CN110693487A

CN110693487A - Electrocardiograph based on 5G communication

Info

Publication number: CN110693487A
Application number: CN201910987718.7A
Authority: CN
Inventors: 廖生武; 廖海帆; 梁有丽; 谭碧慧; 李思远; 陈保安
Original assignee: Shenzhen Lightlink Guangtong Technology Co Ltd
Current assignee: Shenzhen Lightlink Guangtong Technology Co Ltd
Priority date: 2019-10-17
Filing date: 2019-10-17
Publication date: 2020-01-17

Abstract

The invention relates to an electrocardiogram machine based on 5G communication, which comprises a base, a platform, a host, a display screen, a printing mechanism, a detection mechanism and a plurality of keys, wherein the printing mechanism comprises a printing device, a printing port, a sealing assembly, a bottom plate and two hanging rods, the sealing assembly comprises a telescopic unit, a sliding plate and two sealing units, the sealing unit comprises a bracket, a supporting rod and a sealing plate, the detection mechanism comprises a lifting assembly, a lifting plate, a dust cover and a plurality of detection assemblies, the detection assemblies comprise a guide pipe, a lead wire, an electrode, a guide unit and two open holes, the electrocardiogram machine based on 5G communication is convenient to smooth the lead wire through the detection mechanism, the electrode is pulled when the equipment is idle, the dust cover covers the electrode, the electrode is prevented from being stained with dust to influence the contact performance of the electrode, not only is the aim that the printing port can be sealed by the sealing plate when the printing mechanism, when the printing paper feeding device is used, the printing paper is fixed through the guide plate and the sealing plate, the printing paper is prevented from falling, and the practicability of the printing paper feeding device is improved.

Description

Electrocardiograph based on 5G communication

Technical Field

The invention relates to the field of medical instruments, in particular to an electrocardiograph based on 5G communication.

Background

The electrocardiograph is a medical electronic instrument which can automatically record the bioelectric signals generated by the activation of cardiac muscle during the heart activity and is commonly used for clinical diagnosis and scientific research. Before the heart beats, the cardiac muscle is excited first, and weak current is generated during excitation, and the current is conducted to each part through the human tissue, and the distance between each part and the heart is different depending on the tissue of each part of the body, so that each part on the surface of the human body shows different potential changes, and the relationship between the surface potential generated by the electrical activity in the heart of the human body and the time is called electrocardiogram. Electrocardiographs are instruments that record these physiological electrical signals.

The current electrocardiograph is convenient for doctor and patient to observe the detected signal, printing device has still been set up on the electrocardiograph usually, and set up at the equipment surface and print the mouth, the convenience is printed the result, but current printing mostly directly exposes and sets up on the equipment surface, inside outside dust debris got into equipment through printing the mouth easily, influence the cleanness in the equipment, and beat and fall easily on the ground and become dirty when beating the direct discharge of printing paper from printing the mouth, people still probably step on when passing through on printing the paper, not only, electrocardiograph's lead wire is mostly all longer, after finishing using, the doctor needs to spend more time and carries out wholly, the electrode of lead wire port department exposes the setting simultaneously, be stained with the ash easily, influence the contact property of electrode, lead to current electrocardiograph practicality to reduce.

Disclosure of Invention

The technical problem to be solved by the invention is as follows: in order to overcome the defects of the prior art, an electrocardiograph based on 5G communication is provided.

The technical scheme adopted by the invention for solving the technical problems is as follows: a electrocardiograph based on 5G communication comprises a base, a platform, a host, a display screen, a printing mechanism, a detection mechanism, two support legs and a plurality of keys, wherein the support legs are fixed above the base;

the printing mechanism comprises a printing device, a printing port, a sealing assembly, a bottom plate and two hanging rods, the printing device is fixed on one side of a host machine and is electrically connected with a PLC, the printing port is fixed below the host machine, the two hanging rods are respectively positioned on two sides of the printing port, two ends of the bottom plate are respectively fixed below the printing device through the two hanging rods, the sealing assembly comprises a telescopic unit, a sliding plate and two sealing units, two ends of the sliding plate are respectively sleeved on the two hanging rods, the sliding plate is arranged below the bottom plate through the telescopic unit, the two sealing units are respectively positioned on two sides above the sliding plate, the sealing units are in one-to-one correspondence with the hanging rods, each sealing unit comprises a support, a support rod and a sealing plate, one end of the support is fixed on a support leg, the other end of the support is hinged with the sealing plate, and the sealing plate, two ends of the supporting rod are respectively hinged with the sealing plate and the sliding plate;

detection mechanism includes lifting unit, lifter plate, dust cover and a plurality of determine module, lifting unit is connected with lifter plate and dust cover transmission, the lifter plate cover is established on the stabilizer blade, the dust cover supports and leans on the top at the platform, determine module evenly distributed is between two stabilizer blades, determine module includes stand pipe, lead line, electrode, guide unit and two trompils, the guide unit is located the below of platform, the shape of stand pipe is the U-shaped, the top at the lifter plate is fixed to the stand pipe, the electrode is located the inboard of dust cover, the one end of leading the line is connected with the below of host computer through an trompil, the other end of leading the line loops through guide unit, stand pipe and another trompil and is connected with the electrode, the size of trompil is less than the size of electrode.

Preferably, in order to control the sliding plate to move up and down, the telescopic unit comprises a first motor, a driving rod and a driven rod, the first motor is fixed above the bottom plate and electrically connected with the PLC, the first motor is in transmission connection with the driving rod, and the driving rod is hinged to the sliding plate through the driven rod.

Preferably, in order to secure the driving force of the first motor, the first motor is a dc servo motor.

Preferably, in order to prevent the printing paper from falling, guide plates are provided on both sides above the sealing plate, and the guide plates abut against the printing port.

As preferred, for the convenience of control lifter plate lift removal, lifting unit includes second motor, lead screw and sleeve pipe, be equipped with square mouthful on the platform, the top in the dust cover is fixed on sheathed tube top, the inner wall sealing connection of sheathed tube periphery and square mouthful, the top at the base is fixed to the second motor, the second motor is connected with the PLC electricity, the second motor is connected with the top transmission of lead screw, the bottom setting of lead screw is at the intraductal, sheathed tube and the junction of lead screw are equipped with the screw thread that matches with the lead screw, sleeve pipe and lifter plate fixed connection.

Preferably, in order to avoid corrosion of the screw rod, the screw rod is coated with an anti-corrosion zinc coating.

Preferably, the guide unit includes two guide wheels fixed below the platform in order to guide the direction of the lead wire, which passes through the two guide wheels in sequence.

Preferably, in order to reinforce the connection between the platform and the base and the support legs, the platform and the base and the support legs are of an integrally formed structure.

Preferably, in order to avoid abrasion of the lead wires, a sponge ring is arranged on the inner wall of the opening.

Preferably, in order to facilitate the movement of the equipment, a plurality of universal wheels are arranged below the base.

The electrocardiogram machine based on the 5G communication has the advantages that the detection mechanism is convenient for smoothing out conducting wires, the electrodes are pulled when the equipment is idle, the electrodes are covered by the dust cover, the electrodes are prevented from being stained with dust to influence the contact performance of the electrodes, furthermore, the sealing plate can be used for sealing and preventing dust of a printing opening when the printing mechanism is idle, printing paper is clamped by the guide plate and the sealing plate when the electrocardiogram machine is used, the printing paper is fixed, the printing paper is prevented from falling, and therefore the practicability of the equipment is improved.

Drawings

The invention is further illustrated with reference to the following figures and examples.

FIG. 1 is a schematic diagram of a 5G communication-based electrocardiograph according to the present invention;

FIG. 2 is a schematic diagram of a printing mechanism of the electrocardiograph based on 5G communication according to the present invention;

FIG. 3 is a schematic structural diagram of a detection mechanism of the electrocardiograph based on 5G communication according to the present invention;

FIG. 4 is a schematic diagram of the detection assembly of the electrocardiograph based on 5G communication according to the present invention;

in the figure: 1. the printing device comprises a base, 2, a platform, 3, a host, 4, a display screen, 5, a support leg, 6, a key, 7, a printing port, 8, a bottom plate, 9, a hanging rod, 10, a sliding plate, 11, a support, 12, a support rod, 13, a sealing plate, 14, a lifting plate, 15, a dust cover, 16, a guide pipe, 17, a lead wire, 18, an electrode, 19, a first motor, 20, a driving rod, 21, a driven rod, 22, a guide plate, 23, a second motor, 24, a lead screw, 25, a sleeve, 26, a guide wheel, 27, a universal wheel and 28.

Detailed Description

The present invention will now be described in further detail with reference to the accompanying drawings. These drawings are simplified schematic views illustrating only the basic structure of the present invention in a schematic manner, and thus show only the constitution related to the present invention.

As shown in fig. 1, an electrocardiograph based on 5G communication includes a base 1, a platform 2, a host 3, a display screen 4, a printing mechanism, a detection mechanism, two support legs 5 and a plurality of keys 6, wherein the support legs 5 are fixed above the base 1, the platform 2 is erected on the two support legs 5, the host 3 is fixed above the platform 2, the host 3 is internally provided with a PLC and an antenna, the display screen 4 and the keys 6 are both fixed above the host 3, the display screen 4, the keys 6 and the antenna are all electrically connected with the PLC, the printing mechanism is arranged at one side of the host 3, and the detection mechanism is connected with the host 3;

when using this electrocardiograph, the doctor can be after equipment is placed, press button 6 of 3 tops of host computer, starting equipment, with patient's hand through coupling mechanism, foot and heart position are connected, carry out the electrocardio and detect, after the detection finishes, printing mechanism prints the testing result, PLC can show the testing result through display screen 4, and inside host computer 3, make things convenient for equipment to insert the 5G network through the antenna, be convenient for establish with other wireless communication equipment and be connected, still can transmit the testing result for doctor's computer through the 5G network simultaneously, establish archives for patient's detection information, make things convenient for doctor's inquiry to use, be convenient for doctor to give patient's exact diagnostic information according to patient's historical information, help treatment, thereby the practicality of equipment has been improved.

As shown in fig. 2, the printing mechanism includes a printing device 28, a printing port 7, a sealing assembly, a bottom plate 8 and two hanging rods 9, the printing device 28 is fixed on one side of the host 3, the printing device 28 is electrically connected with the PLC, the printing port 7 is fixed below the host 3, the two hanging rods 9 are respectively located on two sides of the printing port 7, two ends of the bottom plate 8 are respectively fixed below the printing device 28 through the two hanging rods 9, the sealing assembly includes a telescopic unit, a sliding plate 10 and two sealing units, two ends of the sliding plate 10 are respectively sleeved on the two hanging rods 9, the sliding plate 10 is arranged below the bottom plate 8 through the telescopic unit, the two sealing units are respectively located on two sides above the sliding plate 10, the sealing units are in one-to-one correspondence with the hanging rods 9, the sealing units include a support 11, a support rod 12 and a sealing plate 13, one end of the support 11 is fixed on the, the other end of the support 11 is hinged with a sealing plate 13, the sealing plate 13 is abutted against the lower part of the printing port 7, and two ends of the support rod 12 are respectively hinged with the sealing plate 13 and the sliding plate 10;

in the printing device 28, the printing port 7 is arranged below the printing device 28, so that sundries can be prevented from falling into the printing device 28, the printing port 7 can be blocked by using two sealing plates 13, the sealing and dust-proof treatment of the printing port 7 can be realized when the device is idle, the sundries are prevented from entering the printing port 7, when printing is performed, a telescopic unit on a PLC control bottom plate 8 is started to drive a sliding plate 10 to move downwards along the axis direction of a suspender 9, when the sliding plate 10 moves downwards, the sealing plate 13 acts on the sealing plate 13 through a support rod 12, so that the sealing plate 13 rotates downwards with one end of a support 11, which is far away from the suspender 9, as the center of a circle, the two sealing plates 13 are opened, so that the printing port 7 is gradually opened, printing paper falls downwards along with the gradually opened printing port 7, the printing paper is clamped by using the two gradually opened sealing plates 13, and plays a certain fixing role on the printing, the printing paper is prevented from falling to the ground, so that the cleanness of the printing paper is ensured, and the practicability of the equipment is improved.

As shown in fig. 3-4, the detection mechanism includes a lifting assembly, a lifting plate 14, a dust cover 15 and a plurality of detection assemblies, the lifting assembly is in transmission connection with the lifting plate 14 and the dust cover 15, the lifting plate 14 is sleeved on the support legs 5, the dust cover 15 abuts against the upper side of the platform 2, the detection assemblies are uniformly distributed between the two support legs 5, each detection assembly includes a guide tube 16, a lead wire 17, an electrode 18, a guide unit and two openings, the guide unit is located below the platform 2, the guide tube 16 is U-shaped, the guide tube 16 is fixed above the lifting plate 14, the electrode 18 is located on the inner side of the dust cover 15, one end of the lead wire 17 is connected with the lower side of the host 3 through one opening, the other end of the lead wire 17 is connected with the electrode 18 sequentially through the guide unit, the guide tube 16 and the other opening, the size of the opening is smaller than the size of the electrode 18.

When the device is idle, the lifting assembly controls the lifting plate 14 to move downwards along the axis of the supporting leg 5 to the lowest position, the lifting plate 14 drives the guide pipe 16 and the dust cover 15 to move downwards, when the guide pipe 16 moves downwards, the guide pipe 16 drives the guide wire 17 to move downwards as the guide wire 17 passes through the guide pipe 16, the electrode 18 is pulled above the platform 2 through the guide wire 17 while the guide wire 17 is stroked down, meanwhile, the dust cover 15 moves upwards along with the lifting assembly, the dust cover 15 covers the electrode 18, the contact performance of the electrode 18 is prevented from being affected by dust on the electrode 18, when an electrocardiograph is used for detection, the lifting assembly controls the lifting plate 14 to move upwards, the dust cover 15 and the guide pipe 16 move upwards simultaneously, after the guide pipe 16 moves upwards, the originally tightened guide wire 17 is loosened, and simultaneously, as the dust cover 15 moves upwards, make things convenient for doctor to take electrode 18 and connect patient's four limbs and chest to detect, after finishing using, take off electrode 18 on one's body from the patient after, lift assembly control lifter plate 14 moves down, when driving the pipe 16 downstream automatically, smooth out in the same direction as lead line 17 to draw electrode 18 to the top of platform 2, dust cover 15 moves down simultaneously, prevents dust to electrode 18 and handles, and then has improved the practicality of equipment.

As shown in fig. 2, the telescopic unit includes a first motor 19, a driving rod 20 and a driven rod 21, the first motor 19 is fixed above the bottom plate 8, the first motor 19 is electrically connected to the PLC, the first motor 19 is in transmission connection with the driving rod 20, and the driving rod 20 is hinged to the sliding plate 10 through the driven rod 21.

The PLC controls the first motor 19 to start, so as to drive the driving rod 20 to rotate, and the driving rod 20 acts on the sliding plate 10 through the driven rod 21, so that the sliding plate 10 can move up and down along the axis of the suspender 9.

Preferably, the first motor 19 is a dc servo motor in order to ensure the driving force of the first motor 19 by utilizing the characteristic that the driving force of the dc servo motor is strong.

Preferably, guide plates 22 are provided on both sides above the sealing plate 13 in order to prevent the printing paper from falling, and the guide plates 22 abut on the printing port 7. When the sealing plate 13 rotates to the vertical angle, the guide plates 22 on the two sides of the sealing plate 13 form a track, the sliding plate 10 is located below the guide plates 22 at the moment, the sliding plate 10 can support the bottom of printing paper, and the two ends of the center of the top of the printing paper are limited by the two guide plates 22 respectively, so that the printing paper is prevented from falling after the clamping of the two sealing plates 13 is lost.

As shown in fig. 2, the lifting assembly includes a second motor 23, a screw rod 24 and a sleeve 25, a square opening is arranged on the platform 2, the top end of the sleeve 25 is fixed at the top of the dust cover 15, the periphery of the sleeve 25 is connected with the inner wall of the square opening in a sealing manner, the second motor 23 is fixed above the base 1, the second motor 23 is electrically connected with the PLC, the second motor 23 is connected with the top end of the screw rod 24 in a transmission manner, the bottom end of the screw rod 24 is arranged in the sleeve 25, a connecting part of the sleeve 25 and the screw rod 24 is provided with a thread matched with the screw rod 24, and the sleeve 25 is fixedly connected with the lifting plate 14.

The PLC controls the second motor 23 to start, the screw rod 24 is driven to rotate, the screw rod 24 acts on the sleeve 25 through threads, and the sleeve 25 is driven to move up and down along the axis of the screw rod 24 due to the fact that the periphery of the sleeve 25 is connected with the inner wall of the upper side opening of the platform 2 in a sealing mode, and then the dust cover 15 fixedly connected with the sleeve 25 and the lifting plate 14 are driven to move up and down.

Preferably, to avoid corrosion of the lead screw 24, the lead screw 24 is coated with an anti-corrosion zinc coating. The corrosion-resistant zinc coating is used for preventing the surface of the screw rod 24 from being rusted by oxygen, and the stable transmission between the screw rod 24 and the sleeve 25 is ensured.

Preferably, in order to guide the direction of the lead wire 17, the guide unit comprises two guide wheels 26, the guide wheels 26 being fixed below the platform 2, the lead wire 17 passing in turn through the two guide wheels 26. The two guide wheels 26 are used for guiding the direction of the lead wire 17, so that the guide tube 16 can be conveniently combed and smoothed along the lead wire 17 when being lifted and moved.

Preferably, the platform 2, the base 1 and the support legs 5 are integrally formed to reinforce the connection between the platform 2 and the base 1 and the support legs 5 by utilizing the characteristic of stability of the integrally formed structure.

Preferably, in order to avoid wear of the lead wires 17, a sponge ring is arranged on the inner wall of the opening. The sponge ring is used for avoiding the contact between the lead wire 17 and the inner wall of the opening, thereby preventing the lead wire 17 from being worn and shortening the service life of the lead wire 17.

Preferably, a plurality of universal wheels 27 are arranged below the base 1 for facilitating the movement of the device.

When the electrocardiograph is used, the lifting assembly drives the lifting plate 14 to move upwards, so that the guide pipe 16 moves upwards, the lead wire 17 is loosened, the dust cover 15 moves upwards, the electrode 18 can be conveniently taken out to be connected with four limbs and the body of a patient for detection, the printing can be carried out by using the printing device 28 after detection, when the printing device 28 is used for printing, the telescopic unit drives the sliding plate 10 to move downwards, the printing paper is clamped by using the guide plate 22 and the sealing plate 13, the printing paper is prevented from falling off, after the printing paper is taken out by a doctor, the telescopic unit drives the sliding plate 10 to move upwards, the sealing plate 13 rotates upwards, the printing port 7 is blocked, sundries in the printing port 7 are prevented from entering, after the usage of the electrocardiograph is finished, the lifting assembly moves downwards through the lifting plate 14, the dust cover 15 and the guide pipe 16 are driven to move downwards, the electrode 18 is pulled, meanwhile, the dust cover 15 covers the electrode 18, so that the electrode 18 is prevented from being stained with dust to influence the contact performance of the electrode, and the practicability of the electrocardiograph is improved.

Compared with the prior art, this electrocardiograph based on 5G communication is convenient for smooth out with fingers in the same direction as lead line 17 through detection mechanism, and when equipment was idle, pulling electrode 18, make dust cover 15 cover electrode 18, avoid electrode 18 to be stained with the ash and influence its contact behavior, moreover, printing mechanism utilizes closing plate 13 can seal dustproof to printing mouth 7 when idle, when using, beat printing paper through deflector 22 and closing plate 13 centre gripping, it is fixed to beat printing paper, avoid beating printing paper and drop, thereby the practicality of equipment has been improved.

In light of the foregoing description of the preferred embodiment of the present invention, many modifications and variations will be apparent to those skilled in the art without departing from the spirit and scope of the invention. The technical scope of the present invention is not limited to the content of the specification, and must be determined according to the scope of the claims.

Claims

1. The electrocardiograph based on 5G communication is characterized by comprising a base (1), a platform (2), a host (3), a display screen (4), a printing mechanism, a detection mechanism, two support legs (5) and a plurality of keys (6), wherein the support legs (5) are fixed above the base (1), the platform (2) is erected on the two support legs (5), the host (3) is fixed above the platform (2), a PLC (programmable logic controller) and an antenna are arranged in the host (3), the display screen (4) and the keys (6) are both fixed above the host (3), the display screen (4), the keys (6) and the antenna are all electrically connected with the PLC, the printing mechanism is arranged on one side of the host (3), and the detection mechanism is connected with the host (3);

the printing mechanism comprises a printing device (28), a printing port (7), a sealing assembly, a bottom plate (8) and two hanging rods (9), the printing device (28) is fixed on one side of a host (3), the printing device (28) is electrically connected with a PLC, the printing port (7) is fixed below the host (3), the two hanging rods (9) are respectively positioned on two sides of the printing port (7), two ends of the bottom plate (8) are respectively fixed below the printing device (28) through the two hanging rods (9), the sealing assembly comprises a telescopic unit, a sliding plate (10) and two sealing units, two ends of the sliding plate (10) are respectively sleeved on the two hanging rods (9), the sliding plate (10) is arranged below the bottom plate (8) through the telescopic unit, the two sealing units are respectively positioned on two sides above the sliding plate (10), and the sealing units are in one-to-one correspondence with the hanging rods (9), the sealing unit comprises a support (11), a support rod (12) and a sealing plate (13), one end of the support (11) is fixed on the support leg (5), the other end of the support (11) is hinged with the sealing plate (13), the sealing plate (13) abuts against the lower part of the printing port (7), and two ends of the support rod (12) are hinged with the sealing plate (13) and the sliding plate (10) respectively;

the detection mechanism comprises a lifting assembly, a lifting plate (14), a dust cover (15) and a plurality of detection assemblies, the lifting assembly is in transmission connection with the lifting plate (14) and the dust cover (15), the lifting plate (14) is sleeved on the support legs (5), the dust cover (15) is abutted against the top of the platform (2), the detection assemblies are uniformly distributed between the two support legs (5), each detection assembly comprises a guide pipe (16), a lead wire (17), an electrode (18), a guide unit and two open holes, the guide unit is positioned below the platform (2), the guide pipe (16) is U-shaped, the guide pipe (16) is fixed above the lifting plate (14), the electrode (18) is positioned on the inner side of the dust cover (15), one end of the lead wire (17) is connected with the bottom of the host (3) through one open hole, the other end of the lead wire (17) is connected with the electrode (18) through a guide unit, a guide tube (16) and another opening in sequence, and the size of the opening is smaller than that of the electrode (18).

2. The electrocardiograph based on 5G communication according to claim 1, wherein the telescopic unit comprises a first motor (19), a driving rod (20) and a driven rod (21), the first motor (19) is fixed above the bottom plate (8), the first motor (19) is electrically connected with the PLC, the first motor (19) is in transmission connection with the driving rod (20), and the driving rod (20) is hinged with the sliding plate (10) through the driven rod (21).

3. The electrocardiograph based on 5G communication according to claim 2, wherein the first motor (19) is a DC servo motor.

4. The electrocardiograph based on 5G communication according to claim 1, wherein the upper two sides of the sealing plate (13) are provided with guide plates (22), and the guide plates (22) abut on the printing port (7).

5. The 5G communication-based electrocardiograph according to claim 1, wherein the lifting assembly comprises a second motor (23), a screw rod (24) and a sleeve (25), the platform (2) is provided with a square opening, the top end of the sleeve (25) is fixed on the top of the dust cover (15), the periphery of the sleeve (25) is connected with the inner wall of the square opening in a sealing manner, the second motor (23) is fixed above the base (1), the second motor (23) is electrically connected with the PLC, the second motor (23) is connected with the top end of the screw rod (24) in a transmission manner, the bottom end of the screw rod (24) is arranged in the sleeve (25), the connecting part of the sleeve (25) and the screw rod (24) is provided with a thread matched with the screw rod (24), and the sleeve (25) is fixedly connected with the lifting plate (14).

6. The electrocardiograph based on 5G communication according to claim 5, wherein the lead screw (24) is coated with an anti-corrosion zinc coating.

7. The electrocardiograph based on 5G communication according to claim 1, wherein the guiding unit comprises two guiding wheels (26), the guiding wheels (26) are fixed under the platform (2), and the lead wire (17) passes through the two guiding wheels (26) in turn.

8. The electrocardiograph based on 5G communication according to claim 1, wherein the platform (2) and the base (1) are integrally formed with the support legs (5).

9. The electrocardiograph according to claim 1, wherein the inner wall of the opening is provided with a sponge ring.

10. The electrocardiograph based on 5G communication according to claim 1, wherein a plurality of universal wheels (27) are arranged below the base (1).