KR101040070B1 - Real time and automatic radon monitoring system and methods using groundwater borehole - Google Patents

Abstract

PURPOSE: A system and method for automatically monitoring radon in real time are provided to monitor the radon even through the sensitivity of an indoor air radon measuring device. CONSTITUTION: An underground water radon gas collecting device collects radon gas emitted from an underground water borehole. An indoor air radon measuring device(200) measures the content of radon gas collected in a sealed container and transmits the measured result to a wireless and wired communication device. A protection layer(400) maintains a constant temperature, a constant humidity, and repairs a sealed container(300) installed in the underground water borehole.

Description

Real Time and Automatic Radon Monitoring System and Methods Using Groundwater Borehole}

The present invention relates to an earthquake prediction system, and more particularly, to a real-time radon monitoring system and method using groundwater boreholes.

In the last 50 years, there have been about 500 earthquakes and earthquakes of magnitude 7.0 or more.

These earthquakes are roughly 15% of the world's earthquakes, with long stretches along the Pacific, Eurasian, Philippine and North American versions of Japan, Eurasia, India, Australia, the Philippines, In the Philippines, Indonesia, and Myanmar, at the border of the Pacific Ocean, more than 7.0 earthquakes in the 20th century occurred around the Himalayas, where more than 10 Southeast Asian, Eurasian and Indian-Australian versions collided. One of the regions belonging to the Indo-Chinese region and the Pacific Rim Earthquake, which is part of the Pacific Rim Earthquake, the North American region where the earthquake frequently occurs along the Aleutian Islands from the US West Coast, the boundary between the Pacific and North American Plates. In addition to the Pacific and the Pacific, In the region where the earthquakes occur along the borders of the small plates called Central America, South America, Nascapan, and Cocospan, where the earthquake meets, the Arabian and Eurasian plates meet a huge fault. Earthquakes are common in the Middle East, the Greek and Italian coastal regions of the Eurasian and African borders, and Morco and Algeria. Recently, the earthquake of Richter's seismograph 5.0 occurred in Chile, accompanied by a magnitude 8.8 dml earthquake and tsunami, and Australia, where earthquakes were relatively rare. Hong Kong Myungbo reported.

Meanwhile, according to the Korea Meteorological Administration's 2009 Earthquake Yearbook, 60 earthquakes of magnitude 2.0 or more occurred last year, of which there were 10 earthquakes, and more than 3.0 earthquakes occurred in Andong, Gyeongbuk. Ten occurrences occurred, including a 4.0 earthquake. Although the total number of earthquakes has increased, earthquakes of magnitude 3.0 and above do not show any significant increase, which can be observed and analyzed even if the earthquake has not been observed in the past due to the increase in the earthquake observation network and the improvement of observation data quality and analysis technology. It seems to be.

If the earthquake is known in advance, the effect of disaster prevention is great. However, vague earthquake forecasts of earthquakes that occur somewhere with little expectation of time, location, and size are of little help. In a place where the earthquake is repeatedly occurring at intervals of several decades or hundreds of years, when the number of years close to the average interval from the previous earthquake has elapsed, the next earthquake can be warned not so far, but more than that. It is difficult to predict when it will happen in detail.

The precursors of the earthquake include earthquake activity, tectonic disturbances, geomagnetism, groundwater, and abnormal behavior of animals. There are many known examples of abnormalities occurring in any of these items before the earthquake, and when an abnormality similar to that is recognized, think about whether it is a precursor to an earthquake.

However, even if an item appears abnormal, it cannot be assumed that an earthquake will occur afterwards, and the earthquake may occur when an abnormality is not recognized. Therefore, it is unlikely that a single item will be successful in forecasting. Sensitive observations of many items in other events are carried out at many points, while studies on the occurrence mechanisms of earthquake precursors, perceptual structures, and physical properties of each region are conducted. It is necessary to develop a method of identification of abnormalities. In order for earthquake forecasts to be helpful in disaster prevention, a system must be arranged for him. In other words, it is important to intensively record and monitor various data about each place.

Although they continue to invest huge amounts of money for earthquake forecasting, earthquake forecasts are still in the early stages of development.

Globally, examples of earthquake-predicting and reducing damage can be found in Jung-gu. That is the 1975 earthquake in China. At the time, China predicted the marine earthquake by combining the precursors of earthquakes, groundwater changes, surface changes, forward phenomena, and animal and human behaviors. There was no.

Existing technologies for earthquake forecasts include, but are not limited to: 1) earthquake wave (P wave) speed change, 2) technology using the Global Positioning System (GPS), 3) groundwater level change, 4) radon measurement, 5) rock Specific resistance, measurement of changes in ground current, and 6) predictive techniques using unusual precursors in animals and nature.

1) Earthquake wave (P wave) speed change observation technology is a method of predicting earthquake by examining the speed of P wave acting vertically in the basement and S wave acting horizontally. Under normal conditions, the P wave travels 1.75 times faster than the S wave. However, just before the earthquake, the P wave slows down by 10 to 15 percent as the rock expands and becomes dense. The minute speed differences of the seismic waves can predict the timing, location, and magnitude of the earthquake.

2) In the technology using the Global Positioning Information System (GPS), the Global Positioning Information System (GPS), which uses satellites to determine positional information, is also a major short-term prediction tool. Seismic occurrence and movement speed are captured by checking the change of location of each region according to the movement of the tectonic plate.

3) Groundwater level change measurement technology causes rocks to grow flat as stress increases before earthquakes occur. Thus, expanding rocks cause the groundwater level to rise.

4) Radon measurement technology is a precursor to earthquake generation, and much research is being conducted on the release of radon gas. Radon gas is a substance produced by radioactive decay of radium (Rd). Thus, radon gas is released along the new fracture surface under stress. Radon gas is relatively easy to observe because it appears to be different than usual for weeks or days before an earthquake is imminent. Groundwater is collected periodically to measure radon gas content in groundwater.

5) The measurement technique of specific resistance and ground current change of rock is used to measure abnormal ridges, tectonic fluctuations, ie expansion, inclination, volume change, etc., where the ground partially rises as the pressure under the ground increases. Measure Before the rock breaks into a single layer, change in electrical conductivity and chemical composition in groundwater due to microcracks generated by pressure are observed. As a result, earthquakes are predicted by phenomena such as changes in rock resistivity, ground current, and electromagnetic radiation.

6) The unique predictive technology that appears in animals and the natural world, first of all, is anxious for animals and refuses to run out of us or vice versa. In addition, the flock of birds is accompanied by a change in movement, such as suddenly flying in a circle or flying at a high speed. In nature, the waters of springs and lakes suddenly become muddy, loud sounds come from the ground, and flowers bloom in any season.

Therefore, the present invention is to propose a new monitoring system and method for predicting the earthquake by automatically measuring in real time the radon content released from the groundwater, which is currently being studied as a precursor of the earthquake.

The present invention, by using a conventional groundwater borehole to configure the system to enable the real-time and continuous continuous monitoring of the radon content emitted from the groundwater in real time, the monitoring cost is reduced because there is no need for always groundwater sampling and analysis process, The purpose of the present invention is to provide a real-time automatic radon monitoring system and method using groundwater boreholes that can be installed together with an automatic water level gauge and a hydraulic pressure gauge to simultaneously collect valuable data for earthquake prediction.

According to a monitoring system feature according to a first embodiment of the present invention for achieving the above objects, in the real-time automatic radon monitoring system using groundwater borehole, the system collects radon (Rn) gas emitted from the groundwater borehole Groundwater radon gas collection device (100A); Through the groundwater radon gas collecting device (100A), the groundwater radon content that changes every hour is measured at a predetermined time interval for the radon (Rn) gas collected in the airtight radon collecting airtight container, and the radon management through the wired / wireless communication device. An indoor air radon meter 200 for transmission to the center 500; In order to collect the radon gas emitted from the groundwater borehole 110 through the groundwater radon gas collecting device 100A, a stainless steel (SUS304) cylinder having a diameter of 30 cm × height 30 cm has a fixed lid, and the indoor air radon Dehumidifier 320 for removing the moisture inside the meter 200 and the sealed container, the styrofoam 330 for moisture-proof, room temperature between the sealed container and the ground surface, and for supplying power to the indoor air radon meter An airtight container for collecting ground water air radon for completely sealing the battery 620; Groundwater borehole, characterized in that it comprises a protective film 400 is installed at a height of 1 ~ 1.5m for the constant temperature, humidity and maintenance of the groundwater air radon collection sealed container 300 is installed on the groundwater borehole 110 It provides real-time automatic radon monitoring system.

Preferably, the indoor air radon meter 200, the moisture-proof vinyl 201 for wrapping the air inlet of the indoor air radon meter 200 to protect the meter from moisture, and the indoor air radon Silicon 340 is included for sealing cracks in holes drilled in the sealed container 300 for collecting ground water air radon to connect the measuring device 200 to an external communication cable and a power cable. It is done.

Preferably, the indoor air radon measuring unit 200 measures the radon gas collected from the groundwater radon gas collecting device 100A from the groundwater radon gas collecting device 100A according to a command of the microprocessor 280. The radon gas detection unit 210 detects through periodic communication for a set time and the initial radon content value in the groundwater borehole 110 through the indoor air radon measuring unit 200 is measured and input, and the measurement to be actually measured. A parameter setting unit 220 for setting a time interval and a final measurement time in advance, and radon gas contained in groundwater air from the groundwater radon gas collecting device 100A is collected in the sealed container 300 for collecting groundwater air radon. To calculate the radon content, by subtracting the data detected from the radon gas detector 210 with the initial radon content value of the parameter setting unit 220 The radon content calculation unit 230 for calculating a radon content collected in the groundwater air radon collecting hermetic container 300 by matching the set value and the initial radon content value input to the indoor air radon measuring device 200 ( Or a reference content value), the set measurement time interval, the final measurement time, and the radon content data calculated by the radon content calculator 230, and a user input application program (Man Machine Interface: MMI). And a memory 240 storing an operation program of the indoor air radon measuring device 200 and the radon content data stored in the memory 240 in the radon management center 500 in real time through a wired / wireless communication device. PC communication modem 250 and short-range wireless communication module 260, and the data on the radon content stored in the memory 240 immediately in the field according to the instructions of the microprocessor 280 The radon content display unit 270 displayed as a digital number so as to be able to be printed out and the radon content contained in the groundwater air are calculated and analyzed according to the data detected from the radon gas detection unit 210 at each set radon measurement time. A microprocessor 280 is provided to control stored data to be transmitted to the radon content display unit 270, the PC communication modem 250, and the short range wireless communication module 260.

Preferably, the radon management center 500 is installed in a remote location, the groundwater radon content data measured from the indoor air radon measuring unit 200 is collected through the PC communication modem 250 and the short-range wireless communication module 260. And a remote management server 510 for analyzing and managing the data, a multi-monitor 520 divided into a maximum of 64 screens, and a radon content alarm display unit 530 for notifying in accordance with the measured change in radon content.

Preferably, the radon content alarm display unit 530 is displayed in the order of green, yellow, red flashing light according to the measured change in radon content, and the intensity of sound by the buzzer is increased. Characterized in step by step.

Preferably, the groundwater air radon collecting hermetically sealed container 300, the outer diameter portion of the borehole 110 exposed to the ground surface inserted into the hole (Hall) drilled in the lower portion of the sealed container with a length of 5 ~ 10cm ( It is characterized in that it comprises a silicon (340) is a sealing repair) crack.

Preferably, the ground water air radon collecting hermetic container 300, the outside of the ground water air radon collecting hermetic container 300 to keep warm in order to prevent condensation due to the temperature difference between the inside and the outside Covered with, the ground water air radon collecting hermetic container 300 is installed inside the freeze protection heater line is connected to the power supply battery 620 of the indoor air radon measuring instrument embedded in the ground water air radon collecting hermetic container It is characterized by.

According to a monitoring system feature according to a second embodiment of the present invention for achieving the above objects, in the real-time automatic radon monitoring system using groundwater boreholes, the system is extended to the existing groundwater boreholes for the Jijibal area , Groundwater borehole 110 for embedding 10-20cm from the ground surface exposed in the airtight air radon collection sealed container 300, and a rubber packer installed smaller than the inner diameter of the borehole above the water level of the groundwater borehole 110 (Packer 130), the air injection pipe 140 for injecting air into the rubber packer 130, and the radon contained in the groundwater air through the hole (Hall) in close contact with the rubber packer 130 A groundwater radon gas collecting device (100B) having a plastic pipe (150) for collecting the gas into a sealed container (300) for collecting groundwater air radon; Through the groundwater radon gas collecting device 100B, the groundwater radon content that changes every hour is measured at a predetermined time interval with respect to radon (Rn) gas collected in a sealed container for collecting radon air in groundwater, and radon management is performed through wired / wireless communication devices. An indoor air radon meter 200 for transmission to the center 500; In order to collect the radon gas emitted from the groundwater borehole 110 through the groundwater radon gas collecting device 100B, a stainless steel (SUS304) cylinder having a diameter of 30 cm × height 30 cm has a fixed lid, and the indoor air radon Supplying power to the measuring device 200, the dehumidifying agent 320 for removing moisture in the sealed container, the styrofoam 330 for moisture proofing and room temperature between the sealed container and the ground surface, and the indoor air radon measuring device. An airtight air radon collection hermetically sealed container 300 which completely seals the battery 620 for it; Groundwater borehole, characterized in that it comprises a protective film 400 is installed at a height of 1 ~ 1.5m for the constant temperature, humidity and maintenance of the groundwater air radon collection sealed container 300 is installed on the groundwater borehole 110 It provides real-time automatic radon monitoring system.

Preferably, the rubber packer, the dense radon gas contained in the groundwater air discharged from the groundwater borehole 110 to be raised to the sealed container 300 for collecting the groundwater air radon with a relatively low air density It is characterized in that it is made of a high elastic rubber tube of the cylindrical shape of the upper and lower flat to enable the air injection.

According to a monitoring method feature according to the first embodiment of the present invention for achieving the above object, in the real-time automatic radon monitoring method using groundwater borehole, the method, the existing borehole 110 or A first step of using a well drilled for earthquake prediction and blocking the upper part of the borehole with a filter 120 to remove moisture; In the first step, the borehole 110 is exposed to the ground surface 10 ~ 20cm in length, 30cm × 30cm in diameter, the borehole (300) in the ground water air radon collection sealed container 300 made of stainless steel (SUS304) cylinder of the standard A second step of embedding 110; A third step of filling the styrofoam 330 for moisture-proofing and room temperature between the groundwater air radon collecting hermetic container 300 and the ground surface; A fourth step of manufacturing and covering a lid 310 at an upper portion of the ground container for collecting radon air radon, wherein the lid is fixed by a plurality of lock devices; The hole (Hall) which is drilled in the lower portion of the manufactured groundwater air radon collecting hermetic container (300), and the part in contact with the outer diameter of the exposed borehole 110 of the second step inserted into the hole to the silicon (340) A fifth step of applying a 5-10 cm length to completely seal the cover; A sixth step of filling the ground water air radon collecting hermetic container 300 with a dehumidifying agent (or five to seven hippo products) for removing moisture and moisture; The indoor air radon measuring device 200 embedded in the groundwater air radon collecting hermetic container 300 is covered with moisture-proof vinyl 201 except for the air inlet of the indoor air radon measuring device to protect the measuring device from moisture. A seventh step; After connecting the indoor air radon measuring device 200 and an external communication cable and a power cable, an eight-hole hole in the lower portion of the groundwater air radon collecting hermetic container 300 is completely sealed with silicon 340. Wow; After the installation of the groundwater air radon collecting hermetically sealed container 300 is completed, the cover is sealed by covering the lid 310 of the groundwater air radon collecting hermetically sealed container, and the ninth step of starting monitoring through the indoor air radon measuring device 200 is performed. Wow; The groundwater radon content data measured by the indoor air radon measuring device 200 includes a tenth step of being transmitted to the remote management server 510 through the PC communication modem 250 or the short range wireless communication module 260. And an eleventh step of installing a protective film 400 having a height of 1 to 1.5 m for constant temperature, humidity, and maintenance of the groundwater air radon collecting airtight container 300 on the borehole 110. It provides real-time automatic radon monitoring method using groundwater boreholes.

Preferably, in the fourth step, the groundwater air radon collecting hermetic container should be completely sealed as a space for collecting groundwater air radon, and the groundwater air radon collecting hermetic container is condensed due to temperature difference between inside and outside. (Iii) In order to prevent the phenomenon, the outer surface of the ground container for collecting radon collecting air is covered with a heat insulating cover, and the inside of the ground container for collecting radon collecting air is connected to a battery by installing a freezing heater line. Characterized in that it comprises a step.

Preferably, in the eighth step, in the connection of the indoor air radon meter 200 and a power cable, the battery 620 is used in case of using in a mountainous area where KEPCO commercial power supply is not possible, and the battery is groundwater air. Radon collection is characterized in that it comprises a thirteenth step of installing in the sealed container 300.

Preferably, in the eighth step, a wired / wireless communication device for transmitting radon content data measured from the indoor air radon measuring device and the communication cable to the indoor air radon measuring device 200 for collecting groundwater air radon. It characterized in that it comprises a fourteenth step of installing in the sealed container (300).

Preferably, in the tenth step, if the administrator presets the groundwater radon content measurement time interval every minute or every hour through the indoor air radon measuring unit 200, the groundwater radon content measurement result is determined according to the control command (radon management center) And a fifteenth step to be automatically transmitted to the remote management server 510 of 500.

According to the monitoring method feature according to the second embodiment of the present invention for achieving the above object, in the real-time automatic radon monitoring method using groundwater borehole, the method, the water level in the groundwater borehole 110 to the ground area A first step of measuring; A second step of installing a rubber packer 130 smaller than an inner diameter of the groundwater borehole 110 at the measured groundwater level 1 to 2m; A third step of injecting and expanding air into the rubber packer 130 to be in close contact with the inner diameter wall surface of the groundwater borehole 110; In the first step, the borehole 110 is exposed to the ground surface 10 ~ 20cm in length, 30cm × 30cm in diameter, the borehole (300) in the ground water air radon collection sealed container 300 made of stainless steel (SUS304) cylinder of the standard A fourth step of embedding 110; A fifth step of filling the styrofoam 330 between the groundwater air radon collecting hermetic container 300 and the ground surface for room temperature and moisture proofing; A sixth step of manufacturing and covering a lid 310 at an upper portion of the ground container for collecting radon air radon, wherein the lid is fixed with a plurality of lock devices; A hole (Hall) drilled in the lower portion of the manufactured groundwater air radon collecting hermetic container (300) and a portion in contact with the outer diameter of the exposed borehole 110 of the fourth step inserted into the hole to the silicon (340) A seventh step of applying a 5-10 cm length to completely seal the cover; An eighth step of filling in the ground water air radon collecting hermetic container 300 with 5 to 7 dehumidifying agents to remove moisture and moisture; The indoor air radon measuring device 200 embedded in the groundwater air radon collecting hermetic container 300 is covered with moisture-proof vinyl 201 except for the air inlet of the indoor air radon measuring device to protect the measuring device from moisture. A ninth step; A tenth step of connecting the indoor air radon measuring device 200 to an external communication cable and a power cable, and then completely sealing a hole formed in the lower portion of the ground container for collecting radon air for ground water with silicon 340; An eleventh step of fixing the cap 310 of the container when the installation of the sealed container 300 for collecting ground water air radon is completed and then starting monitoring through the indoor air radon measuring device 200; The groundwater radon content data measured by the indoor air radon measuring device 200 includes a twelfth step of being transmitted to the remote management server 510 through the PC communication modem 250 or the short range wireless communication module 260. Groundwater, characterized in that it comprises a thirteenth step of installing a protective film 400 of height 1 ~ 1.5m for the constant temperature, humidity and maintenance of the ground water air radon collection sealed container 300 on the borehole 110 It provides a real-time automatic radon monitoring method using boreholes.

Preferably, the rubber packer 130 in the second step is manufactured in the form of a high-elastic rubber tube capable of injecting air, the upper side of the rubber packer 130 injects air through a rubber hose having a predetermined size Air injection tube 140 and the center of the rubber packer to form a hole (Hall) is formed in the upper and lower portions characterized in that it comprises a fourteenth step of connecting the cylindrical plastic pipe 150 to the hole.

Preferably, in the fifth step, the ground water air radon collecting hermetic container 300 should be completely sealed as a space for collecting ground water air radon, and further, the temperature inside and outside the ground water air radon collecting hermetic container. In order to prevent condensation due to the difference, the outer surface of the ground container for collecting radon collecting air is covered with a heat insulating cover, and the inside of the ground container for collecting radon collecting air is installed with a battery line to prevent freezing. It characterized in that it comprises a fifteenth step of connecting.

Preferably, in the tenth step, a battery 620 is used in case of using the indoor air radon measuring device 200 in a mountainous area where KEPCO commercial power supply is impossible, and the battery is a sealed container for collecting ground water air radon ( 300) characterized in that it comprises a sixteenth step of installing therein.

Preferably, in the tenth step, a wired / wireless communication device for transmitting the radon content data measured from the indoor air radon measuring device 200 is embedded in the sealed container 300 for collecting ground water air radon. Characterized in that it comprises a step.

Preferably, in the twelfth step, an eighteenth step of pre-setting the measurement time interval by the manager to measure the groundwater radon content every minute or every hour through the indoor air radon measuring unit 200 It is done.

Real-time automatic radon monitoring system and method using the groundwater borehole of the present invention made by the above method has the following advantages.

(1) Since the radon content of groundwater can be monitored continuously and remotely in real time, it can reduce the number of casualties from earthquakes by predicting and predicting the earthquake precursor phenomenon in advance.

(2) While the existing method of collecting ground water and analyzing radon is complicated in groundwater sampling and analysis every day, the present invention has a significantly lower monitoring cost because only once the dehumidifier is replaced and managed every 15 days. .

(3) In the future, it is possible to install an automatic water level gauge and a water pressure gauge at the same time, so that valuable data can be collected simultaneously for earthquake prediction.

(4) As the dense air rises between the water table and the packer, there is a unique effect that can be monitored even if the sensitivity of the indoor air radon meter is low due to the high radon content.

1 is a view showing a first embodiment of a real-time automatic radon monitoring system using groundwater boreholes according to a preferred embodiment of the present invention
Figure 2 is a block diagram showing the detailed configuration of the indoor air radon measuring instrument (iREMS) for the real-time automatic radon monitoring system using the groundwater borehole in accordance with a preferred embodiment of the present invention
FIG. 3 is a block diagram illustrating a near field wireless communication module (ZigBee) of the indoor air radon detector of FIG. 2.
4 is a view showing a protective film for the real-time automatic radon monitoring system using the groundwater borehole in accordance with a preferred embodiment of the present invention
5 is a view showing a second embodiment of a real-time automatic radon monitoring system using groundwater boreholes according to a preferred embodiment of the present invention
6 is a flowchart showing a first embodiment of a real-time automatic radon monitoring method using groundwater boreholes according to a preferred embodiment of the present invention.
7 is a flowchart specifically illustrating a specific step with respect to FIG. 6.
8 is a flowchart illustrating a second embodiment of a real-time automatic radon monitoring method using groundwater boreholes according to a preferred embodiment of the present invention.
9 and 10 are flowcharts showing specific steps of FIG. 8 in detail.

Real-time automatic radon monitoring system and method using the groundwater borehole of the present invention will be described in more detail with reference to the accompanying drawings. In the following description of the present invention, the same technical configuration as in the prior art will be described with the same name as it is.

First, the concept of measuring and using radon (Rn) and radon prior to the embodiment of the present invention will be described as follows.

Radon (Rn) is a radioactive element caused by 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) (change from the parent element due to radioactive decay), which is formed during the radioactive decay of uranium (U) to ultimately lead (Pb). Therefore, a lot of radon means a lot of uranium. Basically, all the crust contains uranium, so when it is naturally radioactive, radon comes out.

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 are generated, and 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, the present invention is characterized by providing a more accurate and precise radon measurement system and method by automatically and continuously monitoring the radon gas content discharged from the groundwater in real time using a groundwater borehole (well).

1 to 5, a real-time automatic radon monitoring system using groundwater boreholes according to a preferred embodiment of the present invention will be described in detail.

The core technical solution for the implementation of the present invention is largely composed of groundwater radon gas collection device (100A, 100B), indoor air radon measuring device 200, groundwater air radon collection airtight container 300, protective film 400 .

First, referring to FIG. 1, a system for installing and monitoring a ground container for collecting radon air for groundwater air immediately above the groundwater borehole 110, which is the first embodiment of the present invention, will be described.

The groundwater radon gas collecting device 100A is a means for collecting radon (Rn) gas emitted from groundwater using the groundwater borehole 110, and the groundwater borehole 110 and the groundwater borehole upper end filter for removing moisture 120 Has

The groundwater borehole 110 is exposed to within 10 ~ 20cm in length from the ground surface, the length of about 10cm is exposed and embedded in the sealed container 300 for groundwater air radon collection.

Here, the exposure of the groundwater air radon collection hermetically sealed container 300 to about 10 cm in length is not affected by the moisture and moisture on the ground surface because it is the most reasonable length that can be installed at the bottom of the groundwater air radon collecting hermetically sealed container.

In addition, the moisture removal filter 120 is located at the upper end of the borehole 110, and removes the moisture emitted to the top of the borehole for the existing borehole (closed or observation hole) or earthquake prediction for the Jijibal area. It is a means to.

The indoor air radon measuring device 200 is a kind of real-time environmental radiation monitoring system (iERMS), which is collected in the sealed container 300 for collecting groundwater air radon through the groundwater radon gas collecting device 100A. The radon content (or Concentration of Rn Gas) which is changed from time to time with respect to the radon (Rn) gas is measured at a predetermined time interval, and transmitted to the radon management center 500 through the wired / wireless communication device described later. do.

Here, the indoor air radon meter 200 is wrapped with moisture-proof vinyl 201 except for an air inlet (not shown) of the indoor air radon meter 200 to protect the meter from moisture.

In addition, after connecting the indoor air radon measuring device 200 and an external communication cable and a power cable, the hole (Hall) of the ground container for collecting air radon air ground for the connection portion (Hall) sealing with silicon (340) (Sealling) ) Crack repair is performed.

In addition, in using the indoor air radon measuring device 200, the battery 620 is used when using in mountainous areas or remote areas where it is impossible to supply commercial power supplied from KEPCO, and the battery is an airtight container for collecting groundwater air radon (300). ) Inside. At this time, a PC communication modem 250 or a short range wireless communication module 260 for transmitting groundwater radon content measurement data to a remote location is also installed.

The ground container for collecting radon ground air 300 is made of stainless steel (SUS304) to collect groundwater air, and groundwater is discharged from the groundwater borehole 110 through the groundwater radon gas collecting device 100A. As a means for collecting in a sealed container for collecting air radon, a moisture removing filter 120 mounted to the upper end of the borehole 110, and an indoor air radon measuring device 200 for measuring the collected radon content; And groundwater radon measuring devices such as a dehumidifying agent 320 to remove moisture inside the container, and the sealed container is made of a stainless steel (SUS304) cylinder having a diameter of 30 cm x 30 cm in height, and an airtight container for collecting ground water air radon. The upper portion of the lid 310 is provided so as to cover, the lid 310 is fixed with a plurality of lock (Lock) device.

The reason for the size of the groundwater air radon collecting hermetically sealed container 300 is 30 cm in diameter x 30 cm in height, since the size of the indoor air radon measuring instrument is 15 cm in diameter × 10 cm in height and 15 cm in width. This is because it requires a minimum amount of space to go.

The groundwater air radon collecting hermetic container 300 should be completely sealed as a space for collecting groundwater air radon, and condensation may occur due to a temperature difference inside and outside the groundwater air radon collecting hermetic container 300. In order to prevent the phenomenon, the outer surface of the ground air radon collecting hermetically sealed container 300 is covered with a heat insulating cover, and the inside of the ground water air radon collecting hermetically sealed container 300 is provided with a freeze protection heater line to install the indoor air radon. It is connected to the battery 620 for supplying power to the measuring device 200 (see dotted line of the sealed container 300 for collecting ground water air radon of Figure 1).

In addition, between the ground water air radon collection sealed container 300 and the ground surface is filled with styrofoam 330 for moisture-proof, room temperature.

In addition, a hole (Hall) drilled in the lower portion of the groundwater air radon collecting hermetic container (300) and a portion in contact with the outer diameter of the exposed borehole 110 inserted into the hole by about 5 ~ 10cm silicon 340 Apply and seal completely.

The reason why the ground water air radon collection sealed container and the borehole outer diameter are in contact with each other by 5-10 cm of silicon 340 to completely seal the ground air is to prevent inflow of surface air and inflow of moisture and moisture.

In addition, inside the sealed container 300 for collecting ground water air radon 5 to 7 filled with a dehumidifying agent 320 such as a hippo product to drink water to remove moisture and moisture.

Meanwhile, referring to FIGS. 2 and 3, a detailed technical configuration of the indoor air radon measuring device (iERMS) 200 for a real-time automatic radon monitoring system using groundwater boreholes according to an embodiment of the present invention will be described.

First, referring to FIG. 2, the indoor air radon measuring device (iERMS) 200 includes a radon gas detector 210, a parameter setting unit 220, a radon content calculating unit 230, a memory 240, and a PC communication modem. 250, a near field communication module 260, a radon content display unit 270, and a microprocessor 280.

Here, the indoor air radon measuring device 200 is installed in the sealed container 300 for collecting groundwater air radon, being waterproof, moisture-proof, constant temperature, and humidity treatment, and measuring groundwater radon content to measure radon through wired / wireless communication devices. It is transmitted to the management center (500).

The radon gas detector 210 is a means for detecting radon gas contained in groundwater air. The radon gas is collected from the groundwater radon gas collecting device 100A in the groundwater air radon collecting sealed container 300 by a microprocessor. According to the command of (280), it detects through periodic communication during the measurement set time.

The parameter setting unit 220 is a kind of reference value setting unit that measures and inputs an initial radon content value in the groundwater borehole 110 through the indoor air radon measuring device (iERMS) 200, and actually measures a measurement time interval and Set the final measurement time in advance.

Here, the initial radon content value is a value for the radon content existing in the borehole from the beginning before the measurement by the indoor air radon measuring device 200, that is, the first time before the measurement time interval and the final measurement time setting. Groundwater radon content.

In addition, a program for setting parameter values may use a user input application program (Man Machine Interface (MMI)).

The radon content calculating unit 230 collects radon gas contained in the groundwater air from the groundwater radon gas collecting device 100A and collects the radon content (or radon gas concentration) by collecting the radon gas contained in the groundwater air radon collecting hermetic container 300. As a means, the data detected by the radon gas detection unit 210 is subtracted from the initial radon content value of the reference value setting unit 220 to be matched to a predetermined value and collected in the groundwater air radon collecting airtight container 300. Calculate the radon content.

The memory 240 sequentially stores the initial radon content value (or reference content value) input to the indoor air radon measuring instrument (iERMS) 200, the set measurement time interval and final measurement time, and the measured radon content data. FIFO (First In First Out) function. In addition, an operating program of an application program for a user input (MMI) and an indoor air radon measuring instrument (iERMS) 200 may be stored, respectively.

The PC communication modem 250 is a means for allowing an administrator to check the groundwater radon content data stored in the memory 240 in real time in the radon management center 500 through the Internet. Since communication and computing related technologies are well known in the art, further description thereof will be omitted.

The short range wireless communication module 260 wirelessly transmits groundwater radon content data stored in the memory 240 to the remote management server 510 of the radon management center 500, and transmits and receives with the remote management server 510. As a means for the communication, any one of ZigBee, Bluetooth, Infrared Communication Device (IrDA), and UWB (Ultra-wideband) may be selected according to a short range or a long distance to a remote location.

Referring to FIG. 3, the features and technical configuration of a Zigbee module, which is a short range wireless communication module 260 according to an exemplary embodiment of the present invention, will be described in detail.

First, the Zigbee module is characterized by: First, Bluetooth transmits 720kbps network access data using Frequency-Hopping Spread Spectrum, while Zigbee transmits 128kbps network access data. It handles a simple communication stack that takes up less than 32KB of memory resources in an 8-bit computational controller. Third, it can be quickly connected to handle simple stack communication and then returned to power saving mode, so that battery life can be maintained for a long time. Fourth, thousands of clients, and tens of thousands of nodes. This ZigBee technology can transmit data at speeds of 250 kbps over communication distances of tens of meters to up to several kilometers, can form a variety of network topologies and connect tens of thousands of indoor air radon meters (iERMS, 200). It can be small (note, two AA alkaline batteries can last from months to years).

Next, the technical configuration of the Zigbee module is a wireless antenna 261, RF receiver 262, phase locked loop (PLL) 263, power control circuit 264, RF transmitter 265, MAC processor 266 and a module control unit 267.

The Zigbee module 260, which is a short range wireless communication module according to a preferred embodiment of the present invention, performs a role of communicating with another short range wireless communication module based on a communication method capable of communicating wirelessly. Communicate based on the location information of each communication module. In addition, it should be possible to transfer information through the near field communication module between the remote management server 510, the upper system of the near field communication module.

Here, the technical configuration of the ZigBee module is a communication technology well known in the IT technology field, and thus a separate description thereof will be omitted.

Referring back to FIG. 2, the radon content display unit 270 is a means for displaying data on the groundwater radon content stored in the memory 240 as a digital number so that the data can be immediately confirmed in the field. The microprocessor 280 Follow the instructions.

The microprocessor 280 controls the entire indoor air radon detector of the real-time automatic radon monitoring system using groundwater boreholes according to an embodiment of the present invention, and according to the data detected from the radon gas detector 210 at every set measurement time. The radon content included in the groundwater air is calculated, and a control command is performed to transmit the analyzed and stored data to the radon content display unit 270, the PC communication modem 250, and the short range wireless communication module 260.

Referring back to FIG. 2, the radon management center 500 is located at a remote location away from the radon content measuring device at a predetermined distance and transmits groundwater radon content data measured from the indoor air radon measuring device 200 to the PC communication modem 250. And a short range wireless communication module 260 to collect, analyze, and manage the remote management server 510, the multi-monitor 520, and the radon content alarm display unit 530.

The remote management server 510 collects, analyzes, and manages radon content data transmitted through the PC communication modem 250 and the short-range wireless communication module 260, and is not shown in the remote management server 510. Although not included, an analysis control unit (not shown) for analyzing various event data for monitoring the groundwater radon content measurement value may be further included. In addition, the remote management server 510 may receive and manage data.

The multi-monitor 520 may be divided into a maximum of 64 screens, and the multi-monitor may be configured to divide the screen as many as the number of groundwater radon content measuring devices installed in the field.

The radon content alarm display unit 530 may be configured in the form of a signal and an alarm for displaying and warning in stages according to the change of the groundwater radon content measured and transmitted in real time.

In other words, the signal type is displayed in the order of green, yellow, and red blinking lights, and the alarm is to adjust the intensity of the sound by the buzzer step by step.

Here, referring to FIG. 2, the power supply device 600 is a means for supplying power to the indoor air radon measuring device (iERMS, 200), and the commercial power source 610 is used as it is where the KEPCO commercial power supply is possible. And, it is installed in the sealed container 300 for groundwater air radon collection in case of use in the case of impossible mountainous areas or remote areas and power outages.

On the other hand, with reference to Figure 4, the protective film 400 according to an embodiment of the present invention, to protect and manage the groundwater radon measuring devices embedded in the groundwater air radon collecting hermetic container 300 on the groundwater borehole 110 As a means, a protective film having a height of 1 to 1.5 m is installed for constant temperature, humidity, and maintenance of the measuring devices.

The reason why the height of the protective film 400 is 1 to 1.5 m is because the height that is suitable for maintenance by the manager.

Next, with reference to Figure 5, a ground container for collecting ground water air radon on the ground water borehole 110 exposed to the rubber packer (130) and the ground surface on the ground water borehole level 1-2m of the second embodiment of the present invention ( The system to install and monitor 300) will be described.

In the second embodiment of the present invention, the groundwater radon collecting device 100B is different from the first embodiment in which the airtight air radon collecting airtight container 300 is installed directly on the groundwater borehole 110 described above. The technical configurations are all the same. Therefore, hereinafter, in the monitoring system according to the second embodiment, only the groundwater radon gas collecting device 100B will be described in detail.

The groundwater radon gas collection device 100B according to the second embodiment of the present invention includes a groundwater borehole 110, a rubber packer 130, an air injection pipe 140, and a plastic pipe 150.

The groundwater borehole 110 can use an existing groundwater borehole (closed or observation hole) for the geoclimbal area, and the groundwater borehole 110 is typically exposed to within 10-20 cm from the ground surface, so that 10-20 cm in length. The groundwater is exposed and built in the airtight air radon collecting container 300 (same as the first embodiment).

Exposing the ground water air radon collection hermetically sealed container 300 to 10 to 20 cm in length is not affected by moisture and moisture on the ground surface, as in the first embodiment described above, and the lower portion of the ground vessel air radon collected hermetically sealed container. Because it is the most reasonable way to install it.

The rubber packer 130 is a high elastic rubber tube capable of injecting air, and is manufactured in a cylindrical shape having a flat top and bottom, and an airtight container for collecting groundwater air radon having a relatively low air density for high density radon gas contained in the groundwater air (300). As a means to raise the radon to be easily collected by the), the groundwater borehole 110 is installed to produce smaller than the inner diameter of the borehole on the water level of 1 ~ 2m.

The reason why the rubber packer 130 is installed on the groundwater borehole 110 above the water level of 1 to 2m is that, unless there is excessive pumping of the surrounding groundwater, the maximum change width of the groundwater level during the year is usually about 30 cm. If the rubber packer 130 is installed on the ˜2m, it is not necessary to manage the rubber packer movement or maintenance due to the groundwater level change.

In addition, the center of the rubber packer 130 has a hole (Hall) is formed in the upper and lower portions through which the plastic pipe 150 penetrates.

The air injection pipe 140 is a means for connecting the rubber hose having a predetermined size to the upper portion of the rubber packer 130 and injecting air from the outside to inflate the inner wall surface of the groundwater borehole 110 to be in close contact with each other. At this time, when the air injection is finished, the air injection pipe 140 is closed by a valve.

The plastic pipe 150 is a means for collecting radon by allowing the radon gas contained in the groundwater air to penetrate the rubber packer 130 to be raised to the groundwater air radon collecting hermetic container 300.

As described above, in the first and second embodiments of the present invention, the groundwater radon measuring devices including the indoor air radon measuring device 200 are collected on the groundwater borehole 110 that is the groundwater radon gas collecting devices 100A and 100B. When all of the installation is completed inside the sealed container 300 for closing the cap 310 of the ground container for collecting air radon collecting air ground is to start monitoring at all times.

In addition, the groundwater radon content data measured from the groundwater radon gas collection device (100A, 100B) and the indoor air radon measuring device 200 is transmitted to the monitoring system or the administrator personal computer of the radon management center 500 through a wired / wireless communication device. Real time is automatically received continuously.

Here, the groundwater radon content measurement may be set by the administrator through the indoor air radon measuring device 200, the measurement time interval, such as every minute, every hour.

Meanwhile, referring to FIGS. 6 to 10, a real-time automatic radon monitoring method using groundwater boreholes according to a preferred embodiment of the present invention will be described in detail.

First, referring to Figures 6 and 7, the method of the first embodiment to install and monitor the groundwater air radon collecting hermetic container 300 directly above the groundwater borehole 110 is as follows.

1) Using the existing borehole (closed hole or observation hole) 110 or the well drilled for earthquake prediction for the Jijibal area, it is blocked with a filter 120 for removing moisture on the borehole (S01).

2) In the first step (S01), the borehole exposes the length of 10 ~ 20cm on the surface, the borehole in a stainless steel (SUS304) cylindrical groundwater air radon collection sealed container 300 of diameter 30cm × height 30cm standard It is embedded (S02).

3) Filled with styrofoam 330 for moisture-proof, room temperature between the ground water air radon collection sealed container 300 and the ground surface (S03).

4) The lid of the ground water air radon collection sealed container to be made to cover the cover 310, but the lid is fixed by a plurality of lock (Lock) device (S04).

Here, the ground water air radon collecting hermetic container 300 should be completely sealed as a space for collecting ground water air radon, and also prevents condensation due to temperature differences inside and outside the ground water air radon collecting hermetic container. In order to cover the outer surface of the airtight container for collecting radon collecting ground water, the inside of the airtight container for radon collecting the groundwater air is connected to the battery by installing a freeze protection heater line (airtight container for groundwater air radon collection of Figure 1 See the dashed lines inside and outside of 300) (S12).

5) the hole (Hall) which is drilled in the lower portion of the groundwater air radon collecting hermetic container (300), and the part in contact with the outer diameter of the exposed borehole 110 of the second step (S02) inserted into the hole (silicon) 340) by applying a length of 5 ~ 10cm to completely seal (S05).

6) Inside the sealed container 300 for collecting ground water air radon is filled with a dehumidifying agent (or 5 to 7 hippo products to drink water) to remove moisture and moisture (S06).

7) The indoor air radon measuring device 200 embedded in the groundwater air radon collecting hermetic container 300 is a moisture-proof vinyl 201 except for the air inlet of the indoor air radon measuring device in order to protect the measuring device from moisture. Will be wrapped (S07).

8) After connecting the indoor air radon measuring device 200 and an external communication cable and a power cable, a hole (Hall) drilled in the lower portion of the groundwater air radon collecting hermetic container 300 is completely sealed with silicon 340. (S08).

In this case, when the indoor air radon measuring device 200 is used in a mountain area where KEPCO commercial power supply is not possible, the battery 620 is used, and the battery is installed inside the sealed container 300 for collecting ground water air radon (S13). At this time, the wired / wireless communication device for transmitting the radon content measurement data is also installed in the sealed container for collecting ground water air radon (S14).

9) When the installation of the groundwater air radon collecting hermetically sealed container 300 in which groundwater radon measuring devices (iERMS, power and communication cable, etc.) are installed on the borehole 110 is completed, the lid 310 of the groundwater air radon collecting hermetically sealed container 310 is completed. After covering and sealing, the monitoring is always started through the indoor air radon meter 200 (S09).

10) The groundwater radon content data measured by the indoor air radon measuring unit 200 is transmitted to the remote management server 510 through the PC communication modem 250 or the short range wireless communication module 260 (S10).

Here, when the administrator sets the groundwater radon content measurement time interval such as every minute or every hour through the indoor air radon measuring machine 200, the groundwater radon content measurement result is a remote management server 510 of the radon management center 500 according to the control command. It is transmitted to (S15).

11) In addition, a protective film 400 having a height of 1 to 1.5 m is installed for constant temperature, humidity, and maintenance of the groundwater air radon collection sealed container 300 on the borehole 110 (S11).

Next, in the method of the second embodiment to install and monitor the groundwater air radon collecting hermetic container 300 on the ground water borehole 110 exposed to the surface and the rubber packer (Packer) on the ground water borehole 110 level 1 ~ 2m Explain.

1) The second method according to the present invention is the same as or similar to the above-described first method of installing the sealed container 300 for groundwater air radon collection immediately above the groundwater borehole 110, but first, the existing borehole for the target area. Measure from the water level in the groundwater borehole 110 using (S101).

2) Install a rubber packer 130 smaller than the inner diameter of the groundwater borehole 110 at the measured groundwater level 1 ~ 2m point (S102).

Here, the rubber packer 130 is manufactured in the form of a high-elastic rubber tube capable of injecting air, the upper side of the rubber packer 130, the air injection pipe 140 for injecting air through a rubber hose having a predetermined standard is It is provided. In addition, the center of the rubber packer is formed with a hole (Hall) formed in the upper and lower portions, and connects the cylindrical plastic pipe 150 to the hole. At this time, the radon is collected by allowing the groundwater air radon with a high density to rise to the groundwater air radon collecting hermetic container 300 having a relatively low air density through the plastic pipe 150 (S114).

3) Injecting air into the rubber packer 130 to expand and close the ground water borehole 110 to the inner diameter wall surface (S103).

4) In the first step (S101), the borehole is exposed to the ground surface 10 ~ 20cm, the diameter 30cm × height 30cm standard stainless steel (SUS304) cylindrical groundwater air radon collecting the airtight container 300 for collecting the borehole Built-in (S104).

5) Filled with styrofoam 330 for room temperature, moisture-proof between the ground water air radon collection airtight container 300 and the ground surface (S105).

6) to the top of the ground container for collecting air radon collecting lid 310 to be made and covered, the lid is fixed by a plurality of lock (Lock) device (S106).

Here, the ground water air radon collecting hermetic container 300 should be completely sealed as a space for collecting ground water air radon, and also prevents condensation due to temperature differences inside and outside the ground water air radon collecting hermetic container. In order to cover the outside of the sealed container for collecting ground water air radon cover with a heat insulating cover, the inside of the sealed container for collecting ground water air radon is connected to the battery by installing a freeze protection heater line (ground water air radon collection of Figure 5) See dashed line of airtight container 300) (S115).

7) the hole (Hall) which is drilled in the lower portion of the ground water air radon collecting hermetic container (300), and the part in contact with the outer diameter of the exposed borehole 110 of the fourth step (S104) inserted into the hole (silicon) 340) by applying 5 ~ 10cm in length to completely seal (S107).

8) Inside the sealed container 300 for collecting ground water air radon is filled with a dehumidifying agent (or 5 to 7 hippo products to drink water) to remove moisture and moisture (S108).

9) The indoor air radon measuring device 200 embedded in the groundwater air radon collecting hermetic container 300 is a moisture-proof vinyl 201 except for the air inlet of the indoor air radon measuring device in order to protect the measuring device from moisture. Will be wrapped (S109).

10) After connecting the indoor air radon measuring device 200 and an external communication cable and a power cable, the hole (Hall) drilled in the lower portion of the groundwater air radon collecting sealed container is completely sealed with silicon 340 (S110). .

Here, the battery 620 is used in case of using the indoor air radon measuring device 200 in a mountainous region where KEPCO commercial power supply is not possible, and the battery is provided inside the sealed container 300 for collecting ground water air radon (S116). ). At this time, a wired / wireless communication device for transmitting radon content measurement data is also installed (S117).

11) After the installation of the groundwater air radon collecting hermetic container 300 with the groundwater radon measuring devices (iERMS, power cable and communication cable, etc.) installed on the borehole 110 is completed, the lid 310 of the container is covered and fixed. In step S111, the indoor air radon measuring unit 200 starts monitoring.

12) The groundwater radon content data measured by the indoor air radon measuring unit 200 is transmitted to the remote management server 510 through the PC communication modem 250 or the short range wireless communication module 260 (S112).

Here, when the administrator sets the groundwater radon content measurement time interval in advance, such as every minute, every hour through the indoor air radon measuring machine 200, the groundwater radon content measurement result is a remote management server of the radon management center 500 according to the control command. It is automatically sent to 510 (S118).

13) In addition, a protective film 400 having a height of 1 to 1.5 m is installed for constant temperature, humidity, and maintenance of the groundwater air radon collection sealed container 300 on the borehole 110 (S113).

In this embodiment of the present invention, the first method for monitoring by installing the sealed container 300 for groundwater air radon collection immediately above the groundwater borehole 110, and the ground water borehole 110 level 1 ~ 2m rubber packer (Packer) 130 and the second method of installing and monitoring the groundwater air radon collecting hermetic container 300 on the groundwater borehole 110 exposed from the ground surface, the technical configuration steps are mostly the same or similar.

However, unlike the first method, the method of installing the groundwater radon gas collecting device 100B is different from the first method, and the groundwater level accumulated in the borehole 110 is first measured, and then a rubber packer is placed on the borehole level 1 to 2m. Packer (130) is installed, and the rubber packer (130) is given air pressure to expand and close contact with the groundwater borehole (110) inner diameter wall surface, and through the plastic pipe (150) in the center of the rubber packer (130) There is a significant difference in the method of monitoring in that the high density radon gas contained in the groundwater air is collected to be raised to a closed container 300 for collecting groundwater air radon having a relatively low air density.

Therefore, the second method of monitoring the real-time automatic radon by installing a rubber packer (Packer) in the groundwater borehole 110 and the installation of a sealed container 300 for groundwater air radon collection on the groundwater borehole 110 exposed to the ground surface, Compared to the first method of installing the groundwater air radon collecting hermetic container 300 directly above the groundwater borehole, the dense air between the groundwater surface and the rubber packer 130 rises, so the indoor air radon is expected with high radon content. Even if the sensitivity of the meter 200 is low, sufficient monitoring is possible.

As such, the real-time automatic radon monitoring system and method using the groundwater borehole according to the preferred embodiment of the present invention can monitor the radon content in the groundwater borehole continuously and remotely in real time, so that the existing daily sampling and complex analysis In addition, it is possible to install an automatic water level gauge and a pressure gauge at the same time in the future, so that it is possible to collect valuable seismic prediction data, and sufficient monitoring is possible even if the sensitivity of the indoor air measuring device is low. .

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

100, 100A, 100B: Groundwater radon gas collection device
110: groundwater borehole (Gwanjeong)
120: moisture removal filter 130: rubber packer (Packer)
140: air injection pipe 150: plastic pipe
200: indoor air radon measuring instrument 201: vinyl for moisture proof
210: radon gas detection unit 220: parameter setting unit
230: radon content calculation unit 240: memory
250: PC communication modem 260: short range wireless communication module
261: wireless antenna 262: RF receiver
263: phase synchronization circuit 264: power control circuit
265 RF transmitter 266 MAC processor
267: module control unit 270: radon content display unit
280: microprocessor
300: airtight air radon collection airtight container
310: lid 320: dehumidifier
330: Styrofoam 340: Silicon
400: Shield 500: Radon Management Center
510: remote management server 520: multi-monitor
530: radon content alarm display unit 600: power supply device
610: commercial power 620: battery

Claims (20)

In the real-time automatic radon monitoring system using groundwater boreholes,
The system includes: a groundwater radon gas collecting device (100A) for collecting radon (Rn) gas discharged from the groundwater borehole;
Through the groundwater radon gas collecting device (100A), the groundwater radon content that changes every hour is measured at a predetermined time interval for the radon (Rn) gas collected in the airtight radon collecting airtight container, and the radon management through wired / wireless communication device An indoor air radon meter 200 for transmission to the center 500;
In order to collect the radon gas discharged from the groundwater borehole 110 through the groundwater radon gas collecting device 100A, a stainless steel (SUS304) cylinder having a diameter of 30 cm × height 30 cm has a fixed lid, and the indoor air radon Dehumidifier 320 for removing the moisture inside the meter 200 and the sealed container, the styrofoam 330 for moisture-proof, room temperature between the sealed container and the ground surface, and for supplying power to the indoor air radon meter An airtight container for collecting ground water air radon for completely sealing the battery 620;
Groundwater borehole, characterized in that it comprises a protective film 400 is installed at a height of 1 ~ 1.5m for the constant temperature, humidity and maintenance of the groundwater air radon collection sealed container 300 is installed on the groundwater borehole 110 Real time automatic radon monitoring system.
The method according to claim 1,
The indoor air radon measuring device 200 is a moisture-proof vinyl 201 wrapping the air inlet of the indoor air radon measuring device 200 to protect the measuring device from moisture, and the indoor air radon measuring device 200. Groundwater borehole, characterized in that the silicon (340) is included for sealing cracks in the hole (Hall) drilled in the sealed container 300 for groundwater air radon collection to connect the external communication cable and the power cable Real time automatic radon monitoring system.
The method according to claim 1,
The indoor air radon measuring unit 200 cycles the radon gas collected from the groundwater radon gas collecting device 100A to the groundwater air radon collecting hermetic container 300 for a measurement set time according to a command of the microprocessor 280. Radon gas detection unit 210 to detect through the normal communication,
The parameter setting unit 220 for measuring and inputting an initial radon content value in the groundwater borehole 110 through the indoor air radon measuring device 200 and actually setting a measurement time interval and a final measurement time in advance. Wow,
The radon gas contained in the groundwater air is collected from the groundwater radon gas collecting device 100A in the ground container for collecting radon gas for groundwater air, and the radon content is calculated, and the radon gas detection unit 210 detects the radon content. A radon content calculating unit 230 for calculating and processing the radon content collected in the groundwater air radon collecting hermetic container 300 by matching the preset value with the initial radon content value of the parameter setting unit 220 and subtracting it;
Stores the initial radon content value (or reference content value) input to the indoor air radon measuring device 200, the set measurement time interval and the final measurement time, and the radon content data calculated by the radon content calculating unit 230. And a memory 240 for storing a user input application program (MMI) and an operation program of the indoor air radon measuring device 200;
A PC communication modem 250 and a short-range wireless communication module 260 for allowing an administrator to check the radon content data stored in the memory 240 in real time in the radon management center 500 through a wired / wireless communication device;
Radon content display unit 270 is displayed as a digital number so that the data on the radon content stored in the memory 240 can be immediately confirmed in the field according to the instructions of the microprocessor 280,
The radon content contained in the groundwater air is calculated according to the data detected by the radon gas detection unit 210 at every set radon measurement time, and the radon content display unit 270 and the PC communication modem 250 and the short range are analyzed and stored. Real-time automatic radon monitoring system using a groundwater borehole, characterized in that the microprocessor 280 to control to transmit to the wireless communication module 260, respectively.
The method of claim 3,
The radon management center 500 is installed at a remote location, and collects groundwater radon content data measured from the indoor air radon measuring device 200 through the PC communication modem 250 and the short range wireless communication module 260, and analyzes and manages it. Real time automatic using groundwater borehole, characterized in that the remote management server 510 and the multi-monitor 520 is divided into a maximum of 64 screens and the radon content alarm display unit 530 to be notified in accordance with the measured change in radon content Radon monitoring system.
The method of claim 4, wherein
The radon content alarm display unit 530 is displayed in the order of green, yellow, red flashing lights according to the measured change of radon content, and the intensity of the sound by the buzzer is gradually adjusted. Real-time automatic radon monitoring system using groundwater borehole, characterized in that.
The method according to claim 1,
The ground water air radon collecting hermetic container 300 seals the outer diameter portion of the borehole 110 exposed to the ground surface inserted into a hole drilled in a lower portion of the ground water air radon collecting hermetic container to a length of 5 to 10 cm. Real-time automatic radon monitoring system using a groundwater borehole, characterized in that (Sealling) crack repair is made of silicon (340).
The method of claim 6,
The ground water air radon collecting hermetically sealed container 300, the outside of the ground water air radon collecting hermetically sealed container 300 is covered with a heat insulating cover in order to prevent condensation due to internal and external temperature differences, The inside of the groundwater air radon collecting hermetic container 300 is installed in the airtight prevention heater line is connected to the power supply battery 620 of the indoor air radon measuring instrument embedded in the groundwater air radon collecting hermetic container. Real-time automatic radon monitoring system using groundwater boreholes.
In the real-time automatic radon monitoring system using groundwater boreholes,
The system extends to the existing groundwater borehole for the Jijibal area, and the groundwater borehole 110 and the groundwater borehole 110 to embed 10-20 cm from the ground surface in the sealed container 300 for the collection of groundwater air radon. ) Rubber packer (130) is installed smaller than the inner diameter of the borehole on the water level 1 ~ 2m, the air injection pipe 140 for injecting air into the rubber packer 130, and the rubber packer 130 A groundwater radon gas collecting device (100B) having a plastic pipe (150) which penetrates through a hole (Hall) in close contact with and collects radon gas contained in groundwater air with a sealed container for collecting groundwater air radon (300);
Through the groundwater radon gas collecting device 100B, the groundwater radon content that changes every hour is measured at a predetermined time interval with respect to radon (Rn) gas collected in a sealed container for collecting radon air in groundwater, and radon management is performed through wired / wireless communication devices. An indoor air radon meter 200 for transmission to the center 500;
In order to collect the radon gas emitted from the groundwater borehole 110 through the groundwater radon gas collecting device 100B, a stainless steel (SUS304) cylinder having a diameter of 30 cm × height 30 cm has a fixed lid, and the indoor air radon Supplying power to the measuring device 200, the dehumidifying agent 320 for removing moisture in the sealed container, the styrofoam 330 for moisture proofing and room temperature between the sealed container and the ground surface, and the indoor air radon measuring device. An airtight air radon collection hermetically sealed container 300 which completely seals the battery 620 for it;
Groundwater borehole, characterized in that it comprises a protective film 400 is installed at a height of 1 ~ 1.5m for the constant temperature, humidity and maintenance of the groundwater air radon collection sealed container 300 is installed on the groundwater borehole 110 Real time automatic radon monitoring system.

The method of claim 8,
The rubber packer, the air injection is to increase the high density radon gas contained in the groundwater air discharged from the groundwater borehole 110 to the groundwater air radon collecting hermetic container 300 having a relatively low air density Real-time automatic radon monitoring system using groundwater borehole, characterized in that the upper and lower sides are made of high elastic rubber tubes of flat cylindrical shape.
In the real-time automatic radon monitoring method using groundwater borehole,
The method may include a first step of using a well drilled for an existing borehole 110 or an earthquake prediction for a jijibal area, and blocking the top of the borehole with a filter 120 to remove moisture;
In the first step, the borehole 110 is exposed to the ground surface 10 ~ 20cm in length, 30cm × 30cm in diameter, the borehole (300) in the ground water air radon collection sealed container 300 made of stainless steel (SUS304) cylinder of the standard A second step of embedding 110;
A third step of filling the styrofoam 330 for moisture-proofing and room temperature between the groundwater air radon collecting hermetic container 300 and the ground surface;
A fourth step of manufacturing and covering a lid 310 at an upper portion of the ground container for collecting radon air radon, wherein the lid is fixed by a plurality of lock devices;
The hole (Hall) which is drilled in the lower portion of the manufactured groundwater air radon collecting hermetic container (300), and the part in contact with the outer diameter of the exposed borehole 110 of the second step inserted into the hole to the silicon (340) A fifth step of applying a 5-10 cm length to completely seal the cover;
A sixth step of filling the ground water air radon collecting hermetic container 300 with a dehumidifying agent (or five to seven hippo products) for removing moisture and moisture;
The indoor air radon measuring device 200 embedded in the groundwater air radon collecting hermetic container 300 is covered with moisture-proof vinyl 201 except for the air inlet of the indoor air radon measuring device to protect the measuring device from moisture. A seventh step;
After connecting the indoor air radon measuring device 200 and an external communication cable and a power cable, an eight-hole hole in the lower portion of the groundwater air radon collecting hermetic container 300 is completely sealed with silicon 340. Wow;
After the installation of the groundwater air radon collecting hermetically sealed container 300 is completed, the cover is sealed by covering the lid 310 of the groundwater air radon collecting hermetically sealed container, and the ninth step of starting monitoring through the indoor air radon measuring device 200 is performed. Wow;
The groundwater radon content data measured by the indoor air radon measuring device 200 includes a tenth step of transmitting to the remote management server 510 through the PC communication modem 250 or the short range wireless communication module 260.
In addition, the eleventh step of installing a protective film 400 having a height of 1 ~ 1.5m for the constant temperature, humidity and maintenance of the ground water air radon collection sealed container 300 on the borehole 110 Real-time automatic radon monitoring method using groundwater boreholes.
The method of claim 10,
In the fourth step, the ground water air radon collecting hermetic container should be completely sealed as a space for collecting ground water air radon, and the ground water air radon collecting hermetic container is condensation due to temperature difference between inside and outside. In order to prevent the, the outside of the groundwater air radon collection sealed container is covered with a heat insulating cover, the inside of the groundwater air radon collection sealed container includes a twelfth step of installing a freeze protection heater line connected to the battery Real-time automatic radon monitoring method using groundwater borehole, characterized in that.
The method of claim 10,
In the eighth step, in the connection between the indoor air radon measuring device 200 and a power cable, a battery 620 is used in case of use in a mountainous region where KEPCO commercial power supply is impossible, and the battery is sealed for collecting ground water air radon. Real-time automatic radon monitoring method using a groundwater borehole, characterized in that it comprises a thirteenth step of installing in the vessel (300). The method of claim 10,
In the eighth step, the wired and wireless communication device for transmitting the radon content data measured from the indoor air radon meter 200 and the communication cable in the indoor air radon meter 200 to install in the sealed container 300 Real-time automatic radon monitoring method using the groundwater borehole, characterized in that it comprises a fourteenth step.
The method of claim 10,
In the tenth step, if the administrator presets the groundwater radon content measurement time interval every minute or every hour through the indoor air radon measuring device 200, the groundwater radon content measurement result is remote from the radon management center 500 according to the control command. Real-time automatic radon monitoring method using a groundwater borehole, characterized in that it comprises a fifteenth step to be automatically transmitted to the management server (510).
In the real-time automatic radon monitoring method using groundwater borehole,
The method includes a first step of measuring the water level in the groundwater borehole 110 to the ground jibbal region;
A second step of installing a rubber packer 130 smaller than an inner diameter of the groundwater borehole 110 at the measured groundwater level 1 to 2m;
A third step of injecting and expanding air into the rubber packer 130 to be in close contact with the inner diameter wall surface of the groundwater borehole 110;
In the first step, the borehole 110 is exposed to the ground surface 10 ~ 20cm in length, 30cm × 30cm in diameter, the borehole (300) in the ground water air radon collection sealed container 300 made of stainless steel (SUS304) cylinder of the standard A fourth step of embedding 110;
A fifth step of filling the styrofoam 330 between the groundwater air radon collecting hermetic container 300 and the ground surface for room temperature and moisture proofing;
A sixth step of manufacturing and covering a lid 310 at an upper portion of the ground container for collecting radon air radon, wherein the lid is fixed with a plurality of lock devices;
A hole (Hall) drilled in the lower portion of the manufactured groundwater air radon collecting hermetic container (300) and a portion in contact with the outer diameter of the exposed borehole 110 of the fourth step inserted into the hole to the silicon (340) A seventh step of applying a 5-10 cm length to completely seal the cover;
An eighth step of filling in the ground water air radon collecting hermetic container 300 with 5 to 7 dehumidifying agents to remove moisture and moisture;
The indoor air radon measuring device 200 embedded in the groundwater air radon collecting hermetic container 300 is covered with moisture-proof vinyl 201 except for the air inlet of the indoor air radon measuring device to protect the measuring device from moisture. A ninth step;
A tenth step of connecting the indoor air radon measuring device 200 to an external communication cable and a power cable, and then completely sealing a hole formed in the lower portion of the ground container for collecting radon air for ground water with silicon 340;
An eleventh step of fixing the cap 310 of the container when the installation of the sealed container 300 for collecting ground water air radon is completed and then starting monitoring through the indoor air radon measuring device 200;
The groundwater radon content data measured by the indoor air radon measuring device 200 includes a twelfth step of being transmitted to the remote management server 510 through the PC communication modem 250 or the short range wireless communication module 260.
In addition, the thirteenth step of installing a protective film 400 having a height of 1 ~ 1.5m for the constant temperature, humidity and maintenance of the ground water air radon collection sealed container 300 on the borehole 110 Real-time automatic radon monitoring method using groundwater boreholes.
The method of claim 15,
The rubber packer 130 in the second step is manufactured in the form of a high-elastic rubber tube capable of injecting air, an air injection pipe for injecting air through a rubber hose having a predetermined size on the upper side of the rubber packer 130 140 and a real-time automatic radon using a groundwater borehole, comprising a fourteenth step of connecting a cylindrical plastic pipe 150 to the hole by forming a hole (Hall) formed in the center of the rubber packer. Monitoring method.
The method of claim 15,
In the fifth step, the ground water air radon collecting hermetic container 300 should be completely sealed as a space for collecting ground water air radon, and condensation may occur due to a temperature difference inside and outside the ground water air radon collecting hermetic container. (Iii) In order to prevent the phenomenon, the outer surface of the ground container for collecting radon air radon is covered with a heat insulating cover, and the inside of the ground container for collecting radon collecting air is connected with a battery by installing a freezing heater line. Real-time automatic radon monitoring method using groundwater borehole, characterized in that it comprises a step.
The method of claim 15,
In the tenth step, a battery 620 is used in case of using the indoor air radon measuring device 200 in a mountainous region where KEPCO commercial power supply is not possible, and the battery is inside the sealed container 300 for collecting ground water air radon. Real-time automatic radon monitoring method using a groundwater borehole, characterized in that it comprises a sixteenth step of installing.
The method of claim 15,
In the tenth step, comprising a seventeenth step of embedding a wired / wireless communication device for transmitting the radon content data measured from the indoor air radon measuring unit 200 in the sealed container 300 for collecting ground water air radon Real-time automatic radon monitoring method using groundwater borehole, characterized in that.
The method of claim 15,
In the twelfth step, the groundwater borehole comprises an eighteenth step of setting the measurement time interval in advance so that the manager measures the groundwater radon content every minute or every hour through the indoor air radon measuring device 200. Real-time automatic radon monitoring method using.

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