KR101553146B1 - Non-motorized auto-cleaning filter device - Google Patents

Abstract

The present invention relates to a non-motorized automatic cleaning filter apparatus, and more particularly, to a filterless filter having a filter housing having an inlet and an outlet and including a receiver; A filter unit housed in a receiving portion of the filter housing, for filtering the raw water introduced from the inflow portion and discharging the filtered raw water to the discharge portion; A differential pressure sensor mounted on the filter housing for sensing a differential pressure between the inlet and the filter; And cleaning means for drawing a plurality of cleaning balls into the filter portion according to the differential pressure by the differential pressure sensing portion to remove foreign substances from the filter portion by friction between the cleaning balls and the filter portion.
That is, according to the present invention, when a predetermined differential pressure between the front and rear ends of the filter is reached, the impeller mounted on the lower end of the receiver is vertically lowered by the driving cylinder operated by electric or hydraulic pressure, and the cleaning balls are drawn into the filter part, The balls are rotated while the impeller is rotated by the raw water flowing into the filter portion. By removing foreign substances through friction with the filter portion due to the swirling force of the cleaning balls, the cleaning force is secured by non-motive force, .
In the present invention, the impeller which is rotated by the flow of the incoming raw water is introduced into the inlet portion of the filter housing, so that the raw water introduced into the filter portion is reduced in pressure while passing through the impeller and thus the air dissolved in the raw water, it is eluted in a micro bubble form. The eluted microbubbles rupture on the filter surface. The free radicals and the pressure difference cause detergency, sterilization, and degradation of organic matter, and the leached air is collected in the dissolved air trapping section located at the upper part of the filter And then discharged to the outside through an appropriate pressure reducing passage. In this way, a micro-bubble is generated to reduce the amount of dissolved air, to improve cleaning power, and to reduce scale and fouling occurrence rate.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a non-

The present invention is not limited to the conventional cleaning apparatuses that secure the cleaning power through the driving device. In addition, in the cleaning of the filter unit, energy is saved and reliability is improved by securing the cleaning power through the flow of raw water, And more particularly, to a non-powered automatic washing and filtering apparatus capable of improving washing power by utilizing micro bubbles or the like.

In general, most of the refining and chemical industries, thermal and nuclear power generation industries, and water treatment industries require the transfer of fluid in the production process and facilities.

In this case, whether or not the presence of the foreign material in the fluid to be used affects the yield and performance of the production process, and also determines the internal contamination of the piping and the mechanical elements, thereby greatly affecting the performance of the system.

Therefore, these fluids must be supplied in sufficiently purified high-purity fluids.

However, when the pressure of the circumference is insufficient, the filter not only has a low efficiency of the filter, but also the mesh of the filter is clogged with time.

If the hole of the filter is clogged like this, the filtering system is stopped, the filter must be cleaned or replaced, and the filter must be mounted again to operate.

Further, when the filter replacement operation is required, the replacement of the filter increases the cost, which increases the burden of the maintenance cost.

An automatic washing and filtering system that solves the above-mentioned problems has been manufactured and sold to date. The washing washing system is classified into a pressure back washing method, a mechanical washing method, and a pressure difference method using a Bernoulli method.

In the case of the back pressure cleaning method, a part of the filtrate is flowed back to the filter through the pump and the cylinder, thereby cleaning the foreign matters filtered by the filter. In this method, in order to secure pressure backwash driving force, There is a problem that energy consumption and reliability are lowered.

In addition, in the case of the backwashing method, only a part of the foreign matter is washed, and the washing performance is insufficient. In addition, there is a disadvantage that the system operation must be stopped during washing.

In order to solve such a problem, there is a method of solving the problem of stopping the system operation by rotating the operation filter chamber and the cleaning filter chamber by installing a multistage filter chamber. However, in such a case, the system becomes complicated, And the like.

Next, the mechanical cleaning method is a method of rotating the filter and scraping and removing the foreign matter filtered through a scraper or a brush installed on the inside or outside of the filter. In this case, a driving device is required to rotate the filter.

In addition, there is a problem that the reliability is lowered due to an increase in energy consumption and a driving device. Conversely, there is a way to rotate the scraper or brush, but this also causes the same problem.

In addition, the Bernoulli method uses the Bernoulli principle in which the disc is moved up and down by a disc having a predetermined gap to the inside of the filter, thereby lowering the pressure when the fluid to be filtered flows at a high speed through the gap.

In this method, when the pressure inside the filter is temporarily lowered, it is an automatic washing method in which the foreign matter filtered by the filter is desorbed while the washing water flows inward from the outside of the filter.

In this case, as the disk moves downward, the flow area of the raw water is temporarily reduced to increase the load of the pump to reduce the load of the pump and to temporarily supply irregular filtrate, Which causes deterioration and deteriorates the cleaning ability.

Korean Patent No. 10-0530097 (Nov. 14, 2005) Korean Patent No. 10-1169436 (2012.07.23.)

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems,

In the normal operation, when the impeller which has closed the receiver of the cleaning means reaches the predetermined differential pressure in the front and rear ends of the filter sensed by the differential pressure sensing unit, the filter is lowered to the inlet of the filter housing to open the receiver. At this time, the washing balls contained in the receiver descend and are drawn into the filter unit, and the impeller rotates due to the flow of the raw water flowing into the filter unit, thereby inducing cyclone flow in the filter unit. The cleaning balls drawn into the filter unit due to the cyclone flow generate a swirling force. At this time, foreign substances in the filter unit are removed by friction between the cleaning balls and the filter unit, thereby securing the cleaning force by the non- The purpose of the project is to achieve the goal.

In addition, according to the present invention, the rotating impeller is introduced by the flow of raw water flowing through the inlet of the filter housing, so that the raw water flowing into the filter portion is reduced in pressure while passing through the impeller, And is eluted in the form of a micro bubble having a diameter of several tens of μm. The eluted microbubbles are ruptured on the filter surface. In this case, free radical generation and pressure difference lead to improvement of detergency and disinfection and decomposition of organic matter, and the eluted air is collected in a dissolved air collecting part located at the upper part of the filter And then discharged to the outside through an appropriate pressure reducing passage. As described above, another object of the present invention is to lower the amount of dissolved air by introducing an impeller to generate microbubbles, to improve cleaning power, and to reduce scale and fouling occurrence rate.

Another object of the present invention is to improve the cleaning efficiency by allowing the cleaning balls to be uniformly arranged vertically in the filter unit by changing the specific gravity between the cleaning balls of the cleaning means.

Further, the gap between the blade gap of the impeller and the lower end of the receiver of the cleaning means is formed to be smaller than the cross-sectional area or the diameter of the cleaning balls, thereby preventing the cleaning balls from being separated from each other. The purpose.

A non-motorized automatic cleaning filter apparatus according to the present invention includes: a filter housing having an inlet and an outlet, the filter housing including a receiver; A filter portion accommodated in a receiving portion of the filter housing, for filtering the raw water introduced from the inflow portion and discharging the filtered raw water to the discharge portion; A pressure difference sensing unit mounted on the filter housing and sensing a differential pressure between the inlet and the filter unit; And cleaning means for drawing the plurality of cleaning balls into the filter portion according to the differential pressure by the differential pressure sensing portion to remove foreign substances from the filter portion through friction between the cleaning balls and the filter portion.

The impeller is mounted on the filter housing according to the present invention and accommodates cleaning balls, and an impeller which moves up and down according to the differential pressure by the differential pressure sensing unit and opens and closes the inlet of the receiver. When the pressure difference reaches a certain pressure difference, the flow of the raw water flowing down through the inlet portion is lowered to the inlet of the filter housing to induce the cyclone flow in the filter portion.

The impeller of the cleaning means according to the present invention descends to the inlet of the filter housing when the differential pressure by the differential pressure sensing unit reaches a certain differential pressure and rotates by the flow of the raw water flowing in from the inlet to generate microbubbles inside the filter unit .

The cleaning balls of the cleaning means according to the present invention are characterized in that they have different specific gravity so as to be vertically uniformly arranged on the filter portion.

The cleaning means according to the present invention further includes a driving unit for transmitting power for raising and lowering the impeller.

The upper end of the filter portion and the lower end of the receiver according to the present invention have spaced-apart gaps, and the gaps are formed to be smaller than the cross-sectional area or diameter of the cleaning balls.

The gap between the blades constituting the impeller of the cleaning means according to the present invention is formed to be smaller than the cross-sectional area or the diameter of the cleaning balls.

The filter housing further includes an exhaust air discharge pipe for collecting dissolved air eluted from the filter housing and discharging the air eluted through the proper pressure reducing passage to the outside.

In the non-motorized automatic washing and filtering apparatus according to the present invention, when the differential pressure between the front and rear ends of the filter reaches a predetermined differential pressure, the impeller mounted at the lower end of the receiver is vertically lowered by the driving cylinder operated by electric or hydraulic pressure, And the cleaning balls drawn into the filter unit are rotated while the impeller is rotated by the raw water flowing into the filter unit and the foreign substances are removed through the friction with the filter unit due to the turning force of the cleaning balls, The energy saving effect can be achieved.

In addition, according to the present invention, the rotating impeller is introduced by the flow of raw water flowing through the inlet of the filter housing, so that the raw water flowing into the filter portion is reduced in pressure while passing through the impeller, And is eluted in the form of a micro bubble having a diameter of several tens of μm. The eluted microbubbles are ruptured on the filter surface. In this case, free radical generation and pressure difference lead to improvement of detergency and disinfection and decomposition of organic matter, and the eluted air is collected in a dissolved air collecting part located at the upper part of the filter And then discharged to the outside through an appropriate pressure reducing passage. As described above, according to the present invention, by introducing an impeller to generate micro bubbles, it is possible to reduce the amount of dissolved air, improve washing power, and reduce scale and fouling occurrence rate.

In addition, according to the present invention, the cleaning balls can be uniformly arranged vertically in the filter unit by changing the specific gravity between the cleaning balls of the cleaning means, thereby improving the cleaning efficiency.

Further, the gap between the blade gap of the impeller and the lower end of the filter unit and the lower end of the receiver of the cleaning unit is formed to be smaller than the cross-sectional area or diameter of the cleaning balls, thereby preventing detachment of the cleaning balls.

1 is a perspective view of a non-motorized automatic washing and filtering apparatus according to the present invention,
2 is a perspective view showing a state in which the cleaning means of the filtering device according to the present invention is operated,
3 is a perspective view showing various modifications of the cleaning balls in the cleaning means of the filtering device according to the present invention,
4 and 5 are conceptual diagrams showing the characteristics and effects of the micro bubble generated by the impeller of the cleaning means according to the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a non-motorized automatic washing and filtering apparatus according to the present invention will be described in detail with reference to the accompanying drawings.

1 and 2, the non-powered automatic washing filter apparatus according to the present invention includes:

A filter unit 10 accommodated in the filter housing 10; a differential pressure sensing unit 30 for sensing a differential pressure between the inlet unit 11 and the filter unit 20; And a cleaning means (40) provided with a cleaning means (41).

1 and 2, the filter housing 10 according to the present invention includes:

A discharge port 13 for discharging filtered water filtered by the filter unit 20 is provided on a side surface of the inflow port 11,

A feed pipe for introducing raw water is connected to the inlet 11 of the filter housing 10.

1 and 2, the filter unit 20 according to the present invention includes:

And the raw water introduced into the filter housing 10 is discharged to the discharge portion 13 of the filter housing 10 in a lateral direction.

In this case, the filter unit 20 is accommodated in the filter housing 10, and a discharge flow path F is formed between the outer surface of the filter unit 20 and the inner surface of the filter housing 10.

The raw water flowing into the filter portion 20 through the inlet portion 11 of the filter housing 10 is filtered and discharged to the outside of the filter portion 20 due to the pressure difference between the inside of the filter portion 20 and the discharge flow passage ,

The discharged filtered water is discharged to the discharge portion 13 through the discharge flow path F.

At this time, the foreign substances contained in the raw water are filtered by the filter unit 20. However, the filtered foreign matter adheres to the filter unit 20 to increase the pressure inside the filter unit 20 and to lower the filtration efficiency, There is a problem that the filter unit 20 is blocked and the original purpose can not be performed.

In this case, in order to clean the filter unit 20, the system needs to be restarted after the system is shut down and the filter is cleaned and reinstalled.

Therefore, in the present invention, it is desired to provide the cleaning means 40 capable of performing the cleaning operation of the filter unit 20 without stopping the operation of the system, and also performing the cleaning operation through the self inflow force of the raw water.

The washing means 40 can be operated at a certain differential pressure by sensing the differential pressure inside the inlet portion 11 and the filter portion 20 in order to grasp the operating time of the washing means 40. [

1 and 2, the differential pressure sensing unit 30 according to the present invention includes:

A differential pressure between the inlet portion 11 of the filter housing 10 and the filter portion 20 is sensed and the washing means 40 is operated in accordance with the differential pressure to enable automatic washing.

The differential pressure sensing unit 30 is mounted on a control unit C provided in the filter housing 10. The control unit C is connected to the foreign matter discharge valve 50 and the driving unit 47 of the cleaning means 40, Lt; / RTI >

The first and second channels are connected to the inlet portion 11 and the filter portion 20 of the filter housing 10 and the OPAMP is used for receiving the two signals from the respective channels. And applied to the differential pressure terminal, the signal of the difference is obtained and displayed.

When the differential pressure thus obtained reaches a certain differential pressure, that is, when the pressure of the filter unit 20 rises by foreign substances or the like, the differential pressure gradually increases. At this time, the control unit C automatically detects the cleaning time point, And the driving unit 47 of the cleaning means 40 are simultaneously operated.

1 and 2, the cleaning means 40 according to the present invention comprises:

The washing balls 41 are drawn into the filter unit 20 and the washing balls 41 and the filter unit 20 are operated at the same time, And the foreign matter is removed by friction.

The cleaning means 40 for this purpose includes a receiver 43 in which the cleaning balls 41 are accommodated and an impeller 45 which opens and closes the inlet of the receiver 43.

The receptacle 43 of the cleaning means 40 is fixed inside the upper end of the filter housing 10 and is configured in the form of a net smaller than the cross sectional area of the cleaning balls 41 so that the cleaning balls 41 are not released to the outside.

The impeller 45 serving as an opening and closing means of the receiver 43 of the washing means 40 receives the signal from the control unit C and descends when the differential pressure sensed by the differential pressure sensing unit 30 is equal to or higher than the reference differential pressure At this time, when the inlet of the receiver 43 is opened and the differential pressure of the filter unit 20 becomes an appropriate differential pressure, the impeller 45 rises and the inlet of the receiver 43 is closed after the cleaning ball is recovered.

That is, the impeller 5 of the washing means 40 is used as a base means of the receiver 43 during normal operation to prevent the washing balls 41 from escaping from the receiver 43, And is lowered by the driving rod 47b of the driving part up to the inflow part 11 of the main body 10.

At this time, the impeller 45 is rotated by the flow of the raw water flowing through the inlet 11 to induce the cyclone flow CF of the raw water flowing into the filter unit 20.

That is, when the impeller 45 opens the receiver 43, the cleaning balls 41 vertically descend along the impeller and are drawn into the filter unit 20. After the impeller 45 is drawn in, And the cleaning balls 41 are rotated by the cyclone flow CF of FIG.

Accordingly, the foreign substances, scale, and fouling that are attached to the filter unit 20 through contact or friction between the rotating cleaning balls 41 and the inside of the filter unit 20 are removed.

When the foreign matter of the filter unit 20 is removed, the pressure inside the filter unit 20 is lowered. At this time, when the differential pressure sensed by the differential pressure sensing unit 30 reaches the reference differential pressure, the impeller 45 rises The cleaning balls 41 are collected again in the receiver 43 and the impeller 45 closes the inlet of the receiver 43 to end the cleaning operation.

In this case, the gaps of the plurality of blades 45a constituting the impeller 45 are formed to be smaller than the cross-sectional area of the cleaning balls 41, so that the cleaning balls 41 are separated through the blades 45a of the impeller 45 It is desirable to prevent such a problem.

Further, a driving unit 47 connected to the control unit C for raising and lowering the impeller 45 is provided.

The driving unit 47 includes a driving cylinder 47a at the upper end of the filter housing 10 and a driving rod 47b connected to the cylinder rod of the driving cylinder 47a. The impeller 45 is mounted so as to be idle at the lower end of the oil pan 47b.

When the drive cylinder 47a of the drive unit 47 is operated according to the signal of the differential pressure sensing unit 30, the drive rod 47b is moved up or down. At this time, the impeller 45 also moves up or down, 41 can be discharged from the receiver 43, or can be collected.

In particular, the impeller 45 of the cleaning means 40 generates air in the form of micro bubbles (MB), which is dissolved in the raw water by pressure reduction while the raw water passes.

This is because the raw water flowing into the inlet of the filter housing is reduced in pressure as it passes through the impeller, and thus the air dissolved in the raw water is eluted in the form of micro bubbles with a diameter of several tens of micrometers by the impeller.

The microbubbles thus eluted are ruptured on the filter surface as shown in FIGS. 4 and 5, and the amount of dissolved air is reduced by bringing about improvement in detergency, disinfection and decomposition of organic matter by free radical generation and pressure difference As well as to improve the cleaning power and reduce the scale and fouling occurrence rate.

The leached air is collected by the leaking air collecting unit located above the filter unit 20 and then discharged to the outside through the leaking air discharge flow pipe 60.

It is known that about 20% of oxygen is contained in air and about 8 ppm of oxygen is dissolved in water exposed to air at 25 ° C.

The effect of oxygen on the rate of corrosion is found to be dissolved oxygen, which is the most important factor to cause corrosion of steel in neutral fresh water of pH 4 ~ 10.

Dissolved Oxygen not only causes general corrosion in steel, but also can cause local corrosion by Oxygen Condenser Battery, so it is advantageous to remove dissolved oxygen in air as much as possible.

Therefore, it is preferable to introduce the impeller 50 as described above to reduce the amount of dissolved oxygen to prevent corrosion of the member, and to increase the cleaning efficiency by generating micro bubbles (MB).

Further, the cleaning balls 41 for removing foreign substances from the filter unit 20 according to the present invention can be manufactured in various shapes and sizes,

For example, in the case of a conventional tubular heat exchanger, cleaning balls 41 in the form of a sponge ball are introduced, and in the case of a facility operating at a high temperature and high pressure, the cleaning balls 41, (41) is preferably used.

Also, as shown in FIG. 3, a plurality of protrusions 41a and / or grooves 41b may be formed on the outer surface of the cleaning balls 41, or protrusions and grooves may be formed together.

In another modification, the outer shape of the cleaning balls 41 may be formed in the form of teeth 41c, or the teeth 41c and the grooves 41a may be formed at the same time.

That is, the cleaning balls 41 can easily remove the foreign substances adhered to the filter unit 20, the scale, the fouling, and the like when the filter unit 20 is in contact with or rubbed against the filter unit 20, It is preferable to have a shape that can be used.

In particular, the cleaning balls 41 preferably have different specific gravities or densities so that the cleaning balls 41 can be brought into contact with the entire filter unit 20.

That is, the cleaning balls 41 must be continuously arranged from the upper part to the lower part of the filter part 20 so that even contact with the filter part 20 is possible. The washing balls 41 are moved up and down from the upper portion to the lower portion of the filter portion 20 continuously in the up and down direction depending on the specific gravity or density after the cleaning balls 41 are introduced into the filter portion 20 by varying specific gravity or density. So that a uniform cleaning force can be ensured.

1 and 2, the foreign matter discharge valve 50 according to the present invention includes:

As described above, the differential pressure sensed by the differential pressure sensing unit 30 is opened when the differential pressure reaches a predetermined differential pressure, and is closed when the cleaning operation by the cleaning means 40 is completed.

A foreign matter discharge valve 50 is connected to the control unit C and a foreign matter discharge pipe 51 is provided laterally at an upper portion of the filter housing 10 to mount a foreign matter discharge valve 50 therein.

The impeller 45 of the washing means 40 is opened and the washing balls 41 are introduced into the filter unit 20 simultaneously with the opening of the foreign substance discharge valve 50 by the control unit C, Is performed.

At this time, the foreign substances or the like removed from the filter unit 20 by the cleaning balls 41 are discharged to the outside through the foreign matter discharge valve 50 and the foreign matter discharge pipe 51.

When the washing liquid is completely removed by the washing means 40, that is, when the differential pressure returns to the initial differential pressure, the discharge valve 50 is closed by receiving a signal from the control unit C, The impeller 45 ascends and collects the cleaning balls 41 into the inside of the receiver 43 to end the cleaning operation.

In this case, a ball valve or a butterfly valve or similar or equivalent opening / closing device may be used as the foreign matter discharge valve 50.

Further, the lower end of the receiver 43 of the cleaning means 40 according to the present invention is installed so as to be spaced apart from the upper end of the filter unit 20,

The clearance not only allows the cleaning balls 41 to be smoothly cleaned up to the upper end of the filter unit 20 but also forms a space between the lower end of the water body and the upper end of the filter unit 20 so that foreign matter can be smoothly discharged. .

That is, when the lower end of the receiver 43 is introduced into the filter unit 20 or arranged at the same position as the upper end of the filter unit 20, contact between the cleaning ball 41 and the upper end of the filter unit 20, This is to solve this problem because it will interfere.

If the gap is larger than the cross sectional area of the cleaning balls 41, the cleaning balls 41 may be separated from the receptacle 43, It is preferable to prevent the detachment.

In this case, the cleaning balls 41 can be formed into a circular shape or a non-circular shape,

The clearance between the blades 45a of the impeller 45 and the clearance between the receiver 43 and the filter unit 20 are formed to be smaller than the diameter of the cleaning balls 41 do.

The foregoing description is merely illustrative of the technical idea of the present invention, and various changes and modifications may be made by those skilled in the art without departing from the essential characteristics of the present invention. Therefore, the embodiments disclosed in the present invention are intended to illustrate rather than limit the scope of the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments. The scope of protection of the present invention should be construed according to the following claims, and all technical ideas within the scope of equivalents should be construed as falling within the scope of the present invention.

C: Control unit MB: Micro bubble
CF: cyclone flow F: discharge flow
10: Filter housing
11: inlet 13: outlet
20:
30: Differential pressure sensing unit
40: Cleaning means
41: cleaning bowl 41a: projection
41b: groove 43: receptor
45: impeller 45a: blade
47: driving part 47a: driving cylinder
47b: drive rod
50: Foreign matter discharge valve
51: Discharge tube
60: Exhaust air discharge pipe

Claims (8)

A filter housing (10) having an inlet (11) and an outlet (13) and including a receiver;
A filter unit 20 accommodated in a receiving portion of the filter housing 10 and filtering the raw water introduced from the inlet portion 11 and discharging the filtered raw water to the outlet portion 13;
A differential pressure sensing part (30) mounted on the filter housing (10) and sensing a differential pressure between the inlet part (11) and the filter part (20); And
A plurality of cleaning balls 41 are drawn into the filter unit 20 in accordance with the differential pressure of the differential pressure sensing unit 30 and the cleaning balls 41 and the filter unit 20 (40) for removing foreign substances from the filter unit (20) by causing friction with the filter unit (20).
Wherein the non-motorized automatic cleaning filtering device comprises:
The method according to claim 1,
A receiver 43 mounted on the filter housing 10 and receiving the cleaning balls 41,
And an impeller (45) which ascends and descends according to a differential pressure by the differential pressure sensing unit (30) and opens and closes an inlet of the receiver (43).
3. The method of claim 2,
The impeller 45 of the washing means 40 descends to the inlet 11 of the filter housing 10 when the differential pressure by the differential pressure sensing unit 30 reaches a predetermined pressure difference and flows into the inlet 11 from the inlet 11, (MB) and a cyclone flow (CF) in the filter unit (20) by rotatingly driven by the flow of the raw water.
The method according to claim 1,
Wherein the cleaning balls (41) of the cleaning means (40) are different in specific gravity so as to be vertically disposed on the filter unit (20).
The washing machine according to claim 2, wherein the cleaning means (40)
Further comprising a driving unit (47) for transmitting power to move the impeller (45) up and down.
3. The method of claim 2,
The upper end of the filter portion 20 and the lower end of the receiver 43 have a gap formed therebetween,
Wherein the clearance is formed to be smaller than a cross-sectional area of the cleaning balls (41).
3. The method of claim 2,
Wherein the clearance between the blades (45a) constituting the impeller (45) of the cleaning means (40) is smaller than the cross sectional area of the cleaning balls (41).
The method of claim 3,
(60) for collecting dissolved air eluted from the filter housing (10) and discharging the air eluted through the appropriate pressure reducing flow path to the outside. Cleaning filter device.

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