CN107986062B - Non-setting adhesive label cross cutting non-stop waste discharge device - Google Patents

Abstract

The application discloses a non-setting adhesive label die cutting non-stop waste discharge device, which comprises a rotating frame and a conveying frame which are arranged right above a die cutting machine in an up-down aligned manner, a material receiving groove which is arranged right below the conveying frame and is positioned at one side of the die cutting machine, and a suction fan which is arranged on the rotating frame and the conveying frame and is positioned right above the die cutting machine and used for sucking waste materials of the die cutting machine upwards; the beneficial effects of this application are: through setting up this device in the top of cross cutting machine, upwards inhale the waste material of cross cutting to twine the waste material on the winding roller through the winding roller, the winding roller that cyclic permutation set up makes winding abundant waste material back winding roller be shifted out and unload the waste material in retrieving the silo and unify retrieve, makes the self-adhesive label cross cutting realize wasting discharge with not shutting down, has kept the clean and tidy of cross cutting environment, has improved the efficiency of self-adhesive label cross cutting.

Description

Non-setting adhesive label cross cutting non-stop waste discharge device

Technical Field

The present disclosure relates generally to the field of label production equipment, and in particular, to a non-setting adhesive label die cutting non-stop waste discharge device.

Background

The die-cutting process is important in the manufacturing process of the self-adhesive label except printing. The die cutting is a process of cutting the self-adhesive label material into a required shape by using a knife plate.

As shown in fig. 1, waste is generated when the self-adhesive label is die-cut, wherein a region A in the figure is a waste region, and a region B is a label; the waste of the existing die cutting machine is simply removed by blowing away, the waste in the production place is messy by the mode, the waste is required to be collected and recycled regularly, and the environment of the die cutting site is clean and the production efficiency is greatly affected.

Disclosure of Invention

In view of the foregoing drawbacks or shortcomings in the prior art, it is desirable to provide a self-adhesive label die-cutting non-stop waste discharge device that can intensively recycle waste materials.

The first aspect provides a non-setting adhesive label die-cutting non-stop waste discharge device, which comprises a rotary frame and a conveying frame which are arranged right above a die-cutting machine in an up-down aligned manner, a material receiving groove which is arranged right below the conveying frame and is positioned at one side of the die-cutting machine, and a suction fan which is arranged on the rotary frame and the conveying frame and is positioned right above the die-cutting machine and used for sucking waste materials of the die-cutting machine upwards;

the conveying frame comprises a lower outer frame and a lower inner frame sleeved in the lower outer frame, and an annular lower track is formed by combining the lower inner frame and the lower outer frame; the conveying frame further comprises a plurality of annular sliding frames which are uniformly and slidably arranged in the lower rail, clamping lugs which are symmetrically arranged on the outer side surface of the sliding frames and clamped in the lower rail, and winding rollers, the middle upper parts of which are rotatably clamped in the sliding frames, for winding waste materials; the clamping lugs extend downwards to form connecting ends; the connecting ends of the connecting lugs in the lower outer frame are connected through an outer chain; the connecting ends of the connecting lugs in the lower inner frame are connected through an inner chain; a driving motor for driving the outer chain and the inner chain to drive is arranged inside and outside the lower track;

the rotating frame comprises an upper outer frame and an upper inner frame sleeved in the upper outer frame; an upper track is formed between the upper outer frame and the upper inner frame; the winding roller is clamped in the upper rail; the inner side and the top surface of the upper outer frame or the upper inner frame are slidably provided with annular racks which are meshed with the top of the winding roller; the rotary frame is provided with a driving device for driving the annular rack to drive;

the winding roller is provided with a diameter adjusting device for adjusting the diameter of the winding roller.

According to the technical scheme provided by the embodiment of the application, the diameter adjusting device comprises a pressing rod, a cylinder, at least 4 outer arc-shaped sheets, an inner arc-shaped sheet and an adjusting column, wherein the pressing rod is positioned above the material collecting groove and higher than the winding roller, the cylinder is used for driving the pressing rod to move up and down, the at least 4 outer arc-shaped sheets are sleeved outside the winding roller, the inner arc-shaped sheets are sleeved in the winding roller and are correspondingly arranged with the outer arc-shaped sheets, and the adjusting column is inserted between the inner arc-shaped sheets, and the top of the adjusting column is connected with the pressing rod; the outer arc-shaped sheets and the inner arc-shaped sheets which are correspondingly arranged are connected through connecting rods penetrating through the winding rollers; the bottom of the pressure rod is provided with an electromagnet, and the top of the adjusting column is provided with an iron block; the inner arc-shaped sheet is also connected with the inner wall of the winding roller through a spring; the upper portion and the lower part of adjusting column are cylindric, and upper portion diameter is greater than the lower part diameter, the upper portion and the lower part of adjusting column pass through the toper post and link up.

According to the technical scheme provided by the embodiment of the application, the granular bulges are fully distributed on the outer surface of the outer arc-shaped piece.

According to the technical scheme provided by the embodiment of the application, spiral twills are distributed on the outer surface of the outer arc-shaped sheet.

According to the technical scheme provided by the embodiment of the application, one side of the receiving groove is provided with a crushing device for crushing waste into short pieces or fragments; waste materials in the material receiving groove are conveyed to a material inlet of the crushing device through a conveying device.

According to the technical scheme provided by the embodiment of the application, the conveying device is a conveying plate which is obliquely arranged from high to low and is arranged between the bottom end of the material collecting groove and the material inlet of the material crushing device.

The beneficial effects of this application are: through setting up this device in the top of cross cutting machine, upwards inhale the waste material of cross cutting to twine the waste material on the winding roller through the winding roller, the winding roller that cyclic permutation set up makes winding abundant waste material back winding roller be shifted out and unload the waste material in retrieving the silo and unify retrieve, makes the self-adhesive label cross cutting realize wasting discharge with not shutting down, has kept the clean and tidy of cross cutting environment, has improved the efficiency of self-adhesive label cross cutting.

Drawings

Other features, objects and advantages of the present application will become more apparent upon reading of the detailed description of non-limiting embodiments, made with reference to the following drawings, in which:

FIG. 1 is a schematic structural view of a self-adhesive label;

FIG. 2 is a schematic diagram of an embodiment of the present application;

FIG. 3 is a schematic view of the structure of the turret of the present application;

FIG. 4 is a schematic view of the structure of the transfer frame of the present application;

FIG. 5 is a schematic view of the structure of the wind roller in the present application;

FIG. 6 is a schematic structural view of a conditioning column of the present application;

reference numerals in the drawings:

10. a die cutting machine; 20. a rotating frame; 30. a conveying frame; 40. a material collecting groove; 50. a suction fan; 31. a lower outer frame; 32. a lower inner frame; 33. a carriage; 34. a winding roller; 21. an upper outer frame; 22. an upper inner frame; 60. a diameter adjusting device; 61. a compression bar; 62. a cylinder; 63. an outer arcuate sheet; 64. an inner arcuate piece; 65. an adjusting column; 70. and a crushing device.

Detailed Description

The present application is described in further detail below with reference to the drawings and examples. It is to be understood that the specific embodiments described herein are merely illustrative of the invention and are not limiting of the invention. It should be noted that, for convenience of description, only the portions related to the invention are shown in the drawings.

It should be noted that, in the case of no conflict, the embodiments and features in the embodiments may be combined with each other. The present application will be described in detail below with reference to the accompanying drawings in conjunction with embodiments.

Referring to fig. 2, a schematic structural diagram of an embodiment of a non-stop waste discharging device for die-cutting self-adhesive labels in the present application includes a rotary frame 20 and a conveying frame 30 which are arranged above a die-cutting machine 10 and aligned vertically, a material receiving slot 40 which is arranged below the conveying frame 30 and is positioned at one side of the die-cutting machine 10, and a suction fan 50 which is arranged on the rotary frame 20 and the conveying frame 30 and is positioned above the die-cutting machine 10 and is used for sucking waste materials of the die-cutting machine 10 upwards;

as shown in fig. 3, the conveying frame 30 includes a lower outer frame 31, a lower inner frame 32 sleeved in the lower outer frame 31, and an annular lower rail is formed by combining the lower inner frame 32 and the lower outer frame 31; the conveying frame 30 further comprises a plurality of annular sliding frames 33 which are uniformly and slidably arranged in the lower rail, clamping lugs which are symmetrically arranged on the outer side surface of the sliding frames 33 and clamped in the lower rail, and winding rollers 34 which are rotatably clamped in the sliding frames 33 at the middle upper part and are used for winding scraps; the clamping lugs extend downwards to form connecting ends; the connecting ends of the connecting lugs in the lower outer frame 31 are connected through an outer chain; in some embodiments, the opposite surfaces of the lower outer frame 31 and the lower inner frame 32 are provided with grooves, and the connecting lugs of the sliding frame 33 are clamped in the grooves; the connecting ends of the connecting lugs in the lower inner frame 32 are connected through an inner chain; a driving motor for driving the outer chain and the inner chain to drive is arranged inside and outside the lower track; in the embodiment, a transmission gear is fixed on a rotating shaft of a driving motor; an outer driving gear meshed with the outer chain is arranged outside the lower outer frame 31, and an inner driving gear meshed with the inner chain is arranged inside the lower inner frame 32; the inner driving gear and the outer driving gear are respectively provided with a transmission gear correspondingly; in some embodiments, the transfer gear rotates in a vertical plane and the inner drive gear and the outer drive gear rotate in a horizontal plane, and the transfer gear is in meshed connection with the inner drive gear and the outer drive gear through helical gears.

As shown in fig. 4, the rotating frame 20 includes an upper outer frame 21, and an upper inner frame 22 sleeved in the upper outer frame 21; an upper rail is formed between the upper outer frame 21 and the upper inner frame 22; the winding roller 34 is clamped in the upper rail; the inner side and the top surface of the upper outer frame 21 or the upper inner frame 22 are slidably provided with annular racks engaged with the top of the winding roller 34; the upper periphery of the winding roller 34 is provided with a circle of gear surface, the vertical section of the annular rack is 7-shaped, and the vertical surface of the annular rack is meshed with the gear surface of the winding roller 34; the rotating frame 20 is provided with a driving device for driving the annular rack to drive; in this embodiment, the driving device includes a stepping motor, and a rotary gear fixedly connected to a rotation shaft of the stepping motor, and the rotary gear is engaged with a horizontal portion of the ring gear.

The winding roller 34 is provided with a diameter adjusting device 60 for adjusting the diameter of the winding roller 34.

As shown in fig. 5, the diameter-adjusting device 60 includes a pressing rod 61 located above the material receiving groove 40 and higher than the winding roller 34, a cylinder 62 for driving the pressing rod 61 to move up and down, at least 4 outer arc pieces 63 sleeved outside the winding roller 34, an inner arc piece 64 sleeved inside the winding roller 34 and corresponding to the outer arc pieces 63, and an adjusting column 65 inserted between the inner arc pieces 4 and having a top connected with the pressing rod 61; the outer arc-shaped sheet 63 and the inner arc-shaped sheet 64 which are correspondingly arranged are connected through a connecting rod passing through the winding roller 34; the inner arcuate tab 64 is also connected to the inner wall of the wind roller 34 by a spring; an electromagnet is arranged at the bottom of the pressure rod 61, and an iron block is arranged at the top of the adjusting column; the upper and lower portions of the adjustment post 65 are cylindrical and have an upper diameter greater than the lower diameter as shown in fig. 6, and the upper and lower portions of the adjustment post 65 are joined by a tapered post. The outer arc piece 63 is sleeved on the middle lower portion of the winding roller 34.

When the winding roller 34 moves right above the collecting groove 40, the air cylinder 62 controls the pressure rod 61 to move downwards, the electromagnet at the bottom of the pressure rod 61 is electrified, the pressure rod 61 is connected with the adjusting column 65 in an attracting way, the air cylinder 62 controls the pressure rod 61 to move upwards, the upper part of the adjusting column 65 is pulled out from between the inner arc-shaped sheets 64, the inner arc-shaped sheets 64 move towards the center under the recovery of the elastic force of the spring due to the small diameter of the bottom of the adjusting column 65, and meanwhile, the outer arc-shaped sheets 63 are driven to move towards the center, and waste materials wound on the outer arc-shaped sheets 63 drop into the collecting groove 40 under the action of gravity due to the loss of the supported tension; after the waste falls, the electromagnet at the bottom end of the compression bar 61 is powered off, the adjusting column 65 is disconnected from the compression bar 61, the adjusting column 65 falls under the action of gravity, the upper part of the adjusting column 65 falls into the inner arc-shaped sheet 64, and the outer arc-shaped sheet 63 is opened again to be used for winding the waste.

In a preferred embodiment, the outer surface of the outer arcuate piece 63 is covered with granular protrusions.

In a preferred embodiment, the outer surface of the outer arcuate piece 63 is covered with helical diagonal lines.

The granular bulges and twills can increase the surface friction of the outer arc-shaped sheet 63, and the waste materials are prevented from falling off due to sliding in the winding process.

In a preferred embodiment, one side of the receiving chute 40 is provided with a crushing device 70 for crushing the waste into short pieces or chips; the waste in the receiving chute 40 is conveyed to the inlet of the crushing device 70 by a conveying device. The waste is crushed by the crushing device 70 into short pieces or chips, and further, the crushed waste can be directly recycled or further crushed into pulp for recycling.

In a preferred embodiment, the conveying device is a conveying plate which is obliquely arranged between the bottom end of the material receiving groove 40 and the material inlet of the material crushing device 70 from top to bottom. The conveyor may also be other structures, such as a conveyor belt.

The foregoing description is only of the preferred embodiments of the present application and is presented as a description of the principles of the technology being utilized. It will be appreciated by persons skilled in the art that the scope of the invention referred to in this application is not limited to the specific combinations of features described above, but it is intended to cover other embodiments in which any combination of features described above or equivalents thereof is possible without departing from the spirit of the invention. Such as the above-described features and technical features having similar functions (but not limited to) disclosed in the present application are replaced with each other.

Claims (2)

1. The non-setting adhesive label die-cutting non-stop waste discharge device is characterized by comprising a rotating frame (20) and a conveying frame (30) which are arranged right above a die-cutting machine (10) in an up-down alignment manner, a material receiving groove (40) which is arranged right below the conveying frame (30) and is arranged at one side of the die-cutting machine (10), and a suction fan (50) which is arranged on the rotating frame (20) and the conveying frame (30) and is arranged right above the die-cutting machine (10) and used for sucking waste materials of the die-cutting machine (10) upwards;

the conveying frame (30) comprises a lower outer frame (31) and a lower inner frame (32) sleeved in the lower outer frame (31), and the lower inner frame (32) and the lower outer frame (31) are combined to form an annular lower track; the conveying frame (30) further comprises a plurality of annular sliding frames (33) which are uniformly and slidably arranged in the lower rail, clamping lugs which are symmetrically arranged on the outer side surface of the sliding frames (33) and clamped in the lower rail, and winding rollers (34) which are rotatably clamped in the sliding frames (33) at the middle upper part and are used for winding waste materials; the clamping lugs extend downwards to form connecting ends; the connecting ends of the connecting lugs in the lower outer frame (31) are connected through an outer chain; the connecting ends of the connecting lugs in the lower inner frame (32) are connected through an inner chain; a driving motor for driving the outer chain and the inner chain to drive is arranged inside and outside the lower track;

the rotating frame (20) comprises an upper outer frame (21) and an upper inner frame (22) sleeved in the upper outer frame (21); an upper track is formed between the upper outer frame (21) and the upper inner frame (22); the winding roller (34) is clamped in the upper track; an annular rack engaged with the top of the winding roller (34) is slidably mounted on the inner side and the top surface of the upper outer frame (21) or the upper inner frame (22); a driving device for driving the annular rack to drive is arranged on the rotating frame (20);

the winding roller (34) is provided with a diameter adjusting device (60) for adjusting the diameter of the winding roller (34); the diameter adjusting device (60) comprises a pressing rod (61) which is arranged above the material collecting groove (40) and higher than the winding roller (34), an air cylinder (62) for driving the pressing rod (61) to move up and down, at least 4 outer arc-shaped sheets (63) sleeved outside the winding roller (34), inner arc-shaped sheets (64) which are sleeved in the winding roller (34) and are arranged corresponding to the outer arc-shaped sheets (63), and an adjusting column (65) which is inserted between the inner arc-shaped sheets (64) and the top of which is connected with the pressing rod (61); the outer arc-shaped sheets (63) and the inner arc-shaped sheets (64) which are correspondingly arranged are connected through connecting rods penetrating through the winding rollers (34); the inner arc-shaped sheet (64) is also connected with the inner wall of the winding roller (34) through a spring; the upper part and the lower part of the adjusting column (65) are cylindrical, the diameter of the upper part is larger than that of the lower part, and the upper part and the lower part of the adjusting column are connected through a conical column;

the outer surface of the outer arc-shaped piece (63) is covered with granular bulges;

a crushing device (70) for crushing the waste into short pieces or fragments is arranged on one side of the receiving groove (40); waste materials in the material receiving groove (40) are conveyed to a material inlet of the crushing device (70) through a conveying device;

the conveying device is a conveying plate which is obliquely arranged between the bottom end of the material collecting groove (40) and the material inlet of the material crushing device (70) from high to low.

2. The non-setting adhesive label die-cutting non-stop waste discharging device according to claim 1, wherein the outer surface of the outer arc-shaped sheet (63) is fully distributed with spiral twills.