CN114247531A

CN114247531A - Automobile-used silica foot pad recycling and crushing device

Info

Publication number: CN114247531A
Application number: CN202111474794.1A
Authority: CN
Inventors: 詹兴帆
Original assignee: Individual
Current assignee: Individual
Priority date: 2021-12-06
Filing date: 2021-12-06
Publication date: 2022-03-29

Abstract

The invention relates to the field of automobiles, in particular to a device for recovering and crushing a silica foot pad for an automobile. The technical problem of the invention is that: only the paint on one side is removed, and before loading, an operator turns the surface of the silica foot pad with the paint upwards, and then the surface is conveyed to the lower part of the cleaning device for removing the paint. The technical implementation scheme of the invention is as follows: a silica foot pad recovery and crushing device for an automobile comprises a first rack, a second rack, a third rack and the like; a second frame is fixedly connected to the right side of the first frame; the right side of the second frame is fixedly connected with a third frame. The feeding and sorting system is designed, so that the broken silica foot pads are subjected to size screening, a small amount of water is sprayed, and then the large silica foot pads with paint at the bottoms are folded, so that the paint can be conveniently treated by the conveying system.

Description

Automobile-used silica foot pad recycling and crushing device

Technical Field

The invention relates to the field of automobiles, in particular to a device for recovering and crushing a silica foot pad for an automobile.

Background

The silica foot pad is a recyclable resource, and the treatment steps after recycling are as follows: the paint on the broken silica foot pad is removed, after the removal is finished, the broken silica foot pad is broken, after the breaking is finished, the finished silica foot pad is formed through a series of processing and forming processes, and the finished silica foot pad can be put into the market again, if a large amount of paint is not removed on the silica foot pad, the broken silica foot pad can be taken out and broken, and the influence on the manufactured product can be caused, in the prior art, the paint removing method for the silica foot pad only comprises the steps of removing the paint on a single surface, turning the surface with the paint on the silica foot pad upwards before loading by an operator, then conveying the silica foot pad to the lower part of a removing device, and removing the paint by the operator, wherein the method needs the operator to inspect all the silica foot pads in advance, place the surface with the paint on the silica foot pad in the same direction, and after the preparation in advance, break the broken silica foot pad, spend a large amount of time and manpower in the preparation process in advance, the efficiency is low.

Disclosure of Invention

The invention provides a device for recovering and crushing a silica foot pad for an automobile, aiming at overcoming the defect that an operator is required to turn the surface with paint on the silica foot pad upwards before loading, and then convey the silica foot pad to the lower part of a cleaning device for cleaning the paint.

The technical implementation scheme of the invention is as follows: a silica foot pad recovery and crushing device for an automobile comprises a first rack, a second rack, a third rack, a feeding and sorting system, a conveying system and a crushing system; a second frame is fixedly connected to the right side of the first frame; a third frame is fixedly connected to the right side of the second frame; a feeding and sorting system is fixedly connected to the left part of the upper side of the first frame and is used for screening large silica foot pads; the conveying system is arranged on the right part of the upper side of the first machine frame and used for conveying the silica foot pad into the crushing system; and the second rack and the third rack are connected with a crushing system, and the crushing system is used for crushing the silica foot pad.

Optionally, the feeding sorting system comprises a support frame assembly, a first mounting bracket, a feeding bracket, a screening bracket, a second mounting bracket, a sprayer, a first support frame, a first material guide bracket, a vibration motor and a turnover assembly; a support frame component is fixedly connected to the left part of the upper side of the first frame; a first mounting bracket is fixedly connected to the left side of the support frame component; a feeding support is fixedly connected to the upper side of the first mounting support; the upper part of the supporting frame component is fixedly connected with a screening bracket; the right part of the feeding bracket is contacted with the screening bracket; the middle part of the screening bracket is fixedly connected with a second mounting bracket; two sprayers are fixedly connected to the upper part of the second mounting bracket; a first support frame is fixedly connected to the left part of the upper side of the first frame, and the first support frame is positioned between the support frame components; a first material guide bracket is fixedly connected to the upper side of the first support bracket; a vibration motor is fixedly connected to the right part of the lower side of the screening bracket; the screening support is connected with a turnover assembly.

Optionally, the overturning assembly comprises a third mounting bracket, a first mounting plate, a first motor, a first support plate, a shaft sleeve, a spline shaft, a second support plate, a first electric push rod, a third support plate, a push plate, a fourth mounting bracket, a first magnetic attraction block, a first rotating plate, a first mounting block, a second electric push rod, a fifth mounting bracket, a second magnetic attraction block and a second rotating plate; a third mounting bracket is fixedly connected to the front part of the lower side of the screening bracket; the front part of the third mounting bracket is fixedly connected with a first mounting plate; a first motor is fixedly connected to the front side of the first mounting plate; the first motor penetrates through the first mounting plate through an output shaft and is in rotating connection with the first mounting plate; the front part of the third mounting bracket is fixedly connected with a first supporting plate which is positioned behind the first mounting plate; the first supporting plate is fixedly connected with a shaft sleeve; the first motor is fixedly connected with the shaft sleeve through an output shaft; a spline shaft is connected to the shaft sleeve in a sliding manner; the spline shaft penetrates through the screening bracket and is rotationally connected with the screening bracket; a second supporting plate is fixedly connected to the right part of the third mounting bracket; a first electric push rod is fixedly connected to the rear side of the second supporting plate; a third support plate is fixedly connected to the right part of the third mounting bracket and is positioned behind the second support plate; the second supporting plate is fixedly connected with the first electric push rod; the first electric push rod is fixedly connected with a push plate through a telescopic part; the spline shaft is rotationally connected with the left part of the push plate; a fourth mounting bracket is fixedly connected to the front side and the rear side of the screening bracket respectively; the spline shaft penetrates through the fourth mounting bracket and is rotationally connected with the fourth mounting bracket; a first magnetic suction block is fixedly connected to the two fourth mounting brackets; the opposite sides of the two first magnetic suction blocks are fixedly connected with the screening bracket; the two first magnetic suction blocks suck a first rotating plate through magnetic force; the front side and the rear side of the screening support are respectively fixedly connected with a first mounting block, and the two first mounting blocks are positioned above the two fourth mounting supports; two second electric push rods are fixedly connected to the upper sides of the two first mounting blocks; the two second electric push rods are fixedly connected with a fifth mounting bracket through telescopic parts; a second magnetic suction block is fixedly connected to the front part of the lower side and the rear part of the lower side of the fifth mounting bracket respectively; the two second magnetic blocks attract one second rotating plate through magnetic force.

Optionally, the support frame assembly comprises a second support frame, a small sliding block and a first elastic piece; a second support frame is fixedly connected to the left part of the upper side of the first frame; the two left supporting plates of the second supporting frame are fixedly connected with the screening bracket; the upper parts of the two supporting plates on the right of the second supporting frame are connected with two small sliding blocks in a sliding manner, and the two small sliding blocks slide in the two sliding grooves; two first elastic pieces are fixedly connected to the upper side and the lower side of each small sliding block; the eight first elastic pieces are fixedly connected with the two supporting plates on the right of the second supporting frame; the opposite sides of the two small sliding blocks are fixedly connected with the screening bracket.

Optionally, the conveying system comprises a third supporting frame, a first conveyor, a second material guiding support, a third material guiding support and a paint removing assembly; a third supporting frame is fixedly connected to the right part of the upper side of the first frame; the upper part of the third supporting frame is fixedly connected with a first conveyor; the lower part of the third support frame is fixedly connected with a second conveyor; a second material guide bracket is fixedly connected to the upper part of the right side of the third support frame; a third material guide bracket is fixedly connected to the lower part of the right side of the third support frame; the first conveyor is connected with a paint removing assembly.

Optionally, the paint removing assembly comprises a sixth mounting bracket, a spring column, a second mounting plate, a third electric push rod, a clamping block, a seventh mounting bracket, a first electric slide rail, a first electric slide block, a first mounting seat, an electric rotating shaft and a milling cutter; a sixth mounting bracket is fixedly connected to the front side and the rear side of the first conveyor respectively; two spring columns are inserted into the two sixth mounting brackets respectively; a second mounting plate is fixedly connected to the upper sides of the two front spring columns; the upper sides of the two rear spring columns are fixedly connected with another second mounting plate; the lower sides of the two second mounting plates are in contact with the upper sides of the two sixth mounting brackets; the left part and the right part of the two second mounting plates are respectively fixedly connected with a third electric push rod; the front two third electric push rods are fixedly connected with a clamping block through a telescopic part; the two third electric push rods at the rear part are fixedly connected with another clamping block through a telescopic part; a seventh mounting bracket is fixedly connected to the upper sides of the two second mounting plates; a first electric slide rail is fixedly connected to the seventh mounting bracket; the outer surface of the first electric sliding rail is connected with a first electric sliding block in a sliding manner; a first mounting seat is fixedly connected to the left side of the first electric sliding block; an electric rotating shaft is fixedly connected to the first mounting seat; the lower side of the electric rotating shaft is fixedly connected with a milling cutter.

Optionally, the crushing system comprises a crushing barrel, a discharging plate, a striker plate, an eighth mounting bracket, a second motor, a bevel gear, a first crushing cutter, a fluted disc, a second crushing cutter, a second mounting seat, an inclined plate, an arc-shaped strip, a second elastic piece and a sealing assembly; the upper part of the second frame is fixedly connected with a crushing barrel; the upper part of the crushing barrel is fixedly connected with the second material guide bracket; the middle part of the crushing barrel is fixedly connected with a third material guide bracket; the lower part of the crushing barrel is fixedly connected with a discharging plate; a material baffle plate is inserted at the front side of the second frame, and the upper surface of the material baffle plate is in contact with the crushing barrel and is used for blocking the leakage of materials in the crushing barrel; the lower surface of the striker plate is contacted with the discharge plate; an eighth mounting bracket is fixedly connected to the left side of the second rack; a second motor is fixedly connected to the lower side of the eighth mounting bracket; the second motor is fixedly connected with a bevel gear through an output shaft; the center of the lower part of the crushing barrel is rotationally connected with a first crushing cutter; a fluted disc is fixedly connected to the lower part of the first crushing cutter; the fluted disc is meshed with the bevel gear; the upper part of the first crushing cutter is fixedly connected with a second crushing cutter; two second mounting seats are fixedly connected to the upper part of the inner side wall of the crushing barrel, and an inclined plate is fixedly connected to the opposite side of each of the two second mounting seats; the inclined plate is rotatably connected with an arc-shaped strip through a rotating shaft; the upper part of the arc-shaped strip is fixedly connected with a second elastic piece; the lower side of the second elastic piece is fixedly connected with the second mounting seat.

Optionally, the sealing assembly comprises a third mounting plate, a second electric sliding rail, a second electric sliding block, a second mounting block, a cylinder, a pulley, a fourth mounting plate, a cover plate, a fourth electric push rod, a third mounting block and a baffle plate; a third mounting plate is fixedly connected to the upper side of the third rack; two second electric slide rails are fixedly connected to the third mounting plate; the outer surface of the second electric sliding rail is connected with two second electric sliding blocks in a sliding manner; a second mounting block is fixedly connected to the left part of the lower side of each of the two second electric slide rails; the two second mounting blocks are rotatably connected with cylinders; the outer surface of the cylinder is fixedly connected with a pulley; a fourth mounting plate is fixedly connected to the upper sides of the two second electric sliding blocks; a cover plate is fixedly connected to the left side of the fourth mounting plate; two fourth electric push rods are fixedly connected to the upper side of the cover plate; the two fourth electric push rods are fixedly connected with a third mounting block through telescopic parts respectively; a baffle is fixedly connected to the lower sides of the two front third mounting blocks; the lower sides of the two rear third mounting blocks are fixedly connected with another baffle; the two baffles are inserted into the cover plate.

Optionally, the two second elastic members have different strengths, and are used for turning over a large silica foot pad entering the crushing barrel and dropping into the bottom of the crushing barrel.

Optionally, the knife in the second crushing cutter is arranged transversely for protecting the first crushing cutter, preventing the first crushing cutter from being broken due to the falling of the massive silica foot pad from the high position, and the strength of the knife in the second crushing cutter is larger.

The invention has the following advantages: the feeding and sorting system is designed, so that the broken silica foot pads are subjected to size screening, a small amount of water is sprayed, and then the large silica foot pads with paint at the bottoms are folded, so that the paint can be conveniently treated by the conveying system.

The conveying system is designed, so that small silica foot pads are conveyed into the crushing system, and large silica foot pads are conveyed into the crushing system after being subjected to paint removing treatment if paint exists, so that the crushing system can conveniently perform crushing treatment.

The crushing system is designed, so that the silica foot pad is crushed after being completely sealed, and the phenomenon that dust flies when the silica foot pad is crushed is avoided.

Drawings

FIG. 1 is a schematic structural diagram of a first solid of a silica foot pad recycling and crushing device for an automobile, which is disclosed by the invention;

FIG. 2 is a schematic structural diagram of a second solid of the silica foot pad recycling and crushing device for the automobile of the invention;

FIG. 3 is a schematic perspective view of a feeding and sorting system of the device for recovering and crushing the silica foot pad for the automobile of the invention;

FIG. 4 is a schematic view of a first partial perspective structure of a feeding and sorting system of a silica foot pad recycling and crushing device for an automobile according to the present invention;

FIG. 5 is a schematic view of a second partial three-dimensional structure of a feeding and sorting system of the device for recovering and crushing the silica foot pad for the automobile of the present invention;

FIG. 6 is a schematic view of a third partial three-dimensional structure of a feeding and sorting system of the device for recovering and crushing the silica foot pad for the automobile of the present invention;

FIG. 7 is a schematic perspective view of a conveying system of the silica foot pad recycling and crushing device for the automobile of the invention;

FIG. 8 is a schematic partial three-dimensional structure diagram of a conveying system of the silica foot pad recycling and crushing device for the automobile, provided by the invention;

FIG. 9 is a schematic perspective view of a crushing system of the silica foot pad recycling and crushing device for the automobile of the invention;

FIG. 10 is a schematic view of a first partial perspective structure of a crushing system of the silica foot pad recycling and crushing device for the automobile of the invention;

FIG. 11 is a schematic view of a second partial three-dimensional structure of a crushing system of the silica foot pad recycling and crushing device for the automobile of the invention;

fig. 12 is a third partial three-dimensional structure schematic diagram of a crushing system of the silica foot pad recycling and crushing device for the automobile.

The meaning of the reference symbols in the figures: 1-a first frame, 2-a second frame, 3-a third frame, 4-a feeding sorting system, 5-a conveying system, 6-a crushing system, 401-a support frame assembly, 402-a first mounting bracket, 403-a feeding bracket, 404-a screening bracket, 405-a second mounting bracket, 406-a sprayer, 407-a first support frame, 408-a first guide bracket, 409-a vibrating motor, 410-a third mounting bracket, 411-a first mounting plate, 412-a first motor, 413-a first support plate, 414-a shaft sleeve, 415-a spline shaft, 416-a second support plate, 417-a first electric push rod, 418-a third support plate, 419-a push plate, 420-a fourth mounting bracket, 421-a first magnetic attraction block, 422-a first rotating plate, 423-a first mounting block, 424-a second electric push rod, 425-a fifth mounting bracket, 426-a second magnetic attraction block, 427-a second rotating plate, 4011-a second support frame, 4012-a small slide block, 4013-a first elastic piece, 501-a third support frame, 502-a first conveyor, 503-a second conveyor, 504-a second guide support frame, 505-a third guide support frame, 506-a sixth mounting bracket, 507-a spring post, 508-a second mounting plate, 509-a third electric push rod, 510-a clamping block, 511-a seventh mounting bracket, 512-a first electric slide rail, 513-a first electric slide block, 514-a first mounting seat, 515-an electric rotating shaft, 516-a milling cutter, 601-a crushing barrel, 602-a discharge plate, 603-a material baffle plate, 604-an eighth mounting bracket, 605-a second motor, 606-a bevel gear, 607-a first crushing cutter, 608-a fluted disc, 609-a second crushing cutter, 610-a second mounting seat, 611-an inclined plate, 612-an arc strip, 613-a second elastic piece, 614-a third mounting plate, 615-a second electric slide rail, 616-a second electric slide block, 617-a second mounting block, 618-a cylinder, 619-a pulley, 620-a fourth mounting plate, 621-a cover plate, 622-a fourth electric push rod, 623-a third mounting block, 624-a baffle plate, 4011 a-a sliding groove, 601 a-a first feeding hole, 601 b-a second feeding hole and 601 c-a blocking hole.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention will be described in further detail with reference to the accompanying drawings. It is only noted that the invention is intended to be limited to the specific forms set forth herein, including any reference to the drawings, as well as any other specific forms of embodiments of the invention.

Example 1

A silica foot pad recovery crushing device for an automobile is shown in figures 1-12 and comprises a first rack 1, a second rack 2, a third rack 3, a feeding and sorting system 4, a conveying system 5 and a crushing system 6; the right side of the first frame 1 is fixedly connected with a second frame 2; a third frame 3 is fixedly connected to the right side of the second frame 2; a feeding and sorting system 4 is fixedly connected to the left part of the upper side of the first rack 1; a right side conveying system 5 on the upper side of the first frame 1; the second frame 2 and the third frame 3 are connected with a crushing system 6.

When in use, firstly, the silica foot pad recovery and crushing device for the automobile is placed at a required position, the first frame 1, the second frame 2 and the third frame 3 are placed at a stable position, firstly, an operator pours the broken silica foot pad into the feeding and sorting system 4, controls the feeding and sorting system 4 to screen out small silica foot pads and large silica foot pads, then controls the feeding and sorting system 4 to turn the paint at the bottom of the large silica foot pad to the front side if the bottom of the large silica foot pad has the paint, then continuously conveys the paint to the conveying system 5, continuously conveys the small silica foot pads to the crushing system 6 for crushing after the small silica foot pads are conveyed to the conveying system 5, removes the paint on the large silica foot pad after the large silica foot pads are conveyed to the conveying system 5, avoids adverse effects on products when the large silica foot pads are used again, and after the large silica foot pad paint is removed, in the further conveyance into the crushing system 6, the large silica foot mats are crushed.

Example 2

On the basis of the embodiment 1, as shown in fig. 1 to 12, the feeding sorting system 4 comprises a support frame assembly 401, a first mounting bracket 402, a feeding bracket 403, a screening bracket 404, a second mounting bracket 405, a sprayer 406, a first support bracket 407, a first material guiding bracket 408, a vibrating motor 409 and an overturning assembly; a support frame assembly 401 is fixedly connected to the left part of the upper side of the first frame 1; a first mounting bracket 402 is fixedly connected to the left side of the support frame assembly 401; a feeding bracket 403 is fixedly connected to the upper side of the first mounting bracket 402; a screening bracket 404 is fixedly connected to the upper part of the support frame assembly 401; the right part of the feeding bracket 403 is contacted with the screening bracket 404; a second mounting bracket 405 is fixedly connected to the middle part of the screening bracket 404; two sprayers 406 are fixedly connected to the upper part of the second mounting bracket 405; a first support frame 407 is fixedly connected to the left part of the upper side of the first frame 1, and the first support frame 407 is located between the support frame assemblies 401; a first material guiding bracket 408 is fixedly connected to the upper side of the first supporting frame 407; the right part of the lower side of the screening bracket 404 is connected with a vibration motor 409 through a bolt; the screen support 404 is coupled to a flipping assembly.

The overturning assembly comprises a third mounting bracket 410, a first mounting plate 411, a first motor 412, a first support plate 413, a shaft sleeve 414, a spline shaft 415, a second support plate 416, a first electric push rod 417, a third support plate 418, a push plate 419, a fourth mounting bracket 420, a first magnetic block 421, a first rotating plate 422, a first mounting block 423, a second electric push rod 424, a fifth mounting bracket 425, a second magnetic block 426 and a second rotating plate 427; a third mounting bracket 410 is fixedly connected to the front part of the lower side of the screening bracket 404; the front part of the third mounting bracket 410 is fixedly connected with a first mounting plate 411; a first motor 412 is connected to the front side of the first mounting plate 411 through bolts; the first motor 412 penetrates through the first mounting plate 411 through an output shaft and is connected with the first mounting plate in a rotating mode; a first support plate 413 is fixedly connected to the front part of the third mounting bracket 410, and the first support plate 413 is positioned behind the first mounting plate 411; a shaft sleeve 414 is fixedly connected to the first supporting plate 413; the first motor 412 is fixedly connected with the shaft sleeve 414 through an output shaft; a spline shaft 415 is connected on the shaft sleeve 414 in a sliding way; the spline shaft 415 penetrates through the screening bracket 404 and is in rotary connection with the screening bracket; a second supporting plate 416 is fixedly connected to the right part of the third mounting bracket 410; a first electric push rod 417 is fixedly connected to the rear side of the second support plate 416; a third supporting plate 418 is fixedly connected to the right part of the third mounting bracket 410, and the third supporting plate 418 is positioned behind the second supporting plate 416; the second supporting plate 416 is fixedly connected with the first electric push rod 417; the first electric push rod 417 is fixedly connected with a push plate 419 through a telescopic part; the spline shaft 415 is rotationally connected with the left part of the push plate 419; a fourth mounting bracket 420 is fixedly connected to the front side and the rear side of the screening bracket 404; the spline shaft 415 penetrates through the fourth mounting bracket 420 and is in rotary connection with the fourth mounting bracket; a first magnetic block 421 is fixedly connected to the two fourth mounting brackets 420; the opposite sides of the two first magnetic blocks 421 are fixedly connected with the screening bracket 404; the two first magnetic blocks 421 have a first rotating plate 422 attracted by magnetic force; the front side and the rear side of the screening bracket 404 are respectively fixedly connected with a first mounting block 423, and the two first mounting blocks 423 are positioned above the two fourth mounting brackets 420; two second electric push rods 424 are fixedly connected to the upper sides of the two first mounting blocks 423; the two second electric push rods 424 are fixedly connected with a fifth mounting bracket 425 through a telescopic part; a second magnetic suction block 426 is fixedly connected to the front part and the rear part of the lower side of the fifth mounting bracket 425 respectively; two second magnetic blocks 426 magnetically attract a second rotating plate 427.

The support frame assembly 401 comprises a second support frame 4011, a small sliding block 4012 and a first elastic piece 4013; a second support frame 4011 is fixedly connected to the left part of the upper side of the first frame 1; the two left supporting plates of the second supporting frame 4011 are fixedly connected with the screening bracket 404; the upper parts of the two supporting plates on the right of the second supporting frame 4011 are connected with two small sliding blocks 4012 in a sliding manner, and the two small sliding blocks 4012 slide in the two sliding grooves 4011 a; two first elastic pieces 4013 are fixedly connected to the upper side and the lower side of each of the two small sliding blocks 4012; the eight first elastic pieces 4013 are fixedly connected with the two support plates on the right side of the second support frame 4011; the opposite sides of the two small sliding blocks 4012 are fixedly connected with the screening bracket 404.

The left part of the screening bracket 404 is provided with a grid plate for filtering the silica foot pad of the small block.

Firstly, an operator pours broken silica foot mats into a feeding bracket 403, the broken silica foot mats slide from the feeding bracket 403 to the right due to the high left side and the low right side of the feeding bracket 403, enter a screening bracket 404, at the moment, a vibration motor 409 is controlled to be started, the vibration motor 409 starts to vibrate to drive the screening bracket 404 to vibrate on a supporting frame assembly 401, when the screening bracket 404 vibrates, two small sliding blocks 4012 are driven to swing up and down in two sliding grooves 4011a, the broken silica foot mats on the screening bracket 404 are removed to the right in a vibration mode, at the moment, the broken silica foot mats move to a grid plate arranged at the left part of the screening bracket 404 and are influenced by the vibration motor 409, when the broken silica foot mats pass through the grid plate, if small silica foot mats pass through the grid plate of the screening bracket 404 to fall in a first material guide bracket 408 below, and large silica foot mats continue to move to the right on the grid plate of the screening bracket 404, when the large silica foot pad vibrates to the lower part of the two sprayers 406, the two sprayers 406 are controlled to spray water opposite to the large silica foot pad, meanwhile, the small silica foot pad at the lower part can be sprayed by the sprayed water, the vibration motor 409 is further controlled to vibrate continuously, the large silica foot pad is sprayed on the screening bracket 404 and moves rightwards, after the large silica foot pad moves to the lower part of the second rotating plate 427, the vibration motor 409 is controlled to stop, if paint is arranged at the bottom of the large silica foot pad, the two second electric push rods 424 are controlled to retreat, the fifth mounting bracket 425, the two second magnetic suction blocks 426 and the second rotating plate 427 are driven to descend together, the large silica foot pad with the paint at the bottom is pressed, then the first electric push rod 417 is controlled to push out, the spline shaft 415 connected with the push plate 419 is driven to move, the spline shaft 415 is inserted into the grooves in the first rotating plate 422 and the second rotating plate 427, and the first motor 412 is controlled to rotate, based on the front and back view, the first motor 412 rotates clockwise to drive the shaft sleeve 414, the spline shaft 415, the first rotating plate 422, the second rotating plate 427 and the large silica foot pad with paint at the bottom to rotate together, after the first rotating plate 422 and the second rotating plate 427 are exchanged in the up and down positions, the first motor 412 is controlled to stop rotating, at this time, the two first magnetic blocks 421 attract the second rotating plate 427 through magnetic force, the two second magnetic blocks 426 attract the first rotating plate 422 through magnetic force, the large silica foot pad with paint at the bottom is turned over by one hundred eighty degrees to enable the paint at the bottom to face upwards, then the two second electric push rods 424 are controlled to push out to drive the fifth mounting bracket 425, the two second magnetic blocks 426 and the first rotating plate 422 to ascend, the vibration motor is controlled to vibrate continuously, the large silica foot pad with paint on the second rotating plate 427 is continuously vibrated rightwards until the large silica foot pad enters the first conveyor 502, at this time, since the first material guiding bracket 408 is also high at the left and low at the right, the small silica pad in the first material guiding bracket 408 slides to the right onto the second conveyor 503.

The conveying system 5 comprises a third supporting frame 501, a first conveyor 502, a second conveyor 503, a second guide bracket 504, a third guide bracket 505 and a paint removing assembly; a third support frame 501 is fixedly connected to the right part of the upper side of the first frame 1; a first transmitter 502 is fixedly connected to the upper part of the third support frame 501; the lower part of the third supporting frame 501 is fixedly connected with a second transmitter 503; a second material guiding bracket 504 is fixedly connected to the upper part of the right side of the third supporting frame 501; a third material guiding bracket 505 is fixedly connected to the lower part of the right side of the third supporting frame 501; a paint removal assembly is attached to the first conveyor 502.

The paint removing assembly comprises a sixth mounting bracket 506, a spring column 507, a second mounting plate 508, a third electric push rod 509, a clamping block 510, a seventh mounting bracket 511, a first electric slide rail 512, a first electric slide block 513, a first mounting seat 514, an electric rotating shaft 515 and a milling cutter 516; a sixth mounting bracket 506 is fixedly connected to the front side and the rear side of the first conveyor 502; two spring columns 507 are respectively inserted into the two sixth mounting brackets 506; a second mounting plate 508 is fixedly connected to the upper sides of the two front spring columns 507; the upper sides of the two rear spring columns 507 are fixedly connected with another second mounting plate 508; the lower sides of the two second mounting plates 508 are in contact with the upper sides of the two sixth mounting brackets 506; a third electric push rod 509 is fixedly connected to the left part and the right part of each of the two second mounting plates 508; the front two third electric push rods 509 are fixedly connected with a clamping block 510 through a telescopic part; the two rear third electric push rods 509 are fixedly connected with another clamping block 510 through a telescopic part; a seventh mounting bracket 511 is fixedly connected to the upper sides of the two second mounting plates 508; the seventh mounting bracket 511 is connected with a first electric slide rail 512 through bolts; the outer surface of the first electric slide rail 512 is connected with a first electric slide block 513 in a sliding manner; a first mounting seat 514 is fixedly connected to the left side of the first electric sliding block 513; an electric rotating shaft 515 is fixedly connected to the first mounting seat 514; a milling cutter 516 is fixedly connected to the lower side of the electric rotating shaft 515.

When large silica foot pads enter the first conveyor 502 and small silica foot pads also enter the second conveyor 503, the first conveyor 502 and the second conveyor 503 are controlled to rotate to drive the large silica foot pads and the small silica foot pads to move rightwards together, at this time, the small silica foot pads directly move rightwards from the second conveyor 503 to enter the third material guide bracket 505, then continuously slide rightwards on the third material guide bracket 505 and enter the crushing barrel 601 through the second material inlet 601b, after all the small silica foot pads are conveyed to the crushing barrel 601, the second conveyor 503 is controlled to stop rotating, the large silica foot pads move rightwards on the first conveyor 502, if paint is on the large silica foot pads, the first conveyor 502 is controlled to stop rotating when the large silica foot pads move to the lower part of the milling cutter 516, then the first electric sliding block 513 is controlled to slide on the outer surface of the first electric sliding rail 512, the first mounting seat 514, the electric rotating shaft 515 and the milling cutter 516 are driven to move together, the milling cutter 516 is driven to touch a large silica foot pad to adapt to the thickness of the large silica foot pad, when the thickness of the large silica foot pad is a little higher, the milling cutter 516 touches the large silica foot pad, the second mounting plate 508, the third electric push rod 509, the clamping block 510, the seventh mounting bracket 511, the first electric slide rail 512, the first electric slide block 513, the first mounting seat 514 and the electric rotating shaft 515 are driven to ascend a little together, at this time, the four spring columns 507 are compressed, at this time, the four third electric push rods 509 are controlled to push out to drive the two clamping blocks 510 to move, so as to clamp the large silica foot pad with paint on the upper side, the first electric slide block 513 is controlled to slide on the outer surface of the first electric slide rail 512 in a reciprocating manner, the first mounting seat 514, the electric rotating shaft 515 and the milling cutter 516 are driven to move together, and the electric rotating shaft 515 is controlled to rotate at the same time, the milling cutter 516 is driven to rotate, the milling cutter 516 does reciprocating motion on the clamped massive silica foot pad to remove paint on the massive silica foot pad, after the paint is removed, the electric rotating shaft 515 is controlled to stop rotating, the first electric sliding block 513 is controlled to stop moving, then the four third electric push rods 509 are controlled to retreat to drive the two clamping blocks 510 to move, the clamped massive silica foot pad is loosened, the first conveyor 502 is controlled to continue rotating to drive the massive silica foot pad on the first conveyor 502 to be conveyed to the second material guide support 504, then the massive silica foot pad continues to slide rightwards on the second material guide support 504 and enters the crushing barrel 601 through the second feeding hole 601b, and after all the massive silica foot pads are conveyed to the crushing barrel 601, the first conveyor 502 is controlled to stop rotating.

The crushing system 6 comprises a crushing barrel 601, a discharge plate 602, a striker plate 603, an eighth mounting bracket 604, a second motor 605, a bevel gear 606, a first crushing cutter 607, a fluted disc 608, a second crushing cutter 609, a second mounting seat 610, a sloping plate 611, an arc-shaped strip 612, a second elastic piece 613 and a closing component; the upper part of the second frame 2 is fixedly connected with a crushing barrel 601; the upper part of the crushing barrel 601 is fixedly connected with the second material guide bracket 504; the middle part of the crushing barrel 601 is fixedly connected with a third material guide bracket 505; the lower part of the crushing barrel 601 is fixedly connected with a discharging plate 602; a material baffle plate 603 is inserted in the front side of the second frame 2, and the upper surface of the material baffle plate 603 is in contact with the crushing barrel 601 and is used for blocking the leakage of the materials in the crushing barrel 601; the lower surface of the material baffle 603 is in contact with the discharging plate 602; an eighth mounting bracket 604 is fixedly connected to the left side of the second frame 2; a second motor 605 is connected to the lower side of the eighth mounting bracket 604 through bolts; the second motor 605 is fixedly connected with a bevel gear 606 through an output shaft; the center of the lower part of the crushing barrel 601 is rotatably connected with a first crushing cutter 607; a fluted disc 608 is fixedly connected to the lower part of the first crushing cutter 607; the toothed disc 608 is meshed with the bevel gear 606; the upper part of the first crushing cutter 607 is fixedly connected with a second crushing cutter 609; two second mounting seats 610 are fixedly connected to the upper part of the inner side wall of the crushing barrel 601, and an inclined plate 611 is fixedly connected to the opposite sides of each of the two second mounting seats 610; the inclined plate 611 is rotatably connected with an arc-shaped strip 612 through a rotating shaft; a second elastic piece 613 is fixedly connected to the upper part of the arc-shaped strip 612; the lower side of the second elastic element 613 is fixedly connected to the second mounting base 610.

The closing component comprises a third mounting plate 614, a second electric slide rail 615, a second electric slide block 616, a second mounting block 617, a cylinder 618, a pulley 619, a fourth mounting plate 620, a cover plate 621, a fourth electric push rod 622, a third mounting block 623 and a baffle 624; a third mounting plate 614 is fixedly connected to the upper side of the third frame 3; two second electric slide rails 615 are connected to the third mounting plate 614 through bolts; two second electric sliding blocks 616 are connected to the outer surface of the second electric sliding rail 615 in a sliding manner; a second mounting block 617 is fixedly connected to the left part of the lower side of each of the two second electric slide rails 615; the two second mounting blocks 617 are rotatably connected with cylinders 618; a pulley 619 is fixedly connected to the outer surface of the cylinder 618; a fourth mounting plate 620 is fixedly connected to the upper sides of the two second electric sliding blocks 616; a cover plate 621 is fixedly connected to the left side of the fourth mounting plate 620; two fourth electric push rods 622 are fixedly connected to the upper side of the cover plate 621; the two fourth electric push rods 622 are fixedly connected with a third mounting block 623 through telescopic parts respectively; a baffle 624 is fixedly connected to the lower sides of the two front third mounting blocks 623; another baffle 624 is fixedly connected to the lower sides of the two rear third mounting blocks 623; two shutters 624 are inserted into the cover 621.

The crushing barrel 601 is provided with three grooves, namely a first feeding hole 601a, a second feeding hole 601b and a blocking hole 601 c.

The two second elastic members 613 have different strengths, and are used for turning over the massive silica foot pad entering the crushing barrel 601 and dropping into the bottom of the crushing barrel 601.

The knife in the second crushing cutter 609 is arranged transversely and is used for protecting the first crushing cutter 607, the first crushing cutter 607 is prevented from being broken due to falling of a massive silica foot pad from a high place, and the knife strength in the second crushing cutter 609 is larger.

The fourth electric putter 622 is a bidirectional electric putter.

When all the small silica foot pads are conveyed to the crushing barrel 601, the small silica foot pads directly fall to the bottom of the crushing barrel 601, and all the large silica foot pads are conveyed to the crushing barrel 601, firstly, one small silica foot pad transversely enters the crushing barrel 601, two sides of the large silica foot pad after entering can touch two arc-shaped bars 612, and the two arc-shaped bars 612 are different in strength due to the fact that the two second elastic pieces 613 connected with the two arc-shaped bars 612 are connected, so that the large silica foot pads can be subjected to two different forces when touching the two arc-shaped bars 612, the large silica foot pads are turned over and fall into the crushing barrel 601, the back plates are also the same, after all the silica foot pads enter the crushing barrel 601, the two second electric sliding blocks 616 are controlled to move leftwards on the outer surfaces of the two second electric sliding rails 615 to drive the fourth mounting plate 620, the cover plate 621, the fourth electric push rod 621, the third mounting block 623 and the baffle plate 624 to move leftwards together, in the moving process, the pulley 619 can play a supporting role to assist the two second electric sliding blocks 616 to drive the connected components to move left together, when the cover 621 moves into the crushing barrel 601 and touches the inner wall of the crushing barrel 601, the two second electric sliding blocks 616 are controlled to stop moving, then the two fourth electric push rods 622 are controlled to push out to drive the two baffles 624 to move forwards and backwards respectively, the part below the cover 621 in the crushing barrel 601 is completely sealed, so that a large amount of dust generated in the process of crushing the silica foot pad is prevented from flying out of the crushing barrel 601, then the second motor 605 is controlled to rotate to drive the connected bevel gear 606 to rotate, the bevel gear 606 drives the meshed fluted disc 608 to rotate, the fluted disc 608 drives the first crushing cutter 607 to rotate, the first crushing cutter 607 drives the second crushing cutter 609 to rotate, and the first crushing cutter 607 and the second crushing cutter 609 rotate simultaneously, carry out broken handle with the silica foot pad in broken bucket 601, treat first broken cutter 607 and the broken cutter 609 back of second to the silica foot pad is broken completely, control two electronic sliders 616 of second and move to the right, drive the part of connecting and reset, reset and accomplish the back, operating personnel places a collection box in play flitch 602 below, operating personnel takes striker plate 603 out after that, the silica foot pad after breaking can follow and flow out on play flitch 602, get into in the collection box of below.

The above-mentioned embodiments are merely preferred embodiments of the present invention, which are not intended to limit the scope of the present invention, and therefore, all equivalent changes made by the contents of the claims of the present invention should be included in the claims of the present invention.

Claims

1. A silica foot pad recovery and crushing device for an automobile comprises a first rack (1), a second rack (2) and a third rack (3); a second frame (2) is fixedly connected to the right side of the first frame (1); a third frame (3) is fixedly connected to the right side of the second frame (2); the device is characterized by also comprising a feeding and sorting system (4), a conveying system (5) and a crushing system (6); a feeding and sorting system (4) is fixedly connected to the left part of the upper side of the first rack (1), and the feeding and sorting system (4) is used for screening large silica foot pads; the conveying system (5) is arranged on the right side of the upper side of the first rack (1), and the conveying system (5) is used for conveying the silica foot pad into the crushing system (6); and the second rack (2) and the third rack (3) are connected with a crushing system (6), and the crushing system (6) is used for crushing silica foot pads.

2. The device for recovering and crushing the silica foot pad for the automobile as claimed in claim 1, wherein the feeding and sorting system (4) comprises a support frame assembly (401), a first mounting bracket (402), a feeding bracket (403), a screening bracket (404), a second mounting bracket (405), a sprayer (406), a first support frame (407), a first material guiding bracket (408), a vibration motor (409) and a turnover assembly; a support frame assembly (401) is fixedly connected to the left part of the upper side of the first frame (1); a first mounting bracket (402) is fixedly connected to the left side of the support frame assembly (401); a feeding support (403) is fixedly connected to the upper side of the first mounting support (402); the upper part of the support frame component (401) is fixedly connected with a screening support (404); the right part of the feeding bracket (403) is contacted with the screening bracket (404); a second mounting bracket (405) is fixedly connected to the middle part of the screening bracket (404); two sprayers (406) are fixedly connected to the upper part of the second mounting bracket (405); a first support frame (407) is fixedly connected to the left part of the upper side of the first rack (1), and the first support frame (407) is positioned between the support frame assemblies (401); a first material guide bracket (408) is fixedly connected to the upper side of the first support frame (407); a vibration motor (409) is fixedly connected to the right part of the lower side of the screening bracket (404); the screening bracket (404) is connected with a turnover component.

3. The device for recovering and crushing the silica foot pad for the automobile as claimed in claim 2, wherein the overturning component comprises a third mounting bracket (410), a first mounting plate (411), a first motor (412), a first support plate (413), a shaft sleeve (414), a spline shaft (415), a second support plate (416), a first electric push rod (417), a third support plate (418), a push plate (419), a fourth mounting bracket (420), a first magnetic absorption block (421), a first rotating plate (422), a first mounting block (423), a second electric push rod (424), a fifth mounting bracket (425), a second magnetic absorption block (426) and a second rotating plate (427); a third mounting bracket (410) is fixedly connected to the front part of the lower side of the screening bracket (404); a first mounting plate (411) is fixedly connected to the front part of the third mounting bracket (410); a first motor (412) is fixedly connected to the front side of the first mounting plate (411); the first motor (412) penetrates through the first mounting plate (411) through an output shaft and is connected with the first mounting plate in a rotating mode; a first supporting plate (413) is fixedly connected to the front part of the third mounting bracket (410), and the first supporting plate (413) is positioned behind the first mounting plate (411); a shaft sleeve (414) is fixedly connected to the first supporting plate (413); the first motor (412) is fixedly connected with the shaft sleeve (414) through an output shaft; a spline shaft (415) is connected on the shaft sleeve (414) in a sliding way; the spline shaft (415) penetrates through the screening bracket (404) and is in rotary connection with the screening bracket; a second supporting plate (416) is fixedly connected to the right part of the third mounting bracket (410); a first electric push rod (417) is fixedly connected to the rear side of the second supporting plate (416); a third supporting plate (418) is fixedly connected to the right part of the third mounting bracket (410), and the third supporting plate (418) is positioned behind the second supporting plate (416); the second supporting plate (416) is fixedly connected with the first electric push rod (417); the first electric push rod (417) is fixedly connected with a push plate (419) through a telescopic part; the spline shaft (415) is rotationally connected with the left part of the push plate (419); a fourth mounting bracket (420) is fixedly connected to the front side and the rear side of the screening bracket (404) respectively; the spline shaft (415) penetrates through the fourth mounting bracket (420) and is in rotary connection with the fourth mounting bracket; a first magnetic suction block (421) is fixedly connected to the two fourth mounting brackets (420); the back sides of the two first magnetic blocks (421) are fixedly connected with the screening bracket (404); the two first magnetic blocks (421) attract one first rotating plate (422) through magnetic force; the front side and the rear side of the screening support (404) are respectively fixedly connected with a first mounting block (423), and the two first mounting blocks (423) are positioned above the two fourth mounting supports (420); two second electric push rods (424) are fixedly connected to the upper sides of the two first mounting blocks (423); the two second electric push rods (424) are fixedly connected with a fifth mounting bracket (425) through telescopic parts; a second magnetic suction block (426) is fixedly connected to the front part of the lower side and the rear part of the lower side of the fifth mounting bracket (425); the two second magnetic blocks (426) attract a second rotating plate (427) by magnetic force.

4. The device for recovering and crushing the silica foot pad for the automobile as claimed in claim 3, wherein the support frame assembly (401) comprises a second support frame (4011), a small sliding block (4012) and a first elastic piece (4013); a second support frame (4011) is fixedly connected to the left part of the upper side of the first frame (1); the two left supporting plates of the second supporting frame (4011) are fixedly connected with the screening bracket (404); the upper parts of the two supporting plates on the right of the second supporting frame (4011) are connected with two small sliding blocks (4012) in a sliding manner, and the two small sliding blocks (4012) slide in the two sliding grooves (4011 a); two first elastic pieces (4013) are fixedly connected to the upper side and the lower side of each of the two small sliding blocks (4012); the eight first elastic pieces (4013) are fixedly connected with the two supporting plates on the right of the second supporting frame (4011); the opposite sides of the two small sliding blocks (4012) are fixedly connected with the screening bracket (404).

5. The device for recovering and crushing the silica foot pad for the automobile as claimed in claim 4, wherein the conveying system (5) comprises a third supporting frame (501), a first conveyor (502), a second conveyor (503), a second material guiding bracket (504), a third material guiding bracket (505) and a paint removing assembly; a third support frame (501) is fixedly connected to the right part of the upper side of the first frame (1); a first conveyor (502) is fixedly connected to the upper part of the third support frame (501); a second transmitter (503) is fixedly connected to the lower part of the third support frame (501); a second material guide bracket (504) is fixedly connected to the upper part of the right side of the third support frame (501); a third material guide bracket (505) is fixedly connected to the lower part of the right side of the third support frame (501); the first conveyor (502) is connected with a paint removing assembly.

6. The device for recovering and crushing the silica foot pad for the automobile as claimed in claim 5, wherein the paint removing assembly comprises a sixth mounting bracket (506), a spring column (507), a second mounting plate (508), a third electric push rod (509), a clamping block (510), a seventh mounting bracket (511), a first electric slide rail (512), a first electric slide block (513), a first mounting seat (514), an electric rotating shaft (515) and a milling cutter (516); a sixth mounting bracket (506) is fixedly connected to the front side and the rear side of the first conveyor (502); two spring columns (507) are respectively inserted into the two sixth mounting brackets (506); a second mounting plate (508) is fixedly connected to the upper sides of the two front spring columns (507); the upper sides of the two rear spring columns (507) are fixedly connected with another second mounting plate (508); the lower sides of the two second mounting plates (508) are in contact with the upper sides of the two sixth mounting brackets (506); the left part and the right part of the two second mounting plates (508) are respectively fixedly connected with a third electric push rod (509); the front two third electric push rods (509) are fixedly connected with a clamping block (510) through a telescopic part; the other clamping block (510) is fixedly connected with the two third electric push rods (509) at the rear part through the telescopic parts; a seventh mounting bracket (511) is fixedly connected to the upper sides of the two second mounting plates (508); a first electric slide rail (512) is fixedly connected to the seventh mounting bracket (511); the outer surface of the first electric sliding rail (512) is connected with a first electric sliding block (513) in a sliding way; a first mounting seat (514) is fixedly connected to the left side of the first electric sliding block (513); an electric rotating shaft (515) is fixedly connected to the first mounting seat (514); a milling cutter (516) is fixedly connected to the lower side of the electric rotating shaft (515).

7. The device for recycling and crushing the silica foot pad for the automobile as claimed in claim 6, wherein the crushing system (6) comprises a crushing barrel (601), a discharging plate (602), a material baffle plate (603), an eighth mounting bracket (604), a second motor (605), a bevel gear (606), a first crushing cutter (607), a fluted disc (608), a second crushing cutter (609), a second mounting seat (610), an inclined plate (611), an arc-shaped bar (612), a second elastic piece (613) and a closing assembly; the upper part of the second frame (2) is fixedly connected with a crushing barrel (601); the upper part of the crushing barrel (601) is fixedly connected with a second material guide bracket (504); the middle part of the crushing barrel (601) is fixedly connected with a third material guide bracket (505); the lower part of the crushing barrel (601) is fixedly connected with a discharging plate (602); a material baffle plate (603) is inserted in the front side of the second frame (2), and the upper surface of the material baffle plate (603) is in contact with the crushing barrel (601) and is used for blocking the leakage of the materials in the crushing barrel (601); the lower surface of the material baffle plate (603) is contacted with the discharging plate (602); an eighth mounting bracket (604) is fixedly connected to the left side of the second rack (2); a second motor (605) is fixedly connected to the lower side of the eighth mounting bracket (604); the second motor (605) is fixedly connected with a bevel gear (606) through an output shaft; the center of the lower part of the crushing barrel (601) is rotationally connected with a first crushing cutter (607); a fluted disc (608) is fixedly connected with the lower part of the first crushing cutter (607); the fluted disc (608) is meshed with the bevel gear (606); the upper part of the first crushing cutter (607) is fixedly connected with a second crushing cutter (609); two second mounting seats (610) are fixedly connected to the upper portion of the inner side wall of the crushing barrel (601), and two inclined plates (611) are fixedly connected to the opposite sides of the two second mounting seats (610) respectively; the inclined plate (611) is rotatably connected with an arc-shaped strip (612) through a rotating shaft; the upper part of the arc-shaped strip (612) is fixedly connected with a second elastic piece (613); the lower side of the second elastic element (613) is fixedly connected with the second mounting seat (610).

8. The device for recovering and crushing the silica foot pad for the automobile as claimed in claim 7, wherein the closing assembly comprises a third mounting plate (614), a second electric sliding rail (615), a second electric sliding block (616), a second mounting block (617), a cylinder (618), a pulley (619), a fourth mounting plate (620), a cover plate (621), a fourth electric push rod (622), a third mounting block (623) and a baffle plate (624); a third mounting plate (614) is fixedly connected to the upper side of the third rack (3); two second electric slide rails (615) are fixedly connected to the third mounting plate (614); the outer surface of the second electric slide rail (615) is connected with two second electric slide blocks (616) in a sliding way; a second mounting block (617) is fixedly connected to the left part of the lower side of each of the two second electric slide rails (615); the two second mounting blocks (617) are rotatably connected with cylinders (618); a pulley (619) is fixedly connected with the outer surface of the cylinder (618); a fourth mounting plate (620) is fixedly connected to the upper sides of the two second electric sliding blocks (616); a cover plate (621) is fixedly connected to the left side of the fourth mounting plate (620); two fourth electric push rods (622) are fixedly connected to the upper side of the cover plate (621); the two fourth electric push rods (622) are fixedly connected with a third mounting block (623) through telescopic parts respectively; a baffle plate (624) is fixedly connected to the lower sides of the two front third mounting blocks (623); the other baffle plate (624) is fixedly connected to the lower sides of the two rear third mounting blocks (623); two baffles (624) are inserted into the cover plate (621).

9. The silica foot pad recovery and crushing device for the automobile as claimed in claim 8, wherein the two second elastic members (613) have different strengths and are used for turning over the massive silica foot pad entering the crushing barrel (601) and dropping into the bottom of the crushing barrel (601).

10. The device for recovering and crushing the silica foot pad for the automobile as claimed in claim 9, wherein the knife in the second crushing cutter (609) is arranged transversely for protecting the first crushing cutter (607) from breaking due to dropping of the massive silica foot pad from a high position, and the knife in the second crushing cutter (609) has higher strength.