CN113562509A

CN113562509A - Synchronous clout coiling mechanism of automatic unloading is used in shoe-pad production

Info

Publication number: CN113562509A
Application number: CN202110844006.7A
Authority: CN
Inventors: 周志福
Original assignee: Individual
Current assignee: Hunan Jiantai Shoes Manufacturing Co ltd
Priority date: 2021-07-26
Filing date: 2021-07-26
Publication date: 2021-10-29
Anticipated expiration: 2041-07-26
Also published as: CN113562509B

Abstract

The invention discloses an automatic blanking synchronous excess material winding device for insole production, which comprises insole processing equipment, insole raw materials, an insole cutter, a limiting support frame, a trigger device, an excess material guide frame, a splicing frame and a cutting blade, wherein one end face of the limiting support frame is fixedly connected to the center of the side face of the insole processing equipment, the insole raw materials are spliced in the center of the side face of the insole processing equipment in a sliding mode, the insole cutter is installed on the edge of the upper portion of the side face of the insole processing equipment in a sliding mode, the trigger device is installed in the center of the limiting support frame in a sliding mode, the splicing frame is installed in the limiting support frame in a sliding mode and located on the edge of one side of the trigger device, and the cutting blade is installed in the limiting support frame in a sliding mode and located between the trigger device and the splicing frame. According to the automatic cutting and winding device, the automatic blanking of the insoles can be realized, the work efficiency of the insole blanking can be improved, meanwhile, the excess materials can be automatically cut and wound, and the excess materials are prevented from being accumulated on the ground.

Description

Synchronous clout coiling mechanism of automatic unloading is used in shoe-pad production

Technical Field

The invention relates to the technical field of insole production and blanking equipment, in particular to an automatic blanking synchronous excess material winding device for insole production.

Background

The insole is applied to the shoemaking industry in a large number, health care, special function, generally divide into shoemaking industry application type shoe factory application type insole and market commodity type two kinds of modes, the insole that shoemaking industry was used mainly cooperates the shoes outsole, the insole, make corresponding type, make the size board according to shoe last bottom plate or panel, and make corresponding shape, market commodity type insole is mainly that the insole is direct as a commodity and sells, by the design of developer, the product of circulation on the market, wherein the primary importance of insole, can improve the comfort level that people wore shoes, and the insole is when processing production, need processing equipment to carry out the batch cutting to the insole raw materials, thereby can obtain a large amount of insoles fast, and improve the productivity ratio of insole.

However, the existing insole processing equipment has some defects in the using process, such as:

firstly, when the existing insole is processed and produced, the insole blanking efficiency is low, in addition, the insole after blanking can not be transported in a centralized way, the insole can not be blanked automatically, and the redundant operation of insole blanking is increased, so that the insole production capacity is influenced;

secondly, after shoe-pad cutting process, can not carry out synchronous rolling to remaining raw materials, lead to easily that remaining raw materials piles up on ground, can not carry out automatic cutting to remaining raw materials moreover to influence processing equipment's normal operating, so need a synchronous clout coiling mechanism of automatic unloading for shoe-pad production, in order to solve the problem that proposes in the aforesaid.

Disclosure of Invention

The invention aims to provide an automatic blanking synchronous excess material winding device for insole production, which aims to solve the problems in the background technology.

In order to achieve the purpose, the invention provides the following technical scheme: an automatic blanking synchronous excess material winding device for insole production comprises insole processing equipment, insole raw materials, an insole cutter, a limiting support frame, a triggering device, an excess material guide frame, a splicing frame and a cutting blade, wherein one end face of the limiting support frame is fixedly connected to the side center of the insole processing equipment;

a trough is fixedly installed at the inner bottom center of the limiting support frame, a conveying belt is rotatably sleeved at the inner bottom center of the trough, transmission rods are rotatably installed at the inner edges of two ends of the conveying belt, a threaded rod is rotatably installed at the bottom side edge of the limiting support frame, a limiting bracket is welded at the bottom side edge of one end of the limiting support frame, a second driving motor is fixedly installed at the bottom of the other end of the limiting support frame and at one end of the threaded rod, a winding main shaft is rotatably installed at the side center of the limiting support frame, a first gear is fixedly connected to one end face of the winding main shaft, a first transmission belt is sleeved on the outer surface of the first gear, limiting frames are symmetrically welded at the inner center of the limiting support frame and at two ends of the side edge of the winding main shaft, and a first driving motor is fixedly installed at the side center edge of the limiting support frame, a second transmission belt is rotatably sleeved on the outer surface of the edge of one end of the first driving motor, a transmission rod is rotatably mounted on the bottom edge of the side edge of one end face of the limiting support frame, helical gears are fixedly connected to one end of the transmission rod and one end of the transmission rod, and a third transmission belt is rotatably sleeved on the outer surface of the middle part of the transmission rod;

a positioning rod is fixedly installed inside the trigger device, a limiting sleeve is uniformly and fixedly connected to the outer surface of the positioning rod, a pushing plate is inserted into the inner center of the limiting sleeve in a sliding mode, a first reset spring is sleeved on the outer surface of the edge of the upper portion of the pushing plate, transmission shafts are rotatably installed on the upper portions of the two ends of the positioning rod, a lug is uniformly and fixedly connected to the outer surface of each transmission shaft, a second gear is fixedly connected to the outer surface of the edge of one end of each transmission shaft, a connecting rod is welded to the outer surface of the edge of the bottom of the pushing plate, and a cover plate is fixedly connected to one end face of each connecting rod;

the edge of the bottom end of the interior of the excess material guide frame is welded with a limiting guide rod, the outer surface of the edge of the upper part of one end of the excess material guide frame is provided with a sleeve, the center of the interior of the excess material guide frame is welded with an arc-shaped supporting plate, and the center of the top of one end face of the excess material guide frame is welded with a blanking plate;

a top rod is fixedly arranged in the insertion frame, two end faces of the top rod are fixedly connected with a T-shaped support, an insertion rod is inserted into the top face of the T-shaped support in a sliding manner, and an insertion block is fixedly connected to the top end face of the insertion rod;

cutting blade's top end face fixedly connected with roof, cutting blade's side has evenly seted up spacing spout, the inside center fixedly connected with gag lever post of spacing spout, the surface of gag lever post has cup jointed the extrusion spring.

Preferably, the roller is carried to first driving motor's one end fixedly connected with, the inside one end fixedly connected with second reset spring of spacing frame, the inside of spacing support frame and the both ends bottom surface edge fixed mounting who is located cutting blade have control switch.

Preferably, the second gears at one end of the transmission shaft are divided into two groups which are rotatably sleeved with the inner surfaces of one ends of the first transmission belt and the second transmission belt, and the bottom end of the insertion rod is fixedly connected with a third return spring.

Preferably, the transfer line rotates with first driving motor one end edge surface mutually through the third driving belt of surface and is connected, the clout leading truck slides mutually through the lower flitch of one end and the outside of rolling main shaft and cup joints, limit bracket's surface fixed mounting has reset switch.

Preferably, the transmission rod is meshed and connected with the bevel gear on the outer surface of the edge of one end of the transmission rod through the bevel gear on one end, and a cutting clamping groove is formed in the limiting support frame and is located at the edge of the limiting frame.

Preferably, the two ends of the transmission shaft are rotatably inserted into the two end faces inside the limiting support frame, and the two ends of the positioning rod are fixedly connected with the two end faces inside the limiting support frame.

Preferably, the outer surface of the upper part of the material pushing plate is fixedly connected with an extrusion plate, the transmission shaft is movably abutted against the top end face of the material pushing plate through a convex block on the outer surface, and the bottom end of the material pushing plate is positioned right above the trough in the limiting support frame.

Preferably, the clout guide frame slides mutually with a terminal surface of rolling main shaft through the sleeve of one end and pegs graft, the one end bottom surface fixedly connected with gyro wheel of clout guide frame, threaded hole is seted up to another terminal surface bottom central surface of clout guide frame, the clout guide frame is through the screw hole of one end and the outside surface looks spiral shell of threaded rod and is cup jointed.

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

one, through cutting blade's rotation operation, can make scraping wings oscilaltion, thereby promote the shoe-pad after the cutting, thereby prevent that shoe-pad and surplus raw materials can not separate, the apron that can drive connecting rod one end simultaneously slides from top to bottom, and prepare constantly to extrude the grafting piece and extrude the surface of roof, thereby make the cutting blade of being convenient for cut surplus raw materials, when the surplus material tape measure increase extrusion ejector pin of rolling main shaft surface, can make the grafting piece slide to between apron and the roof, make cutting blade descend and cut, thereby the realization is rolled up the automation cutting unloading of going on to the surplus.

Two, through the rotation operation of transmission shaft, can make the lug of surface rotate, the lug can be interrupted the extrusion to the top of scraping wings simultaneously, guarantee that the bottom of scraping wings carries out the oscilaltion, thereby guarantee that the shoe-pad after the cutting is whole to fall into the inside of silo, and the conveyer belt can concentrate the transportation to the inside shoe-pad that gets into the silo, thereby improve the work efficiency to the shoe-pad unloading, wherein the arc layer board can be accepted the clout book that breaks away from rolling main shaft surface, thereby prevent that the clout book from scattering and influencing follow-up collection work.

Drawings

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

FIG. 2 is a schematic view of a structure of a position-limiting support frame according to the present invention;

FIG. 3 is a side view of the spacing support of the present invention;

FIG. 4 is a schematic structural diagram of a triggering device according to the present invention;

FIG. 5 is a schematic view of the remainder guide structure of the present invention;

FIG. 6 is a schematic view of the structure of the plugging frame of the present invention;

figure 7 is a schematic view of a cutting blade of the present invention in section.

In the figure: 1-insole processing equipment, 2-insole raw material, 3-insole cutter, 4-limit support frame, 5-trigger device, 6-excess material guide frame, 7-plug frame, 8-cutting blade, 9-first transmission belt, 10-second transmission belt, 11-first drive motor, 12-trough, 13-conveying belt, 14-transmission rod, 15-second drive motor, 16-first gear, 17-threaded rod, 18-limit bracket, 19-winding spindle, 20-limit frame, 21-third transmission belt, 22-transmission rod, 23-helical gear, 24-cover plate, 25-connecting rod, 26-material pushing plate, 27-transmission shaft, 28-first return spring, 29-lug, etc, 30-positioning rod, 31-second gear, 32-limiting sleeve, 33-arc supporting plate, 34-blanking plate, 35-limiting guide rod, 36-sleeve, 37-T type support, 38-plug rod, 39-plug block, 40-ejector rod, 41-top plate, 42-extrusion spring, 43-limiting rod and 44-limiting sliding groove.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1-7, an embodiment of the present invention is shown: an automatic blanking synchronous excess material winding device for insole production comprises insole processing equipment 1, insole raw materials 2, an insole cutter 3 and a limiting support frame 4, the insole cutting device comprises a trigger device 5, a residual material guide frame 6, an inserting frame 7 and a cutting blade 8, wherein one end face of a limiting support frame 4 is fixedly connected to the center of the side face of insole processing equipment 1, an insole raw material 2 is inserted into the center of the side face of the insole processing equipment 1 in a sliding manner, an insole cutter 3 is installed at the edge of the upper portion of the side face of the insole processing equipment 1 in a sliding manner, the trigger device 5 is installed at the center of the inside of the limiting support frame 4 in a sliding manner, the inserting frame 7 is installed inside the limiting support frame 4 in a sliding manner and is located at the edge of one side face of the trigger device 5, the cutting blade 8 is installed inside the limiting support frame 4 in a sliding manner and is located between the trigger device 5 and the inserting frame 7, and the residual material guide frame 6 is installed at the edge of the bottom of one end face of the limiting support frame 4 in a sliding manner;

a trough 12 is fixedly installed at the center of the inner bottom end of the limit support frame 4, a conveying belt 13 is rotatably sleeved at the center of the inner bottom end of the trough 12, transmission rods 14 are rotatably installed at the inner edges of two ends of the conveying belt 13, a threaded rod 17 is rotatably installed at the edge of the side surface of the bottom of the limit support frame 4, a limit bracket 18 is welded at the edge of the side surface of one end of the limit support frame 4, a second driving motor 15 is fixedly installed at the bottom of the other end of the limit support frame 4 and at one end of the threaded rod 17, a winding main shaft 19 is rotatably installed at the center of the side surface of the limit support frame 4, a first gear 16 is fixedly connected to one end surface of the winding main shaft 19, a first driving belt 9 is sleeved on the outer surface of the first gear 16, limit frames 20 are symmetrically welded at two ends of the inner center of the limit support frame 4 and at the side surface edge of the winding main shaft 19, and a first driving motor 11 is fixedly installed at the edge of the side surface of the limit support frame 4, a second transmission belt 10 is rotatably sleeved on the outer surface of the edge of one end of the first driving motor 11, a transmission rod 22 is rotatably installed on the bottom edge of the side edge of one end face of the limiting support frame 4, helical gears 23 are fixedly connected to one end of the transmission rod 14 and one end of the transmission rod 22, and a third transmission belt 21 is rotatably sleeved on the outer surface of the middle part of the transmission rod 22;

a positioning rod 30 is fixedly installed inside the trigger device 5, a limiting sleeve 32 is uniformly and fixedly connected to the outer surface of the positioning rod 30, a material pushing plate 26 is inserted in the inner center of the limiting sleeve 32 in a sliding mode, a first reset spring 28 is sleeved on the outer surface of the edge of the upper portion of the material pushing plate 26, transmission shafts 27 are rotatably installed on the upper portions of two ends of the positioning rod 30, bumps 29 are uniformly and fixedly connected to the outer surface of the transmission shafts 27, a second gear 31 is fixedly connected to the outer surface of the edge of one end of each transmission shaft 27, a connecting rod 25 is welded to the outer surface of the edge of the bottom of the material pushing plate 26, and a cover plate 24 is fixedly connected to one end face of each connecting rod 25;

a limiting guide rod 35 is welded at the edge of the bottom end inside the excess material guide frame 6, a sleeve 36 is arranged on the outer surface of the edge of the upper part of one end of the excess material guide frame 6, an arc-shaped supporting plate 33 is welded at the center inside the excess material guide frame 6, and a blanking plate 34 is welded at the center of the top of one end face of the excess material guide frame 6;

an ejector rod 40 is fixedly installed inside the inserting frame 7, two end faces of the ejector rod 40 are fixedly connected with a T-shaped support 37, an inserting rod 38 is inserted into the top face of the T-shaped support 37 in a sliding mode, and an inserting block 39 is fixedly connected to the top end face of the inserting rod 38;

cutting blade 8's top terminal surface fixedly connected with roof 41, cutting blade 8's side has evenly seted up spacing spout 44, and the inside center fixedly connected with gag lever post 43 of spacing spout 44, the surface of gag lever post 43 has cup jointed extrusion spring 42.

One end of the first driving motor 11 is fixedly connected with a conveying roller shaft, one end of the inside of the limiting frame 20 is fixedly connected with a second reset spring, the inside of the limiting support frame 4 and the edges of the bottom surfaces of the two ends of the cutting blade 8 are fixedly provided with a control switch, a second gear 31 at one end of the transmission shaft 27 is divided into two groups which are rotatably sleeved with the inner surfaces of one ends of the first transmission belt 9 and the second transmission belt 10, a third reset spring fixedly connected with the bottom end of the inserting rod 38 can provide power for the resetting of the inserting block 39, the transmission rod 22 is rotatably connected with the outer surface of one end edge of the first driving motor 11 through a third transmission belt 21 on the outer surface, the excess material guide frame 6 is slidably sleeved with the outer surface of the winding main shaft 19 through a blanking plate 34 at one end, the outer surface of the limiting bracket 18 is fixedly provided with a reset switch, the transmission rod 14 is meshed with a bevel gear 23 on the outer surface of one end edge of the transmission rod 22 through a bevel gear 23 at one end, the inside of the limit support frame 4 and the cutting clamping groove arranged at the edge of the limit frame 20 can limit the up-and-down sliding of the cutting blade 8, and prevent the cutting blade 8 from shifting when sliding, the two ends of the transmission shaft 27 are rotatably inserted with the two internal end faces of the limit support frame 4, the two ends of the positioning rod 30 are fixedly connected with the two internal end faces of the limit support frame 4, and can play a role in supporting and limiting the whole trigger device 5, the upper outer surface of the material pushing plate 26 is fixedly connected with the extrusion plate, the transmission shaft 27 is movably abutted with the top end face of the material pushing plate 26 through the convex block 29 of the outer surface, the bottom end of the material pushing plate 26 is arranged right above the trough 12 in the limit support frame 4, and can push the insole into the trough 12 accurately when the material pushing plate 26 slides up and down, the residual material guide frame 6 is slidably inserted with one end face of the winding main shaft 19 through the sleeve 36 at one end, the one end bottom surface fixedly connected with gyro wheel of clout guide frame 6, the screw hole has been seted up to another terminal surface bottom central surface of clout guide frame 6, and clout guide frame 6 cup joints with the outside surface of threaded rod 17 mutually the spiral through the screw hole of one end, can make clout guide frame 6 under the rotation control of threaded rod 17, promotes clout material and rolls up the unloading and carry out reciprocating sliding.

The working principle is as follows: when processing and producing insoles, the insole processing equipment 1 can control the insole cutter 3 to cut the insole raw materials 2 in batches, when the insole processing equipment 1 is powered on, the first driving motor 11 can drive the conveying roller shaft at one end to convey the insole raw materials 2 discontinuously, so that the insole cutter 3 can be ensured to stably cut the insole raw materials 2, the cut insoles can be conveyed together with the residual raw materials until the insoles move to the upper surface of the trough 12, meanwhile, the insoles are separated from the residual raw materials under the action of gravity and fall into the trough 12, meanwhile, the first driving motor 11 can drive the transmission shaft 27 to rotate through the second transmission belt 10 and the second gear 31, the transmission shaft 27 can extrude the top end of the material pushing plate 26 when rotating for one circle, so that the bottom end of the material pushing plate 26 descends to push the cut insoles, thereby preventing the insole from being unable to be separated from the residual raw material, when the material pushing plate 26 descends, the first return spring 28 is extruded by the extrusion block on the outer surface to shrink downwards, meanwhile, the limiting sleeve 32 limits the sliding material pushing plate 26, when the material pushing plate 26 descends, the cover plate 24 on one end is driven by the connecting rod 25 on the outer surface to descend together, then when the projection 29 rotates to be separated from the top end of the material pushing plate 26, the material pushing plate 26 slides upwards to return under the elastic action of the first return spring 28, so that the material pushing plate 26 pushes the insole below discontinuously, then one end of the residual raw material is pulled to be wound with the outer surface of the winding main shaft 19, when the transmission shaft 27 rotates, the first transmission belt 9 on the outer surface is driven to rotate by the second gear 31 on one end, and when the first transmission belt 9 rotates, the threaded rod 17 is driven by the first gear 16 on one end to wind the residual raw material, when the first driving motor 11 rotates, the third driving belt 21 on the outer surface drives the transmission rod 22 at the bottom end to rotate, meanwhile, the transmission rod 22 drives the bevel gear 23 at one end of the transmission rod 14 to synchronously rotate through the bevel gear 23 at one end, and when the transmission rod 14 rotates, the transmission belt 13 sleeved on the outer surface is driven to rotate at the inner bottom end of the material groove 12, so that the transmission belt 13 intensively conveys the insoles falling into the material groove 12 to one end of the material groove 12 for centralized collection, after the insoles are produced for a long time, the diameter of the residual raw materials wound on the outer surface of the winding main shaft 19 is increased, so that the outer surface of the residual raw materials extrudes the ejector rod 40 positioned at the upper part of the arc-shaped supporting plate 33 to transversely slide, meanwhile, one end of the ejector rod 40 extrudes the second return spring inside the limiting frame 20 to shrink, and meanwhile, the ejector rod 40 drives the insertion block 39 at the top end of the insertion rod 38 to slide through the T-shaped supports 37 at the two ends, therefore, the plug block 39 transversely slides between the cover plate 24 and the top plate 41, because the cover plate 24 intermittently ascends and descends along with the material pushing plate 26, when the plug block 39 slides between the cover plate 24 and the top plate 41, the cover plate 24 extrudes the upper surface of the plug block 39 when descending, the plug block 39 extrudes the third return spring to shrink when descending, and simultaneously the plug block 39 is pressed to descend and extrude the upper surface of the bottom top plate 41, so that the cutting blade 8 descends in the cutting groove to cut the upper surface of the residual raw material, and simultaneously the extrusion spring 42 extruding the outer surface of the limit rod 43 contracts, when the cutting blade 8 descends to the lowest end, the control switch of the second driving motor 15 is extruded, so that the second driving motor 15 operates to drive the threaded rod 17 at one end to rotate, and simultaneously the residual material guide frame 6 continuously slides on the outer surface of the threaded rod 17 through the surface threaded hole at one end, the excess material guide frame 6 can push the excess raw material roll on the outer surface of the winding main shaft 19 to move together through the blanking plate 34 at one end while sliding, the sleeve 36 at one end of the excess material guide frame 6 can be separated from one end surface of the winding main shaft 19 until one end of the excess material guide frame 6 is in contact with the inner side surface of the limiting bracket 18, one end of the excess raw material roll can be separated from the outer surface of the winding main shaft 19 and fall onto the upper surface of the arc-shaped supporting plate 33, meanwhile, one end of the excess material guide frame 6 can press the reset switch on the outer surface of the limiting bracket 18, so that the second driving motor 15 drives the threaded rod 17 to rotate reversely, meanwhile, the excess material guide frame 6 can reset and slide on the outer surface of the threaded rod 17, when the excess raw material roll is separated from the outer surface of the winding main shaft 19, the extrusion force on the outer surface of the ejector rod 40 can be removed, and the inserting frame 7 can slide and reset under the elastic force of the second reset spring, when the inserting block 39 is separated from the space between the cover plate 24 and the top plate 41, the cutting blade 8 can slide upwards to reset under the elastic force of the extrusion spring 42, and then one end of the residual raw material is continuously wound and connected with the outer surface of the winding main shaft 19, so that the automatic discharging of the insole and the automatic winding of the residual raw material are realized, the work efficiency of the insole discharging is improved, and the step of the insole discharging is simplified.

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

Claims

1. The utility model provides a synchronous clout coiling mechanism of automatic unloading for shoe-pad production, includes shoe-pad processing equipment (1), shoe-pad raw materials (2), shoe-pad cutterbar (3), spacing support frame (4), trigger device (5), clout leading truck (6), grafting frame (7) and cutting blade (8), its characterized in that: one end face of the limiting support frame (4) is fixedly connected to the center of the side face of the insole processing equipment (1), the insole raw materials (2) are inserted into the center of the side face of the insole processing equipment (1) in a sliding mode, the insole cutter (3) is installed on the edge of the upper portion of the side face of the insole processing equipment (1) in a sliding mode, the trigger device (5) is installed in the center of the interior of the limiting support frame (4) in a sliding mode, the inserting frame (7) is installed in the limiting support frame (4) in a sliding mode and located on the edge of one side face of the trigger device (5), the cutting blade (8) is installed in the limiting support frame (4) in a sliding mode and located between the trigger device (5) and the inserting frame (7), and the excess material guide frame (6) is installed on the edge of the bottom of one end face of the limiting support frame (4) in a sliding mode;

the automatic winding machine is characterized in that a trough (12) is fixedly mounted at the inner bottom center of the limiting support frame (4), a conveying belt (13) is sleeved at the inner bottom center of the trough (12) in a rotating mode, a transmission rod (14) is mounted at the inner edges of two ends of the conveying belt (13) in a rotating mode, a threaded rod (17) is mounted at the bottom side edge of the limiting support frame (4) in a rotating mode, a limiting bracket (18) is welded at the bottom side edge of one end of the limiting support frame (4), a second driving motor (15) is fixedly mounted at the bottom of the other end of the limiting support frame (4) and at one end of the threaded rod (17), a winding spindle (19) is mounted at the side center of the limiting support frame (4) in a rotating mode, a first gear (16) is fixedly connected to one end face of the winding spindle (19), and a first transmission belt (9) is sleeved on the outer surface of the first gear (16), the winding mechanism is characterized in that limiting frames (20) are symmetrically welded at the two ends of the side edge of the winding main shaft (19) and at the inner center of the limiting support frame (4), a first driving motor (11) is fixedly installed at the side center edge of the limiting support frame (4), a second transmission belt (10) is rotatably sleeved on the outer surface of the edge of one end of the first driving motor (11), a transmission rod (22) is rotatably installed at the bottom edge of the side edge of one end face of the limiting support frame (4), helical gears (23) are fixedly connected at one end of the transmission rod (14) and one end of the transmission rod (22), and a third transmission belt (21) is rotatably sleeved on the outer surface of the middle part of the transmission rod (22);

a positioning rod (30) is fixedly installed inside the trigger device (5), a limiting sleeve (32) is uniformly and fixedly connected to the outer surface of the positioning rod (30), a material pushing plate (26) is inserted into the center of the inside of the limiting sleeve (32) in a sliding mode, a first reset spring (28) is sleeved on the outer surface of the edge of the upper portion of the material pushing plate (26), transmission shafts (27) are rotatably installed on the upper portions of the two ends of the positioning rod (30), bumps (29) are uniformly and fixedly connected to the outer surface of the transmission shaft (27), a second gear (31) is fixedly connected to the outer surface of the edge of one end of the transmission shaft (27), a connecting rod (25) is welded to the outer surface of the edge of the bottom of the material pushing plate (26), and a cover plate (24) is fixedly connected to one end face of the connecting rod (25);

a limiting guide rod (35) is welded at the edge of the bottom end inside the excess material guide frame (6), a sleeve (36) is arranged on the outer surface of the edge of the upper portion of one end of the excess material guide frame (6), an arc-shaped supporting plate (33) is welded at the center inside the excess material guide frame (6), and a blanking plate (34) is welded at the center of the top of one end face of the excess material guide frame (6);

a top rod (40) is fixedly installed inside the inserting frame (7), two end faces of the top rod (40) are fixedly connected with a T-shaped support (37), an inserting rod (38) is inserted into the top face of the T-shaped support (37) in a sliding mode, and an inserting block (39) is fixedly connected to the top end face of the inserting rod (38);

cutting blade (8) top terminal surface fixedly connected with roof (41), spacing spout (44) have evenly been seted up to cutting blade (8) side, the inside center fixedly connected with gag lever post (43) of spacing spout (44), extrusion spring (42) have been cup jointed to the surface of gag lever post (43).

2. The automatic blanking synchronous excess material winding device for insole production according to claim 1, characterized in that: the one end fixedly connected with of first driving motor (11) carries the roller, the inside one end fixedly connected with second reset spring of spacing frame (20), the inside of spacing support frame (4) and the both ends bottom surface edge fixed mounting that is located cutting blade (8) have control switch.

3. The automatic blanking synchronous excess material winding device for insole production according to claim 2, characterized in that: the second gears (31) at one end of the transmission shaft (27) are divided into two groups and rotatably sleeved with the inner surfaces of one ends of the first transmission belt (9) and the second transmission belt (10), and the bottom end of the insertion rod (38) is fixedly connected with a third return spring.

4. The automatic blanking synchronous excess material winding device for insole production according to claim 3, characterized in that: the transmission rod (22) is rotatably connected with the outer surface of the edge of one end of the first driving motor (11) through a third transmission belt (21) on the outer surface, the excess material guide frame (6) is sleeved with the outer surface of the winding spindle (19) through a blanking plate (34) at one end in a sliding mode, and a reset switch is fixedly mounted on the outer surface of the limiting bracket (18).

5. The automatic blanking synchronous excess material winding device for insole production according to claim 4, characterized in that: the transmission rod (14) is meshed and connected with the bevel gear (23) on the outer surface of the edge of one end of the transmission rod (22) through the bevel gear (23) on one end, and a cutting clamping groove is formed in the limiting support frame (4) and is located on the edge of the limiting frame (20).

6. The automatic blanking synchronous excess material winding device for insole production according to claim 5, characterized in that: the two ends of the transmission shaft (27) are rotatably inserted into the two inner end faces of the limiting support frame (4), and the two ends of the positioning rod (30) are fixedly connected with the two inner end faces of the limiting support frame (4).

7. The automatic blanking synchronous excess material winding device for insole production according to claim 6, characterized in that: the outer surface of the upper part of the material pushing plate (26) is fixedly connected with an extrusion plate, the transmission shaft (27) is movably abutted against the top end face of the material pushing plate (26) through a convex block (29) on the outer surface, and the bottom end of the material pushing plate (26) is positioned right above the trough (12) in the limiting support frame (4).

8. The automatic blanking synchronous excess material winding device for insole production according to claim 7, characterized in that: surplus material guide frame (6) are through sleeve (36) of one end and the smooth grafting of a terminal surface of rolling main shaft (19) mutually, the one end bottom surface fixedly connected with gyro wheel of surplus material guide frame (6), threaded hole is seted up to another terminal surface bottom center surface of surplus material guide frame (6), the outside surface of surplus material guide frame (6) through the screw hole of one end and threaded rod (17) is cup jointed spirally mutually.