CN217394950U - Medical health service robot for accidental injury of children in campus - Google Patents

Abstract

The utility model relates to the field of medical artificial intelligence robots, and discloses a campus children accidental injury medical health service robot, which comprises a base, a robot body, a robot head, first-aid equipment, medicine, a human-computer interaction module and a data storage module, wherein the data storage module stores information such as video, voice, characters or pictures for guiding a first witness to carry out correct treatment after accidental injury occurs, and the human-computer interaction module acquires interaction records of the first witness; the first witness can obtain professional medical guidance and carry out correct rescue treatment at the first time by utilizing the existing robot technology, the first witness can obtain professional medical guidance and carry out correct rescue treatment at the same time when the robot platform is carried into the campus and the first witness is guided to carry out correct rescue treatment within the first time when the accident happens, the handling capacity of the emergency event of the child accident, particularly the implementation rate of CPR of the first witness in the campus sudden cardiac arrest is improved, the life is saved, the cure rate is improved, and the disability rate is reduced.

Description

Medical health service robot for accidental injury of school children

The technical field is as follows:

the utility model relates to a medical treatment artificial intelligence robotechnology field, concretely relates to campus children accident injury medical health service robot can guide first witness person to carry out correct treatment after injury takes place for campus children.

Background art:

accidental injury of children has become the first killer of children of 0-14 years old worldwide, and is a main health problem threatening the life safety and the life quality of children in the 21 st century; according to statistics, about 40% of children died every year in the United states are caused by accidental injuries, and the accidental injuries are also the first cause of the death of the children aged 0-14 years in China as the biggest developing countries in the world; the children accidental injury mainly comprises sudden cardiac arrest, suffocation, drowning, traffic accidents, burns, scalds, abrasions, cutting wounds, lacerations, stabbing wounds, falling wounds, crush wounds and the like, when the accidental injury reaches a certain severity and the consciousness, the respiration, the circulation and the like of a sick child are obstructed and endanger the life, the sudden cardiac arrest (SCA for short) is often accompanied, then a first aid telephone needs to be dialed immediately, and cardiopulmonary resuscitation (CPR for short) needs to be performed if necessary; research shows that, except for families, the campus is a place where children have high accident injuries and occupies 19% of all accidents, in fact, most of injuries of the children in the campus can be prevented and controlled, the lives of children patients are not directly threatened, but once fatal injuries or diseases such as foreign bronchial bodies occur, timely and effective field treatment not only plays a decisive role in disease prognosis and recovery of the children with serious diseases, but also can win precious time for recovering the lives of the children.

Taking sudden cardiac arrest as an example: in the United states, about 45 million deaths are affected by SCA every year, the total number of deaths caused by SCA in China is estimated to be about 54.4 million, SCA is a problem generally concerned in the field of international emergency medical science, SCA which occurs outside hospitals is called out-of-hospital sudden cardiac arrest (called OHCA for short), actually, the OHCA accounts for about 80% of the total number of SCAs, and the gold emergency time is only 4-6 minutes (CPR is given immediately); however, even in a community with a sound emergency network, professional emergency personnel can hardly ensure that the emergency personnel arrive at the site for rescue within 4-6 minutes; according to survey, the autonomous circulation resuscitation success rate of SCA patients in China is only 0.02% -3.40%, and the final brain resuscitation success rate is as low as 0-0.02%, and research shows that school workers including teachers are often the first witnesses of children who are accidentally injured, and whether the first witnesses can be timely and effectively used for rescuing to play a vital role in prognosis and outcome transfer of children patients, the first-aid knowledge level of the campus workers in China on common accidental injuries such as SCA, foreign bodies in bronchus, fracture and the like is generally lower, even if a regularly trained school doctor is available, the school doctor often has no policy in the face of a first site or a sudden-arrest child, excessively depends on professionals and ambulances, depends on the principle of 'sending' and then 'rescuing', often causes the loss of precious gold emergency time, and the mode of implementing CPR in the gold emergency time is the most direct and effective mode; for other accidental injuries such as: suffocation, drowning, traffic accidents, burns, scalds, bruises, cuts, lacerations, stabs, falling wounds, crush wounds and the like, and if correct treatment can be carried out within the first time after the accidental injury happens, the treatment also plays a vital role in prognosis and return of the sick children.

The invention content is as follows:

the utility model aims at solving the above-mentioned problem, provide one kind through arranging intelligent robot in the campus, guide first witness person at the very first time through intelligent robot behind the injury that the campus children take place accident and carry out the campus children accidental injury medical health service robot who is suitable for the campus and uses the scene.

The utility model adopts the following technical scheme to realize the purpose of the invention: a robot for medical health service of accidental injury of children in campus comprises a base, a robot body, a robot head, a human-computer interaction module and a data storage module, wherein the robot body is arranged on the base, and the robot head is arranged at the top of the robot body; the human-computer interaction module comprises a camera, a touch display screen, a robot loudspeaker and a microphone, the camera, the touch display screen and the microphone are arranged on the front face of the head of the robot, and the robot loudspeaker is arranged on the body and/or the head of the robot; the data storage module is arranged in the body or the head of the robot, and stores treatment flow information which guides a first witness to carry out correct treatment after an intentional or traumatic injury occurs, the treatment flow information is broadcasted through a touch display screen and/or a robot loudspeaker, and the treatment flow information corresponding to the accidental injury can be selected and switched through the touch display screen; the camera and the microphone acquire treatment site audio and video information of the first witness during treatment, and the treatment site audio and video information is stored in the data storage module.

Furthermore, the human-computer interaction module still includes the intelligent voice interaction module based on touch display screen, robot speaker and microphone, and intelligent voice interaction module obtains first witness's speech information through the microphone and carries out the pronunciation answer through the robot speaker after speech recognition, processing or carries out the report of treatment flow information through touch display screen and/or robot speaker.

Furthermore, a multi-modal emotion recognition deep neural network is integrated in the human-computer interaction module.

Furthermore, the robot further comprises a power management module, the power management module is arranged on the back of the lower side of the robot body, and the power management module is powered by a 12V lithium battery and used for completing charging and discharging and system power consumption control.

Furthermore, the robot also comprises an information transmission module, wherein the information transmission module is used for positioning a school management platform, a hospital management platform and a teacher management platform in an accident injury occurrence place through a wired network and/or a wireless network, remotely guiding a first witness to carry out correct treatment, remote monitoring, starting an emergency treatment program and interaction of information stored in the data storage module.

Preferably, the school management platform is integrated on a monitoring device of a school security department or a medical office, the hospital management platform is integrated on a network system of a 120-degree emergency control center, and the teacher management platform is integrated on a mobile terminal of a teacher.

Further, the robot also comprises a first-aid kit, the first-aid kit is arranged on the base or the body of the robot, and first-aid medicines and first-aid articles are placed in the first-aid kit in a classified mode.

Further, the robot still includes first-aid equipment, first-aid equipment installs on base or the robot is physically, first-aid equipment includes ECG monitor, oxyhemoglobin saturation monitor and automatic external cardiac defibrillator.

Furthermore, the ECG monitor and the oxyhemoglobin saturation monitor are connected with the data storage module through data lines, and real-time monitoring data are uploaded to the data storage module for storage; the oxyhemoglobin saturation monitor is a finger-clip type oxyhemoglobin saturation monitor.

Furthermore, the automatic external cardiac defibrillator comprises a host, a connecting wire and an electrode plate; one end of each of the two connecting wires is connected with the main machine, and the other end of each of the two connecting wires is connected with the two electrode plates; the host is provided with a display screen, a defibrillator loudspeaker and an electric shock button.

Since the technical scheme is used, the utility model discloses better realization its invention purpose, this school garden children accident injury medical health service robot utilizes current robot technology, carry on the robot platform and get into the campus and guide first witness in the very first time that the accident takes place to carry out the automatic calling for help of automatic start first aid network when correct treatment, make first witness can obtain professional medical guidance and carry out correct treatment at the very first time, improve the throughput of children accident injury emergency especially the implementation rate of first witness's of campus cardiac arrest CPR, in order to save lives, improve the cure rate, reduce the disability rate.

Description of the drawings:

fig. 1 is a schematic view of the overall structure of the front side of the robot according to the present invention.

Fig. 2 is a schematic diagram of the overall structure of the back of the robot.

Fig. 3 is a schematic plane structure diagram of the automatic external cardiac defibrillator 8 of the present invention.

Fig. 4 is the utility model discloses well intelligent voice interaction module principle sketch.

Fig. 5 is a schematic diagram of the principle of the multi-modal emotion recognition deep neural network of the present invention.

Fig. 6 is a flow chart of the working principle of the robot of the present invention.

The reference numerals are illustrated in the following table.

Name of label	Number of mark	Name of label	Number of mark
				1	Base 1	8	Automatic external cardiac defibrillator 8
2	Robot body 2	81	Main unit 81
				3	Robot head 3	811	Display screen 811
4	Camera 4	812	Defibrillator speaker 812
				5	Touch display screen 5	813	Electric shock button 813
6	Robot loudspeaker 6	82	Connecting wire 82
				7	Microphone 7	83	Electrode plate 83

The specific implementation mode is as follows:

in order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings needed to be used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the drawings without creative effort, and the contents of the invention will be further described below with reference to the drawings:

example 1:

referring to the attached drawings 1, 2 and 6, the robot for medical health service of accidental injury of children on campus comprises a base 1, a robot body 2, a robot head 3, a human-computer interaction module and a data storage module, wherein the robot body 2 is installed on the base 1, and the robot head 3 is installed at the top of the robot body 2; the human-computer interaction module comprises a camera 4, a touch display screen 5, a robot loudspeaker 6 and a microphone 7, the camera 4, the touch display screen 5 and the microphone 7 are arranged on the front surface of the robot head 3, and the robot loudspeaker 6 is arranged on the robot body 2 and/or the robot head 3; the data storage module is arranged in the robot body 2 or the robot head 3, and stores treatment process information (including video, voice, characters or pictures and other information) for guiding a first witness to carry out correct treatment after an accidental injury occurs, wherein the treatment process information (including video, voice, characters or pictures and other information) is broadcasted through the touch display screen 5 and/or the robot loudspeaker 6, and the treatment process information (including video, voice, characters or pictures and other information) corresponding to the accidental injury can be selected and switched through the touch display screen 5; the camera 4 and the microphone 7 acquire treatment site audio and video information (including information such as videos, voices, characters or pictures) of the first witness during treatment, and store the treatment site audio and video information (including information such as videos, voices, characters or pictures) in the data storage module.

It should be noted that: the first witnesses comprise relatives of the sick and wounded and other persons on site, such as policemen, security guards, public service personnel, school workers comprising teachers and the like.

In an embodiment, referring to fig. 4, the human-computer interaction module further includes an intelligent voice interaction module based on the touch display screen 5, the robot speaker 6 and the microphone 7, where the intelligent voice interaction module obtains voice information of the first witness through the microphone 7, performs voice recognition and processing on the voice information, and then performs voice reply through the robot speaker 6 or broadcasts information such as video, voice, text or pictures through the touch display screen 5 and/or the robot speaker 6; the intelligent voice interaction module comprises voice pickup, voice recognition, natural language processing, voice synthesis and voice playing, wherein the natural language processing comprises natural language understanding and natural language generation, man-machine interaction between a first witness and the robot can be realized through the intelligent voice interaction module, the first witness can control the robot to perform related operations through voice, and through intelligent voice interaction, the robot can inform the first witness of a processing flow in detail and can collect and arrange feedback information at the same time, so that an important basis is provided for subsequent method improvement and decision making; specifically, the intelligent voice interaction module adopts a hundred-degree voice interaction technology, and in the field of Chinese voice interaction, hundred-degree companies have the leading technical level in the world and provide a relatively perfect application program interface.

In one embodiment, referring to fig. 5, a multi-modal emotion recognition deep neural network is further integrated in the human-computer interaction module; the robot is fully utilized to directly or indirectly obtain various types of data related to the first witness, including information such as videos, voices, characters or pictures, and the like, meanwhile, based on a deep learning technology, a multi-mode emotion recognition deep neural network can be constructed, single-mode internal information is learned through a private layer, and then the single-mode internal information is combined with interaction information between modes learned through a sharing layer to capture effective information of an emotion recognition task, so that the psychological state of the first witness can be accurately judged finally, and the first witness is guided to correctly conduct processing of emergency events of accidental injuries of children.

In one embodiment, the robot further comprises a power management module, the power management module is arranged on the back of the lower side of the robot body 2, and the power management module is powered by a 12V lithium battery and is used for completing charging and discharging and system power consumption control; the reliability of system operation is fully guaranteed, and the cruising ability of the instrument is improved.

In one embodiment, referring to fig. 6, the robot further includes an information transmission module, the information transmission module locates an accident injury occurring place, remotely guides the first witness to perform correct treatment, remote monitoring, starts an emergency treatment program, and interacts information stored in a data storage module through a wired network and/or a wireless network with a school management platform, a hospital management platform, and a teacher management platform, the school management platform is integrated on a monitoring device of a school security department or a medical office, the hospital management platform is integrated on a network system of a 120 emergency control center, and the teacher management platform is integrated on a mobile terminal of a teacher, such as a mobile phone and a tablet computer; the information transmission module is essentially used for comprehensively applying a sensor technology, an RFID technology, a wireless communication technology, a networking technology, a data processing technology, a target identification technology, a positioning technology and the like to the whole medical management system for information exchange so as to realize the functions of identification, positioning, tracking, monitoring, management and the like, thereby establishing a real-time, accurate and efficient medical control and management system; the wired network can support Ethernet, serial port communication, field bus and the like, and the wireless network can support Wi-Fi, a mobile network, RFID, Bluetooth and the like; the gateway carries out data storage and protocol conversion between the network layer and the perception extension layer and sends the data through the access network, and the gateway has the control and management capacity on the service terminal, can enable the campus robot to accurately start an emergency treatment program in the first time and send out a positioning signal, and scientifically designs a processing scheme and an optimal transfer mode and route.

In one embodiment, referring to fig. 6, the robot further comprises a first aid kit, which is mounted on the base 1 or the robot body 2 and in which first aid drugs and first aid articles are classified; the first-aid medicine comprises nikethamide, lobelin, deacetyl hairy flower glycoside, oumaohuaglycoside, nitroglycerin, metahydroxylamine, adrenaline, dopamine, atropine, potassium chloride, aminophylline, dexamethasone, ibuprofen, essential balm, Yunnan white drug powder aerosol, scald ointment, Longhurendan, wrinkled gianthyssop vital essence water and the like; the first-aid articles comprise medical hydrogen peroxide, medical iodine tincture, disposable medical alcohol cotton sheets, medical cotton sticks, medical gauze sheets, medical elastic bandages, benzalkonium chloride, medical tapes, macromolecular first-aid splints, medical disposable cold compress bags, scissors, flashlights, tweezers, safety pins, medical tapes and the like.

In one embodiment, referring to fig. 3 and 6, the robot further comprises emergency equipment, the emergency equipment is mounted on the base 1 or the robot body 2, and the emergency equipment comprises an electrocardiograph monitor, an oxygen saturation monitor and an automatic external cardiac defibrillator 8; the electrocardiogram monitor and the oxyhemoglobin saturation monitor are connected with the data storage module through data lines, and real-time monitoring data are uploaded to the data storage module to be stored; the oxyhemoglobin saturation monitor is a finger-clip type oxyhemoglobin saturation monitor; the automatic external cardiac defibrillator 8 comprises a host 81, a connecting wire 82 and an electrode plate 83; one end of each of the two connecting wires 82 is connected to the main machine 81, and the other end is connected to the two electrode plates 83; the host 81 is provided with a display screen 811, a defibrillator speaker 812 and a shock button 813.

It should be noted that: when the ECG monitor is needed: the buttons of the upper garment of the patient are released under the guidance of videos, pictures, voices and the like of the robot, the chest is exposed, the position outside the lower part of the central line of the clavicles on the left and the right sides and the position between the sixth rib of the front line of the axilla on the left side are selected as the electrode pad pasting position, and the type of the patient is selected by pressing a ' monitor setting ' key ' adult/child/infant; firstly, wiping the skin with small gauze on an electrode film, degreasing and wiping red, wherein the wiping range is as large as that of the electrode film, then wiping the skin pasted with the electrode film with an alcohol cotton ball, pasting the electrode film, connecting a monitoring lead, and the placement method of five electrodes comprises the following steps: upper Right (RA) right clavicle midpoint inferior border; the junction of the right inferior (RL) right clavicle midline and the lower edge of the thorax; upper Left (LA) lower border of midpoint of left clavicle; left inferior (LL) left clavicle midline junction with lower thoracic margin; the fourth intercostal space at the left border of the middle (CF) sternum, avoiding the defibrillation site; the three electrode placement methods are: upper Right (RA) right clavicle midpoint inferior border; upper Left (LA) middle lower edge of left clavicle; left inferior (LL) left mid-clavicular line meets the lower edge of the thorax.

When a finger-clip type oxyhemoglobin saturation monitor is required: the Reset key is pressed under the guidance of video, pictures, voice and the like of the robot, the LCD screen displays a standby state, the clamping opening is pressed, and the middle finger of the left hand or the right hand is inserted into the working bin (the infrared light in the working bin can be seen, and the fingers can not be clamped askew, the hands can not be wet and foreign matters can not be arranged on the surface of the nail); after the finger is completely contacted with the working bin, the LCD displays the detection process (paying attention to entering a detection state, keeping the stability of the detected finger and avoiding shaking up, down, left and right); the upper% SpO2 of the screen of the finger-clipped oxyhemoglobin saturation monitor is the blood oxygen index, and Min below the screen is the pulse rate.

When an automated external cardiac defibrillator 8 is required: the power switch of the AED is turned on under the guidance of video, picture, voice and the like of the robot, electrode plates 83 are tightly attached to the patient at proper positions of the chest of the patient (generally, two electrode plates are respectively attached to the upper part of the right chest and the outer side of the left nipple of the left chest) according to the visual and audio prompting operations of the robot or the AED, the specific positions can refer to the drawing on the AED host 81 and the description of the pictures on the electrode plates 83, a connecting lead 82 plug connected with the electrode plates 83 is inserted into a jack of the AED host 81, the defibrillator can continuously detect the connection condition of the multifunctional electrode plates 83 and prompt whether the connection is normal through a display screen 811 and a loudspeaker 812 of the defibrillator, the AED automatically starts to analyze the heart rate after the connection is normal (in the process, the AED does not need to contact the patient, even if slight touch is possible to influence the analysis of the AED), and after the analysis, the AED sends a suggestion whether to defibrillate or not, when defibrillation is indicated, the AED does not contact the patient, simultaneously tells anyone else nearby to get away from the patient, and the operator presses the shock button 813 to defibrillate, after one shock is finished, the AED can restart analyzing the rhythm of the heart of the patient, judge whether the shock is successful, and simultaneously have voice and text information to prompt to continue to guide to finish more shocks, or assist CPR under the guidance of video, pictures, voice and the like of the robot until the arrival of emergency personnel.

As a supplement to the above, the diagnostic criteria for cardiac arrest are: firstly, the patient suddenly falls down and consciousness is suddenly lost; the large artery such as the carotid artery disappears, and the auscultation heart sound disappears; the pupil is changed from small to big; fourthly, the patient stops spontaneous respiration; the patient's face changes from ruddy to sweet or pale.

The cardiac arrest resuscitation criteria were: firstly, the face color of a patient turns from sweet or pale to ruddy, and lips turn to ruddy; large arteries such as the carotid artery can touch the pulse; (iii) dilated pupil constriction; fourthly, recovering spontaneous respiration; the limb has the contracting machine to recover some involuntary movements: mean arterial pressure.

The use method of the medical health service robot in the patent comprises the following steps: when the first witness discovers that accidental injury (such as sudden cardiac arrest) occurs, the first witness moves the patient into the coverage range of the robot camera or the robot automatically moves to the position near the patient to enable the patient to be in the coverage range of the robot camera, the first witness can guide the first witness to carry out correct treatment corresponding to the accidental injury (such as sudden cardiac arrest) through the touch control display screen 5 or through the voice control robot through broadcasting videos, voices, pictures and the like, so that the first witness can obtain professional medical guidance and carry out correct treatment at the first time, meanwhile, the robot automatically starts an emergency network to automatically call for help from a school management platform, a hospital management platform and a teacher management platform and sends out positioning signals (a recent scientific design treatment scheme of the hospital and an optimal transfer mode and route), and when necessary, the first witness can call for help from the robot videos, the robot and the robot can automatically call for help to the school management platform, the hospital management platform and the teacher management platform to send positioning signals (the optimal transfer mode and route) The emergency treatment method comprises the steps of using emergency drugs, emergency articles and emergency equipment (an ECG monitor, a blood oxygen saturation monitor, an automatic external cardiac defibrillator 8 and the like) under the guidance of pictures, voice and the like, recording and recording sound through a camera 4 and a microphone 7 in the whole treatment process, storing the recorded sound in a data storage module, and meanwhile, realizing the remote online guidance and correct treatment of a school management platform, a hospital management platform and a teacher management platform through the camera 4, the touch display screen 5, a robot loudspeaker 6 and the microphone 7, and improving the capability of handling the campus child accidental injury emergency events (especially the implementation rate of CPR of a first witness in campus cardiac arrest) so as to save lives, improve the cure rate and reduce disability and fatality rates.

It is clear that modifications and/or additions of parts may be made to the campus child accident injury robot as described heretofore, and to the corresponding method, without departing from the field and scope of the present invention.

It is also clear that although the present invention has been described in detail with reference to a campus children accidental injury medical health service robot, a person skilled in the art must be able to obtain many other equivalent campus children accidental injury medical health service robots and corresponding methods thereof, which have the features as claimed and therefore all lie within the scope of protection field defined thereby.

Claims (7)

1. The utility model provides a campus children accidental injury medical health service robot which characterized in that: the robot comprises a base (1), a robot body (2), a robot head (3), a human-computer interaction module and a data storage module, wherein the robot body (2) is arranged on the base (1), and the robot head (3) is arranged at the top of the robot body (2); the human-computer interaction module comprises a camera (4), a touch display screen (5), a robot loudspeaker (6) and a microphone (7), the camera (4), the touch display screen (5) and the microphone (7) are arranged on the front surface of the robot head (3), and the robot loudspeaker (6) is arranged on the robot body (2) and/or the robot head (3); the data storage module is arranged in the robot body (2) or the robot head (3), and stores treatment process information which guides a first witness to carry out correct treatment after an intentional trauma occurs, the treatment process information is broadcasted through a touch display screen (5) and/or a robot loudspeaker (6), and the treatment process information corresponding to the accidental injury can be selected and switched through the touch display screen (5); the camera (4) and the microphone (7) acquire treatment site audio and video information of the first witness during treatment, and the treatment site audio and video information is stored in the data storage module.

2. The medical health service robot for the accidental injury of the campus child as claimed in claim 1, wherein: the man-machine interaction module further comprises an intelligent voice interaction module based on the touch display screen (5), the robot loudspeaker (6) and the microphone (7), wherein the intelligent voice interaction module acquires voice information of a first witness through the microphone (7), and carries out voice reply through the robot loudspeaker (6) after voice recognition and processing or broadcasts treatment flow information through the touch display screen (5) and/or the robot loudspeaker (6).

3. The medical health service robot for the accidental injury of the campus child as claimed in claim 1, wherein: the robot further comprises a power management module, the power management module is arranged on the back of the lower side of the robot body (2), and the power management module is powered by a 12V lithium battery and used for completing charging and discharging and system power consumption control.

4. The medical health service robot for the accidental injury of the campus child as claimed in claim 1, wherein: the robot further comprises a first-aid kit, wherein the first-aid kit is mounted on the base (1) or the robot body (2), and first-aid medicines and first-aid articles are placed in the first-aid kit in a classified mode.

5. The medical health service robot for the accidental injury of the campus child as claimed in claim 1, wherein: the robot further comprises first-aid equipment, the first-aid equipment is installed on the base (1) or the robot body (2), and the first-aid equipment comprises an electrocardiogram monitor, an oxyhemoglobin saturation monitor and an automatic external cardiac defibrillator (8).

6. The medical health service robot for the campus child accidental injury according to claim 5, wherein: the ECG monitor and the oxyhemoglobin saturation monitor are connected with the data storage module through data lines, and real-time monitoring data are uploaded to the data storage module for storage; the oxyhemoglobin saturation monitor is a finger-clip type oxyhemoglobin saturation monitor.

7. The medical health service robot for the campus child accidental injury according to claim 5, wherein: the automatic external cardiac defibrillator (8) comprises a host (81), a connecting lead (82) and an electrode plate (83); one ends of the two connecting wires (82) are respectively connected with the main machine (81), and the other ends of the two connecting wires are respectively connected with the two electrode plates (83); a display screen (811), a defibrillator loudspeaker (812) and a shock button (813) are arranged on the host (81).

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