CN219677751U - Conveying device convenient for cable end processing - Google Patents

Abstract

The utility model discloses a conveying device convenient for processing cable ends, which relates to the technical field of processing machinery and comprises two groups of guide driving assemblies, two positioning blocks and a plurality of clamping assemblies; the two guide driving assemblies are symmetrically arranged, the direction along the guide travel of the guide driving assemblies is a longitudinal direction, and the direction perpendicular to the longitudinal direction is a transverse direction; the two positioning blocks are arranged between the two guide driving assemblies, the upper end face of each positioning block is provided with a plurality of positioning grooves, and the two positioning grooves in the transverse direction are mutually symmetrical; the clamping assemblies have a moving stroke in the vertical direction, each guiding driving assembly is provided with a plurality of clamping assemblies, and the two clamping assemblies in the transverse direction are symmetrical to each other and form a clamping station for clamping two ends of a cable. The conveying device convenient for processing the cable end part can translate and convey the cable in sections, and the stepping type conveying cable is accurate in positioning and is beneficial to positioning and processing the cable end part.

Description

Conveying device convenient for cable end processing

Technical Field

The utility model relates to the technical field of processing machinery, in particular to a conveying device convenient for processing of cable ends.

Background

The processing of a cable includes various processing steps, such as stripping the cable end, and attaching a connection terminal to the exposed cable. In addition, a pretension test is also required for the cable to which the connection terminal has been mounted to determine whether the connection terminal is firmly mounted.

The above-mentioned processes correspond to various devices or processing apparatuses, and the cable is generally manually held by hand, and the end portion is inserted into the corresponding device or apparatus to process the end portion of the cable. To achieve automated production of cable end processing, two difficulties exist that need to be addressed. The first is how various devices and processing devices are arranged and distributed, such as a device for peeling off the cable sheath or a device for adding a connecting terminal to the end of the cable; the second is how the cable is transported between these devices or apparatuses for operation to facilitate the processing of the cable ends.

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 the conveying device which is convenient for processing the cable end, can translate and convey the cable in sections, is accurate in positioning of the stepping conveying cable and is beneficial to positioning and processing the cable end.

According to an embodiment of the utility model, a conveying device for facilitating cable end processing comprises: the two groups of guide driving assemblies are symmetrically arranged, so that the guide strokes of the two guide driving assemblies are parallel to each other;

in a plane formed by the guide strokes of the two guide driving assemblies, the direction along the guide stroke of the guide driving assemblies is a longitudinal direction, and the direction perpendicular to the guide stroke of the guide driving assemblies is a transverse direction;

the two positioning blocks are arranged between the two guide driving assemblies, the length directions of the two positioning blocks are parallel to the longitudinal direction, a plurality of positioning grooves are formed in the upper end face of each positioning block, the positioning grooves are distributed in a arrayed mode along the length direction of the positioning block, and the two positioning grooves in the transverse direction are mutually symmetrical;

the clamping assemblies are provided with moving strokes in the vertical direction, each guiding driving assembly is provided with a plurality of clamping assemblies, the clamping assemblies are distributed in a longitudinal direction, and the clamping assemblies in the transverse direction are symmetrical to each other and form a clamping station for clamping two ends of a cable.

The conveying device convenient for processing the cable end part has at least the following beneficial effects: the clamping assemblies are arranged on two sides and are symmetrical to each other, and the two clamping assemblies in the transverse direction jointly clamp one cable. The guide driving assembly is used for driving the clamping assemblies to synchronously move, and the clamping assemblies move for a fixed distance for a single time to realize step-by-step transportation, and the step-by-step transportation distance corresponds to the distance between two adjacent positioning grooves on the positioning block, so that the clamping assemblies can clamp the cable and place the cable in the positioning grooves. The cable in the positioning groove is in a straight state, two ends of the cable are in a suspended state, other equipment or devices are convenient to butt joint and directly process the end part of the cable, the position of the positioning groove is always fixed, the position of the cable is convenient to determine, and equipment or devices for processing the end part of the cable are conveniently arranged. The cable is provided with a plurality of positioning grooves along the guiding travel direction of the guiding driving assembly, so that the cable is placed in one positioning groove by the clamping assembly to finish one processing of the end part, and can be clamped by the clamping assembly and then moved to the next positioning groove for further processing of the other end part.

According to some embodiments of the utility model, the clamping assembly comprises a first drive cylinder fixed to the guiding drive assembly and having a drive stroke vertically arranged, and a jaw mechanism connected to the movable end of the first drive cylinder to be driven to move in a vertical direction.

According to some embodiments of the utility model, the clamping jaw mechanism comprises a second driving cylinder, a connecting plate, a first clamping jaw and a second clamping jaw, wherein the connecting plate is fixed on the movable end of the first driving cylinder, the second driving cylinder is fixed on the connecting plate, the driving stroke of the second driving cylinder is vertically arranged, the first clamping jaw and the second clamping jaw are hinged on the connecting plate and are symmetrically distributed, a first connecting rod is connected between the movable ends of the first clamping jaw and the second driving cylinder, and a second connecting rod is connected between the movable ends of the second clamping jaw and the second driving cylinder, so that the second driving cylinder can push the first clamping jaw and the second clamping jaw to rotate around a hinge point at the same time, and the first clamping jaw and the second clamping jaw are close to each other to clamp, and are far away from each other in the first position.

According to some embodiments of the utility model, a second guiding driving assembly is further provided, the second guiding driving assembly has a guiding travel in a vertical direction, the positioning block is connected to the second guiding driving assembly, and the second guiding driving assembly drives the positioning block to move in the vertical direction.

According to some embodiments of the utility model, a supporting table is further provided, the supporting table is arranged at the side of the positioning block, the length direction of the supporting table is parallel to the longitudinal direction, a table top is arranged at the upper end of the supporting table, and the table top is flush with the lowest end of the positioning groove.

According to some embodiments of the present utility model, an adjusting assembly is further provided, the adjusting assembly has a movement stroke in a longitudinal direction, the guiding driving assembly and the positioning block located on the same side are both disposed on the adjusting assembly, and the adjusting assembly can drive the guiding driving assembly to move so as to change a distance between the two clamping assemblies in a transverse direction.

According to some embodiments of the utility model, the adjusting component comprises a sliding plate, a transmission mechanism and two guide rails, wherein the two guide rails are arranged in parallel, the guide rails are parallel to the transverse direction, the sliding plate is connected to the guide rails in a sliding manner, the transmission mechanism is connected with the sliding plate so as to drive the sliding plate to move along the guide rails in the transverse direction, and the guide driving component and the positioning block which are positioned on the same side are both arranged on the sliding plate.

According to some embodiments of the utility model, the transmission mechanism comprises a screw rod, a ball nut and a hand wheel, wherein the screw rod is erected in parallel with the guide rail, the ball nut is sleeved on the screw rod and is in matched transmission with the screw rod, the ball nut is fixed on the sliding plate, and the hand wheel is connected to one end of the screw rod.

According to some embodiments of the utility model, the sliding plate is provided with a locking mechanism for restricting movement of the sliding plate in a lateral direction.

According to some embodiments of the present utility model, the locking mechanism includes a first clamping seat, a second clamping seat and a limiting rod, the first clamping seat is fixedly arranged, the second clamping seat is fixed on the sliding plate, clamping grooves are respectively formed in the first clamping seat and the second clamping seat, clamping grooves in the circumferential direction are respectively formed in two ends of the limiting rod correspondingly, the clamping grooves and the clamping grooves can be clamped in a matched manner, one end of the limiting rod is clamped on the first clamping seat, and the other end of the limiting rod is clamped on the second clamping seat.

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 utility model is further described with reference to the accompanying drawings and examples, in which:

FIG. 1 is a schematic diagram of a conveying device for facilitating cable end processing according to an embodiment of the present utility model;

FIG. 2 is a schematic view of a clamping assembly according to an embodiment of the present utility model;

FIG. 3 is a schematic view of a jaw mechanism according to an embodiment of the present utility model;

FIG. 4 is a schematic view of a supporting table according to an embodiment of the present utility model;

FIG. 5 is a schematic view of an adjusting assembly according to an embodiment of the present utility model;

fig. 6 is a schematic structural diagram of a locking mechanism according to an embodiment of the present utility model.

Reference numerals:

the guide driving assembly 100, the positioning block 200, the positioning groove 210, the clamping assembly 300, the first driving cylinder 310, the clamping jaw mechanism 320, the second driving cylinder 321, the connecting plate 322, the first clamping jaw 323, the second clamping jaw 324, the first connecting rod 325, the second connecting rod 326, the supporting table 400, the table top 410, the adjusting assembly 500, the sliding plate 510, the transmission mechanism 520, the screw rod 521, the ball nut 522, the hand wheel 523, the guide rail 530, the locking mechanism 600, the first clamping seat 610, the second clamping seat 620 and the limiting rod 630.

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, 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 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, plural means two or more. The description of the first and second is for the purpose of distinguishing between technical features only and should not be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated or implicitly indicating 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.

Referring to fig. 1, a conveyor for facilitating end processing of a cable according to an embodiment of the present utility model includes two sets of guide driving assemblies 100, two positioning blocks 200, and a plurality of clamping assemblies 300.

The two guiding driving assemblies 100 are symmetrically arranged, so that guiding strokes of the two guiding driving assemblies 100 are parallel to each other;

in the plane formed by the guide strokes of the two guide driving assemblies 100, the direction along the guide stroke of the guide driving assembly 100 is a longitudinal direction, and the direction perpendicular to the guide stroke of the guide driving assembly 100 is a transverse direction;

the two positioning blocks 200 are arranged between the two guide driving assemblies 100, the length directions of the two positioning blocks 200 are parallel to the longitudinal direction, a plurality of positioning grooves 210 are formed in the upper end face of each positioning block 200, the plurality of positioning grooves 210 are distributed along the length direction of the positioning block 200, and the two positioning grooves 210 in the transverse direction are mutually symmetrical;

the clamping assemblies 300 have a moving stroke in a vertical direction, a plurality of clamping assemblies 300 are arranged on each guide driving assembly 100, the clamping assemblies 300 are distributed along a longitudinal direction, and two clamping assemblies 300 in a transverse direction are symmetrical to each other and form a clamping station for clamping two ends of a cable.

The steering drive assembly 100 is used to perform the driving and steering functions of the clamping assembly 300 and may be implemented using various types of devices or structures. For example, guiding is performed using a plurality of slide rails, power driven using a screw drive assembly, or movement of the clamping assembly 300 is driven using a cylinder assembly moving between an up stroke and a down stroke.

Referring to fig. 2, the positioning block 200 is used for forming a plurality of positioning slots 210, and the positioning slots 210 are used for positioning and placing cables. The clamping assemblies 300 are arranged on two sides and are symmetrical to each other, each side is provided with a plurality of clamping assemblies 300, and the two clamping assemblies 300 in the transverse direction jointly clamp one cable. The guide driving assembly 100 drives the clamping assembly 300 to move to clamp the cable to be placed in the positioning groove 210. The cable is clamped by the clamping assembly 300 for translational transportation, when the cable is placed in the positioning groove 210, two ends of the cable are respectively positioned in the positioning grooves 210 at two sides in the transverse direction, and the two positioning grooves 210 in the transverse direction can be called a group. Because the positioning groove 210 has the lowest point, the cable automatically slides into the lowest point under the action of gravity, and the position is determined. Preferably, the positioning groove 210 is formed as a V-shaped groove, the bottom of the V-shaped groove is the lowest point, and the side wall of the groove plays a guiding role to assist the cable to slide into the groove bottom. And the two ends of the cable in the positioning groove 210 are suspended, so that equipment and devices for processing the end of the cable can be additionally arranged beside the positioning groove 210, thereby processing the end of the cable. The conveying device convenient for processing the cable end can translate and convey the segmented cable, is accurate in positioning and is beneficial to positioning and processing the cable end.

Each stepwise movement of the guide driving assembly 100 takes the cable out of one set of positioning slots 210 and moves it to the next set of positioning slots 210. The guide driving assembly 100 then drives the clamping assembly 300 to return to the initial position in synchronization without clamping the cable, waiting for a new cable to be clamped, and thus, the cable is reciprocally transported in translation.

In a specific clamping process, the two clamping assemblies 300 in the transverse direction act to clamp the two ends of the cable, and then the clamping assemblies 300 synchronously move upwards in the vertical direction to remove the cable from the positioning groove 210, so that the positioning groove 210 is prevented from blocking the cable to move in the longitudinal direction. After the clamping assembly 300 takes out the cable from the positioning groove 210, the guiding driving assembly 100 drives the clamping assembly 300 to synchronously move to the position above the next group of positioning grooves 210 along the longitudinal direction, the clamping assembly 300 moves downwards again, and synchronously releases the clamping of the cable, so that the cable falls into the positioning groove 210 and waits for other equipment or devices to process the suspended end of the cable.

Referring to fig. 2, to achieve a vertical travel of the clamping assembly 300, a simple embodiment is: the clamping assembly 300 includes a first driving cylinder 310 and a jaw mechanism 320, the first driving cylinder 310 is fixed to the guide driving assembly 100, and a driving stroke of the first driving cylinder 310 is vertically arranged, and the jaw mechanism 320 is connected to a movable end of the first driving cylinder 310 to be driven to move in a vertical direction. Wherein the movable end of the first drive cylinder 310 is the piston extension end, the movable end.

Referring to fig. 3, it can be understood that the jaw mechanism 320 includes a second driving cylinder 321, a connection plate 322, a first jaw 323 and a second jaw 324, the connection plate 322 is fixed on a movable end of the first driving cylinder 310, the second driving cylinder 321 is fixed on the connection plate 322, driving strokes of the second driving cylinder 321 are vertically arranged, the first jaw 323 and the second jaw 324 are both hinged on the connection plate 322 and symmetrically distributed, a first connecting rod 325 is connected between the movable ends of the first jaw 323 and the second driving cylinder 321, and a second connecting rod 326 is connected between the movable ends of the second jaw 324 and the second driving cylinder 321, so that the second driving cylinder 321 can push the first jaw 323 and the second jaw 324 to rotate around a hinge point at the same time to change between a first position where the first jaw 323 and the second jaw 324 are close to each other to clamp, and a second jaw 324 is far away from each other.

As shown in fig. 3, the second driving cylinder 321 is operated to make the movable end thereof drive the first link 325 and the second link 326 to move, thereby pushing the first clamping jaw 323 and the second clamping jaw 324 to rotate synchronously around the respective hinge points. When the first clamping jaw 323 and the second clamping jaw 324 rotate around the hinge point, two conditions exist, namely, the first clamping jaw 323 and the second clamping jaw 324 are close to each other, and clamping is achieved; the second is that the first jaw 323 and the second jaw 324 are moved away from each other to release the clamped object. In this embodiment, as shown in fig. 3, the second driving cylinder 321 drives the movable end to move upward, and the first jaw 323 and the second jaw 324 are pushed toward each other, i.e., in the first position; the second drive cylinder 321 drives the movable end downwardly, and the first jaw 323 and the second jaw 324 are pulled away from each other, i.e., in the second position. The connection plate 322 is used to provide a mounting base for the second drive cylinder 321 and to connect with the movable end of the first drive cylinder 310 to accommodate the movement travel of the jaw mechanism 320 in the vertical direction.

Referring to fig. 4, it can be understood that a second guiding driving assembly 220 is further provided, the second guiding driving assembly 220 has a guiding stroke in a vertical direction, the positioning block 200 is connected to the second guiding driving assembly 220, and the second guiding driving assembly 220 drives the positioning block 200 to move in the vertical direction.

The second guiding driving assembly 220 can drive the positioning block 200 to move in the vertical direction for being used with the clamping assembly 300. Specifically, when the cable in the positioning slot 210 needs to be transferred, the clamping assembly 300 clamps the cable and moves upward to move out of the positioning slot 210, and at this time, the second guiding driving assembly 220 also synchronously drives the positioning block 200 to move downward, so as to assist the cable to move out of the positioning slot 210 quickly. When a cable needs to be placed, the clamping assembly 300 moves downward, and at this time, the positioning block 200 is driven upward, and the auxiliary cable is quickly introduced into the positioning groove 210. The second guiding driving component 220 may also be driven and guided by a driving cylinder.

Referring to fig. 4, it can be understood that a support stand 400 is further provided, the support stand 400 is disposed at a side of the positioning block 200, and a length direction of the support stand 400 is parallel to the longitudinal direction, a table top 410 is provided at an upper end of the support stand 400, and the table top 410 is flush with a lowermost end of the positioning groove 210.

The table top 410 of the support table 400 is used to support the cable. The table top 410 and the positioning groove 210 support the cable together, so that the cable can be reduced from bending to generate radian due to self gravity, the end of the cable still keeps a certain level, and the processing of the end of the cable is facilitated.

Referring to fig. 5, it can be understood that an adjusting assembly 500 is further provided, the adjusting assembly 500 has a movement stroke in a longitudinal direction, the guide driving assembly 100 and the positioning block 200 located on the same side are both disposed on the adjusting assembly 500, and the adjusting assembly 500 can drive the guide driving assembly 100 to move to change a distance between the two clamping assemblies 300 in a transverse direction.

The adjusting component 500 is used for flexibly adjusting the distance between the clamping components 300 at two sides according to the length of the cable to be processed, and the proper clamping distance can ensure that the two ends and the whole are in a straight state rather than a bending state when the cable is clamped.

Referring to fig. 5, one embodiment is shown as follows: the adjusting assembly 500 includes a sliding plate 510, a transmission mechanism 520 and two guide rails 530, the two guide rails 530 are parallel to each other, the guide rails 530 are parallel to the transverse direction, the sliding plate 510 is slidably connected to the guide rails 530, the transmission mechanism 520 is connected to the sliding plate 510 to drive the sliding plate 510 to move along the guide rails 530 in the transverse direction, and the guide driving assembly 100 and the positioning block 200 located on the same side are both disposed on the sliding plate 510.

The sliding plate 510 is driven by the transmission mechanism 520 to move on the guide rails 530, and the two guide rails 530 support the sliding plate 510 better and more smoothly. The guide rail 530 is disposed in a lateral direction, i.e., the distance between the two side clamping assemblies 300 can be adjusted when the slide plate 510 moves on the guide rail 530. The transmission mechanism 520 has various options, and can provide power for the sliding plate 510, where one option is to use a screw to drive, for example, the transmission mechanism 520 includes a screw 521, a ball nut 522 and a hand wheel 523, the screw 521 is erected parallel to the guide rail 530, the ball nut 522 is sleeved on the screw 521 and is driven in cooperation with the screw 521, the ball nut 522 is fixed on the sliding plate 510, and the hand wheel 523 is connected to one end of the screw 521.

When the hand wheel 523 is rotated, the screw 521 is driven to rotate around the shaft, and the ball nut 522 is cooperatively driven to move on the screw 521 in the axial direction of the screw 521, that is, the ball nut 522 drives the sliding plate 510 to translate.

Referring to fig. 6, it can be appreciated that a locking mechanism 600 is provided on the slide plate 510, and the locking mechanism 600 is used to restrict movement of the slide plate 510 in the lateral direction.

When the lock mechanism 600 is not provided, the movement of the slide plate 510 can be prevented by utilizing the engagement characteristic between the screw 521 and the ball nut 522 (the ball nut 522 cannot move as an active member to reversely rotate the screw 521). However, after a long period of operation, the ball nut 522 may be slightly shifted due to vibration of the apparatus or the like. The locking mechanism 600 can effectively limit the movement of the sliding plate 510, and prevent the distance between the clamping assemblies 300 from being changed after the distance is adjusted.

Referring to fig. 6, it may be understood that the locking mechanism 600 includes a first card holder 610, a second card holder 620 and a stop lever 630, where the first card holder 610 is fixedly disposed, the second card holder 620 is fixed on the sliding plate 510, card slots are disposed on the first card holder 610 and the second card holder 620, two ends of the stop lever 630 are correspondingly disposed with a circumferential card slot, so that the card slot and the card slot can be mutually matched and clamped, one end of the stop lever 630 is clamped on the first card holder 610, and the other end is clamped on the second card holder 620.

The stop lever 630 is manufactured according to the required fixed length, when the distance between the clamping assemblies 300 on two sides is adjusted, namely the position of the sliding plate 510 is determined, the distance between the first clamping seat 610 and the second clamping seat 620 is also determined, one end of the stop lever 630 with a proper length is clamped on the first clamping seat 610, the other end of the stop lever 630 is clamped on the second clamping seat 620, so that the fixing of the sliding plate 510 can be realized, and the sliding of the stop lever on the guide rail 530 is limited.

The embodiments of the present utility model have been described in detail with reference to the accompanying drawings, but the present utility model is not limited to the above embodiments, and various changes can be made within the knowledge of one of ordinary skill in the art without departing from the spirit of the present utility model.

Claims (10)

1. A conveyor for facilitating processing of cable ends, comprising:

the two groups of guide driving assemblies (100), the two guide driving assemblies (100) are symmetrically arranged, so that the guide strokes of the two guide driving assemblies (100) are parallel to each other;

wherein, in the plane formed by the guiding strokes of the two guiding driving assemblies (100), the guiding stroke direction along the guiding driving assemblies (100) is a longitudinal direction, and the direction perpendicular to the guiding stroke of the guiding driving assemblies (100) is a transverse direction;

the two positioning blocks (200), the two positioning blocks (200) are arranged between the two guide driving assemblies (100), the length directions of the two positioning blocks (200) are parallel to the longitudinal direction, a plurality of positioning grooves (210) are formed in the upper end face of each positioning block (200), the plurality of positioning grooves (210) are distributed in a arrayed mode along the length direction of the positioning block (200), and the two positioning grooves (210) in the transverse direction are mutually symmetrical;

the clamping assemblies (300) are provided with a moving stroke in the vertical direction, each guiding driving assembly (100) is provided with a plurality of clamping assemblies (300), the clamping assemblies (300) are distributed in a longitudinal direction, and the two clamping assemblies (300) in the transverse direction are symmetrical to each other and form a clamping station for clamping two ends of a cable.

2. The conveyor for facilitating cable end processing of claim 1, wherein: the clamping assembly (300) comprises a first driving cylinder (310) and a clamping jaw mechanism (320), wherein the first driving cylinder (310) is fixed on the guiding driving assembly (100), the driving stroke of the first driving cylinder (310) is vertically arranged, and the clamping jaw mechanism (320) is connected to the movable end of the first driving cylinder (310) so as to be driven to move in the vertical direction.

3. The conveyor for facilitating cable end processing of claim 2, wherein: the clamping jaw mechanism (320) comprises a second driving cylinder (321), a connecting plate (322), a first clamping jaw (323) and a second clamping jaw (324), wherein the connecting plate (322) is fixed on the movable end of the first driving cylinder (310), the second driving cylinder (321) is fixed on the connecting plate (322), the driving stroke of the second driving cylinder (321) is vertically arranged, the first clamping jaw (323) and the second clamping jaw (324) are hinged on the connecting plate (322) and are symmetrically distributed, a first connecting rod (325) is connected between the movable ends of the first clamping jaw (323) and the second driving cylinder (321), a second connecting rod (326) is connected between the movable ends of the second clamping jaw (324) and the second driving cylinder (321), so that the second driving cylinder (321) can push the first clamping jaw (323) and the second clamping jaw (324) to rotate around a hinge point simultaneously, and are symmetrically distributed, and the first clamping jaw (323) and the second clamping jaw (324) are far away from each other.

4. The conveyor for facilitating cable end processing of claim 1, wherein: the device is also provided with a second guiding driving assembly (220), the second guiding driving assembly (220) is provided with a guiding stroke in the vertical direction, the positioning block (200) is connected to the second guiding driving assembly (220), and the second guiding driving assembly (220) drives the positioning block (200) to move in the vertical direction.

5. The conveyor for facilitating cable end processing of claim 1, wherein: the positioning device is characterized by further comprising a supporting table (400), wherein the supporting table (400) is arranged on the side of the positioning block (200), the length direction of the supporting table (400) is parallel to the longitudinal direction, the upper end of the supporting table (400) is provided with a table top (410), and the table top (410) is flush with the lowest end of the positioning groove (210).

6. The conveyor for facilitating cable end processing of claim 1, wherein: the device is further provided with an adjusting component (500), the adjusting component (500) is provided with a moving stroke in the longitudinal direction, the guide driving component (100) and the positioning block (200) which are positioned on the same side are arranged on the adjusting component (500), and the adjusting component (500) can drive the guide driving component (100) to move so as to change the distance between the two clamping components (300) in the transverse direction.

7. The conveyor facilitating cable end processing of claim 6, wherein: the adjusting component (500) comprises a sliding plate (510), a transmission mechanism (520) and two guide rails (530), wherein the two guide rails (530) are arranged in parallel, the guide rails (530) are parallel to the transverse direction, the sliding plate (510) is slidably connected to the guide rails (530), the transmission mechanism (520) is connected with the sliding plate (510) so as to drive the sliding plate (510) to move along the guide rails (530) in the transverse direction, and the guide driving component (100) and the positioning block (200) which are positioned on the same side are all arranged on the sliding plate (510).

8. The conveyor facilitating cable end processing of claim 7, wherein: the transmission mechanism (520) comprises a screw rod (521), a ball nut (522) and a hand wheel (523), wherein the screw rod (521) is erected in parallel with the guide rail (530), the ball nut (522) is sleeved on the screw rod (521) and is in matched transmission with the screw rod (521), the ball nut (522) is fixed on the sliding plate (510), and the hand wheel (523) is connected with one end of the screw rod (521).

9. The conveyor facilitating cable end processing of claim 7, wherein: the sliding plate (510) is provided with a locking mechanism (600), and the locking mechanism (600) is used for limiting the movement of the sliding plate (510) in the transverse direction.

10. The conveyor for facilitating cable end processing of claim 9, wherein: locking mechanism (600) are including first cassette (610), second cassette (620) and gag lever post (630), first cassette (610) are fixed to be set up, second cassette (620) are fixed on sliding plate (510), first cassette (610) with all be equipped with the draw-in groove on second cassette (620), the both ends of gag lever post (630) all correspond to be equipped with the ascending joint groove of circumference for joint groove and draw-in groove can mutually support the clamping, the one end clamping of gag lever post (630) is in on first cassette (610), the other end clamping is in on second cassette (620).