CN112107080B - Cutting mechanism and process for anti-corrosion high-temperature-resistant safety shoes - Google Patents

Abstract

The application relates to the technical field of shoe processing, in particular to a cutting mechanism for corrosion-resistant and high-temperature-resistant safety shoes and a process thereof, wherein the cutting mechanism comprises a conveyor belt, a cutting assembly, a limiting assembly and a collecting assembly, the cutting assembly comprises a rack and a mounting plate, a lifting piece is arranged on the rack, a plurality of cutting dies are fixed on the mounting plate, and a pressing plate and an elastic piece are arranged on the inner side of each cutting die; the limiting assembly comprises an arc-shaped plate and a limiting plate, the arc-shaped plate and the conveyor belt form an arc-shaped cavity in an enclosing mode, the limiting plate and the conveyor belt form a horizontal cavity in an enclosing mode, and a plurality of notches are formed in the lower surface of the limiting plate and communicated with the horizontal cavity. In the processing process of the fabric, the fabric is conveyed to the lower part of the cutting die through the conveying belt, the lifting piece drives the mounting plate to descend, so that a plurality of insoles are formed at the same time, and the pressing plate presses the insoles, so that the insoles are not easy to clamp on the inner side of the cutting die; then the conveyer belt carries surface fabric and shoe-pad to breach department, and the workman can pick the shoe-pad from the surface fabric this moment. This application improves the machining efficiency of surface fabric.

Description

Cutting mechanism and process for anti-corrosion high-temperature-resistant safety shoes

Technical Field

The application relates to the technical field of shoe processing, in particular to a cutting mechanism for an anti-corrosion high-temperature-resistant safety shoe and a process thereof.

Background

Workers working in the chemical industry, the metallurgical industry or other high-temperature industries often have the trouble of scalding feet on the ground. Therefore, the sole of the existing shoe is usually adhered with an anti-corrosion rubber layer for preventing the sole from being corroded; the bottom of the anti-corrosion rubber layer is usually pasted with a high-temperature-resistant ceramic layer for preventing feet from being scalded at high temperature, so that the safety of workers is effectively protected. Meanwhile, in order to ensure the comfort of the user wearing the shoe, the inner side of the shoe is usually sewed with an insole, and the insole is usually formed by cutting the fabric by a cutting machine.

As shown in fig. 1, the current cutting machine includes a frame 41, a table 47 and two hydraulic cylinders 42 located above the table 47 are installed on the frame 41, a piston rod of the hydraulic cylinder 42 extends in a vertical direction and is fixed with a mounting plate 43, a fabric 9 is placed on the table 47, and a cutting die 44 is placed on the fabric 9. In the cutting process of the fabric 9, the hydraulic cylinder 42 drives the mounting plate 43 to press the cutting die 44 downwards, so that the cutting die 44 cuts the insole 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 since the worker continuously adjusts the position of the cutter die 44 to cut out the shoe pads 91 on the fabric 9 and collect the shoe pads one by one, and thus improvement is required.

Disclosure of Invention

In order to improve the processing efficiency of the fabric, the application provides a cutting mechanism for an anti-corrosion high-temperature-resistant safety shoe and a process thereof.

First aspect, the application provides a cut mechanism for anticorrosive high temperature resistant safety shoes adopts following technical scheme: a cutting mechanism for anti-corrosion high-temperature-resistant safety shoes comprises a conveyor belt for conveying fabric, a cutting assembly for cutting the fabric, a limiting assembly for enabling the fabric to be attached to the conveyor belt and a collecting assembly for collecting insoles, wherein the cutting assembly comprises a rack and a mounting plate, a lifting piece for driving the mounting plate to lift is arranged on the rack, a plurality of cutting dies which are sequentially arranged along the width direction of the fabric are fixed on the mounting plate, a pressing plate and an elastic piece for enabling the pressing plate to be tightly pressed on the fabric are arranged on the inner side of each cutting die, and the lower surface of the pressing plate is lower than the lower end of each cutting die; spacing subassembly is including the arc that is located conveyer belt output end department and the limiting plate that is located the conveyer belt downside, and the arc has enclosed the arc chamber that supplies the surface fabric on the conveyer belt to get into with the conveyer belt, and the limiting plate has enclosed the horizontal cavity that supplies the surface fabric of arc intracavity to get into with the conveyer belt, and the lower surface of limiting plate is equipped with a plurality of breachs that fall into to the collection subassembly along surface fabric width direction arrange in proper order and supply the shoe-pad that corresponds, and the breach communicates in the horizontal cavity.

By adopting the technical scheme, in the processing process of the fabric, the fabric is firstly conveyed to the lower part of the cutting die through the conveyor belt, the lifting piece drives the mounting plate to descend, the pressing plate firstly props against the fabric, the elastic piece deforms and enables the pressing plate to be tightly pressed on the fabric, and the stability of the fabric in the subsequent cutting process is improved; then all the cutting dies cut the fabric at the same time, so that a plurality of insoles are formed at the same time, and the processing efficiency of the fabric is improved; then the lifting piece drives the mounting plate to rise, the cutting die is separated from the fabric firstly, the elastic piece gradually returns to a natural state and prompts the pressing plate to be separated from the fabric, and the insole is not easy to be clamped on the inner side of the cutting die.

Then the conveying belt conveys the fabric and the insoles, so that the cutting die can continuously cut the fabric; in the transportation process of surface fabric, surface fabric and shoe-pad will enter into the horizontal intracavity through the arc chamber to move to breach department in the horizontal intracavity, the workman can scratch the shoe-pad from the surface fabric this moment and put into in the collection subassembly, has realized the collection of shoe-pad, and the surface fabric will follow-up transportation process will fall out from the horizontal intracavity. To sum up, this application has realized the shaping when a plurality of insoles, and at the cutting in-process of surface fabric, the workman can separate surface fabric and insole to improve the machining efficiency of surface fabric.

Preferably, still include the unloading subassembly, the unloading subassembly includes mounting bracket and the driving piece that drives the mounting bracket and go up and down, installs the installation pole on the mounting bracket, is fixed with a plurality of montants of arranging in proper order along surface fabric width direction on the installation pole, is fixed with the flitch down corresponding to the breach on the montant, is fixed with a plurality of sticking strips that are used for pasting the shoe-pad on the flitch down.

Through adopting above-mentioned technical scheme, when surface fabric and shoe-pad pass through arc chamber and horizontal cavity and move to the breach department, the driving piece will drive the mounting bracket and rise for paste the strip on the lower flitch and paste the shoe-pad, then the driving piece will drive the mounting bracket and descend, make shoe-pad and surface fabric separation, the workman tears the shoe-pad from pasting the strip this moment and can put into the shoe-pad to the collection subassembly in, and need not the workman and scratch the shoe-pad from the surface fabric, the collection of the shoe-pad of being convenient for.

Preferably, a speed reduction motor is fixed on the mounting frame, an output shaft of the speed reduction motor extends along the width direction of the fabric and is fixedly connected to the mounting rod, and the mounting rod is rotatably connected to the mounting frame.

By adopting the technical scheme, after the insole is adhered by the adhering strips on the lower material plate, the speed reducing motor drives the mounting rod to rotate so that the insole is arranged downwards, and the driving piece drives the mounting frame to descend so that the insole moves to the collection assembly; when the worker tears the insole off the adhesive strip, the insole falls into the collection assembly.

Preferably, the collection assembly comprises a plurality of collection boxes which are sequentially arranged along the width direction of the fabric, the openings of the collection boxes face upwards and correspond to the notches, and the insoles are embedded in the collection boxes in a sliding manner.

Through adopting above-mentioned technical scheme, when the driving piece drives the mounting bracket decline and makes the shoe-pad move to collecting box department, the workman can tear the shoe-pad from pasting the strip and put into the corresponding collection box with the shoe-pad in, realized the neat collection of shoe-pad.

Preferably, a baffle plate for the insoles to rise and abut against is fixed on the inner wall of the collection box so as to enable the insoles to be separated from the adhesive strips, and the material discharging plate penetrates through the space between the baffle plate and the inner wall of the collection box.

By adopting the technical scheme, when the driving piece drives the mounting frame to descend so that the insoles move to the collection box, the driving piece continues to drive the mounting frame to descend, so that the blanking plate and the insoles enter the collection box and penetrate through the baffle and the inner wall of the collection box; drive the mounting bracket through driving afterwards and rise, the baffle will be contradicted and make the shoe-pad break away from pasting the strip in the upper surface of shoe-pad, and the lower flitch resets the motion, and the shoe-pad will fall into to collection box bottom, need not the workman and tears the shoe-pad from pasting the strip, the neat collection of the shoe-pad of being convenient for.

Preferably, the input end department of conveyer belt is equipped with the subassembly of prepareeing material, and the subassembly of prepareeing material includes the material preparing frame, and the lateral part of material preparing frame is equipped with a plurality of grafting chambeies that supply the surface fabric to insert and arrange along surface fabric direction of delivery in proper order, and the length direction of the surface fabric that is located the grafting intracavity is the same with vertical direction.

By adopting the technical scheme, workers can insert the fabric into the inserting cavity for material preparation, so that the use is convenient; because the length direction of the fabric in the inserting cavity is the same as the vertical direction, the horizontal occupied area of the material preparing rack and the fabric is reduced.

Preferably, the downside interval of preparing the work or material rest is provided with the brace table, and the lower extreme of preparing the work or material rest is equipped with a plurality of intercommunications and wears to establish the chamber in corresponding grafting chamber, and the surface fabric that is located the grafting intracavity wears to locate to wear to establish the chamber and contradicts in the upper surface of brace table.

Through adopting above-mentioned technical scheme, when needs use the surface fabric, the workman is handed the surface fabric and is contradicted in the one end of brace table, can with the surface fabric pulling of grafting intracavity to the conveyer belt on, make things convenient for the material loading of surface fabric.

Preferably, still including drawing the material subassembly, draw the material subassembly to include two sharp modules that extend along surface fabric direction of delivery, the surface fabric is located between two sharp modules, all installs the slide on two sharp modules, is equipped with the rotor plate on the slide and promotes the impeller of rotor plate along surface fabric width direction motion, is equipped with fixed plate, briquetting on the rotor plate and drives the briquetting and compress tightly the compressing tightly piece on the fixed plate with the surface fabric, and the fixed plate is fixed on the rotor plate.

Through adopting above-mentioned technical scheme, when needs use the surface fabric, the impeller will promote the rotor plate motion and make the surface fabric be located between fixed plate and the briquetting, and the piece that compresses tightly will make the briquetting compress tightly the surface fabric on the fixed plate, then sharp module will drive the slide motion for the surface fabric material loading has realized the automatic feeding of surface fabric to the conveyer belt, has improved the machining efficiency of surface fabric.

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

s1, inserting the fabric into the splicing cavity to prepare the material, pushing the rotating plate to move through the pushing piece to enable the fabric to be located between the fixed plate and the pressing block, enabling the pressing block to press the fabric on the fixed plate through the pressing piece, and driving the sliding plate to move through the linear module to enable the fabric to be loaded onto the conveying belt;

s2, conveying the fabric to the lower part of the cutting die through the conveyor belt, driving the mounting plate to descend by the lifting piece, enabling the elastic piece to deform and enable the pressing plate to be pressed tightly on the fabric, and cutting the fabric by all the cutting dies simultaneously to enable a plurality of insoles to be formed simultaneously;

s3, the mounting plate is driven to ascend through the lifting piece, the cutting die is separated from the fabric firstly, the pressing plate is separated from the fabric, the fabric and the insoles are conveyed by the conveyor belt, and the cutting die can continue to cut the fabric;

s4, when surface fabric and shoe-pad passed through arc chamber and horizontal cavity motion to the breach department, it rises to drive the mounting bracket to drive the driving piece, make the strip of pasting on the lower flitch paste the shoe-pad, then gear motor drives the installation pole rotation and makes the shoe-pad set up down, driving piece drives the mounting bracket decline and makes lower flitch and shoe-pad get into in the collection box, it rises to drive the mounting bracket through the driving piece afterwards, the baffle will be contradicted and make the shoe-pad break away from pasting the strip in the upper surface of shoe-pad, the lower flitch resets the motion, the shoe-pad will fall into to the collection box.

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

1. due to the arrangement of the conveying belt, the cutting assembly and the limiting assembly, a plurality of insoles can be formed simultaneously, and a worker can separate the fabric from the insoles in the fabric cutting process, so that the fabric processing efficiency is improved;

2. the arrangement of the blanking assembly and the collecting assembly enables the insoles on the fabric to fall into the corresponding collecting boxes one by one, so that the automatic collection of the insoles is realized;

3. the material preparing component and the material pulling component are arranged, so that the fabric in the material preparing cavity can be automatically fed onto the conveying belt, and the processing efficiency of the fabric is improved.

Drawings

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

FIG. 2 is a schematic diagram of the overall structure in the embodiment of the present application;

FIG. 3 is a schematic structural diagram showing a material preparation assembly and a material pulling assembly in an embodiment of the present application;

FIG. 4 is a schematic structural diagram showing a conveyor belt and a pulling assembly in an embodiment of the present application;

FIG. 5 is a schematic diagram showing the construction of a cutting assembly in an embodiment of the present application;

FIG. 6 is a schematic diagram showing the construction of a cutting assembly and a stop assembly in an embodiment of the present application;

FIG. 7 is a schematic structural diagram showing a limiting assembly, a blanking assembly and a collecting assembly in the embodiment of the application;

FIG. 8 is a schematic structural diagram showing a blanking assembly and a collection assembly in the embodiment of the present application;

FIG. 9 is a schematic diagram showing the structure of a conveyor belt and a waste bin in the embodiment of the present application.

Reference numerals: 1. preparing a material component; 11. preparing a material rack; 111. an insertion cavity; 112. the cavity is penetrated; 12. a support table; 2. a conveyor belt; 21. a support; 22. a rotating roller; 23. a belt; 24. a drive motor; 25. a rubber pad; 3. pulling the material assembly; 31. a linear module; 32. a slide plate; 33. a first electric cylinder; 34. a vertical plate; 35. rotating the motor; 36. a rotating plate; 37. a fixing plate; 38. a second electric cylinder; 39. briquetting; 4. cutting the assembly; 41. a frame; 42. a hydraulic cylinder; 43. mounting a plate; 44. cutting the die; 45. pressing a plate; 46. a spring; 47. a work table; 5. a limiting component; 51. an arc-shaped plate; 52. a limiting plate; 53. an arcuate cavity; 54. an inclined plate; 55. a horizontal cavity; 56. a notch; 6. a blanking assembly; 61. a mounting frame; 62. a third electric cylinder; 63. mounting a rod; 64. a vertical rod; 65. a blanking plate; 66. a bonding strip; 67. a reduction motor; 7. a collection assembly; 71. a collection box; 711. a through groove; 72. a baffle plate; 8. a waste bin; 9. fabric; 91. an insole.

Detailed Description

The present application is described in further detail below with reference to figures 2-9.

The embodiment of the application discloses a cut mechanism for anticorrosive high temperature resistant safety shoes. As shown in fig. 2, a cutting mechanism for corrosion-resistant and high-temperature-resistant safety shoes comprises a material preparation assembly 1 for preparing a material for a fabric 9, a conveying belt 2 for conveying the fabric 9, a material pulling assembly 3 for feeding the fabric 9 on the material preparation assembly 1 onto the conveying belt 2, a cutting assembly 4 for cutting the fabric 9, a limiting assembly 5 for enabling the fabric 9 and an insole 91 to be attached to the conveying belt 2, a collecting assembly 7 for collecting the insole 91, and a discharging assembly 6 for discharging the insole 91 on the limiting assembly 5 into the collecting assembly 7.

As shown in fig. 2 and 3, the material preparation assembly 1 is located at the input end of the conveyor belt 2, the material preparation assembly 1 includes a material preparation frame 11 and a support table 12 located below the material preparation frame 11, a plurality of insertion cavities 111 sequentially arranged along the conveying direction of the fabric 9 are arranged at the side of the material preparation frame 11, and the fabric 9 is inserted into the insertion cavities 111 from the side of the material preparation frame 11 to prepare materials; the length direction of the fabric 9 in the inserting cavity 111 is the same as the vertical direction, so that the horizontal floor area of the material preparing rack 11 and the fabric 9 is reduced. The lower end of the material preparing frame 11 is provided with a plurality of penetrating cavities 112 which are communicated with the corresponding inserting cavities 111, and the fabric 9 positioned in the inserting cavities 111 penetrates through the penetrating cavities 112 and abuts against the upper surface of the supporting table 12.

As shown in fig. 3 and 4, the drawing assembly 3 includes two linear modules 31 extending along the conveying direction of the fabric 9, and the fabric 9 is located between the two linear modules 31; sliding plates 32 are mounted on the two linear modules 31, a first electric cylinder 33 is fixed on each sliding plate 32, and a piston rod of each first electric cylinder 33 extends along the width direction of the fabric 9 and is fixed with a vertical plate 34; a rotating motor 35 is fixed on the vertical plate 34, an output shaft of the rotating motor 35 extends along the width direction of the fabric 9 and is fixed with a rotating plate 36, a fixed plate 37 and a pressing piece are fixed on the rotating plate 36, the pressing piece is a second electric cylinder 38, and a piston rod of the second electric cylinder 38 extends along the conveying direction of the fabric 9 and is fixed with a pressing block 39.

In the feeding process of the fabric 9, the linear module 31 drives the sliding plate 32 to move to the fabric 9 closest to the conveyor belt 2; the first electric cylinder 33 pushes the vertical plate 34 to move towards the fabric 9, so that the fabric 9 is positioned between the fixed plate 37 and the pressing block 39; the second electric cylinder 38 drives the pressing block 39 to press the fabric 9 on the fixed plate 37, and then the rotating motor 35 drives the rotating plate 36 to rotate, so that the part of the fabric 9 clamped by the fixed plate 37 and the pressing block 39 is in a horizontal state; then the linear module 31 drives the sliding plate 32 to move towards the conveyor belt 2, so that the fabric 9 in the inserting cavity 111 is fed onto the conveyor belt 2; subsequently, the second electric cylinder 38 drives the pressing block 39 to be far away from the fixing plate 37, and the first electric cylinder 33 drives the vertical plate 34 to be far away from the fabric 9, so that the fabric 9 is placed on the conveyor belt 2, automatic feeding of the fabric 9 is realized, and the processing efficiency of the fabric 9 is improved.

As shown in fig. 4 and 6, the conveyor belt 2 includes a support 21, two rotating rollers 22 rotatably connected to the support 21, a belt 23 wound around the two rotating rollers 22, and a driving motor 24 fixed to the support 21, and an output shaft of the driving motor 24 extends in the width direction of the fabric 9 and is fixedly connected to one of the rotating rollers 22. When the driving motor 24 is started, the rotating roller 22 drives the belt 23 to move, and the belt 23 conveys the fabric 9 to the cutting assembly 4.

As shown in fig. 5 and 6, the cutting assembly 4 includes a frame 41 and a mounting plate 43, two lifting members are fixed on the frame 41, the lifting members are hydraulic cylinders 42, and piston rods of the hydraulic cylinders 42 extend in a vertical direction and are fixedly connected to the mounting plate 43; a plurality of cutting dies 44 which are sequentially arranged along the width direction of the fabric 9 are fixed on the lower surface of the mounting plate 43, a pressing plate 45 and an elastic piece are arranged on the inner side of each cutting die 44, and the lower surface of the pressing plate 45 is lower than the lower end of the cutting die 44; the elastic member is a spring 46, one end of the spring 46 is fixedly connected to the lower surface of the mounting plate 43, and the other end of the spring 46 is fixedly connected to the upper surface of the pressing plate 45.

In the cutting process of the fabric 9, the hydraulic cylinder 42 drives the mounting plate 43 to descend, the pressing plate 45 firstly props against the fabric 9, the spring 46 deforms and urges the pressing plate 45 to tightly press the fabric 9, and the stability of the fabric 9 in the subsequent cutting process is improved; then all the cutting dies 44 cut the fabric 9 at the same time, so that a plurality of insoles 91 are formed at the same time, and the processing efficiency of the fabric 9 is improved; then the hydraulic cylinder 42 will drive the mounting plate 43 to rise, the cutting die 44 is separated from the fabric 9 first, the spring 46 will gradually return to the natural state and urge the pressing plate 45 to be separated from the fabric 9, so that the insole 91 is not easy to be clamped inside the cutting die 44.

As shown in fig. 6, a plurality of rubber pads 25 annularly arranged around the belt 23 are fixed on the outer side of the belt 23, and the rubber pads 25 not only enable the cutting die 44 to completely cut the fabric 9, but also enable the cutting die 44 not to damage the belt 23.

As shown in fig. 6, the limiting assembly 5 includes an arc-shaped plate 51 at the output end of the conveyor belt 2, an inclined plate 54 arranged on the arc-shaped plate 51, and a limiting plate 52 arranged at the lower side of the conveyor belt 2, the arc-shaped plate 51 is fixedly connected to the limiting plate 52, the arc-shaped plate 51 and the conveyor belt 2 enclose an arc-shaped cavity 53, and the conveyor belt 2 conveys the cut fabric 9 and the insoles 91 into the arc-shaped cavity 53; the lower end of the inclined plate 54 is fixedly connected to the arc-shaped plate 51, and the inclined plate 54 presses the tilted fabric 9 and the insole 91 flat, so that the fabric 9 and the insole 91 enter the arc-shaped cavity 53.

As shown in fig. 6 and 7, the limiting plate 52 is fixed on the bracket 21, the limiting plate 52 and the conveyor belt 2 enclose a horizontal cavity 55, the horizontal cavity 55 is communicated with the arc-shaped cavity 53, and the conveyor belt 2 conveys the fabric 9 and the insoles 91 in the arc-shaped cavity 53 into the horizontal cavity 55. The lower surface of the limiting plate 52 is provided with a plurality of notches 56 which are sequentially arranged along the width direction of the fabric 9, and the notches 56 are communicated with the horizontal cavity 55.

As shown in fig. 7 and 8, the blanking assembly 6 includes a mounting frame 61 and two driving members, the driving member is a third electric cylinder 62, and a piston rod of the third electric cylinder 62 extends in a vertical direction and is fixedly connected to the mounting frame 61; the mounting frame 61 is rotatably connected with a mounting rod 63, a plurality of vertical rods 64 which are sequentially arranged along the width direction of the fabric 9 are fixed on the mounting rod 63, a blanking plate 65 corresponding to the gap 56 is fixed on the vertical rods 64, and a plurality of adhesive strips 66 are fixed on the blanking plate 65; a speed reducing motor 67 is also fixed on the mounting frame 61, and an output shaft of the speed reducing motor 67 extends along the width direction of the fabric 9 and is fixedly connected to the mounting rod 63.

When the fabric 9 and the insole 91 move to the gap 56, the third electric cylinder 62 drives the mounting frame 61 to ascend, so that the adhesive strips 66 on the blanking plate 65 adhere the insole 91; then the speed reducing motor 67 will drive the mounting rod 63 to rotate so that the insole 91 is placed downwards, and the third electric cylinder 62 will drive the mounting frame 61 to descend so that the insole 91 moves to the collecting assembly 7.

As shown in fig. 7 and 8, the collecting assembly 7 includes a plurality of collecting boxes 71 sequentially arranged along the width direction of the fabric 9, the openings of the collecting boxes 71 are upward and correspond to the notches 56, and baffles 72 are fixed on the inner walls of two opposite sides of the collecting boxes 71. When the insole 91 moves to the collection box 71, the third electric cylinder 62 continues to drive the mounting frame 61 to descend, so that the material dropping plate 65 and the insole 91 enter the collection box 71 and pass through between the two baffle plates 72; then, the third electric cylinder 62 drives the mounting frame 61 to rise, the lower surface of the baffle plate 72 abuts against the upper surface of the insole 91, so that the insole 91 is separated from the adhesive strip 66, the material discharging plate 65 resets the movement, and the insole 91 falls into the bottom of the collecting box 71, thereby facilitating the tidy collection of the insole 91.

As shown in fig. 8, through grooves 711 are formed in the inner walls of the opposite sides of the collection box 71, the through grooves 711 penetrate the upper end of the collection box 71, and the worker can take out the insoles 91 in the collection box 71 conveniently through the through grooves 711.

As shown in fig. 9, when the insole 91 is separated from the fabric 9, the conveyor belt 2 will continue to convey the fabric 9, and the fabric 9 will slide out of the horizontal cavity 55. At the input end of the conveyor belt 2 there is a waste bin 8 for collecting the fabric 9 that has slipped out of the horizontal chamber 55.

The embodiment of the application relates to a cutting mechanism for anti-corrosion high-temperature-resistant safety shoes and an implementation principle of the technology thereof, wherein the cutting mechanism comprises: in the processing process of the fabric 9, the fabric 9 is firstly inserted into the insertion cavity 111 for material preparation, and the fabric 9 in the insertion cavity 111 penetrates through the penetrating cavity 112 and abuts against the upper surface of the support table 12.

Then the linear module 31 drives the sliding plate 32 to move to the position, closest to the fabric 9 of the conveyor belt 2, of the fabric 9, and the first electric cylinder 33 pushes the vertical plate 34 to move towards the fabric 9, so that the fabric 9 is located between the fixed plate 37 and the pressing block 39; the second electric cylinder 38 drives the pressing block 39 to press the fabric 9 on the fixed plate 37, and the rotating motor 35 drives the rotating plate 36 to rotate, so that the part of the fabric 9 clamped by the fixed plate 37 and the pressing block 39 is in a horizontal state; the linear module 31 drives the sliding plate 32 to move towards the conveyor belt 2, so that the fabric 9 in the insertion cavity 111 is fed onto the conveyor belt 2; the second electric cylinder 38 drives the pressing block 39 to be far away from the fixing plate 37, and the first electric cylinder 33 drives the vertical plate 34 to be far away from the fabric 9, so that the fabric 9 is placed on the conveyor belt 2, and automatic feeding of the fabric 9 is realized.

Then the driving motor 24 is started, the rotating roller 22 drives the belt 23 to move, and the belt 23 conveys the fabric 9 to the cutting assembly 4; the hydraulic cylinder 42 drives the mounting plate 43 to descend, the pressing plate 45 firstly props against the fabric 9, and the spring 46 deforms and urges the pressing plate 45 to tightly press against the fabric 9; all the cutting dies 44 will cut the fabric 9 at the same time, so that a plurality of insoles 91 are formed at the same time; the hydraulic cylinder 42 drives the mounting plate 43 to rise, the cutting die 44 is separated from the fabric 9 firstly, the spring 46 gradually returns to the natural state and urges the pressing plate 45 to be separated from the fabric 9, so that the insole 91 is not easy to be clamped on the inner side of the cutting die 44.

The conveyor belt 2 will then convey the fabric 9 and the insoles 91 into the arc-shaped chamber 53, and the fabric 9 and the insoles 91 will enter the horizontal chamber 55 through the arc-shaped chamber 53. When the fabric 9 and the insole 91 move to the gap 56, the third electric cylinder 62 drives the mounting frame 61 to ascend, so that the adhesive strips 66 on the blanking plate 65 adhere the insole 91; the speed reducing motor 67 drives the mounting rod 63 to rotate so that the insole 91 is arranged downwards, and the third electric cylinder 62 drives the mounting frame 61 to descend so that the material discharging plate 65 and the insole 91 enter the collecting box 71 and penetrate between the two baffle plates 72.

Then, the third electric cylinder 62 drives the mounting frame 61 to rise, the lower surface of the baffle plate 72 abuts against the upper surface of the insole 91, so that the insole 91 is separated from the adhesive strip 66, the material discharging plate 65 resets the movement, the insole 91 falls into the bottom of the collection box 71, and the insole 91 is conveniently and orderly collected; the cut fabric 9 is conveyed by the conveyor belt 2 to a waste bin 8 for collection.

To sum up, this application has realized the simultaneous molding of the automatic feeding of surface fabric 9, a plurality of shoe-pads 91, the separation of shoe-pads 91 and surface fabric 9, the automatic collection of shoe-pads 91, the automatic collection of surface fabric 9 to the machining efficiency of surface fabric 9 has been improved.

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

s1, inserting the fabric 9 into the inserting cavity 111 for material preparation, so that the fabric 9 in the inserting cavity 111 penetrates through the penetrating cavity 112 and abuts against the upper surface of the support table 12;

s2, the sliding plate 32 is driven to move to the position, closest to the fabric 9 of the conveyor belt 2, of the fabric 9 through the linear module 31, and the first electric cylinder 33 pushes the vertical plate 34 to move towards the fabric 9, so that the fabric 9 is located between the fixed plate 37 and the pressing block 39; the second electric cylinder 38 drives the pressing block 39 to press the fabric 9 on the fixed plate 37, and the rotating motor 35 drives the rotating plate 36 to rotate, so that the part of the fabric 9 clamped by the fixed plate 37 and the pressing block 39 is in a horizontal state; the linear module 31 drives the sliding plate 32 to move towards the conveyor belt 2, so that the fabric 9 in the insertion cavity 111 is fed onto the conveyor belt 2; the second electric cylinder 38 drives the pressing block 39 to be far away from the fixed plate 37, and the first electric cylinder 33 drives the vertical plate 34 to be far away from the fabric 9, so that the fabric 9 is placed on the conveyor belt 2;

s3, the rotating roller 22 is driven to rotate through the driving motor 24, the rotating roller 22 drives the belt 23 to move, and the belt 23 conveys the fabric 9 to the cutting assembly 4;

s4, the mounting plate 43 is driven to descend through the hydraulic cylinder 42, the pressing plate 45 firstly props against the fabric 9, and the spring 46 deforms and enables the pressing plate 45 to be pressed against the fabric 9; all the cutting dies 44 will cut the fabric 9 at the same time, so that a plurality of insoles 91 are formed at the same time; then the hydraulic cylinder 42 drives the mounting plate 43 to rise, the cutting die 44 is separated from the fabric 9 firstly, and the spring 46 gradually returns to the natural state and urges the pressing plate 45 to be separated from the fabric 9;

s5, conveying the fabric 9 and the insoles 91 into the arc-shaped cavities 53 through the conveyor belt 2, and moving the fabric 9 and the insoles 91 to the notches 56 through the arc-shaped cavities 53 and the horizontal cavities 55;

s6, the third electric cylinder 62 drives the mounting frame 61 to ascend, so that the sticking strips 66 on the blanking plate 65 stick the insoles 91, the speed reducing motor 67 drives the mounting rod 63 to rotate, so that the insoles 91 are arranged downwards, and the third electric cylinder 62 drives the mounting frame 61 to descend, so that the blanking plate 65 and the insoles 91 enter the collection box 71 and penetrate between the two baffle plates 72; the third electric cylinder 62 drives the mounting frame 61 to rise, the lower surface of the baffle plate 72 abuts against the upper surface of the insole 91, so that the insole 91 is separated from the adhesive strip 66, the material discharging plate 65 resets the movement, and the insole 91 falls into the bottom of the collecting box 71.

S7, the cut fabric 9 is conveyed further by the conveyor belt 2, so that the fabric 9 is separated from the horizontal cavity 55 and falls into the waste bin 8 for collection.

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 (9)

1. The utility model provides a cut mechanism for anticorrosive high temperature resistant safety shoes which characterized in that: the shoe sole cutting machine comprises a conveying belt (2) used for conveying fabric (9), a cutting assembly (4) used for cutting the fabric (9), a limiting assembly (5) used for enabling the fabric (9) to be attached to the conveying belt (2) and a collecting assembly (7) used for collecting insoles (91), wherein the cutting assembly (4) comprises a rack (41) and a mounting plate (43), a lifting piece used for driving the mounting plate (43) to lift is arranged on the rack (41), a plurality of cutting dies (44) which are sequentially arranged along the width direction of the fabric (9) are fixed on the mounting plate (43), a pressing plate (45) and an elastic piece used for enabling the pressing plate (45) to be tightly pressed on the fabric (9) are arranged on the inner side of each cutting die (44), and the lower surface of the pressing plate (45) is lower than the lower end of the cutting die (44); spacing subassembly (5) including arc (51) that are located conveyer belt (2) output end department and limiting plate (52) that are located conveyer belt (2) downside, arc (51) and conveyer belt (2) have been enclosed into arc chamber (53) that supplies surface fabric (9) on conveyer belt (2) to get into, limiting plate (52) and conveyer belt (2) have been enclosed into horizontal chamber (55) that supplies surface fabric (9) in arc chamber (53) to get into, the lower surface of limiting plate (52) is equipped with a plurality of and arranges in proper order and supplies corresponding shoe-pad (91) to fall into breach (56) in collection subassembly (7) along surface fabric (9) width direction, breach (56) communicate in horizontal chamber (55).

2. The cutting mechanism for the corrosion-resistant and high-temperature-resistant safety shoes according to claim 1, characterized in that: still include unloading subassembly (6), unloading subassembly (6) include mounting bracket (61) and the driving piece that drives mounting bracket (61) and go up and down, install installation pole (63) on mounting bracket (61), be fixed with a plurality of montants (64) of arranging in proper order along surface fabric (9) width direction on installation pole (63), be fixed with flitch (65) down corresponding to breach (56) on montant (64), be fixed with a plurality of paste strip (66) that are used for pasting shoe-pad (91) on flitch (65) down.

3. The cutting mechanism for the corrosion-resistant and high-temperature-resistant safety shoes as claimed in claim 2, is characterized in that: be fixed with gear motor (67) on mounting bracket (61), gear motor (67)'s output shaft extends and fixed connection in installation pole (63) along the width direction of surface fabric (9), and installation pole (63) rotate to be connected in mounting bracket (61).

4. The cutting mechanism for the corrosion-resistant and high-temperature-resistant safety shoes according to claim 3, characterized in that: the collecting assembly (7) comprises a plurality of collecting boxes (71) which are sequentially arranged along the width direction of the fabric (9), the openings of the collecting boxes (71) face upwards and correspond to the notches (56), and the insoles (91) are embedded in the collecting boxes (71) in a sliding manner.

5. The cutting mechanism for the corrosion-resistant and high-temperature-resistant safety shoes according to claim 4, is characterized in that: the inner wall of the collecting box (71) is fixed with a baffle (72) which is used for the insole (91) to rise and abut against so as to promote the insole (91) to be separated from the sticking strip (66), and the blanking plate (65) passes through the space between the baffle (72) and the inner wall of the collecting box (71).

6. The cutting mechanism for the corrosion-resistant and high-temperature-resistant safety shoes according to claim 5, characterized in that: the feed preparation device is characterized in that a feed preparation assembly (1) is arranged at the input end of the conveying belt (2), the feed preparation assembly (1) comprises a feed preparation frame (11), a plurality of insertion cavities (111) for inserting the fabrics (9) and sequentially arranging the fabrics (9) along the conveying direction of the fabrics (9) are arranged on the lateral part of the feed preparation frame (11), and the length direction of the fabrics (9) in the insertion cavities (111) is the same as the vertical direction.

7. The cutting mechanism for the corrosion-resistant and high-temperature-resistant safety shoes according to claim 6, is characterized in that: support tables (12) are arranged on the lower side of the material preparing frame (11) at intervals, a plurality of penetrating cavities (112) communicated with the corresponding inserting cavities (111) are formed in the lower end of the material preparing frame (11), and fabrics (9) located in the inserting cavities (111) penetrate through the penetrating cavities (112) and abut against the upper surface of the support tables (12).

8. The cutting mechanism for the corrosion-resistant and high-temperature-resistant safety shoes according to claim 7, is characterized in that: still including drawing material subassembly (3), draw material subassembly (3) including two straight line modules (31) that extend along surface fabric (9) direction of delivery, surface fabric (9) are located between two straight line modules (31), all install slide (32) on two straight line modules (31), be equipped with rotor plate (36) on slide (32) and promote rotor plate (36) along the impeller of surface fabric (9) width direction motion, be equipped with fixed plate (37) on rotor plate (36), briquetting (39) and drive briquetting (39) compress tightly the piece that compresses tightly on fixed plate (37) surface fabric (9), fixed plate (37) are fixed on rotor plate (36).

9. The cutting process of a cutting mechanism according to claim 8, characterized in that: the method comprises the following steps:

s1, inserting the fabric (9) into the inserting cavity (111) for material preparation, pushing the rotating plate (36) to move through the pushing piece to enable the fabric (9) to be located between the fixing plate (37) and the pressing block (39), enabling the pressing block (39) to press the fabric (9) on the fixing plate (37) through the pressing piece, and then driving the sliding plate (32) to move through the linear module (31) to enable the fabric (9) to be fed onto the conveyor belt (2);

s2, conveying the fabric (9) to the lower side of the cutting die (44) through the conveyor belt (2), enabling the lifting piece to drive the mounting plate (43) to descend, enabling the elastic piece to deform and enabling the pressing plate (45) to be pressed tightly on the fabric (9), and then cutting the fabric (9) through all the cutting dies (44) simultaneously to enable a plurality of insoles (91) to be formed simultaneously;

s3, the mounting plate (43) is driven to ascend through the lifting piece, the cutting die (44) is separated from the fabric (9) firstly, the pressing plate (45) is separated from the fabric (9), and then the fabric (9) and the insoles (91) are conveyed by the conveyor belt (2), so that the cutting die (44) can continuously cut the fabric (9);

s4, when the fabric (9) and the insole (91) move to the notch (56) through the arc-shaped cavity (53) and the horizontal cavity (55), the driving piece drives the mounting frame (61) to ascend, so that the pasting strips (66) on the blanking plate (65) paste the insole (91), then the speed reducing motor (67) drives the mounting rod (63) to rotate to enable the insole (91) to be arranged downwards, the driving piece drives the mounting frame (61) to descend to enable the blanking plate (65) and the insole (91) to enter the collection box (71), then the driving piece drives the mounting frame (61) to ascend, the baffle (72) abuts against the upper surface of the insole (91) to enable the insole (91) to be separated from the pasting strips (66), the blanking plate (65) resets the movement, and the insole (91) falls into the bottom of the collection box (71).

Images