KR101771476B1 - Measuring device of Radon gas in multi purpose with improved function - Google Patents

Abstract

The present invention relates to a multipurpose radon gas concentration measuring apparatus with improved degradability, capable of detecting and measuring the concentration of fine dust while detecting and measuring concentrations of radon and thoron gas by using one radon concentration measuring sensor. The multipurpose radon gas concentration measuring apparatus comprises: a multi-radon detection module unit for detecting, in real time, values of the radon gas concentration, the thoron gas concentration, the humidity and the temperature by corresponding control signals with each sensor, wherein the radon gas and the thoron gas are contained in the ambient air; a multi-radon detection control unit which is connected to the multi-radon detection module unit, confirms an error-free normal operation state of each sensor, inputs each value detected by the corresponding control signals, and controls and monitors each functional unit constituting the system; a multi-radon data format unit which records each value detected by the multi-radon detection module unit in a field data area of 1 byte unit and includes standard coordinate information, time, region information, unique number, overhead and check bit of a detected region, to be formatted into radon packet data of word units consisting of 10 bytes; and a multi-radon communication unit for simultaneously transmitting the radon packet data received from the multi-radon data format unit to a designated party by at least one among Wi-Fi, ZigBee, Bluetooth, infrared rays, and wired communication methods.

Description

[0001] The present invention relates to a multi-type radon gas concentration measuring device having improved resolution,

The present invention relates to a multi-type radon gas concentration measuring apparatus with improved resolution, and more particularly, to a radon concentration measuring apparatus capable of detecting and measuring the concentration of fine dust while measuring the concentration of radon and discussion gas using a single radon concentration measuring sensor, And more particularly to an improved multi-type radon gas concentration measuring apparatus.

Radon corresponds to the sixth decay product of uranium-238 widely distributed in nature. Such radon corresponds to an alpha ray emitter of an inert gas which is liable to be released into the atmosphere, and therefore, when living in a room where the concentration of radon is high is long and exists in indoor and outdoor air, do.

In the following description, the detection and measurement are used in the same sense, and either the selective or all of them are used in accordance with the context.

The Earth's crust has 2-4 ppm of uranium, with an average of 2.6 ppm of uranium, and 99.3% of the total uranium, the uranium 238 has a half-life of 45 to 4.6 billion years. Uranium 238 is naturally decayed through half-life, transforming into radium 226, lead 206, and lead 206, resulting in radon 222, and radon 222 generates an alpha line through alpha-decay after 3.8 days of half-life.

Radon (Rn) is a natural radioactive gas produced by radioactive decay of radium (Ra) in uranium and thorium radioactive series. It has colorless and odorless characteristics. It is inactive and has good mobility and is about 8 times as heavy as air. It is very likely to be inhaled into the human body through the breathing air.

Therefore, it is necessary to measure radon concentration. Especially, it is necessary to measure and evaluate periodically in case of buildings, subway, underground shopping street, etc.

The detection of alpha radionuclide sources is a radiological ecology and medically important factor because alpha rays have a strong biological effect on humans and are especially deposited in the lungs through the respiratory tract.

The annual dose for natural background radiation should not exceed 1 mSv (millisievert) per year.

The main source of radiation that exists naturally around is Radon gas. The lagoon moves to the ground surrounded by permeable obstruction soil and gravel fields and passes through cracks and holes in the concrete and into the building.

Building materials such as rocks, bricks and concrete also emit lardon gas, which is water-soluble and thus enters the room by liquid (moisture) movement.

The risk level of radon concentration varies according to national legislation, but is generally in the range of 60 to 200 Bq / ㎥ (Becquerel per cubic meter), and several detection systems and various measurement methods have been developed for the accurate assessment of radioactive concentrations in air And has been undergoing research and development.

The detection and determination of the radon concentration can be performed using a scintillation counter, a gas counter including Geiger, a proportional and ionization chamber type, a solid state junction, ) Counter method, a method using an activated carbon detector, etc., all of which are derived from a method of detecting alpha particles.

Among the devices for this approach, scintillation counter has historically been the earliest used in experiments on radioactivity. The scintillation device provides energy and count information of the alpha particle by a photo cathode of a photomultiplier that amplifies the signal. The scintillation device requires calibration and is expensive to manufacture and is not practical for monitoring the concentration of lardon gas in real time.

In addition, the gas-filled alpha particle detector uses a Geiger counter or an ionizing / proportional counter, uses a specific gas as the detector material, and the working gas for alpha or radon detection is sealed. The ionization zone into which the alpha particles are introduced has a thin and fragile plastic or metal window in the opening where the alpha particles enter, and such window can easily be damaged, thus requiring a precise maintenance in continuous use.

In addition, when air is used as the counter gas, the amplitude of the output signal becomes very low due to the trapping of electrons by negative atoms and molecules, so a high DC voltage is required, and atmospheric conditions such as pulsed electromagnetic noise, There is a problem that this reading greatly affects. On the other hand, the pulse-shape analysis method is applied to the pulse ionization chamber to detect only the alpha particle signal while excluding the influence of the background atmospheric condition, but this method is very complicated to manufacture and is impractical for real-time monitoring of the concentration of radon gas around.

Junction counters also use a solid state PN junction by reverse bias to collect ionized charge in the path of the alpha particles through the depletion layer, There is an advantage that it can carry. However, the low coverage area of the detector requires a long counting time to obtain accurate results and requires strict control to avoid scratching and abrasion of the detector metal electrode surface and to shield the ambient light by coating the light sensitive electrode . However, when there is a scratch, a light leak occurs, and there is a problem that moisture and dust must be controlled for maintaining the active surface.

In addition, there is a detection device of activated charcoal type for the detection of the lardon gas concentration, but it is difficult to continuously monitor the lardon gas concentration in real time.

Meanwhile, in the related art, since the apparatus for detecting the concentration of radon gas and the apparatus for detecting the concentration of the discussion gas are respectively classified, there is a problem that each detecting apparatus is required to detect the concentration of the radon and the discussion gas.

Therefore, it is necessary to develop a technology for selectively detecting the concentration of lardon gas and the concentration of the lard gas in one device.

Korea Patent Registration No. 10-1299405 (2003. 08. 17.) "Radon Safety Evaluation Method for Facilities" Korean Patent Laid-Open Publication No. 10-2004-0071101 (Aug. 11, 2004) "Advanced Radon Monitor Consisting of Two Chambers Incorporating a P- Korean Patent Registration No. 10-0717953 (Aug. 28, 2007) " Method and Apparatus for Measuring Radon Release Rate " Korean Patent Registration No. 10-0936298 (Jan. 04, 2010) "Method and apparatus for detecting radon gas concentration" Korean Patent Registration No. 10-1040072 (2011.06.02.) "Real-time automatic radon monitoring system using soil gas and its method" Korea Patent Registration No. 10-1183064 (2012.09.10.) "Radon Measurement Standard Equipment"

SUMMARY OF THE INVENTION It is an object of the present invention to provide a multi-type lacuna gas concentration measuring apparatus with improved resolution that detects the concentration of lardon gas and the discussion gas using one sensor, to be.

It is another object of the present invention to provide a multi-type lardon gas concentration measuring device with improved resolution for detecting the concentration of fine dust while detecting the concentration of lardon gas and the discussion gas.

In order to achieve the above-mentioned object, the multi-type radon gas concentration measuring apparatus of the present invention improved the resolution of the present invention by measuring the radon concentration, the humidity, the temperature, the atmospheric pressure and the carbon dioxide concentration of the multi- A multi-radon detection module unit for detecting the multi-radon signals in real time by a control signal; A multi-radon detection control unit connected to the multi-radon detection module unit, for checking the error-free normal operation state of each sensor, for inputting each value detected by the corresponding control signal, and for controlling and monitoring each functional unit constituting the system; The multi-radon detecting module may record each value detected by the multi-radon detecting module by the corresponding control signal of the multi-radon detecting control unit in the field data area of 1 byte unit, and may store standard coordinate information, time, area information, An overhead, and a check bit to form radon packet data of word units consisting of 10 bytes; And a multi-radon data transmitting unit operable to simultaneously transmit the radon packet data received from the multi-radon data format unit to a designated one of at least one of a Wi-Fi, A communication unit; . ≪ / RTI >

A multi-radon geosynthesizer for confirming coordinate information and time information including latitude, longitude, and altitude at the current position by a corresponding control signal of the multi-radon detection control unit by receiving and analyzing the geosynchronous signal; And a multi-radar elevation unit for receiving coordinate information and time information including latitude, longitude, and altitude at the current position by the corresponding control signal of the multi-radon detection control unit by receiving and analyzing the elvis signal. As shown in FIG.

The multi-radon detection control unit may be configured to calculate, by arithmetic operation, a value of a GPS satellite coordinate information by a GPS signal at a current location where the multi-radon detection module is located, an elvis coordinate value by an elvis signal, One of the arithmetic average coordinate values calculated by the average calculation can be selected and designated as the standard coordinate information value.

The multi-radon detecting module includes a multi-radon detecting module, which is formed by coating ZnS (Ag) reacting with an alpha ray on one inner wall of a box shape and having a solar cell on one wall surface, An optical sensor unit; A multi-temperature sensor unit installed in a part of an interior of the housing in which the multi-radon optical sensor unit is installed, for detecting the ambient temperature and outputting it as a digital data signal; A multi-humidity sensor unit installed in an internal portion of the housing in which the multi-lamp light sensor unit is installed, for detecting the ambient humidity and outputting the detected humidity as a digital data signal; A multi-pressure sensor unit installed in a part of an interior of the housing in which the multi-lamp sensor unit is installed, for detecting the ambient air pressure and outputting it as a digital data signal; And a multi-carbon dioxide sensor unit installed in a part of the interior of the housing in which the multi-lamp light sensor unit is installed, for detecting the concentration of carbon dioxide in the surroundings and outputting it as a digital data signal; . ≪ / RTI >

Wherein the multi-radon optical sensor unit comprises: a first multi-radon box having a box shape and coated with ZnS (Ag) for discharging photons in response to an alpha ray on an inner wall; A multi-solar cell unit disposed at a lower inner wall of the first multi-radon box unit to detect photons emitted from the first multi-radon box unit and outputting a digital data signal value; A second multi-radon box part attached to a lower outer wall of the first multi-radon box part and having a box shape; A third multi-radon box attached to an upper outer wall of the first multi-radon box and having a box shape; A multi-gas inlet formed at the center of the lower inner wall of the first multi-radon box portion and penetrating the second multi-radon box portion to receive the multi-gas; A first multi-heap filter unit installed in a detachable state on a plurality of holes formed in a side portion of the second multi-radon box part; A second multi-heparin filter part formed on the upper inner wall center part of the first multi-radon box part and fixed to the hole formed through the third multi-radon box part; And a radon pan unit fixedly installed in a hole formed in a center portion of an upper side of the third multi-radon box unit and being driven in an on-off state by a corresponding control signal; . ≪ / RTI >

Wherein the multi-radon optical sensor unit comprises: a first multi-radon box having a box shape and coated with ZnS (Ag) for discharging photons in response to an alpha ray on an inner wall; A multi-solar cell unit disposed at a lower inner wall of the first multi-radon box unit to detect photons emitted from the first multi-radon box unit and outputting a digital data signal value; A second multi-radon box attached to a lower outer wall of the first multi-radon box and having a box shape; A multi-gas inlet formed at the center of the lower inner wall of the first multi-radon box portion and penetrating the second multi-radon box portion to receive the multi-gas; A first multi-heap filter unit installed in a detachable state on a plurality of holes formed in a side portion of the second multi-radon box part; A first multi-shutter unit attached to the outer surface of the first multi-hepa filter unit and blocking the passage of the deb gas by the control signal; . ≪ / RTI >

Wherein the multi-radon optical sensor unit comprises: a first multi-radon box having a box shape and coated with ZnS (Ag) for discharging photons in response to an alpha ray on an inner wall; A multi-solar cell unit disposed at a lower inner wall of the first multi-radon box unit to detect photons emitted from the first multi-radon box unit and outputting a digital data signal value; A second multi-radon box attached to a lower outer wall of the first multi-radon box and having a box shape; A third multi radon box attached to the upper outer wall of the first multi radon box and having a box shape; A multi-gas inlet formed at the center of the lower inner wall of the first multi-radon box portion and penetrating the second multi-radon box portion to receive the multi-gas; A first multi-heap filter unit installed in a detachable state on a plurality of holes formed in a side portion of the second multi-radon box part; A second multi-heparin filter part formed on the upper inner wall center part of the first multi-radon box part and fixed to the hole formed through the third multi-radon box part; A radon pan fixedly installed in a hole formed in a center portion of an upper side of the third multi-radon box and being driven in an on-off state by a corresponding control signal; And a second multi-shutter unit attached to one or more selected one of the first multi-radon filter unit and the second multi-radon filter unit and interrupting the passage of the discussion gas by a corresponding control signal; . ≪ / RTI >

The multi-gas may be composed of one or more selected from general air, lardon gas, radon-nuclide gas, discussion gas, and fine dust.

The present invention having the above-described structure is advantageous in that it can detect and measure the concentration of the discussion gas, the concentration of fine dust, the temperature, the humidity and the atmospheric pressure using a single lardon concentration measuring sensor.

FIG. 1 is an explanatory view of a configuration of an alpha-ray detecting device, which is a passive type detecting device for a lardon gas concentration, according to an embodiment.
FIG. 2 is an explanatory view of a configuration of an activated carbon canister detecting device according to an embodiment, which is a passive detection device of a lardon gas concentration.
FIG. 3 is an explanatory view of a configuration of a charging membrane iontopor detection device according to an embodiment, which is a passive detection device for a lardon gas concentration.
FIG. 4 is an external view of a pulse-type detecting apparatus according to an embodiment of the present invention,
FIG. 5 is an external view of a flash-cell detecting apparatus according to an embodiment of the present invention,
6 is an external view of a semiconductor detection device according to an embodiment of the present invention,
FIG. 7 is a functional configuration explanatory view of an apparatus for measuring multi-type lard, for which the resolution is improved, according to an embodiment of the present invention;
FIG. 8 is a detailed functional configuration diagram of a multi-radon detecting module according to an embodiment of the present invention,
FIG. 9 is a detailed functional configuration diagram of a multi-radar optical sensor unit constituting the multi-radon detection module unit according to the first embodiment of the present invention,
10 is a detailed functional configuration diagram of a multi-radon optical sensor unit constituting a multi-radon detection module unit according to a second embodiment of the present invention,
And
11 is a detailed functional configuration diagram of a multi-radar optical sensor unit constituting a multi-radon detection module unit according to a third embodiment of the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS The present invention is capable of various modifications and various embodiments, and specific embodiments are illustrated in the drawings and will be described in detail in the detailed description. It should be understood, however, that the invention is not intended to be limited to the particular embodiments, but includes all modifications, equivalents, and alternatives falling within the spirit and scope of the invention. DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

In the following description, the detection and the measurement are the same, and they are selectively used or merged in accordance with the context. In the following description, the multi-gas will be described as including lardon gas and radon nuclide gas, debating gas, fine dust and air, and if necessary, each multi-gas will be separately described.

FIG. 1 is an explanatory view of the configuration of an alpha-ray detecting device according to an embodiment of the present invention. FIG. 2 is an explanatory view of an apparatus for detecting an activated carbon canister, which is a passive- FIG. 3 is an explanatory view of a configuration of a charged membrane ionization detector according to an embodiment of the present invention, which is a passive detector of the concentration of lardon gas. FIG. FIG. 5 is an external view of a scintillator cell detection device which is an active type detection device of a lardon concentration according to an embodiment, and FIG. 6 is a schematic view of an active type detection device of a lardon concentration 7 is a perspective view of a semiconductor detection device according to an embodiment of the present invention, FIG. 8 is a detailed functional configuration diagram of a multi-radon detecting module unit constituting a multi-type radon gas concentration measuring apparatus according to an embodiment of the present invention and having improved resolution. FIG. 9 is a detailed functional configuration diagram of the multi- FIG. 10 is a detailed functional diagram of a multi-radon optical sensor unit constituting a multi-radon detection module according to a first embodiment of the present invention. 11 is a detailed functional configuration diagram of a multi-radon optical sensor unit constituting a multi-radon detection module according to a third embodiment of the present invention.

In general, there are a passive detection device (measuring device) and an active type detecting device (measuring device), and a passive detecting device includes an alpha track detectors and an activated carbon canister detecting device canister detectors, and electret ion chambers. Active detection devices include pulse-type iontophoresis devices, scintillation cell detectors, and semiconductor measurement devices.

The passive radon gas concentration measuring device is a low cost type and it is not a real time measurable type. It is a method to accumulate the measured values and to display the radon concentration per unit after the time integration. To reduce the error range, . The passive specific device changes the radon concentration detected according to the installed position and is used without reference to the indoor average. In the case of the alpha-ray detecting device, the chemical treatment (etching) result is changed according to the skill of the analyst, A large difference occurs.

The active radon gas concentration measuring device has excellent detection ability and it can observe the change of the real time radon concentration, but the sensor and the signal amplifying device are very expensive, so that it is difficult for the individual to use it easily.

One of the passive detection devices, the alpha-ray detecting device, is a solid surface such as a plastic film (Polyallyl diglycol carbonate, CR-39), a cellulose film (cellulose nitrate, LR-115) and a polycarbonate (PC: Polycarbonate, Makrofo) It is a method to detect the trace generated by the minute radiation damage to the texture of the material when the alpha particle as the radon offspring is incident.

The alpha track detector comprises an open cup a, a fiber filter cup b, a membrane cup c and a naked detector < RTI ID = 0.0 > ) Detection device (d), and the range of detection lower limit (LLD) capacity is several Bq / m ³ .

Charcoal canister detectors, which are one of the passive detection devices, are configured as shown in FIG. 2, and are relatively inexpensive and reusable, so that they are suitable for large-scale irradiation in a short time.

Activated carbon canister detection system is a method of determining radon concentration by counting gamma rays emitted from products of Bi-214 and Po-214 which are products of radon decay process penetrated into activated carbon.

The collection efficiency of the activated carbon canister detector varies depending on the type, size, and moisture content of the activated carbon, and the maximum exposure period is 7 days and is not suitable for long-term measurement of about 3 months.

In addition, the activated carbon canister detector is not sensitive to the sampling conditions that can affect the results during the measurement period, and is sensitive to changes in temperature, humidity and air flow, and the range of LLD capacity is several Bq / m ³ .

An electret ion chamber measuring apparatus, which is one of the passive detection apparatuses, is constructed as shown in FIG. 3, and forms a voltage by charging the isolated ionization chamber, and generates ions generated by the collapse of radon diffused into the ionization chamber And the voltage drop caused by collecting the electrons is measured to measure the concentration of lardon gas.

Charging Membrane Ionizer can be used to obtain results directly from the measurement site using a calculator and an electrometer, but since it is sensitive to background gamma rays, calibration is required and the range of LLD capacity is about 7 Bq / m ³ .

A pulse ion-chamber radon detector, which is one of the active type detectors, is the same as the alphagardard model shown in FIG. 4, and has an electrometer and an automatic data storage system. Pulsed ionization chamber detection systems use proportional and ionization chamber type techniques.

The pulse-type ionizer detection system converts radon-containing air into an electric pulse from an electrometer, which is generated by the collapse of the radon after introducing the radon-containing air into the ionizer through a natural diffusion or a power pump. And then converted into Bq / m ³ and detected.

The radon decay products introduced into the pulse type ionizer detection device are filtered by the filter during the inflow process and the radon decay products generated inside the ionizer are electrostatically removed and can not reach the effective induction volume of the ionizer. LLD) capacity is 0.7 Bq / m ³ for 17 hours.

Scintillation cell detectors, which are one of the active type detectors, are a Lucas cell model and an SRM-200T model, which are shown in FIG. 5 as an embodiment. By using a flash cell known as a Lucas cell, And is often used as a proven classical measurement method.

A technique of using a scintillation counter is applied to the flash cell detection device.

The scintillation cell of the scintillation cell detection apparatus has various sizes ranging from 0.09 to 3.0 L and the inner wall of the metal or plastic container is uniformly coated with the ZnS (Ag) scintillator powder.

The flash cell detection device is a device for detecting the light emitted from the reaction of the alpha particles and the ZnS (Ag) scintillators released from radon decay products generated inside the cell and the natural diffusion after passing through the filter or the power pump, (LLD) capacity varies depending on the cell size, but it is generally 1 to 37 Bq / m ³ when measured for 30 minutes.

The semiconductor detection device, which is one of the active type detection devices, is the same as the Durid's Rad7 model shown in the embodiment of FIG. 6, and continuously detects the lardon gas.

The semiconductor detector is a method of collecting the radon decay product (positive charge) generated by the collapse of the radon introduced into the vessel using the high potential difference of 2,200 V between the vessel wall and the detector, on the surface of the semiconductor detector.

In order to improve the detection efficiency, the semiconductor detection device is able to detect the concentration of radon by measuring the concentration of Po-218 within 10 minutes after the air is introduced into the container at an inflow rate of 1 L per minute. However, since the detection efficiency of Po-218 is as low as 45%, the measurement time in the radon environment must be sufficiently long in order to obtain useful coefficient statistics.

The apparatus for measuring the concentration of radon gas by the ionization chamber method and the scintillation method according to the prior art has to be provided with a corresponding dedicated measuring apparatus for measuring the radon gas, Method) can detect and measure these three kinds of gases separately.

Since radon has a half-life of 3.2 to 3.8 days and the discussion is 170 seconds, the measurement of lardon concentration using a passive radon measuring device is open.

Discussion The gas concentration measuring device measures the concentration of lardon gas in the state where the discussion is not measured after the closure rate is increased or the film is not used, The value of the discussion gas concentration is detected (measured) by comparing the difference of the values.

On the other hand, an ionization chamber type radon measuring device and a scintillation (new chiller) type radon measuring device for detecting both the radon and the discussion in real time are provided with the corresponding sensor configuration for measuring the radon and the corresponding sensor configuration for measuring the discussion Respectively. And the corresponding gas concentration is detected or analyzed with a difference value obtained by comparing two measured values of the corresponding sensors disposed in parallel.

The present invention provides a configuration for real-time detection of lardon gas concentration and discussion gas concentration using a lardon gas concentration detection sensor (radon sensor), respectively.

That is, according to the present invention, since one radon sensor is used and the discussion gas does not easily enter into the natural diffusion method, but the discussion gas easily enters when the wind pressure is generated, the radon sensor Is a technical principle to alternately measure.

In addition, the radon concentration in the fine dust is firstly measured by using this technique (method or principle), the total radon concentration is measured by driving the ventilator in the second order, and the measured values are compared with each other Real-time detection is possible.

This method detects and measures the concentration change of the indoor fine dust by using the characteristic that the total radon concentration also increases when the indoor fine dust concentration is increased.

That is, there is an advantage that the concentration of fine dust can be measured with a single radon concentration sensor even without a fine dust concentration measuring device.

Therefore, the technology of the present invention can discriminate the radon and the discussion concentration, which was possible only in the measuring apparatus using the conventional semiconductor sensor, from the ionization chamber system with one sensor or the new Chilean sensor system, The concentration can be detected and measured.

In addition, a single radon sensor can be used to detect and measure changes in the particulate matter in the room. Therefore, a multi-type radon gas concentration measuring device capable of detecting and measuring both types of radon and changes in fine dust concentration with one radon sensor It is a technical idea to provide.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Reference will now be made in detail to the preferred embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like reference numerals refer to like elements throughout. A multi-radon communication part 4000, a multi-radon fiber part 5000, and a multi-radon optical part 6000.

The multi-radon detecting module unit 1000 is configured to detect the lardon gas concentration, the discussion gas concentration, the humidity and the temperature value contained in the ambient air in real time by respective control signals, and the multi- A multi-temperature sensor unit 1200, a multi-humidity sensor unit 1300, a multi-pressure sensor unit 1400, and a multi-carbon dioxide (CO 2) sensor unit 1500.

The multi-radon optical sensor unit 1100 is formed by coating ZnS (Ag) reacting with an alpha ray on one inner side wall of a box shape and having a solar cell on one side wall to detect the concentration of lardon gas and the concentration of the lardon gas, And outputs the converted digital data signal.

It is known that ZnS (Ag) has 90,000 photon / MeV of scattering rate (photon emittance) and peak wavelength of 455nm / photon in case of alpha ray collision, and there is a difference in performance depending on the composition ratio and composition. In addition, the performance of ZnS (Ag) varies depending on the coated thickness.

 It is relatively preferable to coat ZnS (Ag) on the inner wall of the box portion of the multi-radon optical sensor part 1100 with a thickness in the range of 5 to 10 micrometers (um) and with a thickness of 5 micrometers (um) .

ZnS (Ag) coated on the inner wall of the box of the multi-radon optical sensor part 1100 discharges the scintillation (photon) when lardon gas is detected. Therefore, ZnS (Ag) Widening this coated area is a way to improve performance or efficiency.

Since the inner surface of the box of the multi-radon optical sensor part 1100 is curved or wrinkled and the surface of the curved or wrinkled surface is coated with ZnS (Ag), it is important to increase the area coated with ZnS And the same applies to the following description, so that the description may not be repeated.

In an embodiment of the multi-radar optical sensor part 1100, a solar-cell is installed in a range of 1 to 3 cm in width with an interval from one side of the same inner wall coated with ZnS (Ag) It is relatively preferable to repeat the installation every centimeter or 1.5 centimeter width unit. It is preferable that the area coated with ZnS (Ag) is the same as the area covered with the solar cell. Since the general configuration of such a multi-radon optical sensor unit is well known, a detailed description thereof will be omitted.

The enclosure ratio of the box constituting the multi-radon optical sensor unit 1100 is preferably in the range of 1 to 2 atmospheres, but it is preferable to configure it at 1.5 atmospheres for high-speed measurement. The higher the sealing rate, the better the noise characteristics can be.

The shape of the multi-radon optical sensor unit 1100 may be any one of a cylindrical shape and a polygonal shape including a triangular shape. In case of a cone or polygonal shape, the detection efficiency of the radon may be improved.

Paper, glass, and synthetic resin can be used as the material for forming the external shape of the multi-radon optical sensor unit 1100, but aluminum-coated paper is advantageous in that it has high airtightness, is light and easy to handle.

The method of coating ZnS (Ag) on the inside of the shape of the multi-radon optical sensor part 1100 is relatively preferable to the offset printing method.

The multi-radon optical sensor unit 1100 may be installed in a separate housing (not shown).

The configuration of the multi-radon optical sensor unit 1100 will be described by way of example.

- First Embodiment -

The structure of the multi-radon optical sensor unit 1100 according to the first embodiment will be described in detail. The multi-radar optical sensor unit 1100 includes a first multi-radon box unit 1110, a multi-solar cell unit 1120, a second multi-radon box unit 1130, Gas inlet 1150, a first multi-heap filter unit 1160, a second multi-heap filter unit 1170, and a radon pan unit 1180. The box unit 1140, the multi-gas inlet 1150,

In the first multi-radon box part 1110, ZnS (Ag) is coated on one side of the box-shaped inner wall, and photons (scintillation) are emitted in response to the alpha rays of the introduced multi-gas.

By enhancing the photon emission function or efficiency, the first multi-radon box part 1110 can form wrinkles, round or polygonal protrusions of various shapes that can be grasped as a whole.

Such wrinkles and protrusions may be uniformly formed or irregularly formed in height, or may be formed in the shape of branches having different shapes for each of the protrusions.

The multi-solar cell portion 1120 is disposed upward at an interval on the lower inner wall surface of the box-shaped first multi-radon box portion 1110 to detect photons emitted by the first multi-radon box portion 1110, .

In the case of the multi-solar cell portion 1120, it is quite natural that the first multi-radon box portion 1110 may have a wrinkle shape or a variety of protrusion shapes to enhance photon (flash) detection efficiency.

 The second multi-radon box part 1130 is attached to the lower outer wall of the first multi-radon box part 1110 and has a box shape.

In the description of the present invention, it is quite natural that the box includes all shapes including a circle, an ellipse, and a polygon.

The third multi-radon box part 1140 is attached to the upper outer wall of the first multi-radon box part 1110 and has a box shape.

The multi-gas inlet 1150 is formed in the center portion of the lower inner wall of the first multi-radon box portion 1110 and penetrates the upper center portion of the second multi-radon box portion 1130,

The first multi-heparin filter portion 1160 is installed in a detachable state in a plurality of holes formed through a part of a side surface of the second multi-radon box portion 1130. The first multi-HEPA filter unit 1160 may be a well-known Hepa type filter.

The second multi-heparin filter portion 1170 is fixed to the hole formed in the center portion of the upper inner wall of the first multi-radon box portion 1110, and the hole formed through the lower middle portion of the third multi-radon box portion 1140.

The radar pan portion 1180 is fixed to a hole formed in the center portion of the upper side of the third multi radon box portion 1140 and is driven on or off by the corresponding control signal.

The radar pan unit 1180 preferably circulates the multi-radar optical sensor unit 1100 using a fan and discharges the multi-gas introduced into the multi-radar optical sensor unit 1100 at a constant air velocity for forced circulation to be constantly discharged at an air velocity of 2 m / s And it is very natural that the wind speed can be changed according to need.

By using the radar pan part 1180, the surrounding multi-gas concentration can be detected more quickly, and the accuracy is increased as the detection time becomes longer.

The first multi-radon box part 1110, the second multi-radon box part 1130, and the third multi-radon box part 1140 are configured to block the inflow of light from the outside and to smooth the inflow and outflow of air, The same applies to the following.

The configuration according to the first embodiment can detect and measure the radon gas constituting the multi-gas and the radon radionuclide on the fine dust by using a single sensor with the radon pan section 1180, do.

The sensor includes a first multi-radon box part 1110 and ZnS (Ag) 1102 coated on the inner wall of the first multi-radon box part 1110 and a multi-solar cell part 1120, The same applies to the description of the present invention.

- Second Embodiment -

The structure of the multi-radon optical sensor unit 1100 according to the second embodiment will be described in detail. The multi-radar optical sensor unit 1100 according to the second embodiment includes a first multi-radon box unit 1110, a multi-solar cell unit 1120, a second multi-radon box unit 1130, 1150, a first multi-hepa filter unit 1160, and a first multi-shutter unit 1190.

In the first multi-radon box part 1110, ZnS (Ag) is coated on one side of the box-shaped inner wall, and photons (scintillation) are emitted in response to the alpha rays of the introduced multi-gas.

By enhancing the photon emission function or efficiency, the first multi-radon box part 1110 can form wrinkles, round or polygonal protrusions of various shapes that can be grasped as a whole.

Such wrinkles and protrusions may be uniformly formed or irregularly formed in height, or may be formed in the shape of branches having different shapes for each of the protrusions.

The multi-solar cell portion 1120 is disposed upward at an interval on the lower inner wall surface of the box-shaped first multi-radon box portion 1110 to detect photons emitted by the first multi-radon box portion 1110, .

In the case of the multi-solar cell portion 1120, it is quite natural that the first multi-radon box portion 1110 may have a wrinkle shape or a variety of protrusion shapes to enhance photon (flash) detection efficiency.

 The second multi-radon box part 1130 is attached to the lower outer wall of the first multi-radon box part 1110 and has a box shape.

The multi-gas inlet 1150 is formed in the center portion of the lower inner wall of the first multi-radon box portion 1110 and penetrates the upper center portion of the second multi-radon box portion 1130,

The first multi-heparin filter portion 1160 is installed in a detachable state in a plurality of holes formed through a part of a side surface of the second multi-radon box portion 1130. The first multi-HEPA filter unit 1160 may be a well-known Hepa type filter.

The first multi-shutter unit 1190 is attached to the outer side or the inner side or both sides of the first multi-hepa filter unit 1160 and blocks the passage of the discussion gas by the corresponding control signal.

The first multi-shutter unit 1190 may be formed of any one of a generally known mechanical configuration and an electronic configuration in which the electronic arrangement is changed by a DC voltage applied to the film, such as a liquid crystal of an LCD, have.

In the second embodiment, the multi-gas introduced into the first multi-radon box part 1110 flows by the natural convection phenomenon.

The configuration according to the second embodiment can detect and measure the radon gas and the talk gas constituting the multi-gas by one sensor by the opening / closing action of the first multi-shutter unit 1190, do.

- Third Embodiment -

The structure of the multi-radon optical sensor unit 1100 according to the third embodiment will now be described in detail. The multi-radar optical sensor unit 1100 includes a first multi-radon box unit 1110, a multi-solar cell unit 1120, a second multi-radon box unit 1130, A second multihape filter unit 1170, a radon pan unit 1180, and a second multi-shutter unit 1195. The first multihape filter unit 1130 includes a box unit 1140, a multi-gas inlet 1150, a first multi- .

The multi-radar optical sensor unit 1110 according to the third embodiment further includes a second multi-shutter unit 1195 in the multi-radar optical sensor unit 1110 according to the first embodiment.

Therefore, only the second multi-shutter unit 1195 will be described in the description of the multi-radon optical sensor unit 1110 according to the third embodiment.

The second multi-shutter unit 1195 is attached to one or more of the first and second multi-radon filter units 1160 and 1170, In order to block the passage of the light.

The second multi-shutter unit 1195 has the same configuration and material as those of the first multi-shutter unit 1190 in the second embodiment, and a duplicate description thereof will be omitted.

In the third embodiment, the concentrations of the radon gas, the talk gas, and the radon nuclides attached to the fine dusts constituting the multi-gas, together with the concentration of the fine dust, are changed by the opening / closing action of the second multi- The sensor can be separated and detected by one sensor by driving the sensor 1180, so that the resolving ability of the sensor is improved.

In addition, the third embodiment is advantageous in that the lifetime can be prolonged because the concentration of the multi-gas can be detected and measured even if a failure occurs in any one of the configurations of the second multi-shutter unit 1195 and the radar pan unit 1180. Meanwhile, it is quite natural that the multi-radon detection control unit 2000 records and stores the fault condition and provides the necessary notification.

The multi-temperature sensor unit 1200 is installed in an inner portion of the housing where the multi-radon optical sensor unit 1100 is installed, detects the ambient temperature, and outputs the detected temperature as a digital data signal. The configuration of the multi-temperature sensor unit 1200 is generally known, so a detailed description thereof will be omitted.

The multi-humidity sensor unit 1300 is installed in a part of the housing where the multi-radon optical sensor unit 1100 is installed, detects ambient humidity, and outputs the humidity data as a digital data signal. Since the configuration of the multi-humidity sensor unit 1300 is generally known, a detailed description thereof will be omitted.

The multi-air pressure sensor unit 1400 is installed in an inner portion of the housing where the multi-radon optical sensor unit 1100 is installed, detects the subscription of the surroundings, and outputs the digital data signal. The configuration, operation, and function of the multi-air pressure sensor unit 1300 are generally known, so a detailed description thereof will be omitted.

The multi-carbon dioxide (CO 2) sensor unit 1500 is installed in a part of the housing where the multi-radon optical sensor unit 1100 is installed, detects the ambient carbon dioxide concentration humidity, and outputs the detected humidity. Since the configuration of the multi-carbon dioxide sensor unit 1300 is generally known, a detailed description thereof will be omitted.

Here, it is assumed that the circumference is within a range of 2 to 15 meters.

The multi-radon detection control unit 2000 is connected to the multi-radon detection module unit 1000, checks the error-free normal operation state of each sensor, inputs each value detected by the corresponding control signal, Each function is controlled and monitored.

The multi-radon data format unit 3000 records each value detected by the multi-radon detection module unit 1000 in the field data area of 1 byte unit by the corresponding control signal of the multi-radon detection control unit 2000, Formatted into radon packet data in units of words consisting of 10 bytes including standard coordinate information of the area, time, area information, unique number, overhead, and check bit.

The multi-radon communication unit 4000 transmits the radon packet data, which is applied from the multi-radon data format unit 3000, to the designated radio terminal through the Wi-Fi, Zigbee, Bluetooth, infrared, And simultaneously transmits and transmits them in any one or more ways. At this time, it is quite natural that the designated party should be provided with a configuration for simultaneous connection by any one or more of Wi-Fi, ZigBee, Bluetooth, infrared, and wired communication methods.

Wi-Fi, ZigBee, Bluetooth, infrared communication methods are well known and will not be described in detail, and wired communication is described as including wired telephone communication and wired Internet access.

The multi-radon grasping unit 5000 receives coordinate information consisting of latitude, longitude and sea-level values at the current position by the corresponding control signal of the multi-radon detection controller 2000, Is confirmed by receiving and analyzing the GS signal.

A Global Positioning System (GPS) signal is a signal received from more than twenty-four (24) multiple GPS satellites orbiting at altitudes of 200,000 to 250,000 kilometers (Km) above ground, and a GPS signal received from four or more GSIS satellites The information including the longitude, latitude, altitude, moving direction, moving speed, angular velocity and time of the receiving point can be confirmed.

The GS signals can be used anywhere in the world and are available as a free service.

The multi-radon controller 6000 transmits coordinate information and time information including latitude, longitude, and altitude at the current position to the LBS (Location Based Service) signal by the corresponding control signal of the multi- And the results of the analysis.

The LBS signal secures precise coordinate information of each base station based on the operation characteristics of the mobile communication system and analyzes the current coordinate information of the terminal using the coordinates information of each base station, It is known to be high. The LVS signal can be used only within the service area formed by the mobile communication system, and pay service is generally used.

Here, the multi-radon detection control unit 2000 may include a multi-radon detection module 900 including a multi-radon detection module 900 including a multi-radon detection module unit 1000, And an arithmetic mean coordinate value obtained by arithmetically averaging the LVS coordinate information value and the LVS coordinate information value is designated as a standard coordinate information value.

That is, in a place where both the GPS signal and the LVIS signal are received, arithmetic average coordinate values obtained by arithmetically averaging the analyzed GPS coordinates information values and the LVIS coordinate information values are used, and in a place where only the GPS signals are received, Coordinate information value is used, and in a place where only an LVIS signal is received, an LVIS coordinate information value is used. Since the radio signal is a radio signal and the radio signal is highly influenced by the terrain, it is possible to effectively use the GPS signal in some places, effectively use only the LVIS signal in other places, You need to consider the reality that you can use.

In the method of operating the multi-type radon gas concentration measuring apparatus with improved resolution, the multi-radon detecting control unit checks whether a corresponding control command signal for instructing start of operation is input (S110).

If it is determined that the button signal for starting operation is input by the multi-radon detection control unit, the normal operation state of each function unit constituting the radon gas detection system is confirmed (S120).

If it is detected that one or more of the functional units configured by the multi-radon detection control unit does not operate normally, an alarm signal indicating the corresponding failure state is output and the process proceeds to step S180.

On the other hand, if it is determined by the multi-radon detection control unit that each function unit is normally operated, the multi-radon detection module unit is operated in an activated state and a corresponding control signal is output to detect the concentration of radon gas in the air, S130).

The multi-radon detection control unit detects the standard coordinate information value by operating the multi-radon spurious point unit and the multi-radon elastic unit in an active state (S140).

The multi-radon detection control unit operates the multi-radon data format unit in an activated state and formats the detected values into radon packet data of word units each consisting of 10 bytes (S150).

That is, 1 byte is allocated to each of the detected radon concentration value, temperature value, humidity value, coordinate information value of the corresponding area, time value, local information value, unique number value and overhead information, And then standardizes the packets into a single word unit.

It is very desirable that the number of words constituting the packet can be increased when the detected information is large, and it is relatively preferable that all information detected or recorded is stored (recorded) in units of one word packet. A parity check scheme is used for error detection and correction of data signals.

It is relatively preferable to record the order stored in the packets in the order of overhead, parity check, radon concentration value, temperature value, humidity value, coordinate information value of the area, time value, local information value, unique number value, Do.

The multi-radon detection control unit operates the multi-radon communication unit in an active state to connect to the designated party in the wired and wireless manner and transmit packet-based information in real time (S160).

The designated party here may be a resident, an operator, or a specific public entity, and is not limited.

If the signal of the off button is not inputted, the multi-radon detection control unit continuously repeats the detection of the radon concentration in real time (S170).

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 be apparent to those skilled in the art.

900: Multi-type lardon concentration measuring device
1000: Multi radon detecting module part 2000: Multi radon detecting controlling part
3000: Multi radon data format part 4000: Multi radon communication part
5000: Multi-Radon Glycep Department 6000: Multi-Radon Ebb S

Claims (8)

A multi-radon detection module for detecting the radon concentration, the humidity, the temperature, the atmospheric pressure, and the carbon dioxide concentration of the multi-gas contained in the ambient air in real time by the corresponding sensors;
A multi-radon detection control unit connected to the multi-radon detection module unit, for checking the error-free normal operation state of each sensor, for inputting each value detected by the corresponding control signal, and for controlling and monitoring each functional unit constituting the system;
The multi-radon detecting module may record each value detected by the multi-radon detecting module by the corresponding control signal of the multi-radon detecting control unit in the field data area of 1 byte unit, and may store standard coordinate information, time, area information, An overhead, and a check bit to form radon packet data of word units consisting of 10 bytes; And
A multi-radon communication unit for simultaneously transmitting the radon packet data, which is applied from the multi-radon data format unit, to at least one of a Wi-Fi, a Zigbee, ;
An arithmetic average coordinate obtained by arithmetically averaging the values of the GPS coordinates information by the GPS signal at the present location where the multi-radon detecting module is located, the elbis coordinate information by the elvis signal, Values, and designating them as standard coordinate information values;
The multi-radon detecting module includes a multi-radon detecting module, which is formed by coating ZnS (Ag) reacting with an alpha ray on one inner wall of a box shape and having a solar cell on one wall surface, An optical sensor unit;
A multi-temperature sensor unit installed in a part of an interior of the housing in which the multi-radon optical sensor unit is installed, for detecting the ambient temperature and outputting it as a digital data signal;
A multi-humidity sensor unit installed in a part of an interior of the housing in which the multi-radon optical sensor unit is installed, for detecting the ambient humidity and outputting the detected humidity as a digital data signal;
A multi-pressure sensor unit installed in a part of an interior of the housing in which the multi-radon optical sensor unit is installed, for detecting the atmospheric pressure of the surroundings and outputting the detected ambient pressure as a digital data signal; And
A multi-carbon dioxide sensor unit installed in a part of the interior of the housing in which the multi-radon optical sensor unit is installed, for detecting the concentration of carbon dioxide in the surroundings and outputting it as a digital data signal;
Wherein the multi-radon optical sensor unit comprises: a first multi-radon box having a box shape and coated with ZnS (Ag) for discharging photons in response to an alpha ray on an inner wall;
A multi-solar cell unit disposed at a lower inner wall of the first multi-radon box unit to detect photons emitted from the first multi-radon box unit and outputting a digital data signal value;
A second multi-radon box part attached to a lower outer wall of the first multi-radon box part and having a box shape;
A third multi-radon box attached to an upper outer wall of the first multi-radon box and having a box shape;
A multi-gas inlet formed at the center of the lower inner wall of the first multi-radon box portion and penetrating the second multi-radon box portion to receive the multi-gas;
A first multi-heap filter unit installed in a detachable state on a plurality of holes formed in a side portion of the second multi-radon box part;
A second multi-heparin filter part formed on the upper inner wall center part of the first multi-radon box part and fixed to the hole formed through the third multi-radon box part; And
A radon pan fixedly installed in a hole formed in a center portion of an upper side of the third multi-radon box and being driven in an on-off state by a corresponding control signal;
Wherein the multi-radon optical sensor unit comprises: a first multi-radon box having a box shape and coated with ZnS (Ag) for discharging photons in response to an alpha ray on an inner wall;
A multi-solar cell unit disposed at a lower inner wall of the first multi-radon box unit to detect photons emitted from the first multi-radon box unit and outputting a digital data signal value;
A second multi-radon box part attached to a lower outer wall of the first multi-radon box part and having a box shape;
A third multi-radon box attached to an upper outer wall of the first multi-radon box and having a box shape;
A multi-gas inlet formed at the center of the lower inner wall of the first multi-radon box portion and penetrating the second multi-radon box portion to receive the multi-gas;
A first multi-heap filter unit installed in a detachable state on a plurality of holes formed in a side portion of the second multi-radon box part;
A second multi-heparin filter part formed on the upper inner wall center part of the first multi-radon box part and fixed to the hole formed through the third multi-radon box part; And
A radon pan fixedly installed in a hole formed in a center portion of an upper side of the third multi-radon box and being driven in an on-off state by a corresponding control signal; And a measuring device for measuring the concentration of the multi-type lard.
The method according to claim 1,
A multi-radon geosynthesizer for confirming coordinate information and time information including latitude, longitude, and altitude at the current position by a corresponding control signal of the multi-radon detection control unit by receiving and analyzing the geosynchronous signal; And
A multi-radar elevation unit for confirming coordinate information and time information including the latitude, longitude, and altitude at the current location by the corresponding control signal of the multi-radon detection control unit by receiving and analyzing the elvis signal; Further comprising: a measuring device for measuring the concentration of the lard.
delete delete delete The method according to claim 1,
The multi-radon optical sensor unit
A first multi-radon box having a box shape and coated with ZnS (Ag) for emitting photons in response to an alpha ray on the inner wall;
A multi-solar cell unit disposed at a lower inner wall of the first multi-radon box unit to detect photons emitted from the first multi-radon box unit and outputting a digital data signal value;
A second multi-radon box attached to a lower outer wall of the first multi-radon box and having a box shape;
A multi-gas inlet formed at the center of the lower inner wall of the first multi-radon box portion and penetrating the second multi-radon box portion to receive the multi-gas;
A first multi-heap filter unit installed in a detachable state on a plurality of holes formed in a side portion of the second multi-radon box part;
A first multi-shutter unit attached to the outer surface of the first multi-hepa filter unit and blocking the passage of the deb gas by the control signal; And a measuring device for measuring the concentration of the multi-type lard.
The method according to claim 1,
The multi-radon optical sensor unit
A first multi-radon box having a box shape and coated with ZnS (Ag) for emitting photons in response to an alpha ray on the inner wall;
A multi-solar cell unit disposed at a lower inner wall of the first multi-radon box unit to detect photons emitted from the first multi-radon box unit and outputting a digital data signal value;
A second multi-radon box attached to a lower outer wall of the first multi-radon box and having a box shape;
A third multi radon box attached to the upper outer wall of the first multi radon box and having a box shape;
A multi-gas inlet formed at the center of the lower inner wall of the first multi-radon box portion and penetrating the second multi-radon box portion to receive the multi-gas;
A first multi-heap filter unit installed in a detachable state on a plurality of holes formed in a side portion of the second multi-radon box part;
A second multi-heparin filter part formed on the upper inner wall center part of the first multi-radon box part and fixed to the hole formed through the third multi-radon box part;
A radon pan fixedly installed in a hole formed in a center portion of an upper side of the third multi-radon box and being driven in an on-off state by a corresponding control signal; And
A second multi-shutter unit attached to one or more selected one side of the first multi-radon filter unit and the second multi-radon filter unit and interrupting the passage of the discussion gas according to a corresponding control signal; And a measuring device for measuring the concentration of the multi-type lard.
8. The method of claim 7,
The multi-
Characterized in that it comprises at least one selected from the group consisting of general air, lardon gas, radon prodrug gas, discussion gas and fine dust.

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