CN212497923U - Glass fiber coiled material cutting device - Google Patents

Abstract

The application discloses a glass fiber coiled material cutting device, which relates to the technical field of cutting of glass fiber coiled materials, and the technical scheme is characterized by comprising a rack, a cutting plate arranged on the rack and a cutting assembly arranged on the rack, wherein the rack is respectively provided with a feeding assembly and a transmission assembly, and the feeding assembly, the cutting assembly and the transmission assembly are sequentially distributed along the transmission direction of glass fibers; the feeding assembly places the glass fiber coiled material in the frame, and the feeding assembly drives the glass fiber coiled material to move, and the cutting assembly cuts the glass fiber coiled material, thereby the transmission assembly drives the glass fiber that accomplishes the cutting again and removes and leave the frame to this degree of automation that improves glass fiber and cut reduces the time that glass fiber cut in-process cost, improves work efficiency.

Description

Glass fiber coiled material cutting device

Technical Field

The application relates to the technical field of cutting of glass fiber coiled materials, in particular to a cutting device for glass fiber coiled materials.

Background

The glass fiber is an inorganic non-metallic material with excellent performance, has good properties of insulation, heat resistance and the like, and is generally used as a reinforcing material in a composite material; in the production process, in order to meet different production requirements, the glass fiber is cut into different shapes by the equipment.

The utility model discloses a chinese utility model patent that grant bulletin number is CN206418027U discloses an automatic cutting device of dry process glass fiber coiled material, including operation platform, set up the support on operation platform, the operation platform below is equipped with the cylinder, and the support passes through the telescopic link and the cylinder is to being connected, is equipped with the cutter on the support, is equipped with the control box on the operation platform, and the control box is connected with the cylinder to being equipped with hand switch.

When the glass fiber cutting machine works, after cutting is finished every time, workers are required to manually take off the cut glass fibers and manually lay new glass fibers again, and therefore the process is repeated, the automation degree in the process is low, time is consumed in the cutting process, and the efficiency is low.

SUMMERY OF THE UTILITY MODEL

To the not enough of prior art existence, this application provides a glass fiber coiled material cutting device, and its advantage lies in glass fiber degree of automation when cutting is higher, reduces the time that glass fiber was spending at the in-process that cuts, improves work efficiency.

The application is realized by the following technical scheme:

the utility model provides a glass fiber coiled material cutting device, includes the frame, sets up the cutting board in the frame and sets up respectively in the frame and be used for placing glass fiber coiled material's material loading subassembly and be used for cutting glass fiber's cutting means, be equipped with respectively in the frame and be used for sending glass fiber to the pay-off subassembly on the cutting board and be used for transmitting the glass fiber's that the completion cut transmission assembly, material loading subassembly, pay-off subassembly, cutting means and transmission assembly distribute along glass fiber's transmission direction in proper order.

Through adopting above-mentioned technical scheme, when beginning to cut the glass fiber coiled material, place the glass fiber coiled material in the frame through the material loading subassembly, drive the glass fiber coiled material through the pay-off subassembly and remove to being close to cutting assembly one side, cutting assembly cuts the glass fiber coiled material, the transmission assembly drives the glass fiber removal of accomplishing the cutting again and leaves the frame, the pay-off subassembly continues to drive glass fiber again and removes to one side that is close to cutting assembly, repeat above-mentioned step, thereby constantly accomplish cutting the glass fiber coiled material, with this degree of automation that improves glass fiber and cut, reduce the time that glass fiber cuts the in-process cost, and the work efficiency is improved.

Furthermore, the feeding assembly comprises a feeding motor arranged on the rack, a feeding roller arranged on an output shaft of the feeding motor and an auxiliary roller rotatably connected to the cutting plate, the auxiliary roller and the feeding roller are arranged oppositely, a feeding gap for glass fibers to pass through is formed between the auxiliary roller and the feeding roller, and the auxiliary roller and the feeding roller are respectively abutted against two sides of the glass fibers.

Through adopting above-mentioned technical scheme, the glass fiber coiled material passes the pay-off clearance, starts the pay-off motor, and the pay-off motor drives the transmission roller and rotates, and transmission roller and auxiliary roller rub with glass fiber's both sides face respectively to drive glass fiber and remove, glass fiber thus continuously pass the pay-off clearance, and the auxiliary roller reduces the area of contact between glass fiber and the cutting plate, reduces the frictional force between glass fiber and the cutting plate.

Furthermore, be equipped with the pay-off frame in the frame, the pay-off motor with the feed roll all is located the pay-off frame, be equipped with the connecting plate on the pay-off motor, the connecting plate slides and connects on the inside wall of pay-off frame, it is connected with the slide to slide on the inside wall of pay-off frame, the feed roll with the slide rotates to be connected, be equipped with the feeding cylinder on the pay-off frame, be equipped with respectively with connecting plate and slide fixed connection's arm-tie on the piston rod of feeding cylinder.

Through adopting above-mentioned technical scheme, before glass fiber passed the pay-off clearance, drive the piston rod shrink of pay-off cylinder, thereby it removes to drive the arm-tie, the arm-tie drives connecting plate and slide and slides, thereby drive the transmission roller and remove to the one side of keeping away from the auxiliary roll, increase the space in pay-off clearance, make things convenient for glass fiber to pass the pay-off clearance, after glass fiber passed the pay-off clearance, the piston rod of redrive pay-off cylinder stretches out, thereby promote the arm-tie and remove, the arm-tie drives connecting plate and slide and removes, thereby it removes to the one side that is close to the auxiliary roll to drive the transmission roller, thereby the transmission roller offsets.

Further, the feeding component comprises a feeding frame arranged on the rack, a lifting rod arranged on the feeding frame, and a feeding roller which is arranged on the lifting rod and is sleeved with a glass fiber coiled material, wherein a baffle is arranged on one side, far away from the feeding frame, of the lifting rod.

Through adopting above-mentioned technical scheme, when the material loading, place the material loading roller on taking the pole earlier, when glass fiber transmission, glass fiber drives the material loading roller and rotates to the continuous glass fiber coiled material that becomes flexible, the moving range of baffle restriction material loading roller reduces the material loading roller and rotates the possibility that the in-process dropped.

Further, be equipped with two gyro wheels that set up relatively on the roof of taking the pole, the material loading roller is placed two between the gyro wheel, the gyro wheel with the material loading roller is inconsistent.

Through adopting above-mentioned technical scheme, the frictional force that produces between gyro wheel reduction material loading roller and the take-up beam improves the rotation performance of material loading roller.

Furthermore, a feeding arc plate is arranged on the feeding frame and faces the feeding gap.

Through adopting above-mentioned technical scheme, glass fiber leaves the material loading roller after, falls on the material loading arc board, gets into the pay-off clearance through the material loading arc board again to this reduces glass fiber and piles up the possibility on the cutting board.

Further, pay-off subassembly is including setting up transmission motor in the frame, setting in the frame and with transmission motor's output shaft fixed connection's transmission roller and rotate the live-rollers of connection in the frame, the cover is equipped with transmission belt on the transmission roller, one side cover that transmission belt kept away from the transmission roller is established on the live-rollers.

Through adopting above-mentioned technical scheme, the glass fiber who accomplishes the cutting falls on the transmission belt, starts transmission motor, and transmission motor drives the transmission roller and rotates, and the transmission roller drives the transmission belt and rotates, and transmission belt and glass fiber rub to drive glass fiber smoothly and remove, leave the frame, reduce glass fiber and pile up the possibility in the frame.

Further, the cutting assembly comprises a cutting frame arranged on the rack, a cutting cylinder arranged on the cutting frame and a cutting knife connected to the cutting frame in a sliding mode, a piston rod of the cutting cylinder is fixedly connected with the cutting knife, and the cutting edge of the cutting knife faces towards one side of the cutting plate.

Through adopting above-mentioned technical scheme, glass fiber passes cutting frame when removing, and the piston rod that cuts the cylinder stretches out to thereby promote to cut the sword and be close to glass fiber, thereby cut the sword and extrude with glass fiber mutually and cut off glass and accomplish, accomplish and cut, with this improvement and cut the degree of automation of in-process.

In summary, the present application has the following beneficial effects:

1. when cutting is started, firstly, a glass fiber coiled material is fed into the rack through the feeding assembly, then the feeding assembly drives the glass fibers to move, the glass fibers are close to the cutting assembly, the cutting assembly cuts the glass fibers according to the processing requirements, after cutting is completed, the conveying assembly drives the glass fibers to leave the rack, meanwhile, the feeding assembly continues to drive the glass fiber coiled material to be close to the cutting assembly, and the steps are repeated continuously, so that the time spent in the glass fiber cutting process is reduced, and the working efficiency is improved;

2. the contact area between the feeding roller and the lapping rod is reduced by the roller, the friction force between the feeding roller and the lapping rod is reduced, and the rotation performance of the feeding roller is improved;

3. after leaving the feeding roller, the glass fiber falls into the feeding arc plate and smoothly enters the feeding gap through the transmission of the feeding arc plate.

Drawings

Fig. 1 is a schematic structural diagram of the embodiment.

Fig. 2 is a partial structure view of fig. 1 taken along the direction of a-a.

Fig. 3 is a partial structural view in section from B-B in fig. 1.

In the figure: 1. a frame; 11. cutting the board; 2. a feeding assembly; 21. a feeding frame; 22. building a rod; 221. a roller; 23. a baffle plate; 24. a feeding roller; 25. feeding an arc plate; 3. a feeding assembly; 31. a feeding frame; 311. a connecting plate; 312. connecting blocks; 313. connecting grooves; 314. a slide plate; 315. a slider; 316. a chute; 317. a feeding cylinder; 318. pulling a plate; 319. connecting plates; 32. a feeding motor; 33. a feed roller; 34. an auxiliary roller; 35. a feeding gap; 4. cutting the assembly; 41. a cutting frame; 42. cutting knife; 43. a cutting cylinder; 5. a transmission assembly; 51. a transmission motor; 52. a transfer roller; 53. a rotating roller; 54. a transfer belt; 55. and a collection box.

Detailed Description

The present application is described in further detail below with reference to the attached drawings.

Example (b):

referring to fig. 1, a glass fiber coiled material cutting device, which comprises a frame 1, a cutting plate 11, a feeding assembly 2 for placing a glass fiber coiled material, a feeding assembly 3 for driving glass fibers to move, a cutting assembly 4 for cutting the glass fibers, and a transmission assembly 5 for transmitting the cut glass fibers, wherein the frame 1 is fixed on the ground, the cutting plate 11 is fixed on the frame 1, and the feeding assembly 2, the feeding assembly 3, the cutting assembly 4, and the transmission assembly 5 are all fixed on the frame 1 and distributed along the length direction of the frame 1.

Referring to fig. 1, a collecting box 55 is arranged on one side of the frame 1 away from the feeding assembly 2; when cutting the glass fiber coiled material, earlier place the frame 1 through material loading subassembly 2 with the glass fiber coiled material on, rethread pay-off subassembly 3 drives glass fiber and removes to one side that is close to cutting assembly 4, and cutting assembly 4 cuts glass fiber again, and the glass fiber who accomplishes the cutting leaves frame 1 through transmission assembly 5, and the glass fiber who leaves frame 1 falls into in collecting box 55.

Referring to fig. 1, the feeding assembly 3 continues to drive the glass fiber coiled material to move, and the steps are repeated, so that the automation degree of the glass fiber coiled material in the cutting process is improved, the rolling consumed by the glass fiber coiled material in the cutting process is saved, and the working efficiency is improved.

Referring to fig. 1, material loading component 2 includes material loading frame 21, take pole 22 and baffle 23, material loading frame 21 welds on 1 roof of frame, material loading frame 21 sets up along the direction of height of frame 1, it fixes in the one side that material loading frame 21 is close to material loading component 3 to take pole 22, it sets up along the length direction of frame 1 to take pole 22, it adopts a plurality of to take pole 22, a plurality of takes two liang of relative settings of pole 22, a plurality of takes pole 22 along the length direction equipartition of material loading frame 21, baffle 23 sets up in one side that material loading frame 21 was kept away from to take pole 22, baffle 23 sets up along the direction of height of material loading frame 21.

Referring to fig. 1, the top wall of the connecting rod 22 is rotatably connected with two rollers 221, the two rollers 221 are oppositely arranged and uniformly distributed along the length direction of the connecting rod 22, a feeding roller 24 is arranged between the two rollers 221, the rollers 221 are abutted against the side surface of the feeding roller 24, and the glass fiber coiled material is wound on the feeding roller 24; during feeding, firstly, the glass fiber is sleeved on the feeding roller 24, the feeding rollers 24 are sleeved at the same time, and then the feeding roller 24 is erected between the two idler wheels 221, so that when the glass fiber moves, the feeding roller 24 is driven to rotate, the idler wheels 221 reduce the friction force between the feeding roller 24 and the erecting rod 22, and the feeding roller 24 is convenient to rotate; the glass fibers are thereby continuously released from the feed roll 24; the baffle 23 limits the moving range of the feeding roller 24, and reduces the possibility that the feeding roller 24 falls off from the stopper rod.

Referring to fig. 2, a feeding frame 31 is fixedly connected to the frame 1, a connection plate 311 is disposed on an inner side wall of the feeding frame 31, a connection block 312 is integrally formed on one side of the connection plate 311 close to the feeding frame 31, a connection groove 313 for allowing the connection block 312 to slide is disposed on the inner side wall of the feeding frame 31, a sliding plate 314 is disposed on one side of the feeding frame 31 far away from the connection plate 311, a sliding block 315 is disposed on one side of the sliding plate 314 close to the feeding frame 31, and a sliding groove 316 for allowing the sliding block 315 to slide is disposed on the.

Referring to fig. 2, the feeding assembly 3 includes a feeding motor 32, a feeding roller 33 and an auxiliary roller 34, the feeding motor 32 is fixed on one side of the connecting plate 311 away from the connecting block 312, a feeding shaft 321 is arranged on an output shaft of the feeding motor 32, the feeding roller 33 is fixed on the feeding shaft 321, the feeding roller 33 is in interference fit with the feeding shaft 321, the feeding roller 33 is arranged along the width direction of the rack 1, one end of the feeding roller 33 away from the feeding motor 32 is rotatably connected with the side surface of the sliding plate 314, the auxiliary roller 34 is rotatably connected to the cutting plate 11, the auxiliary roller 34 is arranged opposite to the feeding roller 33, and a feeding gap 35 for glass fibers to pass through is formed between the auxiliary roller 34 and the feeding.

Referring to fig. 2, a feeding cylinder 317 is fixedly connected to the top wall of the feeding frame 31, the feeding cylinder 317 is arranged in the height direction of the feeding frame 31 of the rack 1, a piston rod of the feeding cylinder 317 is arranged in the height direction of the rack 1, the piston rod of the feeding cylinder 317 penetrates through the feeding frame 31 and is connected with the feeding frame 31 in a sliding manner, a pulling plate 318 is welded to the end wall of the piston rod of the feeding cylinder 317, and the pulling plate 318 is arranged in the axial direction of the feeding roller 33.

Referring to fig. 2, the pull plate 318 is provided with connecting plates 319 on both sides, the connecting plates 319 are arranged along the thickness direction of the pull plate 318, and one sides of the two connecting plates 319 far away from the pull plate 318 are respectively welded with the connecting plate 311 and the sliding plate 314.

Referring to fig. 1 and 2, a feeding arc plate 25 is arranged on the feeding frame 21, the feeding arc plate 25 is arranged along the length direction of the frame 1, one side of the feeding arc plate 25, which is far away from the feeding frame 21, is arranged towards the feeding gap 35, and the distance between the feeding arc plate 25 and the cutting plate 11 decreases progressively from one side, which is far away from the feeding frame 21, to one side, which is close to the feeding roller 33; during the glass fiber transfer, the glass fibers leaving the feeding roller 24 fall into the feeding arc plate 25, and the feeding arc plate 25 conveys the glass fibers to a side close to the feeding gap 35.

Referring to fig. 2, after the glass fiber is close to the feeding gap 35, the piston rod of the feeding cylinder 317 is driven to contract, so as to drive the pulling plate 318 to move, the pulling plate 318 further drives the connecting plate 319 to move, and the connecting plate 319 respectively drives the connecting plate 311 and the sliding plate 314 to slide, so as to drive the feeding motor 32 and the feeding roller 33 to move towards the side far away from the auxiliary roller 34, thereby increasing the feeding gap 35, and facilitating the smooth insertion of the glass fiber into the feeding gap 35.

Referring to fig. 2, after the glass fiber passes through the feeding gap 35, the piston rod of the feeding cylinder 317 is driven to extend out, so that the pulling plate 318 is pushed to move, the pulling plate 318 pushes the connecting plate 319 to move, the connecting plate 319 pushes the feeding roller 33 to be close to the auxiliary roller 34, the feeding gap 35 is reduced, and the feeding roller 33 and the auxiliary roller 34 are matched to extrude the glass fiber; and then the feeding motor 32 is driven, the feeding motor 32 drives the feeding roller 33 to rotate, the feeding roller 33 is rubbed with the glass fibers, so that the glass fibers are smoothly driven to move, and the auxiliary roller 34 reduces the friction force between the glass fibers and the cutting plate 11.

Referring to fig. 3, the cutting assembly 4 includes a cutting frame 41 and a cutting knife 42, the cutting frame 41 is fixed on the frame 1, a cutting cylinder 43 is disposed on an outer top wall of the cutting frame 41, a piston rod of the cutting cylinder 43 passes through the cutting frame 41 and is connected with the cutting frame 41 in a sliding manner, the cutting cylinder 43 is disposed along the height direction of the frame 1, the piston rod of the cutting cylinder 43 extends out towards one side of the frame 1, the cutting knife 42 is connected in the cutting frame 41 in a sliding manner, the piston rod of the cutting cylinder 43 is fixedly connected with the cutting knife 42, and the cutting knife 42 is disposed along the width direction of the frame 1.

Referring to fig. 3, the cutting blade 42 is located above the cutting plate 11, and when the glass fiber moves onto the cutting plate 11 and passes through the cutting frame 41, the piston rod of the cutting cylinder 43 is driven to extend out, so that the cutting blade 42 is pushed to cooperate with the cutting plate 11 to press the glass fiber, and the glass fiber is cut.

Referring to fig. 3, the transmission assembly 5 includes a transmission motor 51, a transmission roller 52, a rotating roller 53 and a transmission belt 54, the transmission motor 51 is fixed on the frame 1, the transmission roller 52 and the rotating roller 53 are both rotatably connected on the frame 1, the end wall of the transmission roller 52 is fixedly connected with the output shaft of the transmission motor 51, the transmission roller 52 is arranged along the width direction of the frame 1, the axis of the transmission roller 52 is parallel to the axis of the rotating roller 53, the transmission belt 54 is sleeved on the transmission roller 52 and the rotating roller 53, and the transmission belt 54 is located above the collection box 55; the glass fiber after cutting falls on the transmission belt 54, the transmission motor 51 is started, the transmission motor 51 drives the transmission roller 52 to rotate, the transmission roller 52 drives the transmission belt 54 and the rotating roller 53 to rotate, the transmission belt 54 is rubbed with the glass fiber, so that the glass fiber is driven to move, the glass fiber smoothly enters the collection box 55, and the possibility of accumulation of the glass fiber on the rack 1 is reduced.

The implementation principle of the above embodiment is as follows: when the glass fiber coiled material is cut, firstly, glass fibers are placed on the rack 1 through the feeding assembly 2, then the glass fibers are conveyed to the cutting plate 11 through the feeding assembly 3 and are close to the cutting assembly 4, after the glass fibers pass through the cutting assembly 4, the glass fibers are cut through the cutting assembly 4 according to the processing requirement, and the cut glass fibers move away from the rack 1 through the conveying assembly 5; the feeding component 3 continues to drive the glass fiber to move, and the steps are repeated, so that the automation degree of the glass fiber cutting process is improved, the time spent on cutting the glass fiber is saved, and the working efficiency is improved.

The present embodiment is only for explaining the present application, and it is not limited to the present application, and those skilled in the art can make modifications of the present embodiment without inventive contribution as needed after reading the present specification, but all of them are protected by patent law within the scope of the claims of the present application.

Claims (8)

1. The utility model provides a glass fiber coiled material cutting device which characterized in that: including frame (1), cutting plate (11) of setting in frame (1) and set up respectively in frame (1) and be used for placing glass fiber coiled material's material loading subassembly (2) and be used for cutting glass fiber's cutting assembly (4), be equipped with respectively in frame (1) and be used for sending glass fiber to pay-off subassembly (3) on cutting plate (11) and be used for transmitting glass fiber's transmission component (5) that the completion cut, material loading subassembly (2), pay-off subassembly (3), cutting assembly (4) and transmission component (5) distribute in proper order along glass fiber's transmission direction.

2. A glass fiber web slitting device as in claim 1 wherein: the feeding assembly (3) comprises a feeding motor (32) arranged on the rack (1), a feeding roller (33) arranged on an output shaft of the feeding motor (32) and an auxiliary roller (34) rotatably connected to the cutting plate (11), wherein the auxiliary roller (34) is arranged opposite to the feeding roller (33), a feeding gap (35) for glass fibers to pass through is formed between the auxiliary roller (34) and the feeding roller (33), and the auxiliary roller (34) and the feeding roller (33) are respectively abutted against two sides of the glass fibers.

3. A glass fiber web slitting device as set forth in claim 2 wherein: be equipped with on frame (1) and send material frame (31), pay-off motor (32) with feed roller (33) all are located and send material frame (31), be equipped with connecting plate (311) on pay-off motor (32), connecting plate (311) are slided and are connected on the inside wall of sending material frame (31), it is connected with slide (314) to slide on the inside wall of sending material frame (31), pay-off roller (33) with slide (314) rotate to be connected, be equipped with on sending material frame (31) and send material cylinder (317), be equipped with on the piston rod of send material cylinder (317) respectively with connecting plate (311) and slide (314) fixed connection's arm-tie (318).

4. A glass fiber web slitting device as in claim 1 wherein: the feeding assembly (2) comprises a feeding frame (21) arranged on the rack (1), a lapping rod (22) arranged on the feeding frame (21) and a feeding roller (24) which is lapped on the lapping rod (22) and sleeved with a glass fiber coiled material, wherein the lapping rod (22) is far away from one side of the feeding frame (21) and is provided with a baffle (23).

5. A glass fiber web slitting device as set forth in claim 4 wherein: the top wall of the connecting rod (22) is provided with two oppositely arranged rollers (221), the feeding roller (24) is placed between the two rollers (221), and the rollers (221) are abutted to the feeding roller (24).

6. A glass fiber web slitting device as set forth in claim 4 wherein: the feeding frame (21) is provided with a feeding arc plate (25), and the feeding arc plate (25) is arranged towards the feeding gap (35).

7. A glass fiber web slitting device as in claim 1 wherein: pay-off subassembly (3) including setting up transmission motor (51) in frame (1), set up in frame (1) and with transmission motor (51) output shaft fixed connection's transmission roller (52) and rotate rotation roller (53) of connection in frame (1), the cover is equipped with transmission belt (54) on transmission roller (52), one side cover that transmission belt (54) kept away from transmission roller (52) is established on rotation roller (53).

8. A glass fiber web slitting device as in claim 1 wherein: cutting subassembly (4) including setting up cutting frame (41) on frame (1), setting up cutting cylinder (43) and the connection of sliding on cutting frame (41) cut sword (42) that cuts on cutting frame (41), cut the piston rod of cylinder (43) with cut sword (42) fixed connection, the cutting edge orientation that cuts sword (42) stretch out on one side of cutting board (11).

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