CN220578597U - Electrocardiogram monitoring pipeline collector - Google Patents

Abstract

The utility model discloses an electrocardiograph monitoring pipeline collector, and relates to the technical field of electrocardiograph monitors. Comprising the following steps: the multi-pipeline folding mechanism is used for folding a plurality of pipelines which run in parallel, the multi-pipeline folding mechanisms are in a plurality of groups with the same structure, each two adjacent groups of multi-pipeline folding mechanisms in the multi-pipeline folding mechanism are connected through a splicing mechanism, and the plurality of groups of multi-pipeline folding mechanisms are spliced to prolong the length of the folded pipelines; and the long pipeline independent winding mechanism is arranged on one group of the multi-pipeline folding mechanisms positioned at the forefront end in the wiring direction in the multi-pipeline folding mechanisms, and the long pipeline independent winding mechanism is used for winding one or more pipelines with the length longer than that of the rest pipelines in the pipelines.

Description

Electrocardiogram monitoring pipeline collector

Technical Field

The utility model relates to the technical field of electrocardiograph monitors, in particular to an electrocardiograph monitoring pipeline collector.

Background

The electrocardiograph is a basic and common monitoring means in intensive care units, and needs to be rapid and accurate in use. When monitoring is implemented, the electrocardiograph monitor pipeline is messy, the ward is tidy, discomfort is caused to a patient, or the cable is folded to be angled after being used and is easy to break, so that the service life of the instrument is influenced; various leads of the electrocardiograph monitor are numerous and long, if the leads are not well fixed, the electrocardiograph monitor is inconvenient to use, and if a patient is rescued, the rescue opportunity can be delayed. To ensure the cleanliness and the beauty of the bed unit, nurses often spend more time arranging various pipelines, and the workload of the nurses is increased to a certain extent. Currently, for scattered electrocardiographic monitoring pipelines, a common collecting mode is to bind a plurality of cables at one place by winding cables, or to solve the problem that the pipeline length is too long to be scattered by winding the pipeline.

As in the prior art, publication (bulletin) numbers: CN 212687251U, patent title: the utility model relates to an electrocardiograph monitor lead wire collector which consists of a plurality of collector components, wherein each collector component comprises a fixed rod, a winding rod, an outer box and a spiral spring, the outer box is of a cavity structure, the fixed rod is fixedly connected inside the outer box, the fixed rod is connected with the inner wall of the winding rod through a rotating bearing, the spiral spring is fixedly connected between the winding rod and the fixed rod, the middle part of the winding rod is connected with a lead wire fixing plate through bolts, spiral winding grooves extending along the axial direction of the winding rod are symmetrically arranged on the outer wall of the winding rod by taking the lead wire fixing plate as a center, and lead wires symmetrically wind at two sides of the lead wire fixing plate along the winding rod and respectively penetrate through guide pipes and outlets on the outer box to extend to the outside of the outer box.

However, the collecting mode in the above patent is only suitable for collecting by a single pipeline, and cannot cope with the collection of a plurality of lead wires or pipelines of the electrocardiograph monitor; and the bundling is drawn in under the condition of encountering different pipeline lengths, the overlong pipeline can not be reasonably drawn in and collected, the neatness of pipeline arrangement can be influenced, and in order to simultaneously deal with the drawing in and collecting of a plurality of lead wires or pipelines of the electrocardiograph monitor, the rationality of pipeline collection is improved, and an electrocardiograph monitor pipeline collector is required to be designed.

Disclosure of Invention

The utility model aims to provide an electrocardiograph monitoring pipeline collector which can simultaneously deal with the gathering and collecting of a plurality of lead wires or pipelines of an electrocardiograph monitoring device and improve the rationality and the neatness of the collecting of the pipelines.

In order to achieve the above object, the present utility model provides the following technical solutions:

an electrocardiograph monitoring line collector of the present utility model includes:

the multi-pipeline folding mechanism is used for folding a plurality of pipelines which run in parallel, the multi-pipeline folding mechanisms are in a plurality of groups with the same structure, each two adjacent groups of multi-pipeline folding mechanisms in the multi-pipeline folding mechanism are connected through a splicing mechanism, and the plurality of groups of multi-pipeline folding mechanisms are spliced to prolong the length of the folded pipelines; and

the long pipeline independent winding mechanism is arranged on one group of the multi-pipeline folding mechanisms at the forefront end in the wiring direction in the multi-pipeline folding mechanisms, and the long pipeline independent winding mechanism is used for winding one or more pipelines with lengths longer than those of other pipelines in the pipelines.

Further, the multi-pipeline folding mechanism comprises pipeline supporting columns, and a plurality of groups of pipeline embedding openings are uniformly distributed on the circumference of the pipeline supporting columns;

the pipeline embedding openings are arranged in parallel.

Further, the pipeline embedding opening is a cylindrical hole structure with a notch at one side and the notch faces the outer side of the pipeline supporting cylinder, the radius value of the cylindrical hole structure of the pipeline embedding opening is larger than the notch width value of the pipeline embedding opening, and the cylindrical hole structure of the pipeline embedding opening is parallel to the axis of the pipeline supporting cylinder.

Further, the pipeline supporting column body is elastic rubber with a cylindrical structure.

Further, the splicing mechanism comprises a splicing column and a splicing groove;

and the center positions of the two end surfaces of the pipeline supporting column body are respectively provided with the splicing column and the splicing groove.

Further, the spliced pole is elastic rubber with a cylindrical structure.

Further, the long-pipe individual winding mechanism includes:

a support block connected to the pipeline support column; and

the winding mechanisms are in multiple groups with the same structure and are circumferentially arranged on the supporting blocks.

Further, each group of the winding mechanism comprises:

a winding rod vertically connected to a side surface of the support block;

the limiting block is connected to one end, opposite to the supporting block, of the winding rod;

the loading box is provided with an opening at one end and the limiting block extends into the loading box, the limiting block slides in the loading box, a threaded hole is formed in one side, opposite to the opening, of the loading box, a threaded rod in threaded fit with the threaded hole is arranged in the threaded hole, and a threaded groove corresponding to the threaded rod and in threaded fit with the threaded rod are formed in the surface, facing the threaded hole, of the limiting block;

the sliding limiting openings are two groups symmetrically arranged on the surfaces of two sides of the loading box;

the sliding blocks are symmetrically arranged on the two side surfaces of the limiting block and are arranged in one-to-one correspondence with the two groups of sliding limiting openings, and the sliding blocks slide in the corresponding sliding limiting openings; and

the avoidance openings are symmetrically formed in the loading box and distributed adjacent to the side surfaces of the two groups of sliding limiting openings, and are used for avoiding pipelines;

when the threaded rod is screwed into the threaded groove and the bottom surface of the loading box is tightly propped against the limiting block, the winding rod is positioned in the loading box.

In the technical scheme, the electrocardiograph monitoring pipeline collector provided by the utility model has the following beneficial effects:

the multi-pipeline folding mechanism is used for folding the pipelines, so that the pipelines are prevented from being scattered, the multi-group multi-pipeline folding mechanism is used for splicing the multi-pipeline folding mechanism to prolong the length of the folded pipelines, various use requirements are met, when the length of a single pipeline or a plurality of pipelines is longer than that of other pipelines, the long pipeline is further used for winding and collecting the single pipeline through the long pipeline single winding mechanism, the bundled pipeline is collected and the wound pipeline is collected and used in a combined mode, and the plurality of pipelines used by the electrocardiograph monitor are collected and tidied better.

Drawings

In order to more clearly illustrate the embodiments of the present application or the technical solutions in the prior art, the drawings that are needed in the embodiments will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments described in the present utility model, and other drawings may be obtained according to these drawings for a person having ordinary skill in the art.

Fig. 1 is a schematic structural diagram of an electrocardiograph monitoring line collector according to an embodiment of the present utility model;

fig. 2 is a schematic distribution diagram of pipeline embedded openings of an electrocardiograph monitoring pipeline collector according to an embodiment of the present utility model;

fig. 3 is a schematic structural view of a winding rod in a separate winding mechanism of a line of an electrocardiograph monitoring line collector in the loading box according to an embodiment of the present utility model;

fig. 4 is a schematic distribution diagram of a sliding limiting opening and an avoiding opening on a loading box of an electrocardiograph monitoring line collector according to an embodiment of the present utility model.

Reference numerals illustrate:

1. a pipeline support column; 2. pipeline embedding notch; 3. splicing columns; 4. a splice groove; 5. a support block; 6. a winding rod; 7. a limiting block; 8. loading a box; 9. a threaded hole; 10. a threaded rod; 11. a thread groove; 12. sliding limit openings; 13. a sliding block; 14. avoiding the notch.

Detailed Description

In order to make the technical scheme of the present utility model better understood by those skilled in the art, the present utility model will be further described in detail with reference to the accompanying drawings.

See fig. 1-4;

an electrocardiograph monitoring line collector of the present embodiment includes:

the multi-pipeline folding mechanism is used for folding a plurality of pipelines which run in parallel, the multi-pipeline folding mechanisms are in a plurality of groups with the same structure, every two adjacent groups of multi-pipeline folding mechanisms in the multi-group multi-pipeline folding mechanism are connected through a splicing mechanism, and the multi-group multi-pipeline folding mechanisms are spliced to prolong the length of the folded pipelines so as to meet the folding requirement of the pipelines with longer lengths; and

the long pipeline independent winding mechanism is arranged on a group of multi-pipeline folding mechanisms positioned at the forefront end of the wiring direction in the multi-group multi-pipeline folding mechanisms, and is used for winding one or more pipelines with lengths longer than other pipelines in the pipelines, so that the pipelines are reasonably collected in a better collecting mode under the condition that the lengths of the pipelines are different.

Further, the multi-pipeline folding mechanism comprises a pipeline supporting column body 1, and a plurality of groups of pipeline embedding openings 2 are uniformly distributed on the circumference of the pipeline supporting column body 1;

the multiple groups of pipelines are embedded into the notch 2 and are mutually parallel.

Specifically, the pipeline is directly embedded into the pipeline embedding gap 2 on the pipeline supporting column body 1 for fixing, and the diameter of the pipeline embedding gap 2 can be preset according to the pipeline size so as to better match the pipeline for fixing. Or when the device is used on other instruments, the bandage with the magic tape is arranged on the outer side of the pipeline supporting column body 1, the pipeline supporting column body 1 is wound for one circle and then fixed through the magic tape, and further the pipeline is embedded into the pipeline embedded notch 2 for fixation in advance and then further wound fixation is carried out.

Further, the pipeline embedding gap 2 is a cylindrical hole structure with a notch at one side and the notch faces the outer side of the pipeline supporting column 1, the radius value of the cylindrical hole structure of the pipeline embedding gap 2 is larger than the notch width value, and the cylindrical hole structure of the pipeline embedding gap 2 is parallel to the axis of the pipeline supporting column 1.

The pipeline is embedded into the pipeline embedding notch 2 to fix a notch on one side of the pipeline embedding notch, so that the distribution trend situation of the pipeline can be conveniently observed, and the pipeline is convenient to distinguish in the subsequent use process.

Further, the pipeline supporting column 1 is elastic rubber with a cylindrical structure. The elastic rubber has elasticity, and simultaneously meets the strength of supporting the pipeline, and the pipeline is embedded into the pipeline to be fixed in the notch 2, and the elastic rubber of the pipeline supporting column 1 is utilized, so that the notch position can be elastically deformed under the condition that the caliber of the notch is smaller than the diameter of the pipeline to enable the pipeline to enter the pipeline to be embedded into the notch 2, and the pipeline is embedded into the notch 2 to play a limiting role on the pipeline after the position rebounds, so that the pipeline is collected.

Further, the splicing mechanism comprises a splicing column 3 and a splicing groove 4;

and splicing columns 3 and splicing grooves 4 are respectively arranged at the central positions of the two end faces of the pipeline supporting column 1.

Specifically, in the two adjacent groups of pipeline supporting columns 1, the splicing connection of the two groups of pipeline supporting columns 1 is realized in a connection mode that the splicing columns 3 are inserted into the splicing grooves 4, so that the extension length of the pipeline supporting columns 1 and the pipeline embedding openings 2 is prolonged.

Further, the spliced pole 3 is elastic rubber with a cylindrical structure. The elastic rubber has elasticity, so that the splicing column 3 and the splicing groove 4 are in interference fit, the splicing column 3 is extruded into the splicing groove 4 to be connected by utilizing the elastic characteristics of the splicing column 3 and the splicing groove, and the connection of the two groups of pipeline supporting columns 1 is completed by utilizing factors such as friction force between the splicing column 3 and the splicing groove. The connection of the pipeline supporting columns 1 does not need excessive connection strength, and only needs to complete connection aggregation of the pipeline supporting columns 1, because the pipeline supporting columns 1 do not need to bear axial tension and are installed along the extension of a plurality of pipelines in the distribution direction, the pipeline supporting columns cannot be subjected to tension, or the connection of the pipeline supporting columns 1 cannot influence the bundling and collecting of the plurality of pipelines, but the interconnection of the plurality of groups of pipeline supporting columns 1 can be more convenient for collecting the plurality of pipelines. The spliced pole 3 is not limited to elastic rubber, and the requirement can be met by using hard plastic.

Further, the long-pipe individual winding mechanism includes:

a support block 5 connected to the pipeline support column 1; and

the winding mechanisms are of the same structure, are arranged on the supporting blocks 5 in a circumferential direction, and are used for winding and fixing one or more pipelines with overlong lengths.

Further, each winding mechanism includes:

a winding rod 6 vertically connected to a side surface of the support block 5;

a limiting block 7 connected to one end of the winding rod 6 opposite to the supporting block 5;

the loading box 8 is provided with an opening at one end, the limiting block 7 extends into the loading box 8, the limiting block 7 slides in the loading box 8, a threaded hole 9 is formed in one side, opposite to the opening, of the loading box 8, a threaded rod 10 in threaded fit with the threaded hole 9 is arranged in the threaded hole 9, and a threaded groove 11 corresponding to the threaded rod 10 is formed in the surface, facing the threaded hole 9, of the limiting block 7 and is in threaded fit with the threaded rod 10;

the sliding limiting openings 12 are two groups symmetrically arranged on the two side surfaces of the loading box 8;

the sliding blocks 13 are symmetrically arranged on the two side surfaces of the limiting block 7 and are arranged in one-to-one correspondence with the two groups of sliding limiting openings 12, and the sliding blocks 13 slide in the corresponding sliding limiting openings 12; and

the avoidance notch 14 is formed by two groups of symmetrical openings on the loading box 8 and is distributed adjacent to the side surface where the two groups of sliding limiting openings 12 are located, and the avoidance notch 14 is used for avoiding pipelines;

when the threaded rod 10 is screwed into the threaded groove 11 and the bottom surface of the loading box 8 is tightly propped against the limiting block 7, the winding rod 6 is positioned in the loading box 8.

Specifically, the overlong pipeline directly stretches out and winds on the winding rod 6, and then the loading box 8 is buckled on the winding rod 6 to play a role in shielding the wound pipeline, so that two ends of the wound pipeline respectively stretch out from the avoiding openings 14 at two sides of the loading box 8 without affecting the normal use of the winding pipeline. Wherein the movement of the loading box 8 is supported by the limiting block 7, and the sliding block 13 slides in the sliding limiting opening 12 for guiding, so that the loading box 8 is not separated from the limiting block 7. When the loading box 8 is buckled on the winding rod 6 and the wound pipeline is shielded, namely, when the bottom surface of the loading box 8 is propped against the limiting block 7, the threaded rod 10 is screwed to be in threaded fit with the threaded groove 11 so as to fix the loading box 8 on the limiting block 7, so that the wound pipeline is firmly shielded, a certain protection effect is achieved, the length of the pipeline with overlong length is shortened, and the collection effect of a plurality of pipelines is better.

In the technical scheme, the electrocardiograph monitoring pipeline collector provided by the utility model has the following beneficial effects:

the multi-pipeline folding mechanism is used for folding the pipelines, so that the pipelines are prevented from being scattered, the multi-group multi-pipeline folding mechanism is used for splicing the multi-pipeline folding mechanism to prolong the length of the folded pipelines, various use requirements are met, when the length of a single pipeline or a plurality of pipelines is longer than that of other pipelines, the long pipeline is further used for winding and collecting the single pipeline through the long pipeline single winding mechanism, the bundled pipeline is collected and the wound pipeline is collected and used in a combined mode, and the plurality of pipelines used by the electrocardiograph monitor are collected and tidied better.

While certain exemplary embodiments of the present utility model have been described above by way of illustration only, it will be apparent to those of ordinary skill in the art that modifications may be made to the described embodiments in various different ways without departing from the spirit and scope of the utility model. Accordingly, the drawings and description are to be regarded as illustrative in nature and not as restrictive of the scope of the utility model, which is defined by the appended claims.

Claims (4)

1. An electrocardiographic monitoring line collector, comprising:

the multi-pipeline folding mechanism is used for folding a plurality of pipelines which run in parallel, the multi-pipeline folding mechanisms are in a plurality of groups with the same structure, each two adjacent groups of multi-pipeline folding mechanisms in the multi-pipeline folding mechanism are connected through a splicing mechanism, and the plurality of groups of multi-pipeline folding mechanisms are spliced to prolong the length of the folded pipelines; and

the long pipeline independent winding mechanism is arranged on one group of multi-pipeline folding mechanisms positioned at the forefront end in the wiring direction in the multi-pipeline folding mechanisms, and is used for winding one or more pipelines with the length longer than that of the rest pipelines in the pipelines;

the multi-pipeline folding mechanism comprises pipeline supporting columns (1), wherein a plurality of groups of pipeline embedding openings (2) are uniformly distributed in the circumferential direction of the pipeline supporting columns (1);

the pipeline embedding openings (2) are arranged in parallel;

the pipeline embedding gap (2) is a cylindrical hole structure with a notch at one side and faces the outer side of the pipeline supporting column body (1), the radius value of the cylindrical hole structure of the pipeline embedding gap (2) is larger than the notch width value of the cylindrical hole structure, and the cylindrical hole structure of the pipeline embedding gap (2) is parallel to the axis of the pipeline supporting column body (1);

the long pipeline individual winding mechanism includes:

a support block (5) connected to the pipeline support column (1); and

the winding mechanisms are in a plurality of groups with the same structure and are circumferentially arranged on the supporting blocks (5);

each group of winding mechanisms comprises:

a winding rod (6) vertically connected to a side surface of the support block (5);

the limiting block (7) is connected to one end, opposite to the supporting block (5), of the winding rod (6);

the loading box (8) is provided with an opening at one end, the limiting block (7) extends into the loading box (8), the limiting block (7) slides in the loading box (8), a threaded hole (9) is formed in one side, opposite to the opening, of the loading box (8), a threaded rod (10) in threaded fit with the threaded hole is arranged in the threaded hole (9), and a threaded groove (11) corresponding to the threaded rod (10) is formed in the surface, facing to one side of the threaded hole (9), of the limiting block (7) and in threaded fit with the threaded rod (10);

the sliding limiting openings (12) are symmetrically arranged on two groups of the two side surfaces of the loading box (8);

the sliding blocks (13) are symmetrically arranged on two groups of the two side surfaces of the limiting block (7) and are arranged in one-to-one correspondence with the two groups of sliding limiting openings (12), and the sliding blocks (13) slide in the corresponding sliding limiting openings (12); and

the avoidance notch (14) is formed by two groups of symmetrical loading boxes (8) and is distributed adjacent to the side surfaces of the two groups of sliding limiting openings (12), and the avoidance notch (14) is used for avoiding pipelines;

when the threaded rod (10) is screwed into the threaded groove (11) and the bottom surface of the loading box (8) is tightly propped against the limiting block (7), the winding rod (6) is positioned in the loading box (8).

2. An electrocardiographic monitoring line collector according to claim 1, characterized in that the line support column (1) is a cylindrical structure of elastic rubber.

3. An electrocardiographic monitoring line collector according to claim 1, characterized in that the splicing mechanism comprises a splicing column (3) and a splicing groove (4);

the center positions of the two end faces of the pipeline supporting column body (1) are respectively provided with the splicing column (3) and the splicing groove (4).

4. An electrocardiographic monitoring line collector according to claim 3, characterized in that the spliced pole (3) is a cylindrical structure of elastic rubber.