CN213665312U - Remove electrocardio workstation - Google Patents

Abstract

The utility model discloses a remove electrocardio workstation, include: the base is provided with an open concave cavity; the circuit board is arranged in the concave cavity and is provided with an electrocardio measuring circuit and a transmission circuit for transmitting data; the electrode plates are arranged in the concave cavity at intervals, the bottom ends of the electrode plates are exposed out of the bottom surface of the base, and the top ends of the electrode plates are connected with the circuit board; the rechargeable battery is arranged in the concave cavity and is connected with the circuit board; the charging pin is fixed in the concave cavity, the top end of the charging pin is connected with the rechargeable battery, and the bottom end of the charging pin penetrates through the bottom surface of the base and is exposed out of the base. The utility model discloses compact structure has solved the electrocardio monitor volume among the prior art great, the wire is more, leads to carrying and uses inconveniently, influences the technical problem of whole result of use.

Description

Remove electrocardio workstation

Technical Field

The utility model belongs to the electronic technology field especially relates to a remove electrocardio workstation.

Background

Cardiovascular and cerebrovascular diseases are a serious threat to human beings, and the incidence rate is high particularly in the middle-aged and the elderly. In the heart disease treatment process, an effective diagnosis basis is difficult to capture by one-time electrocardiogram, so that the dynamic detection of the electrocardiogram is required to assist the diagnosis and treatment of doctors in most cases.

Most of the existing electrocardio monitoring devices adopt an electrocardio monitor to monitor, when monitoring, the electrocardio monitor needs to be connected with a lead wire through an electrode plate, but the whole length of the lead wire is longer, a plurality of lead wires are needed to be connected, and the volume of the electrocardio monitor is larger, so that the whole volume of the electrocardio monitoring device is larger, the number of wires is larger, the carrying and the use are inconvenient, and the whole use effect is influenced.

Therefore, the above-mentioned techniques have at least the following technical problems: the electrocardio monitor in the prior art has the technical problems of large volume, more leads, inconvenient carrying and use and influence on the whole use effect.

SUMMERY OF THE UTILITY MODEL

The embodiment of the application solves the technical problems that the electrocardio monitor in the prior art is inconvenient to carry and use and affects the overall use effect due to larger volume and more leads by providing the mobile electrocardio workstation, the electrocardiosignal of a user is dynamically detected by arranging the electrode plate, and is transmitted to the circuit board, the circuit board is provided with an electrocardio measuring circuit which receives and processes the electrocardio signals to obtain corresponding electrocardiogram data, the memory circuit of the circuit board stores the electrocardiogram data, the transmission circuit of the circuit board transmits the electrocardiogram data to the mobile phone client for the user to look up the electrocardiogram data, the transmission circuit transmits the electrocardiogram data to the background server, so that medical personnel can look up the electrocardiogram data conveniently, and the technical effects of portability and convenient use are realized.

In order to solve the above problem, an embodiment of the present application provides a mobile electrocardiograph workstation, where the electrocardiograph workstation includes:

the base is provided with an open concave cavity;

the circuit board is arranged in the concave cavity, the circuit board is provided with an electrocardio measuring circuit and a transmission circuit for transmitting data, and the electrocardio measuring circuit is connected with the transmission circuit;

the electrode plates are arranged in the concave cavity at intervals, the bottom ends of the electrode plates are exposed out of the bottom surface of the base, and the top ends of the electrode plates are connected with the circuit board;

the rechargeable battery is arranged in the concave cavity and is connected with the circuit board so as to supply power to the circuit board;

the charging pin is fixed in the concave cavity, the top end of the charging pin is connected with the rechargeable battery, and the bottom end of the charging pin penetrates through the bottom surface of the base and is exposed out of the base.

Furthermore, the circuit board is also provided with a storage circuit for storing the electrocardiogram data, and the storage circuit is connected with the electrocardiogram measuring circuit.

Furthermore, the electrocardio workstation also comprises an upper cover used for sealing the concave cavity, and the upper cover is fixed on the base; the upper cover is transparent, and the upper surface of the upper cover is in an upward convex arc shape;

the base is a soft base, and the base and the upper cover are bonded and fixed.

Furthermore, one side of the circuit board is provided with a notch through which the rechargeable battery can vertically penetrate, and the rechargeable battery is fixedly clamped in the notch;

the cavity is internally provided with a plurality of lugs for upwards supporting the rechargeable battery at intervals, the rechargeable battery is laid on the lugs, and the upper cover compresses the rechargeable battery on the lugs.

Furthermore, the electrocardio workstation also comprises a light homogenizing sheet, the light homogenizing sheet is positioned between the upper cover and the rechargeable battery, and the light homogenizing sheet is fixed on the upper surface of the rechargeable battery.

Furthermore, the electrocardio workstation comprises two electrode plates, the charging pin is arranged between the two electrode plates, and the two electrode plates are symmetrically arranged relative to the charging pin.

Furthermore, a plurality of bearing columns for upwards bearing the circuit board are arranged on the inner wall surface of the cavity at intervals, a bayonet used for positioning the edge of the circuit board is arranged on one side of each bearing column, the opening of each bayonet faces the center of the cavity, and the circuit board is fixed on the base through screws.

Furthermore, a plurality of through holes for installing the electrode plates are formed in the cavity bottom of the concave cavity, fixing rings are coaxially arranged on the through holes, the top surfaces of the electrode plates are erected and fixed on the fixing rings, and the bottom surfaces of the electrode plates sequentially penetrate through the fixing rings and the through holes downwards and are exposed out of the base.

Furthermore, the electrocardio workstation further comprises a switch button, the switch button is connected in series with a series circuit formed by the charging power supply and the circuit board, a window which is right opposite to the switch button is arranged on one side of the base, and the switch button is exposed out of the window so as to be convenient for finger digging operation;

the window still be furnished with sealed waterproof button shell with, the internal surface of waterproof button shell on be equipped with the round snap ring, the window outward flange on be equipped with snap ring matched with draw-in groove, waterproof button shell with the window buckle cooperation.

Furthermore, a center hole is formed in the middle of the electrode plate, a metal elastic sheet is connected in the center hole, the top end of the metal elastic sheet extends upwards and is fixedly welded with the circuit board, and the electrode plate is connected with the circuit board through the metal elastic sheet.

One or more technical solutions provided in the embodiments of the present application have at least the following technical effects or advantages:

1. this application embodiment is through setting up electrode slice dynamic detection user's electrocardiosignal, and will electrocardiosignal carry and give the circuit board, the circuit board have electrocardio measuring circuit, electrocardio measuring circuit receive and handle electrocardiosignal obtain corresponding electrocardiogram data, the storage circuit storage of circuit board electrocardiogram data, the transmission circuit of circuit board will electrocardiogram data transmission give mobile client, supply the user to look up electrocardiogram data, transmission circuit will electrocardiogram data transmission give backstage server, the medical personnel of being convenient for look up. The electrocardio workstation structure small and exquisite and compact, and do not have external power cord and signal line, carry and use very conveniently, solved the electrocardio monitor volume among the prior art great, the wire is more, lead to carrying and use inconvenient, influence the technical problem of whole result of use, realized carrying portablely and convenient to use's technological effect.

2. The electrocardiogram workstation can continuously acquire and record electrocardiogram data for 24 hours, and can transmit the electrocardiogram data to a cloud (background server) for medical staff to check, so that the technical problems that the electrocardiogram monitoring equipment in the prior art cannot move and the medical staff cannot synchronously monitor are solved, the electrocardiogram monitoring is stable and reliable, the technical effect of meeting the requirement of a patient needing the medical staff to monitor remotely in time at home is achieved, and the technical problem that the electrocardiogram detector in the prior art cannot monitor the medical staff remotely is solved.

3. This application embodiment one side of circuit board is equipped with and supplies rechargeable battery breach that runs through from top to bottom, the circuit board with rechargeable battery fully combine, required installation space is littleer, makes electrocardio workstation's overall structure compacter, small and exquisite, portable.

4. The light homogenizing sheet can play a role in homogenizing light, so that the light of the working state indicating lamp is softer.

5. The base be the preparation of plastic material, the base need be close to the human body, the software material can improve and use the travelling comfort.

6. The edge of circuit board establish through the card the bayonet socket in obtain the location, rethread a plurality of the fix with screw the base on, the location is accurate, firm in connection.

7. The waterproof key shell can seal the window to prevent the cavity from water inflow, so that the service life of the electrocardio workstation is prolonged.

8. According to the embodiment of the application, the electrode plate is connected with the circuit board through the metal elastic sheet, so that the electrode plate is firmly connected, electrocardiosignal transmission obtained by electrode plate monitoring is stable, and the electrocardio workstation is reliable in monitoring.

Drawings

FIG. 1 is an exploded view of a mobile ECG workstation according to an embodiment of the present application;

fig. 2 is a schematic structural diagram of a base of a mobile electrocardiograph workstation according to an embodiment of the present application.

Description of reference numerals: the waterproof button comprises a base 100, a bump 110, a bearing column 120, a bayonet 121, a fixing ring 130, a window 140, a waterproof button shell 150, a circuit board 200, a switch button 210, an electrode plate 300, a rechargeable battery 400, a charging pin 500, an upper cover 600, a light equalizing sheet 700 and a metal elastic sheet 800.

Detailed Description

The embodiment of the application provides a remove electrocardio workstation, has solved the electrocardio monitor volume among the prior art great, the wire is more, leads to carrying and use inconvenient, influences the technical problem of whole result of use.

In order to solve the technical problems, the general idea of the embodiment of the application is as follows:

the electrode plate is arranged to dynamically detect electrocardiosignals of a user and convey the electrocardiosignals to the circuit board, the circuit board is provided with an electrocardio measuring circuit, the electrocardio measuring circuit receives and processes the electrocardiosignals to obtain corresponding electrocardiogram data, the storage circuit of the circuit board stores the electrocardiogram data, the transmission circuit of the circuit board transmits the electrocardiogram data to the mobile phone client for the user to look up the electrocardiogram data, and the transmission circuit transmits the electrocardiogram data to the background server for the medical care personnel to look up. The electrocardio workstation structure small and exquisite and compact, and do not have external power cord and signal line, carry and use very conveniently, solved the electrocardio monitor volume among the prior art great, the wire is more, lead to carrying and use inconvenient, influence the technical problem of whole result of use, realized carrying portablely and convenient to use's technological effect.

In order to better understand the technical solution, the technical solution will be described in detail with reference to the drawings and the specific embodiments.

Fig. 1 is an exploded view of a mobile ecg workstation according to an embodiment of the present application, and as shown in fig. 1, the mobile ecg workstation includes a base 100, a circuit board 200, electrode pads 300, a rechargeable battery 400, and a charging pin 500.

An open cavity is provided on the base 100. The circuit board 200 is disposed in the cavity, and the circuit board 200 has an electrocardiographic measurement circuit. The plurality of electrode plates 300 are arranged in the concave cavity at intervals, the bottom ends of the electrode plates 300 are exposed out of the bottom surface of the base 100, and the top ends of the electrode plates 300 are connected with the circuit board 200.

Specifically, the electrocardiograph workstation is worn on the body, for example, a matched electrocardiograph garment is configured, the electrocardiograph workstation is fixed on the electrocardiograph garment, the user wears the electrocardiograph garment, the electrode plate 300 dynamically detects electrocardiograph signals of the user and transmits the electrocardiograph signals to the circuit board 200, the circuit board 200 is provided with an electrocardiograph measuring circuit, and the electrocardiograph measuring circuit receives and processes the electrocardiograph signals to obtain corresponding electrocardiograph data.

The mobile ECG workstation further comprises a mobile phone client and a background server, the circuit board 200 is provided with a transmission circuit which can be in signal connection (for example, connected through Bluetooth or a wireless network) with both the mobile phone client and the background server, and the transmission circuit transmits the ECG data to the mobile phone client for a user to look up the ECG data; the transmission circuit transmits the electrocardiogram data to the background server for establishing a health management file of a user, so that medical personnel can conveniently look up the health management file, and later diagnosis and treatment are facilitated.

Further, the circuit board 200 further has a storage circuit for storing the electrocardiogram data.

The rechargeable battery 400 is disposed in the cavity, and the rechargeable battery 400 is connected to the circuit board 200 to supply power to the circuit board 200. The charging pin 500 is fixed in the cavity, the top end of the charging pin 500 is connected to the rechargeable battery 400, and the bottom end of the charging pin 500 penetrates through the bottom surface of the base 100 and is exposed out of the base 100.

Specifically, the electrocardio workstation be furnished with the charging seat, when needs charge, will the electrocardio workstation put into the charging seat in, the charging seat link to each other with mains power supply, just the charging seat in be equipped with the module of charging, the module of charging be equipped with can with the charge post that needle 500 aligns and switch on that charges, the electric current warp the module of charging the post charge needle 500 carry give rechargeable battery 400, thereby give the electrocardio workstation charge, it is very convenient to charge, and need not the lug connection power cord during the use, and is very convenient.

To sum up, this application embodiment through setting up electrode slice 300 dynamic verification user's electrocardiosignal, and with electrocardiosignal carry give circuit board 200, circuit board 200 electrocardio measuring circuit have, electrocardio measuring circuit receive and handle electrocardiosignal obtain corresponding electrocardiogram data, circuit board 200's storage circuit storage electrocardiogram data, circuit board 200's transmission circuit will electrocardiogram data transmit for mobile client, supply the user to look up electrocardiogram data, transmission circuit will electrocardiogram data transmit for backstage server, the medical personnel of being convenient for look up. The electrocardio workstation structure small and exquisite and compact, and do not have external power cord and signal line, carry and use very conveniently, solved the electrocardio monitor volume among the prior art great, the wire is more, lead to carrying and use inconvenient, influence the technical problem of whole result of use, realized carrying portablely and convenient to use's technological effect.

In addition, the electrocardiogram workstation described in the embodiment of the present application can continuously acquire and record electrocardiogram data for 24 hours, and can transmit the electrocardiogram data to the cloud (background server) for medical staff to check, thereby solving the technical problems that the electrocardiogram monitoring equipment in the prior art cannot move and cannot acquire synchronous monitoring of the medical staff, realizing stable and reliable electrocardiogram monitoring, meeting the technical effects of the requirement of the patient who needs to be monitored by the medical staff at home in time and remotely, and solving the technical problem that the electrocardiogram detector in the prior art cannot acquire remote monitoring of the medical staff.

In an embodiment of the present application, as shown in fig. 1, the electrocardiograph workstation further includes an upper cover 600 for sealing the cavity, and the upper cover 600 is fixed on the base 100; the upper cover 600 is transparent, and the upper surface of the upper cover 600 is in an upward convex arc shape.

Specifically, the upper cover 600 is fixed to the base 100 by bonding, the upper cover 600 is a glass upper cover, the circuit board 200 can be provided with a working state indicator light, when the electrocardiograph workstation works, the working state indicator light is turned on, and a user can identify a working state and a non-working state through the upper cover 600. In addition, the upper surface of the upper cover 600 is in an upward convex arc shape, and the shape is elegant and unique.

In an embodiment of the present application, as shown in fig. 1 and 2, a notch is formed on one side of the circuit board 200 for the rechargeable battery 400 to pass through, and the rechargeable battery 400 is fixedly clamped in the notch; a plurality of lugs 110 for upwards supporting the rechargeable battery 400 are arranged in the cavity at intervals, the rechargeable battery 400 is laid on the lugs 110, and the rechargeable battery 400 is pressed on the lugs 110 by the upper cover 600.

Specifically, one side of the circuit board 200 is provided with a notch for the rechargeable battery 400 to run through up and down, the circuit board 200 is fully combined with the rechargeable battery 400, and the required installation space is smaller, so that the whole structure of the electrocardio workstation is more compact and small, and is convenient to carry.

In an embodiment of the present application, as shown in fig. 1, the electrocardiograph workstation further includes a light homogenizing sheet 700, the light homogenizing sheet 700 is located between the upper cover 600 and the rechargeable battery 400, and the light homogenizing sheet 700 is fixed on the upper surface of the rechargeable battery 400.

Specifically, the light-homogenizing sheet 700 is bonded and fixed on the upper surface of the rechargeable battery 400, and the light-homogenizing sheet 700 can play a role in homogenizing light, so that the light of the working state indicator lamp is softer.

In an embodiment of the present application, as shown in fig. 1, the electrocardiograph workstation includes two electrode pads 300, the charging pin 500 is disposed between the two electrode pads 300, and the two electrode pads 300 are symmetrically disposed with respect to the charging pin 500.

In one embodiment of the present application, as shown in fig. 1 and 2, the base 100 is a soft base, and the base 100 is adhered to the upper cover 600. Specifically, the base 100 is made of plastic materials, the base 100 needs to be close to a human body, and the soft materials can improve the use comfort.

In an embodiment of the present application, as shown in fig. 1 and 2, a plurality of supporting columns 120 for supporting the circuit board 200 upward are arranged on an inner wall surface of the cavity at intervals, a bayonet 121 for positioning an edge of the circuit board 200 is arranged on one side of the supporting columns 120, and an opening of the bayonet 121 faces a center of the cavity; the circuit board 200 is fixed to the base 100 by screws.

Specifically, the edge of the circuit board 200 is positioned in the bayonet 121 by being clamped, and then fixed to the base 100 by a plurality of screws, so that the positioning is accurate and the connection is firm. The circuit board 200 and the inner wall surface of the concave cavity are provided with threaded holes for the screw thread connection.

In an embodiment of the present application, as shown in fig. 1 and 2, a plurality of through holes for installing the electrode plate 300 are disposed at the bottom of the cavity, the through holes are coaxially provided with the fixing rings 130, the top surface of the electrode plate 300 is erected and fixed on the fixing rings 130, and the bottom surface of the electrode plate 300 sequentially penetrates through the fixing rings 130 and the through holes downward and is exposed out of the base 100. Specifically, the fixing ring 130 and the base 100 are integrally formed.

In an embodiment of the present application, as shown in fig. 1 and 2, the electrocardiograph workstation further includes a switch button 210, the switch button 210 is connected in series to a series circuit formed by the charging power supply 400 and the circuit board 200, a window 140 facing the switch button is disposed on one side of the base 100, and the switch button 210 is exposed out of the window 140 so as to facilitate the finger digging operation; the window 140 is further provided with a waterproof key shell 150 for sealing, a circle of snap ring is arranged on the inner surface of the waterproof key shell 150, a clamping groove matched with the snap ring is arranged on the outer edge of the window 140, and the waterproof key shell 150 is in snap fit with the window 140.

Specifically, the waterproof key case 150 can seal the window 140 to prevent the water from entering the cavity, thereby prolonging the service life of the electrocardiograph workstation. When the switch button 210 needs to be used, the waterproof key case 150 can be removed to operate, and after the use is finished, the waterproof key case 150 is covered on the window 140.

In an embodiment of the present application, as shown in fig. 1, a central hole is formed in the middle of the electrode plate 300, a metal elastic sheet 800 is connected in the central hole, the top end of the metal elastic sheet 800 extends upward and is welded and fixed to the circuit board 200, the electrode plate 300 is connected to the circuit board 200 through the metal elastic sheet 800, and the connection is firm, so that the electrocardiosignal obtained by monitoring the electrode plate 300 is stably transmitted, and the monitoring of the electrocardio workstation is reliable.

One or more technical solutions provided in the embodiments of the present application have at least the following technical effects or advantages:

1. this application embodiment is through setting up electrode slice 300 dynamic verification user's electrocardiosignal, and will electrocardiosignal carry and give circuit board 200, circuit board 200 electrocardio measuring circuit have, electrocardio measuring circuit receive and handle electrocardiosignal obtain corresponding electrocardiogram data, circuit board 200's storage circuit storage electrocardiogram data, circuit board 200's transmission circuit will electrocardiogram data transmit for mobile client, supply the user to look up electrocardiogram data, transmission circuit will electrocardiogram data transmit for backstage server, the medical personnel of being convenient for look up. The electrocardio workstation structure small and exquisite and compact, and do not have external power cord and signal line, carry and use very conveniently, solved the electrocardio monitor volume among the prior art great, the wire is more, lead to carrying and use inconvenient, influence the technical problem of whole result of use, realized carrying portablely and convenient to use's technological effect.

2. The electrocardiogram workstation can continuously acquire and record electrocardiogram data for 24 hours, and can transmit the electrocardiogram data to a cloud (background server) for medical staff to check, so that the technical problems that the electrocardiogram monitoring equipment in the prior art cannot move and the medical staff cannot synchronously monitor are solved, the electrocardiogram monitoring is stable and reliable, the technical effect of meeting the requirement of a patient needing the medical staff to monitor remotely in time at home is achieved, and the technical problem that the electrocardiogram detector in the prior art cannot monitor the medical staff remotely is solved.

3. This application embodiment one side of circuit board 200 is equipped with and supplies rechargeable battery 400 breach that runs through from top to bottom, circuit board 200 with rechargeable battery 400 fully combine, required installation space is littleer, makes electrocardio workstation's overall structure compacter, small and exquisite, portable.

4. The light homogenizing sheet 700 can play a role in homogenizing light, so that the light of the working state indicating lamp is softer.

5. The base 100 of this application embodiment be the preparation of plastic material, base 100 need be close to the human body, the software material can improve and use the travelling comfort.

6. The edge of the circuit board 200 is arranged in the bayonet 121 through the card, and then the positioning is achieved, the screw is fixed on the base 100, the positioning is accurate, and the connection is firm.

7. The waterproof key shell 150 in the embodiment of the application can seal the window 140, so that the cavity is prevented from water entering, and the service life of the electrocardio workstation is prolonged.

8. The electrode plate 300 is connected with the circuit board 200 through the metal elastic sheet 800, and the electrode plate is firmly connected, so that electrocardiosignals obtained by monitoring the electrode plate 300 are stably transmitted, and the electrocardio workstation is reliable in monitoring.

It will be understood that, although the terms first, second, etc. may be used herein to describe various elements, these elements should not be limited by these terms. These terms are only used to distinguish one element from another. For example, a first element may be termed a second element, and, similarly, a second element may be termed a first element, without departing from the scope of example embodiments.

The terms of orientation of up, down, left, right, front, back, top, bottom, and the like referred to or may be referred to in this specification are defined relative to the configuration shown in the drawings, and are relative terms, and thus may be changed correspondingly according to the position and the use state of the device. Therefore, these and other directional terms should not be construed as limiting terms.

While the foregoing is directed to the preferred embodiment of the present application, and not to the limiting thereof in any way and any way, it will be understood by those skilled in the art that various changes and modifications may be made without departing from the spirit and scope of the invention as defined by the appended claims. Those skilled in the art can make various changes, modifications and equivalent arrangements to those skilled in the art without departing from the spirit and scope of the present application; moreover, any equivalent alterations, modifications and variations of the above-described embodiments according to the spirit and techniques of this application are intended to be within the scope of the claims of this application.

Claims (10)

1. A mobile ecg workstation, comprising:

the base is provided with an open concave cavity;

the circuit board is arranged in the concave cavity, the circuit board is provided with an electrocardio measuring circuit and a transmission circuit for transmitting data, and the electrocardio measuring circuit is connected with the transmission circuit;

the electrode plates are arranged in the concave cavity at intervals, the bottom ends of the electrode plates are exposed out of the bottom surface of the base, and the top ends of the electrode plates are connected with the circuit board;

the rechargeable battery is arranged in the concave cavity and is connected with the circuit board so as to supply power to the circuit board;

the charging pin is fixed in the concave cavity, the top end of the charging pin is connected with the rechargeable battery, and the bottom end of the charging pin penetrates through the bottom surface of the base and is exposed out of the base.

2. The mobile electrocardiographic workstation of claim 1 wherein said circuit board further comprises a memory circuit for storing electrocardiographic data, said memory circuit being connected to said electrocardiographic measurement circuit.

3. The mobile electrocardiograph workstation of claim 1 further comprising an upper cover for sealing said cavity, said upper cover being secured to said base; the upper cover is transparent, and the upper surface of the upper cover is in an upward convex arc shape;

the base is a soft base, and the base and the upper cover are bonded and fixed.

4. The mobile ECG workstation of claim 3, wherein a notch is formed on one side of the circuit board for the rechargeable battery to pass through, and the rechargeable battery is fixed and clamped in the notch;

the cavity is internally provided with a plurality of lugs for upwards supporting the rechargeable battery at intervals, the rechargeable battery is laid on the lugs, and the upper cover compresses the rechargeable battery on the lugs.

5. The mobile electrocardiograph workstation of claim 3 further comprising a light homogenizing sheet, wherein said light homogenizing sheet is located between said upper cover and said rechargeable battery, and said light homogenizing sheet is fixed to the upper surface of said rechargeable battery.

6. The mobile ECG workstation of claim 1, wherein the ECG workstation comprises two of said electrode pads, said charging pin is disposed between said two of said electrode pads, and said two of said electrode pads are symmetrically disposed with respect to said charging pin.

7. The mobile ECG workstation of claim 4, wherein a plurality of supporting posts for supporting the circuit board upwards are arranged on the inner wall surface of the cavity at intervals, a bayonet for positioning the edge of the circuit board is arranged on one side of each supporting post, the opening of each bayonet faces the center of the cavity, and the circuit board is fixed on the base through screws.

8. The mobile ECG workstation of claim 7, wherein the cavity bottom of the cavity is provided with a plurality of through holes for mounting the electrode plates, the through holes are coaxially provided with fixing rings, the top surfaces of the electrode plates are erected and fixed on the fixing rings, and the bottom surfaces of the electrode plates sequentially penetrate through the fixing rings and the through holes and are exposed out of the base.

9. The mobile electrocardiograph workstation according to claim 8 further comprising a switch button, wherein the switch button is connected in series to a series circuit composed of a charging power source and the circuit board, and a window facing the switch button is provided on one side of the base, the switch button is exposed out of the window for facilitating finger-picking operation;

the window still be furnished with sealed waterproof button shell with, the internal surface of waterproof button shell on be equipped with the round snap ring, the window outward flange on be equipped with snap ring matched with draw-in groove, waterproof button shell with the window buckle cooperation.

10. The mobile ECG workstation of claim 1, wherein the electrode plate has a central hole in the middle thereof, a metal spring is connected in the central hole, the top end of the metal spring extends upwards and is welded and fixed with the circuit board, and the electrode plate is connected with the circuit board through the metal spring.

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