KR101973139B1 - Cardiopulmonary resuscitation simulator for self-learning and evaluation - Google Patents

Abstract

The present invention relates to a CPR simulator for self-learning and evaluation. A chest compression training module measures compression training information when compressing the chest of a dummy. An artificial respiration training module measures respiration training information during artificial respiration through the oral cavity of the dummy. A control unit is installed in the body part of the dummy, acquires the position, depth, and speed of compression and the number of compression based on the compression training information measured by the chest compression training module, and acquires the amount, time and number of respiration based on the respiration training information measured by the artificial respiration training module. A display device is installed in the body part of the dummy and enables the self-learning of a trainee by displaying the compression training information and the respiration training information which are acquired by the control unit on a screen. A monitoring device is connected to the control unit in a wired/wireless way, receives the compression training information and the respiration training information which are acquired by the control unit to execute an evaluation program and generates an evaluation result to be displayed on the screen. The present invention is able to improve a training effect by self-learning and evaluation.

Description

{Cardiopulmonary resuscitation simulator for self-learning and evaluation}

The present invention relates to a cardiopulmonary resuscitation simulator, and more particularly, to a cardiopulmonary resuscitation simulator capable of self-learning and evaluating CPR in a condition similar to a human body.

Cardiopulmonary resuscitation is a procedure that restores cardiopulmonary function and resuscitates when cardiopulmonary function is seriously degraded or stopped. For normal breathing dysfunction or respiratory arrest, first perform artificial respiration after airway is secured, and then perform heart massage to restore heart function.

Artificial respiration refers to the artificial respiration is normally maintained by revitalizing the function of the lungs when the heart is running due to falling into water, poisoning or bleeding, but the breath stops and is in the housekeeping state. The artificial respiration method as the first life-saving treatment includes a breathing method of blowing the exhalation of the practitioner into the lungs of the patient and a water artificial respiration method in which the practitioner presses the chest of the patient by using the hand to inhale and exhale.

In addition, cardiopulmonary resuscitation is used as a method to revitalize cardiac function when the heart stops beating due to falling, electric shock, or poisoning. Cardiopulmonary resuscitation has a sternal compression massage that compresses the heart by pressing the sternum down three to five times toward the spine. It usually refers to heart massage.

In addition, when an AED (Automated External Defibrillator) is installed around the subject, the cardiac arrest rate can be increased by performing automatic defibrillation on the patient promptly.

First, the patient's airway is secured and the presence of respiration is checked to perform artificial respiration if breathing is stopped, and heart massage is started while artificial respiration continues if the heart is stopped. When an automatic defibrillator is provided, automatic defibrillation is performed quickly. Since CPR is performed on the human body, it is not appropriate for the practitioner or trainer to repeatedly practice the above procedure.

In recent years, there have been proposed devices for practicing artificial respiration, cardiopulmonary resuscitation, and automatic defibrillator (educational automatic defibrillator) using a manikin similar in shape to a human body.

Japanese Patent Application Laid-Open No. 10-2017-0135045 (published on December 8, 2017)

The object of the present invention is to provide a CPR simulator for self-learning and evaluation, which enables a trainer to self-learn and evaluate CPR in a realistic manner to enhance a training effect.

In order to achieve the above object, a CPR simulator for self-learning and evaluation according to the present invention includes a human body model, a chest compression training module, an artificial respiration training module, a controller, a display device, and a monitoring device. The anatomical model is similar to the upper body of the human body. The Chest Compression Training Module measures pressure training information on chest compressions of a human body model. The ventilation training module measures breathing training information during artificial respiration through the oral cavity of the human body. The control unit is mounted on the torso of the manikin and obtains the pressing position, the pressing depth, the pressing speed and the pressing frequency based on the pressing training information measured by the chest compression training module, and the respiration training Obtain the volume, breathing time, and breathing frequency based on the information. The display device is mounted on the trunk portion of the human body, and displays the pressure training information and breathing training information obtained by the control portion on the screen, thereby enabling the trainee to self-learn. The monitoring device is connected to the control unit by wired / wireless connection, receives the pressure training information and respiration training information obtained by the control unit, executes the evaluation program, generates the evaluation result, and displays it on the screen.

According to the present invention, it is possible to allow a trainee to realistically train CPR, to visually display CPR training information for self-learning, to monitor training results, and to analyze and evaluate the monitored result data Therefore, the effect of CPR training can be enhanced.

1 is a block diagram of a CPR simulator for self-learning and evaluation according to an embodiment of the present invention.
FIG. 2 is a control block diagram of the CPR simulator shown in FIG. 1. FIG.
FIG. 3 is an exploded perspective view of the human body in FIG. 2; FIG.
Figure 4 is a cross-sectional view of the chest compression training module of Figure 1;
5 is a cross-sectional view illustrating the operation of the chest compression training module shown in FIG.
Figure 6 is a cross-sectional view of the artificial respiration training module in Figure 1;
Fig. 7 is a cross-sectional view of the differential pressure mechanism shown in Fig. 6; Fig.
8 is a cross-sectional view illustrating the operation of the ventilation training module shown in FIG.
9 is a diagram showing an example of a screen configuration of a display device.
10 is a view showing another example of the screen configuration of the display device.
11 is a view showing an example of a screen configuration of the monitoring apparatus.

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 block diagram of a CPR simulator for self-learning and evaluation according to an embodiment of the present invention. FIG. 2 is a control block diagram of the CPR simulator shown in FIG. 1. FIG. FIG. 3 is an exploded perspective view of the human body in FIG. 2; FIG. Figure 4 is a cross-sectional view of the chest compression training module of Figure 1; 5 is a cross-sectional view illustrating the operation of the chest compression training module shown in FIG. Figure 6 is a cross-sectional view of the artificial respiration training module in Figure 1; Fig. 7 is a cross-sectional view of the differential pressure mechanism shown in Fig. 6; Fig. 8 is a cross-sectional view illustrating the operation of the ventilation training module shown in FIG.

1 to 8, a CPR simulator 100 for self-learning and evaluation includes a human body model 110, a chest compression training module 120, an artificial respiration training module 130, a controller 140 ), A display device 150, and a monitoring device 160. [

The human body model 110 has a shape similar to the upper half of the human body. The human body model 110 includes a body portion 111, a neck portion 112, and a head portion 113. The trunk portion 111 is formed similarly to the trunk of the human body. The trunk portion 111 may include a back plate 111a and a trunk artificial skin 111b. The body artificial skin 111b forms an internal space between the back plate 111a and the back plate 111a on the basis of the body 111 being erected. The trunk section 111 receives the chest compression training module 120 therein.

The neck portion 112 is formed similarly to the neck of the human body and is connected to the upper end of the body portion 111. The neck portion 112 may be formed in a neck frame having a shape similar to the neck of a human body and covered with a neck skin.

The head portion 113 is formed to resemble the head of the human body and is connected to the upper end of the neck portion 112. The head portion 113 can be tilted or pulled against the neck portion 112 and can be provided with an elastic restoring force in the direction of being pulled against the neck portion 112 by the head- Thus, the trainer can perform airway maintenance and artificial respiration training through the process of lifting the head 113 against the neck 112.

The head portion 113 may include a back portion 113a and a face portion 113b. The larynx 113a is fixed to the neck 112. The laryngeal portion 113a may be formed in a shape of a larynx frame having a shape similar to the occipital region of the human body and covered with a laryngeal artificial skin. The face portion has an oral cavity. The face portion 113b may be formed in a shape in which the artificial skin of the occiput is covered with a face frame having an outer shape similar to the face of the human body.

The face portion 113b can be rotatably supported with respect to the back portion 113a by a hinge shaft arranged in the left-right direction. Thus, the face portion 113b can be tilted backward or forward with respect to the occipital region 113a on the basis of which the head portion 113 is erected. The head spring 114 may be disposed between the face 113b and the back head 113a to provide an elastic restoring force to the face 113b. Accordingly, when the trainee applies force to the face to remove the force after the face portion 113b is tilted backward with respect to the back portion 113a, the face portion 113b can automatically return to the original state by the head portion spring 114. [ The head spring 114 is composed of a compression coil spring, and both ends can be fixed to the face 113b and the back head 113a. On the other hand, the human body model 110 may have a shape similar to that of the human body.

The chest compression training module 120 measures pressure training information when the chest compresses the human body 110. The chest compression training module 120 is covered by the body artificial skin 111b while being accommodated in the inner space of the body 111. [ For example, the chest compression training module 120 includes a chest plate 121, a spring for a chest plate 122, a chest plate guide 123, a compression position measurement unit 126, and a chest plate displacement measurement unit 129 ).

The chest plate 121 is disposed within the trunk portion 111 of the torso 110. The chest plate 121 is disposed forward of the back plate 111a of the trunk portion 111. [ The chest plate 121 is disposed in the chest of the trunk portion 111. In a state where the back plate 111a is horizontally laid, the chest plate 121 moves up and down in the inner space of the body 111 according to the cardiopulmonary resuscitation operation of the trainee. The chest plate 121 may be disposed inside the body 111 but may be exposed to the outside of the body 111 and may be made of urethane or the like having elasticity similar to the actual skin. The chest plate 121 may have upper and lower side projecting pieces 121a and left and right side projecting pieces 121b. The upper and lower projecting pieces 121a are symmetrical with respect to each other, and the left and right projecting pieces 121b are symmetrical with respect to the left and right.

The spring 122 for the chest plate is disposed between the chest plate 121 and the back plate 111a of the body 111 to provide an elastic restoring force to the chest plate 121. [ When the trainer 122 is pressed between the chest plate 121 and the back plate 111a and the trainer presses the chest plate 121 for cardiopulmonary resuscitation training, the chest plate 121 descends, The chest plate 121 is automatically lifted by the resilient restoring force of the spring 122 for the chest plate.

The spring 122 for the chest plate may be made of a compression coil spring. Both ends of the spring 122 for the chest plate are inserted into the first fixing member 120a of the movable guide 124 and the second fixing member 120b of the back plate 111a and are inserted between the chest plate 121 and the back plate 111a As shown in Fig. A buffer portion such as urethane, rubber, silicon, or the like may be disposed around each of the first and second fixing members 120a and 120b. The cushioning part can mitigate the impact applied to the spring 122 for the chest plate when the chest plate 121 is pressed and minimize the noise.

The chest plate guide 123 guides the movement of the chest plate 121 as the chest plate 121 is pressed or released. The chest plate guide 123 includes a movable guide 124 that moves in response to the compression or release of the chest plate 121 in a state in which the chest plate 121 is seated, And a fixed guide 125 for guiding the linear movement of the movable guide 124.

The movable guide 124 may include a seating table 124a and a movable table 124b. The movable guide 124 can be wrapped by the body frame 111c. The seat cradle 124a has a seating groove 124c for seating the chest plate 121 at the front portion on the basis of the body portion 111 being erected. The seating groove 124c has a size such that the chest plate 121 can be tilted up and down and left and right in a state where the chest plate 121 is seated.

A guide protrusion 124d protruding forward can be formed at the center of the seating groove 124c. In this case, a guide groove portion for inserting the guide projection 124d may be formed at a rear portion of the chest plate 121. [ The movable base 124b may be a rectangular tube having a rear end opened. The distal end of the movable base 124b is fixed to the rear portion of the seating base 124a. The movable base 124b can receive the front portion of the spring 122 for the chest plate by inserting the spring 122 for the chest plate through the rear opening.

The fixing guide 125 may be formed of a rectangular tubular body having a front portion opened. The rear end of the fixing guide 125 is fixed to the back plate 111a. The fixing guide 125 can receive the rear portion of the spring 122 for the chest plate by inserting the spring 122 for the chest plate through the upper opening. The fixing guide 125 can guide the linear movement of the movable base 124b in a state in which the rear side portion of the movable base 124b is inserted through the top opening.

The pressing position measuring unit 126 measures the pressing position of the trainee with respect to the chest plate 121 when the chest plate 121 is pressed and outputs it to the control unit 140. The pressing position measuring unit 126 may include a sensor supporting plate 127, and a pressing position measuring sensor 128.

The sensor supporting plate 127 is disposed on the back of the chest plate 121 on the basis of the human body model 110, and is fixed to the movable guide 124. The sensor support plate 127 has the same outer shape as the outer surface of the chest plate 121 and may have upper and lower protrusions 127a and left and right protrusions 127b. The sensor support plate 127 may have a hole at the center for passing the guide projection 124d of the seating base 124a.

The pressure locating sensors 128 are arranged at upper, lower, left, and right sides of the sensor support plate 127 to detect whether the chest plate 121 is pushed up and down, left and right, and outputs the detected pressure to the control unit 140. For adults and children, the compression position is the lower half of the sternum. To quickly locate the compression site, use a point where the patient's papillary connection meets the sternum, or a point two or three feet above the fingertip of the patient. When chest compressions are performed, it is necessary to be careful not to press the claw protrusion because it may cause damage to the liver and internal bleeding.

The pressing position measuring sensors 128 may be provided in four or more positions so that at least one pressing position measuring sensor 128 may be disposed on each of the upper and lower protrusions 127a and the left and right protrusions 127b of the sensor supporting plate 127. Here, at least one pressing position measuring sensor 128 may be disposed on the upper and lower protruding pieces 127a of the sensor supporting plate 127 in correspondence with the claw-shaped protrusions of the human body.

The control unit 140 can determine that the chest plate 121 is in the normal pressing position when it is detected that the chest plate 121 is not pressed in all four positions on the basis of the information sensed by the pressure position measuring sensors 128 . The control unit 140 can determine whether or not the dentition projection is pressed based on the information sensed by the pressing position measuring sensor 128 of the upper and lower protruded pieces 127a when the chest plate 121 is pressed. The pressing position measuring sensor 128 can sense a pressing force by a surface pressure sensor (FSR), a load cell, or the like, or can detect whether or not there is a push by a push switch, a tack switch or the like.

The chest plate displacement measuring unit 129 measures the displacement of the chest plate 121 when the chest plate 121 is pressed and outputs the measured displacement to the control unit 140. The control unit 140 can calculate the pressing depth, pressing speed, and pressing time according to the pressing of the chest plate 121 based on the displacement information of the chest plate 121 provided from the chest plate displacement measuring unit 129, It is possible to judge whether the compression is incomplete or relaxed.

The chest plate displacement measuring unit 129 may be constituted by an optical distance sensor or the like. The optical distance sensor may be an infrared distance sensor. The chest plate displacement measuring unit 129 can output a time-dependent displacement graph in the process of performing the chest compression exercise while the trainee presses or releases the chest plate 121.

In this case, based on the graph outputted from the chest plate displacement measuring unit 129, the control unit 140 can calculate the pressing depth, the pressing speed, and the pressing frequency by extracting the displacement value for each pressing time of the chest plate 121 have. The control unit 140 may extract the displacement value at the decompression release timing of the chest plate 121 based on the graph output from the chest plate displacement measuring unit 129 and compare the displacement value with the initial position value of the chest plate 121 have. The control unit 140 can determine that the compression is incomplete if the displacement value extracted at the compression release timing of the chest plate 121 is different from the initial position value of the chest plate 121. [

The artificial respiration training module 130 measures breathing training information during artificial respiration through the oral cavity of the torso 110. In one example, the ventilation training module 130 includes an air injector 131, a differential pressure mechanism 132, a flexible tube 135, a waste bag 136, a differential pressure sensor 137, And the backflow prevention portion 138 may be included.

The air injector 131 is installed in the oral cavity of the manikin 110 to inject air according to the artificial respiration of the trainee. The air injector 131 may be configured to receive air supplied through the injection port 131a and discharge air through the discharge pipe 131b. The air injector 131 can be mounted in the face portion 113b such that the injection port 131a communicates with the oral cavity of the face portion 113b.

The differential pressure mechanism 132 is disposed in the manikin 110 to generate a differential pressure during air passage. The differential pressure mechanism 132 may include a differential pressure body 133 and an orifice 134. The differential pressure mechanism body 133 is configured such that air is supplied through the inlet, flows along the air passage, and is discharged to the outlet.

The orifice 134 is formed on the air passage of the differential pressure mechanism body 133. The orifice 134 has a hole with a size smaller than that of the air passage of the differential pressure mechanism body 133, and a portion other than the hole has a shape closing the air passage of the differential pressure mechanism body 133. The orifice 134 generates a differential pressure across the hole through which the air passes. The differential pressure mechanism 132 may include a venturi-tube or a nozzle instead of the orifice 134.

The flexible tube 135 transfers the air injected through the air injector 131 to the differential pressure mechanism 132. The flexible tube 135 opens the air flow as the head portion 113 of the trunk 110 is turned against the neck portion 112 while normally closing the air flow. One end of the flexible tube 135 is connected to the discharge pipe 131b of the air injector 131 and the other end is connected to the inlet of the differential pressure mechanism body 133. The flexible tube 135 may be made of silicon or the like.

If the face portion 113b is normally pulled forward relative to the occipital region 113a, the flexible tube 135 is kept bent to close the air flow. In this state, when the trainee breathes through the oral cavity of the face portion 113b, the air due to the artificial respiration does not pass through the flexible tube 135 and is not transmitted to the lung bag 136. [ That is, if the trainee does not secure airway to the torso 110, then air from the artificial respiration will not be delivered to the lungs bag 136.

When the face portion 113b is tilted backward with respect to the occipital region 113a by the trainee, the flexible tube 135 is released from the bent state to open the air flow. In this state, when the trainee breathes through the oral cavity of the face portion 113b, the air due to the artificial respiration passes through the flexible tube 135 and is delivered to the waste bag 136. That is, when the trainer secures the airway to the human body model 110, air due to artificial respiration is delivered to the lung bag 136. Thus, the trainer will be able to train the anatomy 110 to secure airway.

The waste bag 136 is installed in the thorax of the torso 110 and stores the air discharged through the outlet of the differential pressure mechanism 132. The inlet of the waste bag 136 is connected to the outlet of the differential pressure mechanism 132. The lung bag 136 may be disposed within the trunk portion 111 of the torso 110 so as not to be interfered with movement of the thorax plate 121.

The differential pressure sensor 137 measures the differential pressure generated by the differential pressure mechanism 132 and outputs it to the control unit 140. The differential pressure sensor 137 may be installed to measure the difference between the atmospheric pressure and the pressure of the waste bag 136. The differential pressure mechanism body 133 may have a downstream side tap (tap) 133a on the downstream side of the air passing through the orifice 134. The downstream side tab 133a takes air from the downstream air passage of the differential pressure mechanism body 133 and transfers it to the differential pressure sensor 137. [ The differential pressure sensor 137 may be installed on the downstream side tab 133a.

The differential pressure sensor body 133 may have an upstream side tap on the air upstream side before passing through the orifice 134 and a differential pressure sensor 137 may be provided between the upstream side tap and the downstream side tap 133a To measure the difference between the oral pressure and the lung bag 136 pressure.

In this case, the control unit 140 can acquire the volume of breath, the breathing time, and the breathing frequency based on the pressure difference measured from the pressure difference sensor 137. The differential pressure sensor 137 can output a differential pressure graph over time in the course of performing artificial respiration on the torso 110 by the trainee. The control unit 140 can calculate the amount of respiration, the respiration time, and the number of respirations by extracting the pressure difference value each time the artificial respiration is performed based on the graph output from the pressure difference sensor 137. [

The air flow backflow prevention portion 138 is provided in the differential pressure mechanism 132 to prevent the air stored in the waste bag 136 from flowing back to the oral cavity through the inlet of the differential pressure mechanism 132. The air backflow prevention portion 138 may be formed of a ball-shaped valve body. The valve body can be moved so as to open and close the hole of the orifice 134 by receiving the guide 133c formed on the air downstream side of the differential pressure mechanism body 133. [

The valve body moves to open the hole of the orifice 134 by the pressure of the air entering the hole of the orifice 134 during artificial respiration and by the air discharged from the closed bag 136 when there is no artificial respiration, (134). Therefore, the air-flow-backflow prevention portion 138 can prevent the air stored in the waste bag 136 from flowing back to the oral cavity, thereby minimizing the human body infection during the artificial respiration training.

The differential pressure mechanism body 133 may include an exhaust port 133b. The exhaust port 133b is opened when the valve body is positioned to close the hole of the orifice 134. The air in the waste bag 136 can be discharged through the normally open exhaust port 133b. The exhaust port 133b is closed when the valve body is positioned to open the hole of the orifice 134. Air passing through the orifice 134 can be stored in the waste bag 136 without being discharged to the exhaust port 133b.

As another example, although not shown, the air flow backflow prevention portion 138 may include an elastic valve body. The resilient valve element may be of a plate shape. The resilient valve body opens the hole of the orifice 134 by the pressure of the air entering the hole of the orifice 134 during artificial respiration and returns to close the hole of the orifice 134 by the restoring force when there is no artificial respiration can do.

The control unit 140 is mounted on the body 111 of the human body 110. The control unit 140 may be mounted on the circuit board and disposed in the body 111. [ The control unit 140 acquires the pressing position, the pressing depth, the pressing speed, and the pressing frequency based on the pressing training information measured by the chest compression training module 120. [ Also, the controller 140 acquires the volume of breath, the breathing time, and the breathing frequency based on the respiration training information measured by the artificial respiration training module 130.

The display device 150 is mounted on the body 111 of the torso 110. The display device 150 can be mounted on the body 111 such that the screen 151 is exposed on the lower front surface of the body 111. [ The display device 150 displays the pressure training information and respiration training information obtained by the control unit 140 on the screen 151 to allow the trainee to self-learn.

As shown in FIG. 9, the display device 150 can visually display the pressing position, the pressing depth, the pressing speed, the number of times of pressing, and the like in the chest compressing training on the screen 151 together with the light source. As shown in FIG. 10, the display device 150 can visually display the volume of breathing, the breathing time, the number of times of breathing, and the like in the artificial respiration training together with the light source on the switched screen 151. Although not shown, the display device 150 can visually display the pressing depth and the breath amount on the switched screen 151 together with a real-time graph. In addition, the display device 150 may display the training information of the other trainees for the CPR simulators 100 on the switched screen 151 together.

The display device 150 may include a touch panel. The display device 150 may display a menu screen configured to allow a user to input commands such as start, end, screen switching, setting, and result. The touch panel allows a user to touch a menu screen of the display device 150 to input a command. The configuration of the screen 151 of the display device 150 is not limited to that illustrated and may be variously configured.

The monitoring device 160 is connected to the control unit 140 by wire or wireless. The monitoring device 160 may be a smart phone, a tablet PC, a smart watch, or the like. The monitoring device 160 may be connected to the control unit 140 through a cable or may be connected to the control unit 140 through a wireless communication module such as a Bluetooth or an RF module.

The monitoring device 160 receives the pressure training information and respiration training information obtained by the control unit 140, executes the evaluation program, generates the evaluation result, and displays the evaluation result on the screen 161. 11, the monitoring apparatus 160 executes an evaluation program to analyze actual pressing times, average pressing depth, average pressing speed, pressing position, etc. with respect to the set pressing number, The average breathing amount, the average breathing time, and the like can be analyzed and evaluated, and the evaluated result can be displayed visually on the screen 161.

The monitoring device 160 can display on the screen 161 the same contents as those displayed on the screen 151 of the display device 150 shown in Figs. Accordingly, the evaluator can conveniently monitor the training information simultaneously with the trainee through the screen 161 of the monitoring device 160. Further, even when the display device 150 is turned off, the trainee or the evaluator can perform self-learning or evaluation through the screen 161 of the monitoring device 160. [

Although not shown, the monitoring device 160 can display the learning results of a plurality of trainees on a screen 161 in a scored or a percentage, and display the results of learning of a plurality of trainers on a screen 161. The configuration of the screen 161 of the monitoring device 160 is not limited to the illustrated example, and may be variously configured.

According to the general CPR guideline, eg 2015 American Heart Association (AHA) guidelines, the ratio of chest compression to artificial respiration is 30: 2, chest compression depth is 5 to 6 cm, chest compression rate is 100 to 120 The chest compressions are performed once per minute, and artificial respiration is specified to perform artificial respiration for 1 to 2 seconds so that the chest is relaxed sufficiently. The display device and the monitoring device can confirm that the CPR guideline is complied with.

The above-described CPR simulator 100 allows the trainer to realistically train CPR, self-learns CPR training information, monitors the training results, And thus, the CPR training effect can be enhanced.

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.

110 .. Human Body 120 .. Chest Compression Training Module
121 .. Chest plate 122 .. Spring for chest plate
123 .. chest plate guide 126 .. compression position measuring part
129 .. chest plate displacement measuring part 130 .. artificial respiration training module
131 .. air injector 132 .. differential pressure mechanism
133 .. flexible tube 136 .. waste bag
137 .. Differential pressure sensor 138 .. Air flow prevention part
140. Control unit 150. Display device
160 .. Monitoring device

Claims (4)

A human body model shaped like the upper body of a human body;
A chest compressing training module for measuring pressure training information when compressing the thorax of the human body;
An artificial respiration training module for measuring respiration training information during artificial respiration through the oral cavity of the human body model;
And a controller that is mounted on the trunk portion of the manikin and obtains a pressing position, a pressing depth, a pressing speed, and a pressing frequency based on the pressing training information measured by the chest pressing training module, A controller for acquiring a respiration amount, a respiration time, and a respiration frequency based on the training information;
A display device mounted on a trunk part of the human body and displaying the pressure training information and respiration training information obtained by the control part on a screen to allow the trainee to self-learn; And
And a monitoring device connected to the control unit by wired / wireless connection, receiving the pressure training information and respiration training information obtained by the control unit, executing an evaluation program, generating an evaluation result, and displaying the evaluation result on a screen,
Wherein the artificial respiration training module comprises:
An air injector installed in the mouth of the human body to inject air according to the artificial respiration of the trainee,
A differential pressure mechanism disposed in the human body model for generating differential pressure during air passage,
A flexible tube for transmitting the air injected through the air injector to the differential pressure mechanism and opening the air flow as the head of the human body is turned against the neck in a state where the air flow is normally closed,
A waste bag installed in the chest of the manikin for storing air discharged through an outlet of the differential pressure mechanism,
A differential pressure sensor for measuring a differential pressure generated by the differential pressure mechanism and outputting it to the control unit, and
And an air backflow preventing unit provided in the differential pressure mechanism to prevent air stored in the waste bag from flowing back to the oral cavity through an inlet of the differential pressure mechanism. The method according to claim 1,
The chest compression training module comprises:
A chest plate disposed in the body portion of the human body,
A chest plate spring disposed between the chest plate and the back plate of the body to provide an elastic restoring force to the chest plate;
A chest plate guide for guiding the movement of the chest plate upon pressing or releasing the chest plate,
A pressure position measuring unit for measuring a pressure position of a trainee on the chest plate when the chest plate is pressed and outputting the pressure to the control unit,
And a chest plate displacement measuring unit measuring a displacement of the chest plate when the chest plate is pressed and outputting the measured displacement to the control unit. 3. The method of claim 2,
Wherein the chest plate guide comprises:
And a fixed guide fixed to the back plate of the body and guiding the linear movement of the movable guide, wherein the movable guide moves along the pressing or releasing of the chest plate while the chest plate is seated;
The pressure-
A sensor supporting plate disposed on the back of the chest plate on the basis of the human body model and fixed to the movable guide,
And a pressure position measuring sensor disposed on each of upper, lower, left, and right sides of the sensor support plate for detecting whether the chest plate is pushed up and down, left and right, and outputting the detected pressure to the control unit. delete

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