KR102761325B1 - Pad inspection structure of automatic external defibrillator - Google Patents

Abstract

The present invention relates to a pad inspection structure for an automatic external defibrillator, and more specifically, to a technology for periodically checking the pad status by allowing a pair of pads included in an automatic external defibrillator to be checked by itself to see if they can be used normally, while increasing the reliability of the pad inspection result by measuring an accurate resistance value even under changes in the environment or conditions.
That is, the present invention comprises an impedance measuring liner having a contact layer of a conductive material formed on both sides with a predetermined area in a pad inspection structure of an automatic external defibrillator, a pair of film liners each attached to both sides of the impedance measuring liner and having a plurality of connection holes formed at positions corresponding to the contact layers, and a pair of defibrillation pads attached to the film liner and having gel applied to one side; and the impedance measuring liner is characterized in that the contact layers on both sides are electrically connected to each other through a connecting member, and has a structure capable of measuring the impedance of the gel applied to the defibrillation pad.

Description

{Pad inspection structure of automatic external defibrillator}

The present invention relates to a pad inspection structure for an automatic external defibrillator, and more specifically, to a technology for periodically checking the pad status by allowing a pair of pads included in an automatic external defibrillator to be checked by itself to see if they can be used normally, while increasing the reliability of the pad inspection result by measuring an accurate resistance value even under changes in the environment or conditions.

In general, an automated external defibrillator (AED) is a device that automatically removes atrial fibrillation. When sudden cardiac arrest (SCA) occurs, which is a phenomenon in which the heartbeat stops, blood flow to each tissue is cut off, and the supply of oxygen and other essential functions is cut off, it is a device that delivers an electric shock from outside to return the heartbeat to normal.

The pads (Electrodes Pads) used in the above automated external defibrillator are provided in pairs and are attached to the patient's chest as a means of applying an electric shock. The inside of the pads is coated with gel (hydrogel) so that they can come into close contact with the patient and transmit an electric pulse.

The pad of the automated external defibrillator is provided as a package assembled in the form of an envelope (pouch) or cartridge, including components including a pad that largely forms the exterior, an electrode section that transmits an electric shock, and a conductive sheet coated with gel that allows it to be easily attached to the human body, and the interior of the package is vacuum-sealed and stored.

These pads can have problems such as complete hardening of the gel in the pad or oxidation of the electrode part due to various problems such as damage to the package, management temperature problems, contamination problems due to reuse, and expiration of the use period.

Therefore, it is necessary to periodically check whether the pads in an automated external defibrillator are in normal condition, and a technology for checking the pads has been disclosed by the applicant of the present invention through registered patent No. 10-1236914 (Impedance measuring electrode pad and electrode pad self-diagnosis method) and registered patent No. 10-1259128 (Automatic external defibrillator operation guidance method using impedance measurement of electrode pad).

The above prior art measures impedance by positioning a liner between two pads and bringing the gels of the two pads into contact with each other through a hole formed in the liner. However, in normal times, the impedance value of the gel is low, so there is no problem with measurement. However, in winter, when the temperature is low, the gel temporarily hardens due to the low temperature, making it similar to the patient's impedance, which causes a problem in that it is incorrectly recognized by the automated external defibrillator.

To solve this problem, the applicant of the present invention has solved the problem of incorrect measurement at low temperatures through an impedance bridge made of carbon material with high resistance in registered patent No. 10-1743414 (Pad inspection system for automated external defibrillator).

However, the above prior art has a structural defect that the measured resistance value may vary if the thickness of the carbon resistor is not uniform, and since the impedance bridge is structured to be connected left and right, it is difficult to overlap and arrange the pads when configuring the package.

Registered Patent No. 10-1236914 (Impedance Measuring Electrode Pad and Electrode Pad Self-Diagnosis Method) Registered Patent No. 10-1259128 (Method for guiding the operation of an automated external defibrillator using impedance measurement of electrode pads) Registered Patent No. 10-1743414 (Pad Inspection System for Automated External Defibrillator)

The present invention has been made to solve the above problems, and the purpose of the present invention is to provide a pad inspection structure for an automatic external defibrillator in which impedance measurement is performed through carbon that can come into contact with the gel of both pads, and the contact surface of the carbon is configured to be wide so that the accuracy of the measurement can be increased without being greatly affected by the thickness of the carbon layer, and the pads are arranged to cover the front and back of the impedance circuit liner, thereby increasing storage efficiency and having a structure in which the circuit can be protected.

The present invention relates to a pad inspection structure for an automatic external defibrillator, comprising: an impedance measuring liner having a contact layer of a conductive material formed on both sides with a predetermined area; a pair of film liners each attached to both sides of the impedance measuring liner and having a plurality of connection holes formed at positions corresponding to the contact layers; and a pair of defibrillation pads attached to the film liners and having gel applied to one side; wherein the impedance measuring liner is characterized in that the contact layers on both sides are electrically connected to each other through a connecting member, and has a structure capable of measuring the impedance of the gel applied to the defibrillation pad.

In addition, the connecting member of the impedance measuring liner is characterized by a structure in which it is connected through a via hole formed in the thickness direction.

In addition, the connecting member further includes a resistor having a fixed resistance value, so that the resistance value of the resistor is measured.

In addition, the impedance measurement liner is characterized in that it is composed of a PCB substrate, and the connecting member is composed of a circuit printed on both sides of the substrate.

In addition, the connecting member is characterized by comprising a planar contact portion formed with a certain area in the area of the contact layer, and a connecting line connecting the planar contact portion in the form of a line.

In addition, the above-mentioned surface contact portion is characterized by being formed with a small area compared to the area of the contact layer.

The present invention structurally expands the area of the contact layer that comes into contact with the gel of both pads, so that even if the thickness of the contact layer is not uniform to some extent, it can be ignored, thereby increasing the measurement reliability.

The present invention fundamentally prevents the problem of incorrect recognition due to the gel impedance of the defibrillation pad increasing in sub-zero weather and overlapping with the impedance of the human body by further applying a resistor having a fixed resistance value to a connecting member, and has the functional effect of allowing accurate judgment in the event of a problem with the defibrillation pad.

In addition, the present invention can increase storage efficiency when configuring a package by applying a structure that can be placed and covered on both sides based on an impedance measurement liner, and can prevent the circuit from being disconnected by pulling or damaged by physical impact.

Figure 1 is an exploded perspective view showing the pad inspection structure of an automatic defibrillator according to the present invention.
Figure 2 is a drawing showing the configuration of an impedance measuring liner in the pad inspection structure of the present invention.
Figure 3 is a drawing showing the configuration of a film liner in the pad inspection structure of the present invention.
Figure 4 is a drawing showing a defibrillation pad in the pad inspection structure of the present invention.
Figure 5 is a drawing showing the cross-sectional structure of an impedance measuring liner applied to the present invention.
Figure 6 is a graph showing a constant impedance value of a defibrillation pad through a connecting member including a resistor in the pad inspection structure of the present invention.
FIG. 7 is a drawing showing another embodiment of the pad inspection structure of the present invention.
Fig. 8 is a bottom view that clearly shows the structure of the embodiment of Fig. 7.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the attached drawings. In addition, in describing the present invention, if it is determined that a specific description of a related known function or configuration may unnecessarily obscure the gist of the present invention, the detailed description will be omitted.

The present invention relates to a technology regarding a pad inspection structure of an automatic external defibrillator, and as illustrated in FIG. 1, the structure comprises an impedance measuring liner (100) having a contact layer (110) of a conductive material formed on each side with a predetermined area, a pair of film liners (200) each attached to both sides of the impedance measuring liner (100) and having a plurality of connection holes (210) formed at positions corresponding to the contact layers (110), and a pair of defibrillation pads (300) attached to the film liner (200) and having a gel applied to one side; and the impedance measuring liner (100) is characterized in that the contact layers (110) on both sides are electrically connected to each other through a connecting member (120) so as to have a structure capable of measuring the impedance of the gel applied to the defibrillation pad (300).

In the present invention, the defibrillation pads (300) are composed of a pair and are an important component of an automatic external defibrillator that is directly attached to the patient's body when used on an actual patient and supplies electric energy. The defibrillation pads (300) are connected to the automatic external defibrillator body (10) through a wire (310) and measure the patient's impedance through an impedance measurement circuit inside the body.

The above defibrillation pad (300) and the main body are known components of an automatic defibrillator, and a detailed description thereof will be omitted in the present invention.

The impedance measuring liner (100) of the present invention is a core component intended to measure the impedance of a gel applied to a defibrillation pad (300) in a storage state, and as shown in Fig. 1, a pair of film liners (200) and a defibrillation pad (300) are packaged in a form in which the impedance measuring liner (100) is centered and the defibrillation pad (300) is covered in the front and back.

The above impedance measurement liner (100) has a contact layer (110) made of a conductive material formed on both sides with a certain area. The contact layer (110) is a portion that comes into contact with the gel of the defibrillation pad (300), and is preferably applied with a carbon material. Since the contact layer (110) made of a carbon material can be formed by being applied over a large area on the impedance measurement liner (100), even if the thickness of the contact layer (110) is not uniform to some extent, it is a structure that can increase measurement reliability because it corresponds to a level that can be ignored.

In addition, the impedance measuring liner (100) of the present invention has a structure in which the contact layers (110) on the front and back sides are electrically connected to each other through a connecting member (120), so that the impedance of the gel applied to both defibrillation pads (300) can be measured.

In order to achieve this structure, the connecting member (120) is structured to be connected through a via hole (130) formed in the thickness direction.

In addition, the connecting member (120) of the present invention further includes a resistor (140) having a fixed resistance value as illustrated in the drawing, so that the resistance value of the resistor (140) is measured. The resistor (140) serves as a reference resistance value when measuring the gel impedance of the defibrillation pad (300), and a resistor (140) having a higher resistance value than the impedance value of the human body should be applied so that it can accurately determine whether the defibrillation pad (300) is attached to the patient's body or to the impedance measurement liner (100).

In this way, if a resistor (140) having a fixed resistance value is further applied to the connecting member (120), the problem of incorrect recognition due to the gel impedance of the defibrillation pad (300) increasing in sub-zero weather and overlapping with the impedance of the human body in the prior art can be fundamentally prevented.

As a preferred example of the above impedance measurement liner (100), it is preferred that the impedance measurement liner (100) itself be configured as a PCB substrate, and that the connecting member (120) be configured as a circuit printed on both sides of the substrate. In addition, it is preferred that the impedance measurement liner (100) be applied as a PCB substrate, and that the remaining area except for the contact layer (110) be coated with PSR (Photo Solder Resist) ink for protection.

The above connecting member (120) is composed of a printed circuit, and it is preferable that the material be copper, which allows electricity to flow well. As shown in the drawing, the specific configuration comprises a surface contact portion (121) formed with a certain area in the area of the contact layer (110), and a connecting line (122) connecting the surface contact portion (121) in the form of a line.

The above surface contact portion (121) is formed with a smaller area compared to the area of the contact layer (110) as shown in the drawing. When configured in this manner, the surface contact portion (121) made of copper is first formed on the impedance measurement liner (100) corresponding to the PCB substrate, and a carbon material contact layer (110) can be formed in a form in which it covers the upper portion of the surface contact portion (121) with an area larger than the area of the surface contact portion (121).

The copper surface contact portion (121), which can be corroded by moisture, is structured so that it is not affected at all by moisture in the gel of the defibrillation pad (300) through the contact layer (110) as described above, thereby preventing the problem of the surface contact portion (121) being corroded.

The film liner (200) of the present invention is configured to be positioned between the impedance measurement liner (100) and the defibrillation pad (300) as described above, and is configured as a pair, similar to a pair of defibrillation pads (300).

The above film liner (200) is configured to ensure that the defibrillation pad (300) is well fixed to the impedance measurement liner (100) during storage, while allowing the defibrillation pad (300) to be easily removed during use. Accordingly, the film liner (200) is treated with an adhesive on the surface that comes into contact with the impedance measurement liner (100), and is treated with a silicone release agent on the surface that comes into contact with the defibrillation pad (300).

And the film liner (200) has a number of connection holes (210) formed at positions corresponding to the contact layer (110) so that the gel of the defibrillation pad (300) can come into contact with the contact layer (110) for impedance measurement during storage. The size and area of the connection holes (210) are not particularly limited, but if they are too small, the impedance measurement may be affected, and if they are too large, it may be difficult to remove the defibrillation pad (300) due to the adhesive strength of the gel. Therefore, it is preferable to have an appropriate size and area.

The present invention, which is accomplished in this manner, measures the impedance value of the resistor (140) at a constant level as shown in Fig. 6 through a connecting member (120) including a resistor (140), thereby enabling the following to be determined.

First, when the gel of the defibrillation pad (300) is hardened by exposure or high temperature, if the measured impedance of the gel is higher than the fixed impedance value of the resistor (140) and exceeds a preset threshold value, it can be determined that the defibrillation pad (300) is damaged.

Second, when using an AED, the measured impedance can be measured and judged to be the impedance value when attached to a person or higher than a fixed resistance value, thereby providing accurate guidance on attaching pads to the AED.

Figures 7 and 8 illustrate another embodiment of the present invention, wherein the impedance measuring liner (100) is characterized in that a protective member (150) is further provided on the surface where the resistor (140) is located, the protective member (150) protruding more than the protrusion height of the resistor (140). The protective member (150) is installed only on the surface where the resistor (140) is located, and is preferably placed on both sides based on the resistor (140).

The above protective material (150) prevents the resistor (140) from being damaged by external impact or pressure, and is structured so that external physical influences are transmitted to the protective material (150) rather than the resistor (140) because it protrudes further than the resistor (140).

Although the present invention has been described above with reference to the above embodiments, it is of course possible to make various modifications within the technical scope of the present invention.

10: Defibrillator body
100 : Impedance measurement liner
110 : Contact layer
120 : Connection part
121: Surface contact area
122 : Connection line
130 : Via Hall
140 : Resistor
150 : Protective material
200 : Film Liner
210 : Connection hole
300 : Defibrillation pad
310 : Frontline

Claims (6)

In the pad inspection structure of the automated external defibrillator,
An impedance measurement liner (100) having a contact layer (110) of conductive material formed on each side with a certain area,
A pair of film liners (200) each attached to both sides of the above impedance measurement liner (100) and having a number of connection holes (210) formed at positions corresponding to the contact layer (110),
It consists of a pair of defibrillation pads (300) attached to the above film liner (200) and having gel applied on one side;
The above impedance measuring liner (100) is structured so that the contact layers (110) on both sides are electrically connected to each other through a connecting member (120), and the impedance of the gel applied to the defibrillation pad (300) can be measured.
A pad inspection structure of an automatic external defibrillator, characterized in that the connecting member (120) of the above impedance measuring liner (100) is connected through a via hole (130) formed in the thickness direction.
delete In paragraph 1,
A pad inspection structure of an automatic external defibrillator characterized in that the connecting member (120) further includes a resistor (140) having a fixed resistance value so that the resistance value of the resistor (140) is measured.
In paragraph 1,
A pad inspection structure of an automatic defibrillator, characterized in that the above impedance measurement liner (100) is composed of a PCB board, and the connecting member (120) is composed of a circuit printed on both sides of the board.
In paragraph 4,
The above connecting member (120) is characterized by comprising a surface contact portion (121) formed with a certain area in the area of the contact layer (110), and a connecting line (122) connecting the surface contact portion (121) in the form of a line; a pad inspection structure of an automatic external defibrillator.
In paragraph 5,
The pad inspection structure of an automatic defibrillator is characterized in that the above-mentioned surface contact portion (121) is formed with a smaller area compared to the area of the contact layer (110).