KR102598983B1 - A Fixed type extended vane filter for wet scrubber - Google Patents

Abstract

The present invention relates to a filter applied to a wet scrubber, and more specifically, by generating a flow that rotates along the surface while contacting the surface of a plurality of fixed wings using the inflow flow of gas, etc. flowing from the inside of the case, It increases the contact efficiency between the purified gas and the washing water and increases the sludge discharge efficiency by centrifugal force. In particular, rather than the existing mesh-shaped porous filter structure, the flat plate of the wing extends from the front to the back with respect to the central axis, creating a streamlined curved surface. It is formed to achieve a smooth discharge of sludge by generating a rotating flow while the incoming purification target gas and cleaning water are in contact with the plate. In addition, the outer end of the wing surface is continuous without being separated from the case part. A fixed extension for a wet scrubber that minimizes the space (a type of 'dead space') where purification target gas and cleaning water flowing into the case part pass through without contacting the wing part through a planar structure combined with the case part. It's about vane filters.

Description

Fixed type extended vane filter for wet scrubber {A Fixed type extended vane filter for wet scrubber}

The present invention relates to a filter applied to a wet scrubber, and more specifically, by generating a flow that rotates along the surface while contacting the surface of a plurality of fixed wings using the inflow flow of gas, etc. flowing from the inside of the case, It increases the contact efficiency between the purified gas and the washing water and increases the sludge discharge efficiency by centrifugal force. In particular, rather than the existing mesh-shaped porous filter structure, the flat plate of the wing extends from the front to the back with respect to the central axis, creating a streamlined curved surface. It is formed to achieve a smooth discharge of sludge by generating a rotating flow while the incoming purification target gas and cleaning water are in contact with the plate. In addition, the outer end of the wing surface is continuous without being separated from the case part. A fixed extension for a wet scrubber that minimizes the space (a type of 'dead space') where purification target gas and cleaning water flowing into the case part pass through without contacting the wing part through a planar structure combined with the case part. It's about vane filters.

In general, wet scrubbers are the most common atmospheric equipment that have been used for decades to purify gas. As the time between gas and liquid droplets increases, the amount of substances in the gas absorbed or collided increases, ultimately increasing the removal efficiency. Gas-liquid contact devices use objects with a large specific surface area in various ways. In addition, when removing a substance with high water solubility depending on the type of substance, adding a neutralizing agent to the washing water in advance can increase the removal efficiency and reduce the construction cost of the device.

At this time, in order to efficiently remove various odors and harmful compounds contained in the gas, it was necessary to secure sufficient contact time between the gas and liquid within the filter. To this end, a filter was formed by stacking a number of plate-shaped bodies as shown in the patent document below. It is universal.

<Patent Document> Registered Patent No. 10-1685874 (announced on December 13, 2016) “Porous filter and filter case for wet scrubber”

The prior art disclosed in the above <patent document> is also a shape in which a pair of plate-shaped bodies are assembled into a plurality of connected bodies to cross each other with ventilation holes of a certain shape, which induces a change in air flow and an increase in specific surface area, thereby causing physical adsorption and This is to ensure that chemical absorption occurs simultaneously.

However, in this existing filter structure in which mesh-shaped pieces are cross-laminated, the rate at which the differential pressure rises rapidly increases during actual operation due to blockage caused by sludge adhering and accumulating between the grids, making it necessary to clean the filter periodically. Cleaning cycles are shortened, resulting in a serious increase in operational risks and operating costs.

Accordingly, there is an increasing need for a new type of filter structure that can reduce operating and maintenance costs by solving problems of blockage caused by sludge or increased differential pressure while maintaining the same or improved filter function.

The present invention was devised to solve the above problems,

The purpose of the present invention is to generate a flow that rotates along the surface while contacting the surface of a plurality of fixed wings using the inflow flow of gas flowing from the inside of the case, thereby increasing the contact efficiency between the gas to be purified and the cleaning water. To provide a fixed expansion vane filter for a wet scrubber that increases sludge discharge efficiency by centrifugal force.

Another object of the present invention is that, rather than the existing mesh-shaped porous filter structure, the flat plate of the wing portion is formed to form a streamlined curved surface while extending from the front to the back with respect to the central axis, so that the inflow gas to be purified and the washing water are formed into a flat plate. Sludge can be discharged smoothly by generating a rotating flow while in contact with the surface. In particular, the outer end of the wing surface is continuously connected to the case part without being separated from the case part, so that the planar structure allows sludge to be discharged into the case part. The aim is to provide a fixed expansion vane filter for a wet scrubber that minimizes the space (a type of 'dead space') where incoming purified gas and washing water pass through without contacting the wings.

Another object of the present invention is to support and protect the start and end edges of the plate connecting the central axis and the case part of the wing part on the front side where the gas to be purified and the cleaning water flow from the case part and the back surface on the opposite side, respectively. Durability is increased by including a support structure, and a plurality of ventilation holes are formed on the upper, lower, left, and right sides so that sludge can be easily discharged through centrifugal force caused by the flow along the plurality of wings, thereby discharging sludge and cleaning the filter. The aim is to provide a fixed expansion vane filter for a wet scrubber that can facilitate.

Another object of the present invention is to form 4 to 12 wing parts so that the starting edge of the plate located on the front of the case portion and the end edge of the plate located on the back of the case portion are oriented 90 degrees to 360 degrees. A fixed type for wet scrubber that is arranged at equal intervals along the circumference of the case inside the case, thereby increasing the contact efficiency of the incoming purified gas and washing water with the wing surface while minimizing the increase in differential pressure due to the plurality of wings. It provides an extended vane filter.

In order to achieve the above-described object, the present invention is implemented by an embodiment having the following configuration.

According to one embodiment of the present invention, a fixed expansion vane filter for a wet scrubber according to the present invention includes a case portion accommodating a filter module therein; and a filter module accommodated inside the case unit to increase the efficiency of contact between the gas to be purified and the washing water, wherein the filter module is fixed inside the case unit and filters the gas to be purified and the washing water flowing in from the front. It includes a plurality of wings extending from the front to the back to guide the flow and forming a streamlined curved surface, which increases the contact efficiency between the gas to be purified and the washing water and increases the sludge discharge efficiency by centrifugal force.

According to another embodiment of the present invention, in the present invention, the filter module has a central axis formed in the central portion of the case portion, one end of a plate is coupled to the central axis and the other end is connected to the case portion, and the gas to be purified and a plurality of wings that are formed to form a streamlined curved surface while sloping from the front, where the washing water flows, to the back.

According to another embodiment of the present invention, in the present invention, the wing part is combined with the case part to minimize the space where the gas to be purified and the cleaning water flowing into the case part pass without contacting the wing part. The other end of the wing surface is characterized in that it is continuously coupled to the case portion without being separated from the case portion.

According to another embodiment of the present invention, in the present invention, the case part has a front surface where the gas to be purified and washing water flows in, and a back surface opposite to the starting edge and end of a plate connecting the central axis of the wing part and the case part. It is characterized by including a support structure that supports and protects each corner of the part.

According to another embodiment of the present invention, in the present invention, the case part is provided on the upper, lower, left, and right sides so that sludge can be easily discharged through the centrifugal force of the gas and washing water flows flowing through the plurality of wings. It is characterized in that a plurality of ventilation holes are formed to increase the convenience of cleaning work.

According to another embodiment of the present invention, in the present invention, in the wing portion, the starting edge of the plate located on the front of the case portion and the distal edge of the plate located on the back of the case portion are angled in a direction of 90 degrees to 360 degrees. The streamlined curved surface forming the wing portion is characterized in that the inclination of the curved surface is formed toward the case portion so that centrifugal force is generated in the process of flowing purification target gas and cleaning water flowing backward along the wing portion curved surface. .

According to another embodiment of the present invention, in the present invention, the wing portion includes 4 to 12 wing portions each inside the case portion, and the starting edge of each plate of the plurality of wing portions is formed around the case portion of a rectangular cross-section. By being arranged at equal intervals along the , the contact efficiency of the incoming purification target gas and cleaning water with the wing surface is increased while minimizing the increase in differential pressure due to the plurality of wing parts.

The present invention can achieve the following effects by combining the above-mentioned embodiment with the configuration, combination, and use relationship described below.

The present invention uses the inflow of gas flowing from the inside of the case to generate a flow that rotates along the surface while contacting the surface of a plurality of fixed wings, thereby increasing the contact efficiency between the gas to be purified and cleaning water and reducing centrifugal force. It has the effect of increasing sludge discharge efficiency.

In the present invention, rather than the existing mesh-shaped porous filter structure, the flat plate of the wing portion is formed to form a streamlined curved surface while extending from the front to the back with respect to the central axis, so that the incoming purification target gas and the washing water are in contact with the plate while By generating a rotating flow, sludge can be discharged smoothly. In particular, the outer end of the wing surface is continuously connected to the case part without being separated from the case part, so the planar structure allows purification to flow into the case part. It has the effect of minimizing the space where the target gas and cleaning water pass through without contacting the wing (a type of 'dead space').

The present invention provides a support structure that supports and protects the starting edge and the end edge of the plate connecting the central axis and the case part in the wing part on the front side where the gas to be purified and the cleaning water flow from the case part and the back surface on the opposite side. It increases durability, and forms multiple ventilation holes on the top, bottom, left, and right sides so that sludge can be easily discharged through centrifugal force caused by the flow flowing along the plurality of wings, thereby facilitating sludge discharge and cleaning of the filter. It has a possible effect.

In the present invention, the starting edge of the plate located on the front of the case portion and the end edge of the plate located on the back of the case portion are formed in a direction of 90 degrees to 360 degrees, and 4 to 12 wings are each formed inside the case portion. By being arranged at equal intervals along the circumference of the case, the contact efficiency of the incoming purification target gas and washing water with the wing surface is increased while minimizing the increase in differential pressure due to the plurality of wings.

Figure 1 is an exploded/combined perspective view of a filter having a conventional mesh structure.
Figure 2 is a perspective view of a vane filter according to an embodiment of the present invention.
Figure 3 is a reference diagram showing only one wing portion within the case portion.
Figure 4 is a side view of a vane filter according to an embodiment of the present invention.
Figure 5 is a front view of a vane filter according to an embodiment of the present invention.

Hereinafter, preferred embodiments of the fixed expansion vane filter for a wet scrubber according to the present invention will be described in detail with reference to the attached drawings. It should be noted that like elements in the drawings are represented by like symbols wherever possible. Unless otherwise specified, all terms in this specification have the same general meaning as understood by a person skilled in the art to which the present invention pertains, and if there is a conflict with the meaning of the terms used in this specification, this specification Follow the definitions used in the specification. Throughout the specification, when a part "includes" a certain component, this means that it does not exclude other components but may further include other components, unless specifically stated to the contrary. Terms such as "...unit" and "...module" refer to a unit that processes at least one function or operation, which may be implemented as hardware, software, or a combination of hardware and software.

Referring to Figures 1 to 5, the fixed expansion vane filter for a wet scrubber according to an embodiment of the present invention includes a case portion 10 accommodating a filter module 30 therein; and a filter module 30 that is accommodated inside the case portion 10 to increase the efficiency of contact between the gas to be purified and the cleaning water, wherein the filter module 30 is fixed inside the case portion 10. Contact efficiency between the gas to be purified and the cleaning water, including a plurality of wings 320 formed to form a streamlined curved surface extending from the front to the back to guide the flow of the gas to be purified and the cleaning water flowing in from the front of the furnace. It is characterized by increasing sludge discharge efficiency by centrifugal force due to increase and flow rotation.

In the case of a wet scrubber filter to which the present invention is applied, it is a gas-liquid contact device built into a wet scrubber that treats acids, alkalis, PFC waste gases, and wastewater treatment plant odor gases (H2S, etc.) generated in industry, and is generally installed in multiple units within the filter case. With the filter modules installed, the gas to be purified and washing water are supplied, and odors and harmful components are removed from the gas passing through the filter modules. At this time, the filter module has generally been applied with various network structures to prevent the differential pressure from increasing while increasing the removal efficiency of harmful components by increasing the contact area with gas and washing water. However, as previously explained as a problem with the prior art, in the existing filter structure in which mesh-shaped pieces are cross-stacked, the speed at which the differential pressure rises rapidly increases during actual operation due to blockage caused by sludge adhering and accumulating between the grids. As a result, the cleaning cycle for periodically cleaning the filter is shortened, resulting in a serious increase in operational risks and operating costs. The present invention applies a structure that can fundamentally solve this problem.

That is, the filter module 30 applied to the present invention is not a mesh-shaped piece with a conventional grid, but is made of the surface itself, and the inflow of gas, etc. flowing from the inside of the case portion 10 is controlled by the filter module 30. By inducing a rotating flow while contacting the wings 320, the efficiency of contact between the gas to be purified and the cleaning water is increased and the sludge discharge efficiency by centrifugal force is increased, thereby reducing the differential pressure rise and extending the cleaning cycle. It is done by. Below, these structures and effects will be described in detail.

The case portion 10 can be viewed as a skeletal frame structure that accommodates the filter module 30 therein. It may be formed as a whole into a hexahedral shape, etc., as shown in FIG. 2, and has a filter module 30 therein. As a case that can accommodate, it can be divided into the front and back where the gas to be purified and the washing water flow in, and the parts that connect the front and back to form the top, bottom, left, and right sides. In other words, the front and back sides can be divided into a base frame that forms the main framework of the case portion 10, and the top, bottom, left, and right sides connecting them can be divided into side frames. In addition, the case portion 10 can be implemented in various forms, such as being divided into an inner frame and an outer frame, or the inner and outer sides can be integrally formed into one frame.

Meanwhile, referring to FIG. 2, the case portion 10 has a central axis 310 and a case on the front side in the direction in which the gas to be purified and the cleaning water flow, and on the back side in the opposite direction, respectively, a wing portion 320 to be described later. It may include a support structure 110 that supports and protects the start and end edges of the flat surface (curved surface) connecting the parts 10, respectively.

That is, in the case of the wing portion 320, which will be described later, one end of the surface forming the wing portion 320 is coupled to the central axis 310 and the other end is coupled to the case portion 10, forming a streamlined curved surface extending from the front to the back. It is formed to form a support structure 110 formed on the front and back of the case portion 10, respectively, at the start and end edges of the wing portion 320 exposed at the front and rear portions, respectively. It is to support and protect through. Through this, it is possible to increase the overall durability of the filter module 30 and the case portion 10 including it.

In addition, sludge is applied to the upper, lower, left, and right sides of the case portion 10 through centrifugal force caused by the flow (of purification target gas and washing water) rotating along the curved surface of the plurality of wings 320 of the filter module 30, respectively. In order for the gas to be easily discharged, as shown in FIG. 2, a plurality of ventilation holes 130 may be formed. Through these plurality of ventilation holes 130, not only the ease of discharging sludge, but also the convenience of cleaning the wing portion 320, etc. is increased. However, this does not exclude that the ventilation hole 130 may not be formed depending on needs such as field conditions.

The case part 10 can be installed with multiple case parts 10 connected in various directions depending on the shape/area of the inside, etc. within the wet scrubber, and washing water is discharged before and after the case part 10. Configuration, etc. may be located.

The filter module 30 is accommodated inside the case part 10 and is configured to increase the efficiency of contact between the gas to be purified and the washing water. In particular, in the present invention, the filter module 30 is installed in the case part 10. ), one end of the central axis 310 formed in the central portion of the flat plate (curved surface) is coupled to the central axis 310, and the other end is coupled to the case portion 10, and the gas to be purified and the cleaning water are introduced. It is characterized in that it has a form including a plurality of wings 320 that are formed to form a streamlined curved surface while slanting from the front to the back. In particular, the wing portion 320 is formed in a fixed state to form a streamlined curved surface extending from the front to the back to guide the flow of purification target gas and cleaning water flowing in from the front into a rotating flow. The centrifugal force caused by the flow (of the gas to be purified and the washing water) can increase sludge discharge efficiency and increase the contact efficiency between the gas to be purified and the washing water.

The central axis 310 is formed at the central point of the case portion 10 in a configuration that forms the center of the filter module 30, and a plurality of wings (to be described later) are formed based on the central axis 310. 320) components are arranged at regular intervals.

The wing portion 320 has one end of a flat plate (i.e., a plate shape with the entire surface closed and a curved surface, rather than the mesh-shaped plate structure that has been applied to existing filters, etc.), and the other end is connected to the central axis 310. It is each coupled to the case portion 10 and is formed to form a streamlined curved surface while sloping from the front to the back where the gas to be purified and the cleaning water flow in. A plurality of wings 320 are formed at the back with respect to the central axis. Can be placed and arranged at intervals. At this time, the streamlined curved surface forming each wing 320 is (obliquely at an angle of about 10 to 40 degrees) from the front to the back with respect to the central axis 310 (or the outer surface of the case portion 10). It can be formed to form a streamlined curved surface, and the streamlined curved surface forming the wing portion 320 generates centrifugal force in the process of flowing in the gas to be purified and the cleaning water flowing backward along the curved surface of the wing portion 320. It is preferable that the slope of the curved surface is formed to face the outer surface of the case portion 10 as much as possible.

Through the curved shape (shape) of the wing portion 320, the inflow gas to be purified and the cleaning water are naturally induced to flow along the wing portion 320, and the incoming gas to be purified and the cleaning water are guided to the wing portion ( While being in direct contact with the flat plate of 320, it is smoothly guided along the curved shape of the wing portion 320 and can flow out through the back of the case portion 10. In particular, the streamlined curved shape of the wings 320 causes centrifugal force to be generated in the process of flowing the purification target gas and cleaning water flowing backward along the curved surface of the wings 320, as described above, thereby purifying the wings. The sludge formed when the target gas and cleaning water come into direct contact with the surface of the wing 320 also does not stick or accumulate on the surface of the wing 320 according to the centrifugal force generated in this way, but flows into the case along the end of the wing 320. It can be smoothly discharged through the ventilation holes 130 on the front, left, and right sides of (10). The wing portion 320 may be made of a polymer-based synthetic resin, etc., and is preferably made of a material that can increase the contact efficiency between the gas to be purified and the cleaning water, and can additionally prevent contamination. It can be coated with anti-fouling paint, etc.

In particular, the wing portion 320 is designed to minimize the space (i.e., dead space) in which the gas to be purified and the cleaning water flowing into the case portion 10 pass through without contacting the wing portion 320. For this reason, the other end of the surface of the wing portion 320 that is coupled to the case portion 10 may be formed to be continuously coupled to the case portion 10 without being separated from the case portion 10. That is, if the case portion 10 has a hexahedral shape and a square cross-sectional shape viewed from the front, the outer cross-sectional shape of the wing portion 320 also has a square shape that matches the outer shape of the case portion 10. will be. Through this, the gas to be purified and the cleaning water flowing into the case portion 10 are necessarily in contact with the wing portion 320 that fills the inside of the case portion 10.

Meanwhile, if the shape of each of the wing parts 320 is explained with reference to FIG. 3, etc., the wing part 320 is formed by forming the corner of the starting portion of the (wing part) plate located on the front of the case part 10 and the case part. The edges of the end portions of the (wing portion) plate located on the rear surface of (10) may be formed to form directions of 90 to 360 degrees to each other. That is, the wing part 320 is coupled to the case part 10 in a form that diffracts the case part 10 in a full 360-degree turn, a form that diffracts the case part 10 in a half-turn of 180 degrees, a form that diffracts the case part 10 in about 90 degrees, etc. This allows the incoming purified gas and washing water to be smoothly discharged to the rear of the case portion 10 while contacting the wing portion 320 within the case portion 10, thereby minimizing the occurrence of differential pressure during the operation process. In addition, this is to ensure ease of cleaning during the cleaning process for the wing portion 320 in terms of maintenance.

In this way, the wing portion 320, which is formed in a form that diffracts the case portion 10 by about 180 degrees and a half rotation, preferably has 4 to 12 wing portions 320 (eight in the example shown in FIG. 2, etc.). (This is an example of the wing portion 320 being combined) is each included (disposed) inside the case portion 10, and at this time, the starting edge of each plate of the plurality of wing portions 320 is the case portion 10 of a square cross-section. By being arranged at equal intervals along the circumference, the contact efficiency of the incoming purification target gas and cleaning water with the surface of the wing part 320 is increased, while minimizing the increase in differential pressure due to the plurality of wing parts 320, and in terms of maintenance. It is also possible to ensure ease of cleaning of the wing portion 320. In other words, the more the plurality of wing parts 320 are arranged inside the case part 10, the higher the rate at which the gas to be purified and the water to be purified come into contact with the wings 320. However, as a result, the gas to be purified and the water to be cleaned may increase. As the flow may be slowed or blocked and the differential pressure may increase so that it cannot be discharged smoothly to the rear, in the present invention, the number of wing parts 320 arranged inside the case part 10 is 4 to 8 and their arrangement. By arranging the spacing at equal intervals, the wing portion 320 can be arranged in a structure that can minimize the increase in differential pressure while maximizing the contact ratio.

Meanwhile, the vane filter according to the present invention can also be used as a demister, and antifouling paints that prevent contamination, etc. can be applied to the central axis 310 to the case portion 10, etc.

In the above, the applicant has described various embodiments of the present invention, but such embodiments are only embodiments that embody the technical idea of the present invention, and any changes or modifications are not permitted in the present invention as long as they embody the technical idea of the present invention. It should be interpreted as falling within the scope of.

10: Case part
110: support structure 130: ventilation hole
30: Filter module
310: central axis 320: wing portion

Claims (8)

delete delete delete A case portion that accommodates the filter module therein; and
It includes a filter module accommodated inside the case portion to increase the efficiency of contact between the gas to be purified and the cleaning water,
The filter module is fixed inside the case portion and includes a plurality of wings formed to form a streamlined curved surface extending from the front to the back to guide the flow of purification target gas and cleaning water flowing in from the front, Increases contact efficiency between gas and washing water and increases sludge discharge efficiency by centrifugal force,
The filter module has a central axis formed in the center of the case portion, one end of a flat plate is coupled to the central axis and the other end is connected to the case portion, and is inclined from the front to the back where the gas to be purified and the washing water are introduced. It includes a plurality of wings formed to form a streamlined curved surface,
In order to minimize the space where the gas to be purified and the cleaning water flowing into the case portion pass through without contacting the wing portion, the other end of the wing surface that is coupled with the case portion is continuously connected to the case portion without being separated from the case portion. Combined with wealth,
The case part includes a support structure on the front side where the gas to be purified and the cleaning water flows in and on the opposite side back side, supporting and protecting the start edge and end edge of the plate connecting the central axis and the case part in the wing part, respectively. Characterized by a fixed expansion vane filter for wet scrubber. According to claim 4,
The case part has a plurality of ventilation holes on the sides of the upper, lower, left, and right sides to enable sludge to be easily discharged through the centrifugal force of the gas and cleaning water flow flowing along the plurality of wings and to increase the convenience of cleaning the wings. A fixed expansion vane filter for a wet scrubber, characterized in that it is formed. According to claim 4,
The wing portion is formed so that the starting edge of the plate located on the front of the case portion and the end edge of the plate located on the back of the case portion are oriented 90 degrees to 360 degrees,
The streamlined curved surface forming the wing portion is a fixed type for wet scrubber, characterized in that the inclination of the curved surface is formed toward the case portion so that centrifugal force is generated in the process of the incoming purification target gas and washing water flowing backward along the curved surface of the wing portion. Extended vane filter. According to claim 6,
The wing portion includes 4 to 12 wing portions inside the case portion, and the edges of the starting portions of each plate of the plurality of wing portions are arranged at equal intervals along the circumference of the case portion of a square cross-section, so that the incoming purification target gas And a fixed expansion vane filter for a wet scrubber, characterized in that it minimizes the differential pressure increase due to a plurality of wings while increasing the contact efficiency of the washing water with the wing surface. According to any one of claims 4 to 7,
The fixed expansion vane filter for a wet scrubber is a fixed expansion vane filter for a wet scrubber, characterized in that it is used as a demister.

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