CN210574591U - Full-automatic mobile phone monitoring cardio-pulmonary resuscitation training model - Google Patents

Abstract

The utility model discloses a full-automatic mobile phone monitoring cardiopulmonary resuscitation training model, it includes: a mannequin, comprising: the device comprises a head, a neck, a chest, a control device, a wireless communication device and a state feedback device for simulating clinical response of a patient; the chest part is provided with an external chest compression recognition device and an artificial lung pressure recognition device; the control device is electrically connected with the external chest compression recognition device and the artificial lung pressure recognition device; the state feedback device is electrically connected with the control device; the wireless communication device is electrically connected with the control device; the human body model also comprises a two-dimensional code for connecting the wireless communication device after an operator scans the code; and the mobile terminal is used for scanning the two-dimensional code on the human body model so as to enable the mobile terminal to be in communication connection with the wireless communication device of the human body model and receive and process the state information. The utility model discloses intelligent degree is high, carries out clinical reaction simulation on human body model according to operator's operation, is connected with mobile terminal moreover, feeds back operation data in real time.

Description

Full-automatic mobile phone monitoring cardio-pulmonary resuscitation training model

Technical Field

The utility model relates to a medical training equipment field, in particular to full-automatic cell-phone monitoring cardiopulmonary resuscitation training model.

Background

Cardiopulmonary resuscitation is a critical rescue measure for critically ill patients with respiratory cardiac arrest, namely, an emergency technique in which chest compression forms temporary artificial circulation and recovers spontaneous pulsation. The purpose of cardiopulmonary resuscitation is to open the airways, reestablish breathing and circulation, to restore the heartbeat of a critically ill patient, saving the life of the critically ill patient. Therefore, it is very necessary for the medical staff to master the operation of cardiopulmonary resuscitation and to improve the skill.

At present, generally adopt cardiopulmonary resuscitation model help medical personnel to carry out cardiopulmonary resuscitation training, however the cardiopulmonary resuscitation model of prior art is boring, low efficiency, and intelligent degree is low, and when medical personnel adopted the cardiopulmonary resuscitation model training of prior art, cardiopulmonary resuscitation scene during the actual operation that can't simulate completely, it is not good to lead to cardiopulmonary resuscitation training effect, is difficult to improve the proficiency.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing a full-automatic mobile phone monitoring cardiopulmonary resuscitation training model, this full-automatic mobile phone monitoring cardiopulmonary resuscitation training model simple structure, intelligent degree is high, can carry out clinical reaction simulation on manikin according to operator's operation, is connected with mobile terminal moreover, feeds back operation data in real time.

In order to realize the purpose, the technical scheme of the utility model is that:

full-automatic mobile phone monitoring cardiopulmonary resuscitation training model, it includes:

a mannequin, comprising: the device comprises a head, a neck, a chest, a control device, a wireless communication device and a state feedback device for simulating clinical response of a patient;

the chest is provided with an external chest compression recognition device and an artificial lung air pressure recognition device and is used for acquiring compression information and air pressure information;

the control device is electrically connected with the external chest compression recognition device and the artificial lung air pressure recognition device and is used for receiving and processing compression information and air pressure information to generate reaction information and state information;

the state feedback device is electrically connected with the control device and is used for receiving the reaction information and then working;

the wireless communication device is electrically connected with the control device and used for receiving and sending state information;

the human body model also comprises a two-dimensional code for an operator to connect with the wireless communication device after scanning the code;

and the mobile terminal is used for scanning the two-dimensional code on the human body model so as to enable the mobile terminal to be in communication connection with the wireless communication device of the human body model and receive and process the state information.

Furthermore, the external chest pressure identification device comprises a stepping mechanism, a servo driver, a linear module, a pressure sensor, a pressing block and a pressing identification mechanism;

one end of the pressure sensor is connected with the lower part of the linear module, and the other end of the pressure sensor is connected with the pressing block;

the stepping mechanism is connected with the servo driver; the stepping mechanism is also connected with the linear module to drive the pressing block to be in contact with or separated from the pressing identification mechanism.

Further, the artificial lung pressure identification device comprises an artificial lung, a moisture transmitter and a moisture meter arranged in the artificial lung;

one end of the moisture transmitter is connected with the artificial lung, and the other end of the moisture transmitter is connected with the linear module

Further, the linear module is electrically connected with the control device and used for sending pressing information and air pressure information to the control device.

Further, the human body model further comprises a pressure feedback display lamp which is arranged on the surface of the human body model and is electrically connected with the pressing identification mechanism and the tidal volume meter.

Further, the head is provided with eyes, a nose and a mouth communicated with the nose;

the human model further comprises a breather pipe, one end of the breather pipe is communicated with the mouth, and the other end of the breather pipe is communicated with the artificial lung of the artificial lung air pressure identification device.

Further, the state feedback device comprises a pupil model which is arranged in the eye part and used for simulating the contraction or expansion degree of the pupil.

Further, the state feedback device also comprises a carotid pulsation model which is arranged in the neck and used for simulating the pulse pulsation of the carotid.

Further, the human body model also comprises a voice guidance device which is electrically connected with the control device.

Compared with the prior art, the utility model discloses following technological effect has at least:

the utility model discloses a full-automatic mobile phone monitoring cardiopulmonary resuscitation training model, its simple structure, intelligent degree is high, can carry out clinical reaction simulation on manikin according to operator's operation, is connected with mobile terminal moreover, feeds back operating data in real time.

For a better understanding and an implementation, the present invention is described in detail below with reference to the accompanying drawings.

Drawings

Fig. 1 is a schematic diagram of a training model for monitoring cardiopulmonary resuscitation with a full-automatic mobile phone according to the present invention;

fig. 2 is a schematic connection diagram of the external chest pressure recognition device of the full-automatic mobile phone monitoring cardio-pulmonary resuscitation training model of the present invention;

fig. 3 is a schematic connection diagram of the artificial lung pressure recognition device of the full-automatic mobile phone monitoring training model for cardiopulmonary resuscitation.

[ reference numerals ]

100 manikin 110 head 111 eyes

112 nose 113 mouth

114 pupil model

120 neck 121 carotid pulsation model

130 chest

140 pressure feedback display lamp 150 vent pipe

200 external chest pressure recognition device 210 stepping mechanism 220 servo driver

230 linear module 240 pressure sensor

250 pressing block 260 pressing identification mechanism

300 artificial lung air pressure recognition device 310 artificial lung 320 humidity conveyor

330 tidal volume meter

400 mobile terminal 500 pressure display 600 control device

Detailed Description

In order to fully understand the objects, features and effects of the present invention, the conception, specific structure and technical effects of the present invention will be further described with reference to the accompanying drawings.

As shown in fig. 1, the training model for cardiopulmonary resuscitation with full-automatic mobile phone monitoring includes:

manikin 100, comprising: head 110, neck 120, chest 130, control device 600, wireless communication device and status feedback device for simulating a patient's clinical response;

the chest part 130 is provided with an external chest compression recognition device 200 and an artificial lung pressure recognition device 300 for acquiring compression information and pressure information;

the control device 600 is electrically connected with the external chest compression recognition device 200 and the artificial lung pressure recognition device 300, and is configured to receive and process compression information and pressure information, and generate response information and state information;

the state feedback device is electrically connected with the control device and is used for receiving the reaction information and then working;

the wireless communication device is electrically connected with the control device and used for receiving and sending state information;

the mannequin 100 further comprises a two-dimensional code for an operator to connect to the wireless communication device after scanning the code;

and the mobile terminal 400 is used for scanning the two-dimensional code on the human body model 100, so that the mobile terminal 400 is in communication connection with the wireless communication device of the human body model 100, and receives and processes the state information.

Specifically, an operator scans a two-dimensional code on a human body model to be operated by using a mobile terminal, and the mobile terminal is in communication connection with the wireless communication device after scanning the two-dimensional code. The operator performs cardiopulmonary resuscitation on the manikin, presses the chest and introduces oxygen to the artificial lungs in the manikin through the mouth or nose of the manikin. The chest compression recognition device positioned on the chest acquires compression information generated when an operator compresses the human body model, and sends the compression information to the control device; the artificial lung air pressure recognition device positioned on the chest part acquires air pressure information generated when an operator presses the human body model and sends the air pressure information to the control device; and the control device processes the pressing information and the air pressure information after receiving the pressing information and the air pressure information to generate reaction information and state information. After the state feedback device receives the response information, the clinical response of the patient under the parameter is simulated according to the parameter of the response information, and an operator judges whether the human body model needs to be continuously rescued or successfully rescued by observing the clinical response simulated by the state feedback device so as to carry out the next operation. And after receiving the state information, the mobile terminal processes the state information and displays the state information of the human body model on a screen so as to be convenient for an operator to observe. In addition, the mobile terminal compares the state information with the state information under the standard operation, judges whether the operation of the operator is correct or not, and gives a relevant operation suggestion. It should be noted that, the specific way of processing and analyzing the collected signals may be determined according to the type of the signals and the processing requirements, and may be processed by a processing method known in the art, which is not limited by the present invention.

Further, as shown in fig. 2, the external chest compression identification device 200 includes a stepping mechanism 210, a servo driver 220, a linear module 230, a pressure sensor 240, a compression block 250 and a compression identification mechanism 260;

wherein, one end of the pressure sensor 240 is connected to the lower portion of the linear module 230, and the other end is connected to the pressing block 250;

the stepping mechanism 210 is connected with the servo driver 220; the step mechanism 210 is further connected to the linear module 230 to drive the pressing block 250 to contact or separate from the pressing recognition mechanism 260. The servo driver is electrified, the stepping mechanism drives the linear module to move linearly, the pressure sensor is driven to the end face of the pressing block, the pressing block is close to or far away from the direction of the pressing identification mechanism, the pressing block is in contact with or separated from the pressing identification mechanism, and the pressing identification mechanism counts the pressing position and the pressing frequency.

Preferably, the manikin 100 is further provided with an external pressure display 500 electrically connected to the pressure sensor for displaying the pressure data detected by the pressure sensor.

Further, the artificial lung pressure identification device 300 comprises an artificial lung 310, a tidal transporter 320 and a tidal volume table 330 arranged in the artificial lung;

one end of the moisture transmitter 320 is connected to the artificial lung 310, and the other end is connected to the linear module 230, so that the gas in the artificial lung is pressed by the linear module, the artificial lung is squeezed, and the gas is squeezed out of the manikin, thereby simulating the exhalation of the human body. And the operator can simulate the human body to inhale by introducing oxygen into the human body model through the mouth. And finally, measuring the inhaled or exhaled air volume of each time during respiration in the artificial lung by setting the tidal volume meter.

Further, the linear module 230 is electrically connected to the control device 600, and is configured to send pressing information and air pressure information to the control device 600.

Further, the human body model further comprises a pressure feedback display lamp 140, which is arranged on the surface of the human body model 100, electrically connected with the pressing recognition mechanism 260 and the tidal volume meter 330, and the pressure feedback display lamp performs lighting feedback according to the pressing position and the pressing times counted by the pressing recognition mechanism and the tidal volume counted by the tidal volume meter, so as to simulate the skin color change of the patient.

Further, the head 100 is provided with an eye 111, a nose 112 and a mouth 113 communicating with the nose 112;

the manikin 100 further comprises a ventilation tube 150, wherein one end of the ventilation tube 150 is communicated with the mouth 113, and the other end is communicated with the artificial lung of the artificial lung pressure identification device.

Further, the state feedback device includes a pupil model 114, which is disposed in the eye 111 and used for simulating the contraction or expansion degree of the pupil, and the operator can judge whether the manikin needs to continue rescue or succeed in rescue by observing the contraction or expansion degree of the pupil.

Further, the state feedback device further comprises a carotid artery pulsation model 121, which is arranged in the neck 120 and used for simulating the pulse pulsation of the carotid artery, and an operator judges whether the human body model needs to continue rescue or success rescue through the pulsation condition of the carotid artery.

Further, the human body model also comprises a voice guidance device which is electrically connected with the control device. The voice guidance device is electrically connected with the control device, receives and processes the suggestion information fed back by the mobile terminal, plays the suggestion voice and guides an operator to carry out correct operation.

In the description of the present invention, when it is understood that terms such as "front", "back", "left", "right", "first", "second", etc. are used to define the direction of the components, the terms are used only for better description of the above components, and if not otherwise stated, the terms do not have special meanings, so that the present invention should not be construed as being limited by the scope of the present invention.

The present invention is not limited to the above embodiment, and if various modifications or variations of the present invention do not depart from the spirit and scope of the present invention, they are intended to be covered if they fall within the scope of the claims and the equivalent technology of the present invention.

Claims (9)

1. Full-automatic mobile phone monitoring cardiopulmonary resuscitation training model, its characterized in that includes:

a mannequin, comprising: the device comprises a head, a neck, a chest, a control device, a wireless communication device and a state feedback device for simulating clinical response of a patient;

the chest is provided with an external chest compression recognition device and an artificial lung air pressure recognition device and is used for acquiring compression information and air pressure information;

the control device is electrically connected with the external chest compression recognition device and the artificial lung air pressure recognition device and is used for receiving and processing compression information and air pressure information to generate reaction information and state information;

the state feedback device is electrically connected with the control device and is used for receiving the reaction information and then working;

the wireless communication device is electrically connected with the control device and used for receiving and sending state information;

the human body model also comprises a two-dimensional code for an operator to connect with the wireless communication device after scanning the code;

and the mobile terminal is used for scanning the two-dimensional code on the human body model so as to enable the mobile terminal to be in communication connection with the wireless communication device of the human body model and receive and process the state information.

2. The fully-automatic mobile phone monitoring cardio-pulmonary resuscitation training model of claim 1, wherein:

the external chest compression identification device comprises a stepping mechanism, a servo driver, a linear module, a pressure sensor, a compression block and a compression identification mechanism;

one end of the pressure sensor is connected with the lower part of the linear module, and the other end of the pressure sensor is connected with the pressing block;

the stepping mechanism is connected with the servo driver; the stepping mechanism is also connected with the linear module to drive the pressing block to be in contact with or separated from the pressing identification mechanism.

3. The fully-automatic mobile phone monitoring cardio-pulmonary resuscitation training model of claim 2, wherein:

the artificial lung air pressure identification device comprises an artificial lung, a moisture transmitter and a moisture meter arranged in the artificial lung;

one end of the moisture transmitter is connected with the artificial lung, and the other end of the moisture transmitter is connected with the linear module.

4. The fully-automatic mobile phone monitoring cardio-pulmonary resuscitation training model of claim 3, wherein:

the linear module is electrically connected with the control device and used for sending pressing information and air pressure information to the control device.

5. The fully-automatic mobile phone monitoring cardio-pulmonary resuscitation training model of claim 3, wherein:

the human body model further comprises a pressure feedback display lamp which is arranged on the surface of the human body model and is electrically connected with the pressing recognition mechanism and the tidal volume meter.

6. The fully-automatic mobile phone monitoring cardio-pulmonary resuscitation training model of claim 3, wherein:

the head is provided with eyes, a nose and a mouth communicated with the nose;

the human model further comprises a breather pipe, one end of the breather pipe is communicated with the mouth, and the other end of the breather pipe is communicated with the artificial lung of the artificial lung air pressure identification device.

7. The fully-automatic mobile phone monitoring cardio-pulmonary resuscitation training model of claim 6, wherein:

the state feedback device comprises a pupil model which is arranged in the eye part and is used for simulating the contraction or expansion degree of the pupil.

8. The fully-automatic mobile phone monitoring cardio-pulmonary resuscitation training model of claim 1, wherein:

the state feedback device also comprises a carotid pulsation model which is arranged in the neck and used for simulating the pulse pulsation of the carotid.

9. The fully-automatic mobile phone monitoring cardio-pulmonary resuscitation training model of claim 1, wherein:

the human body model also comprises a voice guidance device which is electrically connected with the control device.

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