KR101431102B1 - Human body model for vital sign assessment training - Google Patents

Abstract

According to the present invention, a human body model device for a vital sign assessment training includes: a body temperature output unit disposed in a human body model to output heat similar to that of an actual human body temperature; an oxygen saturation output unit which outputs an infrared ray and red light through two light sources which are provided; a pulse output unit which outputs a vibration similar to that of an actual human body pulse; an auscultation sound output unit which outputs an auscultation sound similar to that of an actual human body auscultation sound; a blood pressure output unit which outputs a Korotkoff sound through a speaker provided in accordance to a set blood pressure value; an ECG output unit disposed in the chest, wrist, and ankle parts of the human body model and recognizes an ECG measurement position by generating an output voltage in a Hall sensor which is provided based on the frequencies when an ECG measurement probe generating the different frequencies approaches; and a pupilary reflex output unit disposed on the face of the human body model and adjusts the size of an aperture provided through a motor which is provided to output a movement similar to that of an actual human body pupilary reflex when light is detected by an optical sensor which is provided.

Description

{HUMAN BODY MODEL FOR VITAL SIGN ASSESSMENT TRAINING}

TECHNICAL FIELD The present invention relates to a human body model for training a human body's vital sign examination. More specifically, the present invention relates to a vital sign which includes body temperature, pulse, respiration, blood pressure, electrocardiogram, oxygen saturation, This is a technique for implementing the human body model so as to be similar to the human body model.

The vital signs include signs and symptoms indicating a living condition of a human, and include body temperature, pulse, respiration, blood pressure, consciousness, urination, defecation, appetite, sleeping and nerve reflexes appearing from the human body. Medical activities start with observing and evaluating the vital signs of the living body. Therefore, it is necessary to accurately measure vital signs in the human body in order to accurately grasp the condition of the patient and provide effective medical services.

A human body model for vital signs screening training is being developed for training to accurately measure the vital signs of the body. Vital Signs Training physical models simulate the body's vital signs such as body temperature, pulse, respiration, blood pressure, electrocardiogram, oxygen saturation and pupil reflexes, and provide various clinical scenarios and programs. In order to maximize the learning and training effects through the human body model for the vital sign examination training, it requires advanced functions that can provide a similar visual and tactile effect to the human body. If these advanced functions are provided in the human body model for the vital signs screening training, it is possible to create an environment for maximizing the learning effect and provide an environment in which the user can see and feel as if he treats the actual patient. In addition, by providing various types of virtual patient models that reflect actual human anatomy and physiology, it is possible to gradually master appropriate procedures and problems in medical examination, to determine complications and situations, It improves the method. By recording and evaluating the objective performance and the status of the trainees majoring in medicine related field through the human body model for the vital signs screening training, the ability of the unskilled medical person can be compensated.

The human body model for the vigor symptom screening training is now being introduced at the medical field, and its application area is also expanding from professional medical staff to medical practitioner 's education and training. However, in Korea, the development of the human body model has not been completed yet. In addition, the conventional human body model for vital signs examination training has basic functions such as pulse, blood pressure, stethoscopic sound, electrocardiogram, and pupillary response. However, the body temperature examination function and the oxygen saturation examination function, which are typical vital signs, .

The object of the present invention is to provide a human body model capable of exercising body temperature, pulse, respiration, blood pressure, electrocardiogram, oxygen saturation, and pupil reflex vigilance symptom training training, and provides various clinical scenarios and programs through the human body model Apparatus and method.

The human body model apparatus for vital signs examination training according to the present invention includes a human body model having a shape similar to an actual human body and a control unit for controlling the operation of the vital sign output unit. A body temperature output unit installed inside the human body for outputting heat similar to the body temperature of the human body, an oxygen saturation output unit for outputting infrared rays and red light through the two light sources, A pulse output unit installed inside the human body and outputting a vibration similar to a pulse of a human body, a stethoscope sound output unit installed inside the human body model to output a stethoscope sound similar to a human body's stethoscope sound, A blood pressure output unit for outputting through a speaker equipped with a Korotkoff sound in accordance with the set blood pressure value, an electrocardiogram (ECG) measuring unit which is installed in the chest, wrist and ankle part of the human body, An electrocardiogram output unit for generating an output voltage based on the frequency at a Hall sensor provided when the probe approaches; And when installed on the face, light is detected from the provided optical sensor, to adjust the size of the aperture provided through the motor having to include the actual body cavity reflection and the pupil reflection output unit configured to output a similar movement.

Since the human body model apparatus for vital signs examination training exercise according to the present invention elaborates and implements body temperature, pulse, respiration, blood pressure, electrocardiogram, oxygen saturation and pupil reflex, which are vital signs of the human body, Realistic medical examination training can be performed reminiscent of actual patient. Particularly, in the present medical field, various simulator devices such as a human body model device for vital signs screening training are beginning to be expanded and expanded in order to increase the educational effect. In order to meet this trend, a human body model device for vital signs diagnosis training It will help to secure high quality medical personnel by training various medical personnel.

FIG. 1 is a view schematically showing an embodiment of a human body model apparatus for a vital signs examination exercise according to the present invention.
2 is a block diagram showing an embodiment of a human body model apparatus for vital signs and symptoms screening training according to the present invention.
3 is a detailed view of a body temperature output unit 111 of a human body model for a vital signs examination exercise according to an embodiment of the present invention.
4 is a detailed view of a pulse output unit 112 of a human body model for a vital signs examination exercise according to an embodiment of the present invention.
5 is a detailed view of a stethoscope sound output unit 113 of a human body model for a vital signs examination training according to an embodiment of the present invention.
6 is a detailed view of an electrocardiogram output unit 115 of a human body model for a vital sign examination exercise according to an embodiment of the present invention.
7 is a detailed view of the oxygen saturation output unit 116 of the human body model for the vital signs examination training according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. The terms used in the present specification are terms selected in consideration of the functions and effects in the embodiments, and the meaning of the terms may vary depending on the intention of the user or the operator or industry custom. Therefore, the meaning of the term used in the following embodiments is based on the defined definition when specifically stated in this specification, and unless otherwise stated, it should be interpreted in a sense generally recognized by those skilled in the art.

FIG. 1 is a view schematically showing an embodiment of a human body model apparatus for a vital signs examination exercise according to the present invention.

Referring to FIG. 1, the human body model apparatus for vital signs and symptoms examination training according to the present invention includes a human body model 100 and a control unit 130.

The vital sign examination training human body model (100) shows a shape similar to a human shape and includes a vital sign output portion inside. The vital signs for training the human body training model 100 includes a vital sign output unit and the vital sign output unit provides an output corresponding to the vital signs of the actual human body. The user can obtain a training effect similar to the training to measure the vital signs of the actual body through training to measure the output provided by the vital sign output. The output corresponding to the vital signs output from the vital sign output unit includes body temperature, pulse, breath sounds, blood pressure, electrocardiogram, oxygen saturation, and pupil response. The vital sign output is located at a corresponding location in the human body according to the type of signal to be output. For example, the vital sign output that outputs the pupil response is located in the pupil where the pupil is located.

The control unit 130 controls the actuator of the vital sign output unit and transmits the output signal received from the vital sign output unit to the monitoring device 10. The control unit 130 controls the vital sign output unit based on the control request or control signal input from the user through the monitoring device 10. [ A signal received from the vital sign output unit is provided to the monitoring device 10 so that the user can check various information including the state of the vital sign output unit and the output signal through the screen provided in the monitoring device 10. The control unit 130 may be provided outside the human body model 100 for the vital sign examination exercise training or may be provided inside the human body model 100 for the vital sign examination exercise.

The monitoring device 10 is connected to the control unit 130 through wired or wireless communication, and can determine the status of the vital sign output unit through the control unit 130 or can set various scenarios for the vital sign output unit.

2 is a block diagram showing an embodiment of a human body model apparatus for vital signs and symptoms screening training according to the present invention.

Referring to FIG. 2, the human body model apparatus for vital signs examination training according to the present invention includes a vital sign output unit 110 and a control unit 130.

The vital sign output unit 110 includes a body temperature output unit 111, a pulse output unit 112, a stethoscope sound output unit 113, a blood pressure output unit 114, an electrocardiogram output unit 115, an oxygen saturation output unit 116 And a pupil reflection output unit 117. [

The body temperature output unit 111 is a device for generating a predetermined temperature in order to exhibit the same effect as the body temperature of the body in the human body model for the vital sign examination training exercise. The body temperature output unit 111 includes a heat generating unit for generating body temperature, a temperature sensor for controlling the temperature, and a heat radiating plate, and generates heat corresponding to the set body temperature value. The body temperature output unit 111 increases the temperature through the provided heat generating resistor and reduces the temperature through the provided heat sink. The heat sink provided in the body temperature output unit 111 may be included in the body temperature output unit 111 as an additional component or may be constructed by making the housing of the body temperature output unit 111 a heat sink structure. The temperature of the body temperature output unit 111 can be rapidly diverged through the heat dissipation plate provided to lower the temperature of the body temperature output unit 111. [ As a heat generating part of the body temperature output part 111, a general heat generating resistor or a transistor can be used, and a temperature sensor can use the LM35. The heating unit and the temperature sensor constituting the body temperature output unit 111 are not limited to the heating unit and the temperature sensor constituting the body temperature output unit 111, A temperature sensor can be applied.

The body temperature output unit 111 is installed inside the human body model for vital signs examination training. Particularly, the body temperature output unit 111 is made of a human ear shape so as to enhance the effect of the examination training, It is preferable to be installed at the ear of the human body model for examination training. The body temperature output unit 111 can display a human ear-shaped structure when it is installed at the ear portion of the human body model for vital sign examination training. The user can obtain a training effect similar to measuring the body temperature of the human body by measuring the body temperature of the human body model for the vital signs examination training through a method of approaching the body temperature sensor to the body temperature output unit 111. [

The pulse output unit 112 outputs a pulse similar to a pulse generated in the human body. The pulse output 112 includes a pulse-driven speaker and a vascular structure. The pulse output unit 112 outputs a sound source corresponding to a predetermined pulse cycle through a pulse-driven speaker. When the pulse is outputted through the pulse-driven speaker, the voice coil inside the pulse-driven speaker drives up and down based on the period of the sound source, and the diaphragm inside the pulse-driven speaker changes the electric signal into a sound wave according to the up- Up and down. The blood vessel structure of the pulse output unit 112 is located at the upper end of the diaphragm provided in the pulse-driven speaker, and the blood vessel structure moves up and down according to the vertical movement of the diaphragm of the pulsating driving speaker according to the pulse sound source. Pulse is achieved through vertical movement of the blood vessel structure provided in the pulse output unit 112. The pulse output unit 112 may be installed at the position of the human body model for vital sign examination training corresponding to the carotid, radial, and brachial arteries of the human body. The user can obtain a training effect similar to measuring the pulse of the actual human body by measuring the vibration of the pulse output unit 112. [

The stethoscope sound output unit 113 outputs a stethoscope sound similar to a stethoscope sound generated in a human body. The stethoscope sound output unit 113 outputs various stethoscopic sounds through a speaker according to various cases. The stethoscope sound output unit 113 is located at the front part and the rear part of the bronchus, the lung, and the measurement position for measuring the stethoscope sound. The stethoscope sound output unit 113 outputs different stethoscopes according to the positions of the human body model for the vital signs examination training. For example, it can be installed in the trachea or lungs to output breath sounds, to be installed in the heart part to output heart sounds, or to be installed in the large intestine or small intestine to output a long sound. The user can measure various stunning sounds of the stunning sound output unit 113 installed at various positions, grasp the difference of the stunning sounds according to the respective positions, and train the difference of the stunning sounds according to various body conditions .

The blood pressure output unit 114 outputs a Korotkoff sound according to the blood pressure of the human body. The blood pressure output unit 114 is realized by connecting the cuff to the pressure sensor and reproducing the Cortocarp sound through the speaker provided according to the set blood pressure value. The position of the blood pressure output unit 114 may be provided at various positions of the human body model for the vital sign examination exercise. The user performs blood pressure measurement at the position where the blood pressure output unit 114 is installed, Similar training effects can be obtained.

The electrocardiogram output unit 115 is a device for providing a training to measure the electrocardiogram of the human body. The electrocardiogram output unit 115 can measure the electrocardiogram of the human body model for vital signs examination training through an electrocardiogram measurement probe for measuring the electrocardiogram from the electrocardiogram output unit 115. The electrocardiogram output unit 115 is constituted by a hall sensor, and is located in the chest of the chest of the human body model for the vital sign examination training and the ankles of the wrists and left / right legs of the left and right arms. The electrocardiogram measuring probe has a coil and generates different predetermined frequencies depending on the position of the electrocardiogram output unit 115. The hall sensor of the electrocardiogram output unit 115 generates the output voltage based on the frequency generated in the coil of the electrocardiogram measurement probe. Since the electrocardiogram measurement probe generates different frequencies depending on the setting, the hall sensor of the electrocardiogram output unit 115 also generates different output voltages according to the frequency of the electrocardiogram measurement probe. The position of the electrocardiogram can be recognized through the difference in the output voltage generated by the hall sensor of the electrocardiogram output unit 115. [ The electrocardiogram graph previously programmed according to the recognized electrocardiogram measurement position is output on the screen of the monitoring device 10 based on the output voltage output from the Hall sensor of the electrocardiogram output unit 115. [ Thus, by implementing an electrocardiogram measurement, a user can obtain a training effect similar to that of measuring an actual person's electrocardiogram. The electrocardiogram output unit 115 and the electrocardiogram measurement probe will be described later in detail with reference to FIG.

The oxygen saturation output 116 is a device for providing training to measure oxygen saturation in a person's body and is located at the fingertip of the human body model for vital signs screening training. The oxygen saturation output unit 116 includes an infrared LED (Light Emitting Diode) and a red LED. The infrared LED of the oxygen saturation output unit 116 and the light source output from the red LED are measured in an oxygen saturation measurement probe to implement oxygen saturation measurement. The oxygen saturation of the infrared LED of the oxygen saturation output unit 116 is adjusted to change the oxygen saturation and the output pulse of the red LED is adjusted to realize the pulse change. The user can obtain a training effect similar to measuring the oxygen saturation in the human body by measuring the light source output from the infrared LED and the red LED of the oxygen saturation output unit 116 through the oxygen saturation measurement probe. The oxygen saturation output unit 116 and the probe for measuring oxygen saturation will be described later in detail with reference to FIG.

The pupil reflection output unit 117 is a device for providing a training for confirming the pupil reflex in the human body, and is located at a position corresponding to the eye of the face portion of the human body model for the vital sign examination training. The pupil reflection output section 117 is composed of a diaphragm, a motor, and an optical sensor. When the light is projected onto the pupil reflection output unit 117, the optical sensor of the pupil reflection output unit 117 senses the light to drive the provided motor to adjust the size of the iris to realize the pupil reaction state. That is, the change in the size of the diaphragm provided in the pupil-reflection output section 117 indicates the change in pupil size. The user can obtain a training effect similar to that of confirming the pupil reflex in the human body through the change in the size of the iris displayed when the light is reflected on the pupil reflection output part 117. [

The control unit 130 controls the vital sign output unit 110 and transmits data received from the vital sign output unit 110 to the monitoring device 10. The control unit 130 processes sensor signals of various output units provided in the vital sign output unit 110 installed in the human body model for vital signs diagnosis training and controls driving of the actuators of the respective output units. Upon receiving the control signal for the human body model received from the monitoring device 10, the control unit 130 controls the driving of each output unit provided in the vital sign output unit 110 based on the received control signal. The control unit 130 transmits sensor signals of various output units provided in the vital sign output unit 110 to the monitoring device 10. The sensor signal transmitted to the monitoring device 10 can provide various information to the user through the screen provided in the monitoring device 10. [

The control unit 130 may control the vital sign output unit 110 based on various preset scenarios. The various preset scenarios include information about the vital signs that may occur when various medical conditions that may occur in the human body occur. The control unit 130 controls the vital sign output unit 110 on the basis of a scenario input from a user or a scenario stored in advance through the monitoring device 10. Based on the scenario, the control unit 130 includes a body temperature output unit 111, a pulse output unit 112, a stethoscope sound output unit 113, a blood pressure output unit 114, an ECG output The oxygen saturation output unit 116, and the pupil reflection output unit 117, respectively. Under the control of the control unit 130 based on the scenario, the vital sign output unit 110 outputs an output different from the general case. For example, when the scenario for the occurrence of a breathing difficulty state is applied, the controller 130 provides the vital sign output unit 110 with an output corresponding to the vital sign corresponding to the breathing difficulty condition. The user can measure the signal of the vital signs output unit 110 and can grasp the difficulty of breathing. Through this, the user can learn the medical condition occurring in the body from the vital signs that appear in the body, You can train through.

3 is a detailed view of a body temperature output unit 111 of a human body model for a vital signs examination exercise according to an embodiment of the present invention.

Referring to FIG. 3, the body temperature output unit 111 of the human body model for the vital sign examination exercise according to an embodiment of the present invention includes a predetermined body temperature model It is a device that generates temperature. The body temperature output section 111 is composed of a heat generating section 111-1, a temperature sensor 111-2 and a heat dissipation housing 111-3.

The heat generating unit 111-1 generates a temperature corresponding to the set body temperature value. The heat generating resistor 111-1 generates heat corresponding to various body temperature values set by the control unit, and generates heat similar to the body temperature of the body. The heat generating unit 111-1 can be applied to most commonly used heating resistors or transistors. The temperature sensor 111-2 measures the temperature of the heat generating unit 111-1, compares the measured temperature with the set body temperature value, and adjusts the temperature of the heat generating resistor 111-1. The heat dissipation housing 111-3 quickly dissipates the heat of the heat generating portion 111-1 and lowers the temperature of the heat generating portion 111-1. The heat generating unit 111-1 generates heat when it is confirmed that it is lower than the body temperature value set by the temperature sensor 111-2 and when the temperature becomes equal to or higher than the set body temperature value, -1) is diverged to lower the temperature of the body temperature output section 111.

The body temperature output unit 111 is installed at the ear position of the human body model for the vital signs examination training corresponding to the ear of the human body. The body temperature output unit 111 preferably has a shape similar to that of a human ear so that the user can use more realistic training. The user can obtain a training effect similar to measuring a human body temperature by measuring the heat emitted from the body temperature output unit 111 by approaching the ear thermometer to the ear of the human body model for vital signs diagnosis training.

4 is a detailed view of a pulse output unit 112 of a human body model for a checkup training according to an embodiment of the present invention.

Referring to FIG. 4, the pulse output section 112 includes a pulse-driven speaker 112-1 and a blood vessel structure 112-2. The pulse-driven speaker 112-1 includes a voice coil 112-3 and a diaphragm 112-4. The voice coil 112-3 vibrates up and down based on the pulse sound source received from the control unit. The pulse sound source received from the control unit is a sound source having a pulse period similar to a pulse generated in a human body. When the voice coil 112-3 vibrates up and down based on the received pulse source, the diaphragm 112-4 located at the upper end of the voice coil 112-3 vibrates up and down the voice coil 112-3 And oscillates up and down in the same cycle.

The blood vessel structure 112-2 located at the upper end of the diaphragm 112-3 exhibits the same up and down movement in accordance with the up-down vibration of the diaphragm 112-3. The user can measure the pulse that is similar to measuring the pulse in the actual person's body by measuring the up-down movement of the blood vessel structure 112-2 generated in the pulse-driven speaker 112-1.

The pulse output unit 112 may be installed at the position of the human body model for vital sign examination training corresponding to the carotid, radial, and brachial arteries of the human body. The user can obtain a training effect similar to that of measuring the pulse of the actual body by measuring the pulse vibration of the pulse output portion 112 provided at the portion where the artery of the human body passes.

5 is a detailed view of a stethoscope sound output unit 113 of a human body model for a vital signs examination training according to an embodiment of the present invention.

Referring to FIG. 5, the stethoscope sound output unit 113 outputs a stethoscope sound similar to a stethoscope sound generated in a human body. The stethoscope sound output unit 113 may be installed at the position of the human body model for the vital sign examination training corresponding to the bronchus of the human body, the front portion and the back portion of the lung. The stethoscope sound output unit 113 outputs different sounds according to the positions of the human body model for the vital signs examination training. The heart sound output section 113-1 provided at the heart part outputs a sound corresponding to the heart sound and the long sound output section 113-2 provided at the large intestine or small intestine part outputs sound corresponding to the long sound. The user can measure various stunning sounds of the stunning sound output unit 113 installed at various positions, grasp the difference of the stunning sounds according to the respective positions, and train the difference of the stunning sounds according to various body conditions .

6 is a detailed view of an electrocardiogram output unit 115 of a human body model for a vital sign examination exercise according to an embodiment of the present invention.

Referring to FIG. 6, the electrocardiogram output unit 115 is preferably located at six positions on the chest of the human body model for vital sign examination training, and four places on the wrists of the left and right arms and the ankles of the left and right legs. The electrocardiogram output unit 115 is constituted by an Hall sensor, and the electrocardiogram measurement probe 601 can be approached to the electrocardiogram output unit 115 to recognize the electrocardiogram measurement position. The electrocardiogram measuring probe 601 has a coil, and the coils of the electrocardiogram measuring probe 601 generate different frequencies according to the setting. When the electrocardiogram measurement probe 601 approaches the electrocardiogram output unit 115, an output voltage is generated in the hall sensor of the electrocardiogram output unit 115 by the frequency at which the coil of the electrocardiogram measurement probe 601 is generated. The intensity of the output voltage generated by the hall sensor is determined by the frequency generated in the coil of the electrocardiograph measurement probe 601. Accordingly, the electrocardiogram measurement position can be recognized by adjusting the frequency generated by the electrocardiogram measurement probe 601 and adjusting the output voltage generated by the electrocardiogram output unit 115. The output voltage generated by the electrocardiogram output unit 115 is transmitted to the monitoring device through the control unit. The monitoring device provides the electrocardiogram measurement result screen based on the output voltage delivered from the electrocardiogram output section 115. [ The user can obtain a training effect similar to measuring the electrocardiogram of an actual body by accessing the electrocardiogram measuring probe 601 to the electrocardiogram output unit 115 and thereby checking the electrocardiogram measurement result appearing on the screen of the monitoring apparatus.

7 is a detailed view of the oxygen saturation output unit 116 of the human body model for the vital signs examination training according to an embodiment of the present invention.

Referring to FIG. 7, the oxygen saturation output unit 116 of the human body model for the vital signs examination training is located at the fingertip 701 of the human body model for the vital signs examination exercise. The oxygen saturation output unit 116 includes a first light emitting unit 116-1 and a second light emitting unit 116-2.

The first light emitting unit 116-1 is a light source emitting red light, and is preferably implemented as a red LED. The second light emitting unit 116-2 is a light source for emitting infrared rays, and is preferably implemented by an infrared LED.

The oxygen saturation measuring probe 702 is engaged with the oxygen saturation output portion 116 located at the fingertip end 701 of the human body and the first light emitting portion 116-1 and the second light emitting portion 116-2 Measure the oxygen saturation by measuring the emitted red light and infrared light. The oxygen saturation output unit 116 adjusts the output pulse of the red light emitted from the first light emitting unit 116-1 to implement a change in pulse and the light intensity of the infrared light emitted from the second light emitting unit 116-2 To change the oxygen saturation. Accordingly, the oxygen saturation measured through the oxygen saturation output unit 116 can be adjusted to perform the oxygen saturation measurement training according to scenarios in which various body conditions are assumed.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, It is possible.

100: Human body model
110: vital sign output unit
111: Body temperature output unit
112: pulse output section
113: Stethoscope sound output section
114: blood pressure output section
115: Electrocardiogram output section
116: oxygen saturation output unit
117: pupil reflection output section
130:

Claims (5)

Human body model which is similar to actual body shape;
A body temperature output unit installed inside the human body and outputting heat similar to a body temperature of a human body;
An oxygen saturation output unit disposed at a distal end of the human body to output infrared rays and red light through the two light sources;
A pulse output unit installed inside the human body and outputting a vibration similar to a pulse of an actual human body;
A stethoscope sound output unit installed in the human body model and outputting a stethoscope sound similar to a stethoscope sound of an actual human body;
A blood pressure output unit installed in the human body and outputting the blood through a speaker equipped with a Korotkoff sound according to a preset blood pressure value;
An ECG output unit installed inside the human body and recognizing an ECG measurement position;
A pupil reflection output unit installed at a face portion of the human body and outputting a motion similar to a pupil reflection of a human body by adjusting a size of a diaphragm provided through a motor provided when light is sensed by the optical sensor; And
The oxygen saturation output unit, the pulse output unit, the stethoscope sound output unit, the blood pressure output unit, the electrocardiogram output unit, and the pupil reflection output unit, according to a predetermined scenario in consideration of vital signs according to body conditions. A control unit for controlling operations of at least one output unit among the plurality of output units;
And a human body model device for vital signs and symptoms screening training. The method according to claim 1,
The electrocardiogram output unit includes:
When an electrocardiogram measuring probe provided at the chest, wrist and ankle portions of the human body and having coils for generating different frequencies approaches the Hall sensor, an output voltage is generated based on the frequency at a Hall sensor And the position of the electrocardiogram is recognized. The method according to claim 1,
Wherein the pulse output section comprises:
A voice coil oscillating up and down based on the pulse sound source received from the control unit;
A diaphragm installed at an upper end of the voice coil to generate a pulse similar to a pulse of an actual human body based on an up-down vibration of the voice coil; And
A blood vessel structure installed at an upper end of the diaphragm and moving up and down by the up and down vibrations of the voice coil and the diaphragm to exhibit a motion similar to a pulse of an actual human body;
And a human body model device for vital signs and symptoms screening training. The method according to claim 1,
The body-
The ear or the underarm portion of the human body,
A heating unit for generating heat based on the set body temperature value;
A temperature sensor for sensing the heat generated by the heating unit and adjusting the temperature of the heating unit; And
A heat dissipation housing installed in the heat generating unit and radiating heat generated by the heat generating unit to cool the heat dissipation housing;
And a human body model device for vital signs and symptoms screening training. The method according to claim 1,
The oxygen saturation output unit includes:
Wherein the first light emitting unit emits red light and the second light emitting unit emits infrared light, and the output pulse of the red light emitted from the first light emitting unit is adjusted to change the pulse, And the oxygen saturation is changed by adjusting the light amount of the emitting infrared rays.

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