intake air in the hybrid injector.
14 is a diagram schematically showing a state in which a tornado is formed in an upper cover of a hybrid injector according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those of ordinary skill in the art can easily implement the embodiments of the present invention. However, the present invention may be implemented in various different forms and is not limited to the embodiments described herein. In the drawings, parts irrelevant to the description are omitted in order to clearly describe the present invention, and similar reference numerals are assigned to similar parts throughout the specification.

Throughout the specification, when a part "includes" a certain component, it means that other components may be further included rather than excluding other components unless otherwise stated.

4 is a view showing the configuration of a catalyst-integrated dust collector in which an ammonia injection device according to the first embodiment of the present invention is inserted.

4, a catalyst-integrated dust collector into which an ammonia injection device according to a first embodiment of the present invention is inserted,

It is a catalyst-integrated dust collector with an ammonia injection device inserted into the exhaust gas to perform dedusting and output,

A dust collecting case 700 having a dust inlet 710 and an air outlet 720;

A bag filter 400 installed inside the dust collecting case 700 to filter dust of exhaust gas discharged to the outside;

A catalyst module disposed above the bag filter 400 and including at least one catalyst 500 for performing a denitrification reaction after the exhaust gas passing through the bag filter 400 is introduced;

And an injection device 610 for accelerating the denitrification reaction of the catalyst by injecting ammonia gas into the space between the upper portion of the bag filter 400 and the catalyst 500.

The injection device 610 is characterized in that it receives ammonia gas from a vaporizer 630 that converts ammonia in the ammonia tank 620 into gas.

The catalyst 500,

An inlet part is formed on one side of the lower part, an outlet part is formed in the other side of the upper part,

After the exhaust gas flows into the inlet, it moves in an S-shaped curve and exits the outlet.

The catalyst 500 is intimately coupled with the dust collecting case 700 so that the exhaust gas that has passed through the bag filter 400 exits the air outlet 720 only through the catalyst 500.

It is preferable that the catalyst 500 is installed in a shape in which the existing catalyst 500 is laid down to take up less space.

The catalyst 500 allows the first partition wall 531 in the lower right and the second partition 532 in the upper left to move in an S-shaped curve to the upper right after exhaust gas flows through the lower left. The residence time in the catalyst 500 is maximized.

And,

A compressed gas tank 800 for storing compressed gas and supplying compressed gas by opening and closing the valve;

An injector 200 for removing dust adhered to the bag filter 400 by spraying the compressed gas;

It further comprises a compressed gas line for supplying the compressed gas of the compressor tank to the injector (200).

A door 600 is formed on the dust collecting case 700.

The operation of the catalyst-integrated dust collector into which the ammonia injection device according to the first embodiment of the present invention having such a configuration is inserted is as follows.

First, exhaust gas output from a combustion device or the like is introduced into the dust inlet 710. At this time, ammonia or aqueous ammonia as a reducing agent remains in the exhaust gas. That is, ammonia or ammonia water injected during combustion in a combustion device such as a power plant remains.

Then, the exhaust gas is removed while passing through the bag filter 400, and is introduced into the catalyst 500.

At this time, the injection device 610 is supplied with ammonia gas from the vaporizer 630 that converts ammonia in the ammonia tank 620 into gas, and ammonia gas is supplied in the space between the upper portion of the bag filter 400 and the catalyst 500. Inject gas.

Then, the injected ammonia gas also flows into the inlet of the catalyst 500.

At this time, the catalyst 500 is discharged to the outlet 520 while the exhaust gas and ammonia gas flow in through the lower left inlet 510 through the lower left inlet 510 and then move in an S-shaped curve to the upper right. I'm going.

Here, the first partition wall 531 in the lower right and the second partition wall 532 in the upper left are in the upper right after exhaust gas and ammonia gas flow into the inlet 510 through the lower left as in the direction of the arrow in FIG. The nitrogen oxides maximize the residence time in the catalyst 500 by moving in the form of an S-shaped curve and exiting the outlet 520.

Here, the exhaust gas and ammonia gas have a longer residence time and a moving distance in the catalyst 500 than in the related art, so that the efficiency of the denitration reaction is increased.

In the catalyst 500, the number and shape of the catalysts 500 can be modified, but the residence time and movement distance in the catalyst 500 are lengthened.

Then, the exhaust gas and the ammonia gas are combined with the reducing agent while moving in the catalyst 500, so that the denitrification action occurs smoothly.

Then, the exhaust gas passing through the catalyst 500 is discharged through the air outlet 720.

In this embodiment of the present invention, since the denitrification function is improved, ammonia gas injected from the injector 610 as well as ammonia or ammonia water injected during combustion in a combustion apparatus such as a power plant is smoothly denied.

5 is a view showing the configuration of a catalyst-integrated dust collector into which an ammonia injection device according to a second embodiment of the present invention is inserted.

5, a catalyst-integrated dust collector in which an ammonia injection device according to a second embodiment of the present invention is inserted,

It is a catalyst-integrated dust collector with an ammonia injection device inserted into the exhaust gas to perform dedusting and output,

A dust collecting case 700 having a dust inlet 710 and an air outlet 720;

A bag filter installed inside the dust collecting case 700 to filter dust of exhaust gas discharged to the outside;

A catalyst module disposed above the bag filter and including at least one catalyst 500 for performing a denitrification reaction after the exhaust gas passing through the bag filter is introduced;

And an injection device 610 for accelerating the denitrification reaction of the catalyst by injecting ammonia gas into the space between the upper portion of the bag filter 400 and the catalyst 500.

The injection device 610 is characterized in that it receives ammonia gas from a vaporizer 630 that converts ammonia in the ammonia tank 620 into gas.

The catalyst 500,

A third partition wall 530 of a predetermined length is formed from one side to the other side,

An inlet portion 510 is formed on one side of the lower portion, and an outlet portion 520 is formed on one side of the upper portion,

5, the exhaust gas and ammonia gas are introduced into the inlet and then go to the other side according to the guidance of the third partition wall 530, and then flow out to the outlet 520 again.

The catalyst 500,

The sides are blocked,

A third partition wall 530 is formed from the left center to the right,

The outlet portion 520 is formed on the upper right side, and the inlet portion 510 is formed on the lower right side.

Further, a first partition wall 531 is formed on the lower right side, and a second partition wall 532 is formed on the upper right side.

The exhaust gas and ammonia gas are introduced into the inlet 510 and then go to the right according to the guidance of the third partition wall 530 and then go up to the outlet 520 on the left and then flow out.

The lengths of the first partition wall 531, the second partition wall 532, and the third partition wall 530 are 1/2 to 2/3 of the length of the catalyst 500.

The catalyst 500 contains a catalyst material in the form of pellets or powder.

Noble metal substances are platinum, palladium, and rhodium. Transition metals are vanadium, iron, cobalt, copper, and the like. The catalyst material is prepared by reacting at least one of titanium dioxide, vanadium oxide, alumina, and zeolite with at least one of platinum, palladium, rhodium, vanadium, iron, cobalt, and copper.

The operation of the catalyst-integrated dust collector into which the ammonia injection device according to the second embodiment of the present invention having such a configuration is inserted is as follows.

The operation of the second embodiment is the same as that of the first embodiment, except that the movement path of the exhaust gas in the catalyst 500 is different, and thus will be briefly described.

First, exhaust gas output from a combustion device or the like is introduced into the dust inlet 710. At this time, ammonia or aqueous ammonia as a reducing agent remains in the exhaust gas. That is, ammonia or ammonia water injected during combustion in a combustion device such as a power plant remains.

Then, the exhaust gas is removed while passing through the bag filter 400, and is introduced into the catalyst 500.

At this time, the injection device 610 is supplied with ammonia gas from the vaporizer 630 that converts ammonia in the ammonia tank 620 into gas, and ammonia gas is supplied in the space between the upper portion of the bag filter 400 and the catalyst 500. Inject gas.

Then, the injected ammonia gas also flows into the inlet of the catalyst 500.

At this time, in the catalyst 500, exhaust gas and ammonia gas are introduced through the lower left inlet 510 while the side is blocked, and then go to the right according to the induction of the third partition wall, and then again at the left outlet 520 It is characterized in that it goes up in the direction and flows out.

Here, the exhaust gas and ammonia gas have a longer residence time and a moving distance in the catalyst 500 than in the related art, so that the efficiency of the denitration reaction is increased.

Then, the exhaust gas and the ammonia gas are combined with the reducing agent while moving in the catalyst 500, so that the denitrification action occurs smoothly.

Then, the exhaust gas passing through the catalyst 500 is discharged through the air outlet 720.

By the above-described configuration, in this embodiment of the present invention, a catalyst is installed on the bag filter, and ammonia gas is injected into the clean section between the bag filter and the catalyst, thereby maximizing the reaction between nitrogen oxides and ammonia in the exhaust gas. have.

In addition, according to the present invention, a catalyst is installed on the bag filter and ammonia gas is injected into a clean section between the bag filter and the catalyst, so that the bag filter made of a nonwoven fabric is not damaged by ammonia.

In addition, the present invention can be installed in a workplace where it is difficult to provide a denitrification facility due to a narrow installation space, and a catalyst can be installed on the bag filter to perform denitrification.

In addition, the present invention can increase the denitration efficiency by delaying the residence time after the exhaust gas flows into the catalyst to increase the mixing time of the exhaust gas and the reactant.

In addition, according to the present invention, after the exhaust gas flows into the inlet of the catalyst, it descends downward according to the induction of the partition wall and then rises again and goes out through the outlet to increase the time for mixing the exhaust gas and the reactant to increase the denitration efficiency. .

In addition, according to the present invention, after the exhaust gas flows into the inlet portion of the catalyst, the exhaust gas and the reactant are mixed with each other while drawing an E letter and passing through the outlet portion, thereby increasing the denitration efficiency.

In addition, in the present invention, when the pressure difference between the front end and the rear end of the bag filter is sensed, it is determined that the function of the catalyst is not smooth when the pressure is higher than the reference differential pressure, and the compressed gas is injected to the catalyst to perform dedusting.

And, the catalyst-integrated dust collector into which the ammonia injection device according to the embodiment of the present invention is inserted,

If necessary, the pressure difference between the front and rear ends of the bag filter 400 is measured, and when the pressure difference is greater than or equal to a reference value, the compressed gas may be injected under the control of a controller (not shown).

Hereinafter, a process in which the injector 200 in the above process injects compressed gas will be described in more detail.

6 is a view showing a front view of a hybrid injector applied to a catalyst-integrated dust collector in which an ammonia injection device is inserted according to an embodiment of the present invention.

7 is a side view of a hybrid injector.

8 is a diagram showing a plan view of a hybrid injector.

9 is a view showing the front of the hybrid injector separated.

10 is a view showing the inside of the upper cover by separating the hybrid injector.

11 is a view showing the U-bolt of the hybrid injector.

12 is a view showing a compressed gas line of a hybrid injector.

13 is a view showing the flow of compressed gas and intake air in the hybrid injector.

14 is a diagram schematically showing a state in which a tornado is formed in an upper cover of a hybrid injector according to an embodiment of the present invention.

6 to 12, the hybrid injector 200 applied to the embodiment of the present invention,

As a hybrid injector 200 coupled to the compressed gas line 100 for injecting compressed gas and for injecting a mixed gas of compressed gas and air through the bag filter 400,

An upper cover 230 in which a first inlet port 260 of the medium to be sucked is formed, and a plurality of guide vanes 232 for guiding the direction of the compressed gas are formed;

A main body 100 forming a preliminary chamber 240 together with the upper cover 230;

It has an internal passage connecting the preliminary chamber 240 and the compressed gas line 100, has a concave upper portion to pass through the compressed gas line 100, and a plurality of second inlets 211 for compressed gas, Includes cradles 210 and 220 on which 221 is formed.

The preliminary chamber 240 is formed in an annular shape to surround a first inlet 260 for a medium to be sucked, and the holders 210 and 220 have two second inlets 211 and 221 facing each other.

The guide vanes 232 are formed obliquely at regular intervals on the upper cover 230 of the preliminary chamber 240, and the main body 100 and the cover 230 have a circumference 231 so as to maintain a predetermined gap. ) Is formed.

A compressed gas injection hole 130 is additionally formed in the compressed gas line 100, and the center line of the injector 200 is made equal to the center line of the compressed gas line 100 in the upper center of the body 100. ) A high-pressure jet airflow is formed in the center, and a Coanda effect is formed around the inner diameter of the injector 200.

A plurality of ribs (Rib, 251, 252, 253, 254) for fixing the compressed gas line 100 by using a U-BOLT on the side of the main body 100, and the U-bolt The compressed gas line 100 is fixed by fastening the nuts 311 and 312 to the 310. Accordingly, the U-bolts 311 and 312 do not interfere with the air inflow path of the first inlet 260, and the compressed gas line 100 is also spaced apart from the main body 100 by the holders 210 and 220 to provide the air inflow path. A large amount of air can flow in smoothly.

The preliminary chamber 240 is connected to the second inlets 211 and 221 for inhaling compressed gas to be sucked, and an outlet 270 for compressed gas is formed under the main body 100.

The first inlet 260 is located below the plurality of second inlets 211 and 221 of the preliminary chamber 240, and the compressed gas is the second inlet 211 and 221 of the preliminary chamber 240, a holder It is injected into the outlet 270 through the inner passages 210 and 220 and the preliminary chamber 240.

The operation of the hybrid injector having this configuration will be described as follows.

13 is a view showing the flow of compressed gas and intake air in the hybrid injector, Figure 14 is a view schematically showing a state in which a tornado is formed in the upper cover of the hybrid injector.

Referring to FIG. 13, compressed gas is supplied from the outside to the compressed gas line 100. When the injector 200 is connected to the compressed gas line 100, the compressed gas is in the compressed gas line 100 in the direction of the arrow, and the second inlets 211 and 221 connected to the compressed gas injection holes 110 and 130 And it is supplied to the spare chamber 240 through the inner passage of the cradles (210, 220). At this time, a plurality of injectors 200 are provided to operate each, and one injector will be described for convenience.

Then, the compressed gas is converted into a tornado or tornado shape by the guide vanes 232 formed on the upper cover of the annular preliminary chamber 240 and is injected in the direction of the outlet 270.

And, if necessary, a nozzle slot (not shown) inside the preliminary chamber 240 is additionally provided to induce a Coanda effect and generate negative pressure, so that air is passed through the first inlet 260 to the outlet 270. It can be accelerated to flow.

At this time, the inhaled air is mixed with the compressed gas in the form of a tornado or a tornado and flows more quickly toward the outlet. Here, the compressed gas may be compressed air.

On the other hand, since the compressed gas is injected downward through the compressed gas injection hole 120 of the compressed gas line 100, the speed at which air is sucked becomes faster, and the air and whirlwind sucked through the first inlet 260 The mixing and flow rates of compressed gases in the form are also faster.

Therefore, in an embodiment of the present invention, by increasing the amount of suction of the surrounding air to the inlet of the injector 200 due to the compressed gas injected from the compressed gas line, more suction gas can be discharged through the outlet of the injector, and the injection pressure is reduced. You can increase it.

In addition, by increasing the speed of the compressed gas passing through the outlet of the injector, more ambient air can be introduced into the bag filter together with the compressed gas passing through the outlet of the injector, thereby improving the dust removal effect for the bag filter.

In addition, in order to minimize interference between the inflow path of compressed air causing the Coanda effect and the inflow of outside air, the inlet is not arranged on the same plane but on the top (about 2cm or more) to secure the inflow space and It can maximize the exhaustion effect.

In addition, by installing a plurality of guide vanes under the upper cover of the injector, it is possible to efficiently dedust the bag filter by maintaining a certain gap between the injector body and the cover and forming a tornado (tornado) of the flow of the compressed gas that is introduced. .

In addition, by making the center line of the Coanda injector equal to the center line of the compressed air pipe, a compressed air injection hole is formed in the center of the Coanda injector, forming a high-pressure jet airflow in the center, and forming a Coanda effect around the inner diameter of the injector. It can increase the dust removal efficiency.

In addition, by configuring a rib for U-BOLT assembly in the injector body and fastening it with U-BOLT & NUT, it is possible to secure ease of installation and replacement, and fastening durability.

In addition, by configuring a cradle (saddle) capable of mounting a compressed air pipe in the injector body, it is possible to secure ease of assembly by processing only a hole in the pipe.

The embodiment of the present invention described above is not implemented only through an apparatus and/or method, but a program for realizing a function corresponding to the configuration of the embodiment of the present invention, a recording medium in which the program is recorded, etc. Also, such an implementation can be easily implemented by an expert in the technical field to which the present invention belongs from the description of the above-described embodiment.

Although the embodiments of the present invention have been described in detail above, the scope of the present invention is not limited thereto, and various modifications and improvements by those skilled in the art using the basic concept of the present invention defined in the following claims are also provided. It belongs to the scope of rights.

Claims (4)

It is a catalyst-integrated dust collector with an ammonia injection device inserted into the exhaust gas to perform dedusting and output,
A dust collecting case having a dust inlet and an air outlet;
A bag filter installed inside the dust collecting case to filter dust of exhaust gas discharged to the outside;
A catalyst module located above the bag filter and including at least one catalyst for performing a denitrification reaction after the exhaust gas passing through the bag filter is introduced;
Including an injection device for accelerating the denitrification reaction of the catalyst by injecting ammonia gas into the space between the upper bag filter and the catalyst module,
The catalyst,
An inlet part is formed on one side of the lower part, an outlet part is formed in the other side of the upper part,
After the exhaust gas flows into the inlet, it moves in an S-shaped curve and exits the outlet,
The catalyst allows the first partition wall in the lower right and the second partition in the upper left to move in an S-shaped curve to the upper right after the exhaust gas flows through the lower left, so that the nitrogen oxide stays in the catalyst. Delay,
The length of the first and second barrier ribs is 1/2 to 2/3 of the catalyst length,
A catalyst material in the form of pellets or powder is included in the catalyst,
The catalyst material is prepared by reacting at least one of platinum, palladium, rhodium, vanadium, iron, cobalt, and copper with at least one of titanium dioxide, vanadium oxide, alumina, and zeolite,
A compressed gas tank storing compressed gas and supplying compressed gas by opening and closing a valve;
An injector that injects the compressed gas to remove dust adhered to the bag filter;
A catalyst-integrated dust collector in which an ammonia injector is inserted, further comprising a compressed gas line for supplying the compressed gas of the compressed gas tank to the injector. It is a catalyst-integrated dust collector with an ammonia injection device inserted into the exhaust gas to perform dedusting and output,
A dust collecting case having a dust inlet and an air outlet;
A bag filter installed inside the dust collecting case to filter dust of exhaust gas discharged to the outside;
A catalyst module located above the bag filter and including at least one catalyst for performing a denitrification reaction after the exhaust gas passing through the bag filter is introduced;
Including an injection device for accelerating the denitrification reaction of the catalyst by injecting ammonia gas into the space between the upper bag filter and the catalyst module,
The catalyst,
A partition wall of a predetermined length is formed from one side to the other side,
An inlet part is formed on one side of the lower part, an outlet part is formed in one side of the upper part,
After the exhaust gas flows into the inlet, it goes to the other side according to the induction of the partition wall, and then flows out to the outlet again,
The catalyst,
The sides are blocked,
A first partition wall is formed on the right side of the lower side, a second partition wall is formed on the right side of the upper side, and a third partition wall is formed from the left center to the right side,
The outlet is formed on the right side of the top, the inlet is formed on the right side of the bottom,
After the exhaust gas flows into the inlet, it goes to the right according to the induction of the third partition wall, and then rises to the left side and flows out again,
The lengths of the first, second, and third partitions are 1/2 to 2/3 of the catalyst length,
A catalyst material in the form of pellets or powder is included in the catalyst,
The catalyst material is prepared by reacting at least one of platinum, palladium, rhodium, vanadium, iron, cobalt, and copper with at least one of titanium dioxide, vanadium oxide, alumina, and zeolite,
A compressed gas tank storing compressed gas and supplying compressed gas by opening and closing a valve;
An injector that injects the compressed gas to remove dust adhered to the bag filter;
A catalyst-integrated dust collector in which an ammonia injector is inserted, further comprising a compressed gas line for supplying the compressed gas of the compressed gas tank to the injector. The method according to claim 1 or 2,
The injection device receives ammonia gas from a vaporizer that converts ammonia into gas in an ammonia tank, and injects ammonia gas in the direction of the inlet. The method of claim 3,
A catalyst-integrated dust collector with an ammonia injection device inserted therein, characterized in that a door is formed above the dust collection case.

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