KR101858659B1 - Simulator for emergency medical training - Google Patents

Abstract

The emergency medical training simulator according to the present invention includes a human body model, a training module device, and a control unit. The human body model is made in a shape similar to that of the whole human body. The training module device is mounted on the human body. It includes a chest compressing training module for training CPR, a tracheal intubation training module for training the tracheal intubation, a defibrillation training module for training the use of defibrillation, An electrocardiogram examination training module for training, a stethoscope training module for training a heart sound or a closed stethoscope, an intravenous training module for training an intravenous injection, a blood pressure examination training module for training a blood pressure test, A pupil examination training module for training the pupil examination, and a pulse test training module for training the pulse examination. The control unit controls the training module device to implement the case of the emergency patient, and receives and processes the data from the training module device.

Description

[0001] The present invention relates to a simulator for emergency medical training,

The present invention relates to a simulator for emergency medical training, and more particularly, to a simulator capable of emergency medical training through implementation of an emergency patient case.

Emergency medical care refers to the immediate and temporary treatment of an emergency patient in the event of a variety of diseases, accidents or disasters that threaten human life, before the patient can receive medical treatment. Emergency medical care is time consuming and should be done with careful observation of the patient's condition. In particular, in emergency patients with cardiac arrest, the resurgence rate of the patient is reduced by 7 to 10% each time emergency medical treatment is delayed by one minute. There is a statistic that it is reduced to 50% after 4 minutes after cardiac arrest, and more likely to progress to biological death after 6 minutes. Therefore, rapid on-site emergency care is a very important factor that can improve the survival rate of emergency patients.

Currently, the training course of Emergency Medical Officer is mostly focused on theoretical lectures and the experience of clinical practice is very limited. Therefore, proper clinical practice is not possible for emergency patients. Recently, human model simulator training has been utilized as a practical tool in medical education field. However, in the case of emergency training simulator training for emergency medical personnel, the supply and utilization is low. In the case of the simulator for emergency medical training, since it is possible to practice only a few simple emergency medical services rather than scenarios, it is not possible to expect the skilled skill of the job skill.

In the case of the human model simulator commercialized for the emergency medical training, there is a burden to purchase due to the expensive price, and there is a lot of inconvenience in practice due to lack of realism. In addition, there are various functional problems such as lack of body temperature generating function. In addition, due to the absence of a humanoid model simulator integrated with functions suitable for training, a human model capable of performing individualized unit training such as a separate airway intubation model, intravenous injection model, blood pressure / pulse measurement model, and CPR human model And training is being used.

An object of the present invention is to provide an emergency medical training simulator capable of realizing realistic emergency medical training in association with actual emergency patients.

According to an aspect of the present invention, there is provided an emergency medical training simulator including a human body model, a training module, and a control unit. The human body model is made in a shape similar to that of the whole human body. The training module device is mounted on the human body. It includes a chest compressing training module for training CPR, a tracheal intubation training module for training the tracheal intubation, a defibrillation training module for training the use of defibrillation, An electrocardiogram examination training module for training, a stethoscope training module for training a heart sound or a closed stethoscope, an intravenous training module for training an intravenous injection, a blood pressure examination training module for training a blood pressure test, A pupil examination training module for training the pupil examination, and a pulse test training module for training the pulse examination. The control unit controls the training module device to implement the case of the emergency patient, and receives and processes the data from the training module device.

According to the present invention, a fire-fighting paramedic, a doctor, a nurse, etc. can be used for emergency medical care such as CPR, airway intubation, defibrillator use, electrocardiography, cardiac / pulmonary stethoscope, intravenous injection, blood pressure test, body temperature test, Can be realistic and reminiscent of emergency patients. In addition, according to the present invention, the actual performance and the ability to respond to emergency patients can be improved by recording and evaluating the objective performance and the status of the training based on the training data.

1 is a view schematically showing a simulator for emergency medical training according to an embodiment of the present invention.
Fig. 2 is a configuration diagram of the simulator for emergency medical training shown in Fig. 1. Fig.
FIG. 3 is a perspective view of the chest compression training module in FIG. 2; FIG.
FIG. 4 is an exploded perspective view of FIG. 3. FIG.
5 is a side view of Fig.
Fig. 6 is a side view showing the chest plate in a pressurized state in Fig. 5;
Figure 7 is a perspective view of the airway intubation training module in Figure 2;
Figure 8 is a side view of the esophagus and airway in Figure 7;
FIG. 9 is a block diagram showing a defibrillation training module, an electrocardiogram examination training module, and a stethoscope training module in FIG.
Figure 10 is a perspective view of the intravenous injection training module in Figure 2;
FIG. 11 is a perspective view of the blood pressure monitoring training module in FIG. 2; FIG.
Figure 12 is a side view of the body temperature testing training module in Figure 2;
Figure 13 is a side view of the pupil examination training module in Figure 2;
14 is a perspective view of the pupil inspection training module shown in FIG.
Figure 15 is a side view of the pulse test training module in Figure 2;

The present invention will now be described in detail with reference to the accompanying drawings. Here, the same reference numerals are used for the same components, and a detailed description of known functions and configurations that may unnecessarily obscure the gist of the present invention will be omitted. Embodiments of the present invention are provided to more fully describe the present invention to those skilled in the art. Accordingly, the shapes and sizes of the elements in the drawings and the like can be exaggerated for clarity.

1 is a view schematically showing a simulator for emergency medical training according to an embodiment of the present invention. Fig. 2 is a configuration diagram of the simulator for emergency medical training shown in Fig. 1. Fig.

Referring to FIGS. 1 and 2, the emergency medical training simulator includes a human body model 100, a training module device 200, and a control unit 300.

The human body model 100 has a shape similar to that of the human body. That is, the manikin 100 includes a body 110, a neck 120, a head 130, an arm 140, and a leg 150. The human body model 100 is composed of a material such as silicone or urethane which is similar to the elasticity of actual skin. The arm 140 and the leg 150 of the human body model 100 are configured to reproduce the degree of freedom of the human body joint to increase the sense of reality.

The training module device 200 is mounted on the human body model 100 and includes a chest compressing training module 210 for training CPR, a tracheal intubation training module 220 for training a tracheal intubation, An electrocardiogram examination training module 236 for training an electrocardiogram examination, a stethoscope training module 240 for training a heart sound or a pulmonary sound stethoscope, a venous puncture training module 240 for training an intravenous injection, A blood pressure test training module 260 for training a blood pressure test, a body temperature test training module 270 for training a body temperature test, a pupil examination training module 280 for training a pupil examination, And a pulse test training module 290 for training a pulse test.

The control unit 300 controls the training module device 200 to implement a case of an emergency patient, and receives and processes data from the training module device 200. The control unit 300 may transmit the processed signal to the monitoring device 400. [ The data transmitted to the monitoring device 400 may be provided to the user as evaluation data through a screen of the monitoring device 400. When the control unit 300 receives the control signal for the training module device 200 from the monitoring device 400, the control unit 300 controls the driving of the training module device 200 based on the received control signal.

The control unit 300 may control the training module device 200 based on a training program scenario suitable for various predetermined emergency medical field situations. Here, the scenario includes human body change information that may appear when an emergency medical situation occurs. The control unit 300 may control the training module device 200 based on a scenario inputted by the user or a previously stored scenario through the monitoring device 400. [

The controller 300 may be embedded in the manikin 100. The controller 300 can communicate with the monitoring device 400 in a wired or wireless manner. The monitoring device 400 may include an input / output device. The input / output device may be based on a GUI (Graphical User Interface) for the convenience of the user.

The above-mentioned emergency medical training simulator enables realistic emergency medical training and objective evaluation in a field emergency situation by constructing and providing various simulation scenarios necessary for emergency medical treatment to the Korean environment.

FIG. 3 is a perspective view of the chest compression training module in FIG. 2; FIG. FIG. 4 is an exploded perspective view of FIG. 3. FIG. 5 is a side view of Fig. Fig. 6 is a side view showing the chest plate in a pressurized state in Fig. 5;

3 to 6, the chest compression training module 210 includes a chest plate 211, a main spring 212, a support member 213, a link plate 214, a sub spring 215, And a displacement measuring unit 217.

The chest plate 211 is formed similar to the chest of the human body and is disposed forward of the back plate 111 of the body 110 in the body 110. [ The chest plate 211 may be made of urethane or the like having elasticity similar to the actual skin. The chest plate 211 may be shaped like a human rib.

In a state where the back plate 111 is horizontally laid out, the chest plate 211 moves up and down with respect to the back plate 111 in accordance with the chest compression operation of the user. The upper portion of the chest plate 211 may be formed to be inclined from the lower portion to the link plate 214 side. The lower portion of the chest plate 211 may be formed so as to be positioned in parallel with the back plate 111 in an unpressurized state.

The main spring 212 is installed between the chest plate 211 and the back plate 111 to provide an elastic restoring force to the chest plate 211. The main spring 212 may be a compression coil spring. When the user presses the chest plate 211 in a state where the main spring 212 is installed between the chest plate 211 and the back plate 111, as the chest plate 211 descends and the main spring 212 contracts Elastic restoring force is generated.

When the pressing force on the chest plate 211 is released, the chest plate 211 can be automatically raised by the elastic restoring force of the main spring 212. The main spring 212 can be supported on the chest plate 211 and the back plate 111 by the first and second fixing members 216a and 216b.

The support member 213 is disposed above the chest plate 211 and fixed to the front surface of the back plate 111. The support member 213 protrudes at a predetermined height, and a link plate 214, which will be described later, is rotatably connected to the protruding front end. The support member 213 plays a role similar to the rat bone of the human body.

The upper end of the link plate 214 is rotatably connected to the support member 213 in a forward and backward direction and the lower end of the link plate 214 is rotatably connected to the rear surface of the chest plate 211. For example, the link plate 214 may include a central base portion 214a, a pair of upper extensions 214b, and a pair of lower extensions 214c.

The upper extension portions 214b extend upwardly from the central base portion 214a in two halves. The upper side extension portions 214b may be formed to have a larger interval than the lower side extension portions 214c. The upper extension portions 214b are rotatably connected to the support member 213 by a hinge shaft. In this case, the support member 213 may include a pair of support brackets 213a corresponding to the upper extension portions 214b. The upper extension portions 214b may be connected to the support brackets 213a by hinge shafts, respectively.

The lower extension 214c extends bifurcated from the central base 214a to the lower side with the main spring 212 interposed therebetween. Thus, the main spring 212 passes between the lower extension portions 214c and can operate without interference by the link plate 214. [ The lower extension portions 214c are rotatably hingedly connected to the back surface of the chest plate 211 back and forth. Here, the lower ends of the lower extension portions 214c are disposed below the first fixing member 216a.

The sub spring 215 is installed between the chest plate 211 and the link plate 214 to elastically support the chest plate 211 with respect to the link plate 214. The sub spring 215 may be a compression coil spring. The sub spring 215 allows the distance between the chest plate 211 and the link plate 214 to be adjusted according to the stretching operation.

The sub springs 215 may be provided as a pair. The sub springs 215 may be disposed at left and right intervals. The sub springs 215 may be disposed close to the upper end of the chest plate 211. Each of the sub springs 215 can be supported on the chest plate 211 and the link plate 214 by the third and fourth fixing members 216c and 216d.

The displacement measuring unit 217 measures the displacement of the chest plate 211 in response to the pressure of the chest plate 211 and provides the measured displacement to the control unit 300. The control unit 300 can calculate the pressing depth of the chest plate 211, the pressing speed, and the pressing frequency based on the position information of the chest plate 211 provided from the displacement measuring unit 217. [ The displacement measuring unit 217 may be constituted by an optical distance sensor or the like.

The chest compression device 210 of the above-described configuration can act as follows. When the user presses the chest plate 211, the link plate 214 rotates clockwise about the hinge axis of the support member 213. [ As a result, the chest plate 211 is lowered and rotated clockwise about the hinge axis of the support member 213, so that the lower portion is inclined.

At this time, since the pressing force in the direction perpendicular to the back plate 111 is applied to the chest plate 211, the interval between the chest plate 211 and the link plate 214 is narrowed due to the contraction of the sub spring 215. Accordingly, since the chest plate 211 rotates counterclockwise about the connection portion with the link plate 214, the inclined angle of the lower side of the chest plate 211 can be reduced. As a result, the lower portion of the chest plate 211 is inclined downward at an angle of about 5 to 10 degrees with respect to the support shaft 213 as a reference axis, so that it can be realized in a manner similar to the actual chest deformation of the human body.

Figure 7 is a perspective view of the airway intubation training module in Figure 2; Figure 8 is a side view of the esophagus and airway in Figure 7;

As shown in FIGS. 7 and 8, the airway intubation training module 220 may include an airway model 211, and a airway intubation sensing portion 212. The airway model 211 includes an oral cavity 211a formed on the face of the human body model 100 and a airway 211b embedded in the neck 120 and the body 110 of the human body model 100 in communication with the mouth 211a, And esophagus 211c. The intubation intubation sensing unit 212 senses the intubation of the airway 211b and provides it to the control unit 300. [

The intubation intubation sensing unit 212 may include a hall sensor 212a and a magnet 212b. The hall sensor 212a and the magnet 212b may be installed so as to face each other on the outside of the airway 211b of the airway model 211 and the esophagus 211c. Here, the hall sensor 212a and the magnet 212b may be disposed on both sides of the gate of the airway model 211.

When the intubation tube is inserted into the airway 211b, the airway 211b is stretched by the intubation tube, causing a change in the distance between the hall sensor 212a and the magnet 212b. The hall sensor 212a outputs a voltage in accordance with a change in distance from the magnet 212b, thereby enabling to detect whether or not air intubation is performed. Although not shown, the airway intubation sensing unit 212 may be further disposed along the airway 211b to sense the airway intubation depth.

The esophagus 211c may be provided with an esophageal intubation sensing unit 213 for sensing an intubation of the esophagus 211c. The esophageal intubation sensing unit 213 includes a hall sensor 213a and a magnet 213b. The hall sensor 213a and the magnet 213b are arranged to face each other at the starting position of the esophagus 211c.

When the intubation tube is inserted into the esophagus 211c, the esophagus 211c is stretched by the intubation tube and the distance between the hall sensor 213a and the magnet 213b is changed. The hall sensor 213a outputs a voltage corresponding to a change in distance from the magnet 213b, thereby enabling detection of intestinal intubation.

The airway 211b may have a protrusion 214 protruding toward the esophagus 211c at a portion where the human cartilage is formed. In this case, the esophagus 211c is equipped with a pressure sensor 215 for sensing the pressurization of the protrusion at a position facing the protrusion 214. [

When the user presses the protruding portion 214 by manually pressing the ring cartilage, the pressure sensor 215 outputs a voltage in response to the pressing of the protruding portion 214, so that the ring cartilage compression can be sensed. The ring cartilage compression is performed by manually pressing the ring cartilage located at the upper part of the airway (211b) during the intubation of the airway to facilitate the insertion of the intubation tube into the airway (211b) and prevent the stomach contents from flowing backward.

FIG. 9 is a block diagram showing a defibrillation training module, an electrocardiogram examination training module, and a stethoscope training module in FIG.

9, the defibrillation training module 231 may include defibrillation electrodes 232, and an electric shock measuring unit 233. [ The defibrillation electrodes 232 are disposed on the chest of the manikin 100 to which a defibrillation shock is applied, and disposed on the lower side of the right subclavian bone and the lower side of the left nipple, respectively.

The defibrillation electrode 232 is provided with a protrusion formed on the pad of the defibrillator and a groove which is detachable therefrom, so that the defibrillation electrode 232 can be attached and detached in a snap manner to the defibrillator pad. The electric shock measuring unit 233 measures the number of electric shocks applied to the defibrillation electrodes 232 and provides the electric shock to the controller 300.

The electric shock measuring unit 233 may include a voltage divider 233a and a voltage comparator 233b. The voltage divider 233a drops the defibrillation shock voltage input through the defibrillation electrodes 232 during the actual defibrillation by the defibrillator and outputs the defibrillation shock voltage to the voltage comparator 233b. The voltage comparator 233b allows the voltage to be input to the controller 300 when the input voltage is higher than the reference voltage, thereby enabling the number of times of the electric shock to be measured.

A high voltage of about 150 to 200J is applied to the defibrillation electrodes 232. The voltage divider 233a prevents the high current from flowing into the controller 300 by using a high capacity low resistance, To protect the circuitry of the device.

9, the electrocardiogram examination training module 236 includes an electrocardiogram signal generator 237 and an electrocardiogram electrode 238. [ The electrocardiogram signal generator 237 generates the electrocardiogram signal having the characteristics of the actual electrocardiogram signal by the controller 300. [ That is, the electrocardiogram signal generator 237 can implement an analog signal having characteristics such as shape, amplitude, and the like of the waveform of the actual electrocardiogram signal.

Electrocardiogram electrodes 238 are arranged above the right chest of the human body model 100, above the left chest and below the left chest, and output electrocardiogram signals received from the electrocardiogram signal generator 237. Thus, the user can train similarly to measuring an electrocardiogram of an actual human body using an electrocardiogram device.

As shown in FIG. 9, the stuttering training module 240 may include a heart sound speaker 241, and a closed speaker 242. The heart sound speaker 241 is disposed at four places in the heart of the human body model 100 and outputs heart sounds for each case by the controller 300. The closed loudspeaker 242 is disposed on the upper left and upper right and upper and lower ends of the manikin 100 and the bronchial tree, and the controller 300 outputs closed sounds according to the case. Therefore, the user can train the stethoscope similar to stethoscoping the actual heart sound of the human body using the stethoscope.

Figure 10 is a perspective view of the intravenous injection training module in Figure 2;

10, the intravenous injection training module 250 may include a skin pad 251, a liquid supply container 252, and a pump 253. The skin pad 251 is mounted on the arm 140 of the human body model 100 and a blood vessel simulation tube 251a is formed in the fat layer 251b. The outside of the skin pad 251 can be covered with a simulated skin 251c made of silicone and simulating the skin.

The liquid supply container 252 stores liquid for replicating blood. The liquid supply container 252 can be connected to the blood vessel simulation tube 251a by the liquid transfer tube 252a. The pump 253 is controlled by the control unit 300 to supply the liquid stored in the liquid supply container 252 to the blood vessel simulation tube 251a at a speed similar to the blood circulation speed of the human body. The pump 253 may be omitted. In this case, the liquid supply container 252 is positioned higher than the skin pad 251 so that the liquid can be smoothly supplied to the skin pad 251 due to the height difference. Therefore, the user can train similarly to performing intravenous injection to the actual human body.

FIG. 11 is a perspective view of the blood pressure monitoring training module in FIG. 2; FIG.

11, the blood pressure monitoring training module 260 may include a pressure sensor 261, and a blood pressure output section 262. [ The pressure sensor 261 measures the pressure applied to the cuff of the blood pressure monitor mounted on the arm 140 of the human body model 100 and provides the pressure to the control unit 300. The pressure sensor 261 is embedded in the arm 140 of the manikin 100.

The blood pressure output unit 262 is built in the arm 140 of the human body model 100 and outputs a Korotkoff sound according to the set blood pressure value based on the pressure measured from the pressure sensor 261 300). The blood pressure output unit 262 may be a speaker.

The control unit 300 compares the pressure of the blood pressure monitor cuff measured by the pressure sensor 261 with the preset blood pressure value, and if the pressure of the blood pressure monitor cuff is not more than the systolic pressure and the diastolic pressure or more, (262). Therefore, the user can train similarly to checking blood pressure on a real human body using a blood pressure monitor.

Figure 12 is a side view of the body temperature testing training module in Figure 2;

12, the body temperature examination training module 270 includes a heat generating portion 271, a temperature sensor 272, and a heat dissipation housing 273. [ The heating unit 271 is built in the ear 131 of the human body model 100 and generates heat having a set body temperature value by the control unit 300. The heating portion 271 may include an exothermic resistance that generates heat by current flow.

The temperature sensor 272 measures the temperature of the heat generated in the heating unit 271 and provides the measured temperature to the control unit 300. The control unit 300 can adjust the temperature of the heat generating unit 271 by comparing the measured temperature from the temperature sensor 272 with the set body temperature value. The heat dissipation housing 273 dissipates heat generated in the heat generating portion 271 to lower the temperature, thereby allowing the temperature of the heat generating portion 271 to be adjusted. Thus, the user can train similar to using a thermometer to check the body temperature of an actual human body.

Figure 13 is a side view of the pupil examination training module in Figure 2; 14 is a perspective view of the pupil inspection training module shown in FIG.

13 and 14, the pupil examination training module 280 may include a light amount measuring unit 281, a diaphragm 282, and a diaphragm driving unit 283. The light amount measuring unit 281 measures the amount of light introduced through the pupil formed on the face of the human body model 100 and provides the measured light amount to the control unit 300. The diaphragm 282 is installed in the pupil and is opened or closed according to the amount of light measured by the light amount measuring unit 281 to realize the pupil reflex function. The diaphragm driver 283 is controlled by the controller to open and close the diaphragm 282.

The diaphragm 282 is configured such that the diaphragm blades 282a rotate as the rotation lever 282b rotates to expand or contract the central aperture. The diaphragm 282 may be constructed of a conventional diaphragm. The diaphragm driving unit 283 may include a rotary motor 283a and a link mechanism 283b that receives the rotational force of the rotary motor 283a and rotates the rotary lever 282b of the diaphragm 282. [

The control unit 300 rotates the rotary motor 283a in one direction to close the diaphragm 282 when the light amount measured from the light amount measuring unit 281 is larger than the set light amount value, The rotation motor 283a is rotated in the opposite direction to open the diaphragm 282 to realize a pupil reaction state. Thus, the user may be trained similarly to examining the pupil of an actual human body.

Figure 15 is a side view of the pulse test training module in Figure 2;

As shown in FIG. 15, the pulse test training module 290 may include a pulse-driven speaker 291 and a blood vessel structure 292. The pulse-driven speaker 291 is built in the arm 140 of the manikin 100 and vibrates based on the pulse sound source received from the control unit 300. [ The blood vessel structure 292 implements movement similar to the pulse of the human body in accordance with the vibration of the pulse-driven speaker 291.

The pulse-driven speaker 291 may include a voice coil 291a and a diaphragm 291b. The voice coil 291a vibrates based on the pulse sound source received from the control unit 300 and the diaphragm 291b is positioned at one end of the voice coil 291a and is vibrated by the vibration of the voice coil 291a. The vascular structure 292 vibrates in response to the vibration of the diaphragm 291b, so that a movement similar to a pulse of the human body can be realized. Thus, the user can train similar to checking the pulse of a real human body.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be taken by way of limitation and that those skilled in the art will recognize that various modifications and equivalent arrangements may be made therein. It will be possible. Accordingly, the true scope of protection of the present invention should be determined only by the appended claims.

100 .. Human body model
200 .. Training Module Device
210 .. Chest Compression Training Module
220 .. Prayer Intubation Training Module
231 .. Defibrillation Training Module
236 .. ECG Examination Training Module
240 .. Stethoscope training module
250 .. IV Training Module
260 .. Blood Pressure Examination Training Module
270 .. Body temperature examination training module
280 .. Pupil Examination Training Module
290 .. Pulse Examination Training Module
300.
400 .. Monitoring device

Claims (3)

delete A human body model having a shape similar to that of a human whole body;
A chest compression training module for training CPR, an airway intubation training module for training air intubation, a defibrillation training module for training the use of defibrillation, An electrocardiographic examination training module, a stethoscope training module for training cardiac or pulmonary stethoscope, an intravenous training module for training intravenous injection, a blood pressure test training module for training blood pressure test, a body temperature training A training module, including a training module, a pupillary examination training module for training a pupil examination, and a pulse testing training module for training a pulse test; And
And a controller for controlling the training module device to implement a case of an emergency patient and to receive and process data from the training module device,
The defibrillation training module includes:
Defibrillation electrodes disposed on the chest of a human body model to which a shock is applied and disposed on the lower side of the right subclavian bone and the lower side of the left nipple respectively and the number of electric shocks applied to the defibrillation electrodes is measured and provided to the controller And an electric shock measuring unit having a voltage divider and a voltage comparator,
Wherein the voltage divider drops a defibrillation shock voltage input through the defibrillation electrodes during an actual defibrillation by the defibrillator and outputs the defibrillation shock voltage to the voltage comparator,
The voltage comparator allows the voltage to be input to the control unit when the input voltage is higher than the reference voltage, thereby measuring the number of times of the electric shock. The voltage comparator also prevents a high current from flowing into the control unit using a high- Lt; / RTI >
The chest compression training module comprises:
A chest plate which is formed similar to a chest of a human body and is disposed in front of the back plate of the body in the body of the human body,
A main spring installed between the chest plate and the back plate to provide an elastic restoring force to the chest plate,
A support member disposed above the chest plate and fixed to the front surface of the back plate,
A link plate having an upper end connected to the support member so as to be rotatable back and forth, and a lower end rotatably connected to the rear surface of the chest plate,
A sub spring installed between the chest plate and the link plate to support the chest plate against the link plate by elastic force,
And a displacement measuring unit for measuring the position of the chest plate and providing the measured position to the control unit.
3. The method of claim 2,
The airway intubation training module comprises:
An airway model communicating with the oral cavity formed on the face of the human body model and having the airway and esophagus embedded in the neck and the body of the human body model,
And an airway intubation sensing unit for sensing an intubation of the airway and providing the airway intubation sensing unit to the control unit.

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