CN118107127A - Shoe processing mold device and use method thereof - Google Patents

Abstract

The invention relates to the technical field of shoe molds and discloses a shoe mold processing device and a use method thereof, which solve the problem that once the mold device fails, mold closing of an upper mold and a lower mold can cause injury to workers. According to the invention, the plurality of formed soles can be taken out simultaneously without manually demolding, so that the working efficiency is improved, meanwhile, a worker is not required to place hands between the lower die and the movable plate, the injury of the worker possibly caused by the failure of the die device is avoided, and the safety is improved.

Description

Shoe processing mold device and use method thereof

Technical Field

The invention belongs to the technical field of shoe molds, and particularly relates to a shoe processing mold device and a use method thereof.

Background

The sports shoes are shoes designed and manufactured according to the characteristics that people participate in sports or tourism, the sports shoes need to be processed through injection molds to rubber soles thereof in the production process, at present, the injection mold device for shoe processing is used, the molded soles which are molded by injection need to be manually demoulded, time and labor are wasted, the demoulding efficiency is reduced, hands of workers are positioned between an upper mold and a lower mold in the demoulding process, and once the mold device fails, the upper mold and the lower mold are closed to cause damage to the workers, so that certain limitations exist.

Disclosure of Invention

Aiming at the situation, in order to overcome the defects of the prior art, the invention aims to provide a shoe processing die device and a use method thereof, which effectively solve the problem that the upper die and the lower die are clamped to cause injury to staff once the die device fails in the prior art.

In order to achieve the above purpose, the present invention provides the following technical solutions: the utility model provides a shoe mold processing device, includes the base, the top of base is equipped with the roof, base and roof are connected through a plurality of spliced poles, be equipped with the annular box between base and the roof, annular box and roof are connected through a plurality of support columns, the below of roof is equipped with a plurality of bed dies, the below of bed die is equipped with two fly leaves, fixedly connected with a plurality of ejector rods with bed die matched with on the fly leaf, and the ejector rod runs through the bed die, bed die and fly leaf are connected through elastic reset piece, the top of annular box is equipped with the press ring with fly leaf matched with, the top of bed die is equipped with the cope mold, be equipped with on the roof respectively with press ring and a plurality of cope mold matched with different direction elevation structure;

a plurality of first rotating shafts are arranged in the annular box, a first supporting part which is rotationally connected is sleeved outside the first rotating shafts, the first supporting part is fixedly connected with the inner wall of the annular box, a stabilizing frame which is matched with the lower die is fixedly connected on the first rotating shafts, a plurality of first avoiding holes are arranged on the annular box, the stabilizing frame is matched with the first avoiding holes, a plurality of second rotating shafts are arranged in the annular box, the outside cover of second pivot is equipped with the second supporting part that rotates the connection, and the inner wall fixed connection of second supporting part and annular box, and second pivot and bed die pass through the connecting block and connect, have seted up a plurality of second on the annular box and dodge the hole, and the hole is dodged with the connecting block to the second cooperatees, is equipped with the meshing synchronous rotating assembly who is used for driving first pivot and second pivot rotation respectively on the clamping ring, is equipped with the collection mechanism who is used for collecting the shaping sole on the base.

Preferably, the meshing synchronous rotating assembly comprises a third rotating shaft arranged between the first rotating shaft and the second rotating shaft, a third supporting part connected in a rotating mode is sleeved outside the third rotating shaft, the third supporting part is fixedly connected with the inner wall of the annular box, the third rotating shaft is connected with the second rotating shaft through a damping synchronous piece, a first gear is fixedly connected to the third rotating shaft, a plurality of first toothed plates penetrate through the annular box, the first toothed plates are meshed with the first gear, the top ends of the first toothed plates are connected with the pressing ring through a first connecting plate, and the first rotating shaft is connected with the first gear through a meshing unit.

Preferably, the damping synchronous piece comprises a first damping disc fixedly installed on the third rotating shaft, a second damping disc is fixedly connected to the second rotating shaft, and the second damping disc is in contact with the first damping disc.

Preferably, the meshing unit comprises a second gear fixedly mounted at the top end of the first rotating shaft, a plurality of second toothed plates are arranged in the annular box and meshed with the first gear, third toothed plates meshed with the second gear are fixedly connected to the second toothed plates, a plurality of third avoidance holes are formed in the annular box, the second toothed plates and the third toothed plates penetrate through the corresponding third avoidance holes, and a guider matched with the third toothed plates is arranged on the annular box.

Preferably, the guide device comprises a supporting block fixedly mounted on the third toothed plate, a first guide column penetrates through the supporting block, one end of the first guide column is fixedly connected with the inner wall of the annular box, and the other end of the first guide column penetrates through the corresponding third avoidance hole.

Preferably, the anisotropic lifting structure is including setting up in lifting ring and the supporting disk of base top, and the supporting disk is located the below of lifting ring, and the spliced pole runs through the supporting disk, and spliced pole and supporting disk fixed connection, and lifting ring and supporting disk pass through a plurality of first hydraulic telescoping rods and connect, go up mould and lifting ring and pass through leg joint, the top fixedly connected with of press ring a plurality of second guide posts, and the second guide post runs through the roof, and the support is connected through the anisotropic driver with the press ring.

Preferably, the anisotropic driver comprises a fourth toothed plate fixedly mounted on the support, a plurality of second connecting plates are fixedly connected to the pressing ring, a fifth toothed plate is fixedly connected to the second connecting plates, a fourth rotating shaft is arranged between the fifth toothed plate and the fourth toothed plate, a supporting plate in rotating connection is sleeved outside the fourth rotating shaft, the supporting plate is fixedly connected with the bottom of the top plate, a third gear is fixedly sleeved outside the fourth rotating shaft, and the fifth toothed plate and the fourth toothed plate are meshed with the third gear respectively.

Preferably, the collecting mechanism comprises a lifting frame arranged between the base and the annular box, a collecting ring connected in a rotating manner is sleeved outside the lifting frame, and the lifting frame is connected with the base through a plurality of second hydraulic telescopic rods.

Preferably, the elastic resetting piece comprises two limiting blocks arranged at the bottom of the movable plate, the top of each limiting block is fixedly connected with a third guide post, each third guide post penetrates through the movable plate, the bottoms of the third guide posts and the lower die are fixedly connected, a compression spring is sleeved outside each third guide post, two ends of each compression spring are fixedly connected with the movable plate and the lower die respectively, and the movable plate is in contact with each limiting block.

The invention also provides a use method of the shoe processing mould device, which adopts the shoe processing mould device and comprises the following steps:

Step one: when the sole is molded by injection molding, the upper die is driven to move upwards through the anisotropic lifting structure so as to separate the upper die from the lower die, the pressing ring is driven to move downwards by the anisotropic lifting structure, the first rotating shaft is driven to rotate by the pressing ring through the meshing synchronous rotating assembly, and the steady frame is driven to rotate by the first rotating shaft;

Step two: when the stabilizing frame is not contacted with the bottom of the lower die any more, the pressing ring drives the second rotating shaft to rotate through the meshing synchronous rotating assembly, and when the second rotating shaft drives the lower die to rotate by one hundred eighty degrees through the connecting block, the top of the rotating connecting block is contacted with the inner wall of the second avoiding hole;

Step three: the pressing ring drives the first rotating shaft to continuously rotate through the meshed synchronous rotating assembly, so that the stabilizing frame moves to the bottom of the rotated lower die again, at the moment, the cavity opening of the lower die faces downwards, and the movable plate is positioned above the lower die;

Step four: the pressing ring is driven to continuously move downwards through the anisotropic lifting structure, and the movable plate is pressed by the pressing ring, so that the movable plate drives the ejector rod to eject the formed sole in the cavity of the lower die, and the ejected formed sole is collected through the collecting mechanism.

Compared with the prior art, the invention has the beneficial effects that:

When the formed sole is well injected, the pressing ring is driven to move downwards through the different-direction lifting structure, the pressing ring drives the first rotating shaft to rotate through the meshing synchronous rotating assembly, the first rotating shaft drives the stabilizing frame to rotate, when the stabilizing frame is not contacted with the bottom of the lower die any more, the pressing ring drives the second rotating shaft to rotate through the meshing synchronous rotating assembly, when the second rotating shaft drives the lower die to rotate by one hundred eighty degrees through the connecting block, the pressing ring drives the first rotating shaft to continuously rotate through the meshing synchronous rotating assembly, so that the stabilizing frame moves to the bottom of the rotated lower die again, the lower die is prevented from tilting, at the moment, the cavity opening of the lower die faces downwards, the pressing ring is driven to continuously move downwards through the different-direction lifting structure, the pressing ring presses the movable plate, so that the movable plate drives the ejector rod to eject the formed sole in the cavity of the lower die, the ejector mechanism is used for collecting the ejected formed sole, after the formed sole is ejected, the lower die is reset to the initial position through the different-direction lifting structure, the manual demolding is not needed, a plurality of formed soles can be simultaneously taken out, the work efficiency is improved, and staff is not needed to place hands between the lower die and the movable plate, and the safety of the device is prevented from being injured.

Drawings

The accompanying drawings are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate the invention and together with the embodiments of the invention, serve to explain the invention.

In the drawings:

FIG. 1 is a schematic view of the overall structure of the present invention;

FIG. 2 is a schematic view of the structure of the collecting mechanism of the present invention;

FIG. 3 is a schematic view of the structure of the press ring of the present invention;

FIG. 4 is a schematic view of the structure of the annular box of the present invention;

FIG. 5 is an enlarged partial schematic view of the invention at A in FIG. 4;

FIG. 6 is a schematic view of the structure of the lower mold of the present invention;

FIG. 7 is a schematic diagram showing the first gear and the first damping disk of the present invention separated from the third shaft respectively;

fig. 8 is a schematic diagram showing the structure of the elastic restoring member of the present invention.

In the figure: 1. a base; 2. a top plate; 3. a connecting column; 4. an annular box; 5. a lower die; 6. a movable plate; 7. an ejector rod; 8. a pressing ring; 9. an upper die; 10. a stabilizing frame; 11. a first rotating shaft; 12. a first support portion; 13. a second rotating shaft; 14. a second supporting part; 15. a connecting block; 16. a third rotating shaft; 17. a third supporting part; 18. a first gear; 19. a first toothed plate; 20. a first connection plate; 21. a first avoidance hole; 22. a first damping disk; 23. a second damping disk; 24. a second toothed plate; 25. a third toothed plate; 26. a second gear; 27. a first guide post; 28. a support block; 29. a second avoidance hole; 30. a third avoidance hole; 31. a lifting ring; 32. a support plate; 33. a first hydraulic telescoping rod; 34. a bracket; 35. a second guide post; 36. a fourth toothed plate; 37. a fifth toothed plate; 38. a second connecting plate; 39. a fourth rotating shaft; 40. a support plate; 41. a third gear; 42. a lifting frame; 43. a collection ring; 44. a second hydraulic telescoping rod; 45. a third guide post; 46. a limiting block; 47. a compression spring; 48. and (5) supporting the column.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and fully with reference to the accompanying drawings, in which it is evident that the embodiments described are only some, but not all embodiments of the invention; all other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

The first embodiment, as shown in fig. 1 to 8, is that the shoe processing mold device of the invention comprises a base 1, a top plate 2 is arranged above the base 1, the base 1 and the top plate 2 are connected through a plurality of connecting columns 3, an annular box 4 is arranged between the base 1 and the top plate 2, the annular box 4 and the top plate 2 are connected through a plurality of supporting columns 48, a plurality of lower molds 5 are arranged below the top plate 2, two movable plates 6 are arranged below the lower molds 5, a plurality of ejector rods 7 matched with the lower molds 5 are fixedly connected to the movable plates 6, the ejector rods 7 penetrate through the lower molds 5, the lower molds 5 and the movable plates 6 are connected through elastic reset pieces, a pressing ring 8 matched with the movable plates 6 is arranged above the annular box 4, an upper mold 9 is arranged above the lower molds 5, and an anisotropic lifting structure matched with the pressing ring 8 and the plurality of upper molds 9 is arranged on the top plate 2;

A plurality of first rotating shafts 11 are arranged in the annular box 4, a first supporting part 12 which is rotationally connected is sleeved outside the first rotating shafts 11, the first supporting part 12 is fixedly connected with the inner wall of the annular box 4, a steady frame 10 which is matched with the lower die 5 is fixedly connected to the first rotating shafts 11, a plurality of first avoiding holes 21 are formed in the annular box 4, the steady frame 10 is matched with the first avoiding holes 21, a plurality of second rotating shafts 13 are arranged in the annular box 4, a second supporting part 14 which is rotationally connected is sleeved outside the second rotating shafts 13, the second supporting part 14 is fixedly connected with the inner wall of the annular box 4, the second rotating shafts 13 are connected with the lower die 5 through a connecting block 15, a plurality of second avoiding holes 29 are formed in the annular box 4, the second avoiding holes 29 are matched with the connecting block 15, a meshing synchronous rotating assembly which is respectively used for driving the first rotating shafts 11 and the second rotating shafts 13 is arranged on the pressing ring 8, and a collecting mechanism for collecting formed soles is arranged on the base 1;

When the molded shoe sole is well molded, the pressing ring 8 is driven to move downwards through the different-direction lifting structure, the pressing ring 8 drives the first rotating shaft 11 to rotate through the meshing synchronous rotating assembly, the first rotating shaft 11 drives the stabilizing frame 10 to rotate, when the stabilizing frame 10 is no longer contacted with the bottom of the lower die 5, the pressing ring 8 drives the second rotating shaft 13 to rotate through the meshing synchronous rotating assembly, when the second rotating shaft 13 drives the lower die 5 to rotate by one hundred eighty degrees through the connecting block 15, the pressing ring 8 drives the first rotating shaft 11 to continuously rotate through the meshing synchronous rotating assembly, so that the stabilizing frame 10 moves to the bottom of the lower die 5 after rotation again, the lower die 5 is prevented from tilting, at the moment, the cavity opening of the lower die 5 continuously moves downwards through the different-direction lifting structure, the pressing ring 8 presses the movable plate 6, so that the movable plate 6 drives the ejection rod 7 to eject the molded shoe sole in the cavity of the lower die 5, the collection mechanism collects the ejected molded shoe sole, the molded shoe sole is driven to move upwards through the different-direction lifting structure, the lower die 5 can be reset to the initial position, the manual demolding device is not needed, the manual demolding efficiency is not needed to be increased, and the manual demolding efficiency is not needed to be increased, the manual demolding efficiency can be increased, the safety of the personnel can be prevented from being injured, and the personnel can be prevented from being injured by the device from being placed by the personnel.

In the second embodiment, on the basis of the first embodiment, as shown in fig. 4,5, 6, 7 and 8, the meshing synchronous rotating assembly includes a third rotating shaft 16 disposed between a first rotating shaft 11 and a second rotating shaft 13, a third supporting portion 17 rotatably connected is sleeved outside the third rotating shaft 16, the third supporting portion 17 is fixedly connected with the inner wall of the annular case 4, the third rotating shaft 16 and the second rotating shaft 13 are connected through a damping synchronous member, a first gear 18 is fixedly connected to the third rotating shaft 16, a plurality of first toothed plates 19 penetrate through the annular case 4, the first toothed plates 19 are meshed with the first gear 18, the top ends of the first toothed plates 19 are connected with the pressing ring 8 through a first connecting plate 20, the first rotating shaft 11 and the first gear 18 are connected through a meshing unit, the damping synchronous member includes a first damping disc 22 fixedly mounted on the third rotating shaft 16, a second damping disc 23 is fixedly connected to the second rotating shaft 13, the second damping disk 23 is in contact with the first damping disk 22, the meshing unit comprises a second gear 26 fixedly arranged at the top end of the first rotating shaft 11, a plurality of second toothed plates 24 are arranged in the annular box 4, the second toothed plates 24 are meshed with the first gear 18, a third toothed plate 25 meshed with the second gear 26 is fixedly connected to the second toothed plates 24, a plurality of third avoidance holes 30 are formed in the annular box 4, the second toothed plates 24 and the third toothed plates 25 penetrate through the corresponding third avoidance holes 30, a guider matched with the third toothed plates 25 is arranged on the annular box 4, the guider comprises a supporting block 28 fixedly arranged on the third toothed plates 25, a first guide post 27 penetrates through the supporting block 28, one end of the first guide post 27 is fixedly connected with the inner wall of the annular box 4, and the other end of the first guide post 27 penetrates through the corresponding third avoidance holes 30;

When the pressing ring 8 moves downwards, the pressing ring 8 drives the first toothed plate 19 to move downwards through the first connecting plate 20, the first toothed plate 19 drives the first gear 18 and the third rotating shaft 16 to rotate, at the moment, the top of the stabilizing frame 10 is contacted with the bottom of the lower die 5, the stabilizing frame 10 supports the lower die 5, the third rotating shaft 16 and the first damping disc 22 cannot drive the second damping disc 23 and the second rotating shaft 13 to rotate through friction force, the first gear 18 drives the third toothed plate 25 to move horizontally through the second toothed plate 24, the third toothed plate 25 drives the supporting block 28 to slide relative to the first guide post 27, the third toothed plate 25 and the second toothed plate 24 slide smoothly in the horizontal direction through the design of the supporting block 28 and the first guide post 27, the third toothed plate 25 drives the first rotating shaft 11 to rotate through the second gear 26, the first rotating shaft 11 drives the stabilizing frame 10 to rotate, when the steady frame 10 is not contacted with the bottom of the lower die 5 any more, as the pressing ring 8 continuously moves downwards, the first damping disc 22 drives the second damping disc 23 and the second rotating shaft 13 to rotate through friction force, the second rotating shaft 13 drives the lower die 5 to rotate through the connecting block 15, when the lower die 5 rotates by one hundred eighty degrees, the top of the rotating connecting block 15 is contacted with the inner wall of the second avoidance hole 29, the inner wall of the second avoidance hole 29 limits the position of the connecting block 15, so that the connecting block 15 and the lower die 5 stop rotating again, as the pressing ring 8 continuously moves downwards, the first rotating shaft 11 drives the steady frame 10 to move to the bottom of the lower die 5 again, the lower die 5 is supported, so that when the pressing ring 8 presses the movable plate 6 and the ejection rod 7, the lower die 5 is prevented from tilting, and when the pressing ring 8 moves upwards, the lower die 5 can be reset to the initial position in the same way.

In the third embodiment, on the basis of the first embodiment, as shown in fig. 1, fig. 2 and fig. 3, the anisotropic lifting structure comprises a lifting ring 31 and a supporting plate 32 which are arranged above a base 1, the supporting plate 32 is positioned below the lifting ring 31, a connecting column 3 penetrates through the supporting plate 32, the connecting column 3 is fixedly connected with the supporting plate 32, the lifting ring 31 and the supporting plate 32 are connected through a plurality of first hydraulic telescopic rods 33, an upper die 9 is connected with the lifting ring 31 through a bracket 34, the top of a pressing ring 8 is fixedly connected with a plurality of second guide columns 35, the second guide columns 35 penetrate through a top plate 2, the bracket 34 and the pressing ring 8 are connected through an anisotropic driver, the anisotropic driver comprises a fourth toothed plate 36 fixedly arranged on the bracket 34, a plurality of second connecting plates 38 are fixedly connected with the pressing ring 8, a fifth toothed plate 37 is fixedly connected with the second connecting plate 38, a fourth rotating shaft 39 is arranged between the fifth toothed plate 37 and the fourth toothed plate 36, a supporting plate 40 which is rotationally connected with the bottom of the top plate 2 is fixedly connected with the fourth toothed plate 39, and a fourth toothed plate 37 is meshed with a fourth toothed plate 41 which is fixedly sleeved on the outside of the fourth toothed plate 41;

The lifting ring 31 and the support 34 are driven to move upwards through the first hydraulic telescopic rod 33, the support 34 can drive the upper die 9 and the fourth toothed plate 36 to move upwards, the fourth toothed plate 36 drives the third gear 41 and the fourth rotating shaft 39 to rotate, the third gear 41 drives the fifth toothed plate 37 to move downwards, the fifth toothed plate 37 can drive the pressing ring 8 to move downwards through the second connecting plate 38, the second guide column 35 slides relative to the top plate 2, and the pressing ring 8 moves stably relative to the top plate 2 in the vertical direction through the design of the second guide column 35, and similarly, when the lifting ring 31 is driven to move downwards by the first hydraulic telescopic rod 33, the pressing ring 8 moves upwards synchronously, so that the pressing ring 8 and the upper die 9 move in different directions in the vertical direction.

In the fourth embodiment, on the basis of the first embodiment, as shown in fig. 2, 6 and 8, the collecting mechanism includes a lifting frame 42 disposed between the base 1 and the annular box 4, a collecting ring 43 rotatably connected is sleeved outside the lifting frame 42, the lifting frame 42 and the base 1 are connected through a plurality of second hydraulic telescopic rods 44, the elastic resetting member includes two limiting blocks 46 disposed at the bottom of the movable plate 6, the top of the limiting block 46 is fixedly connected with a third guide post 45, the third guide post 45 penetrates through the movable plate 6, the third guide post 45 is fixedly connected with the bottom of the lower die 5, a compression spring 47 is sleeved outside the third guide post 45, two ends of the compression spring 47 are fixedly connected with the movable plate 6 and the lower die 5, and the movable plate 6 and the limiting blocks 46 are in contact;

When the cavity opening of the lower die 5 is downward, the movable plate 6 is located above the lower die 5, the lifting frame 42 and the collecting ring 43 are driven to move upwards through the second hydraulic telescopic rod 44, so that the distance between the collecting ring 43 and the lower die 5 reaches a preset value, the movable plate 6 is driven to move reversely relative to the third guide post 45 along with continuous downward movement of the pressing ring 8, the movable plate 6 and the ejector rod 7 are stopped to move relative to the third guide post 45, the compression spring 47 is in a compressed state, after the formed sole is ejected by the ejector rod 7, the formed sole falls on the collecting ring 43, at the moment, the lifting frame 42 and the collecting ring 43 are driven to move downwards to an initial position through the second hydraulic telescopic rod 44, the collecting ring 43 and the lifting frame 42 are prevented from being interfered by the lower die 5 to return to the initial position, when the pressing ring 8 moves upwards, the movable plate 6 is not pressed again, at the moment, the compression spring 47 drives the movable plate 6 to move reversely relative to the third guide post 45, the movable plate 6 and the ejector rod 7 are stopped to move relative to the lower die 5 when the movable plate 6 is contacted with the limiting block 46, the working staff removes the forming ring 43 to the collecting ring 43, and the working staff can not rotate around the collecting ring 43 to the forming ring 43, and the collecting ring can be conveniently moved around the sole 43.

The application method of the shoe processing mold device of the embodiment adopts the shoe processing mold device and comprises the following steps:

step one: when the sole is molded by injection molding, the upper die 9 is driven to move upwards through the anisotropic lifting structure so as to separate the upper die 9 from the lower die 5, the pressing ring 8 is driven to move downwards by the anisotropic lifting structure, the pressing ring 8 drives the first rotating shaft 11 to rotate through the meshed synchronous rotating assembly, and the first rotating shaft 11 drives the stabilizing frame 10 to rotate;

Step two: when the stabilizing frame 10 is not contacted with the bottom of the lower die 5 any more, the pressing ring 8 drives the second rotating shaft 13 to rotate through the meshing synchronous rotating assembly, and when the second rotating shaft 13 drives the lower die 5 to rotate for one hundred eighty degrees through the connecting block 15, the top of the rotating connecting block 15 is contacted with the inner wall of the second avoiding hole 29;

Step three: the pressing ring 8 drives the first rotating shaft 11 to continuously rotate through the meshed synchronous rotating assembly, so that the stabilizing frame 10 moves to the bottom of the rotated lower die 5 again, at the moment, the cavity opening of the lower die 5 faces downwards, and the movable plate 6 is positioned above the lower die 5;

Step four: the pressing ring 8 is driven to continuously move downwards through the anisotropic lifting structure, the movable plate 6 is pressed by the pressing ring 8, so that the movable plate 6 drives the ejector rod 7 to eject the formed sole in the cavity of the lower die 5, and the ejected formed sole is collected through the collecting mechanism.

Working principle: when the shoe sole is molded, the upper die 9 is driven to move downwards through the anisotropic lifting structure, the upper die 9 and the lower die 5 are clamped, the top of the connecting block 15 is contacted with the inner wall of the second avoidance hole 29, the stabilizing frame 10 is contacted with the bottom of the lower die 5, the lower die 5 is supported through the stabilizing frame 10 to avoid tilting and shaking of the lower die 5, when the shoe sole is molded, the upper die 9 is driven to move upwards through the anisotropic lifting structure to separate the upper die 9 from the lower die 5, the anisotropic lifting structure drives the pressing ring 8 to move downwards, the pressing ring 8 drives the first rotating shaft 11 to rotate through the meshing synchronous rotating assembly, the first rotating shaft 11 drives the stabilizing frame 10 to rotate, when the stabilizing frame 10 is not contacted with the bottom of the lower die 5 any more, the limiting of the position of the lower die 5 is released, the pressing ring 8 drives the second rotating shaft 13 to rotate through the meshing synchronous rotating assembly along with the continuous downward movement of the pressing ring 8, the connecting block 15 rotates in the second avoiding hole 29, when the second rotating shaft 13 drives the lower die 5 to rotate by one hundred eighty degrees through the connecting block 15, the top of the rotated connecting block 15 is contacted with the inner wall of the second avoiding hole 29, the connecting block 15 and the lower die 5 stop rotating, the pressing ring 8 drives the first rotating shaft 11 to continuously rotate through the meshed synchronous rotating assembly, so that the stabilizing frame 10 moves to the bottom of the rotated lower die 5 again, the lower die 5 is prevented from tilting and shaking, at the moment, the cavity opening of the lower die 5 faces downwards, the movable plate 6 is positioned above the lower die 5, the pressing ring 8 is driven by the anisotropic lifting structure to continuously move downwards, the movable plate 6 is pressed by the pressing ring 8, so that the movable plate 6 drives the ejector rod 7 to eject the formed sole in the cavity of the lower die 5, the ejected formed sole is collected through the collecting mechanism, after the sole is ejected, the press ring 8 is driven to move upwards through the anisotropic lifting structure, the movable plate 6 and the ejector rod 7 are driven to reset to the initial position relative to the lower die 5 by the elastic reset piece, and the lower die 5 reversely rotates for one hundred eighty degrees, so that the lower die 5 is reset to the initial position, a plurality of formed soles can be taken out simultaneously without manually demolding, the working efficiency is improved, meanwhile, a worker is not required to place hands between the lower die 5 and the movable plate 6, personnel injury possibly caused by the failure of a die device is avoided, and the safety is improved;

When the pressing ring 8 moves downwards, the pressing ring 8 drives the first toothed plate 19 to move downwards through the first connecting plate 20, the first toothed plate 19 drives the first gear 18 and the third rotating shaft 16 to rotate, at the moment, the top of the stabilizing frame 10 is contacted with the bottom of the lower die 5, the stabilizing frame 10 supports the lower die 5, the third rotating shaft 16 and the first damping disc 22 cannot drive the second damping disc 23 and the second rotating shaft 13 to rotate through friction force, the first gear 18 drives the third toothed plate 25 to move horizontally through the second toothed plate 24, the third toothed plate 25 drives the supporting block 28 to slide relative to the first guide post 27, the third toothed plate 25 and the second toothed plate 24 slide smoothly in the horizontal direction through the design of the supporting block 28 and the first guide post 27, the third toothed plate 25 drives the first rotating shaft 11 to rotate through the second gear 26, the first rotating shaft 11 drives the stabilizing frame 10 to rotate, when the steady frame 10 is not contacted with the bottom of the lower die 5 any more, as the pressing ring 8 continuously moves downwards, the first damping disc 22 drives the second damping disc 23 and the second rotating shaft 13 to rotate through friction force, the second rotating shaft 13 drives the lower die 5 to rotate through the connecting block 15, when the lower die 5 rotates for one hundred eighty degrees, the top of the rotated connecting block 15 is contacted with the inner wall of the second avoidance hole 29, the inner wall of the second avoidance hole 29 limits the position of the connecting block 15, so that the connecting block 15 and the lower die 5 stop rotating again, as the pressing ring 8 continuously moves downwards, the first rotating shaft 11 drives the steady frame 10 to move to the bottom of the lower die 5 again, so as to support the lower die 5, so that when the pressing ring 8 presses the movable plate 6 and the ejection rod 7, the lower die 5 is prevented from tilting and shaking, and when the pressing ring 8 moves upwards, the lower die 5 can be reset to the initial position in the same way;

The lifting ring 31 and the support 34 are driven to move upwards through the first hydraulic telescopic rod 33, the support 34 can drive the upper die 9 and the fourth toothed plate 36 to move upwards, the fourth toothed plate 36 drives the third gear 41 and the fourth rotating shaft 39 to rotate, the third gear 41 drives the fifth toothed plate 37 to move downwards, the fifth toothed plate 37 can drive the pressing ring 8 to move downwards through the second connecting plate 38, the second guide column 35 slides relative to the top plate 2, and the pressing ring 8 moves stably relative to the top plate 2 in the vertical direction through the design of the second guide column 35, and in the same way, when the lifting ring 31 is driven to move downwards by the first hydraulic telescopic rod 33, the pressing ring 8 moves upwards synchronously, so that the pressing ring 8 and the upper die 9 move in different directions in the vertical direction;

When the cavity opening of the lower die 5 is downward, the movable plate 6 is located above the lower die 5, the lifting frame 42 and the collecting ring 43 are driven to move upwards through the second hydraulic telescopic rod 44, so that the distance between the collecting ring 43 and the lower die 5 reaches a preset value, the movable plate 6 is driven to move reversely relative to the third guide post 45 along with continuous downward movement of the pressing ring 8, the movable plate 6 and the ejector rod 7 are stopped to move relative to the third guide post 45, the compression spring 47 is in a compressed state, after the formed sole is ejected by the ejector rod 7, the formed sole falls on the collecting ring 43, at the moment, the lifting frame 42 and the collecting ring 43 are driven to move downwards to an initial position through the second hydraulic telescopic rod 44, the collecting ring 43 and the lifting frame 42 are prevented from being interfered by the lower die 5 to return to the initial position, when the pressing ring 8 moves upwards, the movable plate 6 is not pressed again, at the moment, the compression spring 47 drives the movable plate 6 to move reversely relative to the third guide post 45, the movable plate 6 and the ejector rod 7 are stopped to move relative to the lower die 5 when the movable plate 6 is contacted with the limiting block 46, the working staff removes the forming ring 43 to the collecting ring 43, and the working staff can not rotate around the collecting ring 43 to the forming ring 43, and the collecting ring can be conveniently moved around the sole 43.

It is noted that relational terms such as first and second, and the like are used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Moreover, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

Although embodiments of the present invention have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (10)

1. Shoe processing mould device, including base (1), its characterized in that: the upper part of the base (1) is provided with a top plate (2), the base (1) and the top plate (2) are connected through a plurality of connecting columns (3), an annular box (4) is arranged between the base (1) and the top plate (2), the annular box (4) and the top plate (2) are connected through a plurality of supporting columns (48), a plurality of lower dies (5) are arranged below the top plate (2), two movable plates (6) are arranged below the lower dies (5), a plurality of ejector rods (7) matched with the lower dies (5) are fixedly connected to the movable plates (6), the ejector rods (7) penetrate through the lower dies (5), the lower dies (5) are connected with the movable plates (6) through elastic reset pieces, a pressing ring (8) matched with the movable plates (6) is arranged above the annular box (4), an upper die (9) is arranged above the lower dies (5), and a different-direction lifting structure matched with the pressing ring (8) and the plurality of upper dies (9) is arranged on the top plate (2);

Be equipped with a plurality of first pivots (11) in annular case (4), the outside cover of first pivots (11) is equipped with first supporting part (12) of rotation connection, and the inner wall fixed connection of first supporting part (12) and annular case (4), fixedly connected with and lower mould (5) matched with firm frame (10) on first pivots (11), a plurality of first hole (21) of dodging have been seted up on annular case (4), and firm frame (10) and first hole (21) of dodging cooperate, be equipped with a plurality of second pivots (13) in annular case (4), the outside cover of second pivots (13) is equipped with second supporting part (14) of rotation connection, and the inner wall fixed connection of second supporting part (14) and annular case (4), second pivots (13) and lower mould (5) are connected through connecting block (15), a plurality of second dodging hole (29) have been seted up on annular case (4), and second dodging hole (29) and 15) cooperate, be equipped with on pressing ring (8) and be used for driving first pivots (11) and second pivot (13) and rotatory coupling block (1) of rotation seat (1) of collecting assembly respectively, be equipped with synchronous meshing.

2. A shoe mold processing apparatus according to claim 1, wherein: the meshing synchronous rotating assembly comprises a third rotating shaft (16) arranged between a first rotating shaft (11) and a second rotating shaft (13), a third supporting part (17) connected in a rotating mode is sleeved outside the third rotating shaft (16), the third supporting part (17) is fixedly connected with the inner wall of the annular box (4), the third rotating shaft (16) and the second rotating shaft (13) are connected through damping synchronous pieces, a first gear (18) is fixedly connected to the third rotating shaft (16), a plurality of first toothed plates (19) penetrate through the annular box (4), the first toothed plates (19) are meshed with the first gear (18), the top ends of the first toothed plates (19) are connected with the pressing ring (8) through a first connecting plate (20), and the first rotating shaft (11) and the first gear (18) are connected through a meshing unit.

3. A shoe mold apparatus according to claim 2, wherein: the damping synchronous piece comprises a first damping disc (22) fixedly arranged on a third rotating shaft (16), a second damping disc (23) is fixedly connected to the second rotating shaft (13), and the second damping disc (23) is contacted with the first damping disc (22).

4. A shoe mold apparatus according to claim 2, wherein: the meshing unit comprises a second gear (26) fixedly mounted at the top end of the first rotating shaft (11), a plurality of second toothed plates (24) are arranged in the annular box (4), the second toothed plates (24) are meshed with the first gear (18), third toothed plates (25) meshed with the second gear (26) are fixedly connected to the second toothed plates (24), a plurality of third avoidance holes (30) are formed in the annular box (4), the second toothed plates (24) and the third toothed plates (25) penetrate through the corresponding third avoidance holes (30), and a guider matched with the third toothed plates (25) is arranged on the annular box (4).

5. The shoe mold apparatus according to claim 4, wherein: the guide comprises a supporting block (28) fixedly mounted on the third toothed plate (25), a first guide column (27) penetrates through the supporting block (28), one end of the first guide column (27) is fixedly connected with the inner wall of the annular box (4), and the other end of the first guide column (27) penetrates through a corresponding third avoidance hole (30).

6. A shoe mold processing apparatus according to claim 1, wherein: the utility model provides an anisotropic elevation structure is including setting up in lifting ring (31) and supporting disk (32) of base (1) top, supporting disk (32) are located the below of lifting ring (31), spliced pole (3) run through supporting disk (32), and spliced pole (3) and supporting disk (32) fixed connection, lifting ring (31) and supporting disk (32) are connected through a plurality of first hydraulic telescoping rod (33), go up mould (9) and lifting ring (31) and pass through support (34) to be connected, the top fixedly connected with a plurality of second guide post (35) of pressing ring (8), and second guide post (35) run through roof (2), support (34) and pressing ring (8) are connected through the anisotropic driver.

7. The shoe mold apparatus according to claim 6, wherein: the anisotropic driver comprises a fourth toothed plate (36) fixedly mounted on a support (34), a plurality of second connecting plates (38) are fixedly connected to the pressing ring (8), a fifth toothed plate (37) is fixedly connected to the second connecting plates (38), a fourth rotating shaft (39) is arranged between the fifth toothed plate (37) and the fourth toothed plate (36), a supporting plate (40) in rotating connection is sleeved outside the fourth rotating shaft (39), the supporting plate (40) is fixedly connected with the bottom of the top plate (2), a third gear (41) is fixedly sleeved outside the fourth rotating shaft (39), and the fifth toothed plate (37) and the fourth toothed plate (36) are meshed with the third gear (41) respectively.

8. A shoe mold processing apparatus according to claim 1, wherein: the collecting mechanism comprises a lifting frame (42) arranged between the base (1) and the annular box (4), a collecting ring (43) connected in a rotating mode is sleeved outside the lifting frame (42), and the lifting frame (42) is connected with the base (1) through a plurality of second hydraulic telescopic rods (44).

9. A shoe mold processing apparatus according to claim 1, wherein: the elastic reset piece comprises two limiting blocks (46) arranged at the bottom of the movable plate (6), the top of each limiting block (46) is fixedly connected with a third guide column (45), each third guide column (45) penetrates through the movable plate (6), the bottoms of the third guide columns (45) and the lower die (5) are fixedly connected, compression springs (47) are sleeved outside the corresponding third guide columns (45), two ends of each compression spring (47) are fixedly connected with the movable plate (6) and the corresponding lower die (5) respectively, and the movable plate (6) is in contact with each limiting block (46).

10. A method of using the shoe mold apparatus of claim 1, wherein: the method comprises the following steps:

Step one: when the sole is molded by injection molding, the upper die (9) is driven to move upwards through the anisotropic lifting structure so as to separate the upper die (9) from the lower die (5), the pressing ring (8) is driven to move downwards through the anisotropic lifting structure, the pressing ring (8) drives the first rotating shaft (11) to rotate through the meshed synchronous rotating assembly, and the first rotating shaft (11) drives the stabilizing frame (10) to rotate;

Step two: when the stabilizing frame (10) is not contacted with the bottom of the lower die (5), the pressing ring (8) drives the second rotating shaft (13) to rotate through the meshing synchronous rotating assembly, and when the second rotating shaft (13) drives the lower die (5) to rotate for one hundred eighty degrees through the connecting block (15), the top of the rotating connecting block (15) is contacted with the inner wall of the second avoiding hole (29);

step three: the pressing ring (8) drives the first rotating shaft (11) to continuously rotate through the meshed synchronous rotating assembly, so that the stabilizing frame (10) moves to the bottom of the rotated lower die (5) again, at the moment, the cavity opening of the lower die (5) faces downwards, and the movable plate (6) is positioned above the lower die (5);

step four: the pressing ring (8) is driven to continuously move downwards through the anisotropic lifting structure, the movable plate (6) is pressed by the pressing ring (8), so that the movable plate (6) drives the ejection rod (7) to eject the formed sole in the cavity of the lower die (5), and the ejected formed sole is collected through the collecting mechanism.