CN219980036U - Branching machine - Google Patents

Abstract

The utility model discloses a branching machine, and relates to the technical field of electronic part processing. The branching machine comprises a line pressing component, a first positioning component, a second positioning component and a transferring component; the lower pressing piece is arranged above the first supporting piece, the first driving piece is used for driving the lower pressing piece to move up and down, and the first supporting piece is used for supporting wires; the rotating piece can rotate the wire rod; the first detection piece is arranged above the first supporting piece and is used for detecting wires; the core clamping piece can clamp a plurality of core wires, and the third driving piece is connected with the core clamping piece and can drive the core clamping piece to rotate; the second detection piece is positioned above the sandwich piece, is electrically connected with the sandwich piece and can detect wires; the transfer assembly is arranged on one side of the first positioning assembly and used for moving wires on the first supporting piece to the second supporting piece. The wire dividing machine can adjust the position of the core wire of the wire rod, is high in automation degree, can ensure processing quality and meets production requirements.

Description

Branching machine

Technical Field

The utility model relates to the technical field of electronic part processing and production, in particular to a branching machine.

Background

The USB data wire is a wire commonly used for connection and communication between electronic equipment such as a computer, a mobile phone and the like and external equipment, and can be used for transmitting data and charging, when the USB data wire is processed, the outer skin of the end part of the cut original data wire is required to be peeled off so as to expose a plurality of core wires in the original data wire, the colors of the wrapping layers of different core wires are different, then the original data wire is separated, namely, the plurality of core wires are pushed onto the same plane according to the sequence of the specific colors of the wrapping layers of the core wires in the original data wire, then the plurality of core wires are respectively arranged in different wire clamps, and finally the core wires are welded with the USB interface terminal.

The USB data line is inside to be constituteed by four heart yearns of red, white green and black generally, needs bulldoze these four heart yearns to the coplanar according to specific colour order before the welding, in present production operation, the branch line sequencing work of heart yearn mainly relies on the manual work to accomplish, because the human eye tired easily after long-time work for the condition of colour sequencing mistake very easily appears for operating personnel, and influence operating personnel's separated time efficiency, be difficult to guarantee processingquality, unable meeting production demand.

Disclosure of Invention

The present utility model aims to solve at least one of the technical problems existing in the prior art. Therefore, the utility model provides a wire dividing machine which can adjust the position of a core wire of a wire rod and has high automation degree.

According to an embodiment of the utility model, a branching machine includes: the line pressing assembly comprises a first driving piece, a first bearing piece and a pressing piece; the lower pressing piece is arranged above the first supporting piece and is in driving connection with the first driving piece, the first driving piece is used for driving the lower pressing piece to move up and down, and the first supporting piece is used for supporting wires; the first positioning assembly comprises a first detection piece and a rotating piece; the rotating piece is positioned at one side of the first supporting piece and can rotate the wire rod; the first detection piece is arranged above the first bearing piece and is electrically connected with the rotating piece, and the first detection piece is used for detecting wires; the second positioning assembly comprises a second detection piece, a second bearing piece, a third driving piece and a sandwich piece; the second supporting piece is positioned on one side of the sandwich piece and is used for bearing wires, the sandwich piece can clamp a plurality of core wires, and the third driving piece is connected with the sandwich piece and can drive the sandwich piece to rotate; the second detection piece is positioned above the sandwich piece, is electrically connected with the sandwich piece and can detect wires; and the transferring assembly is arranged on one side of the first positioning assembly and is used for moving wires on the first supporting piece to the second supporting piece.

The branching machine provided by the utility model has at least the following beneficial effects: in the embodiment of the utility model, four core wires are annularly arranged in a wire, the end part of the wire is provided with four core wire end parts exposed outside, a first supporting piece is used for supporting the wire, a first detecting piece is arranged above the first supporting piece, so that the first detecting piece can detect the color and the position of the core wire end of the end part of the wire on the first supporting piece, the rotating piece can rotate the wire so as to drive the four core wires to synchronously rotate, the first detecting piece is electrically connected with the rotating piece, the rotating piece rotates the wire until the first detecting piece detects that the core wire with the preset color is positioned at the preset position, wherein the height of the core wire with the preset color is higher than the height of the other three core wires, after the first detecting piece detects that the core wire with the preset color is moved to the preset position, the rotating piece stops rotating, and then the first driving piece can drive the pressing piece to move downwards, so that the wire can be pressed down to the four core wire end heads on the first supporting piece, so that the four core wires are positioned on the same plane, and the core wires are positioned at the initial position; the transfer assembly transfers wires on the first supporting piece to the second supporting piece, the sandwich piece is positioned on one side of the second supporting piece, two core wires in the four core wires can be clamped through the sandwich piece, the second detection piece is positioned above the sandwich piece, the color of the core wires of the wires can be detected through the second detection piece so as to judge whether the color of the core wires is arranged according to a preset color sequence, the second detection piece is electrically connected with the sandwich piece, detection signals can be transmitted to the sandwich piece, the sandwich piece can clamp the two core wires, the third driving piece drives the sandwich piece to rotate so as to drive the two core wires to synchronously rotate, and therefore the positions of the two core wires can be turned until the color of the four core wires is adjusted to be arranged according to the preset color sequence; the wire dividing machine can adjust the position of the core wire of the wire rod, is high in automation degree, can ensure processing quality and meets production requirements.

According to some embodiments of the utility model, the wire dividing assembly comprises a first wire dividing block and a second driving piece, wherein the bottom end of the first wire dividing block is provided with a plurality of first wire dividing grooves for accommodating core wires, the first wire dividing block is arranged above the first supporting piece and connected with the second driving piece, and the second driving piece is used for driving the first wire dividing block to move up and down.

According to some embodiments of the utility model, the first supporting member further comprises a first supporting block and a second supporting block, the first supporting block is arranged on one side of the second supporting block, a through groove is formed in the upper portion of the first supporting block, the through groove penetrates through two side ends of the first supporting block, the first branching block is located above the through groove, and the second driving member can drive the first branching block to move downwards so as to enable the first branching block to be in butt joint with the inner wall of the through groove.

According to some embodiments of the utility model, the wire pressing assembly further comprises a first lifting member, and the first lifting member is connected with the first bearing block and can drive the first bearing block to move up and down.

According to some embodiments of the utility model, the core clamping piece comprises a core clamping driving piece, a first core clamping block and a second core clamping block, wherein a plurality of first core clamping grooves are formed in the first core clamping block, a plurality of second core clamping grooves are formed in the second core clamping block, the first core clamping grooves and the second core clamping grooves are oppositely arranged one by one, and the core clamping driving piece is respectively connected with the first core clamping block and the second core clamping block and can drive the first core clamping block and the second core clamping block to be close to and far away from each other.

According to some embodiments of the utility model, the transfer assembly further comprises a conveying member, the conveying member is disposed on one side of the sandwich member, the second supporting members are disposed in plurality and one by one on the conveying member, and the conveying member can drive the second supporting members to move.

According to some embodiments of the utility model, a second branching block is arranged on one side of the second supporting member, which is close to the core member, and a plurality of second branching grooves for accommodating core wires are arranged on the second branching block.

According to some embodiments of the utility model, the second positioning assembly further comprises a fourth driving member, wherein the fourth driving member is connected with the core member and can drive the core member to move towards or away from the second supporting member.

According to some embodiments of the utility model, the transfer assembly further comprises a gripping member and a first moving member; the clamping piece is arranged on one side, far away from the first supporting piece, of the rotating piece; the clamping piece comprises two clamping driving pieces and two clamping blocks, wherein the two clamping blocks are oppositely arranged, the clamping driving pieces are connected with the clamping blocks and can drive the two clamping blocks to be close to or far away from each other; the first driving piece is connected with the clamping piece and can drive the clamping piece to move towards a direction close to or far away from the first supporting piece.

According to some embodiments of the utility model, the rotating member comprises a rotating driving member and a plurality of rotating wheels, wherein the rotating driving member is connected with the rotating wheels and can drive the rotating wheels to synchronously rotate, and the rotating wheels can be abutted with the wires and can support the wires.

Additional aspects and advantages of the utility model will be set forth in part in the description which follows, and in part will be obvious from the description, or may be learned by practice of the utility model.

Drawings

The foregoing or additional aspects and advantages of the utility model will become apparent and readily appreciated from the following description of the embodiments, taken in conjunction with the accompanying drawings, in which:

FIG. 1 is a schematic diagram of the structure of a wire pressing assembly, a first positioning assembly and a transfer assembly of the wire dispenser of the present utility model;

FIG. 2 is a schematic view of a portion A of the wire pressing assembly, the first positioning assembly and the transfer assembly of the wire dispenser of FIG. 1;

FIG. 3 is a schematic diagram of a second positioning assembly of the branching machine according to the present utility model;

FIG. 4 is a schematic view of a portion B of the second positioning assembly of the wire-branching machine of FIG. 3;

FIG. 5 is a schematic view of the wire pressing assembly, the transferring assembly and the wire separating assembly of the wire separating machine of the present utility model;

fig. 6 is a schematic structural diagram of a second positioning assembly of the branching machine of the present utility model.

Reference numerals:

a wire 10; a wire pressing assembly 100; a first support 110; a first support block 111; a second support block 112; a through groove 113; a hold-down member 120; a first driving member 130; a first elevating member 140; a first positioning assembly 200; a first detecting member 210; a rotating member 220; a rotating wheel 221; a second positioning assembly 300; a second support 310; a second branching block 311; a second wire dividing groove 312; a second detecting member 320; a sandwich element 330; a first core block 331; a second core block 332; a sandwich driver 333; a third driving member 340; a fourth driving member 350; a transfer assembly 400; a conveyance member 410; a clamp 420; a clamp block 421; a grip drive 422; a first mover 430; a second mover 440; a third mover 450; a wire-dividing assembly 500; a first branching block 510; a first dividing groove 511; a first bump structure 512; a second raised structure 513; and a second driving member 520.

Detailed Description

Embodiments of the present utility model are described in detail below, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to like or similar elements or elements having like or similar functions throughout. The embodiments described below by referring to the drawings are illustrative only and are not to be construed as limiting the utility model.

In the description of the present utility model, it should be understood that the direction or positional relationship indicated with respect to the description of the orientation, such as up, down, left, right, front, rear, etc., is based on the direction or positional relationship shown in the drawings, is merely for convenience of describing the present utility model and simplifying the description, and does not indicate or imply that the apparatus or element to be referred to must have a specific orientation, be constructed and operated in a specific orientation, and thus should not be construed as limiting the present utility model.

In the description of the present utility model, the description of the first and second is only for the purpose of distinguishing technical features, and should not be construed as indicating or implying relative importance or implying the number of technical features indicated or the precedence of the technical features indicated.

In the description of the present utility model, unless explicitly defined otherwise, terms such as arrangement, installation, connection, etc. should be construed broadly and the specific meaning of the terms in the present utility model can be reasonably determined by a person skilled in the art in combination with the specific contents of the technical scheme.

A branching machine according to an embodiment of the present utility model is described below with reference to fig. 1 to 6.

According to the branching machine provided by the embodiment of the utility model, the branching machine comprises a line pressing assembly 100, a first position adjusting assembly 200, a second position adjusting assembly 300 and a transferring assembly 400; the wire pressing assembly 100 comprises a first driving member 130, a first supporting member 110 and a pressing member 120; the pressing piece 120 is disposed above the first supporting piece 110 and is in driving connection with the first driving piece 130, the first driving piece 130 is used for driving the pressing piece 120 to move up and down, and the first supporting piece 110 is used for supporting the wire 10; the first positioning assembly 200 comprises a first detecting member 210 and a rotating member 220; the rotating member 220 is located at one side of the first supporting member 110 and is capable of rotating the wire 10; the first detecting element 210 is disposed above the first supporting element 110 and electrically connected to the rotating element 220, and the first detecting element 210 is used for detecting the wire 10; the second positioning assembly 300 comprises a second detecting member 320, a second supporting member 310, a third driving member 340 and a sandwich member 330; the second supporting member 310 is located at one side of the core member 330 and is used for carrying the wires 10, the core member 330 can clamp a plurality of core wires, and the third driving member 340 is connected with the core member 330 and can drive the core member 330 to rotate; the second detecting member 320 is located above the core member 330, is electrically connected to the core member 330, and is capable of detecting the wire 10; the transferring assembly 400 is disposed at one side of the first positioning assembly 200, and the transferring assembly 400 is used for moving the wire 10 on the first supporting member 110 to the second supporting member 310.

In the embodiment of the utility model, four core wires are annularly arranged in the wire 10, the end part of the wire 10 is provided with four core wire end parts exposed outside, the first supporting member 110 is used for supporting the wire 10, the first detecting member 210 is arranged above the first supporting member 110, so that the first detecting member 210 can detect the color and the position of the core wire end of the end part of the wire 10 on the first supporting member 110, the rotating member 220 can rotate the wire 10 so as to drive the four core wires to synchronously rotate, the first detecting member 210 is electrically connected with the rotating member 220, the rotating member 220 rotates the wire 10 until the first detecting member 210 detects that the core wire with the preset color is positioned at the preset position, wherein the height of the core wire with the preset color is higher than the height of the other three core wires, after the first detecting member 210 detects that the core wire with the preset color is moved to the preset position, the rotating member 220 stops rotating, and then the first driving member 130 can drive the pressing member 120 to move downwards, so that the pressing member 120 can press the end part 10 downwards, and the core wire with the preset color is positioned at the preset position, the first core wire end of the same as the core wire 110; the transferring assembly 400 transfers the wires 10 on the first supporting member 110 to the second supporting member 310, the core clamping member 330 is located at one side of the second supporting member 310, two core wires of the four core wires can be clamped through the core clamping member 330, the second detecting member 320 is located above the core clamping member 330, the color of the core wires of the wires 10 can be detected through the second detecting member 320 so as to judge whether the color of the core wires are arranged according to a preset color sequence, the second detecting member 320 is electrically connected with the core clamping member 330, detection signals can be transmitted to the core clamping member 330, the core clamping member 330 can clamp the two core wires, the third driving member 340 drives the core clamping member 330 to rotate so as to drive the two core wires to rotate synchronously, and therefore the positions of the two core wires can be adjusted until the color of the four core wires is adjusted, and the color mounting of the core wires is arranged according to the preset sequence; the wire dividing machine can adjust the position of the core wire of the wire 10, is high in automation degree, can ensure processing quality and meets production requirements.

The first detecting element 210 and the second detecting element 320 are both camera detecting modules or other visual detecting structures.

Referring to fig. 1, 2 and 5, it can be understood that the wire-separating assembly 500 further includes a wire-separating assembly 500, the wire-separating assembly 500 includes a first wire-separating block 510 and a second driving member 520, a plurality of first wire-separating slots 511 for accommodating the core wires are disposed at the bottom end of the first wire-separating block 510, the first wire-separating block 510 is disposed above the first supporting member 110 and connected with the second driving member 520, and the second driving member 520 is used for driving the first wire-separating block 510 to move up and down.

The first supporting member 110 is used for supporting the wires 10 and the core wires, after the four core wires are pushed down by the pushing member 120 to push the core wires to be located on the same horizontal plane, the second driving member 520 drives the first branching block 510 to move downwards, so that the bottom end of the first branching block 510 is abutted to the first supporting member 110, a plurality of first branching grooves 511 are formed in the bottom end of the first branching block 510, and the plurality of core wires are located in the plurality of first branching grooves 511 one by one so as to separate the core wires, so that the core wires are prevented from blocking each other, and the detection difficulty of the core wires detected by the first detecting member 210 is reduced; specifically, the first wire dividing grooves 511 are provided with four, and the four first wire dividing grooves 511 are arranged in order in the horizontal direction and in order in the radial direction of the wire 10.

Referring to fig. 2 and 5, it can be understood that the first bearing member 110 further includes a first bearing block 111 and a second bearing block 112, the first bearing block 111 is disposed on one side of the second bearing block 112, a through groove 113 is disposed on an upper portion of the first bearing block 111, the through groove 113 penetrates through two side ends of the first bearing block 111, the first branching block 510 is disposed above the through groove 113, and the second driving member 520 can drive the first branching block 510 to move downward, so as to enable the first branching block 510 to abut against an inner wall of the through groove 113.

The first supporting block 111 is arranged on one side of the second supporting block 112, the through groove 113 is formed in the upper portion of the first supporting block 111, the wire 10 can pass through the through groove 113 from one side of the first supporting block 111 and move to the upper portion of the second supporting block 112, the position of the wire 10 can be limited by the through groove 113, the bottom wall surface of the through groove 113 and the top end surface of the second supporting block 112 are arranged in a coplanar mode, so that the first supporting block 111 and the second supporting block 112 can jointly support the wire 10 through the through groove 113, the first branching block 510 is located above the through groove 113, the second driving piece 520 drives the first branching block 510 to move downwards, the bottom end of the first branching block 511 is abutted to the inner wall of the through groove 113, the through groove 113 is closed through the inner wall of the through groove 113, the core wires are prevented from falling out of the lower portion of the first branching block 511, the core wires can be prevented from being adhered to each other through the first supporting block 111 and the first branching block 510.

Specifically, two opposite inner side walls of the through groove 113 are obliquely arranged towards a direction away from the bottom wall of the through groove 113, a first bulge structure 512 and a second bulge structure 513 are arranged at the lower end of the first branching block 510, the second bulge structure 513 is provided with two inclined surfaces which are respectively positioned at two sides of the first bulge structure 512, the first bulge structure 512 and the second bulge structure 513 are arranged at intervals, a first branching groove 511 is formed between the first bulge structure 512 and the second bulge structure 513, and a first branching groove 511 is formed at one side of the second bulge structure 513 away from the first bulge structure 512, so that four first branching grooves 511 are formed, the length of the first bulge structure 512 is longer than that of the second bulge structure 513, and one side of the second bulge structure 513 away from the first bulge structure 512 is provided with an inclined surface, the bottom end of the first bulge structure 512 is in butt joint with the bottom wall of the through groove 113, and the inclined surface at one side end of the second bulge structure 513 is in butt joint with the inner side walls of the through groove 113, so that the core wires positioned at the same side of the first bulge structure 512 are different in height, and a plurality of core wires can be separated more; wherein the two second bump structures 513 are symmetrically arranged with respect to the first bump structure 512.

Referring to fig. 5, it can be understood that the wire pressing assembly 100 further includes a first lifting member 140, where the first lifting member 140 is connected to the first supporting block 111 and can drive the first supporting block 111 to move up and down.

The first supporting block 111 can be controlled to move up and down by providing the first elevating member 140 so that the height of the first supporting block 111 can be controlled; specifically, the second supporting block 112 is configured to support the core wire, after the four core wires are pressed down by the pressing piece 120 to push the core wires to be located on the same horizontal plane, the first lifting piece 140 drives the first supporting block 111 to move upwards until the bottom wall surface of the through slot 113 of the first supporting block 111 is coplanar with the top end surface of the second supporting block 112, and the second driving piece 520 drives the first branching block 510 to move downwards to abut against the inner wall of the through slot 113.

Referring to fig. 3 and 6, it can be understood that the core member 330 includes a core driving member 333, a first core block 331 and a second core block 332, a plurality of first core grooves are disposed on the first core block 331, a plurality of second core grooves are disposed on the second core block 332, the first core grooves and the second core grooves are disposed one to one, and the core driving member 333 is connected with the first core block 331 and the second core block 332, respectively, and is capable of driving the first core block 331 and the second core block 332 to approach each other and separate from each other.

The core wire can stretch into between first core piece 331 and the second core piece 332, and the core driving piece 333 is close to each other through driving first core piece 331 and second core piece 332, can make the internal face in first core groove and the internal face in second core groove all with the core wire butt to clip the core wire, the core driving piece 333 connection of third driving piece 340 and core piece 330 through driving core driving piece 333 rotation, can drive the core wire rotation that first core piece 331 and second core piece 332 centre gripping.

Specifically, since the wire 10 is generally an arc-shaped groove, the first and second core grooves reduce damage to the core wire caused by core wire being pinched; the first core clamping groove and the second core clamping groove are both arranged in two, two adjacent core wires can be clamped through the two first core clamping grooves and the two second core clamping grooves, and the two core wires are rotated, so that the positions of the two core wires outside the wire 10 can be exchanged.

Referring to fig. 3, it can be understood that the transferring assembly 400 further includes a conveying member 410, the conveying member 410 is disposed on one side of the core 330, and the second supporting members 310 are disposed on the conveying member 410 one by one, and the conveying member 410 can drive the plurality of second supporting members 310 to move.

The conveying piece 410 is arranged on one side of the sandwich piece 330, so that the conveying piece 410 can sequentially move the second supporting pieces 310 to one side close to the sandwich piece 330, and the working efficiency is improved; specifically, the conveying member 410 may be a conveying belt assembly or a guide conveying structure, and the plurality of second supporting members 310 are sequentially arranged at intervals along the conveying direction of the conveying member 410.

Referring to fig. 3 and 4, it can be understood that the second supporter 310 is provided with a second branching block 311 at a side near the core 330, and a plurality of second branching grooves 312 for receiving the core wire are provided on the second branching block 311.

The second supporting piece 310 is used for placing the wires 10, four core wires of the wires 10 are placed in the plurality of second branching grooves 312 of the second branching block 311 one by one, and the core wires can be separated in the process of conveying the second supporting piece 310 by the conveying piece 410 through the second branching block 311; specifically, the second wiring grooves 312 are provided with four.

Referring to fig. 6, it can be appreciated that the second positioning assembly 300 further includes a fourth driving member 350, wherein the fourth driving member 350 is connected to the core member 330 and is capable of driving the core member 330 to move in a direction approaching or moving away from the second supporting member 310.

The fourth driving member 350 can drive the core member 330 to move in a direction away from the second supporting member 310, so as to prevent the wire 10 from colliding with the core member 330 when the conveying member 410 conveys the second supporting member 310 to move so as to drive the wire 10 to move to one side of the core member 330; when the second detecting member 320 detects that the order of the four core wires of the wire 10 is incorrect, the fourth driving member 350 drives the core member 330 to move toward the direction approaching the second supporting member 310, so that the core member 330 can clamp the plurality of core wires.

Referring to fig. 1 and 5, it can be appreciated that the transfer assembly 400 further includes a clamping member 420 and a first moving member 430; the clamping member 420 is disposed on a side of the rotating member 220 away from the first supporting member 110; the clamping piece 420 comprises a clamping driving piece 422 and a clamping block 421, wherein the two clamping blocks 421 are oppositely arranged, and the clamping driving piece 422 is connected with the clamping block 421 and can drive the two clamping blocks to be close to or far away from each other; the first driving member 130 is connected to the clamping member 420, and is capable of driving the clamping member 420 to move toward or away from the first supporting member 110.

Specifically, clamping grooves are provided on opposite end surfaces of the clamping blocks 421, and the wire 10 can be placed in the clamping grooves, and the clamping blocks 421 are driven to approach each other by the clamping driving piece 422 so as to be capable of clamping the wire 10; the first moving member 430 can drive the clamping member 420 to move toward a direction approaching or separating from the first supporting member 110, after the clamping member 420 clamps the wire 10 by the clamping block 421, the first moving member 430 can drive the clamping member 420 to move toward a direction approaching the first supporting member 110, so that the first supporting member 110 can support the wire 10, and can move the wire 10 to a position below the first detecting member 210, and when the rotating member 220 needs to rotate the wire 10, the clamping driving member 422 drives the clamping block 421 to move toward a direction separating from each other by a certain distance, so that the wire 10 can be prevented from being excessively clamped, and the rotating member 220 can rotate the wire 10.

Specifically, after the pressing member 120 and the first supporting member 110 press the core wire, the clamping driving member 422 can clamp the wire 10 through the clamping block 421, and then the first moving member 430 drives the clamping member 420 to move towards a direction away from the first supporting member 110, so that the wire 10 can move out of the first supporting member 110, and the core wire can be separated from each other by matching with the first branching block 510.

Specifically, the transfer assembly 400 further includes a second moving member 440 and a third moving member 450; the second moving member 440 is connected with the first moving member 430, and can drive the first moving member 430 to move along the second horizontal direction, so as to drive the clamping member 420 to move along the second horizontal direction, the third moving member 450 is connected with the second moving member 440, and can drive the second moving member 440 to move up and down, so as to drive the clamping member 420 to move up and down, and the clamping member 420 and the wire 10 can be driven to move through the first moving member 430, the second moving member 440 and the third moving member 450, and the clamping member 420 can be moved onto the second supporting member 310 of the conveying member 410, so that the wire 10 on the first supporting member 110 can be transferred onto the second supporting member 310.

Specifically, the first moving member 430, the second moving member 440, and the third moving member 450 may be in other driving forms such as a screw driving structure or a slide rail and slider driving structure; an included angle is formed between the first horizontal direction and the second horizontal direction, wherein the first horizontal direction and the second horizontal direction can be mutually perpendicular.

Referring to fig. 2, it can be understood that the rotating member 220 includes a rotating driving member and a plurality of rotating wheels 221, the rotating driving member is connected with the rotating wheels 221, and can drive the rotating wheels 221 to rotate synchronously, and the rotating wheels 221 can abut against the wire 10 and can support the wire 10.

The wire 10 can be partially placed on the rotating wheels 221, the wire 10 can be borne by the rotating wheels 221, the rotating driving piece drives the rotating wheels 221 to synchronously rotate and can drive the wire 10 to rotate, specifically, the rotating piece 220 can drive the wire 10 to rotate around the axis direction of the wire 10 through rotation, and the rotation axis of the rotating wheels 221 is coaxial with the rotation axis of the wire 10; the rotating wheel 221 may be provided in plurality to improve stability of the rotary wire 10, and the rotary driving member may be a motor or other driving structure.

In the description of the present specification, a description of the terms "one embodiment," "some embodiments," or "some examples," etc., means that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the utility model. In this specification, schematic representations of the above terms do not necessarily refer to the same embodiments or examples. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

While embodiments of the present utility model have been shown and described, it will be understood by those of ordinary skill in the art that: many changes, modifications, substitutions and variations may be made to the embodiments without departing from the spirit and principles of the utility model, the scope of which is defined by the claims and their equivalents.

Claims (10)

1. The branching machine, its characterized in that includes:

the line pressing assembly comprises a first driving piece, a first bearing piece and a pressing piece; the lower pressing piece is arranged above the first supporting piece and is in driving connection with the first driving piece, the first driving piece is used for driving the lower pressing piece to move up and down, and the first supporting piece is used for supporting wires;

the first positioning assembly comprises a first detection piece and a rotating piece; the rotating piece is positioned at one side of the first supporting piece and can rotate the wire rod; the first detection piece is arranged above the first bearing piece and is electrically connected with the rotating piece, and the first detection piece is used for detecting wires;

the second positioning assembly comprises a second detection piece, a second bearing piece, a third driving piece and a sandwich piece; the second supporting piece is positioned on one side of the sandwich piece and is used for bearing wires, the sandwich piece can clamp a plurality of core wires, and the third driving piece is connected with the sandwich piece and can drive the sandwich piece to rotate; the second detection piece is positioned above the sandwich piece, is electrically connected with the sandwich piece and can detect wires;

and the transferring assembly is arranged on one side of the first positioning assembly and is used for moving wires on the first supporting piece to the second supporting piece.

2. The wire branching machine of claim 1, further comprising a wire branching assembly, wherein the wire branching assembly comprises a first wire branching block and a second driving member, a plurality of first wire branching grooves for accommodating core wires are formed in the bottom ends of the first wire branching block, the first wire branching block is arranged above the first supporting member and connected with the second driving member, and the second driving member is used for driving the first wire branching block to move up and down.

3. The branching machine according to claim 2, wherein the first supporting member further comprises a first supporting block and a second supporting block, the first supporting block is disposed on one side of the second supporting block, the first supporting block) is provided with a through groove on the upper portion, the through groove penetrates through two side ends of the first supporting block, the first branching block is located above the through groove, and the second driving member can drive the first branching block to move downwards so as to enable the first branching block to abut against an inner wall of the through groove.

4. The wire dispenser of claim 3, wherein the wire pressing assembly further comprises a first lifting member, wherein the first lifting member is connected to the first support block and is capable of driving the first support block to move up and down.

5. The branching machine of claim 1, wherein the core member comprises a core driving member, a first core block and a second core block, a plurality of first core grooves are formed in the first core block, a plurality of second core grooves are formed in the second core block, the first core grooves and the second core grooves are oppositely arranged one by one, and the core driving member is respectively connected with the first core block and the second core block and can drive the first core block and the second core block to be close to and far away from each other.

6. The branching machine of claim 1, wherein the transfer assembly further comprises a conveying member, the conveying member is disposed on one side of the core member, the second support members are disposed in plurality on the conveying member one by one, and the conveying member is capable of driving the plurality of second support members to move.

7. The wire-dividing machine of claim 1, wherein a second wire-dividing block is disposed on a side of the second support member adjacent to the core member, and a plurality of second wire-dividing grooves are disposed on the second wire-dividing block for accommodating the core wires.

8. The branching machine of claim 1, wherein said second positioning assembly further comprises a fourth drive member coupled to said core member and capable of driving said core member in a direction toward or away from said second support member.

9. The wire-dividing machine of claim 1, wherein the transfer assembly further comprises a clamp and a first moving member; the clamping piece is arranged on one side, far away from the first supporting piece, of the rotating piece; the clamping piece comprises two clamping driving pieces and two clamping blocks, wherein the two clamping blocks are oppositely arranged, the clamping driving pieces are connected with the clamping blocks and can drive the two clamping blocks to be close to or far away from each other; the first driving piece is connected with the clamping piece and can drive the clamping piece to move towards a direction close to or far away from the first supporting piece.

10. The wire dividing machine according to claim 1, wherein the rotating member comprises a rotating driving member and a plurality of rotating wheels, the rotating driving member is connected with the rotating wheels and can drive the rotating wheels to synchronously rotate, and the rotating wheels can be abutted with wires and can support the wires.