CN113117887B - Glass fiber cloth impurity removing device - Google Patents

Abstract

The invention discloses a glass fiber cloth impurity removing device which comprises an impurity removing cavity, wherein a metal impurity removing cavity and a non-metal impurity removing cavity are sequentially arranged in the impurity removing cavity, two ends of the impurity removing cavity are provided with feed rollers for conveying glass fiber cloth, two metal impurity adsorption devices are arranged in the metal impurity removing cavity, and the glass fiber cloth penetrates through a gap between the two metal impurity adsorption devices; be provided with the bar hole that supplies the glass fiber cloth to pass on the baffle, set up the negative pressure edulcoration device in the nonmetal edulcoration intracavity, the below of negative pressure edulcoration device is provided with the vibrating device of drive glass fiber cloth vibration, and the upper end and the lower extreme in bar hole all are provided with spacing roller, are provided with the clearance that supplies the glass fiber cloth to pass between two spacing rollers. The scheme is used for cleaning the produced glass fiber cloth, removing metal or non-metal impurities on the surface of the glass fiber cloth and ensuring the qualification rate of the produced copper-clad plate. In the whole process, the impurity removal effect of the glass fiber cloth is good, the residual degree of impurities on the surface of the glass fiber cloth is effectively reduced, and the quality of the produced copper-clad plate is ensured.

Description

Fine cloth edulcoration device of glass

Technical Field

The invention relates to the technical field of copper-clad plate production, in particular to a glass fiber cloth impurity removing device.

Background

The copper clad laminate is also called a base material, and is a plate-shaped material which is formed by soaking a reinforcing material in resin, covering one side or two sides of the reinforcing material with copper foil and performing hot pressing, and is called a copper clad laminate. It is a basic material for PCB, often called substrate. The glue is filled between two layers of the copper-clad plate, and the glue is firstly coated on one layer of glass fiber cloth, which is called gluing. The colloid coated on the glass fiber cloth has strength and can be thermally pressed with the two layers of copper foils to form the copper-clad plate through the subsequent semi-curing and full-curing processes.

If metal and other impurities exist on the glass fiber cloth, the insulativity of the colloid is seriously influenced, and the problems of short circuit and the like can occur on a circuit board (PCB) made of the copper-clad plate, so the impurities on the glass fiber cloth must be removed before the copper-clad plate is produced. The impurity removal quantity of the existing glass fiber cloth impurity removal device is poor in stability, the impurity removal effect is unstable, the qualified rate of the produced copper-clad plate is low, and the production cost of an enterprise is greatly increased.

Disclosure of Invention

Aiming at the defects in the prior art, the invention provides the glass fiber cloth impurity removing device with a good impurity removing effect.

In order to achieve the purpose of the invention, the technical scheme adopted by the invention is as follows:

the glass fiber cloth impurity removing device comprises an impurity removing cavity, wherein a metal impurity removing cavity and a non-metal impurity removing cavity are sequentially arranged in the impurity removing cavity, the non-metal impurity removing cavity and the metal impurity removing cavity are separated by a partition plate, feeding rollers for conveying glass fiber cloth are arranged at two ends of the impurity removing cavity, a tensioning roller is arranged beside each feeding roller, two metal impurity adsorption devices are arranged in the metal impurity removing cavity, and the glass fiber cloth passes through a gap between the two metal impurity adsorption devices; be provided with the bar hole that supplies the glass fiber cloth to pass on the baffle, set up the negative pressure edulcoration device in the nonmetal edulcoration intracavity, the below of negative pressure edulcoration device is provided with the vibrating device of drive glass fiber cloth vibration, and the upper end and the lower extreme in bar hole all are provided with spacing roller, are provided with the clearance that supplies the glass fiber cloth to pass between two spacing rollers.

The scheme is used for cleaning the produced glass fiber cloth, removing metal or non-metal impurities on the surface of the glass fiber cloth and ensuring the qualification rate of the produced copper-clad plate. The glass fiber cloth is conveyed into the nonmetal impurity removal cavity and the metal impurity removal cavity through the feeding roller, metal impurities on the surface of the glass fiber cloth are removed through the metal impurity adsorption device, then the nonmetal impurities on the surface of the glass fiber cloth are removed through the impurity removal device, in the impurity removal process, the vibration device drives the glass fiber cloth to shake, the impurities can shake off from the glass fiber cloth, and the impurity removal effect is ensured. Meanwhile, the limiting roller is used for limiting the glass fiber cloth when the glass fiber cloth shakes, and the glass fiber cloth is prevented from being damaged due to friction between the limiting roller and the strip-shaped holes. In the whole process, the impurity removal effect of the glass fiber cloth is good, the residual degree of impurities on the surface of the glass fiber cloth is effectively reduced, and the quality of the produced copper-clad plate is ensured.

Furthermore, the metal impurity adsorption device comprises a plurality of electromagnet blocks which are tightly attached to the surface of the glass fiber cloth, each electromagnet block is respectively fixed on a support rod, the support rods are fixed on the turntable, and the electromagnet blocks are uniformly distributed in the circumferential direction; the rotary table is arranged on a first supporting plate, the first supporting plate is fixed on the metal impurity removing cavity, a first motor is arranged on the first supporting plate, and the rotary table is connected with a rotating shaft of the first motor; the other metallic impurity case that is provided with of metallic impurity adsorption equipment, metallic impurity case and first negative-pressure air fan are connected, and first negative-pressure air fan is connected with the scum pipe, and the passageway that passes when power supply magnet piece and bracing piece are rotatory is seted up to the side of metallic impurity case.

Metallic impurity adsorption equipment can all carry out the edulcoration to the both sides of glass fine cloth, it is rotatory to drive the carousel through first motor, a plurality of magnet pieces of carousel drive sweep from glass fine cloth surface, produce magnetism when the magnet piece circular telegram, adsorb the metallic impurity of glass fine cloth surface adhesion on the magnet piece, after the magnet piece that adsorbs metallic impurity got into the metallic impurity case, magnet piece outage magnetism disappears, metallic impurity drops from the magnet piece, metallic impurity inhales away metallic impurity with the negative pressure that first negative-pressure air fan produced, realize metallic impurity's cleaing away.

Furthermore, a trigger switch is arranged on the supporting rod and is matched with the upper end of the channel to control the electrification and the outage of the electromagnet block.

Further, trigger switch includes the stationary blade, and the stationary blade is fixed on the bracing piece, and the upper end of stationary blade is provided with the shell fragment of S-shaped, is provided with the insulating block between the afterbody of stationary blade and the afterbody of shell fragment, and the head of shell fragment is provided with the trigger block, is provided with first reset spring between shell fragment and the stationary blade, and the opening between stationary blade and the shell fragment deviates from the direction of rotation of electromagnet piece.

Trigger switch is used for controlling the circular telegram and the outage of electromagnetism iron plate, because shell fragment and stationary blade are connected with the control system of electromagnetism iron plate, when the bracing piece rotated the passageway department on the metallic impurity case, the upper end of passageway pressed the extrusion shell fragment, made trigger block contact the stationary blade, and electromagnetism iron plate short circuit this moment for the magnetism of electromagnetism iron plate disappears. When the supporting rod leaves the channel, the elastic sheet resets, the electromagnet block is electrified continuously to generate magnetism, and the next round of impurity removal action is carried out. The S-shaped elastic sheet can not obstruct the rotation of the supporting rod and can not be deformed or damaged.

Further, negative pressure edulcoration device includes the absorption case, and the lower extreme of absorption case is provided with a plurality of absorption holes, absorbs the surface that the fine cloth of glass is hugged closely to the hole, and the absorption case passes through the pipeline to be connected with second negative-pressure air fan, and second negative-pressure air fan passes through the pipeline to be connected with non-metallic impurity case, and non-metallic impurity case and second negative-pressure air fan are all installed in the second backup pad, and the second backup pad is fixed at non-metallic impurity intracavity.

Further, the lower end of the second supporting plate is provided with a linear moving module along the length direction of the glass fiber cloth, the absorption box is fixed on a sliding block of the linear moving module through a supporting rod, and a pipeline between the absorption box and the second negative pressure fan is a soft spiral spring pipe.

When the non-metallic impurities on the surface of the glass fiber cloth are removed, negative pressure induced draft is generated through the second negative pressure fan, and the impurities adsorbed on the surface of the glass fiber cloth are absorbed by the absorption holes and stored in the non-metallic impurity box in the moving process of the glass fiber cloth. The impurity can be effectively collected while the effect of removing the non-metallic impurities is ensured, and the environment pollution caused by the emission of the impurities into the air is avoided. The moving direction round trip movement of fine cloth of glass is followed in the drive of absorption box accessible rectilinear movement module, further ensures the effect of edulcoration, ensures that impurity is got rid of completely, ensures the stability of edulcoration effect.

Further, the vibrating device is arranged at the lower end of the glass fiber cloth and comprises a swing rod, the swing rod is parallel to the length direction of the glass fiber cloth, the middle of the swing rod is hinged to the supporting seat, lifting rods are arranged at two ends of the swing rod and are perpendicular to the swing rod, a plurality of soft hammering blocks are arranged at the upper end of the lifting rod, the swing rod is connected with a driving device for driving the swing rod to swing, the supporting seat is arranged on a third supporting plate, and the third supporting plate is fixed on a non-metal impurity removing cavity.

When the vibrating device drives the glass fiber cloth to vibrate, the swinging rod swings back and forth, so that the hammering blocks at the two ends of the swinging rod hammer the glass fiber cloth alternately, impurities are shaken off and then are sucked away by the absorption holes, and the hammering blocks cannot damage the surface of the glass fiber cloth.

Further, drive arrangement is including setting up the actuating lever in the swinging arms below, and the actuating lever articulates on the supporting seat, and the both ends of actuating lever are provided with the cam, and the cam contacts with the lower extreme of swinging arms, and the contact opportunity of the bulge position of both ends cam and swinging arms is different, is provided with driven gear on the actuating lever, driven gear and driving gear meshing, and the driving gear is installed in the pivot of second motor, and the second motor is installed in the third backup pad.

Further, a second return spring is provided between both ends of the swing lever and the third support plate.

The swing rod is driven by the cams at the two ends to swing, the second motor drives the driving rod to rotate, the two cams alternately push against the two ends of the swing rod, the swing of the swing rod is realized, the swing rod swings stably, and the glass fiber cloth can shake or vibrate regularly.

The invention has the beneficial effects that: the method is used for cleaning the produced glass fiber cloth, removing metal or nonmetal impurities on the surface of the glass fiber cloth and ensuring the qualification rate of the produced copper-clad plate. In the whole process, the impurity removing effect of the glass fiber cloth is good, the residual degree of impurities on the surface of the glass fiber cloth is effectively reduced, and the quality of the produced copper-clad plate is ensured.

Drawings

Fig. 1 is a structural view of a glass cloth trash removal device.

FIG. 2 is a schematic diagram of a metal impurity adsorbing device.

FIG. 3 is a view showing the installation structure of the negative pressure trash removal device and the vibration device.

Fig. 4 is a structural view of the vibration device.

Fig. 5 is a structural view of the trigger switch.

Wherein, the device comprises a cleaning cavity 1, an impurity removing cavity 2, a tension roller 3, an electromagnet block 4, a first supporting plate 5, a first motor 6, a turntable 7, a clapboard 8, a vibrating device 9, a limiting roller 10, an absorption box 11, a second negative pressure fan 12, a non-metal impurity box 13, a supporting rod 14, a trigger switch 15, a metal impurity box 16, a channel 17 and a first negative pressure fan, 18, a fixing piece, 19, a spring piece, 20, a trigger block, 21, a first return spring, 22, a lifting rod, 23, a hammering block, 24, a swinging rod, 25, a supporting seat, 26, a cam, 27, a driving rod, 28, a driven gear, 29, a driving gear, 30, an absorption hole, 31, a linear moving module, 32, a third supporting plate, 33, a second return spring, 34 and a second motor.

Detailed Description

The following description of the embodiments of the present invention is provided to facilitate the understanding of the present invention by those skilled in the art, but it should be understood that the present invention is not limited to the scope of the embodiments, and it will be apparent to those skilled in the art that various changes may be made without departing from the spirit and scope of the invention as defined and defined in the appended claims, and all matters produced by the invention using the inventive concept are protected.

As shown in fig. 1 to 5, the glass fiber cloth impurity removing device of the scheme comprises an impurity removing cavity 1, a metal impurity removing cavity and a non-metal impurity removing cavity are sequentially arranged in the impurity removing cavity 1, the non-metal impurity removing cavity and the metal impurity removing cavity are separated by a partition plate 7, feeding rollers for conveying glass fiber cloth are arranged at two ends of the impurity removing cavity 1, a tensioning roller 2 is arranged beside the feeding rollers, two metal impurity adsorbing devices are arranged in the metal impurity removing cavity, and the glass fiber cloth passes through a gap between the two metal impurity adsorbing devices; a strip-shaped hole for glass fiber cloth to pass is formed in the partition plate 7, a negative-pressure impurity removal device is arranged in the nonmetal impurity removal cavity, a vibration device 8 for driving the glass fiber cloth to vibrate is arranged below the negative-pressure impurity removal device, limiting rollers 9 are arranged at the upper end and the lower end of the strip-shaped hole, and a gap for the glass fiber cloth to pass is formed between the two limiting rollers 9.

The scheme is used for cleaning the produced glass fiber cloth, removing metal or non-metal impurities on the surface of the glass fiber cloth and ensuring the qualification rate of the produced copper-clad plate. The fine cloth of glass sends into nonmetal edulcoration chamber and metal edulcoration intracavity through the feed roller, gets rid of the metal impurities on the fine cloth surface of glass through metal impurities adsorption equipment, then gets rid of the fine surperficial nonmetal impurities of glass cloth through the edulcoration device to at the in-process of edulcoration, the fine cloth shake of vibrating device 8 drive glass, make the fine cloth shake off from the fine cloth of glass of impurity ability, ensure the edulcoration effect. Meanwhile, the limiting roller 9 is used for limiting the glass fiber cloth when the glass fiber cloth shakes, and the glass fiber cloth is prevented from being damaged due to friction between the limiting roller and the strip-shaped holes. In the whole process, the impurity removal effect of the glass fiber cloth is good, the residual degree of impurities on the surface of the glass fiber cloth is effectively reduced, and the quality of the produced copper-clad plate is ensured.

The metal impurity adsorption device comprises a plurality of electromagnet blocks 3 tightly attached to the surface of the glass fiber cloth, each electromagnet block 3 is respectively fixed on a support rod 13, the support rods 13 are fixed on the turntable 6, and the electromagnet blocks 3 are uniformly distributed on the circumference; the rotary table 6 is arranged on the first supporting plate 4, the first supporting plate 4 is fixed on the metal impurity removing cavity, the first supporting plate 4 is provided with a first motor 5, and the rotary table 6 is connected with a rotating shaft of the first motor 5; a metal impurity box 15 is arranged beside the metal impurity adsorption device, the metal impurity box 15 is connected with a first negative pressure fan 17, the first negative pressure fan 17 is connected with a slag discharge pipe, and a channel 16 which is penetrated by the power supply magnet block 3 and the support rod 13 when rotating is arranged on the side surface of the metal impurity box 15.

Metallic impurity adsorption equipment can all carry out the edulcoration to the two sides of the fine cloth of glass, it is rotatory to drive carousel 6 through first motor 5, a plurality of magnet pieces of 6 drive of carousel 3 sweep from the fine cloth surface of glass, produce magnetism when 3 circular telegrams of magnet pieces, adsorb the metallic impurity of the fine cloth surface adhesion of glass on magnet piece 3, adsorb metallic impurity's magnet piece 3 and get into behind metallic impurity case 15, 3 outage magnetism of magnet piece disappear, metallic impurity comes off from magnet piece 3, metallic impurity siphons away metallic impurity with the negative pressure that first negative-pressure air fan 17 produced, realize metallic impurity's cleaing away.

A trigger switch 14 is arranged on the support rod 13, and the trigger switch 14 is matched with the upper end of the channel 16 to control the power-on and power-off of the electromagnet block 3.

The trigger switch 14 comprises a fixing plate 18, the fixing plate 18 is fixed on the supporting rod 13, an S-shaped elastic sheet 19 is arranged at the upper end of the fixing plate 18, an insulating block is arranged between the tail of the fixing plate 18 and the tail of the elastic sheet 19, a trigger block 20 is arranged at the head of the elastic sheet 19, a first reset spring 21 is arranged between the elastic sheet 19 and the fixing plate 18, and an opening between the fixing plate 18 and the elastic sheet 19 deviates from the rotating direction of the electromagnet block 3.

Trigger switch 14 is used for controlling the circular telegram and the outage of electromagnetism iron plate 3, shell fragment 19 and stationary blade 18 are connected with the control system of electromagnetism iron plate 3, when bracing piece 13 rotates the passageway 16 department on metallic impurity case 15, the upper end of passageway 16 is pressed and is extruded shell fragment 19, make trigger block 20 contact stationary blade 18, electromagnetism iron plate 3 short circuit this moment, electromagnetism iron plate 3 does not circular telegram, make the magnetism of electromagnetism iron plate 3 disappear, metallic impurity drops in metallic impurity case 15, absorb through first negative pressure air fan 17, realize metallic impurity's collection. When the supporting rod 13 leaves the channel 16, the elastic sheet 19 is reset, the electromagnet block 3 is electrified continuously to generate magnetism, and the next round of impurity removal action is carried out. The S-shaped elastic sheet 19 can not obstruct the rotation of the support rod 13, and the elastic sheet 19 can not be deformed or damaged.

The negative pressure impurity removal device comprises an absorption box 10, a plurality of absorption holes 30 are formed in the lower end of the absorption box 10, the absorption holes 30 are tightly attached to the surface of the glass fiber cloth, the absorption box 10 is connected with a second negative pressure fan 11 through a pipeline, the second negative pressure fan 11 is connected with a non-metal impurity box 1512 through a pipeline, the non-metal impurity box 1512 and the second negative pressure fan 11 are both installed on a second supporting plate, and the second supporting plate is fixed in a non-metal impurity removal cavity.

The lower end of the second supporting plate is provided with a linear moving module 31 along the length direction of the glass fiber cloth, the absorption box 10 is fixed on a slide block of the linear moving module 31 through a support rod, and a pipeline in front of the absorption box 10 and the second negative pressure fan 11 is a soft spiral spring pipe.

When the non-metallic impurities on the surface of the glass fiber cloth are removed, negative pressure induced draft is generated by the second negative pressure fan 11, and the impurities adsorbed on the surface of the glass fiber cloth are sucked away by the absorption holes 30 and stored in the non-metallic impurity box 1512 during the movement of the glass fiber cloth. The impurity can be effectively collected while the effect of removing the non-metallic impurities is ensured, and the environment pollution caused by the emission of the impurities into the air is avoided. The absorption box 10 can be driven by the linear moving module 31 to move back and forth along the moving direction of the glass fiber cloth, so that the impurity removal effect is further ensured, the impurities are completely removed, and the stability of the impurity removal effect is ensured.

Vibrating device 8 sets up the lower extreme at the fine cloth of glass, vibrating device 8 includes swinging arms 24, swinging arms 24 is parallel with the length direction of the fine cloth of glass, swinging arms 24's middle part articulates on supporting seat 25, swinging arms 24's both ends are provided with lifter 22, lifter 22 is perpendicular with swinging arms 24, lifter 22's upper end is provided with a plurality of soft hammering piece 23, swinging arms 24 is connected with the wobbling drive arrangement of drive swinging arms 24, supporting seat 25 installs in third backup pad 32, third backup pad 32 is fixed on nonmetal edulcoration chamber.

When the vibrating device 8 drives the glass fiber cloth to vibrate, the swinging rod 24 swings back and forth, so that the hammering blocks 23 at the two ends of the swinging rod 24 hammer the glass fiber cloth alternately, impurities are shaken off and then are sucked away by the absorption holes 30, and the hammering blocks 23 cannot damage the surface of the glass fiber cloth.

The driving device comprises a driving rod 27 arranged below the swing rod 24, the driving rod 27 is hinged on the supporting seat 25, cams 26 are arranged at two ends of the driving rod 27, the cams 26 are in contact with the lower end of the swing rod 24, protruding parts of the cams 26 at two ends are different from the contact time of the swing rod 24, a driven gear 28 is arranged on the driving rod 27, the driven gear 28 is meshed with a driving gear 29, the driving gear 29 is installed on a rotating shaft of a second motor 34, and the second motor 34 is installed on a third supporting plate 32.

A second return spring 33 is provided between both ends of the swing lever 24 and the third support plate 32.

The swing rod 24 is driven by the cams 26 at the two ends to swing, the second motor 34 drives the driving rod 27 to rotate, so that the two cams 26 alternately push against the two ends of the swing rod 24, the swing of the swing rod 24 is realized, the swing rod 24 swings stably, and the glass fiber cloth can shake or vibrate regularly.

The method is used for cleaning the produced glass fiber cloth, removing metal or nonmetal impurities on the surface of the glass fiber cloth and ensuring the qualification rate of the produced copper-clad plate. In the whole process, the impurity removal effect of the glass fiber cloth is good, the residual degree of impurities on the surface of the glass fiber cloth is effectively reduced, and the quality of the produced copper-clad plate is ensured.

While there have been shown and described what are at present considered to be the basic principles and essential features of the invention and advantages thereof, it will be apparent to those skilled in the art that the invention is not limited to the details of the foregoing illustrative embodiments, but is capable of other specific forms without departing from the spirit or essential characteristics thereof. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Furthermore, it should be understood that although the present specification describes embodiments, not every embodiment includes only a single embodiment, and such description is for clarity purposes only, and it is to be understood that all embodiments may be combined as appropriate by one of ordinary skill in the art to form other embodiments as will be apparent to those of skill in the art from the description herein.

Claims (9)

1. The glass fiber cloth impurity removing device is characterized by comprising an impurity removing cavity, wherein a metal impurity removing cavity and a non-metal impurity removing cavity are sequentially arranged in the impurity removing cavity, the non-metal impurity removing cavity and the metal impurity removing cavity are separated by a partition plate, feeding rollers for conveying glass fiber cloth are arranged at two ends of the impurity removing cavity, a tensioning roller is arranged beside the feeding rollers, two metal impurity adsorbing devices are arranged in the metal impurity removing cavity, and the glass fiber cloth passes through a gap between the two metal impurity adsorbing devices; be provided with the bar hole that supplies the fine cloth of glass to pass on the baffle, nonmetal edulcoration intracavity sets up negative pressure edulcoration device, the below of negative pressure edulcoration device is provided with the vibrating device of the fine cloth vibration of drive glass, the upper end in bar hole and lower extreme all are provided with spacing roller, two be provided with the clearance that supplies the fine cloth of glass to pass between the spacing roller.

2. A glass fiber cloth impurity removing device according to claim 1, wherein the metal impurity adsorbing device comprises a plurality of electromagnet blocks tightly attached to the surface of the glass fiber cloth, each electromagnet block is fixed on a support rod, the support rods are fixed on a turntable, and the electromagnet blocks are uniformly distributed in a circumference; the rotary table is arranged on a first supporting plate, the first supporting plate is fixed on the metal impurity removing cavity, a first motor is arranged on the first supporting plate, and the rotary table is connected with a rotating shaft of the first motor; the other metallic impurity case that is provided with of metallic impurity adsorption equipment, the metallic impurity case is connected with first negative-pressure air fan, first negative-pressure air fan is connected with the scum pipe, the passageway that passes when power supply magnet piece and bracing piece are rotatory is seted up to the side of metallic impurity case.

3. The fiberglass cloth impurity removing device according to claim 2, wherein a trigger switch is arranged on the support rod, and the trigger switch is matched with the upper end of the channel to control the power-on and power-off of the electromagnet block.

4. The fiberglass cloth impurity removing device according to claim 3, wherein the trigger switch comprises a fixed sheet, the fixed sheet is fixed on the support rod, an S-shaped elastic sheet is arranged at the upper end of the fixed sheet, an insulating block is arranged between the tail of the fixed sheet and the tail of the elastic sheet, a trigger block is arranged at the head of the elastic sheet, a first reset spring is arranged between the elastic sheet and the fixed sheet, and an opening between the fixed sheet and the elastic sheet deviates from the rotation direction of the electromagnet block.

5. The glass fiber cloth impurity removing device according to claim 1, wherein the negative pressure impurity removing device comprises an absorption box, a plurality of absorption holes are formed in the lower end of the absorption box, the absorption holes are tightly attached to the surface of the glass fiber cloth, the absorption box is connected with a second negative pressure fan through a pipeline, the second negative pressure fan is connected with a non-metal impurity box through a pipeline, the non-metal impurity box and the second negative pressure fan are both installed on a second supporting plate, and the second supporting plate is fixed in a non-metal impurity removing cavity.

6. A glass fiber cloth impurity removing device according to claim 5, wherein a linear moving module is arranged at the lower end of the second supporting plate along the length direction of the glass fiber cloth, the absorption box is fixed on a sliding block of the linear moving module through a supporting rod, and a pipeline between the absorption box and the second negative pressure fan is a soft spiral spring pipe.

7. The glass fiber cloth impurity removing device according to claim 1, wherein the vibrating device is arranged at the lower end of the glass fiber cloth, the vibrating device comprises a swinging rod, the swinging rod is parallel to the length direction of the glass fiber cloth, the middle part of the swinging rod is hinged to a supporting seat, lifting rods are arranged at two ends of the swinging rod, the lifting rods are perpendicular to the swinging rod, a plurality of soft hammering blocks are arranged at the upper ends of the lifting rods, the swinging rod is connected with a driving device for driving the swinging rod to swing, the supporting seat is installed on a third supporting plate, and the third supporting plate is fixed on the non-metal impurity removing cavity.

8. The fiberglass cloth impurity removing device according to claim 7, wherein the driving device comprises a driving lever arranged below the oscillating lever, the driving lever is hinged to the supporting seat, cams are arranged at two ends of the driving lever, the cams are in contact with the lower end of the oscillating lever, the contact time of the protruding parts of the cams at the two ends is different from that of the oscillating lever, a driven gear is arranged on the driving lever, the driven gear is meshed with a driving gear, the driving gear is arranged on a rotating shaft of a second motor, and the second motor is arranged on a third supporting plate.

9. A glass fiber cloth trash removal device according to claim 8, wherein a second return spring is disposed between both ends of the swing lever and the third support plate.

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