TWM594440U - Wearable electronic stethoscope - Google Patents

Abstract

The present invention discloses a wearable electronic stethoscope, which is an electronic stethoscope provided on the wearable to sense the body signal of the detected person. The wearable electronic stethoscope includes a wearable, at least one respiratory stability sensor, at least One-belt breathing sensor, at least one bowel sound sensor, processing module, wireless transmission module and power supply module; by this, the creation is provided by a plurality of sensing on the wearing parts presented in the form of vest The hardware design of the device effectively approaches the detected position of the person to be detected and detects the signals such as respiratory stability, breathing or bowel sounds, etc., and transmits them to the physician or digital analysis system for real-time analysis through wireless transmission protocol. Effectively reduce the doctor's visit time, digital integration and statistics, and realize the advantages of home monitoring and nursing.

Description

Wearable electronic stethoscope

This creation relates to a wearable electronic stethoscope, in particular to a wearable electronic stethoscope which is arranged on the wearable to sense the respiratory stability signal, respiratory signal and intestinal sound signal of the detected person.

The stethoscope is an important instrument used by general physicians to diagnose the function of internal organs of patients. The most important thing is to listen to the sounds emitted by internal organs of patients, such as lung function or bowel sounds, etc. First-line health care and medical protection methods, in which lung function examination mainly calculates lung volume and lung volume by the amount of air that enters and exits the respiratory tract during breathing to evaluate the ventilation function of the lungs, as well as the distribution of air after entering the lungs, blood flow Through the diffusion of the respiratory membrane, etc.; bowel sounds refer to a kind of grunt or air over water sound produced by the gas and liquid flowing in the bowel when the bowel is peristaltic. Under normal circumstances, the bowel sounds are about every minute 4 to 5 times, the sound is relatively weak and gentle, and it is more difficult for most people to hear. However, if the gastrointestinal motility is abnormal, for example: too fast or too slow, the bowel sounds may become high-frequency or slow down.

Although the traditional stethoscope has the advantages of simple structure, low price and convenient use, however, whether it is physical or electronic, the traditional stethoscope requires the doctor to hold the amplification device to his ear to listen to the sound emitted by the patient's body. Combined with professional experience to determine the physical condition or possible cause represented by the sound, the shortcoming is that it may be due to the doctor's own hearing fatigue or human subjective factors, which may cause misjudgment of the patient's condition; in addition, the traditional stethoscope The doctor can only use the hearing to determine the cause in a short period of time, and can not record for further judgment, or can only compare the previous diagnosis with memory alone, and there is no reliable information for reference; moreover, the stethoscope The transmission of sound has nothing to do with the frequency, and it is impossible to separate the sounds emitted by the respective internal organs. The doctor hears the mixed sound of all organs from the traditional stethoscope, and the body structure of each patient is different and the thickness of the skin tissue is different, which is easy to affect the sound The intensity of the doctor’s doctor’s ability to individually judge the condition of individual organs increases the difficulty of auscultation; therefore, how to effectively detect the sound or signal of individual organs of patients with an innovative hardware design for accuracy Judgement and treatment are still issues that need to be continuously overcome and solved by developers and related researchers in related industries such as medical supplies.

The reason is that the creators have taken this into consideration, and with the help of their rich professional knowledge and many years of practical experience, they have improved and created a wearable electronic stethoscope, whose purpose is to provide a set on the wearable to sense the detected The wearable electronic stethoscope of the breath stability signal, breath signal and intestinal sound signal of the examiner is mainly designed by the hardware design of a plurality of sensors on the wearing parts presented in the form of vest to effectively approach the detected The position of the lungs, abdomen or intestines of the person and detect their respiratory stability, breathing or bowel sounds and other signals, and send them to the doctor or digital analysis system for real-time analysis through wireless transmission protocol, which effectively reduces the time for doctors to see the doctor , Digital integration and statistics, and the main advantages of realizing home monitoring and nursing.

According to the purpose of this writing, a wearable electronic stethoscope is proposed for sensing at least one physiological signal from a body. The wearable electronic stethoscope includes at least one wearing part, at least one respiratory stability sensor, and at least one abdominal Breathing sensor, at least one bowel sound sensor, a processing module, a wireless transmission module, and a power supply module; the wearing part is for wearing on a specific part of the body, the wearing part includes a back, and two Connected to the front of the chest at the two ends of the back; at least one breath stability sensor is placed on one of the inner surfaces of the back or chest and close to the body's lungs to the abdomen to sense a breath stability Degree signal; at least one abdominal breathing sensor is placed on one of the inner surfaces of the back or chest and close to the abdomen of the body to sense a breathing signal; at least one bowel sound sensor is located on the back or One of the inner surfaces of the chest and near the lower abdomen of the body to sense an intestinal sound signal; the processing module is electrically connected to the respiratory stability sensor, abdominal breathing sensor, and intestinal sound sensing The processing module receives and analyzes the respiratory stability signal, respiratory signal, and intestinal sound signal; the transmission module is electrically connected to the processing module, and the transmission module receives the respiratory stability signal and breath from the processing module Signal and intestinal sound signal, and transmitted to a server; the power supply module is electrically connected to the processing module and the transmission module respectively, and the power supply module is connected to an external power supply to provide the power required by the processing module and the transmission module .

In one embodiment of the present creation, the wearing part is one of vest fabric, short-sleeved fabric, or suspender fabric.

In one embodiment of the present creation, an opening is opened at the junction between the back and the chest.

In one embodiment of the present creation, the chest part is correspondingly joined by a connecting member.

In an embodiment of the present creation, the wearable electronic stethoscope system includes at least 9 respiratory stability sensors.

In an embodiment of the present invention, the wearable electronic stethoscope system includes at least 4 abdominal breathing sensors.

In an embodiment of the present invention, the wearable electronic stethoscope includes at least one bowel sound sensor.

In an embodiment of the present invention, the processing module is electrically connected to the breathing stability sensor, the abdominal breathing sensor, and the bowel sound sensor by one of wired or wireless methods.

In an embodiment of the present invention, the processing module is electrically connected to the respiratory stability sensor, the abdominal respiratory sensor, and the bowel sound sensor in a wired manner through at least one signal line.

In an embodiment of the present invention, the processing module is electrically connected to the respiratory stability sensor, the abdominal respiratory sensor, and the bowel sound sensor by a wireless communication protocol.

In an embodiment of the present invention, the wireless communication protocol is a Bluetooth wireless communication module, a WiFi wireless communication module, a WiMAX wireless communication module, a Zigbee wireless communication module, a fourth-generation mobile communication technology, or a fifth-generation mobile One of the wireless communication protocols such as communication technology.

In an embodiment of the present invention, the transmission module is connected to the processing module through a wireless communication protocol.

In an embodiment of the present invention, the transmission module is connected to the server through a wireless communication protocol.

In an embodiment of the present invention, the server is one of a remote server, a remote computer, a notebook computer, a tablet computer, or a smart phone.

In an embodiment of the present invention, the power supply module is a device such as a power plug, a lithium battery, or a rechargeable battery.

In an embodiment of the present invention, the wearable electronic stethoscope may further be provided with a storage module electrically connected to the processing module. The storage module stores the respiratory stability signal, respiratory signal or intestinal sound signal received by the processing module Wait for one of these signals or a combination of two or more.

In this way, the wearable electronic stethoscope of this creation is mainly designed by the hardware design of a plurality of sensors on the wearing parts presented in the form of vests, which is effectively close to the lungs, abdomen or intestines of the detected person. Position and detect its respiration stability, breathing or bowel sound signals, and send it to the doctor or digital analysis system through wireless transmission protocol for real-time analysis, which can effectively reduce the doctor's visit time, digital integration and statistics, and achieve home The main advantage of monitoring nursing.

In order to facilitate the examiner to understand the technical characteristics, content and advantages of this creation and the effects it can achieve, I hereby combine this creation with the drawings and explain in detail in the form of expressions of the embodiments, and the drawings used therein, which The main purpose is only for illustration and auxiliary instructions, and may not be the true proportion and precise configuration after the implementation of the creation, so it should not be interpreted and limited to the relationship between the proportion and configuration of the attached drawings, and the scope of the rights of the creation in the actual implementation. He Xianming.

First, please refer to Figure 1 and Figure 2 together, which is a schematic diagram of the overall structure of a preferred embodiment of a wearable electronic stethoscope and a connection diagram of a server, in which the wearable electronic stethoscope (1 ) Is used to sense at least one physiological signal (as shown in Figure 7) from the body of a detected person (3). The wearable electronic stethoscope (1) at least includes a wearing part (11), At least one breath stability sensor (12), at least one abdominal breath sensor (13), at least one bowel sound sensor (14), a processing module (15), a transmission module (16), And a power supply module (17); the wearable electronic stethoscope (1) of this creation is mainly designed by the hardware design of a plurality of sensors on the wearing part (11) presented in the form of a vest, effectively close to a The position of the lungs, abdomen or intestines of the detected person (3) and the signals such as respiratory stability, breathing or bowel sounds are detected, and transmitted to the physician or digital analysis system for real-time analysis through wireless transmission protocol. Effectively reduce the doctor's visit time, digital integration and statistics, and achieve the main advantages of home monitoring and nursing.

The wearing part (11) provides that the detected person (3) wears on a specific part of the body. The wearing part (11) is at least composed of a back (111), two chest parts (112), and an opening (113) ), and a connector (114), wherein the chest part (112) is connected to the two ends of the back (111), and the opening (113) is provided on the back (111) and The connection between the chest part (112) for the arm of the detected person (3) to pass through, the connector (114) is corresponding to the back part (111) and is arranged on the chest part (112) ) Is used to connect the chest parts (112), wherein the wearing part (11) is a vest fabric, and the wearing part (11) can also be, for example but not limited to, short-sleeved fabric or strap Fabric, etc.

The wearable electronic stethoscope (1) of the present invention includes at least 9 of the respiratory stability sensors (12), wherein the respiratory stability sensors (12) are disposed in the chest (112) Face and close to the position of the lungs to the abdomen of the body of the detected person (3) to sense the signal of the respiratory stability of the detected person (3); please also refer to the figure 3 for This is a schematic diagram of a breathing stability sensor arrangement of a preferred embodiment of the wearable electronic stethoscope, wherein the inner surface of the chest part (112) of the wearing part (11) is provided with 9 sequentially arranged breathing stability The sensor (12) is located close to the position of the lungs of the detected person (3) to the abdomen to sense the state of respiratory fluctuation of the whole body of the detected person (3).

The wearable electronic stethoscope (1) of the present invention includes at least four abdominal breathing sensors (13), wherein the abdominal breathing sensor (13) is disposed on the inner surface of the chest (112) And close to the position of the abdomen of the body of the detected person (3) to sense a breathing signal; the so-called "abdominal breathing" means that the abdomen will swell when inhaling, otherwise the abdomen will naturally sag when exhaling. Breathing is particularly focused on the movement of the diaphragm, because the diaphragm will be pressed down when inhaling, making the range of the chest cavity larger, so the air can enter deeper into the lungs, giving the lungs enough Oxygen; please also refer to Figure 4 for a schematic diagram of the abdominal breathing sensor of a preferred embodiment of the wearable electronic stethoscope, wherein the front part (112) of the wearer (11) The inner surface is provided with four abdominal breathing sensors (13) arranged in line to approach the position of the abdomen of the subject (3) to sense the abdomen of the subject (3) Breathing state.

The wearable electronic stethoscope (1) of the present invention includes at least one bowel sound sensor (14), wherein the bowel sound sensor (14) is disposed on the inner surface of the chest portion (112) and close to the quilt The position of the lower abdomen of the body of the detector (3) to sense an intestinal sound signal; please also refer to FIG. 5 for the intestinal sound sensor setting of a preferred embodiment for creating a wearable electronic stethoscope Schematic diagram, in which the inner surface of the chest part (112) of the wearing part (11) is provided with a bowel sound sensor (14) to approach the position of the lower abdomen of the subject (3) to sense Measure the sound made by the intestine of the subject (3).

The processing module (15) is electrically connected to the breathing stability sensor (12), the abdominal breathing sensor (13), and the bowel sound sensor (14), the processing module (15) It receives and parses the respiration stability signal, the respiration signal and the intestinal sound signal, wherein the processing module (15) is connected to the respiration stability sensor (12) by one of wired or wireless methods , The abdominal breathing sensor (13), and the bowel sound sensor (14), in a preferred embodiment of the present invention, the processing module (15) uses at least one signal line (151) ) And electrically connect the breathing stability sensors (12), the abdominal breathing sensors (13) and the bowel sound sensor (14) in a wired manner to receive the breathing stability signal, the The breathing signal and the intestinal sound signal are analyzed by the built-in judgment program (not shown in the figure) to determine the meaning of the signals to determine the physical health of the detected person (3).

In addition, in another preferred embodiment of the present invention, the processing module (15) can also be electrically connected to the respiration stability sensors (12) and the abdominal breathing through a wireless communication protocol The sensor (13) and the bowel sound sensor (14) to receive the respiration stability signal, the breath signal and the bowel sound signal, and then analyze these by a built-in judgment program (not shown in the figure) The meaning of the signal to determine the physical health of the detected person (3), wherein the wireless communication protocol is Bluetooth wireless communication module, WiFi wireless communication module, WiMAX wireless communication module, Zigbee wireless communication One of the wireless communication protocols such as module, fourth-generation mobile communication technology or fifth-generation mobile communication technology.

Furthermore, the processing module (15) can be further electrically connected to a storage module (not shown in the figure), the storage module can store the respiratory stability signal collected by the processing module (15), the Breathing signal, and the intestinal sound signal.

The transmission module (16) is electrically connected to the processing module (15), and the transmission module (16) receives the respiratory stability signal, the respiratory signal and the bowel sound analyzed by the processing module (15) Signal, and transmitted to a server (2), wherein the transmission module (16) is electrically connected to the processing module (15) and the server (2) through the above wireless communication protocol, and the servo The device (2) is a device such as a remote server, a remote computer, a notebook computer, a tablet computer, or a smartphone; in a preferred embodiment of the present invention, the processing module (15) and The short-distance data transmission of the transmission module (16) can be used, for example, but not limited to a Bluetooth wireless communication module, and the long-distance information transmission of the transmission module (16) and the server (2) can be used For example, but not limited to the fourth-generation mobile communication technology, that is to say, when the processing module (15) transmits the parsed respiratory stability signal, the respiratory signal, and the intestinal audio signal to the Bluetooth wireless communication module to After the transmission module (16), the transmission module (16) transmits the respiratory stability signal, the respiratory signal, and the intestinal sound signal to the server (2) for display using fourth-generation mobile communication technology, To diagnose whether the body of the detected person (3) is abnormal.

The power supply module (17) is electrically connected to the processing module (15) and the transmission module (16), respectively, and the power supply module (17) is connected to an external power supply to provide the processing module (15) and The power required by the transmission module (16), wherein the power supply module (17) is a device such as a power plug, a lithium battery or a rechargeable battery; in a preferred embodiment of the present invention, a power plug is used The power supply module (17) which is electrically connected to the processing module (15) and the transmission module (16) respectively is connected to an external power source (for example: a commercial power supply device) to provide the processing module The power required by the group (15) and the transmission module (16).

In addition, please refer to FIG. 6, which is a schematic diagram of the overall structure of the second preferred embodiment of the wearable electronic stethoscope, in which the respiratory stability sensor (12) and the abdominal respiratory sensor (13) And the bowel sound sensor (14) can be arranged on the inner surface of the back (111) to detect the respiratory stability signal of the detected person (3) from the back of the detected person (3), The breathing signal, the intestinal sound signal, etc. can also achieve the detection effect, and the wearable electronic stethoscope (1) can also incorporate a heart sound sensor (18) that detects the heart sound of the detected person (3) ) The same as the lung sound sensor (19) that detects the lung sound of the subject (3), it can simultaneously detect the heart sound signal and the lung sound signal.

In other words, please refer to FIG. 7 and FIG. 8 together for a schematic diagram of the operation of the respiratory stability sensor and a schematic diagram of the respiratory stability signal of a preferred embodiment of the wearable electronic stethoscope, of which 9 A respiratory stability sensor (12) disposed on the inner surface of the chest part (112) of the wearer (11) and close to the abdomen of the subject (3) senses the subject ( 3) Respiratory stability signal, and correspondingly transmit the respiratory stability signal to the processing module (15) through the signal line (151) for analysis, and then the processing module (15) through the Bluetooth wireless communication module will The respiratory stability signal is transmitted to the transmission module (16), and finally the transmission module (16) transmits the respiratory stability signal to the server (2) through the fourth generation mobile communication technology, and The display (21) displays the respiratory stability signal of the detected person (3); in addition, please refer to FIG. 9 and FIG. 10 together again, which is a preferred embodiment of the creation of a wearable electronic stethoscope The schematic diagram of the operation of the abdominal breathing sensor and the schematic diagram of the abdominal breathing signal, four of which are arranged on the inner surface of the chest part (112) of the wearing part (11) and are close to the abdomen position of the subject (3) The abdominal breathing sensor (13) senses the abdominal breathing signal of the detected person (3), and correspondingly transmits the abdominal breathing signal to the processing module (15) through the signal line (151) for analysis , The processing module (15) transmits the abdominal breathing signal to the transmission module (16) through the Bluetooth wireless communication module, and finally the transmission module (16) passes the fourth generation mobile communication technology The abdominal breathing signal is transmitted to the server (2), and the abdominal breathing signal of the detected person (3) is displayed on the display (21); moreover, please refer to Figure 11 and Figure 12 shows a schematic diagram of the operation of the bowel sound sensor and a schematic diagram of the bowel sound signal of a preferred embodiment of the creation of a wearable electronic stethoscope, one of which is provided on the chest part (112) of the wearing part (11) The bowel sound sensor (14) on the inner surface and close to the lower abdomen of the detected person (3) senses the bowel sound signal of the detected person (3), and corresponds to the signal line (151) The intestinal sound signal is transmitted to the processing module (15) for analysis, the processing module (15) then transmits the intestinal sound signal to the transmission module (16) through the Bluetooth wireless communication module, and finally the transmission module (16) Then pass the fourth-generation mobile communication technology to transmit the bowel sound signal to the server (2), and display the bowel sound signal of the detected person (3) on the display (21); in addition, the The respiratory stability signal, the respiratory signal, and the intestinal sound signal displayed by the server (2) can be provided to the doctor for real-time analysis, or the data can be digitized for digital analysis, which effectively reduces the doctor's time and number of doctor visits Integration and statistics, as well as the main advantages of home monitoring and nursing.

It can be seen from the above implementation description that this creation has the following advantages compared with existing technologies and products:

1. The wearable electronic stethoscope of this creation is mainly designed by the hardware design of a plurality of sensors on the wearing parts presented in the form of vests, which is effectively close to the position of the lungs, abdomen or intestines of the detected person And detect its breathing stability, breathing or bowel sounds and other signals, and send it to the doctor or digital analysis system through wireless transmission protocol for real-time analysis, which can effectively reduce the doctor's visit time, digital integration and statistics, and achieve home monitoring The main advantage of nursing.

In summary, the wearable electronic stethoscope of this creation can indeed achieve the expected use effect through the embodiments disclosed above, and this creation has not been disclosed before the application, and has fully complied with the provisions of the Patent Law and Claim. I filed an application for a new type of patent in accordance with the law, and pleaded for the review and granted the patent.

However, the illustrations and descriptions disclosed above are only preferred embodiments of this creation, and are not intended to limit the scope of protection of this creation; most people who are familiar with this skill, according to the characteristic scope of this creation, do other things Equivalent changes or modifications should be regarded as not departing from the scope of this creative design.

(1): Wearable electronic stethoscope (11): Wearables (111): back (112): Chest (113): opening (114): connector (12): Respiratory stability sensor (13): Abdominal breath sensor (14): Bowel sound sensor (15): Processing module (151): Signal line (16): Transmission module (17): Power supply module (18): Heart sound sensor (19): Lung sound sensor (2): Server (21): display (3): Detected

Figure 1: Schematic diagram of the overall structure of a preferred embodiment of the wearable electronic stethoscope; Figure 2: The connection diagram of the server of a preferred embodiment of the wearable electronic stethoscope; Figure 3: Schematic diagram of the setting of the respiratory stability sensor of a preferred embodiment of the wearable electronic stethoscope; Figure 4: Schematic diagram of the abdominal breathing sensor of a preferred embodiment of the authored wearable electronic stethoscope; Figure 5: Schematic diagram of the bowel sound sensor arrangement of a preferred embodiment of the wearable electronic stethoscope; Figure 6: A schematic diagram of the overall structure of the second preferred embodiment of the wearable electronic stethoscope; Figure 7: Schematic diagram of the operation of the breath stability sensor of a preferred embodiment of the wearable electronic stethoscope; Figure 8: Schematic diagram of the respiratory stability signal of a preferred embodiment of the wearable electronic stethoscope; Figure 9: Schematic diagram of the operation of the abdominal breathing sensor of a preferred embodiment of the wearable electronic stethoscope; Figure 10: A schematic diagram of the abdominal breathing signal of a preferred embodiment of the wearable electronic stethoscope; Figure 11: Schematic diagram of the operation of the bowel sound sensor of a preferred embodiment of the wearable electronic stethoscope; and Figure 12: A schematic diagram of the intestinal sound signal of a preferred embodiment of the wearable electronic stethoscope.

(1): Wearable electronic stethoscope

(11): Wearables

(112): Chest

(12): Respiratory stability sensor

(13): Abdominal breath sensor

(14): Bowel sound sensor

(15): Processing module

(16): Transmission module

(17): Power supply module

Claims (16)

A wearable electronic stethoscope is used to sense at least one physiological signal from a body. The wearable electronic stethoscope (1) includes at least: A wearing part (11) is provided for wearing on a specific part of the body. The wearing part (11) includes a back (111) and two chest parts (112) connected to the two ends of the back (111) respectively ; At least one breath stability sensor (12) is provided on one of the inner surface of the back (111) or the chest (112) and is close to the lungs to the abdomen of the body to sense a breath Stability signal; At least one abdominal breathing sensor (13) is disposed on one of the inner surface of the back (111) or the chest (112) and is close to the abdomen of the body to sense a breathing signal; At least one bowel sound sensor (14) is arranged on one of the inner surface of the back (111) or the chest (112) and is close to the lower abdomen of the body to sense a bowel sound signal; A processing module (15) is electrically connected to the breathing stability sensor (12), the abdominal breathing sensor (13), and the bowel sound sensor (14), the processing module (15) ) Receives and parses the respiratory stability signal, the respiratory signal, and the intestinal sound signal; A transmission module (16) is electrically connected to the processing module (15), and the transmission module (16) receives the respiratory stability signal analyzed by the processing module (15), the respiratory signal and the intestine Audio signals, and transmitted to a server (2); and A power supply module (17) is respectively electrically connected to the processing module (15) and the transmission module (16), the power supply module (17) is connected to an external power supply to provide the processing module (15) And the power required by the transmission module (16). The wearable electronic stethoscope as described in item 1 of the scope of the patent application, wherein the wearing part (11) is one of a vest fabric, a short-sleeved fabric or a strap-type fabric. The wearable electronic stethoscope as described in item 1 of the scope of the patent application, wherein an opening (113) is opened at the connection between the back (111) and the chest (112). The wearable electronic stethoscope as described in item 1 of the patent application scope, wherein the chest parts (112) are correspondingly joined by a connecting member (114). The wearable electronic stethoscope as described in item 1 of the patent application scope, wherein the wearable electronic stethoscope (1) includes at least nine of the respiratory stability sensors (12). The wearable electronic stethoscope as described in item 1 of the patent application scope, wherein the wearable electronic stethoscope (1) includes at least four of the abdominal breathing sensors (13). The wearable electronic stethoscope as described in item 1 of the patent application scope, wherein the wearable electronic stethoscope (1) includes at least one bowel sound sensor (14). The wearable electronic stethoscope as described in item 1 of the patent application scope, wherein the processing module (15) is electrically connected to the respiratory stability sensor (12) and the abdominal type by one of wired or wireless methods Breath sensor (13), and the bowel sound sensor (14). The wearable electronic stethoscope as described in item 8 of the patent application scope, wherein the processing module (15) is electrically connected to the respiratory stability sensor (12) in a wired manner through at least one signal line (151) , The abdominal breathing sensor (13), and the bowel sound sensor (14). The wearable electronic stethoscope as described in item 8 of the patent application scope, wherein the processing module (15) is electrically connected to the respiratory stability sensor (12) and the abdominal breathing by a wireless communication protocol A sensor (13), and the bowel sound sensor (14). The wearable electronic stethoscope as described in item 10 of the patent scope, wherein the wireless communication protocol is Bluetooth wireless communication module, WiFi wireless communication module, WiMAX wireless communication module, Zigbee wireless communication module, fourth generation Mobile communication technology or one of the fifth generation mobile communication technology wireless communication protocols. The wearable electronic stethoscope as described in item 1 or 10 of the patent application scope, wherein the transmission module (16) is connected to the processing module (15) through the wireless communication protocol. The wearable electronic stethoscope as described in item 1 or 10 of the patent application scope, wherein the transmission module (16) is connected to the server (2) through the wireless communication protocol. The wearable electronic stethoscope as described in item 1 of the patent application scope, wherein the server (2) is one of a remote server, a remote computer, a notebook computer, a tablet computer or a smartphone. The wearable electronic stethoscope as described in item 1 of the patent application scope, wherein the power supply module (17) is one of a power plug, a lithium battery or a rechargeable battery. The wearable electronic stethoscope as described in item 1 of the patent application scope, wherein the wearable electronic stethoscope (1) is further provided with a storage module electrically connected to the processing module (15), and the storage module stores the The breathing stability signal received by the processing module (15), the breathing signal or the intestinal sound signal is one or a combination of two or more of them.

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