CN109350035B

CN109350035B - Electrocardiograph intelligence allotment and guardianship data acquisition integration equipment

Info

Publication number: CN109350035B
Application number: CN201811174345.3A
Authority: CN
Inventors: 王建伟
Original assignee: Individual
Current assignee: Individual
Priority date: 2018-10-09
Filing date: 2018-10-09
Publication date: 2021-09-24
Anticipated expiration: 2038-10-09
Also published as: CN109350035A

Abstract

The invention provides an integrated device for intelligent allocation and monitoring data acquisition of an electrocardiograph, which comprises three X-axis guide rails arranged on the wall of a ward, wherein an electrocardiograph mounting seat driven by a first power device is slidably arranged on the X-axis guide rails, the electrocardiograph mounting seat is provided with the electrocardiograph, and a locking device is arranged between the electrocardiograph and the electrocardiograph mounting seat; a Y-axis guide rail is arranged on the corridor wall of the ward group, and a Y-axis mounting plate driven by a second power device is slidably mounted on the Y-axis guide rail; a Z-axis guide rail is fixedly arranged on the Y-axis mounting plate, a blending mounting plate driven by a third power device is slidably arranged on the Z-axis guide rail, and an electrocardiograph blending device is arranged on the blending mounting plate; the invention relates to an intelligent integrated device which can operate an electrocardiogram machine in a medical care room, can freely allocate all the electrocardiogram machines, realizes data acquisition intellectualization and saves time.

Description

Electrocardiograph intelligence allotment and guardianship data acquisition integration equipment

Technical Field

The invention relates to the technical field of medical instruments, in particular to an intelligent allocation and monitoring data acquisition integrated device for an electrocardiograph.

Background

Before the heart beats, the cardiac muscle is excited first, weak current is generated in the exciting process, the current is conducted to each part through human tissues, because the tissues of each part of the body are different, the distances between each part and the heart are different, so that each part on the surface of the human body shows different potential changes, the relation between the surface potential generated by the electrical activity in the heart of the human body and the time is electrocardiogram, and the electrocardiogram machine is an instrument for recording the physiological electrical signals, namely a medical instrument capable of automatically recording the biological electrical signals (electrocardio signals) of the myocardial excitation and the fibrillation during the heart activity. Therefore, electrocardiographs are widely used in clinical diagnosis and scientific research.

The existing electrocardiograph mainly has the following problems: the first is that the electrocardiograph with complete functions and high precision has larger volume and is not convenient to move; secondly, each electrocardiograph needs to be operated by medical staff, and a great deal of time is consumed for the whole operation.

Therefore, there is a need for an integrated device for intelligently deploying electrocardiographs and collecting monitored data, which can solve the above problems.

Disclosure of Invention

The invention provides an integrated device for intelligent allocation and monitoring data acquisition of an electrocardiograph, which can be used for operating the electrocardiograph in a medical care room, can allocate all electrocardiographs freely, realizes data acquisition intellectualization and saves time.

The technical scheme of the invention is realized as follows:

an integrated device for intelligent allocation and monitoring data acquisition of an electrocardiograph comprises two rows of ward groups arranged in parallel and a medical care control room, wherein each row of ward groups comprises a plurality of wards arranged in sequence,

the wall of each ward is provided with three X-axis guide rails extending along the X-axis direction, the three X-axis guide rails are arranged in parallel up and down, an electrocardiograph mounting seat driven by a first power device is slidably mounted on each X-axis guide rail, an electrocardiograph is detachably mounted on each electrocardiograph mounting seat, and a locking device is arranged between each electrocardiograph and the electrocardiograph mounting seat;

a Y-axis guide rail extending along the Y-axis direction is arranged on the corridor wall of each row of ward groups respectively, and a Y-axis mounting plate driven by a second power device is mounted on each Y-axis guide rail in a sliding manner;

each Y-axis mounting plate is fixedly provided with a Z-axis guide rail along the Z-axis direction, each Z-axis guide rail is slidably provided with a deployment mounting plate driven by a third power device, and each deployment mounting plate is provided with an electrocardiograph deployment device for carrying an electrocardiograph;

an industrial personal computer used for controlling the first power device, the second power device, the third power device and the hydraulic pump is arranged in the medical control room.

As a preferred technical scheme, each electrocardiograph blending device comprises a hydraulic cylinder body installed on the blending installation plate, each hydraulic cylinder body is provided with an oil inlet and an oil outlet, two hydraulic chambers extending along the X-axis direction are arranged in the hydraulic cylinder body, each hydraulic chamber is provided with a hydraulic oil inlet communicated with the oil inlet and a hydraulic oil outlet communicated with the oil outlet, the hydraulic oil inlet and the hydraulic oil outlet are communicated with a hydraulic pump through hydraulic pipelines, a blending rod is slidably installed in each hydraulic chamber, the end of each blending rod is provided with a first positioning groove, each electrocardiograph is provided with two blending positioning cavities extending along the X-axis, each blending positioning cavity is provided with a first limiting cavity extending along the Z-axis, each first limiting cavity is internally provided with a limiting ball matched with the first positioning groove, and a first reset spring is arranged between the first limiting cavity and the limiting ball.

As a preferred technical scheme, each locking device comprises a second positioning cavity arranged on the electrocardiograph mounting seat, a sliding claw sleeve extending along the Z-axis direction is arranged in each second positioning cavity, the teeth of each sliding claw sleeve are of a ratchet wheel structure, each electrocardiograph is provided with a lug, each lug is internally provided with a sliding cavity, each sliding cavity is internally provided with a locking push rod arranged opposite to the sliding claw sleeve, the other end of each push rod is provided with a pressing push rod, each pressing push rod extends out of the lug, and each pressing push rod is sleeved with a second reset spring.

As a preferable technical scheme, one end of each locking push rod is provided with a tooth column of a mountain ratchet wheel structure matched with the mountain ratchet wheel structure of the sliding claw sleeve, and the outer surface of each locking push rod is provided with a plurality of sliding grooves extending along the Z-axis direction.

As a preferred technical scheme, each of the first power devices is a first rack and pinion mechanism driven by a first servo motor, a motor housing of each of the first servo motors is fixedly mounted on the electrocardiograph mounting base, each of the first gears is mounted on a motor shaft of the first servo motor, and each of the first racks extending along the X-axis direction is disposed on a wall of the ward.

As a preferred technical scheme, each second power device is a second rack and pinion mechanism driven by a second servo motor, each motor casing of the second servo motor is fixedly mounted on the Y-axis mounting plate, each second gear is mounted on a motor shaft of the second servo motor, and each second rack extending along the Y-axis direction is arranged at the top of the corridor of the ward group.

As a preferred technical solution, each third power device is a third rack and pinion mechanism driven by a third servo motor, a motor housing of each third servo motor is fixedly mounted on the deployment mounting plate, each third gear is mounted on a motor shaft of the third servo motor, and each third rack extending along the Z-axis direction is disposed on the Y-axis mounting plate.

As a preferred technical scheme, each electrocardiograph mounting seat is provided with a lead sub-connector, each lead sub-connector is electrically connected with a lead, each electrocardiograph is electrically connected with a lead female connector matched with the lead sub-connector, and a connecting and positioning device is arranged between each lead sub-connector and the lead female connector.

As a preferred technical scheme, each connect and insert positioner all include one be fixed in the gag lever post of connector sub-connector bottom and one set up in lead the grafting recess of connector female connector tip, each the gag lever post all inserts in the grafting recess, each the bottom of grafting recess all is equipped with a second positioning groove, each the tip of gag lever post all is equipped with the spacing chamber of second, each the spacing intracavity of second is equipped with one the stopper of second positioning groove looks adaptation, each the spacing chamber of second with all be equipped with third reset spring between the stopper.

By adopting the technical scheme, the invention has the beneficial effects that:

because the integrated equipment for intelligently allocating and acquiring the monitoring data of the electrocardiograph comprises three X-axis guide rails which are arranged on the wall of the ward and extend along the X-axis direction, and an electrocardiograph mounting seat and an electrocardiograph which are driven by a first power device are arranged on each X-axis guide rail in a sliding way, when the integrated equipment is used, the first power device can drive the electrocardiograph mounting seat to slide on the X-axis guide rails, medical personnel can arrange sickbeds in the ward and freely adjust the position of the electrocardiograph mounting seat on the X-axis guide rails, and the electrocardiograph does not need to be moved back and forth by the medical personnel, so that the operation is simple and quick, the labor intensity of the medical personnel is reduced, and the working efficiency of the medical personnel is improved; a locking device is arranged between each electrocardiograph and the electrocardiograph mounting seat, when the electrocardiograph needs to be moved, a medical worker presses and presses the push rod to enable the locking push rod to rotate in the sliding cavity and the second positioning cavity, so that the locking push rod and the sliding claw sleeve generate relative position deviation, the second reset spring drives the locking push rod to leave the second positioning cavity by utilizing self elasticity to realize unlocking, then the medical worker can operate and allocate the electrocardiograph, after allocation is completed, the medical worker presses and presses the push rod again to enable the locking push rod to rotate while being inserted into the second positioning cavity, the bottom tip position of the sliding groove of the front end toothed column part of the locking push rod moves to the sliding claw sleeve, the sliding claw sleeve is clamped in the sliding groove position to realize locking of the ratchet wheel structure of the sliding claw sleeve and the sliding groove, the locking device needs the medical worker to perform manual locking and unlocking, and the situation that allocation is performed by using the electrocardiograph due to operation errors of the medical worker is avoided, the safety of the equipment in use is ensured;

when the electrocardiograph is used, medical personnel coordinate the use condition of the electrocardiograph in each ward and control the second power device to drive the Y-axis mounting plate to slide on the Y-axis guide rail, so that the electrocardiograph is allocated, the operation is convenient and quick, the working efficiency of the medical personnel is improved, the labor intensity of the medical personnel is reduced, the time of waiting for a bed for a patient is greatly shortened, and the medical personnel allocate the electrocardiograph for the required patient in time;

when the medical care personnel use the X-axis guide rails, the medical care personnel control the third power device to drive the allocation installation plate to slide on the Z-axis guide rails, and can allocate the electrocardiographs on the three X-axis guide rails, so that the reasonable allocation and use of the electrocardiographs with different grades are ensured, and the working efficiency of the medical care personnel is improved; each allocation mounting plate is provided with an electrocardiograph allocation device for carrying an electrocardiograph, when the electrocardiograph is allocated, the allocation rod is controlled by the hydraulic pump to extend out and be inserted into the allocation positioning cavity, and meanwhile, the limit ball arranged in the allocation positioning cavity is inserted into the first positioning groove at the end part of the allocation rod, so that the positioning and the supporting of the electrocardiograph are realized, the electrocardiograph and the electrocardiograph allocation device are connected together, medical workers can be controlled and finished in a medical care room in the whole process, the operation of the medical workers in one ward is not needed, the labor intensity is reduced, only one medical worker is needed in the whole process, and the number and the cost expenditure of the medical workers are reduced;

be provided with the industrial computer that is used for controlling first power device, second power device, third power device and hydraulic pump in the medical control room, make medical personnel just can operate in the medical control room to accomplish the transmission and the receipt of data in the electrograph, do not need a medical personnel machine to go the record, realized guardianship data acquisition's intellectuality, improved medical personnel's work efficiency.

Each electrocardiograph mounting seat is provided with a lead wire sub-connector, each lead wire sub-connector is electrically connected with a lead wire, each electrocardiograph is electrically connected with a lead wire female connector matched with the lead wire sub-connector, and a plugging positioning device is arranged between each lead wire sub-connector and the lead wire female connector.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to these drawings without creative efforts.

FIG. 1 is an overall layout of the ward group of the present invention;

FIG. 2 is a schematic structural view of the present invention;

FIG. 3 is a top view of the electrocardiogram deployment apparatus of the present invention;

FIG. 4 is a schematic view of the structure of FIG. 2 taken along direction A-A;

FIG. 5 is a schematic view of the connection of the lead sub-connector and the lead female connector;

fig. 6 is an enlarged view of the structure at B in fig. 5.

Wherein: 1. a medical care control room; 2. a ward; 3. an X-axis guide rail; 4. an electrocardiograph mounting base; 5. an electrocardiograph; 6. a locking device; 7. a Y-axis guide rail; 8. a Y-axis mounting plate; 9. a Z-axis guide rail; 10. allocating an installation plate; 11. a blending device of an electrocardiograph; 12. an industrial personal computer; 13. a hydraulic cylinder block; 14. an oil inlet; 15. an oil outlet; 16. a hydraulic chamber; 17. a hydraulic oil injection port; 18. a hydraulic oil outlet; 19. a hydraulic pump; 20. a blending rod; 21. a hydraulic line; 22. a first positioning groove; 23. allocating a positioning cavity; 24. a first limiting cavity; 25. a limiting ball; 26. a first return spring; 27. a second positioning cavity; 28. a sliding claw sleeve; 29. a bump; 30. a sliding cavity; 31. locking the push rod; 32. pressing the push rod; 33. a second return spring; 34. a chute; 35. a first servo motor; 36. a first gear; 37. a first rack; 38. a second servo motor; 39. a second gear; 40. a second rack; 41. a third servo motor; 42. a third gear; 43. a third rack; 44. a lead wire sub-connector; 45. conducting wires; 46. a lead bus connector; 47. a limiting rod; 48. inserting grooves; 49. a second positioning groove; 50. a second limiting cavity; 51. a limiting block; 52. and a third return spring.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

As shown in fig. 1 and fig. 2, the integrated device for electrocardiograph intelligent allocation and monitoring data acquisition comprises two rows of ward groups arranged in parallel and a medical care control room 1, each row of ward group comprises a plurality of sequentially arranged wards 2,

three X-axis guide rails 3 extending along the X-axis direction are arranged on the wall of each ward 2, the three X-axis guide rails 3 are arranged in parallel up and down, an electrocardiograph mounting seat 4 driven by a first power device is slidably mounted on each X-axis guide rail 3, an electrocardiograph 5 is detachably mounted on each electrocardiograph mounting seat 4, a locking device 6 is arranged between each electrocardiograph 5 and the electrocardiograph mounting seat 4, when the novel medical electrocardiogram fixing device is used, the first power device can drive the electrocardiogram machine mounting seat 4 to slide on the X-axis guide rail 3, medical staff can arrange sickbeds in the sickroom 2 and freely adjust the position of the electrocardiogram machine mounting seat 4 on the X-axis guide rail 3, the medical staff does not need to move the electrocardiogram machine 5 back and forth, the operation is simple and fast, the labor intensity of the medical staff is reduced, and the working efficiency of the medical staff is improved;

when the electrocardiogram machine is used, medical personnel coordinate the use condition of the electrocardiogram machine 5 in each ward 2 and control the second power device to drive the Y-axis mounting plate 8 to slide on the Y-axis guide rail 7, so that the electrocardiogram machine 5 is allocated, the operation is convenient and quick, the working efficiency of the medical personnel is improved, the labor intensity of the medical personnel is reduced, the time of waiting for a bed position by the patient is greatly shortened, and the medical personnel allocate the electrocardiogram machine 5 for the required patient in time;

each Y-axis mounting plate 8 is fixedly provided with a Z-axis guide rail 9 along the Z-axis direction, each Z-axis guide rail 9 is slidably provided with a deployment mounting plate 10 driven by a third power device, each deployment mounting plate 10 is provided with an electrocardiograph deployment device 11 used for carrying an electrocardiograph 5, when in use, a medical worker controls the third power device to drive the deployment mounting plate 10 to slide on the Z-axis guide rail 9, and the electrocardiographs 5 on the three X-axis guide rails 3 can be deployed, so that reasonable deployment and use of the electrocardiographs 5 with different grades are ensured, and the working efficiency of the medical worker is improved;

be provided with the industrial computer 12 that is used for controlling first power device, second power device, third power device and hydraulic pump 19 in the medical care control room 1, industrial computer 12 adopts and grinds hua industrial computer IPC-610L, and this industrial computer 12 is established ties with first servo motor, second servo motor, third servo motor and hydraulic pump, realizes the motion of first gear, second gear, third gear and allotment pole through industrial computer 12, for the technique that ordinary skilled person in the art is familiar with, no longer describes here any more.

As shown in fig. 3, each electrocardiograph blending device 11 includes a hydraulic cylinder 13 mounted on the blending mounting plate 10, each hydraulic cylinder 13 has an oil inlet 14 and an oil outlet 15, two hydraulic chambers 16 extending along the X-axis are disposed in the hydraulic cylinder 13, each hydraulic chamber 16 has a hydraulic oil inlet 17 communicated with the oil inlet 14 and a hydraulic oil outlet 18 communicated with the oil outlet 15, the hydraulic oil inlet 17 and the hydraulic oil outlet 18 are both communicated with a hydraulic pump 19 through a hydraulic pipeline 21, a blending rod 20 is slidably mounted in each hydraulic chamber 16, a first positioning groove 22 is disposed at an end of each blending rod 20, two blending positioning cavities 23 extending along the X-axis are disposed on each electrocardiograph 5, a first limiting cavity 24 extending along the Z-axis is disposed in each blending positioning cavity 23, a limiting ball 25 adapted to the first positioning groove 22 is disposed in each first limiting cavity 24, all be equipped with a first reset spring 26 between first spacing chamber 24 and the spacing ball 25, when transferring to electrocardiograph 5, hydraulic pump 19 control allotment pole 20 stretches out, and insert in allotment location chamber 23, spacing ball 25 that the while allotment location intracavity set up inserts in the first positioning groove 22 of allotment pole 20 tip, realized electrocardiograph 5's location and support, make electrocardiograph 5 and electrocardiograph allotment device 11 link together, medical personnel can all accomplish at the indoor control of medical care at whole in-process, do not need medical personnel a ward 2 to operate, labor intensity has been reduced, and whole process only need one medical personnel can, medical personnel's quantity and expense have been reduced.

As shown in fig. 4, each locking device 6 includes a second positioning cavity 27 disposed on the electrocardiograph mounting base 4, a sliding pawl sleeve 28 extending along the Z-axis direction is disposed in each second positioning cavity 27, the teeth of each sliding pawl sleeve 28 are of a ratchet structure, a bump 29 is disposed on each electrocardiograph 5, a sliding cavity 30 is disposed in each bump 29, a locking push rod 31 disposed opposite to the sliding pawl sleeve 28 is disposed in each sliding cavity 30, a pressing push rod 32 is disposed at the other end of each push rod, each pressing push rod 32 extends out of the bump 29, and a second return spring 33 is sleeved on each pressing push rod 32.

One end of each locking push rod 31 is provided with a tooth column of a ratchet wheel structure matched with the ratchet wheel structure of the sliding claw sleeve 28, and the outer surface of each locking push rod 31 is provided with a plurality of sliding grooves 34 extending along the Z-axis direction.

When electrocardiograph 5 is moved, medical personnel press and press push rod 32, separation of electrocardiograph 5 and electrocardiograph mount pad 4 is realized, after allocation is completed, medical personnel press and press push rod 32 again, locking of electrocardiograph 5 and electrocardiograph mount pad 4 is realized, locking device 6 needs medical personnel to manually lock and unlock, the condition that medical personnel misoperation occurs to cause that electrocardiograph 5 is being used for allocation is avoided, and safety during equipment use is guaranteed.

Moreover, each first power device is a first rack and pinion mechanism driven by a first servo motor 35, the motor housing of each first servo motor 35 is fixedly mounted on the electrocardiograph mounting base 4, each first gear 36 is mounted on the motor shaft of the first servo motor 35, and each first rack 37 extending along the X-axis direction is disposed on the wall of the ward 2.

Each second power device is a second gear and rack mechanism driven by a second servo motor 38, the motor housing of each second servo motor 38 is fixedly mounted on the Y-axis mounting plate 8, each second gear 39 is mounted on the motor shaft of the second servo motor 38, and each second rack 40 extending along the Y-axis direction is arranged at the top of the corridor of the ward 2 group.

Each third power device is a third rack and pinion mechanism driven by a third servo motor 41, a motor housing of each third servo motor 41 is fixedly mounted on the allocation mounting plate 10, each third gear 42 is mounted on a motor shaft of the third servo motor 41, and each third rack 43 extending along the Z-axis direction is arranged on the Y-axis mounting plate 8.

As shown in fig. 5, each electrocardiograph mounting seat 4 is provided with a lead wire sub-connector 44, each lead wire sub-connector 44 is electrically connected with a lead wire 45, each electrocardiograph 5 is electrically connected with a lead wire female connector 46 matched with the lead wire sub-connector 44, and a connecting and positioning device is arranged between each lead wire sub-connector 44 and the lead wire female connector 46.

As shown in fig. 6, each plugging positioning device includes a limiting rod 47 fixed at the bottom of the connecting sub-connector and a plugging groove 48 disposed at the end of the connecting bus female connector 46, each limiting rod 47 is inserted into the plugging groove 48, a second positioning groove 49 is disposed at the bottom of each plugging groove 48, a second limiting cavity 50 is disposed at the end of each limiting rod 47, a limiting block 51 adapted to the second positioning groove 49 is disposed in each second limiting cavity 50, and a third return spring 52 is disposed between each second limiting cavity 50 and the limiting block 51.

When electrocardiograph 5 is fixed on electrocardiograph mount pad 4, set up in the female connector 46 of lead wire on electrocardiograph 5 inserts in the son connector 44 of lead wire on electrocardiograph mount pad 4, make electrocardiograph 5 normal use, realized electrocardiograph 5's automatic movement and with lead wire 45's automatic butt joint, do not need medical personnel to operate, avoid lead wire 45 to appear damaging and unmatched phenomenon at electrocardiograph 5's allotment in-process, and simultaneously, medical personnel's quantity has been reduced, the time of operation has been practiced thrift.

In summary, the working process of the invention is as follows:

firstly, preparing the electrocardiograph 5, namely firstly, controlling a first servo motor 35 to start by medical personnel through an industrial personal computer 12, driving a first gear 36 to move on a first rack 37 by the first servo motor 35, so as to drive an electrocardiograph mounting seat 4 to slide on an X-axis guide rail 3, and enabling the electrocardiograph mounting seat 4 to move to the door position of a ward 2 with the electrocardiograph 5; the second servo motor 38 is started to make the second gear 39 move on the second rack 40 to drive the Y-axis mounting plate 8 to slide on the Y-axis guide rail 7, so that the Y-axis mounting plate 8 moves to the door corresponding to the ward 2, the third servo motor 41 is started to make the third gear 42 move on the third rack 43 to drive the allocating mounting plate 10 to slide on the Z-axis guide rail 9, so that the electrocardiogram allocating device is aligned to the allocating and positioning cavity 23 on the electrocardiogram 5; at the moment, the hydraulic pump 19 controls the blending rod 20 to extend out and be inserted into the blending positioning cavity 23, and meanwhile, the limiting ball 25 arranged in the blending positioning cavity 23 is inserted into the first positioning groove 22 at the end part of the blending rod 20, so that the positioning and the supporting of the electrocardiograph 5 are realized; thereafter, the second servomotor 38 drives the second gear 39 to move on the second rack 40, so that the Y-axis mounting plate 8 is moved to the doorway of the patient room 2 where the electrocardiograph 5 is to be deployed, the third servomotor 41 drives the third gear 42 to move on the third rack 43, so that the electrocardiograph 5 is moved to the corresponding electrocardiograph mounting base 4, and the hydraulic pump 19 controls the deployment rod 20 to retract.

Secondly, when fixing the electrocardiograph 5 and the electrocardiograph mounting seat 4, the medical staff presses the pressing push rod 32 and compresses the second return spring 33, the pressing push rod 32 drives the locking push rod 31 to be inserted downwards into the second positioning cavity 27, the locking push rod 31 rotates in the second positioning cavity 27 and the sliding cavity 30, when the tip position of the sliding groove 34 on the locking push rod 31 rotates to the tip position of the ratchet wheel structure of the sliding claw sleeve 28, the sliding claw sleeve 28 is clamped at the position of the sliding groove 34, the locking separation of the electrocardiograph 5 and the electrocardiograph mounting seat 4 is realized, when the electrocardiograph 5 and the electrocardiograph mounting seat 4, the pressing push rod 32 is pressed by the medical staff, the pressing push rod 32 drives the locking push rod 31 to move downwards and simultaneously the locking push rod 31 rotates, the tip position of the ratchet wheel structure of the sliding claw sleeve 28 is separated from the sliding groove 34, the second return spring 33 drives the locking push rod 31 to leave the second positioning cavity 27 by using the self elasticity, the separation of the electrocardiograph 5 and the electrocardiograph mounting seat 4 is realized.

Therefore, the invention provides an integrated device for intelligent allocation and monitoring data acquisition of an electrocardiograph, which is an intelligent integrated device capable of operating the electrocardiograph 5 in a medical care room, freely allocating all electrocardiographs 5, realizing data acquisition intellectualization and saving time.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the invention, and any modifications, equivalents, improvements and the like that fall within the spirit and principle of the present invention are intended to be included therein.

Claims

1. An integrated device for intelligent allocation and monitoring data acquisition of an electrocardiograph is characterized by comprising two rows of ward groups arranged in parallel and a medical care control room, wherein each row of ward group comprises a plurality of wards arranged in sequence,

an industrial personal computer for controlling the first power device, the second power device, the third power device and the hydraulic pump is arranged in the medical care control room;

each electrocardiograph allocation device comprises a hydraulic cylinder body arranged on the allocation mounting plate, each hydraulic cylinder body is provided with an oil inlet and an oil outlet, two hydraulic chambers extending along the X-axis direction are arranged in the hydraulic cylinder body, each hydraulic chamber is provided with a hydraulic oil inlet communicated with the oil inlet and a hydraulic oil outlet communicated with the oil outlet, the hydraulic oil inlet and the hydraulic oil outlet are communicated with a hydraulic pump through hydraulic pipelines, an allocation rod is slidably arranged in each hydraulic chamber, the end part of each allocation rod is provided with a first positioning groove, each electrocardiograph is provided with two allocation positioning cavities extending along the X-axis, each allocation positioning cavity is internally provided with a first limiting cavity extending along the Z-axis, and each first limiting cavity is internally provided with a limiting ball matched with the first positioning groove, a first return spring is arranged between the first limiting cavity and the limiting ball;

each locking device comprises a second positioning cavity arranged on the electrocardiograph mounting seat, a sliding claw sleeve extending along the Z-axis direction is arranged in each second positioning cavity, the teeth of each sliding claw sleeve are of a ratchet wheel structure, a bump is arranged on each electrocardiograph, a sliding cavity is arranged in each bump, a locking push rod arranged opposite to the sliding claw sleeve is arranged in each sliding cavity, a pressing push rod is arranged at the other end of each push rod, each pressing push rod extends out of the bump, and a second reset spring is sleeved on each pressing push rod;

one end of each locking push rod is provided with a tooth column of a mountain ratchet wheel structure matched with the mountain ratchet wheel structure of the sliding claw sleeve, and the outer surface of each locking push rod is provided with a plurality of sliding grooves extending along the Z-axis direction.

2. The integrated electrocardiograph intelligent deployment and monitoring data acquisition device according to claim 1, wherein each of the first power devices is a first rack-and-pinion mechanism driven by a first servo motor, a motor housing of each of the first servo motors is fixedly mounted on the electrocardiograph mounting base, each of the first gears is mounted on a motor shaft of the first servo motor, and each of the first racks extending in the X-axis direction is disposed on a wall of the patient room.

3. The integrated electrocardiograph intelligent deployment and monitoring data acquisition device according to claim 1, wherein each second power device is a second rack-and-pinion mechanism driven by a second servo motor, a motor housing of each second servo motor is fixedly mounted on the Y-axis mounting plate, each second gear is mounted on a motor shaft of the second servo motor, and each second rack extending in the Y-axis direction is disposed on the top of the corridor of the patient room group.

4. The integrated electrocardiograph intelligent deployment and monitoring data acquisition device according to claim 1, wherein each third power device is a third rack-and-pinion mechanism driven by a third servo motor, a motor housing of each third servo motor is fixedly mounted on the deployment mounting plate, each third gear is mounted on a motor shaft of the third servo motor, and each third rack extending in the Z-axis direction is disposed on the Y-axis mounting plate.

5. The integrated equipment for intelligent allocation and monitoring data acquisition of electrocardiographs according to claim 1, wherein each electrocardiograph mounting seat is provided with a lead wire sub-connector, each lead wire sub-connector is electrically connected with a lead wire, each electrocardiograph is electrically connected with a lead wire female connector matched with the lead wire sub-connector, and a connection positioning device is arranged between each lead wire sub-connector and the lead wire female connector.

6. The integrated electrocardiograph blending and monitoring data collecting device as claimed in claim 5, wherein each of the plugging positioning devices comprises a limiting rod fixed to the bottom of the connecting sub-connector and a plugging groove disposed at the end of the connecting bus connector, each of the limiting rods is inserted into the plugging groove, a second positioning groove is disposed at the bottom of each plugging groove, a second limiting cavity is disposed at the end of each limiting rod, a limiting block adapted to the second positioning groove is disposed in each second limiting cavity, and a third return spring is disposed between each second limiting cavity and the limiting block.