CN116031695A - Cable connector and cable parallel device - Google Patents

Abstract

The utility model belongs to the technical field of electric connection, and particularly relates to a cable connector and a cable parallel device, which comprise a fixed block, a conductive clamp, an insulating clamp and a reset mechanism, wherein a positioning hole is formed in the fixed block; the insulating clamp comprises two insulating blocks, the two insulating blocks are oppositely arranged, the two insulating blocks and the two conductive blocks are circumferentially staggered around the end of the positioning hole, an inclined plane is matched between the adjacent insulating blocks and the conductive blocks, the reset mechanism faces the two insulating blocks, when the two conductive blocks lose stress, the reset mechanism drives the two insulating blocks to be close to each other and wrap the end part of the cable so as to protect the exposed part of the end part of the cable, on one hand, the end part of the cable can be prevented from being mechanically damaged by external factors, on the other hand, the outside air can be blocked to a certain extent, the oxidization of the end part of the cable is delayed, and the service life of the cable is prolonged.

Description

Cable connector and cable parallel device

Technical Field

The utility model belongs to the technical field of electrical connection, and particularly relates to a cable connector and a cable parallel device.

Background

The cable is electric energy or signal transmission equipment, in the electric assembly, the cable needs to be connected to corresponding equipment, the most traditional method is to wind the exposed place of the cable through electrician glue to connect the cables, the mode often leads to weak wiring, breakage easily occurs, the operation is complicated when the connected cable is replaced, and the cable is difficult to be suitable for occasions needing to replace the connected cable, such as testing of equipment and connection between different equipment. Therefore, some cable connectors are proposed in the prior art, and the exposed end of the cable is clamped by two metal clamping blocks, so as to realize the connection of the cable, for example, the cable connecting clamp of chinese patent No. CN201720573381.1 and the cable clamp protective housing of CN 201420746488.8. However, the cable is used as a wire for connecting energy supply equipment and processing equipment, so that the cable of the equipment needs to be disconnected when the equipment does not have connection requirements for electricity safety, namely the clamping area needs to be loosened for connection of the next time or connection of other equipment, but after the cable is disconnected, the end part of the cable is exposed in the air and is easy to oxidize, and the end part of the cable is easy to scratch by foreign objects when being stored, so that mechanical damage is caused, and the service life of the cable is influenced.

Disclosure of Invention

The utility model aims to provide a cable connector and a cable parallel device which can protect the end part of a cable after the cable is disconnected.

The present utility model provides a cable connector comprising:

the fixing block is provided with a positioning hole for accommodating or limiting the cable;

the conductive clamp is positioned at one end of the positioning hole, comprises two conductive blocks, and is arranged opposite to each other and is connected with the fixed block in a sliding manner in the radial direction of the positioning hole;

the insulating clamp and the conductive clamp are positioned at the same end of the positioning hole, the insulating clamp comprises two insulating blocks, the two insulating blocks are oppositely arranged and are in sliding connection with the fixed block in the radial direction of the positioning hole, the two insulating blocks and the two conductive blocks are circumferentially staggered around the end of the positioning hole, the adjacent insulating blocks are in inclined plane fit with the conductive blocks, the two conductive blocks are stressed to be close to each other to clamp the end part of the cable, and the two insulating blocks are far away from each other under the inclined plane fit action of the adjacent conductive blocks;

and the reset mechanism is arranged towards the two insulating blocks, and drives the two insulating blocks to be close to each other so as to wrap the end part of the cable when the two conductive blocks lose stress, and the two conductive blocks are far away from each other under the matching action of the inclined planes of the two adjacent insulating blocks.

Further, the fixing block is provided with two first guide plates, the first guide plates extend towards opposite directions, and the two conductive blocks in the single conductive clamp are correspondingly connected with the first guide plates in a sliding mode.

Furthermore, the fixing block is provided with two second guide plates which extend in opposite directions, the first guide plates and the second guide plates are circumferentially staggered around the outer side of the fixing block, and the two insulating blocks in the single insulating clamp are correspondingly and slidably connected with the two second guide plates.

Furthermore, the two conductive clamps and the two insulating clamps are symmetrically arranged at two ends of the positioning hole, one moving plate I is connected to the two guide plates I in a sliding manner, two conductive blocks corresponding to the two conductive clamps in the axial direction of the positioning hole are fixedly connected with the one moving plate I, the other two conductive blocks are fixedly connected with the other moving plate I, the two insulating clamps are symmetrically arranged at two ends of the positioning hole, one moving plate II is connected to the two guide plates II in a sliding manner, and two insulating blocks corresponding to the two insulating clamps in the axial direction of the positioning hole are fixedly connected with the one moving plate II.

Furthermore, the reset mechanism is a spring, the second guide plates are provided with positioning pins, and the spring is sleeved on the positioning pins.

Still further still include the shell, fixed block, conductive clip, insulating clip and canceling release mechanical system all set up in the shell, still be provided with the magnetism on the shell and inhale the piece.

Furthermore, the shell is square, a clamping groove is formed in each of the four inner walls of the shell, and the first guide plate and the second guide plate are respectively inserted into the corresponding clamping grooves.

The utility model also provides a cable parallel connection device, which comprises more than two cable connectors, a box body used for placing the cable connectors, a parallel row arranged in the box body and a power mechanism used for driving the parallel row to move towards the cable connectors, wherein more than two parallel clamps are fixedly arranged on the parallel row, each single parallel clamp comprises two parallel blocks which are oppositely arranged, one surfaces of the two parallel blocks are obliquely arranged, the oblique directions of the two parallel blocks are opposite, and the surfaces of the two conductive blocks in the single conductive clamp are oblique planes matched with the oblique surfaces of the parallel blocks.

Still further, power unit includes screw rod, slider and movable block, slider and screw rod threaded connection, the one side of slider and movable block all is provided with the chute, cooperates through the chute between slider and the movable block, the movable block is used for promoting parallelly connected row and removes.

Furthermore, when the number of the conductive clips in the cable connector is two, two parallel rows are arranged, one surfaces of the two parallel rows provided with the parallel clips are oppositely arranged, the two parallel rows are driven by the same power mechanism, and at least one parallel row is provided with a channel for a cable to pass through.

The utility model has the beneficial effects that the cable connector is arranged at the end part of the cable, when the cable needs to be connected, the conductive clamp is clamped by the conductive connecting piece, so that the two conductive blocks clamp the exposed part of the end part of the cable to conduct, and when the cable needs to be disconnected, the external conductive connecting piece is loosened, the two conductive blocks lose stress, the automatic alternate work between the conductive blocks and the insulating blocks is realized by utilizing the inclined plane fit between the conductive blocks and the insulating blocks and the arrangement of the reset mechanism, when the conductive blocks lose stress, the two insulating blocks can automatically reset and wrap the end part of the cable, and push the two conductive blocks away in the reset process so as to protect the exposed part of the end part of the cable, on one hand, the mechanical damage caused by external factors to the end part of the cable can be avoided, on the other hand, the oxidation of the end part of the cable can be blocked to a certain extent, and the service life of the cable can be prolonged.

Drawings

Fig. 1 is a schematic diagram of the overall structure of the cable connector of the utility model.

Fig. 2 is a schematic view of the cable connector with the outer shell removed.

Fig. 3 is an exploded view of the cable connector of the present utility model.

Fig. 4 is a schematic diagram of a conductive clip holding a cable in a cable connector according to the present utility model.

Fig. 5 is a schematic view of an insulating clip holding a cable in a cable connector according to the present utility model.

Fig. 6 is a schematic diagram of the overall structure of the cable parallel device of the present utility model.

Fig. 7 is a schematic view of the structure of the cable parallel device with the box body removed.

Fig. 8 is a schematic view of the cable connector of fig. 7 according to the present utility model.

Fig. 9 is a schematic structural view of a first embodiment of the parallel rows of the present utility model.

Fig. 10 is a schematic structural view of a parallel row second embodiment of the present utility model.

In the figure, 1-cable connector; 11-a fixed block; 111-positioning holes; 112-first guide plate; 113-a second guide plate; 12-conductive blocks; 13-insulating blocks; 14-a spring; 15-moving the first plate; 16-moving plate II; 17-locating pins; 18-a housing; 181-magnetic attraction piece; 182-clamping groove; 2-a box body; 21-opening; 3-parallel rows; 31-parallel blocks; 32-channels; 4-a power mechanism; 41-screw; 42-sliding blocks; 43-moving block; 44-a hand wheel; 45-gear; 46-racks; 47-connecting plates; 48-insulating plates; 5-cable.

Detailed Description

As shown in fig. 1-5, the utility model provides a cable connector 1, which comprises a fixed block 11, a conductive clamp, an insulating clamp and a reset mechanism, wherein a positioning hole 111 is formed in the fixed block 11, the positioning hole 111 axially penetrates through the fixed block 11 and is used for accommodating or limiting a cable 5, the fixed block 11 can be of a split type assembly structure, for example, the fixed block 11 is formed by splicing two symmetrically arranged subunits, arc-shaped grooves are respectively formed in the two subunits, and after the two subunits are spliced, the arc-shaped groove areas are enclosed to form the positioning hole 111. The conductive clip is located at one end of the positioning hole 111, the conductive clip comprises two conductive blocks 12, the two conductive blocks 12 are oppositely arranged, namely, the two conductive blocks 12 located at one end of the positioning hole 111 and oppositely arranged form a single conductive clip, the two conductive blocks 12 forming the single conductive clip are slidably connected with the fixed block 11 in the radial direction of the positioning hole 111, the two conductive blocks 12 can be mutually close or mutually far away, when the two conductive blocks 12 are mutually close, the end part of the cable 5 is clamped, and the conductive blocks 12 are made of copper.

The insulating clamp and the conductive clamp are positioned at the same end of the positioning hole 111, namely, the end provided with the conductive clamp is also provided with the insulating clamp, the insulating clamp comprises two insulating blocks 13, the two insulating blocks 13 are oppositely arranged, namely, the two insulating blocks 13 positioned at one end of the positioning hole 111 and oppositely arranged form a single insulating clamp, the two insulating blocks 13 forming the insulating clamp are in sliding connection with the fixed block 11 in the radial direction of the positioning hole 111, the two insulating blocks 13 can be mutually close to or mutually far away from each other, and when the two insulating blocks 13 are mutually close to each other, the end part of the cable 5 is wrapped.

The two insulating blocks 13 and the two conductive blocks 12 are circumferentially staggered around the end of the positioning hole 111, and the two insulating blocks 13 are arranged left and right and the two conductive blocks 12 are arranged up and down as illustrated in the view angles of fig. 4 and 5. Among the two insulating blocks 13 and the two conductive blocks 12, the circumferentially adjacent insulating blocks 13 and the conductive blocks 12 are in inclined plane fit, in particular 45-degree inclined plane fit, namely a wedge-shaped inclined plane structure in which the matching surfaces of the adjacent conductive blocks 12 and the adjacent insulating blocks 13 are mutually matched. The reset mechanism is arranged towards the two insulating blocks 13, the reset mechanism is an elastic piece, the two conducting blocks 12 are stressed to be close to each other to clamp the end part of the cable 5, the two insulating blocks 13 are far away from each other under the action of the inclined plane matching with the adjacent conducting blocks 12, and the reset mechanism is in a compressed state at the moment; when the two conductive blocks 12 lose stress, the reset mechanism drives the two insulating blocks 13 to approach each other to wrap the end of the cable 5, namely, in the state shown in fig. 5, the two conductive blocks 12 are far away from each other under the action of the inclined plane cooperation with the adjacent insulating blocks 13.

According to the cable connector 1 provided by the utility model, when the cable 5 is required to be connected, the conductive clamp is clamped by the conductive connecting piece, so that the two conductive blocks 12 clamp the exposed part of the cable 5 end to conduct, and when the cable 5 is required to be disconnected, the external conductive connecting piece is loosened, the two conductive blocks 12 lose stress, the automatic alternate work between the conductive blocks 12 and the insulating blocks 13 is realized by utilizing the inclined plane fit between the conductive blocks 12 and the insulating blocks 13 and the setting of the reset mechanism, when the conductive blocks 12 lose stress, the two insulating blocks 13 can automatically reset and wrap the end of the cable 5, and push the two conductive blocks 12 away in the reset process, so that the exposed part of the cable 5 end is protected, on one hand, the mechanical damage of the cable 5 end caused by external factors can be avoided, on the other hand, the oxidation of the cable 5 end can be blocked to a certain extent, and the service life of the cable 5 is prolonged.

Wherein, in order to ensure that insulating clamp can just wrap up cable 5's tip, two insulating blocks 13 each other are the cambered surface that the opposite one side is the arc surface that matches with cable 5 tip radian in the insulating clamp, and the protection hole of wrap up cable 5 tip is constituteed to the cambered surface of two insulating blocks 13.

The sliding connection manner of the conductive block 12 and the fixed block 11 is specifically that two first guide plates 112 are disposed on the fixed block 11, the two first guide plates 112 extend in opposite directions, as shown in fig. 4 and 5, the two first guide plates 112 are disposed one above the other, and the two conductive blocks 12 in a single conductive clip are correspondingly slidably connected with the two first guide plates 112, i.e. one conductive block 12 in a single conductive clip is slidably connected with one of the first guide plates 112, and the other conductive block 12 is slidably connected with the other first guide plate 112.

The sliding connection manner between the insulating block 13 and the fixing block 11 is specifically that two second guide plates 113 are disposed on the fixing block 11, the two second guide plates 113 extend in opposite directions, as shown in fig. 4 and fig. 5, the two second guide plates 113 are disposed left and right, the two first guide plates 112 and the two second guide plates 113 are circumferentially staggered around the outer side of the fixing block 11, and the two insulating blocks 13 in a single insulating clip are correspondingly slidably connected with the two second guide plates 113, i.e. one insulating block 13 in a single insulating clip is slidably connected with one of the two guide plates 113, and the other insulating block 13 is slidably connected with the other second guide plate 113.

When there are two exposed portions of the end portion of the cable 5 in the axial direction of the cable 5, it is necessary to connect the two exposed portions at the same time when connecting the cable 5. The two conductive clips are symmetrically arranged at two ends of the positioning hole 111, one moving plate I15 is slidably connected to each of the two guide plates I112, the moving plate I15 is specifically sleeved on the guide plate I112 so as to move along the guide plate I112, in the two conductive clips, two conductive blocks 12 corresponding to the two conductive blocks in the axial direction of the positioning hole 111 are fixedly connected with one of the moving plates I15, and the other two conductive blocks 12 corresponding to the two conductive blocks in the axial direction of the positioning hole 111 are fixedly connected with the other moving plate I15, so that the conductive blocks 12 at two ends of the positioning hole 111 can be simultaneously moved through the moving plates I15. The two insulating clamps are symmetrically arranged at two ends of the positioning hole 111, one moving plate two 16 is slidably connected to each of the two guide plates two 113, and the moving plate two 16 is specifically sleeved on the guide plates two 113 so as to move along the guide plates two 113, and in the two insulating clamps, two insulating blocks 13 corresponding to the two insulating clamps in the axial direction of the positioning hole 111 are fixedly connected with one of the moving plates two 16, and the other two insulating blocks 13 corresponding to the two insulating blocks in the axial direction of the positioning hole 111 are fixedly connected with the other moving plate two 16 so as to simultaneously move the insulating blocks 13 at two ends of the positioning hole 111 through the moving plates two 16.

The resetting mechanism is specifically a spring 14, as shown in fig. 2, a positioning pin 17 is disposed on the second guide plates 113, specifically, a groove is formed on the second guide plates 113 along the radial direction of the positioning hole 111, the positioning pin 17 is inserted into the groove, the end is fixed to the end of the second guide plates 113, the spring 14 is sleeved on the positioning pin 17 and can move along the positioning pin 17 in a telescopic manner, the diameter of the spring 14 is greater than the thickness of the second guide plates 113, one end of the spring 14 is abutted to or connected with the end of the positioning pin 17, and the other end of the spring 14 is disposed towards the insulating block 13 or the second moving plate 16. Specifically, when the number of insulating clips is one, the end of the spring 14 is disposed toward the insulating block 13, and when the number of insulating clips is two, the end of the spring 14 is disposed toward the second moving plate 16. Referring to fig. 4, the conductive block 12 is in a state of clamping the end of the cable 5, the spring 14 is in a compressed state, and when the conductive block 12 loses stress, the spring 14 stretches to push the insulating block 13 to clamp and wrap the end of the cable 5, namely, the state shown in fig. 5.

The utility model further comprises a shell 18, the fixed block 11, the conductive clamp, the insulating clamp and the reset mechanism are all arranged in the shell 18 so as to accommodate the components, the shell 18 is also provided with a magnetic attraction piece 181, the magnetic attraction piece 181 is particularly a magnet, the shells of the cable connectors 1 can be magnetically attracted and connected, the storage is convenient, and the magnetic attraction piece 181 can be annular and sleeved or embedded on the shell 18. Preferably, the housing 18 is square, the regular housing 18 is shaped to facilitate positioning and placement of the cable connector 1 during use, the four inner walls of the housing 18 are respectively provided with a clamping groove 182, and the two first guide plates 112 and the two second guide plates 113 are respectively inserted into the corresponding clamping grooves 182, so that assembly is more convenient.

As shown in fig. 6-10, the present utility model further provides a cable parallel device, including more than two cable connectors 1, a box 2 for placing the cable connectors, a parallel row 3 disposed in the box 2, and a power mechanism 4 for driving the parallel row 3 to move toward the cable connectors 1, wherein more than two parallel clips are fixedly disposed on the parallel row 3, the more than two parallel clips are disposed at intervals along the length direction of the parallel row 3, the intervals between the two parallel clips are determined by combining the width or the height of the housing 18, a single parallel clip includes two parallel blocks 31 disposed oppositely, and an interval for accommodating a single conductive clip is reserved between the two parallel blocks 31, as shown in fig. 9 and 10, one side of each of the two parallel blocks 31 in the single parallel clip is disposed obliquely, that is, the two parallel blocks 31 disposed with oblique planes opposite to each other form a single parallel clip, and the oblique directions of the two parallel blocks 31 are opposite to each other, and a V-shaped groove structure is formed between the two parallel blocks 31. Referring to fig. 2 and 3, in the single conductive clip, the surfaces of two conductive blocks 12 are inclined surfaces matched with the inclined surfaces of the parallel blocks 31, so that the parallel rows 3 can only move linearly along the axial direction of the cable 5, the parallel blocks 31 are contacted with the inclined surfaces of the conductive blocks 12, and the conductive blocks 12 are pressed through the inclined surfaces to clamp the end parts of the cable. The parallel rows 3 are made of conductive material, such as copper, and the parallel rows 3 are the conductive connecting pieces.

The parallel device provided by the utility model can be applied to the electric assembly of a plurality of cables and a tool, can conveniently disconnect or connect the cables 5 in parallel, plays a role in conveniently connecting the plurality of cables 5 in parallel, and when disconnected, namely when the parallel row 3 exits, the conductive block 12 loses stress, and the end part of the cable 5 is wrapped by the insulating block 13 to protect the end part of the cable 5. The device can be used by arranging a corresponding number of cable connectors 1 in the box body 1 according to parallel connection requirements, and is suitable for various tools.

The power mechanism 4 comprises a screw 41, a sliding block 42 and a moving block 43, the sliding block 42 is sleeved on the screw 41 and is in threaded connection with the screw 41, when the screw 41 is rotated, the sliding block 42 moves linearly along the axial direction of the screw 41, one surfaces of the sliding block 42 and the moving block 43 are provided with inclined grooves, the sliding block 42 is matched with the moving block 43 through the inclined grooves, and when the sliding block 42 moves, the moving block 43 is driven to move through the matching of the inclined grooves, so that the moving block 43 pushes the parallel rows 31 to move. Specifically, the surface of the sliding block 42 is provided with a plurality of parallel first inclined grooves, the angles of the plurality of first inclined grooves are 45 °, a convex strip is formed between every two adjacent first inclined grooves, one surface of the moving block 43 is provided with a plurality of parallel second inclined grooves, the angles of the plurality of second inclined grooves are the same as the angle and the width of the first inclined grooves, the angles of the plurality of second inclined grooves are 45 °, a convex strip is formed between every two adjacent second inclined grooves, the convex strip penetrates through the first inclined grooves, and meanwhile the convex strip penetrates through the second inclined grooves, namely, a wedge matching structure is formed between the sliding block 42 and the moving block 43, so that when the sliding block 42 moves linearly, the moving block 43 moves transversely in a direction perpendicular to the moving direction of the sliding block 42 under the wedge matching structure, and the parallel rows 31 are pushed to move. Compared with the mode of pushing by an air cylinder or directly pushing by using the sliding block 42, the power mechanism 4 can utilize the space occupied by the parallel rows 3 in the length direction to make the sliding block 42 and the moving block 43 wider, the stress is more uniform during pushing, meanwhile, each chute between the sliding block 42 and the moving block 43 generates acting force between the sliding block 42 and the moving block 43, and the stress can be uniformly dispersed during driving, so that the uniformity of compression during contact between each parallel clamp on the parallel rows 3 and the conductive block 12 is improved. In order to facilitate rotation of the screw 41, one end of the screw 41 is also provided with a hand wheel.

When two conductive clips are arranged in the cable connector 1, two parallel rows 3 are arranged, one surfaces of the two parallel rows 3 provided with the parallel clips are oppositely arranged, the two parallel rows 3 are driven by the same power mechanism 4 through a gear rack mechanism, and particularly referring to fig. 7 and 8, the parallel rows 3 are arranged on a connecting plate 47, the connecting plate 47 plays a role of supporting and bearing the parallel rows 3, the material of the connecting plate is preferably steel, the connecting plate 47 is in sliding fit with the inner wall of the box 2 in the box 2, in order to avoid the connecting plate 47 from affecting the parallel rows 3, an insulating plate 48 is arranged between the connecting plate 47 and the parallel rows 3, racks 45 are arranged on the connecting plate 47 where the two parallel rows 3 are positioned, a gear 46 is arranged between the racks 45 corresponding to the two parallel rows 3 and meshed with the gear 46, the gear 46 is rotationally connected in the box 2, when the moving block 43 pushes the parallel rows 3 to move, the racks 45 on the parallel rows 3 move forward to drive the gears 46 to rotate, and the other parallel rows 3 are driven by the gear 46 to move correspondingly to the other parallel rows 3, so that the two parallel rows 3 are clamped by the two conductive clips 1 simultaneously.

Referring to fig. 6, an opening 21 through which the cable connector 1 and the cable 5 pass is provided on the side of the box body 2, a guiding groove for moving in, moving out and limiting the cable connector 1 is provided inside the box body 2 along the position of the opening 21, the cable connector 1 enters the guiding groove from the position of the opening 21, and can be quickly and conveniently assembled and disassembled, and meanwhile, the guiding groove is used for limiting the cable connector 1 in the axial direction of the cable connector 1. In order to avoid the extension of the cables 5, one of the parallel rows 3 is provided with channels 32 for the cables 5 to pass through, while the connecting plate 47 and the insulating plate 48 where the parallel rows 3 are located are provided with corresponding channels.

Claims (10)

1. A cable connector, comprising:

the fixing block (11), the locating hole (111) for holding or limiting the cable (5) is arranged on the fixing block (11);

the conductive clamp is positioned at one end of the positioning hole (111), and comprises two conductive blocks (12), wherein the two conductive blocks (12) are oppositely arranged and are in sliding connection with the fixed block (11) in the radial direction of the positioning hole (111);

the insulating clamp and the conductive clamp are positioned at the same end of the positioning hole (111), the insulating clamp comprises two insulating blocks (13), the two insulating blocks (13) are oppositely arranged and are in sliding connection with the fixed block (11) in the radial direction of the positioning hole (111), the two insulating blocks (13) and the two conductive blocks (12) are circumferentially staggered around the end of the positioning hole (111), the adjacent insulating blocks (13) and the conductive blocks (12) are in inclined plane fit, the two conductive blocks (12) are stressed to be close to each other to clamp the end part of the cable (5), and the two insulating blocks (13) are far away from each other under the inclined plane fit action of the adjacent conductive blocks (12);

and when the two conductive blocks (12) lose stress, the reset mechanism drives the two insulating blocks (13) to approach each other so as to wrap the end part of the cable (5), and the two conductive blocks (12) are far away from each other under the matching action of the inclined planes of the adjacent insulating blocks (13).

2. A cable connector according to claim 1, wherein the fixing block (11) is provided with two first guide plates (112), the two first guide plates (112) are extended in opposite directions, and the two conductive blocks (12) in the single conductive clip are correspondingly slidably connected with the two first guide plates (112).

3. The cable connector of claim 2, wherein the fixing block (11) is provided with two second guide plates (113), the two second guide plates (113) are extended in opposite directions, the two first guide plates (112) and the two second guide plates (113) are circumferentially staggered around the outer side of the fixing block (11), and the two insulating blocks (13) in the single insulating clamp are correspondingly connected with the two second guide plates (113) in a sliding manner.

4. A cable connector according to claim 3, wherein the two conductive clips and the insulating clip are respectively provided with two conductive clips symmetrically arranged at two ends of the positioning hole (111), one moving plate (15) is slidably connected to each of the two first guide plates (112), among the two conductive clips, two conductive blocks (12) corresponding to the axial direction of the positioning hole (111) are fixedly connected with one moving plate (15), the other two conductive blocks (12) are fixedly connected with the other moving plate (15), the two insulating clips are symmetrically arranged at two ends of the positioning hole (111), one moving plate (16) is slidably connected to each of the two second guide plates (113), among the two insulating clips, two insulating blocks (13) corresponding to the axial direction of the positioning hole (111) are fixedly connected with one moving plate (16), and the other two insulating blocks (13) are fixedly connected with the other moving plate (16).

5. A cable connector according to claim 3 or 4, wherein the return mechanism is a spring (14), two guide plates (113) are provided with positioning pins (17), and the spring (14) is sleeved on the positioning pins (17).

6. A cable connector according to claim 3 or 4, further comprising a housing (18), wherein the fixing block (11), the conductive clip, the insulating clip and the reset mechanism are all arranged in the housing (18), and the housing (18) is further provided with a magnetic attraction member (181).

7. The cable connector of claim 6, wherein the housing (18) is square, each of four inner walls of the housing (18) is provided with a clamping groove (182), and the two first guide plates (112) and the two second guide plates (113) are respectively inserted into the corresponding clamping grooves (182).

8. A cable parallel device, characterized by comprising more than two cable connectors (1) according to any one of claims 1-7, further comprising a box body (2) for placing the cable connectors (1), a parallel row (3) arranged in the box body (2) and a power mechanism (4) for driving the parallel row (3) to move towards the cable connectors (1), wherein more than two parallel clamps are fixedly arranged on the parallel row (3), a single parallel clamp comprises two parallel blocks (31) which are oppositely arranged, the two parallel blocks (31) are obliquely arranged on opposite sides, the oblique directions of the two parallel blocks are opposite, and the surfaces of the two conductive blocks (12) in the single conductive clamp are oblique planes matched with the oblique planes of the parallel blocks (31).

9. The cable parallel arrangement as claimed in claim 8, characterized in that the power mechanism (4) comprises a screw (41), a slide block (42) and a moving block (43), the slide block (42) is in threaded connection with the screw (41), one surfaces of the slide block (42) and the moving block (43) are provided with a chute, the slide block (42) and the moving block (43) are matched through the chute, and the moving block (43) is used for pushing the parallel row (31) to move.

10. The cable parallel arrangement according to claim 8, wherein when there are two conductive clips in the cable connector (1), the parallel rows (3) are two, one surface of the two parallel rows (3) provided with the parallel clips is opposite to the other surface of the two parallel rows (3), the two parallel rows (3) are driven by the same power mechanism (4), and a channel (32) through which the cable (5) passes is formed in at least one parallel row (3).

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