CN116461032A

CN116461032A - Shoe production device

Info

Publication number: CN116461032A
Application number: CN202310442390.7A
Authority: CN
Inventors: 马杰
Original assignee: Individual
Current assignee: Individual
Priority date: 2023-04-23
Filing date: 2023-04-23
Publication date: 2023-07-21

Abstract

The invention relates to the field of shoe processing, in particular to a shoe production device. The invention provides a shoe production device capable of efficiently producing rubber soles and scraping the overflow edges of the soles. A shoe production device comprises a supporting floor frame, a special-shaped slotting support frame, a heating plate, a pressing-down opening and closing assembly and the like; the special-shaped grooving support frame is fixedly arranged on the upper side surface of the supporting floor frame, the heating plate is arranged on the upper side surface of the special-shaped grooving support frame, and the downward pressing opening and closing assembly is arranged on the supporting floor frame. The T-shaped connecting block moves upwards continuously to push the wedge-shaped sliding frame to move towards the direction away from the heating plate, the wedge-shaped sliding frame moves to drive the slotting sliding rod and the scraper to move, and the scraper moves to scrape off the overflow edge of the surface of the formed sole, so that the surface of the formed sole is smoother and more attractive.

Description

Shoe production device

Technical Field

The invention relates to the field of shoe processing, in particular to a shoe production device.

Background

Rubber sole is common sole kind, rubber sole has the wearability advantage such as good, antiskid, elasticity, difficult fracture, at present, when producing rubber sole, need the manual work place the rubber strip in the mould, then close the mould, heat the rubber strip in the mould through the heating for the rubber strip melts and becomes the sole in the mould, need the workman to use the instrument to dig out the shaping sole in the mould after the sole shaping, the production efficiency of sole is low, and the fashioned in-process, rubber can overflow from the mould space, the sole of producing has the edge that overflows, leads to sole surface unevenness, influence the later stage use of sole.

Disclosure of Invention

The invention aims at overcoming the defects, and provides the shoe production device capable of efficiently producing the rubber sole and scraping the overflow edge of the sole.

The technical implementation scheme of the invention is as follows: the utility model provides a shoes apparatus for producing, includes support floor frame, abnormal shape fluting support frame, hot plate, pushes down the subassembly that opens and shuts, pushing away subassembly, elastic component, scrapes limit subassembly and break away from the subassembly, abnormal shape fluting support frame fixed mounting is in support floor frame upside, the hot plate sets up at abnormal shape fluting support frame upside, push down the subassembly that opens and shuts and locate on the support floor frame, pushing away the subassembly and locating on the abnormal shape fluting support frame and being connected with pushing down the subassembly that opens and shuts, elastic component locates on the abnormal shape fluting support frame, scrape the limit subassembly and locate on the subassembly that opens and shuts down, break away from the subassembly and locate on the abnormal shape fluting support frame.

In a preferred embodiment of the invention, the pressing-down opening-closing assembly comprises an electric push rod, a T-shaped connecting block, a lower die block, an upper die block and a first torsion spring, wherein two electric push rods are fixedly arranged on the upper side surface of the supporting floor frame, the two electric push rods are symmetrically arranged, the special-shaped slotting support frame is positioned between the two electric push rods, the T-shaped connecting block is fixedly connected to the top end of a telescopic shaft of the electric push rod, the lower die block is connected to one side, far away from the heating plate, of the upper side surface of the special-shaped slotting support frame in a sliding mode, the upper die block is connected to one side, close to the heating plate, of the lower die block in a rotating mode, and a plurality of first torsion springs are connected between the upper die block and the lower die block.

In a preferred embodiment of the present invention, the pushing assembly includes a wedge-shaped connecting frame and a first return spring, the lower side surface of the lower mold block is fixedly connected with two wedge-shaped connecting frames, the two wedge-shaped connecting frames are symmetrically arranged, the wedge-shaped connecting frames are slidably connected with the special-shaped slotting support frame, the wedge-shaped connecting frames are located below the T-shaped connecting blocks, and the first return spring is connected between the wedge-shaped connecting frames and the special-shaped slotting support frame.

In a preferred embodiment of the invention, the elastic material component comprises an L-shaped slotting frame, an arc-shaped pushing plate and a round head top plate frame, wherein two L-shaped slotting frames are symmetrically arranged on one side, close to the heating plate, of the upper portion of the special-shaped slotting frame, the arc-shaped pushing plate is connected between the two L-shaped slotting frames in a sliding mode, the upper end of the arc-shaped pushing plate is contacted with the top of the T-shaped connecting block, two round head top plate frames are connected on the lower die block in a sliding mode, the two round head top plate frames are symmetrically arranged, the bottom ends of the arc-shaped pushing plates are contacted with the round head top plate frames, and the round head top plate frames are connected with the special-shaped slotting frame in a sliding mode.

In a preferred embodiment of the present invention, the scraping edge assembly includes a slotted sliding rod, a second return spring, a wedge sliding frame, a bevel edge fixing frame, a third return spring, a scraper and a fourth return spring, wherein two slotted sliding rods are connected on the lower die block in a sliding manner, the two slotted sliding rods are symmetrically arranged, the second return spring is connected between the slotted sliding rod and the lower die block, the wedge sliding frame is connected on the slotted sliding rod in a sliding manner, the wedge sliding frame is located below the T-shaped connecting block, the bevel edge fixing frame is fixedly connected at the lower part of the wedge sliding frame, the third return spring is connected between the wedge sliding frame and the slotted sliding rod, the scraper is connected between the two slotted sliding rods in a sliding manner, and the fourth return spring is connected between the scraper and the slotted sliding rod.

In a preferred embodiment of the present invention, the disengaging assembly includes a fixed toggle frame, a rectangular slotted frame, a sliding perforated frame, a first homing spring, a movable rack, a second homing spring and a rotating gear, wherein two fixed toggle frames are fixedly connected to the lower portion of the arc pushing plate, two fixed toggle frames are symmetrically arranged, two rectangular slotted frames are fixedly connected to the special slotted frame, two rectangular slotted frames are symmetrically arranged, the sliding perforated frame is slidably connected to the rectangular slotted frame, the fixed toggle frame is in contact with the sliding perforated frame, a first homing spring is connected between the sliding perforated frame and the rectangular slotted frame, one end of the movable rack is in contact with a bevel edge fixing frame, a second homing spring is connected between the movable rack and the sliding perforated frame, two rotating gears are fixedly connected to the lower portion of the upper die block, and the two rotating gears are symmetrically arranged.

In a preferred embodiment of the invention, the device further comprises a pushing assembly, wherein the pushing assembly is arranged on the supporting floor frame and is connected with one of the wedge-shaped sliding frames, the pushing assembly comprises an N-shaped perforated frame, a special-shaped rack bar, a swinging rod, an adjusting gear and a second torsion spring, the N-shaped perforated frame is fixedly connected to the upper side surface of the supporting floor frame, one of the wedge-shaped sliding frames is fixedly connected with the special-shaped rack bar, the swinging rod is rotatably connected to the upper part of the N-shaped perforated frame, the adjusting gear is fixedly connected to the bottom end of the swinging rod, the adjusting gear is meshed with the special-shaped rack bar, and the second torsion spring is connected between the swinging rod and the N-shaped perforated frame.

Compared with the prior art, the invention has the following advantages:

1. the T-shaped connecting block moves upwards continuously to push the wedge-shaped sliding frame to move towards the direction away from the heating plate, the wedge-shaped sliding frame moves to drive the slotting sliding rod and the scraper to move, and the scraper moves to scrape off the overflow edge of the surface of the formed sole, so that the surface of the formed sole is smoother and more attractive.

2. The round head top plate frame moves downwards under the action of gravity and drives the rubber strip to move downwards, so that the rubber strip moves downwards into the groove of the lower die block, the arc-shaped pushing plate resets upwards to drive the round head top plate frame to reset, the round head top plate frame resets to eject the formed sole upwards, and the formed sole is convenient to take out subsequently.

3. One wedge-shaped sliding frame can drive the abnormal-shaped rack rod to reset, the abnormal-shaped rack rod resets to drive the adjusting gear to rotate, the adjusting gear rotates to drive the swinging rod to rotate, the swinging rod rotates to rapidly push out soles formed on the upper die block, the next double soles can be conveniently processed, and the production efficiency of the soles is improved.

Drawings

Fig. 1 is a schematic perspective view of a first embodiment of the present invention.

Fig. 2 is a schematic perspective view of a second embodiment of the present invention.

Fig. 3 is a schematic perspective view of a first part of the present invention.

Fig. 4 is an enlarged perspective view of the present invention a.

Fig. 5 is a schematic perspective view of a second part of the present invention.

Fig. 6 is a schematic perspective view of a third portion of the present invention.

Fig. 7 is a schematic perspective view of a fourth part of the present invention.

Fig. 8 is an enlarged perspective view of the present invention B.

Fig. 9 is a schematic perspective view of a fifth part of the present invention.

Fig. 10 is a schematic perspective view of a sixth part of the present invention.

Fig. 11 is a schematic perspective view of a seventh part of the present invention.

Fig. 12 is a schematic perspective view of an eighth portion of the present invention.

The marks of the components in the drawings are as follows: 1. the device comprises a supporting floor frame, 21, a special-shaped slotting support frame, 22, a heating plate, 3, a pushing opening and closing component, 31, an electric push rod, 32, a T-shaped connecting block, 33, a lower die block, 34, an upper die block, 35, a first torsion spring, 4, a pushing component, 41, a wedge-shaped connecting frame, 42, a first return spring, 5, a material pushing component, 51, an L-shaped slotting frame, 52, an arc pushing plate, 53, a round head top plate frame, 6, a scraping component, 61, a slotting sliding rod, 62, a second return spring, 63, a wedge-shaped sliding frame, 64, a bevel edge fixing frame, 65, a third return spring, 66, a scraper, 67, a fourth return spring, 7, a disengaging component, 71, a fixed stirring frame, 72, a rectangular slotting frame, 73, a sliding perforating frame, 74, a first return spring, 75, a jacking rack, 76, a second return spring, 77, a rotating gear, 8, a material pushing component, 81, an N-shaped perforating frame, 82, a special-shaped rack rod, 83, a swing rod, 84, an adjusting gear, 85 and a second torsion spring.

Detailed Description

Standard parts used in the invention can be purchased from the market, special-shaped parts can be customized according to the description of the specification and the drawings, and the specific connection modes of the parts adopt conventional means such as mature bolts, rivets, welding, pasting and the like in the prior art, and the detailed description is omitted.

Example 1

1-9 and 12, including supporting floor frame 1, abnormal shape fluting support frame 21, hot plate 22, push down the subassembly 3 that opens and shuts, push assembly 4, elastic material subassembly 5, scrape limit subassembly 6 and break away from subassembly 7, abnormal shape fluting support frame 21 passes through the bolt to be installed at supporting floor frame 1 upside, hot plate 22 sets up at abnormal shape fluting support frame 21 upside, hot plate 22 is used for heating the rubber strip, push down the subassembly 3 that opens and shuts and locate supporting floor frame 1, push down the subassembly 3 and be used for with the rubber sole compression moulding, push assembly 4 locates on the abnormal shape fluting support frame 21 and is connected with push down the subassembly 3 that opens and shuts, elastic material subassembly 5 locates on the abnormal shape fluting support frame 21, scrape limit subassembly 6 and locate on pushing down the subassembly 3, scrape limit subassembly 6 and be used for scraping the overflow limit of rubber sole, break away from subassembly 7 locates on the abnormal shape fluting support frame 21.

The pushing-down opening-closing assembly 3 comprises an electric push rod 31, a T-shaped connecting block 32, a lower die block 33, an upper die block 34 and a first torsion spring 35, wherein the upper side surface of the supporting floor frame 1 is provided with two electric push rods 31 through rivets, the two electric push rods 31 are symmetrically arranged, the electric push rods 31 are vertically arranged, the special-shaped slotting support frame 21 is positioned between the two electric push rods 31, the T-shaped connecting block 32 is fixedly connected to the top end of a telescopic shaft of the electric push rod 31, the lower die block 33 is slidably connected to one side, far away from the heating plate 22, of the upper side surface of the special-shaped slotting support frame 21, the lower die block 33 is provided with two grooves, the grooves of the lower die block 33 are used for placing rubber strips, the upper die block 34 is rotatably connected to one side, close to the heating plate 22, of the lower die block 33, and a plurality of first torsion springs 35 are connected between the upper die block 34 and the lower die block 33.

The pushing component 4 comprises a wedge-shaped connecting frame 41 and a first reset spring 42, two wedge-shaped connecting frames 41 are welded on the lower side face of the lower die block 33, inclined planes are arranged on the upper portion of each wedge-shaped connecting frame 41, the two wedge-shaped connecting frames 41 are symmetrically arranged, each wedge-shaped connecting frame 41 is connected with the corresponding special-shaped grooving support frame 21 in a sliding mode, the inclined planes of the wedge-shaped connecting frames 41 are located below the T-shaped connecting blocks 32, the first reset springs 42 are connected between the wedge-shaped connecting frames 41 and the corresponding special-shaped grooving support frames 21 through hooks, and the first reset springs 42 are horizontally arranged.

The material loading assembly 5 comprises an L-shaped slotting frame 51, an arc-shaped pushing plate 52 and a round head top plate frame 53, wherein two L-shaped slotting frames 51 are installed on one side, close to a heating plate 22, of the upper portion of the special-shaped slotting support frame 21 through bolts, the two L-shaped slotting frames 51 are symmetrically arranged, the arc-shaped pushing plate 52 is connected between the L-shaped slotting frames 51 in a sliding mode, the upper end of the arc-shaped pushing plate 52 is contacted with the top of the T-shaped connecting block 32, the two round head top plate frames 53 are connected onto the lower die block 33 in a sliding mode, the two round head top plate frames 53 are symmetrically arranged, the bottom end of the arc-shaped pushing plate 52 is contacted with the round head top plate frames 53, the round head top plate frames 53 are used for ejecting formed soles upwards, and the formed soles can be conveniently taken out in a sliding mode, and the round head top plate frames 53 are connected with the special-shaped slotting support frame 21 in a sliding mode.

The scraping edge component 6 comprises a slotted sliding rod 61, a second return spring 62, a wedge sliding frame 63, a bevel edge fixing frame 64, a third return spring 65, a scraper 66 and a fourth return spring 67, wherein two slotted sliding rods 61 are connected to the lower die block 33 in a sliding mode, two slotted sliding rods 61 are symmetrically arranged, the second return spring 62 is connected between each slotted sliding rod 61 and the lower die block 33 through a hook, the wedge sliding frame 63 is connected to the slotted sliding rod 61 in a sliding mode, the wedge sliding frame 63 is located below the T-shaped connecting block 32, the bevel edge fixing frame 64 is welded to the lower portion of the wedge sliding frame 63, the third return spring 65 is connected between the wedge sliding frame 63 and the slotted sliding rod 61 through a hook, the scraper 66 is connected between the two slotted sliding rods 61 in a sliding mode, the scraper 66 is located above the lower die block 33, and used for scraping overflowed edges of the surface of a formed sole, and the fourth return spring 67 is connected between the scraper 66 and the slotted sliding rod 61.

The disengaging assembly 7 comprises a fixed toggle frame 71, a rectangular slotted frame 72, a sliding slotted frame 73, a first homing spring 74, a jacking rack 75, a second homing spring 76 and a rotary gear 77, wherein two fixed toggle frames 71 are welded at the lower part of the arc pushing plate 52, two fixed toggle frames 71 are symmetrically arranged, two rectangular slotted frames 72 are mounted on the special slotted frame 21 through bolts, two rectangular slotted frames 72 are symmetrically arranged, the sliding slotted frame 73 is slidably connected to the rectangular slotted frame 72, the fixed toggle frame 71 is in contact with the sliding slotted frame 73, the first homing spring 74 is connected between the sliding slotted frame 73 and the rectangular slotted frame 72 through a hook, one end of the jacking rack 75 is in contact with the bevel edge fixing frame 64, two rotary gears 77 are mounted at the lower part of the upper die block 34 through a flat key, and the two rotary gears 77 are symmetrically arranged and meshed with the rotary gear 77.

Initially, the T-shaped connecting block 32 is propped against the arc-shaped pushing plate 52, the arc-shaped pushing plate 52 is propped against the round head top plate frame 53, the fixed poking frame 71 limits the sliding hole frame 73, the first homing spring 74 is stretched, firstly, a worker places a rubber strip on the round head top plate frame 53, then the worker starts the heating plate 22 and controls the electric push rod 31 to shrink, the electric push rod 31 shrinks to drive the T-shaped connecting block 32 to move downwards, the T-shaped connecting block 32 is not propped against the arc-shaped pushing plate 52 any more, the arc-shaped pushing plate 52 moves downwards under the action of gravity, the round head top plate frame 53 moves downwards under the action of gravity and drives the rubber strip to move downwards, so that the rubber strip moves downwards into a groove of the lower die block 33, the T-shaped connecting block 32 drives the movement to squeeze the wedge-shaped connecting frame 41 to move towards the direction close to the heating plate 22, the wedge-shaped connecting frame 41 moves to drive the lower die block 33 and the upper die block 34 to move, the special-shaped grooving support frame 21 can extrude the upper die block 34 to swing clockwise, then the lower die block 33 and the upper die block 34 continue to move, the upper side surface of the upper die block 34 can be contacted with the lower side surface of the heating plate 22, the heating plate 22 heats the upper die block 34, the upper die block 34 transmits heat to the rubber strip in the groove of the lower die block 33, so that the rubber strip melts in the groove of the lower die block 33, the upper die block 34 extrudes the melted rubber strip in the groove of the lower die block 33, the rubber strip is extruded into a sole, the arc-shaped pushing plate 52 moves downwards to drive the fixed toggle frame 71 to move downwards, the fixed toggle frame 71 moves downwards, the fixed toggle frame 71 does not limit the sliding hole frame 73 any more, the first homing spring 74 is restored to drive the sliding hole frame 73 and the jacking rack 75 to move towards the direction close to the rotating gear 77, the worker controls the electric push rod 31 to extend, the electric push rod 31 extends to drive the T-shaped connecting block 32 to reset upwards, the T-shaped connecting block 32 does not push the wedge-shaped connecting frame 41 any more, the first reset spring 42 resets to drive the lower die block 33 to reset, the special-shaped slotting support frame 21 does not squeeze the upper die block 34 any more, the first torsion spring 35 resets to drive the upper die block 34 to swing anticlockwise to reset, the upper die block 34 swings anticlockwise to drive the rotary gear 77 to reverse, the rotary gear 77 reverses to drive the jacking rack 75 to move upwards, the jacking rack 75 moves upwards to push the two hypotenuse fixing frames 64 to move towards the direction away from each other, the hypotenuse fixing frames 64 moves to drive the wedge-shaped sliding frame 63 to move, the T-shaped connecting block 32 continues to move upwards to push the wedge-shaped sliding frame 63 to move towards the direction away from the heating plate 22, the wedge-shaped sliding frame 63 moves to drive the slotting sliding rod 61 and the scraper 66 to move, the scraper 66 moves to scrape off the overflow edge on the surface of the formed sole, so that the surface of the formed sole is smoother and more attractive, then the T-shaped connecting block 32 resets to push the arc-shaped pushing plate 52 to reset upwards, the arc-shaped pushing plate 52 resets to drive the fixed poking frame 71 to reset, the fixed poking frame 71 resets to push the sliding perforated frame 73 to reset, the sliding perforated frame 73 resets to drive the jacking frame 75 to reset, the jacking frame 75 is disengaged from the rotating gear 77, then the T-shaped connecting block 32 continues to move upwards to be disengaged from the wedge-shaped sliding frame 63, the second reset spring 62 resets to drive the slotting sliding rod 61 and the scraper 66 to reset, the arc-shaped pushing plate 52 resets upwards to drive the round head jacking frame 53 to reset, the round head jacking frame 53 resets to push the formed sole upwards, the formed sole is conveniently taken out, and finally a worker closes the heating plate 22.

Example 2

On the basis of embodiment 1, as shown in fig. 10-11, the shoe sole pushing device further comprises a pushing assembly 8, wherein the pushing assembly 8 is arranged on the supporting floor frame 1 and is connected with one wedge-shaped sliding frame 63, the pushing assembly 8 is used for rapidly pushing out the shoe sole formed on the upper die block 34, the next double shoe soles are convenient to process, the pushing assembly 8 comprises an N-shaped perforated frame 81, a special-shaped rack bar 82, a swinging rod 83, an adjusting gear 84 and a second torsion spring 85, the N-shaped perforated frame 81 is welded on the upper side surface of the supporting floor frame 1, one wedge-shaped sliding frame 63 is fixedly connected with the special-shaped rack bar 82, the special-shaped rack bar 82 is horizontally arranged, the swinging rod 83 is rotatably connected to the upper part of the N-shaped perforated frame 81, the swinging rod 83 is used for rapidly pushing out the shoe sole formed on the upper die block 34, the adjusting gear 84 is fixedly connected to the bottom end of the swinging rod 83, the adjusting gear 84 is meshed with the special-shaped rack bar 82, and the second torsion spring 85 is connected between the swinging rod 83 and the N-shaped perforated frame 81.

When the two wedge-shaped sliding frames 63 move in the directions away from each other, the special-shaped rack bars 82 are driven to move, when the wedge-shaped sliding frames 63 reset, one wedge-shaped sliding frame 63 drives the special-shaped rack bars 82 to reset, the special-shaped rack bars 82 reset to drive the adjusting gear 84 to rotate, the adjusting gear 84 rotates to drive the swinging rod 83 to rotate, the swinging rod 83 rotates to rapidly push out soles formed on the upper die block 34, the next double soles are convenient to process, the production efficiency of the soles is improved, then the special-shaped rack bars 82 are separated from the adjusting gear 84, and the second torsion spring 85 resets to drive the swinging rod 83 to reset.

The foregoing has shown and described the basic principles and main features of the present invention and the advantages of the present invention. It will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, and that the above embodiments and descriptions are merely illustrative of the principles of the present invention, and various changes and modifications may be made without departing from the spirit and scope of the invention, which is defined in the appended claims. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims

1. The utility model provides a shoe production device, characterized by, including supporting floor frame (1), abnormal shape fluting support frame (21), hot plate (22), push down and open and shut subassembly (3), push away subassembly (4), material scraping subassembly (5), scrape limit subassembly (6) and break away from subassembly (7), abnormal shape fluting support frame (21) fixed mounting is in supporting floor frame (1) upside, hot plate (22) set up in abnormal shape fluting support frame (21) upside, push down and open and shut subassembly (3) and locate on supporting floor frame (1), push away subassembly (4) and locate on abnormal shape fluting support frame (21) and be connected with push down and open and shut subassembly (3), material scraping subassembly (5) are located on abnormal shape fluting support frame (21), scrape limit subassembly (6) and locate on pushing down and opening and shutting subassembly (3), break away from subassembly (7) to locate on abnormal shape fluting support frame (21).

2. The shoe production device according to claim 1, wherein the pressing opening and closing assembly (3) comprises an electric push rod (31), a T-shaped connecting block (32), a lower die block (33), an upper die block (34) and a first torsion spring (35), two electric push rods (31) are fixedly arranged on the upper side surface of the supporting floor frame (1), the two electric push rods (31) are symmetrically arranged, the special-shaped slotting support frame (21) is located between the two electric push rods (31), the T-shaped connecting block (32) is fixedly connected to the top end of a telescopic shaft of the electric push rod (31), the lower die block (33) is slidably connected to one side, far away from a heating plate (22), of the upper side surface of the special-shaped slotting support frame (21), the upper die block (34) is rotatably connected to one side, close to the heating plate (22), of the lower die block (33), and a plurality of first torsion springs (35) are connected between the upper die block (34) and the lower die block (33).

3. A shoe production device according to claim 2, wherein the pushing assembly (4) comprises a wedge-shaped connecting frame (41) and a first return spring (42), two wedge-shaped connecting frames (41) are fixedly connected to the lower side face of the lower die block (33), the two wedge-shaped connecting frames (41) are symmetrically arranged, the wedge-shaped connecting frames (41) are slidably connected with the special-shaped grooving support frame (21), the wedge-shaped connecting frames (41) are located below the T-shaped connecting blocks (32), and the first return spring (42) is connected between the wedge-shaped connecting frames (41) and the special-shaped grooving support frame (21).

4. A shoe production device according to claim 3, characterized in that the elastic material component (5) comprises an L-shaped grooved frame (51), an arc-shaped pushing plate (52) and a round head top plate frame (53), two L-shaped grooved frames (51) are arranged on one side, close to a heating plate (22), of the upper portion of the special-shaped grooved frame (21), the two L-shaped grooved frames (51) are symmetrically arranged, the arc-shaped pushing plate (52) is connected between the two L-shaped grooved frames (51) in a sliding mode, the upper end of the arc-shaped pushing plate (52) is in contact with the top of a T-shaped connecting block (32), two round head top plate frames (53) are connected on the lower die block (33) in a sliding mode, the bottom ends of the arc-shaped pushing plates (52) are symmetrically arranged, and the round head top plate frames (53) are in contact with the special-shaped grooved frame (21) in a sliding mode.

5. A shoe production device according to claim 4, wherein the edge scraping assembly (6) comprises a grooved sliding rod (61), a second return spring (62) and a wedge-shaped sliding frame (63), a bevel edge fixing frame (64), a third return spring (65), a scraper (66) and a fourth return spring (67), two grooved sliding rods (61) are connected on the lower die block (33) in a sliding mode, two grooved sliding rods (61) are symmetrically arranged, a second return spring (62) is connected between the grooved sliding rod (61) and the lower die block (33), the wedge-shaped sliding frame (63) is connected on the grooved sliding rod (61) in a sliding mode, the wedge-shaped sliding frame (63) is located below the T-shaped connecting block (32), the bevel edge fixing frame (64) is fixedly connected at the lower portion of the wedge-shaped sliding frame (63), the third return spring (65) is connected between the wedge-shaped sliding frame (63) and the grooved sliding rod (61), the two grooved sliding rods (61) are connected with the second return spring (62) in a sliding mode, and the scraper (66) is connected between the lower die block (33) and the fourth return spring (67).

6. The shoe production device according to claim 5, wherein the disengaging assembly (7) comprises a fixed toggle frame (71), a rectangular slotted frame (72), a sliding slotted frame (73), a first homing spring (74), a top movable rack (75), a second homing spring (76) and a rotary gear (77), two fixed toggle frames (71) are fixedly connected to the lower part of the arc pushing plate (52), the two fixed toggle frames (71) are symmetrically arranged, two rectangular slotted frames (72) are fixedly connected to the special slotted supporting frame (21), the two rectangular slotted frames (72) are symmetrically arranged, the sliding slotted frame (73) is connected to the rectangular slotted frame (72) in a sliding mode, the fixed toggle frame (71) is in contact with the sliding slotted frame (73), the first homing spring (74) is connected between the sliding slotted frame (73) and the rectangular slotted frame (72), the top movable rack (75) is connected to the sliding slotted frame (73) in a sliding mode, the two rectangular slotted frames (72) are fixedly connected to the upper inclined side of the fixed rack (73) and the lower slotted frame (34) is connected to the upper inclined side of the fixed rack (73), the two rotary gears (77) are symmetrically arranged.

7. The shoe production device according to claim 6, further comprising a pushing assembly (8), wherein the pushing assembly (8) is arranged on the supporting floor frame (1) and is connected with one of the wedge-shaped sliding frames (63), the pushing assembly (8) comprises an N-shaped perforated frame (81), a special-shaped rack bar (82), a swinging rod (83), an adjusting gear (84) and a second torsion spring (85), the N-shaped perforated frame (81) is fixedly connected to the upper side surface of the supporting floor frame (1), one of the wedge-shaped sliding frames (63) is fixedly connected with the special-shaped rack bar (82), the swinging rod (83) is rotatably connected to the upper portion of the N-shaped perforated frame (81), the adjusting gear (84) is fixedly connected to the bottom end of the swinging rod (83), the adjusting gear (84) is meshed with the special-shaped rack bar (82), and the second torsion spring (85) is connected between the swinging rod (83) and the N-shaped perforated frame (81).