CN212238907U - Multi-station conveying die for automobile parts - Google Patents

Abstract

The utility model relates to the technical field of stamping equipment, in particular to a multi-station transfer die for automobile parts; the structure is simple, the grabbing and the transferring are more convenient, the later maintenance cost is reduced, and the device is more practical; the automatic punching machine comprises an operation table, a first die station, a second die station, two groups of transmission lead screws, two groups of moving seats, a servo motor, a driving sprocket, two groups of driven sprockets, a chain, a gantry support frame, two groups of pneumatic rods and two groups of pneumatic suckers, wherein the first die station and the second die station respectively comprise a lathe bed, an upper die, a lower die, two groups of punching hydraulic cylinders and four groups of guiding hydraulic cylinders, four groups of through holes matched with the four groups of guiding hydraulic cylinders are formed in the upper die, four groups of limiting jacks matched with the four groups of guiding hydraulic cylinders are formed in the lower die, sliding grooves are formed in the front portion and the rear portion of the top end of the operation table, the two groups of pneumatic rods are fixedly arranged on the gantry support frame, and the two.

Description

Multi-station conveying die for automobile parts

Technical Field

The utility model relates to a stamping equipment's technical field especially relates to an automobile parts multistation transfer mold.

Background

As is known, a multi-station Transfer Die is translated from english Transfer Die, at present, various Chinese translation names in the stamping Die industry are not uniform, and are called multi-station Die, manipulator Die and Transfer Die, because the Transfer Die is generally automatically produced through manipulator picking and placing work, the Transfer Die is actually molded on a Die holder or a supporting plate through a plurality of single projects, and stamping production of a plurality of procedures is carried out on a punch press; in order to facilitate the manipulator to grab a workpiece, the stamping and feeding directions of the dies are on the same horizontal line and the same central line, and the protruding parts of the dies such as guide pillars, inclined wedges and the like need to be subjected to manipulator curve track interference check so as to avoid mutual interference and collision in the production process; therefore, in order to improve the flexibility and accuracy of the manipulator, the dimensions, the steering device and the lifting control system need to be increased, the manufacturing cost is increased, and meanwhile, due to the complex structure of the manipulator, the subsequent maintenance cost is increased, and certain use limitation exists.

SUMMERY OF THE UTILITY MODEL

Technical problem to be solved

Not enough to prior art, the utility model provides a simple structure snatchs and transmits more conveniently, reduces later maintenance cost, more practical automobile parts multistation transfer mold.

(II) technical scheme

In order to achieve the above object, the utility model provides a following technical scheme: the automatic stamping machine comprises an operation table, a first die station, a second die station, two groups of transmission lead screws, two groups of moving seats, a servo motor, a driving sprocket, two groups of driven sprockets, a chain, a gantry support frame, two groups of pneumatic rods and two groups of pneumatic suckers, wherein the first die station and the second die station are respectively arranged at the left part of the top end of the operation table, the first die station and the second die station respectively comprise a lathe bed, an upper die, a lower die, two groups of stamping hydraulic cylinders and four groups of guide hydraulic cylinders, the lathe bed is fixedly arranged at the rear part of the top end of the operation table, the two groups of stamping hydraulic cylinders are fixedly arranged on the lathe bed, the output ends of the two groups of stamping hydraulic cylinders are fixedly connected with the top end of the upper die, the lower die is fixedly arranged at the top end of the operation table, the upper die is positioned under the lower die, the four groups of guide hydraulic cylinders are uniformly distributed on the, the lower die is provided with four groups of limiting jacks matched with four groups of guiding hydraulic cylinders, the output ends of the four groups of guiding hydraulic cylinders penetrate through the four groups of through holes from the top end of the upper die and are inserted into the four groups of limiting jacks, the front part and the rear part of the top end of the operating platform are respectively provided with a sliding chute, two groups of driving screws are rotatably arranged in two groups of sliding chutes, two groups of moving seats are respectively arranged on the driving screws, the driving screws are in threaded transmission connection with the moving seats, the two groups of moving seats can move left and right along the two groups of sliding chutes, the right ends of the two groups of driving screws are respectively fixedly connected with the left ends of two groups of driven sprockets, the left part of the operating platform is provided with an equipment cavity, the servo motor is fixedly arranged in the equipment cavity, the output end of the servo motor is in transmission connection with the left, the bottom end of the gantry support frame is respectively fixedly connected with the top ends of the two groups of moving seats, the two groups of air pressure rods are fixedly arranged on the gantry support frame, and the two groups of pneumatic suckers are arranged at the output ends of the air pressure rods.

Preferably, still include L type frame, telescopic link and gyro wheel, L type frame is fixed to be set up in the top right part of operation panel, the telescopic link is fixed to be set up on L type frame, the extension end of telescopic link with the top fixed connection of gyro wheel, the extension pot head of telescopic link is equipped with the spring, the bottom of gyro wheel with the top face in close contact with of chain.

Preferably, the right end of operation panel is provided with the protection casing, drive sprocket and two sets of driven sprocket all are located the protection casing.

Preferably, the gantry support frame comprises two groups of cantilevers and a gantry frame, the two groups of cantilevers are fixedly arranged at the left end of the gantry frame, and the two groups of pressure bars are arranged on the two groups of cantilevers.

Preferably, the front end of the operating platform is provided with an opening, the opening is communicated with the equipment cavity, and the opening is provided with an access door.

Preferably, two sets of buffer stop blocks are arranged at the left part of the top end of the operating platform, and the two sets of buffer stop blocks are arranged corresponding to the two sets of sliding grooves.

(III) advantageous effects

Compared with the prior art, the utility model provides an automobile parts multistation transfer mold possesses following beneficial effect: the multi-station automobile part conveying die is characterized in that a workpiece to be punched is placed on a second die station, an upper die and a lower die are pressed under the action of two groups of stamping hydraulic cylinders, so that the workpiece is subjected to primary stamping, after the stamping is finished, the two groups of stamping hydraulic cylinders and the four groups of guide hydraulic cylinders on the second die station are started, the output ends of the two groups of stamping hydraulic cylinders and the four groups of guide hydraulic cylinders are shortened, the upper die and the lower die are separated by a certain distance, the bottom of the output end of the guide hydraulic cylinder is positioned at the upper part of the upper die, a servo motor is started at the moment, the servo motor drives a driving chain wheel to rotate, two groups of driven chain wheels are synchronously rotated after chain transmission, two groups of transmission lead screws drive two groups of moving seats to move leftwards along two groups of sliding grooves, when two groups of pneumatic suction cups are positioned right above the lower die of the second, the output ends of the two groups of pneumatic rods extend, the two groups of pneumatic suckers are in close contact with a preliminarily stamped stamping part, at the moment, the two groups of pneumatic suckers are communicated with an external pneumatic station and started, the two groups of pneumatic suckers adsorb the stamping part, the pneumatic rods reset, the servo motor is started again, the pneumatic suckers drive the stamping part to move leftwards to be right above a lower die of a first die station, the two groups of pneumatic rods are started again, the output ends of the two groups of pneumatic rods extend to enable the stamping part to be placed in the lower die on a second die station, at the moment, the two groups of pneumatic suckers stop adsorbing the stamping part, the two groups of pneumatic rods reset, the servo motor is controlled by an external control device to rotate reversely, the moving seat moves rightwards to the initial position, the other group of stamping part to be machined is placed at the right part of the top end of the operating platform, the pneumatic suck, meanwhile, stamping of the first die station is completed, the seat is moved under the drive of the servo motor at the moment, the pneumatic sucker is moved to the position right above the lower die of the first die station, repeated blanking is performed, stamping formed on the second die station is blanked, the pneumatic sucker is moved to the left limit position of the operating table under the drive of the servo motor at the moment, the stamping is released, multi-station stamping and conveying of the stamping are completed, the pneumatic sucker is simple in structure, the grabbing and conveying are more convenient, the later maintenance cost is reduced, and the pneumatic sucker is more practical.

Drawings

FIG. 1 is a schematic perspective view of the present invention without a protective cover;

FIG. 2 is a schematic perspective view of the protective cover of the present invention;

FIG. 3 is a front perspective structural schematic view of the present invention;

fig. 4 is a schematic view of the enlarged structure of a part a in fig. 1 according to the present invention;

FIG. 5 is a schematic view of a right-side cross-sectional structure of the movable seat of the present invention;

in the drawings, the reference numbers: 1. an operation table; 2. a drive screw; 3. a movable seat; 4. a servo motor; 5. a drive sprocket; 6. a driven sprocket; 7. a chain; 8. a pneumatic rod; 9. a pneumatic suction cup; 10. a bed body; 11. an upper die; 12. a lower die; 13. a stamping hydraulic cylinder; 14. a guiding hydraulic cylinder; 15. a through hole; 16. limiting the jacks; 17. a chute; 18. an L-shaped frame; 19. a telescopic rod; 20. a roller; 21. a spring; 22. a protective cover; 23. a cantilever; 24. a gantry; 25. an access door; 26. buffer stop block.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Referring to fig. 1-5, the utility model discloses a multi-station conveying mold for automobile parts, which comprises an operation table 1, a first mold station, a second mold station, two sets of driving screws 2, two sets of moving seats 3, a servo motor 4, a driving sprocket 5, two sets of driven sprockets 6, a chain 7, a gantry support frame, two sets of air pressure rods 8 and two sets of pneumatic suction cups 9, wherein the first mold station and the second mold station are respectively arranged at the left part of the top end of the operation table 1, the first mold station and the second mold station respectively comprise a bed 10, an upper mold 11, a lower mold 12, two sets of stamping hydraulic cylinders 13 and four sets of guiding hydraulic cylinders 14, the bed 10 is fixedly arranged at the back part of the top end of the operation table 1, the two sets of stamping hydraulic cylinders 13 are fixedly arranged on the bed 10, the output ends of the two sets of stamping hydraulic cylinders 13 are fixedly connected with the top end of the upper mold 11, an upper die 11 is positioned right below a lower die 12, four groups of guide hydraulic cylinders 14 are uniformly distributed on a lathe bed 10, four groups of through holes 15 which are matched with the four groups of guide hydraulic cylinders 14 are arranged on the upper die 11, four groups of limiting jacks 16 which are matched with the four groups of guide hydraulic cylinders 14 are arranged on the lower die 12, the output ends of the four groups of guide hydraulic cylinders 14 penetrate through the four groups of through holes 15 from the top end of the upper die 11 and are inserted into the four groups of limiting jacks 16, sliding grooves 17 are respectively arranged at the front part and the rear part of the top end of an operating platform 1, two groups of transmission lead screws 2 can be rotatably arranged in the two groups of sliding grooves 17, two groups of moving seats 3 are respectively arranged on the transmission lead screws 2, the transmission lead screws 2 are in threaded transmission connection with the moving seats 3, the two groups of moving seats 3 can move left and right along the two groups of sliding grooves 17, the servo motor 4 is fixedly arranged in the equipment cavity, the output end of the servo motor 4 is in transmission connection with the left end of the driving chain wheel 5, the driving chain wheel 5 is in transmission connection with the two groups of driven chain wheels 6 through chains 7, the bottom end of the gantry support frame is respectively in fixed connection with the top ends of the two groups of moving seats 3, the two groups of air pressure rods 8 are fixedly arranged on the gantry support frame, and the two groups of pneumatic suckers 9 are arranged at the output ends of the air pressure rods 8; the stamping part is initially stamped by placing the stamping part to be stamped on a second die station, the upper die 11 and the lower die 12 are pressed under the action of the two groups of stamping hydraulic cylinders 13, after stamping is finished, the two groups of stamping hydraulic cylinders 13 and the four groups of guide hydraulic cylinders 14 on the second die station are started, the output ends of the two groups of stamping hydraulic cylinders 13 and the four groups of guide hydraulic cylinders 14 are shortened, the upper die 11 and the lower die 12 are separated by a certain distance, the bottom of the output end of the guide hydraulic cylinder 14 is positioned at the upper part of the upper die 11, at the moment, the servo motor 4 is started, the servo motor 4 drives the driving chain wheel 5 to rotate, the two groups of driven chain wheels 6 synchronously rotate after being driven by the chain 7, the two groups of driving lead screws 2 drive the two groups of moving seats 3 to move leftwards along the two groups of sliding grooves 17, and when the two groups of pneumatic suction, at the moment, two groups of air pressure rods 8 are communicated with an external air pressure station and started, the output ends of the two groups of air pressure rods 8 extend, two groups of pneumatic suckers 9 are in close contact with a preliminarily stamped stamping part, at the moment, the two groups of pneumatic suckers 9 are communicated with the external air pressure station and started, the two groups of pneumatic suckers 9 adsorb the stamping part, the air pressure rods 8 reset, the servo motor 4 is started again, the pneumatic suckers 9 drive the stamping part to move leftwards to be right above a lower die 12 of a first die station, the two groups of air pressure rods 8 are started again, the output ends of the two groups of air pressure rods 8 extend to enable the stamping part to be placed in the lower die 12 of a second die station, at the moment, the two groups of pneumatic suckers 9 stop adsorbing the stamping part, the two groups of air pressure rods 8 reset, the servo motor 4 is controlled to rotate reversely through an external control device, the movable, adsorb through pneumatic chuck 9, the action of repeated material loading, send into the lower mould 12 on the second mould station with another group of stamping workpiece, meanwhile, the stamping workpiece punching press of first mould station department finishes, this moment under servo motor 4 drive removes the effect of seat 3, pneumatic chuck 9 removes directly over the lower mould 12 of first mould station, the action of repeated unloading, carry out the unloading with the stamping workpiece of stamping forming on the second mould station, this moment under servo motor 4's drive, pneumatic chuck 9 removes the left part extreme position to operation panel 1, release the stamping workpiece, thereby accomplish the multistation punching press conveying of stamping workpiece, moreover, the steam generator is simple in structure, it is more convenient to snatch and transmit, reduce the later maintenance cost, and is more practical.

The utility model discloses a car parts multistation conveying mould, still include L type frame 18, telescopic link 19 and gyro wheel 20, L type frame 18 is fixed to be set up in the top right part of operation panel 1, telescopic link 19 is fixed to be set up on L type frame 18, the extension end of telescopic link 19 is fixedly connected with the top of gyro wheel 20, the extension end cover of telescopic link 19 is equipped with spring 21, the bottom of gyro wheel 20 is in close contact with the top face of chain 7; under the action of the telescopic rod 19 and the spring 21, the roller 20 tightly pushes the chain 7, so that the chain 7 is in a stretching state, and the chain 7 can be effectively prevented from automatically separating from the driving chain wheel 5 and the driven chain wheel 6 in a loosening state; a protective cover 22 is arranged at the right end of the operating platform 1, and the driving chain wheel 5 and the two groups of driven chain wheels 6 are both positioned in the protective cover 22; by arranging the protective cover 22, mechanical damage can be effectively reduced, and the device is safer and more reliable; the gantry support frame comprises two groups of cantilevers 23 and a gantry 24, the two groups of cantilevers 23 are fixedly arranged at the left end of the gantry 24, and the two groups of air pressure rods 8 are arranged on the two groups of cantilevers 23; through the arrangement of the cantilever 23, the two groups of pneumatic suction cups 9 can be moved out from the operating platform 1, so that blanking of the stamped and formed part is facilitated, and the stamped and formed part can be conveniently connected with a processing device in the next procedure; the front end of the operating platform 1 is provided with an opening which is communicated with the equipment cavity, and the opening is provided with an access door 25; the servo motor 4 in the equipment cavity can be more conveniently overhauled through the opening; two groups of buffer stop blocks 26 are arranged at the left part of the top end of the operating platform 1, and the two groups of buffer stop blocks 26 are arranged corresponding to the two groups of sliding grooves 17; through the arrangement of the buffer stop 26, when the gantry support frame reaches the leftmost side of the operating platform 1, the impact force of the gantry support frame can be sustained and released, and the noise generated by impact is reduced.

When in use, a workpiece to be stamped is placed on a second die station, the upper die 11 and the lower die 12 are pressed under the action of the two groups of stamping hydraulic cylinders 13, so that the workpiece is initially stamped, after stamping is finished, the two groups of stamping hydraulic cylinders 13 and the four groups of guide hydraulic cylinders 14 on the second die station are started, the output ends of the two groups of stamping hydraulic cylinders 13 and the four groups of guide hydraulic cylinders 14 are shortened, the upper die 11 and the lower die 12 are separated by a certain distance, the bottom of the output end of the guide hydraulic cylinder 14 is positioned at the upper part of the upper die 11, at the moment, the servo motor 4 is started, so that the servo motor 4 drives the driving chain wheel 5 to rotate, the two groups of driven chain wheels 6 are synchronously rotated after being driven by the chain 7, so that the two groups of driving screws 2 drive the two groups of moving seats 3 to move leftwards along the two groups of sliding, the servo motor 4 stops acting, at the moment, the two groups of air pressure rods 8 are communicated with an external air pressure station and started, the output ends of the two groups of air pressure rods 8 extend, the two groups of pneumatic suckers 9 are in close contact with a preliminarily stamped stamping part, at the moment, the two groups of pneumatic suckers 9 are communicated with the external air pressure station and started, the two groups of pneumatic suckers 9 adsorb the stamping part, the air pressure rods 8 reset, the servo motor 4 is started again, the pneumatic suckers 9 drive the stamping part to move leftwards to be right above a lower die 12 of a first die station, the two groups of air pressure rods 8 are started again, the output ends of the two groups of air pressure rods 8 extend, so that the stamping part is placed in the lower die 12 of a second die station, at the moment, the two groups of pneumatic suckers 9 stop adsorbing the stamping part, the two groups of air pressure rods 8 reset, placing another group of stamping parts to be processed on the right part of the top end of the operating platform 1, adsorbing the stamping parts through a pneumatic sucker 9, repeating the feeding action, sending the other group of stamping parts into a lower die 12 on a second die station, finishing stamping of the stamping parts on the first die station at the same time, moving the pneumatic sucker 9 to a position right above the lower die 12 on the first die station under the action of a servo motor 4 driving a moving seat 3, repeating the blanking action, blanking the stamping parts formed by stamping on the second die station, moving the pneumatic sucker 9 to the left limit position of the operating platform 1 under the driving of the servo motor 4, and releasing the stamping parts, so that the multi-station stamping and conveying of the stamping parts are completed, the structure is simple, the grabbing and the transferring are more convenient, the later maintenance cost is reduced, and the device is more practical; under the action of the telescopic rod 19 and the spring 21, the roller 20 tightly pushes the chain 7, so that the chain 7 is in a stretching state, and the chain 7 can be effectively prevented from automatically separating from the driving chain wheel 5 and the driven chain wheel 6 in a loosening state; by arranging the protective cover 22, mechanical damage can be effectively reduced, and the device is safer and more reliable; through the arrangement of the cantilever 23, the two groups of pneumatic suction cups 9 can be moved out from the operating platform 1, so that blanking of the stamped and formed part is facilitated, and the stamped and formed part can be conveniently connected with a processing device in the next procedure; the servo motor 4 in the equipment cavity can be more conveniently overhauled through the opening; through the arrangement of the buffer stop 26, when the gantry support frame reaches the leftmost side of the operating platform 1, the impact force of the gantry support frame can be sustained and released, and the noise generated by impact is reduced.

The utility model discloses a car parts multistation transfer mold, servo motor buy and buy to servo motor carries out the electricity through the instruction manual of buying together and connects.

It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

The electrical components presented in the document are all electrically connected with an external master controller and 220V mains, and the master controller can be a conventional known device controlled by a computer or the like.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (6)

1. A multi-station conveying die for automobile parts is characterized by comprising an operating platform (1), a first die station, a second die station, two groups of transmission lead screws (2), two groups of moving seats (3), a servo motor (4), a driving chain wheel (5), two groups of driven chain wheels (6), a chain (7), a gantry support frame, two groups of air pressure rods (8) and two groups of pneumatic suckers (9), wherein the first die station and the second die station are respectively arranged at the left part of the top end of the operating platform (1), the first die station and the second die station respectively comprise a machine body (10), an upper die (11), a lower die (12), two groups of stamping hydraulic cylinders (13) and four groups of guide hydraulic cylinders (14), the machine body (10) is fixedly arranged at the rear part of the top end of the operating platform (1), and the two groups of stamping hydraulic cylinders (13) are fixedly arranged on the machine body (10), the output ends of the two groups of stamping hydraulic cylinders (13) are fixedly connected with the top end of an upper die (11), the lower die (12) is fixedly arranged at the top end of the operating platform (1), the upper die (11) is positioned under the lower die (12), the four groups of guiding hydraulic cylinders (14) are uniformly distributed on the bed (10), the upper die (11) is provided with four groups of through holes (15) which are matched with the four groups of guiding hydraulic cylinders (14), the lower die (12) is provided with four groups of limiting insertion holes (16) which are matched with the four groups of guiding hydraulic cylinders (14), the output ends of the four groups of guiding hydraulic cylinders (14) penetrate through the four groups of through holes (15) from the top end of the upper die (11) and are inserted into the four groups of limiting insertion holes (16), the front part and the rear part of the operating platform (1) are provided with sliding chutes (17), and the two groups of transmission lead screws (2) can be rotatably arranged in the two groups of, the two groups of moving seats (3) are respectively arranged on a transmission screw rod (2), the transmission screw rod (2) is in threaded transmission connection with the moving seats (3), the two groups of moving seats (3) can move left and right along two groups of sliding grooves (17), the right ends of the two groups of transmission screw rods (2) are respectively fixedly connected with the left ends of two groups of driven chain wheels (6), the left part of the operating platform (1) is provided with an equipment cavity, a servo motor (4) is fixedly arranged in the equipment cavity, the output end of the servo motor (4) is in transmission connection with the left end of a driving chain wheel (5), the driving chain wheel (5) is in transmission connection with the two groups of driven chain wheels (6) through a chain (7), the bottom end of the gantry support frame is respectively fixedly connected with the top ends of the two groups of moving seats (3), and the two groups of air pressure rods (8) are both fixedly, the two groups of pneumatic suckers (9) are arranged at the output end of the pneumatic rod (8).

2. The multi-station automobile part conveying die as claimed in claim 1, further comprising an L-shaped frame (18), a telescopic rod (19) and rollers (20), wherein the L-shaped frame (18) is fixedly arranged at the right portion of the top end of the operating platform (1), the telescopic rod (19) is fixedly arranged on the L-shaped frame (18), the extending end of the telescopic rod (19) is fixedly connected with the top end of the rollers (20), the extending end of the telescopic rod (19) is sleeved with a spring (21), and the bottom end of the roller (20) is in close contact with the top end face of the chain (7).

3. The multi-station automobile part conveying die as claimed in claim 2, wherein a protective cover (22) is arranged at the right end of the operating platform (1), and the driving chain wheel (5) and the two groups of driven chain wheels (6) are located in the protective cover (22).

4. The multi-station automobile part conveying die as claimed in claim 3, wherein the gantry support frame comprises two groups of cantilevers (23) and a gantry (24), the two groups of cantilevers (23) are fixedly arranged at the left end of the gantry (24), and the two groups of pneumatic rods (8) are arranged on the two groups of cantilevers (23).

5. The multi-station automobile part conveying die as claimed in claim 4, wherein an opening is formed in the front end of the operating platform (1), the opening is communicated with the equipment cavity, and an access door (25) is arranged on the opening.

6. The multi-station automobile part conveying die as claimed in claim 5, wherein two sets of buffer stop blocks (26) are arranged at the top left part of the operating platform (1), and the two sets of buffer stop blocks (26) are arranged corresponding to the two sets of slide grooves (17).

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