CN215325133U - Equipment for realizing high-speed neck forming of pop-top can by multi-channel feeding - Google Patents

Abstract

A device for realizing high-speed neck forming of pop cans by multi-channel feeding comprises a can feeding station and a plurality of groups of neck forming stations; the tank inlet station comprises at least two groups of tank inlet channels and a feeding transfer turntable; each group of tank inlet channels comprises a feeding turntable and a feeding transfer turntable, the feeding turntable is arranged corresponding to one feeding channel, and the number of the feeding channels is the same as that of the tank inlet channels; a plurality of vacuum adsorption grooves are uniformly distributed on the feeding rotary table, and a plurality of vacuum adsorption grooves are uniformly distributed on the feeding transfer rotary table; when the feeding turntable and the feeding transfer turntable rotate to feed, two opposite vacuum adsorption tanks on the feeding turntable and the feeding transfer turntable define a joint position together, and the tank body enters the feeding transfer turntable from the feeding turntable through the joint position; the feeding transfer turnplate is positioned at the rear side of each feeding transfer turnplate, and each feeding transfer turnplate alternately feeds materials into the feeding transfer turnplate in sequence. The utility model can multiply improve the production speed or reduce the speed requirement of the original mechanism in the equipment, and ensure the stability of the can when entering the die.

Description

Equipment for realizing high-speed neck forming of pop-top can by multi-channel feeding

Technical Field

The utility model relates to the field of processing equipment of pop cans, in particular to equipment for realizing high-speed neck forming of pop cans by multi-channel feeding.

Background

With the development of socio-economic, the market demands higher and higher production speed and stability of the equipment in the manufacturing industry. For example, in a multi-station neck forming device in a pop Can production process in the metal packaging industry, the market generally requires that the production speed is up to 3000CPM + (CPM is Can Per Minute) or even 3400CPM +, so that the key of the market intense competition is to stably realize high-speed production.

The production of pop-top can needs several processes including cup punching, drawing, trimming, color printing, inner spraying, neck forming, etc. Fig. 1 shows the cut can and fig. 2 shows the neck-formed can. The production speed can be improved by increasing the number of configured devices such as the stretching machine adopted in the stretching process and the internal spraying machine adopted in the internal spraying process, the cost of the devices adopted in the neck forming process is higher, and the occupied area of the devices is large, so that the cost is greatly improved and more occupied areas are occupied by simply increasing the number to improve the production speed.

Meanwhile, the tank bodies are conveyed among a plurality of processes of pop can production through pipelines, the requirement of ultrahigh-speed production on pipeline design is high, and if pipeline conveying is not smooth, equipment cannot run at high speed.

In addition, before the can body enters the neck forming equipment, the can mouth part needs to be lubricated by mineral oil or hot wax so as to form a multi-mouth part. If a non-contact type lubricating system is adopted, the speed of the set of lubricating system (the rated design speed is 3000 CPM) is also the bottleneck for restricting the higher speed increase of the equipment at present.

In summary, the present invention is to solve the problem of high-speed production without changing the conventional neck molding equipment.

Disclosure of Invention

The utility model aims to provide equipment for realizing high-speed neck forming of a pop can by multi-channel feeding.

In order to achieve the purpose, the utility model adopts the technical scheme that:

a device for realizing high-speed neck forming of pop cans through multi-channel feeding sequentially comprises a can feeding station and a plurality of groups of neck forming stations from front to back according to the processing sequence of the pop cans;

the tank inlet station comprises at least two groups of tank inlet channels and a feeding transfer turntable;

each group of tank inlet channels comprises a feeding turntable and a feeding transfer turntable, the feeding turntable is arranged corresponding to one feeding channel, and the number of the formed feeding channels is the same as that of the tank inlet channels; the feeding channel is used for conveying the pop cans to be subjected to neck forming into the feeding turntable;

the feeding turntable is a star wheel, a plurality of vacuum adsorption grooves are uniformly distributed on the circumferential surface of the feeding turntable, and the vacuum adsorption grooves are arc-shaped and are used for adsorbing and positioning the tank body of the pop can;

the feeding transfer turntable is positioned at the rear side of the feeding turntable, and a rotating shaft of the feeding transfer turntable is parallel to a rotating shaft of the feeding turntable; the feeding transfer turntable is a star wheel, and a plurality of vacuum adsorption grooves are uniformly distributed on the circumferential surface of the feeding transfer turntable; when the feeding turntable and the feeding transfer turntable rotate to feed, two opposite vacuum adsorption grooves on the feeding turntable and the feeding transfer turntable are defined together to form a circular joint, and the tank body enters the vacuum adsorption groove of the feeding transfer turntable from the vacuum adsorption groove of the feeding turntable through the joint;

the feeding transfer turnplate is positioned at the rear side of each feeding transfer turnplate, and each group of feeding transfer turnplates of the tank inlet channel sequentially and alternately feed materials into the feeding transfer turnplates.

The relevant content in the above technical solution is explained as follows:

1. in the scheme, the rotating shaft of the feeding transfer turntable is parallel to the rotating shaft of the feeding turntable; the feeding transfer turntable is a star wheel, and a plurality of vacuum adsorption grooves are uniformly distributed on the circumferential surface of the feeding transfer turntable; constitute and when carousel and the material loading were transported in the feeding and transport the carousel and rotate the feeding, two relative vacuum adsorption tanks on the two define jointly and form circular handing-over position, the jar body is followed through this handing-over position enter into in the vacuum adsorption tank of carousel is transported in the feeding in the vacuum adsorption tank of carousel to the material loading.

2. In the above scheme, the neck molding station comprises a main shaft assembly and a transfer assembly; the spindle assembly comprises a forming spindle turntable, and the transfer assembly comprises a forming transfer turntable;

the rotating shafts of the forming main shaft turntable and the forming transfer turntable are parallel to the rotating shaft of the feeding transfer turntable; the forming main shaft turntable and the forming transfer turntable are star wheels, and a plurality of positioning grooves are uniformly distributed on the circumferential surface of the forming main shaft turntable, are in an arc shape and are used for positioning the tank body of the pop can; a plurality of vacuum adsorption grooves are uniformly distributed on the circumferential surface of the forming transfer turntable;

when the loading transfer turntable and the forming spindle turntable rotate to receive materials, the vacuum adsorption groove on the loading transfer turntable and the positioning groove on the forming spindle turntable define together to form a transfer position, and the tank body enters the positioning groove of the forming spindle turntable from the vacuum adsorption groove of the loading transfer turntable through the transfer position;

when the forming spindle turntable and the forming transfer turntable rotate to receive materials, the positioning groove on the forming spindle turntable and the vacuum adsorption groove on the forming transfer turntable define and form the transfer position together, and the tank body enters the vacuum adsorption groove of the forming transfer turntable from the positioning groove of the forming spindle turntable through the transfer position;

and the neck forming stations are connected front and back, the neck forming of the tank body is completed step by step, and the discharging of a finished product is completed in the last campaign.

3. In the above scheme, the main shaft assembly of the neck molding station further comprises a plurality of sets of die assemblies and a plurality of sets of push plate assemblies;

the die assemblies and the push plate assemblies are arranged in a one-to-one correspondence mode and are respectively arranged on two sides of the tank body along the height direction of the tank body. During processing, the execution part push plate in the push plate assembly pushes the tank body to translate towards the mould assembly, and the neck of the tank body is formed through the execution part mould of the latter.

Since the neck forming station can be constructed by the prior art and is not the utility model of the present application, the principle and details thereof are not described in detail in the present application.

The working principle and the advantages of the utility model are as follows:

the utility model relates to equipment for realizing high-speed neck forming of pop cans by multi-channel feeding, which comprises a can feeding station and a plurality of groups of neck forming stations; the tank inlet station comprises at least two groups of tank inlet channels and a feeding transfer turntable; each group of tank inlet channels comprises a feeding turntable and a feeding transfer turntable, the feeding turntable is arranged corresponding to one feeding channel, and the number of the feeding channels is the same as that of the tank inlet channels; a plurality of vacuum adsorption grooves are uniformly distributed on the feeding rotary table, and a plurality of vacuum adsorption grooves are uniformly distributed on the feeding transfer rotary table; when the feeding turntable and the feeding transfer turntable rotate to feed, two opposite vacuum adsorption tanks on the feeding turntable and the feeding transfer turntable define a joint position together, and the tank body enters the feeding transfer turntable from the feeding turntable through the joint position; the feeding transfer turnplate is positioned at the rear side of each feeding transfer turnplate, and each feeding transfer turnplate alternately feeds materials into the feeding transfer turnplate in sequence.

Compared with the prior art, the equipment for realizing multi-channel high-speed feeding by using the multi-slot turntable is designed, and is suitable for the situation that the equipment needs to realize ultrahigh-speed production.

The utility model can reduce the speed requirement on the conveying mechanism and the feeding pretreatment mechanism, namely, the original mechanism for pretreating materials on the conveying mechanism can be continuously used. That is, if a dual pass feed is designed, the same production speed requirements, the conveyor and preconditioner speeds can be reduced to 1/2 of the original speed.

In addition, through increasing the handing-over position, when the jar body got into handing-over position once, the stable calibration of position can all be carried out once to the jar body, and then increased the stabilization time of the jar body to the position is enough stable and avoids taking place the shake when finally guaranteeing jar body entering neck shaping station. Namely, the stable and reliable processing of the neck forming can be carried out at high can height and high speed through repeated can body repositioning.

In conclusion, the present invention can be directly modularized on the existing equipment, multiply increase the production speed or reduce the speed requirement of the original mechanism in the equipment, and meet the requirement of high-speed production by ensuring the stability of the can when entering the neck forming mold.

Drawings

FIG. 1 shows a cut-off pop can;

FIG. 2 shows a formed neck can;

FIG. 3 is a first schematic structural diagram (top view) of an embodiment of the present invention;

FIG. 4 is a second schematic structural diagram (front view angle) according to an embodiment of the present invention;

FIG. 5 is an enlarged view taken at I in FIG. 3;

FIG. 6 is a schematic diagram of a prior art configuration (top view);

fig. 7 is a schematic structural diagram (front view angle) of the prior art.

In the above drawings: 0. a tank body; 1. a feed turntable; 2. a loading transfer turntable; 3. a vacuum adsorption tank; 4. a feed transfer carousel; 4a, a first handover bit; 4 b. a second handover bit; 5. a feeding channel; 7. forming a main shaft turntable; 8. forming a transfer turntable; 9. positioning a groove; 10. a transfer site; 11. pushing the plate; 12. a mold; A. a feed station; B. a neck forming station.

Detailed Description

The utility model is further described with reference to the following figures and examples:

example (b): the present disclosure will be described more fully hereinafter with reference to the accompanying drawings, in which embodiments of the disclosure may be shown and described, and which, when modified and varied by the techniques taught herein, can be made by those skilled in the art without departing from the spirit and scope of the disclosure.

The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the disclosure. The singular forms "a", "an", "the" and "the", as used herein, also include the plural forms.

The terms "first," "second," and the like, as used herein, do not denote any order or importance, nor do they denote any order or importance, but rather are used to distinguish one element from another element or operation described in such technical terms.

As used herein, "connected" or "positioned" refers to two or more elements or devices being in direct physical contact with each other or in indirect physical contact with each other, and may also refer to two or more elements or devices being in operation or acting on each other.

As used herein, the terms "comprising," "including," "having," and the like are open-ended terms that mean including, but not limited to.

As used herein, the term (terms), unless otherwise indicated, shall generally have the ordinary meaning as commonly understood by one of ordinary skill in the art, in this written description and in the claims. Certain words used to describe the disclosure are discussed below or elsewhere in this specification to provide additional guidance to those skilled in the art in describing the disclosure.

Referring to the attached drawings 3-7, the equipment for realizing the high-speed neck forming of the pop cans through multi-channel feeding sequentially comprises a can feeding station A and a plurality of groups of neck forming stations B from front to back according to the processing sequence of the pop cans.

Wherein, the tank inlet station A comprises at least two groups of tank inlet channels and a feeding transfer turntable 2.

Each group of tank inlet channels comprises a feeding turntable 1 and a feeding transfer turntable 4, the feeding turntable 1 is arranged corresponding to a feeding channel 5, and the number of the feeding channels 5 is the same as that of the tank inlet channels; the feeding channel 5 is used for conveying the pop cans to be subjected to neck forming into the feeding turntable 1.

The feeding turntable 1 is a star wheel, a plurality of vacuum adsorption grooves 3 are uniformly distributed on the circumferential surface of the feeding turntable, and the vacuum adsorption grooves 3 are arc-shaped and used for adsorbing and positioning the tank body 0 of the pop can.

The feeding transfer turntable 4 is positioned at the rear side of the feeding turntable 1, and a rotating shaft of the feeding transfer turntable 4 is parallel to a rotating shaft of the feeding turntable 1; the feeding transfer turntable 4 is a star wheel, and a plurality of vacuum adsorption grooves 3 are uniformly distributed on the circumferential surface of the feeding transfer turntable; when the feeding turntable 1 and the feeding transfer turntable 4 rotate to feed materials, two opposite vacuum adsorption tanks 3 on the feeding turntable 1 and the feeding transfer turntable 4 are defined together to form a first cross-over position 4a, and the tank body 0 enters the vacuum adsorption tank 3 of the feeding transfer turntable 4 from the vacuum adsorption tank 3 of the feeding turntable 1 through the first cross-over position 4 a.

The feeding transfer rotary table 2 is positioned at the rear side of each feeding transfer rotary table 4, and each group of the feeding transfer rotary tables 4 of the tank inlet channels sequentially and alternately feed into the feeding transfer rotary table 2.

The rotating shaft of the feeding transfer turntable 2 is parallel to the rotating shaft of the feeding turntable 1; the feeding transfer turntable 2 is a star wheel, and a plurality of vacuum adsorption grooves 3 are uniformly distributed on the circumferential surface of the feeding transfer turntable; when the feeding transfer rotary disc 4 and the feeding transfer rotary disc 2 rotate to feed, two opposite vacuum adsorption grooves 3 on the feeding transfer rotary disc 4 and the feeding transfer rotary disc 2 jointly define a second cross joint 4b, and the tank body 0 enters the vacuum adsorption groove 3 of the feeding transfer rotary disc 2 from the vacuum adsorption groove 3 of the feeding transfer rotary disc 4 through the second cross joint 4 b.

Wherein the neck forming station B comprises a main shaft assembly and a transfer assembly; the main shaft assembly comprises a forming main shaft turntable 7, and the transferring assembly comprises a forming transferring turntable 8.

The rotating shafts of the forming spindle turntable 7 and the forming transfer turntable 8 are parallel to the rotating shaft of the feeding transfer turntable 2; the forming spindle turntable 7 and the forming transfer turntable 8 are star wheels, a plurality of positioning grooves 9 are uniformly distributed on the circumferential surface of the forming spindle turntable 7, and the positioning grooves 9 are arc-shaped (preferably semicircular) and are used for positioning a can body 0 of a pop can; the periphery of the molding transfer turntable 8 is evenly provided with a plurality of vacuum adsorption grooves 3.

When the loading transfer turntable 2 and the forming spindle turntable 7 receive materials in a rotating mode, the vacuum adsorption groove 3 on the loading transfer turntable and the positioning groove 9 on the forming spindle turntable define together to form a transfer position 10, and the tank body 0 enters the positioning groove 9 of the forming spindle turntable 7 from the vacuum adsorption groove 3 of the loading transfer turntable 2 through the transfer position 10.

When the forming spindle rotary table 7 and the forming transfer rotary table 8 receive materials in a rotating manner, the positioning groove 9 on the former and the vacuum adsorption groove 3 on the latter define and form the transfer position 10 together, and the tank 0 enters the vacuum adsorption groove 3 of the forming transfer rotary table 8 from the positioning groove 9 of the forming spindle rotary table 7 through the transfer position 10.

Wherein the spindle assembly of the neck molding station B further comprises a plurality of sets (typically twelve sets) of mold assemblies and a plurality of sets (typically twelve sets) of pusher plate assemblies. The die assemblies and the push plate assemblies are arranged in a one-to-one correspondence mode and are respectively arranged on two sides of the tank body 0 along the height direction of the tank body 0. During processing, the can body 0 is pushed by an actuating part push plate 11 in the push plate assembly to translate towards the die assembly, and the forming of the neck of the can body 0 is realized by an actuating part die 12 of the latter.

And the neck forming stations B are connected in a front-back manner, the neck forming of the tank body 0 is completed step by step, and the discharging of a finished product is completed at the last station. Since the neck forming station B can be constructed by the prior art and is not the utility model of the present application, the principle and details thereof are not described in detail in the present application.

Wherein, the structure of the feeding transfer turntable 2 can be the same as that of the molding transfer turntable 8.

In conclusion, the present invention can be directly modularized on the existing equipment, multiply increase the production speed or reduce the speed requirement of the original mechanism in the equipment, and meet the requirement of high-speed production by ensuring the stability of the can when entering the neck forming mold.

The above embodiments are merely illustrative of the technical ideas and features of the present invention, and the purpose thereof is to enable those skilled in the art to understand the contents of the present invention and implement the present invention, and not to limit the protection scope of the present invention. All equivalent changes and modifications made according to the spirit of the present invention should be covered within the protection scope of the present invention.

Claims (4)

1. The utility model provides a realize fashioned equipment of easy open can high-speed neck through multichannel material loading which characterized in that:

sequentially comprising a can feeding station and a plurality of groups of neck forming stations from front to back according to the processing sequence of the pop cans;

the tank inlet station comprises at least two groups of tank inlet channels and a feeding transfer turntable;

each group of tank inlet channels comprises a feeding turntable and a feeding transfer turntable, the feeding turntable is arranged corresponding to one feeding channel, and the number of the formed feeding channels is the same as that of the tank inlet channels; the feeding channel is used for conveying the pop cans to be subjected to neck forming into the feeding turntable;

the feeding turntable is a star wheel, a plurality of vacuum adsorption grooves are uniformly distributed on the circumferential surface of the feeding turntable, and the vacuum adsorption grooves are arc-shaped and are used for adsorbing and positioning the tank body of the pop can;

the feeding transfer turntable is positioned at the rear side of the feeding turntable, and a rotating shaft of the feeding transfer turntable is parallel to a rotating shaft of the feeding turntable; the feeding transfer turntable is a star wheel, and a plurality of vacuum adsorption grooves are uniformly distributed on the circumferential surface of the feeding transfer turntable; when the feeding turntable and the feeding transfer turntable rotate to feed, two opposite vacuum adsorption grooves on the feeding turntable and the feeding transfer turntable are defined together to form a circular joint, and the tank body enters the vacuum adsorption groove of the feeding transfer turntable from the vacuum adsorption groove of the feeding turntable through the joint;

the feeding transfer turnplate is positioned at the rear side of each feeding transfer turnplate, and each group of feeding transfer turnplates of the tank inlet channel sequentially and alternately feed materials into the feeding transfer turnplates.

2. The high speed neck molding apparatus of claim 1 wherein: the rotating shaft of the feeding transfer turntable is parallel to the rotating shaft of the feeding turntable; the feeding transfer turntable is a star wheel, and a plurality of vacuum adsorption grooves are uniformly distributed on the circumferential surface of the feeding transfer turntable; constitute and when carousel and the material loading were transported in the feeding and transport the carousel and rotate the feeding, two relative vacuum adsorption tanks on the two define jointly and form circular handing-over position, the jar body is followed through this handing-over position enter into in the vacuum adsorption tank of carousel is transported in the feeding in the vacuum adsorption tank of carousel to the material loading.

3. The high speed neck molding apparatus of claim 1 wherein: the neck molding station comprises a main shaft assembly and a transfer assembly; the spindle assembly comprises a forming spindle turntable, and the transfer assembly comprises a forming transfer turntable;

the rotating shafts of the forming main shaft turntable and the forming transfer turntable are parallel to the rotating shaft of the feeding transfer turntable; the forming main shaft turntable and the forming transfer turntable are star wheels, and a plurality of positioning grooves are uniformly distributed on the circumferential surface of the forming main shaft turntable, are in an arc shape and are used for positioning the tank body of the pop can; a plurality of vacuum adsorption grooves are uniformly distributed on the circumferential surface of the forming transfer turntable;

when the loading transfer turntable and the forming spindle turntable rotate to receive materials, the vacuum adsorption groove on the loading transfer turntable and the positioning groove on the forming spindle turntable define together to form a transfer position, and the tank body enters the positioning groove of the forming spindle turntable from the vacuum adsorption groove of the loading transfer turntable through the transfer position;

when the forming spindle turntable and the forming transfer turntable rotate to receive materials, the positioning groove on the forming spindle turntable and the vacuum adsorption groove on the forming transfer turntable are defined together to form the transfer position, and the tank body enters the vacuum adsorption groove of the forming transfer turntable from the positioning groove of the forming spindle turntable through the transfer position.

4. The high speed neck molding apparatus of claim 3 wherein: the main shaft assembly of the neck forming station further comprises a plurality of sets of die assemblies and a plurality of sets of push plate assemblies;

the die assemblies and the push plate assemblies are arranged in a one-to-one correspondence mode and are respectively arranged on two sides of the tank body along the height direction of the tank body.

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