KR20140036688A - Device for measurement of bionic information - Google Patents

Abstract

The present invention relates to a device for measuring bionic information which includes a radiation beam transmission adaptor for allowing an electrode attached to the body of a patent to be used as it is when the body is photographed by using a diagnosis device. According to the present invention, the device for measuring bionic information having a radiation beam transmission adaptor is to use the diagnosis device without separating the electrode from the body of the patent by using an adaptor of a radiation beam transmission material and an electrode made of a radiation beam transmission material when the body of the patient to which the electrode is attached uses the diagnosis device such a X-ray device and so on.

Description

Biometric information measuring device having a radiation transmission adapter {Device for Measurement of Bionic Information}

The present invention relates to a bioinformation measuring device having a radiographic adapter, and more particularly, to a radiographic adapter that uses an electrode attached to a body of a patient when photographing a body using a diagnostic device such as an X-ray. It relates to a biological information measuring device provided.

In general, a biomedical electrode collects electrical changes of minute action currents generated in a subject (eg, the heart and muscles of a human body), attaches the electrode to a subject to be examined, and electrocardiogram (Electrocardiogram, ECG), EMG (Electromyogram, etc.) are measured.

Such a biomedical electrode is configured to be electrically connected to a medical device by using a snap electrode that can be easily attached to or detached from various monitoring pads attached to a human body, such as Korean Patent Publication No. 10-1034998.

1 is a view illustrating a conventional biomedical electrode. Referring to FIG. 1, the conventional biomedical electrode 105 has an insulating shape and has a circular first base 110, a hydrogel adhesive 120 positioned at a center of one side of the first base 110, and a first Located at the center of the other side of the base 110 is configured to include a connection portion 130 of the metal material in close contact with the hydrogel adhesive 120. In addition, the first coupling part 140 of the connection line 150 connected to the display device 200 is coupled to the connection part 130, and an electrical signal generated from a subject to which the electrode 105 is attached to the display device 200. Is displayed.

2 is a view illustrating a state in which a plurality of conventional biomedical electrodes are attached to a patient. 1 and 2, a plurality of electrodes 105 are attached to the required position on the patient's body to measure the patient's electrocardiogram and electrocardiogram in the hospital. The number of electrodes 105 may be added or subtracted according to the purpose to be measured. Each electrode 105 thus attached reads an electrical signal from the patient, and the read electrical signal is transmitted to the display device 200 through each connection line 150. The display device 200 includes an electrocardiogram device or a monitoring device, and the electric signal is displayed to the outside.

Meanwhile, in the hospital, in order to precisely diagnose various diseases or injuries such as fractures, the patient's body is photographed using a diagnostic device such as X-ray. In the case of X-Ray, X-rays are transmitted to a specific part of the human body and the target image is taken. Since X-rays cannot penetrate high-density metal, the patient before taking X-Ray, You must remove all metal from your body.

However, the intensive care unit (or emergency patient in the emergency room) in the intensive care unit manages the patient using a monitoring system (Patient Care and Monitoring Systems) to periodically check the physical condition such as electrocardiogram by attaching a plurality of electrodes 105 to the body I do it.

Accordingly, when the patient's body needs to be photographed using the X-ray apparatus, the plurality of general electrodes 105 having the connection part 130, which is an electric wire including a metal material attached to the patient's body, are removed one by one. A separate radiation transmitting electrode made of only radiolucent materials is reattached to photographing, and after the shooting is completed, the radiation transmitting electrode is detached and a new general electrode 105 is attached to the patient's body. do.

As described above, each critical patient or emergency patient needs to remove the common electrode, use expensive radiation transmitting electrode and attach new electrode after the diagnosis device is finished. There is a problem that is a burden, and it takes a considerable time to remove and attach a plurality of electrodes attached to the body of the patient one by one, there is a problem that both the patient and staff troublesome.

An object of the present invention for solving the problems of the prior art as described above provides a biometric information measuring device having a radiation transmission adapter to use the electrode attached to the body of the patient as it is, when photographing the body using a diagnostic device It's about doing it.

The present invention to achieve the above object is an electrode for obtaining a biological signal; And a first coupling part detachably coupled to the electrode, a second coupling part detachably coupled to a lead wire of the monitoring device, one end connected to the first coupling part, and the other end coupled to the second coupling part. And an adapter having a connection line connected to the unit, wherein the electrode, the first coupling unit, and the connection line are formed of a radiation transmitting material.

In addition, the electrode, the adhesive portion of the conductive material; A base portion having adhesiveness and attached to an upper portion of the adhesive portion; One side is located in the adhesive portion and the other side through the base portion sensor unit located on the outside; And a connection part connected to the sensor part and detachably coupled to the first coupling part.

In addition, the base portion is formed to be larger than the adhesive portion, and provides a biometric information measuring device having a radiation transmitting adapter, characterized in that formed in a porous having a fine hole.

In addition, the base unit provides a biometric information measuring apparatus having a radiation transmitting adapter, characterized in that formed of porous polyurethane or polyethylene foam (Folyethylene-Foam) or paper material.

The first coupling part may include: a main body having a through hole formed at an inner bottom thereof so that the connection part of the electrode is penetrated; And a conducting plate positioned on a bottom surface of the main body, one end of which is formed with an insertion hole to insert the connection part penetrated into the through hole, and the other end of which is formed of a radiation-transmitting material electrically connected to the connection line. It provides a biometric information measuring device having a radiation transmission adapter, characterized in that.

The first coupling part may include: a main body having a rotatable part formed at a position spaced apart in one direction and an opening formed at a position spaced in another direction based on the through hole therein; It is formed long and one end is rotated by being inserted into the rotating part, the other end is located outside the main body through the opening, the one side facing the connecting portion is formed with a guide to guide the connecting portion, the other side the insertion portion A handle portion formed; And an elastic, one end coupled to rotate with the insertion part, and the other end further including a leaf spring of a radiation transmitting material spaced apart from and fixed to the edge of the main body from the other side of the handle part. One end portion of the leaf spring by the elasticity to move the guide portion in the direction of the connecting portion of the handle portion, so that the connecting portion is not separated from the through hole to the outside biometric information measuring apparatus having a transmissive adapter to provide.

The adhesive part may include a conductive hydrogel, the sensor part, the connection part, and the current conduction plate may include a carbon material, and the leaf spring may be made of polytetrafluoroethylene (PTFE). It provides a biometric information measuring apparatus having a radiation transmitting adapter, characterized in that configured to include.

In addition, the second coupling portion, the coupling guide including a wire fixing part coupled to the end of the wire formed along the inside of the connection line, a support plate connected to the fixing portion, and a snap projection protruding upward from the support plate part; And a cover part covering the coupling guide part and positioned to expose the snap protrusion to the outside.

According to the present invention, when a patient with an electrode uses a diagnostic device such as X-ray, the electrode is made of a radioactive material and an adapter of a radiopaque material, so that the diagnostic device is left as it is without removing the electrode attached to the patient's body. There is an effect that can be used.

In addition, the base portion provided in the electrode is formed of a porous having fine pores, so that it can be uniformly in contact with the skin, thereby preventing noise from occurring due to the minute movement of the patient, thereby increasing the reliability of the electrode have.

1 is a view illustrating a conventional biomedical electrode.
2 is a view illustrating a state in which a plurality of conventional biomedical electrodes are attached to a patient.
3 is a view schematically showing a biometric information measuring apparatus having a radiation transmitting adapter according to a preferred embodiment of the present invention.
4 is an exploded view illustrating electrodes of a biometric information measuring apparatus including a radiation transmitting adapter according to a preferred embodiment of the present invention.
5 is a schematic cross-sectional view of an electrode according to a preferred embodiment of the present invention.
6 is a view illustrating a state in which the base portion of the electrode is in close contact with the skin according to a preferred embodiment of the present invention.
7 is an exploded view illustrating the first coupling part of the adapter according to the preferred embodiment of the present invention.
FIG. 8 is a view illustrating a state in which an electrode is attached to a first coupling part of a biometric information measuring apparatus including a radiation transmitting adapter according to a preferred embodiment of the present invention.
FIG. 9 is a view illustrating a state in which an electrode is removed from a first coupling part of a biometric information measuring apparatus including a radiation transmitting adapter according to a preferred embodiment of the present invention.
FIG. 10 is a view illustrating a second coupling part of a biometric information measuring apparatus having a radiation transmitting adapter according to a preferred embodiment of the present invention.
FIG. 11 is a diagram illustrating a state of use of a biometric information measuring apparatus having a radiation transmitting adapter according to a preferred embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings will be described in more detail a biometric information measuring apparatus having a radiation transmitting adapter according to an embodiment of the present invention.

3 is a view schematically showing a biometric information measuring apparatus having a radiation transmitting adapter according to a preferred embodiment of the present invention.

Referring to FIG. 3, a bioinformation measuring device having a radiation transmitting adapter according to an exemplary embodiment of the present invention is for measuring a biosignal such as an electrocardiogram (ECG), and acquires a biosignal 10. And an adapter 30 detachably connected to a display device (not shown) such as an electrocardiogram device or a monitoring device, which is located outside, so that an electrical signal read from the electrode 10 can be displayed.

The electrode 10 reads an electric change of a minute active current generated in the body and transmits the read electrical signal to the display device through the adapter 30. The electrode 10 is made of a radiation-transmitting material, the reason is that when the critically ill patient, such as life-critical in the intensive care unit or emergency room of the hospital using a diagnostic device such as X-Ray, the electrode 10 attached to the body of the patient This is to make it possible to use diagnostic devices such as X-Ray without removing the). Detailed configuration of the electrode 10 will be described in detail with reference to FIG. 4.

The adapter 30 is configured to be electrically connected to a wire connected to an external display device, that is, the lead wire 70 so that the signal measured by the electrode 10 can be processed into meaningful information. In this case, the display device converts a signal read through the electrode 10 and the adapter 30 into a signal that a user can see and outputs the signal to the outside. And the end of the lead wire 70 is provided with a detachable portion 72 to be detachably coupled with the snap projection 57 protruding to the second coupling portion 50 to be described later. The detachable portion 72 may have any shape as long as it is configured to be detachably coupled to the snap protrusion 57. For example, the detachable portion 72 may include the snap protrusion 57 at the detachable portion 72. Is inserted and configured to be male and female combined. Since the detachable part 72 and the lead wire 70 are provided outside the diagnostic device, the detachable part 72 and the lead wire 70 may include a metal material.

Looking at the structure of the adapter 30, the first coupling portion 31 which is detachably coupled to the electrode 10, and the second coupling portion 50 which is detachably coupled to the lead wire 70 of the display device. ) And one end portion is electrically connected to the first coupling portion 31 and the other end includes a connection line 60 electrically connected to the second coupling portion 50.

The first coupling portion 31 and the second coupling portion 50 will be described in detail with reference to the following drawings.

The connection line 60 is formed of a material through which electricity is supplied, and includes an electric wire 62 (shown in FIG. 10) formed of a radiation transmitting material such as carbon (for example, carbon black, carbon nanotube, etc.) that also transmits X-rays. The outer side of the wire 60 is covered with plastic or the like. In addition, the wire 62 of the connection line 60 may be coated with metals such as silver, silver chloride, titanium, gold, and platinum in the form of a thin film along the outside thereof to improve conductivity or to secure a certain level of conductivity. When the metal is coated or coated with a thin film thickness, X-rays are transmitted as they are, so that the electrical conductivity can be ensured.

As such, the connection line 60 and the first coupling part 31 are made of carbon material or plastics including a thin metal material through which radiation is transmitted, such that a critically ill patient, such as a life-threatening patient, in an intensive care unit or an emergency room of a hospital may be X-Ray. When using such a diagnostic device, there is an effect that the diagnostic device such as X-Ray can be used as it is without removing the electrode 10 attached to the body of the patient.

4 is an exploded view of an electrode of a biometric information measuring apparatus having a radiation transmitting adapter according to a preferred embodiment of the present invention, and FIG. 5 is a schematic cross-sectional view of an electrode according to a preferred embodiment of the present invention. Drawing.

Referring to the drawings, the electrode 10 of the biometric information measuring apparatus having a radiation transmitting adapter according to a preferred embodiment of the present invention, the base portion 18, the liner 12, the adhesive portion 14, the sticker 20 , The sensor unit 15 and the connection unit 22 are configured.

The base portion 18 is formed of a non-conductive or insulating material, and is formed in various shapes such as a circular or polygonal shape, and a through hole 18a is formed at the center thereof. And a pressure-sensitive adhesive is applied to the lower surface of the base portion 18 to be easily attached and detached to the body part to be measured. At this time, one side edge of the base portion 18 is formed with a handle portion 19, which is not coated with an adhesive so as to allow the user to easily attach and detach the base portion 18.

The liner 12 is attached to the lower surface of the base portion 18 and protects the adhesive applied to the base portion 18 from the outside. The liner 12 is made of PE (polyethylene) or PET (polyethylene terephthalte) film.

The adhesive part 14 serves to conduct fine electricity of the body to the sensor part 15, and may be made of a material having conductivity and adhesion, for example, hydro gel. The adhesive part 14 is positioned in the center of the lower surface of the base portion 18 in the molten or flow state as it is, or sprays the hydrogel into the through-hole 18a of the base portion 18, the base portion It can be produced by compressing the upper and lower surfaces of (18).

Sticker 20 is formed in the form of a film, attached to the upper surface of the base portion 18 to maintain or protect the shape of the base portion 18, the upper surface may be printed on the brand name, company name and the like. In addition, a through hole 20a is formed in the center of the sticker 20.

The sensor unit 15 is a conductive sensor that converts the bio-ion current conducted by the adhesive unit 14 into an electric current so as to sense a bio-signal, so that silver / silver chloride (Ag / Agcl) is applied to the surface to conduct electricity. It is composed. The sensor unit 15 includes a close contact plate 16 provided on the lower side, and an extension 17 provided above the close contact plate 16. The adhesion plate 16 is in close contact between the lower side of the base portion 18 and the upper side of the adhesive portion 14, and is formed in a plate shape. The extension part 17 is integrally formed to protrude in the direction of the through hole 18a of the base part 18 from the center of the upper surface of the contact plate 16, and the through hole 18a and the sticker of the base part 18 ( It is penetrated through the through hole 20a of 20).

The connection part 22 is for fixing the upper side of the sensor part 15 to the base part 18 or the sticker 20. The fixing plate 23 is fixed to the upper surface of the sticker 20 and the fixing plate ( 23, the fixing part 24 protrudes upward, and is configured to surround the extension part 17 positioned on the sticker 20 through the through hole 20a of the sticker 20. At this time, the inside of the fixing part 24 is in close contact with the extension part 17 and the outside of the fixing part 24 is detachably coupled with the first coupling part 31, the living body detected by the sensor unit 15 The signal is transmitted to the first coupling part 31 through the connection part 22.

In addition, the sensor unit 15 and the connection unit 22 may be formed of a material through which electricity is energized, and may be formed of a material through which radioactive materials such as X-rays are transmitted, for example, carbon through electricity, and an outer surface thereof. A thin film including at least one of silver, silver chloride, titanium, gold, and platinum may be applied by gravure coating, ink jet printing, silkscreen printing, knife coating, or the like. In this case, the thickness of the thin film is applied, but the X-rays are transmitted, the electrical conductivity is preferably applied to a degree that can be secured to a certain level.

As such, when a critically ill patient with a serious life in a intensive care unit or an emergency room of a hospital uses a diagnostic device such as X-ray, an electrode including a sensor part 15 and a connection part 22 having a radioactive material such as carbon or a thin film thickness ( By using 10), it is possible to use the diagnostic device as it is without removing the electrode 10 attached to the patient's body.

6 is a view illustrating a state in which the base portion of the electrode is in close contact with the skin according to a preferred embodiment of the present invention.

First, Figure 6 (a) is a view showing a base 110 of the conventional electrode, referring to Figure 6 (a), the base 110 of the conventional electrode is composed of paper or non-woven fabric, The adhesive part such as the hydrogel 120 is positioned to detect a fine signal of the body. When the base 110 is in close contact with the skin, the lower side of the base 110 adjacent to the edge of the hydrogel 120 is bent by the thickness thereof, and the lifting space 112 is lifted between the base 110 and the skin. Is generated. As such, the base 110 of the conventional electrode does not uniformly contact the skin, and thus the lifting space 112 is generated. Will be generated. In this case, even if an emergency did not occur, the monitoring device is displayed as an emergency occurred, or an emergency occurred, the check is not made properly, there is a problem that a serious medical accident may occur.

Next, FIG. 6B is a view showing the base portion 18 of the electrode 10 of the present invention. Referring to FIG. 6B, the base portion 18 is a microporous hole having moisture permeability. It is made of a quality, it may be formed of a porous polyurethane or polyethylene foam (Folyethylene-Foam) or a paper material and the like, it may be formed in a thin film form. When the base portion 18 is in close contact with the skin, the hydrogel is permeated between the micropores of the base portion 18, so that the hydrogel is perfectly adhered to the base portion 18, so that the hydrogel is in the base portion 18. Fills the gap between the skin and the skin.

As such, since the base portion 18 of the electrode 10 of the present invention is uniformly in contact with the skin, noise is not generated due to the minute movement of the patient, and thus, the reliability of the electrode 10 is increased. have.

7 is an exploded view illustrating the first coupling part of the adapter according to the preferred embodiment of the present invention.

Referring to the drawings, the first coupling portion 31 of the adapter 30 is detachably attached to the connecting portion 22 of the electrode 10 in a snap form, and the main body 32, the conduction plate 42, and the handle portion 38. ) And the leaf spring 40.

The main body 32 is formed so as to have an empty space therein, the upper side is open, the open upper portion of the main body 32 is closed by the cover 44. The through hole 33 is formed in the center of the bottom surface of the main body 32 such that the fixing part 24 of the connecting part 22 is penetrated. In addition, the inner bottom surface of the main body 32 has a rotation part 34 formed at a position spaced apart in one direction on the basis of the through hole 33, and an opening portion 35 is provided at a position spaced in the other direction. do.

The conduction plate 42 is located on the bottom surface of the main body 32, one end is located in the direction of the through hole 33, the other end is located on the side of the opening 35, at this time, A plate guide groove 37 is formed at the bottom to guide the conduction plate 42 to be positioned, and the conduction plate 42 is inserted into the plate guide groove 37 of the main body 32. In addition, an insertion hole 42a is formed at one end of the energizing plate 42 to insert the connecting portion 22 penetrated into the through hole 33 of the main body 32, and the other end is electrically connected to the connecting line 60. . And in order for the other end of the electricity supply plate 42 to be electrically connected with the connection line 60, the connection line 60 is fixed in the position which opposes the other end of the electricity supply plate 42 in the main body 32. The conduction plate 42 is formed of a material through which electricity is supplied, and is formed of a radioactive material such as carbon through which X-rays are transmitted as it is, and thin film silver, silver chloride, titanium, Gold and platinum and the like can be coated. Since such a metal is apply | coated or coated by thin film thickness, it is low in density and X-rays permeate | transmits it as it is.

The handle portion 38 is inserted into the rotating portion 34 formed on the bottom surface of the main body 32 and rotated. The handle portion 38 is elongated, and one end portion is inserted into the rotating portion 34 so that the rotating portion 38a is formed to rotate. The other end is located outside the main body 32 through the opening 35. And the one side facing the connecting portion 22 in the handle portion 38 is formed with a guide portion 38b to guide the connecting portion 22, the other side is inserted into the plate spring 40 to be described later is inserted and rotated 38c is formed.

The leaf spring 40 is formed in a long plate shape in the longitudinal direction, it is preferably composed of a plastic material of the radiation transmitting material having an elasticity. For example, the leaf spring 40 may be molded of polytetrafluoroethylene (PTFE) or the like. As such, when the intensive care unit to which the electrode 10 is attached in an emergency room of a hospital uses a diagnostic device such as X-ray, the plate spring 40 is made of a radioactive material such as plastic, and thus, the electrode 10 attached to the patient's body 10. It is effective that a diagnostic device such as X-Ray can be used without removing the).

One end of the leaf spring 40 is coupled to rotate with the insertion portion 38c of the handle portion 38, the other end is fixed spaced apart from the other side of the handle portion 38 in the direction of the edge of the main body 32. . As a result, the one end of the leaf spring 40 is rotated by the insertion portion 38c of the handle portion 38 by the elasticity of the leaf spring 40, the guide portion 38b of the handle portion 38 The connecting portion 22 is moved in the direction, and the connecting portion 22 is not separated from the through hole 33 to the outside by the pressure applied from the guide portion 38b.

FIG. 8 is a view illustrating a state in which an electrode is attached to a first coupling part of a biometric information measuring apparatus including a radiation transmitting adapter according to a preferred embodiment of the present invention.

Referring to the drawings, a bioinformation measuring device having a radiation transmitting adapter according to a preferred embodiment of the present invention removes the liner 12 attached to the electrode 10 and the base portion 18 to the body part to be measured. Attach. Thereafter, the through hole 33 formed in the main body 32 of the first coupling portion 31 is inserted into the fixing portion 24 provided in the connecting portion 22 of the electrode 10. Then, the guide portion 38b of the handle portion 38 presses the fixing portion 24 by the elastic pressure of the leaf spring 40, so that the fixing portion 24 is not separated from the through hole 33 to the outside. Will not.

The micro electrical signal of the body read from the adhesive part 14 of the electrode 10 is transmitted to the connection part 22 through the sensor part 15, and the micro electrical signal transmitted to the connection part 22 is the first coupling part. It is transmitted to the connecting line 60 through the conduction plate 42 of 31, and is transmitted to a display device (not shown) such as an electrocardiogram device or a monitoring device located outside.

Here, the sensor unit 15, the connection unit 22, the conduction plate 42, and the connection line 60 should transmit the micro electricity of the body read from the adhesive unit 14 of the electrode 10 to the display device. , The material is to be formed of a material that is energized, in the present invention, as described above, X-rays are transmitted through a radioactive material, such as carbon through which electricity is passed or X-rays are transmitted through the thin film thickness of electricity It consists of silver, silver chloride, titanium, gold, platinum, etc. Accordingly, when a critically ill patient, such as a critically ill patient, uses a diagnostic device such as X-Ray in a intensive care unit or an emergency room of a hospital, the electrode 10, the first coupling part 31, and the connecting line 60 attached to the body of the intensive care patient There is an advantage that can be used as it is, without removing or changing.

FIG. 9 is a view illustrating a state in which an electrode is removed from a first coupling part of a biometric information measuring apparatus including a radiation transmitting adapter according to a preferred embodiment of the present invention.

Referring to the drawings, in the biological information measuring apparatus having a radiation transmission adapter according to a preferred embodiment of the present invention, in order for the electrode 10 fixed to the first coupling part 31 to be removed, the user is outside the main body 32. The other end of the handle portion 38 exposed to the pressure is applied in the direction of the leaf spring (40). Then, one end of the leaf spring 40 is rotated in the insertion portion (38c) of the handle portion 38, the handle portion 38 is moved in the direction of the connecting portion 22 by the elasticity of the leaf spring 40, the leaf spring (40) In reverse direction. Then, the guide portion 38b of the handle portion 38, which has pressed the connecting portion 22, is spaced apart from the fixing portion 24 of the connecting portion 22, so that the handle portion 38 no longer presses the connecting portion 22. You will not. As a result, the fixing portion 24 of the connecting portion 22 is easily removed from the through hole 33, so that the electrode 10 is removed from the first coupling portion 31, and thus the first coupling portion 31 When the electrode and the electrode 10 is separated, it is easy to remove or replace the electrode 10 attached to the body of the patient, there is an advantage that easy storage.

FIG. 10 is a view illustrating a second coupling part of a biometric information measuring apparatus having a radiation transmitting adapter according to a preferred embodiment of the present invention.

Referring to FIG. 10 (a), the second coupling part 50 of the adapter 30 is electrically connected to the connection part 22, and the detachable part 72 provided in the lead wire 70 of the monitoring device. It is configured to be detachable, and includes a coupling guide portion 52 and the cover portion (59).

Coupling guide portion 52 is formed in a plate shape and the support plate 54, the end of the connecting line 60 is located on the side, and inserted into the side of the support plate 54 and the wire of the support plate 54 and the connecting line 60 ( A wire fixing part 55 which electrically couples 62 to each other, a coupling protrusion 56 protruding from the center of the upper surface of the support plate 54 to an upper portion thereof, and protruding upward from the center of the upper surface of the coupling protrusion 56; And a snap protrusion 57 formed.

The cover part 59 covers the support plate 54, the wire fixing part 55, and the engaging protrusion part 56 of the coupling guide part 52, which can be injection molded, and is formed on the upper surface of the cover part 59. The snap protrusion 57 penetrates outward and is located.

Here, the coupling guide 52, that is, the support plate 54, the wire fixing part 55, the coupling protrusion 56, and the snap protrusion 57 must transmit the micro electricity of the body transmitted from the electrode 10 to the display device. Therefore, it should be formed of a material through which electricity is applied. In addition, the coupling guide unit 52 may be made of a radioactive material such as carbon, and thus, when a critically ill patient, such as a critically ill patient, uses a diagnostic device such as X-ray in a intensive care unit or emergency room of a hospital, There is an advantage that the electrode 10 or the adapter 30 attached to the body may be used as it is without being removed or changed.

Subsequently, referring to FIG. 10B, the biological signal detected by the electrode 10 is transferred to the second coupling unit 50 through the connection line 60. And the snap protrusion 57 provided in the second coupling portion 50 is inserted into the removable portion 72 of the lead wire 70 is coupled to the removable portion 72 to be detachable, accordingly the second coupling portion The biosignal transmitted to 50 is transferred to a display device such as an electrocardiogram device or a monitoring device on the lead wire 70.

FIG. 11 is a diagram illustrating a state of use of a biometric information measuring apparatus having a radiation transmitting adapter according to a preferred embodiment of the present invention.

Referring to FIG. 11, a patient's condition is periodically managed using a monitoring system for monitoring an electrocardiogram or an electrocardiogram of a patient in a hospital. To this end, a plurality of electrodes 10 are attached to the required position of the patient's body, the number of electrodes 10 can be added or subtracted according to the purpose to be measured.

Each electrode 10 is electrically connected to a lead wire 70 connected to the display device 200 through an adapter 30. In this case, the first coupling part 31 of the adapter 30 is detachably connected to the electrode 10, and the detachable part provided with the lead wire 70 at the second coupling part 50 of the adapter 30. 72 is detachably connected. The signal measured by the electrode 10 is transmitted to the display device 200 through the adapter 30 and the lead wire 70, and the display device 200 converts the signal into a signal that can be seen by the user and outputs the signal to the outside. do.

Here, since the electrode 10, the first coupling portion 31 and the connecting line 60 is made of a radiation transmitting material, when the patient uses a diagnostic device 300 such as X-Ray, the electrode attached to the body of the patient There is an effect that the diagnostic device 300 such as X-Ray can be used as it is without replacing or removing the adapter 10 or the adapter 30.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it will be understood by those skilled in the art that various changes and modifications may be made without departing from the spirit and scope of the invention as defined by the appended claims.

10 electrode 12 liner
14: adhesion part 15: sensor part
16: close contact plate 17: extension part
18: base portion 18a: through hole
19: handle 20: sticker
20a: through hole 22: connection part
23: fixing plate 24: fixing part
30: adapter 31: first coupling portion
32: main body 33: through hole
34: rotating part 35: opening part
37: plate guide groove 38: handle portion
38a: rotating part 38b: guide part
38c: insert 40: leaf spring
42: energizing plate 42a: insertion hole
44: cover 50: second coupling portion
52: coupling guide 54: support plate
55: front line fixing 56: combined protrusion
57: snap projection 59: cover
60: connection line 62: wire
70: lead wire 72: removable part

Claims (8)

An electrode for acquiring a biological signal; And
A first coupling part detachably coupled to the electrode, a second coupling part detachably coupled to a lead wire of the monitoring device, one end of which is connected to the first coupling part, and the other end of the second coupling part An adapter having a connecting line connected to the
And the electrode, the first coupling part, and the connection line are formed of a radiation transmitting material.
The method of claim 1,
The electrode is:
Adhesive portion of a conductive material;
A base portion having adhesiveness and attached to an upper portion of the adhesive portion;
One side is located in the adhesive portion and the other side through the base portion sensor unit located on the outside; And
And a connection part connected to the sensor part and detachably coupled to the first coupling part.
3. The method of claim 2,
And the base portion is formed to be larger than the adhesive portion and is formed of a porous material having micropores.
3. The method of claim 2,
And the base portion is made of porous polyurethane or polyethylene foam (Folyethylene-Foam) or paper material.
3. The method of claim 2,
The first coupling portion:
A main body having a through hole formed at an inner bottom thereof so that the connection part of the electrode is penetrated; And
Located at the bottom of the main body, one end is inserted into the insertion hole is formed so that the connection portion penetrated through the through hole, the other end is electrically connected to the connection line and includes a conducting plate formed of a radiation-transmitting material that is energized Biometric information measuring device having a radiation transmission adapter, characterized in that.
The method of claim 5, wherein
The first coupling portion:
A main body having an opening formed at a position spaced apart in one direction and an opening formed at a position spaced in another direction based on the through hole therein;
It is formed long and one end is rotated by being inserted into the rotating part, the other end is located outside the main body through the opening, the one side facing the connecting portion is formed with a guide to guide the connecting portion, the other side the insertion portion A handle portion formed; And
It has elasticity, one end is coupled to rotate with the insertion portion, the other end further comprises a leaf spring of a radiation transmitting material which is spaced apart and fixed in the edge direction of the main body from the other side of the handle portion,
One end of the leaf spring by the elasticity of the leaf spring to move the guide portion in the direction of the connecting portion of the handle portion, so that the connecting portion is not separated from the through hole to the outside of the living body having a transmissive adapter Information measuring device.
The method according to claim 6,
The adhesive portion comprises a conductive hydrogel,
The sensor unit, the connection unit and the conduction plate comprises a carbon material
The leaf spring is a bioinformation measuring device having a radiation transmission adapter, characterized in that it comprises a polytetrafluoroethylene (PTFE) of a radiation transmitting material having elasticity.
The method of claim 1,
The second coupling portion:
A coupling guide including a wire fixing part coupled to an end of the wire formed along the inside of the connection line, a support plate connected to the fixing part, and a snap protrusion protruding upward from the support plate; And
Covering the coupling guide portion, the biological information measuring device having a radiation transmitting adapter, characterized in that it comprises a cover portion which is positioned so that the snap projection is exposed to the outside.

Images