KR20150000709A - Remote controllable atomated external defibrillator and method of controlling the same - Google Patents

Abstract

The present invention relates to a remote control-type automated external defibrillator and a control method thereof. The remote control-type automated external defibrillator comprises: an automated external defibrillator storage apparatus which comprises a communication unit to receive measurement information including the biosignal of the human body and an infrared transmitting and receiving unit, generates a wake-up signal in the case of receiving the measurement information, transmitting the wake-up signal through the infrared transmitting and receiving unit, generates a control signal to control at least one function among an alarming function and an information providing function, and transmits the control signal through the infrared transmitting and receiving unit; and an automated external defibrillator body which is stored to be detachable in the automated external defibrillator storage apparatus, changes from a sleep mode to a standby mode in the case of receiving the wake-up signal when stored in the automated external defibrillator storage apparatus, receives the control signal, and performs the relevant function. Accordingly, an automated external defibrillator (AED) is allowed to operate in a sleep mode when the AED is in a storage state, and the mode of the AED is allowed to automatically change into a standby mode when an emergency occurs. Meanwhile, the AED allows an emergency to be automatically reported when the emergency occurs, thereby allowing a person to react quickly to the emergency.

Description

Technical Field [0001] The present invention relates to a remotely managed automatic defibrillator and a control method thereof,

The present invention relates to a remotely managed automatic defibrillator and a control method thereof. More particularly, the present invention relates to a remotely managed automatic defibrillator and a control method thereof. More particularly, Mode automatic defibrillator and a control method thereof, which are capable of quickly responding to an emergency situation by automatically reporting an emergency situation when an emergency occurs.

Many of the heart attack patients die from symptoms during sleep at home. A remote controlled automatic defibrillator has been proposed in which a sensor is attached to the patient's body, the patient's information measured through the sensor is measured through the terminal, and the AED sounds an alarm when an abnormality occurs. When an alarm occurs in the AED, people around the patient are aware of the abnormal condition of the patient and can promptly respond to the emergency, thereby increasing the possibility of patient's revival.

In order to perform these functions, the AED and associated equipment must remain in operation at all times. However, in the case of AEDs that supply power to the battery, the available power is limited, and a large amount of power is required for defibrillation shock. Therefore, if the battery power is insufficient, the AED may not be able to perform its function during an emergency shock shock.

Therefore, there is a need for a way to minimize the power consumption of the AED in order to be able to promptly inform the emergency situation through the AED and to operate smoothly in the emergency situation.

Korean Patent Laid-Open No. 10-2009-0092445: Emergency rescue system associated with remotely managed defibrillator and apparatus and method therefor

Disclosure of Invention Technical Problem [8] The present invention has been conceived to solve the above-mentioned problems, and it is an object of the present invention to provide a system and a method for operating a sleep mode when an AED is stored, The present invention provides a remotely managed automatic defibrillator and a method of controlling the same.

According to an aspect of the present invention, there is provided a communication system including a communication unit for receiving measurement information including a human body's bio-signal, an infrared transmission / reception unit, and a wake- An automatic defibrillator storage device for generating a control signal for controlling at least one of an alarm function and an information providing function and transmitting the generated control signal to the infrared transceiver; And a controller which is detachably stored in the automatic defibrillator storage device and is switched from a sleep mode to a standby mode when the wake-up signal is received while being stored in the automatic defibrillator storage device, receives the control signal, And an automatic defibrillator main body for performing an automatic defibrillator operation.

Here, the automatic defibrillator storage device may further include an infrared ray receiving unit for receiving a departure monitor signal from the infrared ray transmitting / receiving unit when the automatic defibrillator main body is in a detached state; The controller may determine that the automatic defibrillator main body is detached and in use when the departure monitor signal is received in the infrared receiver.

The control unit may request the terminal providing the measurement information via the communication unit to report an emergency situation when the departure monitor signal is received.

On the other hand, the automatic defibrillator storage device further includes a magnet; The automatic defibrillator main body includes a magnetic field sensing unit for sensing a magnetic force of the magnet and an automatic defibrillator main body for determining that the automatic defibrillator main body is in a state of being detached when the magnetic force is not sensed through the magnetic field sensing unit And a control unit.

Here, the control unit of the automatic defibrillator main body may output a pre-stored automatic defibrillator usage guidance message if it is determined that the automatic defibrillator main body is deviated from the automatic defibrillator storage device.

According to another aspect of the present invention, there is provided a remote control type automatic defibrillator control method including an automatic defibrillator storage device and an automatic defibrillator main body detachably stored in the automatic defibrillator storage device, (A) receiving the measurement information including the biological signal of the human body in the automatic defibrillator storage device; (B) generating the wake-up signal by the automatic defibrillator storage device and transmitting the wake-up signal through the infrared transmission / reception unit; (C) the automatic defibrillator main body receives the wake-up signal; And (D) switching the automatic defibrillator main body, which has received the wake-up signal, from the sleep mode to the standby mode.

Generating a control signal for controlling at least one of the alarm function and the information providing function by the automatic defibrillator storage device after the step (D), and transmitting the generated control signal to the infrared transceiver; And the automatic defibrillator main body may receive the control signal and execute the corresponding function.

Receiving, by the automatic defibrillator storage device, the departure monitor signal transmitted from the infrared transmitter / receiver through the infrared receiver; And when the departure monitoring signal is received, the automatic defibrillator storage device requests the terminal providing the measurement information through the communication unit to report an emergency situation.

In addition, the automatic defibrillator main body may detect whether or not the automatic defibrillator storage device is detached. And outputting the pre-stored automatic defibrillator usage guidance message if the automatic defibrillator main unit determines that the automatic defibrillator main body is detached from the automatic defibrillator storage device.

Here, the step of detecting whether or not the automatic defibrillator main body has released the automatic defibrillator storage device may include the step of the magnetic defibrillator body sensing the magnetic force of the magnet installed in the automatic defibrillator storage device.

As described above, the remote management type automatic defibrillator and the control method thereof according to the present invention operate in the sleep mode when the AED is in the stored state and automatically switch the mode of the AED to the standby mode when an emergency occurs, There is an effect of minimizing.

In addition, the remote management type automatic defibrillator and the control method of the present invention can generate an alarm or transmit related information when an emergency occurs, and report an emergency situation to an emergency agency when the AED changed into the standby mode And to enable efficient emergency response.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a diagram showing a network connection state of a remote management type automatic defibrillator according to an embodiment of the present invention; FIG.
2 is a block diagram of a remote management type automatic defibrillator according to an embodiment of the present invention.
3 is a flowchart of a remote management type automatic defibrillator control process according to an embodiment of the present invention.
FIGS. 4 and 5 are diagrams illustrating signal transmission / reception states between the AED main body and the AED storage device according to the embodiment of the present invention
6 is a diagram showing a mode switching signal of the remote management type automatic defibrillator according to the embodiment of the present invention

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following description with reference to the accompanying drawings, the same or corresponding components will be denoted by the same reference numerals, and redundant description thereof will be omitted.

1 is a network connection diagram of a remote managed automatic defibrillator (AED) according to an embodiment of the present invention.

1, the remote management type automatic defibrillator includes a living body signal measuring sensor 10 for sensing and transmitting a living body's body signal, a living body signal managing terminal 100 for receiving a living body signal, An AED storage device 200 capable of communicating with the AED storage device 100 and an AED main body 300 stored in the AED storage device 200.

The bio-signal measurement sensor 10 measures bio-signals of the human body to generate measurement information, and transmits the generated measurement information to the bio-signal management terminal 100. The bio-signal measurement sensor 10 can measure an electrocardiogram, a body temperature, a pulse, and the like. The bio-signal measurement sensor 10 can transmit the measurement information to the measurement information by a wireless communication method or a power line communication (PLC) method.

The bio-signal management terminal 100 transmits the measurement information received from the bio-signal measurement sensor 10 to the AED storage device 200. The bio-signal management terminal 100 may be a portable terminal of a person to be measured or a portable terminal of a user located in the vicinity of the measurement target, for example, a portable terminal such as a family, doctor, nurse or the like.

The AED storage device 200 and the AED main body 300 transmit and receive signals including the infrared transmission / reception units 210 and 310, respectively. The AED storage device 200 may be provided in the form of a storage box or a cradle as an apparatus for managing and storing the AED main body 300. The AED storage device 200 transmits a wake up signal to the AED main body 300 through the infrared transmitting and receiving part 210 and transmits the wake up signal to the AED main body 300 Or a control signal capable of controlling the information transmission. The AED storage device 200 can sense the detachment of the AED main body 300 from the AED storage device 200 through the infrared transmission and reception part 210. When the AED main body 300 senses the detachment of the AED main body 300, 300). ≪ / RTI > The AED storage device 200 regularly checks whether there is an abnormality in the driving device of the AED main body 300 and inspects the battery, and informs the administrator terminal when an abnormality occurs.

The AED main body 300 is a device for performing cardiopulmonary resuscitation (CPR), and can automatically apply an electric shock by checking the cardiac condition of a patient. The AED main body 300 is taken out of the AED storage device 200 and used by the AED main body 300 to sense the magnets 220 of the AED storage device 200 through the magnetic field sensing part 320, 200). The AED main body 300 stored in the AED storage device 200 maintains the sleep mode in the normal state and switches to the standby mode state when the wake up signal is received from the AED storage device 200. The AED main body 300 in the standby mode can transmit an alarm or transmit information according to a control signal received from the AED storage device 200. [

When the bio-signal measurement sensor 10 in contact with the human body generates measurement information and transmits the measurement information to the bio-signal management terminal 100, the AED storage device 200 acquires measurement information from the bio-signal management terminal 100 And transmits the wake-up signal to the AED main body 300 through the infrared transmission / reception unit 210. [ The AED storage device 200 generates a control signal so that the AED main body 300 can perform an alarm or information transmission function after transmitting the wake-up signal, and transmits the generated control signal through the infrared transmission / reception unit 210 of the AED.

When the wakeup signal is received by the infrared transmission / reception unit 310, the AED main body 300 is switched from the sleep mode to the standby mode to activate the respective components. The AED main body 300 receives a control signal from the main AED device through the infrared transmission / reception unit 310 and performs an alarm or information transmission function.

Meanwhile, the AED storage device 200 includes an infrared transmitting / receiving unit 210 and a separate infrared receiving unit 230. When the AED main body 300 is mounted, a signal of the infrared transmitting / receiving part 210 of the AED storage device 200 is transmitted to the AED main body 300. When the AED main body 300 is detached, the infrared transmitting / Is transmitted to the infrared receiver 230 of the AED storage device 200. [ The AED storage device 200 can recognize whether or not the AED main body 300 has been detached. If it is determined that the AED main body 300 is detached, it is determined that an emergency situation has occurred and the biometric signal management terminal 100 Send a request to report to the emergency agency.

As described above, the remote management type automatic defibrillator according to the embodiment of the present invention operates in the sleep mode when the AED is in the stored state and automatically switches the mode of the AED to the standby mode when an emergency occurs, The system automatically reports the emergency situation so that the emergency situation can be responded quickly.

2 is a control block diagram of a remote management type automatic defibrillator according to an embodiment of the present invention.

2, the remotely controlled automatic defibrillator includes an AED storage device 200 and an AED main body 300.

The AED storage device 200 includes a communication unit 240, a control unit 250, a power supply unit 260, a magnet 220, an infrared transmission / reception unit 210 and an infrared reception unit 230.

The communication unit 240 transmits and receives data to and from the biological signal management terminal 100. It is possible to receive measurement information of the biological signal management terminal 100 through the communication unit 240 or to request notification of an emergency situation.

The infrared transmitting / receiving unit 210 transmits a wake-up signal to the AED main body 300 and transmits a control signal for controlling the alarm or information transmission function. The infrared transmitting and receiving unit 210 is installed at a position where the infrared transmitting and receiving unit 310 of the AED main body 300 mounted on the AED storage device 200 can transmit and receive.

The infrared receiving unit 230 receives the signal of the infrared transmitting / receiving unit 210 when the AED main body 300 is detached from the AED storage device 200. The infrared ray receiving unit 230 is installed at a position capable of receiving the signal of the infrared ray transmitting / receiving unit 210 installed in the AED storage device 200.

The control unit 250 generates a wake-up signal when the measurement information is received through the communication unit 240 and transmits a wake-up signal to the AED main body 300 through the infrared transmission / reception unit 210. [ Thereafter, the control unit 250 generates a control signal for controlling the alarm function or the information transmission function of the AED main body 300 and transmits the control signal to the AED main body 300 through the infrared transmission / reception unit 210.

The control unit 250 determines that the AED main body 300 is disconnected when a signal transmitted from the infrared transmitting / receiving unit 210 is received by the infrared receiving unit 230. [ The control unit 250 determines that an emergency occurs in which the AED 300 is used and transmits a notification request to the biological signal management terminal 100 through the communication unit 240 so that the biological signal management terminal 100 Report to the emergency agency.

The magnet 220 corresponds to the magnetic field sensing unit 320 installed in the AED main body 300 and is provided to detect a deviation from the AED storage device 200 on the AED main body 300 side.

The power supply unit 260 supplies power for driving the remotely managed automatic defibrillator.

The AED body 300 includes an infrared transmission / reception unit 310, a magnetic field sensing unit 320, a speaker 330, and a control unit 340.

The infrared transmission / reception unit 310 receives a wakeup signal from the AED storage device 200 and receives a control signal for controlling an alarm or information transmission function. Receiving unit 310 of the AED main body 300 is installed at a position where the infrared transmitting and receiving unit 210 of the AED storage device 200 can transmit and receive.

The magnetic field sensing unit 320 senses the magnetic field of the magnet 220 mounted on the AED storage device 200 and transmits the sensing result to the controller 340. If the magnetic field is not detected as a result of the detection by the magnetic field sensing unit 320, the controller may determine that the AED 300 is detached from the AED storage 200, and guide the AED usage method.

The speaker 330 outputs an audio signal such as an alarm or a guidance voice under the control of the control unit 340.

The control unit 340 is activated when the wake-up signal is received from the infrared transmitting / receiving unit 310 and operates in the standby mode. In the standby mode, the control unit 340 activates the respective components and generates alarms or transmits requested data through the speaker 330 according to the control signals received by the infrared transmission / reception unit 310.

FIG. 3 is a control flowchart of a remotely managed automatic defibrillator according to an embodiment of the present invention, illustrating a control flow of the controller 250 of the AED storage device 200.

The control unit 250 of the AED storage device 200 receives the measurement information from the bio-signal management terminal 100 through the communication unit 240 (S110).

When the measurement information is received, the control unit 250 generates a wake-up signal and transmits a wake-up signal to the AED main body 300 via the infrared transmitting / receiving unit 210. Then, And transmits the control signal to the AED main body 300 through the infrared transmission / reception unit 210 (S120).

The control unit 250 of the AED storage device 200 determines that the AED main body 300 is detached when the signal transmitted from the infrared transmission and reception unit 210 is received by the infrared reception unit 230 at step S130, .

If it is determined that the AED main body 300 is detached, the controller 250 requests the bio-signal management terminal 100 to report an emergency state through the communication unit 240 (S150)

4 and 5 are signal transmission / reception state diagrams between the AED main body 300 and the AED storage device 200 according to the embodiment of the present invention.

As shown in FIGS. 4 and 5, the AED storage device 200 and the AED main body 300 transmit and receive signals including the infrared transmission / reception units 210 and 310, respectively.

The AED storage device 200 can detect that the AED main body 300 is separated from the AED storage device 200 through the infrared transmission / reception part 210. The infrared transmitting and receiving unit 210 of the AED storage device 200 is installed at a position where the infrared transmitting and receiving unit 310 of the AED body 300 mounted on the AED storage device 200 can transmit and receive. The infrared receiver 230 of the AED storage device 200 receives the signal of the infrared transmission / reception unit 210 when the AED 300 is detached from the AED storage device 200. The infrared ray receiving unit 230 is installed at a position capable of receiving the signal of the infrared ray transmitting / receiving unit 210 installed in the AED storage device 200.

The control unit 250 of the AED storage device 200 determines that the AED main body 300 is disconnected when a signal transmitted from the infrared transmitting and receiving unit 210 is received by the infrared receiving unit 230. [ When it is determined that the AED main body 300 has been removed, the controller 250 determines that an emergency situation exists in which the AED main body 300 is used, and transmits a report request to the biometric signal management terminal 100 through the communication unit 240 , Thereby causing the bio-signal management terminal 100 to notify the emergency institution.

The AED main body 300 is taken out from the AED storage device 200 and used by the AED main body 300 to sense the magnets 220 of the AED storage device 200 through the magnetic field sensing part 320, It is possible to recognize whether or not the device 200 is detached. The magnetic field sensing unit 320 senses the magnetic field of the magnet 220 mounted on the AED storage device 200 and transmits the sensing result to the controller 340. If the magnetic field is not detected as a result of the detection by the magnetic field sensing unit 320, the controller 340 determines that the AED 300 is detached from the AED storage 200, and can guide the AED usage method.

FIG. 6 is a mode switching signal diagram of a remote management type automatic defibrillator according to an exemplary embodiment of the present invention. FIG. 6 illustrates waveforms of an infrared signal transmitted from the AED storage device 200 to the AED 300 in each mode.

6, the infrared transmitting / receiving unit 210 of the AED storage device 200 receives a departure detection signal for detecting the departure of the AED main body 300 and a wake up signal for waking up the AED main body 300. [ Are output as different waveforms.

The AED main body 300 maintains the sleep mode when the signal for detecting the detachment is received by the infrared transmission / reception unit 310, and can be switched to the standby mode when the wakeup signal is received.

Thus, those skilled in the art will appreciate that the present invention may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. It is therefore to be understood that the embodiments described above are to be considered in all respects only as illustrative and not restrictive. The scope of the present invention is defined by the appended claims rather than the detailed description and all changes or modifications derived from the meaning and scope of the claims and their equivalents are to be construed as being included within the scope of the present invention do.

100: biological signal management terminal 200: AED storage device
210: infrared transmitting / receiving unit 220: magnet
230 infrared ray receiver 240 communication
250: control unit 260:
300: AED main body 310: Infrared transmission /
320: magnetic field sensing unit 330: speaker
340:

Claims (10)

An infrared transmitting / receiving unit for receiving measurement information including a living body's biological signal, and a controller for generating a wake-up signal upon receiving the measurement information, transmitting the wake-up signal through the infrared transmitting / receiving unit, and controlling at least one of an alarm function and an information providing function An automatic defibrillator storage device for generating a control signal to be transmitted to the infrared transmission / reception unit; And
Wherein the sleep mode is switched from a sleep mode to a standby mode when the wake-up signal is received while being stored in the automatic defibrillator retention device, receives the control signal, An automatic defibrillator main body;
A remotely managed automatic defibrillator, including.
The method according to claim 1,
Wherein the automatic defibrillator storage device comprises:
Further comprising an infrared receiver for receiving a departure monitor signal from the infrared transceiver when the automatic defibrillator main body is in a detached state;
Wherein the control unit determines that the automatic defibrillator main body is detached and in use when the departure monitor signal is received in the infrared receiver.
3. The method of claim 2,
Wherein,
And when the departure monitoring signal is received, requests the terminal providing the measurement information through the communication unit to report an emergency situation.
The method according to claim 1,
Wherein the automatic defibrillator storage device further comprises a magnet;
The automatic defibrillator main body includes a magnetic field sensing unit for sensing the magnetic force of the magnet and an automatic defibrillator main body for determining that the automatic defibrillator main body is in a state of being detached when the magnetic force is not sensed through the magnetic field sensing unit And a controller for controlling the automatic defibrillator.
5. The method of claim 4,
The control unit of the automatic defibrillator main body,
And outputs a pre-stored automatic defibrillator usage guidance message if it is determined that the defibrillator is deviated from the automatic defibrillator storage device.
A control method for remotely managed automatic defibrillator comprising an automatic defibrillator storage device and an automatic defibrillator main body detachably stored in the automatic defibrillator storage device,
(A) receiving the measurement information including the biological signal of the human body in the automatic defibrillator storage device;
(B) generating the wake-up signal by the automatic defibrillator storage device and transmitting the wake-up signal through the infrared transmission / reception unit;
(C) the automatic defibrillator main body receives the wake-up signal; And
(D) switching the automatic defibrillator main body, which has received the wake-up signal, from the sleep mode to the standby mode.
The method according to claim 6,
After the step (D)
Generating a control signal for controlling at least one of the alarm function and the information providing function of the automatic defibrillator storage device and transmitting the control signal to the infrared transceiver; And
Wherein the automatic defibrillator main body receives the control signal and executes the function of the automatic defibrillator main body.
The method according to claim 6,
The automatic defibrillator storage device receiving the departure monitor signal transmitted from the infrared transmitter / receiver through an infrared receiver; And
Further comprising the step of the automatic defibrillator storage device requesting the terminal providing the measurement information through the communication unit to report an emergency situation when the departure monitoring signal is received. Way.
The method according to claim 6,
Detecting whether or not the automatic defibrillator main body releases the automatic defibrillator storage device; And
Further comprising the step of: if the automatic defibrillator main body determines that the automatic defibrillator main body is detached from the automatic defibrillator storage device, outputting a pre-stored automatic defibrillator usage guidance message .
10. The method of claim 9,
Wherein the step of detecting whether the automatic defibrillator main body releases the automatic defibrillator storage device comprises:
Wherein the automatic defibrillator main body senses a magnetic force of a magnet installed in the automatic defibrillator storage device.

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