KR101912680B1 - A radon monitoring service system using app and web - Google Patents

Abstract

The present invention relates to a radon monitoring service system using an application and a web, capable of effectively providing radon concentration information, which comprises: a communication type radon sensor separately installed at a specific place of a multi-use facility, and including a communication module for transmitting a radon concentration measured by a radon measurement module; and a radon service management server receiving and monitoring radon concentrations in real time, and storing and managing the same in a corresponding database area.

Description

A RADON MONITORING SERVICE SYSTEM USING APP AND WEB USING APP AND WEB

The present invention relates to a radon monitoring service system using an app and a web. More specifically, the present invention measures a radon concentration from a communication type radon sensor installed in a specific place, and measures the radon concentrations in real time at a radon service management server The present invention relates to a radon monitoring service system using an app and a web, which enables a user or an administrator of a communication type radon sensor to provide collected radon concentration information.

In general, radon (Rn) is a kind of radioactive gas, and the US Environmental Protection Agency warns that inhalation of radon is the main cause of lung cancer following smoking. In general, radon (Rn) gas, which is a major cause of radiation exposure to the general public, is continuously moved to the ground through soil or gravel surrounding the building, and penetrates into the room through the space of buildings or pores of concrete (Rn) penetrating from the surrounding soil is known to be the main cause of indoor radon (Rn), and building materials such as concrete, gypsum board, gravel, and brick are also becoming main sources of indoor radon (Rn).

In addition, radon (Rn) is well dissolved in water, so it flows into the room through the movement of groundwater, and indoor movement through water penetrates due to capillary phenomenon or water pressure through the pores of concrete. , And the lower the pressure, the more radon (Rn) gas flows into the room. Thus, when radon (Rn) gas present in the atmosphere is inhaled into the lungs through respiration, alpha particle radiation emitted from radon (Rn) is directly irradiated to the lung cells to destroy the cells. Therefore, Is a primary carcinogen.

In order to accurately measure and evaluate the indoor concentration of radon (Rn), which has a great influence on human health as described above, various kinds of instruments and various measurement methods and devices have been widely used and used. Radon (Rn) Because it is a colorless, odorless inert gas, it is difficult to directly measure because it is not reactive and the frequency of alpha particles generated by decay of radon (Rn) is proportional to the concentration of radon. do.

As a device for detecting alpha particles in general, surface barrier type, high purity type semiconductor detectors, scintillation detectors, pulse type ionization chambers, and the like are typically used. Since the surface barrier type detector needs to shut off the external light, it is close to airtight and air circulation is not smooth. Therefore, it is necessary to use a forced circulation pump and the charged particles must collide with the surface of the semiconductor. Therefore, a relatively high high- And a semiconductor detection element having a large surface area is required, which is expensive and low in detection efficiency as a limitation of 2D measurement. In addition, high purity semiconductor detectors are very expensive and have a disadvantage in that they are very bulky since liquid nitrogen cooling is essential. In addition, the scintillation detector is disadvantageous in that zinc sulfide (ZnS) or NaI coating is weak in moisture and durability is low, and expensive pyrolysis piping is necessary, which is very expensive. The pulse type ionization chamber detector has a structure in which a probe-shaped electrode is provided at the center of a cylindrical box made of metal, and an electric field is formed by applying a bias voltage between the metal cylinder and the inner probe. The probe is very inexpensive, has good durability and is light-free. Therefore, it has a merit of being able to improve the air permeability. However, since the input impedance is close to infinity and is sensitive to electric noise, it is required to solve the problem of noise of the signal- have.

Radon, which is defined as a first-level carcinogen causing lung cancer, has been approved by the Ministry of Environment in December 16, 2008 and the Ministry of Education in March, The application of the pulse ionization chamber detector among the conventional radon detectors is as follows: a cylindrical ionization chamber is used as the ionization chamber, This radar meter probe is applied to a cylindrical ionization chamber and has a low sensitivity to radon measurement and a disadvantage that the use of the installation and management on the field is reduced due to the cylindrical equipment. There was a limit. In addition, the radon measurement detectors were only checking the radon concentration measured directly by the administrator or user in the installation area.

The present invention has been proposed in order to solve the above-mentioned problems of the previously proposed methods. The present invention measures radon concentration from a communication type radon sensor installed in a specific place, and measures the radon concentrations in real time at a radon service management server And it is possible to provide radon concentration information to the user or administrator of the installation area of the communication type radon sensor, thereby real time management of the radon concentration information measured by the specific place installed and to provide the user or manager with an app It is an object of the present invention to provide a radon monitoring service system using an app and a web, which can effectively provide radon concentration information measured through the web.

In addition, the present invention provides a communication type radon sensor, in which a conventional linear ionization chamber is configured as a slip type rectangular chamber, and a radon meter probe antenna is also configured as a lattice type high sensitivity antenna corresponding to a slip type square chamber type The radon monitoring service system, which utilizes the app and the web, which improves the sensitivity of the radon measurement by applying a high-sensitivity S / N circuit and secures the scalability of the communication through connection between the radon measurement module and the communication module The present invention provides another object.

In addition, since the communication type radon sensor is accommodated in the wall-mounted type wall case body in which the radon measurement module and the communication module are accommodated, it is possible to solve and solve the mounting problem as a customer requirement Of course, it is possible to improve the ease of installation and management, which minimizes the constraints of the installation place, and by applying various communication methods capable of interlocking the user device with the application or the web, various external devices The present invention also provides a radon monitoring service system using an app and a web, which enables radon measurement data communication of a radon.

According to an aspect of the present invention, there is provided a radon monitoring service system using an app and a web,

As a radon monitoring service system that utilizes apps (APP) and web (WEB)

A method of detecting an alpha particle ion generated in the occurrence of alpha decay in a radon gas contained in air introduced into an ionization chamber, the method comprising the steps of: A radon measurement module for measuring the radon concentration through noise removal and pre-processing of amplification and pulse reading, and a communication module connected to the radon measurement module and for transmitting the measured radon concentration in the radon measurement module A communication type radon sensor; And

And a radon service management server for receiving and monitoring the radon concentrations transmitted from the communication type radon sensors in real time through wired or wireless communication and for storing and managing the received radon concentrations in a corresponding database area, .

Advantageously, the radon monitoring service system comprises:

And a user device connected to the radon service management server through a communication network to receive a measured value of radon concentration in a preset radon measurement area.

More preferably, the user device further comprises:

A personal computer (PC), a notebook computer, and a smart device connected and connected to the radon service management server through a communication link of an app interlocking system or a web interlocking system, can be configured as an administrator terminal of a specific area in which the communication type radon sensor is installed .

Preferably, the radon measuring module of the communication type radon sensor comprises:

An ionization chamber in which air is smoothly circulated and a bias power source is applied to form an electric field therein;

A radon meter probe disposed in the ionization chamber for detecting alpha particle ions produced in the ionization chamber when alpha decay occurs in the radon gas;

A signal processing circuit unit for performing noise removal on an external signal and pre-processing of amplification through an amplifier with respect to a signal of alpha particle ions detected from the radon meter probe antenna;

A control unit for generating valid data by reading the pulses outputted after the pre-processing of noise removal and amplification is performed from the signal processing circuit unit, and calculating and outputting the corresponding radon concentration;

A power supply for supplying bias power to the ionization chamber and driving power of the radon measurement module; And

And a communication connection unit connected to the communication module.

More preferably, the radon measurement module comprises:

The ionization chamber may be configured as a slip type square chamber and the radon meter probe antenna may be configured as a lattice type high sensitivity antenna arranged corresponding to the slip type rectangular chamber shape of the ionization chamber.

Even more preferably, the communication type radon sensor comprises:

The wall mount case main body further comprises a wall mount case main body installed on a wall surface of a specific place for measuring the radon concentration, wherein the wall mount case main body comprises a rectangular shape, a disk shape , And a case of a straight shape.

Even more preferably, the radon service management server comprises:

The radon concentration measurement values provided from the communication type radon sensors may be stored and managed in a corresponding database area over time and the evaluated risk level may be displayed and displayed on a monitoring screen.

Even more preferably, the radon service management server comprises:

By using the measured values of the radon concentration, it is possible to provide a radon statistic and graph implementation, a measurement status implementation per sensor, a measurement log, and a report output function for each communication type radon sensor.

According to the radon monitoring service system using the app and the web proposed in the present invention, the radon concentration is measured from the communication type radon sensor installed at a specific place, and the measured radon concentrations are collected in real time from the radon service management server The radon concentration information can be provided to the user or the administrator of the installation area of the communication type radon sensor so that the real time management of the radon concentration information measured by the specific place installed and the user or the manager So that it is possible to effectively provide the measured radon concentration information.

According to the present invention, there is provided a communication type radon sensor, wherein the conventional linear ionization chamber is configured as a slip-type rectangular chamber, and the radon meter probe antenna is also a lattice type high sensitivity antenna corresponding to a slip- The sensitivity of the radon measurement can be improved by applying the high sensitivity S / N circuit, and the scalability of the communication through the connection connection of the radon measurement module and the communication module can be ensured.

In addition, since the communication type radon sensor is accommodated in the wall-mounted type wall case body in which the radon measurement module and the communication module are accommodated, it is possible to solve and solve the mounting problem as a customer requirement Of course, it is possible to improve the ease of installation and management, which minimizes the constraint of the installation place, and by applying various communication methods capable of interlocking the user device with the application or the web, various external devices So that the radon measurement data can be communicated.

Brief Description of the Drawings Fig. 1 is a diagram showing the overall system configuration of a radon monitoring service system using an app and a web according to an embodiment of the present invention. Fig.
BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a radon monitoring service system using an application and a web, and more particularly,
3 is a diagram illustrating the configuration of a functional block of a radon measurement module provided in a communication type radon sensor of a radon monitoring service system utilizing an app and a web according to an embodiment of the present invention.
4 is a perspective view of an example of an ionization chamber and a radon meter probe antenna of a radon measurement module provided in a communication type radon sensor of a radon monitoring service system utilizing an app and a web according to an embodiment of the present invention.
5 is a diagram illustrating an example of a communication module included in a communication type radon sensor of a radon monitoring service system utilizing an app and a web according to an embodiment of the present invention.
6 is a perspective view of an example of the installation of a wall-mounted type wall case body applied to a communication type radon sensor of a radon monitoring service system utilizing an app and a web according to an embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings, in order that those skilled in the art can easily carry out the present invention. In the following detailed description of the preferred embodiments of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear. In the drawings, like reference numerals are used throughout the drawings.

In addition, in the entire specification, when a part is referred to as being 'connected' to another part, it may be referred to as 'indirectly connected' not only with 'directly connected' . Also, to "include" an element means that it may include other elements, rather than excluding other elements, unless specifically stated otherwise.

FIG. 1 is a diagram illustrating an overall system configuration of a radon monitoring service system using an app and a web according to an embodiment of the present invention. FIG. 2 is a diagram illustrating a radon monitoring service system using an app and a web according to an embodiment of the present invention. FIG. 3 is a diagram illustrating a functional block of a communication type radon sensor applied to a service system according to an embodiment of the present invention. FIG. FIG. 4 is a diagram illustrating a configuration of a functional block of a measurement module according to an embodiment of the present invention. FIG. 4 is a diagram illustrating a configuration of a functional module of a radon sensor, FIG. 5 is a diagram illustrating a configuration of a radon monitoring service system using an app and a web according to an embodiment of the present invention. FIG. 6 is a diagram illustrating a configuration example of a communication module included in a sensor, and FIG. 6 is a diagram illustrating an example of a communication module provided in a wall- Fig. 8 is a view showing a perspective configuration of an example of the installation of the main body. 1 to 6, a radon monitoring service system 10 using an app and a web according to an embodiment of the present invention includes a communication type radon sensor 100, a radon service management server 200, And may further comprise a user device 300.

The communication type radon sensor 100 is installed in a specific place of the multi-use facility where the radon measurement is required, and the alpha-particle ion produced in the alpha decay in the radon gas contained in the air introduced into the ionization chamber 111 And a radon measurement module 110 for measuring the radon concentration through the noise elimination and the preprocessing of amplification and pulse readout for an external signal with respect to the detected alpha particle ion and a radon measurement module 110, And a communication module 120 for transmitting the measured radon concentration at the measurement module 110. [ As shown in FIG. 3, the radon measurement module 110 of the communication type radon sensor 100 includes an ionization chamber 111 for smoothly circulating air and receiving an electric bias power to form an electric field therein, A radon meter probe antenna 112 disposed in the chamber 111 for detecting alpha particle ions generated when alpha decay occurs in the radon gas in the ionization chamber 111, A signal processing circuit 113 for performing noise removal on an external signal and pre-processing for amplification through an amplifier, a readout pulse output after a noise removal and amplification preprocessing process is performed from the signal processing circuit 113, A control unit 114 for calculating effective radon concentration and outputting the calculated data and outputting the resultant data to the ionization chamber 111, A power supply unit 115 for supplying a circle, and a communication connection unit 116 connected and connected to the communication module 120.

The radon measurement module 110 includes a slit-type square chamber type ionization chamber 111 and a radar measurement probe 112. The radon measurement probe 110 is connected to the lattice meter 111, Type high-sensitivity antenna. At this time, the bias power applied to the surface of the ionization chamber 111 may be supplied with a DC voltage of 25 to 50 volts. The structure of the ionization chamber of the conventional cylindrical structure and the problem of low sensitivity of the conventional linear radon meter probe antenna are solved through the structural modification of the ionization chamber 111 and the radon meter probe antenna 112, . ≪ / RTI > The radon measurement module 110 removes noise from an external signal through application of a high-sensitivity S / N circuit, amplifies the noise through an OP AMP circuit, and then generates a valid data by reading a pulse in the controller 114 It is possible to measure the radon concentration with high sensitivity.

The communication module 120 is connected to the radon measurement module 110 and has a configuration of a communication device for transmitting the radon concentration measured by the radon measurement module 110 to the radon service server 200, At least one communication method including LTE communication, USB, and Bluetooth capable of data communication with the radon service management server 200, connected to the communication connection 116 of the radon measurement module 110, . Here, the communication module 120 is configured to perform data communication with the radon service management server 200 by measuring the radon concentration measured by the radon measurement module 110. In addition to the domestic LTE module through expansion of the communication mode module, And can be implemented to provide versatility and scalability. In other words, it can be understood that the communication module 120 is composed of a module capable of being detachably attached to a module of a new communication system to be extended.

In addition, the communication type radon sensor 100 may further include a wall-hanging case main body 130 installed on a wall surface of a specific place for measuring the radon concentration. The wall mount case body 130 may be formed of any one of a square shape, a circular plate shape, and a straight shape having a radon measurement module 110 and a communication module 120 accommodated therein. The wall-mounted case body 130 has a wall-type case structure for installing the communication type radon sensor 100 on the wall surface of a specific place for measuring the radon concentration. The wall-mounted case main body 130 forms a through- It is easy to install and maintain without being constrained by the required installation site, so that it can cope with and utilize the demands of various customers' mounting issues. 6A shows an example of the configuration of a wall-hanging case body 130 having a rectangular shape. FIG. 6B shows an example of the configuration of a wall-hanging case body 130 having a circular plate shape. (C) shows an example configuration of the wall-mounting case body 130 having a straight shape. Further, each of the wall-mounted case bodies 130 can be installed on a wall surface of a specific place, and it can be understood that the wall-mounted case body 130 can be attached or installed using an unshown adhesive member or by screwing.

The radon service management server 200 receives and monitors the radon concentrations transmitted from the communication type radon sensors 100 through the wired or wireless communication in real time and outputs the received radon concentrations to the corresponding database 201 area And the like. The radon service management server 200 stores and manages the measured values of the radon concentration at specific locations provided from the communication type radon sensors 100 in the area of the corresponding database 201 and displays the evaluated risk on a monitoring screen . In addition, the radon service management server 200 provides radon statistics and graphs for each communication type radon sensor 100 using measurement values of radon concentration, implementation of measurement status by sensors, and automatic measurement log and report output function You may.

The user device 300 is connected to the radon service management server 200 via a communication network and is configured to receive a measured value of radon concentration in a predetermined radon measurement area. The user device 300 is an administrator terminal of a specific area in which the communication type radon sensor 100 is installed in a specific place in a wall form. The user terminal 300 is connected to the radon service management server 200 through an APP linkage or a web linkage A personal computer (PC) connected via a communication network, a notebook, and a smart device.

The radon monitoring service system 10 utilizing the app and web according to an embodiment of the present invention includes a communication type radon sensor 100 and a radon service management server 200 as a user's home- May be used individually or in the form of a service provider using a cloud server of a communication company.

As described above, the radon monitoring service system utilizing the app and the web according to the embodiment of the present invention measures the radon concentration from the communication type radon sensor installed at a specific place, And real-time management of the radon concentration information measured by a specific place installed and a user or a user of the communication radon sensor can be provided by providing the collected radon concentration information to the user or the administrator of the installation area of the communication type radon sensor. Allowing administrators to effectively provide radon concentration information measured through the app or the web. In addition, a communication type radon sensor is constituted, and a conventional linear ionization chamber is constituted by a slip type rectangular chamber type and a radon meter probe antenna is also constituted by a lattice type high sensitivity antenna corresponding to a slip type square chamber type, It is possible to improve the sensitivity of the radon measurement by applying the / N circuit and ensure the scalability of the communication through the connection connection between the radon measurement module and the communication module. Particularly, since the communication type radon sensor is accommodated in the wall-mounted type wall case body accommodated in the radon measurement module and the communication module, the settlement issue, which is a customer requirement, is solved and utilized, It is possible to improve the ease of installation and management that minimizes constraints, and by applying various communication methods that can link user devices with apps or the Web, radon measurement data communication with various external devices .

The present invention may be embodied in many other specific forms without departing from the spirit or essential characteristics and scope of the invention.

10: Radon monitoring service system according to one embodiment of the present invention
100: Communication type radon sensor
110: Radon measurement module
111: ionization chamber
112: Radon meter probe antenna
113: Signal processing circuit
114:
115: Power supply
116: Communication connection
120: Communication module
130: Wall case body
200: Radon service management server
201: Database (DB)
300: User device

Claims (8)

As a radon monitoring service system 10 utilizing an app (APP) and a web (WEB)
And detecting the alpha particle ions generated at the occurrence of alpha decay in the radon gas contained in the air introduced into the ionization chamber 111, A radon measurement module 110 for measuring the radon concentration through noise removal and amplification and a pulse readout process for an external signal with respect to an external signal and a radon measurement module 110 connected to the radon measurement module 110, A communication type radon sensor (100) including a communication module (120) for transmitting a measured radon concentration; And
A radon service management server for receiving and monitoring the radon concentrations transmitted from the communication type radon sensors 100 in real time via wired or wireless communication and storing the received radon concentrations in a corresponding database 201 area, (200)
The radon measurement module 110 of the communication type radon sensor 100 includes:
An ionization chamber 111 in which air is smoothly circulated and a bias power source is applied to form an electric field therein; an ionization chamber 111 disposed in the ionization chamber 111 for generating an alpha decay in the radon gas in the ionization chamber 111; A radon meter probe antenna 112 for detecting alpha particle ions which are detected by the radon meter probe 112 and a signal processing unit for performing noise removal on an external signal and pre- A control unit 114 for generating valid data by reading the pulses output after the noise removal and amplification preprocessing process is performed from the signal processing circuit unit 113 and calculating and outputting the corresponding radon concentration, A power supply unit 115 for supplying bias power to the ionization chamber 111 and driving power of the radon measurement module 110, And a communication connection unit (116) connected to the module (120)
The radon measurement module 110 may be configured to measure,
The ionization chamber 111 is configured as a slip type square chamber and the radon meter probe antenna 112 is configured as a lattice type high sensitivity antenna arranged in correspondence with the slip type rectangular chamber shape of the ionization chamber 111 A direct current voltage of 25 to 50 volts is applied to the surface of the ionization chamber 111 as a bias power source,
The communication module (120)
At least one communication method connected to the communication connection unit 116 of the radon measurement module 110 and including LTE communication, USB, and Bluetooth capable of data communication with the radon service management server 200, It is composed of a module capable of attaching and detaching a module of a new communication type which is extended to provide general versatility and expandability through combination with an overseas communication module as well as a domestic LTE module through extension of a communication mode module,
The radon monitoring service system (10)
Further comprising a user device (300) connected to the radon service management server (200) via a communication network and capable of receiving a measured value of radon concentration in a preset radon measurement area, wherein the user device 300 is an administrator terminal of a specific area in which the communication type radon sensor 100 is installed and is a personal computer connected to the radon service management server 200 through an APP or an Internet (PC), a notebook, and a smart device,
The communication type radon sensor 100 includes:
The wall mount case main body 130 further includes a wall mount type main body 130 mounted on a wall of a specific place for measuring the radon concentration and the wall mount case main body 130 includes the radon measurement module 110 and the communication module 120, A disk-like shape, and a straight-line-shaped case,
The wall-mounted case body (130)
A plurality of through holes are formed in the outside of the case, through which external air can flow,
The radon service management server (200)
The measured radon concentration values for specific locations provided from the communication type radon sensors 100 are stored and managed in the corresponding database 201 in a time domain and displayed on a monitoring screen to provide an evaluated risk value, Providing radon statistics and graphs for each of the communication type radon sensors 100 using the measured values, implementing the measurement status of each sensor, and automatically outputting measurement logs and reports,
The radon monitoring service system (10)
The communication type radon sensor (100) and the radon service management server (200) are provided in a user's home-built type so that they can be used individually or in the form of a service provider using a communication company cloud server. Radon monitoring service system utilizing app and web. delete delete delete delete delete delete delete

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