KR101665385B1 - Portable radon measurement apparatus and operating method using the same - Google Patents

Abstract

The present invention includes an environmental sensor unit for sensing environmental variables including atmospheric pressure, temperature and humidity of a test region; A first calculation unit for calculating a first correction pressure of the sensed temperature and a second correction pressure of the sensed humidity through the atmospheric pressure / temperature / humidity correlation table; A second calculation unit for calculating the corrected atmospheric pressure by applying the first correction air pressure and the second correction air pressure to the sensed atmospheric pressure; And a control unit for controlling the operation of the environmental sensor unit, and an operation method thereof. The portable radon measuring apparatus according to claim 1, wherein the atmospheric pressure radon correlation table is obtained by comparing the corrected atmospheric pressure with the atmospheric pressure radon correlation table.

Description

FIELD OF THE INVENTION [0001] The present invention relates to a portable radon measuring device,

TECHNICAL FIELD The present invention relates to a portable radon measuring apparatus and an operating method thereof, and more particularly, to a technique for detecting an environment parameter of a test region and determining whether the radon gas is measured for a test region.

Radon, a spontaneous radionuclide, is an element of atomic number 86 and an element symbol of Rn. In the periodic table, helium (He), neon (Ne), arginine (Ar), krypton (Kr) And belong to group 18, called the noble gas group, together with the element at the bottom of the family.

Radon is defined as a primary carcinogen and is associated with death from lung cancer following cigarette smoking. Recently, there have been cases of death by radon in the country, and public interest in radon is increasing.

Patent Document 1 discloses a method of detecting light of alpha particles generated by decay of radon gas corresponding to the direction of the inner wall surface through a single PIN photodiode by an electrical signal and detecting the concentration of radon gas based on the detected electrical signal A technique for measuring a signal is disclosed.

Conventionally, a radon measuring apparatus can be installed to measure the radon gas in the measuring region, and the radon measuring apparatus can measure the radon gas using the measuring method described in Patent Document 1. [

Conventional radon measurement methods include a short-term basic measurement, a short-term measurement, and a long-term measurement, which are classified by measurement period, and the method of measuring radon by each measurement period can be the same.

The short-term baseline measurement period may be from 24 hours to 7 days, the short-term measurement period may be from 2 days to 90 days, and the long-term measurement period may be from 90 days to 365 days, but is not limited thereto.

Conventional short-term baseline measurement-based radon measurement methods include installing a radon measuring device in a measurement area, measuring the radon gas during a short-term basic measurement period, calculating a mean value of the measured radon gas to generate a concentration value of the radon gas, By comparing the concentration value of the radon gas with the reference concentration value, it is possible to determine whether or not the measurement of the radon gas is performed for the measurement region.

The conventional radon measurement method determines that the measurement of the radon gas is necessary when the concentration value of the radon gas generated based on the basic measurement is greater than the reference concentration value, and performs short-term measurement or long-term measurement.

The conventional radon measurement method determines that the measurement of the radon gas is unnecessary when the concentration value of the radon gas generated based on the basic measurement is less than the reference concentration value. The manager who manages the radon measuring device installed in the measuring area may withdraw the installed radon measuring device and reinstall it in another measuring area where the radon gas is expected to be present.

Patent Document 2 discloses a radon test kit for measuring radon gas of charcoal, and is a technique for measuring and displaying the gauge of temperature, humidity and atmospheric pressure in a storage room or a test area while measuring radon gas of charcoal stored in a storage box inside the kit .

Patent Document 3 relates to a method and apparatus for relative calibration of a radon concentration measuring instrument. Since the measurement value of the radon concentration is influenced by changes in temperature, humidity and atmospheric pressure, the measurement value of the radon and the temperature- A technique for comparing values is disclosed.

However, Patent Document 1 has a problem that the installation time required for installing the radon measuring device and the measurement time required for the basic measurement for a short period of time are very long.

Patent Document 2 discloses a technique for measuring and displaying environmental variables including temperature, humidity, and atmospheric pressure, but does not disclose a technique utilizing the measured environmental variables.

Patent Document 3 discloses a technique for calibrating a measured value of a radon concentration measured by using a calibrated temperature measurement value because environmental variables affect radon gas measurement. However, based on a short-term baseline measurement, The present inventors have not been able to disclose a technique for determining whether the radon gas is measured or not.

1. United States Patent No. 5489780 (Feb. 2. U.S. Published Patent Application No. 2009-0032694 (Feb. 3. Korean Patent No. 0734222 (Jun. 26, 2007)

The present invention provides a portable radon measuring device and a method of operating the same that reduce the installation time and measurement time, predict regions or locations where the concentration of the radon gas is high, and increase the prediction accuracy.

The present invention relates to a portable radon measuring device for measuring a concentration value of a radon gas and reducing an error of a concentration value of the measured radon gas with reference to an environmental parameter, a first correcting air pressure, a second correcting air pressure or a corrected atmospheric pressure, to provide.

The portable radon measuring apparatus for detecting the environment variable of the test region of the present invention and determining whether the radon gas is measured for the test region includes an environment sensor unit for sensing environmental variables including atmospheric pressure, temperature and humidity of the test region; A first calculation unit for calculating a first correction pressure of the sensed temperature and a second correction pressure of the sensed humidity through the atmospheric pressure / temperature / humidity correlation table; A second calculation unit for calculating the corrected atmospheric pressure by applying the first correction air pressure and the second correction air pressure to the sensed atmospheric pressure; A discrimination unit for discriminating whether the radon gas is measured for the test region by comparing the corrected atmospheric pressure with the atmospheric pressure radon correlation table, and a control unit for controlling the operation of the environmental sensor unit.

The environmental sensor unit may include an atmospheric pressure sensor, a temperature sensor, and a humidity sensor for sensing the environmental variable.

The first calculation unit may calculate the first correction pressure and the second correction pressure through an atmospheric pressure / temperature / humidity correlation table in which the atmospheric pressure correlated to the air weight is converted into a unit of temperature and humidity.

The second calculation unit may calculate an average of the first correction pressure and the second correction pressure and calculate a correction atmospheric pressure by applying an error of the average correction pressure calculated at the sensed atmospheric pressure.

The discriminating unit can discriminate whether or not the radon is measured for the test region by comparing the atmospheric pressure radon correlation table with one of the atmospheric pressure atmospheric pressure and the correlated atmospheric pressure correlated with the radon gas.

If the corrected atmospheric pressure is greater than or equal to the reference atmospheric pressure included in the atmospheric pressure radon correlation table, the determination unit may determine that the measurement of the radon gas is necessary.

The portable radon measuring apparatus of the present invention comprises: a storage for storing the atmospheric pressure / temperature / humidity correlation table and the atmospheric pressure radon correlation table; A signal processing unit for signal processing the environment variable; A display unit for displaying information on at least one of a result of the measurement of the environment variable, the first correction air pressure, the second correction air pressure, the correction atmospheric pressure, and the measurement of the radon gas; A communication unit for transmitting the display information to a management server or an administrator terminal, and a radon measuring unit for measuring a radon gas in a test area based on a result of the measurement of the radon gas.

A method of operating a portable radon measuring device for detecting an environment variable of a test region of the present invention and determining whether the radon gas is measured for a test region includes storing an atmospheric pressure temperature / humidity correlation table and an atmospheric pressure radon correlation table in a storage portion; Sensing environmental variables including atmospheric pressure, temperature and humidity of the test region in the environmental sensor; Calculating a first correction pressure of the sensed temperature and a second correction pressure of the sensed humidity through the atmospheric pressure / temperature / humidity correlation table in the first calculation unit in the storage unit; Calculating the corrected atmospheric pressure by applying the first correcting air pressure and the second correcting air pressure to the sensed atmospheric pressure in the second calculating unit, and reading out the atmospheric pressure radon correlation table from the storing unit, And determining whether the radon gas is measured for the test region.

The present invention detects the environmental variable of the test area and determines whether or not the radon gas is measured in the test area, thereby reducing the installation time and the measurement time, and can predict a region or a place where the concentration of the radon gas is high.

The present invention calculates a corrected atmospheric pressure by calculating the sensed temperature and humidity at a first correction pressure and a second correction atmospheric pressure, applying the calculated first and second correction atmospheric pressure to the sensed atmospheric pressure, The prediction accuracy can be increased by predicting the region or place where the concentration of the radon gas is high.

When it is determined that the measurement of the radon gas is necessary for the test region, the present invention measures the concentration value of the radon gas for the test region and measures the concentration of the radon gas measured in accordance with the environmental parameter, the first correcting air pressure, the second correcting air pressure, The error of the concentration value of the radon gas can be reduced.

1 is a block diagram showing a portable radon measuring apparatus of the present invention.
2 is a flowchart showing an operation method of the portable radon measuring apparatus of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings and accompanying drawings, but the present invention is not limited to or limited by the embodiments.

FIG. 1 is a block diagram showing a portable radon measuring apparatus of the present invention. The portable radon measuring apparatus 100 includes an environment sensor unit 110, a first calculating unit 131, a second calculating unit 132, a determining unit 140 And a control unit 140. [0028]

The environmental sensor unit 110 includes an atmospheric pressure sensor 111, a temperature sensor 112 and a humidity sensor 113 and detects environmental variables including atmospheric pressure, temperature and humidity of the test region.

Atmospheric pressure is the atmospheric pressure generated by air weight. The density of radon gas at standard condition (0 ℃, 1 atm) is 9.73g / L, which is about 8 times as heavy as air.

The portable radon measuring apparatus 100 can predict or discriminate that the concentration of radon gas is high because the radon gas is heavier than air if the atmospheric pressure in the test region is abnormally high.

Since radon gas is an inert gas, all of the amount inhaled by the body exits as an exhalation, but it collapses into a series of a few radionuclides, so if these progeny are inhaled, they can be deposited in the respiratory tract.

Radon gas can be broken down before the offspring with a short half-life of less than 30 minutes are removed from the lungs of the body, and alpha particles of polonium 218 and polonium 214 among the offspring may be released, And the risk of lung cancer.

Radionuclides such as radon gas have a half-life of half the original number of atoms by radioactive decay, and radon 222 is a natural radioactive gas with a half-life of 3.8 days.

The test area may be a residential facility, a commercial center, a school or a factory where radon gas is expected to be present, an underground living space including underground history and an underground shopping center, and may be a specific closed space. The environmental sensor unit 110 can detect environmental variables near the bottom surface of the test region where the radon gas is expected to be present.

Atmospheric pressure is proportional to temperature and has an inverse relationship with humidity, and radon gas is affected by environmental variables including atmospheric pressure, temperature and humidity. The environment sensor unit 110 can detect environmental variables correlated with the radon gas.

The portable radon measuring apparatus 100 may further include a first signal processing unit 120 for processing the sensed environment variables. For example, the first signal processing unit 120 amplifies environmental variables sensed by an electrical signal, removes noise, converts the digital signal into a digital signal, and processes the digital signal.

The first calculation unit 131 calculates a first correction pressure of the sensed temperature and a second correction pressure of the sensed humidity through the atmospheric pressure temperature / humidity correlation table, and the second calculation unit 132 calculates the first correction pressure and the second correction pressure To the sensed atmospheric pressure to calculate the corrected atmospheric pressure.

The first calculation unit 131 may calculate the first correction pressure and the second correction pressure through an atmospheric pressure / temperature / humidity correlation table in which the atmospheric pressure correlated with the air weight is converted into a unit of temperature and humidity.

The second calculation unit 132 may calculate an average of the first correction pressure and the second correction pressure and calculate a correction atmospheric pressure by applying an error of the average correction pressure calculated at the sensed atmospheric pressure. Further, the second calculation section 132 can use the first correction air pressure or the second correction air pressure as the correction atmospheric pressure.

The discrimination unit 140 compares the corrected atmospheric pressure and the atmospheric pressure radon correlation table to determine whether or not the radon gas is measured for the test region.

The determining unit 140 may determine whether the radon is measured in the test region by comparing the atmospheric pressure radon correlation table and the corrected atmospheric pressure for one of the atmospheric pressure and the correlated atmospheric pressure correlated by the radon gas.

The daily mean atmospheric pressure may be an average atmospheric pressure per day and the correlated atmospheric pressure may be atmospheric pressure correlated by the weight of the air and the radon gas. The correlated atmospheric pressure can be atmospheric pressure correlated by the weight of air, radon and other gases heavier than air. For example, other gases heavier than air may be LPG.

The atmospheric pressure radon correlation table may include a reference atmospheric pressure for determining whether to measure the radon gas for the test region and the reference atmospheric pressure may be a value that is greater than the weight including the air or the radon gas or the weight including other gases, It may be a value including an error range.

The determining unit 140 can determine that the measurement of the radon gas is necessary if the corrected atmospheric pressure is greater than or equal to the reference atmospheric pressure included in the atmospheric pressure radon correlation table. If the corrected atmospheric pressure is less than the reference atmospheric pressure, the determination unit 140 can determine that the measurement of the radon gas is unnecessary.

If the corrected atmospheric pressure is within the reference atmospheric pressure including the error range, the determination unit 140 may detect a plurality of environmental variables at predetermined intervals during a predetermined measurement period of the environmental sensor unit 110, Can calculate an average value of a plurality of environmental variables classified into atmospheric pressure, temperature, and humidity. The first computing unit 131, the second computing unit 132, and the determining unit 140 can re-calculate and re-determine based on the average value of the computed environment variables by the above-described method.

The portable radon measuring apparatus 100 calculates the sensed temperature and humidity at the first correction pressure and the second correction pressure, calculates the correction atmospheric pressure by applying the calculated first correction pressure and the second correction pressure to the sensed atmospheric pressure , Prediction accuracy can be increased by predicting a region or a place where the concentration of the radon gas is high through the calculated corrected atmospheric pressure.

The portable radon measuring apparatus 100 can detect the environmental variable of the test region and determine whether the radon gas is measured for the test region, thereby reducing the installation time and the measurement time, Can be predicted and the prediction accuracy can be improved.

The portable radon measurement apparatus 100 may further include a storage unit 170, a display unit 150, a communication unit 160, and a radon measurement module 180.

The storage unit 170 may store the atmospheric pressure temperature / humidity correlation table and the atmospheric pressure radon correlation table, and may include a test measurement time, a test measurement date, an address or coordinates of the test region, a result of measurement of radon gas, ) Can be stored. The storage unit 170 may store each piece of information corresponding to the identification information.

The display unit 150 may display the display information for at least one of the environmental variable, the first correction pressure, the second correction pressure, the correction atmospheric pressure, and the result of the measurement of the radon gas, The address of the test area or display information for at least one of the coordinates and the user ID included in the identification information.

The communication unit 160 may transmit the display information to the management server (not shown) or the administrator terminal (not shown) through the wireless communication and may receive the control command for remotely controlling the portable radon measurement apparatus 100 from the management server or the manager terminal Lt; / RTI >

The communication unit 160 can perform communication with an administrator terminal, a desktop, or a laptop through a wired / wireless interface for serial connection and data output. For example, a user or an administrator using the radon measuring apparatus 100 may use a communication unit 160 and an administrator terminal, a desktop or a laptop, and a wired or wireless terminal to output data stored in the storage unit 170 of the radar measuring apparatus 100. [ And can output the data through the communication unit 160. [0050]

The radon measurement module 180 can measure the radon gas in the test area based on the result of the measurement of the radon gas. The radon measurement module 180 may include an air collector (not shown), a photoelectric sensor unit 181, and a second signal processor 182 concentration calculator 183.

The air collecting unit receives the radon gas in the air in the test region, and the photoelectric sensor unit 181 is formed inside the air collecting unit to measure the alpha ray generated by the collapse of the radon gas as an electrical signal.

The photoelectric sensor portion 181 may include a PIN photodiode. The PIN photodiode can contain a zinc sulphide (ZnS) material, has a wide bandgap, and can directly detect the alpha line for alpha particles and detect it as an electrical signal.

The PIN photodiode may include a silicon material and may indirectly receive the alpha line for the alpha particle scintillated by the scintillator and detect it as an electrical signal. A scintillator is a material that emits a flash of light when it collides with radiation.

The second signal processing unit 182 can amplify the electrical signal, remove the noise, process the signal with the digital signal, and can be similar to the operation of the first signal processing unit 120 described above.

The concentration calculator 183 can calculate and process the signal-treated alpha rays as the concentration value of the radon gas.

The concentration calculator 183 counts the alpha-rays processed in real time and calculates the density value in units of becquerel or picocurie. Based on the number of counts accumulated during the real time or the measurement period and the calculated concentration value And can be treated with the concentration value of the radon gas.

The unit of becquerel is the number of alpha particles generated per 1 m < ³ > per second, expressed in units of Bq, and the concentration calculator 183 counts each electrical signal and converts it into 1 m < ³ > .

The concentration calculator 183 can reduce the error of the concentration value of the radon gas by referring to the environmental variable, the first correction air pressure, the second correction air pressure, or the correction atmospheric pressure.

The control unit 190 controls the operation of the environmental sensor unit 110. The control unit 190 can control the operation of determining whether to measure the radon gas, the operation of measuring the radon gas, and the communication with the management server or the manager terminal.

FIG. 2 is a flowchart showing an operation method of the portable radon measuring apparatus of the present invention. The operating method of the portable radon measuring apparatus stores an atmospheric pressure temperature / humidity correlation table and an atmospheric pressure radon correlation table in a storage unit, It detects environmental variables including atmospheric pressure, temperature and humidity.

After reading the environmental variable, the storage unit reads the atmospheric pressure temperature / humidity correlation table, and the first calculation unit calculates the first correction pressure of the sensed temperature and the second correction pressure of the sensed humidity through the atmospheric pressure / temperature / humidity correlation table.

After the first correction air pressure and the second correction air pressure are calculated, the second calculation unit applies the first correction air pressure and the second correction air pressure to the sensed atmospheric pressure to calculate the corrected atmospheric pressure.

After calculating the corrected atmospheric pressure, the storage unit reads the atmospheric pressure radon correlation table, and the determination unit compares the corrected atmospheric pressure and the atmospheric pressure radon correlation table to determine whether or not the radon gas is measured for the test region.

100: portable radon measuring device
110: environment sensor unit 120: first signal processing unit
131: first calculation unit 132: second calculation unit
140: discrimination unit 150: display unit
160: communication unit 170:
180: Radon measurement module 181: Photoelectric sensor unit
182: second signal processor 183:

Claims (8)

1. A portable radon measuring device for detecting an environment variable of a test area to determine whether to measure the radon gas in a test area,
An environmental sensor for sensing environmental variables including atmospheric pressure, temperature and humidity of the test area;
A first calculation unit for calculating a first correction pressure of the sensed temperature and a second correction pressure of the sensed humidity through the atmospheric pressure / temperature / humidity correlation table;
A second calculation unit for calculating the corrected atmospheric pressure by applying the first correction air pressure and the second correction air pressure to the sensed atmospheric pressure;
A discrimination unit for comparing the corrected atmospheric pressure with an atmospheric pressure radon correlation table to determine whether to measure the radon gas for the test region,
And a control unit for controlling operation of the environment sensor unit. The method according to claim 1,
The environmental sensor unit,
A portable radon measuring device including an atmospheric pressure sensor, a temperature sensor and a humidity sensor for sensing the environmental variable. The method according to claim 1,
The first calculation unit calculates,
And calculating a first correction air pressure and a second correction air pressure through an atmospheric pressure / temperature / humidity correlation table in which the atmospheric pressure correlated with the air weight is converted into a unit of temperature and humidity. The method according to claim 1,
Wherein the second calculation unit comprises:
Calculating an average of the first correcting air pressure and the second correcting air pressure, and calculating a correction atmospheric pressure by applying an error of an average correcting air pressure calculated at the sensed atmospheric pressure. The method according to claim 1,
Wherein,
A portable radon measuring device for determining whether a radon is measured in a test area by comparing the atmospheric pressure radon correlation table and the corrected atmospheric pressure for one of the daily mean atmospheric pressure and the correlated atmospheric pressure correlated by the radon gas. The method according to claim 1,
Wherein,
And determining that the measurement of the radon gas is necessary if the corrected atmospheric pressure is greater than or equal to the reference atmospheric pressure included in the atmospheric pressure radon correlation table. The method according to claim 1,
A storage unit for storing the atmospheric pressure / temperature / humidity correlation table and the atmospheric pressure radon correlation table;
A signal processing unit for signal processing the environment variable;
A display unit for displaying information on at least one of a result of the measurement of the environment variable, the first correction air pressure, the second correction air pressure, the correction atmospheric pressure, and the measurement of the radon gas;
A communication unit for transmitting the display information to a management server or an administrator terminal;
And a radon measuring unit for measuring the radon gas in the test region based on the result of the measurement of the radon gas. A method of operating a portable radon measuring device for detecting an environment variable of a test area and determining whether to measure the radon gas in a test area,
Storing the atmospheric pressure / temperature / humidity correlation table and the atmospheric pressure radon correlation table in the storage unit;
Sensing environmental variables including atmospheric pressure, temperature and humidity of the test region in the environmental sensor;
Calculating a first correction pressure of the sensed temperature and a second correction pressure of the sensed humidity through the atmospheric pressure / temperature / humidity correlation table in the first calculation unit in the storage unit;
Computing a corrected atmospheric pressure by applying a first correcting air pressure and a second correcting air pressure to the sensed atmospheric pressure in a second computing unit;
And reading the atmospheric pressure radon correlation table from the storage unit and comparing the corrected atmospheric pressure and the atmospheric pressure radon correlation table in the discrimination unit to determine whether or not to measure the radon gas for the test region.

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