CN116282972A

CN116282972A - Glass fiber surface treatment device

Info

Publication number: CN116282972A
Application number: CN202211500972.8A
Authority: CN
Inventors: 张全雷; 尹志强; 张昭; 巫钰珊; 周扬; 陈伟萍
Original assignee: Yuan Yuan New Materials Co ltd
Current assignee: Yuan Yuan New Materials Co ltd
Priority date: 2022-11-28
Filing date: 2022-11-28
Publication date: 2023-06-23

Abstract

The invention relates to a processing device, in particular to a glass fiber surface processing device. It is necessary to design a glass fiber surface treatment device which can enable glass fibers to move to finish soaking treatment and has good treatment effect. The utility model provides a fine surface treatment device of glass, includes reaction frame and unloading frame, pushing down the mechanism, and reaction frame top left side rigid coupling has the unloading frame, still includes fortune material mechanism, is provided with the fortune material mechanism that is used for transporting glass fiber on the reaction frame. The invention pours a proper amount of pickling solution into the reaction frame, pours a proper amount of glass fiber onto the material conveying belt through the blanking frame, starts the double-shaft motor, the material conveying belt positively rotates to drive the glass fiber to move rightwards, the glass fiber moves rightwards to be immersed into the pickling solution to be treated, and rotates the pressing block to enable the material conveying belt to be in a concave state, so that the glass fiber can move to finish the immersing treatment, the pickling solution has fluidity, and the glass fiber treatment effect is better.

Description

Glass fiber surface treatment device

Technical Field

The invention relates to a processing device, in particular to a glass fiber surface processing device.

Background

The glass fiber composite material has high strength, high modulus, good formability, good insulating property, corrosion resistance, fatigue damage resistance and other excellent characteristics, and is widely applied to various fields of aviation, petrochemical industry, processing, automatic industry and the like.

Chinese patent publication No. CN214937054U discloses a novel glass fiber surface treatment device, including the flooding box, the fixed multiunit supporting leg that is equipped with in bottom of flooding box, the fixed section of thick bamboo that communicates with each other in top of flooding box, the fixed external surface of section of thick bamboo is equipped with two backup pads, two the top of backup pad is all fixed and is equipped with servo motor, servo motor's output is fixed and is equipped with the driving gear, the surface meshing of driving gear is connected with driven gear, and above-mentioned patent can carry out surface treatment to glass fiber, but because glass fiber is directly put into the separating drum and handles, because glass fiber is stationary state, leads to glass fiber to not reaching ideal treatment effect.

Based on the defects existing in the prior art, we provide a glass fiber surface treatment device which can enable glass fibers to move to finish soaking treatment and has good treatment effect.

Disclosure of Invention

In order to overcome the defect that the ideal treatment effect of the glass fiber is not achieved due to the fact that the glass fiber is directly placed into the separating cylinder for treatment and is in a static state, the invention provides the glass fiber surface treatment device which can enable the glass fiber to move to finish soaking treatment and is good in treatment effect.

The technical scheme of the invention is as follows:

the glass fiber surface treatment device comprises a reaction frame, a blanking frame, a material conveying mechanism and a material conveying mechanism, wherein the blanking frame is fixedly connected to the left side of the top of the reaction frame, and the material conveying mechanism is arranged on the reaction frame and used for conveying glass fibers.

The device further comprises supporting legs and a pressing mechanism, the supporting legs are fixedly connected to the left side and the right side of the reaction frame, and the pressing mechanism for generating deformation is arranged between the material conveying mechanism and the reaction frame.

Further, the material conveying mechanism comprises a double-shaft motor, a mounting frame, belt pulleys and a material conveying belt, wherein the double-shaft motor is fixedly connected to the left part of the reaction frame, the mounting frame is fixedly connected to the front side and the rear side of the reaction frame, the belt pulleys are arranged between the mounting frames on the front side and the rear side at equal intervals in a rotary mode, the belt pulleys are driven by a synchronous belt between an output shaft of the double-shaft motor and the belt pulley on the lower left side, and the material conveying belt is wound between the belt pulleys.

Further, the pushing mechanism comprises a first rotating rod, a second rotating rod, first column gears and rotating press blocks, the first rotating rods are symmetrically arranged on the left part of the reaction frame in a front-back rotating mode, the first rotating rods on the front side and the rear side are respectively in transmission with output shafts of the double-shaft motor through synchronous belts, the second rotating rods are symmetrically arranged on the right side of the first rotating rods in a front-back mode, four rotating press blocks are arranged on the upper portion of the reaction frame in an interval rotating mode, the two left rotating press blocks are respectively fixedly connected with the second rotating rods on the front side and the rear side, the rotating press blocks are in contact with a material conveying belt, the first column gears are fixedly connected to the first rotating rods on the front side and the rear side and the second rotating rods on the front side and the rear side, the two first column gears are meshed with each other in the front, and the two first column gears on the rear side are meshed with each other.

The device comprises a reaction frame, a first rotating rod, a second rotating gear, a winding wheel, a guide wheel, a first mounting seat, sliding harrows, a reset spring and a pull rope, wherein the third rotating rod is fixedly connected to the outer parts of the first rotating rod and the second rotating rod, the third rotating rod is arranged on the right side of the second rotating rod, the second rotating rod is fixedly connected to the outer parts of the third rotating rods, the short gears on the front side and the rear side can be meshed with the second gears on the front side and the rear side respectively, the winding wheels are fixedly connected to the inner sides of the third rotating rods on the front side and the rear side respectively, the first mounting seat is fixedly connected to the left side of the reaction frame, the reset spring is connected between the two sliding harrows and the first mounting seat, the pull rope is wound on the winding wheels on the front side and the rear side, and the tail ends of the pull rope respectively bypasses the guide wheels on the front side and the rear side and the two sliding harrows.

The device is characterized by further comprising a rubbing mechanism for tiling glass fibers, wherein the rubbing mechanism comprises a second mounting seat, a sliding plate, a connecting frame, pressing wheels, an S-shaped groove plate, a connecting plate and guide rods, the right side of the top of the reaction frame is fixedly connected with the second mounting seat, the sliding plate is arranged in the second mounting seat in a sliding mode, the bottom of the sliding plate is fixedly connected with the connecting frame, the pressing wheels for tiling the glass fibers are rotatably arranged at the lower part of the connecting frame, the S-shaped groove plate is fixedly connected to the top of the sliding plate in a front-back symmetrical mode, the connecting plate is fixedly connected to the upper parts of the right sides of the sliding rakes on the front side and the back side, the guide rods are fixedly connected to the right parts of the connecting plate on the front side and the back side respectively and are respectively located in the front-back side S-shaped groove plates, and the front-back side guide rods are respectively and fixedly connected with the sliding plate.

Further, the device also comprises a pressing mechanism for increasing the working efficiency of the sliding harrow claws, wherein the pressing mechanism comprises a mounting plate and an arc-surface pressing plate, the lower parts of the two sliding harrow claws are fixedly connected with the mounting plate, and the arc-surface pressing plate is fixedly connected on the two mounting plates.

Further, the device also comprises a discharging mechanism for facilitating discharging, the discharging mechanism comprises a receiving hopper and a sponge block, the receiving hopper for facilitating discharging is fixedly connected to the upper side of the right part of the reaction frame, and the sponge block is fixedly connected to the left part of the receiving hopper.

The beneficial effects of the invention are as follows:

1. the invention pours a proper amount of pickling solution into the reaction frame, pours a proper amount of glass fiber onto the material conveying belt through the blanking frame, starts the double-shaft motor, the material conveying belt positively rotates to drive the glass fiber to move rightwards, the glass fiber moves rightwards to be immersed into the pickling solution to be treated, and rotates the pressing block to enable the material conveying pressing block to be in a concave state, so that the glass fiber can move to finish the soaking treatment, the pickling solution has fluidity, and the glass fiber treatment effect is better.

2. Under the effect of the material homogenizing mechanism, the front and back side reels respectively drive the front and back side sliding harrow claws to move inwards and outwards through the front and back side stay ropes, and the front and back side sliding harrow claws move inwards and outwards to repeatedly rake open glass fibers, so that the glass fibers are prevented from being piled in the middle of a material conveying belt, and the influence on the treatment effect can be avoided.

3. Under discharge mechanism's effect, at first operating personnel will collect the container and place under receiving hopper, and when fortune material area corotation drove glass fiber and remove right, glass fiber removes right through receiving hopper and drops in collecting container, so, can avoid glass fiber to be difficult to drop in the collecting container.

Drawings

Fig. 1 is a schematic perspective view of a first view of the present invention.

Fig. 2 is a schematic view of a partial perspective structure of the present invention.

Fig. 3 is a schematic perspective view of a material transporting mechanism according to the present invention.

Fig. 4 is a schematic view of a part of a material transporting mechanism according to the present invention.

Fig. 5 is a schematic perspective view of a pressing mechanism according to the present invention.

Fig. 6 is a schematic view of a second perspective structure of the present invention.

Fig. 7 is a schematic perspective view of a refining mechanism according to the present invention.

Fig. 8 is an enlarged schematic view of the portion a of the present invention.

Fig. 9 is a schematic partial perspective view of the refining mechanism of the present invention.

Fig. 10 is a schematic perspective view of a rubbing mechanism according to the present invention.

FIG. 11 is an enlarged schematic view of section B of the present invention.

Fig. 12 is a schematic perspective view of a pressing mechanism according to the present invention.

Fig. 13 is a schematic view of a first perspective structure of the discharge mechanism of the present invention.

Fig. 14 is a schematic view of a second perspective of the discharge mechanism of the present invention.

The reference symbols in the drawings: 1: reaction frame, 2: landing leg, 3: blanking frame, 4: material transporting mechanism, 41: biaxial motor, 42: mounting frame, 43: pulley, 44: material conveying belt, 5: pressing mechanism, 51: first rotation lever, 52: second rotation lever, 53: first post gear, 54: rotating the pressing block, 6: refining mechanism, 61: third rotating lever, 62: gear-missing, 63: second column gear, 64: reel, 65: guide wheel, 66: first mount, 67: sliding rake fingers, 68: return spring, 69: pull rope, 7: rubbing mechanism, 71: second mount, 72: slide plate, 73: connecting frame, 74: pinch roller, 75: s-shaped channel plate, 76: connection plate, 77: guide bar, 8: pressing mechanism, 81: mounting plate, 82: cambered surface clamp plate, 9: discharge mechanism, 91: receiving hopper, 92: sponge block.

Detailed Description

The invention will be further described with reference to specific examples, illustrative examples and illustrations of which are provided herein to illustrate the invention, but are not to be construed as limiting the invention.

Example 1

The utility model provides a fine surface treatment device of glass, as shown in fig. 1-5, including reaction frame 1, landing leg 2, unloading frame 3, fortune material mechanism 4 and pushing down mechanism 5, reaction frame 1 both sides all rigid coupling has landing leg 2, reaction frame 1 top left side rigid coupling has unloading frame 3, be provided with fortune material mechanism 4 on the reaction frame 1, fortune material mechanism 4 can realize driving glass fiber and remove, be provided with pushing down mechanism 5 between fortune material mechanism 4 and the reaction frame 1, pushing down mechanism 5 can realize carrying out the deformation of pushing down to fortune material mechanism 4.

As shown in fig. 1-4, the material conveying mechanism 4 comprises a double-shaft motor 41, a mounting frame 42, a belt pulley 43 and a material conveying belt 44, wherein the double-shaft motor 41 is fixedly connected to the left part of the reaction frame 1, the mounting frame 42 is fixedly connected to the front side and the rear side of the reaction frame 1, the belt pulley 43 is uniformly and rotatably arranged between the mounting frames 42 on the front side and the rear side at intervals, the belt pulley 44 is wound between the output shaft of the double-shaft motor 41 and the belt pulley 43 on the lower left side through synchronous belt transmission.

As shown in fig. 2 and 5, the pressing mechanism 5 includes a first rotating rod 51, a second rotating rod 52, a first column gear 53 and a rotating pressing block 54, the first rotating rod 51 is symmetrically arranged on the left part of the reaction frame 1 in a front-back rotating manner, the first rotating rods 51 on the front-back two sides are respectively driven by an output shaft of the double-shaft motor 41 through a synchronous belt, the second rotating rod 52 is symmetrically arranged on the front-back part of the reaction frame 1 in a front-back rotating manner, the second rotating rod 52 is positioned on the right side of the first rotating rod 51, four rotating pressing blocks 54 are rotatably arranged on the upper part of the reaction frame 1 at intervals, the two rotating pressing blocks 54 on the left side are respectively fixedly connected with the second rotating rods 52 on the front-back two sides, the rotating pressing blocks 54 are in contact with the material conveying belt 44, the first column gears 53 are fixedly connected on the first rotating rods 51 on the front-back two first column gears 53 which are meshed with each other, and the two first column gears 53 on the back are meshed with each other.

Firstly, an operator pours a proper amount of pickling solution into a reaction frame 1, then a collecting container is placed on the right side of the reaction frame 1, a proper amount of glass fibers are poured onto a material conveying belt 44 through a blanking frame 3, a double-shaft motor 41 is started, the double-shaft motor 41 drives a lower left belt pulley 43 to rotate positively through synchronous belt transmission, so that all belt pulleys 43 rotate positively to drive the material conveying belt 44 to rotate positively, the material conveying belt 44 rotates positively to drive the glass fibers to move rightwards, the glass fibers move rightwards to be immersed in the pickling solution to be treated, the pickling solution continuously flows, meanwhile, the double-shaft motor 41 drives front and rear side first rotating rods 51 to rotate positively through synchronous belt transmission, the front and rear side first rotating rods 51 drive front and rear side second rotating rods 52 to rotate reversely through first column gears 53 respectively, the front and back second rotating rods 52 rotate reversely to drive the left front and back rotating pressing blocks 54 to rotate reversely, the left front and back rotating pressing blocks 54 rotate reversely to the material conveying belt 44 smoothly, meanwhile, the material conveying belt 44 is enabled to be in a concave state by rotating the pressing blocks 54, so that glass fibers are better immersed into pickling solution for treatment, then the material conveying belt 44 continues to rotate positively to drive the glass fibers to move rightwards, the glass fibers move rightwards to fall into the collecting container, after all glass fiber reaction treatment is completed, the double-shaft motor 41 is closed, the belt pulley 43 stops driving the material conveying belt 44 to rotate positively, and the collecting container is taken up to carry out subsequent treatment on the glass fibers.

Example 2

On the basis of embodiment 1, as shown in fig. 6-9, the device further comprises a material homogenizing mechanism 6, wherein the material homogenizing mechanism 6 comprises a third rotating rod 61, a gear-lack 62, a second column gear 63, a reel 64, a guide wheel 65, a first mounting seat 66, a sliding harrow 67, a return spring 68 and a pull rope 69, the gear-lack 62 is fixedly connected to the outer parts of the second rotating rods 52 on the front side and the rear side, the third rotating rod 61 is arranged on the right side of the second rotating rod 52 in a front symmetrical manner on the left part of the reaction frame 1, the second column gear 63 is fixedly connected to the outer parts of the third rotating rods 61 on the front side and the rear side, the gear-lack 62 on the front side and the rear side can be meshed with the second column gear 63 on the front side and the rear side respectively, the inner sides of the third rotating rod 61 on the front side are fixedly connected with the reel 64 on the rear side, the left side of the reaction frame 1 is fixedly connected with the first mounting seat 66, the two sliding harrow 67 on the inner sides of the top of the reaction frame 1 can be uniformly poked by glass fibers, the two sliding harrow 67 are slidably arranged in the first mounting seat 66, the reset spring 68 is connected between the two sliding harrow 67 and the first mounting seat 66, the rear side of the sliding harrow 69 is connected to the front and the two sides of the reel 69 on the front side of the front and the reel 69 respectively.

As shown in fig. 6, 10 and 11, the device further comprises a rubbing mechanism 7, the rubbing mechanism 7 comprises a second mounting seat 71, a sliding plate 72, a connecting frame 73, a pinch roller 74, an S-shaped groove plate 75, a connecting plate 76 and a guide rod 77, the right side of the top of the reaction frame 1 is fixedly connected with the second mounting seat 71, the sliding plate 72 is arranged in the second mounting seat 71 in a sliding manner, the connecting frame 73 is fixedly connected with the bottom of the sliding plate 72, the pinch roller 74 is rotatably arranged at the lower part of the connecting frame 73, flat glass fibers can be paved on the pinch roller 74, the S-shaped groove plate 75 is symmetrically and fixedly connected with the top of the sliding plate 72, the connecting plate 76 is fixedly connected with the upper part of the right side face of the sliding harrow claw 67 at the front and the rear, the guide rod 77 is fixedly connected with the right part of the connecting plate 76 at the front and the rear sides and the guide rod 77 is respectively positioned in the front and the S-shaped groove plate 75 at the front and the rear sides, the guide rod 77 is respectively in sliding connection with the front and the S-shaped groove plate 75 at the rear sides.

When the dual-shaft motor 41 works, the front and rear second rotating rods 52 rotate reversely to drive the front and rear short gears 62 to rotate reversely, the front and rear short gears 62 rotate reversely to be meshed with the front and rear second gears 63 respectively, the front and rear short gears 62 rotate reversely to drive the front and rear second gears 63 to rotate positively, the front and rear second gears 63 rotate positively to drive the front and rear reels 64 rotate positively, the front and rear reels 64 rotate positively to wind the front and rear pull ropes 69 respectively, the front and rear reels 64 drive the front and rear sliding rakes 67 to move outwards through the front and rear pull ropes 69 respectively, the reset springs 68 are compressed, the front and rear sliding rakes 67 move outwards to push away glass fibers evenly, the front and rear short gears 62 rotate reversely to separate from the front and rear second gears 63 respectively, the front and rear sliding rakes 67 move inwards to open the glass fibers again due to the effect of the reset springs 68, the fact that glass fibers are piled in the middle of the conveyer belt 44 is avoided, the effect of repeatedly opening the glass fibers uniformly is avoided, after all glass fiber reaction processing is completed, the front and rear sliding rakes 52 stop rotating respectively, the front and rear sliding rakes 62 stop moving inwards and outwards to avoid the effect of the conveyer belt 44.

When the double-shaft motor 41 works, the front and back sliding harrow feet 67 move inwards and outwards respectively to drive the front and back connecting plates 76 to move inwards and outwards respectively to drive the front and back guide rods 77 to move inwards and outwards respectively, the front and back guide rods 77 move inwards and outwards respectively through the front and back S-shaped groove plates 75 to enable the sliding plate 72 to move left and right, the sliding plate 72 moves left and right to drive the connecting frame 73 to move left and right, the connecting frame 73 moves left and right to drive the pressing wheel 74 to move left and right, the pressing wheel 74 moves left and right to uniformly tile glass fibers, so that the glass fibers react with pickling liquid better, after all glass fiber reaction treatment is completed, the double-shaft motor 41 is closed, the front and back sliding harrow feet 67 stop moving inwards and outwards respectively to drive the front and back guide rods 77 through the front and back connecting plates 76, and the pressing wheel 74 stops moving left and right.

Example 3

On the basis of embodiment 1 and embodiment 2, as shown in fig. 6 and 12, the device further comprises a material pressing mechanism 8, wherein the material pressing mechanism 8 comprises mounting plates 81 and cambered surface pressing plates 82, the lower parts of the two sliding rakes 67 are fixedly connected with the mounting plates 81, and the cambered surface pressing plates 82 are fixedly connected with the two mounting plates 81.

As shown in fig. 6, 13 and 14, the device further comprises a discharging mechanism 9, the discharging mechanism 9 comprises a receiving hopper 91 and a sponge block 92, the receiving hopper 91 is fixedly connected to the upper side of the right part of the reaction frame 1, the receiving hopper 91 can realize better discharging of glass fibers, and the sponge block 92 is fixedly connected to the left part of the receiving hopper 91.

When the double-shaft motor 41 works, the inner and outer movements of the front and rear sliding rakes 67 respectively drive the two mounting plates 81 to move inwards and outwards, the inner and outer movements of the two mounting plates 81 respectively drive the two cambered surface pressing plates 82 to move inwards and outwards, the inner and outer movements of the two cambered surface pressing plates 82 increase glass fiber raking efficiency, after all glass fiber reaction treatment is finished, the double-shaft motor 41 is closed, and the front and rear sliding rakes 67 respectively stop driving the inner and outer movements of the two cambered surface pressing plates 82 through the two mounting plates 81, so that the working effect of the sliding rakes 67 can be increased.

First, an operator places a collecting container under the receiving hopper 91, when the material conveying belt 44 positively rotates to drive glass fibers to move rightwards, the glass fibers rightwards move into the collecting container through the receiving hopper 91, and the sponge block 92 cleans the material conveying belt 44, so that residual impurities on the material conveying belt 44 are avoided, and the situation that the glass fibers are difficult to fall into the collecting container can be avoided.

It is to be understood that the above description is intended to be illustrative only and is not intended to be limiting. Those skilled in the art will appreciate variations of the present invention that are intended to be included within the scope of the claims herein.

Claims

1. The glass fiber surface treatment device comprises a reaction frame (1) and a blanking frame (3), wherein the blanking frame (3) is fixedly connected to the left side of the top of the reaction frame (1), and the glass fiber surface treatment device is characterized by further comprising a material conveying mechanism (4), and the reaction frame (1) is provided with the material conveying mechanism (4) for conveying glass fibers.

2. The glass fiber surface treatment device according to claim 1, further comprising supporting legs (2) and a pushing mechanism (5), wherein the supporting legs (2) are fixedly connected to the left side and the right side of the reaction frame (1), and the pushing mechanism (5) for generating deformation is arranged between the material conveying mechanism (4) and the reaction frame (1).

3. The glass fiber surface treatment device according to claim 1, wherein the material conveying mechanism (4) comprises a double-shaft motor (41), a mounting frame (42), a belt pulley (43) and a material conveying belt (44), the double-shaft motor (41) is fixedly connected to the left part of the reaction frame (1), the mounting frame (42) is fixedly connected to the front side and the rear side of the reaction frame (1), the belt pulleys (43) are uniformly and rotatably arranged between the mounting frames (42) on the front side and the rear side at intervals, and the belt pulley (44) is wound between the output shaft of the double-shaft motor (41) and the belt pulley (43) on the left side through synchronous belt transmission.

4. The glass fiber surface treatment device according to claim 2, wherein the pressing mechanism (5) comprises a first rotating rod (51), a second rotating rod (52), first column gears (53) and rotating press blocks (54), the first rotating rod (51) is symmetrically arranged on the left part of the reaction frame (1) in a front-back rotating mode, the first rotating rods (51) on the front side and the rear side are respectively and fixedly connected with an output shaft of the double-shaft motor (41) through synchronous belt transmission, the second rotating rod (52) is symmetrically arranged on the left part of the reaction frame (1) in a front-back mode, the second rotating rod (52) is located on the right side of the first rotating rod (51), four rotating press blocks (54) are rotatably arranged on the upper part of the reaction frame (1) at intervals, the left two rotating press blocks (54) are respectively and fixedly connected with the second rotating rods (52) on the front side and the rear side, the first rotating rods (51) on the front side and the second rotating rods (52) on the rear side are fixedly connected with the first column gears (53), and the first column gears (53) on the front side and the two first column gears (53) are meshed with each other.

5. The glass fiber surface treatment device according to claim 3, further comprising a refining mechanism (6) for stirring glass fibers, wherein the refining mechanism (6) comprises a third rotating rod (61), a gear-missing (62), a second column gear (63), a reel (64), a guide wheel (65), a first mounting seat (66), a sliding harrow claw (67), a return spring (68) and a pull rope (69), the outside of the second rotating rod (52) at the front and the rear sides is fixedly connected with the gear-missing (62), the left part of the reaction frame (1) is provided with the third rotating rod (61) in a front and rear symmetrical manner, the third rotating rod (61) is positioned at the right side of the second rotating rod (52), the outside of the third rotating rod (61) at the front and the rear sides is fixedly connected with the second column gear (63), the gear-missing (62) at the front and the rear sides is rotatably meshed with the second column gear (63) at the front and the rear sides respectively, the inner side of the third rotating rod (61) at the front and the rear sides is fixedly connected with the reel (64), the first mounting seat (66) is fixedly connected with the left side of the top of the reaction frame (1), the first rotating rod (66) is provided with the third rotating rod (61) and the slide harrow (67) is fixedly connected with the first rotating rod (64) at the front and the second rotating rod (67) at the rear side of the glass fiber, the tail ends of the pull ropes (69) at the front side and the rear side are fixedly connected with two sliding harrow claws (67) by respectively bypassing the guide wheels (65) at the front side and the rear side.

6. The glass fiber surface treatment device according to claim 4, further comprising a rubbing mechanism (7) for tiling glass fibers, wherein the rubbing mechanism (7) comprises a second mounting seat (71), a sliding plate (72), a connecting frame (73), a pressing wheel (74), an S-shaped groove plate (75), a connecting plate (76) and a guide rod (77), the second mounting seat (71) is fixedly connected to the right side of the top of the reaction frame (1), the sliding plate (72) is arranged in the second mounting seat (71), the connecting frame (73) is fixedly connected to the bottom of the sliding plate (72), the pressing wheel (74) for tiling glass fibers is rotatably arranged at the lower part of the connecting frame (73), the S-shaped groove plate (75) is fixedly connected to the front and rear sides of the sliding plate (72), the connecting plate (76) is fixedly connected to the upper part of the right side of the front and rear sliding harrow claws (67), the guide rods (77) are fixedly connected to the right side of the front and rear side connecting plate (76), the guide rods (77) are respectively located in the front and rear side S-shaped groove plates (75), and the front and rear side guide rods (77) are fixedly connected to the front and rear side guide rods (77) respectively.

7. The glass fiber surface treatment device according to claim 5, further comprising a pressing mechanism (8) for increasing the working efficiency of the sliding rakes (67), wherein the pressing mechanism (8) comprises mounting plates (81) and cambered surface pressing plates (82), the mounting plates (81) are fixedly connected to the lower portions of the two sliding rakes (67), and the cambered surface pressing plates (82) are fixedly connected to the two mounting plates (81).

8. The glass fiber surface treatment device according to claim 6, further comprising a discharging mechanism (9) for facilitating discharging, wherein the discharging mechanism (9) comprises a receiving hopper (91) and a sponge block (92), the receiving hopper (91) for facilitating discharging is fixedly connected to the upper side of the right part of the reaction frame (1), and the sponge block (92) is fixedly connected to the left part of the receiving hopper (91).