KR101267384B1 - Manikin for cpr training - Google Patents

Abstract

PURPOSE: A mannequin for cardiopulmonary resuscitation training is provided to perceive an accurate degree of pressure by detecting how deep the mannequin is pressed according to an angle of rotation by installing a magnet on a surface of a cylinder when the mannequin is pressed in a lower part of the magnetic field sensor. CONSTITUTION: A mannequin for cardiopulmonary resuscitation training includes a body, a guide cylinder(104), a rotary cylinder(106) and a spring(108). The body is made of an elastic material while having an empty space inside. The guide cylinder is as an empty cylinder with an upper part opened, is fixedly installed inside of the body, and a protrusion(104a) is protrusively formed in an inner wall. The rotary cylinder is a cylinder being inserted inside and is moving up and down, wherein a screw type groove(106a) is formed as deep as one pitch and is twistedly descending from up to down and the protrusion is inserted into the screw type groove. The spring generates an elastic force elevating the rotary cylinder to the upside while being installed in between the rotary cylinder and the body. The mannequin for cardiopulmonary resuscitation training further includes a magnet(110) installed in an upper part of the rotary cylinder, a magnetic field sensor(114) detecting a located direction of the magnet by detecting the direction of a magnetic flux of the magnet by being installed in the upper part of the cylinder and a control unit(116) calculating a moving distance showing the descent degree of the rotary cylinder.

Description

CPR training mannequins {MANIKIN FOR CPR TRAINING}

The present invention relates to a cardiopulmonary resuscitation training mannequin, and more particularly, the magnet is installed on the upper portion of the rotating cylinder which is lowered by the pressure, and the magnetic field sensor for sensing the direction of the magnetic force line of the magnet thereon to rotate the magnet CPR training mannequins that allow you to know exactly how much pressure the practitioner has applied by grasping the angle.

Cardiopulmonary resuscitation is a treatment that restores cardiopulmonary function when cardiopulmonary function is severely degraded or stopped. In general, for respiratory dysfunction or respiratory arrest, first ventilate and then perform artificial respiration.

Artificial respiration refers to maintaining the normal breathing by artificially revitalizing the lungs when the heart is beating because of drowning or poisoning or bleeding. Artificial respiration as the first life-saving method includes a breathing method of blowing the exhaler of the operator into the lungs of the patient, and a water artificial breathing method of exerting and exhaling the patient's chest by using the hand. The most common of the breathing method is the oral-to-oral method of expanding the patient's lungs by air blown through the oral cavity to the patient.

In addition, CPR is performed as a method used to revitalize the heart function when the heart beats due to a fall, an electric shock or poisoning. Cardiopulmonary resuscitation is a sternal compression cardiac massage method that presses the sternum down to the spine 3 to 5 to pressurize the heart to eject blood. Commonly referred to as heart massage.

First, secure the patient's airway, check for the presence of breathing, and perform resuscitation if it is stopped. If cardiac arrest is performed, the cardiopulmonary resuscitation procedure that starts the heart massage while continuing the resuscitation is for the human body. Therefore, it is not appropriate for the practitioner or practitioner to repeatedly practice the above process.

Recently, apparatuses for practicing artificial respiration and CPR using a mannequin shaped like a human body have been disclosed.

1 is a perspective view showing the structure of a training mannequin according to the prior art.

As shown in Figure 1, the training mannequin, the mannequin 10 in the shape of the human chest and head, and installed inside the mannequin 10, to confirm that the cardiopulmonary resuscitation training was successfully performed Cardiopulmonary resuscitation confirmation unit 20 for generating a constant confirmation sound during chest compressions and consists of an air bag (30) representing the lungs of the human body.

The mannequin 10 includes a lower plate 40 representing the shape of the back, an upper plate 50 representing the shape of the chest, and a head 60 representing the shape of the head. The lower plate 40 has a predetermined space so that the CPR check unit 20 and the air bag 30 may be installed therein, and is formed in the form of a cabinet in which the front plate is opened. Is in the form of a plate having a predetermined width to open and close the lower plate 40. The head 60 is coupled to the upper end of the lower plate 40, the rotating part 62 in the shape of the jaw of the person is installed at the lower end of the front part of the head 60, the rotating part 62 is up and down It is possible to rotate.

The compression spring 70 is installed between the lower plate 40 and the upper plate 50 so that the upper plate 50 is elastic with respect to external force at the center thereof. Therefore, when the upper plate 50 is pressed inward, the upper plate 50 enters inward while receiving a constant resistance by the compression spring 70. A stopper protrudes upward in the lower portion of the lower plate 40.

The cardiopulmonary resuscitation confirmation unit 20 is composed of a leaf spring having a convex portion on one side and a support bracket 26 for supporting the leaf spring.

The support bracket 26 is spaced apart from the lower plate 40 so as to maintain a predetermined distance, the leaf spring is installed at a position corresponding to the stopper, and the leaf spring generates a sound when the leaf spring collides with the stopper. The convex part of is installed so that it may face the stopper.

In addition, the upper plate 50 is provided with a pressing portion 52 for pressing the leaf spring in a position corresponding to the stopper and the leaf spring. Accordingly, when the upper plate 50 is pressed from the outside, the pressing unit 52 presses the leaf spring to generate a sound.

When performing CPR training using the mannequin 10 in this manner, the practitioner presses the top plate 50 of the mannequin 10 with a strong force and it can be seen that an appropriate compression is made when the sound comes from the leaf spring. However, if the position of the leaf spring is changed or the mannequin 10 is used for a long time, the sound may not be good or the volume of the sound may be less noticed by the practitioner or the instructor.

The present invention for solving the above problems is attached to the magnetic field sensor inside the mannequin resembling the upper body of the human body, by installing a magnet on the surface of the cylinder to move down when rotated when pressed from the bottom of the magnetic field sensor to the rotation angle of the magnet Therefore, the aim of the present invention is to provide a CPR training mannequin that detects how much pressure is pressed so that an accurate level of compression can be determined.

The present invention devised to solve the above problems is a mannequin equipped with a sensing means for grasping the degree pressed by the practitioner practicing CPR is pressed, an empty space is formed inside, the body is made of elastic material 102; A guide cylinder (104) having a hollow inside and having an open top, fixedly installed in the body (102), and having protrusions (104a) protruding from the inner wall; The cylinder is inserted into the guide cylinder 104 and moves up and down, and a spiral groove 106a is formed on the surface of the guide cylinder 104 while being spirally twisted from top to bottom, and the protrusion 104a is recessed. A rotary cylinder 106 inserted into the spiral groove 106a; A spring (108) installed between the rotating cylinder (106) and the inside of the body (102) to generate an elastic force to which the rotating cylinder (106) rises; A magnet (110) installed above the rotating cylinder (106); A magnetic field sensor 114 installed above the rotating cylinder 106 to detect a direction of the magnetic force line of the magnet 110 to determine a direction in which the magnet 110 is placed; Moving distance information indicating a degree to which the rotating cylinder 106 is lowered by using information about a distance of one pitch of the spiral groove 106a and rotation angle information indicating a degree of rotation of the magnet 110. It includes; the control unit 116 to calculate.

의 식을 이용하여 상기 회전원통(106)의 이동거리정보를 계산하는 것을 특징으로 한다.The control unit 116

It is characterized by using the equation to calculate the moving distance information of the rotating cylinder 106.

The control unit 116 generates an audio signal or an image signal for informing the learner by sound or image when the moving distance information is relatively larger or smaller than the reference distance information.

According to the present invention, when performing CPR, it is possible to easily and precisely determine how deep the pressure is, so that the learners who learn CPR can have an accurate training.

1 is a perspective view showing the structure of a training mannequin according to the prior art.
Figure 2 is a partial cutaway perspective view showing the structure of a training mannequin according to an embodiment of the present invention.
Figure 3 is an exploded perspective view showing the structure of the detector.
4 is a plan view showing an installation state of the magnet.
5 is a cross-sectional view showing the internal structure of the sensing unit.
6 is a cross-sectional view showing the internal structure of the state in which the sensing unit is pressed.
7 is a conceptual diagram illustrating a process of detecting rotation of a magnet.
8 is an exploded perspective view showing the structure of a sensing unit according to another embodiment;
9 is a perspective view showing a coupling state of the sensing unit shown in FIG.

Hereinafter, with reference to the drawings will be described "cardiopulmonary resuscitation training mannequin" (hereinafter referred to as "mannequin") according to an embodiment of the present invention.

2 is a partial cutaway perspective view showing the structure of a training mannequin according to an embodiment of the present invention, Figure 3 is an exploded perspective view showing the structure of the detector, Figure 4 is a plan view showing the installation state of the magnet, Figure 5 is the inside of the detector A cross section showing the structure.

The mannequin 100 of the present invention consists of a body 102 having an upper body shape of a human body.

Body 102 is made of a size similar to the human body, and made of a material having the same degree of elasticity as the human body.

An empty space is formed inside the body 102, and pressure sensing means are installed in the empty space, and by installing the sensing means at the same position as the human heart, accurate training as in practice is possible.

The guide cylinder 104 is fixed to the bottom surface of the body 102 at the same position as the heart. The guide cylinder 104 may be made of plastic or metal, which is hollow inside and has an open top.

The protrusion 104a protrudes from the inner wall surface of the guide cylinder 104.

A cylindrical rotating cylinder 106 is inserted into the upper portion of the guide cylinder 104 that is open. While no pressure is applied to the rotating cylinder 106, the lower portion of the rotating cylinder 106 is inserted above the guide cylinder 104, and the practitioner exercises the surface of the body 102 while practicing CPR. When pressed, the rotary cylinder 106 rotates and slides into the guide cylinder 104.

A spring 108 is built in the lower portion of the rotating cylinder 106 to generate an elastic force that the rotating cylinder 106 rises upward. By the elastic force of the spring 108, the rotating cylinder 106 is normally up, and down by the pressure of the practitioner and then up again.

The operation of the rotating cylinder 106 will be described later.

On the surface of the rotating cylinder 106 is formed a spiral groove 106a which is twisted downward while spiraling from the top. The projection 104a of the guide cylinder 104 is inserted into the helical groove 106a, and the depth and the width of the helical groove 106a are preferably equal to or slightly larger than the projection 104a.

The helical groove 106a is formed only by one pitch on the surface of the rotating cylinder 106. That is, following the upper end of the spiral groove 106a to the lower end turns the surface of the rotating cylinder 106 by one turn.

The magnet 110 is installed on the upper portion of the rotating cylinder 106, the magnet 110 is preferably installed in the magnet seating groove 106b formed concave on the upper portion of the rotating cylinder 106.

Magnet 110 may be a variety of forms, including a bar magnet, a straight shape will be most advantageous to determine the degree of rotation.

The upper sensing plate 112 is installed above the rotating cylinder 106, the upper sensing plate 112 is preferably attached to the inner upper surface of the body (102). Therefore, the upper sensing plate 112 can move up and down together with the rotation cylinder 106, but does not rotate, it should be able to grasp the degree of rotation of the rotation cylinder 106.

The magnetic field sensor 114 is installed inside the upper sensing plate 112. The magnetic field sensor 114 has a function of detecting the size and the direction of the magnetic field to detect the direction of the magnet 110 located directly below.

The magnetic field sensor 114 is connected to the separate control unit 116 and transmits a data value detecting the direction of the magnet 110 to the control unit 116. The controller 116 stores information about the direction of the magnet 110 by itself or by using a separate memory, and the distance of one pitch of the spiral groove 106a formed on the surface of the rotating cylinder 106 (of the spiral groove). Height information).

Using the mannequin 100 will be described the principle of training the CPR and the sensing means to detect the degree of compression.

6 is a cross-sectional view showing the internal structure of the sensing unit pressed state, Figure 7 is a conceptual diagram showing a process of detecting the rotation of the magnet.

In the state in which no pressure is applied to the body 102, the rotation cylinder 106 is in the state of being raised upward by the elasticity of the spring 108, and the magnetic field sensor 114 is the magnet 110 in the current state. Detects the direction of the magnetic force line of the magnet 110 to determine in which direction. The direction information (initial state information) of the current magnet 110 grasped by the magnetic field sensor 114 is transmitted to the controller 116.

In order to train the cardiopulmonary resuscitation, the practitioner presses a strong portion of the body where the heart is located in the palm 102, while the pressure is applied to the upper sensing plate 112 and the rotating cylinder 106 located directly below, and down.

The rotary cylinder 106 slides into the guide cylinder 104 by the pressure, and the rotary cylinder 106 is rotated by the protrusion 104a inserted into the helical groove 106a.

The rotating cylinder 106 is rotated in proportion to the depth going down. Since the spiral groove 106a is formed by only one pitch, the rotating cylinder 106 descends to the bottom and the rotating cylinder 106 rotates one wheel ( 360 °). If only half is down, the rotating cylinder 106 will be rotated by half a wheel (180 °).

The magnetic field sensor 114 detects the direction of the magnetic force line in the rotated state and transmits it to the controller 116.

The controller 116 compares the information on the direction of the magnet 110 in the initial direction with the information on the direction of the magnet 110 in the rotated state and calculates rotation angle information, which is a value indicating how much the magnet 110 is rotated. do.

The controller 116 calculates moving distance information, which is a value indicating how much the rotating cylinder 106 has moved down based on the rotation angle information of the magnet 110 and the distance of one pitch of the helical groove 106a.

For example, if the distance of one pitch of the helical groove 106a is 10 cm and the rotation angle of the magnet 110 is 180 °, since the rotation cylinder 106 is lowered by half, the movement distance information will be 5 cm. .

If the distance of one pitch of the helical groove 106a is 9 cm, and the rotation angle of the magnet 110 is 240 °, the rotation cylinder 106 is lowered by two thirds, so that the movement distance information becomes 6 cm. will be.

This is expressed as follows.

The control unit 116 may store the reference distance information, which determines that normal CPR is made only when the pressure is greater than a predetermined distance according to the size of the body 102, and the speaker when the moving distance information is larger than the reference distance information. In addition, monitors and other indications can be used to inform the practitioner or instructor of the correct procedure.

On the contrary, when the moving distance information is smaller than the reference distance information, it may be possible to display information indicating that the degree of CPR compression is lower than the standard, and to display the normal pressure and the pressure that does not meet the standard each time. will be.

To this end, when the moving distance information is relatively large or small compared to the reference distance information, the control unit 116 generates an audio signal or an image signal for informing the learner by sound or image, and transmits it to a speaker or a monitor.

On the other hand, Figure 8 is an exploded perspective view showing the structure of the sensing unit according to another embodiment, Figure 9 is a perspective view showing a coupling state of the sensing unit shown in FIG.

In the above-described embodiment, the spring 108 is installed inside the guide cylinder 104 to function to push the rotary cylinder 106 upward. However, in another embodiment, the spring 108 has a structure that is installed outside the guide cylinder 104. In this case, the upper sensing plate 112 is manufactured to be larger than the diameter of the spring 108. The upper end of the spring 108 is in close contact with the bottom of the upper sensing plate 112 to push up the rotary cylinder 106 coupled with the upper sensing plate 112 upwards.

Since the position or function of the magnet 110, the upper sensing plate 112, and the magnetic field sensor 114 are the same as in the above-described embodiment, a description thereof will be omitted.

While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, As will be understood by those skilled in the art. Therefore, the above-described embodiments are to be understood as illustrative and not restrictive in all respects, and the scope of the present invention is indicated by the appended claims rather than the detailed description, and the meaning and scope of the claims and All changes or modifications derived from the equivalent concept should be interpreted as being included in the scope of the present invention.

100: mannequin 102: body
104: guide cylinder 106: rotating cylinder
108: spring 110: magnet
112: upper sensing plate 114: magnetic field sensor
116:

Claims (3)

As a mannequin equipped with a sensing means for detecting the degree of pressure pressed by the practitioner practicing CPR,
An empty space is formed inside, and the body 102 is made of an elastic material;
A guide cylinder (104) having a hollow inside and having an open top, fixedly installed in the body (102), and having protrusions (104a) protruding from the inner wall;
The cylinder is inserted into the guide cylinder 104 and moves up and down, and a spiral groove 106a is formed on the surface of the guide cylinder 104 while being spirally twisted from top to bottom, and the protrusion 104a is recessed. A rotary cylinder 106 inserted into the spiral groove 106a;
A spring (108) installed between the rotating cylinder (106) and the inside of the body (102) to generate an elastic force to which the rotating cylinder (106) rises;
A magnet (110) installed above the rotating cylinder (106);
A magnetic field sensor 114 installed above the rotating cylinder 106 to detect a direction of the magnetic force line of the magnet 110 to determine a direction in which the magnet 110 is placed;
Moving distance information indicating a degree to which the rotating cylinder 106 is lowered by using information about a distance of one pitch of the spiral groove 106a and rotation angle information indicating a degree of rotation of the magnet 110. Control unit 116 for calculating; containing, CPR training mannequins. The method of claim 1,
The control unit 116

Using the formula of calculating the moving distance information of the rotating cylinder 106, CPR training mannequins. The method of claim 2,
The control unit 116, when the moving distance information is relatively large or small compared to the reference distance information, characterized in that to generate a sound signal or an image signal to inform the practitioner by sound or image, CPR training mannequin.

Images