CN210276137U - A cutting equipment for processing of sports shoes shoelace - Google Patents

Abstract

A cutting device for processing shoelaces of sports shoes comprises an end enclosure mechanism, an end enclosure conveying mechanism, a shoelace conveying mechanism and a cutting mechanism, wherein the end enclosure mechanism, the end enclosure conveying mechanism, the shoelace conveying mechanism and the cutting mechanism are all arranged on a platform; a head sealing piece conveying mechanism is arranged on the left side of the mounting seat; the shoelace conveying mechanism is arranged at the rear side of the end enclosure mechanism, and the cutting mechanism is arranged at the rear side of the end enclosure mechanism; the cutting equipment for processing the shoelace of the sports shoe seals the shoelace through the end sealing mechanism, and then conveys the shoelace to the cutting mechanism through the conveying mechanism to be cut into shoelace products; the automation degree is high, the labor force is saved, and the processing efficiency is improved.

Description

A cutting equipment for processing of sports shoes shoelace

Technical Field

The utility model belongs to the technical field of sports clothing auxiliary material technique and specifically relates to a cutting equipment for processing sports shoes shoelace.

Background

The markets of sportswear and casual clothes in textile products are outstanding and popular among consumers, and particularly, products with emphasis on functionality are very popular.

As far as consumers are concerned, the functions of leisure wear and sports wear are different from professional sportsmen, and the manufacturers of their peripheral equipment have also added marketing lines, such as health care and UV-resistant protective fabrics, in order to improve the purchasing behavior of consumers, and the manufacturers of weaving and chemical assistants have continuously developed new fibers and finished products in order to provide increasing functional requirements. Polyester and nylon superfine fibers are developed most rapidly, and high-density and waterproof fabrics are widely applied to casual clothes.

Although the sportswear fabric is important, the auxiliary materials are also indispensable, the sportshoes are generally provided with shoelaces for wearing conveniently, the shoelaces need to be provided with sealing heads for covering in order to avoid the two ends from being off-line, the materials of the sealing heads are mostly metal or plastic materials, the sealing heads of the plastic materials are subjected to heat sealing, but the sealing heads of the metal materials are mostly fixed at the two ends of the shoelaces by adopting manual tool pliers, and the efficiency is low.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing an automatic carry out head and dissection to the shoelace and become the cutting equipment that is used for sports shoes shoelace processing of shoelace product.

In order to achieve the above object, the utility model provides a following technical scheme: a cutting device for processing shoelaces of sports shoes comprises an end enclosure mechanism, an end enclosure conveying mechanism, a shoelace conveying mechanism and a cutting mechanism, wherein the end enclosure mechanism, the end enclosure conveying mechanism, the shoelace conveying mechanism and the cutting mechanism are all arranged on a platform, the end enclosure mechanism comprises a mounting seat, supporting rods, a movable die, a fixed die and a linear driving mechanism, the mounting seat is arranged above the platform, the bottom of the mounting seat is connected with the platform through a plurality of supporting rods, the movable die is arranged between the mounting seat and the platform and is connected with the linear driving mechanism, the linear driving mechanism comprises a first air cylinder, the first air cylinder is fixedly connected with the mounting seat through a front end flange, a through hole in clearance fit with a piston rod of the first air cylinder is arranged on the mounting seat, the piston rod of the first air cylinder is fixedly connected with the top of the movable die, the fixed die is arranged on the platform below the movable die, and a square groove, the fixed mould is embedded in the square groove;

the bottom of the fixed die and the top of the movable die are provided with an upper die cavity and a lower die cavity which are matched with each other, the upper die cavity and the lower die cavity are integrally semi-cylindrical, the upper die cavity and the lower die cavity are spliced to form a cylindrical die cavity, and two ends of the cylindrical die cavity are open. The telescopic link of first cylinder drives the movable mould and reciprocates, and with fixed mould compound die branch mould, the shoelace passes through between fixed mould and the movable mould.

The left side of mount pad is equipped with head conveying mechanism, and head conveying mechanism includes two tracks that set up side by side, and orbital both sides are equipped with the baffle, and orbital inside is equipped with the push rod, and the push rod seat is connected to the left end of push rod, and the piston rod of second cylinder is connected to the left end of push rod seat, and the second cylinder passes through cylinder block fixed mounting on the platform. The second cylinder pushes the push rod seat to drive the two push rods to push the end enclosure piece in the track to reach the lower part of the movable die, so that the end enclosure piece is clamped on the shoelace.

Shoelace conveying mechanism locates the rear side of capping mechanism, and dissection mechanism locates the rear side of capping mechanism, and shoelace conveying mechanism includes first motor and delivery wheel, and first motor passes through motor cabinet fixed mounting on the platform, fixedly on the output shaft of first motor being equipped with the delivery wheel. The first motor drives the conveying wheel to rotate so as to drive the shoelace to move backwards for a certain distance through the friction force of the conveying wheel;

the cutting mechanism comprises a second motor and a cutter blade, the second motor is fixedly mounted on the platform through a motor base, the cutter blade is fixedly mounted on an output shaft of the second motor, and a strip-shaped groove matched with the cutter blade is formed in the platform below the cutter blade. The second motor drives the cutter blade to rotate so as to cut off the shoelace through the cutter blade.

As a further aspect of the present invention: the top surface of fixed mould is parallel and level with the top surface of lower platform.

As a further aspect of the present invention: the left side of the cylindrical cavity formed by splicing the upper cavity and the lower cavity is provided with a recess with an arc-shaped cross section, so that a space is provided for the upper piece to cover the lower piece.

As a further aspect of the present invention: the periphery of the conveying wheel is provided with a plurality of shifting pieces which are uniformly distributed in an annular array. The plectrum can improve the frictional force with the shoelace.

As a further aspect of the present invention: and a strip-shaped groove matched with the shoelace is arranged on the platform below the conveying wheel. The shoelace can be guided.

As a further aspect of the present invention: the front side of platform is equipped with unwinding mechanism, and unwinding mechanism includes unreeling roller, and unreeling roller passes through the roller and installs on the support, and further again, unreeling roller joinable actuating mechanism.

Compared with the prior art, the beneficial effects of the utility model are that: the cutting equipment for processing the shoelace of the sports shoe seals the shoelace through the end sealing mechanism, and then conveys the shoelace to the cutting mechanism through the conveying mechanism to be cut into shoelace products; the automation degree is high, the labor force is saved, and the processing efficiency is improved.

Drawings

Fig. 1 is a schematic structural diagram of the present invention in the first embodiment;

fig. 2 is a schematic structural view of the head sealing mechanism according to the first embodiment of the present invention;

fig. 3 is a schematic structural diagram of a mounting base according to the first embodiment of the present invention;

fig. 4 is a schematic structural view of a cylindrical cavity according to the first embodiment of the present invention.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Example one

Referring to fig. 1-4, in the embodiment of the present invention, a cutting apparatus for processing shoelaces of sports shoes comprises a head sealing mechanism, a head sealing conveying mechanism, a shoelace conveying mechanism and a cutting mechanism, wherein the head sealing mechanism, the head sealing conveying mechanism, the shoelace conveying mechanism and the cutting mechanism are all disposed on a platform 1, the head sealing mechanism comprises a mounting seat 2, supporting rods 3, a movable mold 4, a fixed mold 5 and a linear driving mechanism, the mounting seat 2 is disposed above the platform 1, the bottom of the mounting seat 2 is connected to the platform 1 through a plurality of supporting rods 3, a movable mold 4 is disposed between the mounting seat 2 and the platform 1, the movable mold 4 is connected to the linear driving mechanism, the linear driving mechanism comprises a first cylinder 6, the first cylinder 6 is fixedly connected to the mounting seat 2 through a front end flange, the mounting seat 2 is provided with a through hole in clearance fit with a piston rod of the first cylinder 6, a piston rod of the first air cylinder 6 is fixedly connected with the top of the movable mould 4, a fixed mould 5 is arranged on the platform 1 below the movable mould 4, a square groove matched with the fixed mould 5 is arranged on the platform 1, and the fixed mould 5 is embedded in the square groove;

the bottom of the fixed mold 5 and the top of the movable mold 4 are provided with an upper mold cavity and a lower mold cavity which are matched with each other, the upper mold cavity and the lower mold cavity are integrally semi-cylindrical, the upper mold cavity and the lower mold cavity are spliced to form a cylindrical mold cavity 7, and two ends of the cylindrical mold cavity 7 are opened. The telescopic rod of the first air cylinder 6 drives the movable mould 4 to move up and down, the movable mould and the fixed mould 5 are matched and separated, and the shoelace passes between the fixed mould 5 and the movable mould 4.

The left side of mount pad 2 is equipped with head conveying mechanism, and head conveying mechanism includes two tracks 8 that set up side by side, and track 8's both sides are equipped with the baffle, and track 8's inside is equipped with push rod 9, and the push rod seat is connected to the left end of push rod 9, and the piston rod of second cylinder 10 is connected to the left end of push rod seat, and second cylinder 10 passes through cylinder block fixed mounting on platform 1. The second cylinder 10 pushes the push rod seat to drive the two push rods 9 to push the seal head pieces in the track 8 to reach the lower part of the movable mold 4, so that the seal head pieces are clamped on the shoelace.

Shoelace conveying mechanism locates the rear side of capping mechanism, and dissection mechanism locates the rear side of capping mechanism, and shoelace conveying mechanism includes first motor 11 and delivery wheel 12, and first motor 11 passes through motor cabinet fixed mounting on platform 1, fixedly on first motor 11's the output shaft being equipped with delivery wheel 12. The first motor 11 drives the conveying wheel 12 to rotate so as to drive the shoelace to move backwards for a certain distance through the friction force of the conveying wheel 12;

the section cutting mechanism comprises a second motor 13 and a cutter blade 14, the second motor 13 is fixedly mounted on the platform 1 through a motor base, the cutter blade 14 is fixedly mounted on an output shaft of the second motor 13, and a strip-shaped groove matched with the cutter blade 14 is formed in the platform 1 below the cutter blade 14. The second motor 13 rotates the cutter blade 14 to cut the shoelace by the cutter blade 14.

Further, the top surface of the fixed mold 5 is flush with the top surface of the lower stage 1.

Further, the end enclosure piece comprises a semicircular piece, an upper piece and a lower piece, one side of the semicircular piece is connected with the upper piece, the other side of the semicircular piece is connected with the lower piece, the semicircular piece, the upper piece and the lower piece are connected to form a U-shaped structure, and the length of the upper piece is greater than that of the lower piece; the semicircular sheet preliminarily forms the coating of the shoelace, the upper sheet is bent downwards and the lower sheet is bent upwards during extrusion, the upper sheet with the length larger than that of the lower sheet coats the lower sheet, and finally the end enclosure piece is curled into a cylinder shape.

Further, a depression with an arc-shaped cross section is arranged on the left side of the cylindrical cavity 7 formed by splicing the upper cavity and the lower cavity, so that a space is provided for the upper sheet to cover the lower sheet.

Further, the periphery of the conveying wheel 12 is provided with a plurality of shifting pieces which are uniformly distributed in an annular array. The plectrum can improve the frictional force with the shoelace.

Further, a strip-shaped groove matched with the shoelace is arranged on the platform 1 below the conveying wheel 12. The shoelace can be guided.

Further, the front side of platform 1 is equipped with unwinding mechanism, and unwinding mechanism includes the unwinding roller, and the unwinding roller passes through the roller and installs on the support, and further again, unwinding roller joinable actuating mechanism.

Further, the first cylinder 6 and the second cylinder 10 are of the type MAL-40X 150-S-U. Is connected with an air source through a pipeline and a valve.

Further, the first motor 11 is of a model MSMD5A2P 1D. The power supply is connected through the driver. The rotation angle can be controlled to rotate the conveying wheel 12 by a certain angle.

Further, the second motor 13 is of a model MSMD5A2P 1D. The power supply is connected through the switch.

The utility model discloses a structural feature and theory of operation: conveying mechanism drives the shoelace and passes through head sealing mechanism, place two head sealing spare on track 8 this moment (place or carry on track 8 manually or through other equipment), then second cylinder 10 promotes two head sealing spare cards on the shoelace, then reset, first cylinder 6 promotes movable mould 4 and moves down the compound die, make head sealing spare cladding on the shoelace and form the tubular structure (two head sealing spare side by side, therefore a set of mould of sharing can), then first cylinder 6 resets, first motor 11 drives delivery wheel 12 this moment and makes the head sealing position of shoelace move the below of cutter blade 14, then second motor 13 drives cutter blade 14 and rotates and cuts off the shoelace from the position between two head sealing spares, with this head sealing and the dissection of realization shoelace.

It is obvious to a person skilled in the art that the invention is not restricted to details of the above-described exemplary embodiments, but that it can be implemented in other specific forms without departing from the spirit or essential characteristics of the invention. 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.

Furthermore, it should be understood that although the present description refers to embodiments, not every embodiment may contain only a single embodiment, and such description is for clarity only, and those skilled in the art should integrate the description, and the embodiments may be combined as appropriate to form other embodiments understood by those skilled in the art.

Claims (6)

1. A cutting device for processing shoelaces of sports shoes is characterized by comprising an end enclosure mechanism, an end enclosure conveying mechanism, a shoelace conveying mechanism and a cutting mechanism, wherein the end enclosure mechanism, the end enclosure conveying mechanism, the shoelace conveying mechanism and the cutting mechanism are all arranged on a platform, the end enclosure mechanism comprises a mounting seat, supporting rods, a movable die, a fixed die and a linear driving mechanism, the mounting seat is arranged above the platform, the bottom of the mounting seat is connected with the platform through a plurality of supporting rods, the movable die is arranged between the mounting seat and the platform and is connected with the linear driving mechanism, the linear driving mechanism comprises a first air cylinder, the first air cylinder is fixedly connected with the mounting seat through a front end flange, a through hole in clearance fit with a piston rod of the first air cylinder is arranged on the mounting seat, a piston rod of the first air cylinder is fixedly connected with the top of the movable die, the fixed die is arranged on the platform, a square groove matched with the fixed mold is arranged on the platform, and the fixed mold is embedded in the square groove;

the bottom of the fixed die and the top of the movable die are provided with an upper die cavity and a lower die cavity which are matched with each other, the upper die cavity and the lower die cavity are integrally semi-cylindrical, the upper die cavity and the lower die cavity are spliced to form a cylindrical die cavity, and two ends of the cylindrical die cavity are opened;

the left side of the mounting seat is provided with a seal head conveying mechanism, the seal head conveying mechanism comprises two rails arranged in parallel, two sides of each rail are provided with baffles, a push rod is arranged inside each rail, the left end of each push rod is connected with a push rod seat, the left end of each push rod seat is connected with a piston rod of a second air cylinder, and the second air cylinder is fixedly mounted on the platform through an air cylinder seat;

the shoelace conveying mechanism is arranged at the rear side of the end enclosure mechanism, the cutting mechanism is arranged at the rear side of the end enclosure mechanism, the shoelace conveying mechanism comprises a first motor and a conveying wheel, the first motor is fixedly arranged on the platform through a motor base, and the conveying wheel is fixedly arranged on an output shaft of the first motor;

the cutting mechanism comprises a second motor and a cutter blade, the second motor is fixedly mounted on the platform through a motor base, the cutter blade is fixedly mounted on an output shaft of the second motor, and a strip-shaped groove matched with the cutter blade is formed in the platform below the cutter blade.

2. A cutting apparatus for shoelace processing of sports shoes as claimed in claim 1, wherein a top surface of said stationary mold is flush with a top surface of said lower platform.

3. The cutting apparatus for shoelace processing of sports shoes as claimed in claim 1, wherein a recess having an arc-shaped cross section is formed at a left side of the cylindrical cavity formed by splicing the upper cavity and the lower cavity.

4. A cutting apparatus for shoelace processing of sports shoes as claimed in claim 1, wherein said transfer wheel is provided at its periphery with a plurality of uniformly annularly arrayed picks.

5. The cutting apparatus for shoelace processing of sports shoes as claimed in claim 1, wherein a bar-shaped groove for fitting the shoelace is formed on the platform below the delivery wheel.

6. The cutting apparatus for shoelace processing of sports shoes as claimed in claim 1, wherein an unwinding mechanism is provided at a front side of said platform, said unwinding mechanism comprising an unwinding roller, said unwinding roller being mounted on said support via a roller shaft.

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