KR101992603B1 - Model for training defibrillation and chest compression - Google Patents

Abstract

The present invention relates to a model for training defibrillation and chest compression, wherein electrocardiogram electrodes are embedded in a human body model and are electrically connected to a commercial defibrillator, and a pair of defibrillation paddle electrode modules receives electric shock applied from defibrillation paddles in a state of being coupled to the defibrillation paddles of the commercial defibrillator. In addition, a pressure measuring device measures each pressure at which the defibrillation paddle electrode modules are in contact with the human body model, and a position measuring device measures each position at which the defibrillation paddle electrode modules are in contact with the human body model. A chest compression training unit is embedded in the human body model to enable chest compression training for cardiopulmonary resuscitation and measures information related to chest compression. A control unit generates an electrocardiogram signal including a waveform requiring defibrillation, outputs the electrocardiogram signal to the electrocardiogram electrodes, derives result data according to defibrillation training based on information measured in the pressure measuring device and the position measuring device, and derives result data according to chest compression training based on the information measured in the chest compression training unit. Further, a display device displays result data derived from the control unit on a screen.

Description

Defibrillation and chest compression model.

The present invention relates to a defibrillation and chest compression training model, and more particularly, to a training model that enables rapid and accurate defibrillation and training to provide chest pressure to an acute cardiac arrest patient.

Acute cardiac arrest is often caused by ventricular fibrillation, and electrical defibrillation is the most important treatment for ventricular fibrillation. Defibrillation allows a patient with ventricular fibrillation to pass a strong current through the heart in a very short period of time, causing action potentials in most of the myocardium to prevent ventricular fibrillation from being maintained, thus ending the ventricular fibrillation and allowing the heart to regain normal electrical activity Induction therapy.

Chest compression is a key step in cardiopulmonary resuscitation, a first-aid treatment that artificially circulates blood and assists breathing in the event of a heart attack. It is the act of pressing the sternum with both hands to a depth of 5 to 6 cm. Chest compressions are crucial for delaying brain damage and restoring the heart from paralysis.

If chest compression is not performed, the survival rate by defibrillation is reduced by 7 ~ 10% every minute, and when the chest pressure is applied by witness, the success rate of defibrillation is reduced to 3 ~ 4% per minute. In other words, if chest compression is applied in a cardiac arrest situation, the probability of success increases by 2 ~ 3 times than that of defibrillation without chest compression. In the field, chest compressions by witnesses are used to better maintain the neurological function of the patient, especially when defibrillation is performed within 5 minutes after the cardiac arrest in adults.

However, chest compression alone is not likely to convert normal ventricular fibrillation to normal rhythm, so it is more important to defibrillate at the beginning of cardiac arrest. Therefore, in general, it is recommended that a patient with a cardiac arrest be promptly started to pressurize the chest, but defibrillation should be initiated immediately by a defibrillator if necessary.

The defibrillator is used by doctors, nurses, paramedics, and other medical staff to diagnose the condition of the heart with an electrocardiogram. Based on proven guidelines and experience, physicians determine how much electrical energy to give to the patient's symptoms and apply a shock to the defibrillation paddle on the patient's chest. Defibrillation requires professional and iterative education to be able to cope appropriately because it requires accurate medical knowledge and is a vital part of life.

Specifically, defibrillation paddles for electric shock are composed of a pair. A pair of defibrillation paddles should be located on the medial subclavian line beneath the right clavicle of the thorax and the median side of the outside of the left papilla. The location of the inappropriate defibrillation paddles causes the current to pass through tissue rather than myocardial cells with a high probability, which reduces the likelihood of successful defibrillation. Failure of the defibrillation once means that the patient will attempt to shock after preparation for defibrillation and the survival rate is reduced by 2 ~ 10% every 1 minute after the cardiac arrest, so failure of one defibrillation causes a fatal decrease in survival rate .

The human contact load of the defibrillation paddle is recommended to be about 12 kg. If the contact load is insufficient, the defibrillation paddle may not come into close contact with the human body, causing a problem that the electric shock is not applied, so serious clinical problems may occur, such as an inappropriate defibrillation paddle position.

Patients with cardiac arrest had the highest survival rate when the chest compression depth was between 4.5 and 5.5 cm, especially if the chest compression depth was greater than 6 cm, the incidence of complications was high. Therefore, the chest compression depth should be 5 ~ 6cm, and the rescuer needs to practice enough so that effective chest compression can be performed so that it does not exceed 6cm.

In addition, it is recommended that the chest compressing speed be maintained at 100 to 120 times per minute. After each chest compression, the chest should be relaxed to its normal position for venous return to the heart. Insufficient thoracic relaxation decreases blood flow to the coronary and cerebral arteries by decreasing cardiac output by increasing the pressure inside the thoracic cavity. Sufficient chest relaxation is an essential part of effective chest compressions, so its importance is emphasized.

The present invention provides a defibrillation and chest compression training model that allows practitioners to perform defibrillation and chest compression exercises and accurate assessment.

The defibrillation and chest compression training model according to the present invention includes a human body model, a defibrillation training unit, a chest compression training unit, a control unit, and a display device. The anatomy is made in a shape similar to that of the actual human body. The defibrillation training unit includes electrocardiogram electrodes built in the human body and electrically connected to the commercial defibrillator, a pair of defibrillation paddle electrodes for receiving an electric shock applied from the defibrillation paddles in a state of being coupled to the defibrillation paddles of the commercial defibrillator A pressure gauge measuring each pressure at which the defibrillation paddle electrode modules contact the torso, and a position gauge measuring the angular position at which the defibrillation paddle electrode modules contact the torso. The chest compression training unit is built into the human body to allow for chest compression training for CPR, and measures information related to chest compression. The controller generates an electrocardiogram signal including a waveform required for defibrillation and outputs the electrocardiogram signal to the electrocardiogram electrodes. The controller obtains result data according to the defibrillation training based on the information measured from the pressure meter and the position meter, The results of the chest compression training are derived. The display device displays result data derived from the control section on the screen.

The defibrillation and chest compression training model according to the present invention provides a variety of simulation scenarios required for emergency medical care using a commercial defibrillator, and therefore, it is necessary to provide a variety of simulation scenarios for urgent medical care from urgent medical staff such as doctors, nurses, emergency rescue personnel, Realistic defibrillation training can be performed reminiscent of emergency patients. In addition, the defibrillation and chest compression training model according to the present invention can record and evaluate the objective performance and the status of the defibrillation training and the chest compression training, so that the actual patient response ability can be improved.

1 is a block diagram of a defibrillation and chest compression training model according to an embodiment of the present invention.
Figure 2 is a control block diagram of the defibrillation and chest compression training model shown in Figure 1;
FIG. 3 is a perspective view of the human body model shown in FIG. 1; FIG.
FIG. 4 is a perspective view of the defibrillation paddle and the defibrillation paddle electrode module shown in FIG. 1; FIG.
5 is an exploded perspective view of FIG.
FIG. 6 is an exploded perspective view of the defibrillation paddle electrode module in FIG. 5; FIG.
7 is a perspective view of an example of a chest compression training unit.
Fig. 8 is an exploded perspective view of Fig. 7. Fig.
Figure 9 is a side view of Figure 7;
Fig. 10 is a side view showing the chest plate in a pressurized state in Fig. 9;

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 defibrillation and chest compression training model according to an embodiment of the present invention. Figure 2 is a control block diagram of the defibrillation and chest compression training model shown in Figure 1; FIG. 3 is a perspective view of the human body model shown in FIG. 1; FIG. FIG. 4 is a perspective view of the defibrillation paddle and the defibrillation paddle electrode module shown in FIG. 1; FIG. 5 is an exploded perspective view of FIG. FIG. 6 is an exploded perspective view of the defibrillation paddle electrode module in FIG. 5; FIG.

1 through 6, a defibrillation and chest compression training model 1000 according to an embodiment of the present invention includes a human body model 100, a defibrillation training unit 200, a chest compression training unit 300, A control unit 400, and a display device 500.

The human body model 100 has a shape similar to that of a human body. The human body model 100 may include a head 120 connected to the chest 110. The human body model 100 may be configured to be covered with a material such as silicone or urethane which is similar to the elasticity of actual skin.

The defibrillation training unit (200) allows the practitioner to train defibrillation by the commercial defibrillator (10). The defibrillation training unit 200 includes electrocardiographic electrodes 210, a pair of defibrillation paddle electrode modules 220, a pressure gauge 230, and a position gauge 240.

Electrocardiogram electrodes 210 are embedded in the manikin 100. The electrocardiogram electrodes 210 may be of a 3-lead type. In this case, the electrocardiographic electrodes 210 are disposed on the right upper side, the upper left side, and the lower left side of the chest 110, respectively. The electrocardiogram electrodes 210 are electrically connected to the commercial defibrillator 10. The electrocardiogram electrodes 210 receive the electrocardiogram signal output from the controller 400 and provide the electrocardiogram signal to the commercial defibrillator 10 so that the waveform of the electrocardiogram signal can be displayed on the screen of the defibrillator 10.

The electrocardiogram electrodes 210 may be electrically connected to the commercial defibrillator 10 through commercial electrocardiogram cables 20. The commercial ECG cable 20 has one end connected to the commercial defibrillator 10 and the other end connected to the electrocardiogram electrode 210. The commercial ECG cable 20 has a snap fastener at an end connected to the electrocardiographic electrode 210. Therefore, the electrocardiogram electrode 210 may have a protrusion 211 detachably attached to the snap fastener. The electrocardiogram electrode 210 may be embedded in the human body model 100 in a state where the protrusion 211 protrudes from the human body model 100 to the outside.

The defibrillation paddle electrode modules 220 are coupled to the defibrillation paddles 11 of the commercial defibrillator 10. The defibrillation paddle electrode modules 220 may be releasably coupled to the defibrillation paddles 11 of the commercial defibrillator 10, respectively. The defibrillation paddle electrode modules 220 receive the electric shock applied from the defibrillation paddles 11 in a state of being coupled to the defibrillation paddles 11 and output the same to the control unit 400.

For example, each defibrillation paddle electrode module 220 may include a paddle coupling portion 221, an electric shock transfer plate 223, a paddle base portion 224, and an electrode model plate 225. The paddle coupling portion 221 is detachably coupled to the defibrillation paddle 11. [ The paddle coupling portion 221 is constructed to be detachable from the defibrillation paddles 11 of various models typically used in practice, thereby enhancing convenience.

Normally, the defibrillation paddle 11 basically comprises a child-use electrode 11a, and the adult electrode is constructed so as to be removable as needed. Therefore, the defibrillation paddle 11 has a pair of slide fitting grooves 11b and hooks 11c for attaching / detaching the adult electrode to the lower end portion. Using this, the paddle engaging portion 221 has slide fitting protrusions 221a which are slidably inserted into the slide fitting grooves 11b. In addition, the paddle engaging portion 221 has a hook 11c and a lock lever 222 that is locked or unlocked.

The lock lever 222 is supported so as to be able to move up and down along the guide hole 221b formed in the paddle coupling portion 221. [ The lock lever 222 has a lock projection 222a at the upper end thereof. The locking protrusion 222a is caught by the hook 11c while the locking lever 222 is lifted and the locking protrusion 222a can be released from the hook 11c when the locking lever 222 is lowered. In this process, the defibrillation paddle 11 can be locked to the paddle engagement portion 221 or can be released from the locked state. The lock lever 222 can be raised by the elastic force of the lever spring 222b and can be held in the hooked state by the hook 11c. The lever spring 222b is formed of a leaf spring and can be connected to the electric shock transfer plate 223. [

The paddle coupling portion 221 may be made of a material having insulation properties, such as a plastic material. The paddle coupling portion 221 has an opening 221c at the center thereof. The central opening 221c of the paddle engaging portion 221 is allowed to pass through the electric shock transfer plate 223 to be brought into contact with the electrode 11a for pediatric use of the defibrillation paddle 11. [

The electric shock transmission plate 223 receives the electric shock from the defibrillation paddle 11 in a state where the paddle coupling portion 221 is coupled to the defibrillation paddle 11 and outputs the electric shock to the control portion 400. The electric shock transfer plate 223 is made of a conductive metal material. The electric shock transfer plate 223 may be connected to the control unit 400 through a cable 228 or the like.

The electric shock transfer plate 223 may have a structure in which a plurality of elastic pieces 223b are connected to each other in the rectangular rim 223a. The elastic pieces 223b are arranged on both sides with their respective centers bent upwards convexly. The elastic pieces 223b can be elastically deformed and contact with the electrode 11a for children of the defibrillation paddle 11 in a state where the defibrillation paddle 11 is coupled to the paddle coupling portion 221. [ Accordingly, the defibrillation paddle 11 can be kept in contact with the electric shock transfer plate 223, and can be kept coupled to the paddle coupling portion 221 without shaking.

The paddle base portion 224 is connected to the paddle coupling portion 221 via the electric shock transmission plate 223. The paddle base portion 224 may be made of a material having insulation property, such as a plastic material.

The electrode model plate 225 is coupled to the paddle base portion 224 and contacts the human body model 100. The electrode model plate 225 may be coupled to the bottom of the paddle base portion 224 toward the torso. The electrode model plate 225 may be bonded to the paddle base portion 224 with an adhesive or may be fastened by a fastening mechanism. The electrode model plate 225 contacts the torso 100 to allow the load of the defibrillation paddle 10 to be delivered to the torso 100. The electrode model plate 225 is formed in a shape simulating the actual adult electrodes of the defibrillation paddles 11 so that the practitioner can give a sense of realism to the defibrillation paddle electrode module 220.

The electrode model plate 225 may be made of a non-magnetic metal such as aluminum or the like so as not to affect the permanent magnet 241 and the hall sensor 242 of the position measuring device 240,

The defibrillation paddle electrode module 220 may further include an intermediate block 226 between the electric shock transfer plate 223 and the paddle base portion 224. When the hall sensor 242 and the load cell are embedded in the defibrillation paddle electrode module 220, the intermediate block 226 connects the hall sensor 242 and the sensor circuit portion 227 with the load cell to the paddle base portion 224 ). Therefore, the hall sensor 242 and the sensor circuit portion 227, in which the load cell is mounted, can be electrically insulated from the electric shock transfer plate 223 by the intermediate block 226.

The intermediate block 226 may be made of an insulating material, such as a plastic material. The intermediate block 226 has a structure in which lattice-shaped ribs 226a are formed on the upper surface thereof, so that the intermediate block 226 can have more robust characteristics. The intermediate block 226 can be screwed together with the paddle engagement portion 221 and the paddle base portion 224 by bolts.

The pressure gauge 230 measures each contact pressure of the defibrillation paddle electrode modules 220 when the defibrillation paddle electrode modules 220 contact the torso 100. The load of the defibrillation paddle 11 which is in contact with the human body is recommended to be about 12 kg. The pressure gauge 230 allows the practitioner to practice the defibrillation paddle 11 to apply a recommended load of about 12 kg to the torso 100.

That is, when the practitioner holds the defibrillation paddles 11 with both hands and contacts the defibrillation paddle electrode modules 220 with the torso 100 in a state where the defibrillation paddles 11 are coupled to the defibrillation paddle electrode modules 220, The pressure gauge 230 measures the contact pressure of the defibrillation paddle electrode modules 220. Accordingly, the practitioner can practice and check the loads of the defibrillation paddles 11 applied to the human body model 100 through the contact pressure information of the defibrillation paddle electrode modules 220, Can be improved.

Each contact pressure information of the defibrillation paddle electrode modules 220 measured from the pressure meter 230 is provided to the control unit 400. For example, the pressure gauge 230 may include load cells. The load cells may be embedded in the defibrillation paddle electrode modules 220, respectively. The load cell may be mounted on the sensor circuit 227 and be received between the middle block 226 of the defibrillation paddle electrode module 220 and the paddle base 224. The measured value from the load cell is provided to the control unit 400. As another example, although not shown, the load cells may be embedded in the torso 100. In this case, the load cells may be disposed on the medial subclavian line under the right clavicle and the medial side line outside the left nipple of the chest 110, respectively.

The position meter 240 measures each contact position of the defibrillation paddle electrode modules 220 when the defibrillation paddle electrode modules 220 are contacted with the torso 100. When defibrillation is actually performed on the human body, the defibrillation paddles 11 should be located on the middle subclavian line under the right clavicle of the chest and the mid-lateral line outside the left nipple, and the left and right contact positions of the defibrillation paddles 11 must be distinguished .

The positioner 240 allows the practitioner to practice to place the defibrillation paddles 11 in the left and right positions and place them on the medial subclavian line under the right clavicle and the medial side line outside the left nipple of the chest 110, respectively. That is, when the practitioner holds the defibrillation paddles 11 with both hands and contacts the defibrillation paddle electrode modules 220 with the torso 100 in a state where the defibrillation paddles 11 are respectively coupled to the defibrillation paddle electrode modules 220 , The position measuring device 240 measures the contact positions of the defibrillation paddle electrode modules 220. Accordingly, the practitioner can learn and practice the respective positions of the defibrillation paddles 11 applied to the human body model 100 through the contact position information of the defibrillation paddle electrode module 220, Can be improved.

Each contact position information of the defibrillation paddle electrode modules 220 measured from the position measuring device 240 is provided to the control unit 400. For example, the position finder 240 may include two permanent magnets 241, and hall sensors 242.

The two permanent magnets 241 are embedded in the torso 100 in correspondence with the contact positions set to be in contact with the defibrillation paddle electrode modules 220, respectively. That is, the permanent magnets 241 are disposed on the medial subclavian line under the right clavicle and the medial side line outside the left nipple of the chest 110, respectively. Here, the permanent magnets 241 may be arranged in opposite polarities with respect to the surface of the chest 110. That is, one of the N poles of the permanent magnets 241 may be disposed close to the surface of the chest 110, and the other S pole may be disposed close to the surface of the chest 110.

Hall sensors 242 are embedded in defibrillation paddle electrode modules 220, respectively. When the Hall sensors 242 approach the permanent magnets 241, the Hall sensors 242 output voltages to the controller 400, respectively. Then, the controller 400 determines whether or not the hall sensor 242 outputs a voltage so that the defibrillation paddle electrode modules 220 are placed on the middle subclavian line under the right collarbone of the chest 110 and the mid- It can be judged whether or not it is normally positioned.

Further, the hall sensor 242 generates different voltage values in accordance with the polarity arrangement of the permanent magnets 241 when the permanent magnets 241 are brought close to each other. When the left and right sides of the defibrillation paddles 11 are shifted to be located on the medial subclavian line under the right clavicle and the medial side line outside the left papilla of the chest 110 respectively, the voltage values output from the hall sensors 242 are set Value. Accordingly, the controller 400 can determine whether the left and right positions of the defibrillation paddles 11 are normal by determining whether the voltage values output from the hall sensors 242 are different from the set values.

The hall sensor 242 may be mounted on the sensor circuit portion 227 together with the load cell to be received between the middle block 226 of the defibrillation paddle electrode module 220 and the paddle base portion 224. Here, the sensor circuit unit 227 processes the signals output from the hall sensor 242 and the load cell, and provides the signals to the control unit 400. The sensor circuit unit 227 may include a connector 227a to be connected to the control unit 400 through a cable 228. [ As another example, although not shown, Hall sensors 242 may be embedded in the torso 100 and permanent magnets 241 may be embedded in the defibrillation paddle electrode modules 220, respectively. In this case, the hall sensors 242 may be disposed respectively on the medial subclavian line under the right collarbone of the chest 110 and on the medial side line outside the left nipple.

The chest compression training unit 300 is embedded in the manikin 100 to enable chest compression training for cardiopulmonary resuscitation and measures information related to chest compression. An example of the chest compression training unit 300 will be described later.

The control unit 400 generates and outputs an ECG signal that can be recognized by the commercial defibrillator 10. Here, the controller 400 generates an electrocardiogram signal including a waveform required for defibrillation and outputs the electrocardiogram signal to the electrocardiogram electrodes 210, thereby displaying an electrocardiogram signal on the screen of the defibrillator 10. A waveform that requires defibrillation may correspond to a ventricular fibrillation waveform or a ventricular tachycardia waveform.

The control unit 400 may be embedded in the human body model 100. The control unit 400 can control the defibrillation and chest compression training model 1000 in various manners based on simulation scenarios necessary for emergency medical care. For example, the controller 400 may generate an electrocardiogram signal starting from a normal waveform and continuing with a ventricular fibrillation waveform or a ventricular tachycardia waveform to be displayed on the screen of the defibrillator 10. Then, the practitioner can analyze the electrocardiogram signal displayed on the screen of the commercial defibrillator 10 to check whether it is ventricular fibrillation or ventricular tachycardia, and then practice practicing the actual electric shock. The control unit 400 can control the normal waveform to be output to the screen of the defibrillator 10 when the practitioner appropriately performs the defibrillation.

The controller 400 derives the result data according to the defibrillation training based on the information measured from the pressure meter 230 and the position meter 240. For example, the control unit 400 determines whether the defibrillation paddles 11 applied to the human body model 100 in the defibrillation training process and the defibrillation paddles 11 with respect to the human body are normal or abnormal, 11, and the number of times of defibrillation, etc. may be derived and displayed on the screen of the display device 500. [

The defibrillation and chest compression training model 1000 may further include an electric shock protection circuit 411. [ The electric shock protection circuit 411 is embedded in the human body model 100 to protect the controller 400 from electric shock transmitted to the defibrillation paddle electrode modules 220.

For example, the electric shock protection circuit 411 may include a voltage divider 411a and a voltage comparator 411b. The voltage divider 411a drops the defibrillation shock voltage input through the electric shock transfer plate 223 of the defibrillation paddle electrode module 220 during the actual defibrillation by the commercial defibrillator 10 and outputs the defibrillated electric shock voltage to the voltage comparator 411b Output.

The voltage comparator 411b allows the voltage to be input to the control unit 400 when the input voltage is higher than the reference voltage, thereby enabling to measure whether or not the electric shock is applied. A high voltage of about 150 to 200J is applied to the defibrillation paddle electrode module 220. The voltage divider 411a prevents a high current from flowing into the control unit 400 by using a high capacity low resistance, To protect the circuitry of the circuit.

In addition, the control unit 400 derives the result data according to the chest compression training based on the measured information from the chest compression training unit 300. This will be described later.

The display device 500 displays result data derived from the control unit 400 on the screen. The display device 500 can communicate with the control unit 400 in a wired or wireless manner. The display device 500 may be provided with an input / output unit. The control unit 400 may control the defibrillation and chest compression training model 1000 based on a scenario inputted by the user or a pre-stored scenario through the input / output unit of the display device 500. The input / output unit may be based on a GUI (Graphical User Interface) for the convenience of the user. The display device 500 may be a tablet PC, a notebook computer, a PC monitor, or the like.

The above-described defibrillation and chest compression training model (1000) provides a variety of simulation scenarios necessary for emergency medical care using a commercial defibrillator (10), and therefore, it can be applied to specialist emergency medical staff such as doctors, nurses, Students are able to perform realistic defibrillation training reminiscent of urgent emergency patients. In addition, the defibrillation and chest compression training model (1000) can record and evaluate the objective performance and status of defibrillation training and chest compression training, thereby improving the actual patient response capability.

7 is a perspective view of an example of a chest compression training unit. Fig. 8 is an exploded perspective view of Fig. 7. Fig. Figure 9 is a side view of Figure 7; Fig. 10 is a side view showing the chest plate in a pressurized state in Fig. 9;

7-10, the chest compression training unit 300 may include a chest plate 310, a spring 320 for the chest plate, a chest plate guide 330, and a displacement measurement unit 340 have.

The chest plate 310 is formed similar to the chest of the human body and is disposed in front of the back plate 111 of the chest 110 in the chest 110. [ The chest plate 310 may be made of urethane or the like having elasticity similar to the actual skin. The chest plate 310 may be shaped like a human rib.

In a state where the back plate 111 is horizontally laid, the chest plate 310 ascends and descends with respect to the back plate 111 in accordance with the chest compression operation of the user. The upper portion of the chest plate 310 may be bent from the lower portion toward the link plate 332 of the chest plate guide 330 to be inclined. The lower portion of the chest plate 310 may be formed so as to be positioned side by side with respect to the back plate 111 in an unpressurized state.

The spring 320 for the chest plate is installed between the chest plate 310 and the back plate 111 to provide an elastic restoring force to the chest plate 310. The spring 320 for the chest plate may comprise a compression coil spring. When the user pushes the chest plate 310 in a state where the chest plate spring 320 is installed between the chest plate 310 and the back plate 111 and the chest plate 310 is lowered, Elastic recovery force is generated.

When the pressing force on the chest plate 310 is released, the chest plate 310 can be automatically raised by the elastic restoring force of the spring 320 for the chest plate. The spring 320 for the chest plate can be supported on the chest plate 310 and the back plate 111 by the first and second fixing members 351 and 352 at the front and rear ends, respectively.

The chest plate guide 330 guides the movement of the chest plate 310 as the chest plate 310 is pressed or released. The chest plate guide 330 may include a support member 331, and a link plate 332.

The support member 331 is disposed above the chest plate 310 and is fixed to the front surface of the back plate 111. [ The support member 331 protrudes at a predetermined height, and a link plate 332, which will be described later, is rotatably connected to the protruding front end. The support member 331 plays a role similar to the rat bone of the human body.

The upper end of the link plate 332 is connected to the support member 331 so as to be rotatable back and forth, and the lower end of the link plate 332 is rotatably connected to the back surface of the chest plate 310. For example, the link plate 332 may include a central base portion 332a, a pair of upper extensions 332b, and a pair of lower extensions 332c.

The upper extension portions 332b extend upwardly from the central base portion 332a in two halves. The upper extension portions 332b may be formed to have a larger interval than the lower extension portions 332c. The upper extension portions 332b are rotatably connected to the support member 331 back and forth by a hinge shaft. In this case, the support member 331 may include a pair of support brackets 331a corresponding to the upper extension portions 332b. The upper extension portions 332b may be connected to the support brackets 331a by hinge shafts, respectively.

The lower extension portions 332c extend from the central base portion 332a in two directions downwardly via the spring 320 for the chest plate. Therefore, the spring 320 for the chest plate can pass between the lower extension portions 332c and can operate without interference by the link plate 332. [ The lower extension portions 332c are rotatably hingedly connected to the back surface of the chest plate 310. Here, the lower ends of the lower extension portions 332c are disposed below the first fixing member 351. [

The sub spring 333 may be installed between the chest plate 310 and the link plate 332 to support the chest plate 310 against the link plate 332 with elastic force. The sub spring 333 may be a compression coil spring. The sub spring 333 allows the distance between the chest plate 310 and the link plate 332 to be adjusted according to the stretching operation.

The sub springs 333 may be provided as a pair. The sub springs 333 may be disposed at left and right intervals. The sub-springs 333 may be disposed close to the upper end of the chest plate 310. Each of the sub springs 333 can be supported on the chest plate 310 and the link plate 332 by the third and fourth fixing members 353 and 354 at the front and rear ends.

The displacement measuring unit 340 measures the displacement of the chest plate 310 in response to the compression of the chest plate 310 and provides the measured displacement to the control unit 400. The controller 400 may calculate the chest compression depth, the chest compression rate, and the number of times the chest is compressed by pressing the chest plate 310 based on the displacement information of the chest plate 310 provided from the displacement measuring unit 340 , And whether the chest compression is incomplete or relaxed.

The displacement measuring unit 340 may include an optical distance sensor or the like. The displacement measuring unit 340 may output a displacement graph over time during the chest compression exercise while the practitioner presses or releases the chest plate 310. [ The control unit 400 may calculate the chest compression depth, the chest compression rate, and the number of times of chest compression by extracting a displacement value at each compression time point of the chest plate 310 based on the graph output from the displacement measurement unit 340. [ The control unit 400 may extract the displacement value at the decompression release time point of the chest plate 310 based on the graph output from the displacement measurement unit 340 and compare the displacement value with the initial position value of the chest plate 310. The control unit 400 can determine that the chest compression incomplete relaxation is present if the displacement value extracted at the compression release timing of the chest plate 310 is different from the initial position value of the chest plate 310. [

The display device 500 may display on the screen the chest compression depth of the chest plate 310, the chest pressure rate, the number of times the chest is pressed, and whether the chest pressure is incomplete or relaxed. According to the general CPR guideline, for example the 2015 American Heart Association (AHA) guidelines, the chest compression depth is 5 to 6 cm and the chest compression rate is specified to perform chest compressions between 100 and 120 per minute, ) Can confirm that the chest compression exercise complies with the CPR guideline and can confirm that it has relaxed to its normal position after chest compression. Thus, the training effect can be enhanced and the evaluator can monitor the training result of the practitioner.

The chest compression device 300 of the above-described configuration can act as follows. When the user presses the chest plate 310, the link plate 332 rotates clockwise about the hinge axis of the support member 331. [ Thus, the chest plate 310 is lowered, and is rotated clockwise about the hinge axis of the support member 331, so that the lower portion thereof is inclined.

At this time, since the pressing force in the direction perpendicular to the back plate 111 is applied to the chest plate 310, the interval between the chest plate 310 and the link plate 332 becomes narrower due to contraction of the sub spring 333. Accordingly, since the chest plate 310 rotates counterclockwise about the connection portion with the link plate 332, the inclined angle of the lower side of the chest plate 310 can be reduced. As a result, the lower portion of the chest plate 310 is inclined downward at an angle of about 5 to 10 degrees with respect to the support member 331, so that it can be realized in a manner similar to the actual chest deformation of the 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.

10. Commercial defibrillator 11. Defibrillation paddle
100 .. Manikin 200 .. Defibrillation Training Unit
210 .. Electrocardiogram electrode 220 .. Defibrillation paddle electrode module
230 .. Pressure Meter 240 .. Position Meter
300 .. Chest Compression Training Unit 310 .. Chest Plate
320 .. Spring 330 for chest plate .. Chest plate guide
340. Displacement measuring unit 400. Control unit
500 .. Display device

Claims (3)

A human body model shaped like a chest of a human body;
And a pair of defibrillation paddle electrode modules for receiving an electric shock applied from the defibrillation paddles while being coupled to defibrillation paddles of the defibrillation pads of the commercial defibrillator, An defibrillation training unit comprising a pressure gauge measuring the respective pressures at which the defibrillation paddle electrode modules are brought into contact with the torso and a position gauge measuring angular positions at which the defibrillation paddle electrode modules contact the torso;
A chest compression training unit embedded in the human body to perform chest compression training for cardiopulmonary resuscitation and measuring information related to chest compression;
Generating an electrocardiogram signal including a waveform required for defibrillation and outputting the electrocardiogram signal to the electrocardiogram electrodes, deriving result data according to the defibrillation training based on the information measured from the pressure meter and the position meter, A controller for deriving result data according to the chest compression training based on the information; And
And a display device for displaying result data derived from the controller on a screen,
Each of the defibrillation paddle electrode modules comprises:
A paddle coupling portion detachably coupled to the defibrillation paddle,
An electric shock transfer plate having a shock absorbing paddle coupled to the deflector paddle and receiving an electric shock from the deflector paddle,
A sensor circuit part for mounting a load cell provided in the pressure measuring device and a hall sensor provided in the position measuring device,
A paddle base portion connected to the paddle coupling portion via the electric shock transfer plate and made of an insulating material;
An intermediate block which is disposed between the electric shock transfer plate and the paddle base portion and which houses the sensor circuit portion between the sensor circuit portion and the paddle base portion and is made of an insulating material and is coupled to the paddle base portion,
And an electrode model plate coupled to the paddle base portion and contacting the human body model and made of a non-magnetic metal material,
The paddle-
A pair of slide fittings formed on the defibrillation paddle and slidably inserted into the pair of slide fittings;
And a lock lever which is locked or unlocked with a hook formed on the defibletion paddle;
The locking lever is provided with a locking protrusion at an upper end thereof and is supported so as to be able to ascend and descend along a guide hole of the paddle coupling portion. The locking lever is raised by the elastic force of the spring, and the locking protrusion is held in the hooked state. A defibrillator and a chest compression training model.
delete The method according to claim 1,
The chest compression training unit comprises:
A chest plate disposed in front of the back plate of the chest in the chest of the human body,
A spring for a chest plate installed between the chest plate and the back plate 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, and
And a displacement measuring unit for measuring the displacement of the chest plate and providing the displacement to the control unit.

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