CN115123870A

CN115123870A - Active carbon fiber shearing and winding device

Info

Publication number: CN115123870A
Application number: CN202211044060.4A
Authority: CN
Inventors: 陈天烨
Original assignee: Jiangsu Kelite Environmental Protection Technology Co ltd
Current assignee: Jiangsu Kelite Environmental Protection Technology Co ltd
Priority date: 2022-08-30
Filing date: 2022-08-30
Publication date: 2022-09-30
Anticipated expiration: 2042-08-30
Also published as: CN115123870B

Abstract

The invention discloses an active carbon fiber shearing and winding device which comprises a frame body, wherein conveying shafts are rotatably connected on the inner walls of two sides of the frame body, a conveying roller is fixedly connected between the two conveying shafts, a second servo motor is fixedly installed on one outer side wall of the frame body, one end of one conveying shaft penetrates through one outer side wall of the frame body and is fixedly connected with an output shaft of the second servo motor, a plurality of guide assemblies positioned below the conveying roller are arranged between the inner walls of the two sides of the frame body, a fixing plate is fixedly installed on the outer side wall of one end of the frame body, and a hollow pipe rotatably connected with the frame body penetrates through the other outer side wall of the frame body. The invention can automatically complete the winding and cutting of the activated carbon fiber, has consistent winding thickness, does not need manual operation, can automatically push out the wound activated carbon fiber from the winding block, is easy to pack, improves the working efficiency and is convenient to use.

Description

Active carbon fiber shearing and winding device

Technical Field

The invention relates to the technical field of activated carbon fibers, in particular to an activated carbon fiber shearing and winding device.

Background

The activated carbon fiber is activated carbon-containing fiber, and certain carbon-containing fiber (such as phenolic fiber, PAN-based fiber, viscose-based fiber, asphalt-based fiber and the like) is activated at high temperature (different activation temperatures of different activation methods) to generate nanoscale pore diameters on the surface of the carbon-containing fiber and increase the specific surface area, so that the physicochemical characteristics of the carbon-containing fiber are changed.

At present to the activated carbon fiber cloth wind roll with cut off and rely on the manual work to the operation of machine more, waste time and energy, manual operation may lead to simultaneously not uniform around the thickness of rolling up, inconvenient bagging-off of going on after rolling up, work efficiency is low, use very inconvenient, be unfavorable for the industrial production.

Disclosure of Invention

The invention aims to solve the defects in the prior art and provides an active carbon fiber shearing and winding device.

In order to achieve the purpose, the invention adopts the following technical scheme:

the active carbon fiber shearing and winding device comprises a frame body, wherein conveying shafts are rotatably connected on the inner walls of two sides of the frame body, conveying rollers are fixedly connected between the two conveying shafts, a second servo motor is fixedly installed on the outer side wall of the frame body, one end of each conveying shaft is provided with an output shaft which penetrates through the outer side wall of the frame body and is fixedly connected with the second servo motor, a plurality of guide assemblies positioned below the conveying rollers are arranged between the inner walls of the two sides of the frame body, a fixing plate is fixedly installed on the outer side wall of one end of the frame body, a hollow pipe which is rotatably connected with the frame body is arranged on the other outer side wall of the frame body in a penetrating manner, a driving mechanism connected with the hollow pipe is arranged on the frame body, one end of the hollow pipe which is positioned in the frame body is fixedly connected with a hollow fixing block which is connected with the inner part of the hollow pipe, and two hollow winding blocks which are communicated with the inner part of the hollow pipe are arranged on the side wall of the hollow fixing block which is far away from the hollow pipe, the utility model discloses a winding frame, including support body, cavity, connecting plate, cutting mechanism, drive mechanism, connecting plate, cutting mechanism, the support body is provided with the clamping mechanism who is connected with actuating mechanism in the support body, cavity is provided with the offset plate around the below of rolling up the piece, the interior bottom of support body is provided with the trigger mechanism who is located and is connected with the offset plate, cavity is provided with the connecting plate around rolling up between piece and the guide assembly, be provided with the shutdown mechanism who is connected with trigger mechanism on the fixed plate, it is provided with the first pivot of being connected with the rotation to run through on another lateral wall of support body, be provided with the slewing mechanism who is connected with clamping mechanism in the first pivot, the outside of cavity fixed block is provided with the pushing equipment who is connected with slewing mechanism.

Preferably, actuating mechanism includes the first servo motor of fixed mounting on another lateral wall of support body, first servo motor's output shaft fixedly connected with second pivot, the one end fixed mounting that first servo motor was kept away from in the second pivot has the second gear, the hollow tube is located fixed mounting on the outer one end lateral wall of support body and has the first gear of being connected with the meshing of second gear.

Preferably, clamping mechanism includes the electro-magnet of setting in the hollow tube, be provided with the ejector pad in the cavity fixed block, the one end of ejector pad extends to the cavity and winds the book piece, the ejector pad is provided with the magnetic path on being close to a lateral wall of hollow tube, the ejector pad is close to the extension spring that two symmetries set up on a lateral wall of hollow tube, two the other end fixed connection of extension spring is on the inner wall of cavity fixed block, two all run through two extension rods that are provided with symmetric distribution on the lateral wall of cavity book piece, extension rod and the lateral wall of cavity book piece are sliding connection, lie in two in same cavity book piece the extension rod all is located the both sides of ejector pad, the extension rod all overlaps on the one end lateral wall that lies in the cavity book piece and is equipped with the second spring, one of the cavity book piece one of extension rod lies in the outer one end fixed mounting of cavity book piece has outer kicking block, another in the cavity is around rolling up the piece the extension rod is located cavity and is rolled up the outer one end fixed mounting of piece and press from both sides tight piece, be provided with laser emitter on the one side inner wall of support body, the fixed plate is close to the cavity and is provided with the receipt treater on rolling up the lateral wall of piece, receipt treater and laser emitter all are located cavity and are rolled up between piece and the offset, first servo motor and electro-magnet are established ties mutually, receipt treater and laser emitter all are located the circuit of first servo motor and electro-magnet.

Preferably, trigger mechanism includes two telescopic links of bottom in the support body of fixed mounting, two the equal fixed connection of the flexible end of telescopic link is on supporting the board, two all the cover is equipped with first spring on the telescopic link, the interior bottom fixed mounting who supports the board has the trigger tube, be provided with in the trigger tube rather than inner wall sliding connection press down the sliding plug, press down the sliding plug and pass through connecting rod and supporting board fixed connection, the interior bottom of support body is provided with the press switch who is located the trigger tube.

Preferably, shutdown mechanism includes two first cylinders of fixed mounting on the fixed plate lateral wall, push switch and first cylinder electric connection, two the flexible end of first cylinder all runs through the fixed plate and fixed connection on the connecting plate, the connecting plate is close to and is provided with the cutter on the cavity is around rolling up a lateral wall of piece.

Preferably, the rotating mechanism comprises a third gear connected with the first rotating shaft at one end in the frame body through a one-way bearing, the connecting plate is fixedly connected with a rack meshed with the third gear, a contact block is fixedly mounted on the outer side wall of one end of the first rotating shaft outside the frame body, a second conductive block is arranged on the other outer side wall of the frame body, and the second conductive block and the contact block are both located in circuits of the first servo motor and the electromagnet.

Preferably, pushing equipment is including the piece of unloading that is arranged in the cavity fixed block outside, be provided with two second cylinders on another lateral wall of support body, two the flexible end of second cylinder all runs through another lateral wall and fixed connection of support body on the piece of unloading, be provided with first conducting block on another lateral wall of support body, contact piece and first conducting block are arranged in the circuit of second cylinder.

Preferably, the push block is in a 'U' shape.

Preferably, the outer brace is arc-shaped.

Preferably, the fixing plate and the frame body are integrally formed.

The invention has the beneficial effects that:

the invention can automatically complete the winding and cutting of the activated carbon fiber, has consistent winding thickness, does not need manual operation for winding and cutting, saves time, can automatically push out the wound activated carbon fiber from the winding block, is easy to pack, improves the working efficiency, is convenient to use, and is beneficial to industrial production.

Drawings

FIG. 1 is a schematic perspective view of one side of an apparatus for shearing and winding activated carbon fiber according to the present invention;

FIG. 2 is a schematic perspective view of the other side of the cutting and winding device for activated carbon fiber according to the present invention;

FIG. 3 is a schematic perspective view of the hollow winding block according to the present invention;

FIG. 4 is a schematic plan view of the inside of the hollow winding block according to the present invention;

FIG. 5 is an enlarged view of the structure at A in FIG. 4 according to the present invention;

fig. 6 is a schematic plan view of the trigger mechanism of the present invention.

In the figure: the device comprises a frame body 1, a conveying roller 2, a conveying shaft 3, a guide assembly 4, a connecting plate 5, a fixing plate 6, a cutter 7, a first conductive block 8, a first rotating shaft 9, a contact block 10, a first gear 11, a second gear 12, a second rotating shaft 13, a first servo motor 14, a first cylinder 15, a second conductive block 16, a hollow tube 17, a second cylinder 18, a second servo motor 19, a rack 20, a third gear 21, a material unloading block 22, a receiving processor 23, a resisting plate 24, a first spring 25, a telescopic rod 26, a trigger tube 27, a connecting rod 28, a hollow fixing block 29, a hollow winding block 30, a clamping block 31, an outer supporting block 32, a laser emitter 33, an electromagnet 34, a tension spring 35, an extension rod 36, a second spring 37, a pushing block 38, a magnetic block 39, a pressing switch 40 and a pressing sliding plug 41.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments.

Referring to fig. 1-6, an active carbon fiber shearing and winding device comprises a frame body 1, wherein conveying shafts 3 are rotatably connected to inner walls of two sides of the frame body 1, conveying rollers 2 are fixedly connected between the two conveying shafts 3, a second servo motor 19 is fixedly installed on an outer side wall of the frame body 1, one end of one conveying shaft 3 is provided with a guide assembly 4 which penetrates through an outer side wall of the frame body 1 and is fixedly connected with an output shaft of the second servo motor 19, a plurality of guide assemblies 4 which are positioned below the conveying rollers 2 are arranged between the inner walls of two sides of the frame body 1, a fixing plate 6 is fixedly installed on an outer side wall of one end of the frame body 1, the fixing plate 6 and the frame body 1 are integrally formed, a hollow pipe 17 which is rotatably connected with the other outer side wall of the frame body 1 is penetrated through, and a driving mechanism which is connected with the hollow pipe 17 is arranged on the frame body 1;

the driving mechanism comprises a first servo motor 14 fixedly arranged on the other outer side wall of the frame body 1, an output shaft of the first servo motor 14 is fixedly connected with a second rotating shaft 13, one end, far away from the first servo motor 14, of the second rotating shaft 13 is fixedly provided with a second gear 12, and the outer side wall of one end, located outside the frame body 1, of the hollow pipe 17 is fixedly provided with a first gear 11 in meshed connection with the second gear 12;

one end of the hollow tube 17 positioned in the frame body 1 is fixedly connected with a hollow fixed block 29 connected with the interior of the hollow tube, one side wall of the hollow fixed block 29 away from the hollow tube 17 is provided with two hollow winding blocks 30 communicated with the interior of the hollow fixed block, and the frame body 1 is internally provided with a clamping mechanism connected with a driving mechanism;

the clamping mechanism comprises an electromagnet 34 arranged in a hollow pipe 17, a push block 38 is arranged in a hollow fixed block 29, the push block 38 is U-shaped, one end of the push block 38 extends into the hollow winding block 30, a magnetic block 39 is arranged on one side wall of the push block 38 close to the hollow pipe 17, two symmetrically arranged tension springs 35 are fixedly connected on one side wall of the push block 38 close to the hollow pipe 17, the other ends of the two tension springs 35 are fixedly connected on the inner wall of the hollow fixed block 29, two symmetrically distributed extension rods 36 are respectively arranged on the outer side walls of the two hollow winding blocks 30 in a penetrating manner, the extension rods 36 are in sliding connection with the outer side wall of the hollow winding block 30, the two extension rods 36 positioned in the same hollow winding block 30 are respectively positioned on the two sides of the push block 38, a second spring 37 is respectively sleeved on the outer side wall of one end of the extension rod 36 positioned in the hollow winding block 30, an outer support block 32 is fixedly arranged at one end of one extension rod 36 positioned outside the hollow winding block 30, the outer supporting block 32 is arc-shaped, one end of the other extension rod 36 in the hollow winding block 30, which is positioned outside the hollow winding block 30, is fixedly provided with a clamping block 31, the inner wall of one side of the frame body 1 is provided with a laser emitter 33, one side wall of the fixing plate 6, which is close to the hollow winding block 30, is provided with a receiving processor 23, the receiving processor 23 and the laser emitter 33 are both positioned between the hollow winding block 30 and the resisting plate 24, the first servo motor 14 and the electromagnet 34 are connected in series, and the receiving processor 23 and the laser emitter 33 are both positioned in circuits of the first servo motor 14 and the electromagnet 34;

a supporting plate 24 is arranged below the hollow winding block 30, a trigger mechanism connected with the supporting plate 24 is arranged at the inner bottom of the frame body 1, the trigger mechanism comprises two telescopic rods 26 fixedly arranged at the inner bottom of the frame body 1, the telescopic ends of the two telescopic rods 26 are fixedly connected to the supporting plate 24, first springs 25 are sleeved on the two telescopic rods 26, a trigger pipe 27 is fixedly arranged at the inner bottom of the supporting plate 24, a pressing sliding plug 41 connected with the inner wall of the trigger pipe 27 in a sliding manner is arranged in the trigger pipe 27, the pressing sliding plug 41 is fixedly connected with the supporting plate 24 through a connecting rod 28, a pressing switch 40 positioned in the trigger pipe 27 is arranged at the inner bottom of the frame body 1, and a through hole positioned at one side, close to the pressing switch 40, of the pressing sliding plug 41 is formed in the trigger pipe 27 so that the pressing sliding plug 41 can slide;

a connecting plate 5 is arranged between the hollow winding block 30 and the guide assembly 4, a cutting mechanism connected with the trigger mechanism is arranged on the fixing plate 6, the cutting mechanism comprises two first cylinders 15 fixedly mounted on the outer side wall of the fixing plate 6, a press switch 40 is electrically connected with the first cylinders 15, the telescopic ends of the two first cylinders 15 penetrate through the fixing plate 6 and are fixedly connected to the connecting plate 5, and a cutter 7 is arranged on one side wall of the connecting plate 5, which is close to the hollow winding block 30;

a first rotating shaft 9 connected with the frame body 1 in a rotating mode penetrates through the other outer side wall of the frame body 1, a rotating mechanism connected with the clamping mechanism is arranged on the first rotating shaft 9, the rotating mechanism comprises a third gear 21 connected to one end, located in the frame body 1, of the first rotating shaft 9 through a one-way bearing, a rack 20 connected with the third gear 21 in a meshed mode is fixedly connected to the connecting plate 5, a contact block 10 is fixedly installed on the outer side wall of one end, located outside the frame body 1, of the first rotating shaft 9, a second conducting block 16 is arranged on the other outer side wall of the frame body 1, and the second conducting block 16 and the contact block 10 are located in circuits of the first servo motor 14 and the electromagnet 34;

the outer side of the hollow fixing block 29 is provided with a material pushing mechanism connected with the rotating mechanism, the material pushing mechanism comprises a discharging block 22 located on the outer side of the hollow fixing block 29, the other outer side wall of the frame body 1 is provided with two second cylinders 18, the telescopic ends of the two second cylinders 18 penetrate the other outer side wall of the frame body 1 and are fixedly connected to the discharging block 22, the other outer side wall of the frame body 1 is provided with a first conductive block 8, and the contact block 10 and the first conductive block 8 are located in a circuit of the second cylinder 18.

When the invention is used, the conveying roller 2 is provided with the activated carbon fiber cloth, in an initial state, the contact block 10 is contacted with the second conductive block 16, one switch controlled by the contact block 10 and the second conductive block 16 is in a closed state, the second servo motor 19 is started to rotate the conveying roller 2, the activated carbon fiber cloth passes through the two hollow winding blocks 30 through the guide assembly 4, when the activated carbon fiber cloth is positioned above the laser emitter 33, the receiving processor 23 works and enables the other switch controlled by the controller to be closed, the first servo motor 14, the electromagnet 34, the switch and the other switch are connected in series, the electromagnet 34 and the magnetic block 39 are mutually repelled, so that the tension spring 35 is stretched, the push block 38 moves in a direction far away from the hollow pipe 17, the extension rod 36 moves in a direction far away from the axis of the hollow pipe 17 through the mutual matching of the inclined plane of the extension rod 36 and the inclined plane of the push block 38, the two clamping blocks 31 approach to each other to clamp and fix the activated carbon fiber cloth, the two outer supporting blocks 32 are far away from each other, after the outer supporting blocks 32 return to the initial position, the activated carbon fiber cloth is in a loose state and is easy to dismount, the second spring 37 is compressed, the first servo motor 14 works to rotate the second gear 12, the hollow pipe 17 rotates through the arrangement of the first gear 11, and therefore the two hollow winding blocks 30 rotate around the axis of the hollow pipe 17, and the activated carbon fiber cloth is wound;

when the thickness of the activated carbon fiber cloth is gradually increased, the activated carbon fiber cloth wound on the outer side of the hollow winding block 30 is abutted against the abutting plate 24, the telescopic rod 26 is retracted, the first spring 25 is compressed, the abutting plate 24 drives the connecting rod 28 to move, so that the pressing sliding plug 41 moves towards the direction close to the press switch 40, when the winding thickness is constant, the gap between the two hollow winding blocks 30 is in a vertical state, the pressing sliding plug 41 is abutted against the press switch 40, the first air cylinder 15 works, so that the connecting plate 5 moves towards the direction close to the hollow winding block 30 and then returns to the initial position, in the process that the connecting plate 5 drives the cutter 7 and the rack 20 to move towards the direction close to the hollow winding block 30, the cutter 7 cuts off the activated carbon fiber cloth, the rack 20 drives the third gear 21 to rotate, the one-way bearing does not transmit, the first rotating shaft 9 does not rotate, and the connecting plate 5 drives the cutter 7 and the rack 20 to return to the initial position, the second servo motor 19 is closed, the one-way bearing is driven, the first rotating shaft 9 rotates, so that the contact block 10 is separated from the second conductive block 16 firstly, one switch controlled by the contact block 10 and the second conductive block 16 is in an unclosed state, the first servo motor 14 and the electromagnet 34 are not connected with a circuit any more, the elastic force generated by the extension of the tension spring 35 enables the push block 38 to return to the initial position, the elastic force generated by the compression of the second spring 37 enables the outer supporting block 32 and the clamping block 31 to return to the initial position, the activated carbon fiber cloth is not clamped and fixed and is in a loose state, the contact block 10 is contacted with the first conductive block 8 again, the second air cylinder 18 works to enable the discharge block 22 to move in a direction away from the hollow tube 17, the activated carbon fiber cloth wound on the outer side of the hollow winding block 30 is pushed out and bagged, and the elastic force generated by the compression of the first spring 25 enables the abutting plate 24 to return to the initial position;

the push switch 40 is separated from the push sliding plug 41, the laser generated by the laser transmitter 33 is not shielded any more, the receiving processor 23 works to enable another switch controlled by the receiving processor to be in a non-closed state through the controller, the contact block 10 is separated from the first conductive block 8 subsequently, the second air cylinder 18 does not work any more, the discharging block 22 returns to the initial position, the contact block 10 finally returns to the initial position to be in contact with the second conductive block 16, one switch controlled by the contact block 10 and the second conductive block 16 is in a closed state again, and then the second servo motor 19 is continuously started, so that the automatic winding and the automatic cutting of the activated carbon fiber cloth are realized in a reciprocating mode.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be considered to be within the technical scope of the present invention, and the technical solutions and the inventive concepts thereof according to the present invention should be equivalent or changed within the scope of the present invention.

Claims

1. The utility model provides an active carbon fiber cuts around package and puts, includes support body (1), its characterized in that, all rotate on the both sides inner wall of support body (1) and be connected with delivery shaft (3), two fixedly connected with conveying roller (2) between delivery shaft (3), fixedly mounted has second servo motor (19) on one of them lateral wall of support body (1), one of them the one end of delivery shaft (3) sets up a lateral wall that runs through support body (1) and with the output shaft fixed connection of second servo motor (19), be provided with a plurality of direction subassemblies (4) that are located conveying roller (2) below between the both sides inner wall of support body (1), fixedly mounted has fixed plate (6) on the one end lateral wall of support body (1), it is provided with hollow tube (17) rather than the rotation connection to run through on another lateral wall of support body (1), be provided with the actuating mechanism who is connected with hollow tube (17) on support body (1), one end of the hollow tube (17) in the frame body (1) is fixedly connected with a hollow fixed block (29) connected with the inner part of the hollow tube, one side wall of the hollow fixed block (29) far away from the hollow tube (17) is provided with two hollow winding blocks (30) communicated with the inner part of the hollow winding block, a clamping mechanism connected with a driving mechanism is arranged in the frame body (1), a resisting plate (24) is arranged below the hollow winding blocks (30), the inner bottom of the frame body (1) is provided with a triggering mechanism connected with the resisting plate (24), a connecting plate (5) is arranged between the hollow winding blocks (30) and the guide assembly (4), a cutting mechanism connected with the triggering mechanism is arranged on the fixed plate (6), a first rotating shaft (9) connected with the rotating mechanism is arranged on the other outer side wall of the frame body (1) in a penetrating manner, a rotating mechanism connected with the clamping mechanism is arranged on the first rotating shaft (9), and a material pushing mechanism connected with the rotating mechanism is arranged on the outer side of the hollow fixing block (29).

2. The active carbon fiber cutting and winding device according to claim 1, wherein the driving mechanism comprises a first servo motor (14) fixedly mounted on another outer side wall of the frame body (1), an output shaft of the first servo motor (14) is fixedly connected with a second rotating shaft (13), a second gear (12) is fixedly mounted at one end, away from the first servo motor (14), of the second rotating shaft (13), and a first gear (11) meshed with the second gear (12) is fixedly mounted on one end outer side wall, located outside the frame body (1), of the hollow tube (17).

3. The active carbon fiber shearing and winding device as claimed in claim 2, wherein the clamping mechanism comprises an electromagnet (34) arranged in a hollow tube (17), a push block (38) is arranged in the hollow fixed block (29), one end of the push block (38) extends into the hollow winding block (30), a magnetic block (39) is arranged on one side wall of the push block (38) close to the hollow tube (17), two symmetrically arranged tension springs (35) are fixedly connected to one side wall of the push block (38) close to the hollow tube (17), the other ends of the two tension springs (35) are fixedly connected to the inner wall of the hollow fixed block (29), two symmetrically distributed extension rods (36) are arranged on the outer side wall of the hollow winding block (30) in a penetrating manner, and the extension rods (36) are connected with the outer side wall of the hollow winding block (30) in a sliding manner, two extension rods (36) positioned in the same hollow winding block (30) are positioned on two sides of a push block (38), the extension rods (36) positioned in the hollow winding block (30) are sleeved with second springs (37) on the outer side wall of one end, the extension rods (36) in the hollow winding block (30) are fixedly installed at one end, outside the hollow winding block (30), of one end, positioned in the hollow winding block (30), of each extension rod (36), one end, outside the hollow winding block (30), of each extension rod (36) is fixedly installed with a clamping block (31), a laser transmitter (33) is arranged on the inner wall of one side of the frame body (1), a receiving processor (23) is arranged on one side wall, close to the hollow winding block (30), of the fixing plate (6), the receiving processor (23) and the laser transmitter (33) are positioned between the hollow winding block (30) and the abutting plate (24), the first servo motor (14) and the electromagnet (34) are connected in series, and the receiving processor (23) and the laser transmitter (33) are both located in a circuit of the first servo motor (14) and the electromagnet (34).

4. The active carbon fiber shearing and winding device as claimed in claim 1, wherein the triggering mechanism comprises two telescopic rods (26) fixedly mounted at the inner bottom of the frame body (1), the telescopic ends of the two telescopic rods (26) are fixedly connected to the supporting plate (24), the two telescopic rods (26) are sleeved with first springs (25), the inner bottom of the supporting plate (24) is fixedly provided with a triggering pipe (27), a pressing sliding plug (41) slidably connected with the inner wall of the triggering pipe (27) is arranged in the triggering pipe (27), the pressing sliding plug (41) is fixedly connected with the supporting plate (24) through a connecting rod (28), and the inner bottom of the frame body (1) is provided with a pressing switch (40) located in the triggering pipe (27).

5. The cutting and winding device for the activated carbon fiber as claimed in claim 4, wherein the cutting mechanism comprises two first air cylinders (15) fixedly mounted on the outer side wall of the fixing plate (6), the push switch (40) is electrically connected with the first air cylinders (15), the telescopic ends of the two first air cylinders (15) penetrate through the fixing plate (6) and are fixedly connected to the connecting plate (5), and a cutter (7) is arranged on one side wall of the connecting plate (5) close to the hollow winding block (30).

6. The active carbon fiber cutting and winding device according to claim 3, wherein the rotating mechanism comprises a third gear (21) connected to one end of the first rotating shaft (9) in the frame body (1) through a one-way bearing, a rack (20) meshed with the third gear (21) is fixedly connected to the connecting plate (5), a contact block (10) is fixedly mounted on the outer side wall of one end of the first rotating shaft (9) outside the frame body (1), a second conductive block (16) is arranged on the other outer side wall of the frame body (1), and the second conductive block (16) and the contact block (10) are both located in the circuits of the first servo motor (14) and the electromagnet (34).

7. The active carbon fiber cutting and winding device according to claim 6, wherein the material pushing mechanism comprises a material discharging block (22) located outside the hollow fixing block (29), the other outer side wall of the frame body (1) is provided with two second cylinders (18), the telescopic ends of the two second cylinders (18) penetrate through the other outer side wall of the frame body (1) and are fixedly connected to the material discharging block (22), the other outer side wall of the frame body (1) is provided with a first conductive block (8), and the contact block (10) and the first conductive block (8) are located in the circuit of the second cylinders (18).

8. The activated carbon fiber shearing and winding device as recited in claim 3, wherein said pushing block (38) is "U" shaped.

9. An activated carbon fiber shear winder as claimed in claim 3, wherein said outer support block (32) is arc-shaped.

10. The cutting and winding device for activated carbon fibers according to claim 1, wherein the fixing plate (6) and the frame body (1) are integrally formed.