KR20110127823A - Screen apparatus of a combustion system for preventing particle ashes from being accumulated - Google Patents

Abstract

PURPOSE: A screen device for preventing accumulation of dust of a combustion system is provided to smoothly discharge exhaust gas by preventing the clogging of a SCR catalyst layer by dust. CONSTITUTION: A screen device for preventing accumulation of dust of a combustion system comprises a boiler, a SCR(5), a dust remover, and a screen member(11). The SCR is connected to a boiler with a duct(9). The SCR eliminates NOx(Nitrogen Oxide) of the exhaust gas from the combustion process of the boiler. The screen member filters the dust cake accompanied with the exhaust gas. The screen member is installed in one part of the inlet duct where the velocity of the exhaust gas is slow.

Description

Screen apparatus of a combustion system for preventing particle ashes from being accumulated}

The present invention relates to a screen device for preventing dust accumulation of a combustion system, and more particularly, relatively large particles of exhaust gas generated during combustion by an industrial boiler or an incinerator cannot pass through a catalyst layer of SCR (Selective Catalytic Reduction). Accumulation of dust in the combustion system, thereby preventing the smooth discharge of exhaust gas by accumulating even the fine dusts that have normally passed in the catalyst layer, thereby preventing the combustion system from being outputted or inoperable. It relates to a screen device for prevention.

In general, exhaust gases are generated when burning fuel (or flammables) generated by an industrial boiler or an incinerator, and the exhaust gases pollute the atmosphere, are harmful to the human body, and cause nitrogen rain and light smog. Oxides (NOx), sulfur oxides, and the like.

Nitrogen oxides are removed via an SCR (Selective Catalytic Reduction Processor), which is more convenient to operate and easier to install and handle than other types of nitrogen oxide processors. The SCR converts nitrogen oxides (NOx) in the exhaust gas into harmless water (H ₂ O) and nitrogen (N ₂ ).

1 is a schematic block diagram showing an industrial boiler system according to the prior art.

Industrial boiler system according to the prior art is, as shown in Figure 1, press-fit blower (1), steam type air preheater (2), boiler (3), degasser (4), SCR (5), economizer (6) , Dust remover 7 and stack 8.

Here, the degassing apparatus 4 functions to remove dissolved oxygen in the heat medium (for example, water) for absorbing and transferring heat generated during the combustion process, and the SCR 5 performs the denitrification function as described above. To perform. The economizer 6 serves to absorb the waste heat of the exhaust gas to heat the water supplied from the degasser 4 to the boiler 3, and the dust remover 7 collects dust in the exhaust gas. Play a role.

The boiler 3 is supplied with combustibles such as coal, diesel oil, waste, etc., and the combustion air is supplied through the steam-type air preheater 2 by the press-fit blower 1. In addition, the boiler 3 is supplied with a heating medium, for example, water, which removes dissolved oxygen in the heating medium while passing through the degassing apparatus 4 and absorbs waste heat of exhaust gas while passing through the economizer 6.

Thereafter, the heat medium heated through the boiler 3 is supplied to an external facility or a generator for heating or power generation, and the exhaust gas generated in the combustion process by the boiler 3 is transferred to the SCR 5. Is sent. Nitrogen oxide in the exhaust gas is removed through a catalytic reduction reaction while passing through the SCR (5) and waste heat of the exhaust gas is heated through the economizer (6) as described above to heat the heating medium, for example water.

Thereafter, the dust in the exhaust gas passing through the economizer 6 is collected and removed through the dust remover 7, and the exhaust gas thus purified is discharged to the atmosphere through the stack 8.

However, the industrial boiler system according to the prior art is always accompanied by fine dust in the exhaust gas generated during the combustion process, but sometimes very light or abnormal large particles, such as popcorn ash, when the fuel properties are out of the proper range or the combustion process is unstable. (popcorn ash) or LPA (large particle ash) does not pass through the catalyst layer of the SCR 5 (each cell of the catalyst layer is formed with a pitch of about 6 to 9 mm, for example) and has a problem of blocking the catalyst layer of the SCR 5.

As described above, when the catalyst layer of the SCR (5) is blocked by very light or abnormal large particles such as popcorn ash or LPA, even the fine dusts that normally pass through the catalyst layer do not pass through the catalyst layer and are thus accumulated. This causes resistance to prevent the smooth discharge of exhaust gases and, in severe cases, results in lower output or inoperable conditions of the combustion system.

Accordingly, the present invention has been made to solve the problems described above, the object of the present invention is that the SCR by the very light but abnormal large particles accompanying the exhaust gas generated during combustion and fine dust accompanying them The present invention provides a screen device for preventing dust accumulation of a combustion system that prevents clogging of a catalyst layer of (Selective Catalytic Reduction) to enable a smooth discharge of exhaust gas.

Another object of the present invention is to stall the blowing fan when the ventilation resistance applied to the exhaust fan is too large than the ventilation resistance of the blower fan designed to forcibly exhaust the exhaust gas within the preset range due to the blockage of the catalyst layer of the SCR. The present invention provides a screen device for preventing dust accumulation of a combustion system that can prevent stalls, trips, or overcurrents, which in turn prevents the output of the combustion system from being reduced or disabled.

In order to achieve the above object, the present invention is connected to a boiler (or incinerator), the SCR (removing nitrogen oxides (NOx) in the exhaust gas generated during the combustion process by the boiler and the duct connected to the boiler ( In the combustion system comprising a Selective Catalytic Reduction and a dust remover for collecting the dust accompanying the exhaust gas discharged to the stack through the SCR,

Inlet side of the SCR in which the flow rate of the exhaust gas is slower than that of the other portions of the section of the duct connecting the boiler and the SCR to filter out dust lumps accompanying the exhaust gas discharged from the boiler to the SCR. It provides a screen device for preventing dust accumulation of a combustion system, characterized in that the screen member is installed on a portion of the duct.

In addition, the present invention further provides the following specific embodiments of the above-described embodiment of the present invention.

According to one embodiment of the invention, the screen member is characterized in that composed of at least one mesh member (Mesh member), and a frame member for fixing the mesh member.

According to an embodiment of the present invention, the duct portion in which the screen member is installed connects the boiler and the SCR in a horizontal direction, and the screen member is disposed such that the upper portion is inclined upstream with respect to the exhaust gas flow cross section of the duct. It is characterized by.

According to one embodiment of the invention, it characterized in that it further comprises a rapper unit (Rapper unit) to shake off the dust laminated to the screen member in the duct.

According to an embodiment of the present invention, the thrusting unit is characterized in that it comprises an operating unit which is installed to be supported in the duct, and at least one thrusting rod coupled to the output end of the operating unit and the screen member.

According to one embodiment of the invention, the screen member is composed of at least one mesh member and a frame member for fixing the mesh member, the lower portion of the screen member is blocked by the screen member in the corresponding portion of the duct A concave portion is further formed to accommodate fallen dust, and the lower frame member of the screen member is accommodated in the concave portion.

According to an embodiment of the present invention, the concave portion of the duct is further provided with a dust transporter oriented along the length of the concave portion, the dust transporter is characterized in that to discharge the dust accumulated in the recess to the outside.

According to one embodiment of the present invention, the dust transport device is characterized in that the conveying screw (helix) having a spiral portion of the shape symmetrical to each other outward with respect to the intermediate point.

According to one embodiment of the present invention, between the economizer hopper for collecting the dust falling through the dust transport in the concave of the duct and the lower portion of the concave of the duct collecting the dust discharged through the dust transporter A first gate control unit having a first subhopper and a gate valve for opening or closing the lower end of the first subhopper every predetermined time period is provided.

According to one embodiment of the invention, between the economizer hopper for collecting dust falling through the dust transport in the concave of the duct and the gate valve of the first gate control unit dust discharged through the first subhopper And a second gate control unit having a second subhopper to collect and a gate valve to open or close the lower end of the second subhopper at a predetermined time.

According to an embodiment of the present invention, the first subhopper and the second subhopper are interconnected via a bypass pipe, and the bypass pipe can eliminate the pressure difference between the two subhoppers. Characterized in that the equalizing valve controlled by the control unit is installed.

The present invention installs a screen member on a part of the duct connected to the inlet side of the SCR, and blocks the very light but abnormal large particles accompanying the exhaust gas generated during combustion, so that the catalyst layer of SCR (Selective Catalytic Reduction) It is possible to prevent the blockage by dusts and fine particles in advance, so that the exhaust gas can be smoothly discharged.

In addition, the present invention by installing a screen member on a part of the duct connected to the inlet side of the SCR, blocking the very light or abnormal large particles accompanying the exhaust gas generated during combustion to reduce the output of the combustion system due to clogging of the catalyst layer of the SCR Alternatively, it is possible to prevent incapable of driving.

In addition, the present invention can omit the complicated and low-accuracy exhaust gas flow analysis procedure that has been required in the prior art to simulate the behavior of popcorn ash or large particle ash (LPA).

1 is a schematic block diagram showing an industrial boiler system according to the prior art;
Figure 2 is an overall schematic cross-sectional view showing a screen for preventing dust accumulation of the combustion system according to the present invention.
Figure 3 is an overall schematic view showing the configuration of the screen member, the duct and the subhopper applied to the screen device for preventing dust accumulation of the combustion system according to the present invention.

Hereinafter, an embodiment of the dust accumulation prevention screen device of the combustion system according to the present invention will be described with reference to FIGS. 2 and 3.

Figure 2 is a schematic cross-sectional view showing a screen for preventing dust accumulation of the combustion system according to the present invention, Figure 3 is a configuration of the screen member, ducts and subhoppers applied to the screen for preventing dust accumulation of the combustion system according to the present invention Is a complete schematic diagram.

As shown in FIG. 2, the combustion system to which the screen for preventing dust accumulation of the present invention is applied is connected to a boiler (or an incinerator) through the boiler and the duct 9 and is generated in the combustion process by the boiler. Selective Catalytic Reduction (SCR) 5 for removing NOx in the exhaust gas, and a dust remover for collecting dust accompanying exhaust gas discharged to the stack through the SCR 5 (not shown) It includes.

In addition, the screen for preventing the accumulation of dust 10 is to filter the dust particles, such as popcorn ash (popcorn ash) or LPA (large particle ash) accompanying the exhaust gas discharged from the boiler to the SCR (5) The SCR 5 having a slower flow rate of exhaust gas compared to other portions of the section of the duct 9 connecting the boiler and the SCR 5 (for example, a duct or economizer hopper with a high flow rate of exhaust gas). And a screen member (11) installed at a portion of the inlet side duct (9).

Therefore, the dust accumulation prevention screen device 10 of the present invention configured as described above is the SCR (5) through the screen member 11 installed in the inlet side duct (9) of the SCR (5) from the boiler (not shown) It is possible to filter out the above-mentioned type of dust agglomeration accompanied with the exhaust gas discharged to prevent dust accumulation of the catalyst layer of the SCR (5), and to enable a smooth discharge of the exhaust gas.

In addition, the dust accumulation prevention screen device of the combustion system according to the present invention may be formed in a form that is further limited to the following specific embodiments in the basic configuration as described above.

As shown in FIG. 3, the screen member 11 may include at least one mesh member 11a and a frame member 11b for fixing the mesh member 11a. Each channel cell of the mesh member 11a preferably has the same size as that of the channel cell of the SCR 5 so that dusts smaller than the channel cell of the SCR 5 can easily pass therethrough. When the mesh member 11a is formed in plural as shown in FIG. 3, the plurality of mesh members 11a may be fixed as a single body through the integration member 11c.

In one embodiment, the duct portion in which the screen member 11 is installed connects the boiler and the SCR 5 in a horizontal direction, and the screen member 11 has an upper portion of the exhaust gas of the duct 9. It may be arranged obliquely upstream with respect to the flow cross section.

The horizontal alignment structure of the duct portion in which the screen member 11 is installed as described above mitigates the flow rate and impact of popcorn ash or LPA accompanying the exhaust gas flowing from the boiler to the SCR (5) to the screen member (11). It is possible to reduce the wear of the fan and the loss of the ventilation pressure of the blower fan (not shown) for exhausting the exhaust gas. In addition, the inclined orientation structure of the screen member 11 increases the contact area with the exhaust gas flowing from the boiler (not shown) to the SCR (5) to increase the dust filtering effect, the popcorn ash and the accompanying exhaust gas The LPA makes it easy to fall from the screen member 11 down the duct 9 by its own load.

In one embodiment, the dust accumulation prevention screen device 10 may further include a thruster unit 15 (Rapper unit) to shake off the dust is laminated to the screen member 11 in the duct (9). have. Here, the thrusting unit 15 is coupled to the operating unit 17 is installed to be supported on the duct 9, the output end of the operating unit 17 and at least one rudder to struck the screen member 11 Rod 18. The operation unit 17 may be configured to include an actuator such as a pneumatic cylinder. The thruster unit 15 is controlled to operate every predetermined time to prevent the accumulation of a large amount of dust or more of the mesh size of the screen member on the screen member (11).

In one embodiment, the screen member 11 is composed of at least one mesh member (11a), the frame member (11b) for fixing the mesh member (11a) and the lower side of the screen member (11) the duct ( A concave portion 9a may be further formed at a corresponding portion of 9 to accommodate dust separated and blocked by the screen member 11. In this case, the lower frame member 11b of the screen member 11 is in the recess 9a, for example, so as not to disturb the flow of exhaust gas flowing along the duct 9 toward the SCR 5. It is preferable to be accommodated on one side.

In one embodiment, the concave portion 9a of the duct 9 is further provided with a dust conveyer 21 oriented along the length of the concave portion and the dust conveyer 21 is in the concave portion 9a. The accumulated dust is discharged to the outside. The dust feeder 21 is controlled to be operated every predetermined time so that a large amount of dust does not accumulate in the recess 9a. Here, the dust conveyer 21 is a conveying screw having a spiral portion that is symmetrical to both outer sides with respect to the intermediate point so that the dust accumulated in the recess 9a can be divided and discharged in two directions. It is preferable that it consists of.

In one embodiment, an economizer hopper (not shown) for collecting dust falling through the dust transporter 21 in the recess 9a of the duct 9 and the lower portion of the recess 9a of the duct 9. Between the sides, the first subhopper 22 for collecting the dust discharged through the dust transporter 21, and the gate valve for opening or closing the lower end of the first subhopper 22 at a predetermined time ( A first gate control unit 23 having 23a may be provided.

In another embodiment, an economizer hopper (not shown) which collects dust falling through the dust transporter 21 in the recess 9a of the duct 9 and a gate valve of the first gate control unit 23. A second subhopper 24 for collecting dust discharged through the first subhopper 22 and a gate for opening or closing the lower end of the second subhopper 24 every predetermined time between 23a). A second gate control unit 25 having a valve 25a may be further provided.

On the other hand, when the capacity of the first subhopper 22 is relatively small compared to the discharge of dust per predetermined time discharged from the combustion system, the gate valve 23a of the first gate control unit 23 is opened to open the second. The subhopper 24 can be used.

In another embodiment, the first subhopper 22 and the second subhopper 24 are interconnected via a bypass pipe 26, and the bypass pipe 26 has two subhoppers. An equalizing valve 27 is provided which makes it possible to eliminate the pressure difference between the two and is controlled by a controller (not shown). The equalizing valve 27 prevents dust in the second subhopper 24 from flowing back into the first subhopper 22 due to a pressure difference generated between the two subhoppers. On the other hand, the control unit is preferably made in the form of controlling the overall control of the first and second gate control unit (23, 25) as well as the equalizing valve (27) for the convenience of operation.

In FIG. 2, reference numeral 30 denotes an ammonia injection grid, and the ammonia injection grid 30 injects ammonia into the exhaust gas discharged from the boiler (not shown) to the SCR 5, and primarily discharges the exhaust gas. It converts nitrogen oxides in gas into harmless nitrogen and water. Reference numerals 31 and 31a refer to gas distributors, and each of the gas distributors 31 and 31a functions to induce even discharge of exhaust gas flowing along the inside of the duct 9.

The operation of the dust accumulation prevention screen device of the combustion system configured as described above will be described with reference to FIGS. 2 and 3 as follows.

When combustibles such as coal, diesel, or waste are combusted through a boiler (not shown), the exhaust gas generated from the boiler is guided to the SCR 5 via the screen device 10 for preventing dust accumulation.

At this time, the relatively large dust mass accompanying the exhaust gas is blocked by the screen member 11 of the screen device 10, some of which fall to the bottom in the lower duct 9 of the screen member 11 or The rest sticks to the screen member 11.

As described above, by blocking the dust mass by the screen member 11, the exhaust gas passing through the screen member 11 is guided to the SCR (5) containing only fine dust. Therefore, the catalyst layer of the SCR 5 does not suffer from clogging caused by a relatively large dust mass, thereby enabling smooth exhaust of the exhaust gas.

Nitrogen oxide in the exhaust gas is converted into harmless water and nitrogen through a catalytic reduction reaction while passing through the SCR (5), and waste heat of the exhaust gas is heated through an economizer (not shown) to heat a heat medium such as water.

Thereafter, the dust in the exhaust gas passing through the economizer is collected and removed through a dust remover (not shown), and the purified exhaust gas is discharged to the atmosphere through a stack (not shown).

On the other hand, the screen member 11 is struck through the thrust rod 18 of the thruster 20 at a predetermined time to be able to remove the dust accumulated on the screen member 11, from the screen member 11 Dust accumulated in the recess 9a in the duct 9 can be removed to the outside through the dust transporter 21 at regular intervals.

As shown in FIG. 3, an economizer hopper (not shown) for collecting dust falling through the dust transporter 21 in the recess 9a of the duct 9 and the recess 9a of the duct 9. In the case where a further embodiment including the first subhopper 22 is further applied between the lower portions of), the dusts discharged through the dust transporter 21 are continuously in the first subhopper 22 over time. These dusts can be discharged to the economizer hopper through the opening of the gate valve 23a controlled by the first gate control unit 23 every predetermined time.

In addition, when a further embodiment including a second subhopper 24 is further applied between the economizer hopper (not shown) and the gate valve 23a of the first gate control unit 23, the first subhopper 22 Dust emitted from) may be accumulated in the second subhopper 24. In addition, these dusts can be discharged to the economizer hopper through the opening of the gate valve 25a controlled by the second gate control unit 25 at predetermined time intervals.

At this time, the pressure difference generated between the first subhopper 22 and the second subhopper 24 can be eliminated through the opening of the equalizing valve 27 controlled by a controller (not shown). Dust in the second subhopper 24 is not reversed to the first subhopper 22 side.

The present invention described above is not limited to the above-described embodiments and the accompanying drawings, and simple substitution, modification and alteration within the technical spirit of the present invention will be apparent to those skilled in the art.

5: SCR 9: Duct
9a: recess 10: screen device
11: screen member 11a: mesh member
11b: frame member 11c: integral member
15: chase unit 17: operating part
18: Chutabong 21: Dust Transfer Machine
22: first subhopper 23a, 25a: gate valve
23: first gate control unit 24: second subhopper
25: second gate control unit 26: bypass pipe
27: equalizing valve 30: ammonia injection grid
31,31a: gas distributor

Claims (11)

Selective Catalytic Reduction (SCR) (5) which is connected to a boiler (or incinerator) through the boiler and the duct (9) and removes NOx in the exhaust gas generated during combustion by the boiler; In the combustion system comprising a dust remover for collecting dust accompanying the exhaust gas discharged to the stack through the SCR (5),
Exhaust gas compared to other parts of the section of the duct 9 connecting the boiler and the SCR 5 so as to filter out dust lumps accompanying the exhaust gas discharged from the boiler to the SCR 5. Screen device for preventing dust accumulation of the combustion system, characterized in that the screen member (11) is installed in a portion of the inlet-side duct (9) of the SCR (5) flow rate is slow.
The method of claim 1,
The screen member (11) is composed of at least one mesh member (11a), and the frame member (11b) for fixing the mesh member (11a) of the dust accumulation prevention screen device of the combustion system.
The method of claim 1,
The duct portion in which the screen member 11 is installed connects the boiler and the SCR 5 in a horizontal direction, and the screen member 11 has an upper portion upstream with respect to the exhaust gas flow cross section of the duct 9. Screen unit for preventing dust accumulation of the combustion system is disposed to be inclined to the side.
The method according to claim 1 or 3,
The apparatus for preventing dust accumulation of the combustion system further comprises a chuck unit (15) for shaking off the dust stacked on the screen member (11) in the duct (9).
The method of claim 4, wherein
The thruster unit 15 is coupled to an operating part 17 installed to be supported by the duct 9, and an output end of the operation part 17, and at least one thruster rod for hitting the screen member 11 ( 18) A screen for preventing dust accumulation of a combustion system.
The method of claim 5, wherein
The screen member 11 is composed of at least one mesh member 11a and a frame member 11b for fixing the mesh member 11a and corresponding to the lower side of the screen member 11 of the duct 9. The recessed portion 9a is further formed in the portion so as to accommodate the dust that is blocked by the screen member 11 and the lower frame member 11b of the screen member 11 is in the recessed portion 9a. A screen device for preventing dust accumulation of a combustion system that is accommodated.
The method according to claim 6,
In the concave portion 9a of the duct 9, there is further provided a dust conveyer 21 which is oriented along the length of the concave portion, and the dust conveyer 21 carries dust accumulated in the concave portion 9a to the outside. Screen for preventing dust accumulation of the combustion system to discharge.
The method of claim 7, wherein
The dust transfer device (21) is a screening device for preventing dust accumulation of the combustion system is a conveying screw having a spiral portion of the shape symmetrical to each other outward about the intermediate point.
The method of claim 7, wherein
The dust transporter 21 between the economizer hopper collecting dust falling through the dust transporter 21 in the recess 9a of the duct 9 and the lower side of the recess 9a of the duct 9. The first gate control unit having a first subhopper (22) for collecting dust discharged through the) and a gate valve (23a) for opening or closing the lower end of the first subhopper 22 at predetermined time intervals. A screen device for preventing dust accumulation of a combustion system, wherein 23 is provided.
The method of claim 9,
The first subhopper is located between the economizer hopper collecting dust falling through the dust transporter 21 in the recess 9a of the duct 9 and the gate valve 23a of the first gate control unit 23. A second gate having a second subhopper 24 for collecting dust discharged through the 22 and a gate valve 25a for opening or closing the lower end of the second subhopper 24 at a predetermined time; Screen unit for preventing dust accumulation of the combustion system further provided with a control unit (25).
The method of claim 10,
The first subhopper 22 and the second subhopper 24 are connected to each other via a bypass pipe 26, and the bypass pipe 26 can eliminate the pressure difference between the two subhoppers. And an equalizing valve (27) which is controlled by a control unit.

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