KR20220078018A - Digital healthcare platform system for providing safety management and emergency medical service for radiation workers - Google Patents

Abstract

The present invention is a digital health care platform system that provides safety management and emergency medical services for radiation workers, and a wearable device unit that measures the workers' biological signals and radiation dose, converts them into digital information, and transmits them through wireless communication , A worker terminal that generates health status information of workers based on the digital information on the biosignals and radiation dose and determines emergency medical conditions and notifies the workers to the workers, and the biosignals and radiation dose It consists of a medical management server that manages the health status of workers and provides emergency medical services based on digital information and database about By protecting it with a safety system, it is possible to provide safer and more reliable emergency medical support to workers.

Description

Digital healthcare platform system for providing safety management and emergency medical service for radiation workers}

The present invention is a digital health care that monitors the radiation dose (the amount of radiation the human body receives) and bio-signals of radiation workers working in a radiation environment such as a nuclear power plant, and provides safety management and emergency medical services to workers based on this. It relates to a platform, in particular, by using various types of wearable devices to collect radiation exposure dose and bio-signals and simultaneously transmit them in real time to the mobile terminal and management server of radiation workers through wireless communication. It relates to a customized digital healthcare platform system that can strengthen the safety of people and provide rapid emergency medical services.

Workers performing radiation-related tasks, such as radiation workers working in nuclear power plants, are receiving various safety and health management support to minimize radiation exposure.

A system for protecting and managing workers in relation to radiation exposure has been developed, and recently, a system applied with the Internet of Things (IoT) or wearable devices has also been proposed.

As an example, according to Korean Patent Application Laid-Open No. 10-2016-0015930, a database for accumulating and storing the ID, password, and exposure dose information of radiation workers is provided, and radiation exposure radiation dose information received from a portable electronic dosimeter A worker management system is proposed.

As another example, according to Korea Patent Registration No. 10-1574076, while monitoring so that workers performing radioactive material work can start or stop work by comparing and determining whether radiation safety equipment is worn on work clothes and wrists as prescribed We propose a safety and exposure management system for radiation workers that can transmit and manage various signals to workers by allowing them to start work only in a safe state.

On the other hand, the above-mentioned radiation workers may be exposed to general emergency medical situations such as falls, falls, explosions, suffocation, gas poisoning, cardiovascular disease, hypoglycemia, etc. in addition to radiation exposure.

However, in addition to radiation exposure accidents, the management system that can simultaneously respond to non-radiation general emergency medical situations is still insufficient. There are limits to what you can do.

Therefore, using IoT-based wearable devices and wireless communication technology, not only radiation exposure information of radiation workers, but also bio-signals such as pulse, oxygen saturation, electrocardiogram, body temperature, blood sugar, etc. are simultaneously measured, collected and analyzed. Based on this, it is necessary to develop a new healthcare platform system that can further strengthen the safety and emergency medical support of radiation workers.

KR 10-2016-0015930 A KR 10-1574076 B

The present invention is to solve the problems of safety and health management of radiation workers who work in a radiation environment. Based on a wireless wearable device, the radiation exposure information and bio-signals of workers are used at the same time to provide safety and emergency medical care for workers. This is to provide a new digital healthcare platform system that can further strengthen support for

In order to solve the above problems, the present invention is a digital health care platform system that provides safety management and emergency medical services for radiation workers working in a radiation environment, and is mounted or attached to the body of radiation workers, a wearable device unit including at least one wearable device that measures biosignals and radiation doses, converts them into digital information, and transmits them through wireless communication; A worker terminal unit for receiving the digital information on the biosignal and radiation dose from the wearable device unit, generating health status information of the worker based on this and determining the emergency medical condition, and notifying the worker; and a medical management server unit that receives digital information on the biosignal and radiation dose from the wearable device unit, manages the health status of workers based on this, and provides emergency medical services.

The medical management server unit collects and analyzes digital information on the biosignal and radiation dose for each individual worker and stores it in a database; generate health status information of the worker according to the collected and analyzed results and determine the emergency medical status of the worker; The health status information and the emergency medical condition may be notified to at least one of the worker terminal unit, the wearable device unit, the medical worker's portable terminal, and an external medical system connected to the medical management server unit.

In addition, the medical management server unit, when determining the emergency medical status of the worker, assigns a weight to each worker's biosignal based on the individual health status or medical history database of the worker, to determine whether the emergency medical condition is have.

In addition, the medical management server unit collects the measured radiation dose to calculate the accumulated radiation dose of each wearable device, and calculates the failure rate of the wearable device by collecting the failure occurrence period of each wearable device; predicting the lifespan of each wearable device based on the calculated cumulative radiation dose and failure rate; By transmitting the prediction result to the worker terminal unit, the worker may determine when to replace the wearable device.

The biosignal preferably includes at least one of a pulse, oxygen saturation, electrocardiogram, body temperature, and blood sugar.

The at least one wearable device of the wearable device unit may include: a bio-signal measuring module for measuring a bio-signal of a worker; an exposed radiation dose measuring module for measuring the exposed radiation dose; a signal processing module for amplifying the measured bio-signals and radiation doses and converting them into digital information; and a wireless communication module for wirelessly transmitting digital information about the biosignal and the radiation dose to the worker terminal unit and the medical management server unit.

The biosignal measurement module includes: a photoplethysmography (PPG) sensor for measuring the pulse and oxygen saturation of the worker; A thin film sensor that measures changes in heartbeat status, body temperature, and blood sugar of workers; an infrared proximity sensor that checks whether a worker wears a wearable device; And a motion monitoring sensor for detecting the motion of the worker; It may include at least one of.

The radiation dose measuring module may be one of a Geiger-Müller tube (GM-tube), a PIN photodiode, and a silicon photomultiplier.

In the wireless communication module, the wireless communication between the wearable device unit and the worker terminal unit uses Bluetooth communication, and the wireless communication between the worker terminal unit and the medical management server unit uses Wi-Fi communication. It is preferable to do

The wearable device unit, a wristband-type wearable device worn on the wrist of a worker; Safety helmet-type wearable device worn on the head of a worker; A skin-attachable wearable device attached to the skin of a worker; and at least one of a vest-type wearable device worn on the upper body of the worker.

According to the digital healthcare platform system of the present invention, the following effects can be expected.

First, it is possible to provide safer and more reliable medical support to radiation workers by double monitoring and real-time protection of the health status of radiation workers through mobile terminals and medical management servers.

Second, since the lifespan of the wearable device for monitoring the health status of radiation workers can be predicted and the replacement time can be determined, the reliability of the wearable device and system under the radiation environment can be increased.

Third, using short-distance wireless communication, it is possible to quickly and effectively provide safety and medical support to workers because it is possible to provide immediate medical response by collecting bio-signals and radiation doses of workers in real time.

Fourth, it is possible to quickly determine the emergency medical condition of the worker, and the result of this determination can be notified in real time not only to the worker's terminal and wearable device, but also to the terminal or external medical system of the field worker, in various environments. Comprehensive medical support for radiation workers can be implemented quickly.

Fifth, by utilizing big data that accumulates bio-signals and radiation dose information of workers, it is possible to predict emergency medical situations that may occur during work through an artificial intelligence algorithm, so it is possible to prevent safety accidents or reduce the scale of accidents. have.

1 schematically shows the configuration of a digital healthcare platform system according to an embodiment of the present invention.
2 schematically shows a detailed configuration of a wearable device applied to a digital healthcare platform system according to an embodiment of the present invention.
3 exemplarily shows various types of wearable devices applied to the digital healthcare platform system according to an embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings, an embodiment of the present invention will be described in detail. However, the present invention is not limited to the embodiments described herein, and may be implemented in various other forms. In addition, in order to clearly explain the present invention in the drawings, parts irrelevant to the description are omitted, and similar reference numerals are attached to similar parts throughout the specification.

Throughout the specification, when a part "includes" a certain element, it means that other elements may be further included, rather than excluding other elements, unless otherwise stated.

1 schematically shows the configuration of a digital healthcare platform system according to an embodiment of the present invention.

As shown in FIG. 1, the digital healthcare platform system of the present invention includes a wearable device unit 100 including at least one wearable device, a worker terminal unit 200 carried by a radiation worker, and a health condition of the worker. and a medical management server unit 300 that manages and provides emergency medical services.

First, the wearable device unit 100 is a wearable device that is mounted or attached to the body of a worker working in a radiation environment to measure the worker's bio-signals and radiation dose and convert it into digital information (100-1, 100-) 2, 100-3). In FIG. 1 , only two wearable device units 100 are illustrated and three wearable devices 100-1, 100-2, and 100-3 are illustrated, but the present invention is not limited thereto. It is preferable to be provided corresponding to the number of workers, and the wearable devices 100-1, 100-2, and 100-3 may be at least one.

Each of the wearable devices 100-1, 100-2, 100-3 of the wearable device unit 100 transmits digital information about the biosignal and radiation dose of the worker through wireless communication to the worker terminal unit ( 200) and the medical management server unit 300 .

As shown in FIG. 2 , each of the wearable devices 100-1, 100-2, and 100-3 includes a biosignal measurement module 110, an exposure radiation dose measurement module 120, a signal processing module 130, and a wireless It may be configured to include the communication module 140 . At this time, since it is not necessary for all the wearable devices 100-1, 100-2, and 100-3 to measure the radiation dose, the radiation dose measurement module 120 is provided only in at least one wearable device, and the rest of the wearable devices It may be omitted on the device.

The biosignal measurement module 110 measures the biosignal of the worker, and the biosignal may include a pulse, oxygen saturation, electrocardiogram, body temperature, blood sugar, and the like. Specifically, the biosignal measurement module 110, a photoplethysmograph (PPG) sensor that measures the pulse and oxygen saturation of the worker, a thin film sensor that measures the heartbeat state, body temperature, and blood sugar change of the worker, It may be configured to include an infrared proximity sensor to check whether the wearable device is worn, a motion detection sensor for detecting the movement of the worker (for arousal/syncope, fall, fall determination), and the like. In this case, the thin film sensor preferably uses a MEMS-based patch-type thin film sensor, and the motion detection sensor preferably uses an inertial measurement unit (IMU)-based sensor.

The exposure radiation dose measurement module 120 measures the radiation dose received by workers, and can be implemented using a Geiger-Müller tube (GM-tube), a PIN photodiode, a silicon photomultiplier, etc. have.

The signal processing module 130 amplifies the measured bio-signal and radiation dose, then converts it into a digital signal and digitizes it, and digital information on the bio-signal and radiation dose is generated by this signal processing.

The wireless communication module 140 wirelessly transmits digital information about biosignals and radiation dose to the worker terminal 200 and the medical management server 300, and is Bluetooth, Wi-Fi. Fi), it is preferable to use short-range wireless communication such as ZigBee, but is not necessarily limited thereto. In the case of high-risk facilities such as nuclear power plants, it is necessary to prevent malfunction of electronic equipment in the facility due to high-power radio waves. , a nuclear power plant customized design that has passed the Electromagnetic Compatibility) test should be considered.

In this embodiment, in consideration of the range in which wireless communication is possible, the wireless communication between the wearable device unit 100 and the worker terminal 200 uses Bluetooth communication, and the worker terminal 200 and the medical management server unit The wireless communication between 300 uses Wi-Fi communication, but is not limited thereto, and the wearable device unit 100, the worker terminal unit 200, and the medical management server unit 300 are all connected and used through a Wi-Fi communication network. Alternatively, another type of wireless communication method may be used.

The wearable device unit 100 may include various types of wearable devices. 3, the wristband type wearable device 100-1 worn on the wrist of the worker, the safety helmet type wearable device 100-2 worn on the head of the worker, attached to the skin of the worker It may be configured to include a skin-attached wearable device and a vest-type wearable device 100-3 worn on the upper body of the worker.

Next, the worker terminal 200 receives the digital information about the biosignal and the radiation dose from the wearable device unit 100, processes it, and notifies the worker and stores it. The worker terminal unit 200 may use a portable terminal (eg, a smartphone or tablet) that the worker may possess, and may include a software application for receiving and processing digital information.

The worker terminal 200 generates health status information of the worker based on the digital information about the biosignal and the radiation dose, and determines whether the body of the worker is in an emergency medical state, and displays the result in real time to the worker notify to Such notification may be notified using a screen display using the screen of the portable terminal or an alarm using a lamp or vibration function of the portable terminal.

In addition, the notification of the emergency medical condition is additionally installed with a separate alarm module (not shown) in the wearable device unit 100 , and the worker terminal unit 200 is connected to the wearable device unit 100 through the wearable device unit 100 . Notifications can also be made by activating the alarm module.

Next, the medical management server unit 300 receives digital information on biosignals and radiation dose from the wearable device unit 100 , and manages the health status of workers based on this information and provides emergency medical services do. The medical management server unit 300 may be installed, for example, in each nuclear power plant headquarters or integrated management organization.

The medical management server unit 300 collects and analyzes digital information on biosignals and radiation dose for each individual worker, stores it in a database, and generates health status information of the worker according to the collected and analyzed results, and also works Determine the emergency medical condition of the worker.

When the medical management server unit 300 determines the emergency medical status of the worker, weight is given to each worker's biosignal based on the worker's individual health status or medical history database to determine whether the emergency medical condition is desirable. For example, when a worker has a blood sugar-related history, a higher weight is given to the blood sugar measurement value among the bio-signals than other bio-signals, so that it can respond more sensitively to changes in blood sugar.

The health status information and emergency medical condition obtained as described above are provided to the worker terminal 200 through wireless communication so that the worker can check them.

At this time, the software application of the worker terminal unit 200 executes the generation of health status information and emergency medical status determination of the worker based on the digital information about the biosignal and radiation dose received in real time, while the medical management server In the unit 300, it is executed based on the accumulated big data collected, analyzed, and stored for each individual worker. That is, the medical management server unit 300 may generate more comprehensive and accurate health state information and determine the emergency medical state.

As described above, in the digital health care platform system according to the embodiment of the present invention, the worker terminal unit 200 and the medical management server unit 300 generate health status information of the worker double and determine the emergency medical condition. . The reason for the double monitoring and protection of workers in this way is that in a highly dangerous and complex environment such as a nuclear power plant, when a situation such as a malfunction of equipment occurs, fatal damage can occur. Because.

On the other hand, the notification of the radiation worker's health status information generation and emergency medical status determination is not only notified to the worker terminal 200, but also to the wearable device 100 using an alarm. . In addition, by notifying the external medical system 500 (eg, the management system of the contracting hospital) connected to the mobile terminal 400 or the medical management server unit 300 of the medical workers residing at the work site, comprehensive medical support This can be done very quickly.

Also, the medical management server unit 300 may predict the lifespan of each wearable device by using the radiation dose measured by the wearable device unit 100 . In a radiation environment, the possibility of deterioration of the electronic device is much higher than that of a normal case, and since the malfunction of the wearable device 100 due to the exposure of the electronic device causes fatal damage to the workers, the lifespan of the wearable device is predicted and replaced in a timely manner Being able to do it is very important.

The medical management server unit 300 of the present invention collects the previously measured radiation dose to calculate the cumulative radiation dose of each wearable device, and collects the failure occurrence period of each wearable device to calculate the failure rate of the wearable device. In addition, the lifespan of each wearable device is predicted from the cumulative radiation dose and the failure rate.

In order to increase the reliability of the failure rate and predicted lifespan of the wearable device, it is necessary to collect the radiation exposure dose and the failure cycle over a certain period of time, and through continuous collection, the predicted lifespan of the device can be continuously updated. If a large number of wearable devices are used in the field for a significant period of time, life prediction based on data collected from these wearable devices can guarantee considerable accuracy and reliability.

The life expectancy prediction result of the wearable device may be transmitted to the worker terminal 200 and used by the worker to determine when to replace the wearable device.

As described above, the digital healthcare platform system according to an embodiment of the present invention can reliably and effectively support the safety management and emergency medical care of radiation workers working in a radiation environment. The digital health care platform system of the present invention may be optimally applied to a radiation environment field such as a nuclear power plant, but is not limited thereto, and safety of workers in other fields such as medical care, production plants, architecture, construction, civil engineering, etc. It may be appropriately applied for management and emergency medical care.

Although the present invention has been described with reference to the above preferred embodiments and the accompanying drawings, other embodiments may be constructed within the spirit and scope of the present invention. Accordingly, the scope of the present invention is defined by the appended claims, and should not be construed as limited by the specific embodiments described herein.

100 wearable device
100-1, 100-2, 100-3 wearable devices
110 Bio-signal measurement module
120 Exposure radiation dose measurement module
130 signal processing module
140 wireless communication module
200 worker terminal section
300 Medical Management Server Department
400 medical worker terminals
500 External Medical Systems
[R&D project]
Task number: No. 2018-Technology-03
Client: Korea Hydro & Nuclear Power Co., Ltd.
Research project name: K-CLOUD external open call project
Research project name: Development of IoT-based healthcare platform for nuclear power plant worker safety and optimal on-site emergency medical care
Contribution rate: 1/1
Organized by: Southeast Area Atomic Energy Medical Institute
Research period: 2019. 06. 01 ~ 2021. 05. 31

Claims (10)

As a digital healthcare platform system that provides safety management and emergency medical services for radiation workers working in a radiation environment,
A wearable device unit including at least one wearable device that is mounted or attached to the body of a radiation worker, measures the worker's bio-signals and radiation dose, converts it into digital information, and transmits it through wireless communication;
A worker terminal unit for receiving the digital information on the biosignal and the radiation dose from the wearable device unit, generating health status information of the worker based on this, and determining the emergency medical condition, and notifying the worker; and
and a medical management server unit that receives digital information on the biosignal and radiation dose from the wearable device unit, manages the health status of workers based on this and provides emergency medical services. Digital healthcare platform system. The method of claim 1,
The medical management server unit,
Collect and analyze digital information on the biosignals and radiation dose for each individual worker and store it in a database,
According to the collected and analyzed results, the health status information of the worker is generated and the emergency medical status of the worker is determined,
Digital health care, characterized in that the health status information and emergency medical status are notified to at least one of the worker terminal unit, the wearable device unit, the medical worker's portable terminal, and an external medical system connected to the medical management server unit platform system. The method of claim 1,
The medical management server unit,
Digital healthcare platform system, characterized in that when determining the emergency medical status of the worker, weight is given to each worker's biosignal based on the individual health status or history database of the worker, and determining whether the worker is in emergency medical condition . The method of claim 1,
The medical management server unit,
Calculate the accumulated radiation dose of each wearable device by collecting the measured radiation dose, and calculate the failure rate of the wearable device by collecting the failure occurrence period of each wearable device,
Predicting the lifespan of each wearable device based on the calculated cumulative radiation dose and failure rate,
The digital healthcare platform system, characterized in that by transmitting the prediction result to the worker terminal unit, the worker can determine when to replace the wearable device. The method of claim 1,
The biosignal is
A digital healthcare platform system comprising at least one of pulse, oxygen saturation, electrocardiogram, body temperature, and blood sugar. The method of claim 1,
At least one wearable device of the wearable device unit,
a biosignal measurement module for measuring the biosignal of the worker;
an exposed radiation dose measuring module for measuring the exposed radiation dose;
a signal processing module for amplifying the measured bio-signals and radiation doses and converting them into digital information; and
A digital healthcare platform system comprising a; a wireless communication module for wirelessly transmitting digital information on the biosignal and radiation dose to the worker terminal and the medical management server. 7. The method of claim 6,
The biosignal measurement module,
a photoplethysmic pulse wave (PPG) sensor that measures the pulse and oxygen saturation of workers;
A thin film sensor that measures changes in heartbeat status, body temperature, and blood sugar of workers;
an infrared proximity sensor that checks whether a worker wears a wearable device; and
a motion monitoring sensor for detecting the motion of a worker; Digital healthcare platform system comprising at least one of. 7. The method of claim 6,
The exposure radiation dose measurement module,
A digital healthcare platform system, characterized in that it is one of a Geiger-Müller tube (GM-tube), a PIN photodiode, and a silicon photomultiplier. 7. The method of claim 6,
The wireless communication module,
Wireless communication between the wearable device unit and the worker terminal unit uses Bluetooth communication,
The digital healthcare platform system, characterized in that the wireless communication between the worker terminal unit and the medical management server unit uses Wi-Fi communication. The method of claim 1,
The wearable device unit,
a wristband-type wearable device worn on the wrist of a worker;
Safety helmet-type wearable device worn on the head of a worker;
A skin-attachable wearable device attached to the skin of a worker; and
A vest-type wearable device worn on the upper body of a worker; Digital healthcare platform system comprising at least one of.

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