KR100978839B1 - Soil radon gas collecting method and devices - Google Patents

Abstract

PURPOSE: A soil radon gas collecting method and a device thereof are provided to improve the efficiency of work. CONSTITUTION: A time integrate type radon concentration measurement device(20) is installed in an installation hole under soil(10). The trajectory of radon emission alpha ray inside soil is recorded in real time with a sensor. A gripper(40) installs the time integrate type radon concentration measurement device into the inside the installation hole or collects it to the outside. A cover(30) includes a closure unit(31) and a support unit(32). A sealed part seals the top opening unit of the installation hole. The support part is projected in the outer circumference of the sealed part.

Description

Soil Radon Gas Collecting Method And Devices

The present invention relates to a method for collecting soil radon gas and an apparatus used therein for easily collecting radon gas content in soil and analyzing it.

Radon is a naturally occurring colorless, odorless and tasteless aqueous radioactive gas with isotopes of atomic weights 219, 220 and 222, which are radioactive decay products of U-235, Th-232 and U-222, respectively. Radon, which is inhaled into the lungs when breathing concentrated air or drinking water above environmental standards, is known to enter the body and cause lung cancer. According to the US Environmental Protection Agency (EPA), radon (Rn-222) farming standards are 4 pCi / L in the air and 10,000 pCi / L in drinking groundwater. Breathing air or drinking water that has radon concentrations above environmental thresholds can lead to long-term exposure due to the colorless and odorless nature of radon, and therefore the risk of harm to health is very high.

The purpose of radon management is to reduce the incidence of lung cancer following exposure to radon radiation.

Radon diffuses from groundwater, where rock, soil, and uranium components containing uranium minerals are dissolved in free ions to reach the surface environment, affecting our human rights.

Radon gas research has to be investigated and prepared in the environment for human health, but it is used for uranium resource exploration, underground structure detection and earthquake prediction.

Looking at the radon gas collection and RDA-200 analysis technology using a conventional steel needle, as shown in Figure 1, the soil gas is a steel hammer (outer diameter: 6 ~ 9mm, inner diameter: 2 ~ 3mm) using a split hammer Put an average of 75cm into the ground, collect 20cc of gas sample through a vacuum syringe, and immediately inject it into a scintillation cell, an optical amplification tube made of zinc sulfide, into the inner wall. Analyze with -200 device.

The cell coated with ZnS (Ag) measures radon content by measuring alpha emission rate by connecting to photoelectric amplifier and measurement circuit as radon gas passes.

Radon gas sample analysis is carried out three times every 5 minutes with a standard cell to check the instrument condition of the RDA-200 before sample analysis. After checking that the average value is within the range of 1,020 + -5% dml, the scintillation cell will contain the sample. Measure the background value of.

At this time, if the measured value is over 1 ~ 2cpm, clean it repeatedly using a hand pump or a fish tank for supplying oxygen to the fish tank.

The collected gas sample is aged at least 4 hours in a scintillation cell and then measured by RDA-200. This is because the radon concentration in the scintillation cell is the maximum value after about 3 hours and has the most stable value at about 4 hours (Reimer, 1994). In order to avoid the effect of photoelectrons due to the surrounding light, discard the first 1 minute value and measure 1 time for 1 minute and 3 times for 5 minutes to use the average value.

 However, radon gas collection using the steel needle as described above

First, the soil gas is embedded with steel needles in the ground by using a split hammer on average 75cm and collects 20cc of gas sample through a vacuum syringe, so the number of samples collected is very small (in the same place, 15 ~ Secondly, it is possible to collect 20 samples / day.) Secondly, uncontaminated cells suitable for the sample number are required because the gas is collected by vacuum injection and injected into the scintillation cell. Third, there are many soil gas sampling and analysis equipments. There is a big problem that it is difficult to move outdoors because it is heavy.

Thus, as in Patent Application No. 10-2004-0017942, "Time Integral Radon Concentration Meter with Ring", using a time integral measurement method to measure radon at the same place for a certain period of time, using the average radon concentration as a representative value, Various time-integrated radon concentration meters have been developed that are compact and very easy to move. The time-integrated radon concentration meters are based on average values because the concentration of radon in indoor air varies sensitively with air pressure, temperature and humidity. It has a small cylindrical shape with a special sensor to record and measure the trajectory of the radon's alpha rays in real time.

However, there is a problem in that the method of installing and collecting the time-integrated radon concentration meter in the installation hole dug into a small size is difficult and cumbersome.

The present invention has been made to solve the above problems, the object of the present invention is the installation time of the time integration type radon concentration meter installed / collected in the installation hole to be irradiated in the irradiated area to investigate the radon gas content in the soil In order to shorten this, and to drill a 50 cm deep installation hole, it is necessary to dig a relatively larger hole and to prevent the waste of manpower caused by having to fill the installation hole after installing the installation hole. In order to recover the time-integrated radon concentration meter in a compactly dug installation hole, a method for collecting soil radon gas and a device used therein are provided to eliminate time and human waste of digging a larger hole than the installation hole. It is.

Other objects and advantages of the invention will be described below and will be appreciated by the embodiments of the invention. Furthermore, the objects and advantages of the present invention can be realized by means and combinations indicated in the claims.

The present invention as a means to solve the above problems, the step of drilling the installation hole in the area for examining the radon gas content in the soil (S100); Installing a time-integrated radon concentration meter on the bottom of the installation hole (S200); Sealing the installation hole by press-fitting the cover to an upper opening of the installation hole (S300); A step (S400) of covering the soil on an upper portion of the cover so that radon gas inside the installation hole does not leak out; After the user setting period, step of sequentially removing the covered soil and cover from the installation hole (S500); Recovering the time-integrated radon concentration meter in the installation hole (S600); Analyzing radon gas content in the surveyed area soil through the recovered time-integrated radon concentration meter (S700); Characterized in that comprises a.

In addition, the apparatus used for the soil radon gas collection method includes a time-integrated radon concentration measuring instrument installed in the installation hole of the radon gas content survey area in the soil; An installation recovery tong for installing the time-integrated radon concentration meter inside the installation hole or recovering it to the outside of the installation hole; A cover which closes the upper opening of the installation hole to seal the installation hole; Characterized in that consists of.

In addition, the time-integrated radon concentration meter is characterized by recording and measuring in real time the trajectory of the alpha ray emitted by the radon in the soil by a sensor mounted therein.

In addition, the cover is formed to be indented inward in the center and the sealing portion is pressed into the installation hole; A support part protruding from an outer circumference of the seal part to be supported on soil; Characterized in that consists of.

In addition, installing a display sign on the covered soil between the step S400 and S500, so that the installation position of the time-integrated radon concentration meter can be identified; Is further added.

In addition, the installation hole is characterized in that the perforated to a diameter of 8 to 10cm, depth of 50cm.

In addition, the step S400 is characterized in that the soil is covered with a thickness of 15 to 20cm.

As described above, the present invention has a simple and easy effect of the installation and recovery method of the time-integrated radon concentration meter in the installation hole is dug into the soil radon content investigation area.

In addition, the present invention, because the simple method of installation and recovery of the time-integrated radon concentration meter, not only facilitates radon gas irradiation work of the soil, but also has an effect of increasing work efficiency.

Before describing the various embodiments of the present invention in detail, it will be appreciated that the application is not limited to the details of construction and arrangement of components described in the following detailed description or illustrated in the drawings. The invention may be embodied and carried out in other embodiments and carried out in various ways. It should also be noted that the device or element orientation (e.g., "front," "back," "up," "down," "top," "bottom, Expressions and predicates used herein for terms such as "left," " right, "" lateral, " and the like are used merely to simplify the description of the present invention, Or that the element has to have a particular orientation. Moreover, terms such as "first" and "second" are used in the specification and the appended claims for purposes of illustration and are not intended to indicate or mean the relative importance or spirit.

The present invention has the following features to achieve the above object.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. Prior to this, terms or words used in the present specification and claims should not be construed as being limited to the common or dictionary meanings, and the inventors should properly explain the concept of terms in order to best explain their own invention. Based on the principle that can be defined, it should be interpreted as meaning and concept corresponding to the technical idea of the present invention.

Therefore, the embodiments described in the specification and the drawings shown in the drawings are only the most preferred embodiment of the present invention and do not represent all of the technical idea of the present invention, various modifications that can be replaced at the time of the present application It should be understood that there may be equivalents and variations.

Hereinafter, a method for collecting soil radon gas and an apparatus used therein will be described in detail with reference to FIGS. 2 to 5.

First, as a device used to collect the radon gas content of the soil in the present invention, a time-integrated radon concentration meter 20 was used, and the time-integrated radon concentration meter was a small cylindrical shape, 'time integral measurement method It is a device that measures radon at the same place for a certain period of time and uses the average radon concentration as a representative value. Since the concentration of radon in the air varies sensitively with air pressure, temperature, and humidity, the time-integrated radon concentration meter based on the average value is a small cylinder and is equipped with a special sensor so that the traces of the alpha rays emitted by radon can be measured in real time. Record and measure with. (The time-integrated radon concentration meter is a well-known technique, so do not use a separate technique anymore.)

Soil radon gas collection method according to the present invention and the apparatus used therein,

1. Select an irradiation area for investigating the radon gas content, and drill the installation hole 10 for installing the time-integrated radon concentration meter 20 as described above. The installation hole 10 is a 50cm deep, 8 to 10cm in diameter would be right, but the size of the installation hole 10 can be variously changed by the user according to the size of the time-integrated radon concentration measuring instrument 20. Of course it is. In addition, although the auger is used as the equipment for digging the installation hole 10, it is also correct, but also, if the equipment that can easily excavate the installation hole 10 may be replaced with a variety of equipment. (Step S100)

2. After the step S100, the time-integrated radon concentration measuring device 20 for measuring the radon content is installed in the installation hole 10 drilled in the step S100. At the time of installation, the time-integrated radon concentration measuring device 20 is installed to contact the inner bottom (bottom) of the installation hole 10.

As a means for installing the time-integrated radon concentration measuring device 20, an installation recovery tong 40 is used, and the installation recovery tong 40 is an operation unit 44 on which a handle 43 is formed; A first operating table 41 including a tong part 45 in contact with the time-integrated radon concentration meter 20, a bent part 46 formed between the operation part 44 and the tong part 45, An operating part 44 having a handle 43 formed therein, a tong part 45 contacting the time-integrated radon concentration meter 20, and a bent part formed between the operating part 44 and the tong part 45 ( 46) has the same shape as the first operating table 41, forms a symmetrical shape with the first operating table 41, and intersects at the bent portion 46 to cross the first operating table 41 and 'X'. The second operating table 42 in the form of an (X) shape and the connecting means 48 for connecting the bent portions 46 of the first and second operating tables 41 and 42 to each other. (A bolt, a nut, etc. may be used as the connection means, but it can be variously changed by the user.) That is, the installation recovery tongs 40 have a tongs shape as the name suggests. To explain, first, the time-integrated radon concentration measuring device in the tongs space 47 formed between the tongs 45 of the first operating table 41 and the tongs 45 of the second operating table 42. After positioning the 20, the distance between the handle 43 of the first operating table 41 and the handle 43 of the second operating table 42 is narrowed by the operator's force so that the first and second operating tables ( The forceps 45 of the first and second operation units 41 and the forceps 45 of the second operation unit 42 are time-integrated radon concentrations by narrowing the forceps 45 of the first and second operation units 41 and 42, respectively. In contact with the outer circumferential surface of the measuring device 20 to pick up the time-integrated radon concentration measuring device 20.

As described above, the installation recovery tong 40 has the case of installing the time-integrated radon concentration meter 20 in the installation hole 10, and the time-integrated radon concentration meter 20 in the installation hole 10. ) Are used equally when recovering.

In addition, in the tongs of the installation recovery tongs 40, a rubber fixing pad 49 is formed at a portion in contact with the outer circumference of the time-integrated radon concentration measuring instrument 20, and an installation recovery tongs ( When the time-integrated radon concentration meter 20 is picked up through 40, the time-integrated radon concentration meter 20 is not removed, slipped, or dropped from the installation recovery forceps 40. In addition, the fixing pad 49 to have a shape corresponding to the outer periphery of the time-integrated radon concentration meter 20, in one embodiment, when the time-integrated radon concentration meter 20 is cylindrical, It is obvious that the fixing pad 49 has an arc shape corresponding to the outer circumference of the time-integrated radon concentration measuring instrument 20. (Step S200)

3. After the step S200, when the installation of the time-integrated radon concentration measuring instrument 20 is completed in the installation hole 10, the upper opening 11 of the installation hole 10 which is an opened portion of the installation hole 10. Insert the cover 30 in the

In this case, the cover 30 is formed to be indented inward in the center thereof to correspond to the installation hole 10 and to be press-fitted into the sealing part 31 and the outer periphery of the sealing part 31 to the soil. It consists of a support 32 to be supported. That is, the sealing part 31 of the cover 30 is press-fitted and fitted corresponding to the upper opening 11 of the installation hole 10, and the cover 30 itself is installed by the support part 32. (10) Do not fall inside. This is to maintain the airtight by sealing the inside of the installation hole 10 so that the radon gas inside the installation hole 10 does not leak to the outside, which has the same purpose in step S400 to be described later. (Step S300)

4. After the step S300, the soil is applied to the top of the cover 30. This prevents radon gas from flowing out between the cover 30 and the upper opening 11 of the installation hole 10 even though the cover 30 is press-fitted into the installation hole 10. In order to cover the soil on top of the cover 30, the coating thickness will be correct to 15 to 20cm. (S400 step)

5. After the step S400, after a certain period (7 days after the user set period), the cover soil is removed, and the cover fitted in the upper opening 11 so that the installation hole 10 is sealed. (30) is carefully rolled so that the soil does not fall on the time-integrated radon concentration meter (20). That is, the covered soil and the cover 30 are sequentially removed. (S500 series)

6. After the step S500, the time-integrated radon concentration measuring instrument 20, which is installed on the inner bottom of the installation hole 10, is recovered using the installation recovery forceps 40. (Step S600)

7. After the step S600, quantitative analysis of the radon gas content in the survey area soil through the recovered time-integrated radon concentration measuring instrument (20). (S700 step)

In addition, between the steps S400 to S500 can be installed on the soil cover cover 50, which is easy to install the location of the time-integrated radon concentration measuring instrument 20 installed in the installation hole 10 from the outside Steps to be identifiable may be added. (Step S410)

Steps S100 to S700 are sequentially performed.

As mentioned above, although this invention was demonstrated by the limited embodiment and drawing, this invention is not limited by this, The person of ordinary skill in the art to which this invention belongs, Various modifications and changes may be made without departing from the scope of the appended claims.

1 is an exemplary view showing a conventional method for collecting soil radon gas.

Figure 2 is a flow chart of one embodiment showing the procedure of the soil radon gas collection method according to the present invention.

Figure 3 is a view of one embodiment showing the radon gas extraction of the soil radon gas collection method according to the present invention.

Figure 4 is a perspective view of one embodiment showing the installation recovery forceps according to the present invention.

Figure 5 is a flow chart of one embodiment showing a soil radon gas collection method according to the present invention.

<Indication of symbols for main parts of drawing>

10: mounting hole 11: opening

20: time integration radon concentration meter 30: cover

31: sealing part 32: supporting part

40: installation recovery tong 41: first operating table

42: second operation platform 43: handle

44: operation part 45: tong part

46: bend 47: clamp space

48: connecting means 49: fixing pad

50: Sign

Claims (7)

Perforating the installation hole 10 to a diameter of 8 to 10 cm and a depth of 50 cm in an area for examining radon gas content in the soil (S100); Installing a time-integrated radon concentration meter 20 on a bottom surface of the installation hole 10 (S200); Sealing the installation hole 10 by press-installing the cover 30 in the upper opening 11 of the installation hole 10 (S300); Covering the soil with a thickness of 15 to 20cm in the upper portion of the cover 30 so that the radon gas in the installation hole 10 does not flow to the outside (S400); Installing the display sign 50 on the covered soil so that the installation position of the time-integrated radon concentration measuring instrument 20 can be identified; After the user setting period, step of sequentially removing the covered soil and cover 30 from the installation hole 10 (S500); Recovering the time-integrated radon concentration meter 20 in the installation hole 10 (S600); Analyzing the radon gas content in the irradiated soil through the recovered time-integrated radon concentration measuring instrument 20 (S700); Soil radon gas collection method characterized in that it comprises a. The apparatus used in the soil radon gas collection method formed in claim 1 It is installed in the installation hole (10) of the radon gas content survey area in the soil, and the time-integrated radon concentration measuring device (20) for recording and measuring the trajectory of the alpha ray emitted by radon in the soil in real time by a sensor mounted therein; ; An installation recovery tong (40) for installing the time-integrated radon concentration measuring device (20) in the installation hole (10) or recovering the installation hole (10); Closing the upper opening 11 of the installation hole 10 so that the installation hole 10 is sealed, it is formed to be recessed inward in the center and the sealing portion 31 is pressed into the installation hole 10 and the A cover 30 which protrudes on the outer circumference of the sealing part 31 and is formed of a support part 32 supported by the soil; Apparatus used in the soil radon gas collection method, characterized in that consisting of. delete delete delete delete delete

Images