KR102417017B1 - Portable electrocardiogram measurement system - Google Patents

Abstract

The present invention relates to a portable electrocardiogram measuring system, comprising: an electrocardiogram measuring device holding an electrocardiogram with one hand and placing it on a chest to measure electrocardiogram and body temperature; a display unit for displaying information on an electrocardiogram waveform, pulse, and body temperature measured by the electrocardiogram measuring device; and a server that stores, manages, and analyzes the ECG waveform, pulse, and body temperature information measured by the ECG measuring device.

Description

Portable electrocardiogram measurement system

The present invention relates to a portable electrocardiogram measurement system, and more particularly, to a portable electrocardiogram measuring system for conveniently measuring an electrocardiogram in a non-stick type.

In general, an electrocardiogram (ECG) is an action current according to contraction and relaxation of the heart muscle, which is measured and recorded by attaching an external electrode. The action potential generated when the heart muscle contracts and relaxes causes an electric current that spreads from the heart to the whole body. This electric current generates a potential difference depending on the position of the body. have.

Such an electrocardiogram is used to check the presence of abnormalities in the heart, and is used as a basic method for diagnosing cardiac diseases such as angina pectoris, myocardial infarction, and arrhythmia.

However, the conventional electrocardiogram measurement has problems such as taking off clothes and hair removal in order to attach an electrode containing an adhesive to the body, causing skin rashes, and taking a long measurement time.

An object of the present invention to solve the above problems is to provide a portable electrocardiogram measuring system that can measure the electrocardiogram from time to time conveniently by holding a non-adhesive electrocardiogram measuring device on the chest while holding it with one hand.

The portable electrocardiogram measuring system of the present invention for achieving the above object includes: an electrocardiogram measuring device for measuring an electrocardiogram and body temperature by holding it with one hand and placing it on the chest even when the activity is stopped or active; a display unit for displaying information on an electrocardiogram waveform, pulse, and body temperature measured by the electrocardiogram measuring device; and a server that stores, manages, and analyzes the ECG waveform, pulse and body temperature information measured from the ECG measurement device, wherein the ECG measurement device includes a sensing electrode unit for detecting a biosignal and body temperature, and a power supply for supplying power It characterized in that it comprises a supply unit, an electrocardiogram measuring unit for measuring the biosignal as an electrocardiogram signal, and a communication unit for transmitting the electrocardiogram and body temperature information by wire or wirelessly.

The electrocardiogram measuring device may form a sensing electrode part on the upper surface of the triangular body, and the lower surface may be formed in a convex shape to be held with one hand.

The sensing electrode part is composed of a right leg (RL), a left arm (LA), and a right arm (RA), and the number of electrodes excluding the RL can be used up to nine.

The electrode structure of the sensing electrode unit includes an upper electrode layer that forms a sensing unit electrode using a conductive material to transmit a signal, a biocompatible material coated on one side of the upper electrode layer and in direct contact with the skin, and a dielectric layer that accumulates electric charges and a lower electrode layer forming a grounding electrode made of a conductive material for canceling triboelectricity by clothing or textiles and providing a reference point for a signal, and an insulating layer that plays an insulating role between the upper electrode layer and the lower electrode layer. have.

The electrocardiogram measuring unit includes a filter that removes distortion and noise of the biosignal that has been input through the sensing electrode unit, a signal processing unit including an amplifier that amplifies the signal that has passed through the filter, and converts the analog biosignal measured through the signal processing unit into a digital signal. It may include an MCU configured with an A/D converter for converting, a first algorithm for filtering the noise component of the digital signal, and a second algorithm for calculating a pulse and temperature.

The communication unit may transmit the electrocardiogram waveform, pulse, and body temperature data to the display unit and the server through wired or wireless communication.

The server may transmit the electrocardiogram waveform, pulse, and body temperature data to the user's mobile phone or portable terminal.

As described above, according to the present invention, the non-adhesive ECG measurement device can be placed on the chest while holding with one hand and the non-adhesive ECG measuring device is placed on the chest to measure the ECG, so that personal health management can be performed frequently, and the examination time can be dramatically reduced. have.

In addition, according to the present invention, it is possible to minimize the distortion of the ECG waveform even in situations such as simple movement, walking, and jumping in place, and it is possible to provide a highly reliable ECG signal by removing signal distortion and motion noise in real time.

1 is a plan view of a portable electrocardiogram measuring device according to the present invention.
2 is a cross-sectional view of an electrode structure of a sensing electrode unit according to the present invention.
3 is a block diagram of a portable electrocardiogram measurement system according to the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those of ordinary skill in the art can easily carry out the present invention. However, the present invention may be implemented in several different forms and is not limited to the embodiments described herein.

Then, a portable electrocardiogram measurement system according to an embodiment of the present invention will be described in detail.

1 is a plan view of a portable electrocardiogram measuring device according to the present invention, FIG. 2 is a cross-sectional view of an electrode structure of a sensing electrode unit according to the present invention, and FIG. 3 is a block diagram of a portable electrocardiogram measuring system according to the present invention.

1 to 3, the portable electrocardiogram measuring system of the present invention includes an electrocardiogram measuring device 1000 that measures electrocardiogram and body temperature by holding it with one hand and placing it on the chest even when activity is stopped or active, and the electrocardiogram measuring device 1000 The display unit 2000 for displaying the measured ECG waveform, pulse and body temperature information, and a server 3000 for storing, managing and analyzing the ECG waveform, pulse and body temperature information measured from the ECG measuring device 1000 are included. is composed by

The electrocardiogram measuring device 1000 has three non-adhesive sensing electrodes 100 formed on the upper surface of the triangular body 10, and the lower surface has a convex shape so that it can be easily held with one hand. Here, the electrocardiogram measuring apparatus 1000 may form 3 to 10 sensing electrode units 100 on the upper or lower portion of a body of various shapes such as a triangle, a circle, and a rectangle, but is not limited thereto.

The electrocardiogram measuring device 1000 includes a non-adhesive sensing electrode unit 100 that senses a biosignal and body temperature by holding it with one hand inside the body 10 and placing it on the chest, a power supply unit 200 for supplying power, and the living body It is configured to include an electrocardiogram measuring unit 300 that measures a signal as an electrocardiogram signal, and a communication unit 400 that transmits the electrocardiogram and body temperature information by wire or wirelessly.

The sensing electrode unit 100 does not require an adhesive because it measures a biosignal in a capacitive coupling method. Here, the sensing electrode part 100 is formed in a rhombic shape, but is not limited thereto.

In addition, the sensing electrode part 100 may be formed of a right leg (RL) 110, a left arm (LA) 120, and a right arm (RA) 130 depending on an attachment position, and the RL 110 is The number of excluded electrodes can be used up to 9.

Here, the LA 120 and RA 130 are used to measure the potential difference on the body surface at their respective positions, and the RL 110 transmits a signal from a Driven Right Leg (DRL) circuit to the body. It can be used to cancel external interference noise.

The sensing electrode unit 100 may include a temperature sensor 140 in any one of the RL 110 , LA 120 , and RA 130 to measure body temperature.

Here, the electrode structure of the sensing electrode part 100 is, as shown in FIG. 2, an upper electrode layer forming the sensing part electrode using a conductive material such as copper (Cu) or various types of conductors to transmit a signal. 113, a dielectric layer 114 that is a biocompatible material that is coated on one side of the upper electrode layer 113 and that is in direct contact with the skin and accumulates electric charges, and triboelectric offset by clothing or textiles and provides a reference point for signals a lower electrode layer 111 forming a ground electrode made of a conductive material for

The power supply unit 200 may charge the battery 210 through the USB charging circuit 230 and turn on/off the power supply of the battery 210 through the power switch 220 .

The electrocardiogram measuring unit 300 includes a signal processing unit 310 and an MCU 320 .

Here, the signal processing unit 310 includes a filter 311 for removing distortion and noise of the biosignal received through the sensing electrode unit 100, and an amplifier 312 for amplifying the signal passing through the filter 311. can do.

Here, the MCU 320 includes an A/D converter 321 for converting an analog bio-signal measured by the signal processing unit 310 into a digital signal, and a first algorithm for filtering the noise component of the digital bio-signal ( 322), and a second algorithm 323 for calculating the pulse and temperature are programmed. In this case, the pulse may be measured using an electrocardiogram signal.

The communication unit 400 may transmit the electrocardiogram waveform, pulse, and body temperature data to the display unit 2000 and the server 3000 through wired or wireless communication. That is, the communication unit 400 may transmit the electrocardiogram waveform, pulse, and body temperature data to the display unit 2000 and the server 3000 through UART communication or wireless communication such as Bluetooth, Zigbee, or UWB.

The display unit 2000 may display information such as an electrocardiogram waveform, a pulse, and a body temperature measured by the electrocardiogram measuring unit 300 on an LCD display, a PC monitor, or a mobile phone.

The server 2000 may store, manage, analyze, and monitor ECG waveform, pulse, and body temperature information, and may transmit it to a user's mobile phone, portable terminal, or PC.

Although the embodiments of the present invention have been described in detail above, the scope of the present invention is not limited thereto. is within the scope of the right.

100: sensing electrode 140: temperature sensor
200: power unit 300: electrocardiogram measurement unit
310: signal processing unit 311: filter
312: amplifier 320: MCU
321: A/D converter 400: communication unit
1000: electrocardiogram measuring device 2000: display unit
3000: server

Claims (7)

an electrocardiogram measuring device for measuring electrocardiogram and body temperature by holding it with one hand and placing it on the chest during cessation or activity;
a display unit for displaying information on an electrocardiogram waveform, pulse, and body temperature measured by the electrocardiogram measuring device; and
A server that stores, manages and analyzes the electrocardiogram waveform, pulse and body temperature information measured from the electrocardiogram measuring device;
The electrocardiogram measuring device,
A sensing electrode unit for sensing bio-signals and body temperature;
a power supply for supplying power; and
an electrocardiogram measuring unit for measuring the biosignal as an electrocardiogram signal; and
and a communication unit that transmits the electrocardiogram and body temperature information by wire or wirelessly,
The electrocardiogram measuring device forms three non-adhesive sensing electrodes on the upper surface of the triangular body, and the lower surface is formed in a convex shape so that it can be held with one hand,
The sensing electrode part measures a biosignal in a rhombic shape in a capacitive coupling method, and consists of RL (Right Leg), LA (Left Arm) and RA (Right Arm), and the number of electrodes excluding the RL is used up to 9 and
The LA and RA are used to measure the potential difference on the body surface at each location, and the RL is used to remove external interference noise by flowing a signal from a Driven Right Leg (DRL) circuit to the body,
A portable electrocardiogram measuring system comprising a temperature sensor in any one of RL, LA, and RA of the sensing electrode unit to measure body temperature. delete delete According to claim 1,
The electrode structure of the sensing electrode part,
An upper electrode layer forming a sensing unit electrode using a conductive material to transmit a signal;
A dielectric layer coated on one side of the upper electrode layer and being a biocompatible material in direct contact with the skin and accumulating electric charges;
A lower electrode layer forming a ground electrode made of a conductive material for offsetting triboelectricity by clothing or textiles and providing a reference point for a signal, and
A portable electrocardiogram measuring system, characterized in that it is formed as an insulating layer serving as an insulating layer between the upper electrode layer and the lower electrode layer. According to claim 1,
The electrocardiogram measurement unit,
A filter that removes distortion and noise of bio-signals received through the sensing electrode;
A signal processing unit comprising an amplifier for amplifying the signal that has passed through the filter, and
an A/D converter for converting an analog biosignal measured through the signal processing unit into a digital signal, a first algorithm for filtering the noise component of the digital signal, and
A portable electrocardiogram measuring system comprising an MCU configured with a second algorithm for calculating a pulse and a temperature. According to claim 1,
The communication unit transmits the ECG waveform, pulse, and body temperature data to the display unit and the server through wired or wireless communication. According to claim 1,
The server transmits the ECG waveform, pulse, and body temperature data to the user's mobile phone or portable terminal.

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