CN113584937B - Mica paper crude product modification soaking treatment equipment - Google Patents

Abstract

The invention relates to the technical field of mica paper processing, in particular to mica paper crude product modification and soaking treatment equipment. The technical problem to be solved by the invention is as follows: provides a mica paper crude product modifying and soaking treatment device. The technical scheme of the invention is as follows: a mica paper crude product modification soaking treatment device comprises a portal frame, a first electric push rod, a second electric push rod, a solution tank, a support frame, a soaking smoothing component, a pushing component and a turning component; the overturning assembly is connected with the portal frame. When the mica paper soaking device is used, the mica paper is mutually isolated during soaking, the soaking agent is fully permeated into the mica paper when the mica paper is pressed, and the residual soaking agent in the mica paper is extruded out after the soaking is finished, so that the time required by drying is reduced.

Description

Mica paper crude product modification soaking treatment equipment

Technical Field

The invention relates to the technical field of mica paper processing, in particular to mica paper crude product modification and soaking treatment equipment.

Background

The mica paper is prepared by taking high-quality Sichuan muscovite as a raw material, thermally chemical or hydraulically stripping and crushing the raw material into pulp and papermaking, and then cutting the pulp and papermaking into continuous roll paper or single paper, wherein the market of the mica paper is as follows: the mechanical department has long determined that mica insulating materials for motors mainly use mica paper to replace mica flakes, and the demand of the mica paper is continuously increased along with the development of the electrical industry.

In the prior art, mica pulp is manufactured on a paper machine, then mica paper is dried to obtain a crude mica paper product, a modified soaking agent is prepared according to a formula, the obtained crude mica paper product is soaked in the modified soaking agent to ensure that the crude mica paper product is completely soaked in the modified soaking agent, and the obtained crude mica paper product is taken out and dried to obtain the mica paper; the surface of the mica paper is slightly uneven after being dried, a large amount of modifier is remained in the soaked mica paper, a large amount of time is consumed for directly drying, meanwhile, a plurality of mica papers are easily stacked together during soaking, so that the mica papers are difficult to separate after soaking, and the soaking agent is difficult to fully permeate into the mica paper, so that the soaking effect is poor.

Aiming at the problems, a mica paper crude product modification soaking treatment device is provided to solve the problems.

Disclosure of Invention

In order to overcome the defects that mica pulp is manufactured on a paper machine, mica paper is dried to obtain a crude mica paper product, a modified soaking agent is prepared according to a formula, the obtained crude mica paper product is soaked in the modified soaking agent to ensure that the crude mica paper product is completely soaked in the modified soaking agent, and the crude mica paper product is taken out and dried to obtain the mica paper; the mica paper surface can appear the condition of slight unevenness after the drying, remains a large amount of modifiers in the mica paper after soaking, directly carries out the drying and needs consume a large amount of time, and many mica paper pile together easily when soaking simultaneously for it is difficult to separate after soaking, and during soaking agent was difficult fully to permeate the mica paper, soaks the poor shortcoming of effect, and the technical problem that will solve is: provides a mica paper crude product modifying and soaking treatment device.

The technical scheme of the invention is as follows: a mica paper crude product modification and soaking treatment device comprises a bottom frame, a support column, a base plate, a portal frame, a first electric push rod, a second electric push rod, a solution tank, a support frame, a soaking smoothing component, a pushing component and a turning component; 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 portal frame, the first electric push rod, the second electric push rod and the support frame; the first electric push rod and the second electric push rod are fixedly connected with the solution tank; a soaking and smoothing assembly is arranged in the middle of the upper part of the bottom frame; the soaking smoothing component is connected with the pushing component; the soaking smoothing component enables the mica paper to be soaked and smoothed at the same time; pushing components are arranged at the middle part and the left side above the underframe; the pushing assembly is connected with the supporting frame; the pushing assembly is connected with the overturning assembly; the pushing assembly assists the soaking smoothing assembly and the overturning assembly to process; the left side and the right side above the underframe are provided with turnover components; the overturning assembly is connected with the portal frame; the overturning component enables the mica paper to overturn.

In one embodiment, the soaking and smoothing assembly comprises a first soaking and smoothing unit, a first hinge, a second soaking and smoothing unit, a second hinge, a third soaking and smoothing unit, a third hinge, a fourth soaking and smoothing unit, a fourth hinge, a fifth soaking and smoothing unit, a fifth hinge and a sixth soaking and smoothing unit; the pushing assembly is fixedly connected with the first soaking and smoothing unit; the first soaking smoothing unit is fixedly connected with the first hinge; the first hinge is fixedly connected with the second soaking and smoothing unit; the second soaking smoothing unit is fixedly connected with a second hinge; the second hinge is fixedly connected with the third soaking and flattening unit; the third soaking smoothing unit is fixedly connected with the third hinge; the third hinge is fixedly connected with the fourth soaking and flattening unit; the fourth soaking flattening unit is fixedly connected with a fourth hinge; the fourth hinge is fixedly connected with the fifth soaking and flattening unit; the fifth soaking smoothing unit is fixedly connected with the fifth hinge; the fifth hinge is fixedly connected with the sixth soaking and smoothing unit; and the sixth soaking and flattening unit is fixedly connected with the pushing assembly.

In one embodiment, the pushing assembly comprises a main motor, a first transmission rod, a first shaft sleeve, a first bevel gear, a first fixing frame, a third electric push rod, a second bevel gear, a second transmission rod, a first flat gear, a second shaft sleeve, a third bevel gear, a fourth bevel gear, a second fixing frame, a fourth electric push rod, a fifth bevel gear, a third transmission rod, a second flat gear, a third flat gear, a bidirectional screw rod, a T-shaped connecting plate, a first sliding rod, a first spring piece and a fixing block; the main motor is fixedly connected with the support frame; the output shaft of the main motor is fixedly connected with the first transmission rod; the first transmission rod is rotatably connected with the support frame; the first transmission rod is connected with the first shaft sleeve in a sliding manner; the first shaft sleeve is fixedly connected with the first bevel gear; the first shaft sleeve is rotationally connected with the first fixing frame; the first fixing frame is fixedly connected with the third electric push rod; the third electric push rod is fixedly connected with the support frame; a second bevel gear is arranged on the side surface of the first bevel gear; when the second bevel gear is meshed with the first bevel gear, the second bevel gear rotates; when the second bevel gear is not meshed with the first bevel gear, the second bevel gear does not rotate; the second bevel gear is fixedly connected with a second transmission rod; the second transmission rod is rotatably connected with the support frame; the second transmission rod is fixedly connected with the first flat gear; the second shaft sleeve is connected with the first transmission rod in a sliding manner; two sides of the second shaft sleeve are fixedly connected with a third bevel gear and a fourth bevel gear respectively; the second fixed frame is rotationally connected with the second shaft sleeve; the second fixing frame is fixedly connected with the fourth electric push rod; the fourth electric push rod is fixedly connected with the support frame; a fifth bevel gear is arranged on the side surface of the third bevel gear; when the fifth bevel gear is meshed with the third bevel gear, the fifth bevel gear rotates; when the fifth bevel gear is not meshed with the third bevel gear, the fifth bevel gear does not rotate; the fifth bevel gear is fixedly connected with the third transmission rod; the third transmission rod is rotatably connected with the support frame; the third transmission rod is fixedly connected with the second flat gear; the second flat gear is meshed with the third flat gear; the third horizontal gear is fixedly connected with the bidirectional screw rod; the bidirectional screw rod is rotationally connected with the turnover assembly; the bidirectional screw rod is in screwed connection with the T-shaped connecting plate; the T-shaped connecting plate is fixedly connected with the overturning component; the T-shaped connecting plate is in sliding connection with the first sliding rod; the first sliding rod is fixedly connected with the overturning component; the first spring piece is rotatably connected with the fixed block through a universal ball; the fixed block is fixedly connected with the first soaking and smoothing unit; and a combination of a first spring part and a fixed block is symmetrically arranged by taking the central axis of the first sliding rod as a symmetry axis.

In one embodiment, the overturning assembly comprises a sixth bevel gear, a fourth transmission rod, a circular limiting slide rail, a first arc-shaped slide block and a second arc-shaped slide block; the sixth bevel gear is fixedly connected with the fourth transmission rod; the fourth transmission rod is rotatably connected with the portal frame; the fourth transmission rod is rotatably connected with the round limiting slide rail; the circular limiting slide rail is fixedly connected with the portal frame; the circular limiting slide rail is in sliding connection with the first arc-shaped slide block and the second arc-shaped slide block; the first arc-shaped sliding block is rotationally connected with the bidirectional screw rod; the second arc-shaped sliding block is fixedly connected with the first sliding rod; and a combination of a fourth transmission rod, a circular limiting slide rail, a first arc-shaped slide block and a second arc-shaped slide block is symmetrically arranged by taking the central axis of the portal frame as a symmetry axis.

In one embodiment, the first soaking and flattening unit comprises a soaking grid plate, a first limiting slide block, a second spring part, a U-shaped connecting plate, a third spring part, a second limiting slide block, a first flattening rod, a first pressing plate, a second slide rod, a second pressing plate, a second flattening rod, a third pressing plate, a third flattening rod, an extrusion block, a first fixing spring, a second fixing spring, a third fixing spring, a baffle plate and a fourth spring part; the soaking grid plate is fixedly connected with the fixed block; the soaking grid plate is fixedly connected with the first hinge; the soaking grid plate is in sliding connection with the first limiting slide block; the first limiting slide block is fixedly connected with the second spring part; the second spring part is fixedly connected with the U-shaped connecting plate; the U-shaped connecting plate is fixedly connected with the third spring part; the third spring part is fixedly connected with the second limiting sliding block; the second limiting slide block is in sliding connection with the soaking grid plate; the first smoothing rod is rotatably connected with the U-shaped connecting plate; the first smoothing rod is in contact with the first pressing plate; the first pressing plate is fixedly connected with the second sliding rod; the second sliding rod is in sliding connection with the second pressing plate and the third pressing plate; the second pressing plate is in contact with the second smoothing rod; the second smoothing rod is rotatably connected with the U-shaped connecting plate; the third pressing plate is in contact with the third smoothing rod; the third smoothing rod is rotatably connected with the U-shaped connecting plate; the extrusion block is fixedly connected with the first pressing plate; two sides of the first fixed spring are fixedly connected with the first pressing plate and the second pressing plate respectively; two sides of the second fixed spring are fixedly connected with the second pressure plate and the third pressure plate respectively; two sides of the third fixed spring are fixedly connected with the third pressing plate and the soaking grid plate respectively; the combination of three groups of baffle plates and a fourth spring part is arranged below the extrusion block at equal intervals; the baffle is in sliding connection with the soaking grid plate; a group of fourth spring pieces are fixedly connected to two sides of the baffle; the two groups of fourth spring parts are fixedly connected with the soaking grid plate; a combination of a first limiting sliding block, a second spring part, a U-shaped connecting plate, a third spring part, a second limiting sliding block, a first smoothing rod, a second sliding rod, a second smoothing rod and a third smoothing rod is symmetrically arranged by taking the central axis of the extrusion block as a symmetry axis; a first limiting sliding block, a second spring part, a U-shaped connecting plate, a third spring part, a second limiting sliding block, a second sliding rod, an extrusion block, a first fixing spring, a second fixing spring and a third fixing spring are symmetrically arranged on the central axis of the second smoothing rod.

In one embodiment, the soaking grid plate is provided with a sliding groove matched with the first limiting sliding block.

In one embodiment, the first pressing plate, the second pressing plate and the third pressing plate are provided with arc-shaped grooves on the side faces, which are matched with the first smoothing rod, the second smoothing rod and the third smoothing rod.

In one embodiment, three sets of rectangular through slots are provided in the soaking grid.

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

firstly, in order to solve the problems in the prior art, mica pulp is manufactured on a paper machine, then mica paper is dried to obtain a crude mica paper product, a modified soaking agent is prepared according to a formula, the obtained crude mica paper product is soaked in the modified soaking agent to ensure that the crude mica paper product is completely soaked in the modified soaking agent, and the mica paper is dried after being taken out to obtain the mica paper; the surface of the mica paper is slightly uneven after being dried, a large amount of modifier is remained in the mica paper after soaking, a large amount of time is consumed for directly drying, meanwhile, a plurality of mica papers are easily stacked together during soaking, so that the mica papers are difficult to separate after soaking, and a soaking agent is difficult to fully permeate into the mica paper, so that the soaking effect is poor;

designing a soaking smoothing component, a pushing component, a turning component and a shifting component, putting equipment on a horizontal plane when preparing for work, switching on a power supply, filling a preset amount of modified soaking agent in a solution box in advance, then putting a mica paper crude product to be processed into the soaking smoothing component on a bottom frame supported by a support column and a base plate, controlling the pushing component connected with the support frame to operate through a controller, simultaneously extending a first electric push rod and a second electric push rod to push the solution box below a portal frame to ascend, so that the mica paper in the soaking smoothing component is soaked in the modified soaking agent, pushing the soaking smoothing component to be folded by the pushing component, then enabling the mica paper to be smoothed while being soaked by matching the shifting component and the soaking smoothing component, and enabling the first electric push rod and the second electric push rod to contract and reset after the soaking is finished, so that the mica paper is separated from the modified soaking agent, then the pushing component drives the overturning component to operate, so that the soaking smoothing component drives the mica paper to overturn by one hundred and eighty degrees, then the stirring component and the soaking smoothing component are matched to extrude the mica paper, and most of the modified soaking agent in the mica paper is extruded out, so that the subsequent drying time is reduced;

when the mica paper drying device is used, the mica paper is mutually isolated during soaking, the soaking agent is fully permeated into the mica paper when the mica paper is pressed, and the residual soaking agent in the mica paper is extruded out after the soaking is finished, so that the time required by drying is reduced.

Drawings

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

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

FIG. 3 is a schematic perspective view of a soak smoothing assembly of the present invention;

FIG. 4 is a top view of the soak leveling assembly of the present invention;

FIG. 5 is a schematic view of a first perspective structure of the pushing assembly of the present invention;

FIG. 6 is a second perspective view of the pushing assembly of the present invention;

FIG. 7 is a top view of the pushing assembly of the present invention;

FIG. 8 is a schematic view of a first perspective structure of the flipping module of the present invention;

FIG. 9 is a second perspective view of the flipping module of the present invention;

FIG. 10 is a schematic view of a first perspective structure of the toggle assembly of the present invention;

FIG. 11 is a schematic view of a second perspective structure of the toggle assembly of the present invention;

FIG. 12 is a schematic perspective view of the region B according to the present invention;

fig. 13 is a schematic perspective view of a first immersion smoothing unit according to the present invention;

fig. 14 is a schematic view of a first partial perspective structure of the first soaking and smoothing unit of the present invention;

fig. 15 is a schematic view of a second partial three-dimensional structure of the first soaking and smoothing unit according to the present invention;

FIG. 16 is a schematic perspective view of zone A according to the present invention;

fig. 17 is a third partial perspective structural view of the first soaking and smoothing unit of the present invention.

In the reference symbols: 1-underframe, 2-support column, 3-backing plate, 4-portal frame, 5-first electric push rod, 6-second electric push rod, 7-solution box, 8-support frame, 401-first soaking smoothing unit, 402-first hinge, 403-second soaking smoothing unit, 404-second hinge, 405-third soaking smoothing unit, 406-third hinge, 407-fourth soaking smoothing unit, 408-fourth hinge, 409-fifth soaking smoothing unit, 410-fifth hinge, 411-sixth soaking smoothing unit, 501-main motor, 502-first transmission rod, 503-first shaft sleeve, 504-first bevel gear, 505-first fixing frame, 506-third electric push rod, 507-second bevel gear, 508-a second transmission rod, 509-a first flat gear, 510-a second shaft sleeve, 511-a third bevel gear, 512-a fourth bevel gear, 513-a second fixed frame, 514-a fourth electric push rod, 515-a fifth bevel gear, 516-a third transmission rod, 517-a second flat gear, 518-a third bevel gear, 519-a bidirectional screw rod, 520-a T-shaped connecting plate, 521-a first sliding rod, 522-a first spring part, 523-a fixed block, 601-a sixth bevel gear, 602-a fourth transmission rod, 603-a circular limit sliding rail, 604-a first arc sliding block, 605-a second arc sliding block, 701-an electric sliding rail, 702-a first electric sliding block, 703-a fifth electric push rod, 704-a first shifting plate, 705-a second electric sliding block, 706-sixth electric push rod, 707-second dial plate, 40101-soaking grid plate, 40102-first limit slider, 40103-second spring part, 40104-U-shaped connecting plate, 40105-third spring part, 40106-second limit slider, 40107-first smoothing rod, 40108-first pressure plate, 40109-second sliding rod, 40110-second pressure plate, 40111-second smoothing rod, 40112-third pressure plate, 40113-third smoothing rod, 40114-extrusion block, 40115-first fixed spring, 40116-second fixed spring, 40117-third fixed spring, 40118-baffle plate, 40119-fourth spring part.

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 mica paper crude product modification soaking treatment device is shown by referring to fig. 1-2 and comprises a bottom frame 1, a support column 2, a base plate 3, a portal frame 4, a first electric push rod 5, a second electric push rod 6, a solution tank 7, a support frame 8, a soaking flattening component, a pushing component and a turning component; 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 fixedly connected with a group of backing plates 3 respectively; the underframe 1 is fixedly connected with a portal frame 4, a first electric push rod 5, a second electric push rod 6 and a support frame 8; the first electric push rod 5 and the second electric push rod 6 are fixedly connected with the solution tank 7; a soaking and smoothing assembly is arranged in the middle of the upper part of the underframe 1; the soaking smoothing component is connected with the pushing component; the soaking smoothing component enables the mica paper to be soaked and smoothed at the same time; pushing components are arranged at the middle part and the left side above the underframe 1; the pushing assembly is connected with the supporting frame 8; the pushing assembly is connected with the overturning assembly; the pushing assembly assists the soaking smoothing assembly and the overturning assembly to process; the left side and the right side above the underframe 1 are provided with turnover components; the overturning component is connected with the portal frame 4; the overturning component enables the mica paper to overturn.

When the mica paper soaking machine is ready to work, the equipment is placed on a horizontal plane, a power supply is switched on, a preset amount of modified soaking agent is filled in a solution tank 7 in advance, then a mica paper crude product to be treated is placed in a soaking smoothing component on a bottom frame 1 supported by a support column 2 and a base plate 3, a pushing component connected with a support frame 8 is controlled by a controller to operate, meanwhile, a first electric push rod 5 and a second electric push rod 6 extend to push the solution tank 7 below a portal frame 4 to ascend at the same time, so that the mica paper in the soaking smoothing component is soaked in the modified soaking agent, the pushing component pushes the soaking smoothing component to fold, then the mica paper is smoothed while being soaked by matching of the stirring component and the soaking smoothing component, after the soaking is finished, the first electric push rod 5 and the second electric push rod 6 are contracted and reset, so that the mica paper is separated from the modified soaking agent, then the pushing component drives a turnover component to operate, the soaking smoothing component drives the mica paper to turn over by one hundred eighty degrees, then the stirring component and the soaking smoothing component are matched to extrude the mica paper, and most of the modified soaking agent in the mica paper is extruded, so that the subsequent drying time is reduced; when the mica paper soaking device is used, the mica paper is mutually isolated during soaking, the soaking agent is fully permeated into the mica paper while the mica paper is pressed, and the soaking agent remained in the mica paper is extruded out after the soaking is finished, so that the time required by drying is shortened.

Referring to fig. 3-4, the soaking smoothing assembly includes a first soaking smoothing unit 401, a first hinge 402, a second soaking smoothing unit 403, a second hinge 404, a third soaking smoothing unit 405, a third hinge 406, a fourth soaking smoothing unit 407, a fourth hinge 408, a fifth soaking smoothing unit 409, a fifth hinge 410, and a sixth soaking smoothing unit 411; the pushing assembly is fixedly connected with the first soaking and smoothing unit 401; the first soaking smoothing unit 401 is fixedly connected with a first hinge 402; the first hinge 402 is fixedly connected with the second soaking and flattening unit 403; the second soaking smoothing unit 403 is fixedly connected with a second hinge 404; the second hinge 404 is fixedly connected with the third soaking and smoothing unit 405; the third soaking smoothing unit 405 is fixedly connected with the third hinge 406; the third hinge 406 is fixedly connected with the fourth soaking and smoothing unit 407; the fourth soaking smoothing unit 407 is fixedly connected with a fourth hinge 408; the fourth hinge 408 is fixedly connected with the fifth soaking and smoothing unit 409; the fifth soaking and smoothing unit 409 is fixedly connected with the fifth hinge 410; the fifth hinge 410 is fixedly connected with the sixth soaking and smoothing unit 411; the sixth soaking and smoothing unit 411 is fixedly connected with the pushing assembly.

After mica paper needing to be treated is placed into six groups of soaking and smoothing units, a pushing assembly simultaneously pushes a first soaking and smoothing unit 401 and a sixth soaking and smoothing unit 411 to enable a first hinge 402, a second hinge 404, a third hinge 406, a fourth hinge 408 and a fifth hinge 410 to rotate, further enable the first soaking and smoothing unit 401, a second soaking and smoothing unit 403, a third soaking and smoothing unit 405, a fourth soaking and smoothing unit 407, a fifth soaking and smoothing unit 409 and the sixth soaking and smoothing unit 411 to be in a vertical state and to be mutually extruded, simultaneously extend a first electric push rod 5 and a second electric push rod 6 to push a solution box 7 below a gantry frame 4 to ascend simultaneously to soak the mica paper in the modified soaking agent, then, the assembly is pushed to operate to be matched with the six groups of soaking and smoothing units to enable the mica paper to be soaked in the modified soaking agent and smoothed simultaneously, after soaking is completed, the first electric push rod 5 and the second electric push rod 6 are contracted to reset, then the assembly is pushed to drive the overturning assembly to operate, so that the six groups of soaking flattening units drive the mica paper to overturn by one hundred eighty degrees, then the assembly is pushed to operate, and the mica paper is matched with the six groups of soaking flattening units to extrude the residual modified soaking agent on the mica paper; the mica paper is soaked in the modified soaking agent and smoothed out simultaneously by the component.

Referring to fig. 5 to 7, the pushing assembly includes a main motor 501, a first driving rod 502, a first bushing 503, a first bevel gear 504, a first fixing bracket 505, a third electric push rod 506, a second bevel gear 507, a second driving rod 508, a first flat gear 509, a second bushing 510, a third bevel gear 511, a fourth bevel gear 512, a second fixing bracket 513, a fourth electric push rod 514, a fifth bevel gear 515, a third driving rod 516, a second flat gear 517, a third flat gear 518, a bidirectional screw rod 519, a T-shaped connecting plate 520, a first sliding rod 521, a first spring member 522, and a fixing block 523; the main motor 501 is fixedly connected with the support frame 8; an output shaft of a main motor 501 is fixedly connected with a first transmission rod 502; the first transmission rod 502 is rotatably connected with the support frame 8; the first transmission rod 502 is connected with the first shaft sleeve 503 in a sliding manner; the first shaft sleeve 503 is fixedly connected with the first bevel gear 504; the first shaft sleeve 503 is rotatably connected with the first fixing frame 505; the first fixing frame 505 is fixedly connected with the third electric push rod 506; the third electric push rod 506 is fixedly connected with the support frame 8; a second bevel gear 507 is arranged on the side surface of the first bevel gear 504; when the second bevel gear 507 is engaged with the first bevel gear 504, the second bevel gear 507 rotates; when the second bevel gear 507 is not engaged with the first bevel gear 504, the second bevel gear 507 is not rotated; the second bevel gear 507 is fixedly connected with a second transmission rod 508; the second transmission rod 508 is rotatably connected with the support frame 8; the second transmission rod 508 is fixedly connected with the first flat gear 509; the second sleeve 510 is slidably connected to the first driving rod 502; two sides of the second shaft sleeve 510 are fixedly connected with a third bevel gear 511 and a fourth bevel gear 512 respectively; the second fixing frame 513 is rotatably connected with the second shaft sleeve 510; the second fixing frame 513 is fixedly connected with the fourth electric push rod 514; the fourth electric push rod 514 is fixedly connected with the support frame 8; a fifth bevel gear 515 is arranged on the side of the third bevel gear 511; when fifth bevel gear 515 is engaged with third bevel gear 511, fifth bevel gear 515 rotates; when the fifth bevel gear 515 is not engaged with the third bevel gear 511, the fifth bevel gear 515 does not rotate; a fifth bevel gear 515 is fixedly connected with a third transmission rod 516; the third transmission rod 516 is rotatably connected with the support frame 8; the third transmission rod 516 is fixedly connected with the second flat gear 517; the second pinion 517 meshes with the third pinion 518; the third gear 518 is fixedly connected with a bidirectional screw rod 519; the bidirectional screw rod 519 is rotatably connected with the turnover assembly; the bidirectional screw rod 519 is screwed with the T-shaped connecting plate 520; the T-shaped connecting plate 520 is fixedly connected with the overturning component; the T-shaped connecting plate 520 is connected with the first sliding rod 521 in a sliding manner; the first sliding rod 521 is fixedly connected with the overturning component; the first spring member 522 is rotatably connected to the fixed block 523 via a universal ball; the fixed block 523 is fixedly connected with the first soaking and smoothing unit 401; a combination of the first spring member 522 and the fixed block 523 is symmetrically disposed with the central axis of the first sliding bar 521 as a symmetry axis.

When the solution tank 7 rises, the main motor 501 is started, the output shaft of the main motor 501 drives the first transmission rod 502 to rotate, the first transmission rod 502 drives the first shaft sleeve 503 and the second shaft sleeve 510 to rotate simultaneously, the first shaft sleeve 503 drives the first bevel gear 504 to rotate, when the turning assembly drives the T-shaped connecting plate 520 to turn by one hundred eighty degrees, the third bevel gear 518 just meshes with the first flat gear 509, at this time, the third electric push rod 506 extends to push the first fixing frame 505, so that the first shaft sleeve 503 slides on the first transmission rod 502, the first bevel gear 504 meshes with the second bevel gear 507, the second bevel gear 507 rotates to drive the second transmission rod 508 to drive the first flat gear 509 to rotate, the first flat gear 509 drives the third flat gear 518 to drive the bidirectional screw rod 519 to rotate, further, so that the six groups of soaking and leveling units are mutually separated, part of the six groups of soaking and leveling units are reset, then the middle part of the main motor 501 is reversely rotated, then the six groups of soaking flattening units are mutually extruded so as to be matched with the stirring assembly to extrude residual soaking agents in the mica paper; when the turning assembly needs to deliver power during operation, the fourth electric push rod 514 is contracted, so that the second fixing frame 513 drives the second shaft sleeve 510 to slide on the first transmission rod 502, the fourth bevel gear 512 is meshed with the sixth bevel gear 601, and power is delivered to the turning assembly during operation; the fourth electric push rod 514 extends to enable the third bevel gear 511 to be meshed with the fifth bevel gear 515, the fifth bevel gear 515 rotates to drive the third transmission rod 516 to drive the second flat gear 517 to rotate, the second flat gear 517 drives the third flat gear 518 to drive the two-way screw rod 519 to rotate, the two-way screw rod 519 rotates to drive the two T-shaped connecting plates 520 screwed with the two T-shaped connecting plates to slide on the first sliding rod 521 to approach each other, the two groups of first spring pieces 522 drive the two groups of fixed blocks 523 to push the first soaking and smoothing unit 401 and the sixth soaking and smoothing unit 411, then the universal ball at the joint of the two groups of first spring pieces 522 and the fixed blocks 523 rotates to enable the two groups of first spring pieces 522 to be compressed, and the six groups of soaking and smoothing units are in a horizontal state so as to be matched with the toggle assembly for processing; this subassembly smooths the subassembly with soaking and overturns the subassembly cooperation to handle mica paper.

Referring to fig. 8-9, the turnover assembly includes a sixth bevel gear 601, a fourth transmission rod 602, a circular limit slide rail 603, a first arc-shaped slide block 604 and a second arc-shaped slide block 605; the sixth bevel gear 601 is fixedly connected with the fourth transmission rod 602; the fourth transmission rod 602 is rotatably connected with the portal frame 4; the fourth transmission rod 602 is rotatably connected with the circular limiting slide rail 603; the circular limiting slide rail 603 is fixedly connected with the portal frame 4; the circular limiting slide rail 603 is connected with the first arc-shaped slide block 604 and the second arc-shaped slide block 605 in a sliding manner; the first arc-shaped sliding block 604 is rotatably connected with a bidirectional screw rod 519; the second arc-shaped sliding block 605 is fixedly connected with the first sliding rod 521; and a combination of a fourth transmission rod 602, a circular limiting slide rail 603, a first arc-shaped slide block 604 and a second arc-shaped slide block 605 is symmetrically arranged by taking the central axis of the portal frame 4 as a symmetry axis.

After the mica paper is soaked, the pushing assembly drives the sixth bevel gear 601 to drive the fourth transmission rod 602 to rotate, the fourth transmission rod 602 drives the T-shaped connecting plate 520 to turn over by one hundred eighty degrees, the bidirectional screw rod 519 further drives the first arc-shaped sliding block 604 to slide in the circular limiting sliding rail 603, meanwhile, the first sliding rod 521 drives the second arc-shaped sliding block 605 to slide in the circular limiting sliding rail 603, and then the six groups of soaking flattening units drive the mica paper to turn over by one hundred eighty degrees, so that the soaking flattening assembly and the shifting assembly are matched to process and extrude residual soaking agents in the mica paper; the assembly enables the mica paper to turn over by one hundred eighty degrees after soaking is completed so as to extrude out residual soaking agents in the mica paper.

Referring to fig. 10-12, the gantry crane further comprises a shifting assembly, the shifting assembly is located below the gantry 4, and the shifting assembly comprises an electric slide rail 701, a first electric slide block 702, a fifth electric push rod 703, a first shifting plate 704, a second electric slide block 705, a sixth electric push rod 706 and a second shifting plate 707; the electric slide rail 701 is fixedly connected with the portal frame 4; the electric slide rail 701 is connected with the first electric slide block 702 in a sliding manner; the first electric slider 702 is fixedly connected with the fifth electric push rod 703; the fifth electric push rod 703 is fixedly connected with the first shifting plate 704; the first shifting plate 704 is symmetrically provided with a combination of an electric sliding rail 701, a first electric sliding block 702 and a fifth electric push rod 703 at two sides; the second electric sliding block 705 is connected with the electric sliding rail 701 in a sliding manner; the second electric slide 705 is fixedly connected with a sixth electric push rod 706; the sixth electric push rod 706 is fixedly connected with the second shifting plate 707; a combination of a second electric slider 705 and a sixth electric push rod 706 is symmetrically arranged on two sides of the second poking plate 707; the combination of an electric slide rail 701, a first electric slide block 702, a fifth electric push rod 703, a first shifting plate 704, a second electric slide block 705, a sixth electric push rod 706 and a second shifting plate 707 is symmetrically arranged by taking the central axis of the portal frame 4 as a symmetry axis.

After the six groups of soaking and smoothing units are in a horizontal state, the fifth electric push rod 703 and the sixth electric push rod 706 simultaneously extend to push the first shifting plate 704 and the second shifting plate 707 to be positioned in the interval of the plurality of groups of U-shaped connecting plates 40104, then the first electric slide block 702 and the second electric slide block 705 simultaneously slide reversely in the electric slide rail 701, so that the first shifting plate 704 and the second shifting plate 707 respectively push the plurality of groups of U-shaped connecting plates 40104, so that the first shifting plate 704 and the second shifting plate 707 drive the plurality of groups of U-shaped connecting plates 40107, the plurality of groups of first smoothing rods 40107, the second smoothing rods 40111 and the third smoothing rods 40113 to move, so that the soaking agent fully permeates into the mica paper, and simultaneously smooth the mica paper, after the mica paper is soaked, the fifth electric push rod 703 and the sixth electric push rod 706 shrink to reset, then after the mica paper overturns the one hundred eighty-degree six groups of soaking and smoothing units to be far away from each other, the first electric slide block 702 and the second electric slide block 705 continuously and reversely, so that the first shifting plate 704 and the second shifting plate 707 are respectively positioned at the other sides of the plurality of U-shaped connecting plates 40104, then the fifth electric push rod 703 and the sixth electric push rod 706 extend, then the first electric slide block 702 and the second electric slide block 705 simultaneously slide to approach each other, so that the plurality of groups of U-shaped connecting plates 40104 are reset, then the six groups of soaking and flattening units approach each other, and the first shifting plate 704 and the second shifting plate 707 repeat the action of flattening the mica paper again to extrude the residual soaking agent; the assembly is matched with the soaking smoothing assembly to smooth the mica paper, and the residual soaking agent in the mica paper is extruded out after soaking is finished.

Referring to fig. 13 to 17, the first soaking and smoothing unit 401 includes a soaking grid plate 40101, a first limit slider 40102, a second spring 40103, a U-shaped connecting plate 40104, a third spring 40105, a second limit slider 40106, a first smoothing rod 40107, a first press plate 40108, a second slide bar 40109, a second press plate 40110, a second smoothing rod 40111, a third press plate 40112, a third smoothing rod 40113, a pressing block 40114, a first fixing spring 40115, a second fixing spring 40116, a third fixing spring 40117, a blocking plate 40118, and a fourth spring 40119; the soaking grid plate 40101 is fixedly connected with a fixed block 523; the soaking grid plates 40101 are fixedly connected with the first hinges 402; the soaking grid plate 40101 is in sliding connection with a first limiting slide block 40102; the first limiting slide block 40102 is fixedly connected with the second spring piece 40103; the second spring piece 40103 is fixedly connected with the U-shaped connecting plate 40104; the U-shaped connecting plate 40104 is fixedly connected with a third spring piece 40105; the third spring piece 40105 is fixedly connected with a second limit slide block 40106; the second limit slide block 40106 is in sliding connection with the soaking grid plate 40101; the first smoothing rod 40107 is rotatably connected with the U-shaped connecting plate 40104; the first smoothing bar 40107 is in contact with the first presser plate 40108; the first pressure plate 40108 is fixedly connected with the second sliding rod 40109; the second slide bar 40109 is slidably connected to a second presser plate 40110 and a third presser plate 40112; the second presser plate 40110 is in contact with the second smoothing bar 40111; the second smoothing rod 40111 is rotatably connected with the U-shaped connecting plate 40104; the third presser plate 40112 is in contact with the third smoothing bar 40113; the third smoothing rod 40113 is rotatably connected with the U-shaped connecting plate 40104; the extrusion block 40114 is fixedly connected with the first pressing plate 40108; two sides of the first fixed spring 40115 are fixedly connected with a first pressure plate 40108 and a second pressure plate 40110 respectively; two sides of the second fixed spring 40116 are fixedly connected with a second pressure plate 40110 and a third pressure plate 40112 respectively; two sides of the third fixed spring 40117 are fixedly connected with the third press plate 40112 and the soaking grid plate 40101 respectively; a combination of three groups of baffle plates 40118 and a fourth spring piece 40119 are arranged equidistantly below the extrusion block 40114; the baffle 40118 is in sliding connection with the soaking grid plate 40101; a group of fourth spring pieces 40119 are fixedly connected to two sides of the baffle plate 40118; the two groups of fourth spring elements 40119 are fixedly connected with the soaking grid plate 40101; a combination of a first limit sliding block 40102, a second spring part 40103, a U-shaped connecting plate 40104, a third spring part 40105, a second limit sliding block 40106, a first smoothing rod 40107, a second sliding rod 40109, a second smoothing rod 40111 and a third smoothing rod 40113 is symmetrically arranged by taking a central axis of the extrusion block 40114 as a symmetry axis; the second smoothing rod 40111 is provided with a combination of a first limit sliding block 40102, a second spring part 40103, a U-shaped connecting plate 40104, a third spring part 40105, a second limit sliding block 40106, a second sliding rod 40109, an extrusion block 40114, a first fixed spring 40115, a second fixed spring 40116 and a third fixed spring 40117 symmetrically by taking a central axis of the second smoothing rod 40111 as a symmetry axis.

When six groups of soaking smoothing units are in a horizontal state, two adjacent groups of units are pressed with each other, namely, the pressing block 40114 is pressed, the first pressing plate 40108 pushes the second sliding rod 40109 to slide in the second pressing plate 40110 and the third pressing plate 40112, the first fixing spring 40115 is compressed, the second fixing spring 40116 and the third fixing spring 40117 are compressed, the first pressing plate 40108, the second pressing plate 40110 and the third pressing plate 40112 fix the mica paper, the U-shaped connecting plate 40104 is pressed, the second spring 40103 is compressed, the third spring 40105 is stretched, the first smoothing rod 40107, the second smoothing rod 40111 and the third smoothing rod 40113 are pressed against the surface of the mica paper, and then the two groups of U-shaped connecting plates 40104 are shifted by the first shifting plate 401704 and the second shifting plate 401707 to move reversely, two groups of first limit sliders 40102 and second limit sliders 40106 reversely slide in the soaking grid plate 40101, so that two groups of first smoothing rods 40107, second smoothing rods 40111 and third smoothing rods 40113 tightly cling to the surface of the mica paper and roll to flatten the surface of the mica paper, the first smoothing rods 40107, the second smoothing rods 40111 and the third smoothing rods 40113 contact and press three groups of baffle plates 40118 when rolling to the bottom of the mica paper, so that a plurality of groups of fourth spring members 40119 are compressed, the three groups of baffle plates 40118 slide in the soaking grid plate 40101, and the first smoothing rods 40107, the second smoothing rods 40111 and the third smoothing rods 40113 flatten the bottom of the mica paper; after the mica paper is turned over by one hundred eighty degrees after soaking, after six groups of soaking smoothing units are far away from each other, the second spring part 40103 and the second limiting slide block 40106 enable the U-shaped connecting plate 40104 to drive the first smoothing rod 40107, the second smoothing rod 40111 and the third smoothing rod 40113 to reset due to elasticity, meanwhile, the first fixed spring 40115, the second fixed spring 40116 and the third fixed spring 40117 drive the first pressure plate 40108, the second pressure plate 40110 and the third pressure plate 40112 to reset due to the elastic force, then the two groups of U-shaped connecting plates 40104 are shifted reversely by the first shifting plate 704 and the second shifting plate 707 to reset, after the six groups of soaking smoothing units approach to each other, the first shifting plate 704 and the second shifting plate 707 further shift the two groups of U-shaped connecting plates 40104 to move reversely, at this time, the mica paper is separated from the soaking agent, and the two groups of first smoothing rods 40107, the second smoothing rods 40111 and the third smoothing rods 40113 are attached to the surface of the mica paper again to roll, so that the residual soaking agent is extruded; this unit makes mica paper isolated when soaking each other, handles mica paper with stirring the subassembly cooperation simultaneously.

A chute matched with the first limit slide block 40102 is arranged on the soaking grid plate 40101.

So that the first stopper slide 40102 slides therein.

The side surfaces of the first pressing plate 40108, the second pressing plate 40110 and the third pressing plate 40112 are provided with arc-shaped grooves matched with the first smoothing rod 40107, the second smoothing rod 40111 and the third smoothing rod 40113.

So that the first smoothing bar 40107, the second smoothing bar 40111, and the third smoothing bar 40113 are disposed therein.

Three groups of rectangular through grooves are arranged in the soaking grid plate 40101.

So that the first smoothing bar 40107, the second smoothing bar 40111, and the third smoothing bar 40113 smooth the mica paper.

The above description is only an embodiment of the present invention, and is not intended to limit the scope of the present invention, and all equivalent structures or equivalent processes performed by the present invention or directly or indirectly applied to other related technical fields are also included in the scope of the present invention.

Claims (4)

1. A mica paper crude product modifying and soaking treatment device comprises a bottom frame (1), support columns (2), a base plate (3), a portal frame (4), a first electric push rod (5), a second electric push rod (6), a solution tank (7) and a support frame (8); 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 the group of backing plates (3) respectively; the underframe (1) is fixedly connected with a portal frame (4), a first electric push rod (5), a second electric push rod (6) and a support frame (8); the first electric push rod (5) and the second electric push rod (6) are fixedly connected with the solution tank (7); the method is characterized in that: the device also comprises a soaking smoothing component, a pushing component and a turning component; a soaking smoothing component is arranged in the middle of the upper part of the bottom frame (1); the soaking smoothing component is connected with the pushing component; the soaking smoothing component enables the mica paper to be soaked and smoothed at the same time; pushing components are arranged in the middle and on the left side above the underframe (1); the pushing component is connected with the supporting frame (8); the pushing assembly is connected with the overturning assembly; the pushing assembly assists the soaking smoothing assembly and the overturning assembly to process; the left side and the right side above the underframe (1) are provided with turnover components; the overturning assembly is connected with the portal frame (4); the turning assembly turns the mica paper;

the soaking smoothing assembly comprises a first soaking smoothing unit (401), a first hinge (402), a second soaking smoothing unit (403), a second hinge (404), a third soaking smoothing unit (405), a third hinge (406), a fourth soaking smoothing unit (407), a fourth hinge (408), a fifth soaking smoothing unit (409), a fifth hinge (410) and a sixth soaking smoothing unit (411); the pushing assembly is fixedly connected with the first soaking and smoothing unit (401); the first soaking smoothing unit (401) is fixedly connected with the first hinge (402); the first hinge (402) is fixedly connected with the second soaking and flattening unit (403); the second soaking smoothing unit (403) is fixedly connected with a second hinge (404); the second hinge (404) is fixedly connected with the third soaking and flattening unit (405); the third soaking smoothing unit (405) is fixedly connected with a third hinge (406); the third hinge (406) is fixedly connected with the fourth soaking and smoothing unit (407); the fourth soaking and flattening unit (407) is fixedly connected with a fourth hinge (408); the fourth hinge (408) is fixedly connected with the fifth soaking and smoothing unit (409); the fifth soaking smoothing unit (409) is fixedly connected with a fifth hinge (410); the fifth hinge (410) is fixedly connected with the sixth soaking and smoothing unit (411); the sixth soaking smoothing unit (411) is fixedly connected with the pushing assembly;

the pushing assembly comprises a main motor (501), a first transmission rod (502), a first shaft sleeve (503), a first bevel gear (504), a first fixing frame (505), a third electric push rod (506), a second bevel gear (507), a second transmission rod (508), a first flat gear (509), a second shaft sleeve (510), a third bevel gear (511), a fourth bevel gear (512), a second fixing frame (513), a fourth electric push rod (514), a fifth bevel gear (515), a third transmission rod (516), a second flat gear (517), a third flat gear (518), a bidirectional screw rod (519), a T-shaped connecting plate (520), a first sliding rod (521), a first spring piece (522) and a fixing block (523); the main motor (501) is fixedly connected with the support frame (8); an output shaft of the main motor (501) is fixedly connected with the first transmission rod (502); the first transmission rod (502) is rotationally connected with the support frame (8); the first transmission rod (502) is connected with the first shaft sleeve (503) in a sliding way; the first shaft sleeve (503) is fixedly connected with the first bevel gear (504); the first shaft sleeve (503) is rotatably connected with the first fixing frame (505); the first fixing frame (505) is fixedly connected with a third electric push rod (506); the third electric push rod (506) is fixedly connected with the support frame (8); a second bevel gear (507) is arranged on the side surface of the first bevel gear (504); when the second bevel gear (507) is meshed with the first bevel gear (504), the second bevel gear (507) rotates; when the second bevel gear (507) is not meshed with the first bevel gear (504), the second bevel gear (507) does not rotate; the second bevel gear (507) is fixedly connected with a second transmission rod (508); the second transmission rod (508) is rotatably connected with the support frame (8); the second transmission rod (508) is fixedly connected with the first flat gear (509); the second shaft sleeve (510) is in sliding connection with the first transmission rod (502); two sides of the second shaft sleeve (510) are fixedly connected with a third bevel gear (511) and a fourth bevel gear (512) respectively; the second fixed frame (513) is rotationally connected with the second shaft sleeve (510); the second fixing frame (513) is fixedly connected with the fourth electric push rod (514); the fourth electric push rod (514) is fixedly connected with the support frame (8); a fifth bevel gear (515) is arranged on the side surface of the third bevel gear (511); when the fifth bevel gear (515) is engaged with the third bevel gear (511), the fifth bevel gear (515) rotates; when the fifth bevel gear (515) is not meshed with the third bevel gear (511), the fifth bevel gear (515) does not rotate; the fifth bevel gear (515) is fixedly connected with a third transmission rod (516); the third transmission rod (516) is rotatably connected with the support frame (8); the third transmission rod (516) is fixedly connected with the second flat gear (517); the second flat gear (517) is meshed with the third flat gear (518); the third flat gear (518) is fixedly connected with a bidirectional screw rod (519); the bidirectional screw rod (519) is in rotary connection with the turnover assembly; the bidirectional screw rod (519) is in screwed connection with the T-shaped connecting plate (520); the T-shaped connecting plate (520) is fixedly connected with the overturning component; the T-shaped connecting plate (520) is in sliding connection with the first sliding rod (521); the first sliding rod (521) is fixedly connected with the overturning component; the first spring piece (522) is rotatably connected with the fixed block (523) through a universal ball; the fixed block (523) is fixedly connected with the first soaking and smoothing unit (401); a combination of a first spring piece (522) and a fixed block (523) is symmetrically arranged by taking the central axis of the first sliding rod (521) as a symmetry axis;

the overturning assembly comprises a sixth bevel gear (601), a fourth transmission rod (602), a circular limiting slide rail (603), a first arc-shaped slide block (604) and a second arc-shaped slide block (605); the sixth bevel gear (601) is fixedly connected with the fourth transmission rod (602); the fourth transmission rod (602) is rotationally connected with the portal frame (4); the fourth transmission rod (602) is rotatably connected with the circular limiting slide rail (603); the circular limiting slide rail (603) is fixedly connected with the portal frame (4); the circular limiting slide rail (603) is in sliding connection with the first arc-shaped slide block (604) and the second arc-shaped slide block (605); the first arc-shaped sliding block (604) is rotationally connected with the bidirectional screw rod (519); the second arc-shaped sliding block (605) is fixedly connected with the first sliding rod (521); a fourth transmission rod (602), a circular limiting slide rail (603), a first arc-shaped slide block (604) and a second arc-shaped slide block (605) are symmetrically arranged by taking the central axis of the portal frame (4) as a symmetry axis;

the first soaking smoothing unit (401) comprises a soaking grid plate (40101), a first limiting sliding block (40102), a second spring part (40103), a U-shaped connecting plate (40104), a third spring part (40105), a second limiting sliding block (40106), a first smoothing rod (40107), a first pressing plate (40108), a second sliding rod (40109), a second pressing plate (40110), a second smoothing rod (40111), a third pressing plate (40112), a third smoothing rod (40113), an extrusion block (40114), a first fixing spring (40115), a second fixing spring (40116), a third fixing spring (40117), a baffle plate (40118) and a fourth spring part (40119); the soaking grid plate (40101) is fixedly connected with a fixed block (523); the soaking grid plate (40101) is fixedly connected with a first hinge (402); the soaking grid plate (40101) is in sliding connection with a first limiting slide block (40102); the first limiting slide block (40102) is fixedly connected with the second spring piece (40103); the second spring piece (40103) is fixedly connected with the U-shaped connecting plate (40104); the U-shaped connecting plate (40104) is fixedly connected with the third spring piece (40105); the third spring piece (40105) is fixedly connected with the second limiting slide block (40106); the second limiting slide block (40106) is in sliding connection with the soaking grid plate (40101); the first smoothing rod (40107) is rotatably connected with the U-shaped connecting plate (40104); the first smoothing bar (40107) is in contact with the first pressure plate (40108); the first pressure plate (40108) is fixedly connected with the second slide bar (40109); the second slide bar (40109) is in sliding connection with a second pressure plate (40110) and a third pressure plate (40112); the second pressure plate (40110) is contacted with the second smoothing rod (40111); the second smoothing rod (40111) is rotatably connected with the U-shaped connecting plate (40104); a third presser plate (40112) is in contact with a third smoothing bar (40113); the third smoothing rod (40113) is rotatably connected with the U-shaped connecting plate (40104); the extrusion block (40114) is fixedly connected with the first pressing plate (40108); two sides of the first fixed spring (40115) are fixedly connected with the first pressure plate (40108) and the second pressure plate (40110) respectively; two sides of the second fixed spring (40116) are fixedly connected with the second pressure plate (40110) and the third pressure plate (40112) respectively; two sides of the third fixed spring (40117) are fixedly connected with the third pressure plate (40112) and the soaking grid plate (40101) respectively; a combination of three groups of baffle plates (40118) and a fourth spring piece (40119) is arranged below the extrusion block (40114) at equal intervals; the baffle plate (40118) is in sliding connection with the soaking grid plate (40101); a group of fourth spring pieces (40119) are fixedly connected to the two sides of the baffle plate (40118); the two groups of fourth spring pieces (40119) are fixedly connected with the soaking grid plate (40101); a combination of a first limiting sliding block (40102), a second spring part (40103), a U-shaped connecting plate (40104), a third spring part (40105), a second limiting sliding block (40106), a first smoothing rod (40107), a second sliding rod (40109), a second smoothing rod (40111) and a third smoothing rod (40113) is symmetrically arranged by taking the central axis of the extrusion block (40114) as a symmetry axis; the combination of a first limiting sliding block (40102), a second spring piece (40103), a U-shaped connecting plate (40104), a third spring piece (40105), a second limiting sliding block (40106), a second sliding rod (40109), an extrusion block (40114), a first fixing spring (40115), a second fixing spring (40116) and a third fixing spring (40117) is symmetrically arranged by taking the central axis of the second flattening rod (40111) as a symmetry axis.

2. The mica paper crude product modification and soaking treatment equipment as set forth in claim 1, characterized in that: a sliding groove matched with the first limiting sliding block (40102) is arranged on the soaking grid plate (40101).

3. The mica paper crude product modification and soaking treatment equipment as claimed in claim 1, wherein: first clamp plate (40108), second clamp plate (40110) and third clamp plate (40112) side be provided with first smooth pole (40107), second smooth pole (40111) and third smooth pole (40113) assorted arc recess.

4. The mica paper crude product modification and soaking treatment equipment as claimed in claim 1, wherein: three groups of rectangular through grooves are arranged in the soaking grid plate (40101).

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