CN112193926B

CN112193926B - Take-up auxiliary device on optical cable production line

Info

Publication number: CN112193926B
Application number: CN202010996546.2A
Authority: CN
Inventors: 雷明凯; 孔超; 杨龙山; 胡方翠
Original assignee: Shandong Yibo Photoelectric Technology Co ltd
Current assignee: Shandong Yibo Photoelectric Technology Co ltd
Priority date: 2020-09-21
Filing date: 2020-09-21
Publication date: 2022-07-12
Anticipated expiration: 2040-09-21
Also published as: CN112193926A

Abstract

The utility model relates to a receive line auxiliary device on optical cable production line belongs to optical cable production facility field, including level setting receive line roller the central axis directly over support tight pole, a pair of setting be used for connecting the lifter bar subassembly that supports tight pole on the portal frame, the lifter bar subassembly includes dead lever and lifter, the dead lever is connected with the crossbeam of portal frame, the lifter bar is pegged graft with the dead lever slip and is set up, and lifter one end with support tight pole and be connected, horizontally connect a horizontal pole between the lifter bar, it is provided with the sliding block along its length direction slip to connect the horizontal pole, be connected with on the sliding block and be used for receiving the optical cable on the line roller along receiving line roller axial to tight mechanism of supporting when twining. In the wire winding process, the optical cable firstly passes through the wire guide mechanism and then is wound on the wire winding roller. The arrangement of the take-up auxiliary device enables the optical cable to be kept orderly in the winding process and is difficult to generate staggered winding.

Description

Take-up auxiliary device on optical cable production line

Technical Field

The application relates to the field of optical cable production equipment, in particular to a take-up auxiliary device on an optical cable production line.

Background

Fiber optic cables are telecommunication cable assemblies that utilize one or more optical fibers disposed in a surrounding jacket as a transmission medium and that may be used individually or in groups.

The optical cable needs to be subjected to the processes of core wire releasing, aramid fiber wire releasing, leather sheath injection molding, cooling, code spraying, wire take-up and the like in the production process. When the cable is taken up, a take-up device is generally required to take up the cable, and the take-up device comprises a portal frame 1, a take-up roller 2, a driving mechanism for driving the take-up roller 2 to rotate to take up the optical cable, and a wire guiding mechanism. The central axis of the take-up roller 2 is horizontally arranged, and the take-up roller 2 is rotatably arranged on the upright post of the portal frame 1. The lead mechanism comprises a threaded lead screw 3, a nut connecting plate 4, a limiting rod 5, a fixing frame 6 and a driving motor 36 for driving the threaded lead screw 3 to rotate. The guide wheel 35 provided on the nut attachment plate 4 is rotated. The threaded lead screw 3 rotates along the axis direction of the take-up roller 2 and is arranged on the fixing frame 6, the limiting rod 5 is parallel to the threaded lead screw 3 and is fixedly arranged on the fixing frame 6, and the nut connecting plate 4 is sleeved on the limiting rod 5 in a sliding mode and is in threaded connection with the threaded lead screw 3. The nut connecting plate 4 can be driven by the driving motor 36 to move along the length direction of the threaded screw rod 3 by forward rotation or reverse rotation.

When the optical cable winding device works, the wire winding roller 2 rotates, and the optical cable firstly passes through the wire guide wheel 35 and is wound on the wire winding roller 2. When the optical cable passes through the wire guide wheel, the driving motor 36 rotates to drive the threaded lead screw 3 to rotate, and then the nut connecting plate 4 is driven to move along the direction of the central axis of the take-up roller 2, so that the phenomenon that the take-up roller 2 is wound and dislocated when the optical cable is wound is reduced, and the phenomenon that the optical cable is not wound neatly is caused.

After the optical cable is wound irregularly, the worker often needs to receive and adjust the position of the optical cable so that the optical cable is wound on the take-up roller 2 in order.

The inventor finds that due to the fact that the thickness of the optical cable is different and the like in the technical scheme, the wire receiving roller 2 is prone to winding and dislocation in the actual wire receiving process, and the optical cable is not wound neatly.

Disclosure of Invention

In order to make the receipts line roller keep optical cable neatly to arrange when receiving the line, this application provides a receipts line auxiliary device on optical cable production line.

The application provides a receive line auxiliary device on optical cable production line adopts following technical scheme:

the utility model provides a receive line auxiliary device on optical cable production line, sets up the lifter bar subassembly that is used for connecting the tight pole of holding up including the level to holding up pole, a pair of setting directly over receiving the line roller the central axis, the lifter bar subassembly includes dead lever and lifter, the dead lever is connected with the crossbeam of portal frame, the lifter bar sets up with the dead lever slip grafting, and lifter one end with support the tight pole and be connected, horizontally connect a connection horizontal pole between the lifter bar, it is provided with the sliding block along its length direction slip to connect the horizontal pole, be connected with on the sliding block and be used for receiving the optical cable on the line roller to support tight mechanism along receiving the line roller axial when twining.

By adopting the technical scheme, in the wire winding process, the optical cable firstly passes through the wire guide mechanism and then is wound on the wire winding roller. In the optical cable winding process, the abutting rod abuts against the optical cable on the wire collecting roller under the action of gravity, and the abutting mechanism abuts against the optical cable along the axial direction of the wire collecting roller in the winding process, so that the optical cable is kept orderly in the winding process and is difficult to generate staggered winding.

Preferably, the tight mechanism of supporting includes the connecting rod, goes up the stationary blade, under the stationary blade, a left side supports tight roller, right side supports tight roller, the connecting rod perpendicular to receives the central axis direction setting of line roller, and the connecting rod sets up with the sliding block along its length side in a sliding manner, connecting rod and sliding block are provided with the friction piece that is used for frictional force between the increase, the lower extreme and the last stationary blade fixed connection of connecting rod, a left side supports tight roller and the right side and supports tight roller one end and stationary blade rotation setting, and the other end rotates with lower stationary blade to set up, a left side supports tight roller or the right side supports tight roller and supports tight setting with the optical cable, support tight mechanism still including the control assembly that the control connecting rod rises.

Through adopting above-mentioned technical scheme, go up the stationary blade and can support tight roller, the right side to support tight roller to a left side and play the fixed action with lower stationary blade, and then make to support tight roller and can support the optical cable on the line roller tightly.

Preferably, a left side is supported tight roller, is supported tight roller and is all inwards drawn close the setting from last fixed plate end to the slope of fixed plate end down, control assembly includes a pair of control wing that sets up the fixed plate end down of keeping away from at the connecting rod, the control wing includes articulated portion, arc bend, department of support, articulated portion one end sets up with the connecting rod is articulated, the other end and the fixed setting in distolateral side of arc bend, the arc bend other end sets up with department of support is fixed, the cambered surface and the sliding block of arc bend slide the laminating setting, department of support extends to the outside of sliding block, department of support all corresponds and is provided with a piece of support dog, support the baffle and is connected the fixed setting of horizontal pole.

Through adopting above-mentioned technical scheme, when the sliding block removed to when being close to the position of supporting the dog, the one end of control wing supported and supported the dog, later along with the optical cable continues to twine on the receipts line roller, the optical cable lateral wall supports tightly left side and supports tight roller or right side and support tight roller and receive the tight effect back of supporting of optical cable, the curved portion of arc easily is close to towards the connecting rod along the sliding block, and then makes the control wing can play a component of mentioning along the vertical direction of connecting rod. Meanwhile, due to the fact that the right abutting roller and the left abutting roller are arranged in an inclined mode, the left abutting roller and the right abutting roller can abut against the top of the outmost optical cable in the state, the optical cable continues to be wound on the take-up roller under the effect of the abutting roller after the state is finished, the running direction of the wire guiding mechanism is changed until the side wall of the optical cable is attached to the side wall of the take-up roller, the abutting rod moves upwards under the effect of the optical cable, and the left abutting roller or the right abutting roller acts on the optical cable to abut against the optical cable.

Preferably, the tightening rod is connected with the lifting rod in a rotating mode, the end sides of the two lifting rods, which deviate from the fixed rod, are fixedly provided with a circular ring-shaped bearing frame and a rotary bearing fixedly arranged in the bearing frame, the tightening rod is a cylindrical device, the diameter of the tightening rod is consistent with the outer diameter of the bearing frame, and the central axis of the bearing frame and the central axis of the tightening rod are on the same straight line.

Through adopting above-mentioned technical scheme, the bearing frame is on same central axis with the central axis that supports tight pole, and the external diameter of bearing frame is unanimous with the diameter size that supports tight pole for the bearing frame also can play to the optical cable of receiving on the line pipe and support tight effect.

Preferably, the bearing frame is in sliding fit with an end plate of the take-up roller.

Through adopting above-mentioned technical scheme, the bearing frame slides with the terminal side of receiving the line roller and laminates the setting for the bearing frame can support tightly receives the optical cable of line roller edge position department, makes the optical cable of edge position be difficult to take place the dislocation winding, and then makes the optical cable winding of edge position neat.

Preferably, one end, far away from the lifting rod, of the fixed rod is fixedly provided with a hinged lug, a hinged plate is arranged on the cross beam of the portal frame and corresponds to the hinged lug, the hinged plate is hinged to the hinged lug, and a friction gasket is arranged between the hinged plate and the hinged lug.

Through adopting above-mentioned technical scheme, friction gasket can improve the frictional force between articulated slab and the hinge lug to make to support tight pole and rock at the difficult emergence of during operation, and then guarantee to receive the line effect.

Preferably, the connecting cross rod has seted up the sliding tray along length direction, the sliding block slides along sliding tray length direction and sets up, the friction piece is the friction disc, the length direction of sliding tray and the fixed setting of lateral wall of sliding tray are followed to the friction disc, the lateral wall and the friction disc laminating setting of sliding block.

Through adopting above-mentioned technical scheme, the friction disk set up can increase the sliding block and be connected the frictional force between the horizontal pole, and then make the tight roller of support can support tight fastening more neatly with the optical cable.

Preferably, the lower surface of the lower fixing piece is provided with a sliding surface.

Through adopting above-mentioned technical scheme, along with the optical cable constantly twines on receiving the line roller, when the sliding block removed to the position department that is close to the connection horizontal pole tip, the one end of control wing supported on the lateral wall of lifter, later along with receiving the rotation of line roller, the optical cable supported the roller that supports, because support the roller slope setting, supported the lateral wall of lifter when the department that supports, along with convoluteing of optical cable.

In summary, the present application includes at least one of the following advantageous technical effects:

1. setting of a take-up device: the optical cable winding device has the advantages that a deviation rectifying and positioning effect can be achieved on the optical cable on the winding roller, and in the winding process, the optical cable firstly passes through the wire guiding mechanism and then is wound on the winding roller. In the process of winding the optical cable, the abutting rod abuts against the optical cable on the wire collecting roller under the action of gravity, and meanwhile, the abutting mechanism abuts against the optical cable along the axial direction of the wire collecting roller in the process of winding, so that the optical cable is kept orderly in the winding process and is difficult to generate staggered winding;

2. when the sliding block moves to a position close to the side wall of the lifting rod, one end of the control fin butts against the side wall of the lifting rod, then the optical cable is wound on the take-up roller continuously, the side wall of the optical cable butts against the left or right butting roller, after the left or right butting roller is subjected to the butting force of the optical cable, the arc-bent part is easy to approach towards the connecting rod along the sliding block, and further the control fin can play a lifting force along the vertical direction of the connecting rod. Meanwhile, due to the fact that the right abutting roller and the left abutting roller are arranged in an inclined mode, the left abutting roller and the right abutting roller can abut against the top of the outmost optical cable in the state, the optical cable continues to be wound on the take-up roller under the effect of the abutting roller after the state is finished, the running direction of the wire guiding mechanism is changed until the side wall of the optical cable is attached to the side wall of the take-up roller, the abutting rod moves upwards under the effect of the optical cable, and the left abutting roller or the right abutting roller acts on the optical cable to abut against the optical cable.

Drawings

FIG. 1 is a related art drawing;

FIG. 2 is a schematic view of the working state of the present application;

FIG. 3 is a schematic illustration of an exploded construction of the lifter assembly of the present application;

fig. 4 is an enlarged schematic view of a portion a of fig. 2.

Description of reference numerals: 1. a gantry; 2. a wire take-up roller; 3. a threaded lead screw; 4. a nut connecting plate; 5. a limiting rod; 6. a fixed mount; 7. a tightening rod; 8. fixing the rod; 9. a lifting rod; 10. a lifting groove; 11. a limiting bulge; 12. a raised through groove; 13. a hinge plate; 14. a hinge ear; 15. a rubbing pad; 16. connecting a cross bar; 17. a sliding groove; 18. a slider; 19. a friction plate; 20. a connecting rod; 21. an upper fixing sheet; 22. a lower fixing sheet; 23. a left abutment roller; 24. a right abutment roller; 25. a fixing ring; 26. a slip surface; 27. a hinge portion; 28. an arc bending part; 29. a resisting part; 30. a stop block; 31. a control fin; 32. a bearing frame; 33. a rotating bearing; 34. fixing the vertical rod; 35. a guide wheel; 36. the motor is driven.

Detailed Description

The present application is described in further detail below with reference to figures 2-4.

The embodiment of the application discloses receipts line auxiliary device on optical cable production line. Referring to fig. 2, the device comprises a abutting rod 7 horizontally arranged right above the central axis of the wire take-up roller 2 and used for pressing the optical cable on the wire take-up roller 2, and a pair of lifting rod assemblies arranged on a cross beam of the portal frame 1 and used for connecting the abutting rod 7.

Referring to fig. 2 and 3, the lift lever assembly includes a fixing lever 8, a lift lever 9. One end of the fixing rod 8 is hinged to the cross beam of the portal frame 1, the other end of the fixing rod is provided with a lifting groove 10 along the length direction of the fixing rod 8, the lifting rod 9 is inserted in the lifting groove 10 in a sliding mode, and one end of the lifting rod 9 extends out of the lifting groove 10 and is connected with the abutting rod 7. The one end symmetry fixed welding that the tight pole 7 was kept away from to lifter 9 has two spacing archs 11, and the lateral wall of lift groove 10 corresponds spacing arch 11 along its length side and is provided with protruding logical groove 12, and spacing arch 11 extends to the protruding logical groove 12 outside to the long direction and the protruding logical groove 12 of protruding logical groove 12 along slide the setting. The one end that the lifter 9 was kept away from to dead lever 8 all fixed welding has hinge lug 14, the crossbeam of portal frame 1 corresponds hinge lug 14 and is provided with articulated slab 13, articulated slab 13 sets up through hinge shaft is articulated with hinge lug 14, and be provided with friction pad 15 between articulated slab 13 and the hinge lug 14, friction pad 15 can increase the frictional force between hinge lug 14 and the articulated slab 13, and then make the tightening lever 7 remain stable at the during operation, and simultaneously, the staff still can rotate the angle of dead lever 8 after the receipts line is finished, in order to make things convenient for the staff to take off receipts line roller 2.

During operation, the staff advances to support tight pole 7 and places on the optical cable line of receiving on the line roller 2 the outside to flatten the optical cable line, make the optical cable line be difficult to take place dislocation from top to bottom when convoluteing. After the optical cable is wound on the take-up roller 2 by one row, the optical cable is wound by the next row, and at the moment, the abutting roller moves upwards under the action of the optical cable.

Referring to fig. 2 and 4, a connecting cross rod 16 is connected between the lifting rods 9, the connecting cross rod 16 is L-shaped, the connecting cross rod 16 is arranged along the length direction of the tightening rod 7, and two ends of the tightening rod 7 are fixedly welded to the lifting rods 9. Connecting horizontal pole 16 has seted up sliding tray 17 along length direction, and sliding tray 17 slides along its length direction and is provided with sliding block 18, and sliding block 18 is the I-shaped, and two upper and lower tip of sliding block 18 all with the pole wall slip laminating setting of connecting horizontal pole 16. A friction piece is arranged between the side wall of the sliding groove 17 and the sliding block 18, the friction piece is a friction plate 19, the friction plate 19 is fixedly arranged on the side wall of the sliding groove 17 along the length direction of the sliding groove 17, and the side wall of the sliding block 18 is attached to the friction plate 19. The sliding block 18 is connected with a tight-supporting mechanism which is used for supporting the optical cable on the take-up roller 2 along the axial direction of the take-up roller 2 when the optical cable is wound.

The abutting mechanism comprises a connecting rod 20, an upper fixing sheet 21, a lower fixing sheet 22, a left abutting roller 23 and a right abutting roller 24, and the upper fixing sheet 21 and the lower fixing sheet 22 are fixedly arranged through a connecting vertical rod 34. The connecting rod 20 is perpendicular to the central axis direction of the take-up roller 2, and the connecting rod 20 passes through the sliding block 18 and is arranged in a sliding manner with the sliding block 18 along the length direction of the connecting rod 20. The connecting rod 20 is fixedly sleeved with a fixing ring 25 at a part close to the upper end, and when the connecting rod 20 acts under the action of self gravity, the fixing ring 25 is tightly abutted to the sliding block 18 so as to prevent the connecting rod 20 from completely separating from the sliding block 18 under the action of gravity. The lower end of the connecting rod 20 is fixedly welded with the upper fixing sheet 21, one end of the left abutting roller 23 and one end of the right abutting roller 24 are rotatably arranged with the upper fixing sheet 21, and the other end of the left abutting roller and the lower fixing sheet 22 are rotatably arranged. The left supporting roller 23 or the right supporting roller 24 is tightly arranged with the optical cable, and the supporting mechanism further comprises a control component for controlling the connecting rod 20 to ascend.

The left abutting roller 23 and the right abutting roller 24 are arranged in a way of inclining and inwards approaching from the end of the upper fixing sheet 21 to the end of the lower fixing sheet 22, and the lower surface of the lower fixing sheet 22 is provided with a sliding surface 26. The control assembly includes a pair of control fins 31 disposed on the end of the connecting rod 20 remote from the pinch rolls. The control fin 31 includes a hinge portion 27, an arcuate portion 28, an abutting portion 29, and a pair of abutting pieces 30. One end of the hinge part 27 is hinged with the connecting rod 20 through a hinge shaft, the other end is fixedly arranged with the end side of the arc-shaped bent part 28, the other end of the arc-shaped bent part 28 is fixedly arranged with the resisting part 29, the arc surface of the arc-shaped bent part 28 is in sliding fit with the upper end surface of the sliding block 18, and the resisting part 29 extends to the outside of the sliding block 18. The pair of abutting blocks 30 are respectively arranged at two ends of the sliding groove 17, and the abutting blocks 30 are fixedly welded with the connecting cross bar 16.

Referring to fig. 3, the tightening rod 7 is rotatably connected with the lifting rods 9, the end sides of the two lifting rods 9 departing from the fixing rod 8 are fixedly provided with a circular-ring-shaped bearing frame 32 and a rotating bearing 33 fixedly arranged in the bearing frame 32, the tightening rod 7 is a cylindrical device, the diameter of the tightening rod 7 is consistent with the outer diameter of the bearing frame 32, and the central axis of the bearing frame 32 is on the same straight line with the central axis of the tightening rod 7. The bearing frame 32 is slidably fitted to the end plate of the take-up roll 2.

The implementation principle of the embodiment of the application is as follows: during operation, the staff rotates dead lever 8 to vertical state, later will support tight pole 7 to put on the optical cable line of receiving line roller 2 outside, supports tight pole 7, bearing frame 32 and plays the effect of compressing tightly to the optical cable under the effect of gravity for the optical cable is difficult to take place to misplace from top to bottom at winding in-process. When the optical cable is tightly supported by the supporting rod 7, the worker adjusts the position of the sliding block 18, so that the optical cable can be tightly supported by the left supporting roller 23 or the right supporting roller 24, and the optical cable is tighter in the winding process so as to be kept orderly and difficult to be dislocated. The optical cable is easy to be arranged along the axial direction of the take-up roller 2 in the winding process, as the optical cable is wound to the position close to the two ends of the take-up roller 2 by the take-up roller 2, the sliding block 18 moves to the end part close to the sliding groove 17, the resisting part 29 resists the resisting block 30, as the take-up roller 2 continues to rotate, the left resisting roller 23 or the right resisting roller 24 is difficult to move along the axial direction of the take-up roller 2 under the action of the optical cable, at the moment, the left resisting roller 23 or the right resisting roller 23 tightly receives a component force along the axial direction of the take-up roller 2 and a component force in the vertical direction, the component force in the vertical direction and the component force in the axial direction enable the connecting rod 20 to move upwards, so that the optical cable can pass through the left resisting roller 23 and the right resisting roller 24, then the optical cable is continuously wound to be attached to the plate surface of the end part of the take-up roller 2, and then the optical cable is continuously wound and arranged on the take-up roller 2 in the direction opposite to the original arrangement direction, meanwhile, the abutting rod 7 moves upwards, and the left abutting roller 23 or the right abutting roller 24 continuously acts on the optical cable.

After waiting to receive line roller 2 work, the staff rotates dead lever 8, and dead lever 8 keeps fixed angle under the effect of friction disc 19, and then makes things convenient for the staff to take off and receive line roller 2 to transport the optical cable.

The above embodiments are preferred embodiments of the present application, and the protection scope of the present application is not limited by the above embodiments, so: all equivalent changes made according to the structure, shape and principle of the present application shall be covered by the protection scope of the present application.

Claims

1. The utility model provides a receive line auxiliary device on optical cable production line which characterized in that: including level setting supporting pole (7), a pair of lifter bar subassembly that sets up and be used for connecting supporting pole (7) directly over receiving line roller (2) the central axis, lifter bar subassembly includes dead lever (8) and lifter (9), dead lever (8) are connected with the crossbeam of portal frame (1), lifter (9) and dead lever (8) slip grafting setting, and lifter (9) one end is connected with supporting pole (7), horizontally connect between lifter (9) and connect horizontal pole (16), it is provided with sliding block (18) to connect horizontal pole (16) to slide along its length direction, be connected with on sliding block (18) and be used for supporting the tight mechanism of supporting the optical cable on receiving line roller (2) along receiving line roller (2) axial when twining, support tight mechanism and include connecting rod (20), upper fixing piece (21), The cable take-up device comprises a lower fixing piece (22), a left abutting roller (23) and a right abutting roller (24), wherein the connecting rod (20) is arranged perpendicular to the direction of the central axis of the cable take-up roller (2), the connecting rod (20) is arranged in a sliding mode with the sliding block (18) along the length direction of the connecting rod, a friction piece used for increasing the friction force between the connecting rod (20) and the sliding block (18) is arranged on the connecting rod (20), the lower end of the connecting rod (20) is fixedly connected with the upper fixing piece (21), one ends of the left abutting roller (23) and the right abutting roller (24) are arranged in a rotating mode with the fixing piece, the other ends of the left abutting roller (23) and the right abutting roller (24) are arranged in a rotating mode with the lower fixing piece (22), the left abutting roller (23) or the right abutting roller (24) are arranged in an abutting mode with an optical cable, and the abutting mechanism further comprises a control assembly for controlling the connecting rod (20) to ascend; the left supporting roller (23) and the right supporting roller (24) are arranged from the end of the upper fixing sheet (21) to the end of the lower fixing sheet (22) in an inclined inward closing way, the control assembly comprises a pair of control fins (31) which are arranged at the end of the connecting rod (20) far away from the lower fixing plate (22), the control fin (31) comprises a hinge part (27), an arc bending part (28) and a resisting part (29), one end of the hinge part (27) is hinged with the connecting rod (20), the other end is fixedly arranged with the end side of the arc-shaped part (28), the other end of the arc bending part (28) is fixedly arranged with the resisting part (29), the arc surface of the arc bending part (28) is in sliding fit with the sliding block (18), the stopping parts (29) extend to the outer parts of the sliding blocks (18), the stopping parts (29) are correspondingly provided with stopping blocks (30), and the stopping blocks (30) are fixedly arranged with the connecting cross rod (16).

2. A take-up assist device on an optical cable production line as claimed in claim 1, wherein: support tight pole (7) and lifter (9) and rotate to be connected, two lifters (9) deviate from distolateral all fixed annular bearing frame (32), the fixed rolling bearing (33) that sets up in bearing frame (32) of being provided with of dead lever (8), support tight pole (7) and be the cylinder device, and support the diameter of tight pole (7) and the external diameter size of bearing frame (32) unanimously, the central axis of bearing frame (32) and the central axis of supporting tight pole (7) are on same straight line.

3. A take-up assist device on an optical cable production line as claimed in claim 2, wherein: the bearing frame (32) is in sliding fit with the end plate of the take-up roller (2).

4. A take-up assist device on an optical cable production line as claimed in claim 3, wherein: the one end that lifter (9) was kept away from in dead lever (8) all fixedly is provided with hinge lug (14), the crossbeam of portal frame (1) corresponds hinge lug (14) and is provided with articulated slab (13), articulated slab (13) and hinge lug (14) are articulated to be set up, and are provided with friction pad (15) between articulated slab (13) and hinge lug (14).

5. A take-up assisting device on an optical cable production line as claimed in claim 4, wherein: connecting horizontal pole (16) and having seted up sliding tray (17) along length direction, sliding block (18) slide along sliding tray (17) length direction and set up, the friction member is friction disc (19), the length direction of sliding tray (17) is followed in friction disc (19) and the fixed setting of lateral wall of sliding tray (17), the lateral wall and the friction disc (19) laminating setting of sliding block (18).

6. A take-up aid device according to claim 5, characterised in that: the lower surface of the lower fixing piece (22) is provided with a sliding surface (26).