CN114046642B

CN114046642B - Drying device for processing insulating paper

Info

Publication number: CN114046642B
Application number: CN202210014152.1A
Authority: CN
Inventors: 王婼楠; 吴亚琪; 王文波; 全俊成; 伍秘; 尚建勋; 马玉梅
Original assignee: Jiangsu Junyuan New Material Co ltd
Current assignee: Jiangsu Meiyuan New Material Co ltd
Priority date: 2022-01-07
Filing date: 2022-01-07
Publication date: 2022-03-22
Anticipated expiration: 2042-01-07
Also published as: CN114046642A

Abstract

The invention provides a drying device for processing insulating paper, which relates to the technical field of insulating paper drying and comprises the following components: the drying device comprises a main body frame, a first drying structure, an auxiliary part, a second drying part and a wind drying part; the main body frame is placed on the ground, a paper guide roller is connected to the main body frame in a rotating mode, and insulating paper is conveyed to the paper guide roller. Because the roller and the connecting pipe, be connected for rotating between intake pipe and the blast pipe, so two rollers all are the rotating state at the in-process that the insulating paper removed, it is simply said that if the position temperature that the roller and insulating paper contacted does not change the roller and insulating paper contact can reduce, and after the rotation transform through the roller and the contact position of insulating paper like this, just can guarantee that the temperature when roller and insulating paper contacted is balanced, it can realize the wind-force drying to have solved the rotation through the impeller, and can realize wind-force through the cooperation of impeller and pedestal and block the water conservancy diversion, and the hot gas after the water conservancy diversion can be more with the problem of paper contact.

Description

Drying device for processing insulating paper

Technical Field

The invention relates to the technical field of insulating paper drying, in particular to a drying device for processing insulating paper.

Background

In the process of processing the insulating paper, the insulating paper needs to be quickly dried, and if the drying effect of the insulating paper is not enough, the subsequent insulating effect is influenced.

Based on the above, the existing insulating paper drying device also has the following defects: firstly, the existing device usually performs baking drying on the insulating paper through a heating wire when drying the insulating paper, but the position of the heating wire is fixed, so that the position of the heat generated by the device corresponding to the paper is also fixed, and the baking efficiency is low; further, although the conventional apparatus can dry the paper sheet by pressing, it cannot sufficiently combine the press drying of the paper sheet with the water absorption drying, the heat drying, and the drainage of the water absorption structure.

Disclosure of Invention

In view of the above, the present invention provides a drying device for processing insulating paper, which comprises

The paper drying device comprises a first drying structure, a second drying part and a wind-force drying part, wherein a roller in the first drying part can realize extrusion drainage of paper, hot gas circulating in the roller can realize ironing drying of the paper, and the roller and a roller water absorption sleeve are matched to realize one-time extrusion drainage and increase of the contact area of the paper and the roller;

the drying by wind power can be realized by the rotation of the impeller, the wind power blocking diversion can be realized by the matching of the impeller and the base body, and more hot gas after diversion can be contacted with paper, so that the drying effect is improved;

can collect the moisture of extruding in the cover that absorbs water through the box body, and the box body can prevent moisture evaporation and paper contact once more for semi-enclosed construction to the box body bottom can discharge moisture fast for the slope form, has reduced moisture evaporation probability.

The invention provides a drying device for processing insulating paper, which specifically comprises: the drying device comprises a main body frame, a first drying structure, an auxiliary part, a second drying part and a wind drying part; the main body frame is placed on the ground, a paper guide roller is rotatably connected to the main body frame, and insulating paper is conveyed to the paper guide roller; the main body frame is rotatably connected with a winding roller; the first drying structure consists of a connecting pipe, an air inlet pipe, an air outlet pipe and a roller, the connecting pipe is arranged on the main body frame, and the connecting pipe is of a concave tubular structure; the air inlet pipe is connected to the main body frame, and the exhaust pipe is also connected to the main body frame;

the two rollers are arranged, and the head ends of the two rollers are rotatably connected to the connecting pipe; the tail end of the upper roller is rotatably connected with the air inlet pipe, and the tail end of the lower roller is rotatably connected with the exhaust pipe; the roller is of a hollow tubular structure, and is respectively communicated with the connecting pipe, the air inlet pipe and the exhaust pipe, and the air inlet pipe and the exhaust pipe are both connected with an external hot air supply pump; the two rollers are respectively contacted with the top end surface and the bottom end surface of the insulating paper; the auxiliary part consists of two rolling shafts, a water suction sleeve, a box body, an auxiliary plate and a water drainage pipe, and the two rolling shafts are rotatably connected to the main body frame; the second drying part consists of a seat body and a heating pipe, and the seat body is fixedly connected to the main body frame through bolts;

the wind power drying part is composed of a rotating shaft, an impeller and a servo motor, and the rotating shaft is rotatably connected to the main body frame.

Optionally, four paper guide rollers are arranged, and the four paper guide rollers are distributed in a "Z" shape, and the paper guide rollers distributed in the "Z" shape jointly form a path extending structure of the insulating paper.

Optionally, a water absorbing sleeve is adhered to each roller, and the water absorbing sleeve is in elastic contact with the bottom end face of the insulating paper.

Optionally, the two rollers are respectively positioned at the left side and the right side of the upper roller, the distance between the two rollers and the roller is 0.4cm, and the thickness of the insulating paper is 0.6 cm.

Optionally, the insulating paper is in contact with the position above the outer wall of the water absorption sleeve, the insulating paper is in contact with the position below the outer wall of the upper roller, and the angle of the contact surface of the insulating paper and the outer wall of the upper roller is 70 degrees.

Optionally, two box bodies are arranged, the two box bodies are fixedly connected to the main body frame through bolts, and the two box bodies are respectively located below the two rollers; each box body is welded with an auxiliary plate, the top end surfaces of the two auxiliary plates are respectively abutted against and contacted with the two water absorption sleeves, and the head ends of the two auxiliary plates are of arc structures; the box body is a semi-closed structure, a drain pipe is connected to the box body, and the bottom end face of the box body is of an inclined structure.

Optionally, heating pipes are mounted in the seat body in a linear array manner, the heating pipes are of cylindrical tubular structures, and the heating pipes are located 2cm away from the two rightmost paper guide rollers; the seat body is of a concave structure, and the left end face of the inner wall of the seat body is polished.

Optionally, the servo motor is fixedly connected to the main body frame through a bolt, and a rotating shaft of the servo motor is connected with the rotating shaft; the rotating shaft is provided with impellers in a linear array, the impellers are positioned in the gap between the two paper guide rollers on the right side, and the impellers are positioned at the position 15cm on the left side of the seat body.

Advantageous effects

Firstly, the heat drying of the insulation paper can be realized through the arrangement of the first drying structure, because a hot gas pump injects hot gas into an upper roller through a gas inlet pipe, then the hot gas enters a lower roller through a connecting pipe, and finally the hot gas is discharged through an exhaust pipe, in the process, the upper roller and the lower roller are both in a high-heat state under the heating of the hot gas, and the two rollers are respectively contacted with the top end surface and the bottom end surface of the insulation paper, so that the heating drying of the insulation paper can be realized;

according to the application, when the two rollers are used for heating and drying, the distance between the two rollers is 0.4cm, and the thickness of the insulating paper is 0.6cm, so that the extrusion drainage of the insulating paper can be realized through the two rollers;

secondly, beneficial incremental increase can be realized through the matching arrangement of the auxiliary part and the first drying structure, and the first advantage is that the two rolling shafts are respectively positioned at the left side and the right side of a roller above the first drying structure, the distance between the two rolling shafts and the roller is 0.4cm, and the thickness of the insulating paper is 0.6cm, so that on one hand, the insulating paper can be extruded and drained through the rolling shafts and the roller, on the other hand, the friction force between the insulating paper and the water absorption sleeve can be enhanced under the extrusion of the rolling shafts and the roller, the water absorption sleeve can be ensured to normally rotate, and finally, the auxiliary plate can be ensured to realize the circular extrusion of water on the water absorption sleeve;

the second advantage is that because the insulating paper contacts with the upper positions of the outer walls of the two water absorption sleeves, the insulating paper contacts with the lower position of the outer wall of the upper roller, and the angle of the contact surface of the insulating paper and the outer wall of the upper roller is 70 degrees, the contact area of the insulating paper and the outer wall of the upper roller can be expanded through the limiting of the two rolling shafts, and further the drying efficiency of the insulating paper can be improved;

the third benefit is, because the roller is connected with the rotation between connecting pipe, intake pipe and the blast pipe, so two rollers all are the rotating state at the in-process that the insulating paper removed, thereby just also guaranteed the heating efficiency of insulating paper, it is simply said that if the position temperature that roller and insulating paper contacted does not change in the contact position of roller and insulating paper can reduce, and after the contact position through the rotation transform of roller and insulating paper like this, just can guarantee that the temperature when roller and insulating paper contacted is balanced.

This application passes through the setting of box body, at first can collect the moisture that the accessory plate was extruded through the box body, and because the box body of this application is half closed column structure, and be connected with the drain pipe on the box body, and the box body bottom face is the slope column structure, thereby half closed column structure's box body can reduce the evaporation of water, the vapor contacts with the insulating paper once more after having reduced the evaporation, lead to the increase of insulating paper water content once more, and the bottom face can conveniently collect the quick discharge of moisture for the box body of slope column structure, that is to say moisture discharges fast just also has reduced the probability that the interior moisture of box was evaporated.

According to the application, firstly, the wind power drying of the insulating paper can be realized through the rotation of the impeller in the second drying part;

secondly, the impeller is positioned at the gap between the two paper guide rollers on the right side, and the four paper guide rollers are distributed in a Z shape, so that the utilization rate of wind power generated by the impeller is increased;

thirdly, because the impeller is positioned at the position 15cm on the left side of the seat body, when the servo motor drives the impeller to rotate, wind power generated by the impeller can be shielded by the seat body, so that the wind power generated by the impeller can be prevented from leaking, and the shielded wind power can rotate and flow out along the inner wall of the seat body in an L shape, at the moment, the contact area between the outflow gas and the insulating paper can be expanded, namely, the airflow can also be in contact with the insulating paper above and below, so that the drying efficiency of the insulating paper is improved, namely, the contact area between the airflow and the insulating paper in the rotating and flowing-out process is wider;

finally, because the pedestal is the concave structure, and pedestal inner wall left end face is through polishing treatment, so that namely, can turn red when the heating pipe produces heat, contain thermal light beam accessible pedestal refraction to insulating paper after the heating pipe turns red so to improve insulating paper's heating quality once more.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings of the embodiments will be briefly described below.

The drawings in the following description relate to some embodiments of the invention only and are not intended to limit the invention.

In the drawings:

fig. 1 shows a schematic axial view of a drying apparatus according to an embodiment of the invention.

FIG. 2 shows a schematic axial view in another direction of FIG. 1, according to an embodiment of the invention.

FIG. 3 shows a schematic front view of a body frame and wind-up roll removed in accordance with an embodiment of the present invention.

Fig. 4 shows an enlarged schematic view at a of fig. 3 according to an embodiment of the invention.

FIG. 5 shows a schematic axial view of FIG. 3, in accordance with an embodiment of the present invention.

Fig. 6 shows an enlarged axial view of the cartridge and the auxiliary plate, taken transversely thereto, according to an embodiment of the invention.

Fig. 7 shows an enlarged schematic view at B of fig. 6 according to an embodiment of the present invention.

Fig. 8 shows a schematic axial view of a cartridge and an auxiliary plate according to an embodiment of the invention, cut longitudinally.

Fig. 9 shows an enlarged schematic view at C of fig. 8 according to an embodiment of the present invention.

FIG. 10 shows an isometric view of a body frame and wind-up roll removed in accordance with an embodiment of the present invention.

List of reference numerals

1. A main body frame; 101. paper guide rollers; 2. insulating paper; 3. a first drying configuration; 301. a connecting pipe; 302. an air inlet pipe; 303. an exhaust pipe; 304. a roller; 4. an auxiliary part; 401. a roller; 402. a water absorption sleeve; 403. a box body; 404. an auxiliary plate; 405. a drain pipe; 5. a second drying section; 501. a base body; 502. heating a tube; 6. a wind power drying part; 601. a rotating shaft; 602. an impeller; 603. a servo motor.

Detailed Description

In order to make the objects, aspects and advantages of the embodiments of the present invention more apparent, the embodiments of the present invention will be described in detail with reference to the accompanying drawings. Unless otherwise indicated, terms used herein have the ordinary meaning in the art. Like reference symbols in the various drawings indicate like elements.

Example (b): please refer to fig. 1 to 10:

the invention provides a drying device for processing insulating paper, which comprises: a main body frame 1, a first drying structure 3, an auxiliary part 4, a second drying part 5 and a wind drying part 6;

the main body frame 1 is placed on the ground, a paper guide roller 101 is rotatably connected to the main body frame 1, and the insulation paper 2 is conveyed on the paper guide roller 101; a wind-up roll is rotatably connected on the main body frame 1;

the first drying structure 3 is composed of a connecting pipe 301, an air inlet pipe 302, an air outlet pipe 303 and a roller 304, wherein the connecting pipe 301 is installed on the main body frame 1, and the connecting pipe 301 is a concave tubular structure;

the auxiliary part 4 consists of two rolling shafts 401, a water absorption sleeve 402, a box body 403, an auxiliary plate 404 and a water drainage pipe 405, and the two rolling shafts 401 are rotatably connected to the main body frame 1;

the second drying part 5 is composed of a seat body 501 and a heating pipe 502, and the seat body 501 is fixedly connected to the main body frame 1 through bolts;

the pneumatic drying part 6 is composed of a rotating shaft 601, an impeller 602 and a servo motor 603, and the rotating shaft 601 is rotatably connected to the main body frame 1.

Further, as shown in fig. 3, four guide rollers 101 are provided in total, and the four guide rollers 101 are distributed in a "Z" shape, and the guide rollers 101 distributed in the "Z" shape jointly constitute a path extension structure of the insulating paper 2, so that the path of the insulating paper 2 in the main body frame 1 can be extended, that is, the insulating paper 2 can be dried for a longer time.

Further, as shown in fig. 3 and 4, an intake pipe 302 is connected to the main body frame 1, and an exhaust pipe 303 is also connected to the main body frame 1;

the number of the rollers 304 is two, and the head ends of the two rollers 304 are rotatably connected to the connecting pipe 301; the tail end of the upper roller 304 is rotatably connected with the air inlet pipe 302, and the tail end of the lower roller 304 is rotatably connected with the air outlet pipe 303; the roller 304 is of a hollow tubular structure, the roller 304 is respectively communicated with the connecting pipe 301, the air inlet pipe 302 and the exhaust pipe 303, and the air inlet pipe 302 and the exhaust pipe 303 are both connected with an external hot air supply pump; the two rollers 304 are respectively contacted with the top end face and the bottom end face of the insulating paper 2, so that hot air flows into the roller 304 above through the air inlet pipe 302, then enters the roller 304 below through the connecting pipe 301, then enters the external hot air supply pump through the exhaust pipe 303 to be heated, finally, the heating of the two rollers 304 can be realized through the circulation of the hot air flows, and then the heating and drying of the paper can be realized.

In addition, as shown in fig. 4, a water absorbing sleeve 402 is adhered to each roller 401, and the water absorbing sleeve 402 is in elastic contact with the bottom end surface of the insulating paper 2, so that the water on the insulating paper 2 can be absorbed through the water absorbing sleeve 402, and the drying efficiency of the insulating paper 2 is improved.

In addition, as shown in fig. 4, two rollers 401 are respectively positioned at the left and right sides of the upper roller 304, the distance between the two rollers 401 and the roller 304 is 0.4cm, and the thickness of the insulation paper 2 is 0.6cm, so that the squeezing drainage of the insulation paper 2 can be realized by the rollers 401 and the roller 304.

In addition, as shown in fig. 4, the insulating paper 2 contacts with the upper position of the outer wall of the water absorption sleeve 402, the insulating paper 2 contacts with the lower position of the outer wall of the upper roller 304, and the angle of the contact surface of the insulating paper 2 and the outer wall of the upper roller 304 is 70 degrees, so that the contact area of the insulating paper 2 and the outer wall of the upper roller 304 can be expanded through the limit of the two rollers 401, and the drying efficiency of the insulating paper 2 can be improved.

In addition, as shown in fig. 4, two boxes 403 are provided, and both the two boxes 403 are fixedly connected to the main body frame 1 through bolts, and the two boxes 403 are respectively located below the two rollers 401; all welded an accessory plate 404 on every box 403, and the top terminal surface of two accessory plates 404 supports tight contact with two water absorption cover 402 respectively, and the head end of two accessory plates 404 is the arc structure, so roller 401 and water absorption cover 402 can rotate under the drive of insulating paper 2, just can extrude the moisture on the water absorption cover 402 through accessory plate 404 when roller 401 and water absorption cover 402 rotate, and the moisture that extrudes can flow into box 403 along accessory plate 404 and collect.

In addition, as shown in fig. 6, fig. 7, fig. 8 and fig. 9, the box 403 is a semi-closed structure, the drainage pipe 405 is connected to the box 403, and the bottom end surface of the box 403 is an inclined structure, so that the evaporation of water in the box 403 with the semi-closed structure can be reduced, and the box 403 with the inclined structure can be used for facilitating the rapid drainage of collected water.

In addition, as shown in fig. 3, the heating pipes 502 are installed in the seat body 501 in a linear array, the heating pipes 502 are in a cylindrical tubular structure, and the heating pipes 502 are located at the positions 2cm away from the right sides of the two rightmost paper guide rollers 101, so that the insulating paper 2 can be dried quickly by the heat emitted from the heating pipes 502.

In addition, as shown in fig. 3, the seat body 501 is of a concave structure, and the left end surface of the inner wall of the seat body 501 is polished, so that the light beam containing heat generated by the heating pipe 502 can be refracted onto the insulating paper 2 through the seat body 501, thereby improving the heating quality of the insulating paper 2.

In addition, as shown in fig. 3, the servo motor 603 is fixedly connected to the main body frame 1 by bolts, and a rotating shaft of the servo motor 603 is connected to the rotating shaft 601; install impeller 602 on the pivot 601 and be linear array form, and impeller 602 is located the clearance department of two paper guide rolls 101 on the right side, and impeller 602 is located the 15cm department on the left side of pedestal 501, thereby on the one hand when servo motor 603 rotates, can realize the rapid draing of insulating paper 2 through the wind-force that impeller 602 produced, on the other hand, when servo motor 603 drives impeller 602 and rotates, the wind-force that impeller 602 produced can be sheltered from by pedestal 501, and the wind-force after sheltering from can rotate the outflow along pedestal 501 inner wall, the expanded outflow gas and the area of contact of insulating paper 2 this moment, and then the drying efficiency of insulating paper 2 has been improved.

The specific use mode and function of the embodiment are as follows:

when the winding device is used, the head end of the insulating paper 2 is connected with the winding roller, and then the winding roller is rotated to realize the moving winding of the insulating paper 2;

when the insulation paper 2 passes through the gap between the two rollers 304, hot gas is injected into the upper roller 304 through the air inlet pipe 302 by the hot gas pump, then enters the lower roller 304 through the connecting pipe 301, and finally is discharged through the exhaust pipe 303, the upper roller 304 and the lower roller 304 are both in a high-heat state under the heating of the hot gas in the process, and the two rollers 304 are respectively contacted with the top end surface and the bottom end surface of the insulation paper 2, so that the insulation paper 2 can be heated and dried;

before that, the insulating paper 2 is firstly in elastic contact with the water absorption sleeve 402 on the left side, part of water on the insulating paper 2 can be absorbed by the water absorption sleeve 402, and because the two rolling shafts 401 are respectively positioned on the left side and the right side of the roller 304 above, the distance between the two rolling shafts 401 and the roller 304 is 0.4cm, and the thickness of the insulating paper 2 is 0.6cm, on one hand, the insulating paper 2 can be extruded and drained by the rolling shafts 401 and the roller 304, on the other hand, the friction force between the insulating paper 2 and the water absorption sleeve 402 can be enhanced under the extrusion of the rolling shafts 401 and the roller 304, and further, the water absorption sleeve 402 can normally rotate;

in the process of heating through the roller 304, because the insulating paper 2 is in contact with the upper position of the outer wall of the water absorption sleeve 402, the insulating paper 2 is in contact with the lower position of the outer wall of the upper roller 304, and the angle of the contact surface of the insulating paper 2 and the outer wall of the upper roller 304 is 70 degrees, the contact area of the insulating paper 2 and the outer wall of the upper roller 304 can be expanded through the limiting of the two rollers 401, and the drying efficiency of the insulating paper 2 can be improved;

the water absorbing sleeve 402 rotates under the action of friction force of the insulating paper 2, and when the water absorbing sleeve 402 rotates, the auxiliary plate 404 sequentially extrudes water in the water absorbing sleeve 402, the extruded water flows into the box body 403 and is discharged through the drain pipe 405, in the process, the box body 403 is of a semi-closed structure, the drain pipe 405 is connected to the box body 403, the bottom end face of the box body 403 is of an inclined structure, so that the water evaporation of the box body 403 of the semi-closed structure can be reduced, and the box body 403 with the inclined structure at the bottom end face can be used for conveniently and quickly discharging collected water;

when servo motor 603 rotates, the wind-force that insulating paper 2 can be realized to the wind-force that impeller 602 produced is dry, and because impeller 602 is located the 15cm department in the left side of pedestal 501, so when servo motor 603 drives impeller 602 and rotates the wind-force that impeller 602 produced can be sheltered from by pedestal 501, and the wind-force after sheltering from can rotate along the pedestal 501 inner wall and flow out, the expanded area of contact of outflow gas and insulating paper 2 this moment, and then improved insulating paper 2's drying efficiency, that is to say the air current is wider with insulating paper 2's contact surface at the in-process that rotates the outflow.

Finally, it should be noted that, when describing the positions of the components and the matching relationship therebetween, the present invention is usually illustrated by one/a pair of components, however, it should be understood by those skilled in the art that such positions, matching relationship, etc. are also applicable to other/other pairs of components.

The above description is intended to be illustrative of the present invention and not to limit the scope of the invention, which is defined by the claims appended hereto.

Claims

1. A drying device for processing insulating paper is characterized by comprising: the drying device comprises a main body frame (1), a first drying structure (3), an auxiliary part (4), a second drying part (5) and a wind drying part (6);

the main body frame (1) is placed on the ground, a paper guide roller (101) is connected to the main body frame (1) in a rotating mode, and insulating paper (2) is conveyed to the paper guide roller (101); a wind-up roll is rotatably connected to the main body frame (1);

the first drying structure (3) consists of a connecting pipe (301), an air inlet pipe (302), an air outlet pipe (303) and a roller (304), the connecting pipe (301) is installed on the main body frame (1), and the connecting pipe (301) is of a concave tubular structure; the air inlet pipe (302) is connected to the main body frame (1), and the exhaust pipe (303) is also connected to the main body frame (1);

the number of the rollers (304) is two, and the head ends of the two rollers (304) are rotatably connected to the connecting pipe (301); the tail end of the upper roller (304) is rotatably connected with the air inlet pipe (302), and the tail end of the lower roller (304) is rotatably connected with the air outlet pipe (303); the roller (304) is of a hollow tubular structure, the roller (304) is respectively communicated with the connecting pipe (301), the air inlet pipe (302) and the exhaust pipe (303), and the air inlet pipe (302) and the exhaust pipe (303) are both connected with an external hot air supply pump; the two rollers (304) are respectively contacted with the top end surface and the bottom end surface of the insulating paper (2);

the auxiliary part (4) consists of two rolling shafts (401), a water absorption sleeve (402), a box body (403), an auxiliary plate (404) and a water drainage pipe (405), and the two rolling shafts (401) are rotatably connected to the main body frame (1);

the insulating paper (2) is in contact with the upper position of the outer wall of the water absorption sleeve (402), the insulating paper (2) is in contact with the lower position of the outer wall of the upper roller (304), and the angle of the contact surface of the insulating paper (2) and the outer wall of the upper roller (304) is 70 degrees;

the two box bodies (403) are arranged, the two box bodies (403) are fixedly connected to the main body frame (1) through bolts, and the two box bodies (403) are respectively positioned below the two rolling shafts (401); each box body (403) is welded with an auxiliary plate (404), the top end surfaces of the two auxiliary plates (404) are respectively and tightly contacted with the two water absorption sleeves (402), and the head ends of the two auxiliary plates (404) are of arc structures;

the second drying part (5) consists of a seat body (501) and a heating pipe (502), and the seat body (501) is fixedly connected to the main body frame (1) through bolts;

the wind power drying part (6) is composed of a rotating shaft (601), an impeller (602) and a servo motor (603), and the rotating shaft (601) is rotatably connected to the main body frame (1).

2. A drying apparatus for processing insulating paper as set forth in claim 1, wherein: the paper guide rollers (101) are four in number, the four paper guide rollers (101) are distributed in a Z shape, and the paper guide rollers (101) distributed in the Z shape jointly form a path extending structure of the insulating paper (2).

3. A drying apparatus for processing insulating paper as set forth in claim 1, wherein: each rolling shaft (401) is adhered with a water absorption sleeve (402), and the water absorption sleeve (402) is in elastic contact with the bottom end face of the insulating paper (2).

4. A drying apparatus for processing insulating paper as set forth in claim 1, wherein: the two rolling shafts (401) are respectively positioned at the left side and the right side of the upper roller (304), the distance between the two rolling shafts (401) and the roller (304) is 0.4cm, and the thickness of the insulating paper (2) is 0.6 cm.

5. A drying apparatus for processing insulating paper as set forth in claim 1, wherein: the box body (403) is of a semi-closed structure, the box body (403) is connected with a drain pipe (405), and the bottom end face of the box body (403) is of an inclined structure.

6. A drying apparatus for processing insulating paper as set forth in claim 1, wherein: heating pipes (502) are installed in the base body (501) in a linear array mode, the heating pipes (502) are of cylindrical tubular structures, and the heating pipes (502) are located at the positions, 2cm away from the right side, of the two paper guide rollers (101) on the rightmost side.

7. A drying apparatus for processing insulating paper as set forth in claim 1, wherein: the seat body (501) is of a concave structure, and the left end face of the inner wall of the seat body (501) is polished.

8. A drying apparatus for processing insulating paper as set forth in claim 1, wherein: the servo motor (603) is fixedly connected to the main body frame (1) through a bolt, and a rotating shaft of the servo motor (603) is connected with the rotating shaft (601); impellers (602) are mounted on the rotating shaft (601) in a linear array, the impellers (602) are positioned in the gap between the two paper guide rollers (101) on the right side, and the impellers (602) are positioned 15cm on the left side of the seat body (501).