CN215839100U

CN215839100U - Wire storage device for ECG monitor

Info

Publication number: CN215839100U
Application number: CN202121753576.7U
Authority: CN
Inventors: 李远娟; 刘二凤; 朱珠; 李秀丽; 马永贵
Original assignee: Individual
Current assignee: Individual
Priority date: 2021-07-29
Filing date: 2021-07-29
Publication date: 2022-02-18
Anticipated expiration: 2031-07-29

Abstract

The utility model relates to a wire storage device for an ECG monitor, which comprises a bracket, a platform arranged on the bracket and a plurality of wire collecting devices arranged on the platform, wherein each wire collecting device comprises a winding shaft and a winding box, the winding shafts are rotatably arranged in the winding boxes, wires are wound on the winding shafts, one ends of the wires extend out of the winding boxes and are connected with a monitor body, and the other ends of the wires extend out of the winding boxes and are connected with a monitoring end of a human body. The wire with the required length can be pulled out through the wire take-up device, the wire is pulled out conveniently and quickly, the winding shaft can be moved to rotate after the wire take-up device is used, the winding shaft winds the wire, and the wire is stored in the winding box. The plurality of wire take-up devices realize that different groups of wires are arranged orderly, thereby being convenient for carrying out the electrocardiographic monitoring.

Description

Wire storage device for ECG monitor

Technical Field

The utility model relates to a storage device, in particular to a lead storage device for an electrocardiogram monitor.

Background

The clinical ECG monitor can collect, store and intelligently analyze the information of patient such as ECG waveform, pulse, respiration, invasive or non-invasive blood pressure, central venous pressure, blood oxygen saturation and the like, and further carry out diagnosis, early warning and the like.

The ECG monitor generally employs a plurality of wires to connect with the monitored body, including: electrocardiogram leads, oxyhemoglobin saturation probe leads and invasive or non-invasive blood pressure measuring leads. The length of the lead is 2.5-3.5 meters generally, one end of the lead is connected with the ECG monitor, the other end of the lead is provided with a connecting end connected with a human body, and a plurality of leads are easy to cross and wind during use, so that the use is inconvenient. In addition, when the distance between the patient and the ECG monitor is short, one end of the patient is easily pulled to be connected with the human body when the overlong lead falls down, so that external operation is influenced or the patient is easily damaged during the external operation.

Therefore, it is necessary to design a lead storage device for an electrocardiograph monitor, which can store each set of leads of the electrocardiograph monitor, so that the leads of each set are arranged in order.

SUMMERY OF THE UTILITY MODEL

The technical problem to be solved by the utility model is to provide a lead storage device for an electrocardiograph monitor, which can store each group of leads of the electrocardiograph monitor, so that the leads are arranged orderly.

In order to solve the technical problems, the utility model adopts the following technical scheme:

wire storage device for ECG monitor, including the support, install the platform on the support and place a plurality of take-up on the platform, take-up includes spool and wire winding box, the rotatable setting of spool is in the wire winding box, and the wire winding is on the spool, and wire one end stretches out the wire winding box outer with this body coupling of monitor, and the other end stretches out the wire winding box outer to be connected with human monitoring end.

As a further improvement of the above technical solution:

and the two ends of the winding shaft are provided with the reel type clockwork spring, the reel type clockwork spring is wound on the winding shaft, one end of the reel type clockwork spring is connected with the winding box, and the other end of the reel type clockwork spring is connected with the winding shaft. The wire is automatically wound on the spool by the elastic force of the reel spring. Does not need manual winding, and improves the working efficiency of medical personnel.

Furthermore, a partition plate is arranged in the winding box along the direction of the winding shaft, the partition plate divides the interior of the winding box into a left inner cavity and a right inner cavity, the lead is contained in the left inner cavity, and the reel type spring is contained in the right inner cavity. Prevent the movement of the reel spring and interfere with the winding of the wire around the spool.

The wire winding box is provided with two through holes at intervals, and two ends of the wire respectively penetrate out of the wire winding box through the two through holes; the wire winding box is provided with two fixing devices for fixing the wires, and the two fixing devices are respectively positioned at the two through holes. The rotation of the spool is prevented, and the spool is prevented from being driven to rotate by possible misoperation.

Furthermore, the fixing device comprises a first clamping arm and a second clamping arm, one end of the first clamping arm is hinged to one end of the second clamping arm through a rotating shaft, and the other end of the first clamping arm is connected with the other end of the second clamping arm through a bolt. The distance between the first clamping arm and the second clamping arm can be adjusted according to the size of the wire.

Furthermore, the first clamping arm comprises a first frame with an opening at the bottom and first wing plates protruding from two sides of the opening of the first frame, the second clamping arm comprises a second frame with an opening at the top and second wing plates protruding from two sides of the opening of the second frame, the first wing plate on one side is hinged with the second wing plate on the same side, and the first wing plate on the other side is connected with the second wing plate on the same side through bolts. First pterygoid lamina and second pterygoid lamina make first centre gripping arm and second centre gripping arm be connected more firmly.

Furthermore, the first frame is formed by laminating two wavy elastic plates. The wave-shaped elastic plate can fix wires with different diameters, and the friction force between the wires and the wave-shaped elastic plate can be increased, so that the wires can be fixed more firmly by the fixing device. Meanwhile, the wavy elastic plate has certain flexibility, so that the wire cannot be deformed by extrusion when being fixed, and the service life of the wire is prolonged.

Furthermore, the first frame and the second frame are both arc-shaped. The contact area between the wire and the wave-shaped elastic plate is increased, so that the wire is more firmly fixed by the fixing device.

Compared with the prior art, the utility model has the advantages that:

the wire with the required length can be pulled out through the wire take-up device, the wire is pulled out conveniently and quickly, the wire can be rotated by the winding shaft after use, and the winding shaft winds the wire to enable the wire to be stored in the winding box. The plurality of wire take-up devices realize that different groups of wires are arranged orderly, thereby being convenient for carrying out the ECG monitoring and prolonging the service life of the ECG monitor.

Drawings

Fig. 1 is a structural view of a lead wire storage device for an electrocardiograph monitor.

Fig. 2 is a sectional view of the wire takeup device.

Fig. 3 is a cross-sectional view of the fixation device.

Description of reference numerals:

1. a support; 2. a platform; 3. a take-up device; 4. an electrocardiograph monitor; 5. a fixing device; 6. a wire; 31. a winding box; 32. a spool; 33. a reel type spring; 34. a left inner cavity; 35. a right inner cavity; 36. a partition plate; 51. a first frame; 52. a first wing plate; 53. a first clamp arm; 54. a second wing plate; 55. a second frame; 56. a second clamp arm; 57. a rotating shaft; 58. and (4) bolts.

Detailed Description

In order that the above objects, features and advantages of the present invention can be more clearly understood, there will now be described in detail, with reference to the accompanying drawings, a non-limiting detailed description of the present invention.

As shown in fig. 1 to 3, the wire storage device for the electrocardiograph monitor of the present embodiment includes a support 1, a platform 2 installed on the support 1 and a plurality of wire take-up devices 3 placed on the platform 2, each wire take-up device 3 includes a winding reel 32 and a winding box 31, the winding reel 32 is rotatably disposed in the winding box 31, a wire 6 is wound on the winding reel 32, one end of the wire 6 extends out of the winding box 31 and is connected with the monitor body, and the other end extends out of the winding box 31 and is connected with the monitoring end of the human body. A winding spring 33 is provided at both ends of the winding shaft 32, the winding spring 33 is wound around the winding shaft 32, and one end of the winding spring 33 is connected to the winding case 31 and the other end is connected to the winding shaft 32. A partition 36 is provided in the winding case 31 along the direction of the winding shaft 32, the partition 36 partitions the inside of the winding case 31 into a left inner chamber 34 and a right inner chamber 35, the lead wire 6 is housed in the left inner chamber 34, and the winding spring 33 is housed in the right inner chamber 35.

Wherein, the winding box 31 is provided with two through holes at intervals, and two ends of the lead 6 respectively penetrate out of the winding box 31 through the two through holes; the winding box 31 is provided with two fixing devices 5 for fixing the wire 6, and the two fixing devices 5 are respectively positioned at the two through holes. The fixing device 5 comprises a first clamping arm 53 and a second clamping arm 56, one end of the first clamping arm 53 is hinged with one end of the second clamping arm 56 through a rotating shaft 57, and the other end of the first clamping arm 53 is connected with the other end of the second clamping arm 56 through a bolt 58. The first holding arm 53 includes a first frame 51 with an open bottom and first wing plates 52 protruding from both sides of the open bottom of the first frame 51, and the second holding arm 56 includes a second frame 55 with an open top and second wing plates 54 protruding from both sides of the open bottom of the second frame 55, wherein the first wing plate 52 on one side is hinged to the second wing plate 54 on the same side, and the first wing plate 52 on the other side is bolted 58 to the second wing plate 54 on the same side. The first frame 51 and the second frame 55 are each arc-shaped. The contact area between the first frame 51 and the lead 6 and the contact area between the second frame 55 and the lead 6 are increased, so that the lead 6 is clamped more stably. The first frame 51 is formed by attaching two wavy elastic plates.

For the use of this example, reference is made to the following steps:

when the lead 6 is connected to the electrocardiograph monitor 4, first, the bolt 58 near one end of the electrocardiograph monitor 4 is turned to increase the distance between the first holding arm 53 and the second holding arm 56 of the fixing device 5. Secondly, the lead 6 close to one end of the ECG monitor 4 is pulled, the lead 6 drives the winding shaft 32 to rotate, the lead 6 accumulated at one end close to the ECG monitor 4 is released through the winding shaft 32, and when the length of the pulled lead 6 reaches the required length, pulling is stopped. Then, the bolt 58 near one end of the electrocardiograph monitor 4 is rotated, and the first holding arm 53 and the second holding arm 56 hold the lead 6, so that the lead 6 is fixed. And finally, the connection of the lead 6 and the ECG monitor 4 is realized.

When in use, firstly, the patient lies on the sickbed. Next, the screw 58 near the patient end is turned to increase the distance between the first and second clamp arms 53, 56 of its fixation device 5. And thirdly, the lead 6 close to one end of the patient is pulled, the lead 6 drives the winding shaft 32 to rotate, the lead 6 stacked at one end close to the patient is released through the winding shaft 32, and when the length of the pulled lead 6 reaches the required length, the pulling is stopped. Then, the bolt 58 near one end of the patient is turned, and the first holding arm 53 and the second holding arm 56 hold the lead 6, so that the lead 6 is fixed. Finally, after use, the lead 6 is separated from the patient, the patient monitoring end of the lead 6 is released, and the lead 6 is automatically stored back into the winding box 31 due to the elastic action of the coil spring 33.

Claims

1. Wire storage device for ECG monitor, its characterized in that: including support (1), install platform (2) on support (1) and place a plurality of take-up (3) on platform (2), take-up (3) are including spool (32) and wire winding box (31), the rotatable setting of spool (32) is in wire winding box (31), wire (6) winding is on spool (32), wire (6) one end is stretched out outside wire winding box (31) and is connected with this body coupling of monitor, the other end stretches out outside wire winding box (31) and is connected with human monitoring end.

2. The lead storage device for an electrocardiograph monitor according to claim 1, wherein: and the two ends of the winding shaft (32) are provided with the reel type spring (33), the reel type spring (33) is wound on the winding shaft (32), one end of the reel type spring (33) is connected with the winding box (31), and the other end of the reel type spring (33) is connected with the winding shaft (32).

3. The lead storage device for an electrocardiograph monitor according to claim 2, wherein: a partition plate (36) is arranged in the winding box (31) along the direction of the winding shaft (32), the partition plate (36) divides the interior of the winding box (31) into a left inner cavity (34) and a right inner cavity (35), the conducting wire (6) is stored in the left inner cavity (34), and the coil spring (33) is stored in the right inner cavity (35).

4. The lead storage device for an electrocardiograph monitor according to claim 3, wherein: two through holes are formed in the winding box (31) at intervals, and two ends of the lead (6) penetrate out of the winding box (31) through the two through holes respectively; the winding box (31) is provided with two fixing devices (5) for fixing the lead (6), and the two fixing devices (5) are respectively positioned at the two through holes.

5. The lead storage device for the electrocardiograph monitor according to claim 4, wherein: the fixing device (5) comprises a first clamping arm (53) and a second clamping arm (56), one end of the first clamping arm (53) is hinged to one end of the second clamping arm (56) through a rotating shaft (57), and the other end of the first clamping arm (53) is connected with the other end of the second clamping arm (56) through a bolt (58).

6. The lead storage device for an electrocardiograph monitor according to claim 5, wherein: the first clamping arm (53) comprises a first frame (51) with an opening at the bottom and first wing plates (52) protruding out of two sides of the opening of the first frame (51), the second clamping arm (56) comprises a second frame (55) with an opening at the top and second wing plates (54) protruding out of two sides of the opening of the second frame (55), the first wing plate (52) on one side is hinged with the second wing plate (54) on the same side, and the first wing plate (52) on the other side is connected with the second wing plate (54) on the same side through bolts (58).

7. The lead storage device for an electrocardiograph monitor according to claim 6, wherein: the first frame (51) is formed by attaching two wavy elastic plates.