CN113731745B - Continuous coating equipment for preparing insulating resin by graphene coating heating body - Google Patents

Abstract

The invention relates to the field of graphene, in particular to continuous coating equipment for preparing insulating resin by using a graphene coating heating body. The technical problems of the invention are as follows: a continuous coating device for preparing insulating resin by using a graphene coating heating body is provided. The technical proposal is as follows: a continuous coating device for preparing insulating resin by a graphene coating heating body comprises a first support frame, a second support frame, a first fixing frame, a second fixing frame, a first fixing plate, a side surface sealing assembly and an electrode surface sealing assembly; the electrode surface sealing component is connected with the first support frame and the second support frame. When the invention is used, the cleaning of the sintered quartz glass coating surface is realized before the resin is coated, the resin is continuously coated on the coating surface, the coating speed is improved, the uniformity is greatly improved, the deformation and bending caused by touching the electrode during the coating of the electrode surface are avoided, and the production quality of the product is ensured.

Description

Continuous coating equipment for preparing insulating resin by graphene coating heating body

Technical Field

The invention relates to the field of graphene, in particular to continuous coating equipment for preparing insulating resin by using a graphene coating heating body.

Background

In the prior art, when preparing a graphene coating heating body, firstly, selecting a base material, adopting three quartz glass blocks as the base material, grinding grooves at two ends of one quartz glass block, placing electrodes, fixing by conductive silver colloid, leveling the surfaces of the electrodes and the glass surfaces, coating graphene slurry on the surfaces of the quartz glass blocks after the electrodes are made, then placing the electrodes into a resistance furnace for sintering, clamping a quartz glass substrate coated with the graphene by using two quartz glass blocks which are not coated with the graphene, and coating high-temperature resistant resin on the periphery of the quartz glass blocks for insulating and sealing after the electrodes are well sintered; many dust exists on the surface of the sintered quartz glass, adhesion of the resin is not facilitated when the resin is coated on the periphery of the quartz glass, the resin needs to be repeatedly dipped for coating when the quartz glass is coated manually, the coating speed is low, the uniformity is poor, the quartz glass is inconvenient to operate when one surface with the electrode is coated, the electrode is easily touched to cause deformation and bending of the electrode, and adverse effects are caused on product use.

In view of the above, there is an urgent need for a continuous coating apparatus for preparing an insulating resin for a graphene coating heating body to solve the above problems.

Disclosure of Invention

In order to overcome the defects that when a heating body with a graphene coating is prepared, firstly, three quartz glass blocks are used as base materials, electrodes are placed at grooves at two ends of one quartz glass block and fixed by conductive silver colloid, the surfaces of the electrodes and the surfaces of the glass are smooth, graphene slurry is coated on the surfaces of the quartz glass blocks after the electrodes are prepared, then the quartz glass blocks are placed into a resistance furnace for sintering, two quartz glass blocks which are not coated with graphene are used for clamping a quartz glass base plate coated with the graphene in the middle, and the periphery of the quartz glass blocks are coated with high-temperature resistant resin for insulating sealing after the electrodes are prepared; many dust exists on the surface of the sintered quartz glass, adhesion of the resin is not facilitated when the resin is coated on the periphery of the quartz glass, resin needs to be repeatedly dipped for coating when the resin is manually coated, the coating speed is low, the uniformity is poor, the operation is inconvenient when one surface with an electrode is coated, the electrode is easily touched to cause deformation and bending of the electrode, and the defect of adverse effect on product use is caused, the technical problem of the invention is that: a continuous coating device for preparing insulating resin by using a graphene coating heating body is provided.

The technical proposal is as follows: the continuous coating equipment for preparing the insulating resin by using the graphene coating heating body comprises a bottom frame, support columns, a base plate, a first support frame, a second support frame, a first fixing frame, a second fixing frame, a first fixing plate, a side surface sealing assembly and an electrode surface sealing 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 a group of backing plates respectively; the underframe is fixedly connected with the first support frame, the second support frame, the first fixing frame and the second fixing frame; a group of first fixing plates are fixedly connected to two sides of the underframe; the left side, the middle part and the right side above the underframe are provided with side glue sealing components; the side surface sealing assembly is connected with the first support frame, the second support frame, the first fixing frame and the second fixing frame; the side surface sealing component is connected with the electrode surface sealing component; the side surface sealing component coats resin on two sides of the clamped quartz glass; an electrode surface sealing component is arranged on the left side above the underframe; the electrode surface sealing assembly is connected with the first support frame and the second support frame; the electrode surface sealing component coats resin on the side surface of the quartz glass with the electrode.

The side glue sealing assembly comprises a first bevel gear, a first screw rod, a first connecting plate, a first sliding rod, a first resin box, a first electric push rod, a first push plate, a second electric push rod, a second push plate, an arc-shaped limiting sliding rail, a limiting rod, a second connecting plate, a first spring piece, a glue shovel, a fixed shaft, a second spring piece, a stop block, a wedge block, a glue spreading roller, a first lifting sliding block, a third spring piece, a baffle, a fourth spring piece, a fifth spring piece and a first brush plate; the first bevel gear is fixedly connected with the first screw rod; the first screw rod is in screwed connection with the first connecting plate; the first screw rod is rotationally connected with the second fixing frame; two sides of the first screw rod are respectively connected with the first support frame and the second fixing frame in a rotating way; the first connecting plate is in sliding connection with the first sliding rod; two sides of the first sliding rod are fixedly connected with the second supporting frame and the first fixing frame respectively; the first slide bar is fixedly connected with the first resin box; the first resin box is fixedly connected with the first electric push rod; the first electric push rod is fixedly connected with the first push plate; the second electric push rod is fixedly connected with the first resin box; the second electric push rod is fixedly connected with the second push plate; the two sides of the second push plate are symmetrically provided with a combination of the first electric push rod and the first push plate; the arc-shaped limiting slide rail is fixedly connected with the first resin box; the arc-shaped limiting sliding rail is fixedly connected with two groups of fifth spring pieces; the arc-shaped limit sliding rail is in sliding connection with the limit rod; the limiting rod is fixedly connected with the second connecting plate; the second connecting plate is fixedly connected with the first spring piece; the first spring piece is fixedly connected with the rubber shovel; the fixed shaft is in sliding connection with the second connecting plate; the fixed shaft is rotationally connected with the first resin box through a torsion spring; the second spring piece is fixedly connected with the second connecting plate; the second spring piece is fixedly connected with the fixed shaft; the stop block is fixedly connected with the fixed shaft; the stop block is in contact with the wedge block; the wedge-shaped block is rotationally connected with the glue spreading roller; the wedge block is fixedly connected with the first lifting slide block; the glue spreading roller is rotationally connected with the first lifting sliding block; the first lifting slide block is in sliding connection with the first resin box; the first lifting sliding block is fixedly connected with the third spring piece; the third spring piece is fixedly connected with the first resin box; the two sides of the first resin box are symmetrically provided with a limiting rod, a second connecting plate, a first spring piece, a rubber shovel, a fixed shaft, a second spring piece, a stop block, a wedge block, a first lifting sliding block and a third spring piece; a baffle is arranged below the glue spreading roller; the baffle is fixedly connected with the fourth spring piece; the fourth spring piece is fixedly connected with the first resin box; the two groups of fifth spring pieces are fixedly connected with the first brush plate.

The electrode surface sealing assembly comprises a main motor, a transmission rod, a shaft sleeve, a second bevel gear, a third fixing frame, a third electric push rod, a fourth bevel gear, a second screw rod, a third connecting plate, a first lifting slide rail, a first limiting plate, a second lifting slide block, a sixth spring piece, a fourth connecting plate, a second lifting slide rail, a second limiting plate, a fifth connecting plate, a second slide bar, a seventh spring piece, an eighth spring piece, a ninth spring piece, a sixth connecting plate, a second resin box, a tenth spring piece, a second brush plate, a fourth electric push rod, a third push plate, a first reset spring, a first porous slide plate, a fourth push plate, a second reset spring, a second porous slide plate, a fifth push plate, a third reset spring and a third porous slide plate; the main motor is fixedly connected with the first supporting frame; the output shaft of the main motor is fixedly connected with the transmission rod; the transmission rod is rotationally connected with the first support frame; the transmission rod is in sliding connection with the shaft sleeve; two sides of the shaft sleeve are fixedly connected with the second bevel gear and the third bevel gear respectively; the third fixing frame is rotationally connected with the shaft sleeve; the third fixing frame is fixedly connected with a third electric push rod; the third electric push rod is fixedly connected with the first support frame; a fourth bevel gear is arranged above the side surface of the third bevel gear; when the fourth bevel gear is meshed with the third bevel gear, the fourth bevel gear rotates; when the fourth bevel gear is not meshed with the third bevel gear, the fourth bevel gear does not rotate; the fourth bevel gear is fixedly connected with the second screw rod; the second screw rod is rotationally connected with the first supporting frame; the second screw rod is connected with the third connecting plate in a screwed mode; the third connecting plate is fixedly connected with the first lifting slide rail; the first lifting slide rail is fixedly connected with the first limiting plate through a connecting block; the second lifting sliding block is in sliding connection with the first lifting sliding rail; the second lifting sliding block is fixedly connected with a sixth spring piece; the sixth spring piece is fixedly connected with the fourth connecting plate; the combination of the second lifting sliding block and the sixth spring piece is symmetrically arranged on two sides of the fourth connecting plate; the second lifting slide rail is in sliding connection with the other group of second lifting slide blocks; the second lifting slide rail is fixedly connected with the second limiting plate through a connecting block; the fifth connecting plate is fixedly connected with the second lifting slide rail; the fifth connecting plate is in sliding connection with the second sliding rod; the second sliding rod is fixedly connected with the second supporting frame; the seventh spring piece, the eighth spring piece and the ninth spring piece are fixedly connected with the fourth connecting plate; the seventh spring piece, the eighth spring piece and the ninth spring piece are fixedly connected with a sixth connecting plate; the seventh spring piece, the eighth spring piece and the ninth spring piece are fixedly connected with the second resin box; the second resin box is fixedly connected with a tenth spring piece through a connecting block; the tenth spring piece is fixedly connected with the second brush plate; the fourth electric push rod is connected with the second resin box; the fourth electric push rod is in sliding connection with the third push plate and the fourth push plate; the third push plate is fixedly connected with a seventh spring element; the third push plate is in sliding connection with the second resin box; the third push plate is fixedly connected with the first reset spring; the first reset spring is fixedly connected with the first porous sliding plate; the first porous slide plate is in sliding connection with the second resin box; the fourth push plate is fixedly connected with the eighth spring piece; the fourth push plate is in sliding connection with the second resin box; the fourth push plate is fixedly connected with the second reset spring; the second reset spring is fixedly connected with the second porous sliding plate; the second porous slide plate is in sliding connection with the second resin box; the fifth push plate is fixedly connected with the ninth spring piece; the fifth push plate is fixedly connected with the third reset spring; the third reset spring is fixedly connected with the third porous sliding plate; the third porous slide plate is in sliding connection with the second resin box; a group of fourth electric push rods are symmetrically arranged on two sides of the fourth push plate.

Further stated, the arc-shaped limit sliding rail chute is arranged to be gradually deepened.

Further stated, the outer ring surface of the glue spreader is provided with a glue cloth.

Further stated, the first limiting plate and the second limiting plate are provided with arc-shaped protrusions which are staggered with each other.

Further, the second resin case is provided with two rectangular grooves.

Further stated, the sides of the first porous slide plate, the second porous slide plate and the third porous slide plate are provided with filter cloths.

The beneficial effects of the invention are as follows:

1. in order to solve the problems in the prior art, when a heating body with a graphene coating is prepared, firstly, a base material is selected, three quartz glass pieces are adopted as the base material, electrodes are placed at two ends of one quartz glass piece by grinding grooves and fixed by conductive silver colloid, the surfaces of the electrodes and the glass surfaces are smooth, graphene slurry is coated on the surfaces of the quartz glass pieces after the electrodes are prepared, then, the electrodes are placed into a resistance furnace for sintering, two quartz glass pieces which are not coated with graphene are used for clamping a quartz glass substrate coated with the graphene in the middle, and high-temperature resistant resin is coated on the periphery of the quartz glass pieces for insulating and sealing after the electrodes are prepared; many dust exist on the surface of the sintered quartz glass, adhesion of the resin is not facilitated when the resin is coated on the periphery of the quartz glass, resin needs to be repeatedly dipped for coating when the resin is manually coated, the coating speed is low, uniformity is poor, operation is inconvenient when one surface with an electrode is coated, and the problem that the electrode is deformed and bent due to contact with the electrode easily and bad influence is caused on product use is solved.

2. The side face sealing assembly, the electrode face sealing assembly and the overturning assembly are designed, equipment is placed on a horizontal plane when the equipment is ready to work, a power supply is connected, three clamped quartz glass blocks are placed into the overturning assembly on a bottom frame supported by a support column and a base plate, the overturning assembly is controlled by a controller to be fixed, then the electrode face sealing assembly between the first support frame and the second support frame drives the side face sealing assembly to operate, the side face sealing assembly connected with the first support frame and the second support frame coats resin on the side face of the quartz glass, then the electrode face sealing assembly coats resin on the side face of the quartz glass with an electrode, after the treatment is completed, the side face sealing assembly and the electrode face sealing assembly are reset, and then the overturning assembly connected with the first fixing plate overturns the quartz glass by one hundred eighty degrees, so that the side face sealing assembly and the electrode face sealing assembly process the other two sides.

3. When the invention is used, the cleaning of the sintered quartz glass coating surface is realized before the resin is coated, the resin is continuously coated on the coating surface, the coating speed is improved, the uniformity is greatly improved, the deformation and bending caused by touching the electrode during the coating of the electrode surface are avoided, and the production quality of the product is ensured.

Drawings

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

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

FIG. 3 is a schematic view of a first perspective structure of a side seal assembly according to the present invention;

FIG. 4 is a schematic view of a second perspective structure of a side seal assembly according to the present invention;

FIG. 5 is a schematic view of a first partial perspective view of a side seal assembly according to the present invention;

FIG. 6 is a schematic view of a second partial perspective view of a side seal assembly according to the present invention;

FIG. 7 is a schematic view of a third partial perspective view of a side seal assembly according to the present invention;

FIG. 8 is a top view of a side seal assembly of the present invention;

fig. 9 is a schematic diagram of a first perspective structure of an electrode surface sealing component of the present invention;

FIG. 10 is a schematic view of a second perspective structure of an electrode surface sealing assembly according to the present invention;

FIG. 11 is a schematic view of a first partial perspective view of an electrode surface sealing assembly according to the present invention;

FIG. 12 is a schematic view of a second perspective structure of an electrode face seal assembly according to the present invention;

FIG. 13 is a schematic view of a third perspective structure of an electrode surface sealing assembly according to the present invention;

FIG. 14 is a top view of an electrode face seal assembly of the present invention;

FIG. 15 is a first perspective view of the flipping assembly of the present invention;

fig. 16 is a second perspective view of the flipping assembly of the present invention.

In the above figures: 1: chassis, 2: support column, 3: backing plate, 4: first support frame, 5: second support frame, 6: first mount, 7: second mount, 8: first fixed plate, 301: first bevel gear, 302: first screw, 303: first connection plate, 304: first slide bar, 305: first resin cartridge, 306: first electric putter, 307: first push plate, 308: second electric putter, 309: second push plate, 310: arc limiting slide rail, 311: stop lever, 312: second connection plate, 313: first spring member, 314: glue shovel, 315: fixed shaft, 316: second spring member, 317: stop, 318: wedge, 319: glue applicator, 320: first lifting slide, 321: third spring element, 322: baffle, 323: fourth spring element, 324: fifth spring element, 325: first brush plate, 401: main motor, 402: transmission rod, 403: shaft sleeve, 404: second bevel gear, 405: third bevel gear, 406: third mount, 407: third electric putter, 408: fourth bevel gear, 409: second screw, 410: third connection plate, 411: first lift rail, 412: first limiting plate, 413: second lifting slider, 414: sixth spring element, 415: fourth connection plate, 416: second lifting slide rail, 417: second limiting plate, 418: fifth connecting plate, 419: second slide bar, 420: seventh spring element, 421: eighth spring element, 422: ninth spring member 423: sixth connection plate, 424: second resin cartridge, 425: tenth spring member, 426: second brush plate, 427: fourth electric putter, 428: third push plate, 429: first return spring, 430: first porous slide, 431: fourth push plate, 432: second return spring, 433: a second porous sled, 434: fifth push plate, 435: third return spring, 436: third porous slide, 501: small motor, 502: first telescopic link, 503: fourth mount, 504: second fixing plate, 505: fifth electric putter, 506: first electric chuck, 507: arc slider, 508: second telescopic link, 509: third fixing plate, 510: sixth electric putter, 511: second electric chuck, 512: circular spacing slide rail.

Detailed Description

The present invention now will be described more fully hereinafter with reference to the accompanying drawings, in which currently preferred embodiments of the invention are shown. This invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein; rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the scope of the invention to those skilled in the art.

Examples

The continuous coating equipment for preparing insulating resin by using the graphene coating heating body is shown by referring to figures 1-2 and comprises a bottom frame 1, a support column 2, a base plate 3, a first support frame 4, a second support frame 5, a first fixing frame 6, a second fixing frame 7, a first fixing plate 8, a side surface sealing assembly and an electrode surface sealing 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 fixedly connected with a group of backing plates 3 respectively; the underframe 1 is fixedly connected with a first supporting frame 4, a second supporting frame 5, a first fixing frame 6 and a second fixing frame 7; a group of first fixing plates 8 are fixedly connected to two sides of the underframe 1; the left side, the middle part and the right side above the underframe 1 are provided with side glue sealing components; the side glue sealing assembly is connected with the first support frame 4, the second support frame 5, the first fixing frame 6 and the second fixing frame 7; the side surface sealing component is connected with the electrode surface sealing component; the side surface sealing component coats resin on two sides of the clamped quartz glass; an electrode surface sealing component is arranged on the left side above the underframe 1; the electrode surface sealing component is connected with the first support frame 4 and the second support frame 5; the electrode surface sealing component coats resin on the side surface of the quartz glass with the electrode.

Working principle: when the device is ready to work, the device is placed on a horizontal plane, a power supply is connected, three clamped quartz glass blocks are placed in a turnover assembly on a bottom frame 1 supported by a support column 2 and a base plate 3, the turnover assembly is controlled by a controller to be fixed, then an electrode surface sealing assembly between a first support frame 4 and a second support frame 5 drives the side sealing assembly to operate, the side sealing assembly connected with a first fixing frame 6 and a second fixing frame 7 coats resin on the side surface of the quartz glass, then the electrode surface sealing assembly coats resin on the side surface of the quartz glass with electrodes, after the treatment is finished, the side sealing assembly and the electrode surface sealing assembly are reset, and then the turnover assembly connected with a first fixing plate 8 enables the quartz glass to turn over one hundred eighty degrees so that the side sealing assembly and the electrode surface sealing assembly process the other two sides; when the invention is used, the cleaning of the sintered quartz glass coating surface is realized before the resin is coated, the resin is continuously coated on the coating surface, the coating speed is improved, the uniformity is greatly improved, the deformation and the bending caused by touching the electrode are avoided when the electrode surface is coated, and the production quality of products is ensured.

Referring to fig. 3 to 8, the side sealing assembly includes a first bevel gear 301, a first screw rod 302, a first connection plate 303, a first slide bar 304, a first resin box 305, a first electric push rod 306, a first push plate 307, a second electric push rod 308, a second push plate 309, an arc-shaped limit slide rail 310, a limit rod 311, a second connection plate 312, a first spring 313, a glue shovel 314, a fixed shaft 315, a second spring 316, a stopper 317, a wedge 318, a glue roller 319, a first lifting slider 320, a third spring 321, a baffle 322, a fourth spring 323, a fifth spring 324, and a first brush plate 325; the first bevel gear 301 is fixedly connected with the first screw rod 302; the first screw rod 302 is screwed with the first connecting plate 303; the first screw rod 302 is rotationally connected with the second fixing frame 7; two sides of the first screw rod 302 are respectively in rotary connection with the first supporting frame 4 and the second fixing frame 7; the first connecting plate 303 is in sliding connection with the first sliding rod 304; two sides of the first sliding rod 304 are fixedly connected with the second supporting frame 5 and the first fixing frame 6 respectively; the first slide bar 304 is fixedly connected with the first resin box 305; the first resin box 305 is fixedly connected with a first electric push rod 306; the first electric push rod 306 is fixedly connected with the first push plate 307; the second electric push rod 308 is fixedly connected with the first resin box 305; the second electric push rod 308 is fixedly connected with the second push plate 309; the second push plate 309 is symmetrically provided with a combination of a first electric push rod 306 and a first push plate 307 on both sides; the arc-shaped limit sliding rail 310 is fixedly connected with the first resin box 305; the arc-shaped limiting slide rail 310 is fixedly connected with two groups of fifth spring pieces 324; the arc-shaped limit sliding rail 310 is in sliding connection with the limit rod 311; the limiting rod 311 is fixedly connected with the second connecting plate 312; the second connecting plate 312 is fixedly connected with the first spring member 313; the first spring member 313 is fixedly connected with the glue shovel 314; the fixed shaft 315 is slidably connected with the second connecting plate 312; the fixed shaft 315 is rotatably connected with the first resin case 305 through a torsion spring; the second spring member 316 is fixedly connected with the second connecting plate 312; the second spring member 316 is fixedly connected with the fixed shaft 315; the stop 317 is fixedly connected with the fixed shaft 315; the stop 317 contacts the wedge 318; the wedge 318 is in rotational connection with a glue applicator 319; the wedge block 318 is fixedly connected with the first lifting slide block 320; the glue spreader 319 is rotatably connected with the first lifting slide block 320; the first elevating slider 320 is slidably connected to the first resin cartridge 305; the first lifting slide block 320 is fixedly connected with the third spring member 321; the third spring 321 is fixedly connected with the first resin case 305; the two sides of the first resin box 305 are symmetrically provided with a limiting rod 311, a second connecting plate 312, a first spring member 313, a rubber shovel 314, a fixed shaft 315, a second spring member 316, a stop block 317, a wedge block 318, a first lifting slide block 320 and a third spring member 321; a baffle 322 is arranged below the glue applicator 319; the baffle 322 is fixedly connected with a fourth spring piece 323; the fourth spring 323 is fixedly connected with the first resin case 305; both sets of fifth spring members 324 are fixedly coupled to the first brush plate 325.

After three pieces of quartz glass are fixed in the turnover assembly, the bottom surface of the three pieces of quartz glass is slightly lower than the top of the glue spreading roller 319 at this moment, then the electrode surface glue spreading assembly transmits power to drive the first bevel gear 301 to drive the first lead screw 302 to rotate, the first lead screw 302 drives the first connecting plate 303 connected with the first bevel gear 301 in a screwing way to slide on the first sliding rod 304, further drives the first resin box 305 and connected parts thereof to move, when the first brush plate 325 moves to the bottom surface of the quartz glass, the first brush plate 325 is pressed downwards by the quartz glass so as to compress the two groups of fifth spring pieces 324, the first brush plate 325 is further moved to clean the quartz glass by being closely contacted with the bottom surface of the quartz glass, then the glue spreading roller 319 is contacted with the bottom surface of the quartz glass and pressed, further the first lifting slide 320 slides downwards in the first resin box 305, the third spring piece 321 is compressed, meanwhile the first lifting slide 320 drives the wedge block 318 to downwards move the pressing block 317, the stop 317 drives the fixed shaft 315 to rotate in the first resin case 305, so that the fixed shaft 315 drives the second connecting plate 312 to rotate, the limiting rod 311 slides in the arc-shaped limiting slide rail 310, when the second spring piece 316 is in a stretched state and the limiting rod 311 slides in the chute with gradually deepened arc-shaped limiting slide rail 310, the second spring piece 316 returns to drive the second connecting plate 312 to slide on the fixed shaft 315 due to elastic force, so that the second connecting plate 312 drives the first spring piece 313 to move, the glue shovel 314 is tightly attached to the side surface of the quartz glass, the first spring piece 313 is compressed, the glue spreader 319 further coats the tree on the bottom surface when moving through the bottom surface of the quartz glass, meanwhile, the glue shovel 314 scrapes off the resin adhered to the edge of the side surface of the quartz glass, when the glue spreader 319 coats the resin, the resin in the first resin case 305 slowly decreases, and the pressure applied by the baffle 322 slowly decreases, meanwhile, as the fourth spring piece 323 is in a compressed state, the baffle 322 is pushed to rise by the elastic force, so that the resin liquid level in the first resin box 305 rises to keep a contact state with the glue spreading roller 319, the glue spreading roller 319 can be guaranteed to continuously spread resin, when the glue spreading roller 319 is not extruded, the third spring piece 321 drives the first lifting sliding block 320 to reset by the elastic force, the fixed shaft 315 is reset by the elastic force of the torsion spring, and the second connecting plate 312 drives the limiting rod 311 to reset; after the electrode surface sealing assembly is processed, the third porous slide plate 436 is aligned with the first push plate 307, then the main motor 401 is reversed, so that the first screw rod 302 is reversely rotated, the first push plate 307 is positioned on the side surface of the third porous slide plate 436, then the first electric push rod 306 and the second electric push rod 308 are extended, two groups of the first push plate 307 and one group of the second push plate 309 push the first porous slide plate 430, the third porous slide plate 436 and the second porous slide plate 433, and the third push plate 428, the fifth push plate 434 and the fourth push plate 431 are reset; the assembly continuously coats the bottom surface of the quartz glass with resin and cleans the bottom surface of the quartz glass before coating.

Referring to fig. 9 to 14, the electrode surface sealing assembly includes a main motor 401, a transmission rod 402, a shaft sleeve 403, a second bevel gear 404, a third bevel gear 405, a third fixing frame 406, a third electric push rod 407, a fourth bevel gear 408, a second screw rod 409, a third connecting plate 410, a first lifting slide 411, a first limiting plate 412, a second lifting slide 413, a sixth spring member 414, a fourth connecting plate 415, a second lifting slide 416, a second limiting plate 417, a fifth connecting plate 418, a second slide bar 419, a seventh spring member 420, an eighth spring member 421, a ninth spring member 422, a sixth connecting plate 423, a second resin box 424, a tenth spring member 425, a second brush plate 426, a fourth electric push rod 427, a third push plate 428, a first return spring 429, a first porous slide 430, a fourth push plate 431, a second return spring 432, a second porous slide 433, a fifth push plate 434, a third return spring 435, and a third porous slide 436; the main motor 401 is fixedly connected with the first supporting frame 4; an output shaft of the main motor 401 is fixedly connected with a transmission rod 402; the transmission rod 402 is rotatably connected with the first supporting frame 4; the transmission rod 402 is in sliding connection with the shaft sleeve 403; two sides of the shaft sleeve 403 are fixedly connected with a second bevel gear 404 and a third bevel gear 405 respectively; the third fixing frame 406 is rotatably connected with the shaft sleeve 403; the third fixing frame 406 is fixedly connected with a third electric push rod 407; the third electric push rod 407 is fixedly connected with the first supporting frame 4; a fourth bevel gear 408 is arranged above the side surface of the third bevel gear 405; when the fourth bevel gear 408 is meshed with the third bevel gear 405, the fourth bevel gear 408 rotates; when the fourth bevel gear 408 is not meshed with the third bevel gear 405, the fourth bevel gear 408 does not rotate; the fourth bevel gear 408 is fixedly connected with a second screw rod 409; the second screw rod 409 is rotatably connected with the first supporting frame 4; the second screw 409 is screwed with the third connecting plate 410; the third connecting plate 410 is fixedly connected with the first lifting slide rail 411; the first lifting slide rail 411 is fixedly connected with the first limiting plate 412 through a connecting block; the second lifting slide block 413 is in sliding connection with the first lifting slide rail 411; the second lifting slide block 413 is fixedly connected with the sixth spring element 414; the sixth spring element 414 is fixedly connected with the fourth connecting plate 415; the combination of the second lifting slide block 413 and the sixth spring element 414 is symmetrically arranged on both sides of the fourth connecting plate 415; the second lifting slide rail 416 is in sliding connection with the other group of second lifting slide blocks 413; the second lifting slide rail 416 is fixedly connected with the second limiting plate 417 through a connecting block; the fifth connecting plate 418 is fixedly connected with the second lifting slide rail 416; the fifth connecting plate 418 is in sliding connection with the second sliding rod 419; the second slide bar 419 is fixedly connected with the second supporting frame 5; the seventh spring element 420, the eighth spring element 421 and the ninth spring element 422 are fixedly connected with the fourth connecting plate 415; the seventh spring member 420, the eighth spring member 421 and the ninth spring member 422 are fixedly connected with the sixth connecting plate 423; the seventh spring member 420, the eighth spring member 421 and the ninth spring member 422 are fixedly connected with the second resin case 424; the second resin case 424 is fixedly connected with the tenth spring member 425 through a connection block; the tenth spring member 425 is fixedly coupled to the second brush plate 426; the fourth electric push rod 427 is connected to the second resin case 424; the fourth electric push rod 427 is slidably connected with the third push plate 428 and the fourth push plate 431; the third push plate 428 is fixedly connected with the seventh spring element 420; the third push plate 428 is slidably coupled to the second resin cartridge 424; the third push plate 428 is fixedly connected with a first return spring 429; the first return spring 429 is fixedly connected with the first porous slide plate 430; the first porous slide 430 is slidably coupled to the second resin cartridge 424; the fourth push plate 431 is fixedly connected with the eighth spring member 421; the fourth push plate 431 is slidably coupled to the second resin casing 424; the fourth push plate 431 is fixedly connected with the second reset spring 432; the second return spring 432 is fixedly connected with the second porous sliding plate 433; the second porous slide 433 is slidably connected to the second resin cartridge 424; the fifth push plate 434 is fixedly connected with the ninth spring piece 422; the fifth push plate 434 is fixedly connected with the third return spring 435; the third return spring 435 is fixedly connected with the third porous slide plate 436; the third porous slide 436 is slidably connected to the second resin cartridge 424; a group of fourth electric push rods 427 are symmetrically arranged on two sides of the fourth push plate 431.

When the side sealing assembly is operated and power is required to be transmitted, the main motor 401 is started, the output shaft of the main motor 401 drives the transmission rod 402 to rotate the transmission shaft sleeve 403, the shaft sleeve 403 rotates and drives the second bevel gear 404 and the third bevel gear 405 to rotate, then the third electric push rod 407 contracts to enable the third fixing frame 406 to drive the shaft sleeve 403 to slide on the transmission rod 402, the second bevel gear 404 is meshed with the first bevel gear 301, further power is transmitted to the side sealing assembly, after the side sealing assembly is processed, the third electric push rod 407 extends to enable the third bevel gear 405 to be meshed with the fourth bevel gear 408, the fourth bevel gear 408 rotates to drive the second lead screw 409 to rotate, the second lead screw 409 drives the third connecting plate 410 screwed with the second lead screw 409 to move, further the second resin box 424 is close to the side surface of quartz glass, the second brush plate 426 is tightly adhered to the side surface of quartz glass, the tenth spring member 425 is compressed, simultaneously, the second lifting slide rail 416 drives the fifth connecting plate 418 to slide on the second slide bar 419, then the power of the fourth bevel gear 408 is interrupted, then the two groups of second lifting slide blocks 413 are started, simultaneously the two groups of sixth spring pieces 414 slide downwards in the first lifting slide rail 411 and the second lifting slide rail 416, so that the two groups of sixth spring pieces 414 drive the fourth connecting plate 415 to move downwards, further the second resin box 424 moves downwards, when the first porous slide plate 430 descends to correspond to the side face of quartz glass, the power of the fourth bevel gear 408 is restored, further the filter cloth on the side faces of the first porous slide plate 430, the second porous slide plate 433 and the third porous slide plate 436 is tightly adhered to the side face of quartz glass, simultaneously the two groups of fourth electric push rods 427 are contracted, the restrictions on the third push plate 428, the fourth push plate 431 and the fifth push plate 434 are released, and simultaneously the seventh spring pieces 420, the eighth spring pieces 421 and the ninth spring pieces 422 are in a compressed state, the third push plate 428, the fourth push plate 431 and the fifth push plate 434 are pushed to slide in the second resin box 424 by elastic force, so that resin is gradually extruded and coated on the side surfaces of the quartz glass from the side surfaces of the first porous slide plate 430, the second porous slide plate 433 and the third porous slide plate 436, meanwhile, when the sixth connecting plate 423 moves downwards, the sixth connecting plate 423 extrudes with the bulges on the side surfaces of the first limiting plate 412 and the second limiting plate 417, so that two groups of sixth spring pieces 414 are compressed and stretched in a reciprocating manner, so that the second resin box 424 reciprocates left and right, so that the resin extruded on the side surfaces of the first porous slide plate 430, the second porous slide plate 433 and the third porous slide plate 436 is smeared on the side surfaces of the quartz glass, the positions corresponding to the rectangular grooves of the second resin box 424 are coated with resin, then the sixth connecting plate 423 passes through the rectangular grooves of the first limiting plate 412 and the second limiting plate 417, so that the electrode side surfaces of the quartz glass pass through the rectangular grooves of the second resin box 424, the resin is coated on the quartz glass around the electrodes, and the side surfaces with the electrodes are coated, after the coating of the electrodes is completed, the first porous slide plate 430 corresponds to the first push plate 307; after the side glue sealing assembly is reset, the first porous slide plate 430, the third porous slide plate 436 and the second porous slide plate 433 are pushed by two groups of first push plates 307 and one group of second push plates 309 at the same time, so that the first reset spring 429, the second reset spring 432 and the third reset spring 435 are compressed, so that the third push plate 428, the fourth push plate 431 and the fifth push plate 434 reversely slide and reset, then the two groups of fourth electric push rods 427 are stretched and reset, inserted into round holes of the third push plate 428, the fourth push plate 431 and the fifth push plate 434, then the main motor 401 is reversed, the fourth bevel gear 408 is restored by power, so that the third connecting plate 410 reversely moves and resets, then the two groups of second lifting slide blocks 413 reversely slide and reset, then the overturning assembly is operated to overturn quartz glass by one hundred eighty degrees, so that the side glue sealing assembly and the electrode surface glue sealing assembly coat resin on the other two surfaces; the component coats resin on the electrode surface of quartz glass, and avoids deformation and bending of the electrode caused by touch.

15-16, the turnover assembly is positioned in the middle of the upper part of the chassis 1, and comprises a small motor 501, a first telescopic rod 502, a fourth fixing frame 503, a second fixing plate 504, a fifth electric push rod 505, a first electric sucking disc 506, an arc-shaped sliding block 507, a second telescopic rod 508, a third fixing plate 509, a sixth electric push rod 510, a second electric sucking disc 511 and a circular limiting sliding rail 512; the small motor 501 is fixedly connected with the circular limit sliding rail 512 through a connecting block; an output shaft of the small motor 501 is fixedly connected with a first telescopic rod 502; the first telescopic rod 502 is rotatably connected with the fourth fixing frame 503; the fourth fixing frame 503 is fixedly connected with the circular limiting slide rail 512; the second fixing plate 504 is rotatably connected with the first telescopic rod 502; the second fixing plate 504 is fixedly connected with the fifth electric push rod 505; the fifth electric push rod 505 is fixedly connected with the fourth fixing frame 503; the first electric sucking disc 506 is fixedly connected with the first telescopic rod 502; the arc-shaped sliding block 507 is in sliding connection with the circular limiting sliding rail 512; the arc-shaped sliding block 507 is fixedly connected with a second telescopic rod 508; the second telescopic rod 508 is fixedly connected with a third fixed plate 509; the third fixing plate 509 is fixedly connected to the sixth electric push rod 510; the sixth electric push rod 510 is fixedly connected with the second telescopic rod 508 through a connecting block; the second electric sucking disc 511 is fixedly connected with the second telescopic rod 508; the circular limiting slide rail 512 is fixedly connected with the first fixing plate 8; the combination of the arc-shaped sliding block 507, the second telescopic rod 508, the third fixed plate 509, the sixth electric push rod 510 and the second electric sucking disc 511 is symmetrically arranged by taking the central axis of the fourth fixed frame 503 as a symmetrical axis; the combination of a small motor 501, a first telescopic rod 502, a fourth fixing frame 503, a second fixing plate 504, a fifth electric push rod 505, a first electric sucking disc 506, an arc-shaped sliding block 507, a second telescopic rod 508, a third fixing plate 509, a sixth electric push rod 510, a second electric sucking disc 511 and a circular limiting sliding rail 512 is symmetrically arranged by taking the central axis of the underframe 1 as a symmetrical axis.

Placing the clamped three pieces of quartz glass between two groups of first electric sucking discs 506 and four groups of second electric sucking discs 511, then simultaneously stretching two groups of fifth electric pushing rods 505 and four groups of sixth electric pushing rods 510, pushing the second fixing plate 504 by the fifth electric pushing rods 505 to stretch the first telescopic rods 502, pushing the third fixing plate 509 by the sixth electric pushing rods 510 to stretch the second telescopic rods 508, enabling the two groups of first electric sucking discs 506 to be tightly attached to the surface of the quartz glass, enabling the four groups of second electric sucking discs 511 to be tightly attached to the surface of the quartz glass, and further fixing the quartz glass so as to facilitate the treatment of the side sealing assembly and the electrode surface sealing assembly; after the side surface sealing assembly and the electrode surface sealing assembly are reset after being processed, the small motor 501 is started, an output shaft of the small motor 501 drives the first telescopic rod 502 to rotate in the fourth fixing frame 503, so that the first electric sucking disc 506 drives quartz glass to rotate, and then the quartz glass drives a plurality of groups of second electric sucking discs 511 to do circular motion, so that the second telescopic rod 508 drives the arc-shaped sliding blocks 507 to slide in the circular limiting sliding rails 512, and further enables the quartz glass to turn over one hundred eighty degrees, then the small motor 501 is closed, and then the side surface sealing assembly and the electrode surface sealing assembly repeat the first resin coating operation again, and further the periphery of the quartz glass is coated with resin; the component fixes quartz glass, so that the quartz glass can be turned over for one hundred eighty degrees, and the side surface sealing component and the electrode surface sealing component are convenient to process.

The arc-shaped limit sliding rail 310 is provided with a sliding groove which gradually deepens.

So that the second spring member 316 may be contracted as the stopper rod 311 slides therein.

The outer circumferential surface of the glue applicator 319 is provided with a glue tape.

So that the adhesive resin is coated on the side of the quartz glass.

The first and second limiting plates 412 and 417 are provided with arc-shaped protrusions offset from each other.

So as to reciprocally press the sixth connecting plate 423.

The second resin case 424 is provided with two rectangular grooves.

Avoiding the second resin case 424 from being blocked by the electrode on the side of the quartz glass when moving.

The sides of the first porous sliding plate 430, the second porous sliding plate 433 and the third porous sliding plate 436 are provided with filter cloths.

Slowing the resin extrusion rate in the second resin cartridge 424.

The technical principles of the embodiments of the present invention are described above in connection with specific embodiments. The description is only intended to explain the principles of the embodiments of the invention and should not be taken in any way as limiting the scope of the embodiments of the invention. Based on the explanations herein, those skilled in the art will recognize other embodiments of the present invention without undue burden, and those ways that are within the scope of the present invention.

Claims (6)

1. A continuous coating device for preparing insulating resin by a graphene coating heating body comprises a bottom frame, support columns, a base plate, a first support frame, a second support frame, a first fixing frame, a second fixing frame and a first fixing plate; 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 a group of backing plates respectively; the underframe is fixedly connected with the first support frame, the second support frame, the first fixing frame and the second fixing frame; a group of first fixing plates are fixedly connected to two sides of the underframe; the electrode surface sealing device is characterized by further comprising a side surface sealing assembly and an electrode surface sealing assembly; the left side, the middle part and the right side above the underframe are provided with side glue sealing components; the side surface sealing assembly is connected with the first support frame, the second support frame, the first fixing frame and the second fixing frame; the side surface sealing component is connected with the electrode surface sealing component; the side surface sealing component coats resin on two sides of the clamped quartz glass; an electrode surface sealing component is arranged on the left side above the underframe; the electrode surface sealing assembly is connected with the first support frame and the second support frame; the electrode surface sealing component coats resin on the side surface of the quartz glass with the electrode;

the side glue sealing assembly comprises a first bevel gear, a first screw rod, a first connecting plate, a first sliding rod, a first resin box, a first electric push rod, a first push plate, a second electric push rod, a second push plate, an arc limiting sliding rail, a limiting rod, a second connecting plate, a first spring piece, a glue shovel, a fixed shaft, a second spring piece, a stop block, a wedge block, a glue spreading roller, a first lifting sliding block, a third spring piece, a baffle, a fourth spring piece, a fifth spring piece and a first brush plate; the first bevel gear is fixedly connected with the first screw rod; the first screw rod is in screwed connection with the first connecting plate; the first screw rod is rotationally connected with the second fixing frame; two sides of the first screw rod are respectively connected with the first support frame and the second fixing frame in a rotating way; the first connecting plate is in sliding connection with the first sliding rod; two sides of the first sliding rod are fixedly connected with the second supporting frame and the first fixing frame respectively; the first slide bar is fixedly connected with the first resin box; the first resin box is fixedly connected with the first electric push rod; the first electric push rod is fixedly connected with the first push plate; the second electric push rod is fixedly connected with the first resin box; the second electric push rod is fixedly connected with the second push plate; the two sides of the second push plate are symmetrically provided with a combination of the first electric push rod and the first push plate; the arc-shaped limiting slide rail is fixedly connected with the first resin box; the arc-shaped limiting sliding rail is fixedly connected with two groups of fifth spring pieces; the arc-shaped limit sliding rail is in sliding connection with the limit rod; the limiting rod is fixedly connected with the second connecting plate; the second connecting plate is fixedly connected with the first spring piece; the first spring piece is fixedly connected with the rubber shovel; the fixed shaft is in sliding connection with the second connecting plate; the fixed shaft is rotationally connected with the first resin box through a torsion spring; the second spring piece is fixedly connected with the second connecting plate; the second spring piece is fixedly connected with the fixed shaft; the stop block is fixedly connected with the fixed shaft; the stop block is in contact with the wedge block; the wedge-shaped block is rotationally connected with the glue spreading roller; the wedge block is fixedly connected with the first lifting slide block; the glue spreading roller is rotationally connected with the first lifting sliding block; the first lifting slide block is in sliding connection with the first resin box; the first lifting sliding block is fixedly connected with the third spring piece; the third spring piece is fixedly connected with the first resin box; the two sides of the first resin box are symmetrically provided with a limiting rod, a second connecting plate, a first spring piece, a rubber shovel, a fixed shaft, a second spring piece, a stop block, a wedge block, a first lifting sliding block and a third spring piece; a baffle is arranged below the glue spreading roller; the baffle is fixedly connected with the fourth spring piece; the fourth spring piece is fixedly connected with the first resin box; the two groups of fifth spring pieces are fixedly connected with the first brush plate;

The electrode surface sealing assembly comprises a main motor, a transmission rod, a shaft sleeve, a second bevel gear, a third fixing frame, a third electric push rod, a fourth bevel gear, a second screw rod, a third connecting plate, a first lifting slide rail, a first limiting plate, a second lifting slide block, a sixth spring piece, a fourth connecting plate, a second lifting slide rail, a second limiting plate, a fifth connecting plate, a second slide bar, a seventh spring piece, an eighth spring piece, a ninth spring piece, a sixth connecting plate, a second resin box, a tenth spring piece, a second brush plate, a fourth electric push rod, a third push plate, a first reset spring, a first porous slide plate, a fourth push plate, a second reset spring, a second porous slide plate, a fifth push plate, a third reset spring and a third porous slide plate; the main motor is fixedly connected with the first supporting frame; the output shaft of the main motor is fixedly connected with the transmission rod; the transmission rod is rotationally connected with the first support frame; the transmission rod is in sliding connection with the shaft sleeve; two sides of the shaft sleeve are fixedly connected with the second bevel gear and the third bevel gear respectively; the third fixing frame is rotationally connected with the shaft sleeve; the third fixing frame is fixedly connected with a third electric push rod; the third electric push rod is fixedly connected with the first support frame; a fourth bevel gear is arranged above the side surface of the third bevel gear; when the fourth bevel gear is meshed with the third bevel gear, the fourth bevel gear rotates; when the fourth bevel gear is not meshed with the third bevel gear, the fourth bevel gear does not rotate; the fourth bevel gear is fixedly connected with the second screw rod; the second screw rod is rotationally connected with the first supporting frame; the second screw rod is connected with the third connecting plate in a screwed mode; the third connecting plate is fixedly connected with the first lifting slide rail; the first lifting slide rail is fixedly connected with the first limiting plate through a connecting block; the second lifting sliding block is in sliding connection with the first lifting sliding rail; the second lifting sliding block is fixedly connected with a sixth spring piece; the sixth spring piece is fixedly connected with the fourth connecting plate; the combination of the second lifting sliding block and the sixth spring piece is symmetrically arranged on two sides of the fourth connecting plate; the second lifting slide rail is in sliding connection with the other group of second lifting slide blocks; the second lifting slide rail is fixedly connected with the second limiting plate through a connecting block; the fifth connecting plate is fixedly connected with the second lifting slide rail; the fifth connecting plate is in sliding connection with the second sliding rod; the second sliding rod is fixedly connected with the second supporting frame; the seventh spring piece, the eighth spring piece and the ninth spring piece are fixedly connected with the fourth connecting plate; the seventh spring piece, the eighth spring piece and the ninth spring piece are fixedly connected with a sixth connecting plate; the seventh spring piece, the eighth spring piece and the ninth spring piece are fixedly connected with the second resin box; the second resin box is fixedly connected with a tenth spring piece through a connecting block; the tenth spring piece is fixedly connected with the second brush plate; the fourth electric push rod is connected with the second resin box; the fourth electric push rod is in sliding connection with the third push plate and the fourth push plate; the third push plate is fixedly connected with a seventh spring element; the third push plate is in sliding connection with the second resin box; the third push plate is fixedly connected with the first reset spring; the first reset spring is fixedly connected with the first porous sliding plate; the first porous slide plate is in sliding connection with the second resin box; the fourth push plate is fixedly connected with the eighth spring piece; the fourth push plate is in sliding connection with the second resin box; the fourth push plate is fixedly connected with the second reset spring; the second reset spring is fixedly connected with the second porous sliding plate; the second porous slide plate is in sliding connection with the second resin box; the fifth push plate is fixedly connected with the ninth spring piece; the fifth push plate is fixedly connected with the third reset spring; the third reset spring is fixedly connected with the third porous sliding plate; the third porous slide plate is in sliding connection with the second resin box; a group of fourth electric push rods are symmetrically arranged on two sides of the fourth push plate.

2. The continuous coating apparatus for preparing insulating resin by using a graphene coating heating body according to claim 1, wherein the arc-shaped limit sliding rail chute is arranged to be gradually deepened.

3. The continuous coating device for preparing insulating resin by using a graphene coating heating body according to claim 1, wherein an outer ring surface of the glue spreading roller is provided with a glue cloth.

4. The continuous coating device for preparing insulating resin by using a graphene coating heating body according to claim 1, wherein the first limiting plate and the second limiting plate are provided with arc-shaped protrusions which are staggered with each other.

5. A graphene-coated heating body-preparing insulating resin continuous coating apparatus according to claim 1, wherein the second resin case is provided with two rectangular grooves.

6. The continuous coating apparatus for preparing insulating resin by using a graphene coated heating body according to claim 1, wherein the sides of the first, second and third porous sliding plates are provided with filter cloths.