KR102227796B1 - A dead water protection device and nozzle for radon reduction - Google Patents

Abstract

A radon reduction device according to the present invention includes: a groundwater inlet through which groundwater flows; a groundwater outlet communicating with the groundwater inlet and discharging the introduced groundwater; a first chamber forming a predetermined space in the middle of a flow path connecting the groundwater inlet and the groundwater outlet; and a plurality of inlet-side air inlets formed between the groundwater inlet and the first chamber to introduce air from the outside to the flow path, wherein the air introduced through the inlet-side air inflow path forms microbubbles together with the swirling groundwater in the first chamber. According to the present invention having such a configuration, it is possible to provide a radon-low audit water prevention device that includes a radon reduction nozzle and a radon reduction nozzle that effectively removes radon by naturally contacting radon with air through a simpler and lighter configuration, thereby preventing the occurrence of dead water in the water tank.

Description

Radon reduction nozzle and gunner prevention device {A DEAD WATER PROTECTION DEVICE AND NOZZLE FOR RADON REDUCTION}

The present invention relates to a radon reduction nozzle and a shooting water prevention apparatus, and more particularly, to a radon reduction nozzle capable of efficiently separating and discharging radon gas contained in groundwater, and a shooting water prevention apparatus including the nozzle.

Radon is one of the elements that exist in nature. It is a radioactive substance that emits radiation when the atomic nucleus collapses. It is composed of a colorless, tasteless, and odorless radioactive gas that naturally occurs when radium collapses in soil, rocks, and water. When radon is released into the air from the soil, rocks, or water, it is inhaled into the respiratory tract, and when ingested as drinking water, it is absorbed through the digestive tract, causing lung cancer and stomach cancer.

As described above, more than 90% of radon, which causes diseases such as lung cancer and stomach cancer, is generated from water supply facilities, so research is being conducted to remove radon from water, and the conventional invention for removing the radon flows into the water tank. It is equipped with a device that sprays water (ground water) by dropping force and discharges air from the water using electricity to remove radon by mixing water and air, or by providing activated carbon in the path of water. Radon was removed by passing through this activated carbon.

Techniques related to the removal of radon include:

Republic of Korea Patent Registration No. 10-0988821 (name: radon removal device, registration date: 2010.10.13., hereinafter'document 1') is proposed,

Document 1 is installed on the upper part of the water tank for simple water supply in order to remove radon, which is a natural radioactive substance detected in the groundwater transferred from the simple water supply facility, and to improve the water quality. It comprises an inlet pipe connector into which the connected inverted U-shaped pipe is inserted, and an auxiliary tank provided with a discharge pipe connector into which a discharge pipe for discharging water to the water tank is inserted on a lower surface, and external air is introduced into the inverted U-shaped pipe. An intake pipe vertically penetrating and interpolating from the upper portion of the tank is further provided, and a conical water spray body for radially spraying water at the end of the inverted U-shaped pipe inserted into the auxiliary tank is further provided. Radon removal device that separates radon from water by contacting air and water when external air flows in by this lowering Bernoulli principle, and discharges radon separated from water to the outside through an exhaust port installed in the auxiliary tank and water tank. It is about technology.

As another technology, Korean Patent Registration No. 10-0915867 (name: radon removal device, registration date: 2009.08.31., hereinafter'Document 2') is proposed,

Document 2 is an intake pipe through which external air is introduced by extending from the top of the water tank for water supply to improve water quality and to remove radon, which is a natural radioactive substance detected in the groundwater transferred from the simple water supply facility, and the water tank. An intake pipe extending from the bottom to the inside to transfer groundwater, a discharge pipe vertically mounted on the intake pipe, and a discharge pipe formed in a conical shape in which an outlet through which the groundwater transferred from the intake pipe is discharged gradually narrows, and in the intake pipe Includes a mixer in which the transferred external air is introduced, and the discharge pipe is horizontally inserted, but the diameter of both sides is increased around the middle point where the discharge port of the discharge pipe is provided, and the groundwater combined with the external air is radially sprayed at the intermediate point. However, the mixer is a technology related to a radon removal device, characterized in that it sprays groundwater combined with external air from the edge of the water tank toward the circumferential direction.

As another technology, Korean Patent Registration No. 10-1376046 (name: radon removal device, registration date: 2014.03.11., hereinafter'document 3') is proposed,

Document 3 is equipped with a water spraying means to supply underground source water on the upper part of a water tank for short-term water supply that stores underground source water in order to remove radon, which is a natural radioactive material detected in the source water transported from the simple water supply facility, and improve water quality. However, the water spraying means is configured so that radon can be removed while external air is included at the same time as the inflow of ground source water, so that radon contained therein is easily removed when source ground water is supplied to the inside of the water tank for water supply. It is a technology related to a radon removal device that allows it to be discharged to the outside.

As another technology, Korean Patent Registration No. 10-1808202 (name: groundwater radon removal device, registration date: 2017.12.06.) is proposed,

Document 4 relates to a water intake pipe through which groundwater is pumped, a radon removal tank through which groundwater flows through the water intake pipe, a discharge pipe having an inlet at a position lower than the level of groundwater stored in the radon removal tank, and a discharge pipe. And a water tank in which groundwater stored in the radon removal tank is introduced and stored through the discharge pipe, an aeration means for aeration of air into the groundwater stored in the radon removal tank, and the radon in the groundwater stored in the radon removal tank is discharged to the outside. A non-powered ventilator and a powered ventilator installed in the radon removal tank, a flow-water detector installed in the intake pipe to detect the flow of groundwater flowing into the radon removal tank through the intake pipe, and a water flow detector that detects the flow of groundwater into the radon removal tank. A technology related to a groundwater radon removal device capable of effectively reducing or removing radon contained in groundwater used as drinking water by having a control panel for receiving the signal output from the water flow detector and operating the motorized ventilator and the aeration means to be.

Republic of Korea Patent Registration No. 10-0988821 (Name: Radon removal device, registration date: 2010.10.13.) Republic of Korea Patent Registration No. 10-0915867 (Name: Radon removal device, registration date: 2009.08.31.) Republic of Korea Patent Registration No. 10-1376046 (Name: radon removal device, registration date: 2014.03.11.) Republic of Korea Patent Registration No. 10-1808202 (Name: groundwater radon removal device, registration date: 2017.12.06.)

The present invention is invented to improve the problems of the prior art,

The problem to be solved by the present invention is to provide a radon reduction nozzle that effectively removes radon by natural contact with air through a simpler and lighter configuration.

Another problem to be solved by the present invention is to provide a radon reduction nozzle capable of reducing implementation cost through a simpler and lighter configuration.

Another problem to be solved by the present invention is to provide a shooter prevention apparatus including a radon reduction nozzle.

In detail, external air is supplied to the ground source water accumulated in the water tank, and by circulating the ground source water accumulated in the water tank by forming a vortex using the outlet water pressure of the ground source water, it is possible to prevent the underground source water from becoming pristine. It is an object of the present invention to provide a gunshot prevention device including a radon reduction nozzle.

The technical problem of the present invention is not limited to those mentioned above, and another technical problem that is not mentioned will be clearly understood by those skilled in the art from the following description.

The radon reduction nozzle according to an embodiment of the present invention devised to achieve the above object is a groundwater inlet through which groundwater is introduced, a groundwater outlet through which groundwater inlet is communicated to discharge the introduced groundwater, and connects the groundwater inlet and the groundwater outlet. It includes a rectangular first chamber forming a certain space in the middle of the flow path, and a plurality of inlet side air inflow paths that are formed between the groundwater inlet and the first chamber to introduce air from the outside to the flow path. It is characterized in that the air introduced through forms microbubbles together with groundwater swirling in the first chamber.

In addition, the air inflow path on the inlet side of the radon reduction nozzle is formed to be inclined toward a direction in which groundwater flows through the flow path.

In addition, the outer opening of the air inlet passage on the inlet side of the radon reduction nozzle is formed to form a spiral around the flow passage along the outer surface of the nozzle.

In addition, the radon reduction nozzle is characterized in that it comprises a plurality of inter-chamber air inflow paths formed between the first chamber and the groundwater outlet to introduce air from the outside to the flow path.

In addition, the radon reduction nozzle includes a second chamber of a square shape forming a constant space in the middle of the flow path connecting the first chamber and the groundwater outlet, and the air introduced through the air inflow path between the chambers is inside the second chamber. It is characterized in that it forms microbubbles with groundwater swirling in.

In addition, the outer opening of the interchamber air inflow path of the radon reduction nozzle is formed to form a spiral around the flow path along the outer surface of the nozzle.

In addition, in the radon reduction water prevention apparatus including a radon reduction nozzle and a storage tank, a radon reduction nozzle having one end coupled to an end of the groundwater receiving passage extending from the outside of the radon reduction water prevention apparatus to the inside of the storage tank, and the groundwater receiving passage inside the storage tank, and It includes a groundwater discharge pipe that is coupled to the other end of the radon reduction nozzle and has a plurality of groundwater outlets for discharging groundwater that has passed through the radon reduction nozzle, and the groundwater outlets are paired to discharge groundwater at the same height on the groundwater discharge pipe in opposite directions. It is formed and characterized in that at least one pair is formed on one groundwater discharge pipe.

According to an embodiment of the present invention, there is an effect of providing a radon reduction nozzle that effectively removes radon by naturally contacting air through a simpler and lighter configuration.

In addition, according to an embodiment of the present invention, there is an effect of providing a radon reduction nozzle capable of reducing implementation cost through a simpler and lighter configuration.

In addition, according to an embodiment of the present invention, there is an effect of providing a shooter prevention device including a radon reduction nozzle.

The effects of the present invention are not limited to the above-mentioned effects, and other effects not mentioned will be clearly understood by those skilled in the art from the description of the claims.

1 is a side cross-sectional view of a radon reduction nozzle according to an embodiment of the present invention.
2 is a side cross-sectional view of an embodiment in which a radon reduction nozzle is provided in a radon reduction water prevention apparatus according to an embodiment of the present invention.
3 is a top view of an embodiment in which a radon reduction nozzle is provided in a radon reduction water prevention apparatus according to an embodiment of the present invention.

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

In describing the embodiments, descriptions of technical contents that are well known in the technical field to which the present invention pertains and are not directly related to the present invention will be omitted. This is to more clearly convey the gist of the present invention by omitting unnecessary description.

For the same reason, some elements in the accompanying drawings are exaggerated, omitted, or schematically illustrated. In addition, the size of each component does not fully reflect the actual size. The same reference numerals are assigned to the same or corresponding components in each drawing.

1 is a side cross-sectional view of a radon reduction nozzle according to an embodiment of the present invention.

Referring to FIG. 1, it can be seen that the radon reduction nozzle 100 includes a flow path through which groundwater flows from the left direction to the right direction of the drawing.

From the left to the right of the drawing, when explaining each part based on the order in which groundwater flows,

The groundwater inlet 105 is formed at the left end of the radon reduction nozzle 100 and is a portion into which groundwater is introduced.

The inlet side air inlet path 110 is formed to introduce external air into a flow path inside the nozzle, and is preferably formed to be inclined in a direction in which groundwater flows, that is, from left to right. Here, the reason for the inclined formation is to allow the introduced air to be more actively mixed with the groundwater.

The first chamber 115 is formed in a square shape so that the introduced air swirls together with the groundwater to form microbubbles, whereby, when the groundwater is discharged from the radon reduction nozzle 100, the radon gas contained in the groundwater Is more easily separated from the water and can fly with the air into the air.

The inter-chamber air inlet path 120 is formed between the first chamber 115 and the groundwater outlet 135 and serves to introduce air from the outside to the flow path, and is similar to the inlet side air inlet path 110 , It is preferable that the groundwater is formed to be inclined toward the flow direction.

Like the first chamber 115, the second chamber 125 has a square shape so that the introduced air swirls together with the groundwater to form microbubbles, so that when the groundwater is discharged from the radon reduction nozzle 100, the groundwater It is formed to allow the radon gas contained in the water to be more easily separated from the water and carried away with the air into the air.

A groundwater outlet 135 through which groundwater is discharged is formed at the right end of the radon reduction nozzle 100, through which groundwater containing microbubbles is discharged to the outside of the radon reduction nozzle 100, and is included in the groundwater. The existing radon is blown away with the microbubbles into the outside air.

As described above, the inflow groundwater (Win) flowing into the radon reduction nozzle 100 through the groundwater inlet 105 flows together with the air introduced through the inlet side air inlet path 110, and the first chamber 115 In this state, it swirls with the inlet air and contains microbubbles. In this state, it flows to the right again, and flows into the second chamber 125 together with the air introduced through the inter-chamber air inlet path 120, and together with the inlet air. By swirling and including more microbubbles, when discharged through the underground outlet outlet 135, microbubbles and radon are actively discharged.

The radon reduction nozzle 100 according to the preferred embodiment of the present invention as described above, the inlet side air inlet path 110 and the inter-chamber air inlet path 120, by introducing air in two times, more air is While increasing the amount of air inflow by allowing it to be introduced into the flowing groundwater, the first chamber 115 and the second chamber 125 vortex together the inlet air and groundwater two times, thereby allowing more groundwater to be discharged before being discharged. By allowing microbubbles to be included, the efficiency of discharging radon contained in groundwater can be maximized.

In addition, when the inflow groundwater (Win) and discharge groundwater (Wout) are discharged through the groundwater outlet 135, if the embodiment is configured to have a larger flow rate, the efficiency of removing radon (Rn) can be further increased.

However, it is possible to maximize the efficiency of radon removal compared to the cost of the radon reduction nozzle 100 according to a preferred embodiment of the present invention to avoid requiring additional power in order to increase the flow rate of groundwater as described above. I believe there will be.

2 is a side cross-sectional view of an embodiment in which a radon reduction nozzle according to an embodiment of the present invention is coupled to an underground water receiving channel inside a storage tank included in the radon reduction water prevention device.

Referring to Figure 2, according to a preferred embodiment of the present invention, one end of the radon reduction nozzle 100 is the end of the groundwater receiving passage 210 extending to the inside of the reservoir 205 of the radon reduction water prevention device 200 It can be seen that the groundwater discharge pipe 220 is coupled to the other end of the radon reduction nozzle 100.

Here, the reservoir is included in the radon reduction water prevention device 200, and when the discharged groundwater Wout is discharged from the radon reduction nozzle 100, microbubbles and radon (Rn) contained in the groundwater are more easily It is a component that can be blown into the air and temporarily store groundwater from which radon (Rn) has been removed.

In addition, the groundwater receiving channel 210 shown to extend from the bottom to the top may be extended from the side of the radon reduction water prevention device 200 to the inside of the reservoir 205, and it is irrelevant even if it extends from the top to the inside, radon It is a form that can be coupled and communicated with the radon reduction nozzle 100 among the water tank inner portion 205 inside the reduced shooting water prevention device 200, and only needs to be positioned above the water storage tank inner portion 205.

In addition, a plurality of groundwater outlets 230 are formed in the groundwater discharge pipe 220 coupled to the other end of the radon reduction nozzle 100.

Here, the groundwater outlet 230 is formed to form a pair in a direction opposite to each other at the same height on the groundwater discharge pipe 220, and at least one pair is formed on one groundwater discharge pipe 220.

Here, the reason why the groundwater outlet 230 is installed in pairs to discharge groundwater in a direction opposite to each other around the groundwater discharge pipe 220 is to form a current in a direction opposite to each other in the reservoir according to the groundwater discharge. This is for the purpose, and the reason will be described again with reference to FIG. 3.

In addition, in the embodiment of FIG. 2, it can be seen that three pairs of groundwater outlets 230 formed at different heights on the groundwater outlet pipe 220 are formed. In this way, several pairs of groundwater outlets 230 are installed, but each The reason for the different heights of the pair is to prevent the occurrence of shooting water as much as possible by allowing the current to be formed relatively evenly over the entire depth area of the groundwater temporarily contained in the reservoir so that the area without flow is reduced as much as possible.

In addition, as in the embodiment shown in FIG. 2, the air conditioning device 150 and the ventilation port 160 may be installed in the storage tank of the radon reduction water prevention device 200. Of course, depending on the embodiment, one or both of these may be omitted.

3 is a top view of an embodiment in which a radon reduction nozzle is provided in a radon reduction water prevention apparatus according to an embodiment of the present invention.

3, the groundwater discharge pipe 220 is coupled to the end of the radon reduction nozzle 100 just below the middle height on the left side based on the drawing direction, and the groundwater formed in a direction opposite to each other on the outer surface of the groundwater discharge pipe 220 A pair of outlets 230 are shown, and dotted lines extending in opposite directions from each of the groundwater outlets 230 are shown.

Here, the dotted line is a streamline showing the flow of discharged groundwater Wout discharged through the groundwater outlet 230. The discharged groundwater Wout contains air and microbubbles mixed with groundwater passing through a chamber formed in the radon reduction nozzle 100. As described above, groundwater containing air and microbubbles are discharged in opposite directions through the groundwater outlet 230, thereby creating a flow in a direction opposite to each other in the storage tank interior 205 of the radon reduction water prevention device 200. , The flow in each direction flows along the wall of the storage tank, and then merges in the vicinity of the location opposite to the installation location of the groundwater discharge pipe 220 among the inside of the reservoir 205 and returns to the groundwater discharge pipe 220.

As described above, groundwater includes air and microbubbles mixed through the radon reduction nozzle 100, and groundwater discharged in the opposite direction through the groundwater outlet 230 so that it continuously flows in the storage tank interior 205. As a result, there is an advantage that the possibility of occurrence of shooting water in the water storage tank interior 205 is significantly reduced.

Meanwhile, the present specification and drawings disclose preferred embodiments of the present invention, and although specific terms are used, these are merely used in a general meaning to easily explain the technical content of the present invention and to aid understanding of the present invention. It is not intended to limit the scope of the invention. In addition to the embodiments disclosed herein, it is apparent to those of ordinary skill in the art that other modifications based on the technical idea of the present invention may be implemented.

100: radon reduction nozzle
105: groundwater inlet
110: air inflow path at the inlet side
115: first chamber
120: air inflow path between chambers
125: second chamber
135: groundwater outlet
200: Radon reduction water prevention device
205: inside the reservoir
210: groundwater take-in channel
220: groundwater discharge pipe
230: groundwater outlet
A: air
Win: Inflow groundwater Wout: Outflow groundwater

Claims (7)

In the radon reduction nozzle,
Groundwater inlet through which groundwater flows;
A groundwater outlet communicating with the groundwater inlet and discharging the introduced groundwater;
A rectangular first chamber forming a predetermined space in the middle of a flow path connecting the groundwater inlet and the groundwater outlet; And
And a plurality of inlet side air inlet passages formed between the groundwater inlet and the first chamber to introduce air from the outside to the passage, and
The inlet side air inlet path,
It is formed to be inclined toward a direction in which groundwater flows through the flow path,
The outer opening of the inlet side air inlet passage,
It is formed to form a spiral around the flow path along the outer surface of the nozzle,
The air introduced through the inlet side air inlet vortex together with groundwater in the first chamber to form microbubbles,
A plurality of inter-chamber air inflow paths formed between the first chamber and the groundwater outlet to introduce air from the outside to the flow path; And
A second chamber having a square shape forming a predetermined space in the middle of the flow path connecting the first chamber and the groundwater outlet; further comprises,
The air inflow path between the chambers,
It is formed to be inclined toward a direction in which groundwater flows through the flow path,
The outer opening of the inter-chamber air inflow path
It is formed to form a spiral around the flow path along the outer surface of the nozzle,
Radon reduction nozzle, characterized in that the air introduced through the inter-chamber air inflow path swirls together with groundwater in the second chamber to additionally form microbubbles.
delete delete delete delete delete In the radon reduction water prevention apparatus comprising a radon reduction nozzle and a storage tank according to claim 1,
An underground water receiving channel extending from the outside of the radon reduction water prevention device to the inside of the storage tank;
The radon reduction nozzle having one end coupled to an end of the groundwater receiving passage inside the storage tank; And
Includes; a groundwater discharge pipe coupled to the other end of the radon reduction nozzle and having a plurality of groundwater discharge ports for discharging the groundwater passing through the radon reduction nozzle,
The groundwater outlet is,
A pair is formed to discharge groundwater in a direction opposite to each other at the same height on the groundwater discharge pipe,
Radon reduction water prevention device, characterized in that at least one pair is formed on one groundwater discharge pipe.

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