KR102001630B1 - Rotary Filtering Apparatus - Google Patents

Abstract

The present invention relates to a rotary filtering device which is installed in a front line of a bag filter or a cyclone to collect alien substances in advance. The purpose of the present invention is to provide a rotary filtering device which is installed in the front of the bag filter or the cyclone to increase dust collecting efficiency of alien substance collecting apparatus by collecting contaminants with relatively low specific gravity and high volume in advance. The rotary filtering device of the present invention includes: an upper housing including an upper inlet in which an inflow air is flown and an upper outlet from which a first filtered air obtained by filtering the inflow air is discharged to the outside; a lower housing positioned on the bottom portion of the upper housing and coupled to the upper housing; an inflow module positioned within the upper housing and flowing in the inflow air; a filtering module positioned in at least one side of the inflow module and filtering the inflow air; a collection module positioned under the inflow module and the filtering module within the lower housing to collect first alien substances filtered in the filtering module and transfer the collected first alien substances to a lower part of the lower housing; and a rotating means rotating the collection module.

Description

Rotary Filtering Apparatus

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a rotary filtering device installed at a front end of a bag filter or a cyclone to remove foreign matter having a large volume of dust.

The dust collecting method is generally a method using a bag filter or a method using a centrifugal cyclone. A method using a bag filter is a method of collecting and removing contaminants such as dust having a volume larger than the size of a micro passageway while passing air for dust transfer through a lattice type micro passageway made in a bag filter. These methods can be used in processes such as mineral analysis processes, plywood (MDF, PB) manufacturing processes, and incineration waste treatment processes.

In the method using the bag filter, the dust collecting efficiency is lowered due to clogging due to foreign matter (eg, large particles such as vinyl, PET pieces, and plastic) adhering to the surface of the filter bag. It is inefficient. Therefore, the method using the bag filter has a limitation in treating and removing contaminants having a low specific gravity and a large volume.

An object of the present invention is to provide a rotary filtering device which is installed at a front end of a bag filter or a cyclone to preliminarily collect contaminants having a relatively low specific gravity and a large volume to increase the dust collecting efficiency of the foreign matter collecting device.

According to an aspect of the present invention, there is provided a rotary filtering apparatus including an upper housing having an upper inlet through which inlet air flows and an upper outlet through which primary filtered air is filtered, A lower housing positioned at a lower portion of the upper housing and connected to the upper housing, an inflow module positioned inside the upper housing for introducing inflow air, a filtering module positioned at at least one side of the inflow module, And a collecting module for collecting the primary foreign substances filtered by the filtering module located at a lower portion of the inflow module and the filtering module inside the lower housing and transferring the primary foreign matter to a lower portion of the lower housing, And means for controlling the operation of the apparatus.

The rotary filtering apparatus of the present invention can increase the filtering effect of the filtering network and reduce the clogging of the filtering network by passing the air containing the foreign substance through the filtering network while flowing the air from the top to the bottom.

In addition, the rotary filtering apparatus of the present invention is capable of allowing the air to flow smoothly through the filtering network by forming an inflow space in which the inflow air containing the foreign material flows, together with the filtering net, have.

In addition, the rotary filtering apparatus of the present invention can smoothly introduce air containing foreign matter into the inflow space by lowering the primary foreign matter collected in the inflow space while rotating the collecting rotary plate.

In addition, the rotary filtering apparatus of the present invention is installed at the front end of a bag filter or cyclone to filter contaminants having a low specific gravity and a large volume, thereby increasing the dust collecting efficiency of the bag filter or the cyclone.

In addition, the rotary filtering apparatus of the present invention can be installed anywhere on the front end line of the bag filter or the cyclone without being limited by the installation position and conditions. Since the primary foreign matter having a relatively large particle size is filtered in advance, Which reduces the friction and wear of the conveying duct, the primary foreign matter, and the lifetime of the conveying duct.

Further, the rotary filtering apparatus of the present invention can increase the service life and inspection cycle of the bag filter or the cyclone, and can reduce the maintenance cost such as the material cost or the labor cost due to replacement or inspection.

In addition, since the rotary filtering apparatus of the present invention includes dust particles of a relatively uniform size in the primary filtered air introduced into the bag filter or the cyclone, the dust collected in the bag filter or the cyclone can be reused.

FIG. 1 is a schematic block diagram of an exemplary foreign matter collecting apparatus to which a rotary filtering apparatus according to an embodiment of the present invention is mounted.
FIG. 2 is a schematic block diagram of another exemplary dust collecting apparatus in which a rotary filtering apparatus according to an embodiment of the present invention is mounted.
3 is a perspective view of a rotary filtering apparatus according to an embodiment of the present invention.
FIG. 4 is a perspective view of the rotary filtering device of FIG. 3 rotated by 180 °; FIG.
5 is a vertical cross-sectional view of AA of Fig.
6 is a vertical cross-sectional view of BB of Fig.
7 is a perspective view of an inflow module constituting the rotary filtering apparatus of FIG.
FIG. 8 is a perspective view of the rotary filtering device of FIG. 3 in a state where the inflow module and the filtering module are combined.
9 is a perspective view of a collecting module of the rotary filtering apparatus of FIG.
10 is a vertical cross-sectional view illustrating the operation of a rotary filtering apparatus according to an embodiment of the present invention.
11A and 11B are vertical cross-sectional views illustrating the operation of a rotary filtering apparatus according to an embodiment of the present invention.

Hereinafter, the rotary filtering apparatus of the present invention will be described in more detail with reference to embodiments and accompanying drawings.

First, the structure of a foreign matter collecting apparatus to which a rotary filtering apparatus according to an embodiment of the present invention is mounted will be described.

FIG. 1 is a schematic block diagram of an exemplary foreign matter collecting apparatus to which a rotary filtering apparatus according to an embodiment of the present invention is mounted.

1, the foreign matter collecting apparatus includes a rotary filtering device 10, a bag filter 20, a dust transfer fan 30, a storage box 40, a lower screw conveyor 50, and an external storage box 60 ) May be formed. The foreign matter collecting device may include only foreign substances in the form of small particles relatively to the air introduced into the bag filter 20 to increase the dust collecting efficiency of the bag filter 20 and reduce the maintenance cost for maintenance.

The foreign matter collecting device introduces the inflow air including foreign matter and dust into the inside of the rotary filtering device 10 through a duct for selective collection. The rotary filtering device 10 collects primary foreign matter (for example, vinyl, PET pieces, plastic pieces, etc.) having a relatively large size or area and discharges primary filtered air from which primary foreign matter has been removed. The storage box 40 is located at a lower portion of the rotary filtering device 10 and stores primary foreign substances falling by its own weight collected by the rotary filtering device 10.

The bag filter 20 is connected to the rotary filtering device 10 by a separate transfer pipe 15. The bag filter 20 may be formed of a general bag filter 20 used in a foreign matter collecting apparatus. The bag filter 20 collects secondary particles of a relatively small size contained in the filtered primary filtering air that has passed through the rotary filtering device 10. The dust transfer fan 30 generates a wind pressure to provide the necessary pressure for the air containing foreign matter to pass through the rotary filtering device 10 and the bag filter 20 to the atmosphere. The lower screw conveyor 50 is located at a lower portion of the bag filter 20 and transports foreign matter collected in the bag filter 20 to the lower portion of the external storage box 60. The external storage box 60 stores relatively small foreign substances introduced through the lower screw conveyor 50.

FIG. 2 is a schematic configuration diagram of another exemplary dust collecting apparatus to which a rotary filtering apparatus according to an embodiment of the present invention is mounted.

2, the foreign matter collecting apparatus includes a rotary filtering device 10, a cyclone 20a, a dust transfer fan 30, a storage box 40, a lower valve 50, and an external storage box 60 As shown in FIG. 1, the cyclone 20a is used in place of the bag filter 20. [ In addition, the foreign matter collecting device may use the lower valve 50 without the lower screw conveyor 50 being used.

The cyclone is connected to the rotary filtering device 10 by a separate transfer pipe 15. The cyclone may be a general cyclone used in a foreign matter collecting apparatus. The cyclone passes through the rotary filtering device 10 and collects relatively small foreign substances contained in the primarily filtered air. The dust transfer fan 30 generates a wind pressure to provide a pressure necessary for air containing foreign matter to pass through the rotary filtering device 10 and the cyclone to be discharged to the atmosphere. The lower valve is located at a lower portion of the cyclone, and opens the lower portion of the cyclone to allow the foreign material falling to the lower portion to flow into the external storage box 60. The external storage box 60 stores relatively small foreign substances falling downward through the lower valve.

Next, a configuration of a rotary filtering apparatus according to an embodiment of the present invention will be described.

3 is a perspective view of a rotary filtering apparatus according to an embodiment of the present invention. FIG. 4 is a perspective view of the rotary filtering device of FIG. 3 rotated by 180 °; FIG. 5 is a vertical sectional view taken along line A-A in Fig. 6 is a vertical sectional view taken along the line B-B in Fig. 7 is a perspective view of an inflow module constituting the rotary filtering apparatus of FIG. FIG. 8 is a perspective view of the rotary filtering device of FIG. 3 in a state where the inflow module and the filtering module are combined. 9 is a perspective view of a collecting module of the rotary filtering apparatus of FIG.

The rotary filtering apparatus 10 includes an upper housing 100, a lower housing 200, an inlet module 300, a filtering module 400, a collecting module 500, and a rotating unit 600.

The rotary filtering device 10 is configured such that the upper housing 100 and the lower housing 200 are removably coupled to each other and the inflow module 300 and the filtering module 400 are installed inside the upper housing 100 and the lower housing 200, And a collecting module 500 are installed. The rotary filtering apparatus 10 is constructed such that the upper housing 100 and the lower housing 200 are detachably coupled to each other so that replacement of parts due to long use of the inflow module 300, the filtering module 400 and the collecting module 500 It can be easy.

The upper housing 100 includes an upper inlet 110, an upper opening 120, and an upper outlet 130. The upper housing 100 may further include an inspection window 140. The upper housing 100 may be formed in a hollow box shape. For example, the upper housing 100 may be formed in a box shape in a hexahedron shape by assembling the upper plate 110a and the side plates 110b. The upper housing 100 may be formed by assembling the upper plate 110a and the side plates 110b with bolts or the like. In addition, the upper housing 100 can prevent dust from being scattered to the outside by inserting a packing in a portion where the upper plate 110a and the side plates 110b are connected. The upper housing 100 provides a space in which the inflow module 300 and the filtering module 400 are accommodated.

The upper inlet 110 is located at the center of the upper plate 110a of the upper housing 100 and is formed to pass through from the outside to the inside. The upper inlet 110 is formed with a predetermined diameter to provide a path through which the inflow air flows. The upper inlet 110 is connected to a supply pipe connected to an external inflow air generator (not shown).

The upper opening 120 is formed at a lower portion of the upper housing 100. The upper opening 120 may be formed entirely below the upper housing 100. The upper opening 120 provides a path through which the collecting module 500 is coupled to the lower opening. In addition, the upper opening provides a path for the primary foreign matter filtered from the incoming air to fall downward by the filtering module (400).

The upper outlet 130 may be formed on one side of the upper housing 100. The upper outlet 130 provides a path through which filtered air filtered by the filtering module 400 is discharged to the outside. The upper outlet 130 may be formed in an appropriate area required for smoothly flowing filtered air. The upper outlet 130 may have an area corresponding to the upper inlet 110.

The inspection window 140 may be formed on both sides of the upper housing 100. That is, the inspection window 140 may be formed on the side plates 110b. The inspection window 140 may be formed on both sides of one side of the upper discharge port 130. The inspection window 140 provides a path necessary for maintenance of the filtering module 400 located inside the upper housing 100. In addition, the inspection window 140 provides a path necessary for cleaning the foreign matter accumulated inside the upper housing 100. The inspection window 140 may be formed on both sides of the upper housing 100. The inspection window 140 is enclosed by a separate window and may be formed to open the window as needed.

The lower housing 200 includes a lower opening 210, a lower outlet 220, and a lower fastener 230. The lower housing 200 may further include a lower chute 240.

The lower housing 200 is located below the upper housing 100 and the lower opening 210 is engaged with the upper opening 120 of the upper housing 100. The lower housing 200 is coupled with the upper housing 100 to form an entire housing. The lower housing 200 may be formed in a hollow box shape. The lower housing 200 provides a space in which the collection module 500 is received. Further, the rotating means 600 is fixed to the outer side of the lower housing 200.

The lower opening 210 is formed in the upper portion of the lower housing 200. The lower opening 210 may be formed entirely in a central region of the upper portion of the lower housing 200. The lower opening 210 provides a path through which the filtering module 400 is coupled to the upper part and the collecting module 500 is coupled to the lower part. In addition, the lower opening part provides a path for the foreign substance filtered from the inflow air to fall down by the filtering module 400.

The lower discharge port 220 is formed at a lower portion of the lower housing 200. The lower outlet 220 provides a path for the foreign material collected by the collecting module 500 to fall to the lower portion of the lower housing 200.

The lower fasteners 230 are formed at positions opposite to each other on opposite sides of the lower housing 200. The lower fastener 230 is formed in a central region with respect to the horizontal direction. A collection module 500 is coupled to the lower fastener 230.

The lower chute 240 is coupled to the lower outlet 220. The lower chute 240 may be opened when the primary foreign material collected in the collecting module 500 and falling down is discharged downward. At this time, the primary foreign matter may pass through the lower chute 240 due to its own weight and be discharged to the lower portion. In addition, the lower chute 240 may be always open when the rotary filtering device 10 is operated.

The inflow module 300 includes an upper inflow conduit 310, an intermediate inflow conduit 320, and a lower inflow conduit 330. The inflow module 300 may further include an upper flange 340. The inflow module 300 provides a path for inflow of inflow air from the outside. The inflow module 300 also supplies inflow air to the filtering module 400. Meanwhile, the upper inflow pipe 310, the intermediate inflow pipe 320, and the lower inflow pipe 330 may be integrally formed. The inflow module 300 is seated in the middle of the upper opening 120 of the lower housing 200. More specifically, the inflow module 300 is seated over the upper opening 120 on the front and rear sides of the lower inflow pipe 330. Therefore, a filtering region may be formed on both sides of the upper opening 120 around the lower inflow pipe 330. The filtering region is an area formed between both sides of the lower inflow pipe 330 and the upper opening 120 by dividing the upper opening portion by the lower inflow pipe 330. Accordingly, the filtering region may be formed on two sides of the lower inflow pipe 330.

The upper inflow pipe 310 has a predetermined height and is formed into a hollow tube shape. The upper inflow pipe 310 may be formed in a polygonal tube shape such as a cylindrical shape with an open top and a bottom, a rectangular tube shape, a pentagonal tube shape, or a hexagonal tube shape. The upper inflow pipe 310 may be formed into a cylindrical shape having an upper diameter or a rectangular barrel having an upper width. The upper inflow pipe 310 is installed such that an upper end thereof is exposed to the upper portion of the upper housing 100 and a lower end thereof faces downward.

The intermediate inflow pipe 320 has a predetermined height and is formed into a hollow tubular shape. The intermediate inflow pipe 320 functions to connect the upper inflow pipe 310 and the lower inflow pipe 330 having different horizontal cross-sectional shapes and areas. Accordingly, the intermediate inflow pipe 320 may have various shapes depending on the shapes of the upper inflow pipe 310 and the lower inflow pipe 330. For example, the intermediate inflow pipe 320 may have a shape in which the horizontal cross-sectional area increases from the upper end to the lower end. For example, the intermediate inflow pipe 320 may have a rectangular shape having an upper end in a circular shape having a predetermined upper diameter and a lower end corresponding to the upper end diameter or having a lower end width larger than the upper end diameter and a lower end length longer than the lower end end . In addition, the upper end of the intermediate inflow pipe 320 has the same shape as the lower end of the upper inflow pipe 310. For example, when the lower end of the upper inflow pipe 310 is formed in a circular shape, the upper end of the intermediate inflow pipe 320 may also be formed in a circular shape. The upper end of the intermediate inflow pipe 320 is engaged with the lower end of the upper inflow pipe 310. The intermediate inflow pipe 320 allows the inflow air flowing through the upper end to be dispersed in the longitudinal direction while flowing downward.

The lower inflow pipe 330 has a predetermined height and is formed into a hollow tube shape. The lower inflow pipe 330 may be formed so that the upper and lower ends thereof have the same horizontal surface shape. For example, the lower inflow pipe 330 may be formed in a rectangular shape in which the upper and lower ends have the same bottom width and bottom length. The lower inflow pipe 330 may be formed in a rectangular shape having a long side and a short side. In addition, the upper inflow pipe 330 has a planar shape that is the same as the lower inflow pipe 320. For example, the upper end of the lower inflow pipe 330 may have a lower width and a lower length corresponding to a lower end width and a lower end length of the intermediate inflow pipe 320.

The lower inflow pipe 330 may include a side connection hole 331 and a lower flange 332. The side connection holes 331 may be formed in a shape arcing upward from the lower end of the longer side. More specifically, the side connection hole 331 may be formed to have a length corresponding to the entire length of the lower end of the arc of the arc. The side connection holes 331 may be formed to pass through from the outside to the inside of the long side. The filtering module 400 is coupled to the side connection hole 331.

The lower flange 332 may be formed as a flange extending horizontally outward from the lower end of the short side. The lower flange 332 may have a lower flange hole 333 for fastening.

The upper flange 340 may be formed in a general flange shape such as a ring-shaped plate. The upper flange 340 may have an inner diameter corresponding to an outer diameter or an inner diameter of the upper inflow pipe 310. The upper flange 340 is joined to extend outwardly from the upper end of the upper inflow pipe 310 in a ring shape. The upper flange 340 is exposed to the upper portion of the upper housing 100 and an external inlet pipe is connected to the upper inlet pipe 310. The upper flange 340 may have a through hole 340a through which the bolt passes.

The filtering module 400 may include a filtering network 410 and a filter flange 420. The filtering module 400 may be located on at least one side of the inflow module 300. In addition, the filtering module 400 may be located on both sides of the inflow module 300. The filtering module 400 is coupled by shielding the filtering region formed between the lower inflow pipe 330 of the inflow module 300 and the lower opening 210 of the lower housing 200. Accordingly, the filtering module 400 may be formed of two filters. In addition, the filtering module 400 may be formed symmetrically with respect to each other. The filtering module 400 may filter the primary foreign matters from the inflow air flowing from the inflow module 300 by shielding the filtering area and drop the inflow air to the lower part and pass only the filtered air.

The filtering module 400 may be fixed to the lower housing 200 and the inflow module 300. The filtering module 400 may be detachably coupled to the lower housing 200 and the inflow module 300 by bolts or the like. Thus, the filtering module 400 can be easily replaced when damaged during use.

The filtering network 410 may include a curved surface plate 411 and a vertical plate 412. The filtering network 410 may be formed in various shapes to shield the filtering region according to the shape of the filtering region. The filtering net 410 may include a plurality of filtering holes 410a penetrating from one side to the other side. The filtering holes 410a may be formed in both the curved plate 411 and the vertical plate 412. [ The diameter, number, spacing, and the like of the filtering hole 410a may be adjusted according to characteristics of the primary foreign matter to be filtered. The diameter, number, spacing, and the like of the filtering hole 410a may be adjusted according to operating requirements of the foreign matter collecting apparatus to which the rotary filtering apparatus 10 is mounted. The filtering net 410 passes particles and air smaller than the filtering holes 410a and filters the air without passing primary foreign substances larger than the filtering holes 410a.

The total area of the filtering net 410 may be larger than the area of the lower inflow pipe 330. In addition, the filtering net 410 may have an area larger than the area of the lower inflow pipe 330 in the total area of the filtering holes 410a. Accordingly, the filtering network 410 can reduce the clogging of the filtering holes 410a in the process of filtering the inflow air and increase the filtering efficiency.

The curved surface plate 411 may be formed in a plate shape having a curved surface convex upward along the longitudinal direction. The curved surface plate 411 may have a circular arc shape having a predetermined radius and a vertical cross section cut parallel to the longitudinal direction. The radius of the arc of the curved plate 411 may correspond to the radius of the side connection hole 331. The curved plate 411 may have a shape corresponding to the arc of the side connection hole 331. The curved plate 411 may be coupled to the side connection holes 331 at both sides of the lower inflow pipe 330.

The vertical plate 412 may be formed in a plate shape corresponding to the arc shape of the curved plate 411. That is, the vertical plate 412 may be formed in a plate shape corresponding to the side surface shape of the curved plate 411. The vertical plate 412 is coupled to the other side of the curved plate 411 which is opposite to the one side coupled with the lower inflow pipe 330 and shields the other side of the curved plate 411.

The filter flange 420 may be formed as a flange having a predetermined width from the outer side of the filtering net 410 to the outside. The filter flange 420 may be formed to be in parallel contact with the contact surface of the lower housing 200 or the lower inflow pipe 330 when the filtering net 410 is seated in the filtering area. Therefore, the filter flange 420 may be formed at different angles on the sides of the curved plate 411 and the vertical plate 412. The filter flange 420 may be formed with a through hole 420a through which the bolt passes. The filter flange 420 may be coupled to the lower housing 200 and the inflow module 300 by bolts. The filter flange 420 can secure the filtering net 410 by fixing the filtering net 410 to the lower housing 200 and the inflow module 300. Accordingly, damage to the filtering network 410 due to collision with the primary foreign matter, which may occur during the rotation process of the collecting module 500, can be reduced.

The collecting module 500 may include a collecting housing 510, a collecting shaft 520, a collecting rotary plate 530, and a collecting separating plate 540. The collecting module 500 may further include a collecting and discharging pipe 550.

The collecting module 500 is located below the inlet module 300 and the filtering module 400 and collects the primary foreign substances falling from the filtering module 400 and the inlet module 300 and transfers them to the lower part. The collecting module 500 is coupled to the upper part of the inner side of the lower housing 200 by the collecting housing 510. The collecting rotary plate 530 is radially coupled with the collecting shaft 520 at a predetermined angle in the circumferential direction of the collecting shaft 520, And rotates together with the shaft 520. The collecting module 500 forms an inflow space through which the inflow air is introduced by the collecting housing 510 and the collecting rotary plate 530. The inflow space is formed in a lower portion of the lower inflow pipe 330 in a downward direction. Accordingly, the collecting module 500 reduces the flow rate of the inflow air flowing into the inflow space, so that the first foreign matter having different specific gravity can be more effectively selected.

The collecting housing 510 includes a collecting opening 511 and a collecting outlet 512. The collecting housing 510 is formed in a cylindrical shape having a substantially hollow interior. The collecting housing 510 is formed such that its length in the axial direction is smaller than the width of the lower housing 200. The collecting housing 510 is formed to have a smaller diameter than the depth and height of the lower housing 200. The collecting housing 510 is located inside the lower housing 200 such that the axial direction coincides with the width direction of the lower housing 200. The collecting housing 510 may be formed with the same curvature as the curved plate 411 of the filtering module 400.

The collecting opening 511 may be formed by cutting the upper part of the collecting housing 510 in parallel to the axial direction. Accordingly, the collecting opening 511 may have a rectangular shape when viewed from above. The collecting opening 511 may be formed in a shape corresponding to the lower opening 210. The collecting opening 511 may have the same length and width as the lower opening 210. The collecting opening 511 may have a length corresponding to the length of the collecting housing 510 and a predetermined width. The collecting housing 510 may be coupled to the upper inside of the lower housing 200 so that the collecting opening 511 coincides with the lower opening 210. The collecting opening 511 provides a path through which the inflow air flowing from the lower inflow pipe 330 flows into the collecting housing 510. In addition, the collecting opening 511 provides a path through which the primary foreign matter filtered by the filtering module 400 falls to the lower part of the inflow space.

The collecting outlet 512 may be formed by cutting the lower part of the collecting housing 510 in parallel to the axial direction. Accordingly, the collection outlet 512 may be formed in a rectangular shape when viewed from the bottom. The collecting outlet 512 may be formed to have a smaller width than the collecting opening. The collecting outlet 512 provides a path for discharging the primary foreign matter collected by the collecting module 500 to the lower part.

The collecting shaft 520 is formed in a circular bar shape and is coupled through the collecting housing 510 along the axial direction of the collecting housing 510. The collecting shaft 520 may be formed to be longer than the axial length of the collecting housing 510. The collecting shaft 520 may further include a reinforcing pipe 521 in a region where the collecting rotary plate 530 is coupled. The reinforcing pipe 521 reinforces the strength of the collecting shaft 520 so that the collecting rotary plate 530 is stably engaged. The collecting shaft 520 may be rotatably fixed to the lower housing 200 by bearings 522 located at both ends.

The collecting rotary plate 530 is formed in a plate shape having a predetermined width and length. The collection swing plate 530 may be formed of a collection center plate 531 and a collection peripheral plate 532. The collecting central plate 531 and the collecting peripheral plate 532 may be integrally formed of the same material. The collecting center plate 531 and the collecting peripheral plate 532 may be made of different materials. For example, the collecting center plate 531 may be formed of a material such as rigid metal or plastic. In addition, the collecting peripheral plate 532 may be formed of a material such as rubber having elasticity and abrasion resistance.

The collecting rotary plate 530 may have a width corresponding to the radius of the collecting housing 510 and a length corresponding to the length of the collecting housing 510. The collecting rotary plate 530 is coupled to the collecting shaft 520 such that the longitudinal direction thereof is coupled to the collecting shaft 520 in the axial direction of the collecting shaft 520 and the width direction is directed to the outside of the collecting shaft 520. The collecting rotary plate 530 may contact the end surface of the collecting peripheral plate 532 with the inner peripheral surface of the collecting housing 510. The end of the collecting peripheral plate 532 may be a long side of the collecting rotary plate 530 located on the opposite side of the long side coupled with the collecting shaft 520. Further, the end portion of the collecting peripheral plate 532 may include a short side located between the long sides. The end of the collecting peripheral plate 532 may be spaced apart from the inner peripheral surface of the collecting housing 510. However, when the end portion of the collecting peripheral plate 532 is spaced apart from the inner peripheral surface of the collecting housing 510, the collecting rotary plate 530 can flow the inflow air downward, . When the collecting peripheral plate 532 of the collecting rotary plate 530 is formed of a rubber material, the collecting peripheral plate 532 can move while being in contact with the inner peripheral surface of the collecting housing 510. Therefore, the space between the end of the collecting peripheral plate 532 and the inner circumferential surface of the collecting housing 510 is sealed to prevent the inflow of the inflow air and the re-inflow of the collected primary foreign matter.

The collecting rotary plate 530 may be formed in plural. The collection swing plate 530 may be formed in an appropriate number so that the pressure of the inflow air flowing into the inflow space during the rotation process is not lost to the lower space. For example, at least one of the collecting rotary plates 530 is located on one side or the other side of the lower opening 210 and the other is disposed on the other side or one side of the lower discharge opening 220 opposite to the lower opening 210 Can be located outside. In this case, the lower opening 210 and the lower outlet 220 are separated by two collecting rotary plates 530 and are not directly passed through. Therefore, the inflow air flowing into the inflow space through the lower opening 210 is blocked by the collection swing plate 530, and does not flow directly to the lower outlet 220, which is an atmospheric pressure area. The collecting rotary plate 530 may be coupled to the collecting shaft 520 at a predetermined angle along the circumferential direction of the collecting shaft 520. For example, the collecting rotary plates 530 are formed in six pieces and can be coupled to the collecting shaft 520 while being spaced apart by 60 degrees. The collecting rotary plate 530 can divide the internal space of the collecting housing 510 into a plurality of pieces along the circumferential direction around the collecting shaft 520. For example, the collecting rotary plate 530 can be divided into six spaces from the first space to the sixth space. The collecting rotary plate 530 is rotated by the collecting shaft 520 and collects primary foreign substances falling from the filtering module 400 while passing through the lower part of the filtering module 400 sequentially from the first space, do. The collection swing plate 530 continuously rotates to seal the lower opening 210 and the inflow air flowing through the lower inflow pipe 330 passes through the filtering net 410 and flows into the inside of the upper housing 100 .

The collecting spacing plate 540 may be formed in the shape of a fan-shaped plate, and may be formed to correspond to the spacing angle of the collecting rotary plate 530 adjacent to each other. In the collecting separating plate 540, the call is directed outward and both sides are respectively coupled to the surface of the collecting rotary plate 530. The collecting spacing plates 540 may be spaced apart from each other in the direction of the collecting shaft 520 between adjacent collection collecting plates 530. In addition, the collecting spacing plate 540 may be positioned between neighboring collecting rotary plates 530. The collecting separating plate 540 stably engages the collecting rotary plate 530 with respect to the collecting shaft 520 and maintains the spacing angle. In addition, the collection separating plate 540 can reduce the deformation of the collecting rotary plate 530 due to the load generated during the rotation of the collecting rotary plate 530 by supporting the collecting rotary plate 530.

The collection and discharge pipe 550 is formed in a tubular shape having upper and lower openings. The upper end of the collecting and discharging pipe 550 is connected to the collecting and discharging port 512 and the lower end of the collecting and discharging pipe 550 is connected to the lower discharging port 220. The collecting / discharging pipe (550) connects the collecting outlet (512) and the lower discharging port (220) so that the collected primary foreign substance is discharged to the outside through the lower discharging port (220). Meanwhile, when the collecting outlet 512 is directly connected to the lower outlet 220, the collecting outlet pipe 550 may be omitted.

The rotating means 600 may include a conventional motor 610 used to rotate the shaft. The rotating means 600 may further include a rotation sensor 620 located on the opposite side to which the motor 610 is coupled. The rotating means 600 is located outside the lower housing 200. The rotating means 600 includes a rotating shaft, and the rotating shaft is coupled with one end of the collecting shaft 520 to rotate the collecting shaft 520. The rotating means 600 may be a hollow shaft type, and the collecting shaft 520 may be inserted into the motor 610 and fixed therein. The collecting shaft 520 can be fixed by a key. The rotating means 600 may be supported on the lower housing 200 by a separate supporting member 630.

The rotation sensor 620 can sense whether the collecting shaft 520 is rotating or rotating. The rotation sensor 620 may be a general rotation sensor.

The operation of the rotary filtering apparatus according to an embodiment of the present invention will be described below.

10 is a vertical cross-sectional view illustrating the operation of a rotary filtering apparatus according to an embodiment of the present invention. 11A and 11B are vertical cross-sectional views illustrating the operation of a rotary filtering apparatus according to an embodiment of the present invention.

First, the inflow air including the primary foreign matter c flows into the inflow space through the upper inflow pipe 310 and the intermediate inflow pipe and the lower inflow pipe 330 of the inflow module 300. The inflow space may be formed by a lower inflow pipe 330, a filtering net 410, and a collecting rotary plate 530 located at an upper portion. The inflow air can again rise in the inflow space and pass through the filtering net 410. At this time, the filtering net 410 can filter and filter the primary foreign matter c contained in the inflow air. The primary foreign matter (c) falls down and accumulates in the lower part between the collecting rotary plates (530). Further, the primary foreign matter (c) may flow inside the inflow space when the weight is relatively light. The primary filtered air that has passed through the filtering net 410 is discharged to the outside through the upper outlet 130 of the upper housing 100.

The collecting rotary plate 530 may be rotated by a collecting shaft 520 rotated at a low speed by the rotating means 600. Meanwhile, the collecting rotary plate 530 can be rotated intermittently. The collecting rotary plate 530 rotates continuously to transfer the primary foreign matter c accumulated at the lower part of the inflow space to the lower part. The primary foreign matter c may be transferred to the lower portion and discharged to the outside through the lower outlet 220.

As shown in FIG. 11A, the collecting rotary plate 530 may be arranged in a vertical direction on the upper part of the collecting shaft 520 and two inclinedly arranged at intervals of 60 degrees on both sides. The collecting rotary plates 530 may be arranged at intervals of 60 degrees. The collecting rotary plates 530 located on both sides of the collecting rotary plate 530 may be positioned to coincide with both ends of the lower opening 210. In this case, the inflow space may be formed of two sub-spaces by three collection swing plates 530. 11B, the collecting rotary plate 530 may be positioned such that the collecting rotary plate 530 located on both sides of the collecting rotary plate 530 does not coincide with both side ends of the lower opening 210. In this case, the inflow space may be formed of three sub-spaces by four collecting rotary plates 530.

Since the end portion of the collecting rotary plate 530 rotates while keeping the end portion of the collecting rotary plate 530 at a minimum distance so as not to contact the inner circumferential surface of the collecting housing 510, the inflow air flows between the collecting rotary plate 530 and the inner peripheral surface of the collecting housing 510 Do not. In addition, since the inflow air does not flow downward between the collecting rotary plate 530 and the inner surface of the collecting housing 510, the pressure of the inflow air passing through the filtering net 410 is not reduced. Also, the inflow air does not flow in the direction of the lower outlet 220 and does not flow into the storage box 40 located under the lower housing 200. The inflow air does not blow off the primary foreign matter c conveyed downward by the collecting rotary plate 530 or the primary foreign matter c stored in the storage box 40.

The rotary filtering device 10 increases the filtering effect of the filtering net 410 and reduces the clogging of the filtering net 410 by filtering air passing through the filtering net 410 while flowing air containing foreign matter from the upper part to the lower part. . The rotary filtering apparatus 10 includes a filtering net 410 and a rotating collecting rotary plate 530 disposed below the filtering net 410 to form an inflow space through which the inflow air containing foreign substances flows together with the filtering net 410, So that it can smoothly pass through the filtering net 410. In addition, the rotary filtering device 10 may rotate the collecting rotary plate 530 to drop the primary foreign matter c collected in the inflow space downward to smoothly introduce air containing foreign matter into the inflow space. have. In addition, the rotary filtering device 10 can increase the dust collecting efficiency of the bag filter 20 or the cyclone by filtering contaminants having a low specific gravity and a large volume, which are installed at the front end of the bag filter 20 or the cyclone.

The present invention is not limited to the above-described embodiments, but may be modified in various ways within the spirit and scope of the present invention as set forth in the following claims. It will be understood by those of ordinary skill in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention.

10: Rotary filtering device
20: bag filter 20a: cyclone
30: dust transfer fan 40: storage box
50: Lower screw conveyor 60: External storage box
100: upper housing 110: upper inlet
120: upper opening 130: upper opening
140: Inspection window 200: Lower housing
210: Lower open mouth 220: Lower outlet
230: Lower fastener 240: Lower chute
300: inlet module 310: upper inlet pipe
320: intermediate inlet pipe 330: lower inlet pipe
340: upper flange 400: filtering module
410: Filtering net 420: Filter flange
500: collection module 510: collection housing
520: collecting shaft 530: collecting rotary plate
540: Collecting separation plate 550: Collecting discharge pipe
600: rotating means 610: motor
620: rotation sensor 630: supporting member

Claims (6)

An upper housing having an upper inlet through which the inlet air flows and an upper outlet through which the filtered primary air is discharged to the outside;
A lower housing positioned below the upper housing and coupled with the upper housing,
An inflow module positioned inside the upper housing for introducing inflow air;
A filtering module located at least at one side of the inflow module and filtering the inflow air;
A collecting module for collecting the primary foreign substances filtered by the filtering module located below the inflow module and the filtering module inside the lower housing and transferring the filtered foreign substances to a lower portion of the lower housing;
And rotating means for rotating the collecting module,
Wherein the upper housing has an upper opening at a lower portion thereof, and the lower housing has a lower opening at a position corresponding to the upper opening,
The inflow module
An upper inflow pipe coupled to the upper inflow port and an intermediate inflow pipe connected to a lower portion of the upper inflow pipe and having a horizontal cross sectional area increasing toward the lower portion and an upper end coupled to a lower portion of the intermediate inflow pipe, A lower inflow pipe,
Wherein the filtering module includes a filtering net having a plurality of filtering holes and shielding a filtering area formed between a lower inflow pipe of the inflow module and a lower opening of the lower housing,
Wherein the lower inflow pipe has a side connecting hole formed in a shape of a circular arc having a predetermined radius in the upper direction from a lower end of a long side,
Wherein the filtering module is formed of two pieces located on both sides of the lower inflow pipe, one or the other of which is coupled to the side connection hole,
Wherein the curved surface plate has a curved surface shape in which the radius of the arc corresponds to the radius of the side connection hole, and a vertical plate coupled to the other side or one side of the curved surface plate. delete delete The method according to claim 1,
The collecting module
A collecting housing formed in a hollow cylindrical shape and having a collecting opening communicating with the lower opening at an upper portion thereof and having a collecting and discharging port at a lower portion thereof,
A collecting shaft passing through the collecting housing along the axial direction of the collecting housing,
And a collecting rotary plate which is formed in a plurality of plate shapes and which is arranged to be spaced apart from each other in the circumferential direction of the collecting shaft while being coupled to the collecting shaft in the axial direction of the collecting shaft. 5. The method of claim 4,
The collecting module
A collecting spacing plate which is formed in a fan-shaped plate shape and is formed so as to correspond to a spacing angle of a collecting rotating plate adjacent to each other at a central angle, and which is coupled between adjacent collecting rotating plates;
And a collecting and discharging pipe connected between the collecting outlet and the lower opening. 5. The method of claim 4,
The collecting rotary plate
A width corresponding to a radius of the collecting housing and a length corresponding to a length of the collecting housing,
A collecting center plate and a collecting peripheral plate surrounding the collecting center plate,
Wherein the collecting peripheral plate is made of an elastic material and the end portion is in contact with the inner peripheral surface of the collecting housing.

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