阅读说明：本技术 一种数据线自动焊接机 (Data line automatic weld machine ) 是由 毛建军 徐隽 于 2019-11-19 设计创作，主要内容包括：本发明公开了一种数据线自动焊接机,属于线材加工设备技术领域,具有便于对浸锡后的导向进行修整的优点,其技术方案如下,包括机架、输送卡线治具的输送滑道,以及沿输送滑道长度方向依次设置的拉线模组、切线模组、剥皮模组、助焊剂模组、浸锡模组、焊接模组,浸锡模组与焊接模组之间还设有抵剪模组、整形模组,抵剪模组包括抵剪刀组、驱动抵剪刀组啮合的第一啮合器、以及驱动抵剪刀组向卡线治具移动的第一伸缩器,抵剪刀组包括上抵剪刀与下抵剪刀,上抵剪刀与下抵剪刀上均设抵剪齿,整形模组包括整形刀组、驱动整形刀组啮合的第二啮合器,整形刀组包括上整形刀与下整形刀,上整形刀与下整形刀上均设有整形齿。(The invention discloses an automatic data wire welding machine, which belongs to the technical field of wire processing equipment and has the advantage of facilitating trimming of guide after tin dipping, and the automatic data wire welding machine comprises a frame, a conveying slide way for conveying a wire clamping jig, and a wire pulling module, a wire cutting module, a peeling module, a soldering flux module, a tin dipping module and a welding module which are sequentially arranged along the length direction of the conveying slide way, wherein a shearing resisting module and a shaping module are also arranged between the tin dipping module and the welding module, the shearing resisting module comprises a shearing resisting cutter group, a first meshing device for driving the shearing resisting cutter group to be meshed and a first telescopic device for driving the shearing resisting cutter group to move towards the wire clamping jig, the shearing resisting cutter group comprises an upper shearing resisting cutter and a lower shearing resisting cutter, the shearing resisting teeth are respectively arranged on the upper shearing resisting cutter and the lower shearing resisting cutter, the shaping module comprises a shaping cutter group and a second meshing device for driving the shaping cutter group to be meshed, the shaping cutter group comprises an upper shaping cutter and a, the upper shaping knife and the lower shaping knife are both provided with shaping teeth.)

1. The utility model provides a data line automatic weld machine, includes frame (1), transport slide (11) of transport card line tool (2) to and the module of acting as go-between (12), tangent line module (13), the module of skinning (14), scaling powder module (15), wicking module (16), welding module (17), characterized by that set gradually along transport slide (11) length direction: still be equipped with between wicking module (16) and welding module (17) and support and cut module (3), plastic module (4), support and cut module (3) including supporting scissors group (31), the drive supports the first meshing ware of scissors group (31) meshing and drive and supports first expansion bend (33) that scissors group (31) removed to card line tool (2), support scissors group (31) including supporting scissors (311) and supporting scissors (312) down, on support scissors (311) and support scissors (312) on all establish and support scissors tooth (313), plastic module (4) include plastic knife group (41), the second meshing ware of drive plastic knife group (41) meshing, plastic knife group (41) include plastic knife (411) and lower plastic knife (413), all be equipped with plastic tooth (412) on upper plastic knife (411) and lower plastic knife (413).

2. The automatic data line welding machine of claim 1, wherein: the lower shearing resisting teeth (313) on the shearing resisting scissors (312) comprise a plurality of W-shaped teeth (3131), the upper shearing resisting teeth (313) on the shearing resisting scissors (311) are a plurality of shearing resisting convex teeth (3132) extending into the W-shaped teeth (3131), and the shearing resisting convex teeth (3132) extend into the W-shaped teeth (3131) to form shearing resisting gaps (3133) with the cross sections being slightly larger than the cross sections of the conductive wires (211).

3. The automatic data line welding machine of claim 1, wherein: the shaping teeth (412) on the upper shaping knife (411) comprise U-shaped teeth (4121) located at two ends and a plurality of V-shaped teeth (4122) located in the middle, the width of the U-shaped teeth (4121) is larger than that of the two V-shaped teeth (4122), the shaping teeth (412) on the lower shaping knife (413) are a plurality of shaping convex teeth (4123) extending into the U-shaped teeth (4121) and the V-shaped teeth (4122), and shaping gaps (4124) with the distance slightly larger than the diameter of the conductive wire (211) are formed after the shaping convex teeth (4123) extend into the U-shaped teeth (4121) and the V-shaped teeth (4122).

4. The automatic data line welding machine of claim 1, wherein: the first meshing device comprises two opposite second expansion pieces (32), the second expansion pieces (32) are vertically fixed at the extending ends of the first expansion pieces (33), and the abutting shear sets (31) are respectively fixed at the extending ends of the two second expansion pieces (32).

5. The automatic data line welding machine of claim 1, wherein: the shear resisting knife group (31) is connected with the first meshing device through a screw (5), and the shaping knife group (41) is connected with the second meshing device through a screw (5).

6. The automatic data line welding machine of claim 1, wherein: the second meshing device comprises two opposite third expansion pieces (42), the two third expansion pieces (42) are vertically fixed on the rack (1), and the shaping knife tackle (41) is respectively fixed at the extending ends of the two third expansion pieces (42).

7. The automatic data line welding machine of claim 1, wherein: the width of the shear resisting teeth (313) is 1-2 mm.

8. The automatic data line welding machine of claim 1, wherein: the width of the shaping teeth (412) is 2-5 mm.

Technical Field

The invention relates to the technical field of wire processing equipment, in particular to an automatic data wire welding machine.

Background

With the continuous progress of the current technology level, the popularity of electronic products is very high, and therefore the demand for additional accessories of electronic products is continuously increased, and the requirement for the automatic welding production of data lines is higher and higher at present.

In order to reduce the production cost of the data line and improve the production efficiency of the data line, Chinese patent with application publication number CN109038158A discloses a full-automatic double-end welding machine for the data line, which realizes automatic production and processing by clamping the wire rod on a wire clamping jig and then sequentially passing through a conveying slideway through a wire pulling module, a wire cutting module, a peeling module, a scaling powder module, a tin dipping module, a welding module and the like.

This kind though can be very fast promotion machining efficiency, after the upset wicking, partial unnecessary tin bonds easily between two conducting wires to make two conducting wires bond each other, and subsidiary excessive tin, it is connected together through unnecessary tin to electrocute two easily through welding module welded in-process, consequently leads to the rejection rate higher.

Disclosure of Invention

The invention aims to provide an automatic data wire welding machine which has the advantage of facilitating trimming of a guide after tin immersion.

The technical purpose of the invention is realized by the following technical scheme: the utility model provides a data line automatic weld machine, includes frame, the transport slide of transport card line tool to and the module of acting as go-between, tangent line module, the module of skinning, scaling powder module, wicking module, the welding module that sets gradually along transport slide length direction, still be equipped with between wicking module and the welding module and support and cut module, plastic module, support cut the module including supporting scissors group, drive and support the first meshing ware of scissors group meshing and drive and support the first expansion bend that scissors group removed to card line tool, support scissors group including supporting the scissors and supporting the scissors down, on support the scissors and all establish on supporting the scissors down and support the scissors and cut the tooth, the plastic module includes plastic knife group, drive plastic knife group meshing's second meshing ware, plastic knife group includes plastic sword and lower plastic sword, on all be equipped with the plastic tooth with lower plastic sword.

Through adopting above-mentioned technical scheme, after the conducting wire wicking, carry the slide to carry the card line tool to supporting to cut on the module, make through first meshing ware go up to support the scissors and move to the conducting wire with supporting down the scissors, go up to support the scissors and support the position between two conducting wires again of the tooth extrusion of supporting on the scissors under with, the concertina action of rethread first expansion bend, make the last scissors that supports of mutual conflict state and support the scissors down and remove along conducting wire length direction, thereby scrape unnecessary tin, carry the slide to remove the card line tool to the plastic module again, make through the second meshing ware go up plastic sword and remove to the conducting wire with lower plastic sword, thereby through the guide effect of plastic tooth, clearance between the effectual each conducting wire of assurance.

Further, the lower supporting shear teeth on the supporting scissors comprise a plurality of W-shaped teeth, the upper supporting shear teeth on the supporting scissors are supporting shear convex teeth extending into the W-shaped teeth for a plurality of, and the supporting shear convex teeth extend into the W-shaped teeth to form supporting shear gaps with sections slightly larger than the sections of the conductive wires.

Through adopting above-mentioned technical scheme, move in-process conducting wire along W shape tooth edge and remove to W shape tooth wave valley position to the scissors under, and support and cut the effect of dogtooth and W shape tooth, the separation is located the tin between the conducting wire, and through the flexible effect of first expansion bend, the conducting wire is being supported and is cut the clearance and remove, and effectual messenger's unnecessary tin strikes off.

Furthermore, the shaping teeth on the upper shaping knife comprise U-shaped teeth positioned at two ends and a plurality of V-shaped teeth positioned in the middle, the width of the U-shaped teeth is larger than the width of the two V-shaped teeth, the shaping teeth on the lower shaping knife are a plurality of shaping convex teeth extending into the U-shaped teeth and the V-shaped teeth, and shaping gaps with the distance slightly larger than the diameter of the conductive wire are formed after the shaping convex teeth extend into the U-shaped teeth and the V-shaped teeth.

Through adopting above-mentioned technical scheme, make the conducting wire be located the plastic clearance after the meshing of plastic tooth to effectual keep good distance and shape between the conducting wire, be convenient for weld.

Furthermore, first meshing ware includes that two are relative to be set up the second expansion bend, two the second expansion bend is vertical to be fixed at the end that stretches out of first expansion bend, it fixes the end that stretches out at two second expansion bends respectively to support the scissors group.

Through adopting above-mentioned technical scheme, through the flexible effect of two second expanders, realize supporting the meshing of scissors and lower scissors.

Further, the shear resisting knife group is connected with the first meshing device through a screw, and the shaping knife group is connected with the second meshing device through a screw.

Through adopting above-mentioned technical scheme to can carry out convenient change when processing different data lines.

Furthermore, the second meshing device comprises two opposite third expansion pieces, the two third expansion pieces are vertically fixed on the frame, and the shaping knife group is respectively fixed at the extending ends of the two third expansion pieces.

By adopting the technical scheme, the upper shaping knife is meshed with the lower shaping knife through the telescopic action of the two third retractors.

Furthermore, the width of the shear resisting teeth is 1-2 mm.

Through adopting above-mentioned technical scheme, promote the effect of scraping off tin.

Furthermore, the width of the shaping tooth is 2-5 mm.

Through adopting above-mentioned technical scheme, the electrically conductive silk homoenergetic of whole hourglass promotes the plastic effect to electrically conductive silk in the plastic clearance.

In conclusion, the invention has the following beneficial effects:

1. through the action of the abutting shear knife group, the redundant tin is effectively separated, and the adhesion phenomenon is reduced;

2. through the effect of plastic sword, the state of effectual assurance conducting wire promotes welding precision.

Drawings

FIG. 1 is a structural view of the present embodiment;

FIG. 2 is an enlarged view of A in FIG. 1;

FIG. 3 is a view showing the engagement state of the shear resisting blade set;

fig. 4 is a view showing the state of engagement of the reforming cutter group.

In the figure, 1, a frame; 11. a conveying chute; 12. a wire pulling module; 13. a thread cutting module; 14. a peeling module; 15. a soldering flux module; 16. a tin immersion module; 17. welding the module; 2. a wire clamping jig; 21. a wire; 211. a conductive filament; 3. a shearing module; 31. a shear resisting cutter group; 311. pushing the scissors upwards; 312. pushing the scissors downwards; 313. resisting and shearing teeth; 3131. a W-shaped tooth; 3132. shearing the convex teeth; 3133. a shearing resisting gap; 32. a second retractor; 33. a first retractor; 4. a shaping module; 41. shaping a cutter set; 411. an upper shaping knife; 412. shaping teeth; 4121. a U-shaped tooth; 4122. a V-shaped tooth; 4123. shaping the convex teeth; 4124. shaping the gap; 413. a lower shaping knife; 42. a third expansion piece; 5. and (4) screws.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

The utility model provides a data line automatic weld machine, as shown in figure 1, includes frame 1, transport slide 11, along transport slide 11 length direction set gradually act as go-between module 12, tangent line module 13, the module 14 of skinning, scaling powder module 15, wicking module 16, support and cut module 3, plastic module 4, welding module 17.

As shown in fig. 1 and 3, firstly, a wire 21 to be welded is clamped into a groove of a wire clamping jig 2, the wire 21 is exposed out of the same side of the wire clamping jig 2, then a cover is covered to fix the wire 21 in the wire clamping jig 2, then the wire clamping jig 2 is placed on a conveying slideway 11, and a data plug is welded on a conductive wire 211 through the conveying action of the conveying slideway 11 in sequence through a wire pulling module 12, a wire cutting module 13, a peeling module 14, a soldering flux module 15, a tin immersion module 16, a shearing abutting module 3, a shaping module 4 and a welding module 17.

As shown in fig. 1, when the wire pulling module 12 works, the wire 21 is clamped and pulled towards one end, so that the straightness of the wire 21 is improved, the wire 21 is ensured to be in a regular state, and the subsequent processing is facilitated.

As shown in fig. 1 and 3, the peeling module 14 can peel off the exposed insulation sheath of the wire 21, so that the plurality of conductive wires 211 inside can be exposed, thereby facilitating the later processing.

As shown in fig. 1 and 3, the wire clamping jig 2 moving to the soldering flux module 15 is turned for 90 degrees, so that the conductive wire 211 is immersed in the soldering flux box for surface immersion of the soldering flux, thereby facilitating the adhesion of the soldering flux, the wire clamping jig 2 is turned and reset and then moves to the tin immersion module 16, the wire clamping jig 2 is turned for 90 degrees, the conductive wire 211 is immersed in the tin box, the tin is heated in the tin box to be liquid, thereby facilitating the adhesion of the conductive wire 211 to the surface of the conductive wire, and the wire clamping jig 2 is turned and reset again.

As shown in fig. 2 and 3, the shearing resisting module 3 includes a shearing resisting group 31, a first engaging device for driving the shearing resisting group 31 to engage, and a first expansion device 33 for driving the shearing resisting group 31 to move towards the wire clamping jig 2, the first engaging device includes two opposite second expansion devices 32, the two second expansion devices 32 are vertically fixed at the extending end of the first expansion device 33, the shearing resisting group 31 is respectively fixed at the extending end of the two second expansion devices 32, and the engagement of the upper shearing resisting 311 and the lower shearing resisting 312 is realized through the expansion and contraction effect of the two second expansion devices 32.

As shown in fig. 2 and 3, the scissors set 31 includes an upper scissors 311 and a lower scissors 312, the upper scissors 311 and the lower scissors 312 are both provided with a scissors tooth 313, the scissors tooth 313 has a width of 1-2mm, the scissors tooth 313 on the lower scissors 312 includes a plurality of W-shaped teeth 3131, the scissors tooth 313 on the upper scissors 311 is a plurality of scissors teeth 3132 extending into the W-shaped teeth 3131, the scissors teeth 3132 extend into the W-shaped teeth 3131 to form a scissors gap 3133 having a cross-section slightly larger than that of the conductive wire 211, the upper scissors 311 and the lower scissors 312 are moved toward the conductive wire 211 by a first engaging device, the conductive wire 211 moves along the edge of the W-shaped teeth 3131 to the trough of the W-shaped teeth 3131 during the movement of the lower scissors 312, the scissors tooth 3132 and the W-shaped teeth 3131 act to separate the tin between the conductive wires 211, and the conductive wire 211 moves in the scissors gap 3133 by the expansion and contraction of the first expander 33, effectively scraping off the excessive tin.

As shown in fig. 2 and 4, the shaping module 4 includes a shaping knife set 41, a second engaging device for driving the shaping knife set 41 to engage, the shaping knife set 41 includes an upper shaping knife 411 and a lower shaping knife 413, shaping teeth 412 are respectively disposed on the upper shaping knife 411 and the lower shaping knife 413, the shaping teeth 412 are 2-5mm in width, the second engaging device includes two oppositely disposed third retractors 42, the two third retractors 42 are vertically fixed on the frame 1, the shaping knife set 41 is respectively fixed on the extending ends of the two third retractors 42, the engagement between the upper shaping knife 411 and the lower shaping knife 413 is realized by the telescopic action of the two third retractors 42, wherein the shaping teeth 412 on the upper shaping knife 411 include U-shaped teeth 4121 located at both ends and a plurality of V-shaped teeth 4122 located at the middle portion, the width of the U-shaped teeth 4121 is greater than the width of the two V-shaped teeth 4122, the shaping teeth 412 on the lower shaping knife 413 are a plurality of shaping teeth 4123 extending into the U-shaped teeth 4121 and the V-shaped teeth 4122, the shaping teeth 4123 extend into the U-shaped teeth 4121 and the V-shaped teeth 4122 to form a shaping gap 4124 having a spacing slightly larger than the diameter of the conductive wire 211.

As shown in fig. 2 and 4, during the engagement process, the conductive wires 211 move toward the bottom along the edges of the V-shaped teeth 4122 and the U-shaped teeth 4121, and the shaping protrusions 4123 are also pressed into the V-shaped teeth 4122 and the U-shaped teeth 4121, so that the leaked conductive wires 211 are completely located in the shaping gap 4124, thereby fixing the positions and shapes of the conductive wires 211, effectively ensuring the gaps between the conductive wires 211, improving the shaping effect on the conductive wires 211, and facilitating the subsequent welding.

As shown in fig. 2 and 4, since the shaping teeth 412 at two ends of the upper shaping knife 411 are U-shaped teeth 4121, the conductive wires 211 at two ends are more widely spread, so that the two conductive wires 211 at the ends are conveniently guided, and the two conductive wires 211 are at the bottom of the U-shaped teeth 4121.

As shown in fig. 1 and 4, after finishing the shaping of the conductive wire 211, the wire clamping jig 2 moves to the welding module 17 to weld the data plug, so that the whole processing is realized, and the tin amount on the conductive wire 211 is proper and is not adhered, thereby effectively reducing the adhesion phenomenon after welding.

As shown in fig. 2, since the scissors abutting set 31 is connected to the first engaging device by the screw 5 and the shaping knife set 41 is connected to the second engaging device by the screw 5, when different data lines are processed, the number of the conductive wires 211 inside the data lines is also different, so that another type of data line can be processed by replacing the scissors abutting set 31 and the shaping knife set 41, and the application range of the device is wider.

The present embodiment is only for explaining the present invention, and it is not limited to the present invention, and those skilled in the art can make modifications of the present embodiment without inventive contribution as needed after reading the present specification, but all of them are protected by patent law within the scope of the claims of the present invention.