CN112092444B - Ring-pull can compression device for environmental protection - Google Patents

Abstract

The invention discloses a compression device of an environment-friendly pop can, which comprises a main hollow shell and a main bottom cover body. The zip-top can is firstly compressed by the helical spring, so that the zip-top can be initially compressed, the volume of occupied compression space is reduced, the zip-top can which is initially compressed is conveyed into the last compression space under the action of the helical blades, then the zip-top can is compressed under larger pressure by a hydraulic technology to be compressed into blocks, and the zip-top can is gradually compressed due to the compression into two parts, so that the occupied space of the zip-top can during compression is reduced, the energy utilization rate is improved, meanwhile, the zip-top can be finally shaped in a cylindrical shape and the edge of the zip-top can is provided with a chamfer structure, and the probability and the damage degree of accidents caused by the edges and corners are reduced when finished products are taken out.

Description

Ring-pull can compression device for environmental protection

Technical Field

The invention relates to the technical field of compression devices, in particular to a compression device for an environment-friendly pop can.

Background

At present, in a waste recycling place, resources which can be recycled, such as pop cans, need to be compressed when being collected, so that the occupied space of the pop cans is reduced, the existing compression devices are large-scale equipment, the pop cans which are not compressed at all are flatly laid inside the compression devices and then compressed, but the pop cans need to consume large energy once in work, the compression quantity is small, and the utilization rate of energy is low.

Disclosure of Invention

The invention aims to provide an environment-friendly pop can compression device to solve the problems in the background technology.

In order to achieve the purpose, the invention provides the following technical scheme: a zip-top can compression device for environmental protection comprises a main hollow shell and a main bottom cover body, wherein a main limiting rod is installed on one side of the bottom surface of the main hollow shell, one side of the main bottom cover body is penetrated through by a rod body of the main limiting rod, a main limiting plate is installed at the bottom of the main limiting rod, a main component installation groove is formed in the center of the upper surface of the main bottom cover body, a semicircular end part chamfering mechanism is installed inside the main component installation groove, an iron block installation groove is formed in one side of the upper surface of the main bottom cover body, an iron block is installed inside the iron block installation groove, a longitudinal compression space is formed in the center of the main hollow shell, a main iron core is installed inside one side of the longitudinal compression space, a main coil is sleeved outside the main iron core, and a cylindrical discharge hole is formed in one side of the longitudinal compression space, the pop can packaging structure is characterized in that a conical space is arranged at the transverse end part of the cylindrical discharge hole, a transverse compression space is arranged at the transverse port of the conical space, a driving motor is installed on one side of the main hollow shell, a motor spindle of the driving motor penetrates through the structure on one side of the main hollow shell, a helical blade is installed on a spindle body located in the transverse compression space on the motor spindle, a pop can putting space communicated with the outside space and the top of the transverse compression space is formed in the main hollow shell, a main connecting plate is placed in the longitudinal compression space, the lower surface of the main connecting plate is provided with the other half of annular end part chamfering mechanism, a main push rod is installed at the center of the upper surface of the main connecting plate, and a rod body of the main push rod penetrates through the structure on the top of the main hollow shell; when driving motor made helical blade reverse rotation, can make helical blade drive the easy open can and remove to one side of driving motor, when making driving motor forward rotation for the inside in vertical compression space is entered into to the easy open can of compression.

Further, semi-annular tip chamfer mechanism includes semi-annular tip chamfer mechanism and constructs and construct the bolt hole with semi-annular tip chamfer mechanism with cylindrical plate, semi-annular tip chamfer mechanism.

Furthermore, one end face of the cylindrical plate for the semi-annular end chamfering mechanism is provided with a semi-annular structure for the semi-annular end chamfering mechanism, and a plurality of bolt holes for the semi-annular end chamfering mechanism are formed in the other end face of the cylindrical plate for the semi-annular end chamfering mechanism.

Furthermore, both ends of the semi-annular structure for the semi-annular end chamfering mechanism are connected with the edge line end of the cylindrical plate for the semi-annular end chamfering mechanism, and the diameter of the cylindrical plate for the semi-annular end chamfering mechanism is the same as the inner diameter of the longitudinal compression space.

Further, one end of one of the columnar plates for the semicircular end chamfering mechanism is mounted inside the main part mounting groove at the bolt hole for the semicircular end chamfering mechanism, and the other end of the columnar plate for the semicircular end chamfering mechanism is mounted at the bottom of the main connecting plate by a bolt.

Further, the central line of the longitudinal compression space and the central line of the semi-annular end chamfering mechanism are on the same vertical line.

Furthermore, the central line of the main iron core and the central line of the iron block are positioned on the same vertical line.

Furthermore, the main bottom cover body and the main limiting rod are in clearance connection between penetrating positions.

Further, the distance between the cylindrical discharge hole and the longitudinal compression space is 0.1-1 cm greater than the total thickness of the main web and the semi-annular end chamfer means.

Compared with the prior art, the invention has the beneficial effects that: the invention firstly performs the compression action of the helical spring type on the pop can so that the pop can be preliminarily compressed to reduce the volume of occupied compression space, then conveys the preliminarily compressed pop can into the last compression space under the action of the helical blade, and then performs the compression action on the pop can with larger pressure through the hydraulic technology, realize compressing the blocking, because the compression divide into two parts, so can realize progressively compressing, reduce the occupation space of easy open can when the compression, improve the utilization ratio of the energy, simultaneously, can finalize the design at the cylindricality and edge at last with the easy open can again and have the chamfer structure, when reducing and taking out the finished product, because probability and the damage degree of edges and corners injury people's accident.

Drawings

FIG. 1 is a schematic view of a full-section structure of a compression device for an environmental-friendly pop can of the present invention;

FIG. 2 is a schematic structural view of a semi-annular end chamfering mechanism in the compression device of the ring-pull can for environmental protection of the invention;

in the figure: the pop can comprises a main hollow shell 1, a main hollow shell 2, a main limiting rod 3, a main bottom cover body 4, a main limiting plate 5, a main component mounting groove 6, an iron block mounting groove 7, an iron block 8, a semi-annular end chamfering mechanism 81, a cylindrical plate for the semi-annular end chamfering mechanism 82, a semi-annular structure for the semi-annular end chamfering mechanism 83, a bolt hole for the semi-annular end chamfering mechanism 9, a longitudinal compression space 10, a main push rod 11, a main connecting plate 12, a main iron core 13, a main coil 14, a transverse compression space 15, a conical space 16, a cylindrical discharge hole 17, a driving motor 18, a motor spindle 19, a pop can putting space 20 and a spiral blade.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1, an embodiment of the present invention: comprises a main hollow shell 1 and a main bottom cover body 3, wherein one side of the bottom surface of the main hollow shell 1 is provided with a main limiting rod 2, one side of the main bottom cover body 3 is penetrated by a rod body of the main limiting rod 2, and the bottom of the main limiting rod 2 is provided with a main limiting plate 4, the center of the upper surface of the main bottom cover body 3 is provided with a main part mounting groove 5, a semicircular end chamfering mechanism 8 is arranged in the main component mounting groove 5, an iron block mounting groove 6 is arranged in one side of the upper surface of the main bottom cover body 3, an iron block 7 is arranged in the iron block mounting groove 6, a longitudinal compression space 9 is arranged at the center of the main hollow shell 1, a main iron core 12 is arranged in one side of the longitudinal compression space 9, a main coil 13 is sleeved outside the main iron core 12, one side of the longitudinal compression space 9 is provided with a cylindrical discharge hole 16, and the lateral end of the cylindrical discharge hole 16 is provided with a tapered space 15, a transverse compression space 14 is arranged at the transverse port of the conical space 15, a driving motor 17 is arranged at one side of the main hollow shell 1, a motor spindle 18 of the driving motor 17 penetrates through the structure at one side of the main hollow shell 1, and the motor spindle 18 is provided with a helical blade 20 on a shaft body located inside the lateral compression space 14, the interior of the main hollow shell 1 is provided with a pop can putting space 19 communicated with the external space and the top of the transverse compression space 14, a main connecting plate 11 is arranged in the longitudinal compression space 9, the lower surface of the main connecting plate 11 is provided with the other half of the annular end chamfering mechanism 8, a main push rod 10 is arranged in the center of the upper surface of the main connecting plate 11, and a rod body of the main push rod 10 penetrates through the structure of the top of the main hollow shell 1.

Referring to fig. 2, the semi-annular end chamfering mechanism 8 includes a cylindrical plate 81 for the semi-annular end chamfering mechanism, a semi-annular structure 82 for the semi-annular end chamfering mechanism, and a bolt hole 83 for the semi-annular end chamfering mechanism; a semi-annular structure 82 for a semi-annular end chamfering mechanism is arranged on one end face of the semi-annular end chamfering mechanism cylindrical plate 81, and a plurality of semi-annular end chamfering mechanism bolt holes 83 are formed in the other end face of the semi-annular end chamfering mechanism cylindrical plate 81; both ends of the semi-annular end chamfering mechanism semi-annular structure 82 are connected with the edge line end of the semi-annular end chamfering mechanism cylindrical plate 81, and the diameter of the semi-annular end chamfering mechanism cylindrical plate 81 is the same as the inner diameter of the longitudinal compression space 9; one of the semicircular end chamfering mechanism cylindrical plates 81 is attached to the inside of the main part attachment groove 5 at one end located in the semicircular end chamfering mechanism bolt hole 83, and the other of the semicircular end chamfering mechanism cylindrical plates 81 is attached to the bottom of the main attachment plate 11 by a bolt through the semicircular end chamfering mechanism bolt hole 83.

The central line of the longitudinal compression space 9 and the central line of the semi-annular end chamfering mechanism 8 are positioned on the same vertical line.

The central line of the main iron core 12 and the central line of the iron block 7 are on the same vertical line.

The main bottom cover body 3 and the main limiting rod 2 are in clearance connection between penetrating parts.

The distance between said cylindrical discharge hole 16 and the longitudinal compression space 9 is greater than the overall thickness of the main web 11 and the semi-annular end chamfer means 8 by 0.1-1 cm.

Firstly, the top end of the main push rod 10 is fixedly connected with the end part of a reciprocating rod of a reciprocating motor, the top end is connected with the power input end of the main coil 13 through a wire connected with a power supply, and the iron block 7 is adsorbed at the bottom of the main iron core 12 by utilizing the electromagnetic principle.

The specific use mode is as follows: in the work of the invention, a pop can to be compressed is put into the pop can putting space 19 and falls into the transverse compression space 14 under the action of gravity, at the moment, the driving motor 17 is started to enable the helical blade 20 to rotate reversely, the helical blade 20 drives the pop can to move towards one side of the driving motor 17, as the number of the pop cans is increased, the pop can is preliminarily compressed, after a certain number of the pop cans are compressed, the driving motor 17 is rotated forwardly to enable the compressed pop can to enter the longitudinal compression space 9, after a certain number of the pop cans are compressed, the reciprocating motor is started to enable the main push rod 10 to move downwards, the preliminarily compressed pop can is compressed again, when the compressed pressure value is greater than the adsorption strength between the main iron core 12 and the iron block 7, the main bottom cover body 3 moves downwards, and at the moment, the compressed pop can be taken out.

It will be evident to those skilled in the art that the invention is not limited to the details of the foregoing illustrative embodiments, and that the present invention may be embodied in other specific forms without departing from the spirit or essential attributes thereof. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Claims (9)

1. The utility model provides a zip-top can compressor arrangement for environmental protection, includes main hollow shell (1) and main bottom lid (3), its characterized in that: a main limiting rod (2) is installed on one side of the bottom surface of the main hollow shell (1), one side of a main bottom cover body (3) is penetrated through by a rod body of the main limiting rod (2), a main limiting plate (4) is installed at the bottom of the main limiting rod (2), a main component installation groove (5) is arranged at the upper surface center of the main bottom cover body (3), a semi-annular end part chamfering mechanism (8) is installed inside the main component installation groove (5), an iron block installation groove (6) is installed inside one side of the upper surface of the main bottom cover body (3), an iron block (7) is installed inside the iron block installation groove (6), a longitudinal compression space (9) is arranged at the center of the main hollow shell (1), a main iron core (12) is installed inside one side of the longitudinal compression space (9), a main coil (13) is sleeved outside the main iron core (12), a cylindrical discharge hole (16) is arranged on one side of the longitudinal compression space (9), a conical space (15) is arranged at the transverse end part of the cylindrical discharge hole (16), a transverse compression space (14) is arranged at one side of the main hollow shell (1), and a main motor (17) is penetrated through the main hollow shell (17), a helical blade (20) is mounted on a shaft body positioned in the transverse compression space (14) of the motor spindle (18), a pop can putting space (19) communicated with the outside space and the top of the transverse compression space (14) is formed in the main hollow shell (1), a main connecting plate (11) is arranged in the longitudinal compression space (9), the lower surface of the main connecting plate (11) is provided with the other half of annular end chamfering mechanism (8), a main push rod (10) is mounted at the center of the upper surface of the main connecting plate (11), and a rod body of the main push rod (10) penetrates through the structure at the top of the main hollow shell (1);

and (2) opening the driving motor (17), enabling the spiral blade (20) to rotate reversely, enabling the spiral blade (20) to drive the pop can to move to one side of the driving motor (17), enabling the pop can to be preliminarily compressed as the number of the pop cans is increased, and enabling the driving motor (17) to rotate in the forward direction after the pop cans are compressed by a certain amount, so that the compressed pop cans enter the longitudinal compression space (9).

2. The compression device of claim 1, wherein: the semi-annular end chamfering mechanism (8) comprises a cylindrical plate (81) for the semi-annular end chamfering mechanism, a semi-annular structure (82) for the semi-annular end chamfering mechanism and a bolt hole (83) for the semi-annular end chamfering mechanism.

3. An environmentally friendly can compressing device as set forth in claim 2, wherein: the semi-ring-shaped end chamfering mechanism is characterized in that a semi-ring-shaped structure (82) for the semi-ring-shaped end chamfering mechanism is arranged on one end face of the cylindrical plate (81) for the semi-ring-shaped end chamfering mechanism, and a plurality of bolt holes (83) for the semi-ring-shaped end chamfering mechanism are arranged inside the other end face of the cylindrical plate (81) for the semi-ring-shaped end chamfering mechanism.

4. An environmentally friendly can compressing device as set forth in claim 3, wherein: the two ends of the semi-annular structure (82) for the semi-annular end chamfering mechanism are connected with the edge line end of the cylindrical plate (81) for the semi-annular end chamfering mechanism, and the diameter of the cylindrical plate (81) for the semi-annular end chamfering mechanism is the same as the inner diameter of the longitudinal compression space (9).

5. An environmentally friendly can compressing device as defined in claim 3, wherein: one end of a semi-annular end part cylindrical plate (81) for the chamfering mechanism is arranged in a main component mounting groove (5) at one end of a semi-annular end part bolt hole (83), and the other end of the semi-annular end part cylindrical plate (81) for the chamfering mechanism is arranged at the bottom of a main connecting plate (11) through a bolt at the semi-annular end part bolt hole (83).

6. An environmentally friendly can compressing device as set forth in claim 1, wherein: the central line of the longitudinal compression space (9) and the central line of the semi-annular end chamfering mechanism (8) are positioned on the same vertical line.

7. The compression device of claim 1, wherein: the central line of the main iron core (12) and the central line of the iron block (7) are positioned on the same vertical line.

8. An environmentally friendly can compressing device as set forth in claim 1, wherein: the main bottom cover body (3) and the main limiting rod (2) are in clearance connection between penetrating positions.

9. The compression device of claim 1, wherein: the distance between the cylindrical discharge hole (16) and the longitudinal compression space (9) is greater than the total thickness of the main web (11) and the semi-annular end chamfer means (8) by 0.1-1 cm.

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