CN114315122A

CN114315122A - Glass fiber production method

Info

Publication number: CN114315122A
Application number: CN202111465174.1A
Authority: CN
Inventors: 刘兴月; 杜照孔; 安智广
Original assignee: Shandong Fiberglass Group Co Ltd
Current assignee: Shandong Fiberglass Group Co Ltd
Priority date: 2021-12-03
Filing date: 2021-12-03
Publication date: 2022-04-12

Abstract

The invention discloses a glass fiber production method, which comprises the following steps of: preparing raw materials: according to the parts by weight, 63 parts of pyrophyllite, 32.5 parts of limestone, 12 parts of kaolin, 11 parts of quartz sand, 4 parts of fluorite powder, 3.5 parts of mirabilite and 1.5 parts of soda ash are taken; step 2: putting the pulverized raw materials into a mixing and sending tank, adding auxiliary raw materials, uniformly mixing, and pressing into a melting furnace for melting; and step 3: heating the melting furnace to raise the temperature of the raw materials until the raw materials are in a molten state; and 4, drawing and winding, namely winding the glass fiber on a winding drum, wherein the winding drum in the step 4 is arranged on a glass fiber winding drum dismounting device, and when the winding drum is required to be replaced after winding a rated amount of glass fiber, the glass fiber winding drum dismounting device is used for completing replacement. The invention realizes automatic replacement of the winding tube after winding the glass fiber, thereby improving the working efficiency.

Description

Glass fiber production method

Technical Field

The invention belongs to the technical field of glass fibers, and particularly relates to a glass fiber production method.

Background

Glass fiber (Fibreglass) is an inorganic non-metallic material with excellent performance, and has the advantages of good insulativity, strong heat resistance, good corrosion resistance and high mechanical strength, and is manufactured by processes of high-temperature melting, wire drawing, winding, weaving and the like. Glass fibers are commonly used as reinforcing materials in composite materials, electrical and thermal insulation materials, circuit substrates, and other various fields of the national economy.

Glass fiber need wind glass fiber silk on the forming tube at the in-process of receiving the silk through the wire drawing, and the winding glass fiber process is accomplished, needs to change the forming tube after the coiling through the manual work, increases staff's work load, and it is too loaded down with trivial details to change, reduces work efficiency, consequently is necessary to provide an efficient glass fiber production method.

Disclosure of Invention

The invention aims to overcome the defects in the prior art, and provides an efficient glass fiber production method, which realizes automatic replacement of a winding cylinder after glass fiber winding and improves the working efficiency.

In order to achieve the purpose, the invention adopts the technical scheme that: a method of producing glass fibers comprising the steps of:

step 1: preparing raw materials: taking 63 parts of pyrophyllite, 32.5 parts of limestone, 12 parts of kaolin, 11 parts of quartz sand, 4 parts of fluorite powder, 3.5 parts of mirabilite and 1.5 parts of soda ash in parts by weight:

step 2: putting the pulverized raw materials into a mixing and sending tank, adding auxiliary raw materials, uniformly mixing, pressing into a melting furnace for melting:

and step 3: heating the melting furnace to raise the temperature of the raw materials until the raw materials are in a molten state;

and 4, drawing and winding the glass fiber yarns, and winding the glass fiber yarns on a winding drum.

Preferably, the winding cylinder in the step 4 is arranged on the glass fiber winding cylinder unloading device, and when the winding cylinder is required to be replaced by winding a rated amount of glass fibers, the glass fiber winding cylinder unloading device is used for completing replacement.

Preferably, the glass fiber winding and bobbin discharging device comprises a base, a stand column and a winding bobbin, wherein the stand column is arranged on the upper portion of the base, a bobbin discharging mechanism is arranged on one side of the stand column and comprises a rotary drum, a rotating mechanism, a guide rod and a transmission motor, the rotary drum is arranged on one side of the stand column and connected to the stand column, the guide rod is arranged inside the rotary drum and connected to the central position of the rotary drum, a plurality of guide wheels are arranged on one side of the guide rod, a plurality of cross beams are arranged on one side of the guide wheels, a plurality of connecting rods are arranged on one side of each cross beam corresponding to the corresponding guide wheel, one end of each connecting rod is movably arranged in a limiting groove, the limiting groove is connected to the guide wheel, the other end of each connecting rod is movably connected to the cross beam through a rotating shaft I, a rotating shaft II is arranged on one side of the rotating shaft I, the connecting rods are movably connected to the rotary drum through the rotating shaft II, a chain is arranged on one side of the rotating shaft II, chain wheels are arranged at two ends of the chain and are respectively connected to the rotating shaft I and the rotating shaft II; a transmission motor is arranged on one side of the rotating shaft II, a transmission mechanism is arranged on one side of the rotating shaft I, a plurality of rotating wheels are arranged on one side of the transmission mechanism, rotating wheels are arranged on one sides of the rotating wheels, the rotating shafts are movably connected to the rotating wheels, the rotating wheels are movably connected to the cross beam, and adjacent rotating wheels are connected through connecting wheels; the transmission motor rotates to drive the transmission mechanism to work through the chain, and the transmission mechanism drives the rotating wheel to rotate and drives the rotating wheel to rotate;

unload a section of thick bamboo outside of mechanism and be equipped with a winding section of thick bamboo, winding section of thick bamboo one side is equipped with the push pedal, and push pedal one side is equipped with the fixed plate, and the push pedal passes through telescopic link I to be connected on the fixed plate, and the fixed plate is connected on the base, and the push pedal promotes a winding section of thick bamboo and gets into to unload a section of thick bamboo mechanism, drives the runner through going out drive mechanism and rotates to the equidirectional realization drive rotary drum wire winding and rotate and finish the back along the axis removal with the wire winding and realize unloading a section of thick bamboo process.

Preferably, the transmission mechanism comprises a moving block, a gear, a sliding block and a sliding block sleeve, the moving block is arranged on one side of the connecting wheel, and the moving block is movably connected to the cross beam through a telescopic rod II; one side of the connecting wheel is provided with a worm wheel which is movably connected to the moving block, one side of the worm wheel is provided with a worm which is movably connected to the moving block, one side of the worm is provided with a bevel gear III, one side of the bevel gear III is provided with two bevel gears II, and one of the two bevel gears II is perpendicular to the cross beam and the other one is parallel to the cross beam; a gear is arranged on one side of the bevel gear II and is connected to a bevel gear III through a rotating shaft III, and the rotating shaft III is movably connected to a moving block; a sliding block is arranged on one side of the worm, a sliding block sleeve is arranged on one side of the sliding block, a bevel gear IV is arranged on one side of the sliding block sleeve, and the sliding block sleeve and the bevel gear IV are movably connected to the cross beam through a pin shaft; the bevel gear IV is meshed with the bevel gear I; when the transmission mechanism works, the gear is meshed with the rotating wheel when the telescopic rod II extends, and the connecting wheel is meshed with the rotating wheel when the telescopic rod II contracts.

Preferably, two ends of the rotating shaft II are provided with a bevel gear VI, one side of the bevel gear VI is provided with a rotating rod, the rotating rod is movably connected to the rotating drum, two ends of the rotating rod are provided with a bevel gear V, and the bevel gear V is meshed with the bevel gear VI; the rotating rods drive the rotating wheels to rotate, so that friction force on the winding barrel is increased, and slipping is avoided.

Preferably, a rotating plate is arranged on one side of the rotating drum and is movably connected to the rotating drum; the position of the wire winding cylinder is conveniently limited.

Preferably, the yarn dividing mechanism comprises a moving frame, a support, a yarn dividing block I and a yarn dividing block II, wherein a plurality of yarn dividing blocks I are arranged in the support, the yarn dividing blocks I are movably connected to the support through guide strips I, a spring II is arranged on one side of each yarn dividing block I, and the spring II is connected to the yarn dividing blocks I and the support; one side of the wire dividing block I is provided with a wire dividing block II which is movably connected to the support through a guide strip II, one side of the wire dividing block II is provided with a spring III, and the spring III is connected to the wire dividing block I and the support; one side of the wire dividing block II is provided with a movable frame which is movably connected to the bracket through a telescopic rod IV; the telescopic link IV drives the moving frame to move, the yarn dividing block I and the yarn dividing block II are driven to move along the guide strip I and the guide strip II, and uniform distribution of glass fiber yarns is achieved.

Preferably, a supporting rod is arranged on one side of the rotating plate, a wire dividing mechanism is arranged on one side of the supporting rod, a telescopic rod III is arranged on one side of the wire dividing mechanism, and the telescopic rod III is connected to the supporting rod and the wire dividing mechanism; a rotating plate groove is formed in one side of the rotating plate, a groove is formed in one side of the rotating plate groove and is formed in the wire winding barrel, a limiting block is arranged in the groove, and the limiting block enters the rotating plate groove by rotating the wire winding barrel, so that the position of the wire winding barrel is fixed; the telescopic rod III moves to drive the filament separating mechanism to enter the groove, the filament separating mechanism fixes the glass fiber filaments and then winds the glass fiber filaments, and after the winding is finished, the telescopic rod III drives the filament separating block I and the filament separating block II to shrink into the support.

Preferably, one side of the guide wheel is provided with a spring I, the spring I is sleeved on the guide rod, and one side of the push plate is provided with a pushing block; when the push plate pushes the wire winding barrel to enter the barrel unloading mechanism, the push block pushes the guide wheel to move, so that the rotating wheel is pushed to move, and the wire winding barrels with different diameters are fixed.

Preferably, an arc-shaped plate is arranged on one side of the cylinder unloading mechanism; the winding drum is convenient to unload through the arc-shaped plate.

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

1) the gear is meshed with the rotating wheel when the telescopic rod II in the transmission mechanism is extended, the connecting wheel is meshed with the rotating wheel when the telescopic rod II is retracted, and the rotating wheel is driven by the transmission mechanism to rotate in different directions to drive the rotating drum to rotate in a wire winding manner and move along the axis after the wire winding is finished so as to realize the process of unloading the drum;

2) the pushing block pushes the guide wheel to move so as to drive the rotating wheel to move, so that the winding cylinders with different diameters are fixed;

3) the glass fiber yarns are uniformly fixed on the yarn separating mechanism through the movement of the moving frame of the IV telescopic rod pushing rod in the yarn separating mechanism, and the telescopic rod III drives the yarn separating mechanism to enter the groove so as to facilitate yarn winding.

Drawings

FIG. 1 is a schematic structural view of a glass fiber winding and unloading device according to the present invention;

FIG. 2 is a schematic view of a winding tube structure in the glass fiber winding and tube discharging device according to the present invention;

FIG. 3 is a schematic structural view of a bobbin unloading mechanism in the glass fiber winding bobbin unloading device of the present invention;

FIG. 4 is a schematic view of a drum structure of the glass fiber winding and unloading apparatus of the present invention;

FIG. 5 is a schematic view of a cross beam structure in the glass fiber winding and tube discharging device of the present invention;

FIG. 6 is a schematic view of a chain structure in the glass fiber winding and bobbin discharging device of the present invention;

FIG. 7 is a schematic view of a transmission mechanism in the glass fiber winding and bobbin discharging device according to the present invention;

FIG. 8 is a schematic structural view of a telescopic rod III in the glass fiber winding and tube discharging device of the present invention;

FIG. 9 is a schematic structural view of a fiber separating mechanism of the glass fiber winding and unloading device of the present invention;

in the figure: 1-base, 2-upright post, 3-wire winding barrel, 31-groove, 32-rotating plate, 33-rotating plate groove, 34-supporting rod, 341-telescopic rod III, 35-wire separating mechanism, 351-moving frame, 352-telescopic rod IV, 353-wire separating block I, 354-wire separating block II, 355-guide bar I, 356-guide bar II, 357-spring II, 358-spring III, 359-support, 5-push plate, 51-pushing block, 6-telescopic rod I, 7-fixing plate, 8-barrel unloading mechanism, 81-rotating barrel, 82-rotating mechanism, 83-rotating wheel, 831-rotating wheel, 84-cross beam, 85-connecting wheel, 851-moving block, 852-II and 86-connecting rod, 87-guide rod, 871-rotating shaft I, 872-rotating shaft II, 873-bevel gear I, 874-chain, 875-chain wheel, 88-guide wheel, 881-spring I, 882-limit groove, 89-transmission mechanism, 891-gear, 892-rotating shaft III, 893-bevel gear II, 894-bevel gear III, 895-slide block, 896-bevel gear IV, 897-slide block sleeve, 898-worm, 899-worm wheel, 9-arc plate, 10-transmission motor, 11-rotating rod, 12-bevel gear V and 13-bevel gear VI.

Detailed Description

For the convenience of understanding of those skilled in the art, the technical solution of the present invention will be further described in detail with reference to fig. 1 to 9.

A glass fiber production method is characterized by comprising the following steps:

And 4, arranging the winding tube on the glass fiber winding tube discharging device in the step 4, and when the winding tube is required to be replaced by winding a rated number of glass fibers, finishing the replacement by the glass fiber winding tube discharging device.

Specifically, the glass fiber winding tube unloading device comprises a base 1, an upright post 2 and a winding tube 3, wherein the upright post 2 is arranged at the upper part of the base 1, a tube unloading mechanism 8 is arranged at one side of the upright post 2, the tube unloading mechanism 8 comprises a rotary tube 81, a rotating mechanism 82, a guide rod 87 and a transmission motor 10, the rotary tube 81 is arranged at one side of the upright post 2, the rotary tube 81 is connected to the upright post 2, the guide rod 87 is arranged inside the rotary tube 81, the guide rod 87 is connected to the central position of the rotary tube 81, a plurality of guide wheels 88 are arranged at one side of the guide rod 87, a plurality of cross beams 84 are arranged at one side of the guide wheels 88, a plurality of connecting rods 86 are arranged at one side of the cross beams 84 corresponding to the guide wheels 88, one end of each connecting rod 86 is movably arranged in a limiting groove 882, the limiting groove 882 is connected to the guide wheel 88, the other end of the connecting rod 86 is movably connected to the cross beam 84 through a rotating shaft 871I, a rotating shaft 872 is arranged at one side of the rotating shaft I871, the connecting rod 86 is movably connected to the rotating drum 81 through a rotating shaft II 872, a chain 874 is arranged on one side of the rotating shaft II 872, chain wheels 875 are arranged at two ends of the chain 874, and the chain wheels 875 are respectively connected to the rotating shaft I871 and the rotating shaft II 872; a transmission motor 10 is arranged on one side of the rotating shaft II 872, a transmission mechanism 89 is arranged on one side of the rotating shaft I871, a plurality of rotating wheels 83 are arranged on one side of the transmission mechanism 89, a rotating wheel 831 is arranged on one side of each rotating wheel 83, the rotating shaft is movably connected to the rotating wheel 831, the rotating wheels 831 are movably connected to the cross beam 84, and adjacent rotating wheels 831 are connected through a connecting wheel 85; the transmission motor 10 rotates to drive the transmission mechanism 89 to work through the chain 874, and the transmission mechanism 89 drives the rotating wheel 83 to rotate and drives the rotating wheel 831 to rotate;

unload a 8 outsides of mechanism and be equipped with a forming tube 3, forming tube 3 one side is equipped with push pedal 5, 5 one sides of push pedal are equipped with fixed plate 7, push pedal 5 passes through telescopic link I6 and connects on fixed plate 7, fixed plate 7 connects on base 1, push pedal 5 promotes forming tube 3 and gets into and unload a mechanism 8 on, drive runner 83 to rotate to the equidirectional realization drive rotary drum 81 wire winding rotation and finish the back along the axis removal realization and unload a process through going out drive mechanism 89.

The transmission mechanism 89 comprises a moving block 851, a gear 891, a sliding block 895 and a sliding block sleeve 897, wherein the moving block 851 is arranged on one side of the connecting wheel 85, and the moving block 851 is movably connected to the cross beam 84 through an expansion rod II 852; one side of the connecting wheel 85 is provided with a worm wheel 899, the worm wheel 899 is movably connected to the moving block 851, one side of the worm wheel 899 is provided with a worm 898, the worm 898 is movably connected to the moving block 851, one side of the worm 898 is provided with a bevel gear III 894, one side of the bevel gear III 894 is provided with two bevel gears II 893, one of the two bevel gears II 893 is perpendicular to the beam 84, and the other bevel gear II is parallel to the beam 84; a gear 891 is arranged on one side of the bevel gear II 893, the gear 891 is connected to the bevel gear III 894 through a rotating shaft III 892, and the rotating shaft III 892 is movably connected to the moving block 851; a slide block 895 is arranged on one side of the worm 898, a slide block sleeve 897 is arranged on one side of the slide block 895, a bevel gear IV 896 is arranged on one side of the slide block sleeve 897, and the slide block sleeve 897 and the bevel gear IV 896 are movably connected to the cross beam 84 through a pin shaft; the bevel gear IV 896 is meshed with the bevel gear 891I 873; when the transmission mechanism 89 works, the gear 891 is meshed with the rotating wheel 83 when the telescopic rod II 852 is extended, and the connecting wheel 85 is meshed with the rotating wheel 831 when the telescopic rod II 852 is contracted.

Two ends of the rotating shaft II 872 are provided with bevel gears VI 13, one side of each bevel gear VI 13 is provided with a rotating rod 11, each rotating rod 11 is movably connected to the rotating cylinder 81, two ends of each rotating rod 11 are provided with bevel gears V12, and the bevel gears V12 are meshed with the bevel gears VI 13; the rotating rod 11 drives the rotating wheels 83 to rotate, so that the friction force on the winding drum 3 is increased, and the slipping is avoided.

Preferably, a rotating plate 32 is arranged on one side of the rotating cylinder 81, and the rotating plate 32 is movably connected to the rotating cylinder 81; it is convenient to achieve a definition of the position of the winding reel 3.

The wire dividing mechanism 35 comprises a moving frame 351, a support 359, wire dividing blocks I353 and wire dividing blocks II 354, wherein the support 359 is internally provided with a plurality of wire dividing blocks I353, the wire dividing blocks I353 are movably connected to the support 359 through guide strips I355, one side of each wire dividing block I353 is provided with a spring II 357, and each spring II 357 is connected to the wire dividing block I353 and the support 359; a wire dividing block II 354 is arranged on one side of the wire dividing block I353, the wire dividing block II 354 is movably connected to a support 359 through a guide bar II 356, a spring III 358 is arranged on one side of the wire dividing block II 354, and the spring III 358 is connected to the wire dividing block I353 and the support 359; a movable frame 351 is arranged on one side of the wire dividing block II 354, and the movable frame 351 is movably connected to a support 359 through an expansion link IV 352; the telescopic link IV 352 drives the moving frame 351 to move, so that the filament dividing block I353 and the filament dividing block II 354 are driven to move along the guide strip I355 and the guide strip II 356, and uniform distribution of glass fiber filaments is achieved.

A support rod 34 is arranged on one side of the rotating plate 32, a yarn dividing mechanism 35 is arranged on one side of the support rod 34, a telescopic rod III 341 is arranged on one side of the yarn dividing mechanism 35, and the telescopic rod III 341 is connected to the support rod 34 and the yarn dividing mechanism 35; a rotating plate groove 33 is formed in one side of the rotating plate 32, a groove 31 is formed in one side of the rotating plate groove 33, the groove 31 is formed in the wire winding cylinder 3, a limiting block is arranged in the groove 31, and the limiting block enters the rotating plate groove 33 by rotating the wire winding cylinder 3, so that the position of the wire winding cylinder 3 is fixed; the telescopic rod III 341 moves to drive the filament separating mechanism 35 to enter the groove 31, the filament separating mechanism 35 fixes the glass fiber filament and then winds the glass fiber filament, and after the filament winding is finished, the telescopic rod III 341 drives the filament separating block I353 and the filament separating block II 354 to shrink into the support 359.

A spring I881 is arranged on one side of the guide wheel 88, the spring I881 is sleeved on the guide rod 87, and a pushing block 51 is arranged on one side of the push plate 5; when the push plate 5 pushes the forming tube 3 to enter the tube unloading mechanism 8, the push block 51 pushes the guide wheel 88 to move, so that the push wheel 83 is pushed to move, and the forming tubes 3 with different diameters are fixed.

An arc-shaped plate 9 is arranged on one side of the cylinder unloading mechanism 8; the arc-shaped plate 9 is convenient for the bobbin unloading process of the winding bobbin 3.

The working process of the glass fiber winding and cylinder unloading device is as follows: the telescopic rod I6 pushes the winding drum 3 to enter the drum unloading mechanism 8, and the guide wheel 88 is pushed by the pushing block 51 to fix the winding drum 3; the transmission motor 10 rotates to drive the transmission mechanism 89 to rotate, and the transmission mechanism 89 drives the transmission mechanism 89 to rotate so as to align the groove 31 with the rotary plate groove 33; the telescopic rod IV 352 pushes the moving frame 351 to move, the branching block I and the branching block II move to enable the glass fiber filaments to be uniformly fixed on the filament dividing mechanism 35, the telescopic rod III 341 contracts to enable the filament dividing mechanism 35 to enter the groove 31, and the tube unloading mechanism 8 rotates to achieve a filament winding process. After wire winding is finished, the telescopic rod IV 352 pushes the moving frame 351 to move so that the wire dividing block I353 and the wire dividing block II 354 move into the support 359, the telescopic rod II 852 pushes the moving block 851 to move so that the rotating wheel 831 rotates, the wire winding barrel 3 is enabled to move to the arc-shaped plate 9 along the axis of the rotating barrel 81, and the automatic barrel discharging process is achieved.

The foregoing is merely exemplary and illustrative of the present invention and various modifications, additions and substitutions may be made by those skilled in the art to the specific embodiments described without departing from the scope of the present invention as defined in the accompanying claims.

Claims

1. A glass fiber production method is characterized by comprising the following steps:

2. The glass fiber production method according to claim 1, wherein the winding tube in step 4 is provided on a glass fiber winding take-off device, and when the winding tube needs to be replaced by winding a rated amount of glass fiber around the winding tube, the replacement is performed by the glass fiber winding take-off device.

3. The glass fiber production method according to claim 2, wherein the glass fiber winding can discharging device comprises a base, a column and a winding can, the upper part of the base is provided with an upright post, one side of the upright post is provided with a cylinder unloading mechanism, the cylinder unloading mechanism comprises a rotary cylinder, a rotating mechanism, a guide rod and a transmission motor, one side of the upright post is provided with a rotary drum which is connected with the upright post, a guide rod is arranged in the rotary drum, one side of the guide rod is provided with a guide wheel, a cross beam is arranged on one side of the guide wheel, a connecting rod is arranged on one side of the cross beam corresponding to the guide wheel, the other end of the connecting rod is movably connected to the cross beam through a rotating shaft I, a rotating shaft II is arranged on one side of the rotating shaft I, the connecting rod is movably connected to the rotary drum through the rotating shaft II, a chain is arranged on one side of the rotating shaft II, chain wheels are arranged at two ends of the chain and are respectively connected to the rotating shaft I and the rotating shaft II; a transmission motor is arranged on one side of the rotating shaft II, a transmission mechanism is arranged on one side of the rotating shaft I, a rotating wheel is arranged on one side of the transmission mechanism, a rotating wheel is arranged on one side of the rotating wheel, the rotating shaft is movably connected to the rotating wheel, the rotating wheel is movably connected to the cross beam, and adjacent rotating wheels are connected through connecting wheels;

unload a section of thick bamboo outside of mechanism and be equipped with a forming tube, forming tube one side is equipped with the push pedal, and push pedal one side is equipped with the fixed plate, and the push pedal passes through telescopic link I to be connected on the fixed plate, and the fixed plate is connected on the base, and the push pedal promotes a forming tube and gets into to unload on the section of thick bamboo mechanism.

4. The glass fiber production method according to claim 3, wherein the transmission mechanism comprises a moving block, a gear, a sliding block and a sliding block sleeve, the moving block is arranged on one side of the connecting wheel, and the moving block is movably connected to the cross beam through a telescopic rod II; one side of the connecting wheel is provided with a worm wheel which is movably connected to the moving block, one side of the worm wheel is provided with a worm which is movably connected to the moving block, one side of the worm is provided with a bevel gear III, one side of the bevel gear III is provided with two bevel gears II, and one of the two bevel gears II is perpendicular to the cross beam and the other one is parallel to the cross beam; a gear is arranged on one side of the bevel gear II and is connected to a bevel gear III through a rotating shaft III, and the rotating shaft III is movably connected to a moving block; a sliding block is arranged on one side of the worm, a sliding block sleeve is arranged on one side of the sliding block, a bevel gear IV is arranged on one side of the sliding block sleeve, and the sliding block sleeve and the bevel gear IV are movably connected to the cross beam through a pin shaft; bevel gear IV meshes with bevel gear I.

5. The glass fiber production method according to claim 3, wherein two ends of the rotating shaft II are provided with bevel gears VI, one side of each bevel gear VI is provided with a rotating rod, the rotating rod is movably connected to the rotating drum, two ends of the rotating rod are provided with bevel gears V, and the bevel gears V are meshed with the bevel gears VI.

6. A method for producing glass fibers as in claim 3 wherein the drum is provided with a rotating plate on one side, the rotating plate being movably attached to the drum.

7. The glass fiber production method according to claim 3, wherein the filament dividing mechanism comprises a moving frame, a support, filament dividing blocks I and filament dividing blocks II, a plurality of filament dividing blocks I are arranged inside the support, the filament dividing blocks I are movably connected to the support through guide strips I, springs II are arranged on one sides of the filament dividing blocks I, and the springs II are connected to the filament dividing blocks I and the support; one side of the wire dividing block I is provided with a wire dividing block II which is movably connected to the support through a guide strip II, one side of the wire dividing block II is provided with a spring III, and the spring III is connected to the wire dividing block I and the support; a movable frame is arranged on one side of the wire separating block II and movably connected to the support through a telescopic rod IV.

8. The glass fiber production method according to claim 7, wherein a support rod is arranged on one side of the rotating plate, a fiber dividing mechanism is arranged on one side of the support rod, a telescopic rod III is arranged on one side of the fiber dividing mechanism, and the telescopic rod III is connected to the support rod and the fiber dividing mechanism; the rotating plate is provided with a rotating plate groove on one side, a groove is formed in one side of the rotating plate groove and is formed in the wire winding barrel, a limiting block is arranged inside the groove, the limiting block enters the rotating plate groove by rotating the wire winding barrel, and the position of the wire winding barrel is fixed.