KR102637989B1 - Sacrifying Filter for Purification of Combustion Gas - Google Patents

Abstract

The sacrificial filter for purifying combustion gas of the present invention is installed in the flue (1) to purify the combustion gas discharged from the flue (1) and stops the filtration function when the life of the filter expires to ensure air flow. As a filter, it is located at the upper part of the exhaust gas outlet (2) provided on the circular arc surface on one side of the lower part of the flue (1) and is installed inside the flue (1) perpendicular to the longitudinal direction of the flue (1) to exhaust the exhaust gas. Left and right semicircular dust collectors (10) that filter the exhaust gas discharged from the gas outlet (2) and divide the flue (1) in half in the diametric direction, dividing the left and right sides respectively to filter the exhaust gas; A hinge coupling that connects the central portions of the left and right semicircular dust collection units 10 to each other and allows the left and right semicircular dust collection units 10 to be folded downward to secure air flow by stopping the filtration function of the left and right semicircular dust collection units 10. Wealth (20); It is characterized in that it includes a hinge coupling portion support portion 30 that supports the left and right semicircular dust collecting portions 10 and prevents the left and right semicircular dust collecting portions 10 from lowering.

Description

Sacrificial Filter for Purification of Combustion Gas}

The present invention is installed in a structure such as a stack where it is difficult to replace the filter after installation, and when the filtering function is lost and the air flow becomes difficult, the filter function is stopped to facilitate the flow of air. It is about a sacrificial filter for gas purification.

In order to maximize the plant output and efficiency of gas turbine power generation, combined cycle power plants flow the high-temperature exhaust gas discharged from the gas turbine into a heat recovery steam generator (HRSG) and use it as a heat source to generate high-temperature and high-pressure steam.

The high-temperature, high-pressure steam generated at this time drives a steam turbine and a generator to generate power.

A combined cycle power plant consists of a gas turbine, a heat recovery boiler with a high-pressure evaporator, a medium-pressure evaporator, and a low-pressure evaporator, and a steam turbine.

The power generation method generates primary power by operating a gas turbine, then recovers the discharged high temperature exhaust gas of about 620 ℃ in a heat recovery boiler and uses the recovered heat to produce steam suitable for steam turbine power generation, thereby improving thermal efficiency. It's a way to raise it.

A heat recovery boiler is a type of boiler that uses high-temperature combustion gas discharged from a gas turbine to generate high-temperature, high-pressure steam and is used as steam to drive a steam turbine or for industrial processes.

The fin tube, which is the main cooling equipment of this heat recovery boiler, uses carbon steel as its main material. However, such carbon steel has the property of being easily oxidized at high temperatures, so its surface tends to corrode and oxides (rust, etc.) are easily generated.

These oxides reduce the heat exchange effect and must be removed periodically. Air blowing or CO2 blasting is used to remove these oxides.

However, upon initial startup after removing the oxide, a large amount of excess corrosive matter that falls off the fin tube is discharged into the atmosphere through the chimney, and in some workplaces, red-colored iron oxide particles are actually emitted, causing environmental pollution and civil complaints. there was.

Such combined cycle power plants, etc. are equipped with stacks for discharging iron oxides or harmful substances contained in combustion gases, and a combustion system is used to allow combustion gases to flow into or into the stack to purify iron oxides or harmful substances. A filter is provided at the gas inlet to purify the combustion gas.

Typically, a pre-filter may be provided to purify iron oxides or initial harmful substances, and a main filter may be provided to purify combustion gas primarily purified by the pre-filter.

At this time, the pre-filter for purifying the initial combustion gas filters iron oxides or initial harmful substances, and when it becomes clogged by these and loses its filtering function, it interferes with the air flow and must be replaced. However, it is difficult to replace the filter in the flue. Structures such as (stack) have the problem of not being easy to exchange.

Therefore, even if the filter's function is lost due to the end of its life, measures to ensure air flow are urgently needed.

The present invention was created to solve the above problems, and the purpose of the present invention is to provide a sacrificial filter for purifying combustion gases with a simple structure to ensure air flow by stopping the filtering function when the filter loses its function due to the end of its life. is to provide.

In addition, another object of the present invention is to provide a sacrificial filter for purifying combustion gas that has a multi-layer structure and can collect not only iron oxides but also dust if necessary.

The sacrificial filter for purifying combustion gas of the present invention to achieve the above object is installed in the flue (1), purifies the combustion gas discharged from the flue (1), and stops the filtration function when the life of the filter expires to prevent air flow. As a sacrificial filter for purifying combustion gas, it is located at the upper part of the exhaust gas outlet (2) provided on the arcuate surface of one side of the lower part of the flue (1) and is perpendicular to the longitudinal direction of the flue (1). Left and right semicircular dust collectors (10) installed on the inside to filter the exhaust gas discharged from the exhaust gas outlet (2), dividing the flue (1) in half in the diametric direction and dividing the left and right sides respectively to filter the exhaust gas; A hinge coupling that connects the central portions of the left and right semicircular dust collection units 10 to each other and allows the left and right semicircular dust collection units 10 to be folded downward to secure air flow by stopping the filtration function of the left and right semicircular dust collection units 10. Wealth (20); It is characterized in that it includes a hinge coupling portion support portion 30 that supports the left and right semicircular dust collecting portions 10 and prevents the left and right semicircular dust collecting portions 10 from lowering.

In addition, the left and right semicircular dust collecting parts 10 are maintained horizontally in an unfolded state, and the left and right semicircular dust collecting part support and release parts 40 are characterized in that they further include.

In addition, the left and right semicircular dust collecting parts 10 couple the middle portions of the arcuate portions of the left and right semicircular dust collecting parts 10 to each other when the lower portions of the left and right semicircular dust collecting parts 10 are folded, and the left and right semicircular dust collecting parts 10 are folded downward. It is characterized in that it is further provided with a folding holding part 50 that maintains the folded state.

In addition, the left and right semicircular dust collection units 10 are characterized in that they are arranged in multiple layers and spaced apart at a certain distance.

In addition, the left and right semicircular dust collection units 10 include a frame that forms a semicircular outline to form a semicircular hollow part, and an outline fixed to the frame to close the hollow part, thereby filtering oxides contained in the exhaust gas passing through. It is characterized by consisting of a filter part.

Additionally, the filter unit may be in a flat plate shape or may have a repetitive valley shape in the width direction.

The sacrificial filter for purifying combustion gas of the present invention with the above configuration can not only remove iron oxides emitted during initial operation in industrial facilities such as thermal power plants, but also can remove iron oxides from the filter after initial operation with low generation of iron oxides. It has the advantage of smoothing the flow of exhaust gas by being folded without performing a function, thereby eliminating pressure differential factors. In addition, iron oxides are removed during initial operation when a lot of iron oxides are generated and folded after initial operation when iron oxides are generated less, so it is possible to protect and extend the life of the main oxide filter that can be installed on the upper part of the sacrificial filter. There is an advantage. In addition, since the main purpose is to remove iron oxides, which are emitted in large quantities during initial operation, an inexpensive filter with a low MERV rating can be used, which not only saves the price, but also adopts a method of folding by gravity, so the structure is simple and installation costs are low. It has the advantage of being cheap.

Figure 1 is a diagram showing the schematic structure of a heat recovery boiler.
Figure 2 is a diagram showing the communication of an heat recovery boiler.
Figure 3 is a diagram showing the internal structure of the flue of the heat recovery boiler.
Figure 4 is a perspective view showing a sacrificial filter for purifying combustion gas according to the present invention.
Figures 5 to 7 are diagrams showing the operating state of the sacrificial filter for purifying combustion gas according to the present invention.
Figure 8 is a perspective view showing another type of sacrificial filter for purifying combustion gas according to the present invention.
9 and 10 are diagrams showing the operating state of another type of sacrificial filter for purifying combustion gas according to the present invention.

Hereinafter, the sacrificial filter for purifying combustion gas according to the present invention will be described in detail with reference to the drawings.

Figure 1 is a diagram showing the schematic structure of the heat recovery boiler, Figure 2 is a diagram showing the flue of the heat recovery boiler, Figure 3 is a diagram showing the internal structure of the flue of the heat recovery boiler, and Figure 4 is a diagram showing the combustion according to the present invention. It is a perspective view showing a sacrificial filter for purifying gas, Figures 5 to 7 are diagrams showing the operating state of the sacrificial filter for purifying combustion gas according to the present invention, and Figure 8 is a perspective view showing another type of sacrificial filter for purifying combustion gas according to the present invention. 9 and 10 are diagrams showing the operating state of another type of sacrificial filter for purifying combustion gas according to the present invention.

The sacrificial filter for purifying combustion gas according to the present invention is installed in the flue and serves to purify the combustion gas discharged from the flue.

When the sacrificial filter for purifying combustion gas of the present invention is used in a heat recovery boiler, the heat transfer tube and fin of a heat recovery boiler (HRSG) (see FIG. 1) that recovers heat by exchanging heat with the high temperature gas discharged by operating a gas turbine It is installed in the flue (1), which discharges the contact exhaust gas to the outside after contact with the exhaust gas, and collects iron oxides contained in the exhaust gas during initial operation and discharges the exhaust gas from which the oxides have been removed to the outside of the flue (1). , Ensure air flow after initial operation.

An exhaust gas outlet 2 is provided on one side of the arcuate surface of the lower portion of the flue 1, and a plurality of windows are provided spaced apart in a row (see Figure 2).

The sacrificial filter for purifying combustion gas according to the present invention is located at the upper part of the exhaust gas outlet (2) provided on the arcuate surface of one side of the lower part of the flue (1) and removes iron oxides contained in the exhaust gas discharged to the flue (1). It becomes a dust collection.

As shown in Figures 4 to 10, the sacrificial filter for purifying combustion gas according to the present invention includes left and right semicircular dust collection parts (10); Hinge joint (20); It includes a hinge joint support portion (30).

The left and right semicircular dust collectors 10 are located at the upper part of the exhaust gas outlet 2 provided on one side of the arcuate surface of the lower part of the flue 1 and are located inside the flue 1 in the longitudinal direction of the flue 1. It is installed vertically and horizontally and serves to filter the exhaust gas discharged from the exhaust gas outlet (2). At this time, the left and right semicircular dust collection parts 10 divide the communication pipe 1 in half in the radial direction, dividing the left and right sides respectively, and filtering the exhaust gas.

The hinge coupling portion 20 connects the central portions of the left and right semicircular dust collecting portions 10 to each other and stops the filtration function of the left and right semicircular dust collecting portions 10 to move the left and right semicircular dust collecting portions 10 downward to secure air flow. It is hinged so that it can be folded.

The hinge coupling portion support portion 30 supports the hinge coupling portion 20 to prevent the hinge coupling portion 20 from descending, and the left and right semicircular dust collection portions are hinged by the hinge coupling portion 20 ( 10) serves to prevent it from descending.

In the sacrificial filter for purifying combustion gases according to the present invention, which has the structure described above, the left and right semicircular dust collection parts 10 collect iron oxides during initial operation, and perform the function of a filter after initial operation with little iron oxide generation. By being folded instead of folded, the differential pressure factor is eliminated, allowing smooth flow of exhaust gas.

Not only can iron oxides emitted during initial operation in industrial facilities such as thermal power plants be removed, but after initial operation with low generation of iron oxides, the left and right semicircular dust collectors 10 do not perform the function of a filter and are hinged together. There is an advantage in that the flow of exhaust gas is smoothed by being folded by the portion 20 and the differential pressure factor is eliminated. In addition, iron oxides are removed during initial operation when a lot of iron oxides are generated and folded after initial operation when iron oxides are generated less, so it is possible to protect and extend the life of the main oxide filter that can be installed on the upper part of the sacrificial filter. There is an advantage. In addition, since the main purpose is to remove iron oxides, which are emitted in large quantities during initial operation, an inexpensive filter with a low MERV rating can be used, which not only saves the price, but also adopts a method of folding by gravity, so the structure is simple and installation costs are low. It has the advantage of being cheap.

The upper part of the left and right semicircular dust collection units 10 collects exhaust gas collected by the left and right semicircular dust collection units 10 during initial operation and exhaust gas flowing upward when the left and right semicircular dust collection units 10 are folded after initial operation. A main filter 4 (see FIG. 3) may be provided for.

The diameter of the left and right semicircular dust collection units 10 is slightly smaller than the inner diameter of the communication pipe 1, and packing or brushes are provided on the outer periphery of the left and right semicircular dust collection units 10, so that the outer periphery of the left and right semicircular dust collection units 10 is provided. It is desirable to seal the space between the inner periphery of the communication pipe (1).

The upper part of the flue (1) is provided with a damper (3) that opens and closes according to the amount of exhaust gas discharged to discharge the exhaust gas.

The left and right semicircular dust collection parts 10 are located between the dampers 3 at the upper part of the exhaust gas outlet 2 provided on one side of the arcuate surface of the lower part of the flue 1 (see FIG. 3) to collect the exhaust gas outlet ( 2) Make sure to filter the exhaust gas discharged from the device.

The hinge coupling portion support portion 30 may be installed from the bottom of the communication pipe 1 to the top to be in the form of a pillar supporting the center of the hinge coupling portion 20, and is located at the lower ends of both ends of the hinge coupling portion 20. It may be provided on the inner periphery of the communication pipe (1) in the form of a support jaw for supporting.

In the drawing, the hinge joint support portion 30 is shown in a column shape.

It serves to support the hinge coupling part 20 and prevent the left and right semicircular dust collecting parts 10 hinged by the hinge coupling part 20 from descending.

In addition, the present invention supports and releases the left and right semicircular dust collection parts 10 to keep them horizontal in an unfolded state or to release the left and right semicircular dust collection parts 10 from being supported so that the left and right semicircular dust collection parts 10 are folded. It is desirable to further include a unit 40.

During the initial operation, the left and right semicircular dust collection parts 10 are supported and the left and right semicircular dust collection parts 10 are spread out and maintained horizontally, so that iron oxides are collected by the left and right semicircular dust collection parts 10. After the initial drive, the left and right semicircular dust collection parts 10 are maintained horizontally. By releasing the support of the left and right semicircular dust collecting parts 10, the left and right semicircular dust collecting parts 10 do not play the role of a filter and serve to fold the left and right semicircular dust collecting parts 10 by gravity.

The left and right semicircular dust collection part support and release parts 40 may have various shapes. An example of the left and right semicircular dust collection part support and release parts 40 may be in the form of a piston and a cylinder that allows the piston to slide.

By the withdrawal of the piston, the lower part of the middle part of the arcuate part of the left and right semicircular dust collection parts 10 is supported to maintain the left and right semicircular dust collection parts 10 horizontal in an unfolded state, and by the retraction of the piston, the left and right semicircular dust collection parts 10 are maintained horizontally. By unlocking the lower part of the middle part of the circular arc, the left and right semicircular dust collecting parts 10 do not play the role of a filter and the left and right semicircular dust collecting parts 10 are folded by gravity.

In addition, the left and right semicircular dust collecting parts 10 of the present invention connect the middle portions of the arc portions of the left and right semicircular dust collecting parts 10 to each other when the lower portions of the left and right semicircular dust collecting parts 10 are folded. It is preferable that a folding holding part 50 is further provided to maintain the folded state in the lower part.

Since the folding holding portion 50 maintains the left and right semicircular dust collection portions 10 folded downward, it does not unfold when exhaust gas is discharged through the flue 1 and is attached to the left and right semicircular dust collecting portions 10. By eliminating the differential pressure factor, the flow of exhaust gas can be smoothened.

The folding holding portion 50 may have various forms. An example of the folding holding portion 50 may include a magnet, and another example may include a protrusion 51 on one semicircular dust collecting portion 10. And the other semicircular dust collecting part 10 is provided with a protrusion coupling part 52 so that they are coupled together, so that the left and right semicircular dust collecting parts 10 can be maintained in a downwardly folded state.

In the drawing, the folding holding portion 50 is shown to be composed of a protrusion 51 and a protrusion coupling portion 52.

In the state shown in FIG. 5, the left and right semicircular dust collection parts 10 are supported in an unfolded state within the communication pipe 1 by the left and right semicircular dust collection part support and release parts 40. In this state, when the left and right semicircular dust collection parts 10 supported by the left and right semicircular dust collection part support and release parts 40 are released, the left and right semicircular dust collection parts 10 are folded through the state of FIG. 6 by their own weight. It becomes a state of 7.

In addition, in the present invention, the left and right semicircular dust collecting parts 10 may be provided as a single layer as shown in FIGS. 4 to 7, or may be provided as a multi-layer spaced apart by a certain distance as shown in FIGS. 8 to 10.

If the left and right semicircular dust collection units 10 are provided in multiple layers at a certain distance apart, the dust collection efficiency of iron oxide can be improved during initial operation.

8 to 10 show that the left and right semicircular dust collection units 10 are provided in two layers.

When the left and right semicircular dust collection units 10 are separated by a certain distance and are provided in two layers, each of the left and right semicircular dust collection units 10 is folded after iron oxide dust collection. When the length of the flue 1 is long, the left and right semicircular dust collection units 10 are separated from each other by a certain distance. (10) can be spaced apart by a length longer than the folding length, so this is not a problem. However, when the length of the flue (1) is short and the left and right semicircular dust collection parts 10 are provided in multiple layers, the left and right semicircular dust collection parts located on the upper and lower layers When (10) is folded, the left and right semicircular dust collection parts (10) located on the upper and lower layers inevitably overlap when folded.

In order to maintain the folded state when the left and right semicircular dust collection parts 10 located on the upper and lower layers are folded, the left and right semicircular dust collecting parts 10 located on the lower layer are positioned on the upper layer more than the width of the hinge coupling portion 20. The width of the hinge coupling part 20 of the semicircular dust collection part 10 is made wider. In this case, when the left and right semicircular dust collection units 10 located on the lower floor are folded and the left and right semicircular dust collecting units 10 located on the upper floor are folded, the left and right semicircular dust collecting units 10 located on the upper floor are folded. It is folded in a form that surrounds a part of (10) to facilitate the flow of exhaust gas.

At this time, as in the case where the folding holding part 50 is provided with one left and right semicircular dust collecting part 10, the left and right semicircular dust collecting parts 10 located in the lower layer include a left semicircular dust collecting part 10 and a right semicircular dust collecting part 10. ) so that the left and right semicircular dust collection parts 10 located on the lower layer can maintain a folded state when folded, and the folding holding parts 50 located on the upper layer are provided at the bottom of the left and right semicircular dust collecting parts 10 located on the upper layer. The left semicircular dust collection part 10 and the right semicircular dust collection part 10 of (10) each have protrusions at the bottom, and the left semicircular dust collection part 10 and the right semicircular dust collection part 10 of the left and right semicircular dust collection parts 10 located in the lower layer. The upper part of the protrusion is provided with protrusion coupling parts to which the protrusions are coupled, so that when the left and right semicircular dust collection parts 10 located on the upper layer are folded, they are fixed to the left and right semicircular dust collecting parts 10 located on the lower layer, so that they can be maintained in a folded state. .

In the state shown in FIG. 9, the left and right semicircular dust collection parts 10, which are made up of two layers, are supported in an unfolded state within the communication pipe 1 by the left and right semicircular dust collection part support and release parts 40. In this state, iron oxides are collected by the left and right semicircular dust collection parts 10 located in the lower layer, but their lifespan expires, and the left and right semicircular dust collecting parts located in the lower layer are supported by the left and right semicircular dust collecting parts 10 and the release parts 40 (40). When 10) is released, as in FIG. 7, the left and right semicircular dust collection parts 10 located in the lower layer are folded by their own weight and iron oxide is collected by the left and right semicircular dust collecting parts 10 located in the upper layer. Iron oxide is collected in this state, and after the initial operation, the left and right semicircular dust collection parts 10 located on the upper layer supported by the left and right semicircular dust collection part support and release parts 40 located on the upper layer are released, and the left and right semicircular dust collection parts 10 located on the upper layer are released. 10 in which both the left and right semicircular dust collection parts 10 are folded, the pressure difference factor caused by the left and right semicircular dust collection parts 10 is eliminated, thereby allowing smooth flow of exhaust gas.

In addition, the left and right semicircular dust collection units 10 of the present invention have a pressure drop that lowers the pressure to prevent the dust collection filters of the left and right semicircular dust collection units 10 from being damaged when the rising pressure applied to the left and right semicircular dust collection units 10 is excessive. A damper (not shown) may be provided.

The pressure drop damper is supported by a spring and remains closed when the rising pressure applied to the left and right semicircular dust collection parts 10 is less than a certain pressure, and when the rising pressure applied to the left and right semicircular dust collecting parts 10 exceeds a certain pressure. When the elastic force of the spring becomes greater than that of the spring, it opens upward to reduce the upward pressure applied to the left and right semicircular dust collecting parts 10.

The left and right semicircular dust collection units 10 have a frame forming a semicircular outline to form a semicircular hollow part, and an outline is fixed to the frame to close the hollow part, so as to filter oxides contained in the exhaust gas passing through the filter part. It can be.

The filter unit may be provided in a semicircular shape by combining a plurality of grid-type filters.

In addition, the filter part is preferably composed of a non-woven filter part that purifies the passing exhaust gas, and a mesh reinforcement part made of a metal material located in contact with the rear of the non-woven filter part and reinforcing the strength of the non-woven filter part.

By reinforcing the strength of the non-woven filter part by the mesh reinforcement part, the strength of the non-woven filter part can be increased and tearing or damage can be reduced.

The non-woven filter part and the mesh reinforcement part may have a flat shape and may have a repetitive valley shape in the width direction.

When the non-woven filter portion and the mesh reinforcing portion have a repetitive valley shape in the width direction, the strength of the non-woven filter portion and the mesh reinforcing portion is greater than when the non-woven filter portion and the mesh reinforcing portion are flat, thereby further reducing tearing or damage, The contact area of the non-woven filter unit increases, thereby improving dust collection efficiency.

It is preferable that the non-woven filter part (31b) of the left and right semicircular dust collection parts (10) of the present invention has increasingly higher air permeability from one side closer to the exhaust gas outlet (2) of the communication pipe (1) to the other side.

The exhaust gas that has passed through the exhaust gas outlet (2) of the flue (1) moves upward. At this time, the pressure is relatively low on the side close to the exhaust gas outlet (2) of the flue (1) and the flue ( The pressure becomes relatively high on the side far from the exhaust gas outlet (2) of 1).

Therefore, when the ventilation rate increases gradually from one side close to the exhaust gas outlet 2 of the flue 1 to the other side, the pressure applied to the left and right semicircular dust collection parts 10 becomes the same, thereby causing the left and right semicircular dust collection parts 10 to This allows for smooth dust collection.

In addition, the non-woven filter part of the left and right semicircular dust collection parts 10 of the present invention is preferably thicker from one side close to the exhaust gas outlet 2 of the flue 1 to the other side.

As the thickness of the non-woven filter portion of the left and right semicircular dust collecting portions 10 becomes thicker from one side close to the exhaust gas outlet 2 of the flue pipe 1 to the other side, the nonwoven filter portions of the left and right semicircular dust collecting portions 10 become thicker. It is possible to reduce damage to the non-woven filter unit due to pressure applied to the.

In addition, in the present invention, a plurality of vibrators (not shown) may be provided on the upper part of the left and right semicircular dust collection units 10 to remove oxides laminated on the nonwoven filter unit by vibration.

The technical idea of the present invention should not be interpreted as limited to the above-described embodiments. Not only is the scope of application diverse, but various modifications can be made at the level of those skilled in the art without departing from the gist of the present invention as claimed in the claims. Therefore, such improvements and changes fall within the scope of protection of the present invention as long as they are obvious to those skilled in the art.

1: flue 2: exhaust gas outlet
10: left and right semicircular dust collection parts 20: hinge joint part
30: Hinge joint support part 40: Left and right semicircular dust collection part support and release part
50: folding holding part 51: protruding part
52: Protrusion coupling part

Claims (7)

A sacrificial filter for purifying combustion gas that is installed in the flue (1) to purify the combustion gas discharged from the flue (1) and to secure air flow by stopping the filtration function when the life of the filter expires.
It is located at the upper part of the exhaust gas outlet (2) provided on the arcuate surface of one side of the lower part of the flue (1) and is installed inside the flue (1) perpendicular to the longitudinal direction of the flue (1), so that the exhaust gas outlet (2) ) Filtering the exhaust gas discharged from the flue (1), dividing the flue (1) in half in the diametric direction and dividing the left and right sides respectively, left and right semicircular dust collectors (10) for filtering the exhaust gas;
A hinge coupling connects the central portions of the left and right semicircular dust collection units 10 to each other and allows the left and right semicircular dust collection units 10 to be folded downward to secure air flow by stopping the filtration function of the left and right semicircular dust collection units 10. Wealth (20);
A sacrificial filter for purifying combustion gas, comprising a hinge joint support portion (30) that supports the left and right semicircular dust collecting portions (10) and prevents the left and right semicircular dust collecting portions (10) from descending. According to claim 1,
A sacrificial filter for purifying combustion gas, comprising a left and right semicircular dust collection part support and release part (40) that allows the left and right semicircular dust collection parts (10) to remain horizontal in an unfolded state. The method of claim 1, wherein the left and right semicircular dust collection units (10) are,
When the lower portions of the left and right semicircular dust collecting portions 10 are folded, the middle portions of the arcuate portions of the left and right semicircular dust collecting portions 10 are coupled to each other and a folding holding portion 50 that maintains the left and right semicircular dust collecting portions 10 folded downward. ); A sacrificial filter for purifying combustion gas, characterized in that it is further provided with. According to claim 1,
A sacrificial filter for purifying combustion gas, characterized in that the left and right semicircular dust collection parts (10) are arranged in multiple layers spaced apart at a certain distance. The method of claim 1, wherein the left and right semicircular dust collection units (10) are,
A sacrificial device for purifying combustion gases, comprising a frame forming a semicircular outline to form a semicircular hollow part, and a filter part having an outline fixed to the frame to close the hollow part and filtering out oxides contained in passing exhaust gas. filter. According to claim 5,
A sacrificial filter for purifying combustion gas, characterized in that the filter part is in a flat shape. According to claim 5,
A sacrificial filter for combustion gas purification, wherein the filter portion has a repetitive valley shape in the width direction.

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