CN220585613U - Photoelectric communication composite cable connector - Google Patents

Abstract

The utility model discloses a photoelectric communication composite cable connector, which relates to the technical field of communication power supply and comprises a main connecting cable, a first quick connecting piece, a branch connecting cable and a second quick connecting piece; the first quick connecting piece is fixedly arranged at one end of the main connecting cable and is fixedly connected with one end of a wire core in the main connecting cable; one end of each branch connecting cable is fixedly connected to the outer side wall of the main connecting cable; each second quick connecting piece is fixedly connected to one end of each branch connecting cable far away from the main connecting cable; one end of the wire core in each branch connecting cable is fixedly connected to the first quick connecting piece or the wire core in the main connecting cable, and the other end of the wire core in each branch connecting cable is fixedly connected to each second quick connecting piece; the inner wire core of each branch cable and the inner wire core of the photoelectric communication composite cable can be communicated when the first quick connecting piece is connected with the third quick connecting piece, and each second quick connecting piece is connected with each fourth quick connecting piece; the construction efficiency can be effectively improved.

Description

Photoelectric communication composite cable connector

Technical Field

The utility model relates to the technical field of communication power supply, in particular to a photoelectric communication composite cable connector.

Background

The traditional power supply cable, signal cable and optical fiber cable are laid separately in the construction process, so that connection points are easy to damage, the service period of the cable is short, and the like. Chinese patent CN115862950a discloses a photoelectric communication composite cable, which integrates an optical fiber core, a power supply wire core and a signal transmission wire core, but when a branch cable is externally connected to the photoelectric communication composite cable, one end of the wire core in the branch cable is wound and bound or welded on a corresponding wire core in the photoelectric communication composite cable, which requires more manpower and time, and reduces construction efficiency.

Disclosure of Invention

The utility model aims to provide a photoelectric communication composite cable connector, which solves the problems in the prior art and can effectively improve the construction efficiency.

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

the utility model provides an optoelectronic communication composite cable connector, which comprises a main connecting cable, a first quick connecting piece, at least one branch connecting cable and at least one second quick connecting piece;

the first quick connector is fixedly arranged at one end of the main connecting cable and fixedly connected with one end of a wire core in the main connecting cable, and is used for being quickly connected with a third quick connector preassembled on the photoelectric communication composite cable;

one end of each branch connecting cable is fixedly connected to the outer side wall of the main connecting cable;

the number of the second quick connectors is equal to that of the branch connecting cables, the second quick connectors are fixedly connected to one ends of the branch connecting cables far away from the main connecting cables, and the second quick connectors are used for quick connection with fourth quick connectors preassembled on the branch cables;

one end of the wire core in each branch connecting cable is fixedly connected to the first quick connecting piece or the wire core in the main connecting cable, and the other end of the wire core in each branch connecting cable is fixedly connected to each second quick connecting piece;

the wire core in each branch cable and the wire core in the photoelectric communication composite cable can be communicated when the first quick connector is connected with the third quick connector and each second quick connector is connected with each fourth quick connector.

Preferably, the wire core in the main connection cable comprises a plurality of main connection power supply wire cores and a plurality of main connection signal transmission wire cores, and one end of each main connection power supply wire core and one end of each main connection signal transmission wire core are used for being fixedly connected with the first quick connecting piece;

the first ends of the sub-connection power supply wire cores are fixedly connected to part of the main connection power supply wire cores, each sub-connection power supply wire core is used for extending from the inside of the main connection cable to the inside of at least one sub-connection cable in each sub-connection cable, and the second ends of the sub-connection power supply wire cores are fixedly connected with a second quick connecting piece connected to the sub-connection cable where the second end of the sub-connection power supply wire core is located;

a first end of each sub-connection signal transmission wire core is fixedly connected to a part of the main connection signal transmission wire cores, each sub-connection signal transmission wire core is used for extending from the inside of the main connection cable to the inside of at least one sub-connection cable in each sub-connection cable, and a second end of each sub-connection signal transmission wire core is used for being fixedly connected with a second quick connector connected to the sub-connection cable where the second end of each sub-connection signal transmission wire core is located;

the wire core in at least one of the branch connection cables comprises a plurality of branch connection optical fiber cores, the first ends of the branch connection optical fiber cores are fixedly connected with second quick connectors connected to the branch connection cables where the first ends of the branch connection optical fiber cores are located, the branch connection optical fiber cores are all used for extending into the main connection cables, and the second ends of the branch connection optical fiber cores are fixedly connected to the first quick connectors.

Preferably, the number of the branch connecting cables is one;

each sub-connection power supply wire core is used for extending from the inside of the main connection cable to the inside of the sub-connection cable, and the second end of each sub-connection power supply wire core is used for being fixedly connected with a second quick connecting piece connected with the sub-connection cable;

each of the sub-connection signal transmission wire cores is used for extending from the inside of the main connection cable to the inside of the sub-connection cable, and the second end of each of the sub-connection signal transmission wire cores is used for being fixedly connected with a second quick connecting piece connected with the sub-connection cable;

the wire core in the branch connection cable comprises a plurality of branch connection optical fiber cores, and the first end of each branch connection optical fiber core is used for being fixedly connected with a second quick connecting piece connected with the branch connection cable.

Preferably, the number of the branch connecting cables is three, and the branch connecting cables are a first branch connecting cable, a second branch connecting cable and a third branch connecting cable respectively;

the first ends of the sub-connection power supply cores are fixedly connected with a first quick connecting piece connected with the first sub-connection cable;

each of the sub-connection signal transmission wire cores is used for extending from the inside of the main connection cable to the inside of the second sub-connection cable, and the second end of each of the sub-connection signal transmission wire cores is used for being fixedly connected with a second quick connecting piece connected to the second sub-connection cable;

the wire core in the third branch connecting cable comprises a plurality of branch connecting optical fiber cores, and the first end of each branch connecting optical fiber core is used for being fixedly connected with a second quick connecting piece connected with the third branch connecting cable.

Preferably, the cable further comprises a transition connecting cable, wherein one end of the transition connecting cable is fixedly connected to the outer side wall of the main connecting cable; one end of the first branch connecting cable, one end of the second branch connecting cable and one end of the third branch connecting cable are fixedly connected to the other end of the transition connecting cable; each of the branch connection power supply wire cores is used for penetrating through the transition connection cable from the inside of the main connection cable and extending to the inside of the first branch connection cable; each of the branch connection signal transmission wire cores is used for penetrating through the transition connection cable from the inside of the main connection cable and extending to the inside of the second branch connection cable; each of the split-connection optical fiber cores is used for penetrating through the transition connection cable from the third split-connection cable and extending into the main connection cable.

Preferably, the first quick connector is plugged with the third quick connector, the first quick connector is a first floating socket, and the third quick connector is a first plug; each second quick connector is spliced with each fourth quick connector, the second quick connectors are second plugs, and the fourth quick connectors are second floating sockets.

Preferably, ceramic pins are disposed on the third quick connector and each second quick connector, ceramic bushings are disposed on the first quick connector and each fourth quick connector, when the first quick connector is plugged with the third quick connector, the ceramic pins on the third quick connector are inserted into the ceramic bushings on the first quick connector, and when the second quick connector is plugged with each fourth quick connector, the ceramic pins on each second quick connector are inserted into the ceramic bushings on each fourth quick connector.

Preferably, anti-rotation protrusions are arranged on the third quick connector and each second quick connector, anti-rotation grooves are arranged on the first quick connector and each fourth quick connector, and when the first quick connector is inserted into the third quick connector, the anti-rotation protrusions on the third quick connector are embedded into the anti-rotation grooves on the first quick connector, and when the second quick connector is inserted into each fourth quick connector, the anti-rotation protrusions on each second quick connector are embedded into the anti-rotation grooves on each fourth quick connector.

Compared with the prior art, the utility model has the following technical effects:

according to the photoelectric communication composite cable connector provided by the utility model, the wire cores in the branch cables and the wire cores in the photoelectric communication composite cable are arranged to be communicated when the first quick connectors are connected with the third quick connectors and the second quick connectors are connected with the fourth quick connectors, and the first quick connectors can be quickly connected with the third quick connectors preassembled on the photoelectric communication composite cable and the second quick connectors can be quickly connected with the fourth quick connectors preassembled on the branch cables, so that the quick connection between the photoelectric communication composite cable and the branch cables externally connected on the photoelectric communication composite cable is realized, the construction difficulty can be effectively reduced, the labor and the time are saved, and the construction efficiency can be effectively improved.

Drawings

In order to more clearly illustrate the embodiments of the present utility model 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 of the present utility model, and other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

FIG. 1 is a schematic view of one embodiment of an optoelectronic communications composite cable connector provided by the present utility model;

FIG. 2 is a schematic view of another embodiment of an optoelectronic communications composite cable connector provided by the present utility model;

fig. 3 is a schematic view of still another embodiment of the optical-electrical communication composite cable connector provided by the present utility model.

In the figure: 10-photoelectric communication composite cable, 20-branch cable, 1-main connecting cable, 2-first quick connector, 3-branch connecting cable, 4-second quick connector, 5-third quick connector, 6-fourth quick connector, 7-main connection power supply wire core, 8-main connection signal transmission wire core, 9-branch connection power supply wire core, 11-branch connection signal transmission wire core, 12-branch connection optical fiber core, 13-transition connecting cable, wire core for power supply in 14-photoelectric communication composite cable, wire core for signal transmission in 15-photoelectric communication composite cable, optical fiber core in 16-photoelectric communication composite cable.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

The utility model aims to provide a photoelectric communication composite cable connector, which solves the problems in the prior art and can effectively improve the construction efficiency.

In order that the above-recited objects, features and advantages of the present utility model will become more readily apparent, a more particular description of the utility model will be rendered by reference to the appended drawings and appended detailed description.

Example 1

As shown in fig. 1, the present embodiment provides an optical-electrical communication composite cable connector, which includes a main connecting cable 1, a first quick connector 2, at least one branch connecting cable 3, and at least one second quick connector 4; the first quick connector 2 is fixedly arranged at one end of the main connecting cable 1 and fixedly connected with one end of a wire core in the main connecting cable 1, and the first quick connector 2 is used for being quickly connected with a third quick connector 5 preassembled on the photoelectric communication composite cable 10; one end of each branch connecting cable 3 is fixedly connected to the outer side wall of the main connecting cable 1; the number of the second quick connectors 4 is equal to that of the branch connecting cables 3, the second quick connectors 4 are fixedly connected to one ends of the branch connecting cables 3 far away from the main connecting cable 1, and the second quick connectors 4 are used for quick connection with fourth quick connectors 6 preassembled on the branch cables 20; one end of the wire core in each branch connecting cable 3 is fixedly connected to the first quick connecting piece 2 or the wire core in the main connecting cable 1, and the other end of the wire core in each branch connecting cable 3 is fixedly connected to each second quick connecting piece 4; the core in each branch cable 20 and the core in the photoelectric communication composite cable 10 can communicate when the first quick connector 2 is connected with the third quick connector 5 and each second quick connector 4 is connected with each fourth quick connector 6.

According to the photoelectric communication composite cable connector provided by the embodiment, the wire cores in the branch cables 20 and the wire cores in the photoelectric communication composite cable 10 can be communicated when the first quick connectors 2 are connected with the third quick connectors 5 and the second quick connectors 4 are connected with the fourth quick connectors 6, the first quick connectors 2 can be quickly connected with the third quick connectors 5 preassembled on the photoelectric communication composite cable 10, and the second quick connectors 4 can be quickly connected with the fourth quick connectors 6 preassembled on the branch cables 20, so that quick connection between the photoelectric communication composite cable 10 and the branch cables 20 externally connected on the photoelectric communication composite cable can be realized, the construction difficulty can be effectively reduced, the labor and the time can be saved, and the construction efficiency can be effectively improved; here, the fact that the core in each branch cable 20 is in communication with the core in the optical-electrical communication composite cable 10 when the first quick connector 2 is connected to the third quick connector 5 and each second quick connector 4 is connected to each fourth quick connector 6 means that the core in each branch cable 20 is in communication with the same type of core in the optical-electrical communication composite cable 10, for example, the core for power supply in the branch cable 20 is in communication with the core for power supply 14 in the optical-electrical communication composite cable, the core for signal transmission in the branch cable 20 is in communication with the core for signal transmission 15 in the optical-electrical communication composite cable, and the optical fiber core in the branch cable 20 is in communication with the optical fiber core 16 in the optical-electrical communication composite cable.

Further, the wire core in the main connecting cable 1 comprises a plurality of main connecting power supply wire cores 7 and a plurality of main connecting signal transmission wire cores 8, and one end of each main connecting power supply wire core 7 and one end of each main connecting signal transmission wire core 8 are used for being fixedly connected with the first quick connecting piece 2; the first ends of the sub-connection power supply wire cores 9 are fixedly connected to part of the main connection power supply wire cores 7 in the main connection power supply wire cores 7, the sub-connection power supply wire cores 9 are used for extending from the inside of the main connection cable 1 to the inside of at least one sub-connection cable 3 in the sub-connection cables 3, and the second ends of the sub-connection power supply wire cores 9 are used for being fixedly connected with the second quick connecting pieces 4 connected to the sub-connection cables 3 where the second ends are located; the first ends of the sub-connection signal transmission wire cores 11 are fixedly connected to part of the main connection signal transmission wire cores 8 in the main connection signal transmission wire cores 8, each sub-connection signal transmission wire core 11 is used for extending from the inside of the main connection cable 1 to the inside of at least one sub-connection cable 3 in each sub-connection cable 3, and the second ends of each sub-connection signal transmission wire core 11 are fixedly connected with the second quick connector 4 connected to the sub-connection cable 3 where the second end of each sub-connection signal transmission wire core 11 is located; the wire core in at least one branch connecting cable 3 in each branch connecting cable 3 comprises a plurality of branch connecting optical fiber cores 12, the first end of each branch connecting optical fiber core 12 is fixedly connected with the second quick connecting piece 4 connected on the branch connecting cable 3 where the first end of each branch connecting optical fiber core 12 is positioned, each branch connecting optical fiber core 12 is used for extending into the main connecting cable 1, the second end of each branch connecting optical fiber core 12 is fixedly connected with the first quick connecting piece 2, and the structure is simple and convenient to manufacture, assemble and use; as a preferred implementation manner of this embodiment, the core in the main connection cable 1 further includes a plurality of main connection optical fiber cores, one end of each main connection optical fiber core is used for being fixedly connected with the first quick connector 2, and each main connection optical fiber core is capable of being communicated with an optical fiber core in the optical-electrical communication composite cable 10 except for being communicated with each branch connection optical fiber core 12 when the first quick connector 2 is connected with the third quick connector 5.

Further, the number of the branch connecting cables 3 is one; each sub-connection power supply wire core 9 is used for extending from the inside of the main connection cable 1 to the inside of the sub-connection cable 3, and the second end of each sub-connection power supply wire core 9 is used for being fixedly connected with the second quick connecting piece 4 connected to the sub-connection cable 3; each sub-connection signal transmission wire core 11 is used for extending from the inside of the main connection cable 1 to the inside of the sub-connection cable 3, and the second end of each sub-connection signal transmission wire core 11 is used for being fixedly connected with the second quick connecting piece 4 connected to the sub-connection cable 3; the wire core in the branch connection cable 3 comprises a plurality of branch connection optical fiber cores 12, the first end of each branch connection optical fiber core 12 is fixedly connected with the second quick connector 4 connected on the branch connection cable 3, and the branch connection optical fiber core is simple in structure and suitable for realizing quick connection when one branch cable 20 is externally connected on the photoelectric communication composite cable 10.

As a preferred implementation manner of this embodiment, the first quick connector 2 is plugged with the third quick connector 5, and the first quick connector 2 is a first floating socket, and the third quick connector 5 is a first plug; each second quick connector 4 is spliced with each fourth quick connector 6, the second quick connector 4 is a second plug, the fourth quick connector 6 is a second floating socket, the structure is simple, quick connection is convenient to complete, the existing plug and floating socket products can be directly adopted, and research and development cost is saved.

As a more preferable implementation manner of this embodiment, ceramic pins are arranged on the third quick connector 5 and each second quick connector 4, ceramic sleeves are arranged on the first quick connector 2 and each fourth quick connector 6, when the first quick connector 2 is plugged with the third quick connector 5, the ceramic pins on the third quick connector 5 are inserted into the ceramic sleeves on the first quick connector 2, when each second quick connector 4 is plugged with each fourth quick connector 6, the ceramic pins on each second quick connector 4 are inserted into the ceramic sleeves on each fourth quick connector 6, and the ceramic pins and the ceramic sleeves are plugged and matched to realize precise butt joint of optical fibers, so that the processing manufacturability is better and the structural reliability is higher.

As a more preferable implementation manner of this embodiment, the third quick connector 5 and the second quick connectors 4 are provided with anti-rotation protrusions, the first quick connector 2 and the fourth quick connectors 6 are provided with anti-rotation grooves, when the first quick connector 2 is plugged with the third quick connector 5, the anti-rotation protrusions on the third quick connector 5 are embedded into the anti-rotation grooves on the first quick connector 2, when the second quick connectors 4 are plugged with the fourth quick connectors 6, the anti-rotation protrusions on the second quick connectors 4 are embedded into the anti-rotation grooves on the fourth quick connectors 6, so that radial positioning is realized, and quick plugging combination is conveniently completed.

Example two

As shown in fig. 2, the present embodiment provides an optical-electrical communication composite cable connector, which is mainly different from the optical-electrical communication composite cable connector provided in the first embodiment in that the number of the branch connection cables 3 is different from the number of the arrangement of the branch connection cables 3, and in the present embodiment, the number of the branch connection cables 3 is three and is the first branch connection cable 3, the second branch connection cable 3, and the third branch connection cable 3, respectively; each branch connecting power supply wire core 9 is used for extending from the interior of the main connecting cable 1 to the interior of the first branch connecting cable 3, and the second end of each branch connecting power supply wire core 9 is used for fixedly connecting with the second quick connecting piece 4 connected to the first branch connecting cable 3; each branch connecting signal transmission wire core 11 is used for extending from the inside of the main connecting cable 1 to the inside of the second branch connecting cable 3, and the second end of each branch connecting signal transmission wire core 11 is used for fixedly connecting with the second quick connecting piece 4 connected to the second branch connecting cable 3; the wire core in the third branch connection cable 3 comprises a plurality of branch connection optical fiber cores 12, the first end of each branch connection optical fiber core 12 is fixedly connected with the second quick connector 4 connected on the third branch connection cable 3, the structure is simple, the first branch connection cable 3, the second branch connection cable 3 and the third branch connection cable 3 can be simultaneously connected with the branch cables 20 of the respective corresponding types, or only one or two of the branch cables 20 of the respective corresponding types can be connected, and the quick connection is suitable for realizing the quick connection when one, two or three branch cables 20 of different types are externally connected on the photoelectric communication composite cable 10.

Example III

As shown in fig. 3, the present embodiment provides an optical-electrical communication composite cable connector, which is mainly different from the optical-electrical communication composite cable connector provided in the second embodiment in that the optical-electrical communication composite cable connector provided in the present embodiment further includes a transition connection cable 13, and one end of the transition connection cable 13 is used for being fixedly connected to an outer side wall of the main connection cable 1; one end of the first branch connecting cable 3, one end of the second branch connecting cable 3 and one end of the third branch connecting cable 3 are fixedly connected to the other end of the transition connecting cable 13; each branch connection power supply wire core 9 is used for penetrating through the transition connection cable 13 from the inside of the main connection cable 1 and extending to the inside of the first branch connection cable 3; each branch connection signal transmission wire core 11 is used for penetrating through the transition connection cable 13 from the inside of the main connection cable 1 and extending to the inside of the second branch connection cable 3; each branch connection optical fiber core 12 is used for penetrating through the transition connection cable 13 from the third branch connection cable 3 and extending into the main connection cable 1, and has a simple structure, the first branch connection cable 3, the second branch connection cable 3 and the third branch connection cable 3 can be simultaneously connected with the branch cables 20 of the respective corresponding types, or only one or two of the branch cables 20 of the respective corresponding types can be connected, so that the branch cables are suitable for realizing quick connection when one, two or three branch cables 20 of different types are externally connected on the photoelectric communication composite cable 10.

The principles and embodiments of the present utility model have been described in detail with reference to specific examples, which are provided to facilitate understanding of the method and core ideas of the present utility model; also, it is within the scope of the present utility model to be modified by those of ordinary skill in the art in light of the present teachings. In view of the foregoing, this description should not be construed as limiting the utility model.

Claims (8)

1. An optoelectronic communications composite cable connector, characterized by: comprises a main connecting cable, a first quick connector, at least one branch connecting cable and at least one second quick connector;

the first quick connector is fixedly arranged at one end of the main connecting cable and fixedly connected with one end of a wire core in the main connecting cable, and is used for being quickly connected with a third quick connector preassembled on the photoelectric communication composite cable;

one end of each branch connecting cable is fixedly connected to the outer side wall of the main connecting cable;

the number of the second quick connectors is equal to that of the branch connecting cables, the second quick connectors are fixedly connected to one ends of the branch connecting cables far away from the main connecting cables, and the second quick connectors are used for quick connection with fourth quick connectors preassembled on the branch cables;

one end of the wire core in each branch connecting cable is fixedly connected to the first quick connecting piece or the wire core in the main connecting cable, and the other end of the wire core in each branch connecting cable is fixedly connected to each second quick connecting piece;

the wire core in each branch cable and the wire core in the photoelectric communication composite cable can be communicated when the first quick connector is connected with the third quick connector and each second quick connector is connected with each fourth quick connector.

2. The optical-electrical communication composite cable connector of claim 1, wherein: the wire core in the main connecting cable comprises a plurality of main connecting power supply wire cores and a plurality of main connecting signal transmission wire cores, and one end of each main connecting power supply wire core and one end of each main connecting signal transmission wire core are used for being fixedly connected with the first quick connecting piece;

the first ends of the sub-connection power supply wire cores are fixedly connected to part of the main connection power supply wire cores, each sub-connection power supply wire core is used for extending from the inside of the main connection cable to the inside of at least one sub-connection cable in each sub-connection cable, and the second ends of the sub-connection power supply wire cores are fixedly connected with a second quick connecting piece connected to the sub-connection cable where the second end of the sub-connection power supply wire core is located;

a first end of each sub-connection signal transmission wire core is fixedly connected to a part of the main connection signal transmission wire cores, each sub-connection signal transmission wire core is used for extending from the inside of the main connection cable to the inside of at least one sub-connection cable in each sub-connection cable, and a second end of each sub-connection signal transmission wire core is used for being fixedly connected with a second quick connector connected to the sub-connection cable where the second end of each sub-connection signal transmission wire core is located;

the wire core in at least one of the branch connection cables comprises a plurality of branch connection optical fiber cores, the first ends of the branch connection optical fiber cores are fixedly connected with second quick connectors connected to the branch connection cables where the first ends of the branch connection optical fiber cores are located, the branch connection optical fiber cores are all used for extending into the main connection cables, and the second ends of the branch connection optical fiber cores are fixedly connected to the first quick connectors.

3. The optical-electrical communication composite cable connector of claim 2, wherein: the number of the branch connecting cables is one;

each sub-connection power supply wire core is used for extending from the inside of the main connection cable to the inside of the sub-connection cable, and the second end of each sub-connection power supply wire core is used for being fixedly connected with a second quick connecting piece connected with the sub-connection cable;

each of the sub-connection signal transmission wire cores is used for extending from the inside of the main connection cable to the inside of the sub-connection cable, and the second end of each of the sub-connection signal transmission wire cores is used for being fixedly connected with a second quick connecting piece connected with the sub-connection cable;

the wire core in the branch connection cable comprises a plurality of branch connection optical fiber cores, and the first end of each branch connection optical fiber core is used for being fixedly connected with a second quick connecting piece connected with the branch connection cable.

4. The optical-electrical communication composite cable connector of claim 2, wherein: the number of the branch connecting cables is three, and the branch connecting cables are respectively a first branch connecting cable, a second branch connecting cable and a third branch connecting cable;

the first ends of the sub-connection power supply cores are fixedly connected with a first quick connecting piece connected with the first sub-connection cable;

each of the sub-connection signal transmission wire cores is used for extending from the inside of the main connection cable to the inside of the second sub-connection cable, and the second end of each of the sub-connection signal transmission wire cores is used for being fixedly connected with a second quick connecting piece connected to the second sub-connection cable;

the wire core in the third branch connecting cable comprises a plurality of branch connecting optical fiber cores, and the first end of each branch connecting optical fiber core is used for being fixedly connected with a second quick connecting piece connected with the third branch connecting cable.

5. The optical-electrical communication composite cable connector of claim 4, wherein: the cable also comprises a transition connecting cable, wherein one end of the transition connecting cable is used for being fixedly connected to the outer side wall of the main connecting cable; one end of the first branch connecting cable, one end of the second branch connecting cable and one end of the third branch connecting cable are fixedly connected to the other end of the transition connecting cable; each of the branch connection power supply wire cores is used for penetrating through the transition connection cable from the inside of the main connection cable and extending to the inside of the first branch connection cable; each of the branch connection signal transmission wire cores is used for penetrating through the transition connection cable from the inside of the main connection cable and extending to the inside of the second branch connection cable; each of the split-connection optical fiber cores is used for penetrating through the transition connection cable from the third split-connection cable and extending into the main connection cable.

6. The optical-electrical communication composite cable connector of claim 1, wherein: the first quick connector is spliced with the third quick connector, the first quick connector is a first floating socket, and the third quick connector is a first plug; each second quick connector is spliced with each fourth quick connector, the second quick connectors are second plugs, and the fourth quick connectors are second floating sockets.

7. The optical-electrical communication composite cable connector of claim 6, wherein: the ceramic pins are arranged on the third quick connector and the second quick connectors, the ceramic sleeves are arranged on the first quick connector and the fourth quick connector, when the first quick connector is inserted into the third quick connector, the ceramic pins on the third quick connector are inserted into the ceramic sleeves on the first quick connector, and when the second quick connector is inserted into the fourth quick connector, the ceramic pins on the second quick connector are inserted into the ceramic sleeves on the fourth quick connector.

8. The optical-electrical communication composite cable connector of claim 6, wherein: the third quick connectors and the second quick connectors are provided with anti-rotation protrusions, the first quick connectors and the fourth quick connectors are provided with anti-rotation grooves, when the first quick connectors are inserted into the third quick connectors, the anti-rotation protrusions on the third quick connectors are embedded into the anti-rotation grooves on the first quick connectors, and when the second quick connectors are inserted into the fourth quick connectors, the anti-rotation protrusions on the second quick connectors are embedded into the anti-rotation grooves on the fourth quick connectors.