KR101054361B1 - Real time and automatic radon monitoring system with direct connecter using ground water bore hole - Google Patents

Abstract

PURPOSE: A system for monitoring radon in real time with direct delivering method using subsurface water bore hole is provided to precisely measure radon included in subsurface water or soil without any disturbance and restriction from external environment and prevent frost formation inside a sealed container which occurs due to temperature difference. CONSTITUTION: A rubber packer(21) is formed inside a bore hole(11) and closely adhered to the inner circumference of the bore hole by being expanding with the injection of air. A radon collecting pipe(22) passes through the upper and lower of the rubber packer and collects air in the bottom side of the bore hole which is tightly shut with the rubber packer. A dehumidifier(30) is directly connected to the radon collecting pipe and eliminates moisture in the air which flows in through the radon collecting pipe. A radon collecting apparatus(50) includes a pump(40) which is directly connected to the dehumidifier and forcibly absorbs the air in the bottom side of the bore hole.

Description

Real time and automatic Radon monitoring system with direct connecter using ground water bore hole}

The present invention relates to a system for real-time monitoring of radon by delivering radon gas contained in groundwater or soil directly to an indoor radon meter.

Radon is a chemical element with the symbol Rn and atomic number 86. It is a heavy radioactive inert gas produced by the collapse of radium. It is heavier than air but has a property to rise to the surface. Radon gas has a property to rise to the surface, and it can accumulate in a closed place such as a house or underground. It is harmful to health.

However, these radons are not included in groundwater or soil because their properties, which are intended to rise to the aforementioned indicators, help solve a variety of geological problems, such as uranium, geothermal and oil resource exploration, active fault detection, earthquake and volcanic eruption prediction. Technology that monitors radon in real time is even more important.

An object of the present invention is to use the indoor radon meter in real time monitoring the radon contained in groundwater or soil, and adopts a method of directly delivering the radon contained in the groundwater or soil to the indoor radon meter, and in such a direct delivery method The installation of a dehumidifier that removes problematic moisture provides a radon real-time monitoring system using direct delivery of radon using groundwater boreholes that can accurately monitor radon contained in groundwater or soil in real time without mechanical malfunction. .

An object of the present invention as described above is provided in the interior of the borehole, the rubber packer is expanded by the injection of air and tightly adhered to the inner circumferential surface of the borehole, and penetrates the upper and lower parts of the rubber packer, by the rubber packer A radon collecting tube for collecting air from the lower side of the sealed borehole, a dehumidifying apparatus directly connected to the radon collecting tube to remove moisture from the air introduced through the radon collecting tube, and directly connected to the dehumidifying apparatus; A radon collecting device comprising a pump for forcibly suctioning the lower side air of the pump;

Indoor radon measuring device for measuring the radon content in the air flowing directly connected to the pump at a set time interval and for transmitting the value of the measurement to the radon management center through a wired / wireless communication device; And

A sealing device for protecting the radon collecting device and the indoor radon measuring device from an external environment;

It is achieved by the radon real-time monitoring system of the direct delivery method radon using groundwater borehole, characterized in that it comprises a.

Here, it is preferable that a heating wire is further provided outside the radon collecting tube and the dehumidifier.

The dehumidifier includes: a dehumidifier for removing moisture contained in the air at the lower side of the borehole introduced;

A dehumidifying filter provided on both sides of the dehumidifier and separately removing the dehumidifying agent and the foreign matter from the air before and after dehumidifying the dehumidifier separately from the dehumidifier;

It is preferably configured to include; a heating wire provided on the outside of the dehumidifier to evaporate moisture accumulated in the dehumidifier and the dehumidifier.

The indoor radon measuring device is preferably further provided with a cover for keeping warm, cold and moisture proof to protect from the external environment,

The sealing device, in order to prevent condensation due to temperature difference between the inside and the outside, the outside of the sealing device is covered with a heat insulating cover, the inside of the sealing device is provided with a heater line for preventing the freeze, the power of the heater line It is preferable to include a solar cell and a battery for supply.

According to the present invention, it is possible to prevent condensation inside a sealed container that may be caused by a climate difference, and to accurately deliver the radon contained in groundwater or soil to the indoor radon measuring device without disturbing or restricting the external environment. There is this.

1 is a schematic diagram of a radon real-time monitoring system of the radon direct delivery method using a groundwater borehole in accordance with an embodiment of the present invention,
2 is a view showing a moving direction of radon gas,
3 is a view showing another embodiment of a radon collecting tube and a dehumidifier according to the present invention,
4 is a view showing another embodiment of a dehumidifying apparatus according to the present invention;
5 is a view showing another embodiment of the indoor radon measuring device according to the present invention.

Prior to describing the present invention, the concept of measuring and using radon (Rn) and radon will be described.

Radon (Rn) is a radioactive element that results from the radioactive decay of radium, a product of the disintegration of uranium and thorium, and can be naturally generated and collected anywhere in the geological environment (rock, soil, groundwater, etc.).

Radon (Rn) is the daughter element of lithium (Ra), which is changed from the parent element due to radioactive decay, which is formed during the radioactive decay of uranium (U) -238 to ultimately lead (Pd) -206. . Therefore, a lot of radon means a lot of uranium. Basically, because all the crust contains uranium (1-4 ppm, average 2.6 ppm), this naturally results in radioactive decay, resulting in radon.

The depths of uranium originally contained in the rock's origins, such as deep magma and deep granite bodies formed by it, remain relatively high, but the amount is minimal on the surface. However, if there are passages that can be directly connected to the core, such as faults, volcanoes, hot spots, and large joints, radon is relatively more affected by uranium than the surroundings.

Earthquakes are caused by these faults or volcanic activity. Therefore, the moment the earthquake occurs is more affected by deeper uranium-rich materials such as magma and hydrothermal water.

For example, if there is a fault, it will basically spill more radon along the gap than elsewhere, and this will lead to more gaps when the underground activity becomes active and the fault begins to move, or the fault associated with the fault. This causes more of the magma, hot water, or uranium daughter elements originally contained in the deep rock.

While installing and monitoring radon measuring devices around volcanoes or active fault zones, it is possible to detect earthquake activity when suddenly high radon emissions occur, and to predict earthquake and volcanic eruptions.

Of course, if the time interval between the earthquake and volcanic activity occurs from that moment is too short, its effectiveness will be inferior, but if you monitor it for a long time, you can know its prognosis. Often used in one place.

Therefore, an object of the present invention is to provide a more accurate and accurate radon real-time monitoring system in the automatic continuous monitoring of the radon gas content released from the groundwater in real time in a remote place using a groundwater borehole (well).

On the other hand, since the present invention uses groundwater boreholes, it is obvious that soil boreholes and other boreholes may be used, and therefore, the present invention is not limited to the use of groundwater boreholes.

Hereinafter, with reference to the accompanying drawings showing a preferred embodiment of the present invention will be described in detail.

The radon real-time monitoring system of the radon direct delivery method using the groundwater borehole according to the present invention includes a radon collecting device 50, an indoor radon measuring device 60, and a sealing device 70.

The radon collecting device 50 is configured to include a rubber packer 21, a radon collecting tube 22, a dehumidifying device 30 and a pump 40,

The rubber packer 21 is provided inside the borehole 11 and is inflated by the injection of air to be in close contact with the inner circumferential surface of the borehole 11, and the radon collecting tube 22 of the rubber packer 21 It is a configuration for collecting air from the lower side of the borehole 11 penetrating the upper and lower parts and sealed by the rubber packer 21.

1 and 2, the rubber packer 21 and the radon collecting pipe 22 have the advantage of protecting the lower side air of the borehole 11 from external environmental factors as much as possible and collecting and collecting at the same time. There is this.

The dehumidifier 30 is directly connected to the radon collecting pipe 22 to remove moisture in the air flowing through the radon collecting pipe 22, and the air at the lower side of the borehole 11 is indoor radon measuring device 60. If it is delivered directly to), it may cause malfunction and failure by moisture, so it is essential to prevent it. Therefore, although a commercially available product having excellent dehumidification performance may be used, the dehumidifier 30 in the present invention is a dehumidifier (31) for removing moisture contained in the air at the lower side of the borehole flowing in as shown in FIG. And dehumidifiers (32, 33) provided on both sides of the dehumidifier (31) to remove moisture in the air before and after dehumidification of the dehumidifier (31) separately from the dehumidifier (31). It is preferable to include the structure of the filter 34,35 and the heating wire 36 which is provided in the outer side of the said dehumidifier 30, and evaporates the moisture accumulated in the dehumidifier 31 and the dehumidifier 32,33. .

Alternatively, the surface of the dehumidifier 30 and the radon collecting tube 22 may be provided with a heating wire 91 in order to improve the efficiency of the dehumidification while using the product distributed on the market. .

The pump 40 is configured to be directly connected to the dehumidifying device 30 to forcibly suck air from the lower side of the borehole 11.

The indoor radon measuring device 60 is directly connected to the pump 40 to measure the radon content in the air introduced at a set time interval, and to transmit the value by the measurement to the radon management center through a wired / wireless communication device. As such, the indoor radon measuring device 60 is installed for each borehole and continuously monitors radon contents of various regions at remote locations in real time, thereby enabling earthquake forecasting in real time, thereby minimizing human and property damage.

On the other hand, indoor radon measuring device 60, as shown in Figure 5 may be further provided with a cover 61 for keeping warm, cold and moisture-proof to protect from the external environment, in relation to the indoor radon measuring device 60 For details, refer to the specification (name of the invention: real-time automatic radon monitoring system and method using groundwater boreholes) filed by the applicant.

The sealing device 70 is configured to protect the radon collecting device 50 and the indoor radon measuring device 60 from an external environment (temperature / humidity, direct sunlight, dust, etc.), and may be made of stainless steel (SUS304). As shown in FIG. 1, in order to prevent condensation due to temperature difference between inside and outside, the outside of the sealing device 70 is covered with a heat insulating cover 71, and the inside of the sealing device 70 is for freezing prevention. The heater line 74 is installed and includes a solar cell 72 and a battery 73 for supplying power to the heater line 74.

Normal power uses the power generated by the solar cell 72, but when a situation such as insufficient power generated by the solar cell 72 occurs, the power of the battery 73 is used, and the solar power is consumed more than the power consumed. If there is a lot of power generated by the battery 72, a storage battery (not shown) for storing it may be further provided inside the sealed device 70.

Hereinafter, the operation relationship of the radon real-time monitoring system of the radon direct delivery method using the groundwater borehole according to the present invention.

First, the rubber packer 21 and the radon collecting pipe 22 are installed in the borehole 11 in the borehole 11, and the air is injected into the rubber packer 21 (not shown in the air injection device), so that the borehole ( Seal the bottom of 11).

Next, the pump 40 is driven by the solar cell 72 or by the power of the battery 74 to suck air from the lower side of the borehole 11.

Next, moisture and dust in the inhaled air is removed through the dehumidifier 30, and the radon content in the air flowing into the indoor radon measuring device 60 is measured at a set time interval, and the measurement is performed through a wire / wireless communication device. The value of is transmitted to the radon management center (not shown).

The radon management center uses the radon content collected to calculate volcanic eruptions and earthquakes.

On the other hand, the heating wire 91 may be operated by the power of the solar cell 72 or the battery 74 to improve the efficiency of the dehumidifying device (30). The heater line 74 may be operated to protect the dehumidifier 30, the indoor radon measuring device 60, the pump 40, and the like from moisture introduced from the ground surface.

In addition, the heating wire 36 is connected to both sides of the dehumidifier 30 to remove moisture accumulated in the dehumidifier 31, the dehumidifier 32, 33, and the dehumidification filter 34, 35 of the dehumidifier 30. The dehumidifier 31, the dehumidifiers 32 and 33, and the dehumidification filters 34 and 35 may be regenerated by being able to be operated after the pipe is separated.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is evident that many alternatives, modifications, and variations will readily occur to those skilled in the art without departing from the spirit and scope of the invention. Therefore, it should be understood that the disclosed embodiments are to be considered in an illustrative rather than a restrictive sense, and that the true scope of the invention is indicated by the appended claims rather than by the foregoing description, and all differences within the scope of equivalents thereof, .

11: Borehole 21: Rubber Packer
22: Radon collector 30: Dehumidifier
31: Dehumidifier 32,33: Dehumidifier
34,35: Dehumidification filter 40: Pump
50: radon collecting device 60: indoor radon measuring device
61: cover 70: sealing device
71: cover 72: solar cell
73: battery 74: heater line
36,91: hot wire

Claims (5)

The rubber packer 21 which is provided inside the borehole 11 and is expanded by injection of air to be in close contact with the inner circumferential surface of the borehole 11, and
A radon collecting tube 22 for collecting air from the lower side of the borehole 11 penetrating the upper and lower portions of the rubber packer 21 and sealed by the rubber packer 21;
A dehumidifier 30 connected directly to the radon collecting tube 22 to remove moisture from the air introduced through the radon collecting tube 22;
A radon collecting device 50 connected directly to the dehumidifying device 30 and including a pump 40 for forcibly suctioning the lower side air of the borehole 11;
An indoor radon measuring device (60) for measuring radon content in the air introduced by being directly connected to the pump (40) at set time intervals and transmitting the measured value to a radon management center through a wire / wireless communication device; And
A sealing device 70 for protecting the radon collecting device 50 and the indoor radon measuring device 60 from an external environment;
Radon real-time monitoring system of the direct delivery method radon using groundwater borehole, characterized in that it comprises a. The method of claim 1,
Radon real-time monitoring system of the radon direct delivery method using a groundwater borehole, characterized in that the heating wire 91 is further provided on the outside of the radon collecting pipe 22 and the dehumidifier 30. The method of claim 1,
The dehumidifier 30, Dehumidifier (31) for removing the moisture contained in the air in the lower side of the inlet borehole;
Dehumidifiers provided on both sides of the dehumidifier (31), the dehumidifier (32, 33) to further remove moisture in the air before and after dehumidification of the dehumidifier (31) separate from the dehumidifier (31) and a dehumidification filter for removing foreign matter ( 34,35);
A heating wire (36) provided outside the dehumidifier (30) to evaporate moisture accumulated in the dehumidifier (31) and the dehumidifier (32, 33);
Real-time monitoring system of the radon direct delivery method using the groundwater borehole, characterized in that comprising a. The method of claim 1,
The indoor radon measuring device (60), radon real-time monitoring system of the direct delivery method radon using groundwater borehole, characterized in that the cover is further provided for keeping warm, cold and moisture-proof to protect from the external environment. The method of claim 1,
The sealing device 70, in order to prevent condensation due to temperature difference between the inside and outside, the outside of the sealing device 70 is covered with a heat insulating cover 71, the inside of the sealing device 70 is freeze Radon direct transmission method using a groundwater borehole, characterized in that it comprises a solar heater 72 and a battery 73 for installing the prevention heater line 74, the power supply of the heater line 74. Real time monitoring system.

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