TWI729665B - Cpr training system and cpr training device - Google Patents

Abstract

The present invention provides a CPR training system and CPR training device. The CPR training device includes a human body simulation component and a training monitoring component. The human body simulation component includes a body, a damping unit disposed in the body, a head body disposed on the body, and a blowing tube disposed between the body and the head body. The training monitoring component includes a first bending sensor disposed on the dumping unit, a blowing sensing unit disposed in the body, a processing unit disposed in the body, a power unit disposed in the body. The processing unit is electrically connected to the first bending sensor, the blowing sensing unit, the processing unit, and the power unit. Accordingly, a training data is transmitted to a monitoring display by the processing unit to confirm the training situation.

Description

Cardiopulmonary resuscitation training system and cardiopulmonary resuscitation training device

The invention relates to a training system and a training device, in particular to a cardiopulmonary resuscitation training system and a cardiopulmonary resuscitation training device.

In order for teachers to conveniently guide or allow students to actually operate the correct steps of cardiopulmonary resuscitation (CPR), cardiopulmonary resuscitation training devices are generally used to assist teaching and training. The existing cardiopulmonary resuscitation training devices are made of elastic materials. Mannequin.

Cardiopulmonary resuscitation involves a variety of steps, such as: a certain number of compressions with a certain number of artificial respirations, or a compression depth of 5 centimeters (cm). However, when students operate the existing cardiopulmonary resuscitation training device, the teacher must help confirm whether the student has actually followed the steps to achieve the standard number of compressions, blows, and compression depth, which is very unsatisfactory in the actual supervision of the training process. . Furthermore, if there are a large number of students observing from the sidelines, some of the students will be obstructed by their vision and cannot know which steps the students have completed or have not completed. As a result, the students who are observing may not be able to grasp the correct operation steps.

Therefore, the inventor believes that the above-mentioned shortcomings can be improved, and with great concentration of research and the application of scientific principles, we finally propose an invention with reasonable design and effective improvement of the above-mentioned shortcomings.

The technical problem to be solved by the present invention is to provide a cardiopulmonary resuscitation training system and a cardiopulmonary resuscitation training device in view of the deficiencies of the prior art, which can effectively improve the possible defects of the existing cardiopulmonary resuscitation training device.

The embodiment of the present invention discloses a cardiopulmonary resuscitation training system, which includes: a human body simulation component, including: a body, the body has a first accommodating space; wherein, the body has elasticity, when the body is subjected to an external force When compressed, the body is located at a chest compression position. When the body is not compressed by the external force, the body is elastically reset to a reset position; a head body is arranged on the body, and the head body Having a second accommodating space and a mouth communicating with the second accommodating space, the mouth being used for letting in a gas; and a blowing tube, part of which is located in the first accommodating space, The other part is located in the second accommodating space; wherein, the blowing tube has a first end and a second end opposite to the first end, and the second end of the blowing tube is connected to the The mouth is assembled, and the first end is located in the first accommodating space, and the air blowing tube can pass through the second end to transport the gas to the first end through the first end. A training monitoring component, including: a first resistance change sensor, arranged in the first accommodating space, when the body is in the chest compression position, the first resistance changes The sensor changes in resistance to generate a pressing signal; a gas sensing unit is disposed in the first accommodating space and corresponds to the position of the first end of the blowing tube, the gas sensing The unit is used to sense whether the gas passes through the first end and generate a blowing signal; a processing unit is arranged in the first accommodating space and is respectively connected to the first resistance change sensing And the gas sensing unit are electrically connected for receiving and analyzing the pressing signal and the blowing signal and generating a training data; the processing unit has a transmission module, and the transmission module is used for Transmitting the training data; and a power supply unit disposed in the first accommodating space and electrically connected to the processing unit; and a monitoring display member, including: a display, including: a receiving module For receiving the transmitted signal; and a display interface for displaying the training data.

The embodiment of the present invention further discloses a cardiopulmonary resuscitation training device, which includes: a human body simulation component, including: a body, the body has a first accommodating space; wherein, the body has elasticity, when the body is subjected to a When the body is compressed by external force, the body is in a chest compression position. When the body is not compressed by the external force, the body is elastically reset to a reset position; a head body is arranged on the body, and the head The body has a second accommodating space and a mouth communicating with the second accommodating space, the mouth is used to allow a gas to enter; and a blowing tube, part of which is located in the first accommodating space , And the other part is located in the second accommodating space; wherein, the blowing tube has a first end and a second end opposite to the first end, and the second end of the blowing tube is connected to The mouth is assembled, and the first end is located in the first accommodating space, and the air blowing tube can pass through the second end to transport the gas to the first end through the first end. In an accommodating space; and a training monitoring component for connecting with a display interface, the training monitoring component includes: a first resistance change sensor disposed in the first accommodating space, when the When the body is in the chest compression position, the resistance of the first resistance change sensor changes to generate a compression signal; a gas sensing unit is disposed in the first accommodating space and is connected to the blowing tube The position of the first end corresponds to the position of the first end, and the gas sensing unit is used to sense whether the gas passes through the first end and generate a blowing signal; a processing unit is disposed in the first container Is placed in the space, and electrically connected to the first resistance change sensor and the gas sensing unit, respectively, for receiving and analyzing the pressing signal and the blowing signal and generating a training data; the The processing unit has a transmission module for transmitting the training data; and a power supply unit, which is arranged in the first accommodating space and is electrically connected to the processing unit.

In summary, the cardiopulmonary resuscitation training system and cardiopulmonary resuscitation training device disclosed in the embodiments of the present invention can both sense the operation process of the student through the first resistance change sensor and the gas sensing unit of the training monitoring component. Then the processing unit analyzes and transmits the data collected by the first resistance change sensor and the gas sensing unit to the monitoring display component or other display component, and displays the training status of the trainees through the display interface .

In order to further understand the features and technical content of the present invention, please refer to the following detailed description and drawings about the present invention. However, the provided drawings are only for reference and description, and are not used to limit the present invention.

The following are specific examples to illustrate the implementation of the "cardiopulmonary resuscitation training system and cardiopulmonary resuscitation training device" disclosed in the present invention. Those skilled in the art can understand the advantages and effects of the present invention from the content disclosed in this specification. The present invention can be implemented or applied through other different specific embodiments, and various details in this specification can also be based on different viewpoints and applications, and various modifications and changes can be made without departing from the concept of the present invention. In addition, the drawings of the present invention are merely schematic illustrations, and are not drawn according to actual dimensions, and are stated in advance. The following embodiments will further describe the related technical content of the present invention in detail, but the disclosed content is not intended to limit the protection scope of the present invention.

It should be understood that although terms such as "first", "second", and "third" may be used herein to describe various elements or signals, these elements or signals should not be limited by these terms. These terms are mainly used to distinguish one element from another, or one signal from another signal. In addition, the term "or" used in this document may include any one or a combination of more of the associated listed items depending on the actual situation.

As shown in Figure 1 to Figure 10, which is an embodiment of the present invention, this embodiment discloses a cardiopulmonary resuscitation training system, which is used to monitor the training of students during cardiopulmonary resuscitation (CPR), and to train Information (for example: the number of presses, the number of blows, or the depth of presses, etc.) is converted into training data and presented on a display interface 31 for teachers or other students to understand the training situation; that is, any training data that does not have monitoring ( Information) The cardiopulmonary resuscitation training system is difficult to compare with the cardiopulmonary resuscitation training system in this embodiment.

1 and 10, the cardiopulmonary resuscitation training system includes: a human body simulation component 1, a training monitoring component 2 arranged in the human body simulation component 1, and connected to the training monitoring component 2 A monitoring display component 3 (as shown in Figure 10). It should be noted that the human body simulation component 1, the training monitoring component 2, and the monitoring display component 3 are collectively defined as the cardiopulmonary resuscitation training system in this embodiment. However, the present invention is not limited to this.

For example, in other embodiments not shown in the present invention, the human body simulation component 1 and the training monitoring component 2 can jointly form a cardiopulmonary resuscitation training device, and the cardiopulmonary resuscitation training device can also be a separate cardiopulmonary resuscitation training device. Used (such as: selling) or used with other components.

The human body simulation component 1 includes a body 11, a head body 12 disposed on the body 11, and a blowing tube 13 disposed on the body 11 and the head body 12; specifically, the body 11 and The head body 12 is used to simulate the features of the upper half of the human body.

The body 11 has a first accommodating space X; wherein, the body 11 is elastic, and when the body 11 is compressed by an external force, the body 11 is located at a chest compression position A (as shown in FIG. 2) When the body 11 is not compressed by the external force, the body 11 is reset to a reset position B through its elasticity (as shown in FIG. 3). Specifically, the body 11 may be made of elastic materials to assist in simulating the feedback feeling of pressing the human chest cavity, and the chest pressing position A and the reset position B are along a height direction D (when the body 11 is laid flat The height change in the vertical direction) is 5 cm, which is the standard compression depth for cardiopulmonary resuscitation, but it is not limited to what is contained in this embodiment. Further, the body 11 further includes a neck 111 for simulating the neck of a human body, and the part of the neck 111 far away from the body 11 is defined as a set of joints 1111 (as shown in FIGS. 4 and 5). Show).

Preferably, the human body simulation component 1 further includes a damping unit 4 in this embodiment. The damping unit 4 is disposed in the first accommodating space X and abuts against the inner edge of the body 11 , But not limited to what is contained in this example. Furthermore, the damping unit 4 is arranged in the first accommodating space X and corresponds to the position of the chest cavity of the human body simulated by the body 11, so as to strengthen the feedback feeling during the simulated pressing.

1 and 4, 5, the head body 12 is disposed on the body 11, the head body 12 has a second accommodating space Y and communicating with the second accommodating space Y A mouth 121, and the mouth 121 is used to simulate the oral cavity of the human body, and can allow a gas to enter; in addition, the head body 12 further has a blocking portion 122, the blocking portion 122 is located in the second The accommodating space Y is on the side away from the mouth 121. Furthermore, the head body 12 is pivotally connected to the assembling section 1111, and the assembling section 1111 is located in the second accommodating space Y of the head body 12, so that the head body 12 It can pivot between a head-up position F and a normal position G.

A part of the blowing pipe 13 is located in the first accommodating space X, and another portion is located in the second accommodating space Y; wherein, the blowing pipe 13 has a first end 131 and is connected to the first accommodating space Y. One end 131 is opposite to a second end 132, the second end 132 of the blowing tube 13 is assembled with the mouth 121, and the first end 131 is located in the first accommodating space X , The blowing tube 13 can transport the gas into the first accommodating space X through the first end 131 through the second end 132.

In more detail, as shown in FIGS. 1, 6 and 7, the mouth 121 of the head body 12 is a tubular structure in this embodiment. When the head body 12 is in the normal position G When the head body 12 is adjacent to the assembling section 1111, the head body 12 links the mouth 121 to bend the blowing tube 13 of the compression part of the assembling section 1111 (as shown in FIGS. 5 and 11). 7), so that the gas cannot be transmitted from the second end 132 to the first end 131; when the head body 12 is in the head-up position F, the head body 12 is far away from the The assembly section 1111 enables the head body 12 to link the mouth 121 to pull the blowing tube 13 no longer bends, so that the gas can be transmitted from the second end 132 to the first end 131 (such as Shown in Figure 4 and Figure 6).

1 to 5, the training monitoring component 2 includes a first resistance change sensor 21, a gas sensing unit 22, and a processing unit 23 arranged in the first accommodating space X , And a power supply unit 24, a second resistance change sensor 25 electrically connected to the processing unit 23, a blood display unit 26, a head-up display unit 27, and a sound reminder unit 28.

2 and 3, the first resistance change sensor 21 is disposed in the first accommodating space X, and when the body 11 is in the chest compression position A, the first The resistance change sensor 21 changes in resistance to generate a pressing signal. Furthermore, the first resistance change sensor 21 is a bending sensor in this embodiment, and the bending sensor is arranged on the damping unit 4, and generates the resistance according to different resistance changes. The pressing signal is sent to the processing unit 23.

Further, the pressing signal is further divided into a standard command and a non-standard command. In detail, when the body 11 is driven by the external force to move the damping unit 4 to the pressing position (that is, move down 5 cm in the height direction D), the bending sensor will As the damping unit 4 deforms, the resistance changes to generate the standard command; when the body 11 is driven by the external force to move the damping unit 4 together, but it does not move to the pressing position (that is, the reset Between the position B and the pressing position), the bending sensor generates the non-standard command.

Referring to Figures 1, 8 and 9, the gas sensing unit 22 is disposed in the first accommodating space X and corresponds to the position of the first end 131 of the blowing tube 13, and The gas sensing unit 22 is used for sensing whether the gas passes through the first end 131 and generating a blowing signal.

In detail, the gas sensing unit 22 is an optocoupler module, and the optocoupler module includes: a substrate 221, a light emitter 222 disposed on the substrate 221, and a light sensor 223 , And a light blocking member 224.

The light emitter 222 and the light sensor 223 are respectively disposed on the substrate 221, the light emitter 222 and the light sensor 223 are corresponding to each other and arranged at intervals, and the light emitter 222 is used for A light beam is emitted, and the light sensor 223 is used to receive the light beam.

The light blocking member 224 is disposed on the substrate 221, and the light blocking member 224 includes a bracket 2241 and a stopper 2242 pivoted on the support 2241; wherein, the stopper 2242 is located on the light Between the transmitter 222 and the light sensor 223, and when the stop 2242 is blown by the gas, the stop 2242 can pivot to a passing position J so that the light sensor 223 can receive The light beam causes the light sensor 223 to generate the blowing signal; when the blocking member 2242 is not blown by the gas, the blocking member 2242 pivots to a blocking position K to prevent The light sensor 223 receives the light.

As shown in FIGS. 4 and 5, the second resistance change sensor 25 is disposed in the second accommodating space Y, and is located on the assembly section 1111, and when the head body 12 is in the In the normal position G, the blocking portion 122 abuts the second resistance change sensor 25 to bend it; when the head body 12 is in the head-up position F, the blocking portion 122 no longer abuts By the second resistance change sensor 25, the second resistance change sensor 25 is reset by its own elasticity, so that the second resistance change sensor 25 generates a resistance change and generates a head-up signal Transfer to the processing unit 23.

The processing unit 23 is connected to the first resistance change sensor 21, the gas sensing unit 22, the second resistance change sensor 25, the blood display unit 26, and the head-up display unit 27, respectively. And the sound reminder unit 28 is electrically connected, and receives and analyzes the pressing signal, the blowing signal, and the head-up signal, and generates a training data. In addition, the processing unit 23 has a transmission module 231 for transmitting the training data.

As shown in FIG. 1, the blood display unit 26 is disposed on the body 11 and is electrically connected to the processing unit 23. When the processing unit 23 receives the pressing signal, the blood display unit 26 generates an analog light signal. In detail, the blood display unit 26 in this embodiment may be arranged in a long manner by a plurality of LED lights, and when the blood display unit 26 receives the standard command of the pressing signal, The analog light signal of the blood display unit 26 will be fully lit (that is, all the LED lights); and when the blood display unit 26 receives the non-standard command of the pressing signal, the blood The analog light signal of the display unit 26 is partially lit according to the pressing force (resistance change); accordingly, the size of the pressing force can be simulated by the analog light signal, but it is not limited to what is described in this embodiment.

The head-up display unit 27 is provided on the head body 12. When the head-up display unit 27 receives the head-up signal, the head-up display unit 27 generates a confirmation light; accordingly, the student or teacher can Directly observe the confirmation light to confirm whether there is a head-up step.

The training monitoring component 2 further includes a sound reminder unit 28 electrically connected to the processing unit 23, and when the processing unit 23 receives the blowing signal, the sound reminder unit 28 generates a warning; Accordingly, through the warning, the student or teacher can confirm that the gas (that is, the gas in and out of the mouth 121 for artificial respiration) has been blown into the mouth 121.

Referring to FIG. 10, the monitoring display component 3 includes a display, and the display has a receiving module (not shown) and a display interface 31. The receiving module is used to receive the processing unit 23. The training data transmitted by the transmission module, and the display interface 31 is used to display the training data. In detail, the display interface 31 has a pressing time frame 311, a pressing frequency frame 312, a standard frequency frame 313, an artificial respiration frequency frame 314, and a human body simulation frame 315.

Specifically, the pressing time box 311 displays the time for the student to perform this training process; the pressing times box 312 displays the number of pressings according to the pressing signal, that is, the pressing times box 312 displays the number of pressings. The information is the total number of the standard instructions and non-standard instructions. The standard number box 313 is presented based on the number of the standard instructions; the artificial respiration number box 314 displays the number of blows based on the blow signal .

In addition, it should be noted that because the head-up display unit 27 and the blood display unit 26 are electrically connected to the processing unit 23, respectively, the transmission module of the processing unit 23 can also connect the The confirmation light signal and the simulated light signal are transmitted to the display interface 31, and the display interface 31 presents the current light signal situation through the human body simulation frame 315.

[Technical Effects of Embodiments of the Invention]

In summary, the cardiopulmonary resuscitation training system and cardiopulmonary resuscitation training device disclosed in the embodiments of the present invention can both sense the student’s activity through the first resistance change sensor 21 and the gas sensing unit 22 of the training monitoring component 2 described above. During the operation process, the processing unit 23 analyzes and transmits the data collected by the first resistance change sensor 21 and the gas sensing unit 22 to the monitoring display component 3 or other display components, and passes them through The display interface 31 displays the training status of the trainees.

The content disclosed above is only the preferred and feasible embodiments of the present invention, and does not limit the scope of the patent application of the present invention. Therefore, all equivalent technical changes made using the description and schematic content of the present invention are included in the application of the present invention. Within the scope of the patent.

1: Human body simulation component 11: Body 111: Neck 1111: Assembly section 12: head body 121: Mouth 122: blocking part 13: Blow pipe 131: first end 132: second end 2: Training monitoring component 21: The first resistance change sensor 22: Gas sensing unit 221: Substrate 222: Optical Transmitter 223: Light Sensor 224: light blocking member 2241: bracket 2242: stop 23: processing unit 231: Transmission Module 24: power supply unit 25: The second resistance change sensor 26: blood display unit 27: Head-up display unit 28: Sound reminder unit 3: Monitoring display components 31: display interface 311: Press the time box 312: Press times box 313: Standard Times Box 314: Artificial respiration frequency box 315: Human body simulation frame 4: Damping unit X: The first housing space Y: second housing space A: Chest compression position B: Reset position D: height direction F: Head up position G: Normal position J: Pass position K: blocking position

Fig. 1 is a schematic plan view of the human body simulation component and the training monitoring component of the cardiopulmonary resuscitation training system of the present invention.

Fig. 2 is a schematic diagram of the use state of the cardiopulmonary resuscitation training system of the present invention, which is used to show the state of the body in the chest compression position.

Fig. 3 is a schematic diagram of the use state of the cardiopulmonary resuscitation training system of the present invention, which is used to show the state of the body in the reset position.

FIG. 4 is a schematic diagram of the use state of the cardiopulmonary resuscitation training system of the present invention, which is used to show the state of the head body in the head-up position.

FIG. 5 is a schematic diagram of the use state of the cardiopulmonary resuscitation training system of the present invention, which is used to show the state when the head body is in a normal position.

FIG. 6 is a schematic diagram of the use state of the cardiopulmonary resuscitation training system of the present invention, which is used to display the state of the blowing tube when the head body is in the head-up position.

FIG. 7 is a schematic diagram of the use state of the cardiopulmonary resuscitation training system of the present invention, which is used to show the state when the head body is in the normal position and the blowing tube is bent.

FIG. 8 is a schematic diagram of the use state of the cardiopulmonary resuscitation training system of the present invention, which is used to show the state when the stopper of the gas sensing unit is at the blocking position.

FIG. 9 is a schematic diagram of the use state of the cardiopulmonary resuscitation training system of the present invention, which is used to show the state when the stopper of the gas sensing unit is in the passing position.

Fig. 10 is a schematic plan view of the monitoring display component of the cardiopulmonary resuscitation training system of the present invention.

1: Human body simulation component

11: Body

12: head body

121: Mouth

13: Blow pipe

131: first end

132: second end

2: Training monitoring component

21: The first resistance change sensor

22: Gas sensing unit

23: processing unit

231: Transmission Module

24: power supply unit

26: blood display unit

27: Head-up display unit

28: Sound reminder unit

4: Damping unit

Claims (9)

A cardiopulmonary resuscitation training system, comprising: a human body simulation component, comprising: a body, the body having a first accommodating space; wherein, the body has elasticity, when the body is compressed by an external force, the body The body is located in a chest compression position. When the body is not compressed by the external force, the body is elastically reset to a reset position; a head body is arranged on the body, and the head body has a second volume. And a mouth communicating with the second accommodating space, the mouth is used to allow a gas to enter; and a blowing tube, part of which is located in the first accommodating space, and another part is located in the The second accommodating space; wherein, the blowing tube has a first end and a second end opposite to the first end, and the second end of the blowing tube is assembled with the mouth , And the first end is located in the first accommodating space, and the air blowing tube can convey the gas into the first accommodating space through the first end through the second end; A training monitoring component includes: a first resistance change sensor disposed in the first accommodating space, and when the body is in the chest compression position, the first resistance change sensor generates resistance Change to generate a pressing signal; a gas sensing unit disposed in the first accommodating space and corresponding to the position of the first end of the blowing tube, and the gas sensing unit is used for sensing Whether the gas passes through the first end and generates a blowing signal, the gas sensing unit is an optocoupler module and includes: a substrate; A light emitter is arranged on the substrate to emit a light beam; a light sensor is arranged on the substrate and corresponds to the light emitter, and the light sensor is used to receive the light The light beam of the transmitter; and a light blocking member disposed on the substrate. The light blocking member includes a bracket and a stopper pivoted on the support; wherein, the stopper is located on the Between the light emitter and the light sensor, and when the stopper is blown by the gas, the stopper can pivot to a passing position so that the light sensor receives the light beam, and Causing the light sensor to generate the blowing signal; when the stopper is not blown by the gas, the stopper pivots to a blocking position to prevent the light sensor from receiving the light; A processing unit is disposed in the first accommodating space, and is electrically connected to the first resistance change sensor and the gas sensing unit, respectively, for receiving and analyzing the pressing signal and the Blow signals and generate training data; the processing unit has a transmission module for transmitting the training data; and a power supply unit, which is arranged in the first accommodating space and is connected to The processing unit is electrically connected; and a monitoring display component, including: a display, including: a receiving module for receiving the signal transmitted by the transmission module; and a display interface for displaying the Training data. The cardiopulmonary resuscitation training system according to claim 1, wherein the body further includes a neck, and the part of the neck is defined as a set of joints, and the joints are located at The second accommodating space of the head body is pivotally connected to the head body, so that the head body can pivot between a head-up position and a normal position; wherein, when the head body is in the In the normal position, the head body is adjacent to the assembling section, so that the head body is linked with the mouth and cooperates with the assembling section to press the blowing tube to bend, so that the gas cannot pass from the second End is transmitted to the first end, and when the head body is in the head-up position, the head body pivots away from the assembly section, so that the head body links the mouth to draw the blowing The air pipe is no longer bent, and the gas can be transferred from the second end to the first end. The cardiopulmonary resuscitation training system according to claim 2, wherein the head body further has a blocking portion located in the second accommodating space; the training monitoring component further includes an electrical connection with the processing unit A second resistance change sensor, the second resistance change sensor has elasticity and is arranged in the second accommodating space, and is located on the assembly section, and when the head body is in the In the normal position, the blocking portion abuts against the second resistance change sensor to bend it; when the head body is in the head-up position, the blocking portion no longer abuts against the second resistor The change sensor causes the second resistance change sensor to reset through its elasticity, so that the second resistance change sensor generates a resistance change, and generates a head-up signal to be transmitted to the processing unit, so The processing unit can analyze the head-up signal, the pressing signal, and the blowing signal, and generate the training data. The cardiopulmonary resuscitation training system according to claim 1, wherein the training monitoring component further includes a blood display unit electrically connected to the processing unit, and the blood display unit is disposed on the body. When the processing unit receives the pressing signal, the blood display unit generates an analog light signal. The cardiopulmonary resuscitation training system according to claim 3, wherein the training monitoring structure The device further includes a head-up display unit electrically connected to the processing unit. The head-up display unit is disposed on the head body. When the processing unit receives the head-up signal, the head-up display unit generates 1. Confirm the light signal. The cardiopulmonary resuscitation training system according to claim 1, wherein the training monitoring component further includes a sound reminder unit electrically connected to the processing unit, and when the processing unit receives the blowing signal, The sound reminder unit generates a warning. A cardiopulmonary resuscitation training device, comprising: a human body simulation component, comprising: a body, the body having a first accommodating space; wherein, the body has elasticity, when the body is compressed by an external force, the body The body is located in a chest compression position. When the body is not compressed by the external force, the body is elastically reset to a reset position; a head body is arranged on the body, and the head body has a second volume. And a mouth communicating with the second accommodating space, the mouth is used to allow a gas to enter; and a blowing tube, part of which is located in the first accommodating space, and another part is located in the The second accommodating space; wherein, the blowing tube has a first end and a second end opposite to the first end, and the second end of the blowing tube is assembled with the mouth , And the first end is located in the first accommodating space, and the air blowing tube can convey the gas into the first accommodating space through the first end through the second end; And a training monitoring component for connecting with a display interface, the training monitoring component includes: a first resistance change sensor, arranged in the first accommodating space, when the When the body is in the chest compression position, the resistance of the first resistance change sensor changes to generate a compression signal; a gas sensing unit is disposed in the first accommodating space and interacts with the blowing The position of the first end of the trachea corresponds to the position, the gas sensing unit is used for sensing whether the gas passes through the first end and generating a blowing signal, and the gas sensing unit is an optocoupler The module also includes: a substrate; a light emitter arranged on the substrate to emit a light beam; a light sensor arranged on the substrate and corresponding to the light emitter, so The light sensor is used to receive the light beam of the light emitter; and a light blocking member is disposed on the substrate, and the light blocking member includes a bracket and a stopper pivoted on the bracket; Wherein, the stopper is located between the light emitter and the light sensor, and when the stopper is blown by the gas, the stopper can pivot to a passing position so that the The light sensor receives the light beam and causes the light sensor to generate the blowing signal; when the stopper is not blown by the gas, the stopper pivots to a blocking position to prevent The light sensor receives the light; a processing unit is disposed in the first accommodating space, and is electrically connected to the first resistance change sensor and the gas sensing unit, respectively, for receiving And analyze the pressing signal and the blowing signal to generate a training data; the processing unit has a transmission module, the transmission module is used to transmit the training data; and a power supply unit is arranged in the In the first accommodating space and electrically connected to the processing unit. The cardiopulmonary resuscitation training device according to claim 7, wherein the body further includes a neck, and the part of the neck is defined as a set of joints, and the joints are located at The second accommodating space of the head body is pivotally connected to the head body, so that the head body can pivot between a head-up position and a normal position; wherein, when the head body is in the In the normal position, the head body is adjacent to the assembling section, so that the head body is linked with the mouth and cooperates with the assembling section to press the blowing tube to bend, so that the gas cannot pass from the second End is transmitted to the first end, and when the head body is in the head-up position, the head body pivots away from the assembly section, so that the head body links the mouth to draw the blowing The air pipe is no longer bent, and the gas can be transferred from the second end to the first end. The cardiopulmonary resuscitation training device according to claim 7, wherein the training monitoring component further includes a blood display unit electrically connected to the processing unit and a head-up display unit electrically connected to the processing unit, The blood display unit is arranged on the body, and when the processing unit receives the pressing signal, the blood display unit generates an analog light signal; the head-up display unit is arranged on the head body, when When the processing unit receives a head-up signal, the head-up display unit generates a confirmation light.

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