CN211208023U

CN211208023U - Patch cable and cable assembly

Info

Publication number: CN211208023U
Application number: CN201921539291.6U
Authority: CN
Inventors: 缪爱民; 戚振华; 陈妍
Original assignee: Shanghai Step Electric Corp
Current assignee: Shanghai Step Electric Corp
Priority date: 2019-09-17
Filing date: 2019-09-17
Publication date: 2020-08-07
Anticipated expiration: 2029-09-17

Abstract

The utility model relates to a cable, in particular to connect and insert cable and cable assembly, should connect and insert the cable and include: the cable body, the cable body includes: sinle silk, carry out the flexible insulation layer of cladding to the sinle silk, patch cable still includes: the first electrical connector is arranged at the end part of the cable body, and the second electrical connector is arranged at the tail part of the cable body; the first electrical connector of the cable is used for plugging with the second electrical connector of another cable; the patch cable further comprises: and the locking assembly is used for plugging the first electrical connector and a second electrical connector of another cable and locking the first electrical connector and the second electrical connector with each other. Compared with the prior art, make two cable butt joints the back, can not separate between first electrical property connector and the second electrical property connector, thereby guaranteed the fastness of two cables after pegging graft, in order to further improve the security that the cable used after pegging graft.

Description

Patch cable and cable assembly

Technical Field

The utility model relates to a cable, in particular to connect plug cable and cable subassembly.

Background

Electric cables, which are cables for transmitting electric power, are widely used in various industries, and in some construction sites, heavy construction machinery, such as industrial vehicles, compacting machines, piling machines, etc., are often required, and in order to ensure the normal operation of the construction machinery, the electric cables are often additionally pulled from the distribution box for the operation of the construction machinery. However, the inventor finds that, when the cables are used, the length of the cable is often insufficient due to the problem of the distance between the distribution box and the construction equipment, so that the currently common mode is to twist the exposed core at the end of one cable with the exposed core at the end of the other cable, and to coat the exposed core with an insulating tape, so as to realize the butt joint of the two cables. However, the butt joint method of the cable is simple and crude, and a large potential safety hazard exists in the using process. In the other mode, the connecting terminal is arranged at the end part of the cable and is butted with the connecting terminal at the end part of another cable, and although the safety is greatly improved in the using process, in the butting process of the cable, the terminals are generally in a plugging mode, so that the firmness after plugging between two cable terminals directly influences the safety in use.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a self-luminous cable and self-luminous cable system can realize the self-luminous of cable to reach the warning effect to passerby and constructor, avoid the emergence of potential safety hazard.

In order to solve the technical problem, the utility model provides a plug cable, include: a cable body, the cable body comprising: sinle silk, right the sinle silk carries out the flexible insulation layer of cladding, the patch cable still includes: the first electrical connector is arranged at the end part of the cable body, and the second electrical connector is arranged at the tail part of the cable body; the first electrical connector and the second electrical connector are both electrically connected with the wire core, and the first electrical connector of the cable is used for plugging with the second electrical connector of another cable;

the patch cable further comprises: and the locking assembly is used for plugging the first electrical connector and the second electrical connector of another cable and locking the first electrical connector and the second electrical connector mutually.

Additionally, the utility model also provides a cable subassembly, include: in the patch cable, the first electrical connector of any one patch cable is connected with the second electrical connector of the adjacent cable, and is electrically connected.

The utility model discloses an embodiment is for prior art, because the both ends of cable body set up first electrical property connector and second electrical property connector respectively, second electrical property connector that can another cable through first electrical property connector pegs graft, the cable still includes the locking subassembly simultaneously, this locking subassembly is used for pegging graft first electrical property connector and the second electrical property connector of another cable, and mutual locking, make two cable butt joints back, can not separate between first electrical property connector and the second electrical property connector, thereby the fastness of two cables after pegging graft has been guaranteed, with the security that the cable used after pegging graft further improves.

In addition, the first electrical connector is a male connector with a terminal, the second electrical connector is a female connector with a terminal hole, and the terminal of the male connector is inserted into the terminal hole of the female connector.

Additionally, the male connector includes:

the first insulating shell is arranged at the end part of the cable body and is fixedly connected with the flexible insulating layer;

the male head body is arranged in the first insulating shell; the male head body can slide along the axial direction of the cable body; the male head body is partially formed into the terminal, and the other part of the male head body is formed into a metal sliding seat coaxially fixed with the terminal;

an electrical rebound assembly disposed within the first insulating housing; the electric resilience assembly is respectively connected with the wire core and the metal sliding seat and electrically conducts the wire core and the male head body;

the female joint includes:

the second insulating shell is arranged at the tail part of the cable body and is fixedly connected with the flexible insulating layer;

the female head body is arranged in the second insulating shell; the female head body is provided with a terminal hole for the terminal of the male head body to be inserted into.

In addition, a first sliding groove and a second sliding groove connected with the tail end of the first sliding groove are formed in the first insulating shell, the first sliding groove is formed along the axis direction of the cable body, the second sliding groove is formed along the direction perpendicular to the axis direction of the cable body, and the tail end of the first sliding groove is one end far away from the cable body;

the locking assembly includes: the first annular connecting piece, the second annular connecting piece and the sliding block;

the sliding block part penetrates through the first sliding groove, is connected with the male head body, and is partially exposed out of the first insulating shell; the sliding block can slide along the direction of the first sliding groove; when the sliding block slides to the tail end of the first sliding groove, the sliding block can slide along the direction of the second sliding groove, and when the terminal is inserted into the terminal hole of the female joint, the sliding block is positioned at the tail end of the first sliding groove;

the first annular connecting piece is arranged at one end, far away from the cable body, of the first insulating shell and is connected with the first insulating shell in a rotating mode, the second annular connecting piece is arranged at one end, far away from the cable body, of the second insulating shell and is fixedly connected with the second insulating shell, and the first annular connecting piece is screwed with the second annular connecting piece of the other cable in a threaded mode.

In addition, the first insulating housing includes: the flexible insulation layer is arranged on the shell body, and the first annular bulge and the second annular bulge are arranged in the shell body and are opposite to each other along the axial direction of the shell body; the first annular bulge is used for resisting the metal sliding seat when the sliding block slides to the tail end of the first sliding groove; the second annular protrusion abuts the electrical rebound assembly.

Additionally, the electrically resilient component comprises: the metal slide seat is provided with an arc-shaped guide groove around the axial direction of the terminal relative to one side of the electric resilience assembly, and the metal ball is clamped in the arc-shaped guide groove and is in rolling fit with the metal slide seat.

In addition, the metal ball is rotatably arranged at one end, away from the second annular bulge, of the metal rebound part.

In addition, the first insulating shell and the second insulating shell are used for being mutually abutted and tightly attached after the first annular connecting piece is screwed with the second annular connecting piece of the other cable.

In addition, the first insulating shell and the second insulating shell are both plastic shells.

Drawings

Fig. 1 is a schematic view of a first embodiment of the present invention when two cables are butted;

fig. 2 is a schematic view illustrating the first electrical connector and the second electrical connector being plugged together according to the first embodiment of the present invention;

fig. 3 is an assembly view of the first embodiment of the present invention when two cables are butted;

fig. 4 is a schematic view illustrating the sliding of the sliding block on the first sliding groove according to the first embodiment of the present invention;

fig. 5 is a schematic view illustrating the sliding of the sliding block on the second sliding chute according to the first embodiment of the present invention;

fig. 6 is a schematic view of the first insulating housing when the third sliding slot is added to the sliding block according to the first embodiment of the present invention;

fig. 7 is a schematic view illustrating a state in which the metal balls are in rolling engagement with the metal slide according to the first embodiment of the present invention;

fig. 8 is a schematic view illustrating the first electrical connector and the second electrical connector being plugged together according to the second embodiment of the present invention.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention clearer, the following will explain in detail each embodiment of the present invention with reference to the accompanying drawings. However, it will be appreciated by those of ordinary skill in the art that in various embodiments of the invention, numerous technical details are set forth in order to provide a better understanding of the present application. However, the technical solutions claimed in the claims of the present application can be implemented without these technical details and with various changes and modifications based on the following embodiments.

The first embodiment of the present invention relates to a self-luminous cable, as shown in fig. 1 and 2, including: a cable body 1, the cable body 1 comprising: the cable comprises a cable core 11 and a flexible insulating layer 12 for coating the cable core 11. As shown in fig. 1, the patch cable according to the present embodiment further includes: the cable comprises a first electrical connector 2 arranged at the end part of the cable body 1 and a second electrical connector 3 arranged at the tail part of the cable body. The first electrical connector 2 and the second electrical connector 3 are electrically connected to the core 11. In actual use, the first electrical connector 2 of the cable can be used for plugging with the second electrical connector 3 of another cable, thereby realizing the electrical connection of the two cables.

As shown in fig. 2 and 3, the patch cable according to the present embodiment further includes: and the locking assembly 4 is used for plugging the first electrical connector 2 with the second electrical connector 3 on the other cable, and locking the first electrical connector 2 and the second electrical connector 3 of the other cable mutually. From this, it can be seen that the cable of the present embodiment includes: locking subassembly 4, this locking subassembly 4 can peg graft first electrical property connector 2 and second electrical property connector 3, simultaneously with first electrical property connector 2 and the mutual locking of second electrical property connector 3 for can not separate between first electrical property connector 2 and the second electrical property connector 3, thereby guaranteed the fastness of two cables after pegging graft, in order to further improve the security that the cable used after pegging graft.

In the present embodiment, as shown in fig. 1, the first electrical connector 2 is a male connector with a terminal 211, the second electrical connector 3 is a female connector with a terminal hole 311, and the terminal 211 of the male connector is inserted into the terminal hole 311 of the female connector.

Specifically, in the present embodiment, as shown in fig. 2 and 3, the male connector includes: a first insulating shell 22 arranged at the end part of the cable body 1, and a male head body 21 arranged in the first insulating shell 22, wherein the first insulating shell 22 is fixedly connected with the flexible insulating layer 12. In the present embodiment, as shown in fig. 2, the male body 21 is slidable in the insulating housing 22 in the axial direction of the cable body 1. The male body 21 is partially constituted as a terminal 211, and is partially constituted as a metal slider 212 coaxially fixed to the terminal 211. In addition, as shown in fig. 2, the male connector further includes: and the electrical rebound assembly 23 is arranged in the first insulating housing 22, and the electrical rebound assembly 23 is respectively connected with the wire core 11 and the metal slide 212 and electrically connects the wire core 11 and the male body 21.

Accordingly, as shown in fig. 2 and 3, the female connector includes: a second insulating housing 32 and a female body 31. The second insulating housing 32 is disposed at the tail of the cable body 1 and is fixedly connected to the flexible insulating layer 12 of the cable body 1, the female body 31 is disposed in the second insulating housing 32, and the female body 31 is provided with a terminal hole 311, and the terminal hole 311 is used for being inserted into the terminal 211 of the male body 21. In the present embodiment, the first insulating housing 22 and the second insulating housing 32 are both plastic housings and can be connected to the flexible insulating layer 12 in a melting manner, but in the actual application, the first insulating housing 22 and the second insulating housing 32 may also be extension sections of the flexible insulating layer 12 and are integrally formed with the flexible insulating layer 12.

In order to achieve this, the terminals 211 of the male body 21 are interlocked after being inserted into the terminal holes 311 of the female body 31 of another cable. In the present embodiment, as shown in fig. 4, the first insulating housing 22 is provided with a first sliding groove 221 and a second sliding groove 222 connected to a terminal of the first sliding groove 221, the first sliding groove 221 is provided along an axial direction of the cable body 1, the second sliding groove 222 is provided along a direction perpendicular to the axial direction of the cable body 1, and the terminal of the first sliding groove 221 is an end away from the cable body 1.

And the corresponding locking assembly 4, as shown in fig. 2 and 3, comprises: a first annular connector 41, a second annular connector 42 and a slider 43. Wherein, a part of the sliding block 43 passes through the first sliding slot 221 and is fixedly connected with the metal sliding seat 212 of the male head body 21, and another part is exposed outside the first insulating housing 22 for operation by the worker, the sliding block 43 is slidable along the direction of the first sliding slot 221, and when the sliding block 43 slides to the end of the first sliding slot 221, the sliding block 43 is also slidable along the direction of the second sliding slot 222, as shown in the state shown in fig. 5. Next, the first annular connecting member 41 is disposed at one end of the first insulating housing 22 away from the cable body 1, and is rotatably connected to the first insulating housing 22, for example, an annular protrusion (not shown) may be disposed on an inner side of the first annular connecting member 41, and an annular groove (not shown) for the annular protrusion to be clamped into is disposed on an outer side of the first insulating housing 22, so that after the annular protrusion is clamped into the annular groove, the first insulating housing 22 and the first annular connecting member 41 can rotate relatively around an axial direction of the terminal 211. In addition, as shown in fig. 2 and fig. 3, the second annular connecting member 42 is disposed at an end of the second insulating housing 32 away from the cable body 1, and is coaxially and fixedly connected with the second insulating housing 32, and the first annular connecting member 41 can be screwed with the second annular connecting member 42 of another cable. It can be seen that, when the first electrical connector 2 of a cable is plugged with the second electrical connector 3 of another cable, as shown in fig. 3, a worker can first screw the first annular connector 41 with the second annular connector 42 of another cable to ensure the relative position relationship between the male body 21 of the cable and the female body 31 of another cable during plugging, and then the worker can slide the slider 43 along the first sliding slot 221, as shown in fig. 4, until the slider 43 slides to the end of the first sliding slot 221, and the slider 43 slides to drive the male body 21 to move towards the second plugging direction 2 of another cable, so that the terminal 211 of the male body 21 can smoothly enter the terminal hole 311 of the female body 31 of another cable, i.e. the state shown by the terminal 211 in fig. 2. Moreover, after the terminal 211 enters the terminal hole 311, the metal slide 212 of the male body 21 can still be under the resilience of the electrical resilience component 23, so that the terminal 211 can always be kept at the current position in the terminal hole 311. In addition, since the slider 43 is located at the end of the first sliding slot 221 after the terminal 211 is inserted into the terminal hole 311, the slider 43 can be locked by sliding the slider 43 into the second sliding slot 222, as shown in fig. 5.

It can be easily found from the above description that, since the first electrical connector 2 and the second electrical connector 3 are connected by screwing the first annular connector 41 and the second annular connector 42, the stability of the two electrical connectors after connection is ensured, and the terminal 211 cannot be easily separated from the terminal hole 311 after the terminal 211 of the male connector body 21 is inserted into the terminal hole 311 of the female connector body 31. Meanwhile, after the terminal 211 is inserted into the terminal hole 311, the terminal 211 can be locked by sliding the slider 43 into the second sliding slot 222, so that the stability of the first electrical connector 2 and the second electrical connector 3 after being plugged is further improved. Preferably, as shown in fig. 6, a third sliding groove 223 may be further disposed at the head end of the first sliding groove 221, and the third sliding groove 223 is also opened along a direction perpendicular to the axis of the cable body 1, that is, when the sliding block 43 slides to the head end of the first sliding groove 221, the sliding block 43 may also slide into the third sliding groove 223, so as to ensure that when the cable is not plugged with another cable, the sliding block 43 is locked by the third sliding groove 223, so that the terminal 211 may be hidden inside the insulating housing 221, so as to protect the terminal 211, and prevent the terminal 211 from being exposed to the outside and causing oxidation, corrosion, and the like.

In addition, it is worth integrating that, in order to ensure that the electrically resilient assembly 23 can effectively exert a resilient force on the metal slide 212 of the male body 21 in the first insulating housing 22, as shown in fig. 2 and 3, the first insulating housing 22 includes: the flexible insulation layer 12 comprises a shell body 221 fixedly connected with the flexible insulation layer 12, and a first annular bulge 222 and a second annular bulge 223 arranged in the shell body 221, wherein the first annular bulge 222 and the second annular bulge 223 are oppositely arranged along the axial direction of the shell body 221. As shown in fig. 3, the first annular protrusion 222 is used to abut against the metal slide 212 when the slide 43 slides to the end of the first sliding slot 221, and the second annular protrusion 223 can directly abut against the electrically resilient component 23. In the present embodiment, as shown in fig. 2 and 3, electrical rebound assembly 23 includes: the metal resilient member 231 abutting against the second annular protrusion 223, and the metal ball 232 disposed at an end of the metal resilient member 231 away from the second annular protrusion 223. In the present embodiment, as shown in fig. 3, the metal resilient member 231 may be a spring, one end of the spring abuts against the second annular protrusion 223, the other end of the spring is provided with a metal ball 232, and the spring is further connected to the wire core 11 to achieve electrical conduction therebetween. Meanwhile, as shown in fig. 7, an arc-shaped guide groove 213 is formed in one side of the metal slide 212 opposite to the electrical rebound assembly 23 around the axial direction of the terminal 211, and the metal ball 232 is clamped in the arc-shaped guide groove 213 and is in rolling fit with the metal slide 212. Therefore, when the sliding block 43 slides into the second sliding slot 222 from the end of the first sliding slot 221, the male connector body 21 is driven to rotate around the axis direction of the terminal 211, and the male connector body 21 can rotate in the process of rotation by means of the arc-shaped guide slot 213 arranged on the metal sliding seat 212, so that the male connector body 21 and the metal ball 232 of the electrical resilience assembly 23 can be in a rolling fit manner, it is ensured that the electrical resilience assembly 23 cannot follow the male connector body 21 to rotate, and therefore, the electrical conductivity of the two cables after being butted can be unaffected, and the first electrical connector 2 and the second electrical connector 3 can be conveniently plugged into each other.

Furthermore, as a preferable mode, in order to further improve the rolling performance between the metal ball 232 and the metal slide 212, in the present embodiment, as shown in fig. 2, the metal ball 232 is rotatably disposed at one end of the metal resilient member 231, which is far away from the second annular protrusion 223, so that when the slider 43 rotates the male driving body 21, the metal ball 232 can rotate by means of mutual friction with the metal slide 212, so that the slider 43 can more easily slide into the second sliding slot 222, thereby improving the operability of the slider 43 for a worker.

The second embodiment of the present invention relates to a patch cable, and the second embodiment is further improved on the basis of the first embodiment, and the main improvement thereof lies in: in this embodiment, the lengths of the first insulating housing 22 and the second insulating housing 32 can be properly adjusted, so that the first insulating housing 22 and the second insulating housing 32 can abut against each other and tightly adhere to each other after the first annular connecting member 41 is screwed with the second annular connecting member 42 of another cable, and thus a relatively closed space can be formed between the first insulating housing 22 and the second insulating housing 32, so as to ensure that the male connector body 21 and the female connector body 31 can be completely isolated from the space through the cooperation between the first insulating housing 22 and the second insulating housing 32 after the terminal 211 of the male connector body 21 is inserted into the terminal hole 311 of the female connector body 31, thereby avoiding potential safety hazards caused by electric leakage.

As a preferable mode, in the present embodiment, as shown in fig. 8, a groove 224 is formed on one side of the first insulating housing 22 opposite to the second insulating housing 32, and a limiting protrusion 321 inserted into the groove 224 is formed on one side of the second insulating housing 32 opposite to the first insulating housing 22, so that the stability of the first insulating housing 22 and the second insulating housing 32 after being attached can be further improved by the cooperation between the limiting protrusion 321 and the groove 224.

The utility model discloses a third embodiment relates to a cable assembly, include: a plurality of the patch cables as described in the first embodiment or the second embodiment, and the first electrical connector of any one patch cable is plugged with the second electrical connector of the adjacent cable, so as to realize electrical conduction between two patch cables.

It will be understood by those skilled in the art that the foregoing embodiments are specific examples of the invention, and that various changes in form and details may be made therein without departing from the spirit and scope of the invention in its practical application.

Claims

1. A patch cable, comprising: a cable body, the cable body comprising: sinle silk, right the sinle silk carries out the flexible insulation layer of cladding, its characterized in that: the patch cable further comprises: the first electrical connector is arranged at the end part of the cable body, and the second electrical connector is arranged at the tail part of the cable body; the first electrical connector and the second electrical connector are both electrically connected with the wire core, and the first electrical connector of the cable is used for plugging with the second electrical connector of another cable;

2. The patch cable of claim 1, wherein the first electrical connector is a male connector with a terminal and the second electrical connector is a female connector with a terminal aperture, the terminal of the male connector being adapted to be inserted into the terminal aperture of the female connector.

3. The patch cable of claim 2, wherein the male connector comprises:

the female joint includes:

4. The patch cable according to claim 3, wherein the first insulating housing has a first slot and a second slot connected to a distal end of the first slot, the first slot is formed along an axial direction of the cable body, the second slot is formed along a direction perpendicular to the axial direction of the cable body, and the distal end of the first slot is an end away from the cable body;

the sliding block partially penetrates through the first sliding groove, is connected with the male head body, is partially exposed out of the first insulating shell, and can slide along the direction of the first sliding groove; when the sliding block slides to the tail end of the first sliding groove, the sliding block can slide along the direction of the second sliding groove, and when the terminal is inserted into the terminal hole of the female joint, the sliding block is positioned at the tail end of the first sliding groove;

5. The patch cable of claim 4, wherein said first insulative housing comprises: the flexible insulation layer is arranged on the shell body, and the first annular bulge and the second annular bulge are arranged in the shell body and are opposite to each other along the axial direction of the shell body;

the first annular bulge is used for resisting the metal sliding seat when the sliding block slides to the tail end of the first sliding groove; the second annular protrusion abuts the electrical rebound assembly.

6. The patch cable of claim 5, wherein the electrically resilient component comprises: the metal slide seat is provided with an arc-shaped guide groove around the axial direction of the terminal relative to one side of the electric resilience assembly, and the metal ball is clamped in the arc-shaped guide groove and is in rolling fit with the metal slide seat.

7. The patch cable of claim 6, wherein said metal ball is rotatably disposed at an end of said metal resilient member remote from said second annular projection.

8. The patch cable of claim 4, wherein said first and second insulative housings are adapted to abut one another in a snug fit after said first annular connector is threadably engaged with said second annular connector of another cable.

9. The patch cable of any one of claims 3 to 8, wherein the first and second insulative housings are plastic housings.

10. An electrical cable assembly, comprising: the patch cable of any one of claims 1-9, wherein the first electrical connector of any one of the patch cables is plugged into and electrically connected to the second electrical connector of an adjacent cable.