CN116509403A

CN116509403A - Simple heart health monitor and application method thereof

Info

Publication number: CN116509403A
Application number: CN202210081110.XA
Authority: CN
Inventors: 葛均; 田玉昇; 黄禹豪
Original assignee: Poct Biotechnology Co ltd
Current assignee: Poct Biotechnology Co ltd
Priority date: 2022-01-24
Filing date: 2022-01-24
Publication date: 2023-08-01

Abstract

A simple and easy heart health monitor and its application method, comprising: a plurality of electrocardio detection points are arranged on the adhesive surface of a conductive patch, a hollowed first combination part and a second combination part with conductive contacts are arranged on the back surface of the conductive patch, a microcomputer circuit is arranged in a micro-host, one side of the micro-host is provided with a key switch, the other side of the micro-host is provided with a third combination part of an ultrasonic probe, and a fourth combination part with conductive contacts.

Description

Simple heart health monitor and application method thereof

Technical Field

The invention relates to the technical field of heart detection, in particular to a simple heart health monitor and an application method thereof.

Background

Continuous Doppler ultrasound (Doppler) is a specialized, non-invasive device for measuring cardiovascular parameters including blood flow rate, cardiac output, cardiac blood output, etc. The miniaturized, high sensitivity and low power consumption probe can monitor and collect cardiovascular data for a long time, thereby being beneficial to home care and long-distance instant monitoring. The intelligent mobile phone (or nursing station) can be connected, the change of tracking parameters can be recorded, the use occasions of the intelligent mobile phone can be expanded to the home care, and the remote instant monitoring can be performed by changing the use method of the intelligent mobile phone.

An Electrocardiogram (ECG) can record the current generated by the human heart during the beating and image the waveform, is the simplest and most widely used method for detecting the heart condition and the heart pathological changes, and generates a PQRST wave every time the heart beats, so that a doctor can observe the PQRST wave of the electrocardiogram by naked eyes to carry out professional medical judgment, and can effectively help the doctor to check and diagnose various heart diseases. Such as arrhythmia, ventricular hypertrophy, myocardial infarction or other heart conditions, and the like.

However, the traditional electrocardiogram must use special detection equipment in a hospital, so that a patient needs to go to the hospital to perform electrocardiogram measurement, and a great deal of time is spent in the hospital for queuing in the process; moreover, the operation is very tedious and troublesome when each electrocardiogram is detected, and each detection patch is manually attached to a detection part on the body of a detected person by special medical staff to continuously monitor the electrocardiograph. Although the volume of the current advanced dynamic electrocardiograph is smaller and can be carried with the user, the design of each part is still imperfect, and the electrocardiograph is still required to be connected with an electrocardiograph lead in application, so that a wearer feels uncomfortable and causes inconvenience in life, and the result is not provided with heart sound detection, so that more heart data cannot be obtained in practice to provide correct diagnosis for medical staff.

In recent years, health awareness is raised, medical quality requirements are increased, and aging phenomena are more remarkable, so that health care is an important subject. More and more portable small-sized sensing and detecting devices are manufactured and pushed out, so that people can know the heart state of the people without going to a hospital and wearing the sensing devices at home through a mobile phone or other display devices. Although there are many cardiac sensing products, the acquisition accuracy and the post-processing of the cardiac sensing products often have various defects such as signal interference, distortion, blurring and the like, so that the detection is not accurate enough, and the cardiac sensing products are still limited in self-health management and the assistance of doctor disease diagnosis and treatment.

Disclosure of Invention

Accordingly, the present invention provides a simple and easy-to-paste heart health monitor, which mainly comprises: a conductive patch and a micro-host; wherein the method comprises the steps of

One side of the conductive patch is an adhesive surface, and is covered with a piece of stripping paper, wherein the double-sided stripping paper is used as the best but not limited to the best practice, a plurality of electrocardiographic detection points are arranged on the adhesive surface, a hollowed first combination part and a second combination part with conductive contacts are arranged on the back surface of the conductive patch, and the conductive contacts are electrically connected with the electrocardiographic detection points;

the micro-host is internally provided with a microcomputer circuit with a self-contained charging power supply, one side of the micro-host is provided with a key switch, the other side of the micro-host is provided with a third combination part of an ultrasonic probe and a fourth combination part with a conductive contact, wherein the key switch, the ultrasonic probe and the conductive contact are electrically connected with the microcomputer circuit, the micro-host and the conductive patch are in separable mutual opposite groups, the fourth combination part is in electric connection with the second combination part in opposite groups, and the third combination part is in opposite groups with the first combination part which is hollowed out, so that the ultrasonic probe of the third combination part can be convexly embedded in the middle of the adhesive surface of the conductive patch for detecting and reading cardiac function signals in close-fitting use.

In a preferred embodiment, the conductive patch is a disposable patch, the first combination portion is a circular through hole, the third combination portion is a circular convex step, and a groove is formed around the periphery of the circular convex step to form a clamping fixation with the circular through hole of the first combination portion.

In a preferred embodiment, the second combination part is a double socket with opposite protrusions, and the double sockets are distributed on two sides of the circular perforation of the first combination part; the fourth combination part is double concave holes which are arranged in a pair, and the fourth combination part is distributed on two sides of the circular convex steps of the third combination part.

In a preferred embodiment, the micro-host further comprises an LED lamp on the switch button side.

In a preferred embodiment, the micro-host is further provided with a magnetically attracted charging contact, which is located between the third combination portion and the fourth combination portion.

In a preferred embodiment, the conductive patch is a bandage streamline sheet with waists.

In a preferred embodiment, a method for applying a simple patch heart health monitor includes:

constructing a simple attached heart health monitor attached to the chest of a living body to collect heart physiological detection signals, wirelessly transmitting the collected detection signals to a mobile computing device for computation, and displaying data of heart detection results; and a cloud network operation storage unit for the mobile operation device to transmit the data recording the heart detection result,

wherein this simple and easy subsides heart health monitor includes: the device comprises a conductive patch and a miniature host, wherein one side of the conductive patch is an adhesive surface, a piece of stripping paper is coated outside the adhesive surface, a plurality of electrocardiograph detection points are arranged on the adhesive surface, a hollowed first combination part and a second combination part with conductive contacts are arranged on the back surface of the conductive patch, and the conductive contacts are electrically connected and communicated with the electrocardiograph detection points; the micro-host is internally provided with a microcomputer circuit with a self-contained charging power supply, one side of the micro-host is provided with a switch key, the other side of the micro-host is provided with a third combination part of an ultrasonic probe and a fourth combination part with a conductive contact, wherein the switch key, the ultrasonic probe and the conductive contact are electrically connected with the microcomputer circuit, the micro-host and the conductive patch are in separable mutual opposite groups, the fourth combination part is in electric connection with the second combination part in opposite groups, and the third combination part is in opposite groups with the first combination part which is hollowed out, so that the ultrasonic probe of the third combination part can pass through the middle of the pasting surface of the conductive patch for close-fitting detection and reading of cardiac function signals, and the following method is implemented;

s110, pressing a probe of the micro host machine on the chest;

step S120, detecting whether the pulmonary artery blood vessel position is correct, if not, step S121, executing step S122, moving the probe position, if yes, executing step S123, combining and aligning and pasting the conductive patch and the micro-host, and starting measurement in step S124;

s130, detecting blood flow velocity;

s140, detecting a heart physiological signal;

s150, detecting the heart rate;

step S201, carrying out step S212 to save a file through wireless transmission and step S211, and carrying out step S212 to an action computing device through a wireless receiver; s345, performing biological calculation to obtain at least three waveforms; step S301, an electrocardiogram waveform, step S401, a heart sound waveform and step S501, a blood flow waveform;

step S302, further obtaining step S303, heart rate and heart rate variability according to the parameters of step S301 and step S302, which are obtained by the electrocardiogram waveform, and displaying the detection result;

the heart sound waveforms are further taken through step S402 according to the step S401, the step S403, the step 1 heart sound, the step 2 heart sound, the step 3 heart sound and the step 4 heart sound are obtained through recognition, and detection results are displayed;

the parameters of step S502 are further obtained according to the blood flow waveform of step S501 to obtain the pulse wave, the peak blood flow, the integral blood flow, the stroke volume and the heart output of step S503, and the detection result is displayed.

In a preferred embodiment, the method for applying the simple and easy-to-attach cardiac health monitor as described above, wherein the conductive patch is a disposable patch, the first combination portion is a circular through hole, the third combination portion is a circular convex step, a groove is formed around the periphery of the circular convex step to form a snap fit with the circular through hole of the first combination portion, and the second combination portion is a double socket with opposite protrusions and is distributed on two sides of the circular through hole of the first combination portion; the fourth combination part is double concave holes which are arranged in a pair, and the fourth combination part is distributed on two sides of the circular convex steps of the third combination part.

In a preferred embodiment, the method for applying the simple-to-heart health monitor as described above further comprises an application unit, a display unit, a control unit, and a network connection unit on the mobile computing device for receiving the physiological signals of the heart transmitted from the simple-to-heart health monitor, performing calculation processing, and displaying the detection result on the display unit.

In a preferred embodiment, the method for applying the simple-to-paste cardiac health monitor as described above, wherein the mobile computing device is further provided with a cardiac health detection APP application program, and the providing the display item includes: electrocardiogram waveform, heart sound waveform, blood flow waveform, heart rate, blood velocity peak, blood velocity time integral, single cardiac output, continuous cardiac output index, and heart rate variability, and providing a linear index map of the relative switching of the above display items.

The whole effective design utilizes the micro-host and the conductive patch to form a separable alignment group, the third combination part is aligned and combined with the first combination part, and the fourth combination part is aligned and combined with the second combination part, so that the micro-host and the conductive patch can be mutually and conveniently electrically connected, the operation is simple, the bonding strength can be effectively improved, and simultaneously, the ultrasonic probe of the third combination part can be effectively embedded in the middle of the adhesive surface of the conductive patch in a penetrating way, so that the heart function signals, such as electrocardio and cardiac output, can be detected and read in a simple and close-fitting way, but the heart function physiological indexes are not limited to the practical situation, so as to analyze each heart function physiological index and serve as the basis for the advanced inspection of heart focus.

Drawings

Fig. 1 is a diagram illustrating an application configuration of a simple paste heart health monitor according to the present invention.

Fig. 2 is an external view of the simple paste heart health monitor of the present invention.

Fig. 3 is an application diagram of the present invention.

FIG. 4 is a flow chart of an application method of the present invention.

FIG. 5 is a schematic diagram of a heart measurement data display item according to the present invention.

Symbol description:

simple and easy heart health monitor … 100

Conductive patch … 10

Adhesive surface … 11

Electrocardiographic probe … 110

Release paper … 111

First combined part … 12

Circular perforations … 121

Second combined part … 13

Double socket … 130

Conductive contact … 131

Micro-host … 20

Microcomputer circuit … 21

Charging power supply … 210

Push-button switch … 211

LED lamp … 212

Third combined part … 22

Ultrasonic probe … and 220

Round convex step … 221

Groove … 222

Fourth combined part … 23

Double concave holes … and 230

Conductive contact … 231

Charging contact … 24

Action computing device … 200

Application unit … and 201

Display unit … 202

Control unit … 203

Network connection unit … and 204

APP application … 205

Display item … 250

Cloud network computing storage unit … and 300

Step … s110.S120.S121.S122.S123.

Step … S124.S130.S140.S150

Step … S201S 211S 212

Step … S301.S302.S303.S345

Step … S401S 402S 403

Step … s501.S502.S503.

Detailed Description

For a convenient understanding of the invention, and the advantages achieved, reference should be made to the following detailed description of illustrative embodiments in conjunction with the accompanying drawings, in which: as shown in fig. 1 to 2, a simple-to-paste heart health monitor 100 according to the present invention includes: a conductive patch 10 and a micro-host 20; wherein the method comprises the steps of

One side of the conductive patch 10 is an adhesive surface 11, and a release paper 111 is coated on the adhesive surface 11, a plurality of electrocardiographic detection points 110 are provided on the adhesive surface 11, and a hollowed first combination part 12 and a second combination part 13 with conductive contacts 131 are provided on the back surface of the conductive patch 10, wherein the conductive contacts 131 are electrically connected with the electrocardiographic detection points 110, and;

the micro-host 20 is internally provided with a microcomputer circuit 21 with a self-contained charging power supply 210, one side of the micro-host 20 is provided with a key switch 211, the other side is provided with a third combination part 22 of an ultrasonic probe 220 and a fourth combination part 23 with a conductive contact 231, wherein the key switch 211, the ultrasonic probe 220 and the conductive contact 231 are electrically connected with the microcomputer circuit 21,

in a preferred embodiment, the micro-host 20 and the conductive patch 10 are detachably assembled to each other, the fourth assembly 23 is assembled to the second assembly 13 to form an electrical communication, and the third assembly 22 is assembled to the first assembly 12, so that the ultrasonic probe 220 of the third assembly 22 can penetrate through and fit between the adhesive surface 11 of the conductive patch 10 for detecting and reading cardiac function signals.

In a preferred embodiment, the conductive patch 10 is a disposable patch, such as a bandage streamline sheet with waists, the first combination portion 12 is a circular through hole 121, the third combination portion 22 is a circular convex step 221, and a groove 222 is formed around the periphery of the circular convex step to form a snap fit with the circular through hole 121 of the first combination portion 12.

In a preferred embodiment, the second combination portion 13 is a pair of sockets 130 with protrusions disposed opposite to each other, and disposed on two sides of the circular through hole 121 of the first combination portion 12; the fourth combination portion 23 is a pair of double concave holes 230, which are disposed on both sides of the circular convex step 221 of the third combination portion 22.

In a preferred embodiment, the micro-host 20 is further provided with an LED lamp 212 on the side of the switch button 211. And a magnetic charging contact 24 is further disposed between the third combination portion 22 and the fourth combination portion 23 of the micro-host 20, so as to dock with a charging seat (not shown) for charging.

The whole effective design utilizes the micro-host 20 and the conductive patch 10 to form a separable alignment group, the third combination part 22 is aligned and combined with the first combination part 12, the fourth combination part 23 is aligned and combined with the second combination part 13, so that the micro-host 20 and the conductive patch 10 can be mutually and conveniently electrically connected, the operation is simple, the bonding strength can be effectively improved, and meanwhile, the ultrasonic probe 220 of the third combination part 22 can pass through and be embedded in the middle of the adhesive surface 11 of the conductive patch 10 so as to be used for detecting and reading cardiac function signals in a simple and close-fitting manner.

In a preferred embodiment, as shown in fig. 1 to 4, a method for applying a simple-to-paste cardiac health monitor 100 of the present invention includes: constructing a simple attached heart health monitor 100 attached to the chest of a living body to collect detection signals of heart physiology, wirelessly transmitting the collected detection signals to a mobile computing device 200 for calculation processing, and displaying data of heart detection results; and a cloud computing storage unit 300 for the mobile computing device 200 to transmit data recording the heart detection result, wherein

The simple post-care cardiac health monitor 100 includes: a conductive patch 10 and a micro-host 20, one side of the conductive patch 10 is an adhesive surface 11, a release paper 111 is covered on the adhesive surface 11, a plurality of electrocardiograph detection points 110 are arranged on the adhesive surface 11, a hollowed first combination part 12 and a second combination part 13 with conductive contact points 131 are arranged on the back surface of the conductive patch 10, wherein the conductive contact points 131 are electrically connected with the electrocardiograph detection points 110, a micro-computer circuit 21 with a self-contained charging power supply 210 is arranged in the micro-host 20, a switch key 211 is arranged on one side of the micro-host 20, a third combination part 22 with an ultrasonic probe 220 is arranged on the other side, and a fourth combination part 23 with a conductive contact point 231 is arranged on the other side, wherein the switch key 211, the ultrasonic probe 220 and the conductive contact point 231 are electrically connected with the micro-computer circuit 21, the micro-host 20 and the conductive patch 10 are in a separable mutual opposite group, the fourth combination part 23 is electrically connected with the second combination part 13, and the third combination part 22 is connected with the hollowed first combination part 12, so that the third combination part 22 can be inserted into the middle of the ultrasonic probe 220 to read out the conductive patch 10, and the ultrasonic patch can read out from the middle surface of the heart, and the ultrasonic patch can read out;

step S110, pressing the probe (ultrasonic probe 220) of the micro host 20 on the chest;

step S120, detecting whether the pulmonary artery blood vessel position is correct, if not, step S121, executing step S122, moving the probe position if not, if so, executing step S123, combining and aligning and pasting the conductive patch 10 and the micro-host 20, and starting measurement in step S124;

s130, detecting blood flow velocity;

s140, detecting a heart physiological signal;

s150, detecting the heart rate;

step S201, carrying out step S212 on the mobile computing device 200 through wireless transmission and step S211, and storing the file; s345, performing biological calculation to obtain at least three waveforms; step S301, an electrocardiogram waveform, step S401, a heart sound waveform and step S501, a blood flow waveform;

wherein the heart sound waveform is further obtained by step S402 according to step S401 and the recognition to obtain step S403, 1 st heart sound, 2 nd heart sound, 3 rd heart sound and 4 th heart sound, and the detection result is displayed, and

the parameters are further obtained according to step S501 and step S502 of blood flow waveform acquisition to obtain step S503, pulse blood flow peak blood flow velocity integral stroke volume and cardiac output, and the detection result is displayed.

In a preferred embodiment, as shown in fig. 1 and 4, the mobile computing device 200 is further provided with an application unit 201, a display unit 202, a control unit 203, and a network connection unit 204, so as to receive the heart physiological signal transmitted from the simple-to-paste heart health monitor 100, perform calculation processing, and display the detection result on the display unit 202.

In a preferred embodiment, as shown in fig. 4 and 5, the mobile computing device 200 is further provided with a cardiac health detection APP application 205, and the providing a display item 250 includes: electrocardiogram waveforms, heart sound waveforms, blood flow waveforms, heart rate, blood velocity peaks, blood velocity time integral, single cardiac output, continuous cardiac output index, and heart rate variability, while providing a linear index map of the relative switching of the above display items 250.

Therefore, as shown in fig. 3 to 5, the invention has simple structure, simple combination and quite convenient operation, and can be applied to the health management of home self heart detection and the remote medical treatment. To collect heart functions of living subjects such as infants, humans, pets, and livestock, for a wider variety of applications, for example, the mobile computing device 200 of the present invention is provided with an APP application 205 for providing basic display items 250 based on the collected heart sounds, heart rate, and heart physiological signals detected by the simple-to-paste heart health monitor 100: electrocardiographic waveforms, heart sound waveforms, blood flow waveforms, heart rate, peak blood velocity, and time integral of blood velocity are used as references for the health care of the individual's general home self-healthy heart.

Even more detailed contents may include: the single cardiac output, continuous cardiac output index, heart rate variability, etc., and the above cardiac function detection contents and display items 250 are transferred to the cloud network computing storage unit 300 for filing management, so as to further provide remote medical unit use display on the terminal application device 400, so that the doctor can judge the cardiac state of the living body to be detected according to the detected and collected cardiac functions and the records of the display items 250, and use the living body as medical assistance.

In summary, the present invention is novel and practical and fully meets the requirements of the patent, and therefore, the invention is applied for patent application. The foregoing is merely illustrative of the preferred embodiments of the present invention and is not intended to limit the scope of the invention; therefore, all equivalent changes and modifications made in accordance with the contents of the claims and the written specification shall fall within the scope of the patent covered by the present invention.

Claims

1. A simple post-care cardiac health monitor comprising: a conductive patch and a micro-host; wherein the method comprises the steps of

One side of the conductive patch is an adhesive surface which is externally covered with a piece of stripping paper, a plurality of electrocardiograph detection points are arranged on the adhesive surface, a hollowed first combination part and a second combination part with conductive contacts are arranged on the back surface of the conductive patch, wherein the conductive contacts are electrically connected with the electrocardiograph detection points, and the first combination part and the second combination part are electrically connected with the electrocardiograph detection points;

the micro-host is internally provided with a microcomputer circuit with a self-contained charging power supply, one side of the micro-host is provided with a key switch, the other side of the micro-host is provided with a third combination part of an ultrasonic probe and a fourth combination part with a conductive contact, wherein the key switch, the ultrasonic probe and the conductive contact are electrically connected with the microcomputer circuit, the micro-host and the conductive patch are in separable mutual opposite groups, the fourth combination part is electrically connected with the second combination part in opposite groups, and the third combination part is opposite to the first combination part which is hollowed-out, so that the ultrasonic probe of the third combination part can pass through the middle of the adhesive surface of the conductive patch for close-fitting use detection and reading of cardiac function signals.

2. The simple and easy-to-attach cardiac health monitor of claim 1, wherein the conductive patch is a disposable patch, the first assembly portion is a circular through hole, the third assembly portion is a circular convex step, and a groove is formed around the periphery of the circular convex step to form a snap fit with the circular through hole of the first assembly portion.

3. The simple and easy heart health monitor according to claim 2, wherein the second combination part is a double socket with oppositely arranged protrusions, and is distributed on two sides of the circular perforation of the first combination part; the fourth combination part is double concave holes which are arranged in a pair, and the fourth combination part is distributed on two sides of the circular convex steps of the third combination part.

4. The simple and easy-to-paste heart health monitor of claim 2, wherein said micro-host further comprises an LED light on said switch button edge.

5. The simple and easy-to-paste heart health monitor of claim 2, wherein the micro-host further comprises a magnetically-attracted charging contact between the third combination portion and the fourth combination portion.

6. The simple and conformable cardiac health monitor of claim, wherein the conductive patch is a bandage streamline sheet with waists.

7. An application method of a simple and easy heart health monitor comprises the following steps:

constructing a simple attached heart health monitor attached to the chest of a living body to collect heart physiological detection signals, wirelessly transmitting the collected detection signals to a mobile computing device for computing, and displaying data of heart detection results; and a cloud network computing storage unit for the mobile computing device to transmit data recording the heart detection result,

wherein this simple and easy subsides heart health monitor includes: the device comprises a conductive patch and a micro host, wherein one side of the conductive patch is an adhesive surface, a stripping paper is covered on the adhesive surface, a plurality of electrocardiograph detection points are arranged on the adhesive surface, a hollowed first combination part and a second combination part with conductive contacts are arranged on the back surface of the conductive patch, the conductive contacts are electrically connected with the electrocardiograph detection points, a microcomputer circuit with a self-contained charging power supply is arranged in the micro host, a switch button is arranged on one side of the micro host, a third combination part of an ultrasonic probe and a fourth combination part with conductive contacts are arranged on the other side of the micro host, the switch button, the ultrasonic probe and the conductive contacts are electrically connected with the microcomputer circuit, the micro host and the conductive patch are in separable mutual opposite groups, the fourth combination part is electrically connected with the second combination part, and the third combination part is electrically connected with the hollowed first combination part, so that the ultrasonic probe of the third combination part can penetrate through the middle of the adhesive surface of the conductive patch for close fitting detection and reading of heart function signals, and the method is implemented;

s110, pressing a probe of the micro host machine on the chest;

s130, detecting blood flow velocity;

s140, detecting a heart physiological signal;

s150, detecting the heart rate;

step S201, carrying out step S212 to save a file through wireless transmission and step S211, and carrying out step S212 to an action computing device through a wireless receiver;

s345, performing biological calculation to obtain at least three waveforms; step S301, an electrocardiogram waveform, step S401, a heart sound waveform and step S501, a blood flow waveform;

8. The method of claim 7, wherein the conductive patch is a disposable patch, the first assembly portion is a circular hole, the third assembly portion is a circular convex step, a groove is formed around the periphery of the circular convex step to form a fastening connection with the circular hole of the first assembly portion, and the second assembly portion is a double socket with opposite protrusions and is distributed on two sides of the circular hole of the first assembly portion; the fourth combination part is double concave holes which are arranged in a pair, and the fourth combination part is distributed on two sides of the circular convex steps of the third combination part.

9. The method of claim 7, wherein the mobile computing device is further provided with an application unit, a display unit, a control unit, and a network connection unit for receiving the physiological signals of the heart from the simple-to-be-attached heart health monitor, performing the computing process, and displaying the detection result on the display unit.

10. The method of claim 7, wherein the mobile computing device further comprises a heart health monitoring APP application program, and providing the display item comprises: electrocardiogram waveform, heart sound waveform, blood flow waveform, heart rate, blood velocity peak, blood velocity time integral, single cardiac output, continuous cardiac output index, and heart rate variability, and providing a linear index map of the relative switching of the above display items.