CN112120349A

CN112120349A - Cutting mechanism for antistatic boots and process thereof

Info

Publication number: CN112120349A
Application number: CN202010828283.4A
Authority: CN
Inventors: 钟永生
Original assignee: Hangzhou Fuyang Gaoyi Shoes Co ltd
Current assignee: Hangzhou Fuyang Gaoyi Shoes Co ltd
Priority date: 2020-08-18
Filing date: 2020-08-18
Publication date: 2020-12-25
Anticipated expiration: 2040-08-18
Also published as: CN112120349B

Abstract

The application relates to the technical field of boot processing, in particular to a cutting mechanism for an antistatic boot and a process thereof, wherein the cutting mechanism comprises a rack, a conveying component, a cutting component and a winding component; a workbench is fixed on the frame; the cutting assembly comprises a first hydraulic cylinder fixed on the rack, a mounting plate fixed on a piston rod of the first hydraulic cylinder and a plurality of cutting dies fixed on the lower surface of the mounting plate; conveying assembly includes rotary drum and driving piece, and the transversal polygon setting of personally submitting of rotary drum, and all be equipped with on each face of rotary drum lateral part and paste the layer. All cutting dies can cut simultaneously and paste the surface fabric on the layer is pasted to the rotary drum upside, and during rolling subassembly rolling surface fabric, will make the surface fabric of cutting the completion and paste the vamp separation on the layer to the workman will paste and tear the vamp on pasting the layer one by one. To sum up, this application can cut out a plurality of vamp simultaneously, and can accomplish the vamp automatically and cut the separation of accomplishing the surface fabric. This application has improved the machining efficiency of surface fabric.

Description

Cutting mechanism for antistatic boots and process thereof

Technical Field

The application relates to the technical field of boot processing, in particular to a cutting mechanism for an antistatic boot and a process thereof.

Background

As the fashion concept is popularized to the public, boots of various styles are indispensable in shoe cabinets. The boot comprises a boot sole, a boot vamp and a boot leg. Because static electricity may be generated when a user wears a boot, an antistatic agent is generally added to a sole preparation material of the boot at present to remove the static electricity. The vamp of the boot is usually cut from the shell fabric by a cutting machine.

As shown in fig. 1, the current cutting machine includes a frame 1, a worktable 11 and two first hydraulic cylinders 31 located above the worktable 11 are installed on the frame 1, piston rods of the first hydraulic cylinders 31 extend in a vertical direction and are fixed with mounting plates 32, a fabric 9 is placed on the worktable 11, and a cutting die 33 is placed on the fabric 9. During the cutting process of the fabric 9, the first hydraulic cylinder 31 drives the mounting plate 32 to press the cutting die 33 downwards, so that the cutting die 33 cuts the shoe surface 91 on the fabric 9.

With respect to the related art among the above, the inventors consider that the following drawbacks exist: the efficiency is low by the worker continuously adjusting the position of the cutter die 33 to cut the individual boots 91 on the material 9, and thus improvement is required.

Disclosure of Invention

In order to improve the processing efficiency of fabrics, the application provides a cutting mechanism for an antistatic boot and a process thereof.

In a first aspect, the application provides a cutting mechanism for an antistatic boot, which adopts the following technical scheme: a cutting mechanism for antistatic boots comprises a rack, a conveying component for conveying fabric, a cutting component for cutting the fabric and a winding component for winding the fabric; a workbench for placing the fabric is fixed on the frame; the cutting assembly comprises a first hydraulic cylinder fixed on the rack, a mounting plate fixed on a piston rod of the first hydraulic cylinder and a plurality of cutting dies fixed on the lower surface of the mounting plate, and the piston rod of the first hydraulic cylinder extends in the vertical direction; conveying component is including being located cutting die below and along the rotary drum of surface fabric width direction extension with be used for driving the rotary drum around the rotatory driving piece of self axis, the transversal polygon setting of personally submitting of rotary drum, and all be equipped with the layer of pasting that is used for pasting the surface fabric on each face of rotary drum lateral part, the length of pasting the layer along surface fabric direction of delivery of rotary drum upside is greater than the length of vamp.

By adopting the technical scheme, in the processing process of the fabric, the fabric is firstly placed on the workbench, and then the driving piece drives the rotary drum to rotate, so that the upper side of the rotary drum is parallel to the horizontal plane; then, a worker presses the fabric on the sticking layer, and the first hydraulic cylinder drives the mounting plate to descend, so that all the cutting dies cut the fabric stuck on the sticking layer on the upper side of the rotary drum at the same time; because the length of the pasting layer on the upper side of the rotary drum along the fabric conveying direction is greater than that of the boot vamp, the cutting die can cut a plurality of complete boot vamp on the fabric, and the boot vamp and the fabric are pasted on the pasting layer.

Then the first hydraulic cylinder drives the mounting plate to ascend, and the winding assembly winds the fabric, so that the cut fabric is separated from the vamp on the adhesive layer; simultaneously, the driving piece will drive the rotary drum rotatory for the another side of rotary drum is parallel with the horizontal plane, and the workman can continue the cutting of surface fabric with the surface fabric of not cutting paste on this face afterwards. In the cutting process of the fabric, workers can tear the boot vamp adhered to the adhering layer one by one. To sum up, this application can cut out a plurality of vamp simultaneously, and can accomplish the vamp automatically and cut the separation of accomplishing the surface fabric to the machining efficiency of surface fabric has been improved.

Preferably, each surface of the side part of the rotary drum and the adhesive layer are respectively provided with a plurality of through holes, and each shoe surface corresponds to a plurality of through holes; the frame is provided with a material ejecting component, the material ejecting component comprises a lifting plate positioned on the inner side of the rotary drum and a lifting piece driving the lifting plate to lift, and a plurality of ejector rods which are slidably embedded in the corresponding through holes are fixed on the lifting plate.

Through adopting above-mentioned technical scheme, when only pasting the one side rotation that has the vamp on the rotary drum and being on a parallel with the horizontal plane, the lifter will drive the lifter plate and descend, and the ejector pin will wear out the through-hole and will all push up the all boots face of this face and move and break away from in pasting the layer, need not the workman and tears a plurality of boots faces from pasting the layer one by one, has improved the collection efficiency of boots face.

Preferably, a material receiving assembly is arranged below the rotary drum and comprises a plurality of material receiving boxes for receiving the falling shoe surfaces, and the shoe surfaces are embedded in the material receiving boxes in a sliding manner.

Through adopting above-mentioned technical scheme, when only pasting the one side that has the vamp on the rotary drum and rotating when being on a parallel with the horizontal plane, every vamp all is located corresponding material receiving box directly over, and the lifter will drive the lifter plate and descend this moment, and the ejector pin will wear out the through-hole and all the vamp of this face all push up in the material receiving box that corresponds, and the vamp will slide to the bottom of material receiving box for the vamp is accomodate in the material receiving box neatly.

Preferably, the material pressing assembly is arranged at the position of the workbench and comprises a support, a pressing plate and a spring are arranged on the support, the pressing plate is located above the workbench, the spring enables the pressing plate to press the fabric on the workbench, one end of the spring is fixedly connected to the pressing plate, and the other end of the spring is fixedly connected to the support.

By adopting the technical scheme, when the driving piece drives the rotary drum to rotate, the fabric is stuck on the sticking layer of the rotary drum, so that the fabric is pulled to move by the rotary drum; because of the spring impels the clamp plate to compress tightly the surface fabric on the workstation, so the surface fabric is in the tensioning state all the time, along with the rotation of rotary drum, the surface fabric that is not cut will paste automatically on the layer of pasting of rotary drum, need not the workman and press the surface fabric on pasting the layer, has improved the machining efficiency of surface fabric.

Preferably, the winding assembly comprises a fixing frame, a winding roller rotatably connected to the fixing frame and a driving motor fixed to the fixing frame, an output shaft of the driving motor is fixedly connected to the winding roller, and the output shaft of the driving motor and the winding roller extend along the width direction of the fabric.

Through adopting above-mentioned technical scheme, when driving motor drove the wind-up roll rotation, the wind-up roll will cut the surface fabric rolling of accomplishing for the surface fabric that cuts accomplish breaks away from in pasting the layer and separate with the vamp, so that the collection of follow-up vamp.

Preferably, the winding assembly further comprises a pull rope and a puncture rod, one end of the pull rope is fixedly connected to the winding roller, the other end of the pull rope is fixedly connected to the puncture rod, and a tip end used for puncturing the fabric is arranged on the puncture rod.

By adopting the technical scheme, when the fabric is cut at the beginning, the fabric cannot be wound on the winding roller, so that the winding roller cannot wind the fabric, and workers are required to pull the fabric to the winding roller, so that the operation is inconvenient; and the setting of puncture pole and stay cord for the puncture pole can be handed to the workman to puncture the surface fabric through the pointed end of puncture pole, puncture the pole and will pass the surface fabric and tie on the stay cord, it is rotatory to drive the wind-up roll through driving motor this moment, and the stay cord will be convoluteed on the wind-up roll and with the surface fabric pull to the wind-up roll, has realized the automatic rolling of surface fabric, has improved the machining efficiency of surface fabric.

Preferably, still include supporting component, supporting component includes the swivel that the supporting seat and the fixed cover that are located the rotary drum below were established outside the rotary drum, and the upper surface of supporting seat is equipped with and supplies the swivel to rotate to inlay the cavity of establishing.

Through adopting above-mentioned technical scheme, at the rotation in-process of rotary drum, the change ring will be at the cavity internal rotation, has improved the stability of rotary drum.

Preferably, the workbench is fixed with two limiting plates clamped on the fabric together, and the arrangement direction of the two limiting plates is the same as the width direction of the fabric.

By adopting the technical scheme, the limiting plate enables the fabric to be difficult to deviate in the conveying process, and ensures that the cutting die can accurately reach the fabric every time.

In a second aspect, the present application provides a cutting process of a cutting mechanism, which adopts the following technical scheme: a cutting process of a cutting mechanism comprises the following steps:

s1, placing the fabric on a workbench, enabling the pressing plate to tightly press the fabric on the workbench through a spring, and enabling the driving piece to drive the rotary drum to rotate so that the upper side of the rotary drum is parallel to the horizontal plane;

s2, puncturing the fabric through the tip end of the puncture rod, enabling the puncture rod to penetrate through the fabric, and tying the puncture rod to the pull rope;

s3, driving the winding roller to rotate through the driving motor, and pulling and adhering the fabric on the adhering layer of the rotary drum by the pull rope;

s4, the mounting plates are driven to descend through the first hydraulic cylinders, so that the shell fabrics are cut by all the cutting dies at the same time, a plurality of boot surfaces are cut by the shell fabrics, then the mounting plates are driven to ascend by the first hydraulic cylinders, and the shell fabrics and the boot surfaces are still adhered to the adhering layer;

s5, the winding roller is driven to rotate through the driving motor, the cut fabric is wound on the winding roller, meanwhile, the driving piece drives the rotary drum to rotate, the other surface of the rotary drum is parallel to the horizontal plane, the fabric which is not cut is pasted on the surface of the rotary drum, the first hydraulic cylinder drives the mounting plate to descend, and the cutting die continues to cut the fabric;

s6, when the surface of the rotary drum, which is only adhered with the shoe surface, rotates to correspond to the material receiving box, the lifting piece drives the lifting plate to descend, and the ejector rod penetrates out of the through hole and pushes the shoe surface into the material receiving box.

By adopting the technical scheme, simultaneous molding of a plurality of vamp, separation of the fabric and the vamp and full-automatic collection of the vamp are realized, so that the processing efficiency of the fabric is improved.

To sum up, the application comprises the following beneficial technical effects:

1. due to the arrangement of the conveying assembly, the cutting assembly and the winding assembly, a plurality of vamp can be cut simultaneously, and the separation of the vamp and the cut fabric can be automatically completed, so that the processing efficiency of the fabric is improved;

2. the ejector assembly is arranged, so that the ejector rod can eject all the vamp surfaces to be separated from the adhesive layer, workers do not need to tear off the plurality of vamp surfaces from the adhesive layer one by one, and the collection efficiency of the vamp surfaces is improved;

3. the material receiving assembly is arranged, so that the boot surface is neatly accommodated in the material receiving box;

4. due to the arrangement of the material pressing component, uncut fabric is automatically adhered to the adhesive layer of the drum, workers do not need to press the fabric on the adhesive layer, and the processing efficiency of the fabric is improved;

5. the setting of stay cord and puncture rod, the stay cord will be the surface fabric pull to the wind-up roll, has realized the automatic rolling of surface fabric, has improved the machining efficiency of surface fabric.

Drawings

FIG. 1 is a schematic diagram of a cutting machine according to the prior art;

FIG. 2 is a schematic structural diagram of the whole in the embodiment of the present application;

FIG. 3 is a schematic diagram showing the structure of a conveying assembly, a cutting assembly and a pressing assembly in an embodiment of the present application;

FIG. 4 is a schematic structural diagram of a take-up assembly shown in the embodiment of the present application;

FIG. 5 is a schematic structural view showing a receiving assembly, an ejecting assembly and a supporting assembly in an embodiment of the present application;

FIG. 6 is a schematic structural view showing a receiving assembly and an ejecting assembly in the embodiment of the present application.

Reference numerals: 1. a frame; 11. a work table; 12. a limiting plate; 2. a delivery assembly; 21. a rotating drum; 211. a through hole; 22. a bonding layer; 23. a reduction motor; 3. cutting the assembly; 31. a first hydraulic cylinder; 32. mounting a plate; 33. cutting the die; 4. a winding component; 41. a fixed mount; 42. a wind-up roll; 43. a drive motor; 44. pulling a rope; 45. a puncture rod; 451. a tip; 5. a material pressing component; 51. a support; 52. pressing a plate; 53. a spring; 6. a material receiving assembly; 61. a material receiving box; 611. an opening; 7. a material ejecting component; 71. a lifting plate; 72. a transverse plate; 73. a second hydraulic cylinder; 74. a top rod; 8. a support assembly; 81. a supporting seat; 811. a concave cavity; 82. rotating the ring; 9. fabric; 91. a boot surface.

Detailed Description

The present application is described in further detail below with reference to figures 2-6.

The embodiment of the application discloses decide mechanism for antistatic boot. As shown in fig. 2, a cutting mechanism for antistatic boots comprises a rack 1, a conveying assembly 2 for conveying a fabric 9, a cutting assembly 3 for cutting the fabric 9, a winding assembly 4 for winding the fabric 9, a pressing assembly 5 for ensuring stability of the fabric 9, a material collecting assembly 6 for collecting a vamp 91, a material ejecting assembly 7 for ejecting the vamp 91 on the conveying assembly 2 onto the material collecting assembly 6, and a supporting assembly 8 for supporting the conveying assembly 2.

As shown in fig. 2, be fixed with the workstation 11 that supplies surface fabric 9 to place in the frame 1, be fixed with two limiting plates 12 on the workstation 11, the direction of arranging of two limiting plates 12 is the same with the width direction of surface fabric 9, and two limiting plates 12 centre gripping in surface fabric 9 jointly for surface fabric 9 is difficult for the skew in transportation process, has guaranteed that cutting assembly 3 can accurately cut surface fabric 9.

As shown in fig. 2 and 3, the cutting assembly 3 includes two first hydraulic cylinders 31 fixed on the frame 1, a mounting plate 32 fixed on piston rods of the two first hydraulic cylinders 31, and a plurality of cutting dies 33 fixed on the lower surface of the mounting plate 32, the piston rods of the first hydraulic cylinders 31 extend in the vertical direction, and the plurality of cutting dies 33 are sequentially arranged in the width direction of the fabric 9. The conveying assembly 2 comprises a rotary drum 21 and a driving part, the rotary drum 21 is positioned below the cutting die 33 and extends along the width direction of the fabric 9, the cross section of the rotary drum 21 is arranged in a polygon shape, the cross section of the rotary drum 21 is in a hexagon shape in the embodiment, and each surface of the side part of the rotary drum 21 is provided with an adhering layer 22 for adhering the fabric 9; the driving part is a speed reducing motor 23 fixed on the frame 1, and an output shaft of the speed reducing motor 23 extends along the width direction of the fabric 9 and is fixedly connected to the rotary drum 21.

In the processing process of the fabric 9, the speed reducing motor 23 drives the rotary drum 21 to rotate, so that the upper side of the rotary drum 21 is parallel to the horizontal plane, and the fabric 9 is adhered to the adhering layer 22 on the upper side of the rotary drum 21; the first hydraulic cylinder 31 drives the mounting plate 32 to descend, so that all the cutting dies 33 simultaneously cut the fabric 9 adhered on the adhesive layer 22 on the upper side of the rotary drum 21; since the length of the adhesive layer 22 on the upper side of the drum 21 in the conveyance direction of the cover material 9 is longer than the length of the shoe surface 91, the cutting die 33 can cut a plurality of complete shoe surfaces 91 on the cover material 9, and both the shoe surfaces 91 and the cover material 9 are adhered to the adhesive layer 22.

As shown in fig. 4, the winding assembly 4 includes a fixing frame 41, a winding roller 42, a driving motor 43, a pull rope 44 and a puncture rod 45, the winding roller 42 is rotatably connected to the fixing frame 41, the driving motor 43 is fixed on the fixing frame 41, an output shaft of the driving motor 43 is fixedly connected to the winding roller 42, and the output shaft of the driving motor 43 and the winding roller 42 both extend along the width direction of the fabric 9; one end of the pulling rope 44 is fixedly connected to the winding roller 42, the other end of the pulling rope 44 is fixedly connected to the puncture rod 45, and a tip 451 for puncturing the fabric 9 is arranged on the puncture rod 45.

When the fabric 9 starts to be cut, a worker holds the puncture rod 45 by hand and punctures the fabric 9 through the tip 451 of the puncture rod 45, and the puncture rod 45 penetrates through the fabric 9 and is tied on the pull rope 44; after the cutting of the fabric 9 is completed, the driving motor 43 drives the winding roller 42 to rotate, the reduction motor 23 drives the drum 21 to rotate in the same direction, the pull rope 44 winds the winding roller 42 and pulls the fabric 9 to the winding roller 42, and the cut fabric 9 is separated from the adhesive layer 22 and separated from the vamp 91.

As shown in fig. 5, the supporting assembly 8 includes a supporting seat 81 located below the drum 21 and a rotating ring 82 fixedly sleeved outside the drum 21, a cavity 811 is provided on an upper surface of the supporting seat 81, and during the rotation of the drum 21, the rotating ring 82 will rotate in the cavity 811, thereby improving the stability of the drum 21.

As shown in fig. 2 and 3, the pressing assembly 5 includes a bracket 51, a pressing plate 52 and two springs 53 are disposed on the bracket 51 and located above the worktable 11, one end of each spring 53 is fixedly connected to the pressing plate 52, and the other end of each spring 53 is fixedly connected to the bracket 51. In the process of rotating the take-up roller 42 and the rotary drum 21, the pull rope 44 pulls the fabric 9 to the take-up roller 42, and the fabric 9 is pulled by the rotary drum 21 to move as the fabric 9 is stuck on the sticking layer 22 of the rotary drum 21; because the pressing plate 52 is urged by the spring 53 to press the fabric 9 against the worktable 11, the fabric 9 is always in a tensioned state, and as the drum 21 rotates, the fabric 9 which is not cut is automatically adhered to the adhesive layer 22 on the upper side of the drum 21, so that the cutting die 33 continues to cut the fabric 9.

As shown in fig. 5 and 6, a plurality of through holes 211 are formed on each of the side portions of the drum 21 and the adhesive layer 22, and each of the shoe surfaces 91 corresponds to the plurality of through holes 211. The material ejecting assembly 7 comprises a lifting plate 71 located inside the rotary drum 21, a transverse plate 72 fixed on the bracket 51 and two lifting pieces fixed on the transverse plate 72, wherein a plurality of ejector rods 74 embedded in the corresponding through holes 211 in a sliding manner are fixed on the lifting plate 71, the lifting pieces are second hydraulic cylinders 73, and piston rods of the second hydraulic cylinders 73 extend in the vertical direction and are fixedly connected to the lifting plate 71. When the drum 21 is rotated downward with only the shoe surface 91 adhered thereto, the second hydraulic cylinder 73 lowers the lifting plate 71, and the lift pins 74 are pushed out of the through holes 211 to separate all the shoe surfaces 91 from the adhesive layer 22.

As shown in fig. 6, the material receiving assembly 6 includes a plurality of material receiving boxes 61 sequentially arranged along the width direction of the fabric 9, and the openings of the material receiving boxes 61 face upward. When the shoe surfaces 91 are pushed by the push rods 74 to be separated from the sticking layer 22, each shoe surface 91 is inserted into the corresponding material receiving box 61 in a sliding manner, so that the shoe surfaces 91 are neatly received in the material receiving box 61; an opening 611 extending in the vertical direction is formed in the outer wall of the material receiving box 61, and the opening 611 penetrates through the inner wall of the material receiving box 61 and the upper end of the material receiving box 61, so that a worker can take out the shoe surface 91 in the material receiving box 61.

The implementation principle of the cutting mechanism for the antistatic boot in the embodiment of the application is as follows: in the processing process of the fabric 9, a worker holds the puncture rod 45 and punctures the fabric 9 through the tip 451 of the puncture rod 45, and the puncture rod 45 penetrates through the fabric 9 and is tied on the pull rope 44; then the driving motor 43 drives the wind-up roll 42 to rotate, the speed reduction motor 23 drives the rotary drum 21 to rotate in the same direction, and the pull rope 44 pulls the fabric 9 to move, so that the fabric 9 is adhered on the adhering layer 22 on the upper side of the rotary drum 21, and the upper side of the rotary drum 21 is parallel to the horizontal plane at the moment.

Then the first hydraulic cylinder 31 drives the mounting plate 32 to descend, so that all the cutting dies 33 simultaneously cut the fabric 9 adhered on the adhesive layer 22 on the upper side of the drum 21, the fabric 9 is cut into a plurality of complete vamp 91, and the vamp 91 and the fabric 9 are both adhered on the adhesive layer 22; then the driving motor 43 drives the winding roller 42 to rotate, the speed reduction motor 23 drives the rotary drum 21 to rotate in the same direction, the pull rope 44 winds the winding roller 42 and pulls the fabric 9 to the winding roller 42, the cut fabric 9 is separated from the adhesive layer 22 and is separated from the boot surface 91, and the fabric 9 which is not cut is automatically adhered to the adhesive layer 22 on the upper side of the rotary drum 21, so that the cutting die 33 continues to cut the fabric 9.

When only one surface of the drum 21 to which the shoe surface 91 is adhered rotates downward, the second hydraulic cylinder 73 drives the lifting plate 71 to descend, the push rod 74 penetrates through the through hole 211 and pushes all the shoe surfaces 91 of the surface into the corresponding material receiving box 61, so that the shoe surfaces 91 are neatly received in the material receiving box 61.

To sum up, this application has realized that the synchronous accuracy of the automatic feeding of surface fabric 9, a plurality of vamp 91 cuts, cuts the surface fabric 9 of accomplishing and the autosegregation of vamp 91, cuts the rolling of accomplishing surface fabric 9, neatly accomodating of vamp 91 to the machining efficiency of surface fabric 9 has been improved.

The embodiment of the application also discloses a cutting process of the cutting mechanism. A cutting process of a cutting mechanism comprises the following steps:

s1, placing the fabric 9 on the workbench 11, enabling the pressing plate 52 to press the fabric 9 on the workbench 11 by the spring 53, holding the puncture rod 45 by a worker, puncturing the fabric 9 through the tip 451 of the puncture rod 45, and enabling the puncture rod 45 to penetrate through the fabric 9 and be tied on the pull rope 44;

s2, driving the winding roller 42 to rotate through the driving motor 43, driving the rotary drum 21 to rotate in the same direction through the speed reducing motor 23, and pulling the fabric 9 to move through the pull rope 44, so that the fabric 9 is adhered to the adhering layer 22 on the upper side of the rotary drum 21, and the upper side of the rotary drum 21 is parallel to the horizontal plane;

s3, the mounting plate 32 is driven to descend through the first hydraulic cylinder 31, so that all the cutting dies 33 simultaneously cut the fabric 9 adhered on the adhesive layer 22 on the upper side of the drum 21, the fabric 9 is cut into a plurality of complete vamp 91, and the vamp 91 and the fabric 9 are both adhered on the adhesive layer 22;

s4, the winding roller 42 is driven to rotate by the driving motor 43, the rotary drum 21 is driven to rotate in the same direction by the speed reducing motor 23, the pull rope 44 winds on the winding roller 42 and pulls the fabric 9 to the winding roller 42, the cut fabric 9 is separated from the adhesive layer 22 and separated from the vamp 91, and the fabric 9 which is not cut is automatically adhered to the adhesive layer 22 on the upper side of the rotary drum 21, so that the cutting die 33 continues to cut the fabric 9;

s5, when only the surface of the drum 21 to which the shoe surfaces 91 are adhered rotates downward, the second hydraulic cylinder 73 will drive the lifting plate 71 to descend, and the push rod 74 will pass through the through hole 211 and push all the shoe surfaces 91 of the surface into the corresponding receiving box 61, so that the shoe surfaces 91 are neatly received in the receiving box 61.

The above embodiments are preferred embodiments of the present application, and the protection scope of the present application is not limited by the above embodiments, so: all equivalent changes made according to the structure, shape and principle of the present application shall be covered by the protection scope of the present application.

Claims

1. The utility model provides a decide mechanism for antistatic boot which characterized in that: comprises a frame (1), a conveying component (2) for conveying the fabric (9), a cutting component (3) for cutting the fabric (9) and a winding component (4) for winding the fabric (9); a workbench (11) for placing the fabric (9) is fixed on the frame (1); the cutting assembly (3) comprises a first hydraulic cylinder (31) fixed on the rack (1), a mounting plate (32) fixed on a piston rod of the first hydraulic cylinder (31) and a plurality of cutting dies (33) fixed on the lower surface of the mounting plate (32), and the piston rod of the first hydraulic cylinder (31) extends in the vertical direction; conveying assembly (2) are including being located cutting die (33) below and along rotary drum (21) of surface fabric (9) width direction extension and being used for driving rotary drum (21) around the rotatory driving piece of self axis, the transversal polygon setting of personally submitting of rotary drum (21), and all be equipped with on each face of rotary drum (21) lateral part and be used for pasting layer (22) of surface fabric (9), the length of pasting layer (22) on rotary drum (21) upside along surface fabric (9) direction of delivery is greater than the length of vamp (91).

2. A cutting mechanism for antistatic boots as claimed in claim 1, characterized in that: each surface of the side part of the rotary drum (21) and the adhesive layer (22) are respectively provided with a plurality of through holes (211), and each boot surface (91) corresponds to a plurality of through holes (211); the machine frame (1) is provided with a material ejecting component (7), the material ejecting component (7) comprises a lifting plate (71) positioned on the inner side of the rotary drum (21) and a lifting piece driving the lifting plate (71) to lift, and a plurality of ejector rods (74) which are embedded in the corresponding through holes (211) in a sliding manner are fixed on the lifting plate (71).

3. A cutting mechanism for antistatic boots as claimed in claim 2, characterized in that: the collecting component (6) is arranged below the rotary drum (21), the collecting component (6) comprises a plurality of collecting boxes (61) used for receiving the falling shoe surfaces (91), and the shoe surfaces (91) are embedded in the collecting boxes (61) in a sliding mode.

4. A cutting mechanism for antistatic boots as claimed in claim 1, characterized in that: the fabric pressing device is characterized in that a pressing component (5) is arranged at the position of the workbench (11), the pressing component (5) comprises a support (51), a pressing plate (52) located above the workbench (11) and a spring (53) enabling the pressing plate (52) to compress a fabric (9) on the workbench (11) are arranged on the support (51), one end of the spring (53) is fixedly connected to the pressing plate (52), and the other end of the spring (53) is fixedly connected to the support (51).

5. A cutting mechanism for antistatic boots as claimed in claim 1, characterized in that: the winding assembly (4) comprises a fixing frame (41), a winding roller (42) which is rotatably connected to the fixing frame (41) and a driving motor (43) which is fixed to the fixing frame (41), an output shaft of the driving motor (43) is fixedly connected to the winding roller (42), and the output shaft of the driving motor (43) and the winding roller (42) extend along the width direction of the fabric (9).

6. A cutting mechanism for antistatic boots as claimed in claim 5, characterized in that: the winding assembly (4) further comprises a pull rope (44) and a puncture rod (45), one end of the pull rope (44) is fixedly connected to the winding roller (42), the other end of the pull rope (44) is fixedly connected to the puncture rod (45), and a tip end (451) used for puncturing the fabric (9) is arranged on the puncture rod (45).

7. A cutting mechanism for antistatic boots as claimed in claim 1, characterized in that: the rotary drum support device is characterized by further comprising a supporting component (8), wherein the supporting component (8) comprises a supporting seat (81) located below the rotary drum (21) and a rotary ring (82) fixedly sleeved outside the rotary drum (21), and a concave cavity (811) for the rotary ring (82) to be rotatably embedded is formed in the upper surface of the supporting seat (81).

8. A cutting mechanism for antistatic boots as claimed in claim 1, characterized in that: two limiting plates (12) clamped on the fabric (9) together are fixed on the workbench (11), and the arrangement direction of the two limiting plates (12) is the same as the width direction of the fabric (9).

9. A cutting process of a cutting mechanism according to any one of claims 1 to 8, characterized in that: the method comprises the following steps:

s1, placing the fabric (9) on the workbench (11), wherein the spring (53) is used for urging the pressing plate (52) to press the fabric (9) on the workbench (11);

s2, piercing the fabric (9) through the tip (451) of the piercing rod (45), enabling the piercing rod (45) to penetrate through the fabric (9), and tying the piercing rod (45) to the pull rope (44);

s3, the winding roller (42) is driven to rotate by the driving motor (43), the rotary drum (21) is driven to rotate in the same direction by the driving piece, the fabric (9) is pulled by the pull rope (44) and is adhered to the adhesive layer (22) on the upper side of the rotary drum (21), and at the moment, the upper side of the rotary drum (21) is parallel to the horizontal plane;

s4, the mounting plates (32) are driven to descend through the first hydraulic cylinders (31), so that the fabric (9) is cut by all the cutting dies (33) at the same time, a plurality of vamp surfaces (91) are cut by the fabric (9), then the mounting plates (32) are driven to ascend by the first hydraulic cylinders (31), and the fabric (9) and the vamp surfaces (91) are still adhered to the adhering layer (22);

s5, the winding roller (42) is driven to rotate through the driving motor (43), the rotary drum (21) is driven to rotate in the same direction through the driving piece, the cut fabric (9) is separated from the pasting layer (22) and wound on the winding roller (42), the fabric (9) which is not cut is pasted on the other surface of the rotary drum (21), the surface of the rotary drum (21) is parallel to the horizontal plane, and then the first hydraulic cylinder (31) drives the mounting plate (32) to descend, so that the cutting die (33) continues to cut the fabric (9);

s6, when the surface of the rotary drum (21) only adhered with the shoe surface (91) rotates to correspond to the material collecting box (61), the lifting piece drives the lifting plate (71) to descend, and the ejector rod (74) penetrates through the through hole (211) and ejects the shoe surface (91) into the material collecting box (61).