KR101031830B1 - Apparatus for cleaning a filter of dust collector - Google Patents

Abstract

The filter blading device of the dust collecting device according to the present invention relates to a device for cleaning the filter of the dust collecting device, wherein a nozzle which is positioned inside the filter and in which air is injected is formed at both ends, and the inside is a hollow tube through which air flows. A first link member, one end of which is in communication with a central portion of the first link member, and rotatably installed, an inside of which is a second link member which is a hollow tube through which air flows, and one end of which is in communication with the other end of the second link member, The second link member is rotatably installed, and the other end includes a third link member into which compressed air is introduced from the outside, and a nozzle pump unit for supplying compressed air to the other end of the third link member. According to this, the first link member is rotated by the jet propulsion force of the air, and the second link member is rotated by the rotational force of the first link member. As a result, the air is injected as the air is injected while rotating the entire inner circumferential surface of the filter. While covering the whole, it is possible to remove contaminants such as dust and dirt, thereby maintaining the overall performance of the dust collector at an optimal state.

Dust Collector, Filter, Cleaning, Blade, Blading, Dust Collector

Description

Filter cleaning device for dust collector {APPARATUS FOR CLEANING A FILTER OF DUST COLLECTOR}

The present invention relates to a filter blading device for a dust collecting device, and more particularly, to a filter blading device for cleaning a filter of a dust collecting device to continuously maintain the effect of collecting dust. .

In general, industrial facilities that require a clean area, etc. are provided with a dust collecting device 10 for collecting dust as shown in Figure 1 to filter the dust to filter 17 so that only clean air flows in, it is necessary to include dust As air passes through the filter 17, foreign matter such as dust is filtered out by the filter 17, and only clean air is supplied through the filter 17.

But. As long time use of the dust collector 10 causes dust to cling to or accumulate in the filter 17, the micropores of the filter 17 are blocked, so that not only the dust is filtered through the filter but also the inflow of air is blocked. There exists a problem that the function of the dust collector 10 falls remarkably.

In order to solve such a problem, it is necessary to remove dust accumulated or stuck on the filter 17 of the dust collecting device 10. For this purpose, air in the longitudinal direction of the filter 17 is conventionally shown in FIG. The air injection unit 19 provided with the nozzle 19a is installed so that the injection is carried out.

The air injection unit 19 periodically injects air through the nozzle 19a toward the filter 17 to eliminate the problem of accumulation or accumulation on the filter 17. A separate nozzle pump (not shown) is required for this purpose. .

Referring to the operation of the conventional dust collector 10 configured as described above, the outside air is introduced into the air inlet 13 by the operation of the pump 11, the filter through the lower portion of the filter 17 through the inlet duct 15 (17) flowed into the inside, the air introduced into the filter 17 is supplied to the outside through the outflow duct 18 while the dust and the like filtered through the filter 17. At this time, air is strongly injected from the air spray nozzle 19a which is fixed periodically, and the dust adhered by the filter 17 is removed.

However, this conventional filter cleaning method has the following problems.

First, as the air is injected only at the position defined in the lengthwise direction of the filter 17, the dust at the position where the air is injected may be removed, but the dust at the position where the air is sprayed is not easily removed and thus the filter ( There is a problem that the cleaning state of 17) becomes incomplete and the performance of the dust collector 10 is degraded.

Second, there is a problem that the filter 17 may not be cleaned because the nozzle 19a may be blocked by dust or the like as the air is sprayed while the nozzle 19a to which the air is injected is fixed.

Third, when air is injected from the nozzle 19a to clean the filter 17, the function of the dust collecting device 10 should be stopped, that is, the external air is sucked from the dust collecting device 10 and the filter 17 After the dust is removed, the clean air should be introduced, but the operation of the entire dust collector 10 is stopped while the air is sprayed from the nozzle 19a due to the large number of air spray nozzles 19a located inside the filter 17. There is a problem that should be.

The present invention was derived to solve the above problems, to provide a filter cleaning device of the dust collecting apparatus that can uniformly remove the dust on the filter of the dust collecting apparatus to maintain the performance of the entire dust collecting apparatus in an optimal state. The purpose is.

The filter blading device of the dust collecting device according to the preferred embodiment of the present invention relates to a device for cleaning the filter of the dust collecting device, and nozzles are disposed at both ends of the inside of the filter and are sprayed with air. A first link member which is a hollow tube; A second link member whose one end is in communication with a central portion of the first link member and is rotatably installed and has a hollow tube through which air flows; A third link member having one end fixedly connected to the other end of the second link member, the second link member rotatably installed, and the other end into which compressed air is introduced from the outside; And a nozzle pump unit supplying compressed air to the other end of the third link member.

As a result, as the compressed air supplied from the outside is injected through the nozzles of the first link member through the third link member and the second link member, contaminants such as dust or the like accumulated on the filter can be easily removed.

In addition, according to a preferred embodiment of the present invention, the nozzle is formed in the rotatable direction in the air blowing direction of the nozzle of the first link member by the action of the air is injected into the first link member.

As a result, the first link member is rotated by the jet propulsion force of the air, and the second link member is rotated by the rotational force of the first link member. It can remove contaminants such as dust, while covering the cover, thereby maintaining the overall performance of the dust collector in an optimal state.

Moreover, as for the said air injection direction, it is more preferable that a nozzle is formed so that it may face the inner wall side of the said filter.

As a result, the air injected from the nozzle may be injected into the filter inner circumferential surface as well as the rotational driving force of the first link member, so that it is possible to more effectively remove contaminants such as dust or the like deposited on the filter inner circumferential surface.

According to the present invention described above, as the compressed air supplied from the outside is injected through the nozzle of the first link member via the third link member and the second link member, contaminants such as dust or the like accumulated on the filter are accumulated. It can be easily removed.

In addition, the first link member is rotated by the jet propulsion force of the air and the second link member is rotated by the rotational force of the first link member, as a result, the entire inner circumference of the filter as the air is injected while rotating the entire inner peripheral surface of the filter. It can remove contaminants such as dust, while covering the cover, thereby maintaining the overall performance of the dust collector in an optimal state.

In addition, the air injected from the nozzle may be injected into the filter inner circumferential surface as well as the rotational driving force of the first link member, so that it is possible to more effectively remove contaminants such as dust or the like accumulated on the filter inner circumferential surface.

In addition, since the air injection nozzle is rotated, it is possible to minimize the problem that the nozzle is clogged with contaminants such as dust, so that the filter can be cleaned more effectively, and thus the overall performance of the dust collector can be maintained at an optimal state.

In addition, since air may be injected to a part of the inside of the filter, air is injected from a plurality of injection nozzles collectively as a whole, thereby solving the problem of stopping the operation of the entire dust collector when the filter is cleaned.

Hereinafter, a filter blading device of a dust collecting device according to a preferred embodiment of the present invention will be described with reference to the accompanying drawings.

1 is a view schematically showing a dust collecting device, FIG. 3 is a view schematically showing a filter cleaning device according to a preferred embodiment of the present invention, FIG. 4 is a view for explaining the operation of the filter cleaning device shown in FIG. FIG. 5 is a view for explaining a cleaning trajectory of the filter cleaning device illustrated in FIG. 3.

1 and 3 to 5, the filter cleaning device 100 of the dust collector 10 according to the preferred embodiment of the present invention may include a first link member 110 and a second link member 120. , The third link member 130 and the nozzle pump unit 140.

The first link member 110 is a nozzle 111 to which compressed air is injected is formed at both ends to remove contaminants such as dust or accumulated in the filter 17, the first link member 110 The inside of the nozzle 111 is formed as a hollow tube so that the compressed air flows, and the injection direction of the nozzle 111 is the nozzle (1) in the rotatable direction by the propulsion force by the air injected by the first link member 110 as its rotational axis. 111) is preferred.

More preferably, the air jetting direction of the nozzle 111 is directed toward the filter 17 side in addition to the jetting direction in which propulsion force may be generated, thereby directly removing dust or the like deposited on the filter 17.

The second link member 120 is connected such that one end thereof is in communication with the center point of the first link member 110, that is, air is supplied to the first link member 110, and the connection point is connected to the first link member 110. It is rotatably connected and the second link member 120 is also formed in a hollow tube through which compressed air flows. On the other hand, the other end of the second link member 120 is in communication with the third link member 130 is rotatably connected.

As described above, one end of the third link member 130 communicates with the other end of the second link member 120, that is, air is supplied to the second link member 120, and the connection point is connected to the second link member 120. 120 is rotatably connected and the third link member 130 is also formed in a hollow tube such that the inside thereof may be supplied with compressed air by an external nozzle pump unit 140. At this time, unlike the first link member 110 and the second link member 120, the third link member 130 is fixed to the outside so as not to rotate.

The nozzle pump unit 140 supplies compressed air so that the compressed air is injected through the nozzle 111 to clean the inner circumferential surface of the filter 17. The nozzle pump unit 140 supplies the compressed air to the third link member 130. In communication with the other end.

Referring to the operation of the filter cleaning device 100 configured as described above, the compressed air generated by the nozzle pump unit 140 is supplied to the other end of the third link member 130 and passes through the inner space of the third link member. The filter 17 passes through the second link member 120 in communication with one end of the 130, and passes through the first link member 110 in communication with the second link member 120 through a nozzle 111 formed at one end thereof. Sprayed to the inner peripheral surface side of the dirt, such as dirt on the filter 17 is removed.

At this time, the injection force of the compressed air injected through the nozzle 111 generates a driving force for rotating the first link member 110 to rotate the first link member 110, such that the first link member 110 The rotational force rotates the second link member 120 to interlock, and the rotational trajectory covers the entire inner circumferential surface of the filter 17 as shown in FIG. 5.

Thus, conventionally, air is injected at a position where the nozzle 19a is fixed to cover the entire inner circumferential surface of the filter 17, and only dust adhered to the inner circumferential surface of the filter 17 at the fixed position where the nozzle 19a is sprayed is removed to remove the filter ( By solving the problem that 17 is not uniformly cleaned as a whole, the entire inner circumference of the filter 17 can be cleaned, so that the performance of the entire dust collector 10 can be maintained in an optimal state.

Referring to the operation of the dust collector 10 is provided with such a filter cleaning device 100, first, when the pump 11 is operated as shown in FIG. 1 while the air is introduced into the air inlet 13, the inlet duct 15 Through the lower portion of the filter 17, the filter 17 is introduced into the filter 17, and the air introduced into the filter 17 passes through the filter 17, and dust and the like are filtered through the outlet duct 18. It is supplied to the outside. At this time, the nozzle pump unit 140 is driven periodically or continuously so that the compressed air is injected into the nozzle 111 of the first link member 110 and the first link member 110 and the second link member 120 influence each other. In other words, the entire inner circumference of the filter 17 is uniformly cleaned, so that the performance of the entire dust collector 10 may be optimally maintained.

As mentioned above, although the preferred embodiment of the present invention has been shown and described, the present invention is not limited to the above-described embodiment, and any person having ordinary skill in the art to which the present invention pertains without departing from the claims. Various modifications and variations will be possible.

1 is a view showing a general dust collecting device,

2 is a view showing an apparatus for cleaning a filter of a conventional dust collector;

3 is a view showing a filter cleaning apparatus according to a preferred embodiment of the present invention;

4 is a view for explaining the operation of the filter cleaning device shown in FIG.

FIG. 5 is a diagram for describing a cleaning trajectory of the filter cleaning device illustrated in FIG. 4.

Description of the Related Art

10: dust collector 11: pump

13 air inlet 15 inlet duct

17 filter 18 outflow duct

19: nozzle unit 19a: nozzle

Claims (3)

A device for cleaning a filter of a dust collector, Nozzles positioned inside the filter and into which air is sprayed are formed at both ends, the first link member being a hollow tube through which air flows; A second link member whose one end is connected to the center point of the first link member and is rotatably installed and has a hollow tube through which air flows; A third link member having one end fixedly connected to the other end of the second link member, the second link member rotatably installed, and the other end into which compressed air is introduced from the outside; And And a nozzle pump unit configured to supply compressed air to the other end of the third link member. The nozzle of the first link member, The air injection direction is a direction rotatable by the propulsion force of the air to which the first link member is injected as its center point as the rotation axis, and is formed to face the inner wall side of the filter, The injection force of the compressed air injected through the nozzle generates a driving force for rotating the first link member to rotate the first link member, and the rotational force of the first link member rotates the second link member to interlock. And the rotational trajectory of the filter is the entire inner circumferential surface of the filter. delete delete

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