JPS6158633A - Suction type induction electrode for living body - Google Patents

Abstract

(57) [Summary] This bulletin contains application data before electronic filing, so abstract data is not recorded.

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to an adsorption-type induction electrode for biological use, and in particular, pressurized air is introduced into an adsorption-type induction electrode to create a gap between the skin surface and the electrode. This invention relates to an adsorption-type induction electrode for biological use that has improved adsorption properties by causing a phenomenon.

"Conventional technology" As is well known, the bioelectricity generated in the living body is the heart.

It is induced by the activities of the brain, muscles, etc. In particular, cardiac bioelectricity is detected by detecting weak currents induced on the skin of a living body using an external electrocardiograph to diagnose cardiac abnormalities. Electrodes must be closely attached to the surface of the skin in order to electrically connect the input part of this electrocardiograph to the living body.

A conventional electrode that is brought into close contact with the skin surface will be explained with reference to FIG. The electrode shown in Fig. 6 uses a suction method as a means of bringing it into close contact with the skin surface of a living body.The conventional rubber suction electrode 1 has a suction hole 3 of a metal semicircular electrode cup 2 and a hollow rubber It has a structure in which the opening 5 (!:) of the dropper 4 is communicated with a metal hollow vibro, and a terminal 7 that is led to the input side of an electrocardiograph (not shown) is connected to the outer spherical surface of the electrode cup 2. be.

To use such a conventional rubber suction electrode 1, first press the rubber dropper 4 by hand and then apply pressure to the skin surface 8 of the living body.
When the electrode cup 2 is brought into contact with the top of the skin and then the pressing force of this hand is released, the pressure inside the electrode cup 2 is reduced by the elastic restoring force of the rubber dropper 4, so that the rubber suction electrode 1 is attracted to the skin surface. That's what I do.

``Problems to be Solved by the Invention'' By the way, abnormalities in the heart are diagnosed by guiding the weak current generated in the heart by attaching the rubber adsorption electrode 1 to the skin surface to an electrocardiograph. Since the rubber suction electrode 1 has a considerable suction force, there is the inconvenience that the roots of the semicircular electrode cup 2 remain on the skin surface for several days after using the rubber suction electrode 1, causing severe discomfort. . In addition, some people may experience pain in their □ skin, sores, or Ct skin, and those with □ problems tend to experience problems such as poor adsorption.

"Means for Solving the Problems" Therefore, the present invention has been made by focusing on such problems in the conventional art, and includes a top plate having an insertion groove 27 and a fitting groove 28 formed therein. Between the surface portion 23 and the opening 25 formed by the contact piece 24 that hangs from the periphery of the top surface portion 23 and is curved to match the skin surface of the living body, and between this opening 25 and the insertion groove 27. an elastic cylindrical suction cup 22 having a communication hole 29 communicating with the electrode support plate 30 fitted into the fitting groove 28 of the suction cup 22; One of the suction cups 22 is inserted into the insertion groove 27, and the nozzle pipe 31 is detachably attached to the back surface of the electrode support plate 30 in order to contact the skin surface of the living body and lead the current inside the living body out of the body. It consists of an electrode plate 34,
1. A suction-type induction electrode for a living body, which is configured to generate negative pressure in the opening 25 and be adsorbed to the skin surface of the living body.

The object of the present invention is to solve the above-mentioned problems by providing a biological adsorption type electrode with excellent adsorption properties. .

``Example'' Hereinafter, how the configuration of the present invention is actually embodied will be explained with reference to the drawings, together with its operation.

FIG. 5 is an overall perspective view of a biological electrode adsorption device to which the biological adsorption type induction electrode of the present invention is attached.
A rotating section] 1 is loosely fitted into the upper part of the column 10, and the rotating section 11 can freely rotate 360 degrees in the horizontal direction with respect to the column 10. Further, the lower part of the support column 10 is fixed to a carrier table 13 on which an electrocardiograph 12 is placed.

An electrode tube support arm 14 projects horizontally from the pivot section 11 of the support column 10, and this electrode tube support arm 14 has a 7"" pivot section".
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It can be stopped at any desired position. Further, this electrode support arm 14 can be rotated, that is, can be moved up and down, as shown by the arrow, about the up-and-down movement mechanism 15 as an axis. A disk-shaped relay head 16 is fixedly provided at the tip of this electrode support arm 14 . A plurality of electrode tubes 17 made of gold are suspended from this relay head 16, and a biological adsorption type induction electrode 18 of the present invention is attached to one end of each electrode tube 17. The structure of the electrode 18 will be explained in detail later.

A pressurizing pump 19 for feeding pressurized air to the adsorption type induction electrode 18 is disposed below the conveyance table 13.
20 is a foot switch for starting this pressurizing pump 19.

The biological suction type induction electrode 18 has a nozzle tube and an electrode plate fitted to the lower part of a suction cup, and the suction cup 22 is made of elastic plastic, as shown in FIGS. 1 and 2. It is formed into a cylindrical shape by a circular flat top part 23 and an adhesion piece 24 that hangs down from the periphery of the top part 23 and comes into close contact with the skin surface of the living body. The lower end of this contact piece 24 is curved so that it can easily fit against the skin surface of the living body, and the opening 25 is formed by forming this contact piece 24.
is formed as shown in FIG.

As shown in FIG. 2, a protruding portion 26 is provided approximately at the center of the upper surface of the top surface portion 23, and an insertion groove 27 is formed within the protruding portion 26 as shown in FIGS. Show me.

At the same time, a fitting groove 28 is formed in the center of the back surface of the top surface portion 23 and communicates with the insertion groove 27L, as shown in FIGS. 3 and 5.

Further, as shown in FIG. 4, a communication hole 29 is bored in the top surface portion 23 adjacent to the fitting groove 28, and the opening 25 is provided with a communication hole 29.
and the push-in groove 2'7 are in communication with each other.

30 is a circular electrode plate support plate that is fitted into the fitting groove 28 as shown in FIG. 2, and a nozzle is provided on the outer surface of this electrode plate support plate 30 as shown in FIG. A tube 31 is fixedly installed, and an injection nozzle 32 is formed within this nozzle tube 31, as shown in FIG. 4, with a diameter narrowed at the tip. Further, on the circumferential surface of the nozzle pipe 31, a second
As shown in FIG. 4, a ventilation hole 33 is bored, and this ventilation hole 32 communicates with the communication hole 29 formed in the suction cup 22 when the nozzle pipe 31 is inserted into the insertion groove 27. It has become.

Further, on the back surface of the electrode support plate 30, an electrode plate 34 shown in FIG. 2 is attached by screws 35, as shown in FIG. It is removably fixed to the The electrode support plate 30 can also be used as an electrode plate, but the electrode plate is corroded due to its close contact with the skin surface of the living body and the applied cleaner, and as a result it must be replaced. The plate 30 and the electrode plate 34 are separable so that they can be replaced at any time.

As shown in FIG. 4, the electrode support plate 30 to which the electrode plate 34 and the nozzle pipe 31 are fixed is inserted into the insertion groove 27 formed in the protrusion 26 of the suction cup 22. At the same time, the electrode support plate 30 is fitted into the fitting groove 28 formed in the top surface 23 of the suction cup 22.

When the nozzle pipe 31 is inserted into the insertion groove 27 and the electrode support plate 30 is fitted to the top surface, the opening 25, the communication hole 29 and the ventilation hole 33 are aligned to form an air flow path. The injection nozzle faces this airflow passage. Moreover, when the nozzle pipe 31 is inserted into the push-in groove 27, the nozzle pipe 3
1 protrudes from the suction cup 22 and is fitted into a holder 36 attached to the proximal end ζ of the rubber electrode tube 17. A cord 37 is connected to this electrode tube 17, and this cord 37 is connected to a connection cord 2 which is disposed inside the rotating part 11 of the electrode support arm 14 strut 10 and connected to the electrocardiograph 12 in FIG. has been done.

Next, to explain how to use the bioadhesive electrode 18 having the following configuration, first, as shown in FIG. Then, the biological electrode adsorption device 9 is transported near the bed 38. Next, the foot switch 20 of the pressurizing pump 19 is operated to supply pressurized air to the column 10. After this pressurized air is introduced into the column 10, the electrode tube support arm 14 is rotated horizontally and moved downward by -L, and the suction cup of the suction type induction electrode 18 attached to the tip of the electrode tube 17 is 19 close contact piece 2
3 to the patient's skin.

If this suction type induction electrode 18 comes into contact with the patient's skin,
The pressurized air sent into the support column 10 is transferred to the support arm 14;
The liquid passes through the electrode tube] 7, enters the nozzle tube 31 of the adsorption type induction electrode 18, and is vigorously sprayed from the injection nozzle 32 whose tip is constricted. This pressurized air is sent to the injection nozzle 32
As shown in FIG. 4, the air in the opening 25 formed between the contact piece 24 and the skin surface passes through the communication hole 29 and the ventilation hole 33 and exits from the discharge port 39. It is discharged to the outside of the suction cup 22 together with the pressurized air.

As the air inside the opening 25 is discharged, a negative pressure phenomenon occurs inside the opening 25, and as a result, the contact piece 2 of the suction cup 22
The skin surface in contact with electrode 4 is attracted in both directions, and the skin surface is attracted to the contact piece 24, and the adsorption type induction electrode 8 is brought into close contact with the skin surface.

After the cardiac examination is completed in this way, if the drive of the pressurizing pump is stopped, the adsorption of the adsorption type induction electrode 18 to the skin surface can be easily released.

"Effects of the Present Invention" According to the present invention, pressurized air is fed into the suction type induction electrode, and a negative pressure phenomenon is generated between the skin surface of the living body and the suction type induction electrode. 3L to adsorb the adsorption type induction electrode to
As a result, there is no need to forcefully press the suction type against the skin surface to adsorb it, unlike the conventional adsorption electrodes made by Go. Nothing will happen.

In addition, the adhesion piece of the suction cup is elastic and is curved to fit the skin surface of the living body, so it is negative.

When pressure is generated and the adhesive piece sticks to the skin surface, it is elastically deformed by the negative pressure and can completely adhere to the skin surface.

Furthermore, with conventional rubber suction electrodes, the traces of the suction electrodes that are stuck to the skin surface do not disappear for several days, but with this suction type induction electrode, the traces of the suction electrodes disappear after 1 to 2 hours, and the discomfort disappears. .

Furthermore, the electrode support plate and the electrode plate can be separated so that the electrode plate can be detachably attached to the electrode support plate, which has the advantage of making it easy to replace the electrode plate and making it more convenient. have

[Brief explanation of drawings]

FIG. 1 is a perspective view of a suction type induction electrode according to an embodiment of the present invention, FIG. 2 is an exploded perspective view of the suction type induction electrode of FIG. 1,
Fig. 3 is a plan view of the adsorption type induction electrode shown in Fig. 1 as seen from below, Fig. 4 is a longitudinal sectional view of the adsorption type induction electrode shown in Fig. 1, and Fig. 5 is a diagram showing the adsorption type induction electrode of the present invention mounted thereon. FIG. 6, a perspective view of the biological electrode adsorption device, is an explanatory diagram of a conventional rubber adsorption cap. 18... Adsorption type induction electrode for living body, 22...
... Suction cup, 23 ... Top surface part, 24 ... Close contact piece, 25 ... Open] part, 27 ... Insertion groove, 28 ... ... Fitting groove, 29 ... Communication hole, 30 ... Electrode support plate, 31 ... Nozzle pipe,

Claims (1)

[Claims] It is formed by a top surface part 23 in which an insertion groove 27 and a fitting groove 28 are formed, and an adhesion piece 24 that hangs from the periphery of this top surface part 23 and is curved to match the skin surface of the living body. An elastic cylindrical suction cup 22 having an opening 25 and a communication hole 29 that communicates between the opening 25 and the insertion groove 27, and an electrode fitted into the fitting groove 28 of the suction cup 22. The support plate 30 and the nozzle pipe 31 bonded to the outer surface of the electrode support plate 30 and inserted into the insertion groove 27 of the suction cup 22 contact the skin surface of the living body to transfer the current inside the living body to the outside of the body. This is an adsorption type for living organisms, which is composed of an electrode plate 34 detachably attached to the back surface of the electrode support plate 30 to lead out the electrode, and is made to generate negative pressure in the opening 25 to be adsorbed to the skin surface of the living body. Induction electrode.