KR20220102070A - System for monitoring radiation exposure using appararus of skin attachment type for measuring radiation - Google Patents

Abstract

The present invention relates to a radiation exposure monitoring system using a skin-attached radiation measurement device, which comprises: a radiation measurement device configured in a patch type which can be attached to a body skin of a user and attached to the body skin of the user to measure a radiation exposure amount; and a monitoring device receiving measurement information related to the radiation exposure amount from the radiation measurement device and displaying information related to the radiation exposure amount of the user. Therefore, the present invention suggests possibility of real-time monitoring of the radiation exposure amount for each body portion of a person in a radiation work environment or a radiation medical environment.

Description

SYSTEM FOR MONITORING RADIATION EXPOSURE USING APPARARUS OF SKIN ATTACHMENT TYPE FOR MEASURING RADIATION

The present invention relates to a radiation exposure monitoring system using a skin-attached radiation measuring device, and more particularly, the possibility of monitoring the radiation exposure amount for each specific body part of a person in a radiation work environment or a radiation medical environment in real time. It relates to a radiation exposure monitoring system using a skin-attached radiation measuring device.

People exposed to radiation work environments (e.g. workers in nuclear power plants) or radiation medical environments (e.g. patients or medical staff in radio-diagnostic or therapeutic settings) may experience central nervous system damage, hematopoiesis, and hematopoiesis when radiation exposure exceeds certain limits. It causes damage such as tissue damage, leukemia, osteosarcoma, thyroid cancer, and death.

Accordingly, a dosimeter capable of measuring the radiation dose of a person exposed to a radiation environment has been developed.

The types of dosimeters include a thermo-luminescence dosimeter (TLD) that can monitor using the thermal fluorescence phenomenon that occurs when a crystalline material irradiated with radiation is heated, and luminescence generated when a laser is irradiated to irradiated aluminum oxide. There are optically stimulated luminescent dosimeters (OSLDs) that use phenomena, and pocket dosimeters (P.Ds) that use the principle of thin film detectors.

However, thermal fluorescence dosimeters and photostimulated luminescence dosimeters have limitations in measuring the radiation dose in real time because they evaluate the cumulative dose. there is a limit to

Republic of Korea Patent Publication No. 10-1574076 (Registered on November 27, 2015)

In solving the above problems, an object of the present invention is to use a skin-attached radiation measuring device that provides a possibility to monitor the radiation exposure amount for each specific body part of a person belonging to a radiation work environment or a radiation medical environment in real time. To provide a radiation exposure monitoring system.

A radiation exposure monitoring system using a skin-attached radiation measuring device according to an embodiment of the present invention includes: a radiation measuring device configured in the form of a patch that can be attached to the user's body skin and attached to the user's body skin to measure the radiation dose; and a monitoring device for receiving measurement information about the radiation exposure amount from the radiation measuring device and displaying information about the user's radiation exposure amount.

In this case, the radiation measuring device may include: a radiation sensitive unit configured to generate electric charges in response to radiation; a charge collection unit for storing charges generated by the radiation sensitive unit; a first control unit for measuring the amount of charge stored in the charge collection unit; and a first communication unit configured to transmit information on the amount of charge measured by the first control unit to the monitoring device.

In this case, the radiation-sensitive unit is configured to include perovskite, and is preferably configured in the form of a film.

In addition, it is preferable that the charge collection unit is composed of a supercapacitor, and is composed of a film form.

In this case, it is preferable that the first control unit is configured as a MOSFET-based circuitry module to be switched ON by charging the supercapacitor over a predetermined period.

On the other hand, it is preferable that the first communication unit is configured to transmit the information on the amount of charge measured by the first control unit to the monitoring device in a wireless communication method.

In this case, it is more preferable that the first communication unit is configured to transmit the information on the amount of charge measured by the first control unit to the monitoring device in a short-range wireless communication method.

On the other hand, the monitoring device, the second communication unit for receiving the measurement information about the radiation exposure amount from the radiation measuring device; a database unit for storing matching information on the radiation exposure amount corresponding to the measured charge amount, and storing measurement information on the radiation exposure amount received by the second communication unit; a display unit for displaying information on radiation exposure; And after extracting the user's radiation dose by using the matching information about the radiation dose of the database unit based on the measurement information about the radiation dose received by the second communication unit, the display unit to display information about the user's radiation dose It is preferable to include; a second control unit for controlling.

In this case, it is preferable that the second communication unit is configured to receive measurement information about the radiation exposure amount from the radiation measurement apparatus in a wireless communication method.

At this time, it is more preferable that the second communication unit is configured to receive measurement information about the radiation exposure amount from the radiation measuring device in an NFC wireless communication method.

On the other hand, the radiation measuring device is configured in the form of a flat or dome-shaped patch, it is preferable to be configured to be flexible.

In this case, the radiation measuring device has a structure surrounded by a primary coating body made of a hydrophobic material, and has a structure in which at least some surfaces of the primary coating body are wrapped with a secondary coating body made of a hydrophilic material or a hydrophobic material desirable.

As described above, the radiation exposure monitoring system using the skin-attached radiation measuring device according to the present invention suggests the possibility of monitoring the radiation exposure amount for each specific body part of a person belonging to a radiation work environment or a radiation medical environment in real time. do.

1 is a conceptual diagram for explaining a radiation exposure monitoring system using a skin-attached radiation measuring device according to an embodiment of the present invention.
2 is a block diagram of a radiation measuring apparatus.
3 is a conceptual diagram schematically expressing the shape of a radiation measuring apparatus.
4 is a block diagram of a monitoring device.

In the present invention, the accompanying drawings may be shown in exaggerated expression for the convenience of understanding the technology, as well as for differentiation and clarity from the prior art. In addition, the terms to be described below are terms defined in consideration of functions in the present invention, and may vary depending on the intention or custom of the operator or operator, so definitions of these terms should be made based on the technical content throughout this specification. will be. On the other hand, the embodiments are merely exemplary matters of the components presented in the claims of the present invention, do not limit the scope of the present invention, the scope of the rights should be interpreted based on the technical idea throughout the specification of the present invention. .

1 is a conceptual diagram for explaining a radiation exposure monitoring system using a skin-attached radiation measuring device according to an embodiment of the present invention, FIG. 2 is a block diagram of the radiation measuring device, and FIG. 3 is a form of the radiation measuring device It is a schematic conceptual diagram, and FIG. 4 is a block diagram of a monitoring device.

1 to 4 , a radiation exposure monitoring system using a skin-attached radiation measuring device according to an embodiment of the present invention includes a radiation measuring device 100 and a monitoring device 200 .

The radiation measuring apparatus 100 is configured in the form of a patch that can be attached to the user's body skin, and is attached to the user's body skin to measure the amount of radiation exposure.

In this case, 'user' may be a person exposed to a radiation work environment (e.g., a worker in a nuclear power plant) or a person belonging to a radiation medical environment (e.g. a patient or medical staff in a radiation diagnosis or treatment environment), and 'user's' 'Body' refers to a specific body part for monitoring radiation exposure, such as the user's gonads, eyeballs, and thyroid glands.

The radiation measuring apparatus 100 is preferably configured to include a radiation sensitive unit 110 , a charge collection unit 120 , a first control unit 130 , and a first communication unit 140 .

The radiation sensitive unit 110 is configured to generate electric charge in response to radiation.

At this time, the radiation-sensitive unit 110 is configured to include perovskite, it is preferable to be configured in the form of a film.

Perovskite is the name given to a newly discovered mineral in the Ural Mountains of Russia in 1839, named after Russian mineralogist Lev Perovsky in the 19th century. The chemical formula of perovskite is CaTiO ₃ , and furthermore, perovskite refers to all materials having the same structure as CaTiO ₃ .

Perovskite forms a compound crystal structure by combining metals, organic substances, and halogen groups (fluorine, chlorine, bromine, etc.), and has high light absorption and excellent charge transfer ability. generate In this case, the amount of moving charge is roughly proportional to the radiation dose, that is, the radiation exposure amount of the radiation sensitive unit 110 .

Accordingly, when the radiation sensitive unit 110 is irradiated with radiation in a radiation work environment or a radiation medical environment, since it is composed of perovskite, it generates mobile charges.

The charge collection unit 120 is configured to store charges (moving charges) generated in the radiation sensitive unit 110 .

At this time, the charge collection unit 120, is composed of a supercapacitor, it is preferable to be composed of a film form.

A supercapacitor is a component designed to be used for the purpose of a battery, as the performance of the capacitor (capacitor), especially the performance of the electric capacity, is strengthened.

The charge collection unit 120 serves to store the charge (moving charge) generated by the radiation sensitive unit 110 and supply power to all components in the radiation measuring device 100 configured as a circuit. will perform Accordingly, an effect of eliminating the need for a separate power supply source is also achieved.

The first control unit 130 is configured to measure the amount of charge stored in the charge collection unit 130 .

The first control unit 130, when the charge collection unit 120 is composed of a supercapacitor, it is preferable to be composed of a MOSFET-based circuitry module so as to be switched ON by charging the supercapacitor over a certain amount.

The first control unit 130 measures the amount of charge stored in the charge collection unit 130, and the first communication unit 140 monitors the measured charge amount information (ie, measurement information about the radiation exposure amount). to the device 200 .

The first communication unit 140 is configured to transmit information on the amount of charge measured by the first control unit 130 to the monitoring device 200 .

In this case, the first communication unit 140 is preferably configured to transmit the information on the amount of charge measured by the first control unit 130 to the monitoring device 200 in a wireless communication method.

In this case, the first communication unit 140 is more preferably configured to transmit the information on the amount of charge measured by the first control unit 130 to the monitoring device 200 in a short-range wireless communication method. Such a wireless communication method may be a Wi-Fi method, a Zigbee method, a Z-Wave method, a Bluetooth method, a near field communication (NFC) method, or the like.

In particular, it is more preferable that the first communication unit 140 is configured to transmit the information on the amount of charge measured by the first control unit 130 to the monitoring device 200 in an NFC wireless communication method. The NFC wireless method is a contactless wireless communication method that can exchange data at a short distance within about 10 cm using a frequency of 13.56 MHz band, and has the advantage of not requiring a separate power supply, and the user has the monitoring device 200 In the case of a user terminal (smartphone, etc.) that can do this, the monitoring device 200 is brought into close contact with the radiation measuring device 100 so that the current radiation exposure amount of the corresponding body part can be monitored in real time. In addition, in a similar manner, a specific observer (radiotherapy medical staff) may be used to measure the radiation dose of a body part of a user (radiotherapy patient) in real time.

On the other hand, the radiation measuring device 100, each component may be manufactured as an integrated circuit of a circuitization module, in particular, the radiation sensitive unit 110 and the charge collection unit 120 may be configured in the form of a film. Therefore, due to these characteristics, it is preferable that the overall flat type (FIG. In this case, the flat patch form is advantageous when attached to the skin for each specific body part, such as the user's gonad, thyroid, and the like, and the domed patch form is advantageous when attached to the user's eyeball.

In this case, the radiation measuring apparatus 100 may be configured to have a structure surrounded by a primary coating material made of a hydrophobic material (eg, silicone material) having excellent waterproof properties. Furthermore, the radiation measuring device 100 has a structure in which at least a portion of the primary coating body (preferably, the contact surface with the user's skin) is wrapped with a secondary coating made of a hydrophilic material or a hydrophobic material. more preferably. The secondary coating body serves to protect the primary coating body, and in particular, when it is composed of a hydrophilic material (eg, polymacon material, hippocampal material, etc.), it is comfortable to wear when in contact with the user's body skin (eg, eyeball) will improve That is, the radiation measuring device 100 may be manufactured in a form in which each component is molded inside the primary coating body made of a silicone material, and in this case, the feeling of attachment or wearing comfort when attached to the user's body skin In order to improve it, it may be manufactured by coating the surface of the side that is attached to the body skin with a secondary coating body made of a material including at least one of a polymacon material and a hippocampal material.

The monitoring apparatus 200 is configured to receive measurement information about the radiation exposure amount from the radiation measurement apparatus 100 and display information about the user's radiation exposure amount.

In this case, the monitoring device 200 may be a user's portable terminal (smartphone, tablet, notebook) or a separate terminal (desktop, monitoring display device).

The monitoring device 200 is preferably configured to include a second communication unit 210 , a database unit 220 , a display unit 230 , and a second control unit 240 .

The second communication unit 210 is configured to receive measurement information about the radiation exposure amount from the radiation measurement apparatus 100 .

In this case, the second communication unit 210 is configured to receive measurement information about the radiation exposure amount (charge information measured by the first control unit 130) from the radiation measuring device 100 in a wireless communication method. it is preferable

In this case, the second communication unit 210 is preferably configured to receive the measurement information about the radiation exposure amount from the radiation measuring apparatus 100 in a short-range wireless communication method. Such a wireless communication method may be a Wi-Fi method, a Zigbee method, a Z-Wave method, a Bluetooth method, a NFC method, or the like.

In particular, it is more preferable that the second communication unit 210 is configured to receive measurement information about the radiation exposure amount from the radiation measuring device 100 in an NFC wireless communication method. The NFC wireless method is a contactless wireless communication method that can exchange data at a short distance within about 10 cm using a frequency of 13.56 MHz band, and has the advantage of not requiring a separate power supply, and as described above, the user can use the monitoring device In the case of a user terminal (smartphone, etc.) that 200 can carry, the monitoring device 200 can be brought into close contact with the radiation measuring device 100 to monitor the current radiation exposure amount of the corresponding body part in real time. there will be In addition, in a similar manner, a specific observer (radiotherapy medical staff) may be used to measure the radiation dose of a body part of a user (radiotherapy patient) in real time.

Meanwhile, the second communication unit 140 may be a user's portable terminal (smartphone, tablet, notebook) or a wireless communication module of a separate terminal (desktop, monitoring display device).

The database unit 220 stores matching information on the radiation exposure amount corresponding to the amount of charge measured by the first control unit 130 , and stores measurement information on the radiation exposure amount received by the second communication unit 210 . is a configuration that At this time, the database unit 220 stores matching information regarding the radiation exposure amount in consideration of the extent to which the moving charges collected and stored in the charge collection unit 120 in the radiation measurement device 100 are lost by being used for power supply. can be configured.

In this case, the database unit 220 may be a user's portable terminal (smartphone, tablet, notebook) or a storage module of a separate terminal (desktop, monitoring display device).

The display unit 230 is configured to display information about the radiation exposure amount.

In this case, the display unit 230 may be a user's portable terminal (smartphone, tablet, notebook) or a display module of a separate terminal (desktop, monitoring display device).

The second control unit 240, the second communication unit 210, based on the measurement information about the radiation dose received by the first control unit 130 (charge information measured by the first control unit 130), the radiation of the database unit 230 After extracting the radiation exposure amount of the user by using the matching information on the exposure amount, the display unit 230 is configured to control to display the information on the radiation exposure amount of the user. In this case, the second control unit 240 extracts the currently measured radiation exposure amount information and calculates the total information of the radiation exposure amount accumulated for a specific time, so that the display unit 230 causes the user's radiation exposure amount information may be configured to control to display. The second control unit 240 may be implemented as an app or software.

As described above, the radiation exposure monitoring system using the skin-attached radiation measuring device according to the present invention according to the present invention can monitor the radiation exposure amount for each specific body part of a person belonging to a radiation work environment or a radiation medical environment in real time. present the possibilities

As described above, the present invention has been described with reference to the embodiment shown in the drawings, but this is merely exemplary, and various modifications and equivalent other embodiments are possible based on common knowledge in the field to which the art pertains. should understand Therefore, the true technical protection scope of the present invention depends on the claims to be described below, and should be determined based on the specific content of the above-described invention.

The present invention relates to a radiation exposure monitoring system using a skin-attached radiation measurement device, and can be used in industrial fields related to radiation measurement.

100: radiation measuring device
110: radiation sensitive unit
120: charge collection unit
130: first control unit
140: first communication unit
200: monitoring device
210: second communication unit
220: second control unit
230: display unit
240: database unit

Claims (12)

a radiation measuring device configured in the form of a patch attachable to the user's body skin and attached to the user's body skin to measure the radiation dose; and
a monitoring device for receiving measurement information on the radiation exposure amount from the radiation measurement device and displaying information on the radiation exposure amount of the user;
A radiation exposure monitoring system using a skin-attached radiation measuring device comprising a.
According to claim 1, wherein the radiation measuring device,
a radiation sensitive unit for generating electric charges in response to radiation;
a charge collection unit for storing charges generated by the radiation sensitive unit;
a first control unit for measuring the amount of charge stored in the charge collection unit; and
a first communication unit for transmitting information on the amount of charge measured by the first control unit to the monitoring device;
Radiation exposure monitoring system using a skin-attached radiation measuring device, characterized in that it comprises a.
According to claim 2, wherein the radiation-sensitive unit,
A radiation exposure monitoring system using a skin-attached radiation measuring device, characterized in that it comprises perovskite and is configured in a film form.
The method of claim 2, wherein the charge collection unit,
A radiation exposure monitoring system using a skin-attached radiation measuring device, characterized in that it is composed of a supercapacitor and is composed of a film.
According to claim 4, wherein the first control unit,
A radiation exposure monitoring system using a skin-attached radiation measuring device, characterized in that it is composed of a MOSFET-based circuitry module to be switched ON by charging the supercapacitor over a certain period.
According to claim 2, wherein the first communication unit,
Radiation exposure monitoring system using a skin-attached radiation measuring device, characterized in that configured to transmit the information on the amount of charge measured by the first control unit to the monitoring device in a wireless communication method.
The method of claim 6, wherein the first communication unit,
Radiation exposure monitoring system using a skin-attached radiation measuring device, characterized in that configured to transmit the information on the amount of charge measured by the first control unit to the monitoring device in an NFC wireless communication method.
According to claim 2, wherein the monitoring device,
a second communication unit for receiving measurement information on radiation exposure from the radiation measuring device;
a database unit for storing matching information on the radiation exposure amount corresponding to the measured charge amount, and storing measurement information on the radiation exposure amount received by the second communication unit;
a display unit for displaying information on radiation exposure; and
After extracting the radiation exposure amount of the user by using the matching information on the radiation exposure amount of the database unit based on the measurement information on the radiation exposure amount received by the second communication unit, the display unit controls to display the information about the radiation exposure amount of the user a second control unit;
Radiation exposure monitoring system using a skin-attached radiation measuring device, characterized in that it comprises a.
The method of claim 8, wherein the second communication unit,
A radiation exposure monitoring system using a skin-attached radiation measuring device, characterized in that it is configured to receive measurement information on a radiation dose in a wireless communication manner from the radiation measuring device.
The method of claim 9, wherein the second communication unit,
Radiation exposure monitoring system using a skin-attached radiation measuring device, characterized in that it is configured to receive measurement information about the radiation dose in a short-range wireless communication method from the radiation measuring device.
According to claim 1, wherein the radiation measuring device,
A radiation exposure monitoring system using a skin-attached radiation measuring device, characterized in that it is configured in a flat or dome-type patch shape and is configured to be flexible.
The method of claim 11, wherein the radiation measuring device,
A skin-attached radiation measuring device, characterized in that it has a structure surrounded by a primary coating body made of a hydrophobic material, and has a structure in which at least some surfaces of the primary coating body are wrapped with a secondary coating body made of a hydrophilic material or a hydrophobic material Radiation exposure monitoring system using

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