CN211700868U - Automatic assembly line of data line - Google Patents

Abstract

The utility model belongs to the technical field of automation equipment, especially, relate to an automatic assembly line of data line, which comprises a frame, remove tool and controlling means, be equipped with the mobile rail in the frame, the both ends of mobile rail are equipped with artifical cycloid station and artifical line station of getting respectively, the mobile rail removes along the mobile rail and is used for transmitting the data line, be provided with the automatic adhesive deposite device who is used for spraying and solidification colloid toward the data line body who arranges in proper order in the frame, an automatic Mylar device that pastes for pasting the data line after accomplishing the point gluing, a data line shielding shell riveting device that is used for going into the riveting to the data line after accomplishing the welding carries out welded automatic spot welding device and is used for going into the riveting to the data line after accomplishing the welding, controlling means locates in the frame, automatic adhesive deposite device who arranges in proper order in controlling means and the frame, an automatic Mylar device that pastes, The automatic spot welding device is electrically connected with the data wire shielding shell riveting device; thereby making the produced product more accurate.

Description

Automatic assembly line of data line

Technical Field

The utility model belongs to the technical field of automation equipment, especially, relate to an automatic assembly line of data line.

Background

The USB 3.0 popularization organization publishes a rendering map of a new generation of USB connector, the core wire arrangement position is special, the worldwide problem that the USB is inserted for a long time is formally solved, the normal work can be realized by inserting the front surface and the back surface, and the USB data wire matched with the USB connector for use is thinner and lighter. Along with the increasing popularization of Type-C plug terminal equipment, the demand of subsequent TYPE-C product wires can also be gradually increased, but the production process is more complicated, the number of production processes is more, a plurality of people can process the wires according to the process requirements of each process, the production efficiency of enterprises is low, and the production cost of the enterprises is higher.

The American fragrant meadow conference center apple in san Francisco has released brand-new Lightning Dock interface, and the interface both sides all have 8Pin contacts, and positive and negative insertion all can normally work, and new interface not only is more easy to use, and the incorruptibility is also higher moreover. In addition, the new Lightning wire can transmit specific signals required by the accessory through the interface according to different accessories, and simultaneously supports video output. With the increasing popularity of apple products, the market demand of Lightning wire is also increasing.

Aiming at the complex production processes of the two products, more production processes are basically completed by multiple persons at the present stage, one or more persons complete the previous process, and then the next process flows into the next process and is completed by one or more persons, so that the whole process of one product is completed by the process. At present, the processing and production processes of USB and Lightning wires generally include: arranging core wires, removing the core wires, dipping tin, comparing and shearing, installing parts, welding, riveting, dispensing and the like. The series of processes are complicated, require a large amount of labor and are inefficient, so that designing a brand new automatic device becomes a problem to be solved by those skilled in the art.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide an automatic assembly line of data line, it is low to aim at solving the data line production facility degree of automation among the prior art, thereby needs the manual work to control and lead to production precision and the lower technical problem of production efficiency.

In order to achieve the above object, an embodiment of the utility model provides an automatic assembly line of data line, including frame, removal tool and controlling means, be equipped with the mobile rail in the frame, the both ends of mobile rail are equipped with artifical cycloid station and artifical line station of getting respectively, it follows to remove the tool the mobile rail removes in order to be used for transmitting the data line, be provided with the automatic adhesive deposite device who is used for spraying and solidification colloid toward the data line body that arranges in proper order in the frame, be used for pasting the Mylar film-drawing device to the data line after accomplishing the point gluing, be used for carrying out welded automatic spot welding device to the data line after accomplishing the Mylar film-drawing and be used for entering the data line shielding shell riveting device of riveting to the data line after accomplishing the welding, controlling means locates in the frame, controlling means with automatic adhesive deposite device who arranges in proper order in the frame, The automatic Mylar pasting device, the automatic spot welding device and the data line shielding shell riveting device are electrically connected.

Optionally, the automatic mylar sticking device comprises a bracket, a limiting mechanism, a clamping mechanism, a mylar sticking mechanism, a rotating mechanism and a shearing mechanism; the support with frame fixed connection, stop gear locates the moving guide below is in order to be used for the location the removal tool, fixture locates the side of moving guide is with the centre gripping the removal tool, paste the wheat and draw the mechanism and locate the moving guide top, rotary mechanism locates on the linear path of moving tool in order to be used for loading data line plug body, it locates to cut the mechanism the moving track top is in order to be used for cutting the wheat pulling-on piece.

Optionally, the mylar sticking mechanism comprises two first linear modules, a first bottom plate, a first air cylinder, two second linear modules, a second bottom plate, a second air cylinder and a tape coiling module; the bottoms of the two first linear modules are fixedly connected with the support, the two first linear modules are transversely arranged, the bottom of the first bottom plate is fixedly connected with the output ends of the two first linear modules, and a piston rod of the first air cylinder is in driving connection with the first bottom plate;

the bottoms of the two second linear modules are connected with the top of the first bottom plate, the two second linear modules are arranged in the vertical direction, the second bottom plate is fixedly connected with the output ends of the two second linear modules, and a piston rod of the second air cylinder is in driving connection with the second bottom plate; the tape coiling module is rotationally connected with the second bottom plate.

Optionally, the winding module includes first running roller, second running roller, third running roller and adsorption apparatus, first running roller the second running roller with the third running roller all with the second bottom plate rotates to be connected, adsorption apparatus locates the side of third running roller is in order to be used for adsorbing around locating wheat pulling-on piece on the second running roller.

Optionally, the automatic mylar sticking device further comprises an adjusting mechanism, wherein the adjusting mechanism comprises a third linear module, a third bottom plate and a third air cylinder; the bottom of the third linear module is fixedly connected with the top of the second bottom plate, the bottom of the third bottom plate is fixedly connected with the output end of the third linear module, a piston rod of the third cylinder is in driving connection with the third bottom plate, and the second roller wheel is in rotating connection with the third bottom plate so as to be used for adjusting the length of the Mylar film adsorbed on the adsorption mechanism;

automatic paste mylar device still covers the mechanism including pressing, press to cover the mechanism and include fourth cylinder and briquetting, the cylinder body of fourth cylinder with support fixed connection, the briquetting with the piston rod fixed connection of fourth cylinder is in order to be used for flattening attached mylar piece on the data line.

Optionally, the data line shielding shell riveting device comprises a riveting support, a first rotating mechanism, a second rotating mechanism, a first riveting mechanism, a second riveting mechanism and a positioning mechanism; the riveting support is characterized in that the first rotating mechanism and the second rotating mechanism are respectively arranged at two ends of the top of the riveting support in the length direction, the first riveting mechanism is rotatably connected with the first rotating mechanism, the second riveting mechanism is rotatably connected with the second rotating mechanism, an installation cavity is formed between the first riveting mechanism and the second riveting mechanism, and the positioning mechanism is fixedly connected with the riveting support and arranged in the installation cavity.

Optionally, the first riveting mechanism includes a first riveting base plate, a first connecting seat, a first jacking piece and a first clamping block; the first riveting base plate is rotationally connected with the first rotating mechanism, the bottom of the first connecting seat is connected with the first riveting base plate in a sliding fit manner, the first jacking piece is arranged on the first riveting base plate, the output end of the first jacking piece is in driving connection with the first connecting seat, and the first clamping block is fixedly connected with the first connecting seat; the first riveting mechanism further comprises a first push rod and a first riveting head; the first push rod is connected with the top of the first connecting seat in a sliding fit mode, and the first riveting head is fixedly connected with the first push rod;

the riveting mechanism is characterized in that a first limiting plate is arranged on the first riveting mechanism, the first limiting plate is fixedly connected with the top of the first connecting seat, a first containing cavity is formed between the first limiting plate and the first connecting seat, and the first push rod is arranged in the first containing cavity.

Optionally, the second riveting mechanism includes a second riveting base plate, a second connecting seat, a second jacking piece, and a second clamping block; the second riveting bottom plate is rotationally connected with the second rotating mechanism, the bottom of the second connecting seat is connected with the second riveting bottom plate in a sliding fit manner, the second jacking piece is arranged on the second riveting bottom plate, the output end of the second jacking piece is in driving connection with the second connecting seat, and the second clamping block is fixedly connected with the second connecting seat; the second riveting mechanism further comprises a second push rod and a second riveting head; the second push rod is connected with the top of the second connecting seat in a sliding fit mode, and the second riveting head is fixedly connected with the second push rod;

the second riveting mechanism is provided with a second limiting plate, the second limiting plate is fixedly connected with the top of the second connecting seat, a second containing cavity is formed between the second limiting plate and the second connecting seat, and the second push rod is arranged in the second containing cavity.

Optionally, the automatic glue dispensing device comprises a glue spraying mechanism and a UV light source glue baking mechanism; the glue spraying mechanism is arranged at the side of the artificial cycloid station and used for spraying glue on the data line, and the UV light source glue baking mechanism is arranged at the side of the glue spraying mechanism and used for carrying out glue fixation on the data line subjected to glue spraying treatment.

Optionally, the stitch welding device comprises a first electrode and a second electrode; the first electrode and the second electrode are arranged above the movable guide rail and used for welding the data wire shielding shell.

The embodiment of the utility model provides an above-mentioned one or more technical scheme in the automatic assembly line of data line have one of following technological effect at least: the utility model discloses an automatic assembly line of data line, during operation, firstly, turn on the working power supply, then the workman carries on the material loading at the artifical pendulum winding displacement station, insert the data line into the removal tool, then, click the start key of controlling means, at this moment the removal tool comes to the side of automatic adhesive deposite device along the track of moving guide rail, at this moment automatic adhesive deposite device carries out the point glue technology to the data line, make glue a layer of glue on the data line, then, the removal tool moves to the side of automatic Mylar pasting device, at this moment automatic Mylar pasting device carries out the Mylar pasting step to the data line, after the Mylar pasting step, the security of the internal circuit of data line has very big part to promote, then carry out the process of shelling to the data line, after the dress is finished, the automatic spot welding device carries out metal shell spot welding to the data line, at last, carry out the riveting to the data line through data line shielding shell riveting device, the final product is output from the manual wire taking station, and through the automatic glue dispensing device, the automatic Mylar pasting device, the automatic spot welding device and the data wire shielding shell riveting device, automation and integration of data wire production are realized, the labor intensity of workers is liberated, the data wire can be kept in higher ground precision fit in the assembling process, the processing quality of the device is improved, and the precision of the produced product is higher.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings required for the embodiments or the prior art descriptions will be briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art to obtain other drawings without inventive labor.

Fig. 1 is a schematic structural diagram of an automatic assembly line for data lines according to an embodiment of the present invention.

Fig. 2 is a schematic structural view of an automatic mylar pasting device of an automatic data line assembly line according to an embodiment of the present invention.

Fig. 3 is another schematic structural diagram of an automatic mylar pasting device of an automatic data line assembly line according to an embodiment of the present invention.

Fig. 4 is a schematic structural view of a mylar pasting mechanism of an automatic mylar pasting device of an automatic data line assembly line according to an embodiment of the present invention.

Fig. 5 is another schematic structural diagram of a mylar pasting mechanism of an automatic data line assembly line according to an embodiment of the present invention.

Fig. 6 is a schematic structural view of a tape coiling module of an automatic data line assembly line according to an embodiment of the present invention.

Fig. 7 is a schematic structural diagram of an adjusting mechanism of an automatic data line assembly line according to an embodiment of the present invention.

Fig. 8 is a schematic structural view of a pressing mechanism of an automatic data line assembly line according to an embodiment of the present invention.

Fig. 9 is a schematic structural view of a clamping mechanism of an automatic data line assembly line according to an embodiment of the present invention.

Fig. 10 is a schematic structural diagram of a rotating mechanism of an automatic data line assembly line according to an embodiment of the present invention.

Fig. 11 is a schematic structural view of a data line shielding shell riveting device of an automatic data line assembly line according to an embodiment of the present invention.

Fig. 12 is another schematic structural diagram of a data line shielding shell riveting device of an automatic data line assembly line according to an embodiment of the present invention.

Fig. 13 is a schematic structural diagram of a positioning mechanism of a data wire shielding shell riveting device of an automatic data wire assembly line according to an embodiment of the present invention.

Fig. 14 is a schematic structural diagram of a feeding mechanism of an automatic data line assembly line according to an embodiment of the present invention.

Wherein, in the figures, the respective reference numerals:

10-frame 20-data line shielding shell riveting device 21-riveting support

22-first rotating mechanism 23-second rotating mechanism 24-first riveting mechanism

25-second riveting mechanism 26-positioning mechanism 30-movable guide rail

40-automatic Mylar attaching device 41-support 42-jig base

43-limiting mechanism 44-clamping mechanism 45-mylar sticking mechanism

46-rotating mechanism 47-shearing mechanism 48-adjusting mechanism

49-pressing mechanism 49 a-pressing mechanism 50-moving jig

60-control device 70-automatic adhesive dispensing device 71-glue spraying mechanism

72-UV light source glue baking mechanism 80-automatic spot welding device 81-first electrode

82-second electrode 90-feeding mechanism 91-proximity switch

92-TYPE-C head pressing cylinder 93-wire feeding cylinder 94-ascending and descending motor

95-TYPE-C head clamping cylinder 96-left and right shifting motor 97-wire guide block

98-wire-plugging carrier cylinder 241-first riveting base plate 242-first connecting seat

243-first lifting piece 244-first clamping block 245-first push rod

246-first riveting head 247-first limit plate 251-second riveting bottom plate

252-second connecting seat 253-second lifting piece 254-second clamping block

255-second push rod 256-second riveting head 257-second limiting plate

261-positioning plate 262-inductor 263-first positioning block

264-second positioning block 265-third jacking piece 441-fourth linear module

442-fourth base plate 443-fifth cylinder 444-clamping block

451-first Linear Module 452-first base 453-first Cylinder

454-second linear module 455-second base plate 456-second cylinder

457-winding module 461-first fixing plate 462-second fixing plate

463-motor 464-coupling 465-rotating head

481-third straight line module 482-third bottom plate 483-third cylinder

491-fourth cylinder 492-briquetting 491 a-ninth cylinder

492 a-pressure plate 4571-first roller 4572-second roller

4573-third roller 4574-adsorption mechanism.

Detailed Description

Reference will now be made in detail to embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like reference numerals refer to the same or similar elements or elements having the same or similar function throughout. The embodiments described below by referring to the drawings are exemplary and intended to explain the embodiments of the present invention and are not to be construed as limiting the present invention.

In an embodiment of the present invention, as shown in fig. 1, there is provided an automatic data line assembly line, including a frame 10, a moving jig 50 and a control device 60, wherein a moving guide 30 is disposed on the frame 10, an artificial cycloid station and an artificial line taking station are disposed at two ends of the moving guide 30, respectively, the moving jig 50 moves along the moving guide 30 for transmitting data lines, an automatic dispensing device 70 for spraying and solidifying glue onto a body of the data lines, an automatic mylar sticking device 40 for sticking mylar sheets onto the data lines after dispensing, an automatic spot welding device 80 for welding the data lines after the mylar sheets are stuck, and a data line shielding shell riveting device 20 for riveting the data lines after the welding are disposed on the frame 10, the control device 60 is electrically connected to the automatic dispensing device 70, the automatic mylar sticking device 40, the automatic spot welding device 80 and the data line shielding shell riveting device 20 which are sequentially arranged on the rack 10.

Specifically, the utility model discloses an automatic assembly line of data line, during operation, firstly, turn on the working power supply, then the workman carries out the material loading at artifical pendulum winding displacement station, at this moment, open the clip on the removal tool 50 by external equipment, then insert the TYPE-C head on the data line into the TYPE-C hole on the removal tool 50 by the manipulator, at this moment, external equipment withdraws the clip and tightly accomplishes the wire inserting action by the spring clamp on the removal tool 50 automatically, then, click the start key of controlling means 60, at this moment, the removal tool 50 comes to the side of automatic glue dispensing device 70 along the track of mobile rail 30, at this moment, automatic glue dispensing device 70 carries out the glue dispensing technology to the data line, make glue a layer on the data line, then, the removal tool 50 moves to the side of automatic wheat-pasting device 40, at this moment, automatic wheat-pasting device 40 carries out the wheat-pasting step to the data line, after the Mylar attaching step, the safety of the internal circuit of the data line is improved to a great extent, then the data line is subjected to a shell installing process, after the shell installing is finished, the automatic spot welding device 80 performs metal shell spot welding on the data line, finally, the data line is riveted through the data line shielding shell riveting device 20, the final finished product is output from a manual line taking station, and through the arranged automatic spot welding device 70, the automatic Mylar attaching device 40, the automatic spot welding device 80 and the data line shielding shell riveting device 20, the automation and integration of data line production are realized, the labor intensity of workers is relieved, the data line can be kept in higher ground precision matching in the assembling process, the processing quality of the device is improved, and the precision of the produced product is higher.

In another embodiment of the present invention, as shown in fig. 1 to 3, the automatic mylar sticking device 40 includes a bracket 41, a limiting mechanism 43, a clamping mechanism 44, a mylar sticking mechanism 45, a rotating mechanism 46, and a shearing mechanism 47; the support 41 is fixedly connected with the rack 10, the limiting mechanism 43 is arranged below the movable guide rail 30 and used for positioning the movable jig 50, the clamping mechanism 44 is arranged beside the movable guide rail 30 and used for clamping the movable jig 50, the mylar sticking mechanism 45 is arranged above the movable guide rail 30, the rotating mechanism 46 is arranged on a linear path of the movable jig 50 and used for loading a data line plug body, and the shearing mechanism 47 is arranged above the movable rail 30 and used for cutting the mylar. Specifically, when a data line comes to the side of the automatic mylar sticking device 40, at this time, the limiting mechanism 43 and the clamping mechanism 44 limit the moving jig 50 in the horizontal position, then the mylar sticking mechanism 45 conveys the mylar sheets to the upper side of the data line plug body, at this time, the mylar sheets are firstly stuck on the upper side of the data line plug body, then the rotating mechanism 46 rotates the data line plug body by 180 degrees, at this time, the surface of the data line plug body is covered with a layer of complete mylar sheets, finally, the shearing mechanism 47 cuts off the redundant mylar sheets, then the limiting mechanism 43 and the clamping mechanism 44 return to the original position, the moving jig 50 drives the data line plug body to enter the next station for processing, in the whole mylar sticking process, except for manual feeding, the rest steps are completed by the machine itself, the highly automated production process is realized, and the problem of traditional manual control is solved, greatly improving the production precision.

In another embodiment of the present invention, as shown in fig. 1 to 5, the mylar sticking mechanism 45 includes two first linear modules 451, a first bottom plate 452, a first cylinder 453, two second linear modules 454, a second bottom plate 455, a second cylinder 456, and a tape coiling module 457; the bottoms of the two first linear modules 451 are fixedly connected with the bracket 41, the two first linear modules 451 are transversely arranged, the bottom of the first bottom plate 452 is fixedly connected with the output ends of the two first linear modules 451, and the piston rod of the first cylinder 453 is in driving connection with the first bottom plate 452;

the bottoms of the two second linear modules 454 are connected with the top of the first bottom plate 452, the two second linear modules 454 are arranged in a vertical direction, the second bottom plate 455 is fixedly connected with the output ends of the two second linear modules 454, and the piston rod of the second cylinder 456 is in driving connection with the second bottom plate 455; the tape coiling module 457 is rotatably connected with the second bottom plate 455. Specifically, two first linear modules 451 arranged in the transverse direction are arranged on the bracket 41, after the first bottom plate 452 and the two first linear modules 451 are fixedly connected, the first bottom plate 452 can move along the length direction of the two first linear modules 451 by driving the first air cylinder 453, so as to realize the transverse movement, two second linear modules 454 arranged in the vertical direction are further arranged on the first bottom plate 452, the two second linear modules 454 are provided with the second bottom plate 455, the second bottom plate 455 is in driving connection with the second air cylinder 456, when the second air cylinder 456 is driven, the second bottom plate 455 is driven by the second air cylinder 456, so that the second bottom plate 455 of the second air cylinder 456 can move along the length direction of the two second linear modules 454, so as to realize the vertical movement, a tape coiling module 457 is arranged on the top of the second bottom plate 455, the winding belt module 457 that sets up can twine the Mylar piece for the Mylar piece can neatly enter into the processing position accurately, is favorable to improving the precision of processing.

In another embodiment of the present invention, as shown in fig. 1 to 6, the winding module 457 includes a first roller 4571, a second roller 4572, a third roller 4573 and an adsorption mechanism 4574, the first roller 4571, the second roller 4572 and the third roller 4573 are all connected to the second bottom plate 455 in a rotating manner, and the adsorption mechanism 4574 is disposed beside the third roller 4573 for adsorbing the mylar sheets wound on the third roller 4573. Specifically, through the arrangement of the first roller 4571, the second roller 4572 and the third roller 4573, the wheat pull tab can be orderly wound on the first roller 4571, the second roller 4572 and the third roller 4573, when the wheat pull tab needs to be used, the wheat pull tab can be used by rotating the first roller 4571, the second roller 4572 and the third roller 4573, and the adsorption mechanism 4574 is arranged beside the third roller 4573, so that when the wheat pull tab is output from the third roller 4573, the adsorption mechanism 4574 can tightly adsorb the wheat pull tab, and thus the data line is processed.

In another embodiment of the present invention, as shown in fig. 1 to 8, the automatic mylar sticking device 40 further includes an adjusting mechanism 48, and the adjusting mechanism 48 includes a third linear module 481, a third bottom plate 482 and a third air cylinder 483; the bottom of the third linear module 481 is fixedly connected with the top of the second bottom plate 455, the bottom of the third bottom plate 482 is fixedly connected with the output end of the third linear module 481, the piston rod of the third cylinder 483 is in driving connection with the third bottom plate 482, and the second roller 4572 is rotatably connected with the third bottom plate 482 for adjusting the length of a Mylar film adsorbed on the adsorption mechanism;

the automatic mylar sticking device 40 further comprises a pressing mechanism 49, the pressing mechanism 49 comprises a fourth cylinder 491 and a pressing block 492, a cylinder body of the fourth cylinder 491 is fixedly connected with the support 41, and the pressing block 492 is fixedly connected with a piston rod of the fourth cylinder 491 for flattening the mylar sheets stuck on the data lines. Specifically, the second roller 4572 is fixedly connected with a third base plate 482 arranged on the adjusting mechanism 48, the third base plate 482 can move on a third linear module 481 arranged, and by driving a third air cylinder 483, the second roller 4572 can move in the transverse direction, that is, the third air cylinder 483 can be driven to drive the second roller 4572, so that the length of the wheat pulling sheet is in a controllable range, the length adjustment can be performed according to the requirement of actual production, during the adjustment, the third air cylinder 483 drives the second roller 4572 to move to the right, the second roller 4572 elongates the wheat pulling sheet, then the third air cylinder 483 resets, at this moment, the length of the wheat pulling sheet can be changed, the whole adjustment process does not need to be manually participated, when the wheat pulling sheet is output to the upper side of the data line from the bottom of the adsorption mechanism 4574, at this moment, the wheat pulling sheet needs to be pressed on the data line for pasting, when the pressing is needed, the fourth cylinder 491 is driven, the pressing block 492 arranged at the output end of the fourth cylinder 491 is driven to the upper side of the data line, the pressing block 492 resets the Mylar film above the data line, the whole process is automatically controlled, and the precision is improved.

In another embodiment of the present invention, as shown in fig. 1 to 9, the clamping mechanism 44 includes two fourth linear modules 441, a fourth bottom plate 442, a fifth cylinder 443 and a clamping block 444; the bottoms of the two fourth linear modules 441 are fixedly connected to the bracket 41, the bottom of the fourth base plate 442 is fixedly connected to the tops of the two fourth linear modules 441, the output end of the fifth cylinder 443 is drivingly connected to the fourth base plate 442, and the clamping block 444 is fixedly connected to the fourth base plate 442. Specifically, two fourth straight line modules 441 are horizontally arranged on the support 41, a fourth bottom plate 442 is installed above the two fourth straight line modules 441, a clamping block 444 is fixedly connected to one end of the top of the fourth bottom plate 442, and when the fifth cylinder 443 is driven, the fifth cylinder 443 drives the fourth bottom plate 442 to move along the length direction of the two fourth straight line modules 441, so that the clamping block 444 can clamp the movable jig 50, the movable jig 50 is just matched with the clamping block 444, the movable jig 50 is limited in the horizontal position, automatic control is realized in the whole process, and the improvement of the precision is facilitated.

In another embodiment of the present invention, as shown in fig. 1 to 10, the rotating mechanism 46 includes a first fixing plate 461, a second fixing plate 462, a motor 463, a coupling 464, and a rotating head 465; the first fixing plate 461 and the second fixing plate 462 are both fixedly connected to the fourth base plate 442, the motor 463 body is fixedly connected to the first fixing plate 461, the rotating head 465 is rotatably connected to the second fixing plate 462, and the coupling 464 is disposed between the motor 463 and the coupling 464. Specifically, after the data line top is exported from adsorption apparatus 4574's bottom to the wheat pulling-on piece, the wheat pulling-on piece is pasted to the data line top, this moment, need process the below of data line, at this moment, the motor 463 that sets up on fixture 44 begins to work, motor 463 begins to rotate, the output of motor 463 is connected with a shaft coupling 464, the other end of shaft coupling 464 is provided with a rotating head 465, when motor 463 rotates, rotating head 465 also is driven rotatoryly, rotating head 465 and removal tool 50 cooperate this moment, with the rotatory 180 of data line, at this moment paste the wheat to another part of data line and draw the process, automated control is realized to whole process, be favorable to improving the precision.

In another embodiment of the present invention, as shown in fig. 2, the automatic mylar sticking device 40 further comprises a pressing mechanism 49a, wherein the pressing mechanism 49a comprises a ninth cylinder 491a and a pressing plate 492 a; the cylinder body of the ninth cylinder 491a is fixedly connected with the bracket 41, and the output end of the ninth cylinder 491a is fixedly connected with the pressure plate 492 a. Specifically, after the data line finishes the mylar attaching process, the movable jig 50 conveys the data line to the position below the pressing mechanism 49a to press corners of the data line, and the redundant leftover materials can be effectively pressed through the process, so that the redundant leftover materials are pressed, the integrity of the data line is kept, the whole process is automatically controlled, and the improvement of the precision is facilitated.

In another embodiment of the present invention, as shown in fig. 1, 11, 12 and 13, the data cable shielding shell riveting device 20 includes a support 21, a first rotating mechanism 22, a second rotating mechanism 23, a first riveting mechanism 24, a second riveting mechanism 25 and a positioning mechanism 26; the first rotating mechanism 22 and the second rotating mechanism 23 are respectively arranged at two ends of the top of the support 21 in the length direction, the first riveting mechanism 24 is rotatably connected with the first rotating mechanism 22, the second riveting mechanism 25 is rotatably connected with the second rotating mechanism 23, an installation cavity (not shown) is formed between the first riveting mechanism 24 and the second riveting mechanism 25, and the positioning mechanism 26 is fixedly connected with the support 21 and arranged in the installation cavity. Specifically, when the data line comes to the side of the data line shielding shell riveting device 20, the first rotating mechanism 22 and the second rotating mechanism 23 both rotate downward, the first riveting mechanism 24 and the second riveting mechanism 25 respectively connected to the first rotating mechanism 22 and the second rotating mechanism 23 also rotate downward at the same time, when the first riveting mechanism 24 and the second riveting mechanism 25 reach the lower position, the first riveting mechanism 24 and the second riveting mechanism 25 take material at the same time, after the material taking is completed, the first riveting mechanism 24 and the second riveting mechanism 25 return to the processing position, the data line is inserted into the positioning mechanism 26 at this time, the positioning mechanism 26 performs vertical positioning on the data line, after the vertical positioning is completed, the first riveting mechanism 24 and the second riveting mechanism 25 both move toward the positioning mechanism 26, when the first riveting mechanism 24 and the second riveting mechanism 25 contact the data line, can fix a position the horizontal direction of data line, after the location was accomplished, first riveting mechanism 24 and second riveting mechanism 25 carry out the riveting to the data line, obtain the product at last, first rotary mechanism 22 and second rotary mechanism 23 through this device setting, realized getting the material to the automation of shield cover, workman's intensity of labour has been liberated, and the first riveting mechanism 24 that sets up, second riveting mechanism 25 and positioning mechanism 26 have carried out the location of level and vertical direction to the data line, make the data line can not take place the offset at the in-process of riveting, the processingquality of this device has been promoted, thereby the product precision of making production is higher.

In another embodiment of the present invention, as shown in fig. 1, 11, 12 and 13, the first riveting mechanism 24 includes a first riveting base plate 241, a first connecting seat 242, a first lifting member 243 and a first clamping block 244; the first riveting base plate 241 is rotatably connected to the first rotating mechanism 22, the bottom of the first connecting seat 242 is connected to the first riveting base plate 241 in a sliding fit manner, the first lifting member 243 is disposed on the first riveting base plate 241, the output end of the first lifting member 243 is in driving connection with the first connecting seat 242, and the first clamping block 244 is fixedly connected to the first connecting seat 242; the first riveting mechanism 24 further comprises a first push rod 245 and a first riveting head 246; the first push rod 245 is connected with the top of the first connecting seat 242 in a sliding fit manner, and the first riveting head 246 is fixedly connected with the first push rod 245;

the first riveting mechanism 24 is provided with a first limiting plate 247, the first limiting plate 247 is fixedly connected to the top of the first connecting seat 242, a first accommodating cavity (not shown) is formed between the first limiting plate 247 and the first connecting seat 242, and the first push rod 245 is disposed in the first accommodating cavity. Specifically, when the first rotating mechanism 22 works, the first rotating mechanism 22 will drive the first riveting base plate 241 to rotate, at this time, the first connecting seat 242, the first lifting piece 243 and the first clamping block 244 connected to the first riveting base plate 241 are also driven along the same line, when the first lifting piece 243 rotates in place, the first lifting piece 243 starts to drive the first connecting seat 242 to approach the feeding position, when the first connecting seat 242 approaches the feeding position, the first clamping block 244 arranged on the first connecting seat 242 clamps the shielding shell at the feeding position, then the first lifting piece 243 drives the first connecting seat 242 to leave the feeding position, at this time, the first rotating mechanism 22 continues to rotate, and the first riveting base plate 241, the first connecting seat 242, the first lifting piece 243 and the first clamping block 244 are simultaneously rotated to the processing position, so as to implement the processing process, and when the first rotating mechanism 22 rotates the first riveting base plate 241, the first connecting seat 242, the first lifting piece 243 and the first clamping block 244 to the processing position, so that the first rotating mechanism 22 rotates the first riveting base plate, When the first lifting member 243 and the first clamping block 244 are simultaneously screwed to the machining position, the first push rod 245 and the first riveting head 246 provided on the first coupling seat 242 start to work, since one end of the first push rod 245 is connected to the external punch motor and the other end of the first push rod 245 is fixedly connected to the first riveting head 246, in operation, the external punch motor drives the first push rod 245 to approach the shielding cover, the first riveting head 246 arranged on the first push rod 245 rivets the shielding cover to complete riveting in the first direction, because the first containing cavity formed in the first connecting seat 242 is provided with the first limiting plate 247, when the first push rod 245 moves in the first accommodation chamber, the first stopper plate 247 restricts the moving range of the first push rod 245, so that the first push rod 245 is not shifted when approaching the shielding cover, thereby improving the riveting precision of the first riveting head 246 on the shielding cover.

In another embodiment of the present invention, as shown in fig. 1, 11, 12 and 13, the second riveting mechanism 25 includes a second riveting base plate 251, a second connecting seat 252, a second jacking piece 253 and a second clamping block 254; the second riveting base plate 251 is rotatably connected with the second rotating mechanism 23, the bottom of the second connecting seat 252 is connected with the second riveting base plate 251 in a sliding fit manner, the second jacking piece 253 is arranged on the second riveting base plate 251, the output end of the second jacking piece 253 is in driving connection with the second connecting seat 252, and the second clamping block 254 is fixedly connected with the second connecting seat 252; the second riveting mechanism 25 further comprises a second push rod 255 and a second riveting head 256; the second push rod 255 is connected with the top of the second connecting seat 252 in a sliding fit manner, and the second riveting head 256 is fixedly connected with the second push rod 255;

the second riveting mechanism 25 is provided with a second limiting plate 257, the second limiting plate 257 is fixedly connected to the top of the second connecting seat 252, a second accommodating cavity is formed between the second limiting plate 257 and the second connecting seat 252, and the second push rod 255 is disposed in the second accommodating cavity (not shown). Specifically, when the second rotating mechanism 23 works, the second rotating mechanism 23 will drive the second riveting base plate 251 to rotate, at this time, the second connecting seat 252, the second lifting piece 253, and the second clamping block 254 connected to the second riveting base plate 251 are also driven along the same direction, when the second connecting seat 252 is rotated in place, the second lifting piece 253 starts to drive the second connecting seat 252 to approach the feeding position, when the second connecting seat 252 approaches the feeding position, the second clamping block 254 disposed on the second connecting seat 252 clamps the shielding shell at the feeding position, and then the second lifting piece 253 drives the second connecting seat 252 to leave the feeding position, at this time, the second rotating mechanism 23 continues to rotate, and the second riveting base plate 251, the second connecting seat 252, the second lifting piece 253, and the second clamping block 254 are simultaneously moved to the processing position, so as to implement the processing process, when the second rotating mechanism 23 rotates the second riveting base plate 251, the second connecting seat 252, the second lifting piece 253, and, When the second lifting piece 253 and the second clamping block 254 are simultaneously screwed to the processing position, the second push rod 255 and the second riveting head 256 arranged on the second connecting seat 252 start to work, since the second push rod 255 has two ends connected to the external punch motor and the second push rod 255 has the other ends fixedly connected to the second riveting head 256, in operation, the external punch motor drives the second push rod 255 to approach the shield cover, the second riveting head 256 arranged on the second push rod 255 rivets the shield cover to complete riveting in the second direction, since the second containing cavity formed in the second connecting seat 252 is provided with the second limiting plate 257, when the second push rod 255 moves in the second receiving chamber, the second stopper plate 257 limits the moving range of the second push rod 255, so that the second push rod 255 does not deviate when approaching the shielding cover, and the riveting precision of the second riveting head 256 to the shielding cover is further improved.

In another embodiment of the present invention, as shown in fig. 1, the automatic glue dispensing device 70 includes a glue spraying mechanism 71 and a UV light source glue baking mechanism 72; the glue spraying mechanism 71 is arranged at the side of the artificial cycloid station and used for spraying glue on the data lines, and the UV light source glue baking mechanism 72 is arranged at the side of the glue spraying mechanism 71 and used for fixing the data lines subjected to glue spraying treatment. Specifically, spray glue on the data line, rethread UV light source shines and makes the solidification of UV curing glue, and the light source shines perpendicularly downwards for the pointolite for light can not disperse, can not cause light pollution, and two UV light sources all are equipped with zoom lens, play the effect of spotlight, accelerate curing speed, improve production efficiency, and convenient to use, long service life, the sensitivity to the control of light source intensity is high.

In another embodiment of the present invention, as shown in fig. 1, the stitch welding device 80 includes a first electrode 81 and a second electrode 82; the first electrode 81 and the second electrode 82 are disposed above the moving guide 30 for welding a data wire shielding case. Particularly, the data line is subjected to metal shell spot welding through the first electrode 81 and the second electrode 82, so that the internal circuit structure of the data line can be better protected, and the service life of a finished data line product is prolonged.

In another embodiment of the present invention, as shown in fig. 1 and 14, the automatic assembly line for data line comprises a feeding mechanism 90, wherein the feeding mechanism 90 is disposed beside the artificial cycloid station for feeding the data line. Specifically, firstly, feeding is carried out at a manual wire arrangement swinging station, at the moment, a clamp on a movable jig 50 is opened by external equipment, then a manipulator inserts a TYPE-C head on a data wire into a TYPE-C hole on the movable jig 50, at the moment, the external equipment is withdrawn, the clamp automatically clamps by a spring on the movable jig 50 to finish wire plugging, then, a starting key of a control device 60 is clicked, at the moment, the movable jig 50 comes to the side of a feeding mechanism 90 along the track of a movable guide rail 30, at the moment, the clamp is pressed by a TYPE-C head pressing cylinder 92 after being sensed to be in place by a proximity switch 91, then, the wire is sent to a terminal position by a wire sending cylinder 93, then, an ascending and descending motor 94 is used for appointing a wire taking position, a TYPE-C head clamping cylinder 95 is used for clamping the TYPE-C head on the data wire, a left and right shifting motor 96 is moved to an ascending and descending motor 94 above a movable socket 50 and, meanwhile, the data wire is pressed into the clamp by the wire guide block 97, and the wire is inserted into the carrier cylinder 98 and pulled back into the movable jig 50, so that the wire insertion is completed.

The above description is only exemplary of the present invention and should not be taken as limiting the scope of the present invention, as any modifications, equivalents, improvements and the like made within the spirit and principles of the present invention are intended to be included within the scope of the present invention.

Claims (10)

1. The automatic data line assembly line comprises a rack, wherein a movable guide rail is arranged on the rack, and two ends of the movable guide rail are respectively provided with an artificial cycloid station and an artificial line taking station; the method is characterized in that: the automatic assembly line of data line still includes removal tool and controlling means, remove the tool and follow the removal guide rail removes in order to be used for transmitting the data line, be provided with the automatic adhesive deposite device who is used for spraying and solidification colloid on the data line body that arranges in proper order in the frame, be used for pasting the Mylar device to the automation that the data line after accomplishing the point was glued, be used for carrying out welded automatic spot welding device to the data line after accomplishing pasting the Mylar and be used for advancing the data line shield shell riveting device of riveting to the data line after accomplishing the welding, controlling means locates in the frame, controlling means with automatic adhesive deposite device, automatic Mylar device, automatic spot welding device and data line shield shell riveting device electric connection that arrange in proper order in the frame.

2. The automatic data-line assembly line according to claim 1, characterized in that: the automatic Mylar sticking device comprises a bracket, a limiting mechanism, a clamping mechanism, a Mylar sticking mechanism, a rotating mechanism and a shearing mechanism; the support with frame fixed connection, stop gear locates the moving guide below is in order to be used for the location the removal tool, fixture locates the side of moving guide is with the centre gripping the removal tool, paste the wheat and draw the mechanism and locate the moving guide top, rotary mechanism locates on the linear path of moving tool in order to be used for loading data line plug body, it locates to cut the mechanism moving guide top is in order to be used for cutting the wheat pulling-on piece.

3. The automatic data-line assembly line according to claim 2, characterized in that: the Mylar sticking mechanism comprises two first linear modules, a first bottom plate, a first air cylinder, two second linear modules, a second bottom plate, a second air cylinder and a tape coiling module; the bottoms of the two first linear modules are fixedly connected with the support, the two first linear modules are transversely arranged, the bottom of the first bottom plate is fixedly connected with the output ends of the two first linear modules, and a piston rod of the first air cylinder is in driving connection with the first bottom plate;

the bottoms of the two second linear modules are connected with the top of the first bottom plate, the two second linear modules are arranged in the vertical direction, the second bottom plate is fixedly connected with the output ends of the two second linear modules, and a piston rod of the second air cylinder is in driving connection with the second bottom plate; the tape coiling module is rotationally connected with the second bottom plate.

4. The automatic data-line assembly line according to claim 3, characterized in that: the winding module comprises a first roller wheel, a second roller wheel, a third roller wheel and an adsorption mechanism, wherein the first roller wheel, the second roller wheel and the third roller wheel are all connected with the second bottom plate in a rotating mode, the adsorption mechanism is arranged on the side of the third roller wheel, and the side of the third roller wheel is used for adsorbing and winding the wheat pulling sheet on the third roller wheel.

5. The automatic data-line assembly line according to claim 4, characterized in that: the automatic mylar sticking device further comprises an adjusting mechanism, wherein the adjusting mechanism comprises a third linear module, a third bottom plate and a third air cylinder; the bottom of the third linear module is fixedly connected with the top of the second bottom plate, the bottom of the third bottom plate is fixedly connected with the output end of the third linear module, a piston rod of the third cylinder is in driving connection with the third bottom plate, and the second roller wheel is in rotating connection with the third bottom plate so as to be used for adjusting the length of the Mylar film adsorbed on the adsorption mechanism;

automatic paste mylar device still covers the mechanism including pressing, press to cover the mechanism and include fourth cylinder and briquetting, the cylinder body of fourth cylinder with support fixed connection, the briquetting with the piston rod fixed connection of fourth cylinder is in order to be used for flattening attached mylar piece on the data line.

6. The automatic assembly line of data line according to any one of claims 1 to 4, characterized in that: the data line shielding shell riveting device comprises a riveting support, a first rotating mechanism, a second rotating mechanism, a first riveting mechanism, a second riveting mechanism and a positioning mechanism; the riveting support is characterized in that the first rotating mechanism and the second rotating mechanism are respectively arranged at two ends of the top of the riveting support in the length direction, the first riveting mechanism is rotatably connected with the first rotating mechanism, the second riveting mechanism is rotatably connected with the second rotating mechanism, an installation cavity is formed between the first riveting mechanism and the second riveting mechanism, and the positioning mechanism is fixedly connected with the riveting support and arranged in the installation cavity.

7. The automated data-line assembly line of claim 6, wherein: the first riveting mechanism comprises a first riveting bottom plate, a first connecting seat, a first jacking piece and a first clamping block; the first riveting base plate is rotationally connected with the first rotating mechanism, the bottom of the first connecting seat is connected with the first riveting base plate in a sliding fit manner, the first jacking piece is arranged on the first riveting base plate, the output end of the first jacking piece is in driving connection with the first connecting seat, and the first clamping block is fixedly connected with the first connecting seat; the first riveting mechanism further comprises a first push rod and a first riveting head; the first push rod is connected with the top of the first connecting seat in a sliding fit mode, and the first riveting head is fixedly connected with the first push rod;

the riveting mechanism is characterized in that a first limiting plate is arranged on the first riveting mechanism, the first limiting plate is fixedly connected with the top of the first connecting seat, a first containing cavity is formed between the first limiting plate and the first connecting seat, and the first push rod is arranged in the first containing cavity.

8. The automated data-line assembly line of claim 6, wherein: the second riveting mechanism comprises a second riveting bottom plate, a second connecting seat, a second jacking piece and a second clamping block; the second riveting bottom plate is rotationally connected with the second rotating mechanism, the bottom of the second connecting seat is connected with the second riveting bottom plate in a sliding fit manner, the second jacking piece is arranged on the second riveting bottom plate, the output end of the second jacking piece is in driving connection with the second connecting seat, and the second clamping block is fixedly connected with the second connecting seat; the second riveting mechanism further comprises a second push rod and a second riveting head; the second push rod is connected with the top of the second connecting seat in a sliding fit mode, and the second riveting head is fixedly connected with the second push rod;

the second riveting mechanism is provided with a second limiting plate, the second limiting plate is fixedly connected with the top of the second connecting seat, a second containing cavity is formed between the second limiting plate and the second connecting seat, and the second push rod is arranged in the second containing cavity.

9. The automatic assembly line of data line according to any one of claims 1 to 4, characterized in that: the automatic glue dispensing device comprises a glue spraying mechanism and a UV light source glue baking mechanism; the glue spraying mechanism is arranged at the side of the artificial cycloid station and used for spraying glue on the data line, and the UV light source glue baking mechanism is arranged at the side of the glue spraying mechanism and used for carrying out glue fixation on the data line subjected to glue spraying treatment.

10. The automatic assembly line of data line according to any one of claims 1 to 4, characterized in that: the stitch welding device comprises a first electrode and a second electrode; the first electrode and the second electrode are arranged above the movable guide rail and used for welding the data wire shielding shell.

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