CN206295352U - A kind of 12 lead cardiac electrophysiology monitoring and transmission equipment and its system - Google Patents

Abstract

The utility model discloses a kind of 12 lead cardiac electrophysiology monitoring and transmission equipment, including microprocessor, electrocardiosignal receiver, screen output circuit and wireless communication circuit；Microprocessor is connected by electrocardiosignal receiver with twelve-lead electrocardiogram electrode, the ecg information that receiving electrode sends；Screen output circuit, wireless communication circuit are connected with microprocessor, and ecg information is exported through screen output circuit and carries out network transmission through wireless communication circuit；Device housings are in wrist-watch shape structure, and it is respectively arranged at the two ends with a watchband connector.The utility model discloses a kind of 12 lead cardiac electrophysiology monitoring and Transmission system, including aforementioned device, twelve-lead electrocardiogram electrode and cloud platform；Aforementioned device is closely connected and is connected with cloud platform with electrode；Cloud platform is docked with emergency cardiac care center.Equipment described in the utility model is portable, easy to operate, complete into figure, and the utility model realizes network transmission, storage and the high in the clouds analysis of ecg information.

Description

Twelve-lead electrocardio physiological monitoring and transmission equipment and system thereof

Technical Field

The utility model belongs to the technical field of medical instrument device, concretely relates to twelve lead electrocardio physiology monitoring and transmission equipment and system thereof.

Background

At present, China enters an aging society, the number of old people is increased, cardiovascular diseases are life-threatening fatal diseases and also ubiquitous diseases of the old people, and therefore the incidence of the cardiovascular diseases is increased year by year. For the middle-aged and the elderly people who are relatively healthy, the middle-aged and the elderly people need to know the physiological states of the heart and the blood vessels at any time; for the elderly who suffer from heart diseases, the physiological state of the heart needs to be monitored at any time.

Electrocardiographic examination is a non-invasive examination and is also the primary examination item for heart diseases. Generally, a professional must be found in a hospital or a medical care center to perform an electrocardiographic examination. However, going to hospital for examination inevitably requires registration, queuing, and a lot of time and effort, which is extremely inconvenient for patients with mobility difficulties. In addition, patients with heart diseases such as sudden myocardial infarction often delay the condition and lose the chance of rescue without the first diagnosis of an electrocardiogram, resulting in death.

There are some portable electrocardiographs on the market today, which mainly include two forms: (1) one is the traditional 12-lead connected electrocardiograph, specifically including electrocardiograph, dynamic electrocardiograph, etc. used in hospitals, but the electrocardiograph detection device has the problems of high specialty and complex operation; (2) the other is a simplified version electrocardiograph with single lead or 3 leads, such as some household electrocardiographs and the like, which is characterized by simple operation and wide application, but because the leads are incomplete, the comprehensive electrocardio-physiological information of the patient can not be obtained, and for the patient suffering from sudden myocardial infarction, the myocardial infarction area can not be judged at the first time.

Moreover, the current medical electrocardiograph has no network transmission and network storage functions; while home-use electrocardiographs may support network transmission, they generally simplify leads (requiring expertise for ordinary 12-lead electrocardiography operations) and are not known as true electrocardiographs.

However, due to the particularity of acute onset, rapid change, high fatality rate and the like of heart diseases, a complete electrocardiogram is obtained at the first time at the medical base and even at home, and the method has very important significance for emergency treatment of heart diseases. Therefore, it is necessary to develop an electrophysiological monitoring device capable of solving the above-mentioned technical problems.

SUMMERY OF THE UTILITY MODEL

In order to overcome the technical defect, the utility model provides an electrocardio physiology monitoring and transmission equipment, it not only can acquire complete, the twelve lead heart electrograph of standard, convenient operation, easily carry moreover, and in addition, the electrocardio information that its monitoring obtained can be acquireed at the very first time anytime and anywhere.

In order to solve the above problem, the utility model discloses realize according to following technical scheme:

the utility model provides a twelve lead electrocardio physiology monitoring and transmission equipment, including equipment shell and power supply, its characterized in that:

the electrocardiosignal acquisition device also comprises a microprocessor, an electrocardiosignal receiver, a screen output circuit and a wireless network communication circuit;

the microprocessor is connected with the twelve-lead electrocardiogram electrodes through the electrocardiosignal receiver and receives electrocardio information sent by the twelve-lead electrocardiogram electrodes;

the screen output circuit and the wireless network communication circuit are respectively connected with the microprocessor; the electrocardio information is output through a screen output circuit and is subjected to network transmission through the wireless network communication circuit;

the equipment shell is of a watch-shaped structure, and two watchband connectors are arranged at two ends of the equipment shell respectively.

Furthermore, the system also comprises a GPS signal receiving circuit which is connected with the microprocessor.

Furthermore, the device also comprises an electrocardio early warning circuit which is connected with the microprocessor.

Furthermore, the liquid crystal display device also comprises a liquid crystal touch screen, and the liquid crystal touch screen is connected with the microprocessor through the screen output circuit.

Furthermore, the system also comprises a service request input circuit which is connected with the microprocessor.

The intelligent alarm device further comprises an alarm input circuit, a voice output circuit and a voice receiving circuit, wherein the alarm input circuit, the voice output circuit and the voice receiving circuit are respectively connected with the microprocessor.

Furthermore, the electrocardiosignal receiver comprises an electrocardiosignal receiving circuit and an electrocardiogram electrode interface which are mutually connected, and the microprocessor is in wired connection with the twelve-lead electrocardiogram electrode through the electrocardiogram electrode interface; or,

the electrocardiosignal receiver comprises a first Bluetooth communication circuit, and the microprocessor is in wireless connection with the twelve-lead electrocardiogram electrode through the first Bluetooth communication circuit.

Further, the wireless network communication circuit is a 4G network communication circuit, a WIFI network communication circuit or a second Bluetooth communication circuit.

In order to overcome the technical defect, the utility model also provides an electrocardio physiology monitoring and transmission system, it utilizes remote communication technology to realize electrocardio information's network transmission, networking storage and high in the clouds analysis based on the cloud platform to help heart emergency patients such as suspected myocardial infarction to obtain timely treatment, specifically realize through following scheme:

a twelve-lead electrocardio-physiological monitoring and transmission system is characterized in that:

the system comprises twelve-lead electrocardio-physiological monitoring and transmission equipment, twelve-lead electrocardiogram electrodes attached to a human body and a cloud platform;

the twelve-lead electrocardiogram physiological monitoring and transmission equipment is connected with the twelve-lead electrocardiogram electrodes in a short distance;

the twelve-lead electrocardio-physiological monitoring and transmitting equipment is connected with the cloud platform through the wireless network communication circuit;

the cloud platform is in butt joint with a heart first-aid center through the Internet.

Furthermore, the system also comprises a mobile terminal, and the twelve-lead electrocardio-physiological monitoring and transmitting equipment is connected with the mobile terminal through the wireless network communication circuit.

Compared with the prior art, the beneficial effects of the utility model are that:

the twelve-lead electrocardiogram physiological monitoring and transmission equipment of the utility model is connected with the twelve-lead electrocardiogram electrode, so that the microprocessor can acquire the twelve-lead electrocardiogram which is comprehensive and reaches the professional standard; moreover, the equipment is provided with a wireless network communication circuit, so that the electrocardiogram information can be acquired at the first time at any time and any place. In addition, the equipment shell based on this equipment is wrist-watch column structure, and is light and handy simple, can wear in wrist department or dress at the waist, when it is wireless connection with twelve lead heart electrograph electrode, can directly put in the pocket even, and this equipment easily carries, convenient operation promptly.

A twelve lead electrocardio physiology monitoring and transmission system, with twelve lead electrocardio physiology monitoring and transmission equipment (it is connected with twelve lead heart electrograph electrode), heart first aid center is connected with cloud platform. Therefore, the system can realize network transmission, networking storage and cloud analysis of the electrocardiogram information by utilizing a remote communication technology based on a cloud platform technology, and after the electrocardiogram is locally and preliminarily analyzed, the difficult electrocardiogram can obtain diagnosis and suggestions of a remote doctor at the first time, so that remote medical consultation is realized, namely, the dynamic electrocardiogram monitoring and data analysis are not limited by time and space any more. Moreover, for patients with emergencies such as suspected myocardial infarction and the like, the system can confirm the electrocardiogram through the cloud platform to preliminarily judge the infarcted area and then connect a heart emergency center in time, so that the patients can be treated at the first time.

Drawings

The following detailed description of embodiments of the invention is provided with reference to the accompanying drawings, in which:

FIG. 1 is a block diagram of the overall structure of a twelve-lead ECG physiological monitoring and transmitting device according to the present invention;

fig. 2 is a block diagram of an electrocardiographic signal receiver according to embodiment 1 of the present invention;

fig. 3 is a block diagram of another electrocardiographic signal receiver according to embodiment 2 of the present invention;

FIG. 4 is a front view of the twelve lead ECG physiological monitoring and transmitting device of the present invention;

FIG. 5 is a block diagram of the overall structure of the twelve-lead ECG physiological monitoring and transmitting system of the present invention;

fig. 6 is a schematic view of a working flow of the twelve-lead electrocardiographic physiological monitoring and transmission system of the present invention.

Description of the labeling:

1. twelve-lead electrocardiographic physiological monitoring and transmission equipment; 11. a power supply; 12. an equipment housing; 13. a microprocessor; 14. an electrocardiosignal receiver; 141. an electrocardiosignal receiving circuit; 142. an electrocardiogram electrode interface; 143. a first bluetooth communication circuit; 15. a data storage; 16. a screen output circuit; 17. a wireless network communication circuit; 18. a GPS signal receiving circuit; 19. an electrocardio early warning circuit; 110. a USB interface; 111. a liquid crystal touch screen; 112. a service request input circuit; 113. a first button; 114. a second button; 115. a third button; 116. an alarm input circuit; 117. a fourth button; 118. a voice output circuit; 119. a microphone port; 120. a voice receiving circuit; 121. a tin mouth; 122. a tape head; 2. twelve-lead electrocardiogram electrodes; 3. a cloud platform; 4. an internet; 5. a heart emergency center; 6. a mobile terminal.

Detailed Description

The preferred embodiments of the present invention will be described in conjunction with the accompanying drawings, and it will be understood that they are presented herein only to illustrate and explain the present invention, and not to limit the present invention.

Example 1

The embodiment discloses a twelve-lead electrocardiograph physiological monitoring and transmission device 1, which comprises a device shell 12, a power supply 11 (such as a lithium battery and the like), a microprocessor 13, an electrocardiograph signal receiver 14, a screen output circuit 16 and a wireless network communication circuit 17, as shown in fig. 1, 4 and 5.

The microprocessor 13 is connected with the external twelve-lead electrocardiogram electrodes through the electrocardiogram signal receiver 14, and receives and processes comprehensive electrocardiogram information sent by the twelve-lead electrocardiogram electrodes. More specifically, as shown in fig. 2 and 4, the electrocardiographic signal receiver 14 includes an electrocardiographic signal receiving circuit 141 and an electrocardiographic electrode interface 142 connected to each other, and the microprocessor 13 is connected to twelve-lead electrocardiographic electrodes outside the apparatus by wires via the electrocardiographic electrode interface 142.

The screen output circuit 16 and the wireless network communication circuit 17 are respectively connected with the microprocessor 13, the electrocardiographic information (usually in the form of an electrocardiograph) is output through the screen output circuit 16 for checking, and the electrocardiographic information is transmitted through the wireless network communication circuit 17 in a network manner.

As shown in FIGS. 1 and 4, the twelve-lead electrophysiological cardiac monitoring and transmitting device 1 further includes a data storage 15 and a USB interface 110. The data memory 15 is used for locally storing the electrocardiographic information monitored by the microprocessor 13; the USB interface 110 is connected to the power supply 11 and the data memory 15, and the device can be charged, the electrocardiographic data can be introduced into the device, or the electrocardiographic data can be extracted from the device through the USB interface 110.

In order to facilitate timely obtaining of the specific position of the twelve-lead electrophysiological monitoring and transmitting device 1 (i.e., the position of the user for electrocardiographic detection), as shown in fig. 1, the twelve-lead electrophysiological monitoring and transmitting device 1 further includes a GPS signal receiving circuit 18 connected to the microprocessor 13. Based on the design of the structure, the position of the user for electrocardio detection can be tracked and positioned, and when the user confirms that diagnosis and treatment are needed, the user can be quickly found.

As shown in fig. 1, the twelve-lead electrocardiographic physiological monitoring and transmitting device 1 further comprises an electrocardiographic early warning circuit 19, which is connected to the microprocessor 13 and used for electrocardiographic information tracking analysis and disease occurrence prediction. Cardiovascular diseases are mainly prevented, for healthy people, the twelve-lead electrocardio-physiological monitoring and transmitting equipment 1 can monitor, record and display normal electrocardiograms, and the twelve-lead electrocardio-physiological monitoring and transmitting equipment 1 is provided with an electrocardio early warning circuit 19 which can track the changes of the electrocardiograms, thereby realizing the prediction of the cardiovascular diseases; the electrocardiographic warning circuit 19 can provide more disease diagnosis information by comparing the electrocardiogram of each person with the electrocardiogram of the person at the time of onset. The electrocardiogram early warning circuit 19 can track the change condition of the electrocardiogram, and the advantage is more prominent for patients suffering from heart diseases.

More specifically, as shown in fig. 1 and 4, the twelve-lead electrocardiographic monitoring and transmitting device 1 further includes a liquid crystal touch screen 111, and the liquid crystal touch screen 111 is connected to the microprocessor 13 through a screen output circuit 16, so that not only the electrocardiographic information (usually, an electrocardiogram) monitored by the twelve-lead electrocardiographic monitoring and transmitting device 1 is displayed on the liquid crystal touch screen 111 for the user to view (i.e., a common display function), but also the user can perform a touch operation on the liquid crystal touch screen 111 to input various information parameters into the device, thereby greatly improving human-computer interaction experience. Of course, the liquid crystal touch panel 111 may be replaced with another general electronic display panel.

As shown in FIG. 1, the twelve lead electrophysiological cardiac monitoring and transmitting device 1 further includes a service request input circuit 112 coupled to the microprocessor 13. In this embodiment, the microprocessor 13 is loaded with an intelligent operating system (for example, a common Android system or an ios system is selected), and an application client capable of implementing the functions of electrocardiographic monitoring, electrocardiographic preliminary analysis, data communication, remote consultation, treatment guidance and the like is embedded in the intelligent operating system. More specifically, as shown in fig. 1, the twelve lead electrophysiological monitoring and transmitting device 1 further includes a first button 113, a second button 114, and a third button 115, which are connected to the microprocessor 13 via a service request input circuit 112, and are disposed on the device housing 12 (as shown in fig. 4). Wherein, pressing the first button 113 can select displaying the electrocardiogram in a full screen mode, the second button 114 is used for controlling the operation interface of the smart operating system to return to the main interface (similar to the home key of the mobile phone, the more detailed control technology of the second button 114 refers to the home key control technology of the mobile phone), and the third button 115 is used for setting the system parameters of the smart operating system (similar to the setting key of the mobile phone, the more detailed control technology of the second button 115 refers to the setting key control technology of the mobile phone). Based on the structural design, the twelve-lead electrocardio-physiological monitoring and transmitting equipment 1 can meet more and more actual requirements of users, and based on an intelligent operating system, the twelve-lead electrocardio-physiological monitoring and transmitting equipment 1 can continuously develop and optimize an electrocardio-data analysis mode, so that the twelve-lead electrocardio-physiological monitoring and transmitting equipment has better expansibility.

As shown in fig. 1 and 4, the twelve-lead electrocardiographic physiological monitoring and transmitting device 1 further comprises an alarm input circuit 116, a fourth button 117, a voice output circuit 118, a microphone port 119, a voice receiving circuit 120 and a receiver port 121, wherein the fourth button 117 is connected to the microprocessor 13 through the alarm input circuit 116, the microphone port 119 is connected to the microprocessor 13 through the voice output circuit 118, the receiver port 121 is connected to the microprocessor 13 through the voice receiving circuit 120, and the fourth button 117, the microphone port 119 and the receiver port 121 are all disposed on the device housing 12. The circuit structure of the voice output circuit 118 is similar to that of a microphone circuit of a current smart phone, so that the voice output circuit 118 can realize a voice sending function by matching with a microphone port 119, and the circuit structure of the voice receiving circuit 120 is similar to that of a receiver circuit of the current smart phone, so that the voice receiving circuit 120 can realize a voice receiving function by matching with a receiver port 121, namely, the device realizes a call function; the alarm input circuit 116 in cooperation with the fourth button 117 can implement a chest pain onset one-touch call function. Therefore, based on the aforementioned setting of the GPS signal receiving circuit 18, in case of emergency, the patient can press the fourth button 117 to call a nearby or specific heart emergency center, and simultaneously can make an instant call with the medical staff through the microphone port 119 and the earpiece port 121 to accurately guide the corresponding heart emergency center to send an ambulance to the location of the patient, or the patient to go to the heart emergency center, thereby greatly shortening the treatment time.

As shown in fig. 4, the device case 12 is a watch-like structure, and the size of the device case is substantially the same as that of a conventional watch, and the device case is very small, and two ends of the device case 12 are respectively provided with a band connector 122. The watchband connector 122 can be connected with a wrist watchband to wear the device on the wrist or a common belt to fasten the device on the waist, so that the device is very convenient to carry and convenient for electrocardiographic detection anytime and anywhere. It should be noted that, in the present invention, the shape of the device housing 12 includes but is not limited to the square structure shown in fig. 4, and it can also be set to other shapes, all belonging to the equivalent protection scope of the present invention.

In this embodiment, the wireless network communication circuit 17 is selected as a 4G network communication circuit (similar to a card insertion mode of a mobile phone), a WIFI network communication circuit, or a second bluetooth communication circuit, and can all implement wireless network transmission.

Of course, the twelve-lead electrocardiographic physiological monitoring and transmission device 1 can also connect partial leads according to the requirements, is used for dynamic monitoring and data analysis of the electrocardiogram and has great flexibility.

Example 2

The embodiment discloses another twelve-lead electrocardiographic physiological monitoring and transmission device 1, which is specifically different from the embodiment 1 in that:

the twelve-lead electrocardiogram electrode is provided with a bluetooth module (see another patent of the inventor of the present invention for specific technology, "an integrated lead electrocardiogram electrode strip"), in this embodiment, as shown in fig. 3 and 5, the electrocardiogram signal receiver 14 includes a first bluetooth communication circuit 143, and the microprocessor 13 performs wireless bluetooth connection with the twelve-lead electrocardiogram electrode 2 outside the device through the first bluetooth communication circuit 143, so that the device is not bound to move and is convenient to carry about, and can even be directly placed in a pocket.

The other structures and principles of the twelve-lead electrocardiographic physiological monitoring and transmission device 1 described in this embodiment are completely the same as those of embodiment 1, and are not described herein again.

As shown in fig. 5, the utility model discloses a twelve-lead electrocardiographic physiological monitoring and transmission system, which comprises the twelve-lead electrocardiographic physiological monitoring and transmission equipment 1, a twelve-lead electrocardiographic electrode 2 attached to a human body and a cloud platform 3.

Wherein, twelve lead electrocardio physiology monitoring and transmission equipment 1 and twelve lead heart electrograph electrode 2 are connected closely, and its connected mode has two kinds: (1) the wired connection as described in example 1, the length of the connecting lead wire is the lead wire length of a conventional electrocardiograph; (2) the wireless bluetooth connection (using the conventional bluetooth transmission technology) as described in embodiment 2, the distance between the twelve-lead ecg physiological monitoring and transmitting device 1 and the twelve-lead ecg electrode 2 is not greater than the conventional bluetooth maximum transmission distance.

The twelve-lead electrocardio-physiological monitoring and transmission equipment 1 is connected with the cloud platform 3 through the wireless network communication circuit 17, and the wireless network communication circuit 17 can select a 4G network communication circuit, a WIFI network communication circuit or a second Bluetooth communication circuit. In the twelve-lead electrocardio physiological monitoring and transmission system, the cloud platform 3 can be used as a background for electrocardio data analysis and storage by utilizing the powerful calculation and analysis function and the storage space, can also remotely display the electrocardiogram for the first time remote consultation of doctors, and can make instant communication between the doctors and patients in the process of remote consultation of the doctors, thereby greatly ensuring the diagnosis and treatment effect and greatly improving the diagnosis and treatment efficiency.

The cloud platform 3 is connected with a heart first-aid center 4 through the internet 5, and the heart first-aid center 4 can be the heart first-aid center closest to the patient or a specific heart first-aid center selected by the patient.

In addition, the system also comprises a mobile terminal 6, and the twelve-lead electrocardio-physiological monitoring and transmitting equipment 1 is connected with the mobile terminal 6 through a wireless network communication circuit 17. Similarly, the wireless network communication circuit 17 can select a 4G network communication circuit, a WIFI network communication circuit or a second bluetooth communication circuit, and the mobile terminal 6 can be a smart phone, a tablet computer and other handheld electronic devices, and can also be a smart television, a notebook computer and other devices, so that a user holding the mobile terminal 6 can complete interconnection with the microprocessor 13 through the wireless network communication circuit 17, and then perform real-time tracking and understanding on electrocardiographic data and information monitored by the microprocessor 13, if the mobile terminal 6 also has a call function, the mobile terminal can also perform instant call with the twelve-lead electrocardiographic physiological monitoring and transmission device 1, thereby greatly improving the convenience of monitoring, and avoiding the problem of limitation of regions.

The above is the description of the overall structure of the system for twelve-lead electrocardiographic physiological monitoring and transmission of the present invention, and a working process thereof is described in detail as shown in fig. 6:

(1) the twelve-lead electrocardiogram electrode 2 is attached to a human body to test heart rate and the like, and the electrocardiogram information obtained by the test is sent to the twelve-lead electrocardiogram physiological monitoring and transmission equipment 1 through an electrocardiogram signal receiver 14 (which can be connected by wire or wireless Bluetooth).

(2) In the twelve-lead electrocardio-physiological monitoring and transmitting device 1, local primary analysis and local storage of electrocardio information data and electrocardiogram display are carried out, and electrocardiogram change is tracked to carry out disease incidence prediction. In the process, the mobile terminal 6 can track and know the electrocardiogram information data of the microprocessor 13 in real time through the wireless network communication circuit 17 (when the mobile terminal 6 has a call function, an instant call can also be carried out). In addition, based on the GPS signal receiving circuit 18, when the patient encounters a special emergency such as chest pain, the patient can call the nearby or specific heart emergency center 4 by one key, and the patient can communicate with the heart emergency center 4 immediately, so as to accurately guide the heart emergency center 4 to send an ambulance to the position of the patient or the patient to go to the heart.

(3) The microprocessor 13 further uploads the electrocardiogram information data to the cloud platform 3 through the wireless network communication circuit 17 (which may be a 4G network communication circuit, a WIFI network communication circuit or a second bluetooth communication circuit), the cloud platform 3 performs cloud analysis on the received electrocardiogram information data to give a preliminary diagnosis and advice, the difficult electrocardiogram can be interpreted by a cloud platform doctor, or the cloud platform doctor activates a nearby or specific heart emergency center 4 based on the internet and the GPS signal receiving circuit 18 to confirm, and during this period, the patient can communicate with the doctor instantly. Meanwhile, the electrocardiogram information data is synchronously stored in the cloud platform 3, and electrocardiogram display can be performed.

(4) After further confirming the condition of an illness, if necessary (for example, confirming an emergency such as myocardial infarction), the patient is first treated by guiding an ambulance dispatched from a nearby or specific heart emergency center 4 to the location of the patient or the patient to the heart emergency center 4 by the GPS signal receiving circuit 18 and by communicating with a medical staff in real time.

To sum up, twelve lead electrocardio physiological monitoring and transmission equipment and system thereof, based on cloud intelligent platform technique, collect multiple functions in an organic whole such as electrocardio dynamic monitoring, high in the clouds data analysis, data network storage, long-range consultation, GPS location, conversation, become the picture and can reach professional standard, diagnostic information is more comprehensive, reliable, moreover, equipment easily carries, convenient operation has extremely strong specialty and practicality. Furthermore, the utility model discloses can also realize heart disease early warning function, and still be favorable to handling emergency such as the sudden myocardial infarction of patient more high-efficiently. In other words, the utility model discloses both can be used for electrocardio monitoring at ordinary times, also can obtain the heart electrograph of standard when necessary, provide the doctor in order to obtain professional judgement, it all can satisfy the actual demand at hospital and family terminal well, consequently, the utility model discloses have huge market value in medical instrument device technical field.

The twelve-lead electrocardio-physiological monitoring and transmission equipment and other parts of the system thereof are referred to the prior art.

The above description is only a preferred embodiment of the present invention, and is not intended to limit the present invention in any way, so that any modification, equivalent change and modification made by the technical spirit of the present invention to the above embodiments do not depart from the technical solution of the present invention, and still fall within the scope of the technical solution of the present invention.

Claims (10)

1. The utility model provides a twelve lead electrocardio physiology monitoring and transmission equipment, including equipment shell and power supply, its characterized in that:

the electrocardiosignal acquisition device also comprises a microprocessor, an electrocardiosignal receiver, a screen output circuit and a wireless network communication circuit;

the microprocessor is connected with the twelve-lead electrocardiogram electrodes through the electrocardiosignal receiver and receives electrocardio information sent by the twelve-lead electrocardiogram electrodes;

the screen output circuit and the wireless network communication circuit are respectively connected with the microprocessor; the electrocardio information is output through a screen output circuit and is subjected to network transmission through the wireless network communication circuit;

the equipment shell is of a watch-shaped structure, and two watchband connectors are arranged at two ends of the equipment shell respectively.

2. The twelve-lead electrophysiological monitoring and transmission device of claim 1, wherein: and the GPS signal receiving circuit is connected with the microprocessor.

3. The twelve-lead electrophysiological monitoring and transmission device of claim 1, wherein: the electrocardio early warning circuit is connected with the microprocessor.

4. The twelve-lead electrophysiological monitoring and transmission device of claim 1, wherein: the liquid crystal touch screen is connected with the microprocessor through the screen output circuit.

5. The twelve-lead electrophysiological monitoring and transmission device of claim 1, wherein: and the service request input circuit is connected with the microprocessor.

6. The twelve-lead electrophysiological monitoring and transmission device of claim 2, wherein: the alarm device also comprises an alarm input circuit, a voice output circuit and a voice receiving circuit, wherein the alarm input circuit, the voice output circuit and the voice receiving circuit are respectively connected with the microprocessor.

7. The twelve-lead electrophysiological cardiac monitoring and transmission device of any of claims 1 to 6, wherein: the electrocardiosignal receiver comprises an electrocardiosignal receiving circuit and an electrocardiogram electrode interface which are mutually connected, and the microprocessor is in wired connection with the twelve-lead electrocardiogram electrode through the electrocardiogram electrode interface; or,

the electrocardiosignal receiver comprises a first Bluetooth communication circuit, and the microprocessor is in wireless connection with the twelve-lead electrocardiogram electrode through the first Bluetooth communication circuit.

8. The twelve-lead electrophysiological cardiac monitoring and transmission device of any of claims 1 to 6, wherein: the wireless network communication circuit is a 4G network communication circuit, a WIFI network communication circuit or a second Bluetooth communication circuit.

9. A twelve-lead electrocardio-physiological monitoring and transmission system is characterized in that:

the device comprises the twelve-lead electrocardio-physiological monitoring and transmitting equipment as claimed in any one of claims 1 to 8, a twelve-lead electrocardiogram electrode attached to a human body and a cloud platform;

the twelve-lead electrocardiogram physiological monitoring and transmission equipment is connected with the twelve-lead electrocardiogram electrodes in a short distance;

the twelve-lead electrocardio-physiological monitoring and transmitting equipment is connected with the cloud platform through the wireless network communication circuit;

the cloud platform is in butt joint with a heart first-aid center through the Internet.

10. The twelve-lead electrophysiological monitoring and transmission system of claim 9, wherein: the device also comprises a mobile terminal, and the twelve-lead electrocardio-physiological monitoring and transmitting equipment is connected with the mobile terminal through the wireless network communication circuit.