CN113629471A

CN113629471A - Multi-core flat cable fusion welding equipment

Info

Publication number: CN113629471A
Application number: CN202111177865.1A
Authority: CN
Inventors: 郭志华
Original assignee: Sunke Sungoin Technology Jiangsu Co ltd
Current assignee: Wuhan Suoyate Electromechanical Equipment Co ltd
Priority date: 2021-10-09
Filing date: 2021-10-09
Publication date: 2021-11-09
Anticipated expiration: 2041-10-09
Also published as: CN113629471B

Abstract

The invention discloses a multi-core flat cable fusion welding device which comprises a case, wherein two horizontal guide rails are symmetrically installed in the case, two overturning guide rails are symmetrically and rotatably installed at two ends of each horizontal guide rail, a plurality of conveyors are slidably installed on each horizontal guide rail and the two overturning guide rails at the same side, a sliding port is formed in each conveyor, a plurality of controllable rods are symmetrically and slidably inserted in each conveyor, a fixed frame is installed at the upper ends of the controllable rods together, a return spring is sleeved on each controllable rod, and two ends of each return spring are respectively fixed on the bottom wall of the fixed frame and the upper surface of the conveyor. Realize the synchronous welding in winding displacement both ends through two-way synchronous welding, make it can once only accomplish all sinle silk weldings of winding displacement, welding efficiency is high, and manual operation is simple, and work load is low, and strikes off unnecessary solder after welding through the melting contact, increases the homogeneity of welded, improves the quality of product.

Description

Multi-core flat cable fusion welding equipment

Technical Field

The invention relates to the field of flat cable production and processing, in particular to a multi-core flat cable fusion welding device.

Background

The existing flat cable welding equipment is usually a spot welding machine, namely, the wire cores of all wires of a flat cable are manually spot-welded one by one, the work load is large, the efficiency is low, in the spot welding process, welding spots are uneven due to the fact that manual operation errors easily cause the flat cable to be connected with a product difficultly or the contact surface is reduced, and the quality of the product is affected.

Disclosure of Invention

The invention aims to solve the problems that manual one-by-one welding is high in workload and low in efficiency, and the welding is uneven to influence the product quality in the prior art, and provides a multi-core flat cable fusion welding device.

In order to achieve the purpose, the invention adopts the following technical scheme:

the utility model provides a multicore winding displacement fusion welding equipment, includes quick-witted case, two horizontal guide rails are installed to quick-witted incasement symmetry, and two upset guide rails are installed to the equal symmetric rotation in both ends of every horizontal guide rail, every equal slidable mounting has a plurality of cargo conveyers, every on two upset guide rails of horizontal guide rail and homonymy all seted up sliding opening on the cargo conveyer, every equal symmetric sliding insertion is equipped with a plurality of controllable poles on the cargo conveyer, it is a plurality of fixed frame, every are installed jointly to the upper end of controllable pole all the cover is equipped with reset spring on the controllable pole, every reset spring's both ends are fixed respectively on the diapire of fixed frame and the upper surface of cargo conveyer, every all fixed inserting is equipped with the winding displacement locating piece on the fixed frame, every the equal slidable insertion of winding displacement locating piece is in corresponding the sliding opening, every melting tank's notch department all installs the sinle silk locating plate.

Furthermore, each flat cable positioning block is provided with a plurality of flat cable positioning holes, the flat cable positioning holes are sequentially intersected, the lower end of the inner wall of each flat cable positioning hole is provided with a positioning conical ring, the diameter of the lower end of each positioning conical ring is smaller than that of the upper end of each positioning conical ring, and the diameter of the upper end of each positioning conical ring is equal to that of the flat cable positioning hole.

Further, every a plurality of sinle silk beam splitting holes have been seted up to impartial distance on the sinle silk locating plate, every the cone ring tied in a bundle is all installed to the inner wall lower extreme in sinle silk beam splitting hole, every the lower extreme diameter of cone ring tied in a bundle all is less than its upper end diameter, every the diameter of the upper end diameter of cone ring tied in a bundle is impartial in the diameter in sinle silk beam splitting hole, every the diameter in sinle silk beam splitting hole all is less than the diameter in winding displacement locating hole.

Further, every equal symmetry is installed two electromagnetic plates, every on the fixed frame the upper surface of winding displacement locating piece flushes with the upper surface of fixed frame, every install centre gripping frame, every between two parties on the fixed frame symmetrical slidable mounting has two fastening splint, every on the inner wall of centre gripping frame impartial distance installs a plurality of elastic pieces, every on the fastening splint the one end that fastening splint was kept away from to the elastic piece is all fixed on the inner wall of centre gripping frame, every the circular arc wave fastening groove has all been seted up to the one end that fastening splint kept away from the elastic piece, the circular arc internal diameter in circular arc wave fastening groove is less than the diameter of winding displacement locating hole.

Further, two it is equipped with the average material pipe to insert jointly between the horizontal guide rail, the vertical inlet pipe that is equipped with of inserting on the average material pipe, the upper end of inlet pipe extends to the top of quick-witted case, the coiling has the melt heating coil on the average material pipe, the one end that the inlet pipe is close to the average material pipe has the feeding heating coil, the last fixed surface of quick-witted case installs the support frame, rotate on the support frame and install the solder wire roller, the upper surface of quick-witted case is located inlet pipe department symmetry and installs two backup pads, two common symmetry rotation installs two inlet wire wheels between the backup pad.

Further, every a plurality of horizontal guide slots and upset guide slot have all been seted up to the symmetry on the lateral wall of horizontal guide rail and upset guide rail, every horizontal guide slot all aligns with the upset guide slot that corresponds, every the equal sliding assembly of conveyer is on horizontal guide slot and upset guide slot.

Has the advantages that: realize the synchronous welding in winding displacement both ends through two-way synchronous welding, make it can once only accomplish all sinle silk weldings of winding displacement, welding efficiency is high, and manual operation is simple, and work load is low, and strikes off unnecessary solder after welding through the melting contact, increases the homogeneity of welded, improves the quality of product.

Drawings

FIG. 1 is a schematic structural diagram of a multi-core flat cable fusion welding apparatus according to the present invention;

FIG. 2 is a schematic view of a horizontal rail and a turning rail of a multi-core flat cable fusion welding apparatus according to the present invention;

FIG. 3 is an enlarged view of a horizontal rail portion of a multi-core flat cable fusion welding apparatus according to the present invention;

FIG. 4 is an enlarged view of a conveyor portion of a multi-core flat cable fusion welding apparatus according to the present invention;

FIG. 5 is a schematic view of a flat cable positioning block of a multi-core flat cable fusion welding apparatus according to the present invention partially cut away;

FIG. 6 is a partially cut-away schematic view of a core positioning plate of the multi-core flat cable fusion welding device according to the present invention;

FIG. 7 is an enlarged view taken at A in FIG. 1;

fig. 8 is an enlarged view of fig. 4 at B.

In the figure: the device comprises a case 1, a support frame 11, a solder wire roller 12, a support plate 13, a wire inlet wheel 14, a horizontal guide rail 2, a horizontal guide groove 21, a melt groove 22, a turnover guide rail 3, a turnover guide groove 31, a conveyor 4, a sliding opening 41, a wire core positioning plate 5, a wire core splitting hole 51, a wire core splitting conical ring 52, a water average material pipe 6, a feed pipe 61, a melt heating coil 62, a feed heating coil 63, a controllable rod 7, a fixed frame 71, a reset spring 72, an electromagnetic plate 73, a wire arranging positioning block 8, a wire arranging positioning hole 81, a positioning conical ring 82, a clamping frame 9, a fastening clamping plate 91, an elastic sheet 92 and a circular arc wave fastening groove 93.

Detailed Description

Referring to fig. 1-4, a multi-core flat cable fusion welding device comprises a case 1, wherein two horizontal guide rails 2 are symmetrically installed in the case 1, two overturning guide rails 3 are symmetrically and rotatably installed at two ends of each horizontal guide rail 2, a plurality of conveyors 4 are respectively and slidably installed on each horizontal guide rail 2 and the two overturning guide rails 3 on the same side, a sliding port 41 is formed in each conveyor 4, a plurality of controllable rods 7 are symmetrically and slidably inserted in each conveyor 4, a fixed frame 71 is commonly installed at the upper ends of the controllable rods 7, a return spring 72 is sleeved on each controllable rod 7, two ends of each return spring 72 are respectively fixed on the bottom wall of the fixed frame 71 and the upper surface of each conveyor 4, a flat cable positioning block 8 is fixedly inserted in each fixed frame 71, each flat cable positioning block 8 is slidably inserted in the corresponding sliding port 41, a melting groove 22 is formed in the upper surface of each horizontal guide rail 2, a wire core positioning plate 5 is arranged at the notch of each melting groove 22;

the conveyor 4 can slide on the horizontal guide rail 2 and the turnover guide rail 3, and the turnover guide rail 3 can turn over the conveyor 4 to adjust the direction, so that the plurality of conveyors 4 can circularly move up and down to perform wire arrangement transportation welding;

the controllable rod 7 can move the fixing frame 71 up and down under the control of the conveyor 4, so that the flat cable positioning block 8 moves up and down in the sliding opening 41, the flat cable positioning block 8 is used for fixing the end of a flat cable, and the end of the flat cable can move down under the action of the flat cable positioning block 8 and is inserted into the cable core positioning plate 5 for welding.

Referring to fig. 5, each flat cable positioning block 8 is provided with a plurality of flat cable positioning holes 81, the flat cable positioning holes 81 are sequentially intersected, the lower end of the inner wall of each flat cable positioning hole 81 is provided with a positioning conical ring 82, the diameter of the lower end of each positioning conical ring 82 is smaller than that of the upper end thereof, and the diameter of the upper end of each positioning conical ring 82 is equal to that of the flat cable positioning hole 81;

the winding displacement passes through winding displacement locating piece 8 fixedly, the winding displacement both ends are inserted respectively and are established on two winding displacement locating pieces 8 on two conveyors 4 of symmetry on two horizontal guide rails 2, the winding displacement inserts in a plurality of winding displacement locating holes 81 that coincide promptly, make the winding displacement can be fixed a position by winding displacement locating hole 81 and slide down, and location taper ring 82 can block the outer rubber of winding displacement, only make the sinle silk of winding displacement pass location taper ring 82 to the below of winding displacement locating piece 8, realize the quick accurate installation of winding displacement, and can make the fixed welding of winding displacement both ends simultaneously, high efficiency.

Referring to fig. 6, a plurality of core splitting holes 51 are equally spaced on each core positioning plate 5, a bundling conical ring 52 is mounted at the lower end of the inner wall of each core splitting hole 51, the diameter of the lower end of each bundling conical ring 52 is smaller than that of the upper end thereof, the diameter of the upper end of each bundling conical ring 52 is equal to that of the core splitting hole 51, and the diameter of each core splitting hole 51 is smaller than that of the flat cable positioning hole 81;

when the flat cable positioning block 8 moves downwards, the wire cores passing through the positioning conical ring 82 below the flat cable positioning block 8 are accurately inserted into the plurality of wire core beam splitting holes 51, so that the plurality of wire cores of the flat cable are separated to avoid mutual interference, the wire cores entering the wire core beam splitting holes 51 are gathered and folded under the extrusion of the beam-gathering conical ring 52, so that the plurality of wire cores of each wire of the flat cable are folded and then pass through the beam-gathering conical ring 52 to extend into the melt tank 22, and the molten soldering tin material in the melt tank 22 is attached to the wire cores to start fusion welding;

when winding displacement locating piece 8 moved up, drive the winding displacement and shift up, then the sinle silk was extracted from sinle silk beam splitting hole 51, when then sinle silk shifts up and extracts, the cone ring 52 of bundling strikes off unnecessary solder around the sinle silk, only makes the inside solder of sinle silk adhere to, then when the sinle silk breaks away from cone ring 52 of bundling, the solder cools off the sinle silk welding fast for all sinle silks at winding displacement both ends are welded simultaneously, realize the quick welding of winding displacement sinle silk, and efficiency is better and convenient operation, need not spot welding one by one.

Referring to fig. 4 and 8, two electromagnetic plates 73 are symmetrically installed on each fixing frame 71, the upper surface of each flat cable positioning block 8 is flush with the upper surface of the fixing frame 71, a clamping frame 9 is installed on each fixing frame 71 in the middle, two fastening clamping plates 91 are symmetrically and slidably installed on the inner wall of each clamping frame 9, a plurality of elastic pieces 92 are equally spaced on each fastening clamping plate 91, one end of each elastic piece 92, which is far away from the fastening clamping plate 91, is fixed on the inner wall of the clamping frame 9, an arc wave fastening groove 93 is formed in one end of each fastening clamping plate 91, which is far away from the elastic piece 92, and the arc inner diameter of each arc wave fastening groove 93 is smaller than the diameter of the flat cable positioning hole 81;

the electromagnetic plate 73 is electrified at the turnover guide rail 3, and is powered off on the horizontal guide rail 2, so that when the conveyor 4 is positioned at the turnover guide rail 3, the electromagnetic plate 73 is electrified to generate magnetic force to attract the fastening clamp plates 91, so that the two fastening clamp plates 91 are far away, the fastening clamp plates 91 open the winding displacement positioning hole 81, the winding displacement can be quickly inserted and installed, and the winding displacement can be quickly dropped off during turnover, so that feeding and discharging are realized;

when the conveyer 4 is located horizontal guide 2, the electromagnetic plate 73 loses the outage and loses magnetic force, then the fastening splint 91 is tight under the effect of elastic sheet 92, makes circular arc wave fastening groove 93 fixed the winding displacement, and skew or drop when avoiding welding increase welded reliability.

Referring to fig. 1, 2, 3 and 7, a horizontal material homogenizing pipe 6 is commonly inserted between two horizontal guide rails 2, a material feeding pipe 61 is vertically inserted on the horizontal material homogenizing pipe 6, the upper end of the material feeding pipe 61 extends to the upper part of the case 1, a molten material heating coil 62 is wound on the horizontal material homogenizing pipe 6, a material feeding heating coil 63 is wound at one end of the material feeding pipe 61 close to the horizontal material homogenizing pipe 6, a supporting frame 11 is fixedly installed on the upper surface of the case 1, a solder wire roller 12 is rotatably installed on the supporting frame 11, two supporting plates 13 are symmetrically installed on the upper surface of the case 1 at the position of the material feeding pipe 61, and two wire feeding wheels 14 are symmetrically installed between the two supporting plates 13;

the heating temperature of the melt heating coil 62 is higher than that of the feeding heating coil 63, the heating temperature of the melt heating coil 62 is higher than the melting point of the solder, so that the solder in the average material pipe 6 and the melt groove 22 is always fluid, the welding failure caused by solidification is avoided, the heating temperature of the feeding heating coil 63 is equal to the melting point of the solder, and the solder entering the feeding pipe 61 can be quickly melted for supplement;

the wire feeding wheel 14 is controlled by a servo motor, and after the conveyor 4 transports the flat cable for welding at every time, the wire feeding wheel 14 rotates to convey linear solder on the solder wire roller 12 to the feeding pipe 61, so that the linear solder can be supplemented after being consumed by welding at every time, the amount of the solder in the melting tank 22 is kept all the time, and the welding quality of the flat cable wire core is ensured.

Referring to fig. 2 and 3, a plurality of horizontal guide grooves 21 and turnover guide grooves 31 are symmetrically formed in the side walls of each of the horizontal guide rails 2 and the turnover guide rails 3, each of the horizontal guide grooves 21 is aligned with the corresponding turnover guide groove 31, and each of the conveyors 4 is slidably fitted over the horizontal guide grooves 21 and the turnover guide grooves 31;

connect through step motor rotation between horizontal guide 2 and the upset guide 3, the tip of horizontal guide 2 or the tip of upset guide 3 inlays establishes step motor promptly, the upset of the accurate control upset guide 3 of being convenient for, horizontal guide slot 21 and upset guide slot 31 can be conducting material, realize the contact power supply.

The conveyor 4 moves to the turnover guide rail 3, the electromagnetic plate 73 is electrified to attract the two fastening clamping plates 91 to separate and compress the elastic sheet 92, after the flat cable is bent, two ends of the flat cable are respectively inserted into the flat cable positioning holes 81 of the flat cable positioning blocks 8 on the two conveyors 4 on the turnover guide rail 3, the rubber of the flat cable is blocked by the positioning conical ring 82, and the cable core is only extended to the lower part of the flat cable positioning block 8.

When the conveyor 4 moves to the horizontal guide rail 2, the electromagnetic plate 73 is powered off and loses magnetic force, the two fastening clamping plates 91 clamp the flat cable under the action of the elastic sheet 92, the conveyor 4 conveys the flat cable to the position right above the melting tank 22, then the controllable rod 7 is controlled to move downwards, the fixing frame 71 drives the flat cable positioning block 8 to move downwards, the flat cable positioning block 8 enables the flat cable to downwards insert the flat cable into the cable core beam splitting hole 51 of the cable core positioning plate 5, the flat cable is bundled in the cable core beam splitting hole 51 and then is gathered under the action of the beam splitting conical ring 52 and extends into the melting tank 22 to be contacted with molten solder, and then the solder attached to the flat cable core starts welding.

The conveyor 4 is in contact with the controllable rod 7, and the reset spring 72 pushes the fixing frame 71 to move upwards, so that the flat cable positioning block 8 drives the flat cable to move upwards, namely the flat cable is driven to be pulled out of the cable core beam splitting hole 51, the cable core scrapes off redundant solder at the lower end of the beam-concentrating conical ring 52 and is separated from the cable core beam splitting hole 51 to be cooled and solidified, and welding is achieved.

The conveyor 4 drives the welding-completed flat cable to move to the turnover guide rail 3 on the other side, the electromagnetic plate 73 is electrified, the fastening clamping plate 91 is loosened, the turnover guide rail 3 drives the conveyor 4 to rotate reversely, the flat cable is separated from the conveyor 4 downwards, and automatic blanking is achieved.

Claims

1. A multi-core flat cable fusion welding device comprises a case (1) and is characterized in that two horizontal guide rails (2) are symmetrically installed in the case (1), two turnover guide rails (3) are symmetrically and rotatably installed at two ends of each horizontal guide rail (2), a plurality of conveyors (4) are respectively and slidably installed on the horizontal guide rails (2) and the two turnover guide rails (3) on the same side, a sliding opening (41) is formed in each conveyor (4), a plurality of controllable rods (7) are symmetrically and slidably inserted in each conveyor (4), a fixed frame (71) is jointly installed at the upper ends of the controllable rods (7), a reset spring (72) is sleeved on each controllable rod (7), two ends of each reset spring (72) are respectively fixed on the bottom wall of the fixed frame (71) and the upper surface of each conveyor (4), every all fixed inserting is equipped with winding displacement locating piece (8) on fixed frame (71), every winding displacement locating piece (8) all slides and inserts and establish in corresponding sliding opening (41), every melting tank (22) have all been seted up to the upper surface of horizontal guide (2), every sinle silk locating plate (5) are all installed to the notch department of melting tank (22).

2. The apparatus of claim 1, wherein each of the plurality of wire positioning blocks (8) has a plurality of wire positioning holes (81), the plurality of wire positioning holes (81) are sequentially overlapped, a positioning conical ring (82) is disposed at a lower end of an inner wall of each of the wire positioning holes (81), a diameter of a lower end of each positioning conical ring (82) is smaller than a diameter of an upper end thereof, and a diameter of an upper end of each positioning conical ring (82) is equal to a diameter of each wire positioning hole (81).

3. The multi-core flat cable fusion welding device according to claim 2, wherein a plurality of cable core splitting holes (51) are equally spaced on each cable core positioning plate (5), a bundling cone ring (52) is mounted at the lower end of the inner wall of each cable core splitting hole (51), the diameter of the lower end of each bundling cone ring (52) is smaller than the diameter of the upper end of each bundling cone ring, the diameter of the upper end of each bundling cone ring (52) is equal to the diameter of each cable core splitting hole (51), and the diameter of each cable core splitting hole (51) is smaller than the diameter of each flat cable positioning hole (81).

4. The multiple core flat cable fusion welding device according to claim 2, wherein two electromagnetic plates (73) are symmetrically installed on each fixing frame (71), the upper surface of each flat cable positioning block (8) is flush with the upper surface of the fixing frame (71), a clamping frame (9) is installed on each fixing frame (71) in the middle, two fastening clamping plates (91) are symmetrically and slidably installed on the inner wall of each clamping frame (9), a plurality of elastic sheets (92) are installed on each fastening clamping plate (91) at equal intervals, one end of each elastic sheet (92) far away from the fastening clamping plate (91) is fixed on the inner wall of the clamping frame (9), and one end of each fastening clamping plate (91) far away from the elastic sheet (92) is provided with an arc wave fastening groove (93), the arc inner diameter of the arc wave fastening groove (93) is smaller than the diameter of the flat cable positioning hole (81).

5. The apparatus for fusion welding of multiple core wires according to claim 1, wherein a horizontal material pipe (6) is commonly inserted between two horizontal guide rails (2), a feeding pipe (61) is vertically inserted into the horizontal feeding pipe (6), the upper end of the feeding pipe (61) extends to the upper part of the case (1), a melt heating coil (62) is wound on the water average material pipe (6), a feeding heating coil (63) is wound at one end of the feeding pipe (61) close to the water average material pipe (6), a support frame (11) is fixedly arranged on the upper surface of the case (1), a solder wire roller (12) is rotatably arranged on the support frame (11), two supporting plates (13) are symmetrically arranged on the upper surface of the case (1) at the position of the feeding pipe (61), and two wire feeding wheels (14) are symmetrically and rotatably arranged between the supporting plates (13) together.

6. The apparatus of claim 1, wherein a plurality of horizontal guide grooves (21) and turning guide grooves (31) are symmetrically formed on the side walls of each of the horizontal guide rails (2) and the turning guide rails (3), each of the horizontal guide grooves (21) is aligned with the corresponding turning guide groove (31), and each of the conveyors (4) is slidably mounted on the horizontal guide grooves (21) and the turning guide grooves (31).