CN210648216U

CN210648216U - Flanging, necking and rib rolling integrated machine

Info

Publication number: CN210648216U
Application number: CN201921602108.2U
Authority: CN
Inventors: 许明聪
Original assignee: Foshan Huaxinkai Machinery Co Ltd
Current assignee: Foshan Huaxinkai Machinery Co Ltd
Priority date: 2019-09-25
Filing date: 2019-09-25
Publication date: 2020-06-02
Anticipated expiration: 2029-09-25

Abstract

The utility model discloses a turn-ups necking down rolls muscle all-in-one, which comprises a frame, power device, mould power device rises, mould group device, press from both sides and send device and jacking device all to locate in the frame, mould group device includes outer spinning die, inner membrance and central shaft, the central shaft is connected with mould power device that rises, the outside of centre form is located to outer spinning die, corresponding with the centre form, the center sleeve is established in the center department of centre form, the centre form includes the turn-ups centre form of necking down and rolls the muscle centre form, it is located the below of turn-ups centre form of necking down to roll the muscle centre form, outer spinning die is connected with power device, jacking device and clamp send the. Under the combined action of the external spinning die, the necking and flanging internal die and the rib rolling internal die, the necking, the flanging and the rib rolling of the can body are realized; the tank body is not required to be processed by a plurality of devices, so that the device cost is saved, the production cost is reduced, and the processing efficiency of the tank body is improved.

Description

Flanging, necking and rib rolling integrated machine

Technical Field

The utility model belongs to a can seamer especially relates to a turn-ups necking down rolls muscle all-in-one.

Background

When the existing tank body is processed, the flanging, necking and rolling of the tank body are respectively completed in three machines with different functions, namely three different dies. Therefore, the jar body need consume longer process time in the course of working, and has increased equipment cost, has increased the manpower loss, has reduced production efficiency.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a turn-ups necking down rolls muscle all-in-one that can solve at least one in the above-mentioned problem.

According to the utility model discloses an aspect provides a turn-ups necking down rolls muscle all-in-one, which comprises a frame, power device, mould power device rises, the mould group device, press from both sides and send device and jacking device all to locate in the frame, the mould group device includes outer spinning die, inner membrance and central axle, the central axle is connected with mould power device that rises, outer spinning die locates the outside of centre form, corresponding with the centre form, the center department at the centre form is established to the central axis cover, the centre form includes the turn-ups of necking down centre form and rolls the muscle centre form, roll the muscle centre form and be located the below of turn-ups centre form of necking down, outer spinning die is connected with power device, jacking device and clamp send the device.

The utility model has the advantages that: the power device can drive the die set device to work, so that the rotation of the outer spinning die is realized; the central shaft is driven by the expansion die power device to move up and down, so that expansion and contraction of the necking down flanging internal die and the rib rolling internal die are realized, and necking down, flanging and rib rolling of the tank body are realized under the combined action of the external rotation pressing die, the necking down flanging internal die and the rib rolling internal die. Therefore, the flanging, necking and beading all-in-one machine does not need multiple devices to process the tank body respectively, greatly saves the device cost, reduces the production cost, and can improve the processing efficiency of the tank body.

In some embodiments, the central shaft is provided with a first cone and a second cone, the first cone corresponds to the necking-flanging inner die, the second cone corresponds to the rolling rib inner die, and the central shaft can move along the axial direction. From this, through be equipped with first centrum and second centrum on the center pin to when making the center pin drive two centrums rebound, can promote necking down turn-ups centre form and the outside expansion of roll muscle centre form, thereby the can body with the jar body is by the centre form full, is convenient for realize the processing to the jar body through the combined action of outer spinning mould.

In some embodiments, the mold expansion power device comprises a first motor, a first speed reducer, two bevel gears, a crankshaft and a swing rod, the two bevel gears are meshed, the first motor is connected with the first speed reducer, the first speed reducer is arranged on the frame, one bevel gear is sleeved on an output shaft of the first speed reducer, the crankshaft is sleeved on the other bevel gear, one end of the swing rod is connected with the crankshaft, and the other end of the swing rod is connected with the central shaft. Therefore, the control over the up-and-down movement of the central shaft is realized through the mutual matching action of all parts of the die expansion power device, and the acting force and the moving stability of the central shaft during up-and-down movement are ensured.

In some embodiments, the power device includes a second motor, a belt pulley, a transmission shaft, a first gear, a second gear, a third gear and a fourth gear, the second motor is disposed on the frame, one end of the belt pulley is connected with an output shaft of the second motor, the other end of the belt pulley is connected with the transmission shaft, the first gear and the second gear are both sleeved on the transmission shaft, the third gear is meshed with the first gear, the fourth gear is meshed with the second gear, and the third gear and the fourth gear are both sleeved outside the central shaft and are matched with the mold assembly device. Therefore, the third gear and the fourth gear are respectively in meshing transmission with two different gears, so that the differential motion of the third gear and the fourth gear can be conveniently realized, and the die set device is convenient to realize corresponding processing actions on the tank body.

In some embodiments, the mold set apparatus further includes a rotating disc, a connecting sleeve, a first cam and a second cam, the connecting sleeve is located between the third gear and the central shaft, the connecting sleeve is fixed to the third gear, the rotating disc is sleeved outside the connecting sleeve, the outer spinning mold is arranged on the rotating disc, the first cam and the second cam are both fixed to the fourth gear, and the outer spinning mold corresponds to the first cam and the second cam. Therefore, the third gear drives the rotary table to rotate, the fourth gear drives the two cams to rotate, the outer spinning die is driven to rotate, and the rotary table and the outer spinning die are respectively rotated.

In some embodiments, the outer spinning die includes a neck-down flanging wheel corresponding to the neck-down flanging inner film and a rib-rolling side wheel corresponding to the rib-rolling inner film. Therefore, the necking flanging wheel and the beading side wheel can be used for respectively processing the can body conveniently.

In some embodiments, the necking down flanging inner die comprises eight first modules, a first fixing block and a first spring, the eight first modules are uniformly distributed on the periphery of the central shaft, a first accommodating cavity is formed in each first module, the first fixing block is located in the first accommodating cavity, the first spring is located in the first accommodating cavity, one end of the first spring is connected with the first fixing block, and the other end of the first spring is connected with the first module. Therefore, when the first cone moves upwards, the plurality of first modules move outwards to inflate the tank body, and the first spring is compressed; after the necking and flanging of the tank body are completed, the first cone moves downwards, and the first module can be pushed to reset to one side of the central shaft through the rebound force of the first spring.

In some embodiments, the rib rolling inner die comprises eight second modules, a second fixing block and second springs, the eight second modules are uniformly distributed on the periphery of the central shaft, a second accommodating cavity is formed in each second module, the second fixing block is located in the second accommodating cavity, the second springs are located in the second accommodating cavities, one ends of the second springs are connected with the second fixing block, and the other ends of the second springs are connected with the second modules. Therefore, when the second cone moves upwards, the plurality of second modules move outwards to inflate the tank body, and the second spring is compressed; when the rib rolling is finished, the second cone moves downwards, and the second module can be pushed to one side of the central shaft to reset through the rebound force of the second spring.

In some embodiments, the jacking device comprises a third motor, a second speed reducer, a crank, a connecting rod, a lifting shaft and a supporting plate, the third motor is arranged on the rack, the second speed reducer is connected with an output shaft of the third motor, the crank is connected with an output shaft of the second speed reducer, one end of the connecting rod is arranged on the crank, the connecting rod rotates eccentrically on the crank, the lifting shaft is connected with the other end of the connecting rod, the supporting plate is arranged at the top end of the lifting shaft, two ends of the connecting rod are respectively provided with threads, and the connecting rod is in threaded connection with the lifting shaft. Therefore, the connecting rod eccentrically rotates on the crank, and when the connecting rod drives the lifting shaft to rotate, the lifting rod is just in a speed reduction state due to the inertia effect of the lifting rod when rotating, so that when the lifting rod runs to an upper dead point and a lower dead point, the inertia impact of the supporting plate when the running is stopped is greatly reduced, the mechanical abrasion is reduced, the service life is prolonged, the lifting stability of the tank body is ensured, and the processing quality of the tank body is ensured; through rotating the connecting rod, the thread fit length of the connecting rod and the lifting shaft can be changed, so that the initial height of the supporting plate can be adjusted.

In some embodiments, the clamping and conveying device comprises a first tank holding hand, a second tank holding hand, a transverse guide rail, a longitudinal guide rail and a moving frame, wherein the longitudinal guide rail is arranged on the machine frame, the moving frame is arranged on the longitudinal guide rail, the transverse guide rail is arranged on the moving frame, and the first tank holding hand and the second tank holding hand are arranged on the transverse guide rail and are arranged oppositely. Therefore, the tank body conveying device is provided with the transverse guide rail and the longitudinal guide rail, so that the first tank embracing hand and the second tank embracing hand can be conveniently moved, and the tank body can be conveyed.

Drawings

FIG. 1 is a schematic structural view of a flanging, necking and beading integrated machine of the present invention;

FIG. 2 is a schematic view of the cross-sectional structure of the middle part mechanism of the flanging, necking and beading integrated machine of the present invention;

FIG. 3 is a schematic cross-sectional view of a die set device and a part of the structure in the flanging, necking and beading integrated machine of the present invention;

FIG. 4 is a schematic view of an exploded structure of a die set device in the flanging, necking and beading integrated machine of the present invention;

FIG. 5 is a schematic view of the structure of the inner film of the necking flange in the flanging, necking and beading integrated machine of the present invention;

fig. 6 is the utility model discloses a sectional structure schematic diagram of jacking device in turn-ups necking down rolls muscle all-in-one.

Detailed Description

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

Refer to fig. 1 to 6. The flanging, necking and beading integrated machine comprises a frame 1, a power device 2, an expansion die power device 3, a die set device 4, a clamping and conveying device 5 and a jacking device 6, wherein the power device 2, the expansion die power device 3, the die set device 4, the clamping and conveying device 5 and the jacking device 6 are all arranged on the frame 1. The die set device 4 comprises an outer spinning die 41, an inner die 42 and a central shaft 43, the central shaft 43 is connected with the die expansion power device 3, the outer spinning die 41 is arranged on the outer side of the inner die 42 and corresponds to the inner die 42, and the central shaft 43 is sleeved at the center of the inner die 42. The inner die 42 comprises a necking down flanging inner die 421 and a rib rolling inner die 422, the rib rolling inner die 422 is located below the necking down flanging inner die 421, the outer spinning die 41 is connected with the power device 2, and the jacking device 6 and the pinch device 5 are both corresponding to the die set device 4.

The utility model discloses a turn-ups necking down rolls muscle all-in-one when using, carries the jar body to 4 below of mould group device through pinch device 5, and rethread jacking device 6 processes jar body jacking to 4 departments of mould group device. When the can body is processed, the can body is necked down and flanged through the necking flanging inner film 421 and the outer spinning die 41, and the can body is ribbed through the rib rolling inner film 422 and the outer spinning die 41.

The central shaft 43 is provided with a first cone 7 and a second cone 8, the first cone 7 corresponds to the necking and flanging internal mold 421, the second cone 8 corresponds to the beading internal mold 422, and the central shaft 43 can move along the axial direction. The first cone 7 and the second cone 8 and the central shaft 43 may be integrally formed, or may be fixed to the central shaft 43 by a screw connection.

The mold expansion power device 3 comprises a first motor 31, a first speed reducer 32, two bevel gears 33, a crankshaft 34 and a swing rod 35, the bevel gears 33 are meshed, the first motor 31 is connected with the first speed reducer 32, the first speed reducer 32 is arranged on the rack 1, one bevel gear 33 is sleeved on an output shaft of the first speed reducer 32, the crankshaft 34 is sleeved on the other bevel gear 33, one end of the swing rod 35 is connected with the crankshaft 34, and the other end of the swing rod is connected with the central shaft 43. In practical use, the first motor 31 may be a servo motor, and the first speed reducer 32 is a commonly used speed reducer for adjusting the speed of the motor. When the mold expansion power device 3 works, the first motor 31 is started, and drives one of the bevel gears 33 to rotate through the first speed reducer 32, and then drives the other bevel gear 33 engaged with the one bevel gear to rotate, so that the crankshaft 34 is rotated. The swing rod 35 is driven to move up and down through the rotation of the crankshaft 34, so that the central shaft 43 at the other end of the swing rod 34 is driven to move up and down, and the first vertebral body 7 and the second vertebral body 8 are driven to move up and down when the central shaft 43 moves up and down.

The power device 2 comprises a second motor 21, a belt pulley 22, a transmission shaft 23, a first gear 24, a second gear 25, a third gear 26 and a fourth gear 27, the second motor 21 is arranged on the rack 1, one end of the belt pulley 22 is connected with an output shaft of the second motor 21, the other end of the belt pulley is connected with the transmission shaft 23, the first gear 24 and the second gear 25 are both sleeved on the transmission shaft 23, the third gear 26 is meshed with the first gear 24, the fourth gear 27 is meshed with the second gear 25, the third gear 26 and the fourth gear 27 are both sleeved on the outer side of the central shaft 43 and are matched with the mold set device 4. The second motor 21 may be a servo motor. When the power device 2 works, the second motor 21 rotates to drive the belt pulley 22 to rotate, the belt pulley 22 drives the transmission shaft 23 to rotate, and the transmission shaft 23 drives the first gear 24 and the second gear 25 to rotate. In practical use, the first gear 24 and the second gear 25 are both helical gears, and the inclination directions of the two are opposite, so that the differential rotation of the third gear 26 and the fourth gear 27 is facilitated.

The mold set device 4 further includes a turntable 44, a connecting sleeve 45, a first cam 46 and a second cam 47, the connecting sleeve 45 is located between the third gear 26 and the central shaft 43, the connecting sleeve 45 is fixed with the third gear 26, the turntable 44 is sleeved outside the connecting sleeve 45, the outer spinning mold 41 is arranged on the turntable 44, the first cam 46 and the second cam 47 are both fixed with the fourth gear 27, and the outer spinning mold 41 corresponds to the first cam 46 and the second cam 47.

The outer spinning die 41 comprises a necking flanging wheel 411 and a rib rolling side wheel 412, the necking flanging wheel 411 corresponds to the necking flanging inner film 421, the necking flanging wheel 411 corresponds to the first cam 46, the rib rolling side wheel 412 corresponds to the rib rolling inner film 422, and the rib rolling side wheel 412 corresponds to the second cam 46.

Therefore, when the second motor 21 rotates, the third gear 26 drives the turntable 44 to rotate, and when the turntable 44 rotates, the outer spinning die 41 is driven to rotate on the turntable 44 together; the fourth gear 27 rotates the first cam 46 and the second cam 47 together. Since the third gear 26 and the fourth gear 27 perform differential rotation, when the outer spinning die 41 rotates together with the turntable 44, differential rotation is also achieved with the first cam 46 and the second cam 47. Therefore, when the necking flanging wheel 411 and the rib-rolling side wheel 412 respectively act with the first cam 46 and the second cam 47, the necking flanging wheel 411 and the rib-rolling side wheel 412 can gradually approach the necking inner die 421 and the rib-rolling inner die 422 along with the rotation of the turntable 44, and the can body can be conveniently processed.

Wherein, the outer wall of the neck flange inner film 421 is provided with a groove 4211 and a flange 4212, the groove 4211 corresponds to the neck flange wheel 411, and the flange 216 is arranged at the top end of the groove 215.

The outer wall of the rib rolling inner film 422 is provided with a rib reinforcing part 4221, and the rib reinforcing part 4221 corresponds to the rib rolling side wheel 412.

The necking down turn-ups centre die 421 includes first module 423, first fixed block 424 and first spring 425, and first module 423 is eight, and the equipartition is in the periphery of center pin 43, has all seted up first holding chamber 426 on every first module 423, and first fixed block 424 is located first holding chamber 426, and first spring 425's one end is connected with first fixed block 424, and the other end is connected with first module 423.

The rib rolling inner die 422 comprises eight second die blocks 427, eight second fixed blocks 428 and eight second springs, the eight second die blocks 427 are uniformly distributed on the periphery of the central shaft 43, each second die block 427 is provided with a second accommodating cavity 429, the second fixed blocks 428 are positioned in the second accommodating cavities 429, the second springs are positioned in the second accommodating cavities 429, one ends of the second springs are connected with the second fixed blocks 428, and the other ends of the second springs are connected with the second die blocks 427.

In the actual use process, when the central shaft 43 moves up and down, the inclined surface of the first cone 7 can act on the necking inner die 421, and the inclined surface of the second cone 8 can act on the beading inner die 422.

The first vertebral body 7 has a bottom outer diameter greater than a top outer diameter. Therefore, when the central shaft 43 drives the first cone 7 to move upwards together, the periphery of the first cone 7 acts on the inner side of the first module 423, so that the eight first modules 423 all move outwards, the first spring 425 is compressed by the first module 423, the tank body sleeved on the outer side of the first module 423 is expanded fully, and the tank body and the necking flanging wheel 411 together perform necking flanging on the tank body. After the can body necking and flanging process is completed, the central shaft 43 moves downward, and the first module 423 is pushed back to the initial position under the action of the resilience of the first spring 425, so that the next process can be conveniently carried out.

The outer diameter of the second vertebral body 8 at the bottom end is greater than the outer diameter of the top end, and the outer diameter of the second vertebral body 8 at the bottom end is greater than the outer diameter of the first vertebral body 7 at the bottom end. The first vertebral body 7 has a bottom outer diameter greater than a top outer diameter. Therefore, when the central shaft 43 drives the second cone 8 to move upward together, the periphery of the second cone 8 acts on the inner side of the second module 427, so that the eight second modules 427 all move outward, the second spring is compressed by the second module 427, and the tank body sleeved on the outer side of the second module 427 is expanded, thereby facilitating the rib rolling processing of the tank body together with the rib rolling side wheel 412. After the can body rib rolling processing is completed, the central shaft 3 moves downwards, and the second module 427 is pushed back to the initial position under the action of the rebounding force of the second spring, so that the next processing is facilitated.

When the first module 423 tensions the can body, the groove 4211 and the flange 4212 of the neck flange inner film 421 and the neck flange wheel 411 work together on the can body, thereby realizing the locking and flanging of the can body. When the second block 427 is moved outward to tension the can, the bead portion 4221 and the bead rolling side wheel 412 work together on the can to roll the bead on the can.

The jacking device 6 comprises a third motor 61, a second speed reducer 62, a crank 63, a connecting rod 64, a lifting shaft 65 and a supporting plate 66, the third motor 61 is arranged on the rack 1, the second speed reducer 62 is connected with an output shaft of the third motor 61, the crank 63 is connected with an output shaft of the second speed reducer 62, one end of the connecting rod 64 is arranged on the crank 63, the connecting rod 64 eccentrically rotates on the crank 63, the lifting shaft 65 is connected with the other end of the connecting rod 64, the supporting plate 66 is arranged at the top end of the lifting shaft 65, two ends of the connecting rod 64 are respectively provided with threads, and the connecting rod 64 is in threaded connection with the lifting shaft 65.

This tin supporting device of tin seamer is when using, because the initial position of layer board 66 and tin seamer board delivery track's plane looks parallel and level need be adjusted the initial height position of layer board 66, guarantees its normal tin supporting to the jar body. The specific adjustment of the starting height of the pallet 66 is: the connecting rod 64 is rotated, so that the thread matching length of the connecting rod 64 and the lifting shaft 5 is correspondingly increased or reduced, the vertical height of the supporting plate 66 above the lifting shaft 65 is correspondingly adjusted, and the starting position of the supporting plate 66 meets the use requirement.

The output speed of the third motor 61 can be adjusted by arranging the second speed reducer 62; the connecting rod 64 eccentrically rotates on the crank, so when the connecting rod 64 drives the lifting shaft 65 to rotate, due to the inertia effect of the lifting shaft 65 during rotation, when the lifting shaft 65 runs to an upper dead point and a lower dead point, the lifting shaft is just in a speed reduction state, so that the inertia impact of the supporting plate 66 when the running is stopped is greatly reduced, the mechanical abrasion is reduced, the service life is prolonged, the lifting stability of the tank body is ensured, and the processing quality of the tank body is ensured.

The second reducer 62 is a cycloidal-pin gear reducer. Therefore, the output requirement on the speed can be met, and meanwhile, the rotating stability of the output shaft is guaranteed.

The outer diameter of the elevating shaft 65 is larger than that of the connecting rod 64. The lifting shaft 65 is made of metal parts with larger shaft diameters, so that the lifting shaft 65 has larger mass, the inertia of the lifting shaft during movement is increased, and the lifting shaft is in a speed reduction state when moving to the highest point, namely when being conveyed between the inner die and the outer spinning die.

The clamping and conveying device 5 comprises a first tank embracing hand 51, a second tank embracing hand 52, a transverse guide rail 53, a longitudinal guide rail 54 and a moving frame 55, wherein the longitudinal guide rail 54 is arranged on the rack 1, the moving frame 55 is arranged on the longitudinal guide rail 54, the transverse guide rail 53 is arranged on the moving frame 55, and the first tank embracing hand 51 and the second tank embracing hand 52 are arranged on the transverse guide rail 53 and are arranged oppositely. In the actual use process, a longitudinal cylinder is mounted on the frame 1, the longitudinal cylinder is connected with the moving frame 55, and the extension and contraction of a piston rod of the longitudinal cylinder drives the moving frame 55 to move along the longitudinal guide rail 54; install horizontal cylinder on frame 1, horizontal cylinder is two, embraces jar hand 51 with first respectively and is connected with second and embrace jar hand 52, and through the flexible of the piston rod of horizontal cylinder, can drive two and embrace jar hand motion or opposite direction motion in opposite directions, realized the centre gripping of the jar body and unclamped. The can bodies can be conveyed to the supporting plate 66 by the clamping and conveying device 5, and then the can bodies are pushed to the die set device through the supporting plate 66 to be processed.

The foregoing is only a preferred embodiment of the present invention, and it should be noted that, for those skilled in the art, many modifications and improvements can be made without departing from the inventive concept, and all of them belong to the protection scope of the present invention.

Claims

1. The flanging, necking and beading integrated machine is characterized by comprising a rack (1), a power device (2), a die expansion power device (3), a die set device (4), a clamping and conveying device (5) and a jacking device (6), wherein the power device (2), the die expansion power device (3), the die set device (4), the clamping and conveying device (5) and the jacking device (6) are all arranged on the rack (1), the die set device (4) comprises an outward-rotation die (41), an inner die (42) and a central shaft (43), the central shaft (43) is connected with the die expansion power device (3), the outward-rotation die (41) is arranged on the outer side of the inner die (42) and corresponds to the inner die (42), the central shaft (43) is sleeved at the center of the inner die (42), the inner die (42) comprises a necking and beading inner die (421) and a beading inner die (422), and the beading inner die (422) is positioned below the necking and beading inner die (421), the outer spinning die (41) is connected with the power device (2), and the jacking device (6) and the clamping and conveying device (5) correspond to the die set device (4).

2. The flanging, necking and beading all-in-one machine according to claim 1, wherein a first cone body (7) and a second cone body (8) are arranged on the central shaft (43), the first cone body (7) corresponds to the necking and flanging internal mold (421), the second cone body (8) corresponds to the beading internal mold (422), and the central shaft (43) can move along the axial direction.

3. The flanging, necking and beading all-in-one machine according to claim 2, wherein the expansion die power device (3) comprises two meshed umbrella teeth (33), a first motor (31), a first speed reducer (32), two umbrella teeth (33), a crankshaft (34) and a swing rod (35), the first motor (31) is connected with the first speed reducer (32), the first speed reducer (32) is arranged on the frame (1), one of the umbrella teeth (33) is sleeved on an output shaft of the first speed reducer (32), the crankshaft (34) is sleeved on the other umbrella tooth (33), one end of the swing rod (35) is connected with the crankshaft (34), and the other end of the swing rod is connected with the central shaft (43).

4. The flanging, necking and beading integrated machine according to any one of claims 1 to 3, the power device (2) comprises a second motor (21), a belt pulley (22), a transmission shaft (23), a first gear (24), a second gear (25), a third gear (26) and a fourth gear (27), the second motor (21) is arranged on the frame (1), one end of the belt pulley (22) is connected with an output shaft of the second motor (21), the other end is connected with the transmission shaft (23), the first gear (24) and the second gear (25) are sleeved on the transmission shaft (23), the third gear (26) meshes with the first gear (24), the fourth gear (27) meshes with the second gear (25), and the third gear (26) and the fourth gear (27) are sleeved on the outer side of the central shaft (43) and are matched with the die set device (4).

5. The flanging, necking and beading all-in-one machine according to claim 4, wherein the die set device (4) further comprises a turntable (44), a connecting sleeve (45), a first cam (46) and a second cam (47), wherein the connecting sleeve (45) is positioned between the third gear (26) and the central shaft (43), the connecting sleeve (45) is fixed with the third gear (26), the turntable (44) is sleeved outside the connecting sleeve (45), the outer spinning die (41) is arranged on the turntable (44), the first cam (46) and the second cam (47) are both fixed with the fourth gear (27), and the outer spinning die (41) corresponds to the first cam (46) and the second cam (47).

6. The flanging, necking and beading integrated machine according to claim 5, wherein the outer spinning die (41) comprises a necking flanging wheel (411) and a beading side wheel (412), the necking flanging wheel (411) corresponds to the necking flanging inner die (421), the necking flanging wheel (411) corresponds to the first cam (46), the beading side wheel (412) corresponds to the beading inner die (422), and the beading side wheel (412) corresponds to the second cam (47).

7. The flanging, necking and beading all-in-one machine according to claim 6, wherein the necking inner die (421) comprises a first module (423), a first fixed block (424) and a first spring (425), the first module (423) is eight, the eight first modules are uniformly distributed on the periphery of the central shaft (43), each first module (423) is provided with a first accommodating cavity (426), the first fixed block (424) is located in the first accommodating cavity (426), the first spring (425) is located in the first accommodating cavity (426), one end of the first spring (425) is connected with the first fixed block (424), and the other end of the first spring (425) is connected with the first module (423).

8. The flanging, necking and beading all-in-one machine according to claim 7, wherein the beading inner die (422) comprises a second die block (427), a second fixed block (428) and a second spring, the number of the second die block (427) is eight, the eight second die blocks are uniformly distributed on the periphery of the central shaft (43), each second die block (427) is provided with a second accommodating cavity (429), the second fixed block (428) is positioned in the second accommodating cavity (429), the second spring is positioned in the second accommodating cavity (429), one end of the second spring is connected with the second fixed block (428), and the other end of the second spring is connected with the second die block (427).

9. The flanging, necking and beading integrated machine according to claim 8, wherein the jacking device (6) comprises a third motor (61), a second speed reducer (62), a crank (63), a connecting rod (64), a lifting shaft (65) and a supporting plate (66), the third motor (61) is arranged on the frame (1), the second speed reducer (62) is connected with an output shaft of the third motor (61), the crank (63) is connected with an output shaft of the second speed reducer (62), one end of the connecting rod (64) is arranged on the crank (63), the connecting rod (64) eccentrically rotates on the crank (63), the lifting shaft (65) is connected with the other end of the connecting rod (64), the supporting plate (66) is arranged at the top end of the lifting shaft (65), threads are respectively arranged at two ends of the connecting rod (64), and the connecting rod (64) is in threaded connection with the lifting shaft (65).

10. The flanging, necking and beading all-in-one machine according to claim 8, wherein the clamping and conveying device (5) comprises a first can embracing hand (51), a second can embracing hand (52), a transverse guide rail (53), a longitudinal guide rail (54) and a moving frame (55), the longitudinal guide rail (54) is arranged on the frame (1), the moving frame (55) is arranged on the longitudinal guide rail (54), the transverse guide rail (53) is arranged on the moving frame (55), and the first can embracing hand (51) and the second can embracing hand (52) are arranged on the transverse guide rail (53) and are arranged oppositely.