KR20220061668A - Auto dust removing apparatus for filter - Google Patents

Abstract

The present invention relates to a device for removing dust of a filter capable of removing the dust attached to the filter (13) by being provided to an upper part of the filter for filtering the dust included in contaminated air. The device for removing dust of a filter comprises: brackets (110, 110a); a vibration generating air supplying unit (120); and a compressed air outlet pipe (150). The brackets (110, 110a) are fixed and combined with an upper surface of the filter (13). The vibration generating air supplying unit (120) is combined to be rotated in upper parts of the brackets (110, 110a); and individually includes: an air inlet pipe (125) into which compressed air flows into the inside, and an air outlet pipe (129) which discharges the compressed air of the inside to the outside. The compressed air outlet pipe (150) is combined with the air outlet pipe (129); is rotated along the outer circumferential surface of the filter (13) with rotation of the vibration generating air supplying unit (120); discharges the compressed air to a surface of the filter (13); and removes the dust attached to the filter (13).

Description

Automatic filter dust removal device {AUTO DUST REMOVING APPARATUS FOR FILTER}

The present invention relates to an automatic filter dust removal apparatus, and more particularly, to an automatic filter dust removal apparatus coupled to a filter used in a dust collector, a dust collector, a dust remover, and the like to automatically remove dust adhering to the filter.

Dust eliminators, dust collectors, and dust removers are used to purify polluted air in various industrial sites, etc. A filter is provided inside the dust collector, dust collector, and dust remover, and contaminated air moves through the filter, dust is attached to the filter surface, and only purified air from which dust is removed is discharged to the outside.

However, conventional dust eliminators, dust collectors, and dust removers do not have a means for cleaning a filter to which dust in the air is attached. That is, when used for a long time, dust is attached to the surface of the filter, thereby reducing the dust removal efficiency. Accordingly, the process of disassembling the dust eliminator or dust collector and manually cleaning the filter or replacing the filter with a new one was required.

Korean Patent Laid-Open Patent No. 10-2020-0049171 "Filter for filter dust collector using catalyst" Korean Patent Laid-Open Patent No. 10-1992-0016417 "Self-cleaning bag filter dust collector"

SUMMARY OF THE INVENTION It is an object of the present invention to provide an automatic filter dust removal device coupled to a filter and capable of automatically removing dust adhering to the filter surface by supplying vibration and compressed air to the filter surface. .

The above objects and various advantages of the present invention will become more apparent from preferred embodiments of the present invention by those skilled in the art.

The object of the present invention can be achieved by a filter dust removal device that is provided on the upper part of a filter that filters out dust contained in polluted air to remove dust attached to the filter 13 . The filter dust removal device of the present invention includes: brackets (110, 110a) fixedly coupled to the upper surface of the filter (13); Vibration generation in which an air inlet pipe 125 through which compressed air is introduced and an air outlet pipe 129 through which the inner compressed air is discharged to the outside is rotatably coupled to the upper portions of the brackets 110 and 110a, respectively. an air supply unit 120; The filter 13 is coupled to the air discharge pipe 129 and rotates along the outer circumferential surface of the filter 13 in conjunction with the rotation of the vibration generating air supply unit 120 to discharge compressed air to the surface of the filter 13 . It is characterized in that it includes a compressed air discharge pipe 150 to remove the dust attached to the.

According to one embodiment, the vibration generating air supply unit 120, the air inlet pipe 125 is formed on the outer peripheral surface of the air supply body 121 and; an air motor 123 rotationally driven by compressed air introduced through the air inlet pipe 125 on the inner upper portion of the air supply body 121; It is provided to rotate in association with the rotation of the air motor 123 at the lower part of the air motor 123, and has an eccentric blade 127b formed eccentrically inside the air supply body 121 to provide the air supply body ( a vibration generating eccentric member 127 for generating vibration so that 121 can be rotated; It is integrally coupled to the lower part of the air supply body 121, and the air discharge pipe 129 is formed on the outer periphery, and by the vibration generated by the vibration generating eccentric member 127, it is on the upper surface of the brackets 110 and 110a. It may include a rotating housing 128 that rotates with respect to the.

According to an embodiment, it further includes a compressed air moving pipe 140 horizontally coupled to the air outlet pipe 129 to supply air to the compressed air outlet pipe 150, wherein the compressed air outlet pipe 150 is an external pipe 151 fixedly coupled to the compressed air pipe 140 and having a plurality of external air discharge holes 151a, 151b, and 151c formed on the same line along the height direction; A plurality of eccentric air discharge holes ( 153a, 153b, 153c) with an inner tube 153; The inner tube 153 and the lower portions of the outer tube 151 are coupled together, and a coupling tube 155 for supporting the inner tube 153 to be rotatable is included, and the plurality of eccentric air discharge holes 153a. , 153b, 153c) may be formed through the inner tube 153 to be deflected in the rotational direction.

The automatic filter dust removal device according to the present invention is provided above the filter and effectively removes dust from the filter by vibration generated by compressed air and spraying of compressed air.

In particular, the compressed air discharge pipe is divided into an outer tube and an inner tube, and compressed air is selectively sprayed at a high pressure into the external air discharge holes of different heights, so that the entire area of the filter can be cleaned evenly.

1 is an exemplary view schematically showing a cross-sectional configuration of a dust collector coupled with an automatic filter dust removal device according to the present invention;
2 is a perspective view showing the configuration of a filter combined with an automatic filter dust removal device according to the present invention;
3 is a perspective view showing the external configuration of the vacuum generating air supply unit of the automatic filter dust removal device according to the present invention;
4 is a perspective view showing the lower configuration of the vacuum generating air supply unit of the automatic filter dust removal device according to the present invention;
5 is a cross-sectional view showing the cross-sectional configuration of the vacuum generating air supply unit of the automatic filter dust removal device according to the present invention;
6 is an exploded perspective view showing the coupling structure of the compressed air moving pipe and the compressed air exhaust pipe of the automatic filter dust removal device according to the present invention;
7 is a cross-sectional view showing the air exhaust structure of the compressed air exhaust pipe of the automatic filter dust removal device according to the present invention;
8 is a cross-sectional view illustrating a process in which the compressed air exhaust pipe of the automatic filter dust removal device according to the present invention discharges compressed air to the filter.

In order to fully understand the present invention, preferred embodiments of the present invention will be described with reference to the accompanying drawings. Embodiments of the present invention may be modified in various forms, and the scope of the present invention should not be construed as being limited to the embodiments described in detail below. This example is provided to more completely explain the present invention to those of ordinary skill in the art. Accordingly, the shapes of elements in the drawings may be exaggerated to emphasize a clearer description. It should be noted that the same members in each drawing are sometimes shown with the same reference numerals. Detailed descriptions of well-known functions and configurations determined to unnecessarily obscure the gist of the present invention will be omitted.

1 is a cross-sectional schematic view showing a schematic configuration of a dust collector 10 to which an automatic filter dust removal device 100 according to the present invention is coupled, and FIG. 2 is an automatic filter dust removal device 100 coupled to a filter 13 according to the present invention. ) is a perspective view showing the configuration of

As shown, the dust collector 10 is coupled to a casing 11 having a polluted air inlet 12 formed therein, a filter 13 provided inside the casing 11, and the upper end of the casing 11 , and a purified air exhaust fan 15 that forms a negative pressure for discharging the purified air A' to the outside. The filter 13 is formed in a cylindrical shape, and the filter support plate 13a is coupled to the upper portion.

When the purified air exhaust fan 15 is driven, a negative pressure is formed inside the casing 11 , and the contaminated air A is introduced into the filter 13 through the contaminated air inlet 12 . Contaminated air (A) introduced into the filter 13 is moved to the outside of the filter 13 across the filter 13 by the negative pressure. In this process, dust (M) contained in the polluted air (A) is attached to the inner wall surface of the filter (13), and the purified air (A') is moved out of the casing (11) through the purified air exhaust fan (15).

The automatic filter dust removal device 100 according to the present invention is provided on the filter support plate 13a to apply vibration to the filter 13 surface and spray compressed air B at the same time to the inner wall surface of the filter 13 . The dust (M) adhering to the filter (13) is separated from the surface. Accordingly, it is possible to periodically clean the filter 13 even if the operator does not manually clean the filter 13 .

As shown in Fig. 2, the automatic filter dust removal device 100 is provided on the brackets 110 and 110a fixedly coupled to the filter support plate 13a above the filter 13, and the brackets 110 and 110a, and rotates. A vibration generating air supply unit 120 that serves as a passage for compressed air (B) while applying vibration, a compressed air inlet pipe 125 for supplying compressed air (B) to the vibration generating air supply unit 120, and vibration A compressed air pipe 140 through which the compressed air (B) is moved from the generated air supply unit 120, and a compressed air discharge pipe that injects the compressed air (B) moved through the compressed air pipe 140 to the filter 13 ( 150).

3 is a perspective view showing the external configuration of the brackets 110 and 110a and the vibration generating air supply unit 120, and FIG. 4 is a bottom perspective view showing the lower configuration of the brackets 110 and 110a and the vibration generating air supply unit 120. .

The brackets 110 and 110a are fixedly coupled to the filter support plate 13a so that the vibration generating air supply unit 120 can be rotated with respect to the filter support plate 13a. A pair of the brackets 110 and 110a is formed of a rectangular plate-shaped material, and a housing insertion groove 111 into which the vibration generating air supply unit 120 is inserted is formed in an area facing each other.

The pair of brackets 110 and 110a is provided with a vibration generating air supply unit 120 inserted into the housing insertion groove 111 facing each other, and the position is fixed by the bracket coupling shaft 112 . The pair of bracket coupling shafts 112 penetrate through the inside of the pair of brackets 110 and 110a and are exposed to the outside, and their positions are fixed by coupling shaft nuts 112a.

At this time, the pair of brackets 110 and 110a is provided to surround the vibration generating air supply unit 120 so as to have a clearance to the extent that the vibration generating air supply unit 120 can be rotated.

A plurality of fastening member insertion holes 111b are formed on the surfaces of the pair of brackets 110 and 110a. The fastening member 113 is fastened to the fastening member insertion hole 111b as shown in FIG. 2 to fix the brackets 110 and 110a to the filter support plate 13a.

5 is a cross-sectional view showing the cross-sectional configuration of the vibration generating air supply unit 120 and the brackets (110, 110a). 3 to 5, the vibration generating air supply unit 120 is rotatably coupled to the brackets 110 and 110a, and is rotated by the compressed air (B) introduced through the compressed air inlet pipe 125 and By generating vibration, the dust (M) attached to the surface of the filter 13 is primarily separated. In addition, the vibration generating air supply unit 120 supplies the compressed air (B) introduced into the compressed air moving pipe (140).

The vibration generating air supply unit 120 includes an air supply body 121 , an air motor 123 rotatably coupled by compressed air B inside the air supply body 121 , and an air supply body 121 . The compressed air inlet hose 130 for supplying the compressed air (B) to the furnace, the air inlet port 126 connecting the compressed air inlet hose 130 and the compressed air inlet pipe 125, and the air motor 123. A vibration generating eccentric member 127 coupled to the lower portion and eccentrically rotated in association with the rotation of the air motor 123 and generating vibration so that the air supply body 121 can be rotated, and the air supply body 121 at the lower part A rotary housing 128 provided and coupled to the brackets 110 and 110a, and a compressed air discharge pipe 150 provided on the outer periphery of the rotary housing 128 to discharge the compressed air (B) to the compressed air moving pipe 140. include

The air supply body 121 and the rotating housing 128 are vertically coupled to form a space in which the compressed air (B) flows. The air supply body 121 is formed of a metal material, and the rotating housing 128 is formed of a plastic material. The air supply body 121 and the rotating housing 128 are coupled in a sealed state so that the compressed air (B) inside does not leak to the outside.

An air inlet pipe 125 through which compressed air (B) flows into the outer periphery of the air supply body 121 is integrally formed. The compressed air inlet hose 130 is coupled to the air inlet pipe 125 to introduce the compressed air (B) to the inside. At this time, an air inlet port 126 is provided at the end of the air inlet pipe 125 and is connected to the compressed air inlet hose 130 .

On the outer periphery of the rotating housing 128, the air inlet pipe 125 and the air outlet pipe 129 are integrally formed in parallel. The compressed air pipe 140 is coupled to the air discharge pipe 129 . An air discharge port 129a is provided between the air discharge pipe 129 and the compressed air moving pipe 140 .

The air motor 123 is coupled to the inside of the air supply body 121 as shown in FIG. The air motor 123 is provided in the form of an impeller and is located in an area corresponding to the air inlet pipe 125 .

An upper bearing 123b is provided on the upper portion of the air motor 123 to support the air motor 123 to rotate smoothly.

A shaft insertion groove 123a into which the motor coupling shaft 127a of the vibration generating eccentric member 127 is inserted is provided at a lower portion of the air motor 123 . A lower bearing 127c is provided on the outside of the shaft insertion groove 123a to support the motor coupling shaft 127a to be rotated.

The vibration generating eccentric member 127 is coupled to the lower portion of the air motor 123, rotates together with the air motor 123, and generates vibration so that the air supply body 121 and the rotating housing 128 are connected to the brackets 110 and 110 by vibration. a) can be rotated about

The vibration generating eccentric member 127 includes a motor coupling shaft 127a coupled to the shaft insertion groove 123a of the air motor 123, and an eccentric blade 127b provided under the motor coupling shaft 127a. . The motor coupling shaft 127a is coupled to the air motor 123 and rotates together in conjunction with the air motor 123 when the air motor 123 is rotated by the supply of compressed air (B).

The eccentric wing 127b is formed to extend under the motor coupling shaft 127a, and is provided eccentrically to generate vibration by rotation. The eccentric blades 127b are provided with different diameters (r1≠r2) on both sides with respect to the motor coupling shaft 127a as shown in FIG. 4 eccentrically. When the eccentric blade 127b is rotated together with the air motor 123 as shown in FIGS. 5A and 5B , vibration is generated in the rotational direction.

At this time, since the brackets 110 and 110a are fixed to the filter support plate 13a, the rotating housing 128 and the air supply body 121 coupled thereto rotate with respect to the brackets 110 and 110a. The rotating housing 128 and the air supply body 121 are rotated while shaking by vibration, and these vibrations and vibrations are transmitted to the filter 13 through the filter support plate 13a. Accordingly, the dust M attached to the inside of the filter 13 is primarily separated from the filter 13 .

The compressed air inlet hose 130 is provided between the compressor 131 and the air inlet pipe 125 as shown in FIG. 1 to supply the compressed air (B) to the air inlet pipe 125 .

The compressed air pipe 140 is coupled to the air discharge pipe 129 as shown in FIG. 2 to supply the compressed air (B) to the compressed air discharge pipe 150 . The compressed air pipe 140 and the filter support plate 13a are horizontally provided on the upper surface, and the compressed air discharge pipe 150 is formed on the outside of the filter 13 in a vertical direction. The compressed air pipe 140 and the compressed air discharge pipe 150 are connected by a bent connection pipe 141 .

Since the compressed air pipe 140 is coupled to the air outlet pipe 129, the air supply body 121 and the rotating housing 128 rotate with respect to the filter support plate 13a in conjunction with the rotation with respect to the brackets 110 and 110a. .

In addition, the compressed air discharge pipe 150 coupled to the compressed air pipe 140 also rotates along the outer circumferential surface of the filter 13 to spray the compressed air (B) into the entire area of the filter 13 .

6 is an exploded perspective view showing the compressed air discharge pipe 150 in an exploded configuration, and FIG. 7 is a cross-sectional view showing the cross-sectional configuration of the compressed air discharge pipe 150 .

As shown, the compressed air discharge pipe 150 includes an external pipe 151 coupled to the bent connector pipe 141, and is provided inside the external pipe 151 and is provided inside the external pipe 151 by compressed air (B). Including an inner tube 153 rotated in, and a coupling tube 155 coupled to the outer tube 151 so that the inner tube 153 can be rotated.

The outer tube 151 is provided to have a length corresponding to the height of the filter 13 . The upper end of the outer tube 151 is coupled to the bent connector 141 , and the lower end of the outer tube 151 is inserted into the coupling tube 155 . A plurality of external air discharge holes (151a, 151b, 151c) are provided on the outer peripheral surface of the outer tube (151) at regular intervals along the height direction. A plurality of external air discharge holes (151a, 151b, 151c) are disposed coaxially at different heights of the external tube (151).

The inner tube 153 is provided with the same length inside the outer tube 151 . The inner tube 153 is rotatably coupled to the coupling tube 155 by the lower bottom surface of the rotating shaft 155a as shown in FIG. A plurality of eccentric air exhaust holes (153a, 153b, 153c) are provided on the outer peripheral surface of the inner tube (153) at the same height as the plurality of external air exhaust holes (151a, 151b, 151c). A plurality of eccentric air discharge holes (153a, 153b, 153c) are arranged at different angles along the circumferential direction.

In the compressed air discharge pipe 150 of the present invention, three eccentric air discharge holes 153a, 153b, and 153c are formed in the inner pipe 153 . The three eccentric air outlet holes (153a, 153b, 153c) are respectively disposed at 120° intervals at different heights corresponding to the external air outlet holes (151a, 151b, 151c).

As shown in (b) of Figure 7, each of the eccentric air discharge holes (153a, 153b, 153c) are formed eccentrically in the oblique direction with respect to the plate surface of the inner tube (153). When the inner tube 153 is rotated and the first eccentric air outlet hole 153a is positioned at the same position as the first outer air outlet hole 151a as shown in FIGS. 7 (a) and (b), the inner tube (153) The compressed air (B) supplied to the inside is discharged to the outside through the first eccentric air discharge hole (153a) through the first external air discharge hole (151a).

On the other hand, as shown in (b) of Figure 7, the second eccentric air exhaust hole (153b) and the third eccentric air exhaust hole (153c) is a second external air exhaust hole (151b) and a third external air exhaust hole ( 151c) and the position are staggered, so the compressed air (B) discharged therefrom is tangentially supplied to the space between the outer tube 151 and the inner tube 153 in an eccentric direction.

In this way, the inner tube 153 is rotated in the horizontal direction inside the outer tube 151 by the compressed air (B) supplied in a tangential direction between the inner tube 153 and the outer tube 151 . As the inner tube 153 is rotated, the compressed air B is sequentially supplied from the second eccentric air outlet hole 153b and the third eccentric air outlet hole 153c to the second outer air outlet hole 151b and the third outer air hole. It is discharged to the discharge hole (151c).

In this way, the compressed air (B) is sequentially discharged to one external air discharge hole (151a, 151b, 151c) having different heights, and is supplied to the surface of the filter (13) as shown in FIG. The compressed air (B) moves from the outside of the filter 13 to the inside and separates the dust M attached to the inner wall surface of the filter 13 from the filter 13 .

Since the compressed air (B) is discharged only through one external air discharge hole (151a, 151b, 151c), the discharge pressure of the compressed air (B) is concentrated and not dispersed and comes into contact with the filter 13, so that the surface of the filter 13 is The dust M can be effectively removed.

In addition, the inner tube 153 is rotated and compressed air (B) is uniformly discharged to the filters 13 of different heights. In addition, since the compressed air discharge pipe 150 rotates along the outer circumferential surface of the filter 13 in conjunction with the rotation of the vibration generating air supply unit 120 , dust from the entire filter 13 can be uniformly removed.

A process for removing dust from the filter 13 using the filter dust removing apparatus 100 according to the present invention having such a configuration will be described with reference to FIGS. 1 to 8 .

As shown in FIG. 2 , the filter dust removal device 100 of the present invention is coupled to the filter support plate 13a provided on the upper portion of the cylindrical filter 13 . The brackets 110 and 110a of the filter dust removal device 100 are fixed to the filter support plate 13a by the fastening member 113 . In addition, the compressed air inlet hose 130 is connected to the air inlet pipe 125 , and the compressed air inlet hose 130 is connected to the compressor 131 .

The compressor 131 is provided with a solenoid valve (not shown) driven by an input signal of an operator. The compressor 131 is operated by driving a solenoid valve (not shown), and compressed air B is supplied to the vibration generating air supply unit 120 .

A compressed air pipe 140 is horizontally arranged for a certain length in the air discharge pipe 129 of the vibration generating air supply unit 120 , and the compressed air discharge pipe 150 is vertically provided at an end of the compressed air pipe 140 .

It is arranged to be spaced apart from the outer wall surface of the filter 13 of the compressed air discharge pipe 150 at regular intervals.

As shown in FIG. 1 , when the purified air exhaust fan 15 of the dust collector 10 is rotated, a negative pressure is generated inside the casing 11 and the contaminated air A is introduced into the contaminated air inlet 12 .

After the polluted air (A) flows into the filter (13), it moves from the inner wall surface to the outer wall surface of the filter (13) to remove the dust (M), and the purified air (A') is the purified air exhaust fan (15). It is discharged to the outside of the casing 11 through the.

When this polluted air purification process is repeated for a set time, as shown in FIG. 1 , a solenoid valve (not shown) is driven and the compressed air (B) is vibrated through the compressed air inlet hose 130 , the vibration generating air supply unit 120 is supplied with

As shown in (a) of Figure 5, compressed air (B) is introduced into the air motor 123 through the air inlet pipe (125). Accordingly, the air motor 123 is rotated, and the vibration generating eccentric member 127 coupled to the lower portion of the air motor 123 is also rotated.

It is rotated by the eccentric shape of the eccentric blade 127b of the vibration generating eccentric member 127 and vibration is generated, and the vibration generating air supply unit 120 is rotated in the horizontal direction inside the brackets 110 and 110a. The vibration generated by the vibration generating eccentric member 127 is transmitted to the brackets 110 and 110a and the filter 13 through the vibration generating air supply unit 120 . Thereby, the dust M adhering to the filter 13 is primarily removed by vibration.

When the vibration generating air supply unit 120 rotates, the compressed air pipe 140 and the compressed air discharge pipe 150 coupled thereto also rotate along the circumferential direction of the filter 13 as shown in FIG. 2 .

In this process, as shown in FIG. 8, the compressed air (B) supplied to the compressed air exhaust pipe 150 is directed to the external air exhaust holes 151a, 151b, and 151c of the external pipe 151 through the internal pipe 153. It is discharged and is sprayed into the filter (13). Compressed air (B) is sprayed to the filter (13), and the dust (M) attached to the inner wall surface of the filter (13) is removed from the filter (13) secondarily.

Here, the compressed air (B) is discharged to the external air discharge holes (151a, 151b, 151c) of different heights according to the positions of the plurality of eccentric air discharge holes (153a, 153b, 153c) formed in the inner tube (153). Compressed air (B) is evenly sprayed over the entire area of the filter 13 to clean the filter (13).

When the cleaning of the filter 13 is completed, the driving of the solenoid valve (not shown) is stopped, the operation of the compressor 131 is stopped, and the filter cleaning process using the compressed air (B) is terminated.

As described above, the automatic filter dust removal device according to the present invention is provided on the upper part of the filter and effectively removes dust from the filter by vibration generated by compressed air and injection of compressed air.

In particular, the compressed air discharge pipe is divided into an outer tube and an inner tube, and compressed air is selectively sprayed at a high pressure into the external air discharge holes of different heights, so that the entire area of the filter can be cleaned evenly.

The embodiments of the automatic filter dust removal device of the present invention described above are merely exemplary, and those of ordinary skill in the art to which the present invention pertains will appreciate that various modifications and equivalent other embodiments are possible therefrom. You will know well. Therefore, it will be well understood that the present invention is not limited to the form mentioned in the above detailed description. Therefore, the true technical protection scope of the present invention should be determined by the technical spirit of the appended claims. Moreover, it is to be understood that the present invention covers all modifications, equivalents and substitutions falling within the spirit and scope of the invention as defined by the appended claims.

10: dust collector 11: casing
12: polluted air inlet 13: filter
13a: filter support plate 15: purified air exhaust fan
100: filter dust removal device 110, 110a: bracket
111: housing insertion groove 111b: fastening member insertion hole
112: bracket coupling shaft 112a: coupling shaft nut
113: fastening member 120: vibration generating air supply unit
121: air supply body 123: air motor
123a: shaft insertion groove 123b: upper bearing
125: air inlet pipe 126: air inlet port
127: vibration generating eccentric member 127a: motor coupling shaft
127b: eccentric wing 127c: lower bearing
128: rotary housing 128a: bracket insertion end
129: air exhaust pipe 129a: air exhaust port
130: compressed air inlet hose 131: compressor
140: compressed air pipe 141: bent connector pipe
150: compressed air exhaust pipe 151: external pipe
151a, 151b, 151c: external air exhaust hole 153: inner pipe
153a, 153b, 153c: eccentric air exhaust hole 155: coupling pipe
155a: axis of rotation
A: polluted air
A' : Purified air
B: compressed air
M: dust

Claims (3)

In the filter dust removal device provided on the upper part of the filter for filtering the dust contained in the polluted air to remove the dust attached to the filter (13),
brackets (110, 110a) fixedly coupled to the upper surface of the filter (13);
Vibration generation in which an air inlet pipe 125 through which compressed air is introduced and an air outlet pipe 129 through which the inner compressed air is discharged to the outside are respectively rotatably coupled to the upper portions of the brackets 110 and 110a. an air supply unit 120;
It is coupled to the air discharge pipe 129 and rotates along the outer circumferential surface of the filter 13 in conjunction with the rotation of the vibration generating air supply unit 120 to discharge compressed air to the surface of the filter 13 to discharge the compressed air to the filter (13). Filter dust removal device comprising a compressed air discharge pipe (150) to remove the dust attached to the.
According to claim 1,
The vibration generating air supply unit 120,
an air supply body 121 having the air inlet pipe 125 formed on an outer circumferential surface;
an air motor 123 rotationally driven by compressed air introduced through the air inlet pipe 125 on the inner upper portion of the air supply body 121;
It is provided to rotate in association with the rotation of the air motor 123 at the lower part of the air motor 123, and has an eccentric blade 127b formed eccentrically inside the air supply body 121 to provide the air supply body ( a vibration generating eccentric member 127 for generating vibration so that 121 can be rotated;
It is integrally coupled to the lower part of the air supply body 121, the air discharge pipe 129 is formed on the outer periphery, and the upper surface of the brackets 110 and 110a by the vibration generated by the vibration generating eccentric member 127. Filter dust removal device, characterized in that it comprises a rotating housing (128) that rotates with respect to.
3. The method of claim 2,
It further includes a compressed air pipe 140 that is horizontally coupled to the air discharge pipe 129 and supplies air to the compressed air discharge pipe 150,
The compressed air discharge pipe 150,
an external pipe 151 fixedly coupled to the compressed air pipe 140 and having a plurality of external air discharge holes 151a, 151b, and 151c formed on the same line along the height direction;
A plurality of eccentric air discharge holes ( 153a, 153b, 153c) with an inner tube 153;
The inner tube 153 and the lower portion of the outer tube 151 are coupled together, and a coupling tube 155 for supporting the inner tube 153 to be rotatable is included,
The plurality of eccentric air discharge holes (153a, 153b, 153c) are formed through the surface of the inner tube (153) to be deflected in the rotational direction.

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