CN205729352U - Conducting wire cable structure and cardioelectric monitor equipment - Google Patents

Abstract

The utility model discloses a lead cable structure and ECG monitoring equipment, comprising a first branching device, a first main cable, a body lead wire group, a chest lead wire group, and a second branch device, Wherein, one end of the first branching device is provided with the limb lead wire set and the first main cable, the limb lead wire set is arranged side by side with the first main cable, and the first main cable A cable connects the first branching device and the second branching device, and the chest lead line set is provided at an end of the second branching device away from the first main cable. The utility model also discloses an electrocardiogram monitoring device. The lead cable structure and the electrocardiogram monitoring device of the utility model have the advantages of simple structure, simple and convenient processing, lead wires are not easily entangled, and the human body feels comfortable.

Description

Lead cable structure and ECG monitoring equipment

technical field

The utility model relates to the technical field of medical equipment, in particular to a lead cable structure and an electrocardiographic monitoring device.

Background technique

Currently, lead cable structures are widely used in electrocardiographs or monitors. Among them, the main cable is divided into various lead wires after passing through the splitter, and the ends of each lead wire are respectively connected with electrodes, and each lead wire is connected to various parts of the human body surface through the electrodes, which are used to collect data from the human body. ECG signal. In the current ECG lead cable structure, multiple limb lead wires and multiple chest lead wires are separated from a splitter, and the setting of multiple limb lead wires and multiple chest lead wires leads to the The structure of the cable is complicated, and the connection processing between the lead wire and the splitter is cumbersome; and the slender lead wires are easy to be entangled, which also affects the service efficiency and life.

Utility model content

In view of this, the utility model provides a lead cable structure and an electrocardiogram monitoring device, wherein the structure of the branching device is simple, the processing process is simple, the human body feels comfortable, and the lead wire is not easily entangled.

A lead cable structure, including a first branching device, a first main cable, a limb lead wire set, and a chest lead wire set, the lead cable structure also includes a second branching device, an instrument end connection device and a second main cable, wherein one end of the first branching device is provided with the limb lead wire set and the first main cable, and the limb lead wire set is arranged side by side with the first main cable Setting, each limb lead wire in the limb lead wire group is provided with wires, the first main cable connects the first branching device and the second branching device, and the second branching device One end of the sub-connection device away from the first main cable is provided with the chest lead wire set, and the opposite ends of the second main cable are respectively connected to the instrument end connector and the first sub-connection device. One end away from the first main cable, the second main cable includes a first wire group and a second wire group, the first wire group and the second wire group each include a plurality of wires, the first The wires in the wire group are respectively electrically connected to the wires in each limb lead wire in the limb lead wire group; the first main cable includes a plurality of wires, and the wires in the second wire group are directly connected to each other. As a conductor in the first main cable.

Wherein, the length of each chest lead wire in the chest lead wire group is less than the length of any limb lead wire in the limb lead wire group.

Wherein, each limb lead wire in the limb lead wire group is away from the end of the first branching device, and each chest lead wire in the chest lead wire group is far away from the end of the first branching device. One end of the two branching devices is provided with a human body end connector.

Wherein, both the first branching device and the second branching device are line splitters.

A kind of electrocardiogram monitoring equipment, has lead cable structure, and described lead cable structure comprises first sub-connection device, first main cable, limb lead wire group, chest lead wire group, and described lead wire The cable structure also includes a second branching device, an instrument end connector and a second main cable, wherein one end of the first branching device is provided with the limb lead wire set and the first main cable, the The limb lead wire group is arranged side by side with the first main cable, each limb lead wire in the limb lead wire group is provided with a wire, and the first main cable is connected to the first branching device As with the second branching device, the chest lead wire set is provided on the end of the second branching device away from the first main cable, and the opposite ends of the second main cable are respectively connected to the The instrument end connector is connected to one end of the first branching device away from the first main cable, and the second main cable includes a first wire group and a second wire group, and the first wire group is connected to the first wire group. The two wire groups each include a plurality of wires, and the wires in the first wire group are electrically connected to the wires in each limb lead wire in the limb lead wire group; the first main cable includes multiple wires. wires, and the wires in the second wire group directly serve as wires in the first main cable.

Wherein, the length of each chest lead wire in the chest lead wire group is less than the length of any limb lead wire in the limb lead wire group.

Wherein, each limb lead wire in the limb lead wire group is away from the end of the first branching device, and each chest lead wire in the chest lead wire group is far away from the end of the first branching device. One end of the two branching devices is provided with a human body end connector.

Wherein, both the first branching device and the second branching device are line splitters.

Therefore, the lead cable structure and the ECG monitoring equipment of the present invention adopt a two-level branching scheme including the first branching device and the second branching device, wherein the same end of the first branching device is provided with multiple Limb lead wires and a main cable, one end of the second branch device is provided with multiple chest lead wires; at the same time, the first branch device and the second branch device are connected by the same main cable, thus the branch device The internal structure is relatively simple. At the same time, the two-level branching scheme can reduce the volume of a single branching device, thereby improving the patient's comfort.

Description of drawings

In order to more clearly illustrate the structural features and functions of the utility model, it will be described in detail below in conjunction with the accompanying drawings and specific embodiments.

Fig. 1 is a schematic diagram of the structure of the lead cable provided by the embodiment of the present invention.

Fig. 2 is a schematic diagram of the internal circuit structure of the first branching device shown in Fig. 1 .

detailed description

The following will clearly and completely describe the technical solutions in the embodiments of the present invention with reference to the drawings in the embodiments of the present invention. Apparently, the described embodiments are some of the embodiments of the present invention, but not all of them. Based on the embodiments of the present utility model, all other embodiments obtained by persons of ordinary skill in the art without creative efforts shall fall within the protection scope of the present utility model.

As shown in Figure 1, the lead cable structure 100 of the embodiment of the present invention includes a first branching device 120, a first main cable 130, a second branching device 140, a limb lead wire group 150 and a chest lead wire Group 160. The lead cable structure 100 can be used as an accessory of an electrocardiograph, and can also be applied to other electrocardiographs or other medical devices.

One end of the first branching device 120 is provided with a first main cable 130 and a limb lead wire set 150, and the first branching device 120 is the connection center of the first main cable 130 and the limb lead wire set 150, and simultaneously plays a role in connecting the first main cable 130 and the limb lead wire set 150 The protection function of the connecting contact between the main cable 130 and the limb lead wire set 150 . In this embodiment, the first branching device 120 is a cable splitter, wherein the body of the cable splitter and the cables branched out are a non-detachable integral body. The first branching device 120 may also be other devices having the above-mentioned functions, such as a connector. Wherein, the cable of the connector is detachably plugged into the connector body.

The first main cable 130 and the limb lead wire set 150 are located at the same end of the first branching device 120 and arranged side by side. The first main cable 130 connects the first branching device 120 and the second branching device 140 . The first main cable 130 includes a plurality of wires and a shielding layer. For example, in this embodiment, the first main cable 130 includes 6 wires, and the 6 wires are surrounded by a shielding layer.

The second branching device 140 is provided with a chest lead wire set 160 at its end away from the first main cable 130 . The second branching device 140 is the connection hub between the first main cable 130 and the chest lead wire set 160 , and also serves as a protection function for the connection contacts between the main cable 130 and the chest lead wire set 160 . Likewise, in this embodiment, the second branching device 140 is a cable splitter, wherein the body of the cable splitter and the cables it branches out form a non-detachable integral body. The second branching device 140 may also be other devices having the above-mentioned functions, such as a connector. Wherein, the cable of the connector is detachably plugged into the connector body.

The limb lead wire set 150 extends from one end of the first branching device 120 and is separately and symmetrically arranged on both sides of the first main cable 130 . In the present invention, the relative positions of the limb lead wires in the limb lead wire group 150 and the first main cable 130 can be arranged according to specific conditions. For example, all the limb lead wires in the limb lead wire group 150 may also be arranged on the same side of the first main cable 130 . In this embodiment, as shown in FIG. 1 , the limb lead wire group 150 includes 4 limb lead wires, and each limb lead wire has the same length, wherein each limb lead wire is provided with 1 wire and shield. But in fact, the solution of the present invention is not limited thereto. According to specific medical scenarios, the number of corresponding limb lead wires can be set, and the length of each limb lead wire can be flexibly set.

The chest lead wire set 160 extends from an end of the second branching device 140 away from the first main cable 130 . As shown in FIG. 1 , in this embodiment, the chest lead wire set 160 includes 6 chest lead wires, and each chest lead wire has the same length. Wherein, each chest lead wire is provided with a wire and a shielding layer. But in fact, the solution of the present invention is not limited thereto. According to specific medical scenarios, the number of corresponding chest lead wires can be set, and the length of each chest lead wire can be flexibly set.

In this embodiment, the length of each of the 6 chest lead wires is shorter than the length of each of the 4 limb lead wires. For example, each limb lead wire is set to 60 cm, and each chest lead wire is set to 15 cm-30 cm. Therefore, the chest lead wire and the limb lead wire are easily distinguished, and are not easy to be entangled, thereby improving the use efficiency and prolonging the service life.

In this embodiment, as shown in FIG. 1, each chest lead wire extends from the end of the second branching device 140 away from the first main cable 130, and the extended end of each chest lead wire is also provided with a human body end connector 170 . Similarly, each limb lead wire extends from one end of the first branching device 120 , and the extension end of each limb lead wire is also provided with a human body end connector 170 . The human body end connector 170 directly contacts the body surface of the human body, so as to collect the electrocardiographic signals of the human body. The human body connector 170 includes, but is not limited to, limb sandwich electrodes, chest suction ball ECG electrodes, and the like.

The lead cable structure 100 of this embodiment adopts a two-stage branching scheme including a first branching device 120 and a second branching device 140 . The same end of the first branching device 120 is provided with 4 limb lead wires and 1 main cable, and one end of the second branching device 140 is provided with 6 chest lead wires. If only one branching device is used to separate multiple limb lead wires and multiple chest lead wires, the internal structure of the branching device will be complicated and the processing cost will be increased. However, the solution of the utility model avoids this defect, and the internal structure of the branching device is comparatively simple. In addition, in the actual medical process, the sub-connection device is attached to the patient's body surface, and a large-volume sub-connection device will affect the comfort of the human body. In the first-level splitting scheme using only one splitting device, the volume of the splitting device is larger; and the second-level splitting scheme in this embodiment, compared with the first-level splitting scheme, can The volume of the individual branching devices is reduced, thereby also increasing patient comfort.

In this embodiment, as shown in FIG. 1 , the lead cable structure 100 further includes an instrument end connector 180 and a second main cable 110 . The instrument end connector 180 is connected to an end of the first branching device 120 away from the first main cable 130 through the second main cable 110 . The instrument end connector 180 is connected to the corresponding interface of the electrocardiograph, and transmits the collected electrocardiographic signal to the processing unit of the electrocardiograph.

Further, as shown in FIG. 2 , a printed circuit board 121 is disposed inside the first branching device 120 . The second main cable 110 includes a first wire group 122 and a second wire group 123 , and both the first wire group 122 and the second wire group 123 include a plurality of wires. In this embodiment, the first wire group 122 includes 4 wires, and the second wire group includes 6 wires. The 4 wires in the first wire group 122 are respectively soldered to one end of the printed circuit board 121 near the instrument end connector 180; the 4 wires in the 4 limb wires in the limb wire group 150 are respectively soldered to the printed circuit board The end of the board 121 away from the instrument end connector 180 , and the four wires in the first wire group 122 are respectively electrically connected to the four wires in the limb lead wire on the printed circuit board 121 . The 6 wires in the second wire group directly serve as the 6 wires in the first main cable 130 . In this embodiment, the second main cable 110 includes 10 wires, the first wire group 122 includes 4 wires, and the second wire group 123 includes 6 wires as an example for description, but in fact the utility model is not limited to this. The number of wires in the second main cable 110, the number of wires in the first wire group 122, and the number of wires in the second wire group 123 are determined according to specific medical needs. In other embodiments, different from this embodiment, the four wires in the first wire group 122 and the four wires in the four limb lead wires in the limb lead wire group 150 can also be electrically connected in other ways. sexual connection. For example, soldering together directly; or crimping together through terminal blocks.

As shown in FIG. 1 , the first main cable 130 extends from one end of the first branching device 120 and is connected to one end of the second branching device 140 . A printed circuit board is also arranged inside the second branching device 140 . In the second branching device 140, the 6 wires in the first main cable 130 are welded to one end of the printed circuit board respectively, and the 6 wires in the 6 chest lead wires in the chest lead wire set 160 are respectively soldered to one end of the printed circuit board. It is soldered to the other end of the printed circuit board, and the 6 wires in the first main cable 130 are respectively electrically connected to the 6 wires in the chest lead wire through the printed circuit board. Therefore, only one main cable 130 is needed to connect the first branching device 120 and the second branching device 140 , thereby simplifying the manufacturing process, making the structure of the lead cable simple and reducing the cost. In other implementations of this embodiment, the first main cable, the second main cable, the wires in each limb lead wire and the wires in each chest lead wire can also be connected to the printed circuit board in other ways. The first main cable 130, the second main cable 110, each limb lead wire, and each chest lead wire also include a shielding layer (not marked in the figure), and the shielding layer is stripped from the wire when the circuit is connected. , twisted into a wire, and then connected to the printed circuit board. In other embodiments, different from this embodiment, the 6 wires in the first main cable 130 and the 6 wires in the 6 chest lead wires in the chest lead wire set 160 can also be electrically connected in other ways. sexually connected. For example, soldering together directly; or crimping together through terminal blocks.

The utility model also provides an electrocardiogram monitoring device. The electrocardiographic monitoring device has the lead cable structure 100 , and the electrocardiographic monitoring device includes, but is not limited to, medical equipment such as an electrocardiograph.

It should be understood that the structure or function of each component in the ECG monitoring device corresponds to the corresponding content described in the above embodiments, and for the sake of brevity, details are not repeated here.

The above is only a specific embodiment of the utility model, but the scope of protection of the utility model is not limited thereto. Any person familiar with the technical field can easily think of various Any equivalent modification or replacement should be covered by the protection scope of the present utility model. Therefore, the protection scope of the present utility model should be based on the protection scope of the claims.

Claims (8)

1. a conducting wire cable structure, including first point of coupling device, the first leader cable, limb lead line group, chest leads line group, it is characterised in that

nullDescribed conducting wire cable structure also includes second point of coupling device、Instrument terminal adapter and the second leader cable，Wherein，One end of described first point of coupling device is provided with described limb lead line group and described first leader cable，Described limb lead line group is arranged side by side with described first leader cable，It is provided with wire in each bar limb lead line in described limb lead line group，Described first leader cable connects described first point of coupling device and described second point of coupling device，On described second point of coupling device, the one end away from described first leader cable is provided with described chest leads line group，The two ends that described second leader cable is relative connect the one end on described instrument terminal adapter and described first point of coupling device away from described first leader cable respectively，Described second leader cable includes the first wire group and the second wire group，Described first wire group and described second wire group all include a plurality of wire，Wire in described first wire group is electrical connected with the wire in each bar limb lead line in described limb lead line group respectively；Described first leader cable includes a plurality of wire, and the wire in described second wire group is directly as the wire in described first leader cable.

2. according to the conducting wire cable structure described in claim 1, it is characterised in that in described chest leads line group, the length of every chest leads line is less than the length of any one limb lead line in described limb lead line group.

Conducting wire cable structure the most according to claim 1 and 2, it is characterized in that, it is provided with human body terminal adapter away from one end away from described second point of coupling device on every chest leads line in one end of described first point of coupling device, and described chest leads line group on every limb lead line in described limb lead line group.

Conducting wire cable structure the most according to claim 1 and 2, it is characterised in that described first point of coupling device and described second point of coupling device are deconcentrator.

5. a cardioelectric monitor equipment, has conducting wire cable structure, and described conducting wire cable structure includes first point of coupling device, the first leader cable, limb lead line group, chest leads line group, it is characterised in that

nullDescribed conducting wire cable structure also includes second point of coupling device、Instrument terminal adapter and the second leader cable，Wherein，One end of described first point of coupling device is provided with described limb lead line group and described first leader cable，Described limb lead line group is arranged side by side with described first leader cable，It is provided with wire in each bar limb lead line in described limb lead line group，Described first leader cable connects described first point of coupling device and described second point of coupling device，On described second point of coupling device, the one end away from described first leader cable is provided with described chest leads line group，The two ends that described second leader cable is relative connect the one end on described instrument terminal adapter and described first point of coupling device away from described first leader cable respectively，Described second leader cable includes the first wire group and the second wire group，Described first wire group and described second wire group all include a plurality of wire，Wire in described first wire group is electrical connected with the wire in each bar limb lead line in described limb lead line group respectively；Described first leader cable includes a plurality of wire, and the wire in described second wire group is directly as the wire in described first leader cable.

6. according to the cardioelectric monitor equipment described in claim 5, it is characterised in that in described chest leads line group, the length of every chest leads line is less than the length of any one limb lead line in described limb lead line group.

7. according to the cardioelectric monitor equipment described in claim 5 or 6, it is characterized in that, it is provided with human body terminal adapter away from one end away from described second point of coupling device on every chest leads line in one end of described first point of coupling device, and described chest leads line group on every limb lead line in described limb lead line group.

8. according to the cardioelectric monitor equipment described in claim 5 or 6, it is characterised in that described first point of coupling device and described second point of coupling device are deconcentrator.