CN114147355B - Data line Type-C connects equipment welding production line - Google Patents

Abstract

The application relates to a data line Type-C connects equipment welding production line relates to the field of data line production facility, and it includes the workstation, be equipped with welding wire feeding mechanism, joint conveying subassembly, joint transfer unit and welding set on the workstation, the last welding zone that is equipped with of welding set, welding wire feeding mechanism is used for conveying the head of data line to the welding zone, joint conveying subassembly is used for conveying and connects the iron shell, joint transfer unit is used for adorning the iron shell of joint on the data line, welding set is used for welding the iron shell of joint. This application has the precision that increases the installation of interface iron shell, promotes production efficiency simultaneously to reduce the effect of human cost.

Description

Data line Type-C connects equipment welding production line

Technical Field

The application relates to the field of data line production equipment, in particular to a data line Type-C joint assembly welding production line.

Background

The data line connector is used as one of the essential basic elements for data transmission, is widely applied to the technical fields of aviation, aerospace, military equipment, automobiles, communication, computers, household appliances and the like, becomes one of the pillar industries of electronic information basic products, and gradually tends to be miniaturized along with the continuous development and innovation of electronic technology, in particular to portable electronic products.

In the related art, an interface iron shell of a data line of a Type-C connector is generally formed by splicing two semicircular iron shells, and then welding is performed at the splicing position, so that the interface iron shell is installed on the data line. When the data line connector is installed, the iron shell of the data line connector is required to be installed on the data line manually and then welded, but the manual operation efficiency is low, and the precision is difficult to guarantee.

Disclosure of Invention

In order to improve the above problems, the present application provides a data line Type-C joint assembly welding line.

The application provides a data line Type-C connects equipment welding production line adopts following technical scheme:

the utility model provides a data line Type-C connects equipment welding production line, includes the workstation, be equipped with welding send line mechanism, joint transfer unit and welding set on the workstation, the last welding district that is equipped with of welding set, welding send line mechanism is used for conveying the head of data line to the welding district, joint transfer unit is used for conveying and connects the iron shell, joint transfer unit is used for adorning the iron shell of joint on the data line, welding set is used for welding the iron shell of joint.

Through above-mentioned technical scheme, the welding send line mechanism to the welding district with the head of data line, connects the interface iron shell of conveying subassembly transmission simultaneously, connects the interface iron shell that the subassembly will be transmitted by the joint conveying subassembly and adorn on the head of data line, and welding set welds the interface afterwards. The whole process is realized mechanically, so that the installation precision of the interface iron shell is improved, the production efficiency is improved, and the labor cost is reduced.

Optionally, connect the transfer unit and include rotary drive spare, first flexible drive spare and holder, rotary drive spare is located on the workstation, rotary drive spare's output is connected with first flexible drive spare, first flexible drive spare's output is connected with the holder, be equipped with the standing groove that is used for placing the joint iron shell on the holder, be equipped with the negative pressure mouth in the standing groove.

Through above-mentioned technical scheme, when installing the interface iron shell, the output of first flexible driving piece stretches out for the standing groove overlaps on the joint iron shell, then the negative pressure mouth produces and adsorbs the post interface iron shell, and then the output of first flexible driving piece withdraws. Then the output end of the rotary driving piece rotates, so that the output end of the first telescopic driving piece faces the head of the data line, and then the output end of the first telescopic driving piece extends out, so that the interface iron shell is arranged on the head of the data line. The first telescopic driving assembly is matched with the negative pressure port, the interface iron shell can be driven to move without the clamping assembly, deformation of the interface iron shell is not easy to cause, and the possibility of damage to the interface iron shell is reduced. The first telescopic driving piece and the rotary driving piece are matched with each other to realize the transfer of the interface iron shell, and the transfer track is simple and stable.

Optionally, connect the conveying subassembly and include unreel dish, transfer rail and conveying piece, unreel the dish and locate on the workstation, unreel the dish and be used for rolling interface iron shell, transfer rail is used for supplying the interface iron shell to pass, conveying piece is used for driving the interface iron shell and removes in transfer rail.

Through above-mentioned technical scheme, unreel the reel and unreel interface iron shell, the conveying piece provides power, and the transfer track then is convenient for interface iron shell conveying, and then realizes the order conveying and the transfer of interface iron shell, promotes production efficiency.

Optionally, the welding send line mechanism includes pencil conveyer, pencil conveyer includes first slide rail, pencil seat and first removal subassembly, first slide rail is located on the workstation, pencil seat and first slide rail sliding connection, the pencil seat is used for placing the pencil, first removal subassembly is used for driving the pencil seat and slides.

Through above-mentioned technical scheme, the line beam seat slides with first slide rail, drives through first removal subassembly simultaneously, is convenient for realize the stable conveying of data line.

Optionally, first removal subassembly includes flexible driving piece of second, slip board and first impeller, on the workstation was located to flexible driving piece of second, the output and the slip board fixed connection of flexible driving piece of second, the slip board is articulated with first impeller, first impeller is equipped with a plurality ofly along the length direction of slip board, be equipped with first baffle on the slip board, when first impeller perpendicular to slip board, the lateral wall butt of first baffle and first impeller is equipped with first elastic component on the slip board, first elastic component is used for exerting towards first baffle pivoted thrust for pushing away first baffle, the top surface of first impeller is higher than the bottom surface of pencil seat.

Through above-mentioned technical scheme, the flexible driving piece of second is convenient for drive and slides board reciprocating motion, and when the pencil seat was kept away from one side of first baffle, first thrust plate can promote the pencil seat and remove, realizes the conveying of data line. When the first pushing plate moves reversely, the first pushing plate is abutted with the wire harness seat, so that the first pushing plate overcomes the elasticity of the first elastic piece and then rotates towards one end far away from the first baffle plate, the whole height of the first pushing plate is lower than the bottom surface of the wire harness seat, and at the moment, the first pushing plate passes through the lower part of the wire harness seat and cannot push the wire harness seat. Thus, the first pushing plate can push the plurality of wire harness seats to move step by step at the same time, and the wire harness seats cannot be reversed.

Optionally, the wire bundle seat is provided with a wire bundle groove for placing the data wire, the wire bundle seat is provided with a support plate, and the support plate is provided with a wire bundle hole for inserting the head of the data wire.

Through above-mentioned technical scheme, pencil groove and pencil hole cooperation are in order to carry out spacingly to the data line, reduce the data line and take place the possibility that rocks when removing and welding, promote welding quality.

Optionally, be equipped with the second slide rail on the workstation, the second slide rail is located the below of first slide rail, the length direction of second slide rail is the same with the length direction of first slide rail, be equipped with circulation subassembly between first slide rail and the second slide rail, circulation subassembly is used for shifting the pencil seat between first slide rail and second slide rail, still be equipped with the second on the workstation and remove the subassembly, the second removes the subassembly and is used for driving the pencil seat on the second slide rail and remove.

Through above-mentioned technical scheme, the pencil seat removes on first slide rail, finishes the back with the data line transmission, on transferring the pencil seat to the second slide rail through circulating assembly, after sliding on the second slide rail, rethread circulating assembly gets back to first slide rail, walks out a rectangular removal orbit, is convenient for last conveys the data line.

Optionally, the circulation subassembly includes two flexible driving pieces of third, the flexible driving piece of third locates the both ends of first slide rail relatively along the self length direction of first slide rail, the output of flexible driving piece of third is equipped with the third slide rail, the output of flexible driving piece of third moves along vertical direction, the workstation still is equipped with flexible driving piece of fourth and flexible driving piece of fifth, flexible driving piece of fourth and flexible driving piece of fifth locates the both ends of first slide rail relatively along the length direction of first slide rail, flexible driving piece of fourth is close with the height of first slide rail, flexible driving piece of fifth is close with the height of second slide rail, flexible driving piece of fourth and flexible driving piece of fifth reciprocate along the length direction of first slide rail.

Through the technical scheme, the first moving assembly transfers the wire harness seat onto the third sliding rail, then the corresponding third telescopic driving piece drives the third sliding rail to move downwards, so that the third sliding rail is equal to the second sliding rail in height, then the output end of the fourth telescopic driving piece stretches out, the wire harness seat is pushed to move onto the second sliding rail, then the second moving assembly drives the wire harness seat to move onto the third sliding rail positioned at the other end of the first sliding rail, then the corresponding third telescopic driving piece drives the third sliding rail to move upwards, so that the third sliding rail is equal to the first sliding rail, then the output end of the fifth telescopic driving piece stretches out, the wire harness seat is pushed onto the first sliding rail, then the first moving assembly drives the wire harness seat to slide again, circulation conveying of the wire harness seat is achieved, and continuous conveying of data wires is facilitated.

Optionally, the welding wire feeding mechanism further comprises a wire feeding device, the wire feeding device comprises a sixth telescopic driving piece and a fourth sliding rail, the sixth telescopic driving piece is arranged on the workbench, the output end of the sixth telescopic driving piece is connected with the fourth sliding rail, a conveying groove for the fourth sliding rail to pass through is formed in the first sliding rail, and when the output end of the sixth telescopic driving piece stretches out, the fourth sliding rail is located in the welding area.

Through the technical scheme, after the wire harness seat is sent to the fourth sliding rail by the first moving assembly, the sixth telescopic driving piece pushes the fourth sliding rail to move, so that the fourth sliding rail is located in the welding area, and the interface iron shell is conveniently mounted on the head of the data wire.

In summary, the present application includes at least one of the following beneficial technical effects:

through the arrangement of the welding wire feeding mechanism, the joint conveying assembly, the joint transferring assembly and the welding device, the installation precision of the interface iron shell is increased, the production efficiency is improved, and the labor cost is reduced;

through the setting of first removal subassembly, second removal subassembly, first slide rail, second slide rail and circulation subassembly, realize the circulation motion of line beam seat on first slide rail and second slide rail, and then continue to convey the data line, promote production efficiency.

Drawings

Fig. 1 is a schematic structural diagram of the whole embodiment of the present application.

Fig. 2 is a partial enlarged view of the portion a in fig. 1.

Fig. 3 is a schematic structural view showing a wire harness transfer device in the embodiment of the present application.

Fig. 4 is a schematic structural view of a wire harness seat according to an embodiment of the present application.

Fig. 5 is a schematic structural diagram of a first mobile component according to an embodiment of the present application.

Fig. 6 is a schematic structural diagram of a second mobile component according to an embodiment of the present application.

Fig. 7 is a partial enlarged view of the portion B in fig. 3.

Fig. 8 is a schematic structural view of a male housing and a transfer sheet embodied in an embodiment of the present application.

Fig. 9 is a schematic structural view of a parent case according to an embodiment of the present application.

Fig. 10 is a schematic view of a construction embodying a joint transfer assembly and a joint transfer assembly in an embodiment of the present application.

Fig. 11 is a schematic diagram showing the structure of a transfer block and a transfer wheel in the embodiment of the present application.

Fig. 12 is a schematic structural view of a receiving block, a cutting blade, and an adapter in an embodiment of the present application.

Reference numerals illustrate: 1. a work table; 2. welding wire feeding mechanism; 21. a harness transfer assembly; 211. a work plate; 212. a first motor; 213. a first screw; 214. a first threaded block; 215. a thread groove; 216. a first telescopic cylinder; 217. a first clamping cylinder; 22. a harness transmission device; 221. a first slide rail; 2211. a conveying trough; 222. a wire bundle seat; 2221. a wire bundle groove; 2222. a support plate; 2223. a wire bundle hole; 223. a first moving assembly; 2231. a second telescopic driving member; 2232. a slip plate; 2233. a first push plate; 2234. a first baffle; 2235. a first elastic member; 2236. a first inclined surface; 224. a second slide rail; 225. a circulation assembly; 2251. a third telescopic driving member; 2252. a fourth telescopic driving member; 2253. a fifth telescopic driving member; 2254. a third slide rail; 2255. a push plate; 226. a second moving assembly; 2261. a second pushing plate; 2262. a second baffle; 2263. a second elastic member; 2264. a second inclined surface; 23. a wire feeding device; 231. a sixth telescopic driving member; 232. a fourth slide rail; 3. a joint transfer assembly; 31. placing a reel; 32. a transfer rail; 33. a transfer member; 331. a transfer block; 332. a transfer wheel; 4. a joint transfer assembly; 41. a rotary driving member; 42. a first telescopic driving member; 43. a clamping member; 431. a placement groove; 44. a transfer table; 441. a receiving block; 442. a cutting knife; 5. a welding device; 51. a welding area; 6. a transfer sheet; 61. a male shell; 62. a parent shell.

Detailed Description

The present application is described in further detail below in conjunction with figures 1-12.

Examples:

the application discloses data line Type-C connects equipment welding production line. Referring to fig. 1, a data line Type-C joint assembling and welding line includes a workbench 1, a welding wire feeding mechanism 2, a joint conveying assembly 3, a joint transferring assembly 4 and a welding device 5 are arranged on the workbench 1, and a welding area 51 is arranged on the welding device 5. In operation, the welding wire feeding mechanism 2 sends the head of the data wire to the welding area 51, the joint transmission assembly 3 transmits the interface iron shell, the joint transfer assembly 4 loads the interface iron shell transmitted by the joint transmission assembly 3 onto the head of the data wire, and then the welding device 5 welds the interface.

Referring to fig. 1 and 2, the welding wire feeding mechanism 2 includes a wire harness transferring assembly 21, the wire harness transferring assembly 21 includes a working plate 211 and a first motor 212, the working plate 211 is fixed on the working table 1, the first motor 212 is fixed on the working plate 211, a first screw 213 is coaxially fixed on an output shaft of the first motor 212, a first screw block 214 is connected to the first screw 213 in a threaded manner, a screw groove 215 is formed in the working plate 211 along a length direction of the working plate, and the first screw block 214 slides in the screw groove 215. A first telescopic cylinder 216 is fixed on the first threaded block 214, and a first clamping cylinder 217 is fixed on the first telescopic cylinder 216. The first clamping cylinder 217 is provided with two clamping cylinders for clamping the middle and head portions of the data line.

Referring to fig. 3 and 4, the welding wire feeding mechanism 2 includes a wire harness transfer device 22, the wire harness transfer device 22 including a first slide rail 221, a wire harness seat 222, and a first moving assembly 223, the first slide rail 221 being disposed along a length direction of the table 1 and being fixed to the table 1. The wire bundle seat 222 slides on the first sliding rail 221, a wire bundle groove 2221 for placing the data wire is formed in the top surface of the wire bundle seat 222, a supporting plate 2222 is fixedly connected to the wire bundle seat 222, and a wire bundle hole 2223 for inserting the head of the data wire is formed in the supporting plate 2222.

Referring to fig. 2 and 3, in operation, the first clamping cylinder 217 is located above a data line to be transferred, then the first telescopic cylinder 216 drives the first clamping cylinder 217 to move towards the data line, then the first clamping cylinder 217 clamps the data line, then the piston rod of the first telescopic cylinder 216 is reset, the first motor 212 is started to drive the first screw 213 to rotate, the first screw 213 drives the screw block to move towards the first sliding rail 221, after the data line moves above the wire harness seat 222, the piston rod of the first telescopic cylinder 216 extends out, so that the data line is inserted into the wire harness groove 2221, then the first motor 212 is started again to drive the head of the data line to be inserted into the wire harness hole 2223, and the section of the wire harness hole 2223 is rectangular, so that the possibility of deflection of the head of the data line can be reduced.

Referring to fig. 3 and 5, the first moving assembly 223 includes a second telescopic driving member 2231, a sliding plate 2232 and a first pushing plate 2233, the second telescopic driving member 2231 is fixedly connected to the workbench 1, an output end of the second telescopic driving member 2231 is fixedly connected to the sliding plate 2232, and the second telescopic driving member 2231 and the sliding plate 2232 are all disposed along a length direction of the first sliding rail 221. The first pushing plates 2233 are hinged to the top surface of the sliding plate 2232, a plurality of first pushing plates 2233 are arranged along the length direction of the sliding plate 2232, first baffles 2234 are fixed on the sliding plate 2232, the number of the first baffles 2234 is the same as that of the first pushing plates 2233, and each first baffle 2234 corresponds to one first pushing plate 2233. When the first push plate 2233 is perpendicular to the slip plate 2232, the first stopper 2234 abuts against a sidewall of the first push plate 2233. A first elastic member 2235 is connected between the sliding plate 2232 and the first pushing plate 2233, and the first elastic member 2235 is configured to apply a pushing force to push the first stopper 2234 to rotate toward the first stopper 2234, and the first elastic member 2235 may be a torsion spring. The top surface of the first push plate 2233 is higher than the bottom surface of the wire harness seat 222.

When the wire harness seat 222 needs to be moved, the output end of the second telescopic driving member 2231 extends to drive the sliding plate 2232 to move, and drive the first pushing plate 2233 to move, and the first pushing plate 2233 pushes the wire harness seat 222 to move, at this time, the first baffle 2234 is located at an end of the first pushing plate 2233 away from the wire harness seat 222, so as to support the first pushing plate 2233. When the wire bundle seat 222 is sent in place, the output end of the second telescopic driving member 2231 is retracted to drive the sliding plate 2232 to move reversely, at this time, a new wire bundle seat 222 is provided at the original position of the wire bundle seat 222 pushed by the first pushing plate 2233, and one end of the wire bundle seat 222 close to the first baffle 2234 is abutted against the new wire bundle seat 222, and the new wire bundle seat 222 overcomes the elasticity of the first elastic member 2235 to push down the first pushing plate 2233, so that the first pushing plate 2233 can pass through the lower part of the new wire bundle seat 222. The output end of the second telescopic driving piece 2231 is then extended again, so as to push the new wire harness seat 222 to move on the first sliding rail 221.

Referring to fig. 5, an end of the first push plate 2233 away from the sliding plate 2232 is provided with a first inclined surface 2236, the first inclined surface 2236 is disposed near the first baffle 2234, and when the first push plate 2233 moves reversely and abuts against the wire harness seat 222, the first inclined surface 2236 is convenient for the first push plate 2233 to be pressed down, so that the first push plate 2233 can conveniently pass through from below the wire harness seat 222.

Referring to fig. 3, a second sliding rail 224 is fixedly connected to the workbench 1, the second sliding rail 224 is located below the first sliding rail 221, and the length direction of the second sliding rail 224 is the same as the length direction of the first sliding rail 221, and the lengths of the second sliding rail 224 and the first sliding rail 221 are equal. The table 1 is further provided with a circulation assembly 225, and the circulation assembly 225 includes a third telescopic driving member 2251, a third slide rail 2254, a fourth telescopic driving member 2252, and a fifth telescopic driving member 2253. Two third telescopic driving pieces 2251 and two third sliding rails 2254 are provided, and each third sliding rail 2254 is fixedly connected with the output end of one third telescopic driving piece 2251. Two third telescopic driving pieces 2251 are located at both ends of the first rail 221 in the length direction thereof, and the third telescopic driving pieces 2251 are fixed to the table 1. When the output end of the third telescopic driving piece 2251 is in an extended state, the top surface of the third sliding rail 2254 is equal to the top surface of the first sliding rail 221; when the output end of the third telescopic driving piece 2251 is in the retracted state, the third sliding rail 2254 is at the same height as the top surface of the second sliding rail 224.

The fourth telescopic driving piece 2252 and the fifth telescopic driving piece 2253 are disposed at two ends of the first sliding rail 221 along the length direction of the first sliding rail 221, and the output end of the fourth telescopic driving piece 2252 and the output end of the fifth telescopic driving piece 2253 are disposed opposite. The fourth telescopic drive 2252 and the fifth telescopic drive 2253 are both fixed to the table 1, and the output ends of both are fixed with the push plate 2255. The bottom surface of the push plate 2255 on the fourth telescoping drive 2252 is level with the top surface of the first rail 221 and the bottom surface of the push plate 2255 on the fifth telescoping drive 2253 is level with the top surface of the second rail 224. The workbench 1 is further provided with a second moving assembly 226 for driving the wire harness base 222 to move on the second sliding rail 224.

The wire harness seat 222 moves on the first sliding rail 221, and finally is pushed onto the third sliding rail 2254 by the first pushing plate 2233, then the piston rod of the corresponding third telescopic driving member 2251 is retracted, the third sliding rail 2254 is driven to move to be equal to the height of the second sliding rail 224, at this time, the output end of the fifth telescopic driving member 2253 extends, the pushing plate 2255 is driven to move, the pushing plate 2255 pushes the wire harness seat 222 to move onto the second sliding rail 224, the second moving assembly 226 drives the wire harness seat 222 to move on the second sliding rail 224 until the wire harness seat 222 is pushed onto the third sliding rail 2254 located at one end, far from the fifth telescopic driving member 2253, of the second sliding rail 224, then the corresponding third telescopic driving member 2251 drives the third sliding rail 2254 to rise to be equal to the height of the first sliding rail 221, and at this time, the output end of the fourth telescopic driving member 2252 pushes the wire harness seat 222 to move onto the first sliding rail 221. Thus reciprocating, a cyclic motion of the wire bundle seat 222 is achieved.

Referring to fig. 6, the second moving assembly 226 includes a second push plate 2261, a second barrier 2262, and a second elastic member 2263, the second push plate 2261 being abutted against the bottom surface of the slip plate 2232, the second barrier 2262 being also fixed to the bottom surface of the slip plate 2232. The number of the second push plates 2261 and the second barrier plates 2262 are equal to the number of the first push plates 2233, and each of the second barrier plates 2262 corresponds to one of the second push plates 2261. When the second push plate 2261 is perpendicular to the slip plate 2232, the side wall of the second push plate 2261 abuts against the side wall of the barrier, and the second barrier 2262 is located at an end of the second push plate 2261 remote from the fifth telescopic drive 2253. The second elastic member 2263 is installed between the second push plate 2261 and the slip plate 2232, for applying a pushing force to the second push plate 2261 to rotate the second push plate 2261 toward the second barrier 2262. The second pushing plate 2261 is provided with a second inclined surface 2264 at an end thereof remote from the slip plate 2232, and the second inclined surface 2264 is disposed adjacent to the second barrier 2262. The bottom surface of the second push plate 2261 is lower than the top surface of the wire harness seat 222 on the second slide rail 224, so that the second push plate 2261 can be contacted with the wire harness seat 222.

When the wire bundle seat 222 is pushed onto the second sliding rail 224 by the fifth telescopic driving piece 2253, the wire bundle seat 222 abuts against the second inclined surface 2264 on one second pushing plate 2261, and overcomes the elastic force of the second elastic piece 2263 to rotate the second pushing plate 2261, so that the wire bundle seat 222 is convenient to pass over the second pushing plate 2261. Then, when the output end of the second telescopic driving member 2231 is retracted, the sliding plate 2232 is driven to move toward the fourth telescopic driving member 2252, and at this time, the second pushing plate 2261 moves along with the sliding plate 2232 and pushes the beam seat 222 on the second sliding rail 224 to move toward the fourth telescopic driving member 2252. When the first pushing plate 2233 pushes the wire harness seat 222 on the first sliding rail 221 to move, the second pushing plate 2261 also pushes the wire harness seat 222 on the second sliding rail 224 to move, so that the circulating movement of the wire harness seat 222 is realized at a lower cost.

Referring to fig. 7, the welding wire feeding mechanism 2 further includes a wire feeding device 23, the wire feeding device 23 includes a sixth telescopic driving member 231 and a fourth sliding rail 232, the sixth telescopic driving member 231 is fixed on the workbench 1, an output end of the sixth telescopic driving member 231 is fixedly connected with the fourth sliding rail 232, and a conveying groove 2211 for the fourth sliding rail 232 to pass through is formed in the first sliding rail 221. The output end of the sixth telescopic driving piece 231 is disposed towards the welding area 51, so as to drive the fourth sliding rail 232 to reciprocate between the conveying groove 2211 and the welding area 51.

Referring to fig. 8 and 9, the connector iron case includes a male case 61 and a female case 62, a plurality of male cases 61 are fixed to one transfer sheet 6, a plurality of female cases 62 are fixed to another transfer sheet 6, and the transfer sheet 6 facilitates conveyance of the male cases 61 and the female cases 62.

Referring to fig. 10 and 11, the joint transfer assembly 3 includes a reel 31, a transfer rail 32, and a transfer member 33, and the reel 31, the transfer rail 32, and the transfer member 33 are provided with two sets. The two unreels 31 are both rotatably connected with the workbench 1, the unreels 31 are used for rolling the conveying sheet 6, so that the male shell 61 and the female shell 62 can be rolled conveniently, the male shell 61 is rolled on one unreel 31, and the female shell 62 is rolled on the other unreel 31. Both transfer rails 32 are fixed to the table 1, and the transfer rails 32 are used for passing through the transfer sheet 6 and guiding the transfer sheet 6. The conveying member 33 is used for driving the conveying sheet 6 to move. The conveying member 33 comprises a conveying block 331 and two conveying wheels 332, the conveying block 331 is fixed on the workbench 1, the two conveying wheels 332 are rotatably connected with the conveying block 331, one conveying wheel 332 is driven by a motor, the conveying sheet 6 passes through the space between the two conveying wheels 332, and the conveying wheels 332 drive the conveying sheet 6 to move through friction force.

Referring to fig. 12, the joint transfer assembly 4 is provided with two sets, one set of joint transfer assemblies 4 for transferring the male housing 61 and the other set for transferring the female housing 62. The joint transfer assembly 4 comprises a rotary driving piece 41, a first telescopic driving piece 42 and a clamping piece 43, wherein the rotary driving piece 41 is fixed on the workbench 1, the output end of the rotary driving piece 41 is fixedly connected with the first telescopic driving piece 42, and the output end of the first telescopic driving piece 42 is fixedly connected with the clamping piece 43. The holding member 43 is provided with a placement groove 431 for placing the male shell 61 or the female shell 62, and a negative pressure port is provided in the placement groove 431. The workbench 1 is fixedly connected with a switching table 44, the switching table 44 is fixedly provided with a bearing block 441, and the bearing block 441 is provided with two blocks, one block is used for placing the male shell 61 and the other block is used for placing the female shell 62. Two cutters 442 are also fixed on the transfer table 44, the two cutters 442 correspond to the two receiving blocks 441, and the cutters 442 are used for matching the clamping piece 43 to cut the male shell 61 or the female shell 62 from the conveying sheet 6.

In operation, the driving wheel transfers the driving piece to the upper side of the transfer table 44, and the male shell 61 and the female shell 62 are positioned on the corresponding receiving blocks 441, then the output end of the first telescopic driving piece 42 is extended, the male shell 61 or the female shell 62 is clamped between the receiving blocks 441 and the clamping piece 43, and the connection between the male shell 61 or the female shell 62 and the transferring piece 6 is also cut off. At this time, the male housing 61 or the female housing 62 is sucked by the negative pressure generated from the negative pressure port, and then stays in the placement groove 431. Then, the piston rod of the first telescopic driving piece 42 rotates the driving piece 41 to drive the first telescopic driving piece 42 to rotate, so that the openings of the male shell 61 and the female shell 62 are oppositely arranged, and at the moment, the sixth telescopic driving piece 231 drives the fourth sliding rail 232 to move to the welding area 51, so that the head of the data wire is located between the male shell 61 and the female shell 62. The output end of the first telescopic driving piece 42 is then extended so that the male housing 61 and the female housing 62 are spliced with each other and together sleeve the head of the data line, and then the welding device 5 performs welding so that the male housing 61 and the female housing 62 are welded together.

Referring to fig. 10, the welding device 5 is provided with two welding apparatuses, one above the welding area 51 and one below the welding area 51, for welding two splices of the male shell 61 and the female shell 62. The welding device 5 may employ a laser welding machine.

The first telescopic driving member 42, the second telescopic driving member 2231, the third telescopic driving member 2251, the fourth telescopic driving member 2252, the fifth telescopic driving member 2253 and the sixth telescopic driving member 231 each employ telescopic cylinders, and the rotary driving member 41 may employ a motor.

The implementation principle of the data line Type-C joint assembly welding production line is as follows: when the wire harness seat 222 is in operation, the first clamping cylinder 217 is located above a data wire to be transferred, then the first telescopic cylinder 216 drives the first clamping cylinder 217 to move towards the data wire, then the first clamping cylinder 217 clamps the data wire, then a piston rod of the first telescopic cylinder 216 is reset, the first motor 212 is started to drive the first screw 213 to rotate, the first screw 213 drives the screw block to move towards the first sliding rail 221, after the data wire moves to the position above the wire harness seat 222, the piston rod of the first telescopic cylinder 216 stretches out, the data wire is inserted into the wire harness groove 2221, and then the first motor 212 is started again to drive the head of the data wire to be inserted into the wire harness hole 2223.

Then, the output end of the second telescopic driving member 2231 extends to drive the sliding plate 2232 to move, and drive the first pushing plate 2233 to move, and the first pushing plate 2233 pushes the wire harness seat 222 to move, so that the wire harness seat 222 moves onto the fourth sliding rail 232, and at this time, the sixth telescopic driving member 231 drives the fourth sliding rail 232 to move onto the welding area 51.

At the same time, the driving wheel transfers the driving piece to the upper side of the transfer table 44, and the male shell 61 and the female shell 62 are positioned on the corresponding receiving blocks 441, then the output end of the first telescopic driving piece 42 is extended, the male shell 61 or the female shell 62 is clamped between the receiving blocks 441 and the clamping piece 43, and the connection between the male shell 61 or the female shell 62 and the transferring piece 6 is also cut off. At this time, the male housing 61 or the female housing 62 is sucked by the negative pressure generated from the negative pressure port, and then stays in the placement groove 431. Then, the piston rod of the first telescopic driving piece 42 will rotate the driving piece 41 to drive the first telescopic driving piece 42 to rotate, so that the openings of the male shell 61 and the female shell 62 are oppositely arranged, and the male shell 61 and the female shell 62 are positioned at two ends of the head of the data line. The output end of the first telescopic driving piece 42 is then extended so that the male housing 61 and the female housing 62 are spliced with each other and together sleeve the head of the data line, and then the welding device 5 performs welding so that the male housing 61 and the female housing 62 are welded together.

The foregoing are all preferred embodiments of the present application, and are not intended to limit the scope of the present application in any way, therefore: all equivalent changes in structure, shape and principle of this application should be covered in the protection scope of this application.

Claims (7)

1. Data line Type-C connects equipment welding production line, its characterized in that: the welding wire feeding device comprises a workbench (1), wherein a welding wire feeding mechanism (2), a joint conveying assembly (3), a joint transferring assembly (4) and a welding device (5) are arranged on the workbench (1), a welding area (51) is arranged on the welding device (5), the welding wire feeding mechanism (2) is used for conveying the head of a data wire to the welding area (51), the joint conveying assembly (3) is used for conveying a joint iron shell, the joint transferring assembly (4) is used for installing the joint iron shell on the data wire, and the welding device (5) is used for welding the joint iron shell;

the welding wire feeding mechanism (2) comprises a wire harness conveying device (22), the wire harness conveying device (22) comprises a first sliding rail (221), a wire harness seat (222) and a first moving assembly (223), the first sliding rail (221) is arranged on the workbench (1), the wire harness seat (222) is in sliding connection with the first sliding rail (221), the wire harness seat (222) is used for placing a wire harness, and the first moving assembly (223) is used for driving the wire harness seat (222) to slide;

the first moving assembly (223) comprises a second telescopic driving piece (2231), a sliding plate (2232) and a first pushing plate (2233), the second telescopic driving piece (2231) is arranged on the workbench (1), the output end of the second telescopic driving piece (2231) is fixedly connected with the sliding plate (2232), the sliding plate (2232) is hinged with the first pushing plate (2233), the first pushing plate (2233) is provided with a plurality of sliding plates (2232) along the length direction of the sliding plate (2232), the sliding plate (2232) is provided with a first baffle plate (2234), when the first pushing plate (2233) is perpendicular to the sliding plate (2232), the first baffle plate (2234) is abutted against the side wall of the first pushing plate (2233), a first elastic piece (2235) is arranged on the sliding plate (2232), and the first elastic piece (2235) is used for applying the first baffle plate (2234) to push the first pushing plate (2234) to rotate towards the first baffle plate (2232), and the first baffle plate (2233) is higher than the top surface (2233) of the wire harness seat (222).

2. The data line Type-C joint assembly welding line of claim 1, wherein: the connector transferring assembly (4) comprises a rotary driving piece (41), a first telescopic driving piece (42) and a clamping piece (43), wherein the rotary driving piece (41) is arranged on the workbench (1), the output end of the rotary driving piece (41) is connected with the first telescopic driving piece (42), the output end of the first telescopic driving piece (42) is connected with the clamping piece (43), a placing groove (431) for placing a connector iron shell is formed in the clamping piece (43), and a negative pressure port is formed in the placing groove (431).

3. The data line Type-C joint assembly welding line of claim 1, wherein: the connector conveying assembly (3) comprises a unreeling disc (31), a conveying track (32) and a conveying piece (33), wherein the unreeling disc (31) is arranged on the workbench (1), the unreeling disc (31) is used for reeling the interface iron shell, the conveying track (32) is used for allowing the interface iron shell to pass through, and the conveying piece (33) is used for driving the interface iron shell to move in the conveying track (32).

4. The data line Type-C joint assembly welding line of claim 1, wherein: the wire harness seat (222) is provided with a wire harness groove (2221) for placing the data wire, the wire harness seat (222) is provided with a support plate (2222), and the support plate (2222) is provided with a wire harness hole (2223) for inserting the head of the data wire.

5. The data line Type-C joint assembly welding line of claim 4, wherein: be equipped with second slide rail (224) on workstation (1), second slide rail (224) are located the below of first slide rail (221), the length direction of second slide rail (224) is the same with the length direction of first slide rail (221), be equipped with circulation subassembly (225) between first slide rail (221) and second slide rail (224), circulation subassembly (225) are used for shifting pencil seat (222) between first slide rail (221) and second slide rail (224), still be equipped with second remove subassembly (226) on workstation (1), second remove subassembly (226) are used for driving pencil seat (222) on second slide rail (224) and remove.

6. The data line Type-C joint assembly welding line of claim 5, wherein: the circulating assembly (225) comprises two third telescopic driving pieces (2251), the third telescopic driving pieces (2251) are relatively arranged at two ends of the first sliding rail (221) along the length direction of the first sliding rail (221), the output end of each third telescopic driving piece (2251) is provided with a third sliding rail (2254), the output end of each third telescopic driving piece (2251) moves along the vertical direction, the workbench (1) is further provided with a fourth telescopic driving piece (2252) and a fifth telescopic driving piece (2253), the fourth telescopic driving pieces (2252) and the fifth telescopic driving pieces (2253) are relatively arranged at two ends of the first sliding rail (221) along the length direction of the first sliding rail (221), the heights of the fourth telescopic driving pieces (2252) and the first sliding rail (221) are similar, the heights of the fifth telescopic driving pieces (2253) and the second sliding rail (224) are similar, and the fourth telescopic driving pieces (2252) and the fifth telescopic driving pieces (2253) move along the length direction of the first sliding rail (221) in a reciprocating mode.

7. The data line Type-C joint assembly welding line of claim 1, wherein: the welding wire feeding mechanism (2) further comprises a wire feeding device (23), the wire feeding device (23) comprises a sixth telescopic driving piece (231) and a fourth sliding rail (232), the sixth telescopic driving piece (231) is arranged on the workbench (1), the output end of the sixth telescopic driving piece (231) is connected with the fourth sliding rail (232), a conveying groove (2211) for the fourth sliding rail (232) to pass through is formed in the first sliding rail (221), and when the output end of the sixth telescopic driving piece (231) stretches out, the fourth sliding rail (232) is located in the welding area (51).

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