CN115874342A

CN115874342A - Weaving method of multi-thread carbon fiber cloth

Info

Publication number: CN115874342A
Application number: CN202310165093.2A
Authority: CN
Inventors: 杨滢; 季铖; 吕威
Original assignee: Wuxi Dingqi New Material Technology Co ltd
Current assignee: Wuxi Dingqi New Material Technology Co ltd
Priority date: 2023-02-27
Filing date: 2023-02-27
Publication date: 2023-03-31

Abstract

The invention discloses a weaving method of a multi-thread carbon fiber cloth, which belongs to the technical field of textile technology.A frame is provided with a dust removing mechanism, and an electrostatic eliminating component on the dust removing mechanism is used for removing static electricity on carbon fiber warps and removing impurities such as dust, broken filaments and the like adhered on the carbon fiber warps due to electrostatic adsorption; dust removal component on the dust removal mechanism is arranged in adsorbing and impurity such as dust, wool in the filtered air, adsorbs because of dust and the wool impurity of wandering away in the air behind the electrostatic elimination, utilizes the stripper to collect simultaneously, has reduced dust and wool impurity in the air, has improved carbon cloth's weaving quality, avoids influencing carbon cloth's subsequent processing.

Description

Weaving method of multi-thread carbon fiber cloth

Technical Field

The invention relates to the technical field of textile technology, in particular to a weaving method of multi-thread carbon fiber cloth.

Background

The carbon fiber cloth is also called carbon fiber cloth, carbon fiber woven cloth, carbon fiber prepreg cloth, carbon fiber reinforced cloth, carbon fiber fabric, carbon fiber tape, carbon fiber sheet and the like. With the continuous development of the carbon fiber cloth industry, more and more industries and enterprises use the carbon fiber cloth, the carbon fiber cloth not only has the inherent characteristics of the carbon material, but also has the spinning limiting soft machinability, and is an important material in the aspects of national defense, military industry and civil use.

Carbon cloth is weaving the in-process, and carbon fiber line friction can produce the loss on the material roller, leads to carbon fiber line can produce adhesion such as broken filament on carbon fiber line surface, and the static that carbon fiber line produced when the friction simultaneously causes impurity in dust and the air can the adhesion on carbon fiber line surface, influences carbon cloth's weaving, makes the carbon cloth surface adhesion debris that weaves the acquisition many simultaneously, influences subsequent processing, just can carry out process on next step after needing clearance many times.

Disclosure of Invention

Aiming at the defects in the prior art, the invention aims to provide a weaving method of a multi-thread carbon fiber cloth, which solves the following technical problems: static electricity generated by the carbon fiber wire during friction causes dust and impurities in air to adhere to the surface of the carbon fiber wire to influence subsequent processing.

The purpose of the invention can be realized by the following technical scheme:

a weaving method of multi-thread carbon fiber cloth comprises the following steps:

the method comprises the following steps: a row of carbon fiber warps are led out from a material roller of the carbon fiber cloth weaving machine and then wound around a guide roller, each carbon fiber warp is staggered and divided into two halves, one half of the carbon fiber warps penetrate through a branching ring of a first branching assembly, the other half of the carbon fiber warps penetrate through a branching ring of a second branching assembly, and the carbon fiber warps sequentially penetrate through gaps of a top line frame;

step two: when carbon fiber warps pass through the lower part of the dust removing mechanism, static electricity on each carbon fiber warp is eliminated through the static electricity eliminator, dust and wool impurities adhered to the carbon fiber warps due to electrostatic adsorption are removed, the fan extracts air at the bottom of the fixing frame through the dust hood, the air with the dust and the wool is filtered through the filter screen on the exhaust hood, the air is discharged from the filter screen, the impurities such as the dust and the wool fall onto the discharging plate at the bottom of the exhaust hood, and the discharging plate is driven to rotate through the piston rod of the discharging cylinder so as to discharge the dust and the wool impurities stored in the exhaust hood;

step three: start elevator motor, the elevator motor output shaft drives drive gear and rotates, drive gear drives first lifting rack and second lifting rack relative motion simultaneously, and then drive the carbon fiber warp of first wire-separating subassembly and the carbon fiber warp of second wire-separating subassembly crisscross from top to bottom respectively, simultaneously introduce weft through the rapier in the shed that the frame front end formed in the top line, start sliding motor, the sliding motor output shaft drives the slip lead screw and rotates, the slip lead screw rotates and drives top line frame reciprocating motion through the sliding block, weft is pressed with the warp to the weft that the top line pole of repeatedly movable's top line frame will be introduced, accomplish carbon cloth's weaving operation.

As a further scheme of the invention, the carbon fiber cloth weaving machine comprises a frame, wherein a thread separating mechanism is arranged on the frame, a material roller for winding a row of carbon fiber warps is arranged on one side of the thread separating mechanism, a dust removing mechanism is arranged on one side of the thread separating mechanism close to the material roller, and a thread ejecting mechanism is arranged on one side of the thread separating mechanism away from the dust removing mechanism.

As a further scheme of the invention, the dust removing mechanism comprises a fixed frame, wherein a static eliminating component for removing static electricity on the surface of the carbon fiber warp is arranged on the fixed frame, and the static eliminating component comprises a static eliminator; the utility model discloses a dust removal assembly, including the dust removal assembly, the dust removal assembly is provided with the dust removal assembly on one side, the fixed guard of dust removal assembly runs through the mount top and communicates with there is the suction hood, fixed guard top intercommunication has the exhaust hood, the exhaust hood opening part is provided with the filter screen that is arranged in dust, the hair impurity in the filtered air, the exhaust hood bottom is rotated and is provided with the stripper, states the exhaust hood bilateral symmetry and is fixed with the cylinder of unloading, two the cylinder piston rod of unloading rotates to be connected in the stripper both sides, and through starting the cylinder of unloading, the cylinder piston rod of unloading drives the stripper and rotates, and then impurity such as the dust and the hair of the interior storage of exhaust hood of discharging, be provided with the fan that is used for extracting mount below air in the fixed guard.

As a further scheme of the present invention, the fixed frame is mounted on the frame, a first fixed rod and a second fixed rod are respectively fixedly mounted on two sides of the static eliminator, the first fixed rod is slidably mounted on the fixed frame, the second fixed rod is in threaded connection with the fixed frame, a rotating handle is arranged on the top of the second fixed rod, the rotating handle drives the second fixed rod to rotate on the fixed frame by rotating the rotating handle, so as to drive the static eliminator to move up and down, and the static eliminator moves to above the carbon fiber warps to remove impurities such as dust and fuzz adhered to the carbon fiber warps due to electrostatic adsorption, wherein the static eliminator has a static eliminating distance, and the static eliminator capable of moving up and down is used for adjusting the height of the static eliminator, so as to conveniently obtain an optimal static eliminating distance.

As a further scheme of the present invention, the branching mechanism includes a first branching rod and a second branching rod, a first branching assembly and a second branching assembly are disposed between the first branching rod and the second branching rod, the first branching assembly and the second branching assembly have the same structure, the first branching assembly includes a branching frame, branching rings are disposed in the middle of a plurality of branching devices fixedly mounted in the branching frame, the first branching rod and the second branching rod are both provided with a first lifting groove and a second lifting groove, two sides of the branching frame of the first branching assembly are respectively slidably mounted on the first lifting grooves of the first branching rod and the second branching rod, and two sides of the branching frame of the second branching assembly are respectively slidably mounted on the second lifting grooves of the first branching rod and the second branching rod.

As a further aspect of the present invention, an output shaft of the lifting motor fixedly installed at one side of the first wire dividing rod penetrates through a side wall of the first wire dividing rod and is fixedly connected to a driving gear, the driving gear is disposed in the first wire dividing rod, two sides of the driving gear are respectively engaged with a first lifting rack and a second lifting rack, the first lifting rack is fixedly connected to a wire dividing frame of the first wire dividing assembly, and the second lifting rack is fixedly connected to a wire dividing frame of the second wire dividing assembly.

As a further scheme of the invention, sliding blocks are fixedly arranged on two sides of a top line frame of the top line mechanism, the two sliding blocks are respectively arranged in sliding grooves formed in two sides of a rack in a sliding mode, a plurality of top line rods are arranged in the top line frame, and gaps for carbon fiber warps to pass through are formed between every two adjacent top line rods.

As a further scheme of the invention, a sliding lead screw is rotatably mounted in one of the sliding grooves, a sliding block positioned on one side of the sliding lead screw is connected to the sliding lead screw in a threaded manner, and a sliding motor for driving the sliding lead screw to rotate is fixedly mounted in the rack.

Compared with the prior scheme, the invention has the beneficial effects that:

according to the invention, the dust removing mechanism is arranged on the frame, the static electricity eliminating component on the dust removing mechanism is used for removing static electricity on carbon fiber warp threads and removing dust, broken filaments and other impurities adhered to the carbon fiber warp threads due to the electrostatic adsorption effect, the height-adjustable static electricity eliminator is convenient to obtain the optimal static electricity eliminating distance, and the static electricity eliminating quality is improved;

dust removal component on the dust removal mechanism is arranged in adsorbing and impurity such as dust, broken filament in the filtered air, adsorbs because of dust and the broken filament impurity of scattering in the air behind the electrostatic elimination, utilizes the stripper to collect simultaneously, has reduced the dust and the broken filament impurity in the air, has improved carbon cloth's weaving quality, avoids influencing carbon cloth's subsequent processing.

Drawings

Fig. 1 is a schematic structural view of a carbon fiber cloth loom according to the present invention.

Fig. 2 is a schematic structural diagram of a branching mechanism in the invention.

Fig. 3 is a schematic structural view of a first branch rod according to the present invention.

Fig. 4 is a schematic structural view of the rack of the present invention.

Fig. 5 is a schematic structural view of the top line mechanism of the present invention.

FIG. 6 is a schematic view of the dust removing mechanism of the present invention.

FIG. 7 is a schematic view of the electrostatic discharge device of the present invention.

Fig. 8 is a schematic structural view of the dust removing assembly of the present invention.

In the figure: 1. a frame; 11. a sliding groove; 12. a sliding lead screw; 2. a material roller; 3. a wire separating mechanism; 31. a first branching rod; 311. a first lifting groove; 312. a second lifting groove; 32. a second wire-distributing rod; 33. a first wire-splitting assembly; 331. a line dividing frame; 332. a wire divider; 333. a coil splitting; 34. a second wire-dividing assembly; 35. a lifting motor; 36. a first lifting rack; 37. a second lifting rack; 38. a drive gear; 4. a dust removal mechanism; 41. a fixed mount; 42. a static elimination component; 421. a static eliminator; 422. a first fixing lever; 423. a second fixing bar; 424. rotating the handle; 43. a dust removal assembly; 431. a fixed cover; 432. an exhaust hood; 433. a stripper plate; 434. a discharge cylinder; 435. a filter screen; 5. a thread ejecting mechanism; 51. a top line frame; 52. a slider; 53. a thread-ejecting rod.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings and specific embodiments. The embodiments of the present invention have been presented for purposes of illustration and description, and are not intended to be exhaustive or limited to the invention in the form disclosed. Many modifications and variations will be apparent to practitioners skilled in this art. The embodiment was chosen and described in order to best explain the principles of the invention and the practical application, and to enable others of ordinary skill in the art to understand the invention for various embodiments with various modifications as are suited to the particular use contemplated.

Referring to fig. 1 to 8, the invention relates to a weaving method of a multi-thread carbon fiber cloth, comprising the following steps:

the method comprises the following steps: a row of carbon fiber warps are led out from a material roller 2 of the carbon fiber cloth weaving machine and then wound around a guide roller, each carbon fiber warp is staggered and divided into two halves, one half of the carbon fiber warps passes through a branching ring 333 of a first branching assembly 33, the other half of the carbon fiber warps passes through a branching ring 333 of a second branching assembly 34, and the carbon fiber warps sequentially pass through gaps of a top line frame 51;

step two: when carbon fiber warps pass through the lower part of the dust removing mechanism 4, static electricity on each carbon fiber warp is eliminated through the static electricity eliminator 421, impurities such as dust and broken filaments adhered to the carbon fiber warps due to electrostatic adsorption are removed, the fan in the fixed cover 431 is started, the fan extracts air at the bottom of the fixed frame 41 through the dust absorption cover, the air with the dust and the broken filaments is filtered through the filter screen 435 on the exhaust cover 432, the air is discharged from the filter screen 435, the impurities such as the dust and the broken filaments fall onto the discharge plate 433 at the bottom of the exhaust cover 432, and the piston rod of the discharge cylinder 434 drives the discharge plate 433 to rotate by starting the discharge cylinder 434, so that the impurities such as the dust and the broken filaments stored in the exhaust cover 432 are discharged;

step three: start elevator motor 35, elevator motor 35 output shaft drives drive gear 38 and rotates, drive gear 38 drives first lifting

rack

36 and 37 relative motion of second lifting rack simultaneously, and then drive the carbon fiber warp of first wire dividing subassembly 33 and the carbon fiber warp of second wire dividing subassembly 34 respectively and crisscross from top to bottom, simultaneously introduce weft through the rapier in the shed that top line frame 51 front end formed, start sliding motor, sliding motor output shaft drives sliding lead screw 12 and rotates, sliding lead screw 12 rotates and drives top line frame 51 reciprocating motion through sliding block 52, but repeatedly moving's top line pole 53 of top line frame 51 presses the weft with the warp of introducing, accomplish the weaving operation of carbon cloth.

Specifically, this carbon fiber cloth loom includes frame 1, be provided with branching mechanism 3 in the frame 1, branching mechanism 3 one side is provided with and is used for being listed as carbon fiber warp's material roller 2 to the winding, material roller 2 passes through motor drive and rotates, material roller 2 one side is provided with the guide roll that plays the guide effect to carbon fiber warp, carbon fiber warp walks around from the guide roll after drawing forth from material roller 2 after then, branching mechanism 3 is close to material roller 2 one side and is provided with dust removal mechanism 4, branching mechanism 3 deviates from 4 one sides of dust removal mechanism and is provided with terminal line mechanism 5, carbon fiber warp and carbon fiber weft are the carbon fiber line.

The wire dividing mechanism 3 comprises a first wire dividing rod 31 and a second wire dividing rod 32, a first wire dividing component 33 and a second wire dividing component 34 are arranged between the first wire dividing rod 31 and the second wire dividing rod 32, the first wire dividing component 33 and the second wire dividing component 34 are identical in structure, the first wire dividing component 33 comprises a wire dividing frame 331, a plurality of wire dividers 332 are fixedly installed in the wire dividing frame 331, wire dividing rings 333 are arranged in the middles of the wire dividers 332, a first lifting groove 311 and a second lifting groove 312 are formed in the first wire dividing rod 31 and the second wire dividing rod 32, two sides of the wire dividing frame 331 of the first wire dividing component 33 are slidably installed on the first lifting grooves 311 of the first wire dividing rod 31 and the second wire dividing rod 32 respectively, two sides of the wire dividing frame 331 of the second wire dividing component 34 are slidably installed on the second lifting grooves 312 of the first wire dividing rod 31 and the second wire dividing rod 32 respectively, and the first wire dividing rod 31 and the second wire dividing rod 32 are fixedly installed on the rack 1;

a lifting motor 35 is fixedly installed on one side of the first wire dividing rod 31, an output shaft of the lifting motor 35 penetrates through the side wall of the first wire dividing rod 31 and is fixedly connected with a driving gear 38, the driving gear 38 is arranged in the first wire dividing rod 31, two sides of the driving gear 38 are respectively meshed and connected with a first lifting rack 36 and a second lifting rack 37, the first lifting rack 36 is fixedly connected with a wire dividing frame 331 of the first wire dividing component 33, and the second lifting rack 37 is fixedly connected with the wire dividing frame 331 of the second wire dividing component 34; during the use, start elevator motor 35, elevator motor 35 output shaft drives drive gear 38 and rotates, and drive gear 38 drives first lifting rack 36 and second lifting rack 37 relative motion simultaneously, and then drives the carbon fiber warp of first wire dividing component 33 and the carbon fiber warp of second wire dividing component 34 respectively and staggers from top to bottom, is convenient for introduce the weft through the rapier in the shed that top line frame 51 front end formed.

Top line mechanism 5 includes top line frame 51, the equal fixed mounting in top line frame 51 both sides has sliding block 52, sliding tray 11 has all been seted up to frame 1 both sides, sliding lead screw 12 is installed to one of them sliding tray 11 internal rotation, two sliding blocks 52 are respectively in the sliding tray 11 of slidable mounting, and be located sliding lead screw 12 one side sliding block 52 threaded connection on sliding lead screw 12, fixed mounting has sliding motor in frame 1, sliding motor output shaft fixed connection sliding lead screw 12 tip, be provided with a plurality of top line poles 53 in the top line frame 51, be provided with the clearance that supplies carbon fiber warp to pass between the adjacent top line pole 53, top line mechanism 5 is used for realizing carbon fiber weft's the pressure latitude operation, start sliding motor, sliding motor output shaft drives sliding lead screw 12 and rotates, sliding lead screw 12 rotates and drives top line frame 51 reciprocating motion through sliding block 52, but repeatedly movable top line frame 51's top line pole 53 makes things convenient for the rapier to draw in the shed.

The dust removing mechanism 4 comprises a fixing frame 41, the fixing frame 41 is installed on the rack 1, a static electricity eliminating assembly 42 for eliminating static electricity on the surface of carbon fiber warps is arranged on the fixing frame 41, the static electricity eliminating assembly 42 comprises a static electricity eliminator 421, a first fixing rod 422 and a second fixing rod 423 are respectively and fixedly installed on two sides of the static electricity eliminator 421, the first fixing rod 422 is slidably installed on the fixing frame 41, the second fixing rod 423 is in threaded connection with the fixing frame 41, a rotating handle 424 is arranged at the top of the second fixing rod 423, the rotating handle 424 is rotated to drive the second fixing rod 423 to rotate on the fixing frame 41, so as to drive the static electricity eliminator 421 to move up and down, static electricity on the carbon fiber warps of the static electricity eliminator 421 is conveniently removed by moving the static electricity eliminator 421 to the position above the carbon fiber warps, impurities such as dust and hair and the like adhered to the carbon fiber warps due to electrostatic adsorption effect are removed, the static electricity eliminating distance of the static electricity eliminator 421 exists, and the static electricity eliminating distance capable of moving up and down is used for adjusting the height of the static electricity eliminator 421, so as to conveniently obtain the optimal static electricity eliminating distance;

a dust removal assembly 43 is arranged on one side of the static elimination assembly 42, the dust removal assembly 43 comprises a fixed cover 431, the fixed cover 431 penetrates through the top of the fixed frame 41 and is communicated with a dust suction cover, an exhaust cover 432 is communicated with the top of the fixed cover 431, a filter screen 435 is arranged at the opening of the exhaust cover 432, the filter screen 435 is used for filtering impurities such as dust, broken filaments and the like in the air, a discharge plate 433 is arranged at the bottom of the exhaust cover 432, the discharge plate 433 is rotatably arranged on one side of the bottom of the exhaust cover 432, discharge cylinders 434 are symmetrically fixed on two sides of the exhaust cover 432, piston rods of the two discharge cylinders 434 are rotatably connected with two sides of the discharge plate 433, and by starting the discharge cylinders 434, the piston rods of the discharge cylinders 434 drive the discharge plate 433 to rotate, and then the impurities such as dust and broken filaments stored in the exhaust cover 432 are discharged, a fan is arranged in the fixed cover 431, the fan rotates to extract air below the fixed frame 41 through the dust hood, the air is conveyed to the exhaust cover 432, the air with the dust and the broken filaments is filtered through the filter screen 435 on the exhaust cover 432, the air is discharged from the filter screen 435, the impurities such as the dust and the broken filaments fall onto the discharging plate 433 at the bottom of the exhaust cover 432, the discharging plate 433 is driven to rotate through the discharging cylinder 434, the impurities such as the dust and the broken filaments stored in the exhaust cover 432 are further discharged, the impurities such as the dust and the broken filaments in the air are reduced, the weaving quality of the carbon fiber cloth is improved, and the subsequent processing of the carbon fiber cloth is prevented from being influenced.

In the description of the present invention, it should be understood that the terms "upper", "lower", "left", "right", etc. indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings only for convenience in describing the present invention and simplifying the description, but do not indicate or imply that the device or element referred to must have a specific orientation and a specific orientation configuration and operation, and thus, should not be construed as limiting the present invention. Furthermore, "first" and "second" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include one or more of that feature. In the description of the present invention, "a plurality" means two or more unless otherwise specified.

In the description of the present invention, it should be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "connected," and the like are to be construed broadly and may be, for example, fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; they may be directly connected or indirectly connected through an intermediate member, or they may be connected through two or more elements. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

While one embodiment of the present invention has been described in detail, the description is only a preferred embodiment of the present invention and should not be taken as limiting the scope of the invention. All equivalent changes and modifications made within the scope of the present invention shall fall within the scope of the present invention.

Claims

1. A weaving method of a multi-thread carbon fiber cloth is characterized by comprising the following steps:

the method comprises the following steps: a row of carbon fiber warps are led out from a material roller (2) of the carbon fiber cloth weaving machine and then wound around a guide roller, each carbon fiber warp is staggered and divided into two halves, one half of the carbon fiber warps penetrate through a branching ring (333) of a first branching assembly (33), the other half of the carbon fiber warps penetrate through a branching ring (333) of a second branching assembly (34), and the carbon fiber warps sequentially penetrate through gaps of a top line frame (51);

step two: when carbon fiber warp passes below the dust removal mechanism (4), static electricity on each carbon fiber warp is eliminated through the static electricity eliminator (421), dust and wool impurities adhered to the carbon fiber warp due to electrostatic adsorption are removed, a fan extracts air at the bottom of the fixing frame (41) through the dust hood, the air with the dust and the wool is filtered through the filter screen (435) on the exhaust hood (432), the air is discharged from the filter screen (435), impurities such as the dust and the wool fall onto the discharge plate (433) at the bottom of the exhaust hood (432), the discharge plate (433) is driven to rotate through the piston rod of the discharge cylinder (434), and then the dust and the wool impurities stored in the exhaust hood (432) are discharged;

step three: the method comprises the steps of starting a lifting motor (35), driving a driving gear (38) to rotate by an output shaft of the lifting motor (35), driving the driving gear (38) to simultaneously drive a first lifting rack (36) and a second lifting rack (37) to move relatively, further driving carbon fiber warps of a first dividing component (33) and carbon fiber warps of a second dividing component (34) to move up and down in a staggered mode, simultaneously leading in wefts in sheds formed at the front end of a top line frame (51) through rapiers, starting a sliding motor, driving a sliding lead screw (12) to rotate by an output shaft of the sliding motor, driving the top line frame (51) to move back and forth through a sliding block (52) by the rotation of the sliding lead screw (12), pressing wefts led in with the warps by a top line rod (53) of the top line frame (51) capable of moving repeatedly, and finishing weaving operation of the carbon fiber cloth.

2. The weaving method of the multi-thread carbon fiber cloth according to claim 1 is characterized in that the carbon fiber cloth weaving machine comprises a frame (1), a thread separating mechanism (3) is arranged on the frame (1), a material roller (2) for winding a row of carbon fiber warps is arranged on one side of the thread separating mechanism (3), a dust removing mechanism (4) is arranged on one side of the thread separating mechanism (3) close to the material roller (2), and a thread ejecting mechanism (5) is arranged on one side of the thread separating mechanism (3) away from the dust removing mechanism (4).

3. The weaving method of the multi-thread carbon fiber cloth according to claim 2, characterized in that the dust removing mechanism (4) comprises a fixing frame (41), a static electricity eliminating component (42) for eliminating the static electricity on the surface of the carbon fiber warp threads is arranged on the fixing frame (41), and the static electricity eliminating component (42) comprises a static electricity eliminator (421); the utility model discloses a dust removal assembly, including static elimination subassembly (42), dust removal subassembly (43), fixed cover (431) of dust removal subassembly (43) run through mount (41) top and communicate and have the suction hood, fixed cover (431) top intercommunication has exhaust hood (432), exhaust hood (432) opening part is provided with dust, the filter screen (435) of wool impurity that are arranged in the filtered air, exhaust hood (432) bottom is rotated and is provided with stripper (433), states exhaust hood (432) bilateral symmetry and is fixed with discharge cylinder (434), two discharge cylinder (434) piston rod rotates and connects in stripper (433) both sides, be provided with the fan that is used for extracting mount (41) below air in fixed cover (431).

4. The weaving method of the multi-thread carbon fiber cloth according to claim 3, characterized in that the fixing frame (41) is installed on the frame (1), a first fixing rod (422) and a second fixing rod (423) are respectively fixedly installed on both sides of the static eliminator (421), the first fixing rod (422) is slidably installed on the fixing frame (41), the second fixing rod (423) is connected to the fixing frame (41) in a threaded manner, and a rotating handle (424) is arranged at the top of the second fixing rod (423).

5. The weaving method of the multi-thread carbon fiber cloth according to claim 2, characterized in that the thread dividing mechanism (3) comprises a first thread dividing rod (31) and a second thread dividing rod (32), a first thread dividing component (33) and a second thread dividing component (34) are arranged between the first thread dividing rod (31) and the second thread dividing rod (32), the first thread dividing component (33) and the second thread dividing component (34) have the same structure, the first thread dividing component (33) comprises a thread dividing frame (331), thread dividing rings (333) are respectively arranged in the middle of a plurality of thread dividers (332) fixedly arranged in the thread dividing frame (331), a first lifting groove (311) and a second lifting groove (312) are respectively formed in each of the first thread dividing rod (31) and the second thread dividing rod (32), both sides of the thread dividing frame (331) of the first thread dividing component (33) are respectively slidably arranged on the first lifting grooves (311) of the first thread dividing rod (31) and the second thread dividing rod (32), and both sides of the first thread dividing component (34) are respectively slidably arranged on the second lifting grooves (312) of the first thread dividing rod (31) and the second thread dividing rod (32).

6. The weaving method of the multi-thread carbon fiber cloth according to claim 5, wherein an output shaft of a lifting motor (35) fixedly installed at one side of the first dividing rod (31) penetrates through a side wall of the first dividing rod (31) and is fixedly connected with a driving gear (38), the driving gear (38) is arranged in the first dividing rod (31), two sides of the driving gear (38) are respectively engaged and connected with a first lifting rack (36) and a second lifting rack (37), the first lifting rack (36) is fixedly connected with a dividing frame (331) of the first dividing component (33), and the second lifting rack (37) is fixedly connected with the dividing frame (331) of the second dividing component (34).

7. The weaving method of the multi-thread carbon fiber cloth according to claim 2, characterized in that sliding blocks (52) are fixedly installed on both sides of a top thread frame (51) of the top thread mechanism (5), the two sliding blocks (52) are respectively installed in sliding grooves (11) formed on both sides of the frame (1) in a sliding manner, a plurality of top thread rods (53) are arranged in the top thread frame (51), and a gap for carbon fiber warp threads to pass through is arranged between the adjacent top thread rods (53).

8. The weaving method of the multi-thread carbon fiber cloth according to claim 7, wherein a sliding screw (12) is rotatably installed in one of the sliding grooves (11), a sliding block (52) located at one side of the sliding screw (12) is threadedly connected to the sliding screw (12), and a sliding motor for driving the sliding screw (12) to rotate is fixedly installed in the frame (1).