CN114361910B - Data line heart yearn rotation type branching mechanism and welding equipment - Google Patents

Abstract

The invention provides a data line core wire rotary branching mechanism, which comprises: a wire rotating member for holding the data wire rod and rotating the data wire rod so that the core wires exposed at the ends thereof are arranged in two rows; at least one branch step which is symmetrically arranged is arranged on two sides of the branch needle, and the height of the branch step is equal to the diameter of the core wire; and the driving part is connected with the branching needle and is used for driving the branching needle to lift so that the branching needle is inserted between two rows of core wires and driving the branching needle to rotate so that each stage of branching step pushes each core wire to move different distances. The invention has the beneficial effects that: the accurate separation and sequencing of the plurality of core wires are realized, the branching action is simple, the time is short, and the production efficiency is improved; the branching is accurate, the severe requirement of terminal soldering tin equipment on the separation degree of the wire cores is met, the automatic assembly line before data wire welding is realized, the production efficiency and the product quality of the branching and assembly line are improved, and the production reject ratio is reduced.

Description

Data line heart yearn rotation type branching mechanism and welding equipment

Technical Field

The invention relates to the technical field of data wire welding processing, in particular to a data wire core wire rotary branching mechanism and welding equipment.

Background

The USB data line is used for connecting and communicating the electronic equipment such as a computer, a mobile phone and the like with external equipment to transmit data and charge. When the USB data wire is processed, the outer skin of the end part of the cut original data wire is peeled off, and the outer skin of the cut end part of the cut original data wire is respectively arranged in different wire clamps according to different colors of the outer skin of the core wire inside the data wire and then welded with the USB interface terminal.

If the general USB data line is internally composed of four core wires of red, white, green and black, the four core wires are required to be respectively arranged in the wire clamps according to a specific sequence before welding, and in the current production operation, the wire separation and sorting work of the core wires is mainly finished by manpower. The manual assembly line clamping mainly has the following problems that the production efficiency is limited by the proficiency and working state of operators; the error rate of manual operation of wire clamping is higher, resulting in higher reject ratio of the whole production.

Disclosure of Invention

In view of this, in order to solve the problem that the wire separation clamping needs to be manually operated before the data wire and the interface terminal are welded, the embodiment of the invention provides a data wire core wire rotating wire separation mechanism and welding equipment.

The embodiment of the invention provides a data line core wire rotary branching mechanism, which comprises:

a wire rotating member for holding the data wire rod and rotating the data wire rod so that the core wires exposed at the ends thereof are arranged in two rows;

at least one branch step which is symmetrically arranged is arranged on two sides of the branch needle, and the height of the branch step is equal to the diameter of the core wire;

and the driving part is connected with the branching needle and is used for driving the branching needle to lift so that the branching needle is inserted between two rows of core wires and driving the branching needle to rotate so that each stage of branching step pushes each core wire to move different distances.

Further, the wire pressing device further comprises a wire pressing part, the wire pressing part comprises a clamping groove matched with the shape of the wire dividing needle and a bearing flat plate arranged below the clamping groove, the upper portion of the clamping groove is connected with the driving part and driven by the driving part to lift, the data wire is limited between the clamping groove and the bearing flat plate before the core wire is dispersed, and a constraint space of the core wire is formed between each wire dividing step of the wire dividing needle and the clamping groove before the core wire is dispersed.

Further, the driving component comprises a lifting component and a turning component;

the lifting assembly comprises a multi-shaft air cylinder, an upper movable plate, a lower movable plate and a core wire limiting piece, wherein the upper movable plate and the lower movable plate are arranged at intervals up and down, a first piston shaft and a plurality of second piston shafts are arranged at the output end of the multi-shaft air cylinder, the first piston shaft penetrates through and is fixedly connected with the upper movable plate, the lower end of the first piston shaft is connected with a branching needle, the upper end of the branching needle penetrates through the lower movable plate and is in sliding connection with the lower movable plate, each second piston shaft penetrates through the upper movable plate and is connected with the lower movable plate, a spring is sleeved on a part of the second piston shaft between the upper movable plate and the lower movable plate, the core wire limiting piece is fixed at the bottom of the lower movable plate, the clamping groove is arranged at the lower part of the core wire limiting piece, the upper end of the branching needle penetrates through the core wire limiting piece, and the first piston shaft sequentially pushes the core wire limiting piece to press the data wire and the branching needle to be inserted between two rows of core wires;

the rotary assembly is fixed on the upper movable plate and comprises a rotary cylinder and an elastic component, and the elastic component is connected with the first piston shaft and the upper movable plate.

Further, the elastic component is a torsion spring sleeved on the first piston shaft, one end of the torsion spring is fixed on the first piston shaft, the other end of the torsion spring is fixed on the upper movable plate, a pushed column is arranged on the side wall of the first piston shaft, the rotary cylinder is arranged on one side of the pushed column, and the output end faces the pushed column.

Further, a limiting piece is arranged on the other side of the pushed column and used for blocking the pushed column from rotating so as to limit the rotation angle of the first piston shaft.

Further, a first limiting ring is sleeved on the first piston shaft, and the pushed column is arranged on the side wall of the first limiting ring.

Further, the upper end of the branching needle is connected with the lower end of the axis of the first piston through a coupler.

Further, the branching needle is in a shape of a Chinese character 'yang', and the data wire is provided with four core wires.

Further, the driving part further comprises a displacement cylinder, the displacement cylinder is connected with the lifting assembly, an empty groove is formed in the bearing flat plate, the wire groove is arranged below the empty groove, the displacement cylinder is used for driving the lifting assembly to descend so that the wire groove penetrates through the empty groove, and then each core wire is clamped into the wire groove.

The technical scheme provided by the embodiment of the invention has the beneficial effects that: compared with the existing branching ordering mode, the method has at least the following beneficial effects: each core wire is automatically dispersed to a preset position by rotating the branching needle, so that the accurate separation and sequencing of the plurality of core wires are directly completed, the branching action is simple, the time is short, and the production efficiency is improved; the branching is accurate, and the severe requirement of terminal soldering tin equipment on the separation degree of the wire core is met; the volume is small, and most of the existing terminal soldering equipment can be adapted; the device has simple integral structure and simple control, and the fault tolerance rate of the device during operation is correspondingly lower, thereby being beneficial to realizing the automatic assembly line before welding the data line interface terminals, improving the production efficiency and the product quality of the branching and assembly line, and reducing the production defective rate.

The embodiment of the invention provides a data wire core wire terminal welding device based on the data wire core wire rotary type branching mechanism, which comprises the data wire core wire rotary type branching mechanism and a soldering machine.

The technical scheme provided by the embodiment of the invention has the beneficial effects that: and the automatic branching core wire is welded with the inlet wire of the interface terminal, so that the full-automatic welding of the interface terminal is realized, the overall production efficiency of the data wire is greatly improved, and the labor cost is reduced.

Drawings

FIG. 1 is an exploded view of a data line core rotary wire splitting mechanism of the present invention;

fig. 2 is a partial enlarged view at a in fig. 1;

FIG. 3 is a front view of a data line core rotary branching mechanism of the present invention;

fig. 4 is a partial enlarged view at B in fig. 3;

FIG. 5 is a side view of a data line core rotary wire splitting mechanism of the present invention;

FIG. 6 is a schematic diagram of the process of rotating the branching needle 18 to branch;

fig. 7 is a schematic view of the core wire limiter 17 of fig. 2;

FIG. 8 is a schematic view of the split needle 18 of FIG. 2;

FIG. 9 is a schematic diagram of a data line core wire terminal bonding apparatus of the present invention;

fig. 10 is a partial enlarged view at C in fig. 6.

In the figure: 1-data line core wire rotary type branching mechanism, 2-data line wire, 201-core wire, 3-displacement cylinder, 4-multiaxis cylinder, 401-first piston shaft, 402-second piston shaft, 5-upper movable plate, 6-lower movable plate, 7-bearing flat plate, 8-rotary cylinder, 9-first spacing ring, 10-second spacing ring, 11-fixed support, 12-pushed column, 13-torsion spring, 14-coupling, 15-spring, 16-supporting plate, 17-core wire spacing piece, 18-branching needle, 19-guiding groove, 20-displacement cylinder support, 21-end spacing piece, 22-guiding column, 23-spacer, 24-bearing, 25-clamping groove, 26-spacing piece, 27-wire groove and 28-soldering machine.

Detailed Description

For the purpose of making the objects, technical solutions and advantages of the present invention more apparent, embodiments of the present invention will be further described with reference to the accompanying drawings.

Referring to fig. 1, 3 and 5, an embodiment of the present invention provides a data line core wire rotating branching mechanism 1 for branching, sorting, and even loading a plurality of core wires 201 exposed after peeling the end of a data line 2 into a wire slot 27, so as to prepare for the next welding with an interface terminal. The data wire 2 is internally composed of a plurality of core wires 201, and the outer skins of the core wires 201 are different in color and function. In this embodiment, the branching sequence of the USB data lines composed of the four core lines 201 is specifically described, but it is understood that the branching capability of the data line core line rotating branching mechanism is not limited to the four core lines 201, and it is also applicable to other various types of data lines. Any mechanism device achieving the purpose of separating the wire cores by the principle is required to be within the protection scope of the design.

Referring to fig. 1, 3 and 5, an embodiment of the present invention provides a data line core wire rotating wire dividing mechanism 1, and the structure of the wire dividing mechanism claimed in the present application is not limited to this embodiment, but the embodiment is only for the sake of clarity of the principle of the wire core wire dividing mechanism. The data line core wire rotary branching mechanism 1 in the embodiment comprises a line rotating component, a branching needle, a driving component and a line pressing component.

Because the data wire 2 is in different states, the four core wires 201 therein have multiple arrangements, so that the sorting can be automatically completed after the subsequent data wire 2 is separated, and thus the data wire 2 needs to be adjusted, and the core wires 201 are preliminarily sorted.

The individual core wires 201 are initially ordered by the wire-turning means before the core wires 201 of the data line wire 2 are separated. If the mechanical clamping jaw clamps the data wire 2, the end of the data wire 2 is identified through machine vision, and then the positions of the core wires 201 are determined according to the colors, the mechanical clamping jaw is controlled to drive the data wire 2 to rotate until the core wires 201 reach the preset positions, namely, the data wire 2 is rotated to enable the core wires 201 with the exposed end to be arranged in two rows. In the present embodiment, the four cores 201 are arranged in two rows and two columns, and are horizontal and vertical, for example, the red core and the black core are arranged in the upper row, and the white core and the green core are arranged in the lower row.

Referring to fig. 8, at least one branch step is symmetrically disposed on both sides of the branch needle 18, and the height of the branch step is equal to the diameter of the core wire 201. The branching needle 18 is inserted between two rows of the core wires 201, each of the branching steps being located between one row of the core wires 201. The individual cords 201 are pushed to move different distances by rotating the wire-dividing needle 18. The number of the branching steps on both sides of the branching needle 18 should be the same according to the number of the core wires 201 of the core wire 2 of each column. In this embodiment, only two stages of branching steps are required, i.e. the branching needle 18 has a sheet-like structure with a shape of "convex".

The driving component is used for driving the branching needle 18 to lift and rotate, and various implementation forms can be adopted, and the detailed description is given here by way of example. The driving part in this embodiment includes a displacement cylinder 3, a lifting assembly, and a swing assembly.

Referring to fig. 2 and 4, the upper part of the displacement cylinder 3 is fixed by a displacement cylinder bracket 20, and the upper part and the lower part are connected by fasteners such as bolts. The displacement cylinder support 20 is fixedly arranged to enable the displacement cylinder 3 to be fixed, the displacement cylinder 3 is vertically arranged, the lower end of the displacement cylinder is a piston shaft output end, and the lower end of the displacement cylinder 3 is connected with the support plate 16. The lifting component is fixed on the supporting plate 16, and the displacement cylinder 3 stretches out and draws back to drive the lifting component to lift.

The lifting assembly comprises a multi-shaft cylinder 4, an upper movable plate 5, a lower movable plate 6 and a core wire limiting part 17, in this embodiment, the multi-shaft cylinder 4 is a three-shaft cylinder, the multi-shaft cylinder 4 is vertically arranged, the output end of the multi-shaft cylinder is downward, the multi-shaft cylinder is provided with a first piston shaft 401 and a plurality of second piston shafts 402, the number of the second piston shafts 402 is two, the second piston shafts 402 are located on two sides of the first piston shaft 401, and the length of the first piston shaft 401 is shorter than that of the second piston shafts 402.

The upper movable plate 5 and the lower movable plate 6 are arranged at an upper-lower interval, and the upper movable plate 5 is fixed on the fixed bracket 11 through fasteners such as screws. The fixing bracket 11 is a U-shaped plate, a guide post 22 is disposed at the rear side of the fixing bracket, a vertical long guide groove 19 is disposed at a position corresponding to the support plate 16, and the guide post 22 passes through the guide groove 19 and can slide along the vertical direction. The guide post 22 is preferably a bolt, the end of which is connected to the fixing bracket 11, and the head of which passes through the guide groove 19. In addition, the rear side of the lower movable plate 6 is provided with the same guide post 22, and the corresponding position on the support plate 16 is also provided with a guide groove 19, so that the guide effect of vertical sliding is realized through the cooperation of the guide post 22 and the guide groove 19.

The part of the first piston shaft 401, which is close to the cylinder barrel of the multi-shaft cylinder 4, is sleeved with a second limiting ring 10, the second limiting ring 10 is sleeved on the first piston shaft 401 and keeps a reasonable distance with the cylinder barrel of the multi-shaft cylinder 4, and the second limiting ring 10 is matched with the cylinder barrel of the multi-shaft cylinder 4 to limit the retraction distance of the first piston shaft 401.

The first piston shaft 401 penetrates through and is fixedly connected with the upper movable plate 5, and the first piston shaft 401 is connected with the upper movable plate 5 through fasteners such as screws. The lower end of the first piston shaft 401 penetrates through the upper movable plate 5, and the upper end of the branching needle 18 penetrates through the lower movable plate 6 and is in sliding connection with the lower movable plate 6.

The upper end of the branching needle 18 is preferably connected with the lower end of the first piston shaft 401 through a coupling 14. The outer wall of the coupler 14 is mounted in the upper movable plate 5 through fasteners such as screws, a bearing 24 is further mounted in the upper movable plate 5, the bearing 24 is mounted on the upper portion of the coupler 14, the first piston shaft 401 penetrates through the bearing 24 and then is inserted into the coupler 14 to be mounted and connected, and a gasket 23 can be arranged between the bearing 24 and the coupler 14 to enhance stability of connection. While the upper end of the branching needle 18 is inserted into the lower end of the coupling 14 for installation connection.

Each second piston shaft 402 penetrates through the upper movable plate 5 and then is connected with the lower movable plate 6, and the second piston shafts 402 are slidably connected with the upper movable plate 5 and the lower movable plate 6. In addition, a spring 15 is partially sleeved between the upper movable plate 5 and the lower movable plate 6 by the second piston shaft 402, and an end limiting member 21 is further connected to the lower end of each second piston shaft 402, and the end limiting member 21 is located below the lower movable plate 6 to prevent the lower movable plate 6 from falling off from the second piston shaft 402.

The core wire limiting piece 17 is fixed at the bottom of the lower movable plate 6, the core wire limiting piece 17 is of a cylindrical hollow structure, and the upper portion of the core wire limiting piece 17 penetrates through the lower movable plate 6 and is connected with the lower movable plate 6 through fasteners such as screws.

Referring to fig. 2 and 7, the pressing component includes a slot 25 with a shape matching with the branching pin 18, and a receiving plate 7 disposed below the slot 25, where an upper portion of the slot 25 is connected with the driving component and driven by the driving component to lift. The shape of the clamping groove 25 is similar to that of the branching needle 18, but the area is larger, and the clamping groove 25 is also in a shape of a convex shape, and is arranged at the lower part of the core wire limiting member 17. The receiving flat plate 7 is fixed at the bottom of the supporting plate 16 and is positioned below the lower movable plate 6. The upper end of the branching needle 18 penetrates through the core wire limiting piece 17 and then is connected with the coupler 14, and the branching needle 18 is not connected with the core wire limiting piece 17. The data wire 2 is restricted between the clamping groove 25 and the receiving flat plate 7 before the core 201 is dispersed, and a restriction space of the core 201 is formed between each branching step of the branching needle 18 and the clamping groove 25 after the core is dispersed.

The rotary assembly is fixed on the upper movable plate 5 and comprises a rotary cylinder 8 and an elastic component. The first piston shaft 401 is connected to the upper movable plate 5 through an elastic member, and the revolving cylinder 8 is used for pushing the first piston shaft 401 to rotate, and the elastic member revolves the first piston shaft 401. Specifically, the revolving cylinder 8 is fixed on the fixed bracket 11. The elastic component is the cover is located torsional spring 13 on the first piston axle 401, torsional spring 13 one end is fixed in first piston axle is last 401, the other end is fixed in go up fly leaf 5, specifically be fixed in on the fixed bolster 11, first piston axle 401 lateral wall is equipped with the push-by post 12 that radially extends, revolving cylinder 8 set up in one side of push-by post 12, and the output orientation receive push-by post 12.

Preferably, the first piston shaft 401 is sleeved with a first limiting ring 9, and the pushed column 12 is disposed on a side wall of the first limiting ring 9. The first limiting ring 9 is located below the second limiting ring 10, and is fixedly connected with the first piston shaft 401 through fasteners such as screws.

In order to limit the rotation angle of the first piston shaft 401 pushed by the rotary cylinder 8, a limiting piece 26 is arranged on the other side of the pushed column 12, the limiting piece 26 is a gear rod and is level to the pushed column 12, the rotary cylinder 8 stretches to apply pushing force to the pushed column 12, and the first piston shaft 401 is pushed to rotate for a set angle and then is abutted against the limiting piece 26, so that the rotation angle of the first piston shaft 401 is limited. The setting angle here, i.e. the angle at which the branching needle 18 is to be driven in rotation, may be set to 90.

In addition, in order to load the core wires 201 after the wire division sequencing into the wire groove 27, the receiving plate 7 is provided with an empty groove, the wire groove 27 is arranged below the empty groove, and the displacement cylinder 3 is used for driving the lifting assembly to descend so that the wire groove 27 passes through the empty groove, and then each core wire 201 is clamped into the wire groove 27. Here, the bottom surface of the lower movable plate 6 may be configured as a stepped surface, so that the lower movable plate 6 may be supported on the receiving plate 7 when the clamping groove 25 presses the data wire 2 onto the receiving plate 7, and the wire grooves 27 may be more easily clamped into the respective core wires 201 when the lifting assembly is lowered.

Referring to fig. 3, 4 and 6, the main working process of the above-mentioned data line core wire rotary branching mechanism 1 is as follows:

(1) The four core wires 201 of the data line wire 2 to be branched are first ordered by the wire turning part.

(2) Then, the multi-shaft cylinder 4 is started, the first piston shaft 401 and the second piston shaft 402 are extended, the upper movable plate 5 and the lower movable plate 6 are pushed to move downwards until the core wire limiting piece 17 is in contact with the bearing flat plate 7, the data wire 2 is pressed, and the lower movable platform 6 cannot move continuously under the action of the elasticity of the spring 15.

(3) The first piston shaft 401 is controlled to extend continuously, so that the branching needle 18 is driven to move downwards to be inserted between the two rows of core wires 201.

(4) The rotary cylinder 8 is controlled to extend to push the first piston shaft 401 to rotate 90 degrees, namely the branching needle 18 rotates 90 degrees, and each branching step of the branching needle 18 pushes each core wire 201 to move transversely to a preset distance, so that branching is completed.

(5) The displacement cylinder 3 is controlled to extend, so that the driving part moves downwards as a whole, the wire grooves 27 penetrate through the empty grooves on the bearing flat plate 7, and then the core wires 201 are directly clamped into the notch of each wire groove 27, so that the groove loading of the core wires 201 is completed.

Referring to fig. 9 and 10, the embodiment of the present invention further provides a data line core wire terminal welding device based on the data line core wire rotating type branching mechanism 1, which specifically comprises the data line core wire rotating type branching mechanism 1 and a soldering machine 28. The soldering machine 28 is used for welding the core wire 201 after automatic wire separation and groove assembly with the inlet wire of the interface terminal, so that the full-automatic welding of the interface terminal is realized, the overall production efficiency of the data wire is greatly improved, and the labor cost is reduced.

In this document, terms such as front, rear, upper, lower, etc. are defined with respect to the positions of the components in the drawings and with respect to each other, for clarity and convenience in expressing the technical solution. It should be understood that the use of such orientation terms should not limit the scope of the protection sought herein.

The embodiments described above and features of the embodiments herein may be combined with each other without conflict.

The foregoing description of the preferred embodiments of the invention is not intended to limit the invention to the precise form disclosed, and any such modifications, equivalents, and alternatives falling within the spirit and scope of the invention are intended to be included within the scope of the invention.

Claims (10)

1. A data line core wire rotary branching mechanism, comprising:

a wire rotating member for holding the data wire rod and rotating the data wire rod so that the core wires exposed at the ends thereof are arranged in two rows;

at least one branch step which is symmetrically arranged is arranged on two sides of the branch needle, and the height of the branch step is equal to the diameter of the core wire;

and the driving part is connected with the branching needle and is used for driving the branching needle to lift so that the branching needle is inserted between two rows of core wires and driving the branching needle to rotate so that each stage of branching step pushes each core wire to move different distances.

2. A data line core wire rotary branching mechanism as in claim 1, wherein: the wire pressing component comprises a clamping groove matched with the shape of the wire dividing needle and a bearing plate arranged below the clamping groove, the upper portion of the clamping groove is connected with the driving component and driven by the driving component to lift, the data wire is limited between the clamping groove and the bearing plate before the core wire is dispersed, and a constraint space of the core wire is formed between each wire dividing step of the wire dividing needle and the clamping groove before the core wire is dispersed.

3. A data line core wire rotary branching mechanism as in claim 2, wherein: the driving component comprises a lifting component and a rotating component;

the lifting assembly is a multi-shaft cylinder, an upper movable plate, a lower movable plate and a core wire limiting piece, the upper movable plate and the lower movable plate are arranged at intervals up and down, a first piston shaft and a plurality of second piston shafts are arranged at the output end of the multi-shaft cylinder, the first piston shaft penetrates through and is fixedly connected with the upper movable plate, the lower end of the first piston shaft is connected with a branching needle, the upper end of the branching needle penetrates through the lower movable plate and is in sliding connection with the lower movable plate, each second piston shaft penetrates through the upper movable plate and is connected with the lower movable plate, a spring is sleeved on a part of the second piston shaft between the upper movable plate and the lower movable plate, the core wire limiting piece is fixed at the bottom of the lower movable plate, the clamping groove is arranged at the lower part of the core wire limiting piece, the upper end of the branching needle penetrates through the core wire limiting piece, and the first piston shaft sequentially pushes the core wire limiting piece to press the data wire and the branching needle to be inserted between two rows of core wires;

the rotary assembly is fixed on the upper movable plate and comprises a rotary cylinder and an elastic component, and the elastic component is connected with the first piston shaft and the upper movable plate.

4. A data line core wire rotary wire dividing mechanism as claimed in claim 3, wherein: the elastic component is the cover and locates the epaxial torsional spring of first piston, torsional spring one end is fixed in on the first piston, the other end is fixed in on the fly leaf, first piston side wall is equipped with receives the post that pushes away, the gyration cylinder set up in receive one side of pushing away the post, and the output orientation receive and push away the post.

5. The data line core wire rotary branching mechanism as set forth in claim 4, wherein: the other side of the pushed column is provided with a limiting piece, and the limiting piece is used for blocking the pushed column from rotating so as to limit the rotation angle of the first piston shaft.

6. The data line core wire rotary branching mechanism as set forth in claim 4, wherein: the first piston shaft is sleeved with a first limiting ring, and the pushed column is arranged on the side wall of the first limiting ring.

7. The data line core wire rotary branching mechanism as set forth in claim 4, wherein: the upper end of the branching needle is connected with the lower end of the first piston axis through a coupler.

8. A data line core wire rotary branching mechanism as in claim 1, wherein: the branching needle is in a convex shape, and the data wire is provided with four core wires.

9. The data line core wire rotary branching mechanism as set forth in claim 4, wherein: the driving part further comprises a displacement cylinder, the displacement cylinder is connected with the lifting assembly, an empty groove is formed in the bearing flat plate, the wire groove is arranged below the empty groove, the displacement cylinder is used for driving the lifting assembly to descend so that the wire groove penetrates through the empty groove, and then each core wire is clamped into the wire groove.

10. The utility model provides a data sinle silk line welding equipment which characterized in that: a data line core wire rotary branching mechanism comprising the data line core wire rotary branching mechanism as set forth in any one of claims 1 to 9, and a soldering machine.