CN113731555B - Non-contact type high-molecular viscous diaphragm suspension laying and crushing device - Google Patents

Abstract

The invention relates to the field of polymer diaphragms, in particular to a non-contact type polymer viscous diaphragm suspension laying crushing device. The technical problem to be solved is as follows: the recovery work of the inner core body after the ball is punctured prolongs the processing time of the diaphragm medium production and influences the sticking performance of the product. The technical scheme of the invention is as follows: a non-contact high-molecular viscous membrane suspension laying crushing device comprises a displacement assembly, a salvaging assembly, a material distributing assembly, a conveying assembly, a chassis, a stirring cabin and the like; the inner surface of the bottom frame is fixedly connected with a stirring cabin. According to the technical scheme provided by the invention, the crushing work of the magnetic spheres and the recovery work of the inner core body are synchronously carried out, so that the magnetic spheres are crushed above the medium plate to enable the inner liquid to fall on the medium plate, the inner core body is recovered before contacting the medium plate, and the treatment efficiency of covering the medium plate with the viscous diaphragm is improved.

Description

Non-contact type high-molecular viscous diaphragm suspension laying and crushing device

Technical Field

The invention relates to the field of polymer diaphragms, in particular to a non-contact type polymer viscous diaphragm suspension laying crushing device.

Background

In the production of a magnetic polymer diaphragm medium, because the polymer stock solution has high viscosity, the problems of poor fluidity and easy agglomeration are caused, the conventional spraying method cannot well perform thin coating and laying work, and the uniformity after laying is not ideal.

The existing method for coating the outer membrane makes the magnetic polymer stock solution into a spherical shape, and an inner core body capable of improving buoyancy is inserted into the spherical body, so that the obtained magnetic spherical body can be suspended in water, then a layer of magnetic spherical body floating on the liquid surface is fished and is paved on a medium plate, finally a needle-shaped roller is used for puncturing the magnetic spherical bodies paved on the medium plate one by one, so that the outer membrane of the magnetic spherical body is punctured, the flowing magnetic stock solution is paved on the upper surface of the medium plate to form a thin polymer membrane, however, after the spherical body is punctured, the inner core body is remained on the medium plate, and the inner core body needs to be recovered before the subsequent drying treatment of the magnetic stock solution, so that the treatment time for producing the membrane medium is prolonged.

Because the magnetism stoste has high stickness, when carrying out the work of inner core body recovery, the inner core body will take away partial magnetism stoste, makes the diaphragm layer attenuate of laying on the medium board to influence the adhesion performance of product.

Therefore, there is a high necessity for an automatic apparatus for simultaneously performing the core body recovery operation during the magnetic ball crushing process to solve the above problems.

Disclosure of Invention

In order to overcome and to puncture the spheroid back and retrieve the work to the internal core, will prolong the processing time of diaphragm medium production to and when carrying out internal core and retrieve the work, the high stickness of magnetism stoste, partial magnetism stoste will be taken away by the internal core, make the diaphragm layer attenuate of laying on the medium board, thereby influence the shortcoming of the adhesion performance of product, the technical problem that solves is: provides a non-contact high-molecular viscous diaphragm suspension laying crushing device.

The technical scheme of the invention is as follows: a non-contact high-molecular viscous membrane suspension laying crushing device comprises a displacement assembly, a fishing assembly, a material distribution assembly, a conveying assembly, a bottom frame, a stirring cabin, a grid, a main support, a bottom plate and a collecting disc; the inner surface of the bottom frame is connected with a stirring cabin; a grid is welded at the bottom in the stirring cabin; a main bracket is connected in front of the stirring cabin; a bottom plate is connected above the main bracket; a collecting tray is arranged at the front upper part of the main bracket; the upper surface of the main bracket is connected with a displacement component; the rear side of the displacement component is connected with a salvaging component; a material distributing component is connected below the displacement component; the inner side of the material distributing component is connected with a conveying component.

Furthermore, the displacement assembly comprises a left long slide rail, a first electric slide block, a right long slide rail, a second electric slide block, a first fixing frame, a second fixing frame, a first electric push rod, a telescopic bracket and a second electric push rod; the left side of the upper surface of the main support is connected with a left long sliding rail; the rear side of the left long slide rail is connected with a first electric slide block; the right side of the upper surface of the main bracket is connected with a right long sliding rail; the rear side of the right long slide rail is connected with a second electric slide block; the upper surfaces of the first electric sliding block and the second electric sliding block are respectively connected with a group of first fixing frames; the lower parts of the two groups of first fixing frames are respectively connected with a material distributing component; the upper parts of the two groups of first fixing frames are connected with the same group of second fixing frames; the rear side of the middle part of the second fixing frame is connected with a first electric push rod; the left side and the right side of the rear part of the second fixing frame are connected with the same group of telescopic brackets; the rear part of the first electric push rod is connected with the middle part of the telescopic bracket; two groups of second electric push rods are connected to the rear lower part of the telescopic bracket; and the two groups of second electric push rods are connected with a fishing assembly.

Furthermore, the salvaging assembly comprises a fixed plate, an adapter plate, a tray, a side fixing frame, a first rotating shaft, a first straight gear, a first sliding rail, a first sliding block, a second sliding rail, a second sliding block, a first toothed plate, a sliding baffle and a partition plate; the lower parts of the two groups of second electric push rods are connected with the same group of fixed plates; the left side and the right side of the fixed plate are respectively connected with a group of adapter plates; the inner sides below the two groups of adapter plates are connected with the same group of trays; the left end surfaces of the group of adapter plates positioned on the left side are connected with a side fixing frame; the front part of the side fixing frame is connected with a first rotating shaft; the outer surface of the first rotating shaft is connected with a first straight gear; the left front part of the fixed plate is connected with a first slide rail; a first sliding block is connected below the first sliding rail; the left side of the first sliding block is connected with a first toothed plate; the first toothed plate is meshed with the first straight gear; a second slide rail is connected to the right front of the fixed plate; a second sliding block is connected below the second sliding rail; the front parts of the first sliding block and the second sliding block are connected with the same group of sliding baffles; the left side and the right side of the sliding baffle are connected with the tray; the lower end of the sliding baffle is connected with a clapboard.

Furthermore, the material distributing assembly comprises a third fixing frame, a fourth fixing frame, a first motor, a second straight gear, a fifth fixing frame, a third sliding rail, a third sliding block, a third straight gear, a sixth fixing frame, a second toothed plate, a fourth sliding rail, a fourth sliding block, a second rotating shaft, a material distributing plate, an electromagnetic generator and a third toothed plate; the right sides of a group of first fixing frames positioned above the first electric sliding block are connected with a third fixing frame; a fourth fixing frame is connected to the rear upper part of the third fixing frame; the rear side of the fourth fixing frame is connected with a first motor; the output shaft of the first motor is connected with a second straight gear; the rear side of the fourth fixing frame is connected with a fifth fixing frame; the rear part of the fifth fixing frame is connected with a third sliding rail; the right side of the third slide rail is connected with a third slide block; a second gear plate is connected to the front upper part of the third sliding block; the second gear plate is meshed with the second straight gear; the left side of the group of first fixing frames positioned above the second electric sliding block is connected with a sixth fixing frame; the rear part of the sixth fixing frame is connected with a fourth sliding rail; the left side of the fourth slide rail is connected with a fourth slide block; the left side of the third sliding block is connected with a second rotating shaft; the right end of the second rotating shaft is connected with a fourth sliding block; the left side of the second rotating shaft is connected with a third straight gear; the middle part of the second rotating shaft is connected with a material distributing plate; an electromagnetic generator is connected above the material distributing plate; the right side of the fifth fixed frame is connected with a third toothed plate; the third toothed plate is meshed with a third straight gear; the inner sides of the third fixing frame and the sixth fixing frame are both connected with the conveying assembly.

Furthermore, the conveying assembly comprises an eighth fixed frame, a left short slide rail, a third electric slide block, a ninth fixed frame, a right short slide rail, a fourth electric slide block, a third rotating shaft, a first shaft sleeve, an upper baffle, a material receiving rod, a fourth straight gear, a second motor and a fifth straight gear; the right side of the third fixing frame is connected with an eighth fixing frame; a left short slide rail is connected below the eighth fixed frame; the rear side of the left short slide rail is connected with a third electric slide block; the left side of the sixth fixing frame is connected with a ninth fixing frame; a right short slide rail is connected below the ninth fixing frame; the rear side of the right short slide rail is connected with a fourth electric slide block; the right side of the third electric sliding block is connected with a third rotating shaft; the right end of the third rotating shaft is connected with a fourth electric sliding block; the middle part of the third rotating shaft is connected with a first shaft sleeve; an upper baffle plate is connected to the front upper part of the first shaft sleeve; the front middle part of the upper baffle is connected with a material receiving rod; the left side of the third rotating shaft is connected with a fourth straight gear; a second motor is connected to the rear of the third electric sliding block; an output of the second motor; the output shaft is connected with a fifth straight gear; the fifth spur gear meshes with the fourth spur gear.

The crushing device comprises a conveying assembly, a first shaft sleeve, a second shaft sleeve, a third straight gear, a crushing rod and a fourth toothed plate, wherein the conveying assembly is arranged in front of the conveying assembly; the right side of the left long slide rail is connected with a fifth electric slide block; the upper surface of the fifth electric sliding block is connected with a tenth fixing frame; two groups of fifth electric sliding blocks and tenth fixing frames are symmetrically arranged on the left long sliding rail and the right long sliding rail; the inner surfaces of the two groups of tenth fixing frames are connected with the same group of second shaft sleeves through rotating shafts; the outer surface of the second shaft sleeve is connected with a plurality of groups of crushing rods; the left front part of the bottom plate is connected with a fourth toothed plate.

Furthermore, only the rear side and the left and right sides of the tray are provided with flanges.

Furthermore, the material receiving rod is of a tooth-shaped structure.

Furthermore, the middle part of the upper surface of the crushing rod is provided with a slot.

The invention has the following advantages: in the technical scheme provided by the invention:

(1) The utility model discloses a high viscidity of magnetism stoste, including the spheroid, the inner core body is punctured to the inner core body, and the inner core body recovery work is punctured to the inner core body, and for solving, will prolong the processing time of diaphragm medium production to and when carrying out inner core body recovery work, the high stickness of magnetism stoste, partial magnetism stoste will be taken away by the inner core body, make the diaphragm layer attenuate of laying on the medium board, thereby influence the technical problem of the adhesion performance of product.

(2) The recovery work through setting up the spheroidal broken work of magnetism and inner core goes on in step, lets the magnetism spheroid carry out the breakage in the top of medium board and makes interior liquid fall on the medium board, makes the inner core body retrieved before contacting the medium board to the treatment effeciency that carries out stickness diaphragm cover to the medium board has been improved.

Drawings

FIG. 1 is a schematic perspective view of the present application;

FIG. 2 is a top view of the stirring member of the present application;

FIG. 3 is a perspective view of a displacement assembly of the present application;

FIG. 4 is a perspective view of the displacement assembly and fishing assembly of the present application;

FIG. 5 is a schematic perspective view of the region C of the present application;

FIG. 6 is a perspective view of a left side component of the dispensing assembly of the present application;

FIG. 7 is a perspective view of the right side component of the dispensing assembly of the present application;

FIG. 8 is a perspective view of a transfer assembly of the present application;

fig. 9 is a perspective view of a breaking assembly according to the present application.

In the reference symbols: 1-an underframe, 2-a stirring cabin, 3-a grid, 4-a main support, 5-a bottom plate, 6-a collecting disc, 101-a left long slide rail, 102-a first electric slide block, 103-a right long slide rail, 104-a second electric slide block, 105-a first fixing frame, 106-a second fixing frame, 107-a first electric push rod, 108-a telescopic support, 109-a second electric push rod, 201-a fixing plate, 202-an adapter plate, 203-a tray, 204-a side fixing frame, 205-a first rotating shaft, 206-a first straight gear, 207-a first slide rail, 208-a first slide block, 209-a second slide rail, 210-a second slide block, 211-a first toothed plate, 212-a sliding baffle, 213-a clapboard, 301-a third fixing frame and 302-a fourth fixing frame, 303-a first motor, 304-a second spur gear, 305-a fifth fixing frame, 306-a third slide rail, 307-a third slide block, 308-a third spur gear, 309-a sixth fixing frame, 310-a second toothed plate, 311-a fourth slide rail, 312-a fourth slide block, 313-a second rotating shaft, 314-a material separating plate, 315-an electromagnetic generator, 316-a third toothed plate, 401-an eighth fixing frame, 402-a left short slide rail, 403-a third electric slide block, 404-a ninth fixing frame, 405-a right short slide rail, 406-a fourth electric slide block, 407-a third rotating shaft, 408-a first shaft sleeve, 409-an upper baffle, 410-a material receiving rod, 411-a fourth spur gear, 412-a second motor, 413-a fifth spur gear, 501-a fifth electric slide block, 502-a tenth fixing frame, 503-a second shaft sleeve, 504-a sixth spur gear, 505-a crushing rod, 506-a fourth toothed plate.

Detailed Description

The invention is described in detail below with reference to the figures and the embodiments.

Examples

A non-contact high-molecular viscous membrane suspension laying crushing device is shown in a figure 1-2 and comprises a displacement assembly, a salvaging assembly, a material distribution assembly, a conveying assembly, a bottom frame 1, a stirring cabin 2, a grid 3, a main support 4, a bottom plate 5 and a collecting disc 6; the inner surface of the bottom frame 1 is fixedly connected with a stirring cabin 2; the inner bottom of the stirring cabin 2 is welded with a grid 3; the main bracket 4 is connected with the front bolt of the stirring cabin 2; a bottom plate 5 is connected with the upper part of the main bracket 4 through a bolt; a collecting tray 6 is arranged at the front upper part of the main bracket 4; the upper surface of the main bracket 4 is fixedly connected with a displacement component; the rear side bolt of the displacement component is connected with a fishing component; the fishing assembly is used for fishing the magnetic ball; the lower part of the displacement assembly is connected with a material distribution assembly through bolts; the material distributing assembly is used for discharging the magnetic spheres in batches; the inner side of the material distributing assembly is connected with a conveying assembly through bolts; the transmission assembly is used for transmitting the magnetic ball; the displacement assembly is used for driving the fishing assembly, the material distributing assembly and the conveying assembly to perform displacement work.

When the device is used, the underframe 1 and the main support 4 are placed stably, the medium plate to be processed is placed on the bottom plate 5, the rear side of the upper surface of the medium plate is positioned below the crushing rod 505 in the crushing component, the stirring cabin 2 is used for stirring the magnetic suspension to be processed, the magnetic spheres are enabled to float and sink in the stirring cabin 2 in a reciprocating manner, then the displacement component drives the salvaging component to enter the stirring cabin 2 downwards, the tray 203 in the salvaging component salvages the floated magnetic spheres, then the displacement component drives the salvaging component to move the salvaged magnetic spheres to be contacted with the material distribution component and drive the salvaging component, the material distribution component and the conveying component to move to the upper rear part of the medium plate, then the material distribution component carries out batch blanking on the magnetic spheres in the salvaging component through generating a magnetic field, and sequentially loads each batch of separated magnetic spheres into the conveying component, the conveying assembly drives the magnetic ball to move to be in contact with the breaking assembly, the breaking assembly drives the conveying assembly to crush and extrude the magnetic ball, so that an outer film of the magnetic ball is crushed, inner liquid flows out and falls on the rear side of the upper surface of the medium plate, meanwhile, the remaining inner core is taken away by the breaking assembly, then the conveying assembly resets to take off a batch of magnetic balls separated by the material separating assembly, the inner core is poured into the collecting disc 6 to be recovered by the breaking assembly, then the fishing assembly, the material separating assembly and the conveying assembly are driven by the displacement assembly to move forwards to the rear upper part of the medium plate according to the steps, the position of the breaking assembly is adjusted along with the displacement assembly after the inner core collecting operation is completed each time, and the upper surface of the medium plate is sequentially covered by the crushed inner liquid from back to front and dried to form a layer of viscous diaphragm; the device gradually covers the upper surface of the medium plate with the inner liquid from back to front in a batch blanking mode, so that the upper surface of the medium plate is uniformly covered with a layer of viscous diaphragm, the magnetic ball body is crushed above the medium plate, the inner liquid falls on the medium plate, the recovery of the inner core body is more convenient, and the processing efficiency of covering the medium plate with the viscous diaphragm is improved.

Referring to fig. 1, 3 and 4, the displacement assembly includes a left long slide rail 101, a first electric slider 102, a right long slide rail 103, a second electric slider 104, a first fixing frame 105, a second fixing frame 106, a first electric push rod 107, a telescopic bracket 108 and a second electric push rod 109; a left long slide rail 101 is fixedly connected to the left side of the upper surface of the main support 4; the rear side of the left long slide rail 101 is connected with a first electric slide block 102 in a sliding way; a right long slide rail 103 is fixedly connected to the right side of the upper surface of the main support 4; the rear side of the right long slide rail 103 is connected with a second electric slide block 104 in a sliding way; the upper surfaces of the first electric sliding block 102 and the second electric sliding block 104 are respectively connected with a group of first fixing frames 105 through bolts; the lower parts of the two groups of first fixing frames 105 are respectively connected with the material distributing assembly through bolts; the upper parts of the two groups of first fixing frames 105 are connected with the same group of second fixing frames 106 through bolts; a first electric push rod 107 is fixedly connected to the rear side of the middle part of the second fixing frame 106; the same group of telescopic brackets 108 are connected to the left and right sides of the rear part of the second fixing frame 106 through bolts; the rear part of the first electric push rod 107 is connected with the middle part of the telescopic bracket 108 through a bolt; two groups of second electric push rods 109 are connected to the rear lower part of the telescopic bracket 108 through bolts; two sets of second electric putter 109 all bolted connection salvage the subassembly.

Firstly, the second electric push rod 109 pushes the salvaging component to enter the mixing cabin 2 downwards, then the salvaging component resets upwards, the tray 203 in the salvaging component salvages the floated magnetic ball, then the first electric push rod 107 drives the telescopic bracket 108 and the parts connected with the telescopic bracket to contract inwards, the salvaging component drives the salvaged magnetic ball to move to be contacted with the material distributing component, the first electric slide block 102 and the second electric slide block 104 respectively drive the salvaging component, the material distributing component and the conveying component to move to the rear upper part of the medium plate along the left long slide rail 101 and the right long slide rail 103, then the material distributing component carries out batch blanking on the magnetic ball in the salvaging component by generating a magnetic field, the separated magnetic ball is loaded into the conveying component, and the conveying component and the breaking component carry out crushing and extruding work on the magnetic ball above the rear side of the medium plate, the outer membrane of the magnetic sphere is squeezed open, so that the inner liquid flows out and falls on the rear side of the upper surface of the medium plate, meanwhile, the remaining inner core body is taken away by the breaking component, then the conveying component is reset to receive and take off a batch of magnetic spheres separated by the material separating component, meanwhile, the inner core body is poured into the collecting tray 6 by the breaking component for recovery, after the inner liquid covering treatment work of a first region on the rear side of the upper surface of the medium plate is finished, the salvaging component, the material separating component and the conveying component are respectively driven by the first electric slide block 102 and the second electric slide block 104 along the left long slide rail 101 and the right long slide rail 103 to move forwards, the inner liquid covering treatment work of another region of the upper surface of the medium plate is carried out, and then the steps are repeated, and the inner liquid covering work of the upper surface of the medium plate is finished from back to front; the assembly drives the fishing assembly, the material distributing assembly and the conveying assembly to move.

Referring to fig. 3 to 5, the fishing assembly includes a fixing plate 201, an adapter plate 202, a tray 203, a side fixing frame 204, a first rotating shaft 205, a first straight gear 206, a first slide rail 207, a first slide block 208, a second slide rail 209, a second slide block 210, a first toothed plate 211, a sliding baffle 212, and a partition plate 213; the lower parts of the two groups of second electric push rods 109 are connected with the same group of fixing plates 201 through bolts; a group of adapter plates 202 are fixedly connected to the left side and the right side of the fixing plate 201 respectively; the inner sides of the lower parts of the two groups of adapter plates 202 are fixedly connected with the same group of trays 203; a side fixing frame 204 is fixedly connected to the left end face of the group of adapter plates 202 on the left side; the front part of the side fixing frame 204 is rotationally connected with a first rotating shaft 205; a first straight gear 206 is fixedly connected to the outer surface of the first rotating shaft 205; a first slide rail 207 is bolted to the left front of the fixed plate 201; a first sliding block 208 is connected below the first sliding rail 207 in a sliding manner; a first toothed plate 211 is fixedly connected to the left side of the first sliding block 208; the first toothed plate 211 engages the first straight gear 206; a second slide rail 209 is connected to the right front bolt of the fixing plate 201; a second sliding block 210 is connected below the second sliding rail 209 in a sliding manner; the front parts of the first sliding block 208 and the second sliding block 210 are bolted with the same group of sliding baffles 212; the left side and the right side of the sliding baffle 212 are connected with the tray 203 in a sliding way; the lower end of the sliding baffle 212 is fixedly connected with a baffle 213.

Firstly, the second electric push rod 109 pushes the fixed plate 201 and the components connected with the fixed plate to move downwards, so that the tray 203 enters the stirring cabin 2 downwards, then the second electric push rod 109 drives the fixed plate 201 and the components connected with the fixed plate to reset upwards, so that the tray 203 salvages the floated magnetic spheres, then the first electric push rod 107 drives the telescopic bracket 108 and the components connected with the telescopic bracket to contract inwards, so that the tray 203 drives the salvaged magnetic spheres to move towards the direction of the material distribution assembly, the first straight gear 206 is meshed with the second straight gear 304 in the material distribution assembly, then the rotating second straight gear 304 is meshed with the first straight gear 206 and drives the first straight gear to rotate, the first straight gear 206 is meshed with the first toothed plate 211 to drive the first sliding block 208, the sliding baffle plate 212, the second sliding rail 209 and the partition plate 213 to move upwards along the first sliding rail 207 and the second sliding block 210 respectively, so that the right side of the tray 203 is opened, meanwhile, the magnetic spheres in the tray 203 are sucked by the material distribution assembly, then the second straight gear 304 is meshed with the first straight gear 206 and drives the second sliding block 209 and the partition plate 213 to move upwards, so that the second sliding block 209 and the magnetic spheres are separated from the material distribution assembly, and the second sliding block 213 are conveyed downwards in time, and the magnetic sphere is removed into the material distribution assembly 213, and the tray 203; the assembly completes batch de-charging processing work on the magnetic spheres.

Referring to fig. 4 to 7, the material separating assembly includes a third fixing frame 301, a fourth fixing frame 302, a first motor 303, a second spur gear 304, a fifth fixing frame 305, a third slide rail 306, a third slide block 307, a third spur gear 308, a sixth fixing frame 309, a second toothed plate 310, a fourth slide rail 311, a fourth slide block 312, a second rotating shaft 313, a material separating plate 314, an electromagnetic generator 315, and a third toothed plate 316; a third fixing frame 301 is connected to the right side of the group of first fixing frames 105 positioned above the first electric sliding block 102 through bolts; a fourth fixing frame 302 is connected to the rear upper part of the third fixing frame 301 through bolts; a first motor 303 is fixedly connected to the rear side of the fourth fixing frame 302; a second straight gear 304 is fixedly connected with an output shaft of the first motor 303; a fifth fixing frame 305 is fixedly connected to the rear side of the fourth fixing frame 302; a third slide rail 306 is bolted to the rear part of the fifth fixing frame 305; a third slide block 307 is connected to the right side of the third slide rail 306 in a sliding manner; a second gear plate 310 is bolted to the upper front of the third slider 307; the second toothed plate 310 engages the second spur gear 304; a sixth fixing frame 309 is connected to the left side bolt of the group of first fixing frames 105 above the second electric slider 104; a fourth slide rail 311 is bolted to the rear part of the sixth fixing frame 309; a fourth sliding block 312 is connected to the left side of the fourth sliding rail 311 in a sliding manner; a second rotating shaft 313 is rotatably connected to the left side of the third sliding block 307; the right end of the second rotating shaft 313 is rotatably connected with the fourth sliding block 312; a third spur gear 308 is fixedly connected to the left side of the second rotating shaft 313; a material distributing plate 314 is fixedly connected to the middle part of the second rotating shaft 313; an electromagnetic generator 315 is fixedly connected above the material distributing plate 314; a third toothed plate 316 is fixedly connected to the right side of the fifth fixing frame 305; the third toothed plate 316 engages the third spur gear 308; the inner sides of the third fixing frame 301 and the sixth fixing frame 309 are both connected with the transmission assembly through bolts.

When the first spur gear 206 is meshed with the second spur gear 304, the material separating plate 314 is located at the front lower part of the tray 203, then the output shaft of the first motor 303 drives the second spur gear 304 to rotate, the second spur gear 304 is meshed with the second toothed plate 310 to drive the third sliding block 307 and components connected with the third sliding block 307 to move upwards along the third sliding rail 306, meanwhile, the second rotating shaft 313 drives the fourth sliding block 312 to move upwards along the fourth sliding rail 311, meanwhile, the third spur gear 308 is meshed with the third toothed plate 316 to drive the second rotating shaft 313 to rotate, the second rotating shaft 313 drives the material separating plate 314 to rotate, so that the material separating plate 314 moves upwards and replaces the upwards-leaving sliding baffle 212 to be clamped at the front side of the tray 203, then the electromagnetic generator 315 starts to generate a magnetic field, so that part of magnetic spheres in the tray 203 are sucked into the material separating plate 314, and then the output shaft of the first motor 303 drives the second spur gear 304 to rotate reversely, so that the loaded magnetic spheres are poured downwards into the conveying assembly by the material separating plate 314; the assembly completes batch blanking work on the magnetic spheres.

Referring to fig. 6 to 8, the conveying assembly includes an eighth fixed frame 401, a left short slide rail 402, a third electric slider 403, a ninth fixed frame 404, a right short slide rail 405, a fourth electric slider 406, a third rotating shaft 407, a first sleeve 408, an upper baffle 409, a material receiving rod 410, a fourth spur gear 411, a second motor 412, and a fifth spur gear 413; the right side of the third fixing frame 301 is connected with an eighth fixing frame 401 through bolts; a left short slide rail 402 is connected to the lower part of the eighth fixing frame 401 through a bolt; a third electric sliding block 403 is connected to the rear side of the left short sliding rail 402 in a sliding manner; a ninth fixing frame 404 is bolted to the left side of the sixth fixing frame 309; a right short slide rail 405 is connected to the lower part of the ninth fixing frame 404 through a bolt; a fourth electric sliding block 406 is connected to the rear side of the right short sliding rail 405 in a sliding manner; the right side of the third electric sliding block 403 is rotatably connected with a third rotating shaft 407; the right end of the third rotating shaft 407 is rotatably connected with a fourth electric slide block 406; a first shaft sleeve 408 is fixedly connected to the middle part of the third rotating shaft 407; an upper baffle 409 is fixedly connected to the front upper part of the first shaft sleeve 408; the front middle part of the upper baffle 409 is fixedly connected with a material receiving rod 410; a fourth spur gear 411 is fixedly connected to the left side of the third rotating shaft 407; a second motor 412 is fixedly connected to the rear of the third electric sliding block 403; the output of the second motor 412; the output shaft is fixedly connected with a fifth straight gear 413; the fifth spur gear 413 engages the fourth spur gear 411.

Firstly, the material distributing plate 314 pours the loaded magnetic sphere into the space between the upper baffle 409 and the material receiving rod 410, because the material receiving rod 410 is in an obliquely upward state, the magnetic sphere is supported and clamped in the tooth seam of the tooth-shaped structure of the material receiving rod 410, then the third electric slide block 403 and the fourth electric slide block 406 respectively drive the connected components to move towards the direction of the breaking component along the left short slide rail 402 and the right short slide rail 405, so that the material receiving rod 410 is positioned above the breaking rod 505 in the breaking component, meanwhile, the fourth spur gear 411 is meshed with the sixth spur gear 504 in the breaking component, then, the output shaft of the second motor 412 drives the fifth spur gear 413 to rotate, the fifth spur gear 413 is meshed with the fourth spur gear 411 to drive the third rotating shaft 407 to rotate, the third rotating shaft 407 drives the upper baffle 409 and the material receiving rod 410 to turn downwards through the first shaft sleeve 408, meanwhile, the fourth spur gear 411 is meshed with the sixth spur gear 504 and drives the crushing rods 505 to turn upwards, so that each group of crushing rods 505 respectively penetrate through tooth gaps in the material receiving rod 410 upwards, the crushing rods 505 press the magnetic spheres clamped in the tooth gaps of the material receiving rod 410 upwards to be in contact with the upper baffle 409, the upper baffle 409 crushes the magnetic spheres, the outer membranes of the magnetic spheres are crushed, the inner liquid flows out and falls on the upper surface of the medium plate, meanwhile, the remaining inner cores enter the grooves in the crushing rods 505, then the third electric slide block 403 and the fourth electric slide block 406 respectively drive connected components to reset reversely along the left short slide rail 402 and the right short slide rail 405, the next group of magnetic spheres separated by the material separating assembly are collected and conveyed, and meanwhile, the inner cores are poured into the collecting disc 6 by the crushing assembly to be recovered; the assembly completes the work of conveying the magnetic ball.

Referring to fig. 1 and 9, the device further comprises a breaking assembly, the breaking assembly is located in front of the conveying assembly, and the breaking assembly comprises a fifth electric sliding block 501, a tenth fixing frame 502, a second shaft sleeve 503, a sixth spur gear 504, a breaking rod 505 and a fourth toothed plate 506; a fifth electric sliding block 501 is connected to the right side of the left long sliding rail 101 in a sliding manner; the upper surface of the fifth electric sliding block 501 is connected with a tenth fixing frame 502 through bolts; two groups of fifth electric sliding blocks 501 and tenth fixing frames 502 are symmetrically arranged on the left long slide rail 101 and the right long slide rail 103; the inner surfaces of the two groups of tenth fixing frames 502 are rotatably connected with the same group of second shaft sleeves 503 through rotating shafts; a plurality of groups of crushing rods 505 are fixedly connected to the outer surface of the second shaft sleeve 503; a fourth toothed plate 506 is bolted to the front left of the bottom plate 5.

Firstly, the fourth spur gear 411 is meshed with the sixth spur gear 504 and drives the second shaft sleeve 503 and a crushing rod 505 connected with the second shaft sleeve to upwards overturn, so that each group of crushing rods 505 respectively upwards penetrate through tooth gaps in the material receiving rod 410, the crushing rod 505 presses magnetic spheres clamped in the tooth gaps of the material receiving rod 410 upwards to be in contact with an upper baffle 409, the upper baffle 409 crushes the magnetic spheres, an outer membrane of the magnetic spheres is crushed, inner liquid flows out and falls on the upper surface of a medium plate, meanwhile, the remaining inner core body enters a groove in the crushing rod 505, then, the third electric sliding block 403 and the fourth electric sliding block 406 respectively drive components connected with the third electric sliding block to reversely reset along the left short sliding rail 402 and the right short sliding rail 405, meanwhile, the two groups of fifth electric sliding blocks 501 drive the tenth fixing frame 502 and the components connected with the tenth fixing frame 502 to move towards the collecting disc 6 along the left long sliding rail 101 and the right long sliding rail 103, when the sixth spur gear 504 passes through the fourth spur gear 506, the sixth spur gear 506 is meshed with the fourth shaft sleeve 503 and the second shaft sleeve 505 connected with the collecting disc 6, and the collecting disc 6 is poured into the collecting disc 6 to be collected; this subassembly has accomplished and has carried out broken work and inner core body recovery work to the magnetism spheroid.

Wherein, only the rear side and the left and right sides of the tray 203 are provided with flanges.

The slide shutter 212 may be a front rib of the tray 203, and after the slide shutter 212 is separated from the tray 203, the material distributing plate 314 abuts on the front side opening of the tray 203.

The material receiving rod 410 is a tooth-shaped structure.

The magnetic ball can be stuck in the tooth-shaped structure of the material receiving rod 410 to wait for being broken.

Wherein, the middle part of the upper surface of the crushing rod 505 is provided with a slot.

The inner core body obtained after crushing can fall into the open slot for recovery.

The above description is only for the specific embodiments of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art can easily conceive of the changes or substitutions within the technical scope of the present invention, and all the changes or substitutions should be covered within the scope of the present invention. Therefore, the protection scope of the present invention shall be subject to the protection scope of the claims.

Claims (4)

1. A non-contact high-molecular viscous membrane suspension laying crushing device comprises a bottom frame, a stirring cabin, a grid, a main support, a bottom plate and a collecting disc; the inner surface of the bottom frame is connected with a stirring cabin; a grid is welded at the bottom in the stirring cabin; a main bracket is connected in front of the stirring cabin; a bottom plate is connected above the main bracket; a collecting tray is arranged at the front upper part of the main bracket; the method is characterized in that: the fishing device also comprises a displacement component, a fishing component, a material distributing component and a conveying component; the upper surface of the main bracket is connected with a displacement assembly; the rear side of the displacement assembly is connected with a salvaging assembly; a material distributing component is connected below the displacement component; the inner side of the material distributing component is connected with a conveying component;

the displacement assembly comprises a left long slide rail, a first electric slide block, a right long slide rail, a second electric slide block, a first fixing frame, a second fixing frame, a first electric push rod, a telescopic bracket and a second electric push rod; the left side of the upper surface of the main support is connected with a left long sliding rail; the rear side of the left long slide rail is connected with a first electric slide block; the right side of the upper surface of the main bracket is connected with a right long sliding rail; the rear side of the right long slide rail is connected with a second electric slide block; the upper surfaces of the first electric sliding block and the second electric sliding block are respectively connected with a group of first fixing frames; the lower parts of the two groups of first fixing frames are respectively connected with a material distributing component; the upper parts of the two groups of first fixing frames are connected with the same group of second fixing frames; the rear side of the middle part of the second fixing frame is connected with a first electric push rod; the left side and the right side of the rear part of the second fixing frame are connected with the same group of telescopic brackets; the rear part of the first electric push rod is connected with the middle part of the telescopic bracket; two groups of second electric push rods are connected to the rear lower part of the telescopic bracket; the two groups of second electric push rods are connected with the fishing assembly;

the salvaging component comprises a fixed plate, an adapter plate, a tray, a side fixing frame, a first rotating shaft, a first straight gear, a first sliding rail, a first sliding block, a second sliding rail, a second sliding block, a first toothed plate, a sliding baffle and a partition plate; the lower parts of the two groups of second electric push rods are connected with the same group of fixed plates; the left side and the right side of the fixed plate are respectively connected with a group of adapter plates; the inner sides below the two groups of adapter plates are connected with the same group of trays; the left end surfaces of the group of adapter plates positioned on the left side are connected with a side fixing frame; the front part of the side fixing frame is connected with a first rotating shaft; the outer surface of the first rotating shaft is connected with a first straight gear; the left front part of the fixed plate is connected with a first slide rail; a first sliding block is connected below the first sliding rail; the left side of the first sliding block is connected with a first toothed plate; the first toothed plate is meshed with the first straight gear; a second slide rail is connected to the right front of the fixed plate; a second sliding block is connected below the second sliding rail; the front parts of the first sliding block and the second sliding block are connected with the same group of sliding baffles; the left side and the right side of the sliding baffle are connected with the tray; the lower end of the sliding baffle is connected with a clapboard;

the material distribution assembly comprises a third fixing frame, a fourth fixing frame, a first motor, a second straight gear, a fifth fixing frame, a third sliding rail, a third sliding block, a third straight gear, a sixth fixing frame, a second toothed plate, a fourth sliding rail, a fourth sliding block, a second rotating shaft, a material distribution plate, an electromagnetic generator and a third toothed plate; the right sides of a group of first fixing frames positioned above the first electric sliding block are connected with a third fixing frame; a fourth fixing frame is connected to the rear upper part of the third fixing frame; the rear side of the fourth fixing frame is connected with a first motor; the output shaft of the first motor is connected with a second straight gear; the rear side of the fourth fixing frame is connected with a fifth fixing frame; the rear part of the fifth fixing frame is connected with a third sliding rail; the right side of the third slide rail is connected with a third slide block; a second gear plate is connected to the front upper part of the third sliding block; the second gear plate is meshed with the second straight gear; the left side of the group of first fixing frames positioned above the second electric sliding block is connected with a sixth fixing frame; the rear part of the sixth fixing frame is connected with a fourth sliding rail; the left side of the fourth sliding rail is connected with a fourth sliding block; the left side of the third sliding block is connected with a second rotating shaft; the right end of the second rotating shaft is connected with a fourth sliding block; the left side of the second rotating shaft is connected with a third straight gear; the middle part of the second rotating shaft is connected with a material distributing plate; an electromagnetic generator is connected above the material distributing plate; the right side of the fifth fixed frame is connected with a third toothed plate; the third toothed plate is meshed with a third straight gear; the inner sides of the third fixing frame and the sixth fixing frame are both connected with the conveying assembly;

the conveying assembly comprises an eighth fixing frame, a left short slide rail, a third electric slide block, a ninth fixing frame, a right short slide rail, a fourth electric slide block, a third rotating shaft, a first shaft sleeve, an upper baffle, a material receiving rod, a fourth straight gear, a second motor and a fifth straight gear; the right side of the third fixing frame is connected with an eighth fixing frame; a left short slide rail is connected below the eighth fixed frame; the rear side of the left short slide rail is connected with a third electric slide block; the left side of the sixth fixing frame is connected with a ninth fixing frame; a right short slide rail is connected below the ninth fixing frame; the rear side of the right short slide rail is connected with a fourth electric slide block; the right side of the third electric sliding block is connected with a third rotating shaft; the right end of the third rotating shaft is connected with a fourth electric sliding block; the middle part of the third rotating shaft is connected with a first shaft sleeve; an upper baffle plate is connected to the front upper part of the first shaft sleeve; the front middle part of the upper baffle is connected with a material receiving rod; the left side of the third rotating shaft is connected with a fourth straight gear; a second motor is connected to the rear of the third electric sliding block; an output of the second motor; the output shaft is connected with a fifth straight gear; the fifth straight gear is meshed with the fourth straight gear;

the crushing assembly is positioned in front of the conveying assembly and comprises a fifth electric sliding block, a tenth fixing frame, a second shaft sleeve, a sixth straight gear, a crushing rod and a fourth toothed plate; the right side of the left long slide rail is connected with a fifth electric slide block; the upper surface of the fifth electric sliding block is connected with a tenth fixing frame; two groups of fifth electric sliding blocks and tenth fixing frames are symmetrically arranged on the left long sliding rail and the right long sliding rail; the inner surfaces of the two groups of tenth fixing frames are connected with the same group of second shaft sleeves through rotating shafts; the outer surface of the second shaft sleeve is connected with a plurality of groups of crushing rods; the left front of the bottom plate is connected with a fourth toothed plate.

2. The non-contact high-molecular adhesive membrane suspension laying and crushing device as claimed in claim 1, wherein: only the rear side and the left and right sides of the tray are provided with flanges.

3. The non-contact high-molecular adhesive membrane suspension laying and crushing device as claimed in claim 1, wherein: the material receiving rod is of a tooth-shaped structure.

4. The non-contact high-molecular adhesive membrane suspension laying and crushing device as claimed in claim 2, wherein: the middle part of the upper surface of the crushing rod is provided with a slot.

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