KR102541340B1 - Apparatus for purifying radon from water comprising helical water flow path - Google Patents

Abstract

According to the present invention, a radon purification device including a spiral flow path comprises: a housing member made of metal and formed in a cylindrical shape to have a space inside; an ejector member installed to spray water into the housing member; an air outlet formed at an upper end part of the housing member; a flow path forming member formed to allow the water sprayed from the ejector member to drop while rotating and flowing; a water dispersion member for dispersing the water which drops from the flow path forming member; and a discharge member for discharging the water from the housing member. In addition, the flow path forming member is formed to allow the water sprayed from the ejector member to flow in a spiral shape, and a drop opening for dropping water is formed at the bottom of the flow path forming member. According to the present invention, a device for purifying radon can be constructed in a small and compact manner, and can be easily installed in remote areas or existing buildings. Moreover, a concentration of radon can be detected in real time and utilized, and the dispersion efficiency of water to be purified can be increased, thereby increasing the efficiency of purifying harmful substances other than radon.

Description

Radon water purification device including a spiral flow path {APPARATUS FOR PURIFYING RADON FROM WATER COMPRISING HELICAL WATER FLOW PATH}

The present invention relates to a radon water purification device, and more particularly, to a radon water purification device including a spiral flow path configured to increase the efficiency of removing radon from water while being compact.

Radon is one of the natural radioactive substances and is a major carcinogen defined by the World Health Organization.

Therefore, continuous exposure to radon is undesirable for health, so it is recommended to manage the radon concentration in indoor air in recent years.

On the other hand, in island areas or remote areas where water supply is not supplied, their own simple water supply is operated by village or region.

The simple water supply is used after pumping up groundwater by operating a pump or drawing natural valley water and storing it in a water tank.

Therefore, in the simple waterworks, water from various intake sources is stored in a tank and then supplied to each household for use.

As described above, water obtained from various water intake sources may be exposed to various pollutants, and thus water treatment before supplying to each household is essential.

Therefore, it is also necessary to remove radon from water introduced from a water intake source, and besides, radon is also preferably removed from cooling and heating water used for heating and cooling buildings.

However, in the case of conventional water purification facilities for removing radon from water, there is a disadvantage in that the scale is large.

When the scale of the device for purifying radon is large, it is difficult to install it in an island area, etc., which increases cost, and there is a problem that it is difficult to install it in a building such as an existing building.

Therefore, it is required to develop a highly efficient device for removing radon from water while being compact and compact.

An object of the present invention is to provide a radon water purification device including a spiral flow path configured to efficiently purify radon from water while being small and compact.

Another object of the present invention is to provide a radon water purification device including a spiral flow path configured to detect the concentration of radon in real time.

Another object of the present invention is to provide a radon water purification device including a spiral flow path configured to increase the dispersion efficiency of water to be purified.

Radon water purification device including a spiral flow path according to the present invention for achieving the above object is a housing member formed of a metal material and formed in a cylindrical shape to have a space therein, an ejector member installed to inject water into the housing member, and the An air outlet formed at an upper end of the housing member, a flow path forming member configured to drop water sprayed from the ejector member while rotating it, and a water dispersing member for dispersing the water dropped from the flow path forming member; and a discharge member for discharging water from the housing member, the flow path forming member is configured to spirally flow the water injected from the ejector member, and a drop for dropping water to a bottom portion of the flow path forming member. Characterized in that an opening is formed.

Preferably, a concave-convex portion is formed on a sidewall of the flow path forming member.

Here, the water dispersion member may include a housing for accommodating the filler and a filler accommodated in the housing.

In addition, a crushing member for crushing water falling from the flow path forming member is disposed on the water distributing member, and an upper surface of the crushing member may have a concave-convex portion formed thereon.

In addition, an air inlet and an air outlet are formed between the flow path forming member and the water dispersion member, and an air inlet fan and an air outlet fan are installed in the air inlet and the air outlet, and the air inlet fan and the air outlet fan are installed. An aberration member rotated by water falling from the flow path forming member may be installed between the flow path forming members so that the air intake fan and the air outlet fan are rotated by the rotation of the aberration member.

Preferably, a filter member is installed between the aberration member and the water dispersion member.

In addition, a post-treatment member is connected to the discharge member, and an inlet for introducing water discharged from the discharge member and an outlet for discharging water from the post-treatment member are formed in the post-treatment member. A second filter member for collecting moisture and foreign substances may be installed inside the treatment member, and a second air outlet for forcibly exhausting air may be formed above the second filter member.

A radon detection member is installed in the air outlet or the second air outlet, and a flow passage for flowing air discharged from the air outlet or the second air outlet is formed in the radon detection member. A water collecting member is installed in the flow passage, and a radon concentration measuring sensor unit may be connected and installed to the radon detecting member.

In addition, the moisture collecting member is convexly formed upward, and a plurality of pieces are intersected along a height direction inside the flow passage of the radon sensing member, and a concave-convex portion may be formed on a surface of the moisture collecting member.

Preferably, the filler is formed of a synthetic resin material, and includes a plurality of rings formed in the shape of a hollow cone column, and a spacer portion connecting the plurality of rings, and passage openings may be formed in the entire area of the rings and the spacer portion. there is.

According to the present invention, a device for purifying radon can be configured in a small and compact size, so that it can be easily installed in remote areas or existing buildings.

In addition, the concentration of radon can be detected in real time and utilized.

In addition, the dispersion efficiency of water to be purified may be increased, thereby increasing the efficiency of purifying harmful substances other than radon.

The accompanying drawings are for understanding the technical spirit of the present invention together with the detailed description of the invention, and the present invention should not be construed as being limited to the matters shown in the drawings.
1 is a cross-sectional view of a radon water purification device including a spiral flow path according to the present invention;
2 is a perspective view of a flow path forming member included in the water purifying device;
3 is a plan view of the flow path forming member,
4 is a perspective view of a filler included in the water purifying device;
5 is a perspective view of a crushing member included in the water purifying device;
6 is a cross-sectional view of a water purifying device according to another embodiment of the present invention;
7 is a schematic cross-sectional view of a radon detecting member included in the water purifying device.

Hereinafter, the configuration of the present invention will be described in detail with reference to the accompanying drawings.

Prior to this, the terms used in this specification and claims should not be construed as limited in a dictionary sense, and based on the principle that the inventor can appropriately define the concept of terms in order to best explain his/her invention. , It should be interpreted as a meaning and concept consistent with the technical idea of the present invention.

Therefore, the embodiments described in this specification and the configurations shown in the drawings are only preferred embodiments of the present invention and do not represent all of the technical spirit of the present invention, so various equivalents that can replace them at the time of this application It should be understood that water and variations may exist.

1 is a cross-sectional view of a radon water purification device including a spiral flow path according to the present invention, FIG. 2 is a perspective view of a flow path forming member included in the water purification device, FIG. 3 is a plan view of the flow path forming member, and FIG. FIG. 5 is a perspective view of a crushing member included in the water purifying device, FIG. 6 is a cross-sectional view of a water purifying device according to another embodiment of the present invention, and FIG. 7 is included in the water purifying device. It is a schematic cross-sectional view of the radon sensing member.

1 to 3, the radon water purification device including a spiral flow path according to the present invention includes a housing member 10 made of a metal material and formed in a cylindrical shape to have a space therein, and water is sprayed into the housing member 10. An ejector member 20 installed to do so, an air outlet 30 formed at an upper end of the housing member 10, and a flow path configured to drop water ejected from the ejector member 20 while rotating it. A member 40, a water dispersing member 50 for dispersing the water dropped from the flow path forming member 40, and a discharge member 60 for discharging water from the housing member 10, The flow path forming member 40 is configured to spirally flow the water ejected from the ejector member 20, and the bottom portion 42 of the flow path forming member 40 has a drop opening 46 for dropping water. ) is characterized in that it is formed.

The housing member 10 is a metal material and is formed in a cylindrical shape so that a space is formed therein.

An ejector member 20 for injecting water to be purified into the housing member 10 is installed on an upper portion of the housing member 10 .

A nozzle is disposed at an end of the ejector member 20, and water is strongly injected into the flow path forming member 40 inside the housing member 10 through the nozzle.

Thus, the water discharged from the ejector member 20 is configured to strongly collide with the flow path forming member 40 and crush it into small pieces.

An air outlet 30 is formed at an upper end of the housing member 10 , and a fan for forcibly exhausting air inside the housing member 10 may be installed in the air outlet 30 .

In the upper space inside the housing member 10, a flow path forming member 40 for dropping water sprayed from the ejector member 20 while rotating it is disposed.

As shown in FIG. 2, a side wall 44 for guiding water is spirally arranged inside the flow path forming member 40.

Thus, the water ejected from the ejector member 20 flows along the spiral passage by the side wall 44 disposed in a spiral shape.

As described above, by flowing the water through the spiral flow path, it is possible to form a flow path as long as possible for a narrow space or floor area.

In addition, a drop opening 46 for dropping water is formed at the bottom portion 42 of the flow path forming member 40 .

The drop opening 46 may be formed by perforating the bottom portion 42 .

Thus, in the course of the water flowing into the flow path forming member 40 passing through the drop opening 46 and falling, it is possible to provide an effect of crushing the water so that the surface area of the water is widened.

In addition, uneven portions 48 are formed on the sidewall 44 of the flow path forming member 40 .

Thus, the water flowing inside the flow path forming member 40 can be crushed even in the process of colliding with the concave-convex portions 48 .

In this state, by strongly driving the fan installed in the air outlet 30, it is possible to separate the radon particles contained in the water.

Water falling from the flow path forming member 40 flows into the water distributing member 50 .

The water distributing member 50 is configured to crush the inflowing water, and includes a housing 52 and a filler 54 filled in the housing 52.

Although, in FIG. 1, it is shown that the filler 54 is sparsely disposed inside the accommodation housing 52, but this is to be easily identified through the drawing, in fact, the inside of the accommodation housing 52 Fillers 54 are tightly packed.

The accommodation housing 52 is a metal material such as stainless steel and may be formed of a net so that water passes smoothly.

Alternatively, the receiving housing 52 may be configured in a state in which a plurality of passage openings through which water passes are formed in a state in which a metal plate is formed in a cylindrical shape.

The filler 54 filled in the accommodation housing 52 is formed of a synthetic resin material, and as shown in FIG. 4, a plurality of rings 542 formed in the shape of a hollow cone column, and the plurality of rings 542 ) and a spacer portion 544 connecting them.

The plurality of rings 542 may be formed in a ring shape having a constant thickness, and the spacer portion 544 may be formed in a plate shape and formed in an “X” shape between the two rings 542 .

Thus, in the process of passing through the fillers 54 filled in the accommodation housing 52, it is possible to provide an effect in which water is crushed into small pieces.

In addition, in order to further increase the effect of crushing water as described above, as shown in FIG. 4 , passage openings 546 may be formed in the entire area of the ring 542 and the spacer portion 544 .

The passage openings 546 may be formed as small-sized circular openings penetrating the ring 542 and the spacer portion 544 .

In addition, a crushing member 70 may be disposed above the water distributing member 50 to increase a surface area of water falling from the flow path forming member 40 .

As shown in FIG. 5, the crushing member 70 includes a cylindrical columnar portion 74 and a conical or hat-shaped crushing portion 72, and the columnar portion 74 is the accommodating housing 52 ) can be fixed to the top of the

In addition, uneven portions 76 may be formed on the surface of the crushing portion 72 of the crushing member 70 .

Thus, in the process of contacting the falling water to the crushing part 72, the surface area of the water can be increased by receiving the effect of being crushed by the concave-convex parts 76.

The water passing through the water distributing member 50 is discharged through the discharge member 60 formed at the lower end of the housing member 10 .

Meanwhile, in another embodiment of the present invention, an air inlet 2 and an air outlet 4 may be formed between the flow path forming member 40 and the water distributing member 50 .

In addition, an air inlet fan 12 and an air outlet fan 14 may be installed in the air inlet 2 and the air outlet 4.

The air intake fan 12 is configured to introduce air into the air inlet 2 from the outside by rotation, and the air outlet fan 14 passes air through the air outlet 4 by rotation. It is configured to discharge.

In addition, between the air inlet fan 12 and the air outlet fan 14, an aberration member 15 rotated by water falling from the flow path forming member 40 may be installed.

The aberration member 15 may include a rotation shaft and an aberration to receive force from the water falling from the flow path forming member 40 to rotate.

Also, the rotation shaft of the aberration member 15 is connected to the shafts of the air inlet fan 12 and the air outlet fan 14 .

Thus, the air inlet fan 12 and the air outlet fan 14 are rotated by the rotation of the aberration member 15 .

At this time, a water guide member 80 may be disposed above the aberration member 15 to guide the water falling from the flow path forming member 40 to the aberration wheel.

The water guide member 80 is configured similarly to a funnel as a whole, and a drop opening for dropping water may be formed at an upper portion of the aberration unit.

Meanwhile, a filter member 90 may be installed between the aberration member 15 and the water dispersion member 50.

The filter member 90 is configured as a filter to filter radon and other foreign substances contained in falling water, and preferably includes a non-woven filter and a housing for accommodating the filter.

Meanwhile, as in another embodiment of the present invention shown in FIG. 6, a post-treatment member 110 may be installed on the side of the housing member 10.

Here, the inlet 112 of the post-treatment member 110 is connected to the discharge member 60 formed at the lower end of the housing member 10 .

Thus, water discharged from the discharge member 60 may be supplied to the post-treatment member 110 through the inlet 112 .

A second filter member 116 for collecting moisture and foreign substances is installed inside the post-treatment member 110 .

The second filter member 116 may also include a non-woven filter and a housing for accommodating the filter, and the air flowing through the second filter member 116 inside the post-treatment member 110 and Capable of capturing radon and other contaminants from water vapor.

A second air outlet 118 for forcibly exhausting air is formed above the second filter member 116, and an air discharge fan is installed in the second air outlet 118.

In addition, an outflow part 114 is formed at the lower end of the post-treatment member 110 so that water flowing inside the post-treatment member 110 can be discharged.

And, in another embodiment of the present invention, the air inlet 122 of the radon detecting member 120 shown in FIG. 7 is connected and installed to the air outlet 30 or the second air outlet 118. can

The radon sensing member 120 includes a housing 121 formed in a cylindrical shape as a whole, and the air discharged from the air outlet 30 or the second air outlet 118 in the inner space of the housing 121 It is configured to serve as a flow passage for flowing.

In addition, moisture collecting members 124 for collecting moisture from flowing air are installed in the inner space of the housing 121, which is a flow passage.

The moisture collecting member 124 may be formed to be convex upward on a side end surface of, for example, a stainless steel plate.

In addition, a plurality of the moisture collecting members 124 may be arranged to cross each other along the height direction inside the housing 121 .

In addition, a concave-convex portion 125 is formed on the surface of the moisture collecting member 124 to increase a contact area with air so that moisture contained in the flowing air can be condensed into water droplets.

Thus, in the course of air flowing into the housing 121, it collides with the surface of the moisture collecting member 124 so that moisture in the air is condensed.

In addition, an air discharge unit 123 is formed on the upper part of the housing 121, and the air discharge unit 123 includes a dehumidifier unit 126 for removing moisture from the flowing air and a radon concentration measuring sensor unit ( 127) can be connected and installed.

In addition, a communication unit 128 may be connected and installed to the radon concentration measuring sensor unit 127.

Thus, by measuring the radon concentration of the air flowing inside the housing 121 and notifying it to an external institution such as a local government, it is configured to discuss measures for water purification.

Terms used in the embodiments of the present invention have the same meaning as commonly understood by a person of ordinary skill in the art to which the present invention belongs.

Although the present invention has been described with limited embodiments and drawings, the above embodiments are not intended to limit the technical idea of the present invention but to explain it, so the technical idea of the present invention is not limited to these, and the present invention belongs Various modifications and variations will be possible by those skilled in the art within the scope of equivalents of the technical spirit of the present invention and the claims to be made below.

Therefore, the protection scope of the present invention should be construed according to the claims, and all technical ideas within the scope equivalent thereto should be construed as being included in the scope of the present invention.

And, if it is within the scope of the object of the present invention, all of the components may be configured by selectively combining one or more.

The term "includes" or "consists of" described above means that the corresponding component may be included, and should be interpreted as being able to additionally include other components.

10: housing member
20: ejector member
30: air outlet
40: flow path forming member
50: water dispersing member
60: discharge member
70: crushing member
80: water guide member
90: filter member
110: post-processing member
120: radon sensing member

Claims (10)

a housing member made of a metal material and formed in a cylindrical shape to have a space therein;
an ejector member installed to inject water into the housing member;
an air outlet formed at an upper end of the housing member;
a flow path forming member configured to drop the water ejected from the ejector member while rotating it;
a water distributing member for dispersing the water that has fallen from the flow path forming member;
It includes a discharge member for discharging water from the housing member,
The flow path forming member is configured to spirally flow the water injected from the ejector member,
A drop opening for dropping water is formed at the bottom of the flow path forming member,
An uneven portion is formed on the sidewall of the flow path forming member,
The water dispersion member includes a housing for accommodating a filler and a filler accommodated in the housing,
A crushing member for crushing water falling from the flow path forming member is disposed on the water distributing member,
Radon water purification device comprising a spiral flow path, characterized in that the concave-convex portion is formed on the upper surface of the crushing member. According to claim 1,
An air inlet and an air outlet are formed between the flow path forming member and the water distributing member,
An air inlet fan and an air outlet fan are installed in the air inlet and the air outlet,
An aberration member rotated by water falling from the flow path forming member is installed between the air inlet fan and the air outlet fan,
Radon water purification device comprising a spiral flow path, characterized in that the air inlet fan and the air outlet fan are configured to rotate by the rotation of the aberration member. According to claim 2,
Radon water purification device comprising a spiral flow path, characterized in that a filter member is installed between the aberration member and the water dispersing member. According to claim 1,
A post-treatment member is connected to the discharge member,
The post-treatment member includes an inlet for introducing water discharged from the discharge member;
An outlet for discharging water from the post-treatment member is formed,
A second filter member for collecting moisture and foreign substances is installed inside the post-treatment member,
A radon water purifying device comprising a spiral flow path, characterized in that a second air outlet for forcibly exhausting air is formed above the second filter member. According to claim 4,
A radon detecting member is installed in the air outlet or the second air outlet,
A flow passage for flowing air discharged from the air outlet or the second air outlet is formed in the radon sensing member,
A moisture collecting member is installed in the flow passage,
Radon water purification device comprising a spiral flow path, characterized in that the radon concentration measuring sensor unit is connected to the radon sensing member. According to claim 5,
The moisture collecting member is formed convexly upward, and a plurality of pieces are cross-disposed along the height direction inside the flow passage of the radon sensing member,
Radon water purification device comprising a spiral flow path, characterized in that the uneven portion is formed on the surface of the water collecting member. According to claim 1,
The filler is formed of a synthetic resin material, a plurality of rings formed in the shape of a hollow cylinder column,
A spacer portion connecting the plurality of rings,
Radon water purification device including a spiral flow path, characterized in that through openings are formed in the entire area of the ring and the spacer portion. delete delete delete

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