CN216984894U - Integrated recording instrument for cardiac shock and respiration - Google Patents

Integrated recording instrument for cardiac shock and respiration Download PDF

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Publication number
CN216984894U
CN216984894U CN202220041934.XU CN202220041934U CN216984894U CN 216984894 U CN216984894 U CN 216984894U CN 202220041934 U CN202220041934 U CN 202220041934U CN 216984894 U CN216984894 U CN 216984894U
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piezoelectric
electrode layer
integrated
respiration
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邓元
张珂
杨杰
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Hangzhou Innovation Research Institute of Beihang University
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Hangzhou Innovation Research Institute of Beihang University
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Abstract

The utility model discloses a heart-shaking-breathing integrated recorder, and relates to the technical field of medical instruments. The utility model discloses a heart-shake and respiration integrated recorder which comprises a host, wherein the host comprises a heart-shake and respiration integrated sensor and a circuit board, the heart-shake and respiration integrated sensor comprises a contact separation type friction nano generator and a piezoelectric nano generator, the contact separation type friction nano generator is used for collecting heart-shake signals, and the piezoelectric nano generator is used for collecting respiration signals; the contact separation type friction nano generator and the piezoelectric nano generator are connected with the circuit board, the circuit board is connected with the receiving terminal, and the cardiac shock signals collected by the contact separation type friction nano generator and the respiration signals collected by the piezoelectric nano generator are converted by the circuit board and then sent to the receiving terminal. The integrated recording instrument for the heart-shaking and the respiration can realize the simultaneous monitoring of the heart-shaking signals and the respiration signals of a user through the contact separation type friction nano generator and the piezoelectric nano generator.

Description

Integrated recording instrument for cardiac shock and respiration
Technical Field
The utility model relates to the technical field of medical instruments, in particular to a heart-shake-respiration integrated recorder.
Background
A cardiac shock signal is a weak mechanical signal that causes the body to vibrate synchronously by the pumping activity of the heart, which contains a large amount of important information about the periodic activity of the heart. In the prior art, an accelerometer or a gyroscope sensor is mostly used as a sensing device for recording a heart seismographic signal.
The respiration signal can exactly reflect the ventilation/oxygenation condition of the human body, which is not limited to the conventional items of respiration frequency, respiration rhythm, arterial blood gas, common chest radiography and the like, but under the existing technical condition, it is very difficult to realize real-time dynamic continuous monitoring of a series of physiological parameters by using a portable respiration monitoring device.
The applicant finds that the prior art using an accelerometer or a gyroscope sensor as a sensing device for monitoring a cardiac signal has at least the following disadvantages: (1) the method comprises the following steps that a heart-shaking signal is weak, an accelerometer or a gyroscope sensor is used for monitoring the heart-shaking signal, a user is required to keep a forbidden state, otherwise, the heart-shaking signal is disturbed by movement and is not easy to separate, and the heart-shaking signal can be annihilated; (2) the accelerometer or gyroscope sensor needs external power supply, so that energy consumption is increased, and convenience in use is reduced; (3) accelerometers or gyroscopes are relatively high in cost and are not easy to manufacture; (4) the accelerometer or gyroscope cannot synchronously monitor and record the heart-shaking signal and the respiration signal. Therefore, it is an urgent technical problem to be solved by those skilled in the art to provide a integrated recording instrument for heart and respiration.
SUMMERY OF THE UTILITY MODEL
The utility model provides a heart-shake and respiration integrated recorder which solves the technical problem that an accelerometer or a gyroscope sensor cannot synchronously monitor and record heart-shake signals and respiration signals when the accelerometer or the gyroscope sensor is used as a sensing device to monitor the heart-shake signals in the prior art. The various technical effects that can be produced by the preferred technical solution of the present invention are described in detail below.
In order to achieve the purpose, the utility model provides the following technical scheme:
the integrated recording instrument for the cardiac shock and the respiration comprises a host, wherein the host comprises an integrated sensor for the cardiac shock and the respiration and a circuit board, the integrated sensor for the cardiac shock and the respiration comprises a contact separation type friction nano generator and a piezoelectric nano generator, the contact separation type friction nano generator is used for collecting cardiac shock signals, and the piezoelectric nano generator is used for collecting respiration signals; the contact separation type friction nano generator and the piezoelectric nano generator are connected with the circuit board, the circuit board is connected with the receiving terminal, and the circuit board enables a heart shock signal acquired by the contact separation type friction nano generator and a respiration signal acquired by the piezoelectric nano generator to be transmitted to the receiving terminal after being converted by the circuit board.
According to a preferred embodiment, the contact separation type friction nano-generator and the piezoelectric nano-generator are arranged in an integrated manner, and the integrated cardiac shock-respiration sensor comprises a substrate, a first piezoelectric layer, a first electrode layer, an isolation layer, a first friction electric layer and a second electrode layer, wherein the first electrode layer is arranged on the substrate, the first piezoelectric layer is arranged on the first electrode layer, the first friction electric layer and the second electrode layer are arranged on the first piezoelectric layer at intervals, the isolation layer is arranged between the first piezoelectric layer and the first friction electric layer, and the first piezoelectric layer, the first electrode layer, the isolation layer and the first friction electric layer form the contact separation type friction nano-generator; the first piezoelectric layer, the first electrode layer and the second electrode layer constitute a piezoelectric nanogenerator.
According to a preferred embodiment, the contact separation type friction nano-generator and the piezoelectric nano-generator are arranged in a split manner, and the integrated heartbeat-respiration sensor comprises a substrate, a first piezoelectric layer, a first electrode layer, an isolation layer, a first friction electric layer, a second electrode layer, a third electrode layer and a second friction electric layer, wherein the first electrode layer is arranged on the substrate, the second friction electric layer is arranged on the first electrode layer, the first friction electric layer is arranged on the second friction electric layer, and the isolation layer is arranged between the first friction electric layer and the second friction electric layer; the first piezoelectric layer is arranged on the third electrode layer, the second electrode layer is arranged on the first piezoelectric layer, and the third electrode layer, the first piezoelectric layer and the second electrode layer are arranged at intervals with the first electrode layer, the isolation layer, the first friction electric layer and the second friction electric layer; the first electrode layer, the second triboelectric layer, the isolation layer and the first triboelectric layer form a contact separation type friction nano-generator; the third electrode layer, the first piezoelectric layer and the second electrode layer constitute a piezoelectric nanogenerator.
According to a preferred embodiment, the insulating layer is a hollow structure shaped like a Chinese character 'hui'.
According to a preferred embodiment, the integrated sensor further comprises a packaging layer, wherein the packaging layer is arranged on the substrate and wraps and covers the first piezoelectric layer, the first electrode layer, the isolation layer, the first triboelectric layer and the second electrode layer, or the packaging layer is arranged on the substrate and wraps and covers the first piezoelectric layer, the first electrode layer, the isolation layer, the first triboelectric layer, the second electrode layer, the third electrode layer and the second triboelectric layer.
According to a preferred embodiment, the integrated sensor for cardiac shock and respiration further comprises an adhesive layer, wherein the adhesive layer is arranged on one surface of the integrated sensor for cardiac shock and respiration, which is in contact with a user, and the adhesive layer is at least arranged on the integrated sensor for cardiac shock and respiration, where the piezoelectric nano generator is arranged.
According to a preferred embodiment, the host further comprises a battery, the battery is connected with the circuit board, and the battery is used for supplying power to the circuit board.
According to a preferred embodiment, the main machine further comprises a casing, wherein the casing is at least used for covering a part of the integrated heart-breath sensor, on which the contact separation type friction nano generator is arranged, the circuit board and the battery; a switch and a charging port are arranged on the shell, wherein the switch is used for controlling the working state of the integrated heart-breath sensor and/or the circuit board; the charging port is a magnetic type charging port, and the charging port is used for connecting the battery with an external power supply.
According to a preferred embodiment, the integrated cardiac shock and respiration recorder further comprises chest belts, the chest belts are fixed on two sides of the main machine, and the chest belts are used for placing the main machine at the lowest skin of the sternum.
The integrated recording instrument for the heart beat and the breath provided by the utility model at least has the following beneficial technical effects:
the utility model discloses a heart-shake and respiration integrated recorder which comprises a host machine, wherein the host machine comprises a heart-shake and respiration integrated sensor and a circuit board, wherein the heart-shake and respiration integrated sensor comprises a contact separation type friction nano generator and a piezoelectric nano generator, the contact separation type friction nano generator is used for collecting heart-shake signals, and the piezoelectric nano generator is used for collecting respiration signals; the contact separation type friction nano generator and the piezoelectric nano generator are connected with the circuit board, the circuit board is connected with the receiving terminal, and the heart vibration signals collected by the contact separation type friction nano generator and the respiration signals collected by the piezoelectric nano generator are converted by the circuit board and then are sent to the receiving terminal.
On the other hand, the contact separation type friction nano generator is adopted to collect the heart shock signals, has good response capability to weak and low-frequency chest shock signals (caused by heart shock), can monitor the heart shock signals and the respiration signals when a user is in a non-forbidden state, has weak motion interference and is easy to separate, and solves the technical problems that in the prior art, the heart shock signals are monitored by using an accelerometer or a gyroscope sensor, the user is required to keep the forbidden state, otherwise, the heart shock signals are subjected to motion interference and are difficult to separate, and the heart shock signals can be annihilated.
On the other hand, when the contact separation type friction nano-generator and the piezoelectric nano-generator are self-powered, the energy consumption of the integrated cardiac shock-respiration recorder can be reduced, the wearable experience of a user can be improved, and the technical problems that an accelerometer or a gyroscope sensor used in the prior art needs external power supply, the energy consumption is increased, and the use convenience is reduced are solved.
In a fourth aspect, the contact separation type friction nano-generator and the piezoelectric nano-generator are low in cost and easy to manufacture, and the technical problems that an accelerometer or a gyroscope used in the prior art is high in cost and difficult to manufacture are solved.
Drawings
In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings 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 efforts.
FIG. 1 is an exploded view of a preferred embodiment of the host of the present invention;
FIG. 2 is an assembled view of a preferred embodiment of the host of the present invention;
FIG. 3 is a top view of a preferred embodiment of the integrated heartbeat-respiration sensor of the present invention;
FIG. 4 is a cross-sectional view of a first preferred embodiment of the integrated heartbeat-respiration sensor of the utility model;
FIG. 5 is a cross-sectional view of a second preferred embodiment of the integrated heartbeat-respiration sensor of the utility model;
FIG. 6 is a schematic wearing view of the integrated recorder of the utility model;
FIG. 7 is a flow chart of a method of using the integrated seismograph-respiration recorder of the present invention.
In the figure: 1. a heart-breath integrated sensor; 11. a substrate; 12. a first piezoelectric layer; 13. a first electrode layer; 14. an insulating layer; 15. a first triboelectric layer; 16. a second electrode layer; 17. an encapsulation layer; 18. a pasting layer; 19. a third electrode layer; 110. a second triboelectric layer; 2. a circuit board; 3. a battery; 4. a housing; 41. a switch; 42. a charging port; 5. a chest strap.
Detailed Description
In order to make the objects, technical solutions and advantages of the present invention more apparent, the technical solutions of the present invention will be described in detail below. It is to be understood that the described embodiments are merely exemplary of the utility model, and not restrictive of the full scope of the utility model. All other embodiments, which can be derived by a person skilled in the art from the examples given herein without any inventive step, are within the scope of the present invention.
The utility model will be described in detail with reference to the accompanying drawings 1-7 and examples 1 and 2.
Example 1
This example describes the structure of a first preferred embodiment of the integrated heartbeat-respiration recorder of the present invention in detail.
The integrated recording instrument for the heart and the breath comprises a host. Preferably, the main unit comprises a heart and breath integrated sensor 1 and a circuit board 2, as shown in fig. 1 and 2. More preferably, the integrated sensor 1 for cardiac shock and respiration comprises a contact separation type friction nano generator and a piezoelectric nano generator, wherein the contact separation type friction nano generator is used for collecting cardiac shock signals, and the piezoelectric nano generator is used for collecting respiration signals; the contact separation type friction nano generator and the piezoelectric nano generator are connected with the circuit board 2, the circuit board 2 is connected with the receiving terminal, and the heart vibration signals collected by the contact separation type friction nano generator and the respiration signals collected by the piezoelectric nano generator are converted by the circuit board 2 and then sent to the receiving terminal, as shown in figures 1-5. More preferably, the circuit board 2 is connected to the receiving terminal via bluetooth.
Specifically, the integrated recorder of the present embodiment of the heart-shaking and respiration is an analog signal, the heart-shaking signal collected by the contact separation type friction nano generator and the respiration signal collected by the piezoelectric nano generator are sent to the circuit board 2 by the integrated recorder of the heart-shaking and respiration, the heart-shaking signal and the respiration signal collected by the contact separation type friction nano generator and the piezoelectric nano generator are AD-converted by the circuit board 2, and then the AD-converted signals can be stored in the memory card, or the data can be sent to the receiving terminal for analysis by the bluetooth. The receiving terminal is for example a mobile phone or a PC.
The integrated recording instrument for the heart-shaking and the respiration of the embodiment can realize the simultaneous monitoring of the heart-shaking signals and the respiration signals of a user through the contact separation type friction nano generator and the piezoelectric nano generator, and solves the technical problem that the accelerometer or the gyroscope sensor cannot synchronously monitor and record the heart-shaking signals and the respiration signals when the accelerometer or the gyroscope sensor is used as a sensing device to monitor the heart-shaking signals in the prior art.
On the other hand, the contact separation type friction nano generator is adopted to collect the heart shock signals, the contact separation type friction nano generator has good response capability on weak and low-frequency chest shock signals (caused by heart shock), the heart shock signals and the respiration signals can be monitored when a user is in a non-forbidden state, the movement interference is weak, the separation is easy, and the technical problems that in the prior art, the heart shock signals are monitored by an accelerometer or a gyroscope sensor, the user is required to keep the forbidden state, otherwise, the heart shock signals are subjected to the movement interference and are not easy to separate, and the heart shock signals are possibly annihilated are solved.
On the other hand, in the period that the contact separation type friction nano-generator and the piezoelectric nano-generator are self-powered, the energy consumption of the integrated heart-shaking and breathing recorder can be reduced, the wearable experience of a user is improved, and the technical problems that an accelerometer or a gyroscope sensor used in the prior art needs external power supply, the energy consumption is increased, and the use convenience is reduced are solved.
In a fourth aspect, the contact separation type friction nano-generator and the piezoelectric nano-generator of the embodiment have low cost and are easy to manufacture, and the technical problems that an accelerometer or a gyroscope used in the prior art is high in cost and difficult to manufacture are solved.
According to a preferred embodiment, the contact separation type friction nano-generator and the piezoelectric nano-generator are arranged in a whole. Preferably, the integrated sensor 1 includes a substrate 11, a first piezoelectric layer 12, a first electrode layer 13, an isolation layer 14, a first triboelectric layer 15 and a second electrode layer 16, wherein the first electrode layer 13 is disposed on the substrate 11, the first piezoelectric layer 12 is disposed on the first electrode layer 13, the first triboelectric layer 15 and the second electrode layer 16 are disposed on the first piezoelectric layer 12 at intervals, and the isolation layer 14 is disposed between the first piezoelectric layer 12 and the first triboelectric layer 15, as shown in fig. 4. More preferably, the first piezoelectric layer 12, the first electrode layer 13, the isolation layer 14 and the first triboelectric layer 15 constitute a contact separation type triboelectric nanogenerator; the first piezoelectric layer 12, the first electrode layer 13 and the second electrode layer 16 constitute a piezoelectric nanogenerator.
Specifically, in the preferred technical scheme of this embodiment, the first piezoelectric layer 12, the first electrode layer 13, the isolation layer 14 and the first triboelectric layer 15 form a contact separation type friction nano-generator, and the principle of the contact separation type friction nano-generator for collecting the shake signal is as follows: the lower end of the sternum vibrates due to the cardiac vibration, the vibration is transmitted to the cardiac vibration-respiration integrated sensor 1, so that the first piezoelectric layer 12 and the first triboelectric layer 15 are in contact, and when the two layers of materials are in contact, charges with opposite signs are generated on the surfaces of the two layers of materials due to the electrostatic induction effect of the contact generated charges; when the vibration is slowed down or disappears, the two layers of materials are separated to generate potential difference, the open-circuit voltage changes, and the circuit board 2 can obtain the heart-shocking signals by recording the open-circuit voltage changes.
Specifically, in the preferred technical scheme of this embodiment, the first piezoelectric layer 12, the first electrode layer 13 and the second electrode layer 16 form a piezoelectric nanogenerator, and the principle of the piezoelectric nanogenerator for acquiring respiratory signals is as follows: the human body breathes to cause the abdominal cavity to rise and fall, the integral heart-shaking and breathing sensor 1 attached to the abdominal cavity can generate bending deformation due to the rise and fall of the abdominal cavity, so that the polarized first piezoelectric layer 12 generates piezoelectric charges, the upper surface and the lower surface generate potential differences to cause open-circuit voltage change, and the circuit board 2 can obtain a breathing signal by recording the open-circuit voltage change.
According to a preferred embodiment, the insulating layer 14 is a hollow structure shaped like a Chinese character 'hui'. Without being limited thereto, the insulating layer 14 may also be a remaining elastic member, such as a spring. In the preferred technical solution of this embodiment, the isolation layer 14 is a hollow structure shaped like a Chinese character 'hui', so that the isolation layer 14 has a certain elasticity, and when the vibration of the heart is transmitted to the integrated sensor 1, the integrated sensor 1 can extrude the isolation layer 14 by the pressure, so that the first piezoelectric layer 12 can be in contact with the first triboelectric layer 15; when the vibration is reduced or eliminated, the pressure applied to the isolation layer 14 is reduced or eliminated, and the isolation layer 14 is restored to its original position, so that the first piezoelectric layer 12 and the first triboelectric layer 15 can be separated.
According to a preferred embodiment, the integrated heart-breath sensor 1 further comprises an encapsulation layer 17, as shown in fig. 4. Preferably, the encapsulation layer 17 is disposed on the substrate 11 and covers the first piezoelectric layer 12, the first electrode layer 13, the isolation layer 14, the first triboelectric layer 15 and the second electrode layer 16, as shown in fig. 4. The integrated sensor 1 for cardiac shock and respiration in the preferred technical solution of this embodiment further includes an encapsulation layer 17, and the first piezoelectric layer 12, the first electrode layer 13, the isolation layer 14, the first triboelectric layer 15 and the second electrode layer 16 can be protected by the action of the encapsulation layer 17.
According to a preferred embodiment, the integrated heart-respiration sensor 1 further comprises an adhesive layer 18, as shown in fig. 4 and 5. Preferably, the adhesive layer 18 is disposed on a surface of the integrated sensor 1 contacting with a user, and the adhesive layer 18 is disposed at least on the integrated sensor 1 where the piezoelectric nanogenerator is disposed, as shown in fig. 4 and 5. The integrated heart-respiration sensor 1 of the preferred technical scheme of the embodiment further comprises the adhesive layer 18, and the integrated heart-respiration sensor 1 can be adhered to the chest of the user through the adhesive layer 18 to fix the integrated heart-respiration sensor 1, so that the monitoring accuracy of the integrated heart-respiration sensor 1 can be improved.
Preferably, the substrate 11 is made of Kapton material, PET material, PTFE material or PVDF material. Without being limited thereto, the substrate 11 may be made of other materials that are easily bent.
Preferably, the first piezoelectric layer 12 is made of a polarized PVDF film, a polarized PVDF-Trfe film, or a polarized piezoelectric composite film. More preferably, the first piezoelectric layer 12 is made of a polarized PDMS-BTO composite material, a polarized PDMS-PZT composite material, or a polarized PVDF-BTO composite material.
Preferably, the first electrode layer 13 is made of Au, Al, Ag, Cu or Pt electrode material. The first electrode layer 13 may be prepared by one of a magnetron sputtering method, an electron beam evaporation method, a thermal evaporation method, a blade coating method, a tape casting method, a screen printing method, and an ink jet printing method. As shown in fig. 4, the first electrode layer 13 is entirely disposed on the lower surface of the first piezoelectric layer 12.
Preferably, the first triboelectric layer 15 is made of a metal material or a dielectric material plated with an electrode.
Preferably, the second electrode layer 16 is made of Au, Al, Ag or Cu electrode material. The second electrode layer 16 may be prepared using one of a magnetron sputtering method, an electron beam evaporation method, a thermal evaporation method, a blade coating method, a tape casting method, a screen printing method, and an inkjet printing method. As shown in fig. 4, the second electrode layer 16 is disposed on a portion of the upper surface of the first piezoelectric layer 12.
Preferably, the encapsulating layer 17 is made of PDMS or silicone rubber.
Preferably, the adhesive layer 18 is made of double-sided tape, non-woven adhesive tape or adhesive gel material.
According to a preferred embodiment, the host machine further comprises a battery 3, as shown in fig. 1. Preferably, a battery 3 is connected to the circuit board 2, and the battery 3 is used to power the circuit board 2. Preferably, the battery 3 may be a pouch battery. The host computer of the preferred technical scheme of this embodiment also includes battery 3, can be for circuit board 2 power supply through battery 3 to guarantee circuit board 2 normal operating.
According to a preferred embodiment, the host further comprises a housing 4, as shown in fig. 1 and 2. Preferably, the housing 4 is at least used for covering the portion of the integrated heart-respiration sensor 1 where the contact separation type friction nano generator is arranged, the circuit board 2 and the battery 3, as shown in fig. 2. More preferably, a switch 41 and a charging port 42 are arranged on the housing 4, wherein the switch 41 is used for controlling the working state of the integrated sensor 1 and/or the circuit board 2; the charging port 42 is a magnetic attraction type charging port, and the charging port 42 is used to connect the battery 3 with an external power supply, as shown in fig. 1 and 2. The main machine of the preferred technical scheme of the embodiment also comprises a shell 4, and the integrated heart-breath sensor 1, the circuit board 2 and the battery 3 can be protected by the shell 4. Further, a switch 41 and a charging port 42 are arranged on the housing 4, the switch 41 can control the working state of the integrated sensor 1 and/or the circuit board 2, and the charging port 42 can charge the battery 3.
According to a preferred embodiment, the integrated seismograph-respiration recorder further comprises a chest strap 5, as shown in fig. 6. Preferably, the chest bands 5 are fixed on both sides of the main body, and the chest bands 5 are used to place the main body at the lowest skin of the body of the sternum, as shown in fig. 6. The lowest skin of the sternum is the location near the xiphoid process. The integrated cardiac shock-respiration recorder of the preferred technical scheme of the embodiment further comprises a chest strap 5, and the main machine can be firmly placed at the lowest end skin of the chest bone body through the chest strap 5 so as to detect cardiac shock signals and respiration signals of a user. Specifically, the host part is placed on the lowest skin of the sternum of a user and is bound by a chest belt 5; the adhesive layer 18 is adhered to the skin of the abdomen, so that the lower hem part (the piezoelectric nano generator) of the main machine of the integrated heart-respiration recorder can swing along with the fluctuation of the abdomen.
As shown in fig. 7, the usage of the integrated recorder for heart-breath of this embodiment is as follows:
step 1: after the integrated recorder for cardiac shock and respiration is worn in a predetermined manner, the switch 41 is turned on.
Step 2: and opening an app on a receiving terminal such as a mobile phone, and connecting the receiving terminal with the integrated heart-rhythm and respiration recorder through Bluetooth.
And step 3: and observing the heart-shaking signal and the respiration signal, and finely adjusting the position of the heart-shaking-respiration integrated recorder according to the signal quality.
And 4, step 4: after the position of the integrated recording instrument for the heart and the breath is adjusted, the recording is started, and signals are stored in a memory card of the integrated recording instrument for the heart and the breath.
And 5: and after the recording is finished, taking out the memory card, and reading the analysis data at the computer end.
Example 2
This example describes the structure of a second preferred embodiment of the integrated heartbeat-respiration recorder of the present invention in detail. In this embodiment, only the differences from embodiment 1 will be described.
The contact separation type friction nano-generator and the piezoelectric nano-generator are arranged in a split mode. Preferably, the integrated sensor 1 includes a substrate 11, a first piezoelectric layer 12, a first electrode layer 13, an isolation layer 14, a first triboelectric layer 15, a second electrode layer 16, a third electrode layer 19, and a second triboelectric layer 110, wherein the first electrode layer 13 is disposed on the substrate 11, the second triboelectric layer 110 is disposed on the first electrode layer 13, the first triboelectric layer 15 is disposed on the second triboelectric layer 110, and the isolation layer 14 is disposed between the first triboelectric layer 15 and the second triboelectric layer 110; the first piezoelectric layer 12 is disposed on the third electrode layer 19, the second electrode layer 16 is disposed on the first piezoelectric layer 12, and the third electrode layer 19, the first piezoelectric layer 12 and the second electrode layer 16 are disposed at intervals from the first electrode layer 13, the isolation layer 14, the first triboelectric layer 15 and the second triboelectric layer 110, as shown in fig. 5. More preferably, the first electrode layer 13, the second triboelectric layer 110, the insulating layer 14 and the first triboelectric layer 15 constitute a contact separation type triboelectric nanogenerator; the third electrode layer 19, the first piezoelectric layer 12 and the second electrode layer 16 constitute a piezoelectric nanogenerator.
According to a preferred embodiment, the integrated heart-breath sensor 1 further comprises an encapsulation layer 17, as shown in fig. 5. Preferably, the encapsulation layer 17 is disposed on the substrate 11 and covers the first piezoelectric layer 12, the first electrode layer 13, the isolation layer 14, the first triboelectric layer 15, the second electrode layer 16, the third electrode layer 19, and the second triboelectric layer 110, as shown in fig. 5. The integrated sensor 1 for cardiac shock and respiration in the preferred technical solution of this embodiment further includes an encapsulation layer 17, and the first piezoelectric layer 12, the first electrode layer 13, the isolation layer 14, the first triboelectric layer 15, the second electrode layer 16, the third electrode layer 19 and the second triboelectric layer 110 can be protected by the action of the encapsulation layer 17.
Preferably, the third electrode layer 19 is made of Au, Al, Ag or Cu electrode material. Without being limited thereto, the third electrode layer 19 may also be made of the remaining electrode material.
Preferably, the second triboelectric layer 110 is made of PDMS, PET, PVDF, PI or PTFE dielectric material. Without being limited thereto, the second triboelectric layer 110 may also be made of the remaining dielectric material.
Specifically, in the preferred technical scheme of this embodiment, the first electrode layer 13, the second frictional electric layer 110, the isolation layer 14 and the first frictional electric layer 15 form a contact separation type friction nano-generator, and the principle of the contact separation type friction nano-generator for collecting the shake signal is as follows: the lower end of the sternum vibrates due to the cardiac vibration, the vibration is transmitted to the cardiac vibration-respiration integrated sensor 1, so that the second triboelectric layer 110 is in contact with the first triboelectric layer 15, and when the two layers of materials are in contact, charges with opposite signs are generated on the surfaces of the two layers of materials due to the electrostatic induction effect of the contact generated charges; when the vibration is slowed down or disappears, the two layers of materials are separated to generate potential difference, the open-circuit voltage changes, and the circuit board 2 can obtain the heart-shocking signals by recording the open-circuit voltage changes.
Specifically, in the preferred technical scheme of this embodiment, the first piezoelectric layer 12, the first electrode layer 13 and the second electrode layer 16 form a piezoelectric nanogenerator, and the principle of the piezoelectric nanogenerator for acquiring respiratory signals is as follows: the human body breathes to cause the abdominal cavity to rise and fall, the integral heart-shaking and breathing sensor 1 attached to the abdominal cavity can generate bending deformation due to the rise and fall of the abdominal cavity, so that the polarized first piezoelectric layer 12 generates piezoelectric charges, the upper surface and the lower surface generate potential differences to cause open-circuit voltage change, and the circuit board 2 can obtain a breathing signal by recording the open-circuit voltage change.
In the description of the present invention, it is to be noted that, unless otherwise specified, "a plurality" means two or more; the terms "upper", "lower", "left", "right", "inner", "outer", "front", "rear", "head", "tail", and the like, indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, are only for convenience in describing and simplifying the description, and do not indicate or imply that the device or element referred to must have a particular orientation, be constructed in a particular orientation, and be operated, and thus, should not be construed as limiting the utility model. Furthermore, the terms "first," "second," "third," and the like are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.
In the description of the present invention, it should also be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, e.g., as meaning either a fixed connection, a removable connection, or an integral connection; can be mechanically or electrically connected; may be directly connected or indirectly connected through an intermediate. Specific meanings of the above terms in the present invention can be understood as appropriate by those of ordinary skill in the art.
The above description is only for the specific embodiments of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art can easily think of the changes or substitutions within the technical scope of the present invention, and shall cover the scope of the present invention. Therefore, the protection scope of the present invention shall be subject to the protection scope of the appended claims.

Claims (9)

1. A heart-shake and breath integrated recorder is characterized by comprising a host machine, wherein the host machine comprises a heart-shake and breath integrated sensor (1) and a circuit board (2), wherein,
the integrated heart-vibration-respiration sensor (1) comprises a contact separation type friction nano generator and a piezoelectric nano generator, wherein the contact separation type friction nano generator is used for acquiring a heart-vibration signal, and the piezoelectric nano generator is used for acquiring a respiration signal;
the contact separation type friction nano generator and the piezoelectric nano generator are connected with the circuit board (2), the circuit board (2) is connected with a receiving terminal, and the cardiac shock signals collected by the contact separation type friction nano generator and the respiration signals collected by the piezoelectric nano generator are converted by the circuit board (2) and then sent to the receiving terminal.
2. The integrated recording instrument of claim 1, wherein the contact separation type friction nano generator and the piezoelectric nano generator are integrally arranged, and the integrated sensor of heart and breath (1) comprises a substrate (11), a first piezoelectric layer (12), a first electrode layer (13), an insulating layer (14), a first friction electric layer (15) and a second electrode layer (16),
the first electrode layer (13) is arranged on the substrate (11), the first piezoelectric layer (12) is arranged on the first electrode layer (13), the first triboelectric layer (15) and the second electrode layer (16) are arranged on the first piezoelectric layer (12) at intervals, the isolation layer (14) is arranged between the first piezoelectric layer (12) and the first triboelectric layer (15),
the first piezoelectric layer (12), the first electrode layer (13), the isolation layer (14) and the first triboelectric layer (15) form a contact separation type friction nano-generator; the first piezoelectric layer (12), the first electrode layer (13) and the second electrode layer (16) constitute a piezoelectric nanogenerator.
3. The integrated recording instrument of claim 1, wherein the contact separation type friction nano generator and the piezoelectric nano generator are arranged in a split manner, and the integrated sensor of heart and breath (1) comprises a substrate (11), a first piezoelectric layer (12), a first electrode layer (13), an insulating layer (14), a first friction electric layer (15), a second electrode layer (16), a third electrode layer (19) and a second friction electric layer (110),
the first electrode layer (13) is arranged on the substrate (11), the second triboelectric layer (110) is arranged on the first electrode layer (13), the first triboelectric layer (15) is arranged on the second triboelectric layer (110), and the isolation layer (14) is arranged between the first triboelectric layer (15) and the second triboelectric layer (110);
the first piezoelectric layer (12) is arranged on the third electrode layer (19), the second electrode layer (16) is arranged on the first piezoelectric layer (12), and the third electrode layer (19), the first piezoelectric layer (12) and the second electrode layer (16) are arranged at intervals with the first electrode layer (13), the isolation layer (14), the first triboelectric layer (15) and the second triboelectric layer (110);
the first electrode layer (13), the second triboelectric layer (110), the insulating layer (14) and the first triboelectric layer (15) form a contact separation type triboelectric nanogenerator; the third electrode layer (19), the first piezoelectric layer (12) and the second electrode layer (16) constitute a piezoelectric nanogenerator.
4. The integrated recorder of claim 2 or 3, wherein the insulating layer (14) is a hollow structure shaped like a Chinese character 'hui'.
5. The integrated recorder according to claim 2 or 3, wherein the integrated sensor (1) further comprises an encapsulation layer (17), and the encapsulation layer (17) is disposed on the substrate (11) and covers the first piezoelectric layer (12), the first electrode layer (13), the isolation layer (14), the first friction electric layer (15) and the second electrode layer (16) or covers the first piezoelectric layer (12), the first electrode layer (13), the isolation layer (14), the first friction electric layer (15) and the second electrode layer (16) in an enveloping manner
The packaging layer (17) is arranged on the substrate (11) and wraps and covers the first piezoelectric layer (12), the first electrode layer (13), the isolation layer (14), the first friction electric layer (15), the second electrode layer (16), the third electrode layer (19) and the second friction electric layer (110).
6. The integrated recording instrument of claim 5, wherein the integrated sensor of cardiac shock and respiration (1) further comprises an adhesive layer (18), the adhesive layer (18) is disposed on a surface of the integrated sensor of cardiac shock and respiration (1) contacting with a user, and the adhesive layer (18) is at least disposed on the integrated sensor of cardiac shock and respiration (1) where the piezoelectric nano generator is disposed.
7. The integrated recorder of claim 1, wherein the main unit further comprises a battery (3), the battery (3) is connected to the circuit board (2), and the battery (3) is used for supplying power to the circuit board (2).
8. The integrated recorder of claim 7, wherein the main machine further comprises a casing (4), the casing (4) is at least used for covering the part of the integrated sensor (1) provided with the contact separation type friction nano generator, the circuit board (2) and the battery (3); and a switch (41) and a charging port (42) are provided on the housing (4), wherein,
the switch (41) is used for controlling the working state of the integrated heart-respiration sensor (1) and/or the circuit board (2); the charging port (42) is a magnetic attraction type charging port, and the charging port (42) is used for connecting the battery (3) with an external power supply.
9. The integrated cardiac shock-respiration recorder according to claim 1, further comprising chest straps (5), wherein the chest straps (5) are fixed on both sides of the main body, and the chest straps (5) are used for placing the main body at the lowest skin of the sternum.
CN202220041934.XU 2022-01-05 2022-01-05 Integrated recording instrument for cardiac shock and respiration Active CN216984894U (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
CN202220041934.XU CN216984894U (en) 2022-01-05 2022-01-05 Integrated recording instrument for cardiac shock and respiration

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
CN202220041934.XU CN216984894U (en) 2022-01-05 2022-01-05 Integrated recording instrument for cardiac shock and respiration

Publications (1)

Publication Number Publication Date
CN216984894U true CN216984894U (en) 2022-07-19

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Family Applications (1)

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Country Status (1)

Country Link
CN (1) CN216984894U (en)

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