KR100670810B1 - Biological signal measuring electrode and biosignal measuring device using same - Google Patents

Abstract

Disclosed are a biosignal measuring electrode made of a conductive rubber including an adsorption electrode plate, and a biosignal measuring device using the same. The garment contact plate is made of flexible rubber which is attached to one inner side of the garment and is conductive, and the adsorption electrode plate is made of conductive and sticky rubber, which includes a flexible concave surface in contact with the human body, and the electrode body is at least It consists of a conductive and tacky rubber that fixes one adsorption electrode plate to the garment contact plate. Thus, there is no inconvenience in wearing for a long time, it is possible to measure the accurate bio-signal even in the movement.

Adsorption electrode plate, conductive rubber, bio signal measuring electrode, adhesive

Description

Biological signal measuring electrode and biosignal measuring apparatus using same {Physiologic signal measuring electrode and apparatus}

1 is a view showing the structure of an embodiment of a biosignal measuring electrode according to the present invention;

2 is a view showing before and after the bio-signal measuring electrode in contact with the skin,

3A and 3B show the structure of another embodiment of a biosignal measuring electrode according to the present invention;

4 is a view showing a garment with a biosignal measuring electrode according to the present invention;

5A and 5B show another embodiment of a garment having a biosignal measuring electrode attached thereto;

The present invention relates to a biosignal measuring electrode and a biosignal measuring apparatus, and more particularly, to a biosignal measuring electrode consisting of a conductive rubber electrode including an adsorption electrode plate and a biosignal measuring apparatus using the same.

Recently, telemedicine has emerged as the medical environment has shifted from provider-driven to consumer-driven. Telemedicine is evolving into ubiquitous healthcare that can monitor and check health status anytime and anywhere through the rapid development and dissemination of information and communication technology.

In ubiquitous healthcare, it is important to monitor and check bio signals without causing inconvenience to the wearer's life. For this purpose, it is useful to monitor and check the bio signals by attaching electrodes to bands or garments.

However, if a conventional disposable electrode (disposable electrode) is attached to the skin for a long time causes a problem on the skin, so it is unreasonable to use it as it is. A dry electrode or a conductive rubber using a metal having good conductivity may be used for a long time to attach the electrode, but a problem arises in that the contact is poor due to movement.

Electrodes that can be attached to clothing are mainly flexible, rubber-based electrodes containing conductive materials. These electrodes are heavily influenced by the movement of the wearer due to the property of being attached to the garment, and thus, the measured bio-signals incorporate a lot of noise.

In order to securely hold the electrode in contact with the skin, it can be attached to a very tight type of garment or a band can be used, which causes inconvenience to the wearer of the garment. This discomfort causes feelings of rejection for wearing tight clothing with electrodes.

In order to monitor the long-term bio-signals, the biggest problem to be solved is to minimize noise mixing due to movement and to avoid discomfort during wearing.

The technical problem to be achieved by the present invention is to eliminate the discomfort caused by the long time wearing of the bio-signal measuring electrode and to prevent the contact is bad according to the user's movement to measure the bio-signal made of a conductive rubber that can measure the accurate bio-signal To provide an electrode.

The technical problem to be achieved by the present invention is to remove the inconvenience caused by wearing for a long time, to prevent poor contact according to the user's movement and to attach a bio-signal measuring electrode made of conductive rubber to measure the accurate bio-signal to the garment To provide a biological signal measuring device.

In order to achieve the above technical problem, an embodiment of the biosignal measuring electrode according to the present invention includes a garment contact plate made of a flexible rubber attached to one side of the garment and conductive; An adsorption electrode plate comprising a flexible concave surface in contact with a human body and made of conductive and tacky rubber; And an electrode body made of conductive and tacky rubber for fixing at least one adsorption electrode plate to the garment contact plate.

In order to achieve the above technical problem, an embodiment of the biological signal measuring apparatus according to the present invention, clothing; And at least one conductive rubber electrode attached to the inside of the front of the body of the garment to measure a bio-signal, wherein the front side of the body of the garment includes one side fixed to the garment and the other part including a zipper and a button. The conductive rubber electrode is fixed to the member and can be opened and closed, and the conductive rubber electrode includes a flexible concave surface in contact with the human body and is made of a conductive and adhesive rubber.

Thus, there is no inconvenience in wearing for a long time, it is possible to measure the accurate bio-signal even in the movement.

Hereinafter, the biosignal measuring electrode and the biosignal measuring apparatus according to the present invention will be described in detail with reference to the accompanying drawings.

1 is a view showing the structure of an embodiment of a biosignal measuring electrode according to the present invention.

FIG. 1 is a plan view and a side view of the biosignal measuring electrode 100 including the garment contact plate 110, the electrode body 120, and the adsorption electrode plate 130. The biosignal measuring electrode 100 is connected to a biosignal measuring module (not shown), and the biosignal measuring module is installed at one side of the garment to analyze and display the biosignal received from the biosignal measuring electrode 100. In detail, the biosignal measuring module amplifies the biosignal measured by the biosignal measuring electrode, removes noise, converts the biosignal into a digital signal, displays the biosignal converted into the digital signal on its own, or measures it with an external device through a communication module. Transmit the generated biosignal.

The electrode body 120 includes at least one adsorption electrode plate 130, and the electrode body 120 and the adsorption electrode plate 130 are rubber electrodes having a viscosity of at least 250,000 cps or more. . In addition, the electrode body 120 and the adsorption electrode plate 130 have at least enough conductivity to obtain a biosignal using the electrode.

The garment contact plate 110 is a conductive plate that is flexible and has a higher hardness than the electrode body 120 and the adsorption electrode plate 130 so as to support pressure pressed by hand from the outside. The garment contact plate 110 is in direct contact with the garment is fixed to the garment by sewing. At this time, the connection from the garment contact plate 110 to the biosignal measurement module (not shown) located on one side of the garment is connected by sewing using a conductive yarn. Alternatively, the biosignal measuring electrode 100 and the biosignal measuring module may be connected by printing a conductive rubber on the garment. In order to sew and attach the garment, it is preferable that the garment contact plate 110 be slightly larger in top, bottom, left and right than the electrode body 120.

2 is a diagram illustrating before and after the biosignal measuring electrode contacts the skin.

Referring to FIG. 2, A is a case where the biosignal measuring electrode 100 is in contact with the skin 200, and A ′ is a case where the biosignal measuring electrode 100 is in contact with the skin 200. When the biosignal measuring electrode is pressed by applying a small force as shown by the arrow of A 'of FIG. 2, the adsorption electrode plate 130 is absorbed by the skin and is firmly fixed. The biosignal measuring electrode 100 according to the present invention is firmly attached to the skin 200 even by severe movement by using at least one adsorption electrode plate 130 and a sticky material and does not easily fall off. In addition, it keeps the contact with the skin stable without being affected by the bending of the body to minimize the mixing of noise.

3A and 3B illustrate structures of another embodiment of the biosignal measuring electrode according to the present invention.

3A and 3B, the electrode bodies 300 and 302 attached to the garment contact plate 110 may have various shapes such as a round shape. In addition, the suction electrode plate connected to the electrode bodies 300 and 302 may have various shapes such as a round suction electrode plate 310 and a rhombus suction electrode plate 312. The number of the adsorption electrode plates 310 and 312 attached to the electrode bodies 300 and 302 is larger in the curved part to reduce the size of the adsorption electrode plate and attaches more. It is preferable to attach.

4 is a view showing a garment with a bio-signal measuring electrode according to the present invention.

Referring to FIG. 4, the biosignal measuring electrode 100 attached to the garment 400 is the conductive rubber electrode illustrated in FIG. 1. The garment 400 to which the conductive rubber electrode 100 is attached may be a tight garment or a loose garment. However, loose clothing provides comfort to the wearer, which is advantageous for long time wearing. The connection from the biosignal measuring electrode 100 to the biosignal measuring module (not shown) may be connected by sewing using a conductive thread. Alternatively, the conductive rubber may be printed onto the garment to connect the biosignal measurement module. As another method, the biosignal measuring electrode 100 may protrude outward from the inside of the garment to be connected to the biosignal measuring module using a cable connected to the connector.

5A and 5B illustrate another embodiment of a garment to which a biosignal measuring electrode is attached.

5A and 5B, a conductive seal (not shown) connecting a biosignal measuring electrode 100 and a biosignal measuring module (not shown), a cable using conductive rubber printing, or a general cable are not exposed to the outside. It is designed to not.

The garment 500 is composed of a body (520, 522) and the cover (530, 532) having opening and closing devices (510, 512) to open and close the body. The opening and closing device 510 may use a button or a zipper, and the structure may be variously changed in addition to those shown in FIGS. 5A and 5B.

The biosignal measuring electrode 100 is attached to the inside of the body of the garment 500, and the general cables connected to the biosignal measuring module 100 (not shown) from the biosignal measuring electrode 100 may be installed by opening the covers 530 and 532. Inside the covers 530 and 532 are structures such as Velcro or rubber rings that hold the cables.

When the cable connected to the biosignal measuring module uses conductive yarns or conductive rubber printing, the cover 530 and 532 of the garment serve to prevent contact with the outside, thereby reducing noise.

According to the present invention, the biosignal measuring electrode, that is, the garment having the biosignal measuring electrode including the adsorption electrode plate attached thereto, can measure the biosignal of a lot of athletes and can be usefully used for measuring athletic ability. Using the biosignal measuring electrode according to the present invention on the underside of the mobile biosignal measurement wireless module to be used without a special attachment support.

So far I looked at the center of the preferred embodiment for the present invention. Those skilled in the art will appreciate that the present invention can be implemented in a modified form without departing from the essential features of the present invention. Therefore, the disclosed embodiments should be considered in descriptive sense only and not for purposes of limitation. The scope of the present invention is shown in the claims rather than the foregoing description, and all differences within the scope will be construed as being included in the present invention.

According to the present invention, since the adhesive conductive rubber electrode with the adsorption electrode plate has a garment attached to the inside of the clothes and attaches the electrode by applying a slight force to the electrode part, the wearer can attach the electrode easily and conveniently, one The above-mentioned adsorption electrode plate can maintain stable contact with the skin even when the body is bent or body movement, thereby reducing the contact resistance between the skin and the biosignal measuring electrode, thereby reducing noise generated during the measurement of the biosignal. In addition, it can be applied to loose clothing, not tightly tightened clothing, so that it can be measured comfortably even for long-term monitoring of biological signals.

Claims (9)

A garment contact plate made of a conductive flexible rubber attached to one side of the garment; An adsorption electrode plate comprising a flexible concave surface in contact with a human body and made of conductive and tacky rubber; And And an electrode body made of conductive and tacky rubber for fixing at least one adsorption electrode plate to the garment contact plate. The method of claim 1, wherein the garment contact plate, The biosignal measuring electrode of claim 1, wherein the biosignal is measured by being attached to the garment or fixed by sewing with a thread. The method of claim 1, wherein the garment contact plate, Biosignal measuring electrode characterized in that connected to the biosignal measuring module and the conductive rubber printed on the garment. The method of claim 1, wherein the adsorption electrode plate, The biosignal measuring electrode, characterized in that the air between the concave surface of the adsorption electrode plate and the human body is compressed and tightly fixed to the human body by external pressure. The method of claim 1, wherein the electrode body, The biosignal measuring electrode of claim 4, wherein the four adsorption electrode plates are arranged two by one each in width and length and fixed to the garment contact plate. cloth; And Includes at least one conductive rubber electrode attached to the inside of the front of the body of the garment for measuring the bio-signal, The body front of the garment is openable and closeable using a connecting member including a zipper and a button, The conductive rubber electrode comprises a flexible concave surface in contact with the human body, characterized in that the biosignal measuring apparatus made of a conductive and adhesive rubber. The method of claim 6, And a conductive line connecting the conductive rubber electrode and a biosignal measuring module for analyzing and displaying the biosignal. The method of claim 7, wherein the conductive line, A biosignal measuring device, characterized in that it is fixed with a velcro or thread or printed inside the garment. The method of claim 6, wherein the conductive rubber electrode, A garment contact plate made of a flexible rubber that is attached to an inner side of the body front of the garment and is conductive; An adsorption electrode plate comprising a flexible concave surface in contact with a human body and made of conductive and tacky rubber; And And an electrode body made of conductive and tacky rubber to secure at least one of the adsorption active plates to the garment contact plate.

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