KR20120124534A - Soil radon gas measuring system for uranium exploration - Google Patents

Abstract

PURPOSE: A soil radon measurement system for uranium resource exploration is provided to accurately measure soil radon by directly delivering soil radon to an indoor radon measurement device without a disturbance of an external environment. CONSTITUTION: A radon collecting device collects radon while isolating air in a soil radon collecting hole(200) from the atmosphere. A sealing supplementation device seals the top of the soil radon collecting hole to isolate the air in the soil radon collecting hole from the atmosphere. A dehumidifying device(20) is connected with the radon collecting device to remove humidity in the air collected through the radon collecting device. An inhalation device is connected with the dehumidifying device to forcibly inhale the air in soil radon collecting hole. An indoor radon measurement device(40) is connected with the inhalation device to measure radon in the air in the soil radon collecting hole. [Reference numerals] (AA) Bedrock

Description

Soil radon gas measuring system for uranium exploration

The present invention relates to a soil radon measuring system for exploring uranium resources applicable to outdoor sites using a convenient and convenient radon, and relates to a radon measuring system that can be used for mobile exploration of uranium resources in overseas resource exploration or outdoors.

Nuclear fission of certain radioisotopes releases alpha, beta, and gamma rays. Alpha and beta rays have mass and electric charge, so in other words they are particles. Alpha particles are like the helium nucleus and consist of two protons and two neutrons, and beta particles are electrons with negative charges. Since alpha and beta rays have mass and charge, their depth of penetration through underground materials is within a few millimeters, whereas the depth of transmission of gamma rays, which are high-energy electromagnetic radiation without mass and charge, is relatively long. Used for radiological exploration

So far, uranium resource exploration has used the following methods: 1) NaI scintillation meter, 2) Geiger counter and 3) alpha cup.

1) NaI scintillation meter

The scintillation meter is a device that measures the amount of gamma rays by using a photo-electric effect that occurs when gamma rays are absorbed by crystals of NaI or ZnS treated with thallium. An extension of the principle of scintillation meters is the gamma-ray spectrometer, which measures the gamma rays by their energy levels and estimates the decay element of the emitted gamma rays.

In the detection of gamma rays, a NaI scintillation meter using fluorescence is generally used. The gamma rays incident on the sensor fluoresce, pass through the photomultiplier tube, and finally become electric pulses of a magnitude corresponding to that energy. Counting this pulse signal several times is a device of the total gamma ray method, and counting the magnitude (energy) of a pulse for every energy is a device of the spectral method. The larger the diameter of the NaI crystal, which is a sensor of the scintillation meter, the higher the detection efficiency for the incident gamma ray and the higher the measurement accuracy.

From the earth's interior is emitted from radioactive isotopes contained in trace minerals. Among these, a method of detecting a gamma ray, measuring its intensity (number of radiations per unit time) and energy, and estimating the geological state of the surface layer from the distribution state, is radioactive exploration. Nuclides that emit gamma rays with energy available for exploration include bismuth ( ²¹⁴ Bi), thallium ( ²⁰⁸ Tl), potassium ( ⁴⁰ K), and the like. These nuclides migrate and concentrate in monolayers or hot poles as gases or dissolved in groundwater. This increases the intensity of the gamma rays where the cracks exposed to the surface extend to the subterranean core. In addition, when the monolayer becomes clay and has a high water content, the radioactivity intensity may be lowered in the reverse direction. Using these phenomena, the gamma ray intensity can be measured to identify lipid structures such as monolayers. In other words, if the ground forms geological structures such as cracks and fault zones due to tectonic drift, it will serve as a transport passageway and accumulation zone for more radioactive material than other regions, and strong radioactive abnormalities will appear here.

NaI scintillation meters have been used for the exploration of radioactive minerals, such as uranium deposits, but recently they have been used to check faults and fracture zones for groundwater and hot spring development, civil construction, and earthquake disaster prevention.

The problem with the NaI scintillation meter, however, is that the gamma-ray intensity distribution of the earth's surface is obtained, and the exploration below the surface is not possible. The intensity of gamma rays emitted from radioactive isotopes is attenuated by the interaction of matter or the influence of distance. Most of the gamma rays detected near the surface are due to the ground within about 10cm below the ground surface. The measured gamma-ray intensity thus strongly reflects the influence of the strata covering the surface. If the rock is exposed and the alluvial layer is thick, the strength is different and the material of the fill is affected. It is also easy to be affected by artificial structures. The measurement plan should be carefully considered in consideration of surface conditions such as surface geology and artificial structures, and the results should be carefully reviewed. It is often carried out for the purpose of identifying the fault, but in the case of cracks exposed to the surface, gamma-ray intensity is generally high, and in the case of clay, it may be low.

The gamma ray intensity of the photoelectric maximum point of total gamma dose, potassium, bismuth, and thallium is calculated | required, it arrange | positions for every side line, and is shown by a line graph etc.

2) Geiger counter (Geiger counter)

When radiation generated by the decay of radioactive elements into a stable isotope enters the discharge tube, the gas is ionized and discharged momentarily to pass current. This current is amplified and the number of incoming signals is counted to determine the radioactive element content and used for exploration. However, this exploration method is less accurate because the gas is ionized to detect radioactive elements. Geiger counters are not very effective because they are relatively inexpensive and very sensitive to high gamma rays, but they do not output pulses proportional to the detected gamma rays.

3) Alpha Cup (Alpha Drop Detector)

Charged charge detectors, such as cellulose nitrate, CR-39 (GE) and LR-115 (KODAK KODAK, France) plastic non-detectors are used. A radon cup with a plastic non-detector is used to detect the alpha decaying radon content. The alpha-track that appears upon alpha decay in the plastic droplet detector is quantitatively analyzed as it is compared with the standard sample under a microscope after dilute hydrochloric acid treatment.

The detection principle of alpha detector is alpha of radon and radon progeny on the surface of solid films such as plastic film (polyallyl diglycol carbonate; CR-39), cellulose nitrate (LR-115) and polycarbonate (PC: Makrofol, polycarbonate). When particles are incident, droplets are generated due to microscopic radiation damage to the tissue of the material, and the principle is to calculate the radon concentration by counting the number of detections.

Chemically or electrochemically etching the droplets generated on the film with NaOH solution to enlarge the size of the damaged droplets and then count the generated droplets through a microscope, an image processor or an automated optical scanning system.

Alpha cups (alpha-drop detectors) measure alpha rays from uranium decay. The problem is that after the Alpha Cup is buried in the field, it is recovered three weeks later and the trajectory of the alpha track is counted to determine the radon content. The problem with the Alpha Cup is that it is difficult to measure in the short term unless the radon concentration is high. The static on the surface of the film also affects the attachment of radon daughter nuclides to the film surface. Film quality changes over time due to UV and moisture, and tracks are also produced by thoron in some detectors.

An object of the present invention is to provide an optimized radon measurement system in consideration of mobility, simplicity, survey efficiency, easy establishment of outdoor field exploration strategy, the possibility of investigating the relative radon content in the economic investigation area in uranium resource exploration.

An object of the present invention as described above, Radon collection device for collecting the air inside the soil radon collecting hole in a state isolated from the air; An airtight complementary device for sealing the upper portion of the soil radon collecting hole to isolate the air inside the soil radon collecting hole from the atmosphere; A dehumidifier connected to the radon collecting device to remove moisture from the air collected through the radon collecting device; A suction device connected to the dehumidifier to forcibly suck air in the soil radon collecting hole; It is achieved by the soil radon measurement system for uranium resource exploration, characterized in that it comprises a; radon measuring device for measuring the radon content in the air inside the soil radon harvesting hole is connected to the suction device.

Radon collecting device in the soil radon measurement system for uranium resource exploration as described above is a sealing plate corresponding to the inner diameter of the soil radon sampling hole; Or a radon collecting tube for collecting air from the radon collecting hole at the lower side of the sealing plate through the upper and lower parts of the sealing plate.

An aperture diaphragm whose outer diameter is changed by rotation for isolating a lower portion of the soil radon collecting hole; And a radon collecting tube for collecting air from the soil radon collecting hole at the lower side of the diaphragm through the upper and lower portions of the diaphragm.

In addition, one side of the radon collector tube is characterized in that the dehumidifying filter paper is provided to remove moisture in the air introduced.

In addition, the airtight complementary device is formed on the surface of the ground near the top of the radon collecting hole, the periphery of the lower end is made of a sawtooth shape, the top is closed but the stopper formed through-hole through which the radon collection pipe; And a rubber packing that fills the gap between the inner diameter of the stopper and the outer diameter of the radon collecting tube.

In addition, the radon collector tube and the dehumidifier is directly connected, the radon collector tube coupled to the dehumidifier is formed with a female thread, both sides of the dehumidifier is formed by a male thread is rotatably coupled, the dehumidifier and the suction device Is directly connected to the rotary through the first connecting tube formed Amsan acid, the suction device and the indoor radon measuring device is rotatably coupled to the suction device side through the second connecting tube having a close contact plate formed on one side, the indoor The radon meter side is characterized in that the direct connection to the crimp seal.

In addition, the surface of the radon collector tube, dehumidifier, suction device is characterized in that the heating wire, or the heating wire and the heat insulating cover is closed.

According to the present invention, there is an advantage of good mobility, simplicity, efficient surveying, establishment of outdoor field exploration strategy, economical, and investigation of relative radon content in the survey area.

In addition, there is an advantage that enables precise measurement by delivering the radon included in the soil directly to the indoor radon meter without disturbing and restricting the external environment.

1 is a view showing a soil radon measurement system for uranium resource exploration according to an embodiment of the present invention,
2 is a view showing a soil radon measurement system for uranium resource exploration according to another embodiment of the present invention,
3 is a view showing the operation relationship of the opening of the aperture according to the present invention,
4 is a view showing an installation process of a system according to the present invention;
5 is a view showing the configuration of a closed supplementary device according to the present invention,
6 is a view showing in detail the second connector according to the invention,
7 is a view showing a state in which a heating wire is added to the surface of the radon collector tube, dehumidifier, suction device according to the present invention,
8 is a view showing a state in which the heating wire and the insulation cover is additionally configured on the surface of the radon collector tube, dehumidifier, suction device according to the present invention.

Soil radon measurement system (hereinafter referred to as 'radon measurement system') for uranium resource exploration according to the present invention,

It comprises a radon collecting device, a closed supplementary device, a dehumidifying device 20, a suction device and an indoor radon measuring device 40.

Radon collecting device is a configuration for collecting the air inside the soil radon collecting hole 200 in a state separated from the atmosphere, as shown in Figure 1 comprises a closed plate 12 and a radon collecting pipe 13 Alternatively, as shown in FIG. 2, the diaphragm 17 and the radon collecting tube 13 may be formed. Here, the soil radon collecting hole 200 is preferably sold differently depending on the depth of development of the soil layer. That is, it is better to first investigate the development depth of the soil layer to collect the radon gas, and to dig the depth of the soil radon collecting hole 200 differently, usually it will be appropriate to dig to a depth within 30 to 50cm.

The sealing plate 12 is configured to have an outer diameter corresponding to the inner diameter of the soil radon collecting hole 200. When the soil radon collecting hole 200 is formed, the sealing plate 12 is considered when the sealing plate 12 is formed. ), The lower side of the soil radon collecting hole 200 can be sufficiently isolated from the atmosphere.

The radon collecting tube 13 is configured to collect air from the soil radon collecting hole 200 at the lower side of the sealing plate 12 through the upper and lower portions of the sealing plate 12, and preferably with FIG. Likewise, the lower side of the radon collecting tube 13 further includes a dehumidifying filter paper 11. The dehumidifying filter paper 11 as described above first removes moisture in the air at the lower side of the incoming soil radon collecting hole 200.

Meanwhile, as another embodiment of the radon collecting device, the diaphragm 17 has a configuration in which the outer diameter is changed by rotation to isolate the lower portion of the soil radon collecting hole 200 as shown in FIGS. 2 and 3. Like the sealing plate 12 is a configuration for isolating the air and the air at the lower side of the soil radon collecting hole 200. Such a diaphragm 17 is inserted into the inside of the soil radon collecting hole 200 with the radon collecting tube 13 in a state in which the outer diameter was reduced at the time of initial installation, and then rotated to expand the outer diameter and radon collecting tube 13. When lifted slightly, the bottom of the soil radon collecting hole 200 and the atmosphere is isolated.

The radon collecting tube 13 in the radon collecting device as described above collects the air from the radon collecting hole 200 at the lower side of the diaphragm 17 through the upper and lower portions of the diaphragm 17, and collects radon. The lower side of the tube 13 may further include a dehumidifying filter paper 11, and the effects are as described above.

The airtight complementary device is configured to close the upper part of the soil radon collecting hole 200 to isolate the air inside the soil radon collecting hole from the atmosphere, as shown in FIGS. 1 and 5. If the airtight plate 12 or the diaphragm 17, which is a structure to be isolated from the atmosphere, is a primary isolation configuration, the airtight complementary device is a secondary isolation configuration and the present invention collects soil radon through the first and second isolation configurations. It is possible to measure by blocking the external environment as much as possible in the radon measurement by associating the lower side air of the ball 200 with the atmosphere as much as possible.

This closed complementary device is composed of a stopper 14 and a rubber packing 15 as shown in Figure 5, the stopper 14 is installed on the ground near the top of the soil radon collecting hole 200 is fixed to the bottom The circumference is formed in the shape of a sawtooth (14b), the top is closed but the through hole (14a) through which the radon collection pipe 13 is formed.

The rubber packing 15 is a structure that fills the gap between the inner diameter of the through hole 14a of the stopper 14 and the outer diameter of the radon collecting tube 13 in an airtight manner.

That is, the radon collecting device and the airtight complementary device has the advantage of protecting the lower side air of the soil radon collecting hole 200 from external environmental factors as much as possible and collecting and collecting at the same time.

The dehumidifier 20 is connected to the radon collecting device to remove moisture in the air collected through the radon collecting device, and the radon collecting pipe 13 and the dehumidifying device 20 of the radon collecting device are directly connected. In particular, the radon collection tube 13 is coupled to the dehumidifier 20 is formed with a female thread, both sides of the dehumidifier 20 is formed by male threads 25, 26 are rotatably coupled as shown in FIG.

That is, the dehumidifier 20 is directly connected to the radon collecting pipe 13 to remove moisture in the air flowing through the radon collecting pipe 21, and the air on the lower side of the soil radon collecting hole 200 is indoors. If it is delivered directly to the radon measuring device 40 may cause malfunction and failure by moisture, as a necessary component in order to prevent this, may be a commercially available product with excellent dehumidification performance, but dehumidification in the present invention Apparatus 20 includes a dehumidifier for removing moisture contained in air at the lower side of the incoming soil radon collecting hole 200, and is provided at both sides of the dehumidifier, and separately adds moisture in the air before and after dehumidification of the dehumidifier. It is preferable to include the configuration of the dehumidifying agent (23, 24) to remove and the dehumidifying filter (21, 22) for removing the foreign matter.

The suction device is connected to the dehumidifying device 20 to forcibly suck the air inside the soil radon collecting hole 200. As illustrated in FIG. 4, the suction device includes a pump 30 operated by a battery 31. , The suction device 60 may be manually forced to suck, and the dehumidifier 20 and the suction device may be directly connected to the rotary device through the first connecting pipe 51 formed with the female acid. The radon measuring device 40 is rotatably coupled to the suction device side through a second connecting pipe 52 having a close contact plate 52a having a support piece 52b formed on one side thereof, and the indoor radon measuring device side is directly connected in a compression-tight manner. do.

Here, the inhaler 60 is composed of an elastic material, and as shown in FIG. 4, an inlet 62 connected to the first connector 51 and an outlet 63 connected to the second connector 52 and It is formed between the inlet 62 and the outlet 63 is composed of an air compression unit 61 formed in a diameter larger than the diameter of the inlet 62 and the outlet (63). Threads are formed on the inner circumferential surfaces of the inlet port 62 and the outlet port 63 so as to be rotatably coupled to the first connecting pipe 51 and the second connecting pipe 52, respectively, for easy assembly.

Meanwhile, as shown in FIG. 5, the second connection pipe 52 is provided with a rubber contact plate 52a having a support piece 52b formed on one side thereof, although not shown in detail. (52a) is the same configuration as the adsorption plate configured for fixing the current navigation to the windshield plate of the vehicle, and the attachment method with the indoor radon measuring device 40 is also the same as the attachment method of the adsorption plate of the navigation, except that the adhesion plate in the present invention ( 52a) improved the adsorption | suction support force by forming the support piece 52b to protrude further about the circumference.

The indoor radon measuring device 40 is configured to measure the radon content in the air inside the soil radon collecting hole 200 which is connected to the suction device and is directly connected to the suction device (pump 30) as shown in FIG. 4. The radon content in the air that is connected and measured is measured in real time.

That is, the indoor radon measuring device 40 is directly connected to the pump 30 by the second connecting pipe 52 to measure the radon content in the air flowing in real time, and the measured value is recorded by the measurer in a note by hand. Leave a record, and when the measurement is completed, the components are collected and used in the next soil radon collector 200.

Therefore, the radon measuring system according to the present invention can quickly measure the radon gas at the site of a plurality of soil radon harvesting hole 200, can be utilized for the underground resource exploration and earthquake disaster prediction.

On the other hand, the surface of the radon collecting tube 13, the dehumidifier 20, the suction device in the radon measuring system configured as described above is a hot wire 71, as shown in Figure 7, or as shown in Figure 8 hot wire ( 71) and the warming cover 72. Of course, the surface of the indoor radon measuring device 40 is preferably finished with such a heating wire 71 and the insulating cover 72, but if the external environment is severely changed in consideration of the convenience of movement (rain, snow, etc.) Or do not need to finish, the heating wire 71 and the heat insulating cover 72 to prevent condensation due to the temperature difference between the radon collection pipe 13, the dehumidifier 20, the suction device.

And although not shown, the present invention may be further provided with a solar cell (not shown) for the purpose of providing environmentally friendly power to the power-consuming configuration, such as the pump 30, the heating wire 71 and the like.

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, .

200: soil radon collector 11: dehumidification filter paper
12: Closed board 13: Radon collector
14: stopper 15: rubber packing
17: aperture opening 20: dehumidifier
25, 26: Male thread 40: Indoor radon measuring device
51: first connector 52: second connector
52a: contact plate 52b: support piece
71: heating wire 72: thermal cover

Claims (7)

A radon collecting device for collecting the air inside the soil radon collecting hole 200 in an isolated state from the atmosphere;
An airtight complementary device for sealing the upper portion of the soil radon collecting hole 200 to isolate the air inside the soil radon collecting hole from the atmosphere;
A dehumidifier 20 connected to the radon collecting device to remove moisture from the air collected through the radon collecting device;
A suction device connected to the dehumidifier 20 to forcibly suck air in the soil radon collecting hole 200;
An indoor radon measuring device 40 measuring radon content in the air inside the soil radon collecting hole 200 connected to the suction device;
Soil radon measurement system for uranium resource exploration, characterized in that comprises a. The method of claim 1,
The radon collecting device includes a sealing plate 12 having an outer diameter corresponding to the inner diameter of the soil radon collecting hole 200;
A radon collecting tube 13 for collecting air from the soil radon collecting hole 200 at the lower side of the sealing plate 12 through the upper and lower parts of the sealing plate 12;
Soil radon measurement system for uranium resource exploration, characterized in that comprises a. The method of claim 1,
The radon collecting device includes a diaphragm 17 whose outer diameter is changed by rotation for isolating the lower portion of the soil radon collecting hole 200;
A radon collecting tube 13 for collecting air from the soil radon collecting hole 200 at the lower side of the diaphragm 17 through upper and lower portions of the diaphragm 17;
Soil radon measurement system for uranium resource exploration, characterized in that comprises a. 4. The method according to claim 2 or 3,
One side of the radon collection pipe 13 is provided with a dehumidifying filter paper (11) is a soil radon measurement system for uranium resource exploration, characterized in that to remove moisture in the incoming air. 4. The method according to claim 2 or 3,
The airtight complementary device is installed on the ground surface near the top of the soil radon collecting hole 200, the periphery of the lower end is made of a sawtooth (14b) shape, the upper end is blocked through the radon collecting pipe 13 is penetrated The ball 14a is formed with a stopper 14;
A rubber packing 15 for filling the gap between the inner diameter of the through hole 14a of the stopper 14 and the outer diameter of the radon collecting tube 13 in an airtight manner;
Soil radon measurement system for uranium resource exploration, characterized in that consisting of. 4. The method according to claim 2 or 3,
The radon collecting tube 13 and the dehumidifier 20 is directly connected, the radon collecting tube 13 is coupled to the dehumidifying apparatus 20 is a female thread is formed, both sides of the dehumidifier 20 is a male thread ( 25, 26) are formed and rotated,
The dehumidifier 20 and the suction device is directly connected to the rotary through the first connecting pipe 51 formed with female acid,
The suction device and the indoor radon measuring device 40 are rotatably coupled to the suction device side through a second connecting pipe 52 having a close contact plate 52a having a support piece 52b formed on one side thereof, and the indoor radon measuring device is compressed. Soil radon measurement system for uranium resource exploration, characterized in that the direct connection to the hermetic. 4. The method according to claim 2 or 3,
The surface of the radon collecting tube 13, the dehumidifier 20, the suction device is heated radon for exploration of uranium resources, characterized in that the heating wire 71, or the heating wire 71 and the insulation cover 72 is finished Measuring system.

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