CN111957904A

CN111957904A - Metal packaging jar casting forming die

Info

Publication number: CN111957904A
Application number: CN202010852979.0A
Authority: CN
Inventors: 程浩; 黄继寨; 郭金生
Original assignee: Individual
Current assignee: Individual
Priority date: 2020-08-22
Filing date: 2020-08-22
Publication date: 2020-11-20

Abstract

The invention relates to a metal packaging can casting forming die which comprises a base and a forming device, wherein the forming device is arranged on the upper surface of the base. The invention can solve the following problems in the design of the casting forming die of the metal packaging can at present: the existing metal packaging can casting forming die directly peels off the inner die and the outer die from the can body when the metal packaging can is subjected to demoulding treatment, the mould is easily damaged by the demoulding mode, the unevenness of the appearance and the deviation problem exceeding the specified error range of the size can be caused in the casting forming of the can body at the back, the demoulding of the can body after the existing cooling forming is realized by manual demoulding of workers, the surface of the formed can body has burrs, the risk of scratching the hands of the workers can be caused, the manual demoulding efficiency is low, and the production efficiency of the can body is influenced.

Description

Metal packaging jar casting forming die

Technical Field

The invention relates to the field of casting, in particular to a metal packaging can casting forming die.

Background

The packaging can made of metal materials has very good comprehensive protection performance, because the water vapor transmission rate of metal is very low and completely light-proof, the packaging can effectively avoid the harmful influence of ultraviolet rays, and the gas barrier property, the moisture resistance, the light-proof property and the fragrance retention property of the packaging can greatly exceed those of other types of packaging materials such as plastics, paper and the like, so the packaging can made of metal materials can keep the quality of articles for a long time, which is especially important for food packaging, and the metal packaging materials have special metal luster and are easy to print and decorate, thereby the appearance of the product is luxurious and beautiful; additionally, various metals Bamboo mold and metallized films are highly desirable branding materials. At present, most of metal packaging tins are manufactured by casting and molding through a molding die, so that the production efficiency of the metal packaging tins is higher.

At present, the design of a metal packaging can casting forming die has the following problems: the existing metal packaging can casting forming die directly peels off the inner die and the outer die from the can body when the metal packaging can is subjected to demoulding treatment, the mould is easily damaged by the demoulding mode, the unevenness of the appearance and the deviation problem exceeding the specified error range of the size can be caused in the casting forming of the can body at the back, the demoulding of the can body after the existing cooling forming is realized by manual demoulding of workers, the surface of the formed can body has burrs, the risk of scratching the hands of the workers can be caused, the manual demoulding efficiency is low, and the production efficiency of the can body is influenced.

Disclosure of Invention

The invention aims to provide a metal packaging can casting forming die to solve the problems in the background technology.

In order to achieve the purpose, the invention provides the following technical scheme:

a metal packaging can casting forming die comprises a base and a forming device, wherein the forming device is arranged on the upper surface of the base; wherein:

the forming device comprises forming pillars, turning branch chains, outer mold units, a lifting cylinder and an inner mold unit, wherein the forming pillars are symmetrically arranged at two ends of the upper surface of the base, the turning branch chains are symmetrically arranged on opposite surfaces between the forming pillars, the outer mold units are arranged between the turning branch chains, the lifting cylinder is arranged at the upper end of each forming pillar, the inner mold unit is mounted at the output end of the lifting cylinder, the outer mold units are positioned outside the inner units, and the outer mold units and the inner mold units are positioned on the same central line;

the outer die unit comprises an outer die bottom plate, outer die frame bodies, a driving cavity, a driving assembly, outer die supporting rods, an outer die plate, an outer die sliding groove and an outer die bottom block, wherein the outer die frame bodies are uniformly arranged on the edge of the upper surface of the outer die bottom plate;

the inner mold unit comprises an inner mold supporting plate, an inner mold, a feeding pipe, an exhaust pipe, a vibration cavity and a vibration assembly, the inner mold supporting plate is arranged at the output end of the lifting cylinder, the inner mold is arranged in the middle of the lower surface of the inner mold supporting plate, the feeding pipes are symmetrically arranged on the left and right sides of the upper end surface of the inner mold, the exhaust pipe is symmetrically arranged in front of and behind the upper end surface of the inner mold, the vibration cavity is formed in the inner mold, and the;

the driving assembly comprises a driving motor, a first driving rotating rod, a driving wheel disc, a second driving rotating rod, a driving worm wheel and a driving worm, the driving motor is installed in the middle of the bottom of the driving cavity, the output end of the driving motor is rotatably installed at one end of the first driving rotating rod, the other end of the first driving rotating rod is rotatably installed in the middle of the driving wheel disc, a plurality of second driving rotating rods are uniformly and rotatably arranged on the driving wheel disc along the circumferential direction of the driving wheel disc, the driving worm wheel is fixedly installed on a pin shaft for connecting the outer mold frame body and the outer mold support rod, the driving worm is vertically installed in the driving frame body, the driving worm wheel is matched and connected with the driving worm, and the other end of each second;

the vibration component comprises a vibration support plate, a first vibration gear, a second vibration gear, a vibration rack, a vibration block and a vibration slide block, the vibration support plate is arranged above the vibration cavity, the first vibration gear is symmetrically arranged at two ends of one side surface of the vibration support plate, and two first vibration gears are meshed and connected, a vibration motor is arranged on the inner wall of the vibration cavity, the output end of the vibration motor is connected with one first vibration gear, two second vibration gears are symmetrically arranged at two ends of the other end of the vibration support plate, the first vibration gear and the second vibration gear rotate coaxially, a vibration rack is arranged in the middle of the second vibration gear, the second vibration gear is an incomplete gear, and the second vibration gear is meshed with the vibration rack, a vibration block is arranged below the vibration rack, a vibration sliding block is arranged at the lower end of the inner module in a sliding mode through a supporting spring, and the lower end face of the vibration block is in contact connection with the upper end face of the vibration sliding block.

As a further scheme of the invention: the upset branch chain is including the upset spout, the upset slider, the upset lead screw, the upset rack, upset axostylus axostyle and upset gear, the inside upset cavity of having seted up of shaping pillar, the upset spout has been seted up to upset cavity below, slidable mounting has the upset slider in the upset spout, pass the upset lead screw in the upset spout, be connected through screw-thread fit between upset slider and the upset lead screw, be provided with the upset rack on the upset slider, rotate through the bearing in the middle of the upset cavity lateral wall and install the upset axostylus axostyle, the upset gear is installed to upset axostylus axostyle one end, the upset rack.

As a further scheme of the invention: the outer die bottom plate is provided with an outer die frame body and an outer die sliding groove, the outer die bottom plate is provided with a first auxiliary sliding groove, a first auxiliary sliding block is arranged in the first auxiliary sliding groove in a sliding mode, the lower end of the outer die plate is provided with a second auxiliary sliding groove, a second auxiliary sliding block is arranged in the second auxiliary sliding groove in a sliding mode through an auxiliary spring, and the upper end of the first auxiliary sliding block is fixedly connected with the lower end of the second auxiliary sliding block.

As a further scheme of the invention: the positioning device is characterized in that a positioning groove with a Y-shaped cross section is formed in the upper end face of the outer die frame body, positioning blocks are symmetrically arranged at two ends of the lower surface of the inner die support plate and can be in matched contact with the positioning blocks, a positioning rod is rotatably mounted at the lower end of each positioning block through a pin shaft, a positioning spring is arranged between each positioning block and the upper end of each positioning rod, and a positioning roller is mounted.

As a further scheme of the invention: the upper end face of the outer template is provided with a positioning hole, the cross section of the inner module is T-shaped, positioning pins are arranged on the lower end faces of two sides of the inner module, and the positioning hole can be in matched contact with the positioning pins.

As a further scheme of the invention: a herringbone cavity is formed in the vibrating block, a vibrating ball is slidably mounted in the cavity, a vibrating spring is connected between the vibrating ball and two ends of the bottom of the cavity, and a rubber hard plate is arranged in the middle of the bottom of the cavity in a hanging mode.

Compared with the prior art, the invention has the following advantages:

the design that can solve present packing jar casting forming die has following problem: when the existing metal packaging can casting forming die is used for demoulding the metal packaging can, the inner die and the outer die are directly stripped from the can body, the mould is easily damaged by the demoulding mode, the problems of uneven appearance and deviation exceeding a specified error range in size can be caused when the rear can body is cast and formed, the existing can body after cooling and forming is manually demoulded by workers, the risk of scratching the hands of the workers can be caused due to the burrs on the surface of the formed can body, the manual demoulding efficiency is low, and the production efficiency of the can body is influenced;

according to the casting forming die for the metal packaging can, the formed can body is separated from the outer template and the inner module in an automatic vibration mode, so that the demolding efficiency of the can body is effectively accelerated, the risk of scratching hands of workers due to burrs on the surface of the can body is avoided, the outer template in the outer die unit can be automatically separated and assembled, the demolding efficiency of the can body is effectively improved, and the production efficiency of the can body is accelerated;

the turning branched chain designed by the invention can turn over the external mold unit to enable the demolded tank body to slide out of the external mold unit, so that a worker does not need to take out the tank body from the mold, the internal mold of the mold is hung above the external mold and has the risk of falling, and the problems that the worker is injured and the working progress is influenced can be effectively avoided.

Drawings

The invention is further illustrated with reference to the following figures and examples.

FIG. 1 is a schematic perspective view of the present invention;

FIG. 2 is a schematic view of the front cross-sectional structure of the present invention;

FIG. 3 is a perspective view of the drive assembly of the present invention;

FIG. 4 is an enlarged schematic view of FIG. 2 at A of the present invention;

FIG. 5 is a schematic cross-sectional view taken along line B-B of FIG. 2 according to the present invention.

Detailed Description

In order to make the technical means, the creation features, the achievement purposes and the effects of the invention easy to understand, the invention is further explained with reference to fig. 1 to 5.

A metal packaging can casting forming die comprises a base 1 and a forming device 2, wherein the forming device 2 is arranged on the upper surface of the base 1; wherein:

the forming device 2 comprises forming support columns 20, turning branch chains 21, outer mold units 22, lifting cylinders 23 and inner mold units 24, the forming support columns 20 are symmetrically arranged at two ends of the upper surface of the base 1, the turning branch chains 21 are symmetrically arranged on opposite surfaces between the forming support columns 20, the outer mold units 22 are arranged between the turning branch chains 21, the lifting cylinders 23 are arranged at the upper ends of the forming support columns 20, the inner mold units 24 are arranged at the output ends of the lifting cylinders 23, and the outer mold units 22 are positioned outside the inner units and on the same central line; when the metal packaging can is in specific work, after the outer die unit 22 is assembled and adjusted, the lifting cylinder 23 drives the inner die unit 24 to move downwards to be combined with the outer die unit 22, then metal raw materials required by the metal packaging can are melted and poured into a material injection cavity of a combined section of the outer die unit 22 and the inner die unit 24, after the raw materials are cooled and formed, the outer die unit 22 and the inner die unit 24 are separated, then the outer die unit 22 is turned over by the turning branched chain 21 for a certain angle, so that the formed packaging can body slides out of the outer die unit 22, and then the forming and demolding of the metal packaging can be completed.

The turning branched chain 21 comprises a turning chute 210, a turning slider 211, a turning lead screw 212, a turning rack 213, a turning shaft rod 214 and a turning gear 215, a turning cavity is formed in the forming support column 20, the turning chute 210 is formed below the turning cavity, the turning slider 211 is slidably mounted in the turning chute 210, the turning lead screw 212 penetrates through the turning chute 210, the turning slider 211 is connected with the turning lead screw 212 in a threaded fit manner, the turning rack 213 is arranged on the turning slider 211, the turning shaft rod 214 is rotatably mounted in the middle of the side wall of the turning cavity through a bearing, the turning gear 215 is mounted at one end of the turning shaft rod 214, the turning rack 213 is meshed with the turning gear 215, and the outer die unit 22 is fixedly connected with the other; during specific work, when the outer die unit 22 needs to be turned, the turning screw 212 is rotated to enable the turning sliding block 211 to slide in the turning sliding groove 210, the sliding of the turning sliding block 211 drives the turning rack 213 to move, the turning rack 213 moves to drive the turning gear 215 to rotate, and the turning gear 215 rotates to drive the turning shaft rod 214 to rotate, so that the turning shaft rod 214 drives the outer die unit 22 to turn.

The outer die unit 22 comprises an outer die bottom plate 220, outer die frame bodies 221, a driving cavity 222, driving components 223, outer die support rods 224, outer die plates 225, outer die sliding grooves 226 and outer die bottom blocks 227, wherein the outer die frame bodies 221 are uniformly installed on the edge of the upper surface of the outer die bottom plate 220, the driving cavity 222 is formed in the outer die bottom plate 220, the driving components 223 are arranged in the driving cavity 222, two outer die support rods 224 are sequentially arranged on one side of each outer die frame body 221 in the length direction of the outer die frame body through a pin shaft, the other end of each outer die support rod 224 is connected with the outer side of each outer die plate 225 through a hinge, the outer die sliding groove 226 is formed in the middle of the upper; in operation, the driving assembly 223 in the driving cavity 222 can rotate the outer mold support rod 224 in the outer mold frame 221, so that the other end of the outer mold support rod 224 pushes the outer mold plates 225 to approach or separate from each other, thereby realizing the combination or separation between the outer mold plates 225 and the inner mold unit 24, when the outer mold plates 225 approach each other, the outer mold plates will finally contact with the edge of the outer mold bottom block 227, so as to form a cavity except the upper opening, and then a closed cavity can be formed by matching with the inner mold unit 24 for casting the metal packaging can.

The inner die unit 24 comprises an inner die support plate 240, an inner die 241, a feeding pipe 242, an exhaust pipe 243, a vibration cavity 244 and a vibration component 245, the inner die support plate 240 is arranged at the output end of the lifting cylinder 23, the inner die 241 is arranged in the middle of the lower surface of the inner die support plate 240, the feeding pipes 242 are symmetrically arranged on the upper end surface of the inner die 241 in a left-right mode, the exhaust pipes 243 are symmetrically arranged on the upper end surface of the inner die 241 in a front-back mode, the vibration cavity 244 is arranged in the inner die 241, and; when the metal packaging can is specifically operated, the inner module 241, the outer template 225 and the outer mold bottom block 227 form a closed cavity, then casting operation can be carried out, metal raw materials required by the metal packaging can are poured into the cavity from the feeding pipe 242 after being melted, the exhaust pipe 243 can exhaust redundant gas in the cavity and can also dissipate heat, and after molten liquid is cooled and formed, the inner module 241, the outer template 225 and the outer mold bottom block 227 can be quickly separated from a formed can body through the vibration effect of the vibration assembly 245 in the vibration cavity 244 so as to achieve the effect of demolding.

A first auxiliary sliding groove 2200 is formed in the part between the outer mold frame body 221 and the outer mold sliding groove 226 on the outer mold bottom plate 220, a first auxiliary sliding block 2201 is installed in the first auxiliary sliding groove 2200 in a sliding manner, a second auxiliary sliding groove 2250 is formed in the lower end of the outer mold plate 225, a second auxiliary sliding block 2251 is installed in the second auxiliary sliding groove 2250 in a sliding manner through an auxiliary spring, and the upper end of the first auxiliary sliding block 2201 is fixedly connected with the lower end of the second auxiliary sliding block 2251; in specific operation, when the outer die supporting rod 224 pushes the outer die plate 225 to move, the first auxiliary sliding block 2201 slides in the first auxiliary sliding groove 2200 so that the outer die plate 225 can move stably, and the second auxiliary sliding block 2251 moves in the second auxiliary sliding groove 2250 so that the outer die plate 225 can also move up and down, so that the outer die plate 225 can be in fit contact with the outer die base plate 227.

The upper end surface of the outer mold frame body 221 is provided with a positioning groove 2210 with a Y-shaped cross section, two ends of the lower surface of the inner mold support plate 240 are symmetrically provided with positioning blocks 2211, the positioning groove 2210 and the positioning blocks 2211 can be in matched contact, the lower end of the positioning block 2211 is rotatably provided with a positioning rod 2212 through a pin shaft, a positioning spring is arranged between the positioning block 2211 and the upper end of the positioning rod 2212, and the lower end of the positioning rod 2212 is provided with a positioning roller; during specific work, because the outer mold unit 22 can rotate along with the turning branched chain 21, when the inner mold 241 is in butt joint with the outer mold plate 225, the positioning roller 2213 at the lower end of the positioning rod 2212 at the lower end of the positioning block 2211 contacts with the wall of the positioning groove 2210 first, and then in the process that the positioning rod 2212 slowly enters the bottom of the positioning groove 2210, the opposite surfaces of the outer mold frame 221 and the inner mold support plate 240 are aligned, so that the probability of errors occurring when the outer mold plate 225 is in butt joint with the inner mold plate 241 can be effectively reduced.

The driving assembly 223 comprises a driving motor 2230, a first driving rotating rod 2231, a driving wheel disc 2232, a second driving rotating rod 2233, a driving worm wheel 2234 and a driving worm screw 2235, the middle of the bottom of the driving cavity 222 is provided with the driving motor 2230, the output end of the driving motor 2230 is rotatably installed with one end of the first driving rotating rod 2231, the other end of the first driving rotating rod 2231 is rotatably installed with the middle of the driving wheel disc 2232, the driving wheel disc 2232 is uniformly and rotatably provided with a plurality of second driving rotating rods 2233 along the circumferential direction thereof, a driving worm wheel 2234 is fixedly installed on a pin shaft for connecting the outer mold frame 221 and the outer mold support rod 224, the driving worm screw 2235 is vertically installed in the driving frame, the driving worm wheel 2234 is connected with the driving worm screw 2235 in a matching manner, and the other end of the second driving rotating rod 2233; during specific work, the driving motor 2230 can drive the driving wheel disc 2232 to rotate through the first driving rotating rod 2231, the rotating axis of the driving wheel disc 2232 is not consistent with the rotating axis of the driving motor 2230, then the driving wheel disc 2232 can drive the driving worm 2235 to rotate through the second driving rotating rod 2233, then the driving worm 2235 drives the driving worm wheel 2234 to rotate, and the driving worm wheel 2234 can drive the outer mold support rod 224 to rotate, so that the outer mold plates 225 can be close to or far away from each other.

The upper end face of the outer template 225 is provided with a positioning hole, the cross section of the inner module 241 is T-shaped, positioning pins are arranged on the lower end faces of two sides of the inner module 241, and the positioning hole can be in matched contact with the positioning pins; during specific work, the positioning hole is in contact with the positioning rod in a matched mode, so that the butt joint effect between the outer template 225 and the inner module 241 is better, the error is smaller, and the tank manufacturing effect is better.

The vibrating component 245 comprises a vibrating support plate 2450, a first vibrating gear 2451, a second vibrating gear 2452, a vibrating rack 2453, a vibrating block 2454 and a vibrating slide 2455, the vibrating support plate 2450 is arranged above the vibrating cavity 244, the first vibrating gear 2451 is symmetrically arranged at two ends of one side surface of the vibrating support plate 2450, the two first vibrating gears 2451 are meshed and connected, a vibrating motor is arranged on the inner wall of the vibrating cavity 244, the output end of the vibrating motor is connected with one first vibrating gear 2451, the second vibrating gear 2452 is symmetrically arranged at two ends of the other end of the vibrating support plate 2450, the first vibrating gear 2451 and the second vibrating gear 2452 rotate coaxially, the vibrating rack 2453 is arranged in the middle of the second vibrating gear 2452, the second vibrating gear 2452 is an incomplete gear, the second vibrating gear 2452 is meshed and connected with the vibrating rack 2453, the vibrating block 2454 is arranged below the vibrating rack 2454, the vibrating slide 5 is arranged at the lower end of the inner module 241 through a supporting spring in a sliding, the lower end face of the vibrating block 2454 is in contact connection with the upper end face of the vibrating slide block 2455; when the cooling forming tank needs to be demoulded, the vibration motor is started to drive the first vibration gear 2451 to rotate, the rotation directions of the first vibration gear 2451 are opposite, so that the rotation directions of the second vibration gear 2452 are opposite, then the second vibration gear 2452 drives the vibration rack 2453 to move upwards, when no tooth meshed with the vibration rack 243 exists on the second vibration gear 2452, the vibration block 2454 falls down under the action of gravity, then the vibration block 2454 impacts the vibration slide block 2455, then the vibration slide block 2455 vibrates the bottom of the forming tank under the action of the vibration spring, so that the tank is separated from the outer template 225 and the inner module 241, when the tooth on the second vibration gear 2452 is meshed with the tooth on the vibration rack 243 again, the vibration block 2454 is driven to move upwards, then no tooth meshed with the vibration rack 243 exists on the second vibration gear 2452, the vibrating mass 2454 falls down due to gravity, thereby realizing repeated vibration demoulding operation of the tank body.

A herringbone cavity is formed in the vibrating block 2454, a vibrating ball 2456 is slidably mounted in the cavity, a vibrating spring is connected between the vibrating ball 2456 and two ends of the bottom of the cavity, and a rubber hard plate 2457 is suspended in the middle of the bottom of the cavity; during specific work, when the vibrating mass 2454 falls, due to the inertia effect, the vibrating ball 2456 cannot fall along with the vibrating mass 2454, when the vibrating spring is stretched by the vibrating mass 2454, the vibrating spring can pull the vibrating ball 2456 to move downwards, the vibrating ball can hit the rubber hard plate 2457, then the rubber hard plate 2457 can transmit vibration to the vibrating mass 2454, the impact force of the vibrating mass 2454 on the vibrating slide block 2455 is increased, and the rubber hard plate 2457 can effectively reduce noise generated by vibration.

Although the preferred embodiments of the present patent have been described in detail, the present patent is not limited to the above embodiments, and various changes can be made without departing from the spirit of the present patent within the knowledge of those skilled in the art.

Claims

1. The utility model provides a metal packaging jar casting forming die, includes base (1) and forming device (2), its characterized in that: the upper surface of the base (1) is provided with a forming device (2); wherein:

the forming device (2) comprises forming support columns (20), turning branch chains (21), outer mold units (22), lifting cylinders (23) and inner mold units (24), the forming support columns (20) are symmetrically arranged at two ends of the upper surface of the base (1), the turning branch chains (21) are symmetrically arranged on opposite surfaces between the forming support columns (20), the outer mold units (22) are arranged between the turning branch chains (21), the lifting cylinders (23) are arranged at the upper ends of the forming support columns (20), the inner mold units (24) are installed at the output ends of the lifting cylinders (23), and the outer mold units (22) are located on the outer sides of the inner units and located on the same central line;

the outer die unit (22) comprises an outer die base plate (220), an outer die frame body (221), a driving cavity (222), a driving assembly (223), outer die support rods (224), an outer die plate (225), an outer die sliding groove (226) and an outer die bottom block (227), wherein the outer die frame bodies (221) are uniformly installed on the edge of the upper surface of the outer die base plate (220), the driving cavity (222) is formed in the outer die base plate (220), the driving assembly (223) is arranged in the driving cavity (222), two outer die support rods (224) are sequentially arranged on one side of each outer die frame body (221) in the length direction of the outer die frame body through a pin shaft, the other ends of the outer die support rods (224) are connected with the outer side of the outer die plate (225) through hinges, the outer die sliding groove (226) is formed in the middle of the;

the internal mold unit (24) comprises an internal mold support plate (240), an internal module (241), a feeding pipe (242), an exhaust pipe (243), a vibration cavity (244) and a vibration assembly (245), the internal mold support plate (240) is arranged at the output end of the lifting cylinder (23), the internal module (241) is arranged in the middle of the lower surface of the internal mold support plate (240), the feeding pipes (242) are symmetrically arranged on the left and right of the upper end surface of the internal module (241), the exhaust pipes (243) are symmetrically arranged in front and at the back of the upper end surface of the internal module (241), the vibration cavity (244) is formed in the internal module (241), and the vibration assembly (;

the driving component (223) comprises a driving motor (2230), a first driving rotating rod (2231), a driving wheel disc (2232), a second driving rotating rod (2233), a driving turbine wheel (2234) and a driving worm (2235), a driving motor (2230) is installed in the middle of the bottom of the driving cavity (222), the output end of the driving motor (2230) is rotatably installed with one end of a first driving rotating rod (2231), the other end of the first driving rotating rod (2231) is rotatably installed with the middle of a driving wheel disc (2232), a plurality of second driving rotating rods (2233) are uniformly and rotatably arranged on the driving wheel disc (2232) along the circumferential direction of the driving wheel disc, a driving turbine (2234) is fixedly installed on a pin shaft for connecting the outer mold frame body (221) and the outer mold support rod (224), a driving worm (2235) is vertically installed in the driving frame body, the driving turbine (2234) is connected with the driving worm (2235) in a matching manner, and the other end of the second driving rotating rod (2233) is fixedly connected with the lower end;

the vibration assembly (245) comprises a vibration support plate (2450), a first vibration gear (2451), a second vibration gear (2452), a vibration rack (2453), a vibration block (2454) and a vibration slide block (2455), the vibration support plate (2450) is arranged above the vibration cavity (244), the first vibration gear (2451) is symmetrically arranged at two ends of one side surface of the vibration support plate (2450), the two first vibration gears (2451) are connected in a meshed mode, a vibration motor is arranged on the inner wall of the vibration cavity (244), the output end of the vibration motor is connected with one first vibration gear (2451), the second vibration gear (2452) is symmetrically arranged at two ends of the other end of the vibration support plate (2450), the first vibration gear (2451) and the second vibration gear (2452) rotate coaxially, the vibration rack (243) is arranged in the middle of the second vibration gear (2452), the second vibration gear (2452) is an incomplete gear, and the second vibration gear (2452) is meshed with the vibration rack (2453), a vibration block (2454) is arranged below the vibration rack (2453), the lower end of the inner module (241) is provided with a vibration slide block (2455) in a sliding manner through a supporting spring, and the lower end face of the vibration block (2454) is in contact connection with the upper end face of the vibration slide block (2455).

2. The metal packaging can casting mold of claim 1, wherein: the turning branched chain (21) comprises a turning chute (210), a turning sliding block (211), a turning lead screw (212), a turning rack (213), a turning shaft lever (214) and a turning gear (215), the inside upset cavity of having seted up of shaping pillar (20), upset spout (210) have been seted up to upset cavity below, slidable mounting has upset slider (211) in upset spout (210), pass upset lead screw (212) in upset spout (210), be connected through screw-thread fit between upset slider (211) and upset lead screw (212), be provided with upset rack (213) on upset slider (211), install upset axostylus axostyle (214) through the bearing rotation in the middle of the upset cavity lateral wall, upset gear (215) are installed to upset axostylus axostyle (214) one end, upset rack (213) are connected with upset gear (215) meshing, external mold unit (22) and upset axostylus axostyle (214) other end fixed connection.

3. The metal packaging can casting mold of claim 1, wherein: the part between outer mold frame body (221) and outer mold spout (226) on outer mold bottom plate (220) has seted up one auxiliary sliding groove (2200), and slidable mounting has one auxiliary sliding block (2201) in one auxiliary sliding groove (2200), No. two auxiliary sliding grooves (2250) have been seted up to outer template (225) lower extreme, have No. two auxiliary sliding block (2251) through auxiliary spring slidable mounting in No. two auxiliary sliding groove (2250), No. two auxiliary sliding block (2251) lower extreme fixed connection of one auxiliary sliding block (2201) upper end and No. two auxiliary sliding block (2251).

4. The metal packaging can casting mold of claim 1, wherein: positioning grooves (2210) with Y-shaped cross sections are formed in the upper end face of the outer die frame body (221), positioning blocks (2211) are symmetrically arranged at two ends of the lower surface of the inner die supporting plate (240), the positioning grooves (2210) can be in matched contact with the positioning blocks (2211), positioning rods (2212) are rotatably mounted at the lower ends of the positioning blocks (2211) through pin shafts, positioning springs are arranged between the upper ends of the positioning blocks (2211) and the upper ends of the positioning rods (2212), and positioning rollers (2213) are mounted at the lower ends of the positioning rods (2212.

5. The metal packaging can casting mold of claim 1, wherein: the upper end face of the outer template (225) is provided with a positioning hole, the cross section of the inner module (241) is T-shaped, positioning pins are arranged on the lower end faces of the two sides of the inner module (241), and the positioning holes can be in matched contact with the positioning pins.

6. The metal packaging can casting mold of claim 1, wherein: a herringbone cavity is formed in the vibrating block (2454), a vibrating ball (2456) is slidably mounted in the cavity, a vibrating spring is connected between the vibrating ball (2456) and two ends of the bottom of the cavity, and a rubber hard plate (2457) is arranged in the middle of the bottom of the cavity in a hanging mode.