CN113617512A - High-insulativity mica paper pulping pretreatment equipment - Google Patents

Abstract

The invention relates to the field of insulating materials, in particular to high-insulativity mica paper pulping pretreatment equipment. The technical problem to be solved by the invention is as follows: provides a high-insulativity mica paper pulping pretreatment device. The technical scheme of the invention is as follows: a high-insulation mica paper pulping pretreatment device comprises a support frame, a first support plate, a second support plate, a connecting frame, a controller, a separation assembly and a flotation assembly; the flotation cell is connected to the second support plate. When the flotation device is used, the stacked mica sheets are separated and then subjected to flotation, and when the flotation is finished, the floating mica sheets are separated out at one time and shaken to remove part of water, so that the resource waste is avoided, the treatment efficiency is improved, and the subsequent processing is facilitated.

Description

High-insulativity mica paper pulping pretreatment equipment

Technical Field

The invention relates to the field of insulating materials, in particular to high-insulativity mica paper pulping pretreatment equipment.

Background

The mica paper is made of high-quality Sichuan muscovite as raw material through thermochemical or hydraulic stripping and crushing to make pulp paper, and cutting into continuous web or sheet.

In the prior art, before pulping, mica ore is required to be added into a hammer mill to be crushed to obtain flaky mica sheets, then the mica sheets are added into a calcining furnace to be calcined, calcined mica is subjected to flotation, namely, the calcined mica sheets are put into a water tank to be subjected to flotation, flotation liquid injected into the water tank is water, and the floated mica is selected; when the mica sheets are stacked together after being calcined and directly put into a water tank for flotation, part of the mica sheets are not floated due to the fact that the mica sheets are stacked together heavily, and then part of useful materials are not effectively utilized, so that resource waste is caused.

In conclusion, a pretreatment device for high-insulation mica paper pulping is provided to solve the problems.

Disclosure of Invention

In order to overcome the problem that before pulping, mica ore needs to be added into a hammer mill to be crushed to obtain flaky mica sheets, then the mica sheets are added into a calcining furnace to be calcined, the calcined mica is subjected to flotation, namely the calcined mica sheets are put into a water tank to be subjected to flotation, the flotation liquid injected into the water tank is water, and the floated mica is selected; the mica sheet is calcined the back and is piled up when directly putting into the pond with it and carrying out the flotation, part mica sheet is because piling up when heavier and do not float together, and then make the useful material of part not effectively utilized, cause the wasting of resources, the mica sheet floats the back position random indefinite in the pond, the manual work is dragged for the great efficiency of work load and is lower, the mica sheet of fishing out simultaneously has many water, inconvenient direct follow-up processing's of carrying out shortcoming, the technical problem that will solve is: provides a high-insulativity mica paper pulping pretreatment device.

The technical scheme of the invention is as follows: a high-insulation mica paper pulping pretreatment device comprises a bottom frame, supporting columns, a base plate, a supporting frame, a first supporting plate, a second supporting plate, a connecting frame, a controller, a separation assembly and a flotation assembly; four corners of the bottom surface of the underframe are fixedly connected with a group of support columns respectively; the four groups of support columns are fixedly connected with one group of base plates respectively; the underframe is fixedly connected with the support frame; the underframe is fixedly connected with the first supporting plate, the second supporting plate and the connecting frame; the controller is fixedly connected with the support frame; a separation component is arranged in the middle above the underframe; the separation component is connected with the support frame; the separation assembly is connected with the connecting frame; the separation component is in transmission connection with the flotation component; the separating component separates the stacked mica sheets; flotation components are arranged in the middle and on the right side above the underframe; the flotation component is connected with the supporting frame; the flotation component is connected with the second supporting plate; the flotation assembly separates the floating mica sheets.

In one embodiment, the separating assembly comprises a first bevel gear, a first transmission rod, a second bevel gear, a third bevel gear, a separating roller, a first shaft sleeve, a first cylinder, a feeding frame, a first wedge-shaped plate, a second shaft sleeve, a transmission cylinder, a second cylinder, a first connecting rod, a strip plate, a second connecting rod, a separating plate, a first arc-shaped plate, a second arc-shaped plate and a spring; the first bevel gear is meshed with the flotation component; the first bevel gear is fixedly connected with the first transmission rod; the first transmission rod is rotatably connected with the connecting frame; the first transmission rod is fixedly connected with the second bevel gear; the second bevel gear is meshed with the third bevel gear; the third bevel gear is fixedly connected with the separation roller; the separating roller is rotationally connected with the first shaft sleeve; the separation roller is rotationally connected with the support frame; the first shaft sleeve is rotatably connected with the first cylinder; the first shaft sleeve is rotatably connected with the support frame; the first cylinder is fixedly connected with the support frame; a feeding frame is arranged above the separation roller; the feeding frame is fixedly connected with the first wedge-shaped plate and the second wedge-shaped plate; the feeding frame is fixedly connected with the supporting frame; the second shaft sleeve is rotationally connected with the separation roller; the second shaft sleeve is rotatably connected with the support frame; the second shaft sleeve is in transmission connection with the transmission cylinder; the second cylinder is rotatably connected with the second shaft sleeve; the second cylinder is fixedly connected with the support frame; the first connecting rod is fixedly connected with the second shaft sleeve; the first connecting rod is fixedly connected with the long strip plate through an elastic piece; the long slat is fixedly connected with the second connecting rod through an elastic piece; the long strip plate is connected with the separating plate in a sliding way; the second connecting rod is fixedly connected with the first shaft sleeve; a plurality of groups of separating plates are arranged on the side surface of the second connecting rod at equal intervals; the groups of separating plates are fixedly connected with the first arc-shaped plate; the first arc-shaped plate is fixedly connected with the feeding frame; the first arc-shaped plate is rotatably connected with the second arc-shaped plate through a rotating shaft and a torsion spring; the second arc-shaped plate is also fixedly connected with a plurality of groups of separating plates; one side of the spring is fixedly connected with the second connecting rod; the other side of the spring is fixedly connected with the first cylinder; a group of springs are also arranged between the second cylinder and the first connecting rod; the side surface of the first shaft sleeve is provided with two groups of combinations of second connecting rods and springs; the side surface of the second shaft sleeve is provided with two groups of combinations of first connecting rods and springs; the side surfaces of the first arc-shaped plate and the second arc-shaped plate are provided with a group of long strip plates.

In one embodiment, the flotation assembly comprises a main motor, a second transmission rod, a third shaft sleeve, a fourth bevel gear, a first fixed frame, a first electric push rod, a fourth shaft sleeve, a fifth bevel gear, a second fixed frame, a second electric push rod, a first transmission wheel, a second transmission wheel, a third transmission rod, a first flat gear, a third transmission wheel, a fourth transmission rod, a second flat gear, a sixth bevel gear, a screw rod, a first connecting plate, a flotation tank, a second connecting plate, a sliding rod, a seventh bevel gear, a fifth transmission rod, an eighth bevel gear, a third flat gear, a sixth transmission rod, a third cylinder, a first sieve plate, a third fixed frame, a seventh transmission rod, a fourth flat gear, a fourth cylinder, a second sieve plate, a first electric sliding plate and a second electric sliding plate; the main motor is fixedly connected with the underframe; the output shaft of the main motor is fixedly connected with the second transmission rod; the second transmission rod is rotatably connected with the underframe; the second transmission rod is sequentially in transmission connection with the third shaft sleeve and the fourth shaft sleeve; the third shaft sleeve is fixedly connected with a fourth bevel gear; the third shaft sleeve is rotatably connected with the first fixing frame; the first fixing frame is fixedly connected with the first electric push rod; the first electric push rod is fixedly connected with the underframe; the fourth shaft sleeve is fixedly connected with a fifth bevel gear; the fourth shaft sleeve is rotatably connected with the second fixing frame; the second fixing frame is fixedly connected with the second electric push rod; the second electric push rod is fixedly connected with the underframe; the first driving wheel is fixedly connected with the second driving rod; the first driving wheel is in transmission connection with the second driving wheel through a belt; the second driving wheel is fixedly connected with the third transmission rod; the third transmission rod is rotatably connected with the underframe; the third transmission rod is fixedly connected with the first flat gear; the third driving wheel is fixedly connected with the second driving rod; the third driving wheel is in transmission connection with the fourth driving wheel through a belt; the fourth driving wheel is fixedly connected with the fourth transmission rod; the fourth transmission rod is rotatably connected with the underframe; the fourth transmission rod is fixedly connected with the second flat gear; a sixth bevel gear is arranged on the side surface of the fourth bevel gear; when the sixth bevel gear is meshed with the fourth bevel gear, the sixth bevel gear rotates; when the sixth bevel gear is not meshed with the fourth bevel gear, the sixth bevel gear does not rotate; the sixth bevel gear is fixedly connected with the screw rod; the screw rod is rotationally connected with the support frame; the screw rod is connected with the first connecting plate in a rotating mode; the first connecting plate is fixedly connected with the flotation tank; the flotation tank is fixedly connected with the second connecting plate; the second connecting plate is in sliding connection with the sliding rod; two sides of the sliding rod are fixedly connected with the underframe and the supporting frame respectively; a seventh bevel gear is arranged on the side surface of the fifth bevel gear; when the seventh bevel gear is meshed with the fifth bevel gear, the seventh bevel gear rotates; when the seventh bevel gear is not meshed with the fifth bevel gear, the seventh bevel gear does not rotate; the seventh bevel gear is fixedly connected with the fifth transmission rod; the fifth transmission rod is rotatably connected with the support frame; the fifth transmission rod is fixedly connected with the eighth bevel gear; the eighth bevel gear is meshed with the first bevel gear; a third pinion is arranged on the side surface of the flotation tank; the third flat gear is fixedly connected with a sixth transmission rod; the sixth transmission rod is rotatably connected with the flotation tank; the sixth transmission rod is fixedly connected with the third cylinder; the third cylinder is fixedly connected with the first sieve plate; the third fixing frame is rotationally connected with the sixth transmission rod; the third fixing frame is rotationally connected with the seventh transmission rod; the seventh transmission rod is fixedly connected with the fourth flat gear; the fourth cylinder is fixedly connected with a seventh transmission rod; the fourth cylinder is fixedly connected with the second sieve plate; and the first electric sliding plate and the second electric sliding plate are both in sliding connection with the flotation tank.

In one embodiment, the second sleeve and the transmission cylinder are provided with two matching gear teeth.

In one embodiment, the second cylinder is provided with two rectangular holes as the first cylinder.

In one embodiment, the second arcuate plate is closer to the outer circumferential surface of the separation roller than the first arcuate plate.

In one embodiment, the second wedge plate is disposed at a distance from the outer circumferential surface of the separation roller.

In one embodiment, the first electric sliding plate and the second electric sliding plate are provided with a plurality of groups of sieve holes.

The invention has the advantages that: firstly, before pulping, mica ore needs to be added into a hammer mill to be crushed to obtain flaky mica sheets, then the mica sheets are added into a calcining furnace to be calcined, the calcined mica is subjected to flotation, namely the calcined mica sheets are put into a water pool to be subjected to flotation, the flotation liquid injected into the water pool is water, and the floated mica is selected; when the mica sheets are stacked together after being calcined and directly put into a water tank for flotation, part of the mica sheets are not floated due to the fact that the mica sheets are stacked together heavily, and then part of useful materials are not effectively utilized, so that resource waste is caused.

Secondly, designing a separation component, a flotation component and a collection component, placing equipment in a flotation tank when the equipment is ready to work, enabling the water level of the flotation tank to be lower than that of the collection component, switching on a power supply, slowly pouring calcined and cooled mica sheets into the separation component on the underframe supported by a first support column and a base plate, separating the stacked mica sheets by the flotation component through controlling a controller on a support frame, dropping the mica sheets into the flotation component connected with a connecting frame, driving the mica sheets to sink into the flotation tank by the flotation component, separating the floated mica sheets by the flotation component, resetting the flotation component, and collecting the separated floated mica sheets by the collection component supported by the first support plate and a second support plate;

thirdly, when the method is used, the stacked mica sheets are separated and then subjected to flotation, and when the flotation is finished, the floating mica sheets are completely separated at one time and are shaken to remove part of water, so that the resource waste is avoided, the treatment efficiency is improved, and the subsequent processing effect is facilitated.

Drawings

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

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

FIG. 3 is a first perspective view of the separator assembly of the present invention;

FIG. 4 is a second perspective view of the separator assembly of the present invention;

FIG. 5 is a third perspective view of the separator assembly of the present invention;

FIG. 6 is a first partial perspective view of the separator assembly of the present invention;

FIG. 7 is a second partial perspective view of the separator assembly of the present invention;

FIG. 8 is an enlarged view of area A of the present invention;

FIG. 9 is a third partial perspective view of the separator assembly of the present invention;

FIG. 10 is a perspective view of the slat of the present invention;

figure 11 is a schematic view of a first perspective view of a flotation cell of the present invention;

figure 12 is a schematic view of a second perspective view of the flotation cell of the present invention;

figure 13 is a schematic view of a first partial perspective view of a flotation cell of the present invention;

figure 14 is a schematic view of a second partial perspective view of a flotation cell of the present invention;

figure 15 is a top plan view of a flotation cell of the present invention;

FIG. 16 is a schematic view of a first perspective view of the collection assembly of the present invention;

FIG. 17 is a second perspective view of the collection assembly of the present invention;

fig. 18 is a partial perspective view of the collection assembly of the present invention.

In the reference symbols: 1-underframe, 2-support column, 3-backing plate, 4-support frame, 5-first support plate, 6-second support plate, 7-connecting frame, 8-controller, 401-first bevel gear, 402-first transmission rod, 403-second bevel gear, 404-third bevel gear, 405-separating roller, 406-first shaft sleeve, 407-first cylinder, 408-feeding frame, 409-first wedge plate, 410-second wedge plate, 411-second shaft sleeve, 412-transmission cylinder, 413-second cylinder, 414-first connecting rod, 415-strip plate, 416-second connecting rod, 417-separating plate, 418-first arc plate, 419-second arc plate, 420-spring, 501-main motor, 502-second drive rod, 503-third shaft sleeve, 504-fourth bevel gear, 505-first fixed mount, 506-first electric push rod, 507-fourth shaft sleeve, 508-fifth bevel gear, 509-second fixed mount, 510-second electric push rod, 511-first drive wheel, 512-second drive wheel, 513-third drive rod, 514-first flat gear, 515-third drive wheel, 516-fourth drive wheel, 517-fourth drive rod, 518-second flat gear, 519-sixth bevel gear, 520-screw rod, 521-first connecting plate, 522-flotation tank, 523-second connecting plate, 524-slide rod, 525-seventh bevel gear, 526-fifth drive rod, 527-eighth bevel gear, 528-third gear, 529-a sixth transmission rod, 530-a third cylinder, 531-a first sieve plate, 532-a third fixed frame, 533-a seventh transmission rod, 534-a fourth flat gear, 535-a fourth cylinder, 536-a second sieve plate, 537-a first electric sliding plate, 538-a second electric sliding plate, 601-an electric sliding rail, 602-an electric sliding block, 603-a collection box, 604-a fixed frame, 605-a collection cloth bag, 606-an elastic clamping plate, 607-a fixed block, 608-a rack, 609-a fifth flat gear, 610-a first shaking roller, 611-a sixth flat gear and 612-a second shaking roller.

Detailed Description

The invention will be further described with reference to examples of embodiments shown in the drawings to which the invention is attached.

Examples

A high-insulation mica paper pulping pretreatment device is shown in a figure 1-2 and comprises a bottom frame 1, a support column 2, a base plate 3, a support frame 4, a first support plate 5, a second support plate 6, a connecting frame 7, a controller 8, a separation assembly and a flotation assembly; four corners of the bottom surface of the underframe 1 are fixedly connected with a group of support columns 2 respectively; the four groups of support columns 2 are respectively fixedly connected with a group of backing plates 3; the underframe 1 is fixedly connected with the support frame 4; the underframe 1 is fixedly connected with a first supporting plate 5, a second supporting plate 6 and a connecting frame 7; the controller 8 is fixedly connected with the support frame 4; a separation component is arranged in the middle of the upper part of the underframe 1; the separation component is connected with the support frame 4; the separation component is connected with the connecting frame 7; the separation component is in transmission connection with the flotation component; the separating component separates the stacked mica sheets; flotation components are arranged in the middle and on the right side above the underframe 1; the flotation component is connected with the supporting frame 4; the flotation assembly is connected with the second support plate 6; the flotation assembly separates the floating mica sheets.

During preparation, the equipment is placed in a flotation tank, the water level of the flotation tank is lower than that of a collecting component, a power supply is switched on, the calcined and cooled mica sheets are slowly poured into a separating component on a bottom frame 1 supported by a first support column 2 and a base plate 3, the separating component is driven by the flotation component to separate the stacked mica sheets by controlling a controller 8 on a support frame 4, then the mica sheets fall into a flotation component connected with a connecting frame 7, then the flotation component drives the mica sheets to sink into the flotation tank, the flotation component separates the floating mica sheets, then the flotation component resets, and then the separated floating mica sheets are collected by the collecting component supported by a first support plate 5 and a second support plate 6; when the flotation device is used, the stacked mica sheets are separated and then subjected to flotation, and when the flotation is finished, the floating mica sheets are separated out at one time and shaken to remove part of water, so that the resource waste is avoided, the treatment efficiency is improved, and the subsequent processing is facilitated.

Referring to fig. 3-10, the separating assembly includes a first bevel gear 401, a first driving rod 402, a second bevel gear 403, a third bevel gear 404, a separating roller 405, a first bushing 406, a first cylinder 407, a feeding frame 408, a first wedge plate 409, a second wedge plate 410, a second bushing 411, a driving cylinder 412, a second cylinder 413, a first connecting rod 414, a long strip 415, a second connecting rod 416, a separating plate 417, a first arc plate 418, a second arc plate 419 and a spring 420; the first bevel gear 401 is meshed with the flotation cell; the first bevel gear 401 is fixedly connected with the first transmission rod 402; the first transmission rod 402 is rotatably connected with the connecting frame 7; the first transmission rod 402 is fixedly connected with the second bevel gear 403; the second bevel gear 403 is meshed with the third bevel gear 404; the third bevel gear 404 is fixedly connected with the separation roller 405; the separation roller 405 is in rotational connection with the first hub 406; the separation roller 405 is rotatably connected with the support frame 4; the first sleeve 406 is rotatably connected to the first cylinder 407; the first shaft sleeve 406 is rotatably connected with the support frame 4; the first cylinder 407 is fixedly connected with the support frame 4; a feeding frame 408 is arranged above the separation roller 405; the feeding frame 408 is fixedly connected with a first wedge-shaped plate 409 and a second wedge-shaped plate 410; the feeding frame 408 is fixedly connected with the support frame 4; the second bushing 411 is rotationally connected with the separation roller 405; the second shaft sleeve 411 is rotatably connected with the support frame 4; the second shaft sleeve 411 is in transmission connection with the transmission cylinder 412; the second cylinder 413 is rotatably connected with the second shaft sleeve 411; the second cylinder 413 is fixedly connected with the support frame 4; the first connecting rod 414 is fixedly connected with the second shaft sleeve 411; the first connecting rod 414 is fixedly connected with the long strip plate 415 through an elastic piece; the long strip plate 415 is fixedly connected with the second connecting rod 416 through an elastic piece; the long strip plate 415 is connected with the separation plate 417 in a sliding way; the second connecting rod 416 is fixedly connected with the first shaft sleeve 406; a plurality of groups of separation plates 417 are equidistantly arranged on the side surface of the second connecting rod 416; the multiple groups of separating plates 417 are fixedly connected with the first arc-shaped plate 418; the first arc plate 418 is fixedly connected with the feeding frame 408; the first arc plate 418 is rotatably connected with the second arc plate 419 by a rotating shaft and a torsion spring 420; the second arc-shaped plate 419 is also fixedly connected with a plurality of groups of separating plates 417; one side of the spring 420 is fixedly connected with the second connecting rod 416; the other side of the spring 420 is fixedly connected with the first cylinder 407; a set of springs 420 is also arranged between the second cylinder 413 and the first connecting rod 414; the side surface of the first shaft sleeve 406 is provided with two groups of combinations of the second connecting rods 416 and the springs 420; the side of the second shaft sleeve 411 is provided with two groups of combinations of the first connecting rods 414 and the springs 420; the first arcuate plate 418 and the second arcuate plate 419 are each flanked by a set of elongated strips 415.

Slowly pouring the calcined and cooled mica sheets into a feeding frame 408, falling on a first wedge plate 409 and a second wedge plate 410 and sliding into a space between a separation roller 405 and a first arc plate 418, simultaneously, the contraction power of the flotation assembly drives a first bevel gear 401 to drive a first transmission rod 402 to rotate, the first transmission rod 402 drives a second bevel gear 403 to drive a third bevel gear 404 to rotate, the third bevel gear 404 drives the separation roller 405 to rotate, the separation roller 405 drives the mica sheets to move downwards along the outer ring surface when rotating, the mica sheets collide with a multi-group separation plate 417 on the first arc plate 418 and the second arc plate 419 when moving downwards, the stacked mica sheets are separated by the separation plate 417 and then fall into the flotation assembly downwards, a transmission cylinder 412 is driven to rotate when the separation roller 405 rotates, gear teeth on the transmission cylinder 412 and gear teeth on a second shaft sleeve 411 drive the second shaft sleeve 411 to rotate by a preset angle, the second bushing 411 drives the two sets of first connecting rods 414 to swing in the rectangular holes of the second cylinder 413, thereby causing the spring 420 therein to be stretched, the first connecting rod 414 swings to bring the strip 415 to slide on the multi-component stripping plate 417, thereby driving the two sets of second connecting rods 416 on the first shaft sleeve 406 to swing in the rectangular holes in the first cylinder 407, thereby causing the springs 420 therein to be stretched, while the elastic members at both sides of the strip 415 are stretched, so that it can always slide against the separation plate 417, and when the gear teeth on the second collar 411 are not engaged with the gear teeth on the transmission cylinder 412, the spring 420 drives the first connecting rod 414 and the second connecting rod 416 to return due to the elastic force, the strip plate 415 is then reversely slid and reset on the separation plate 417, so that the mica sheets clamped in the separation plate 417 are pushed out and fall down, and after all the mica sheets are separated, the mica sheets are treated by a flotation assembly; the assembly separates stacked mica sheets and drops the separated mica sheets into the flotation assembly for treatment.

Referring to fig. 11-15, the flotation cell comprises a main motor 501, a second transmission rod 502, a third shaft sleeve 503, a fourth bevel gear 504, a first fixed frame 505, a first electric push rod 506, a fourth shaft sleeve 507, a fifth bevel gear 508, a second fixed frame 509, a second electric push rod 510, a first transmission wheel 511, a second transmission wheel 512, a third transmission rod 513, a first flat gear 514, a third transmission wheel 515, a fourth transmission wheel 516, a fourth transmission rod 517, a second flat gear 518 and a sixth bevel gear 519, the device comprises a screw rod 520, a first connecting plate 521, a flotation tank 522, a second connecting plate 523, a sliding rod 524, a seventh bevel gear 525, a fifth transmission rod 526, an eighth bevel gear 527, a third bevel gear 528, a sixth transmission rod 529, a third cylinder 530, a first screen plate 531, a third fixed frame 532, a seventh transmission rod 533, a fourth bevel gear 534, a fourth cylinder 535, a second screen plate 536, a first electric sliding plate 537 and a second electric sliding plate 538; the main motor 501 is fixedly connected with the underframe 1; the output shaft of the main motor 501 is fixedly connected with a second transmission rod 502; the second transmission rod 502 is rotatably connected with the underframe 1; the second transmission rod 502 is in transmission connection with the third shaft sleeve 503 and the fourth shaft sleeve 507 in sequence; the third shaft sleeve 503 is fixedly connected with the fourth bevel gear 504; the third shaft sleeve 503 is rotatably connected with the first fixing frame 505; the first fixing frame 505 is fixedly connected with the first electric push rod 506; the first electric push rod 506 is fixedly connected with the underframe 1; the fourth shaft sleeve 507 is fixedly connected with a fifth bevel gear 508; the fourth shaft sleeve 507 is rotatably connected with the second fixing frame 509; the second fixing frame 509 is fixedly connected with the second electric push rod 510; the second electric push rod 510 is fixedly connected with the underframe 1; the first driving wheel 511 is fixedly connected with the second driving rod 502; the first driving wheel 511 is in driving connection with the second driving wheel 512 through a belt; the second driving wheel 512 is fixedly connected with a third transmission rod 513; the third transmission rod 513 is rotatably connected with the underframe 1; the third transmission rod 513 is fixedly connected with the first flat gear 514; the third driving wheel 515 is fixedly connected with the second driving rod 502; the third driving wheel 515 is in driving connection with the fourth driving wheel 516 through a belt; the fourth driving wheel 516 is fixedly connected with a fourth driving rod 517; the fourth transmission rod 517 is rotatably connected with the underframe 1; the fourth transmission rod 517 is fixedly connected with the second flat gear 518; a sixth bevel gear 519 is arranged on the side surface of the fourth bevel gear 504; when the sixth bevel gear 519 is engaged with the fourth bevel gear 504, the sixth bevel gear 519 rotates; when the sixth bevel gear 519 is not engaged with the fourth bevel gear 504, the sixth bevel gear 519 does not rotate; the sixth bevel gear 519 is fixedly connected with the screw 520; the screw rod 520 is rotatably connected with the support frame 4; the screw rod 520 is rotatably connected with the first connecting plate 521; the first connecting plate 521 is fixedly connected with the flotation tank 522; the flotation tank 522 is fixedly connected with a second connecting plate 523; the second connecting plate 523 is connected with the sliding rod 524 in a sliding manner; two sides of the sliding rod 524 are fixedly connected with the underframe 1 and the support frame 4 respectively; a seventh bevel gear 525 is arranged on the side surface of the fifth bevel gear 508; when the seventh bevel gear 525 is engaged with the fifth bevel gear 508, the seventh bevel gear 525 rotates; when the seventh bevel gear 525 is not engaged with the fifth bevel gear 508, the seventh bevel gear 525 does not rotate; the seventh bevel gear 525 is fixedly connected with the fifth transmission rod 526; the fifth transmission rod 526 is rotatably connected with the support frame 4; the fifth transmission rod 526 is fixedly connected with the eighth bevel gear 527; the eighth bevel gear 527 is meshed with the first bevel gear 401; a third pinion 528 is arranged on the side surface of the flotation tank 522; the third flat gear 528 is fixedly connected with the sixth transmission rod 529; the sixth drive link 529 is rotationally connected to the flotation tank 522; the sixth transmission rod 529 is fixedly connected with the third cylinder 530; the third cylinder 530 is fixedly connected with the first sieve plate 531; the third fixing frame 532 is rotatably connected with a sixth transmission rod 529; the third fixing frame 532 is rotatably connected with the seventh transmission rod 533; the seventh transmission rod 533 is fixedly connected with the fourth flat gear 534; the fourth cylinder 535 is fixedly connected to the seventh driving rod 533; the fourth cylinder 535 is fixedly connected to the second screen 536; both the first and second motorized slide plates 537, 538 are slidably connected to the flotation tank 522.

After all mica sheets are separated and fall into the flotation tank 522, the main motor 501 is started, the output shaft of the main motor 501 drives the second transmission rod 502 to rotate, the second transmission rod 502 simultaneously drives the third shaft sleeve 503, the fourth shaft sleeve 507, the first transmission wheel 511 and the third transmission wheel 515 to rotate, the third shaft sleeve 503 drives the fourth bevel gear 504 to rotate, the fourth shaft sleeve 507 drives the fifth bevel gear 508 to rotate, when the separation assembly needs to transmit power, the second electric push rod 510 extends to push the second fixed frame 509, so that the fourth shaft sleeve 507 slides on the second transmission rod 502, the fifth bevel gear 508 is meshed with the seventh bevel gear 525, the seventh bevel gear 525 drives the fifth transmission rod 526 to transmit the rotation of the eighth bevel gear 527 to transmit power to the operation of the separation assembly, then the first electric push rod 506 extends to push the first fixed frame 505, so that the third shaft sleeve 503 slides on the second transmission rod 502, the fourth bevel gear 504 is meshed with a sixth bevel gear 519, the sixth bevel gear 519 rotates to drive a screw rod 520 to rotate, the screw rod 520 drives a first connecting plate 521 which is in rotary connection with the screw rod 520 to move downwards, a flotation tank 522 drives a second connecting plate 523 to slide downwards on a sliding rod 524, the flotation tank 522 further drives mica sheets to be immersed into water in a flotation tank, meanwhile, a third gear 528 is meshed with a first gear 514, a second gear 518 is meshed with a fourth gear 534, then, a main motor 501 is turned off to perform flotation on the mica sheets in the mica sheets, after the flotation is completed, the main motor 501 is started, a first transmission wheel 511 drives a second transmission wheel 512 to drive a third transmission rod 513 to rotate, the third transmission rod 513 drives the first gear 514 to drive the third gear 528 to rotate, a third gear sieve plate 528 drives a sixth transmission rod 529 to drive a third cylinder 530 to rotate, and the third cylinder 530 drives the first transmission wheel 531 to turn to a horizontal state, meanwhile, the third transmission wheel 515 drives the fourth transmission wheel 516 to transmit the fourth transmission rod 517 to rotate, the fourth transmission rod 517 drives the second flat gear 518 to transmit the fourth flat gear 534 to rotate, the fourth flat gear 534 drives the seventh transmission rod 533 to transmit the fourth cylinder 535 to rotate, the fourth cylinder 535 drives the second sieve plate 536 to turn to the horizontal state, the initial state of the second sieve plate 536 and the first sieve plate 531 is the merging state, the second sieve plate 536 and the first sieve plate 531 simultaneously turn to the horizontal state, the mica sheets floating in the flotation tank 522 are separated and left on the second sieve plate 536 and the first sieve plate, then the first electric sliding plate 537 and the second electric sliding plate 538 simultaneously slide away from each other to drop the mica sheets at the bottom of the flotation tank 522, then slide reversely to reset, then the main motor 501 rotates reversely, and then the second transmission rod 502 rotates reversely, so that the second sieve plate 536 and the first sieve plate 531 reversely turn to reset to the merging state, then the main motor 501 is turned off, meanwhile, due to the fact that the elastic parts are arranged on the opposite surfaces of the second sieve plate 536 and the first sieve plate 531, when the second sieve plate 536 and the first sieve plate 531 are combined, the elastic parts are extruded, the second sieve plate 536 and the first sieve plate 531 shake, mica sheets left on the surfaces of the second sieve plate 536 and the first sieve plate 531 shake, the mica sheets shake and fall on the first electric sliding plate 537 and the second electric sliding plate 538, then the main motor 501 rotates reversely, the sixth bevel gear 519 rotates reversely, the flotation tank 522 is lifted and reset, then the collecting assembly operates, then the first electric sliding plate 537 and the second electric sliding plate 538 below the third fixing frame 532 slide away from each other at the same time, and the mica sheets on the surfaces of the first electric sliding plate 537 and the second electric sliding plate 538 fall into the collecting assembly; the assembly carries out flotation on the separated mica sheets and separates the floating mica sheets.

Referring to fig. 16-18, the collecting device is further included, and the collecting device includes an electric slide rail 601, an electric slide block 602, a collecting box 603, a fixed frame 604, a collecting cloth bag 605, an elastic clamping plate 606, a fixed block 607, a rack 608, a fifth flat gear 609, a first shaking roller 610, a sixth flat gear 611 and a second shaking roller 612; the electric slide rail 601 is fixedly connected with the first support plate 5 and the second support plate 6 respectively; the electric slide rail 601 is connected with the electric slide block 602 in a sliding manner; the electric slide block 602 is fixedly connected with the collection box 603; the collection box 603 is connected with the fixed frame 604 in a sliding way; the fixed frame 604 is connected with the collecting cloth bag 605 in a sliding way; a group of elastic clamping plates 606 are fixed on the periphery of the inner wall of the fixed frame 604; a group of fixed blocks 607 is fixed on both sides of the fixed frame 604; a rack 608 is arranged on the side surface of the collecting box 603; the rack 608 is fixedly connected with the underframe 1; the rack 608 is in transmission connection with a fifth flat gear 609; the fifth spur gear 609 is fixedly connected with the first shaking roller 610; the first shaking roller 610 is rotatably connected with the collection tank 603; the sixth flat gear 611 is in transmission connection with the rack 608; the sixth spur gear 611 is fixedly connected with the second shaking roller 612; the second shaking roller 612 is rotatably connected with the collection box 603; a plurality of sets of combinations of a fifth spur gear 609, a first shaking roller 610, a sixth spur gear 611 and a second shaking roller 612 are equidistantly arranged in the collection box 603; the bottom surface of the collecting cloth bag 605 is in contact with the outer circumferential surfaces of the plurality of sets of the first and second shaking rollers 610 and 612.

After the flotation tank 522 rises and resets, the electric sliding block 602 slides in the electric sliding rail 601, further drives the collecting box 603 to move to the position under the flotation tank 522, then mica sheets drop into the collecting cloth bag 605, then the electric sliding block 602 slides and resets reversely, the collecting box 603 drives a plurality of groups of first shaking rollers 610 and second shaking rollers 612 to move when moving, so that a fifth flat gear 609 and a sixth flat gear 611 are meshed with the rack 608, further the first shaking rollers 610 and the second shaking rollers 612 rotate, further, the bottom of the collecting cloth bag 605 is pressed by the protrusions on the outer ring surface of the collecting cloth bag to shake the mica sheets, the water in the mica sheets flows out of the sieve holes at the bottom of the collecting box 603 through the collecting cloth bag 605, then the four groups of elastic clamping plates 606 slide and are separated from the collecting cloth bag 605 by lifting the fixing blocks 607 on two sides of the fixing frame 604, further, the collecting cloth bag 605 can be taken out of the collecting box 603, so as to carry out subsequent processing treatment on the mica sheets in the collecting cloth bag 605; the assembly collects mica sheets and shakes the mica sheets at the same time, so that residual water in the mica sheets flows away.

The second sleeve 411 and the transmission cylinder 412 are provided with two matching gear teeth.

So that the rotation of the transmission cylinder 412 drives the rotation of the second shaft sleeve 411.

The second cylinder 413 is provided with two rectangular holes like the first cylinder 407.

So that the first connecting rod 414 swings therein.

The second arcuate plate 419 is closer to the outer circumferential surface of the separation roller 405 than the first arcuate plate 418 is to the outer circumferential surface of the separation roller 405.

So that the separator plate 417 on the second arcuate plate 419 further separates the mica sheets.

A distance is provided between the second wedge plate 410 and the outer circumferential surface of the separation roller 405.

So that the mica enters between the separation roller 405 and the first arcuate plate 418.

A plurality of groups of sieve holes are arranged on the first electric sliding plate 537 and the second electric sliding plate 538.

So that water flows out of the sieve holes.

The above description is only an example of the present invention and is not intended to limit the present invention. All equivalents which come within the spirit of the invention are therefore intended to be embraced therein. Details not described herein are well within the skill of those in the art.

Claims (8)

1. A high-insulation mica paper pulping pretreatment device comprises a bottom frame (1), support columns (2), a base plate (3), a support frame (4), a first support plate (5), a second support plate (6) and a connecting frame (7); four corners of the bottom surface of the bottom frame (1) are fixedly connected with a group of support columns (2) respectively; the four groups of support columns (2) are fixedly connected with a group of backing plates (3) respectively; the underframe (1) is fixedly connected with the support frame (4); the underframe (1) is fixedly connected with the first supporting plate (5), the second supporting plate (6) and the connecting frame (7); the method is characterized in that: also comprises a separation component and a flotation component; a separation component is arranged in the middle above the bottom frame (1); the separation component is connected with the support frame (4); the separation component is connected with the connecting frame (7); the separation component is in transmission connection with the flotation component; the separating component separates the stacked mica sheets; flotation components are arranged in the middle and on the right side above the underframe (1); the flotation component is connected with the supporting frame (4); the flotation component is connected with a second supporting plate (6); the flotation assembly separates the floating mica sheets.

2. The high-insulation mica paper pulping pretreatment equipment as recited in claim 1, characterized in that: the separating assembly comprises a first bevel gear (401), a first transmission rod (402), a second bevel gear (403), a third bevel gear (404), a separating roller (405), a first shaft sleeve (406), a first cylinder (407), a feeding frame (408), a first wedge plate (409), a second wedge plate (410), a second shaft sleeve (411), a transmission cylinder (412), a second cylinder (413), a first connecting rod (414), a long strip plate (415), a second connecting rod (416), a separating plate (417), a first arc plate (418), a second arc plate (419) and a spring (420); a first bevel gear (401) is meshed with the flotation component; the first bevel gear (401) is fixedly connected with the first transmission rod (402); the first transmission rod (402) is rotatably connected with the connecting frame (7); the first transmission rod (402) is fixedly connected with the second bevel gear (403); the second bevel gear (403) is meshed with the third bevel gear (404); the third bevel gear (404) is fixedly connected with the separation roller (405); the separation roller (405) is in rotational connection with the first bushing (406); the separation roller (405) is rotatably connected with the support frame (4); the first shaft sleeve (406) is rotatably connected with the first cylinder (407); the first shaft sleeve (406) is rotatably connected with the support frame (4); the first cylinder (407) is fixedly connected with the support frame (4); a feeding frame (408) is arranged above the separation roller (405); the feeding frame (408) is fixedly connected with the first wedge-shaped plate (409) and the second wedge-shaped plate (410); the feeding frame (408) is fixedly connected with the supporting frame (4); the second shaft sleeve (411) is rotationally connected with the separation roller (405); the second shaft sleeve (411) is rotationally connected with the support frame (4); the second shaft sleeve (411) is in transmission connection with the transmission cylinder (412); the second cylinder (413) is rotatably connected with the second shaft sleeve (411); the second cylinder (413) is fixedly connected with the support frame (4); the first connecting rod (414) is fixedly connected with the second shaft sleeve (411); the first connecting rod (414) is fixedly connected with the long strip plate (415) through an elastic piece; the long strip plate (415) is fixedly connected with the second connecting rod (416) through an elastic piece; the long strip plate (415) is connected with the separation plate (417) in a sliding way; the second connecting rod (416) is fixedly connected with the first shaft sleeve (406); a plurality of groups of separation plates (417) are equidistantly arranged on the side surface of the second connecting rod (416); the groups of separating plates (417) are fixedly connected with the first arc-shaped plate (418); the first arc-shaped plate (418) is fixedly connected with the feeding frame (408); the first arc-shaped plate (418) is rotatably connected with the second arc-shaped plate (419) through a rotating shaft and a torsion spring (420); a plurality of groups of separating plates (417) are also fixedly connected to the second arc-shaped plate (419); one side of the spring (420) is fixedly connected with the second connecting rod (416); the other side of the spring (420) is fixedly connected with the first cylinder (407); a group of springs (420) are also arranged between the second cylinder (413) and the first connecting rod (414); the side surface of the first shaft sleeve (406) is provided with two groups of combinations of second connecting rods (416) and springs (420); the side surface of the second shaft sleeve (411) is provided with two groups of combinations of first connecting rods (414) and springs (420); the sides of the first arc-shaped plate (418) and the second arc-shaped plate (419) are provided with a group of long strip plates (415).

3. The high-insulation mica paper pulping pretreatment equipment as recited in claim 2, characterized in that: the flotation component comprises a main motor (501), a second transmission rod (502), a third shaft sleeve (503), a fourth bevel gear (504), a first fixing frame (505), a first electric push rod (506), a fourth shaft sleeve (507), a fifth bevel gear (508), a second fixing frame (509), a second electric push rod (510), a first transmission wheel (511), a second transmission wheel (512), a third transmission rod (513), a first flat gear (514), a third transmission wheel (515), a fourth transmission wheel (516), a fourth transmission rod (517), a second flat gear (518), a sixth bevel gear (519), a screw rod (520), a first connecting plate (521), a flotation tank (522), a second connecting plate (523), a sliding rod (524), a seventh bevel gear (525), a fifth transmission rod (526), an eighth bevel gear (527), a third flat gear (528), a sixth transmission rod (529), a flotation tank (522), a flotation tank (523), a sliding rod (524), a seventh bevel gear (525), a fifth transmission rod (526), an eighth bevel gear (527), a third bevel gear (528), a sixth transmission rod (529), A third cylinder (530), a first sieve plate (531), a third fixing frame (532), a seventh transmission rod (533), a fourth flat gear (534), a fourth cylinder (535), a second sieve plate (536), a first electric sliding plate (537) and a second electric sliding plate (538); the main motor (501) is fixedly connected with the underframe (1); the output shaft of the main motor (501) is fixedly connected with a second transmission rod (502); the second transmission rod (502) is rotatably connected with the underframe (1); the second transmission rod (502) is in transmission connection with the third shaft sleeve (503) and the fourth shaft sleeve (507) in sequence; the third shaft sleeve (503) is fixedly connected with a fourth bevel gear (504); the third shaft sleeve (503) is rotatably connected with the first fixing frame (505); the first fixing frame (505) is fixedly connected with a first electric push rod (506); the first electric push rod (506) is fixedly connected with the bottom frame (1); the fourth shaft sleeve (507) is fixedly connected with a fifth bevel gear (508); the fourth shaft sleeve (507) is rotatably connected with the second fixed frame (509); the second fixing frame (509) is fixedly connected with a second electric push rod (510); the second electric push rod (510) is fixedly connected with the underframe (1); the first driving wheel (511) is fixedly connected with the second driving rod (502); the first driving wheel (511) is in transmission connection with the second driving wheel (512) through a belt; the second driving wheel (512) is fixedly connected with the third transmission rod (513); the third transmission rod (513) is rotatably connected with the underframe (1); the third transmission rod (513) is fixedly connected with the first flat gear (514); the third driving wheel (515) is fixedly connected with the second driving rod (502); the third driving wheel (515) is in transmission connection with a fourth driving wheel (516) through a belt; the fourth driving wheel (516) is fixedly connected with a fourth driving rod (517); the fourth transmission rod (517) is rotatably connected with the underframe (1); the fourth transmission rod (517) is fixedly connected with the second flat gear (518); a sixth bevel gear (519) is arranged on the side surface of the fourth bevel gear (504); when the sixth bevel gear (519) is meshed with the fourth bevel gear (504), the sixth bevel gear (519) rotates; when the sixth bevel gear (519) is not meshed with the fourth bevel gear (504), the sixth bevel gear (519) does not rotate; the sixth bevel gear (519) is fixedly connected with the screw rod (520); the screw rod (520) is rotatably connected with the support frame (4); the screw rod (520) is in screwed connection with the first connecting plate (521); the first connecting plate (521) is fixedly connected with the flotation tank (522); the flotation tank (522) is fixedly connected with the second connecting plate (523); the second connecting plate (523) is in sliding connection with the sliding rod (524); two sides of the sliding rod (524) are fixedly connected with the underframe (1) and the support frame (4) respectively; a seventh bevel gear (525) is arranged on the side surface of the fifth bevel gear (508); when the seventh bevel gear (525) is engaged with the fifth bevel gear (508), the seventh bevel gear (525) rotates; when the seventh bevel gear (525) is not meshed with the fifth bevel gear (508), the seventh bevel gear (525) does not rotate; the seventh bevel gear (525) is fixedly connected with the fifth transmission rod (526); the fifth transmission rod (526) is rotatably connected with the support frame (4); the fifth transmission rod (526) is fixedly connected with the eighth bevel gear (527); the eighth bevel gear (527) is meshed with the first bevel gear (401); a third pinion (528) is arranged on the side surface of the flotation tank (522); the third flat gear (528) is fixedly connected with a sixth transmission rod (529); the sixth transmission rod (529) is in rotary connection with the flotation tank (522); the sixth transmission rod (529) is fixedly connected with the third cylinder (530); the third cylinder (530) is fixedly connected with the first sieve plate (531); the third fixing frame (532) is rotatably connected with a sixth transmission rod (529); the third fixed frame (532) is rotatably connected with the seventh transmission rod (533); the seventh transmission rod (533) is fixedly connected with the fourth flat gear (534); the fourth cylinder (535) is fixedly connected with a seventh transmission rod (533); the fourth cylinder (535) is fixedly connected with the second sieve plate (536); the first electric sliding plate (537) and the second electric sliding plate (538) are both connected with the flotation tank (522) in a sliding way.

4. The high-insulation mica paper pulping pretreatment equipment as recited in claim 2, characterized in that: two matched gear teeth are arranged on the second shaft sleeve (411) and the transmission cylinder (412).

5. The high-insulation mica paper pulping pretreatment equipment as recited in claim 2, characterized in that: the second cylinder (413) is provided with two rectangular holes like the first cylinder (407).

6. The high-insulation mica paper pulping pretreatment equipment as recited in claim 2, characterized in that: the second arc-shaped plate (419) is closer to the outer circumferential surface of the separation roller (405) than the first arc-shaped plate (418).

7. The high-insulation mica paper pulping pretreatment equipment as recited in claim 2, characterized in that: a certain distance is arranged between the second wedge-shaped plate (410) and the outer ring surface of the separation roller (405).

8. The high-insulation mica paper pulping pretreatment equipment as recited in claim 3, characterized in that: a plurality of groups of sieve holes are arranged on the first electric sliding plate (537) and the second electric sliding plate (538).

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