KR102591183B1 - Water pipe cleaning device - Google Patents

Abstract

The present invention relates to a water pipe cleaning device, comprising: a compressed air supply unit (10) that produces and supplies compressed air; A compressed air filtration unit (20) that filters foreign substances contained in the compressed air produced and discharged from the compressed air supply unit (10); It includes a compressed air injection unit 30 that injects the compressed air filtered in the compressed air filtration unit 20 into the water pipe that needs internal cleaning to create a vortex inside the water pipe.
According to the present invention, compressed air filtered by a filtration device is injected into the water pipe to create a vortex, which has the effect of efficiently cleaning the water pipe and preventing secondary contamination after cleaning.

Description

Water pipe cleaning device

The present invention relates to a water pipe cleaning device, and more specifically, to a device that injects compressed air filtered by a filtration device into the water pipe to create a vortex, thereby efficiently cleaning the water pipe and preventing secondary contamination after cleaning. It relates to a water pipe cleaning device.

When water pipes that supply tap water are used for a long time after installation, as they age, various minerals and foreign substances contained in the tap water are deposited as sludge or the inside of the pipe is oxidized, forming rust, etc., and these harden to form scale. A layer is formed.

Like this, when a scale layer is formed inside the aged water pipe and gradually thickens and hardens over time, it interferes with the smooth flow of tap water and causes a decrease in water pressure. As the scale layer attached inside the water pipe dissolves in tap water, it becomes thicker and hardens. Because it causes contamination of tap water, regular cleaning of water pipes is necessary.

Conventional methods of cleaning water pipes include a method of physically removing the scale layer by inserting physical means into the water pipe, and a method of chemically removing the scale layer by inserting chemicals such as a clearing agent into the water pipe. there was.

However, the conventional physical method of cleaning the inside of the water pipe by inserting physical means into the water pipe not only has the disadvantage of increasing the cost due to the insertion and operation of the physical means, but also has the disadvantage of increasing the cost of the water pipe when the water pipe is damaged during the cleaning process. There are also frequent drawbacks.

In addition, the conventional chemical method of cleaning the inside of the water pipe by injecting chemicals into the water pipe not only incurs a cost burden due to the use of chemicals, but also involves the burden of costs due to the use of chemicals, as well as the removal of residual chemicals inside the water pipe after handling and cleaning the chemicals. It had the disadvantage of requiring considerable care to remove.

Therefore, in recent years, a device that supplies compressed air and water to the inside of a water pipe to clean the inside of the water pipe has been developed and is mainly used.

However, the conventional water pipe cleaning device using compressed air has the disadvantage of not having excellent cleaning performance because it simply cleans the inside of the water pipe using a flow of water mixed with compressed air.

In addition, the compressed air (Plant Air) produced by the air compressor (COMPRESSOR) for cleaning water pipes contains various impurities such as moisture, oxidized oil, and carbon, so when such compressed air is supplied as is inside the water pipes. There is a problem that causes secondary contamination in water pipes.

Public Utility Model No. 20-2001-0000077

In order to solve the conventional shortcomings as described above, the present invention is a water supply system that injects compressed air filtered by a filtration device into the water pipe to create a vortex, thereby efficiently cleaning the water pipe and preventing secondary contamination after cleaning. The purpose is to provide a pipe cleaning device.

In order to achieve the above-mentioned purpose, the water pipe cleaning device of the present invention,

A compressed air supply unit (10) that produces and supplies compressed air;

A compressed air filtration unit (20) that filters foreign substances contained in the compressed air produced and discharged from the compressed air supply unit (10);

A compressed air injection unit (30) that injects the compressed air filtered by the compressed air filtering unit (20) into the water pipe that needs internal cleaning to create a vortex inside the water pipe; Includes.

In one embodiment, the compressed air filtration unit 20,

A filter unit (201) that filters foreign substances contained in the compressed air produced and discharged from the compressed air supply unit (10);

A pressure control tank (202) that adjusts the discharge pressure of the compressed air filtered in the filter unit (201); It is characterized by including.

In one embodiment, the pressure control tank 202 is,

Pressure control means (203) for automatically adjusting the internal pressure to automatically adjust the discharge pressure of the compressed air filtered in the filter unit (201); It is characterized by further comprising:

In one embodiment, the compressed air filtration unit 20,

A sensor unit 204 that inspects the quality of compressed air discharged from the outlet of the pressure control tank 202;

An opening/closing valve (205) whose opening/closing direction is automatically adjusted according to the inspection value provided by the sensor unit (204);

A return pipe (206) connected to one side outlet of the on-off valve (205) to return compressed air to the filter unit (201);

A discharge pipe (207) connected to the other outlet of the on-off valve (205) and discharging compressed air to the compressed air injection unit (30); It is characterized in that it further includes.

In one embodiment, the compressed air injection unit 30,

A connecting member (301) attached to a water pipe that requires internal cleaning;

A compressed air supply pipe (302) installed between the compressed air filtering unit (20) and the upper flange of the connecting member (301);

A vortex generating member 303 that is detachably installed inside the upper flange of the connecting member 301 and generates a vortex of compressed air supplied through the compressed air supply pipe 302; It is characterized by including.

In one embodiment, the connecting member 301 is characterized as a Y-shaped elbow.

In one embodiment, the vortex generating member 303 is,

A coupling pipe (303a) detachably coupled to a coupling groove formed inside the upper flange of the connecting member (301), the lower end of which is partially submerged in tap water passing through the connecting member (301);

Guide vanes (303b) formed in a spiral shape on the inner peripheral surface of the coupling pipe (303a);

A rotary blade (303c) installed on the inner lower part of the coupling pipe (303a) and rotated by compressed air while partially submerged in tap water; It is characterized by including.

In one embodiment, the coupling pipe 303a is characterized in that the lower end is formed in a wedge shape.

In one embodiment, the rotary blades 303c are formed long along the longitudinal direction of the coupling pipe 303a, and the lower end of the rotary blades 303c is immersed in tap water passing through the connecting member 301. .

In one embodiment, the rotary blade 303c is,

An upper wing (303c2) formed on the upper side of the rotary shaft (303c1) of the rotary wing (303c) on which the discharge pressure of the compressed air passing through the coupling pipe (303a) acts.

A lower wing (303c3) formed below the rotating shaft (303c1) of the rotating blade (303c) and submerged in tap water passing through the connecting member (301); It is characterized by including.

In one embodiment, the rotary blade 303c is further provided with a plurality of through holes 303c4 penetrating the blade surface.

In one embodiment, the vortex generating member 303 is,

A fine bubble generating unit 304 for generating fine bubbles at the lower end of the coupling pipe 303a; It is characterized in that it further includes.

In one embodiment, the vortex generating member 303 is,

The lower end of the coupling pipe (303a) further includes an angle adjusting portion that adjusts the discharge angle of compressed air.

In one embodiment, the angle adjusting unit,

A corrugated pipe portion (305a) formed at the lower end of the coupling pipe (303a);

At least one guide tube (305b) formed on the outer surface of the coupling tube (303a);

At least one angle adjustment wire (305C) whose one end is fixed to one side of the corrugated pipe portion (305a) and the other end of which is discharged to the outside through the guide pipe (305b) to adjust the angle of the corrugated pipe portion (305a) through tension adjustment. ; It is characterized by including.

The water pipe cleaning device of the present invention has the effect of improving the removal efficiency of the scale layer present in the water pipe by rotating compressed air to form a vortex.

In addition, by filtering the compressed air injected into the water pipes to prevent contamination of the compressed air, secondary contamination due to compressed air after cleaning the water pipes is prevented, thereby further improving the cleanliness inside the water pipes.

1 is a configuration diagram according to a first embodiment of the present invention.
Figure 2 is an exemplary diagram showing a compressed air injection unit according to the first embodiment of the present invention.
Figure 3 is an exemplary diagram showing another example of a rotary blade according to the first embodiment of the present invention.
Figure 4 is an exemplary diagram showing a fine bubble generator according to a second embodiment of the present invention.
Figure 5 is an exemplary diagram showing an angle adjustment unit according to a third embodiment of the present invention.

Below, with reference to the attached drawings, embodiments of the present invention will be described in detail so that those skilled in the art can easily implement the present invention.

Since the description of the present invention is only an example for structural or functional explanation, the scope of the present invention should not be construed as limited by the examples described in the text.

In other words, since the embodiments can be modified in various ways and can take various forms, the scope of rights of the present invention should be understood to include equivalents that can realize the technical idea.

In addition, the purpose or effect presented in the present invention does not mean that a specific embodiment must include all or only such effects, so the scope of the present invention should not be understood as limited thereby.

All terms used in the description of the present invention have the same meaning as generally understood by a person of ordinary skill in the field to which the present invention pertains, unless otherwise defined.

Terms defined in commonly used dictionaries should be interpreted as consistent with the meaning they have in the context of the related technology, and cannot be interpreted as having an ideal or excessively formal meaning unless clearly defined in the present invention.

In addition, terms such as “first” and “second” are only used to distinguish different components, and are not limited by the order of manufacture, and the scope of rights should not be limited by these terms.

Figure 1 is a configuration diagram according to a first embodiment of the present invention, Figure 2 is an exemplary diagram showing a compressed air injection unit according to a first embodiment of the present invention, and Figure 3 is a rotational diagram according to a first embodiment of the present invention. This is an illustration showing another example of wings.

Description will be made with reference to FIGS. 1 to 3.

The water pipe cleaning device of the present invention according to the first embodiment includes a compressed air supply unit (10), a compressed air filtration unit (20), and a compressed air injection unit (30).

In order to produce compressed air and supply it to the compressed air filtration unit 20, the compressed air supply unit 10 preferably uses an air compressor that sucks in atmospheric air and compresses it above a certain pressure to generate compressed air. .

The compressed air filtering unit 20 includes a filter unit 201 and a pressure regulating tank 202 to filter foreign substances contained in compressed air produced and discharged from the compressed air supply unit 10.

The filter unit 201 filters foreign substances contained in compressed air produced and discharged from the compressed air supply unit 10.

At this time, the filter unit 201 includes a pre-filter that primarily filters large particles such as moisture contained in compressed air compressed at high pressure in the compressed air supply unit 10, and fine particles in the compressed air that have passed through the pre-filter. It is preferable that it consists of a HEPA filter or Ulpa filter that performs secondary filtration.

In addition, it is desirable that all filters used in the filter unit 201 use filters certified by HACCP from the Korea Food Safety Management Certification Institute.

The pressure control tank 202 is a chamber type with a predetermined size and controls the discharge pressure of the compressed air filtered in the filter unit 201.

In one embodiment, the pressure control tank 202 may further be provided with a pressure control means 203 for automatically adjusting the internal pressure in order to automatically control the discharge pressure of the compressed air filtered in the filter unit 201.

The pressure control means 203 may include one or more of a safety valve, a pressure reducing valve, a pressure control valve, and a venting valve. Since the function or operation of each valve is well known, a detailed description thereof will be omitted.

In one embodiment, the compressed air filtration unit 20 may further include a sensor unit 204, an opening/closing valve 205, a return pipe 206, and a discharge pipe 207.

The sensor unit 204 is installed on one side of the discharge part of the pressure control tank 202 and inspects the quality (moisture, oil, foreign substances, microorganisms, etc.) of the compressed air discharged from the discharge part.

The opening/closing valve 205 has one inlet part and a plurality of outlet parts, and automatically adjusts the direction of the outlet part from which compressed air flowing into the inlet part is extracted according to the inspection value provided by the sensor unit 204.

Therefore, it is desirable to use an electronic valve that is electronically controlled as the opening/closing valve 205 by processing the signal provided from the sensor unit 204.

The return pipe 206 is connected to one side outlet of the on-off valve 205 and returns the compressed air introduced through the inlet of the on-off valve 205 to the filter unit 201, thereby allowing the compressed air to pass through the pressure control tank 202. The compressed air can be filtered by sending it back to the filter unit 201.

The discharge pipe 207 is connected to the other outlet of the on-off valve 205 and finally discharges compressed air to the compressed air injection unit 30.

Therefore, the contamination level of the compressed air that has passed through the filter unit 201 and the pressure control tank 202 is finally inspected using the sensor unit 204, and if contamination of the compressed air is detected as a result of the inspection, it is returned to the filter unit 201. By sending and re-filtering, the air quality of the compressed air finally supplied to the compressed air injection unit 30 can be kept cleaner.

The compressed air injection unit 30 injects the compressed air filtered by the compressed air filtration unit 20 into the water pipe that requires internal cleaning, and a connecting member 301 and a compressed air supply pipe to create a vortex inside the water pipe. (302), and includes a vortex generating member (303).

The connecting member 301 is installed in a water pipe that requires internal cleaning.

At this time, since the connecting member 301 must be connected to the water pipe buried in the ground and at the same time connected to the compressed air filtration unit 20, it is preferable to be a Y-shaped elbow, but it is not limited to this.

The compressed air supply pipe 302 is installed between the compressed air filtration unit 20 and the upper flange of the connecting member 301 and supplies the compressed air finally discharged from the compressed air filtration unit 20 into the connecting member 301. .

The vortex generating member 303 is detachably installed inside the upper flange of the connecting member 301 and generates a vortex of compressed air supplied through the compressed air supply pipe 302.

In one embodiment, the vortex generating member 303 includes a coupling pipe (303a), a guide blade (303b), and a rotary blade (303c).

The coupling tube 303a is detachably coupled to a coupling groove formed inside the upper flange of the connecting member 301.

At this time, the coupling pipe 303a is installed at an angle along the flow direction of tap water passing through the connecting member 301 due to the shape of the connecting member 301, which is a Y-shaped elbow, and its lower end passes through the connecting member 301. Partially submerged in tap water.

Therefore, when compressed air passes through the coupling pipe 303a and combines with tap water passing through the connecting member 301, the compressed air is combined along the flow direction of the tap water, making it possible to further increase the flow rate and hydraulic pressure of the tap water.

In one embodiment, the lower end of the coupling tube 303a is formed in a wedge shape, thereby increasing the discharge pressure of the compressed air discharged through the coupling tube 303a.

The guide vanes 303b are formed in a spiral shape on the inner peripheral surface of the coupling tube 303a, and may be formed at least one or more, but many are formed in a conformal radial shape so that the compressed air passing through the interior of the coupling tube 303a is guided by the guide vanes ( 303b), it passes while forming a vortex.

The rotary blade 303c is installed on the inner lower part of the coupling pipe 303a and is installed to rotate by compressed air while partially submerged in tap water.

In one embodiment, the rotary blades 303c are formed to be long along the longitudinal direction of the coupling pipe 303a, and the lower end of the rotary blades 303c is submerged in tap water passing through the connecting member 301.

In another embodiment, the rotary blade 303c may include an upper blade 303c2 and a lower blade 303c3.

The upper wing (303c2) is formed on the upper side of the rotating shaft (303c1) of the rotary wing (303c) and acts on the discharge pressure of compressed air passing through the coupling pipe (303a).

The lower wing 303c3 is formed below the rotating shaft 303c1 of the rotary wing 303c and is submerged in tap water passing through the connecting member 301.

Therefore, as the compressed air passing through the coupling pipe 303a passes through the rotary blade 303c, the rotary blade 303c is rotated by the discharge pressure of the compressed air, and as a result, the compressed air passing through the connecting member 301 Vortex bubbles are generated inside the tap water by the rotating blade 303c submerged in tap water, and as these vortex bubbles pass through the inside of the water pipe, they apply physical stimulation to the inside of the water pipe, thereby removing various foreign substances attached to the inside of the water pipe. As it is removed, efficient cleaning of the inside of the water pipe is achieved.

In one embodiment, the rotary blade 303c may be further provided with a plurality of through holes 303c4 penetrating the blade surface.

That is, the through holes 303c4 are spaced apart from each other at regular intervals, and it is preferable that the through holes 303c4 be formed to have a diameter of 20 to 30 μm, but it is not limited thereto.

Therefore, as the compressed air passing through the coupling pipe 303a passes through the rotary blade 303c, the rotary blade 303c is rotated by the discharge pressure of the compressed air, and as a result, the compressed air passing through the connecting member 301 Vortex bubbles are generated in tap water, and as the through hole (303c4) formed on the wing surface of the rotary blade (303c), which is partially submerged in tap water, is further provided, the tap water and air are broken into smaller pieces, generating fine bubbles, and thus, the water pipe. The cleaning performance of the interior can be further improved.

Here, fine bubbles refer to small air bubbles less than 50㎛ in size. As the size of the bubbles decreases, the contact area increases and cleaning efficiency increases.

Figure 4 is an exemplary diagram showing a fine bubble generator according to a second embodiment of the present invention.

Although the description will be made with reference to FIG. 4, detailed descriptions of components overlapping with the above-described embodiments and components having the same reference numerals will be omitted.

The water pipe cleaning device of the present invention according to the second embodiment may further include a fine bubble generating unit 304.

The fine bubble generator 304 may be provided on one side of the lower end of the coupling pipe 303a, and it is preferable to use an ultrasonic generator.

That is, while the fine bubble generator 304 provided at the lower part of the coupling pipe 303a is immersed in tap water passing through the connecting member 301, compressed air generates a vortex through the lower part of the coupling tube 303a. During the discharge process, the fine bubble generator 304 uses ultrasonic waves to generate fine bubbles inside the tap water, thereby further improving the cleaning performance of the inside of the water pipe.

Figure 5 is an exemplary diagram showing an angle adjustment unit according to a third embodiment of the present invention.

The description will be made with reference to FIG. 5, but detailed descriptions of components overlapping with the above-described embodiments and components having the same reference numerals will be omitted.

The water pipe cleaning device of the present invention according to the third embodiment may further include an angle adjustment unit that adjusts the discharge angle of compressed air.

The angle adjusting portion is installed at the lower end of the coupling pipe 303a and includes a corrugated pipe portion 305a, a guide pipe 305b, and an angle adjusting wire 305C to adjust the discharge angle of the compressed air.

The corrugated pipe portion 305a is formed integrally with a predetermined length at the lower end of the coupling pipe 303a.

At least one guide tube 305b is formed on the outer surface of the coupling tube 303a and is formed along the longitudinal direction of the coupling tube 303a.

One end of the angle adjustment wire (305C) is fixed to one side of the corrugated pipe portion (305a), and the other end is discharged to the outside through the guide pipe (305b), thereby adjusting the tension of the angle adjusting wire (305C) to the corrugated pipe portion (305a). ) can be adjusted.

Of course, the tension of the angle adjustment wire (305C) can be adjusted automatically by pulling it manually by the operator or by providing a separate tension adjustment means using a motor, etc.

Therefore, when compressed air passes through the coupling pipe 303a and is combined with tap water passing through the connecting member 301, the discharge angle of the compressed air is adjusted using the angle adjuster so that the compressed air passing inside the water pipe for cleaning is By being able to control the flow rate and hydraulic pressure of the mixed tap water, it is possible to prevent damage or breakage of water pipes, as well as adjust the cleaning power inside the water pipes.

Although the present invention has been described above with respect to limited embodiments, the scope of the present invention is not limited thereto, and the technical idea of the present invention and the claims below are understood by those skilled in the art in the technical field to which the present invention pertains. Various modifications and improvements made within the scope of equivalent scope will also fall within the scope of the present invention.

A: Water pipe 10: Compressed air supply unit
20: compressed air filtration unit 201: filter unit
202: pressure control tank 203: pressure control means
204: Sensor unit 205: Open/close valve
206: return pipe 207: discharge pipe
30: Compressed air injection unit 301: Connection member
302: Compressed air supply pipe 303: Vortex generating member
303a: Coupler 303b: Guide vane
303c: rotary blade 303c1: rotary shaft
303c2: upper wing 303c3: lower wing
303c4: Through hole 304: Fine bubble generation unit
305a: Corrugated pipe part 305b: Guide pipe
305c: Angle adjustment wire

Claims (5)

A compressed air supply unit (10) that produces and supplies compressed air;
A compressed air filtration unit (20) that filters foreign substances contained in the compressed air produced and discharged from the compressed air supply unit (10);
A compressed air injection unit (30) that injects the compressed air filtered by the compressed air filtering unit (20) into the water pipe that needs internal cleaning to create a vortex inside the water pipe; It is composed including,
The compressed air filtration unit 20,
A filter unit 201 that filters foreign substances contained in compressed air produced and discharged from the compressed air supply unit 10;
A pressure control tank (202) that adjusts the discharge pressure of the compressed air filtered in the filter unit (201);
A sensor unit 204 that inspects the quality of compressed air discharged from the outlet of the pressure control tank 202;
An opening/closing valve (205) whose opening/closing direction is automatically adjusted according to the inspection value provided by the sensor unit (204);
A return pipe (206) connected to one side outlet of the on-off valve (205) to return compressed air to the filter unit (201);
A discharge pipe (207) connected to the other outlet of the on-off valve (205) and discharging compressed air to the compressed air injection unit (30); A water pipe cleaning device comprising a.
delete delete According to paragraph 1,
The compressed air injection unit 30,
A connecting member (301) attached to a water pipe that requires internal cleaning;
A compressed air supply pipe (302) installed between the compressed air filtering unit (20) and the upper flange of the connecting member (301);
A vortex generating member 303 that is detachably installed inside the upper flange of the connecting member 301 and generates a vortex of compressed air supplied through the compressed air supply pipe 302; A water pipe cleaning device comprising a.
According to paragraph 4,
The vortex generating member 303 is,
A coupling pipe (303a) detachably coupled to a coupling groove formed inside the upper flange of the connecting member (301), the lower end of which is partially submerged in tap water passing through the connecting member (301);
Guide vanes (303b) formed in a spiral shape on the inner peripheral surface of the coupling pipe (303a);
A rotary blade (303c) installed on the inner lower part of the coupling pipe (303a) and rotated by compressed air while partially submerged in tap water; A water pipe cleaning device comprising a.