CN215697642U - Movable buckle processing equipment - Google Patents

Abstract

The utility model provides a movable buckle processing device which comprises a forming device, wherein the forming device comprises two cavity molds which are arranged oppositely, each cavity mold is provided with a cavity surface and a material bearing surface which is adjacent to the cavity surface and used for bearing a wire rod, the two cavity surfaces are arranged oppositely, the cavity surface is provided with a first forming cavity used for forming a shifting part and a second forming cavity used for forming a sliding part, and the second forming cavity is close to the material bearing surface; the first stamping die is used for pressing part of the wire rods into the two first forming cavities; the first die driving assembly is connected with the first stamping die to drive the first stamping die to perform stamping action; the second stamping die is used for pressing the wire into the two second forming cavities and driving the formed movable buckle to discharge from the two cavity dies; and the second die driving component is connected with the second stamping die and is used for driving the second stamping die to do stamping action after the first stamping die does stamping action. The processing mode of activity knot in this embodiment is simple, and machining efficiency is high.

Description

Movable buckle processing equipment

Technical Field

The utility model relates to the field of spring buckle assembling equipment, in particular to movable buckle processing equipment.

Background

In a necklace, a spring clip is usually used for connection, so that the wearing convenience is improved. As shown in fig. 1, the spring buckle 10 mainly includes a housing 101, a movable buckle 104, and a spring. The outer shell 101 is in a circular ring shape and is provided with a buckle port 102, the spring buckle 10 is used for buckling a necklace through the buckle port 102, a cavity is formed in the outer shell 101, a spring inlet 103 communicated with the cavity is formed in one end of the outer shell 101, the spring inlet 103 faces the other end of the outer shell 101, a side face loading port 107 is formed in the outer side face of the outer shell 101, and the movable buckle 104 is assembled in the outer shell 101 from the side face loading port 107. The movable buckle 104 includes a toggle portion 105 and a sliding portion 106, the sliding portion 106 is installed in the cavity of the housing 101, and the toggle portion 105 protrudes from the housing 101. The spring is an elongated compression spring disposed within the housing 101. One end of the movable buckle 104 extends into the housing 101 from one end extending into the housing 101 and abuts against the spring, and the other end of the movable buckle 104 abuts against the other end of the housing 101. The moveable clasp 104 is moved along the cavity in the housing 101 by toggling the toggle portion 105, thereby opening or closing the opening. The shaping mode of activity knot usually is weld forming, processes sliding part and toggle portion respectively earlier, later with sliding part and toggle portion welding together, sliding part and toggle portion process respectively, the process steps increase, because the sliding part is with the maximum profile size of cross section of toggle portion between 2mm to 3mm, the welding difficulty leads to machining efficiency to hang down.

SUMMERY OF THE UTILITY MODEL

In order to overcome the defects of the prior art, the utility model aims to provide movable buckle processing equipment to solve the technical problems of low efficiency and high labor cost in the existing manual spring assembling process.

One of the purposes of the utility model is realized by adopting the following technical scheme: a movable buckle processing device comprises a forming device, wherein the forming device comprises:

the wire rod forming die comprises two cavity dies arranged oppositely, wherein each cavity die is provided with a cavity surface and a material bearing surface which is adjacent to the cavity surface and used for bearing a wire rod before forming, the two cavity surfaces are arranged oppositely, a first forming cavity used for forming a shifting part and a second forming cavity used for forming a sliding part are arranged on the cavity surfaces, and the second forming cavity is close to the material bearing surface;

the first stamping die is used for pressing part of the wire rods into the two first forming cavities;

the first die driving assembly is connected with the first stamping die to drive the first stamping die to perform stamping action;

the second stamping die is used for pressing the wire into the two second forming cavities and driving the formed movable buckle to discharge from the two cavity dies; and

and the second die driving component is connected with the second stamping die and is used for driving the second stamping die to do stamping action after the first stamping die does stamping action.

Optionally, the molding device further includes a cavity driving assembly, and the cavity driving assembly is connected to the two cavity molds and is configured to drive the two cavity molds to perform a pressing operation after the second stamping mold performs a stamping operation.

Optionally, the movable buckle processing equipment further comprises a mounting plate;

the forming device further comprises a mounting seat, the mounting seat comprises a sliding seat, a rotating seat and a first telescopic rod, the sliding seat is arranged on the mounting plate in a sliding mode along the stamping action direction, the rotating seat is rotatably arranged on the sliding seat, the first telescopic rod is arranged on the rotating seat in a sliding mode, the telescopic direction of the first telescopic rod is perpendicular to the stamping action direction and faces to the gap between the two cavity dies, and the second stamping die is fixed on the first telescopic rod;

the second die driving assembly comprises a telescopic driving assembly, a stamping driving assembly and a first rotary driving assembly, the stamping driving assembly is connected with the sliding seat to drive the second stamping die to perform stamping action, the telescopic driving assembly is connected with the first telescopic rod to drive the first telescopic rod to avoid the first stamping die, and the first rotary driving assembly is connected with the rotary seat to drive the second stamping die and the movable buckle to rotate.

Optionally, a material receiving groove for limiting the position of the wire rod is arranged on at least one material receiving surface.

Optionally, a first positioning groove for limiting the position of the wire rod is arranged in the first molding cavity;

and a second positioning groove used for limiting the position of the wire rod is arranged in the second molding cavity, and the second positioning groove is communicated with the first positioning groove.

Optionally, the movable buckle processing equipment further comprises an assembling device, and the assembling device grabs the shifting part of the movable buckle and is assembled in the shell of the spring buckle.

Optionally, the fitting device comprises:

the clamping jaw mounting table is provided with a rotatable mounting rod;

the clamping jaw is arranged on the mounting rod;

the clamping jaw driving assembly is connected with the clamping jaw and used for driving the clamping jaw to open and close;

the angle adjusting assembly is connected with the mounting rod and used for adjusting the opening and closing directions of the clamping jaws;

the second rotary driving assembly is connected with the clamping jaw mounting table and used for driving the clamping jaw to move between a forming and blanking position and a station for fixing a workpiece;

and the assembly driving assembly is connected with the clamping jaw mounting table to drive the clamping jaw mounting table to move towards the side loading port of the shell.

Optionally, the movable buckle processing equipment further comprises a rotating table, and a plurality of stations for fixing the workpiece are arranged on the rotating table.

Optionally, the activity is detained processing equipment and is still included wire rod feed mechanism, wire rod feed mechanism includes:

an unwinding roller for unwinding the wire;

and driving the roller assembly to pull the wire to move towards the material bearing surface.

Optionally, the wire feeding mechanism further includes a discharging plane located at one side of the cavity mold close to the driving roller assembly, through which the wire moves toward the material bearing surface;

wire rod feed mechanism still includes cutting mechanism, cutting mechanism includes cutter and cutting drive assembly, cutting drive assembly with the cutter is connected in order to drive the cutter to ejection of compact plane removes.

Compared with the prior art, the utility model has the beneficial effects that:

in the movable buckle processing equipment, the two cavity dies which are arranged oppositely are used as the lower forming die of the movable buckle, the first stamping die and the second stamping die are used as the upper forming die of the movable buckle, and the toggle part and the sliding part are respectively formed by two times of stamping, so that the movable buckle is obtained.

Drawings

FIG. 1 is a schematic structural view of a spring buckle according to the present invention;

FIG. 2 is a schematic top view of the removable button forming apparatus of the present invention;

FIG. 3 is a schematic perspective view of the movable buckle processing equipment of the present invention, including a forming device, an installation plate, an assembling device, and a wire feeding mechanism;

FIG. 4 is a schematic perspective view of another perspective view of the movable buckle processing apparatus of the present invention, including a forming device, an installation plate, an assembling device, and a wire feeding mechanism;

FIG. 5 is a schematic perspective view of the movable buckle processing apparatus of the present invention, including a forming device, an installation plate, and a wire feeding mechanism;

FIG. 6 is an enlarged view of a portion A of FIG. 5;

FIG. 7 is a schematic structural view of the second stamping die of FIG. 6 after rotation;

FIG. 8 is a schematic view of the assembled state of a cavity mold and a cavity driving assembly in the movable buckle processing apparatus according to the present invention;

FIG. 9 is an enlarged view of a portion B of FIG. 8;

FIG. 10 is a schematic view showing the structure of an assembling device in the removable button processing apparatus according to the present invention;

fig. 11 is a schematic view showing the moving state of the clamping jaws in the movable buckle processing equipment of the utility model.

In the figure:

1. a molding device; 11. a first stamping die; 12. a first mold drive assembly; 13. a second stamping die; 14. a second mold drive assembly; 141. a telescopic drive assembly; 142. a punch drive assembly; 143. a first rotary drive assembly; 15. a cavity mold; 151. a cavity surface; 152. a material bearing surface; 153. a first molding cavity; 154. a second molding cavity; 155. a material bearing groove; 156. a first positioning groove; 157. a second positioning groove; 16. a cavity drive assembly; 17. a mounting seat; 171. a sliding seat; 172. a rotating base; 173. a first telescopic rod;

2. mounting a plate; 21. a through hole;

3. an assembly device; 31. a clamping jaw mounting table; 311. mounting a rod; 32. a clamping jaw; 321. a clamping member; 33. a jaw drive assembly; 331. a second telescopic rod; 34. an angle adjustment assembly; 35. a second rotary drive assembly; 36. assembling a driving component;

4. a rotating table;

5. a wire feeding mechanism; 51. unwinding rollers; 52. driving the roller assembly; 521. driving the roller; 522. a roller power assembly; 53. correcting the roller; 54. a guide member; 541. a discharging plane; 55. a cutting mechanism; 551. a cutter; 552. a cutting drive assembly;

10. a spring buckle; 101. a housing; 102. buckling an interface; 103. a spring inlet; 104. a movable buckle; 105. a toggle part; 106. a sliding part; 107. the side is provided with an inlet.

Detailed Description

The present invention will be further described with reference to fig. 1 to 11 and the detailed description thereof, and it should be noted that, in the case of no conflict, any combination between the embodiments or technical features described below may form a new embodiment.

The utility model provides a processing device suitable for assembling a movable buckle 104 in a spring buckle 10, as shown in fig. 3, 6 and 9, in particular suitable for assembling the movable buckle 104 in the spring buckle 10. The movable buckle processing equipment comprises a forming device 1, a mounting plate 2, an assembling device 3, a rotating table 4 and a wire material feeding mechanism 5, wherein the wire material is bent and formed into a movable buckle 104 through the forming device 1, the mounting plate 2 is used for mounting the forming device 1 and the wire material feeding mechanism 5, and the assembling device 3 grabs the movable buckle 104 from the forming device 1 and loads the movable buckle 104 into a shell 101 on the rotating table 4.

As shown in fig. 3, the forming apparatus 1 includes a first stamping die 11, a first die driving assembly 12, a second stamping die 13, a second die driving assembly 14, and two cavity dies 15 disposed opposite to each other.

As shown in fig. 9, the cavity mold 15 is provided with a cavity surface 151 and a material receiving surface 152, and the material receiving surface 152 is adjacent to the cavity surface 151 and is used for carrying the wire before molding. The two cavity surfaces 151 are oppositely arranged, a first molding cavity 153 for molding the toggle part 105 and a second molding cavity 154 for molding the sliding part 106 are arranged on the cavity surfaces 151, and the second molding cavity 154 is close to the material bearing surface 152; a first stamping die 11 for pressing a part of the wire into the two first molding cavities 153; the first die driving component 12 is connected with the first stamping die 11, and the first die driving component 12 drives the first stamping die 11 to perform stamping action; the second stamping die 13 is used for pressing the wire into the two second molding cavities 154, and after the movable buckle 104 is subjected to punch forming, the formed movable buckle 104 is driven to discharge from the two cavity dies 15; and the second die driving component 14 is connected with the second stamping die 13 and is used for driving the second stamping die 13 to perform stamping action after the first stamping die 11 performs stamping action. In this embodiment, the two cavity molds 15 disposed opposite to each other are used as a lower forming mold of the movable buckle 104, the first stamping mold 11 and the second stamping mold 13 are used as an upper forming mold of the movable buckle 104, and the toggle portion 105 and the sliding portion 106 are formed by two stamping processes, so as to obtain the movable buckle 104.

The second stamping die 13 presses the wire into the two second molding cavities 154, and the sliding portion 106 in the movable buckle 104 clamps the second stamping die 13, so that after the movable buckle 104 is formed by punching, the second stamping die is used as a discharging mechanism of the movable buckle 104, and the second stamping die 13 drives the formed movable buckle 104 to move out of the first molding cavity 153 and the second molding cavity 154. The movable buckle 104 can be driven to discharge after being formed, so that the discharging convenience of the movable buckle 104 is improved, a discharging mechanism does not need to be additionally arranged, and the next process of the movable buckle 104 is facilitated.

In some embodiments, as shown in fig. 5, the forming apparatus 1 further includes a cavity driving assembly 16, and the cavity driving assembly 16 is connected to the two cavity molds 15 for driving the two cavity molds 15 to perform a pressing action after the second stamping mold 13 performs a stamping action. The two cavity molds 15 are pressed together, so that the left part and the right part of the movable buckle 104 are close to the middle, the size of the toggle part 105 in the left and right directions is reduced, and the size of the toggle part 105 is matched with the size of the spring buckle 10. In addition, when the movable buckle 104 is assembled on the casing 101, the space occupied by the toggle part 105 in the side loading opening can be reduced. In addition, the cavity driving assembly 16 drives the two cavity dies 15 to perform a pressing action, so that the force of the sliding part 106 clamping the second stamping die 13 is improved, and the movable buckle 104 is prevented from falling off from the second stamping die 13 during discharging.

Further, the cavity driving assembly 16 includes two linear modules, the two linear modules correspond to the two cavity molds 15 one by one, the linear modules are connected to the corresponding cavity molds 15, and the two cavity molds 15 move in opposite directions or depart from each other under the driving of the two linear modules.

In some embodiments, as shown in fig. 3 to 5, the movable buckle processing apparatus further includes a mounting plate 2, the forming device 1 further includes a mounting seat 17, the mounting seat 17 includes a sliding seat 171, a rotating seat 172 and a first telescopic rod 173, the sliding seat 171 is slidably disposed on the mounting plate 2 along a stamping direction, the rotating seat 172 is rotatably disposed on the sliding seat 171, the first telescopic rod 173 is slidably disposed on the rotating seat 172, a telescopic direction of the first telescopic rod 173 is perpendicular to the stamping direction and faces a gap between the two-cavity molds 15, and the second stamping mold 13 is fixed on the first telescopic rod 173.

The second mold driving assembly 14 includes a telescopic driving assembly 141, a stamping driving assembly 142 and a first rotating driving assembly 143, the stamping driving assembly 142 is connected to the sliding seat 171 to drive the second stamping mold 13 to perform stamping operation, the telescopic driving assembly 141 is connected to the first telescopic rod 173 to drive the first telescopic rod 173 to move away from the first stamping mold 11, and the first rotating driving assembly 143 is connected to the rotating seat 172 to drive the second stamping mold 13 and the movable buckle 104 to rotate.

During the forming process of the movable buckle 104, the first stamping die 11 firstly enters the first forming cavity 153 from top to bottom through the second forming cavity 154, and the second stamping die 13 also enters the second forming cavity 154 from top to bottom, so that there is interference between the first stamping die 11 and the second stamping die 13. Therefore, in this embodiment, the telescopic driving assembly 141 and the first telescopic rod 173 are provided, the telescopic driving assembly 141 drives the first telescopic rod 173 to perform telescopic motion, and before the first stamping die 11 performs stamping, the first telescopic rod 173 retracts to drive the second stamping die 13 to leave the first stamping die 11. After the first stamping die 11 is stamped, the telescopic driving assembly 141 drives the second stamping die 13 to extend through the first telescopic rod 173, and then the stamping driving assembly 142 drives the sliding seat 171 to slide downwards, so as to perform stamping action; after the cavity driving assembly 16 drives the two cavity molds 15 to perform a pressing operation, the punch driving assembly 142 drives the sliding seat 171 to slide upwards to take out the formed movable buckle 104. Finally, the first rotation driving assembly 143 drives the rotating base 172 to rotate, and the rotating base 172 drives the first telescopic rod 173 to rotate, so as to finally rotate the second stamping die 13, thereby adjusting the angle of the movable buckle 104. Therefore, in this embodiment, the sliding seat 171, the rotating seat 172, the first telescopic rod 173, the telescopic driving assembly 141, the punching driving assembly 142, and the first rotating driving assembly 143 are provided to realize the punching movable buckle 104, and simultaneously, the interference of the movement can be avoided, and the angle of the movable buckle 104 can be adjusted.

As shown in fig. 6 and 7, the mounting plate 2 is provided with a through hole 21 through which at least the first telescopic rod 173 can be inserted. The shape of the through hole 21 may be a rectangular through hole 21, a circle or an ellipse, and the rectangular through hole 21 is preferable in the present embodiment. Of course, the size of the through hole 21 may be increased to allow the rotary seat 172 to pass through. It is also possible to increase the size of the through-hole 21 so that the through-hole 21 can receive a part of the sliding seat 171 to provide a sliding space for the sliding seat 171. The sliding seat 171 is a position for applying a punching force to the punching driving assembly 142, and the end of the second punching mold 13 is a direct punching position, so that when the sliding seat 171 partially extends into the through hole 21, the distance between the sliding seat 171 and the cavity mold 15 can be reduced, the bending moment of the second punching mold 13 during punching can be reduced, and the bending deformation of the second punching mold 13 can be reduced.

In some embodiments, as shown in fig. 8 and 9, at least one material receiving surface 152 is provided with a material receiving groove 155 for limiting the position of the wire. In this embodiment, the wire is positioned by the material receiving groove 155, so that the wire is prevented from shifting when the first stamping die 11 performs stamping operation. In this embodiment, it is preferable that the material receiving grooves 155 are formed on both the material receiving surfaces 152, and the wires are positioned from both ends of the wires, thereby increasing the positioning effect on the wires.

In some embodiments, as shown in fig. 9, a first positioning groove 156 for limiting the position of the wire is provided in the first molding cavity 153; a second positioning groove 157 for limiting the position of the wire is provided in the second molding cavity 154, and the second positioning groove 157 communicates with the first positioning groove 156. In this embodiment, in the first molding cavity 153, the first positioning groove 156 can position the wire rod pressed into the first molding cavity 153, so as to prevent the wire rod from shifting when the second pressing mold 13 performs a pressing operation, and also prevent the wire rod in the first molding cavity 153 from shifting when the two molding cavity molds 15 perform a pressing operation. In the second molding cavity 154, the second positioning groove 157 can position the wire rod pressed into the second molding cavity 154 to prevent the wire rod from deviating when the second pressing mold 13 performs a pressing operation, and also can prevent the wire rod from deviating in the second molding cavity 154 when the two molding cavity molds 15 perform a pressing operation. The first positioning groove 156 and the second positioning groove 157 can guide the wire to be precisely formed according to a preset shape, and the yield and the forming precision of the movable buckle 104 are improved.

In some embodiments, as shown in fig. 3 and 4, the moveable fastener processing apparatus further comprises a mounting device 3, and the mounting device 3 grabs the toggle part 105 of the moveable fastener 104 and mounts into the housing 101 of the spring fastener 10.

Specifically, as shown in fig. 10 and 11, the assembling apparatus 3 includes a jaw mounting table 31, a jaw 32, a jaw driving unit 33, an angle adjusting unit 34, a second rotation driving unit 35, and an assembling driving unit 36.

The jaw mounting table 31 is provided with a rotatable mounting rod 311, and the jaws 32 are provided on the mounting rod 311.

The clamping jaw driving assembly 33 is connected with the clamping jaw 32 and used for driving the clamping jaw 32 to open and close.

The angle adjusting assembly 34 is connected with the mounting rod 311 to drive the mounting rod 311 to rotate so as to adjust the opening and closing directions of the clamping jaws 32.

And a second rotary driving assembly 35 connected with the clamping jaw mounting table 31 and used for driving the clamping jaw 32 to move between a forming and blanking position and a station for fixing the spring fastener 10.

The assembly drive assembly 36 is connected to the jaw mounting table to drive the jaw mounting table 31 to move toward the side loading opening of the housing 101, and the movable catch 104 on the jaw 32 is loaded into the housing 101 as the jaw mounting table 31 moves. In the forming device 1, the first stamping die 11 and the second stamping die 13 respectively stamp the wire from top to bottom, and the movable buckle 104 is taken out by the second stamping die 13, and finally, the second stamping die 13 and the movable buckle 104 are driven to rotate by the first rotating driving component 143, so that the angle of the movable buckle 104 is as shown in fig. 7 and 11, and the actual housing 101 is horizontally fixed. Therefore, in this embodiment, the assembly driving component 36 drives the clamping jaws 32 to grab the movable buckle 104, and the angle of the movable buckle 104 is adjusted through the matching of the angle adjusting component 34 and the mounting rod 311, so that the movable buckle 104 is matched with the side loading opening on the casing 101, and the assembly and the angle adjustment of the movable buckle 104 are completed.

In some embodiments, as shown in fig. 10 and 11, the clamping jaw 32 includes two clamping members 321, one end of each clamping member 321 is a clamping portion, the other end of each clamping member 321 is a handle portion, the two clamping members 321 are oppositely arranged, and the middle portions of the two clamping members 321 are hinged. More specifically, the two clamping members 321 are hinged by means of a hinge shaft fixed to the aforesaid mounting rod 311.

Specifically, the clamping jaw driving assembly 33 includes a second telescopic rod 331, the second telescopic rod 331 of the clamping jaw driving assembly 33 can perform telescopic movement, a guide hole extending along the axial direction is formed in the mounting rod 311, the end of the second telescopic rod 331 is wedge-shaped, and the end of the second telescopic rod 331 passes through the guide hole and extends to between the two clamping members 321, specifically to between the handles of the two clamping members 321. The second telescopic rod 331 extends, the second telescopic rod 331 pushes the handle parts of the two clamping pieces 321 open, so that the clamping parts of the two clamping pieces 321 are clamped, the second telescopic rod 331 contracts, the handle parts of the two clamping pieces 321 reset, the clamping parts of the two clamping pieces 321 expand, and the telescopic motion of the second telescopic rod 331 controls the clamping jaw 32 to clamp and loosen the movable buckle.

In some embodiments, as shown in fig. 2, the moveable fastener processing apparatus further comprises a rotating table 4, and the rotating table 4 is provided with a plurality of stations for fixing the snap fasteners 10. In this embodiment, the rotating table 4 is provided to automatically switch the spring fastener 10, thereby improving the assembling efficiency of the movable fastener 104.

In some embodiments, as shown in fig. 3 to 5, the movable buckle processing apparatus further includes a wire feeding mechanism 5, the wire feeding mechanism 5 includes an unwinding roller 51 and a driving roller assembly 52, the unwinding roller 51 winds the wire thereon, and the unwinding roller 51 is used for unwinding the wire. The wire passes through the driving roller assembly 52, the driving roller assembly 52 pulls the wire to be discharged from the unwinding roller 51, and pulls the wire to move towards the material bearing surface 152, so that the wire feeding is realized.

Further, as shown in fig. 3 to 5, the wire feeding mechanism 5 further includes a correcting roller assembly located between the unwinding roller 51 and the driving roller assembly 52, the correcting roller assembly including a plurality of correcting rollers 53, wherein a part of the correcting rollers 53 is located below the wire, another part of the correcting rollers 53 is located above the wire, and two adjacent correcting rollers 53 are located one above the wire and the other below the wire. The wire is wound up and unwound from the winding and unwinding roller 51, so that the wire is bent, which may cause the wire not to be aligned with the material receiving groove 155 of the material receiving surface 152. In this embodiment, the straightening roller assembly is arranged to straighten the wire rod, so that the wire rod is returned to a straight state, and the wire rod is conveniently and accurately fed to the material receiving surface 152 and accurately enters the material receiving groove 155 in the foregoing.

In some embodiments, as shown in fig. 6 and 7, the wire feeding mechanism 5 further includes a discharging plane 541, the discharging plane 541 is located at a side of the cavity mold 15 close to the driving roller assembly 52, and the wire moves toward the material receiving surface 152 through the discharging plane 541. The wire feeding mechanism 5 further comprises a cutting mechanism 55, wherein the cutting mechanism 55 comprises a cutter 551 and a cutting driving assembly 552, and the cutting driving assembly 552 is connected with the cutter 551 to drive the cutter 551 to move towards the discharging plane 541 so as to cut the wire.

In some embodiments, as shown in fig. 6 and 7, the wire feeding mechanism 5 further includes a guide 54 for guiding the wire to move toward the material receiving surface 152, and a side of the guide 54 close to the cavity mold 15 is provided with the aforementioned discharging plane 541, and the wire moves toward the material receiving surface 152 through the discharging plane 541. The guide 54 is provided with a guide slot therein through which the wire passes and passes the discharge plane 541, and the guide 54 is provided to guide and support the wire to be fed toward the loading surface 152.

In some embodiments, as shown in fig. 3 to 5, for the aforementioned mounting plate 2, the mounting plate 2 is a mounting structure of the wire feeding mechanism 5, the cutting mechanism 55, and the molding device 1. The wire feeding mechanism 5 is arranged at the feeding end of the mounting plate 2, the forming device 1 is arranged at the forming end of the mounting plate 2, and the cutting mechanism 55 is arranged between the wire feeding mechanism 5 and the forming device 1.

Specifically, with the wire feeding mechanism 5, the unwinding roller 51 is fixed to the front face of the feeding end of the mounting plate 2 by a connecting member, the leveling roller assembly is provided to the front face of the mounting plate 2, the leveling rollers 53 are provided to the front face of the mounting plate 2 side by side in two rows from top to bottom and two rows of the leveling rollers 53 extend from the feeding end to the forming end. The driving roller assembly 52 includes two driving rollers 521 and a roller power assembly 522, wherein the two driving rollers 521 are disposed on the front surface of the mounting plate 2 and located on one side of the correcting roller assembly near the forming end, the roller power assembly 522 is disposed on the back surface of the mounting plate 2, and the roller power assembly 522 is connected with the two driving rollers 521 and drives the two driving rollers 521 to rotate. The guide 54 is located on the side of the two drive rollers 521 near the forming end, and the guide 54 extends toward the forming end.

In the cutting mechanism 55, a cutter 551 is located on the front surface of the mounting plate 2, and a cutting drive assembly 552 is fixed on the plate of the mounting plate 2.

The above embodiments are only preferred embodiments of the present invention, and the protection scope of the present invention is not limited thereby, and any insubstantial changes and substitutions made by those skilled in the art based on the present invention are within the protection scope of the present invention.

Claims (10)

1. The utility model provides a processing equipment is detained in activity which characterized in that, includes forming device, forming device includes:

the wire rod forming die comprises two cavity dies arranged oppositely, wherein each cavity die is provided with a cavity surface and a material bearing surface which is adjacent to the cavity surface and used for bearing a wire rod before forming, the two cavity surfaces are arranged oppositely, a first forming cavity used for forming a shifting part and a second forming cavity used for forming a sliding part are arranged on the cavity surfaces, and the second forming cavity is close to the material bearing surface;

the first stamping die is used for pressing part of the wire rods into the two first forming cavities;

the first die driving assembly is connected with the first stamping die to drive the first stamping die to perform stamping action;

the second stamping die is used for pressing the wire into the two second forming cavities and driving the formed movable buckle to discharge from the two cavity dies; and

and the second die driving component is connected with the second stamping die and is used for driving the second stamping die to do stamping action after the first stamping die does stamping action.

2. The removable button processing apparatus according to claim 1, wherein: the forming device further comprises a cavity driving assembly, and the cavity driving assembly is connected with the two cavity dies and used for driving the two cavity dies to perform pressing action after the second stamping die performs stamping action.

3. The removable button processing apparatus according to claim 1, wherein: the movable buckle processing equipment also comprises a mounting plate;

the forming device further comprises a mounting seat, the mounting seat comprises a sliding seat, a rotating seat and a first telescopic rod, the sliding seat is arranged on the mounting plate in a sliding mode along the stamping action direction, the rotating seat is rotatably arranged on the sliding seat, the first telescopic rod is arranged on the rotating seat in a sliding mode, the telescopic direction of the first telescopic rod is perpendicular to the stamping action direction and faces to the gap between the two cavity dies, and the second stamping die is fixed on the first telescopic rod;

the second die driving assembly comprises a telescopic driving assembly, a stamping driving assembly and a first rotary driving assembly, the stamping driving assembly is connected with the sliding seat to drive the second stamping die to perform stamping action, the telescopic driving assembly is connected with the first telescopic rod to drive the first telescopic rod to avoid the first stamping die, and the first rotary driving assembly is connected with the rotary seat to drive the second stamping die and the movable buckle to rotate.

4. The removable button processing apparatus according to claim 1, wherein: and a material bearing groove for limiting the position of the wire rod is arranged on at least one material bearing surface.

5. The removable button processing apparatus according to claim 1, wherein: a first positioning groove used for limiting the position of a wire rod is arranged in the first molding cavity;

and a second positioning groove used for limiting the position of the wire rod is arranged in the second molding cavity, and the second positioning groove is communicated with the first positioning groove.

6. The removable button processing apparatus according to any one of claims 1 to 5, wherein: the movable buckle processing equipment further comprises an assembling device, and the assembling device grabs the shifting part of the movable buckle and assembles the shifting part into the shell of the spring buckle.

7. The removable button processing apparatus according to claim 6, wherein: the assembling apparatus includes:

the clamping jaw mounting table is provided with a rotatable mounting rod;

the clamping jaw is arranged on the mounting rod;

the clamping jaw driving assembly is connected with the clamping jaw and used for driving the clamping jaw to open and close;

the angle adjusting assembly is connected with the mounting rod and used for adjusting the opening and closing directions of the clamping jaws;

the second rotary driving assembly is connected with the clamping jaw mounting table and used for driving the clamping jaw to move between a forming and blanking position and a station for fixing a workpiece;

and the assembly driving assembly is connected with the clamping jaw mounting table to drive the clamping jaw mounting table to move towards the side loading port of the shell.

8. The removable button processing apparatus according to claim 1, wherein: the movable buckle processing equipment further comprises a rotating table, and a plurality of stations for fixing workpieces are arranged on the rotating table.

9. The removable button processing apparatus according to claim 1, wherein: the activity is detained processing equipment and is still included wire rod feed mechanism, wire rod feed mechanism includes:

an unwinding roller for unwinding the wire;

and driving the roller assembly to pull the wire to move towards the material bearing surface.

10. The removable button processing apparatus according to claim 9, wherein: the wire rod feeding mechanism further comprises a discharging plane, the discharging plane is located on one side of the cavity die close to the driving roller assembly, and a wire rod moves to the material bearing surface through the discharging plane;

wire rod feed mechanism still includes cutting mechanism, cutting mechanism includes cutter and cutting drive assembly, cutting drive assembly with the cutter is connected in order to drive the cutter to ejection of compact plane removes.

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