CN109746317B - Equipment for manufacturing hoop buckle device - Google Patents

Abstract

The invention belongs to the technical field of mechanical equipment, in particular to equipment for manufacturing a buckle device. The invention aims to provide equipment for manufacturing a buckle device, which has the advantages of high processing speed, simple structure, low cost, convenient assembly and long service life. The purpose of the invention is realized in the following way: the equipment for manufacturing the hoop buckle device comprises a frame, wherein a blanking mechanism, a slideway mechanism, a stamping mechanism and a discharging mechanism are arranged on the frame; the machine frame comprises an upper machine frame and a lower machine frame, and a power device for providing up-and-down reciprocating motion power for the stamping mechanism is arranged on the upper machine frame; the blanking mechanism comprises a trough, and a blanking opening is formed in the end part of the side of the trough; a feeding rotating shaft is arranged below the discharging opening, a material placing groove which is arranged opposite to the discharging opening is formed in the axial direction of the outer end surface of the feeding rotating shaft, and the material placing groove can only accommodate one raw material to enter; the slide way mechanism is arranged below the feeding rotating shaft.

Description

Equipment for manufacturing hoop buckle device

Technical Field

The invention belongs to the technical field of mechanical equipment, in particular to equipment for manufacturing a buckle device.

Background

At present, greenhouse cultivation technology is playing an increasing role for national vegetable supply. Therefore, the demand of the related equipment and accessories of the greenhouse is very large, and the method has great significance for the national stable fruit and vegetable price and ensuring the daily life of residents. Meanwhile, when the greenhouse is installed, because the field is large, the stress between the frameworks is strong, and the construction characteristics of the greenhouse are not suitable for industrial operation or mechanical arm operation, so that the greenhouse accessories which are simple and practical and can save relatively labor are particularly important.

Particularly, an authorized bulletin number CN 101451566B discloses a hoop buckling device, which comprises a hoop groove, a left groove, a right groove, a left claw arm, a right claw arm, a left hoop buckling claw and a right hoop buckling claw, wherein the hoop groove is arched upwards, the left side and the right side of the hoop groove are respectively extended to form the left groove and the right groove, one ends of the left groove and the right groove opposite to the hoop groove are respectively extended to form the left claw arm and the right claw arm, the end part of the left claw arm is provided with the left hoop buckling claw, the end part of the right claw arm is provided with the right hoop buckling claw, and the left hoop buckling claw and the right hoop buckling claw are in arched semicircular arc and are oppositely folded and parallel.

Because of the characteristics of simple operation, convenient use, time saving, labor and material cost saving, good fastening effect, reusability and the like, the cross bracket fastening device is widely demanded in the field of fastening devices for fastening cross brackets. However, since the shape of the buckle device is special, if the conventional method is adopted, the process is more and the efficiency is lower, so that a device is required for rapidly manufacturing the buckle device.

Disclosure of Invention

The invention aims to provide equipment for manufacturing a buckle device, which has the advantages of high processing speed, simple structure, low cost, convenient assembly and long service life.

The purpose of the invention is realized in the following way: the equipment for manufacturing the hoop buckle device comprises a frame, wherein a blanking mechanism is arranged on the frame and is provided with a trough, a blanking opening is formed in the end part of the side of the trough, and raw materials in the trough sequentially enter a slideway mechanism through the blanking opening;

the slide way mechanism comprises a sliding table for feeding in a reciprocating manner, and a plurality of groups of push heads for pushing raw materials into one working procedure of the stamping mechanism are arranged on the sliding table;

the stamping mechanism is provided with a plurality of stamping stations and is used for stamping and forming raw materials; and is collected by a discharging mechanism the finished product is delivered to a material bearing position;

the upper end of the frame is provided with a power device which provides power for the punching mechanism to reciprocate up and down.

Preferably, a feeding rotating shaft is arranged below the blanking opening, a material placing groove which is arranged opposite to the blanking opening is formed in the axial direction of the outer end surface of the feeding rotating shaft, and the material placing groove can only accommodate one raw material to enter; the slide way mechanism is arranged below the feeding rotating shaft.

Preferably, a plurality of protruding edges are formed on the feeding rotating shaft, the material placing grooves are formed on the protruding edges, and the material placing grooves are axially aligned.

Preferably, the side wall of the trough is provided with a plurality of longitudinal open grooves, and eccentric wheels are adapted to the open grooves.

Preferably, the discharging mechanism comprises a material distributing fork for sorting raw materials, the upper end part of the material distributing fork is in butt joint with the discharging opening, the material distributing fork is provided with a material distributing opening, and the material distributing opening is adapted to and wound on the outer side of the feeding rotating shaft and is arranged towards the feeding rotating shaft.

Preferably, the pushing head is provided with an inclined plane, a pushing head groove matched with the pushing head is formed on the sliding table, a compression spring is fixedly arranged at the bottom of the pushing head groove, and the compression spring abuts against the lower end part of the pushing head.

Preferably, a limiting rod is arranged above two sides of the sliding table along the direction of the sliding table, and the limiting rod is used for limiting the up-and-down movement of the raw materials.

Preferably, the stamping mechanism comprises a stamping part, wherein the stamping part comprises an upper die I arranged on the upper frame and a lower die I matched with the upper die I; the first upper stamping die is arranged on two sides of the sliding table and is of an inverted U-shaped design; the lower punch die I is in a platform shape and is arranged on the inner side of the upper punch die I; an upper sub-die I is formed on the outer side of the upper die I, an inclined plane I is formed on one side, close to the sliding table, of the upper sub-die I, a lower sub-die I which is opposite to the inclined plane I is arranged on one side of the lower die I, and the inclined plane I of the upper sub-die I drives and extrudes raw materials to form through abutting action in the descending process; the lower sub-die I comprises a sub-die I support, the sub-die I support is provided with a mounting hole, a push rod is arranged in the mounting hole in a penetrating mode, and a reset spring capable of achieving reciprocating motion of the push rod is sleeved between the push rod and the wall of the mounting hole.

Preferably, the stamping mechanism comprises a stamping part three, wherein the stamping part three comprises a forming groove III arranged on the sliding table, and a forming column III which is arranged opposite to the forming groove III is arranged on the lower rack; the sliding table is provided with a step part, a stop block is sleeved on one end, close to the step part, of the limiting rod in a telescopic manner, the stop block is provided with an inclined plane, and the inclined plane is abutted against the step part; the upper frame is provided with an elastic limiting piece for controlling the time of raw materials entering the step part.

Preferably, the two sides of the forming groove III are respectively formed with a limiting column, the periphery of the limiting column is sunken with a limiting groove, and the limiting groove is used for pushing the raw materials to the forming groove III.

Preferably, the stamping mechanism comprises a stamping four part, the stamping four part comprises an upper die four and a stamping four lower die which are connected to the upper frame, the upper die four is formed with a molding strip four and a molding strip five, and the stamping four lower die is respectively formed with a molding groove four and a molding groove five which are matched with the molding strip four and the molding strip five; the forming strip five comprises a forming block I and a connecting block I, a guide column is arranged on the upper side face of the forming block I, a spring is sleeved on the guide column, the spring is propped between the forming block I and the connecting block I, and a limit nut is sleeved above the connecting block I through the guide column.

Preferably, one side of the four stamping parts is provided with the material bearing part, the feeding device is provided with an inductor for inducing that the raw materials are processed, the inductor is connected with the feeding device, and the feeding device can send the processed raw materials to the material bearing part.

Compared with the prior art, the invention has the following outstanding and beneficial technical effects:

1. the structure adopts a fully-automatic design thought, and after raw materials enter the material placing groove, the power device drives the upper punching die and the slideway mechanism, so that full-automatic feeding and punching forming can be realized. And conveying the product to a designated position by a discharging mechanism after molding. Therefore, the whole system completes the processing of the parts, is very trouble-saving and labor-saving, and has very high efficiency.

2. The equipment has clear and definite steps and boundaries for each procedure. And each procedure is pushed to a designated position by a specific push head, so that the method is very concise. Thus, the efficiency of the part processing is high, and the output rate is very regular.

3. Compared with the current situation that the prior manufacturing process adopts repeated stamping of a plurality of devices, the technical equipment is specially used for manufacturing the buckle device, and the equipment has no considered factors because of full-automatic design, so that the processing precision and the processing efficiency of products are greatly improved.

Drawings

FIG. 1 is one of the structural schematic diagrams of the present invention;

FIG. 2 is a second schematic diagram of the structure of the present invention;

FIG. 3 is one of the schematic structural diagrams of the blanking mechanism;

FIG. 4 is a second schematic diagram of the blanking mechanism;

FIG. 5 is a schematic view of the crank link assembly;

FIG. 6 is a partial enlarged view at A;

FIG. 7 is a schematic view of a structure of a part of the press;

FIG. 8 is a schematic view of the structure of the two parts of the press;

FIG. 9 is a schematic view of the structure of the three and four stamped parts;

FIG. 10 is a partial enlarged view at B;

FIG. 11 is a schematic illustration of the feedstock after a stamping process;

FIG. 12 is a schematic illustration of the feedstock after a stamping two-part process;

FIG. 13 is a schematic illustration of the feedstock after a three-part stamping process;

fig. 14 is a schematic view of the raw material after the four-part press working.

In the figure: 1-a frame; 2-a blanking mechanism; 3-a slide mechanism; 4-a stamping mechanism; 5-a discharging device; 6-power plant; 7-crank connecting rod device; 8-raw materials; 21-a trough; 22-a feed opening; 23-feeding a rotating shaft; 24-placing a trough; 25-separating a tooth fork; 26-eccentric wheel; 31-pushing head; 32-sliding rails; 33-sliding table; 34-push head groove; 35-compressing a spring; 36-limiting rods; 37-elastic sheet; 41-stamping a part; 42-stamping two parts; 43-stamping three parts; 44-stamping four parts; 51-a material bearing part; 53-inductor; 71-connecting rod; 72-rotating disc; 211-open slots; 251-a dispensing opening; 331-a receiving groove; 332-connecting holes; 333-inclined plane; 334-step; 361-a stop; 362-slope two; 411-on a first stamping die; 412-lower die one; 413—sub-die one; 414-sub-die two; 416-sub-die-one rack; 417-ejector pins; 418-first bevel; 421-upper punch second; 422-lower punch second; 423-forming groove II; 424-bump two; 431-forming groove III; 432-forming column three; 433-limit column; 434-a limit groove; 441-upper die four; 442-lower die four; 443-molding a fourth strip; 444-forming a fifth strip; 445-forming slot four; 446-forming groove five; 447-forming blocks; 448-connection block one; 449-guide posts; 450-springs.

Detailed Description

The invention is further described below with reference to specific examples.

Embodiment one: 1-14, the device for manufacturing the buckle device comprises a frame 1, wherein a blanking mechanism 2 is arranged on the frame 1, the blanking mechanism 2 is provided with a trough 21, a blanking opening 22 is arranged at the end part of the trough 21 side, and raw materials 8 in the trough 21 sequentially enter a slideway mechanism 3 through the blanking opening 22;

the slideway mechanism 3 comprises a reciprocating feeding sliding table 33, and a plurality of groups of push heads 31 for pushing the raw materials 8 into one process of the stamping mechanism 4 are arranged on the sliding table 33;

the stamping mechanism 4 is provided with a plurality of stamping stations for stamping and forming the raw material 8; and collecting the finished product to a material bearing position 51 by a discharging mechanism 5;

the upper end part of the frame 1 is provided with a power device 6, and the power device 6 provides power for the stamping mechanism 4 to reciprocate up and down.

By means of the design, the structure adopts a fully-automatic design thought, after the raw materials 8 enter the material placing groove 24, the punching die and the slideway mechanism 3 are driven by the power device 6, the slideway mechanism 3 conveys the raw materials 8 to a plurality of working procedures above the punching mechanism 4, and after all working procedures are completed, full-automatic feeding and punching forming can be achieved. Until the product is transported to a designated position by a discharging mechanism 5 after molding. Therefore, the whole system finishes the processing of parts, so that the labor and the trouble are saved, the speed is high, and the efficiency is high; in addition, the power device 6 of the design can drive all working procedures on the stamping mechanism 4 in a linkage way, namely, when the power device 6 provides power for lifting or lowering once, the working procedures on the stamping mechanism 4 can all move together. Thus, a plurality of processes can be completed at the same time.

Preferably, as shown in fig. 1-2, the power device 6 is connected with all the upper dies in the punching sub-part, so that one power device 6 can control and drive the movement of the whole upper die; the power device 6 is connected with a crank connecting rod device 7 in the slideway mechanism 3 through a chain. The technical scheme provides a scheme that a plurality of procedures can be completed at one time. The power device 6 can complete a whole process by one reciprocating motion, thus greatly improving the working efficiency.

Preferably, as shown in fig. 1-4, the discharging mechanism 2 includes a material distributing fork 25 for sorting the raw materials 8, the upper end of the material distributing fork 25 abuts against the discharging opening 22, the material distributing fork 25 is provided with a material distributing opening 251, and the material distributing opening 251 is adapted to and wound on the outer side of the feeding rotating shaft 23 and is disposed towards the feeding rotating shaft 23. The design of the material distributing tooth fork 25 can ensure that the raw material 8 in the material placing groove 24 cannot be separated from the material feeding rotating shaft 23 due to rotation in the rotating process of the material feeding rotating shaft 23. The whole equipment is ensured to operate orderly. In actual production, the upper end of the feed fork 25 is located at a distance from the feed opening 22 and is intended to be accessible for a raw material 8, so that a subsequent orderly operation is ensured.

Preferably, as shown in fig. 1-4, the side wall of the trough 21 is provided with a plurality of longitudinal open slots 211, and an eccentric wheel 26 adapted to the open slots 211 is arranged above the material dividing fork 25. The preferred direction of rotation of the eccentric 26 may be opposite to the direction of rotation of the feed shaft 23. The eccentric 26 may preferably be an eccentric, so that the eccentric 26, when rotated, moves the material 8 more orderly in a direction away from the feed opening 22 and again towards the feed opening 22 under the force of gravity. Such a reciprocating design ensures that the raw material 8 can enter the feed opening 22 more orderly. In practice, the eccentric 26 should be spaced from the feed opening 22 and be accessible for one feedstock 8.

Preferably, as shown in fig. 1, 2, 5 or 6, a plurality of protruding edges 231 are formed on the feeding rotating shaft 23, and the material placing grooves 24 are formed on the protruding edges 231, and the material placing grooves 24 are axially aligned. The convex edge 231 designed by the technical scheme can simplify the structure on the basis of realizing the original bearing of the raw material 8. The groove on the shaft is now required to be formed entirely, and only two convex edges 231 are required. Moreover, the design of the convex edge 231 can enable the raw material 8 to enter the material placing groove 24 more easily due to the reduction of the contact area, so that the cost of manufacturing equipment is greatly reduced.

Preferably, as shown in fig. 1 or 2 or 5 or 6, the flange 231 and the feeding shaft 23 are connected to the assembly by a flat key. The convex edge 231 is connected with the feeding rotating shaft 23 through a flat key, the design is more convenient to assemble in actual production, and is beneficial to later maintenance.

Preferably, as shown in fig. 1, 2 or 5, the crank-link device 7 includes a link 71, two sides of the link 71 are respectively hinged with the turntable 72 and the sliding table 33, one end of the sliding table 33 is formed with a receiving groove 331, two sides of the receiving groove 331 are formed with a connecting hole 332, and the link 71 is disposed in the receiving groove 331 and is hinged with the other end of the link 71 through the connecting hole 332. According to the technical scheme, the crank connecting rod device 7 and the sliding table 33 can be connected through the power device 6, so that reciprocating motion of the sliding table 33 is realized, and the effect of conveying the raw materials 8 to a designated station is realized.

Preferably, as shown in fig. 6, the sliding table 33 is provided with a push head groove 34 adapted to the push head 31, a compression spring 35 is fixedly arranged at the bottom of the push head groove 34, and the compression spring 35 abuts against the lower end part of the push head 31. The action of the technical scheme can ensure that the sliding table 33 can not bring the raw material 8 away from the station in the backward process after one-time pushing. When the raw material 8 passes through, the pushing head 31 is embedded into the pushing head groove 34 under the action of the compression spring 35, so that the raw material can be smoothly retracted to a designated position, and then pushing in the next round is performed. The technical scheme is more perfect and meets the requirements of actual production. Meanwhile, in the actual use process, a magnet is arranged on the surface of the sliding rail 32, and the magnet is used for adsorbing the workpiece, so that the workpiece cannot run everywhere and deviate when the pushing head 31 pushes the workpiece. Thereby ensuring that the appearance of each product is consistent, and reducing the error of the product.

Preferably, as shown in fig. 6, the pusher 31 on the slide table 33 is provided with an inclined surface 333, and the inclined surface 333 is disposed toward a side away from the crank link 71. By adopting the design, the inclined surface 362 of the push head 31 can be designed to be smoother in the retreating process in the operation process of the actual sliding table 33, so that the obstruction is reduced.

Preferably, as shown in fig. 1 or 2, a limiting rod 36 is disposed above two sides of the sliding table 33 along the direction of the sliding table 33, and the limiting rod 36 is used for limiting the up-and-down movement of the raw material 8. The stopper rod 36 is designed to reduce the displacement of the material 8 caused by the vertical movement of the material 8 during actual production, and prevent the material 8 from being separated from the die.

Preferably, as shown in fig. 7, the stamping mechanism 4 includes a stamping part 41, and the stamping part 41 includes an upper die 411 provided at the upper end of the frame 1 and a lower die 412 adapted to the upper die 411; the first upper punch 411 is arranged at two sides of the sliding table 33 and is of an inverted U-shaped design; the first lower die 412 is in a platform shape and is arranged on the inner side of the first upper die 411; an upper sub-die I413 is formed on the outer side of the upper die I411, an inclined plane I418 is formed on one side of the upper sub-die I413 close to the sliding table, a lower sub-die I414 which is opposite to the inclined plane I418 is arranged on one side of the lower die I412, and the inclined plane I418 of the upper sub-die I413 drives and extrudes raw materials to form through abutting action in the descending process; the lower sub-die A414 comprises a sub-die A bracket 416, the sub-die A bracket 416 is formed with a mounting hole, a push rod 417 is penetrated in the mounting hole, and a reset spring 450 capable of realizing reciprocating motion of the push rod 417 is sleeved between the push rod 417 and the wall of the mounting hole. The thus designed dies not only can rapidly complete the punching process, but also can complete the punching between the upper die one 411 and the lower die one 412 and the punching of the upper sub-die one 413 and the lower sub-die one 414 twice with only one movement. The problem that the stamping is not in place due to insufficient stroke of the stamping die can be solved, and the raw material 8 can be stamped and formed each time. The structure can also be extended to other structures, so that the power of one-time stamping can be fully utilized.

Preferably, as shown in fig. 1 or 8, the second stamping part 42 includes a second upper die 421 and a second lower die 422, where the second upper die 421 is connected to the power unit 6; the lower end of the second upper die 421 is recessed with a second molding groove 423, and the second lower die 422 is disposed at two sides of the sliding table 33 and is molded with a second protrusion 424 adapted to the second molding groove 423. When the first stamping part 41 is finished, the pushing head conveys the raw materials to the second stamping part 42, and the second stamping part can be used for forming one working procedure of the product through one-time stamping, so that the method is a preferable technical scheme in actual production and accords with the arrangement of the process of the product.

Preferably, as shown in fig. 1 or 8, the second upper punch 421 includes two upper punch dies respectively disposed on two sides of the upper end of the frame 1, the second forming grooves 423 are disposed on the two upper punch dies, the second lower punch 422 includes two lower punch dies disposed opposite to the two upper punch dies, and the second protrusion 424 is disposed on the two lower punch dies. The scheme of dividing both sides design can make things convenient for maintenance and after-sale.

Preferably, as shown in fig. 1, 9 or 10, the third stamping part 43 includes a third molding groove 431 disposed on the sliding table 33, and the third molding post 432 disposed opposite to the third molding groove 431 is disposed on the lower frame 12. When the raw material 8 is transported to the third molding column 432 by the third molding groove 431 on the sliding table 33, the raw material 8 is naturally bent according to the shape of the third molding column 432, thus completing a procedure, and being simple and convenient.

Preferably, as shown in fig. 1, 9 or 10, two sides of the third molding groove 431 are respectively molded with a limit post 433, and a limit groove 434 is recessed in the periphery of the limit post 433, and the limit groove 434 is used for pushing the raw material 8 to the third molding groove 432. In this technical scheme, raw materials 8 card is in spacing groove 434, and the removal through slip table 33 pushes raw materials 8 to spacing post 433 department. The design can ensure that the position of the raw material 8 is relatively fixed in the pushing process, and particularly can also play a role in limiting and abutting in the bending process of the raw material 8.

Preferably, as shown in fig. 1, 9 or 10, the sliding table 33 is provided with a step portion 334, one end of the limiting rod 36 near the step portion 334 is telescopically sleeved with a stop 361, the stop 361 is provided with an inclined surface 362, and the inclined surface 362 abuts against the step part 334; an elastic limiting piece 37 is arranged at the upper end of the frame 1 and used for controlling the time when the raw material 8 enters the stepped part 334. When the raw material 8 is pushed to the step portion 334 by the slide table 33, the raw material 8 is stopped by the stopper 361 to ensure that the raw material 8 does not leave the station by inertia. The purpose of the elastic sheet is also to further limit its position.

Preferably, as shown in fig. 1, 9 or 10, the stamping four part 44 includes an upper die four 441 and a lower die four 442 connected to the upper end of the frame 1, the upper die four 441 is formed with a molding strip four 443 and a molding strip five 444, and the lower die four 442 is formed with a molding groove four 445 and a molding groove five 446 which are respectively matched with the molding strip four 443 and the molding strip five 444. Two forming columns are arranged on one stamping die, so that the forming of two parts can be completed by one stamping, and the processing efficiency is further improved.

Preferably, as shown in fig. 1, 9 or 10, the molding strip five 444 includes a molding block one 447 and a connection block one 448, a guide post 449 is disposed on the upper side of the molding block, a spring 450 is sleeved on the guide post 449, the spring 450 abuts between the molding block one 447 and the connection block one 448, and the guide post 449 passes through the connection block one 448 and is connected with a limit nut above the connection block one 448. The structure of this technical scheme design provides a structure and is used for solving the problem that produces when processing shaping to raw materials 8 when two shaping posts simultaneous processing. Because the device needs a plane and two concave processing conditions, the elastic design can better meet the requirements.

Preferably, as shown in fig. 1, 9 or 10, the four stamping parts 44 are provided with a material receiving part 51 at one side, and further comprise an inductor 53 for sensing the processing of the raw material 8, wherein the inductor 53 is connected with a pneumatic device, and the pneumatic device blows the processed raw material 8 to the material receiving part 51. After the processing of the raw material 8 is completed, the sensor 53 senses the lifting of the upper die, and a pneumatic device is triggered to blow the finished product to the material bearing part 51, so that a complete set of processing is completed. A conveyor is also provided in the general material receiving portion 51 to transport the product to the packaging portion.

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

Claims (9)

1. An apparatus for manufacturing a binding device, comprising a frame (1), characterized in that: the feeding device is characterized in that a feeding mechanism (2) is arranged on the frame (1), the feeding mechanism (2) is provided with a feeding groove (21), a feeding opening (22) is formed in the end part of the side of the feeding groove (21), and raw materials in the feeding groove (21) sequentially enter the slideway mechanism (3) through the feeding opening (22);

the slideway mechanism (3) comprises a reciprocating feeding sliding table (33), and a plurality of groups of push heads (31) for pushing raw materials into one working procedure of the stamping mechanism (4) are arranged on the sliding table (33);

the stamping mechanism (4) is provided with a plurality of stamping stations and is used for stamping and forming raw materials; and collecting the finished product to a material bearing position (51) by a discharging mechanism (5);

the upper end part of the frame (1) is provided with a power device (6), and the power device (6) provides power for the stamping mechanism (4) to reciprocate up and down;

the stamping mechanism (4) comprises a stamping part (41), wherein the stamping part (41) comprises an upper die I (411) arranged at the upper end of the frame (1) and a lower die I (412) matched with the upper die I (411); the upper punch die I (411) is arranged on two sides of the sliding table (33) and is of an inverted U-shaped design; the lower first die (412) is in a platform shape and is arranged on the inner side of the upper first die (411); an upper sub-die I (413) is formed on the outer side of the upper die I (411), an inclined plane I (418) is formed on one side of the upper sub-die I (413) close to the sliding table, a lower sub-die I (414) which is arranged opposite to the inclined plane I (418) is arranged on one side of the lower die I (412),

the inclined plane one (418) of the upper sub-die one (413) drives and extrudes raw materials to be molded through abutting action in the descending process; the lower sub-die I (414) comprises a sub-die I bracket (416), the sub-die I bracket (416) is formed with a mounting hole, a mandril (417) is penetrated in the mounting hole, and a reset spring (450) capable of realizing reciprocating motion of the mandril (417) is sleeved between the mandril (417) and the wall of the mounting hole;

the stamping mechanism (4) comprises a stamping three part (43), the stamping three part (43) comprises a forming groove III (431) arranged on the sliding table (33), and a forming column III (432) arranged opposite to the forming groove III (431) is arranged on the lower side of the frame;

limiting columns (433) are respectively formed on two sides of the forming groove III (431), limiting grooves (434) are recessed in the periphery of the limiting columns (433), and the limiting grooves (434) are used for pushing raw materials to the forming groove III (432);

the stamping mechanism (4) comprises a stamping four part (44), the stamping four part (44) comprises an upper stamping die four (441) and a lower stamping die four (442) which are connected to the upper end of the frame (1), the upper stamping die four (441) is formed with a forming strip four (443) and a forming strip five (444), and the lower stamping die four (442) is respectively formed with a forming groove four (445) and a forming groove five (446) which are matched with the forming strip four (443) and the forming strip five (444);

the molding strip five (444) comprises a molding block one (447) and a connecting block one (448), a guide post (449) is arranged on the upper side face of the molding block one (447), a spring (450) is sleeved on the guide post (449), the spring (450) is propped between the molding block one (447) and the connecting block one (448), and the guide post (449) penetrates through the connecting block one (448) and is sleeved with a limit nut above the connecting block one (448).

2. The apparatus for manufacturing a buckle device according to claim 1, wherein: a feeding rotating shaft (23) is arranged below the blanking opening (22), a material placing groove (24) which is arranged opposite to the blanking opening (22) is formed in the axial direction of the outer end surface of the feeding rotating shaft (23), and the material placing groove (24) can only accommodate one raw material to enter; the slide way mechanism (3) is arranged below the feeding rotating shaft (23).

3. The apparatus for manufacturing a buckle device according to claim 2, wherein: a plurality of protruding edges (231) are formed on the feeding rotating shaft (23), the material placing grooves (24) are formed on the protruding edges (231), and the material placing grooves (24) are axially aligned.

4. The apparatus for manufacturing a buckle device according to claim 1, wherein: the side wall of the trough (21) is provided with a plurality of longitudinal open grooves (211), and eccentric wheels (26) are adapted to the open grooves (211).

5. An apparatus for manufacturing a buckle device according to claim 2 or 3, wherein: the blanking mechanism (2) comprises a material distributing fork (25) for sorting raw materials, the upper end part of the material distributing fork (25) is abutted to the blanking opening (22), the material distributing fork (25) is provided with a material distributing opening (251), and the material distributing opening (251) is adapted to and wound on the outer side of the material feeding rotating shaft (23) and is arranged towards the material feeding rotating shaft (23).

6. The apparatus for manufacturing a buckle device according to claim 1, wherein: the push head (31) is provided with an inclined surface (333), a push head groove (34) matched with the push head (31) is formed on the sliding table (33), a compression spring (35) is fixedly arranged at the bottom of the push head groove (34), and the compression spring (35) abuts against the lower end part of the push head (31).

7. The apparatus for manufacturing a buckle device according to claim 1 or 4, wherein: a limiting rod (36) is arranged above two sides of the sliding table (33) along the direction of the sliding table (33), and the limiting rod (36) is used for limiting the up-and-down movement of the raw materials.

8. The apparatus for manufacturing a binding device of claim 7, wherein: a step part (334) is arranged on the sliding table (33), a stop block (361) is sleeved at one end, close to the step part (334), of the limiting rod (36) in a telescopic manner, an inclined surface (362) is arranged on the stop block (361), and the inclined surface (362) abuts against the step part (334); an elastic limiting piece (37) is arranged at the upper end of the frame (1) and used for controlling the time of raw materials entering the step part (334).

9. The apparatus for manufacturing a buckle device according to claim 1, wherein: one side of the stamping four parts (44) is provided with the material bearing part (51); the device also comprises an inductor (53) for inducing the finishing of the raw material (8), wherein the inductor (53) is connected with a pneumatic device, and the pneumatic device can send the finished raw material to the material bearing part (51).