KR100926700B1 - Breast belt for detecting physiological signal - Google Patents

Abstract

PURPOSE: A chest belt for measuring a bio signal is provided to easily check a health condition of user by transmitting a bio signal to a bio signal display device on a real time. CONSTITUTION: A chest belt includes a conductive fabric band(1), a signal converter, and a bio signal transmitter. The conductive fabric band is formed in a part contacted with a chest. The conductive fabric band is formed by weaving conductive yarn 30~40weight% and non-conductive yarn 60~70weight%. The signal converter converts an electric potential difference signal sensed by the conductive fabric band into a digital bio signal. The bio signal transmitter is formed in a fastener(2) attached to an end part of the chest belt. The bio signal transmitter transmits a bio signal converted by the signal converter to a monitoring device.

Description

Chest belt for detecting physiological signals

The present invention is a conductive fabric band is formed in close contact with the human thorax to continuously measure the potential difference signal generated in the human thorax and convert it into a biosignal in real time to transmit to the biosignal display device, thereby real-time health status of the belt wearer The present invention relates to a chest belt for measuring a physiological signal that can be easily checked continuously.

In order to objectively diagnose the state of health of the body, it is very effective to measure and display the bio signals generated in each part of the body, and especially to measure and display the bio signals of the chest where the most important organs in the body are concentrated. It is extremely important to display the data.

To this end, a checkup should be performed to monitor the bio signals generated in the chest such as electrocardiogram and heart rate. The one-time examination of the chest, which is performed regularly, has a problem that the examination results are likely to be distorted due to various reasons such as a temporary disease or a change in condition.

In particular, heart disease often occurs suddenly during sports activities, and in order to respond quickly to heart disease, such as above, to monitor the signs of heart disease by continuously monitoring the vital signs generated in the chest in real time. It should be recognized, but there is a problem that it is extremely difficult to prepare for the possibility of sudden onset of heart disease only by the conventional one-time examination of the chest.

Accordingly, an object of the present invention is to form a conductive fabric band in close contact with the human chest to continuously measure the potential difference signal generated in the human chest and convert it into a bio-signal in real time to transmit to the bio-signal display device, The present invention provides a chest belt for measuring a bio-signal to easily and continuously check a physical condition in real time.

In order to achieve the above object, in the present invention, the conductive yarn and non-conductive formed at a portion in close contact with the human chest and at least one selected from the group consisting of conductive yarn, metal coated fiber yarn, metal yarn covering fiber yarn. Conductive fabric bands in which yarns are woven; A signal converter that digitally processes the potential difference signal detected by the conductive fabric band and converts the signal into a biosignal; And a biosignal transmitter configured to transmit the biosignal converted by the signal converter to a monitoring device.

Chest belt for bio-signal measurement according to the present invention by continuously measuring the potential difference signal generated in the human chest, and converts it into a bio-signal and transmits it to the bio-signal display device in real time, thereby easily checking the physical condition of the belt wearer in real time It has the effect of supporting it.

In addition, the bio-signal chest belt of the present invention has the effect of supporting the rapid response to the chest disease by quickly capturing the signs of chest disease that occurs suddenly during sports activities and the like.

Chest belt for measuring the bio-signal of the present invention is characterized in that the conductive fabric band is formed by weaving a conductive fiber in a portion in close contact with the human chest, the potential signal is detected.

With reference to the drawings and the embodiment will be described in detail with respect to the belt for measuring the biological signal of the present invention.

1 illustrates the overall structure of a chest belt for measuring a bio-signal according to an embodiment of the present invention, and FIG. 2 illustrates an expanded state of the chest belt for measuring a bio-signal according to an embodiment of the present invention. Figure 3 shows a cross-sectional structure of a metal coated fiber yarn woven into the conductive fabric band of the present invention, Figure 4 shows the outer shape of the metal yarn covering fiber yarn woven into the conductive fabric band of the present invention.

1 to 4, first, the bio-signal measuring chest belt of the present invention is formed in close contact with the human chest and at least one selected from the group consisting of conductive yarns, metal coated fiber yarns, metal yarn covering fiber yarns Conductive fabric bands comprising woven and non-conductive yarns are included.

In order to measure the biological signal of the human body, it is essential to detect a potential difference signal generated in the human chest using a conductive material having a current flowing property.

As described above, a band of a certain size made of a conductive material is bonded or sewn to a portion of the chest belt of a general belt material such as leather, fabric, and knitted fabric, which is in close contact with the human chest to detect a potential difference signal occurring in the human chest. It is composed.

Theoretically, various types of conductive materials such as metals, conductive plastics, and conductive ceramics are used to form a conductive band of a certain size that can detect a potential difference signal of the human chest, and the conductive band closely adheres to the human chest of the chest belt. Attached or sewn on the portion to be made can be configured for the chest belt for measuring the biological signal. In practice, however, there is a unique requirement of the chest belt to be in close contact with the wearer's chest, not to slip or move when the wearer is in motion, and the wearer's skin to not feel rejected. The conductive bands formed must also meet the same requirements, and since conductive materials other than conductive fibers containing conductive yarns do not meet the above requirements, they cannot be practically used to construct a chest belt for measuring a biosignal. .

Accordingly, in the present invention, the conductive metal is coated on the surface of the fiber yarn 11 which is a known conductive yarn, general synthetic fiber or natural fiber having a property of flowing current, thereby providing conductivity by forming a metal coating layer 12. And a metal coated fiber yarn which is provided with additional sterilization effect, and a metal yarn covering fiber yarn which is provided with conductivity and is concomitantly given sterilization effect by winding the metal yarn 13 on the surface of the fiber yarn 11. Or non-conductive yarns which impart the human chest and adhesion and the fit of the chest belt wearer are woven together to the conductive yarns to be used or mixed with two or more to form the conductive fabric band.

By the way, the conductive yarn used as the conductive yarn has a property that the current flows, there is a problem that the mechanical properties are somewhat lacking. In order to solve this problem, in the present invention, a plurality of conductive yarns can be twisted to form conductive yarns with improved mechanical properties, and the conductive yarns and general non-conductive yarns can be woven together to form a conductive fabric band.

In addition, as a conductive yarn, a metal coating fiber yarn having a metal coating layer formed by coating various kinds of conductive metals such as silver, copper, aluminum, etc. may be formed on the surface of the base yarn, but the various kinds of metals described above Among them, it is preferable to form a metal-coated fiber yarn by coating silver on the surface of the yarn having excellent conductivity and excellent gloss with excellent gloss. Likewise, metal yarn covering fiber yarns may be formed by winding various kinds of conductive metal yarns such as silver, copper yarn, aluminum yarn, etc. on the surface of the base yarn, but have the highest conductivity among the various kinds of metals described above. It is preferable that a silver yarn having excellent gloss and excellent appearance is wound on the surface of the yarn to form a metal yarn covering fiber yarn.

And, as described above, non-conductive yarns woven together with at least one conductive yarn selected from the group consisting of conductive yarns, metal-coated fiber yarns, metal yarn covering fiber yarns to form a conductive fabric band, polyester having no conductivity, It may be made of polypropylene, nylon, and the like, but a general elastic fiber may be formed of a conductive fabric band using a non-conductive yarn made of a rubber material or a spandex yarn made of a high elastic material alone or mixed. It is desirable in terms of giving a weight and providing comfort to the belt wearer.

Specifically, 30-40% by weight of the conductive yarn selected from the group consisting of conductive yarns, metal coated fiber yarns, metal yarn covering fiber yarns, and 60-70% by weight of non-conductive yarns may be used as needle looms, weaving machines, or air jet machines. The woven fabric is made of a conductive fabric band consisting of a variety of structures, such as plain weave, bone weave. Alternatively, 30-40% by weight of conductive yarns and 60-70% by weight of non-conductive yarns may be irregularly arranged and bonded to form a conductive fabric band having a nonwoven form.

When the content of the conductive yarn contained in the conductive fabric band is less than 30% by weight, the conductivity of the conductive fabric band is lowered due to the lack of the content of the conductive yarn, and when the content of the conductive yarn contained in the conductive fabric band exceeds 40% by weight. Due to the excessive content of the conductive yarn and the lack of the relative content of the non-conductive yarn, the fit of the human chest and adhesion and the wear of the chest belt are reduced.

That is, 30-40% by weight of conductive yarns, 60-70% by weight of non-conductive yarns are woven to form a conductive fabric band 1 having almost no rejection with the human skin while being in close contact with the human chest. Since the band 1 is attached to or sewn on the part of the chest belt closely attached to the human chest, the chest belt for measuring a biosignal having a function of detecting a potential difference signal of the human chest is configured. However, the conductive fabric band, which includes a conductive yarn and detects the potential difference signal of the human chest, is formed to protrude slightly from the portion in close contact with the human chest of the chest belt, and the conductive fabric band is more sure of the potential difference signal of the human chest. It is preferable in that it can detect.

The potential difference signal of the human chest detected by the conductive fabric band 1 of the chest belt for measuring the biosignal is transmitted to the signal converter in real time.

In addition, the chest belt for measuring the bio-signal of the present invention includes a signal converter for digitally processing the potential difference signal detected by the conductive fabric band to convert to a bio-signal.

Means for digitally processing the potential difference signal should be formed to convert the potential difference signal of the human chest detected by the conductive fabric band 1 into a quantified biosignal as described above.

For this purpose, a signal converter (not shown) which is connected to the conductive fabric band 1 and converts the potential difference signal of the human chest transmitted from the conductive fabric band 1 into a quantified biosignal in real time, has a chest belt. Is formed at any point.

Such a signal converter digitally processes the potential difference signal of the human chest transmitted from the conductive fabric band 1 in real time, whereby a biological signal of the chest such as an electrocardiogram, heart rate, etc., which is quantified based on the potential difference signal, is obtained. The signal is processed and displayed at the monitoring device.

The biosignal digitally processed and quantified in a signal converter formed at one point of the breast belt is transmitted to a biosignal transmitter (not shown) in real time.

In addition, the biosignal measuring chest belt of the present invention includes a biosignal transmitter configured to transmit the biosignal converted by the signal converter to a monitoring device.

As described above, a means for transmitting the biosignal converted by the signal converter and transmitted in real time to the monitoring device should be formed.

To this end, a biosignal transmitter for transmitting a biosignal of the chest, such as an electrocardiogram, heart rate, etc., quantified based on the potential difference signal, is formed at any point of the chest belt. And. A signal converter for digitally processing a potential difference signal of a human chest in real time and converting the signal into a biosignal and a biosignal transmitter for transmitting the biosignal transmitted from the signal converter are physically coupled and physically coupled as described above. The signal converter and the biosignal transmitter are preferably formed in the fastener 2 detachable from the end of the chest belt so as to fasten the chest belt at the chest of the human body, in terms of the fact that the biosignal measuring device of the chest belt can be compactly configured. Do.

A biosignal of a chest such as an electrocardiogram, a heart rate, etc. is transmitted in real time to various kinds of monitoring devices such as a computer having a biosignal processing function, a wristwatch, etc. from a biosignal transmitter formed at one point of the chest belt. The biosignal transmission from the biosignal transmitter of the chest belt to the monitoring device is performed by wired / wireless communication, from the biosignal transmitter to achieve the object of the present invention to continuously check the convenience of the chest belt wearer and the biosignal. The biosignal transmission to the monitoring device is preferably carried out by wireless communication.

The biosignal transmitted from the biosignal transmitter may be processed and displayed in real time by the monitoring device, and, if necessary, may support medical activities based on the biosignal processed by the monitoring device.

For example, if there are signs of a sudden onset of heart disease during sporting activities, the device detects in real time the potential difference in the conductive fabric band of the biosignal measuring belt and sends it to the signal converter. The signal converter converts the potential difference change in real time into a biosignal that is a symptom of heart disease and transmits it to a biosignal transmitter, and transmits a biosignal that is a symptom of heart disease to a monitoring device in real time. The monitoring device performs necessary measures such as immediately contacting a medical institution based on a biosignal, which is a sign of a received heart disease.

That is, the bio-signal chest belt of the present invention can support the chest disease to be quickly responded to by quickly catching signs of a suddenly occurring chest disease.

In addition, when the chest belt for measuring the bio-signal of the present invention is continuously worn, the body state of the belt wearer is continuously measured by measuring the potential difference signal generated in the human chest and converting the signal into a bio-signal in real time. Can be easily and continuously checked in real time.

In addition, the bio-signal measuring chest belt may further include a non-slip band made of a non-conductive material formed on the surface facing the human body of the chest belt.

In order to prevent the bio-signal chest belt from slipping in a worn state, frictional force is applied to a surface facing the human body of the chest belt, for example, around the conductive fabric band 1 or the surface of the chest belt facing the back of the human body. This excellent non-slip band 3 is formed so as not to affect the conductivity of the conductive fabric band 1.

Specifically, a number of protrusions such as silicone, natural rubber, synthetic rubber, etc., which are made of non-conductive non-slip material having excellent friction and non-conductive properties such as silicone, natural rubber, synthetic rubber, or the like, which provide frictional force, A non-slip band 3 made of the formed non-conductive material is attached or sewn to form a biosignal measuring chest belt which does not slip in a worn state. Alternatively, in order to provide a bio-signal chest belt that does not slip in a worn state, a non-slip material having excellent friction is coated on the surface facing the human body of the chest belt as it is, so that the anti-skid band 3 may be configured. have.

As described above, in order to prevent the bio-signal chest belt from slipping in a worn state, the non-conductive anti-slip material used to form the conductive fabric band may be made of various materials such as silicone, natural rubber, synthetic rubber, etc. Among these materials, a non-slip band (3) made of silicone having a very good friction and adsorption force and a soft surface feel is very excellent in anti-slip effect and provides a wearer with a satisfactory fit. It is preferable at the point which can comprise a measuring chest belt.

In addition, the bio-signal measuring chest belt of the present invention may further include a non-slip tag that is detachable to the chest belt and made of a non-conductive anti-slip material or a coating formed.

In addition to the non-slip band described above, a non-slip tag 5 that can be attached to and detached from the chest belt is additionally formed to prevent the bio-signal measurement belt from slipping in a worn state. A part of the anti-slip tag 5 is cut and the incision is detached by passing through the breast belt, or the anti-slip tag 5 is detached from the breast belt by a known detachment outlet such as a latch or a ring.

The non-slip tag detachable from the chest belt is composed of non-slip material such as silicone, natural rubber, synthetic rubber, etc. like the non-slip band, and specifically, the non-slip tag is made of non-slip material. The non-slip tag is constructed by coating the surface of the tag or non-conductive anti-slip material.

In addition, the non-conductive anti-slip material used in the anti-slip tag may also be used in various materials such as silicone, natural rubber, synthetic rubber, but among these materials, silicone, particularly, has excellent friction and adsorptive force, and has a soft surface feel. Using the non-slip tag (5) is preferable in view of the fact that the non-slip effect can be configured in the chest belt for measuring the bio-signal for providing a satisfactory fit to the wearer with a very excellent anti-slip effect.

The anti-slip band or anti-slip tag described above prevents the bio-signal measurement belt from slipping in a worn state.

When the bio-signal measuring chest belt configured as described above is fastened to the chest and fastened with a fastener, the potential difference signal generated at the chest is continuously measured and converted into a bio-signal and transmitted to the bio-signal display device in real time. The physical condition can be easily and continuously checked in real time.

The present invention is not limited to the above-described embodiments and the accompanying drawings, and various forms of substitutions, modifications, and changes can be made without departing from the spirit of the present invention.

1 is an overall structural diagram of a chest belt for measuring a biological signal of the present invention

Figure 2 is a development state diagram of the chest belt for measuring the biological signal of the present invention

3 is a cross-sectional view of a metal coated fiber yarn woven into the conductive fabric band of the present invention.

Figure 4 is an external view of the metal yarn covering fiber yarn woven in the conductive fabric band of the present invention

* Explanation of symbols for the main parts of the drawings

1: conductive fabric band 2: fastener

3: non-slip band 5: non-slip tag

11: yarn 12: metal coating layer

13: metal yarn

Claims (11)

For chest belts, At least one selected from the group consisting of a metal yarn covering fiber yarn formed in a portion in close contact with the human chest and made of a conductive coating, a metal coated fiber yarn for coating the conductive yarn with silver, and a silver yarn for covering the conductive yarn. Conductive fabric band composed of 30 to 40% by weight of conductive yarns and 60 to 70% by weight of non-conductive yarns made of rubber or spandex yarns alone or mixed, woven or irregularly arranged and bonded to form a nonwoven fabric. ; A signal converter that digitally processes the potential difference signal detected by the conductive fabric band and converts the signal into a biosignal; And And a biosignal transmitter formed on a fastener detachable from an end of the chest belt and configured to transmit the biosignal converted by the signal converter to a monitoring device. delete delete delete delete delete delete delete The chest belt of claim 1, further comprising a non-slip band made of a non-conductive anti-slip material formed on a surface of the chest belt facing the human body. The chest belt of claim 1, further comprising an anti-slip tag detachable from the chest belt and made of a non-conductive anti-slip material or formed with a coating. 11. The chest belt according to any one of claims 9 to 10, wherein the non-conductive anti-slip material is silicon.

Images