CN112941883A

CN112941883A - Glass fiber cloth quantitative shearing equipment

Info

Publication number: CN112941883A
Application number: CN202110120855.8A
Authority: CN
Inventors: 张全雷; 周扬; 张昭; 张鸿乐; 张廷然
Original assignee: Yuan Yuan New Materials Co ltd
Current assignee: Yuan Yuan New Materials Co ltd
Priority date: 2021-01-28
Filing date: 2021-01-28
Publication date: 2021-06-11
Anticipated expiration: 2041-01-28
Also published as: CN112941883B

Abstract

The invention relates to a cutting device, in particular to a glass fiber cloth quantitative cutting device. The invention provides a glass fiber cloth quantitative cutting device which can rapidly cut glass fiber cloth, can guide the glass fiber cloth to reduce wrinkles, and can clamp the glass fiber cloth to avoid shaking and displacement. The utility model provides a fine cloth ration of glass cuts equipment, is equipped with the support frame including bottom plate and support frame, bottom plate top, and the support frame top is equipped with drop feed mechanism, is equipped with guide mechanism on the drop feed mechanism, guide mechanism and drop feed mechanism cooperation. The discharging mechanism and the material guiding mechanism rotate to guide the glass fiber cloth so as to avoid the glass fiber cloth from being wrinkled; through being equipped with material clamping mechanism and drop feed mechanism, material clamping mechanism moves at the interval and can pulls the fine cloth of glass downwards, realizes need not the manual fine cloth of glass of pulling downwards of workman.

Description

Glass fiber cloth quantitative shearing equipment

Technical Field

The invention relates to a cutting device, in particular to a glass fiber cloth quantitative cutting device.

Background

The glass fiber cloth is divided into high-alkali cloth, medium-alkali cloth, alkali-free cloth and the like according to the alkali content, the lower the alkali content, the better the breaking resistance, generally, workers need to manually cut the glass fiber cloth into proper lengths before using the glass fiber cloth, the workers need to consume large strength to manually cut the glass fiber cloth, meanwhile, the workers cannot quickly straighten wrinkles on the surface of the glass fiber cloth, and the workers can shake and displace in the process of cutting the glass fiber cloth.

Therefore, the glass fiber cloth quantitative cutting equipment which can rapidly cut the glass fiber cloth, can guide the glass fiber cloth to reduce wrinkles and can clamp the glass fiber cloth to avoid shaking and displacement is urgently needed to be designed.

Disclosure of Invention

The invention aims to provide a glass fiber cloth quantitative cutting device which can rapidly cut glass fiber cloth, can guide the glass fiber cloth to reduce wrinkles, and can clamp the glass fiber cloth to avoid shaking and displacement, so as to solve the defects that in the background technology, a worker needs to consume large force to manually cut the glass fiber cloth, the worker cannot rapidly straighten the wrinkles on the surface of the glass fiber cloth, and the worker can shake and displace in the process of cutting the glass fiber cloth.

In order to achieve the purpose, the invention provides the following technical scheme: the utility model provides a fine cloth ration of glass cuts equipment, is equipped with the support frame including bottom plate and support frame, bottom plate top, and the support frame top is equipped with drop feed mechanism, is equipped with guide mechanism on the drop feed mechanism, guide mechanism and drop feed mechanism cooperation.

As the improvement of above-mentioned scheme, the welding of support frame top has the riser, is connected with the link between the riser upper portion both sides, and the rotary type is equipped with the coil stock pole between the link upper portion.

The improvement as above-mentioned scheme, the connecting plate has all been welded to riser top both sides, the rotary type is equipped with first cylinder between two connecting plate belows, the rotary type is equipped with the second cylinder between two connecting plate tops, first cylinder is located second cylinder below, the equal rotary type in connecting plate two parts is equipped with first transmission shaft, first gear is all installed at first cylinder both ends, all install the second gear on two first transmission shafts, first gear and second gear meshing, be connected with first pulley subassembly between first transmission shaft and the second cylinder, first pulley subassembly comprises two belt pulleys and belt, a belt pulley connection is on first transmission shaft, another belt pulley connection is on the second cylinder, the belt is around between two belt pulleys.

As the improvement of above-mentioned scheme, the riser middle part has the motor through the bolt rigid coupling, be connected with the second transmission shaft on the output shaft of motor, riser lower part rotary type is equipped with the bull stick, the third gear is all installed at the both ends of bull stick, be connected with the second belt pulley subassembly between second transmission shaft and the bull stick, the second belt pulley subassembly comprises two belt pulleys and belt, a belt pulley connection is on the second transmission shaft, another belt pulley connection is on the bull stick, the belt is around between two belt pulleys, riser lower part both sides all slidingtype are equipped with connects hollow pole, the rack bar has all been welded to two connection hollow pole inner walls, rack bar and third gear contact cooperation, the pin has all been welded to two connection hollow pole bottoms, the symmetry rigid coupling has the kickboard on the riser, pin upper portion rotary type is equipped with splint, the cover is equipped with clamping spring on the splint, the clamping spring.

As the improvement of above-mentioned scheme, two rack bar bottoms all weld and connect the pole, install the long slab on two connection poles, the equal symmetry rigid coupling in riser both sides lower part has vice tight piece of clamp of short, the vice tight piece of clamp of long is installed to the riser lower part, slidingtype is equipped with main tight piece of clamp between two vice tight pieces of clamp of horizontal homonymy, the main tight piece of clamp of downside and the cooperation of vice tight piece contact of clamp of long, short vice tight piece both sides all overlap and are equipped with first reset spring, first reset spring's both ends are connected respectively on vice tight piece of clamp of short and main tight piece of clamp, be connected with the connection pin between two main tight pieces of clamp.

As the improvement of above-mentioned scheme, the welding has short connecting rod on the main clamp splice of top, and the cutting knife is installed to short connecting rod bottom, and the equal rigid coupling in cutting knife both sides has first rack.

As the improvement of above-mentioned scheme, riser upper portion symmetrical welding has the fixed axle, and the fourth gear is installed to equal rotary type on two fixed axles, and riser upper portion symmetrical rigid coupling has the gag lever post, and the slidingtype is equipped with the piece that rises between the gag lever post, and the riser is worn out to the piece that rises, and the piece both sides that rise all weld has the second rack, and second rack and fourth gear contact cooperation are equipped with second reset spring on the gag lever post, and second reset spring's both ends are connected respectively on piece and the gag lever post that rises.

As a modification of the above, the shape of the stop lever is L-shaped.

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

1. the discharging mechanism and the material guiding mechanism rotate to guide the glass fiber cloth so as to avoid the glass fiber cloth from being wrinkled;

2. the glass fiber cloth can be pulled downwards by the material clamping mechanism moving at intervals through the material clamping mechanism and the material discharging mechanism, so that the glass fiber cloth is not required to be pulled downwards by a worker manually;

3. by arranging the clamping mechanism and the material clamping mechanism, the glass fiber cloth can be clamped by the clamping mechanism, and meanwhile, the glass fiber cloth is effectively prevented from shaking or displacing;

4. by arranging the cutting mechanism and the clamping mechanism, the cutting mechanism slides forwards and backwards at intervals, so that the glass fiber cloth can be cut off quickly;

5. by arranging the lifting mechanism and the cutting mechanism, the lifting mechanism slides forwards and backwards at intervals, and the cutting effect of the glass fiber cloth can be improved.

Drawings

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

Fig. 2 is a schematic perspective view of the discharging mechanism of the present invention.

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

Fig. 4 is a schematic perspective view of a part of the material guiding mechanism of the present invention.

Fig. 5 is a schematic perspective view of the material clamping mechanism of the present invention.

Fig. 6 is a schematic perspective view of the material clamping mechanism of the present invention.

Fig. 7 is a schematic perspective view of the clamping mechanism of the present invention.

Fig. 8 is a schematic perspective view of the cutting mechanism of the present invention.

Fig. 9 is a perspective view of the lifting mechanism of the present invention.

Fig. 10 is a partial perspective view of the lift mechanism of the present invention.

In the reference symbols: 1. a bottom plate, 2, a support frame, 3, a discharging mechanism, 31, a connecting frame, 32, a coiling rod, 33, a vertical plate, 4, a material guiding mechanism, 41, a connecting plate, 42, a first cylinder, 43, a second cylinder, 44, a first transmission shaft, 45, a first gear, 46, a second gear, 47, a first belt pulley assembly, 5, a clamping mechanism, 51, a motor, 52, a second transmission shaft, 53, a third gear, 531, a rotating rod, 54, a second belt pulley assembly, 55, a rack rod, 56, a connecting hollow rod, 57, a stop rod, 58, a shifting plate, 59, a clamping plate, 510, a clamping spring, 6, a clamping mechanism, 61, a long plate, 62, a connecting round rod, 63, a short auxiliary clamping block, 64, a long auxiliary clamping block, 65, a main clamping block, 66, a first return spring, 67, a connecting thin rod, 7, a cutting mechanism, 71, a cutting knife, 72, a short connecting rod, 73, a first rack, 8. the lifting mechanism 81, the fixed shaft 82, the fourth gear 83, the second rack 84, the lifting block 85, the limiting rod 86 and the second return spring.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1-10, the present invention provides a technical solution: a glass fiber cloth quantitative cutting device comprises a bottom plate 1, a support frame 2, a discharging mechanism 3, a connecting frame 31, a material rolling rod 32, a vertical plate 33, a material guiding mechanism 4, a connecting plate 41, a first cylinder 42, a second cylinder 43, a first transmission shaft 44, a first gear 45, a second gear 46, a first belt pulley assembly 47, a material clamping mechanism 5, a motor 51, a second transmission shaft 52, a third gear 53, a rotating rod 531, a second belt pulley assembly 54, a rack rod 55, a connecting hollow rod 56, a stop rod 57, a shifting plate 58, a clamping plate 59, a clamping spring 510, a clamping mechanism 6, a long plate 61, a connecting round rod 62, a short auxiliary clamping block 63, a long auxiliary clamping block 64, a main clamping block 65, a first return spring 66, a connecting thin rod 67, a cutting mechanism 7, a cutting knife 71, a short connecting rod 72, a first rack 73, a lifting mechanism 8, a 81, a fourth gear 82, a second rack 83, The lifting device comprises a lifting block 84, a limiting rod 85 and a second return spring 86, wherein a support frame 2 is arranged at the top of a bottom plate 1, a discharging mechanism 3 is arranged at the top end of the support frame 2, a material guide mechanism 4 is arranged on the discharging mechanism 3, and the material guide mechanism 4 is matched with the discharging mechanism 3.

The top welding of support frame 2 has riser 33, is connected with link 31 between the riser 33 upper portion left and right sides, and the rotary type is equipped with coil stock pole 32 between link 31 upper portion.

Connecting plate 41 has all been welded to the riser 33 top left and right sides, the rotary type is equipped with first cylinder 42 between two connecting plate 41 below, the rotary type is equipped with second cylinder 43 between two connecting plate 41 tops, first cylinder 42 is located second cylinder 43 below, connecting plate 41 front side left and right sides equal rotary type in both parts is equipped with first transmission shaft 44, first gear 45 is all installed at both ends about first cylinder 42, all install second gear 46 on two first transmission shafts 44, first gear 45 and the meshing of second gear 46, be connected with first pulley subassembly 47 between first transmission shaft 44 and the second cylinder 43, first pulley subassembly 47 comprises two belt pulleys and belt, a belt pulley connection is on first transmission shaft 44, another belt pulley connection is on second cylinder 43, the belt is around between two belt pulleys.

A motor 51 is fixedly connected to the middle part of the rear side of the vertical plate 33 through bolts, a second transmission shaft 52 is connected to an output shaft of the motor 51, a rotating rod 531 is rotatably arranged on the lower part of the rear side of the vertical plate 33, third gears 53 are installed at two ends of the rotating rod 531, a second belt pulley component 54 is connected between the second transmission shaft 52 and the rotating rod 531, the second belt pulley component 54 consists of two belt pulleys and a belt, one belt pulley is connected to the second transmission shaft 52, the other belt pulley is connected to the rotating rod 531, the belt is wound between the two belt pulleys, connecting hollow rods 56 are slidably arranged on the left side and the right side of the lower part of the rear side of the vertical plate 33, rack rods 55 are welded on the inner walls of the two connecting hollow rods 56, the rack rods 55 are in contact fit with the third gears 53, stop rods 57 are welded at the bottom ends of the two connecting hollow rods 56, a shifting plate, the clamping plate 59 is sleeved with a clamping spring 510, and two ends of the clamping spring 510 are respectively connected to the clamping plate 59 and the stop lever 57.

The bottom of two rack rods 55 all has welded and has connected pole 62, install long board 61 on two connection pole 62, the equal symmetry rigid coupling in riser 33 left and right sides lower part has short vice clamping piece 63, long vice clamping piece 64 is installed to riser 33 front side lower part, slidingtype is equipped with main clamping piece 65 between two short vice clamping piece 63 of horizontal homonymy, main clamping piece 65 and the contact cooperation of long vice clamping piece 64 of downside, short vice clamping piece 63 all overlaps on both sides is equipped with first reset spring 66 about, the both ends of first reset spring 66 are connected respectively on short vice clamping piece 63 and main clamping piece 65, be connected with between two main clamping piece 65 and connect pin 67.

The short connecting rod 72 is welded on the front side of the main clamping block 65 above, the cutting knife 71 is installed at the bottom end of the short connecting rod 72, and the first racks 73 are fixedly connected to the left side and the right side of the cutting knife 71.

The upper portion of the vertical plate 33 is symmetrically welded with the fixed shaft 81, the four gears 82 are mounted on the two fixed shafts 81 in an equal rotating mode, the limiting rods 85 are symmetrically fixedly connected to the upper portion of the rear side of the vertical plate 33, the lifting blocks 84 are arranged between the limiting rods 85 in a sliding mode, the vertical plate 33 is penetrated out of the front side of the lifting blocks 84, the second racks 83 are welded to the left side and the right side of the lifting blocks 84, the second racks 83 are in contact fit with the fourth gears 82, the limiting rods 85 are sleeved with the second reset springs 86, and the two ends of the second reset springs 86 are connected to the lifting blocks 84 and.

When a worker needs to cut off the glass fiber cloth, the worker firstly needs to put the glass fiber cloth on the discharging mechanism 3, then the worker can rotate the material guiding mechanism 4, the material guiding mechanism 4 rotates to drive the discharging mechanism 3 to rotate, the discharging mechanism 3 can slowly discharge the glass fiber cloth, the material guiding mechanism 4 can guide the glass fiber cloth to avoid wrinkles, then the worker can manually pull the glass fiber cloth downwards, after the glass fiber cloth is pulled out by the worker to a proper length, the worker can cut off the glass fiber cloth by using a cutter, when the worker does not need to cut off the glass fiber cloth temporarily, the worker can temporarily rotate the discharging mechanism 3, then the material guiding mechanism 4 can stop rotating along with the glass fiber cloth, if the worker needs to continue to cut off the glass fiber cloth, the worker repeats the operation again, and the device can quickly cut off the glass fiber cloth as required.

The workman can put the glass fiber cloth on the coiling material pole 32, and the workman can make the coiling material pole 32 internal rotation in the link span 31 afterwards, and the coiling material pole 32 can slowly emit the glass fiber cloth, and the riser 33 can carry on spacingly to the glass fiber cloth, and when the workman need not emit the glass fiber cloth for a while, the workman stops temporarily to rotate the coiling material pole 32 can, if the workman still need continue to emit the glass fiber cloth, the workman repeats above-mentioned operation once more, and this equipment can be as required quick emits the glass fiber cloth.

In order to avoid wrinkles of the glass fiber cloth, a worker can rotate the first cylinder 42 in the connecting plate 41, the first cylinder 42 rotates to drive the first gear 45 to rotate, the first gear 45 rotates to drive the second gear 46 to rotate, the second gear 46 rotates to drive the first transmission shaft 44 to rotate, the first belt pulley assembly 47 rotates along with the first cylinder, the first belt pulley assembly 47 rotates to drive the second cylinder 43 to rotate, the first cylinder 42 and the second cylinder 43 rotate to guide the glass fiber cloth to avoid wrinkles of the glass fiber cloth, when the worker does not need to guide the glass fiber cloth for a while, the worker stops rotating the first cylinder 42, the first cylinder 42 and the second cylinder 43 rotate to stop guiding the glass fiber cloth for a while, if the worker needs to continue to guide the glass fiber cloth, the worker repeats the above operation again, the device can guide the glass fiber cloth again to avoid wrinkles of the glass fiber cloth, thereby effectively increasing the flatness of the glass fiber cloth and facilitating subsequent use.

The worker pulls out the glass fiber cloth downwards and needs to consume large strength, the worker needs to control the motor 51 to rotate, the output rotation of the motor 51 can drive the second transmission shaft 52 to rotate, the second transmission shaft 52 rotates and drives the second belt pulley assembly 54 to rotate, and then the third gear 53 and the rotating rod 531 rotate along with the second transmission shaft, the third gear 53 rotates and can drive the rack rod 55 and the connecting hollow rod 56 to slide upwards, the connecting hollow rod 56 slides upwards and can drive the stop rod 57 and the clamping plate 59 to move upwards, the clamping spring 510 moves upwards along with the second transmission shaft, when the clamping plate 59 moves upwards to be in contact with the shifting plate 58 above, the shifting plate 58 can drive the clamping plate 59 to rotate, when the clamping plate 59 rotates to be in contact with the stop rod 57, the clamping plate 59 can clamp the glass fiber cloth, the clamping spring 510 can increase the clamping force of the clamping plate 59, the worker can control the motor 51 to rotate reversely, the output reverse rotation of the motor 51 can drive, the second transmission shaft 52 rotates reversely to drive the second belt pulley assembly 54 to rotate, and then the third gear 53 and the rotating rod 531 rotate along with the third gear 53, the third gear 53 rotates to enable the rack rod 55 and the connecting hollow rod 56 to slide downwards, the connecting hollow rod 56 slides downwards to drive the stop rod 57 and the clamping plate 59 to move downwards, the clamping plate 59 moves downwards to pull the glass fiber cloth downwards, the clamping spring 510 moves upwards along with the clamping plate 53, when the clamping plate 59 moves upwards to be in contact with the shifting plate 58 below, the shifting plate 58 enables the clamping plate 59 to rotate and reset, when the clamping plate 59 rotates to be temporarily stopped to be in contact with the stop rod 57, the clamping plate 59 releases the glass fiber cloth, the clamping spring 510 resets, so that the glass fiber cloth can be pulled downwards at intervals at the top, and the labor intensity of workers is effectively relieved.

In order to reduce the shaking or displacement of the glass fiber cloth during the cutting process, when the connecting hollow rod 56 moves upwards, the connecting hollow rod 56 moves upwards to drive the long plate 61 and the connecting round rod 62 to move upwards, when the long plate 61 moves upwards to be contacted with the main clamping block 65 at the lower side, the long plate 61 pushes the main clamping block 65 at the lower side to slide forwards on the short auxiliary clamping block 63, the first return spring 66 is compressed, the connecting thin rod 67 can drive the main clamping block 65 at the upper side to slide synchronously, when the main clamping block 65 at the lower side slides forwards to temporarily stop being contacted with the long auxiliary clamping block 64, the long auxiliary clamping block 64 and the main clamping block 65 can temporarily stop clamping the glass fiber cloth, when the connecting hollow rod 56 moves downwards, the connecting hollow rod 56 moves downwards to drive the long plate 61 and the connecting round rod 62 to move downwards, and when the long plate 61 moves downwards to temporarily stop being contacted with the main clamping block 65, first reset spring 66 reset action, first reset spring 66 can make main clamping block 65 slide to the rear on short vice clamping block 63 and reset, and main clamping block 65 slides to the rear to when contacting with long vice clamping block 64, and long vice clamping block 64 and main clamping block 65 can press from both sides the fine cloth of glass tightly, and this equipment can press from both sides the fine cloth of glass tightly so, and the fine cloth of effectual avoidance glass rocks or the displacement appears.

A worker needs to spend a great deal of effort to cut the glass cloth using the cutter, and when the main clamping block 65 moves to the rear side, the main clamping block 65 will drive the short connecting rod 72 to move backward, the short connecting rod 72 will drive the cutter 71 to move backward, the cutter 71 will drive the first rack 73 to move backward, the cutter 71 will cut the fiberglass cloth when moving backward, when the main clamping block 65 moves forward, the main clamping block 65 will drive the short connecting rod 72 to move forward, the short connecting rod 72 will drive the cutting knife 71 to move forward, the cutting knife 71 will drive the first rack 73 to move forward, the cutting knife 71 will stop cutting the glass fiber cloth temporarily when moving forward, if the worker needs to continuously cut the glass fiber cloth, the worker repeats the operation again, and the device can quickly cut the glass fiber cloth.

In order to further increase the cutting effect of the glass fiber cloth, when the first rack 73 moves to the rear side, the first rack 73 can make the fourth gear 82 rotate on the fixed shaft 81, the fourth gear 82 rotates to drive the second rack 83 to move to the front side, the second rack 83 moves to the front side to drive the lifting block 84 to slide to the front side in the vertical plate 33 through the limiting rod 85, the cutting knife 71 and the lifting block 84 can increase the cutting effect of the glass fiber cloth, the second return spring 86 is stretched, when the first rack 73 moves to the front side, the first rack 73 can make the fourth gear 82 rotate reversely on the fixed shaft 81, the fourth gear 82 rotates to drive the second rack 83 to move to the rear side, the second rack 83 moves to the rear side to drive the lifting block 84 to slide to the rear side in the limiting rod 85 in the vertical plate 33, the second return spring 86 is reset to assist the lifting block 84 to slide to the rear side, if the worker needs to further increase the cutting effect of the glass fiber cloth, the worker repeats the above operation again.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims

1. The utility model provides a fine cloth ration of glass cuts equipment, includes bottom plate (1) and support frame (2), characterized by, and bottom plate (1) top is equipped with support frame (2), and support frame (2) top is equipped with drop feed mechanism (3), is equipped with guide mechanism (4) on drop feed mechanism (3), and guide mechanism (4) and drop feed mechanism (3) cooperation.

2. A quantitative cutting apparatus for fiberglass cloth according to claim 1, wherein a riser (33) is welded to the top of the supporting frame (2), a connecting frame (31) is connected between two sides of the upper part of the riser (33), and a winding rod (32) is rotatably arranged between the upper parts of the connecting frame (31).

3. The quantitative shearing device of the fiberglass cloth as claimed in claim 2, wherein the connecting plates (41) are welded on both sides of the top end of the vertical plate (33), the first cylinders (42) are rotatably arranged below the two connecting plates (41), the second cylinders (43) are rotatably arranged above the two connecting plates (41), the first cylinders (42) are positioned below the second cylinders (43), the first transmission shafts (44) are rotatably arranged on both sides of the connecting plates (41), the first gears (45) are respectively arranged at both ends of the first cylinders (42), the second gears (46) are respectively arranged on the two first transmission shafts (44), the first gears (45) are meshed with the second gears (46), the first pulley assembly (47) is connected between the first transmission shafts (44) and the second cylinders (43), the first pulley assembly (47) is composed of two pulleys and a belt, one pulley is connected to the first drive shaft (44) and the other pulley is connected to the second cylinder (43), with the belt being wound between the two pulleys.

4. A glass fiber cloth quantitative cutting device according to claim 3, characterized in that a motor (51) is fixedly connected to the middle of a vertical plate (33) through a bolt, a second transmission shaft (52) is connected to an output shaft of the motor (51), a rotating rod (531) is rotatably arranged at the lower part of the vertical plate (33), third gears (53) are respectively installed at two ends of the rotating rod (531), a second belt pulley component (54) is connected between the second transmission shaft (52) and the rotating rod (531), the second belt pulley component (54) is composed of two belt pulleys and a belt, one belt pulley is connected to the second transmission shaft (52), the other belt pulley is connected to the rotating rod (531), the belt is wound between the two belt pulleys, connecting hollow rods (56) are respectively arranged at two sides of the lower part of the vertical plate (33) in a sliding manner, rack rods (55) are welded on the inner walls of the two connecting hollow rods (56), and the rack rods (55) are in contact, the bottom ends of the two connecting hollow rods (56) are respectively welded with a stop lever (57), the vertical plate (33) is symmetrically and fixedly connected with a shifting plate (58), the upper part of the stop lever (57) is rotatably provided with a clamping plate (59), the clamping plate (59) is sleeved with a clamping spring (510), and two ends of the clamping spring (510) are respectively connected to the clamping plate (59) and the stop lever (57).

5. A glass fiber cloth quantitative cutting device according to claim 4, characterized in that connecting round rods (62) are welded at the bottom ends of two rack rods (55), long plates (61) are installed on the two connecting round rods (62), short auxiliary clamping blocks (63) are symmetrically and fixedly connected to the lower portions of two sides of a vertical plate (33), long auxiliary clamping blocks (64) are installed on the lower portions of the vertical plate (33), main clamping blocks (65) are slidably arranged between the two short auxiliary clamping blocks (63) on the same lateral side, the main clamping blocks (65) on the lower side are in contact fit with the long auxiliary clamping blocks (64), first return springs (66) are sleeved on two sides of each short auxiliary clamping block (63), two ends of each first return spring (66) are respectively connected to the short auxiliary clamping blocks (63) and the main clamping blocks (65), and connecting thin rods (67) are connected between the two main clamping blocks (65).

6. A glass fiber cloth quantitative cutting device according to claim 5, wherein a short connecting rod (72) is welded on the upper main clamping block (65), a cutting knife (71) is installed at the bottom end of the short connecting rod (72), and first racks (73) are fixedly connected to two sides of the cutting knife (71).

7. The glass fiber cloth quantitative cutting equipment as claimed in claim 6, wherein fixing shafts (81) are symmetrically welded to the upper portions of vertical plates (33), fourth gears (82) are rotatably mounted on the two fixing shafts (81), limiting rods (85) are symmetrically and fixedly connected to the upper portions of the vertical plates (33), lifting blocks (84) are slidably arranged between the limiting rods (85), the lifting blocks (84) penetrate through the vertical plates (33), second racks (83) are welded to the two sides of the lifting blocks (84), the second racks (83) are in contact fit with the fourth gears (82), second return springs (86) are sleeved on the limiting rods (85), and the two ends of the second return springs (86) are connected to the lifting blocks (84) and the limiting rods (85) respectively.

8. A quantitative cutting apparatus for fiberglass cloth according to claim 4, wherein the shape of the stop lever (57) is L-shaped.