CN215545607U - Automatic production line for connecting wires - Google Patents

Abstract

The utility model relates to the technical field of automatic production, in particular to an automatic production line for a connecting line, which comprises a pretreatment unit, a first shell loading unit and a second shell loading unit, wherein the pretreatment unit is used for respectively carrying out soldering tin treatment on two ends of the connecting line, the first shell loading unit is used for mounting a TYPE-C connector on one end of the connecting line, and the second shell loading unit is used for mounting a USB connector on the other end of the connecting line. According to the utility model, through the cooperation of the pretreatment unit, the first shell loading unit and the second shell loading unit, the automatic shell loading of the connecting line is realized without manual intervention, so that the efficiency is improved.

Description

Automatic production line for connecting wires

Technical Field

The utility model relates to the technical field of automatic production, in particular to an automatic production line for connecting wires.

Background

After the electronic devices are respectively welded at the two ends of the connecting wire, the electronic devices are wrapped by iron shells, and then the manufacturing can be finished. Because both ends of the connector need to be provided with iron shells, in the prior art, the connector is generally transferred and end-changed in a manual mode, and then equipment is adopted for shell installation, so that the processing efficiency is reduced, and large-scale high-efficiency production cannot be realized.

Disclosure of Invention

The utility model provides an automatic production line of connecting wires, which aims to solve the problems in the prior art and can realize automatic shell-mounting production of the connecting wires.

In order to solve the technical problems, the utility model adopts the following technical scheme:

the utility model provides an automatic production line of a connecting wire, which comprises a pretreatment unit, a first shell loading unit and a second shell loading unit, wherein the pretreatment unit is used for respectively carrying out soldering tin treatment on two ends of the connecting wire, the first shell loading unit is used for mounting a TYPE-C connector on one end of the connecting wire, and the second shell loading unit is used for mounting a USB connector on the other end of the connecting wire.

Further, the pretreatment unit includes preceding transport mechanism, preceding soldering tin mechanism, preceding shell mechanism, spouts gluey mechanism and antedisplacement line mechanism of lifting, preceding transport mechanism is used for transmitting the preceding carrier that is equipped with the connecting wire, preceding soldering tin mechanism is used for carrying out soldering tin to the connecting wire both ends that the preceding carrier loaded, preceding shell mechanism of lifting is used for opening the preceding carrier, it is used for spouting gluey respectively to the both ends of connecting wire to spout gluey mechanism, preceding shell mechanism is used for picking up and transferring the connecting wire in the preceding carrier to first shell unit of loading.

Furthermore, the front transmission mechanism comprises a guide part, a driving mechanism and a transfer assembly, the guide part is used for guiding the front carrier, the transfer assembly comprises a transfer part and a plurality of transmission parts, the transmission parts are arranged on the transfer part at intervals, the driving mechanism is used for driving the transfer part to move back and forth, the transmission parts are used for pushing the front carrier to move along with the movement of the transfer part and are driven by the driving mechanism to move to the next front carrier to push the next front carrier to move after pushing the front carrier.

Preferably, one end of the pushing part is rotatably connected with the transmission part, the other end of the pushing part is provided with a protruding part used for abutting against the front carrier, and a yielding inclined plane is arranged between the protruding part and the pushing part; the pushing part resetting piece is connected between the other end of the pushing part and the transmission part.

Furthermore, first dress shell unit includes first transmission device, processing transmission device, rubberized paper mechanism, dress shell mechanism, welding mechanism, riveting mechanism and first line moving mechanism, first transmission device is used for cliping and transmitting the connecting wire, processing transmission device is used for loading the one end of connecting wire and transmits, rubberized paper mechanism is used for the one end rubberized paper to the connecting wire, dress shell mechanism is used for assembling the iron shell to the one end of connecting wire behind the rubberized paper, welding mechanism is used for welding the iron shell of assembly, riveting mechanism is used for carrying out the riveting to the iron shell after the welding, first line moving mechanism is used for transferring the connecting wire after the iron shell riveting to second dress shell unit.

Furthermore, the gummed paper pasting mechanism comprises a paper placing mechanism, a gummed paper pasting mechanism, a sticker positioning mechanism, a sticker overturning mechanism and a paper cutting mechanism, wherein the paper placing mechanism is used for discharging gummed paper, the sticker positioning mechanism is used for positioning the connecting wire, the sticker mechanism is used for pasting the gummed paper to the connecting wire, the sticker overturning mechanism is used for controlling the connecting wire to rotate after pasting paper so that the sticker wraps the connecting wire, and the paper cutting mechanism is used for cutting off the sticker after the sticker wraps the connecting wire.

Preferably, the sticker turnover mechanism comprises a turnover part, a turnover driving component and a turnover translation component, wherein the turnover part is provided with a turnover groove, the turnover driving component is used for driving the turnover part to rotate, and the turnover groove is used for driving the connecting line to turn over; the overturning and translating assembly comprises an overturning and translating cylinder, a translating seat and at least one overturning guide piece, the translating seat is arranged on the guide piece in a sliding mode, the overturning and translating cylinder is used for driving the translating seat to slide, and the overturning and driving assembly and the overturning guide piece are both arranged on the translating seat.

Furthermore, welding mechanism includes welding assembly, welding tilting mechanism, first welding fixture and second welding fixture, first welding fixture is used for transferring the shielding shell of connecting wire extremely welding assembly, second welding fixture is used for cliping the design to the shielding shell, welding mechanism is used for welding the one end of shielding shell, welding tilting mechanism is used for the upset shielding shell so that welding mechanism welds the other end of shielding shell.

Furthermore, the riveting mechanism comprises a first riveting component and a second riveting component, the first riveting component comprises a first riveting driving piece, a first riveting transmission piece and a first riveting piece, the first riveting driving piece is used for driving the first riveting transmission piece to rotate, and the first riveting transmission piece is driven by the first riveting driving piece and then used for driving the first riveting piece to be close to or far away from the second riveting component; the second riveting component is matched with the first riveting component to be used for riveting the iron shell.

Furthermore, a first wire taking unit is arranged between the pretreatment unit and the first shell loading unit, the first wire taking unit is used for transferring one end of a connecting wire to the processing and conveying mechanism, a second wire taking unit is arranged between the first shell loading unit and the second shell loading unit, and the second wire taking unit is used for transferring one end of the connecting wire from the processing and conveying mechanism to the first conveying mechanism.

The utility model has the beneficial effects that: according to the utility model, through the cooperation of the pretreatment unit, the first shell loading unit and the second shell loading unit, the automatic shell loading of the connecting line is realized without manual intervention, so that the efficiency is improved.

Drawings

FIG. 1 is a schematic diagram of the present invention.

FIG. 2 is a schematic diagram of a preprocessing unit according to the present invention.

Fig. 3 is a schematic view of the front transfer mechanism of the present invention.

Fig. 4 is a schematic view of a transfer assembly of the present invention.

FIG. 5 is an exploded schematic view of a transmission member of the present invention.

Fig. 6 is a schematic view of a first housing unit of the present invention.

Fig. 7 is a schematic view of a gummed paper mechanism of the present invention.

FIG. 8 is a schematic view of another perspective of the gummed paper mechanism of the present invention.

Fig. 9 is a schematic view of a decal flipping mechanism of the present invention.

FIG. 10 is a schematic view of a flatbed mechanism according to an embodiment.

Fig. 11 is a schematic view of the welding mechanism of the present invention.

Fig. 12 is a schematic view of the welding canting mechanism of the present invention.

Fig. 13 is a schematic view of a process carrier of the present invention.

Fig. 14 is a schematic view of the riveting mechanism of the utility model.

Fig. 15 is an exploded view of the first rivet assembly of the present invention.

Fig. 16 is an exploded view of a second rivet assembly according to the present invention.

Reference numerals:

1-pretreatment unit, 11-front transmission mechanism, 13-front shell lifting mechanism, 15-front wire moving mechanism, 111-guide piece, 112-driving mechanism, 113-transfer component, 115-front carrier, 1131-transfer piece, 1132-transmission piece, 1133-transmission part, 1134-pushing part, 1135-resetting piece, 1136-convex part, 1138-abdicating slope;

2-a first housing unit, 21-a first transmission mechanism, 22-a processing transmission mechanism, 23-a gummed paper pasting mechanism, 24-a housing mechanism, 25-a welding mechanism, 26-a riveting mechanism, 27-a first wire shifting mechanism, 241-a paper placing mechanism, 242-a paper pasting mechanism, 243-a sticker positioning mechanism, 244-a sticker turnover mechanism, 245-a paper cutting mechanism, 252-a welding turnover mechanism, 253-a first welding clamping mechanism, 254-a second welding clamping mechanism, 255-a welding limiting part, 256-a limiting lifting component, 261-a first riveting component, 262-a second riveting component, 263-a first riveting driving component, 264-a first riveting driving component, 265-a first riveting component, 266-a second riveting driving component, 267-a second riveting driving component, 268-a riveting base, 269-a second riveting component, 2411-a paper placing component, 2412-a guide wheel, 2413-a paper positioning part, 2414-a flat paper component, 2415-adjusting component, 2441-turning component, 2442-turning driving component, 2443-turning translation component, 2610-first riveting limiting block, 2611-second riveting limiting block, 2631-riveting motor, 2632-riveting speed reducer, 2641-rotating component, 2642-driven block, 2643-guide groove, 2651-transmission groove, 2652-first riveting groove, 2671-inclined groove, 2672-limiting groove, 2673-buffer groove, 2681-translation groove, 2691-driving hole, 2692-second riveting groove, 24141-flat paper driving component 241, 42-flat paper component, 24143-paper pressing tooth, 25221-welding turning driving component, 25222-welding driving component and 25223-welding turning component;

3-a second housing unit;

4-processing carrier, 41-base body, 42-clamping piece, 43-hollowed-out hole and 44-control block; 5-a first thread taking unit;

6-second line taking unit.

Detailed Description

In order to facilitate understanding of those skilled in the art, the present invention will be further described with reference to the following examples and drawings, which are not intended to limit the present invention. The present invention is described in detail below with reference to the attached drawings.

As shown in fig. 1 to 16, the automatic production line for the connecting line provided by the utility model comprises a pretreatment unit 1, a first shell-mounting unit 2 and a second shell-mounting unit 3, wherein the pretreatment unit 1 is used for respectively performing soldering treatment on two ends of the connecting line, the first shell-mounting unit 2 is used for mounting a TYPE-C connector on one end of the connecting line, and the second shell-mounting unit 3 is used for mounting a USB connector on the other end of the connecting line.

During the in-service use, the connecting wire is loaded by preceding carrier 115, after pretreatment unit 1 carries out actions such as soldering tin, transfer to first dress shell unit 2 and carry out the iron-clad assembly of TYPE-C specification to the one end of connecting wire, then transfer to second dress shell unit 3 and carry out the iron-clad assembly of USB joint (also called A head) to the other end of connecting wire again, can automize the automatic assembly of accomplishing TYPE-C to A's connecting wire, promoted efficiency.

In this embodiment, the pre-processing unit 1 includes a front conveying mechanism 11, a front soldering mechanism (not shown), a front shell-lifting mechanism 13, a glue-spraying mechanism (not shown), and a front wire-moving mechanism 15, where the front conveying mechanism 11 is configured to convey a front carrier 115 equipped with a connecting wire, the front soldering mechanism is configured to solder two ends of the connecting wire loaded on the front carrier 115, the front shell-lifting mechanism 13 is configured to open the front carrier 115, the glue-spraying mechanism is configured to spray glue on two ends of the connecting wire, and the front wire-moving mechanism 15 is configured to pick up and transfer the connecting wire in the front carrier 115 to the first shell-mounting unit 2. Specifically, the front soldering mechanism and the glue spraying mechanism both output conventional structures, and although not shown, the utility model does not affect the understanding of the technicians in the field.

That is, in the pre-processing unit 1, the front carrier 115 is loaded with the connecting wires and is transmitted by the front transmission mechanism 11, so that the wires of the front carrier 115 enter the front soldering mechanism, the front soldering mechanism performs soldering processing on two ends of the connecting wires, and the connecting wires are in the front carrier 115, so that the exposed positions of the front carrier 115 allow the front soldering mechanism 25 to solder only two ends of the connecting wires and corresponding circuit boards; then the front carrier 115 is opened by the front shell-lifting mechanism 13, so that the glue-spraying mechanism can spray glue on the circuit board part and the connection part of the circuit board and the connecting line; and then the connecting wire subjected to glue spraying treatment is transmitted to the first shell filling unit 2 by the front wire moving mechanism 15 for shell filling so as to realize the subsequent shell filling action of the connecting wire.

Specifically, the front transmission mechanism 11 includes a guide 111, a driving mechanism 112 and a transfer assembly 113, the guide 111 is used for guiding the front carrier 115, the transfer assembly 113 includes a transfer member 1131 and a plurality of transmission members 1132, the plurality of transmission members 1132 are arranged at intervals on the transfer member 1131, the driving mechanism 112 is used for driving the transfer member 1131 to move back and forth, and the transmission members 1132 are used for pushing the front carrier 115 to move along with the movement of the transfer member 1131, and are driven by the driving mechanism 112 to move to the next front carrier 115 to push the next front carrier 115 to move after pushing the front carrier 115.

Taking the perspective of fig. 3 as an example, in actual use, the front carrier 115 is transferred to the guide 111, the driving mechanism 112 is operated to move the transfer member 1131, so that the left transmission member 1132 abuts against the left side of the front carrier 115, and then the driving mechanism 112 drives the transmission member 1132 to make the transmission member 1132 push the front carrier 115 to move rightward; after moving for one stroke, the driving mechanism 112 resets the front carrier 115 and continues to push the front carrier 115, and the leftmost transmission member 1132 pushes the next front carrier 115 to move rightward, and the second front carrier 115 from left to right pushes the previous front carrier 115 to move rightward, thereby achieving the effect of transferring the front carrier 115 in a sectional manner.

Preferably, one end of the pushing part 1134 is rotatably connected to the transmission part 1133, the other end of the pushing part 1134 is provided with a protruding part 1136 for abutting against the front carrier 115, and a yielding slope 1138 is arranged between the protruding part 1136 and the pushing part 1134; the pushing portion 1134 and the restoring member 1135 are connected between the other end of the pushing portion 1134 and the transmission portion 1133.

In actual use, the reset element 1135 is a spring, that is, when the pushing element 1134 abuts against the left side of the front carrier 115, the reset element 1135 is in a state of being jacked up, so as to ensure that the pushing element 1134 can stably push the front carrier 115 along with the action of the driving mechanism 112; after the certain distance is pushed, the transmission member 1132 is driven by the driving mechanism 112 to move reversely, and the pushing portion 1134 is moved to the left side of the next front carrier 115 through the lower portion of the next front carrier 115, and then the resetting member 1135 resets the pushing portion 1134, so as to ensure that the pushing portion 1134 is abutted against and pushed by the next front carrier 115.

Specifically, one end of the pushing part 1134 is rotatably connected to the transmission part 1133, the other end of the pushing part 1134 is provided with a protruding part 1136 for abutting against the front carrier 115, and a yielding slope 1138 is arranged between the protruding part 1136 and the pushing part 1134; the pushing portion 1134 and the restoring member 1135 are connected between the other end of the pushing portion 1134 and the transmission portion 1133. Namely, the protrusion 1136 is used to ensure that it has a sufficient height to interfere with the front carrier 115; the abdicating slope 1138 is used to guide the pushing portion 1134 to enter the lower portion of the next front carrier 115, so as to reduce the stable collision between the pushing portion 1134 and the next front carrier 115, and make the action smoother.

In this embodiment, the first housing unit 2 includes a first transmission mechanism 21, a processing transmission mechanism 22, a gummed paper pasting mechanism 23, a housing mechanism 24, a welding mechanism 25, a riveting mechanism 26, and a first wire moving mechanism 27, the first transmission mechanism 21 is configured to clamp and transmit a connection wire, the processing transmission mechanism 22 is configured to load and transmit one end of the connection wire, the gummed paper pasting mechanism 23 is configured to paste gummed paper on one end of the connection wire, the housing mechanism 24 is configured to assemble an iron housing on one end of the connection wire after being pasted with gummed paper, the welding mechanism 25 is configured to weld the assembled iron housing, the riveting mechanism 26 is configured to rivet the welded iron housing, and the first wire moving mechanism 27 is configured to transfer the connection wire after being riveted to the second housing unit 3.

After the connecting wire enters the first housing unit 2, one end of the connecting wire enters the processing carrier 4 of the processing and conveying mechanism 22, namely, the first conveying mechanism 21 and the processing and conveying mechanism 22 simultaneously convey the connecting wire to move, so that one end of the connecting wire is firstly pasted with a layer of gummed paper for protecting the circuit part, and then the housing mechanism 24 mounts the iron housings on the circuit part at two sides, wherein the housing mechanism 24 is the prior art and is not described again; after the shell is installed, the iron shell can be welded by the welding mechanism 25, so that the iron shells on two sides are fixed and cannot be separated, and then the iron shell is riveted and molded by the riveting mechanism 26, and the iron shell assembling effect on the end of TYPE-C is realized. After the equipment is accomplished, the connecting wire is sent into second dress shell unit 3 and is carried out the iron-clad equipment that the USB connects, and second dress shell unit 3 of this embodiment can be prior art, and it mainly directly carries out the riveting behind the other end of connecting wire to the iron-clad cover fixed can, and it is no longer repeated here.

Specifically, the sticker attaching mechanism 23 includes a paper placing mechanism 241, a sticker attaching mechanism 242, a sticker positioning mechanism 243, a sticker turning mechanism 244 and a paper cutting mechanism 245, the paper placing mechanism 241 is used for placing out the sticker, the sticker positioning mechanism 243 is used for positioning the connecting line, the sticker attaching mechanism 242 is used for attaching the sticker to the connecting line, the sticker turning mechanism 244 is used for controlling the connecting line to rotate after the sticker is attached, so that the sticker wraps the connecting line, and the paper cutting mechanism 245 is used for cutting off the sticker after the sticker wraps the connecting line.

In practical use, the connecting wire is conveyed to the position of the utility model, the paper placing mechanism 241 discharges the adhesive paper, the paper pasting mechanism 242 pastes the discharged adhesive paper on the connecting wire after the adhesive paper positioning mechanism 243 lifts the connecting wire, and the adhesive paper overturning mechanism 244 drives the connecting wire to overturn, so that the adhesive paper can wrap the connecting wire, and the effect of automatically pasting the adhesive paper is achieved.

Preferably, the sticker overturning mechanism 244 comprises an overturning member 2441, an overturning driving assembly 2442 and an overturning translation assembly 2443, wherein the overturning member 2441 is provided with an overturning groove, the overturning driving assembly 2442 is used for driving the overturning member 2441 to rotate, and the overturning groove is used for driving the connecting line to overturn; the overturning and translating assembly 2443 comprises an overturning and translating cylinder, a translating seat and at least one overturning guide 111, the translating seat is slidably arranged on the guide 111, the overturning and translating cylinder is used for driving the translating seat to slide, and the overturning driving assembly 2442 and the overturning guide 2441 are both arranged on the translating seat.

In this embodiment, the paper placing mechanism includes a paper placing roller assembly 2411, a guide wheel 2412 and a paper positioning member 2413, the paper positioning member 2413 is provided with a paper feeding groove, the paper placing roller assembly 2411 is used for discharging adhesive paper to the guide wheel 2412, and the guide wheel 2412 is used for guiding the adhesive paper to be transferred to the paper sticking mechanism after passing through the paper feeding groove.

The paper feeding roller assembly 2411 is a conventional component, adhesive paper is fed in a rotating mode, the adhesive paper is guided to the paper feeding groove through the guide wheel 2412 for limiting, the adhesive paper is guided to the paper pasting mechanism through the paper feeding groove, and the adhesive paper is pressed on a connecting line through the paper pasting mechanism, so that the adhesive paper pasting effect is achieved. Through the setting in paper feed groove for the adhesive tape can have a passageway to lead to, has both protected the safety of adhesive tape, can avoid the adhesive tape to take place the self-adhesion again and lead to the unreliable circuit board of encircleing.

The paper placing mechanism 241 further comprises a flat paper assembly 2414, the flat paper assembly 2414 comprises a flat paper driving member 24141 and a flat paper member 24142, the flat paper member 24142 is provided with a plurality of paper pressing teeth 24143, the flat paper driving member 24141 is used for driving the flat paper member 24142 to approach or separate from the paper feeding groove, and the paper pressing teeth 24143 are used for extending into the paper feeding groove to abut against the adhesive paper. This paper driving piece 24141 is an electric cylinder or an air cylinder, and is used for driving the paper pressing teeth 24143 of the paper piece 24142 to be inserted into the paper feeding groove before the gummed paper is pasted, because the paper pressing teeth 24143 have a small contact area with the gummed paper, the paper pressing teeth 24143 are equivalent to flattening the gummed paper, so that the wrinkles on the surface of the gummed paper can be flattened, the gummed paper becomes smooth, and the pasting effect cannot be influenced by wrinkling on the surface of the gummed paper during the gummed paper pasting.

During the in-service use, in order to guarantee the accuracy of connecting wire gesture, processing carrier 4 include base member 41 and rotate set up in the holder 42 of base member 41, holder 42 is used for fixing a position the end of a thread of connecting wire, the bottom of base member 41 is provided with and is used for right positioning mechanism yields fretwork hole 43, and holder 42 is provided with control block 44, sticker tilting mechanism 244 is used for cliping control block 44 is in order to drive holder 42 rotates.

When the connecting wire is transmitted, the wire end at one end of the processing tool is inserted into the clamping piece 42 of the processing carrier 4 for fixing the posture, and then the connecting wire is transferred to the position right below the paper pasting mechanism 242, the paper pasting positioning mechanism 243 supports the connecting wire after passing through the hollow hole 43, and the paper pasting mechanism 242 acts to paste the adhesive paper on the connecting wire; then the sticker positioning mechanism 243 and the sticker mechanism 242 reset respectively, the overturning and translation assembly 2443 drives the overturning part 2441 to move forwards to the overturning groove to be sleeved on the control block 44, and the overturning driving assembly 2442 drives the overturning part 2441 to rotate for a circle, so that the connecting line is driven to rotate for a circle to enable the adhesive paper to wrap the connecting line, and the action of pasting the adhesive paper is realized.

Specifically, the overturning driving assembly 2442 consists of a motor and a belt transmission mechanism, and can accurately control the rotation amplitude of the connecting line; the overturning translation assembly 2443 includes conventional components such as an electric cylinder or an air cylinder, and controls the overturning member 2441 to be close to or far from the processing carrier 4, so as to achieve a control effect, and can be away from the processing carrier 4 after overturning, thereby avoiding interference on subsequent actions.

Specifically, the welding mechanism 25 includes a welding assembly, a welding turnover mechanism 252, a first welding clamping mechanism 253 and a second welding clamping mechanism 254, the first welding clamping mechanism is used for transferring the shielding case of the connecting wire to the welding assembly, the second welding clamping mechanism 254 is used for clamping and shaping the shielding case, the welding mechanism 25 is used for welding one end of the shielding case, and the welding turnover mechanism 252 is used for turning over the shielding case so that the welding mechanism 25 welds the other end of the shielding case.

In this embodiment, the welding and turning mechanism includes a welding and turning driving element 2521, a welding transmission element 2522, and a welding and turning element 2523, the welding and turning driving element 2521 drives the welding and turning element 2523 to rotate through the welding transmission element 2522, and the welding and turning element 2523 is used to turn the shielding housing. After the welding finishes, the shielding shell can be loosened to second welding fixture promptly, and welding upset 2523 drives the shielding shell and overturns to make the shielding shell other end towards welding mechanism, let welding mechanism can weld. The welding turner 2523 is turned over by driving a corresponding structure on the processing carrier 4.

Specifically, the riveting mechanism 26 includes a first riveting component 261 and a second riveting component 262, where the first riveting component 261 includes a first riveting driving element 263, a first riveting transmission element 264, and a first riveting element 265, the first riveting driving element 263 is used to drive the first riveting transmission element 264 to rotate, and the first riveting transmission element 264 is used to drive the first riveting element 265 to approach or leave the second riveting component 262 after being driven by the first riveting driving element 263; the second riveting component 262 is matched with the first riveting component 265 for riveting the iron shell. Compared with the traditional mode of directly adopting cylinders and the like to drive and rivet, the utility model adopts a rotating mode to realize driving, so that the requirement on space caused by formation reasons can be reduced, and the required space of the utility model is smaller.

In this embodiment, the first riveting driving component 263 includes a riveting motor 2631 and a riveting reducer 2632, and the riveting motor 2631 drives the first riveting driving component 264 to rotate via the riveting reducer 2632. That is, after the riveting motor 2631 is converted by the riveting speed reducer 2632, the output rotation speed thereof tends to be more stable, and the rotation of the first riveting transmission element 264 can be effectively controlled, so as to achieve the effect of controlling the first riveting element 265 to move back and forth.

Specifically, the first riveting transmission element 264 includes a rotation element 2641, a driven block 2642 and a guide groove 2643, the first riveting transmission element 263 is drivingly connected to the rotation element 2641, the rotation block is disposed on the rotation element 2641, the first riveting element 265 is disposed with a transmission groove 2651, and the driven block 2642 is movably disposed in the transmission groove 2651; the first riveting driving element 2633 is used to drive the rotating element 2641 to rotate and drive the driven block 2642 to make a circular motion in the transmission slot 2651, so that the first riveting element 265 moves back and forth in the guide slot 2643. That is, the riveting reducer 2632 drives the rotating member 2641 to rotate, so that the driven block 2642 disposed on the rotating member 2641 performs circumferential rotation therewith, because the driven block 2642 is movably disposed in the transmission slot 2651, and the first riveting member 265 is movable in the guide slot 2643 only to move back and forth, when the driven block 2642 rotates, it can be decomposed into horizontal and vertical movements, the vertical movement enables the driven block 2642 to move up and down in the transmission slot 2651, and the horizontal direction is reversed to drive the first riveting member 265 to move back and forth, thereby achieving an effect of being close to or far away from the second riveting member 262, and realizing the action of performing iron shell riveting with the second riveting member 262. According to the structure of the first riveting transmission element 264, the rotating action is skillfully converted into the linear action of the first riveting element 265, and due to the structural characteristics of the riveting motor 2631 and the riveting speed reducer 2632, the spatial distribution of all parts of the first riveting component 261 can be more flexible, so that the space utilization rate is improved.

Of course, the follower block 2642 is preferably cylindrical, so that when the follower block 2642 moves in the transmission slot 2651, the friction between the follower block 2642 and the transmission slot 2651 is reduced, thereby ensuring the transmission effect and prolonging the service life.

As another embodiment of this embodiment, the shape of the first riveting transmission element 264 can be circular or cam-shaped, and the same effect can be achieved.

Preferably, a first riveting groove 2652 is disposed on a side of the first riveting member 265 close to the second riveting mechanism, and the first riveting groove 2652 is used for clamping the iron shell and moving the iron shell toward the second riveting component 262. That is, when the first rivet element 265 contacts with the iron shell, the iron shell is accommodated in the first riveting groove 2652 and is pushed by the first rivet element 265 to move toward the second rivet element 269, thereby realizing the riveting effect.

In this embodiment, the second riveting component 262 includes a second riveting driving element 266, a second riveting driving element 267, a riveting seat 268 and a second riveting element 269, the second riveting element 269 is movably disposed on the riveting seat 268, and the second riveting driving element 266 drives the second riveting element 269 to approach or separate from the first riveting element 265 through the second riveting driving element 267. The second riveting driving element 266 is preferably a conventional linear driving mechanism 112 such as an electric cylinder or an air cylinder, and is used for driving the second riveting transmission element 267 to ascend and descend, and the second riveting element 269 is driven by the second riveting transmission element 267 to ascend and descend to move back and forth, so that the space utilization rate can be improved.

Specifically, the second riveting transmission member 267 is provided with an inclined groove 2671, the second riveting member 269 is provided with a driving hole 2691, and the riveting seat 268 is provided with a plug (not shown in the figure), wherein the plug is installed in the inclined groove 2671 and the driving hole 2691; the second riveting driving element 266 is used for driving the second riveting driving element 267 to move up and down so as to drive the second riveting element 269 to approach or move away from the first riveting element 265.

That is, the second riveting driving member 2677 is driven by the second riveting driving member 266 to move up and down only, and due to the existence of the inclined groove 2671, and the latch keeps the inclined groove 2671 and the driving hole 2691 communicated all the time, so that the second riveting member 269 moves in the horizontal direction along with the lifting of the second riveting driving member 267, and the second riveting member 269 does not move up and down in the vertical direction due to the limitation of the riveting seat 268, thereby enabling the second riveting member 269 to realize the effect of horizontal movement. According to the riveting device, the lifting drive is converted into the translation motion of the second riveting piece 269, so that the second riveting driving piece 266 and the second riveting piece 269 can be arranged in the same vertical plane, and the space utilization rate is improved.

Specifically, the rivet seat 268 is provided with a translation slot 2681 for allowing the plug pin to slide.

Preferably, the second riveting transmission member 267 is provided with a limiting groove 2672, and the second riveting member 269 is arranged on the riveting seat 268 in a liftable manner; the two sides of the limiting groove 2672 are respectively communicated with an inclined groove 2671, and the second riveting element 269 is movably disposed in the limiting groove 2672. The arrangement of the limiting groove 2672 enables the second riveting member 269 to move back and forth in the second riveting transmission member 267, so that the transmission effect of the second riveting transmission member 267 on the second riveting member 269 is ensured, and the unreliable transmission caused by dislocation between the second riveting member 269 and the second riveting member is avoided.

More preferably, the top and bottom of the inclined groove 2671 are respectively connected to a buffer groove 2673, and the buffer groove 2673 is used for accommodating a plug. Buffer slot 2673 is used for when second riveting driving member 267 moves to the highest or lowest position, spacing and guarantee that the bolt can not take place to remove the bolt to the effect of the tight lock to second riveting piece 269 has been realized.

Specifically, a second riveting groove 2692 is formed in one side, close to the first riveting part 265, of the second riveting part 269, the radian of the inner wall of the second riveting groove 2692 is matched with the radian of the iron shell, and the second riveting groove 2692 is used for abutting against the iron shell. That is, after the first riveting groove 2652 positions the iron case, the second riveting groove 2692 clamps the iron case, and the second riveting groove 2692 approaches or enters the first riveting groove 2652, so that the opened iron case can be riveted.

In this embodiment, the first riveting component 261 includes a first riveting limiting block 2610, and the second riveting component 262 includes a second riveting limiting block 2611, when the iron shell is riveted, the first riveting limiting block 2610 and the second riveting limiting block 2611 abut against each other to avoid over-riveting the iron shell, so that the safety of the present invention is ensured and the yield of the iron shell is ensured. Specifically, the first riveting limiting block 2610 can be provided with a positioning insertion block, the second riveting limiting block 2611 can be provided with a positioning insertion slot, positioning is achieved through the mode that the positioning insertion block is inserted into the positioning insertion slot, and therefore it is further ensured that the first riveting component 261 and the second riveting component 262 cannot be dislocated.

Specifically, a first wire taking unit 5 is arranged between the pretreatment unit 1 and the first shell loading unit 2, the first wire taking unit 5 is used for transferring one end of a connecting wire to the processing and conveying mechanism 22, a second wire taking unit 6 is arranged between the first shell loading unit 2 and the second shell loading unit 3, and the second wire taking unit 6 is used for transferring one end of the connecting wire from the processing and conveying mechanism 22 to the first conveying mechanism 21.

The first wire taking unit 5 is formed by matching a manipulator with pneumatic fingers and is used for grabbing one end of a connecting wire and putting the connecting wire into the processing carrier 4, so that two ends of the connecting wire are staggered on the same horizontal plane for synchronous transportation, and the other end of the connecting wire is not influenced during processing; after the processing is completed, the second wire taking unit 6 moves the one end to a position flush with the other end, and then when the connection wire is conveyed to the second housing unit 3, the second housing unit 3 has a corresponding structure to move the other end of the connection wire to be misaligned with the one end, thereby performing the processing.

After the two ends are respectively shelled, the connecting wire is processed and produced, and blanking can be carried out.

Although the present invention has been described with reference to the above preferred embodiments, it should be understood that various changes, substitutions and alterations can be made herein without departing from the spirit and scope of the utility model as defined by the appended claims.

Claims (10)

1. The utility model provides a connecting wire automatic production line which characterized in that: including pretreatment unit, first dress shell unit and second dress shell unit, pretreatment unit is used for carrying out soldering tin respectively to the both ends of connecting wire and handles, first dress shell unit is used for connecting the one end installation TYPE-C of connecting wire and connects, second dress shell unit is used for connecting the other end installation USB of connecting wire and connects.

2. The automatic production line of connecting wires according to claim 1, characterized in that: the pretreatment unit includes preceding transmission device, preceding soldering tin mechanism, preceding shell mechanism, spouts gluey mechanism and antedisplacement line mechanism of lifting, preceding transmission device is used for transmitting the preceding carrier that is equipped with the connecting wire, preceding soldering tin mechanism is used for carrying out soldering tin to the connecting wire both ends that the preceding carrier loaded, preceding shell mechanism of lifting is used for opening the preceding carrier, it is used for spouting gluey respectively to the both ends of connecting wire to spout gluey mechanism, antedisplacement line mechanism is used for picking up the connecting wire in the preceding carrier and transferring to first shell unit of loading.

3. The automatic production line of connecting lines as claimed in claim 2, characterized in that: the front conveying mechanism comprises a guide part, a driving mechanism and a transferring assembly, the guide part is used for guiding the front carrier, the transferring assembly comprises a transferring part and a plurality of transmission parts, the transmission parts are arranged on the transferring part at intervals, the driving mechanism is used for driving the transferring part to move back and forth, the transmission parts are used for pushing the front carrier to move along with the movement of the transferring part, and the driving mechanism drives the front carrier to move to the next front carrier to push the next front carrier to move after pushing the front carrier.

4. The automatic production line of connecting lines as claimed in claim 3, characterized in that: one end of the pushing part is rotatably connected with the transmission part, the other end of the pushing part is provided with a protruding part which is used for abutting against the front carrier, and a abdicating inclined plane is arranged between the protruding part and the pushing part; the pushing part resetting piece is connected between the other end of the pushing part and the transmission part.

5. The automatic production line of connecting wires according to claim 1, characterized in that: the first shell loading unit comprises a first transmission mechanism, a processing transmission mechanism, a gummed paper pasting mechanism, a shell loading mechanism, a welding mechanism, a riveting mechanism and a first line moving mechanism, the first transmission mechanism is used for clamping and transmitting a connecting line, the processing transmission mechanism is used for loading one end of the connecting line and transmitting the connecting line, the gummed paper pasting mechanism is used for pasting gummed paper on one end of the connecting line, the shell loading mechanism is used for assembling an iron shell on one end of the connecting line after pasting gummed paper, the welding mechanism is used for welding the assembled iron shell, the riveting mechanism is used for riveting the welded iron shell, and the first line moving mechanism is used for transferring the connecting line after riveting the iron shell to the second shell loading unit.

6. The automatic production line of connecting wires according to claim 5, characterized in that: the adhesive paper sticking mechanism comprises a paper placing mechanism, an adhesive paper sticking mechanism, a sticker positioning mechanism, a sticker overturning mechanism and a paper cutting mechanism, the paper placing mechanism is used for discharging adhesive paper, the sticker positioning mechanism is used for positioning the connecting wire, the sticker mechanism is used for sticking the adhesive paper to the connecting wire, the sticker overturning mechanism is used for controlling the connecting wire to rotate after the sticker is stuck so that the sticker wraps the connecting wire, and the paper cutting mechanism is used for cutting off the sticker after the sticker wraps the connecting wire.

7. The automatic production line of connecting wires according to claim 6, characterized in that: the sticker turnover mechanism comprises a turnover part, a turnover driving component and a turnover translation component, wherein the turnover part is provided with a turnover groove, the turnover driving component is used for driving the turnover part to rotate, and the turnover groove is used for driving a connecting wire to turn over; the overturning and translating assembly comprises an overturning and translating cylinder, a translating seat and at least one overturning guide piece, the translating seat is arranged on the guide piece in a sliding mode, the overturning and translating cylinder is used for driving the translating seat to slide, and the overturning and driving assembly and the overturning guide piece are both arranged on the translating seat.

8. The automatic production line of connecting wires according to claim 5, characterized in that: welding mechanism includes welding subassembly, welding tilting mechanism, first welding fixture and second welding fixture, first welding fixture is used for transferring the shielding shell of connecting wire extremely welding subassembly, second welding fixture is used for cliping the shielding shell and stereotypes, welding mechanism is used for welding the one end of shielding shell, welding tilting mechanism is used for the upset shielding shell so that welding mechanism welds the other end of shielding shell.

9. The automatic production line of connecting wires according to claim 5, characterized in that: the riveting mechanism comprises a first riveting component and a second riveting component, the first riveting component comprises a first riveting driving piece, a first riveting transmission piece and a first riveting piece, the first riveting driving piece is used for driving the first riveting transmission piece to rotate, and the first riveting transmission piece is used for driving the first riveting piece to be close to or far away from the second riveting component after being driven by the first riveting driving piece; the second riveting component is matched with the first riveting component to be used for riveting the iron shell.

10. The automatic production line of connecting wires according to claim 5, characterized in that: the pretreatment unit with be provided with first line unit of getting between the first dress shell unit, first line unit of getting is used for transferring the one end of connecting wire extremely processing transmission device, first dress shell unit with be provided with second line unit of getting between the second dress shell unit, second line unit of getting is used for transferring the one end of connecting wire extremely processing transmission device.

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