CN210056013U - Wearable remote electrocardiogram monitoring device - Google Patents

Abstract

The utility model discloses a wearable remote electrocardiogram monitoring device, which comprises a coat main body, a plurality of groups of electrode induction sheets and an integrated electrocardiogram monitoring assembly, wherein the electrode induction sheets are distributed on the coat main body, and the integrated electrocardiogram monitoring assembly is arranged on the coat main body; the integrated electrocardio monitoring assembly comprises a plurality of acquisition circuits, a control chip, a wireless communication circuit and a power supply, wherein the lead wires of a plurality of groups of electrode induction sheets are divided into groups according to the distribution positions of electrocardio detection points and then are respectively connected to the acquisition circuits which are mutually parallel and independent, each acquisition circuit is connected to the control chip, the wireless communication circuit is connected to the control chip, and the power supply is connected to each part in the integrated electrocardio monitoring assembly. The utility model can be worn by patients at any time, and can ensure the accuracy and stability of the collected data, and provide the detection data with medical reference value; the remote electrocardio monitoring of the wearer is realized, and the real-time monitoring of the state of illness change of the wearer is ensured.

Description

Wearable remote electrocardiogram monitoring device

Technical Field

The utility model belongs to the technical field of the electrocardio monitoring device, especially, relate to a long-range electrocardio guardianship device of wearing formula.

Background

Cardiovascular disease is one of the leading causes of death and disability worldwide, with approximately 1670 million deaths annually due to cardiovascular disease worldwide. Coronary heart disease, i.e., heart disease caused by coronary atherosclerosis, heart disease caused by narrowing or blocking of the lumen of a blood vessel by lipid plaques on the inner wall of the blood vessel, or (and) myocardial ischemia, hypoxia or necrosis due to functional changes (spasm) of the coronary artery.

The cause of sudden clinical death in patients with cardiovascular diseases is mainly sudden acute events (sudden cardiac death, the etiology includes acute coronary syndrome, malignant arrhythmia, acute left heart failure, etc.), of which more than 70% occur outside the hospital, and 82% of sudden cardiac death occur at home and 15% occur in public places. Active and effective prevention and treatment measures are taken, so that the life can be effectively saved. Epidemiological data show that effective improvement of pre-hospitalization medical levels has the potential to reduce mortality from cardiovascular disease more than intensive treatment of hospitalized patients and that earlier treatment is more effective, and therefore, the time from initial symptoms to the determination of treatment must be shortened.

Self-monitoring and management of high risk populations has been demonstrated to improve disease prognosis. The method expands from in-hospital monitoring to out-of-hospital real-time monitoring, early diagnosis and timely treatment, can reduce the death rate and the rate of readmission, can improve the life quality of patients, reduces unnecessary medical expenses, and is an effective way for improving the prevention and treatment level of cardiovascular diseases. Statistics show that due to psychological or physiological stress, a significant proportion of patients have data measured in hospitals that differ significantly from data measured in environments where they are familiar, affecting the diagnosis of disease.

Most of the conventional electrocardio monitoring devices are heavy in size, and single-lead or three-lead electrocardio motors with low measurement speed are accelerated along with aging of population, so that the requirements of people on remote medical home care cannot be met. Although wearable electrocardiogram monitoring equipment exists in the current market, most of the wearable electrocardiogram monitoring equipment are wristbands, watches and the like capable of measuring heart rate, the principle and the accuracy of the wearable electrocardiogram monitoring equipment cannot meet the requirements of medical levels, and the wearable electrocardiogram monitoring equipment can only be used for tracking daily data and has no medical reference value.

SUMMERY OF THE UTILITY MODEL

In order to overcome the defects of the prior art, the utility model aims to provide a wearable remote electrocardiogram monitoring device which can be worn by a patient at any time conveniently, can ensure the accuracy and stability of the acquired data and provide medical staff with detection data with medical reference value; the remote electrocardio monitoring of a doctor or a guardian on the wearer can be realized, and the real-time monitoring of the state of illness of the wearer is ensured.

In order to achieve the above purpose, the utility model adopts the technical scheme that: a wearable remote electrocardiogram monitoring device comprises a coat main body, a plurality of groups of electrode induction sheets and an integrated electrocardiogram monitoring assembly, wherein the coat main body is provided with the electrode induction sheets according to the distribution of electrocardiogram detection points, the electrode induction sheets are connected to the integrated electrocardiogram monitoring assembly through lead wires, and the integrated electrocardiogram monitoring assembly is arranged on the coat main body;

the integrated electrocardio monitoring assembly comprises a plurality of acquisition circuits, a control chip, a wireless communication circuit and a power supply, wherein lead wires connected with a plurality of groups of electrode induction sheets are divided into groups according to the distribution positions of electrocardio detection points and then are respectively connected to the acquisition circuits which are mutually independent in parallel, each acquisition circuit is connected to the control chip, the control chip is connected with the wireless communication circuit, and the power supply is connected to each component in the integrated electrocardio monitoring assembly.

Further, an outer pocket is arranged on the outer side wall of the coat main body, and an integrated electrocardio monitoring component is placed in the outer pocket; the integrated electrocardio monitoring component is stably arranged on the coat main body, and the stable work of the integrated electrocardio monitoring component can be protected; the integrated electrocardio monitoring component can be flexibly placed or taken out of the outer pocket, and the jacket main body can be conveniently cleaned.

Furthermore, through holes are distributed on the coat main body in a grid-type manner, the electrode induction sheet is arranged on the inner side of the coat main body, and a lead wire of the electrode induction sheet passes through the through holes and is connected to the integrated electrocardio monitoring component; because the detection points of the human body are different, the electrode induction sheet is arranged at the corresponding through hole according to the detection point of the patient, and the lead wire of the electrode induction sheet passes through the through hole and is connected to the integrated electrocardio monitoring component; the fixed position of the electrode induction sheet can be adjusted according to the difference of the detection point positions of the patients, so that the electrode induction sheet is suitable for different patients, and the application range is wide; through the through holes distributed on the jacket main body in the net-shaped manner, the heat dissipation function can be realized, and the jacket is more comfortable to wear; the electrode induction sheet is convenient to mount and dismount, and can be used for conveniently cleaning the coat main body.

Furthermore, a fixing rubber ring is arranged at the joint of the electrode induction sheet and the lead wire, and the fixing rubber ring is clamped in the through hole, so that the electrode induction sheet is conveniently and stably fixed on the coat main body.

Furthermore, the coat main body is of an elastic body-tightening T-shirt structure, so that the electrodes distributed at each position on the coat main body can be stably attached to the human body detection position.

Further, the acquisition circuit is an ADS1293 electrocardio acquisition device and is communicated with the control chip in an SPI bus mode; the control chip is an STM32F103VET6 embedded control chip, and is used for receiving the acquisition signals of a plurality of groups of ADS1293 electrocardiosignal acquisition devices and transmitting the electrocardiosignals to a client terminal through a wireless network by processing.

Furthermore, the wireless communication circuit adopts a Bluetooth circuit or a 4G network circuit; the electrocardiograph monitoring device is in communication connection with a remote user terminal through a wireless communication circuit, so that the electrocardiograph state of a patient can be remotely monitored.

Furthermore, the power supply comprises a storage battery, a power supply converter and a power supply interface, the storage battery is connected to the power supply converter, the power supply converter is connected to the power supply interface, the power supply interface is connected to each component in the integrated electrocardio monitoring assembly, electric energy is provided for the operation of the integrated electrocardio monitoring assembly, the electrocardio monitoring assembly is convenient to carry about, and the electrocardio monitoring at any time is carried out.

Furthermore, the periphery of the integrated electrocardio monitoring component is wrapped with a closed shell, and a sealing ring is arranged at the lead wire on the shell and the lead wire of the power supply component.

The beneficial effects of the technical scheme are as follows:

the utility model can realize that the patient can wear the device at any time, and can collect the electrocardio detection information by laminating the electrocardio detection positions of the human body through a plurality of groups of electrodes, thereby ensuring the accuracy and stability of the collected data, and sending the detection information to the client terminal of the doctor or the guardian in real time through the remote communication of the wireless network; the monitoring equipment can be worn comfortably for a long time by a wearer; can realize the electrocardio detection of various types of leads.

The utility model discloses be connected to each acquisition circuit independent side by side each other respectively after dividing the line of leading that multiunit electrode response piece is connected according to electrocardio detection point position distribution position in groups, can overcome the anti-interference problem of data acquisition under the multi-lead, many use cases, guarantee that data acquisition's is reliable, accurate and stable, provide the detection data that have medical reference value for medical personnel.

The utility model transmits information with the client terminal of the medical staff through the remote wireless network, so that doctors can remotely diagnose patients, and strive for treatment time for the patients to reduce the danger caused by the contingency and the paroxysmal state of an illness; the remote monitoring can be carried out in the environment familiar to the patient, so that the psychological pressure of the patient is relieved, and the diagnosis accuracy is improved; the remote monitoring of sub-health people can discover early symptoms of diseases, thereby achieving the purposes of health care and disease prevention.

Drawings

Fig. 1 is a schematic structural view of a wearable remote electrocardiographic monitoring device according to the present invention;

fig. 2 is a schematic structural view of a middle integrated electrocardiogram monitoring assembly according to the present invention;

fig. 3 is a schematic structural view of the upper middle garment body of the present invention;

wherein, 1 is the jacket main part, 2 is the electrode response piece, 3 is integrated form electrocardio monitoring subassembly, 4 is the outer pocket, 5 is the through-hole.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention clearer, the present invention is further explained below with reference to the accompanying drawings.

In this embodiment, referring to fig. 1-2, a wearable remote electrocardiographic monitoring device includes a jacket main body 1, a plurality of sets of electrode sensing strips 2 and an integrated electrocardiographic monitoring assembly 3, wherein the electrode sensing strips 2 are distributed on the jacket main body 1 according to electrocardiographic detection points, the electrode sensing strips 2 are connected to the integrated electrocardiographic monitoring assembly 3 through lead wires, and the integrated electrocardiographic monitoring assembly 3 is arranged on the jacket main body 1;

the integrated electrocardio monitoring component 3 comprises a plurality of acquisition circuits, a control chip, a wireless communication circuit and a power supply, wherein lead wires connected with a plurality of groups of electrode induction sheets 2 are divided into groups according to the distribution positions of electrocardio detection points and then are respectively connected to the acquisition circuits which are mutually independent in parallel, each acquisition circuit is connected to the control chip, the wireless communication circuit is connected to the control chip, and the power supply is connected to each part in the integrated electrocardio monitoring component 3.

The specific embodiment is as follows: when 12-lead electrocardiogram monitoring is carried out, 3 ADS1293 are arranged; layering 12 lead wires into three groups, wherein each group of lead wires is accessed to an ADS 1293; three ADS1293 blocks are coded and operated by a control chip and a register is operated, so that 12-lead electrocardiosignals are acquired.

As an optimized solution of the above embodiment, as shown in fig. 3, an outer pocket 4 is provided on an outer side wall of the jacket main body 1, and an integrated electrocardiographic monitoring component 3 and a power supply component are placed in the outer pocket 4; the integrated electrocardio monitoring component 3 and the power supply component are stably arranged on the coat main body 1, so that the integrated electrocardio monitoring component 3 and the power supply component can be protected from working stably; the integrated electrocardio monitoring component 3 and the power supply component can be flexibly placed in or taken out of the outer bag 4, and the jacket main body 1 can be conveniently cleaned.

Through holes 5 are distributed on the coat main body 1 in a grid-type manner, the electrode induction sheet 2 is arranged on the inner side of the coat main body 1, and a lead wire of the electrode induction sheet 2 passes through the through holes 5 to be connected to the integrated electrocardio monitoring component 3; because the detection points of the human body are different, the electrode induction sheet 2 is arranged at the corresponding through hole 5 according to the detection point of the patient, and the lead wire of the electrode induction sheet 2 passes through the through hole 5 and is connected to the integrated electrocardio monitoring component 3; the fixing position of the electrode induction sheet 2 can be adjusted according to the difference of the detection point positions of the patients, so that the electrode induction sheet is suitable for different patients, and the application range is wide; through the through holes 5 distributed on the jacket main body 1 in a net-shaped manner, the heat dissipation function can be realized, and the jacket is more comfortable to wear; the electrode induction sheet 2 is convenient to mount and dismount, and can be used for conveniently cleaning the coat main body 1.

And a fixed rubber ring is arranged at the joint of the electrode induction sheet 2 and the lead wire, and is clamped in the through hole 5, so that the electrode induction sheet 2 is conveniently and stably fixed on the coat main body 1.

The coat main body 1 is of an elastic body-tightening T-shirt structure, and electrodes distributed on each position on the coat main body 1 can be stably attached to a human body detection position.

As an optimization scheme of the above embodiment, the acquisition circuit is an ADS1293 electrocardiograph acquisition device, and communicates with the control chip in an SPI bus manner; the control chip is an STM32F103VET6 embedded control chip, and is used for receiving the acquisition signals of a plurality of groups of ADS1293 electrocardiosignal acquisition devices and transmitting the electrocardiosignals to a client terminal through a wireless network by processing.

The wireless communication circuit adopts a Bluetooth circuit or a 4G network circuit; the electrocardiograph monitoring device is in communication connection with a remote user terminal through a wireless communication circuit, so that the electrocardiograph state of a patient can be remotely monitored.

The power supply comprises a storage battery, a power supply converter and a power supply interface, the storage battery is connected to the power supply converter, the power supply converter is connected to the power supply interface, the power supply interface is connected to each component in the integrated electrocardio monitoring assembly 3, electric energy is provided for the operation of the integrated electrocardio monitoring assembly 3, the portable electrocardio monitoring device is convenient to carry about, and the electrocardio monitoring is carried out at any time.

As an optimized scheme of the above embodiment, a closed shell is wrapped around the integrated electrocardiograph monitoring component 3, and a sealing ring is arranged at the lead-in line on the shell and the lead-in line of the power supply component.

For better understanding, the utility model discloses, following is to the theory of operation of the utility model make a complete description:

when the multifunctional upper garment is used, the position of the electrode induction sheet 2 on the upper garment main body 1 is adjusted according to the body type and the electrocardio detection position of a wearer, and the electrode induction sheet 2 is arranged on the upper garment main body 1 according to requirements;

after the wearer wears the electrocardiosignal acquisition device, the electrode induction sheet 2 acquires signals and transmits the acquired signals to the corresponding acquisition circuits, the control chip integrates the acquired signals of the acquisition circuits, and the electrocardio detection data is transmitted to a client of a doctor or a guardian in real time through a wireless network through a wireless communication circuit, so that the detection data with medical reference value is provided for medical staff, and the doctor can carry out remote diagnosis on patients.

The foregoing shows and describes the general principles, essential features, and advantages of the invention. It will be understood by those skilled in the art that the present invention is not limited to the above embodiments, and that the foregoing embodiments and descriptions are provided only to illustrate the principles of the present invention without departing from the spirit and scope of the present invention. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims (9)

1. A wearable remote electrocardiogram monitoring device is characterized by comprising a coat main body (1), a plurality of groups of electrode induction sheets (2) and an integrated electrocardiogram monitoring assembly (3), wherein the coat main body (1) is provided with the electrode induction sheets (2) according to the distribution of electrocardiogram detection points, the electrode induction sheets (2) are connected to the integrated electrocardiogram monitoring assembly (3) through lead wires, and the integrated electrocardiogram monitoring assembly (3) is arranged on the coat main body (1);

the integrated electrocardio monitoring assembly (3) comprises a plurality of acquisition circuits, a control chip, a wireless communication circuit and a power supply, lead wires connected with a plurality of groups of electrode induction sheets (2) are divided into groups according to the distribution positions of electrocardio detection points and then are respectively connected to the acquisition circuits which are mutually independent in parallel, each acquisition circuit is connected to the control chip, the control chip is connected with the wireless communication circuit, and the power supply is connected to each component in the integrated electrocardio monitoring assembly (3).

2. A wearable remote electrocardiographic monitoring device according to claim 1, wherein an outer pocket (4) is provided on the outer side wall of the jacket main body (1), and the integrated electrocardiographic monitoring component (3) is placed in the outer pocket (4).

3. The wearable remote electrocardiographic monitoring device according to claim 2, wherein through holes (5) are distributed on the coat main body (1) in a grid-like manner, the electrode sensing sheet (2) is arranged inside the coat main body (1), and lead wires of the electrode sensing sheet (2) are connected to the integrated electrocardiographic monitoring component (3) through the through holes (5).

4. The wearable remote electrocardiographic monitoring device according to claim 3, wherein a fixed rubber ring is arranged at the joint of the electrode sensing piece (2) and the lead wire, and the fixed rubber ring is clamped in the through hole (5).

5. The wearable remote ECG monitoring device according to claim 4, wherein the coat body (1) is of an elastic body-shaping T-shirt structure.

6. The wearable remote electrocardiac monitoring device according to claim 1, wherein said acquisition circuit is an ADS1293 electrocardiac acquisition device, communicating with the control chip in SPI bus mode; the control chip is an STM32F103VET6 embedded control chip.

7. The wearable remote electrocardiographic monitoring device according to claim 1, wherein the wireless communication circuit is a bluetooth circuit or a 4G network circuit.

8. A wearable remote electrocardiac monitoring device according to claim 1, wherein said power source comprises a storage battery, a power converter and a power interface, said storage battery is connected to said power converter, said power converter is connected to said power interface, said power interface is connected to each component of said integrated electrocardiac monitoring assembly (3).

9. The wearable remote electrocardiograph monitoring device according to claim 1, wherein a closed housing is wrapped around the integrated electrocardiograph monitoring component (3), and a sealing ring is disposed at the lead-in wire of the housing and the lead-in wire of the power supply component.

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