KR101793735B1 - Smart defibrllators and operating method thereof - Google Patents

Abstract

The present invention relates to a smart defibrillator, and an operation method thereof. According to the present invention, the smart defibrillator comprises: a main control device controlling in response to an abnormal signal; a defibrillation band attached to the chest of a patient, and applying electric shocks through a defibrillation electrode using power supplied from the main control device upon control of the main control device; a smart terminal receiving a control signal of the main control device so as to transmit an emergency relief signal; and a smart band including a heartbeat sensor to measure heartbeat of the patient.

Description

[0001] SMART DEFIBRILLATOR AND OPERATING METHOD THEREOF [0002]

The present invention relates to a smart defibrillator and a method of operating the same.

A cardiac defibrillator is an emergency medical device that is used to automatically analyze the heart condition of a patient when the heart stops beating and the oxygen supply is stopped, and to restore function of the heart by delivering an electric shock as needed.

However, since such a cardiac defibrillator is very necessary, it is obligatory to install the cardiac defibrillator in a public period and a specific facility, but the use frequency is low in that it is used in an emergency such as a cardiac arrest.

In addition, the conventional cardiac defibrillator can not be used without the help of another person in the event of an emergency due to an accident in daily life, and it is difficult to request relief of the patient and emergency relief at the same time.

SUMMARY OF THE INVENTION The present invention has been conceived to solve the above-mentioned problems, and it is an object of the present invention to provide a smart control device for controlling a smart terminal to transmit an emergency relief signal when an abnormality signal of a patient is detected in a defibrillation band and a smart band, The patient is urged to apply a shock to cope with sudden abnormalities or accidents.

In the present invention, when an abnormality of a patient is detected, an emergency character is transmitted to a contact such as 119 through the smart terminal through the smart terminal, an emergency rescue signal is transmitted to the emergency relief destination together with the current position information, And to transmit the measured electrocardiographic information of the patient to enable quicker emergency structure.

In addition, the present invention provides a diabetic mode in which a climatic mode at the time of climbing a heart patient, an exercise mode at the time of exercise, a sleep mode at the time of sleep, etc. can be detected and a sudden unconscious state of the diabetic patient can be detected, We want to be able to deal with emergencies arising from accidents in daily life or cope with emergencies during travel.

In addition, the present invention can be set to a driving mode at the time of operation of a patient with heart disease, and can be applied to a patient suffering from heart disease, a patient suffering from angina pectoris, Such as a patient, in a situation in which the relief measure of another person is not possible when an emergency occurs.

The present embodiment for solving the above-mentioned problems includes a main control device for executing control corresponding to an abnormal signal; A defibrillation band attached to a chest of a patient and applying an electric shock through a defibrillation electrode using a power supplied from the main control device under the control of the main control device; A smart terminal for receiving a control signal of the main control device and transmitting an emergency relief signal; And a smart band including a heart rate sensor for measuring a heart rate of the patient.

According to another embodiment of the present invention, the defibrillation band includes: an electrocardiogram sensor for measuring the electrocardiogram of the patient; A defibrillation electrode for applying an electric shock to the patient; And a body temperature sensor for measuring a body temperature of the patient.

According to another embodiment of the present invention, the main control device includes a battery for applying power to a defibrillation electrode of the defibrillation band; A GPS sensor for acquiring current position information; A balance sensor for measuring the balance of the patient; And a controller for transmitting a control signal for applying the electric shock through the defibrillation electrode or a control signal for transmitting an emergency relief signal to the smart terminal by an abnormality signal sensed by each sensor of the defibrillation band or the smart band can do.

A method of operating a smart defibrillator according to an embodiment of the present invention includes a first step of sensing an abnormal signal by each sensor of a defibrillation band or the smart band; When the main control device receives the abnormal signal, transmits a control signal for transmitting an emergency relief signal to the smart terminal or transmits a control signal for allowing the main control device to apply an electric shock through the defibrillation electrode to the defibrillation band ; And a third step in which the smart terminal transmits an emergency relief signal or the defibrillation band applies an electric shock through a defibrillation electrode.

According to another embodiment of the present invention, the second step includes: generating a warning sound through the speaker when the main control device receives the abnormal signal; And transmitting a control signal for transmitting an emergency relief signal to the smart terminal if the main control device does not receive a signal for releasing the warning sound, or the main control device may transmit an electric shock through the defibrillation electrode And transmitting the control signal to the control unit.

According to another embodiment of the present invention, in the third step, the smart terminal can transmit the current position information and the electrocardiographic information of the patient along with the emergency relief signal.

According to an embodiment of the present invention, when an abnormality signal of the patient is detected in the defibrillation band and the smart band, the main control device controls the smart terminal to transmit the emergency relief signal, or the electric shock is applied through the defibrillation electrode, You can cope with sudden abnormalities or accidents.

In addition, according to the embodiment of the present invention, when an abnormality of a patient is detected, the smart terminal transmits the current position information to the contact such as 119, the emergency position signal together with the current position information, , The electrocardiogram information of the patient measured by the electrocardiograph sensor is transmitted to enable quicker emergency structure.

In addition, according to an embodiment of the present invention, it is possible to set a climbing mode at the time of climbing a heart patient, an exercise mode at the time of exercise, a sleep mode at the time of sleep, etc., Provides diabetic mode, can cope with emergencies caused by accidents in daily life, or responds to emergencies during travel.

In addition, according to the embodiment of the present invention, the operation mode can be set at the time of driving the heart disease patient, and the patient can be set to the driving mode in the case of a patient admitted to the hospital due to heart disease, Or in a situation in which relief measures of others are impossible when an emergency occurs, such as a patient requiring protection.

1 is a conceptual diagram for explaining a configuration of a smart defibrillator according to an embodiment of the present invention.
2 is a view for explaining a method of operating a smart defibrillator 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 the following description, well-known functions or constructions are not described in detail to avoid unnecessarily obscuring the subject matter of the present invention. In addition, the size of each component in the drawings may be exaggerated for the sake of explanation and does not mean a size actually applied.

1 is a conceptual diagram for explaining a configuration of a smart defibrillator according to an embodiment of the present invention.

Hereinafter, the configuration of a smart defibrillator according to an embodiment of the present invention will be described with reference to FIG.

1, the smart defibrillator according to an exemplary embodiment of the present invention includes a main control device 110, a defibrillation band 120, a smart terminal 130, and a smart band 140.

The main control device 110 is attached to the waist of the patient and performs control corresponding to the abnormality signal sensed by each sensor of the defibrillation band 120 or the smart band 140.

More specifically, the main control device 110 may include a GPS sensor 111, a balance sensor 112, an acceleration sensor 113, and a controller 114.

The GPS sensor 111 can acquire the current position information of the patient, and the balance sensor 112 measures the balance degree of the patient.

The control unit 114 transmits a control signal for applying the electric shock through the defibrillation electrode 122 by an abnormality signal sensed by each of the defibrillation bands 120 or the sensors of the smart band 140, The smart terminal 130 may transmit a control signal for transmitting an emergency relief signal.

At this time, the main control device 110 may apply power to the defibrillation electrodes of the defibrillation band including the battery, and may detect an abnormality detected by the sensors of the defibrillation band 120 or the smart band 140 When a signal is received, a warning sound can be output through the speaker.

The defibrillation band 120 is attached to the patient's chest and is electrically connected to the defibrillation electrode 122 through the defibrillation electrode 122 using a power supplied from the main control device 110 under the control of the main control device 110. [ do.

More specifically, the defibrillation band 120 may be attached to the patient's chest through a Velcro tape 124. The defibrillation band 120 may include an electrocardiogram sensor 121, a defibrillation electrode 122, As shown in FIG.

The electrocardiogram sensor 121 measures the electrocardiogram of the patient, the defibrillation electrode 122 applies the electric shock to the patient, and the body temperature sensor 123 measures the body temperature of the patient.

At this time, the electrocardiogram sensor 121 provides the electrocardiogram information of the patient to the main control device 110, and the body temperature sensor 123 may provide the patient's body temperature information to the main control device 110 So that the electrocardiographic information and the body temperature information can be transmitted together when the emergency terminal of the smart terminal 130 transmits the emergency relief signal.

The smart terminal 130 can communicate with the main control device 110 wirelessly and more specifically the smart terminal 130 can communicate with the main control device 110 via Bluetooth short distance communication.

Accordingly, the smart terminal 130 can transmit the emergency relief signal by receiving the control signal of the main control device 110 through the wireless communication.

The smart band 140 includes a heart rate sensor for measuring a heart rate of a patient, and can measure the activity of the patient, check the sleep state, and provide a pedometer function together with a clock function.

The smart band 140 configured as described above can provide the patient's heartbeat, sleep state information, and pedometer information to the smart terminal 130 through a wireless communication method such as Bluetooth wireless communication with the smart terminal 130.

2 is a view for explaining a method of operating a smart defibrillator according to an embodiment of the present invention.

Hereinafter, an operation method of the smart defibrillator according to an embodiment of the present invention will be described with reference to FIG.

First, as shown in FIG. 2, a patient wears a defibrillation band 120, a smart band 140, and a main control device 110. At this time, the patient may attach the defibrillation band 120 to the chest, attach the smart band 140 to the cuff, and attach the main control device 110 to the waist.

The patient may then pair the smart band 140 and the main control device 110 with the smart terminal 130.

Accordingly, the defibrillation band 120 and the smart band 140 can be monitored for operation and can detect an abnormal signal of a patient using each sensor. The main control unit 110 controls the operation of the defibrillation band 120 and the smart band 140, You can issue an order.

Accordingly, when the main control unit 110 receives an abnormal signal from the defibrillation band 120 and the smart band 140, it transmits a control signal for transmitting an emergency relief signal to the smart terminal 130, An electric shock can be applied to the defibrillation band 120 through the defibrillation electrode 122.

More specifically, when the main control device 110 receives an abnormal signal, the main control device 110 may generate a warning sound through the speaker. For example, when the balance sensor 123 senses continuous 10 seconds or more, It is possible to generate a warning sound when it occurs for 20 seconds or more or when the electrocardiogram sensor 121 generates an abnormal signal for 20 seconds or more.

Alternatively, if the waiting time elapses when an abnormal signal of each sensor is generated, a warning sound is generated in the main control device 110 and the warning sound can be manually released. In addition, when the warning sound is not manually released even after a predetermined time, the system enters the secondary warning mode and enters the emergency occurrence and action mode when manual release is not made even after the second warning wait time has elapsed.

In such an emergency occurrence and measure mode, the smart terminal 130 may transmit an emergency relief signal or the defibrillation band 120 may apply an electric shock through the defibrillation electrode 122.

For example, if the smart terminal 130 sends an urgent character to the contact information such as 119 of the current position information of the GPS sensor 111, transmits the emergency rescue signal to the emergency relief destination together with the current position information, The electrocardiogram information of the patient measured by the sensor 121 can be transmitted.

The defibrillation band 120 may periodically apply an electric shock through the defibrillation electrode 122 located in the patient's chest to perform relief measures. The defibrillation band 120 and the smart band 140 The sensors can continue to monitor the condition of the patient, and the relief action can be terminated when the data of each sensor is restored to normal.

In addition, according to one embodiment of the present invention, the main control device 110 can be set to a climbing mode at the time of climbing a heart patient, an exercise mode at the time of exercise, a sleep mode at the time of sleeping, A diabetic mode capable of detecting a sudden unconscious state of the diabetes mellitus can be provided and can be set as a normal mode in which an emergency can be dealt with in case of an accident in daily life or in case of an emergency in a trip.

In addition, according to the embodiment of the present invention, the operation mode can be set at the time of driving the heart disease patient, and the patient can be set to the driving mode in the case of a patient admitted to the hospital due to heart disease, Or in a situation in which relief measures of others are impossible when an emergency occurs, such as a patient requiring protection.

In the foregoing detailed description of the present invention, specific examples have been described. However, various modifications are possible within the scope of the present invention. The technical spirit of the present invention should not be limited to the above-described embodiments of the present invention, but should be determined by the claims and equivalents thereof.

110: main control device
111: GPS sensor
112: Balance sensor
113: Accelerometer
114:
120: Defibrillation band
122: defibrillation electrode
123: Body temperature sensor
124: Velcro tape
130: Smart terminal
140: Smart Band

Claims (6)

A defibrillation band having a defibrillation electrode, an electrocardiogram sensor and a body temperature sensor and attached to the patient's chest;
A main control device attached to the body of the patient and including a balance sensor for measuring the degree of balance of the patient, an acceleration sensor, a global positioning system (GPS) sensor for measuring the position of the patient, and a controller, A control device connected to the balance sensor, the acceleration sensor, the GPS sensor, the defibrillation electrode, the electrocardiogram sensor, and the body temperature sensor to receive a signal; And
A smart band having a heartbeat sensor for measuring a heartbeat of the patient,
The main control device may be configured to detect an abnormality signal corresponding to the climbing mode, the exercise mode, the sleep mode, the diabetes mode, or the operation mode preset in the balance sensor, the heart rate sensor or the electrocardiogram sensor, Generating a warning sound through a smart terminal and a speaker connected to the main control device; And a control signal for periodically applying an electric shock to the chest of the patient according to the detected abnormality signal to the defibrillation electrode when the occurrence of the alarm is not manually released for a predetermined time, Lt; / RTI >
The main control device transmits a control signal for emergency relief signal transmission to the smart terminal based on an abnormality signal from any one of the balance sensor, the acceleration sensor, the GPS sensor and the body temperature sensor.
delete The method according to claim 1,
Wherein the main control device includes a battery for applying power to a defibrillation electrode of the defibrillation band.
A defibrillation band attached to a patient's chest and having a defibrillation electrode, an electrocardiogram sensor and a body temperature sensor; a balance sensor, an acceleration sensor, a global positioning system (GPS) sensor and a control device attached to the body of the patient; A controller for receiving signals from the balance sensor, the acceleration sensor, the GPS sensor, the defibrillation electrode, the electrocardiogram sensor and the body temperature sensor, and a smart band having a heartbeat sensor for measuring the heartbeat of the patient A method of operating a smart defibrillator comprising:
From a defibrillation electrode, an electrocardiogram sensor or a body temperature sensor of a defibrillation band attached to the patient's chest, from a balance sensor, an acceleration sensor, a GPS sensor of the main control device worn by the patient, A first step of detecting an abnormal signal corresponding to a predetermined climbing mode, a motion mode, a sleep mode, a diabetic mode, or an operation mode from a heart rate sensor for measuring a heart rate;
When the abnormal signal is detected for a predetermined time, the main control device generates a warning sound through the speaker, and if the generation of the alarm is not manually released for a predetermined time, the main control device determines that an emergency occurs, For providing a control signal to the defibrillation electrode for periodically applying an electric shock to the chest of the patient in accordance with a signal and monitoring a state of the patient and transmitting a control signal for sending an emergency relief signal to the smart terminal step; And
And a third step wherein, in response to the control signal, an electric shock caused by the defibrillation electrode is applied to the chest of the patient, and an emergency relief signal is transmitted to a preset recipient through the smart terminal.
delete The method of claim 4,
And the third step transmits the current location information and the electrocardiographic information of the patient along with the emergency relief signal through the smart terminal.

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