CN220720203U - Optical cable coating layer processing device - Google Patents

Abstract

The utility model relates to an optical cable cladding layer processing device. Including guider and extrusion district, guider and extrusion district's guiding mouth coincide, extrusion district's inside is provided with the leveling roller, one end top that keeps away from the leveling roller on the guider is provided with the stirring storehouse, the top of stirring storehouse is provided with the feed inlet, the bottom of stirring storehouse is provided with the discharge gate, stirring storehouse inside is provided with stirring structure, be provided with the push head that promotes the optical cable and remove on the extrusion district, the other end fixed mounting of push head has the baffle, the other end of baffle is provided with the cam that promotes its pivoted, be provided with pushing structure between cam and the push head, pushing structure includes the horizontal pole, the both sides fixed mounting that the horizontal pole is located the fixed block has the touch wheel for the optical cable enters into the time of cladding optical cable material fully laminating and optical cable surface behind the extrusion district, improve the homogeneity and the stability of follow-up cladding optical cable.

Description

Optical cable cladding layer processing device

Technical Field

The utility model relates to the field of optical cable coating layer processing devices, in particular to an optical cable coating layer processing device.

Background

The optical cable is manufactured to meet the performance specifications of optics, machinery or environment, and is a communication cable component which uses one or more optical fibers arranged in a cladding sheath as a transmission medium and can be used singly or in groups.

When the optical cable coating layer is processed, the optical cable is usually slowly and intermittently fed into the coating region through the conveying belt, so that the uneven coating layer is easily caused by insufficient contact time between the optical cable and the coating layer material, the quality of the finally formed optical cable is affected, and therefore the optical cable coating layer processing device is provided.

Disclosure of Invention

Aiming at the defects of the prior art, the utility model provides an optical cable coating layer processing device which solves the problems.

In order to achieve the above purpose, the present utility model provides the following technical solutions: the utility model provides an optical cable coating processingequipment, includes guider and extrusion district, guider and extrusion district's guiding mouth coincide, extrusion district's inside is provided with the leveling roller, the one end top of keeping away from the leveling roller on the guider is provided with the stirring storehouse, the top in stirring storehouse is provided with the feed inlet, the bottom in stirring storehouse is provided with the discharge gate, stirring storehouse inside is provided with stirring structure, be provided with the push head that promotes the optical cable and remove on the extrusion district, the other end fixed mounting of push head has the baffle, the other end of baffle is provided with the cam that promotes its pivoted, be provided with the promotion structure between cam and the push head.

Preferably, the stirring structure comprises stirring blades, a first motor is fixedly arranged at the top end of the stirring bin, a rotating shaft is fixedly arranged at the output end of the first motor, a supporting frame is arranged at the top end of the inside of the stirring bin, eight supporting rods are fixedly arranged at the bottom end of the supporting frame at equal intervals in an annular shape around the central shaft of the stirring bin, a plurality of groups of stirring blades are fixedly arranged on six supporting rods, and scraping plates are fixedly arranged on the remaining two supporting rods.

Preferably, the bottom of pivot runs through and fixed mounting on the support frame, the bottom of pivot is located the discharge gate internal fixation and installs the screw axis.

Preferably, stirring blades on the adjacent supporting rods are distributed in a staggered mode, the adjacent stirring blades are not interfered, and the stirring blades are of a four-blade knife-shaped structure.

The two preferred scrapers are of a circular arc plate structure, and the outer surfaces of the scrapers are attached to the inner wall of the stirring bin.

Preferably, the pushing structure comprises a cross rod, a motor II is fixedly arranged on one side of the cam, a rotary table is fixedly arranged at the center position of the other side of the cam, a fixed block is rotationally connected at one side position of the rotary table, which is close to the edge, of the rotary table, the cross rod penetrates through two sides of the top end of the fixed block, and one end of the cross rod, which is close to the stirring bin, is rotationally connected with the guide plate.

Preferably, the cross rod is located the both sides fixed mounting of fixed block and supports the touch wheel, is kept away from between the touch wheel and the fixed block of stirring storehouse one side fixed mounting spring.

Preferably, the rotating disc is provided with a limiting column near the edge and positioned at the symmetrical end of the fixed block, and the limiting column is contacted with the corresponding abutting wheel.

Compared with the prior art, the utility model provides an optical cable coating layer processing device, which has the following advantages:

1. this optical cable coating processingequipment, through the crisscross setting of multiunit stirring leaf, improve the material and make the inhomogeneous phenomenon of material stirring of central point position department owing to the inertia of stirring, can effectively prevent that the material adhesion from causing the phenomenon of skinning in the stirring storehouse inner wall through the setting of scraper blade, can effectively solve the material accumulation and cause the jam of discharge gate at the discharge gate through the setting of screw axis.

2. This optical cable coating processingequipment, motor two drives the cam and rotates for spacing post on the motor two rotates in step, when the spacing post rotates the position department of conflict wheel, after the power that the conflict wheel received the conflict face, drive stirring leaf motion and incline towards guider's direction, baffle rotation on the horizontal pole drives the push head joint on the optical cable this moment, drive the baffle through the cam and shift up and make the push head promote the optical cable to remove in the extrusion district, form intermittent type stability through spacing post every round with the time of conflict wheel contact and promote the optical cable to enter into the extrusion district in, make the optical cable enter into the time of cladding optical cable material fully laminating and optical cable surface behind the extrusion district, improve the homogeneity and the stability of follow-up cladding optical cable.

Drawings

FIG. 1 is a schematic diagram of the structure of the present utility model;

FIG. 2 is a schematic rear view of the present utility model;

FIG. 3 is a schematic view of the stirring structure of the present utility model;

FIG. 4 is a schematic top view of the stirring blade and scraper of the present utility model;

fig. 5 is a schematic diagram of a pushing structure of the present utility model.

In the figure: 1. a guide device; 2. an extrusion molding zone; 3. a leveling roller; 4. a stirring bin; 5. a feed inlet; 6. a first motor; 7. a rotating shaft; 8. a support frame; 9. a support rod; 10. stirring the leaves; 11. a scraper; 12. a screw shaft; 13. a discharge port; 14. a cam; 15. a second motor; 16. a turntable; 17. a limit column; 18. a fixed block; 19. a cross bar; 20. a contact wheel; 21. a spring; 22. a guide plate; 23. pushing head.

Detailed Description

Referring to fig. 1-5, an optical cable cladding layer processing device comprises a guiding device 1 and an extrusion forming area 2, wherein the guiding device 1 is matched with a guiding opening of the extrusion forming area 2, a leveling roller 3 is arranged in the extrusion forming area 2, a stirring bin 4 is arranged above one end, far away from the leveling roller 3, of the guiding device 1, a feeding opening 5 is arranged at the top end of the stirring bin 4, a discharging opening 13 is arranged at the bottom end of the stirring bin 4, the discharging opening 13 is communicated with the extrusion forming area 2, a stirring structure is arranged in the stirring bin 4, a push head 23 for pushing an optical cable to move is arranged in the extrusion forming area 2, a guide plate 22 is fixedly arranged at the other end of the push head 23, a cam 14 for pushing the push head to rotate is arranged at the other end of the guide plate 22, and a pushing structure is arranged between the cam 14 and the push head 23.

Further, stirring structure includes stirring leaf 10, stirring storehouse 4's top fixed mounting has motor one 6, stirring storehouse 4 fixed mounting is run through to motor one 6's output has pivot 7, stirring storehouse 4's inside top is provided with support frame 8, support frame 8's bottom is around stirring storehouse 4's center pin as the center, be annular equidistant fixed mounting and have eight bracing pieces 9, wherein fixed mounting has multiunit stirring leaf 10 on six bracing pieces 9, fixed mounting has scraper blade 11 on remaining two bracing pieces 9, drive the rotation of pivot 7 through the rotation of motor one 6, thereby make eight bracing pieces 9 rotations of support frame 8 bottom, stirring leaf 10 on the bracing piece 9 stirs the mixture to the material, scraper blade 11 scrapes stirring storehouse 4 inner wall adhesion's material.

Further, the bottom of the rotating shaft 7 penetrates through and is fixedly mounted on the supporting frame 8, the bottom of the rotating shaft 7 is located in the discharging hole 13, the screw shaft 12 is fixedly mounted in the discharging hole 13, and the screw shaft 12 in the discharging hole 13 extrudes materials into the extrusion forming area 2 along with the rotation of the rotating shaft 7.

Further, the stirring blades 10 on the adjacent supporting rods 9 are distributed in a staggered manner, the adjacent stirring blades 10 are not interfered, and the stirring blades 10 are of a four-blade knife-shaped structure, so that stirring is more uniform.

Further, the two scraping plates 11 are of arc plate structures, and the outer surfaces of the scraping plates 11 are attached to the inner wall of the stirring bin 4.

Further, the pushing structure comprises a cross rod 19, a motor II 15 is fixedly arranged on one side of the cam 14, the motor II 15 is fixed through a supporting seat, a rotary table 16 is fixedly arranged at the center position of the other side of the cam 14, one side position of the rotary table 16 close to the edge is rotationally connected with a fixed block 18, the cross rod 19 penetrates through two sides of the top end of the fixed block 18, one end of the cross rod 19 close to the stirring bin 4 is rotationally connected with a guide plate 22, the motor II 15 drives the cam 14 to rotate, a limiting column 17 on the motor II 15 rotates synchronously, and when the limiting column 17 rotates to the position of a collision wheel 20, the collision wheel 20 is driven to move to incline towards the direction of the guide device 1 after being subjected to force of a collision surface.

Further, the cross bar 19 is located at two sides of the fixed block 18 and is fixedly provided with a contact wheel 20, and a spring 21 is fixedly arranged between the contact wheel 20 at one side far away from the stirring bin 4 and the fixed block 18.

Further, a limiting column 17 is fixedly mounted on the turntable 16 near the symmetrical end of the fixed block 18, the limiting column 17 is in contact with the corresponding abutting wheel 20, a guide plate 22 on the cross rod 19 rotates to drive a push head 23 to be clamped on the optical cable, and the cam 14 drives the guide plate 22 to move upwards to enable the push head 23 to push the optical cable to move towards the extrusion forming area 2.

The working process of the utility model is as follows: the optical cable is placed on the guiding device 1, the motor II 15 is started, the motor II 15 drives the cam 14 to rotate, the limiting column 17 on the motor II 15 rotates synchronously, when the limiting column 17 rotates to the position of the abutting wheel 20, the abutting wheel 20 is driven to move and incline towards the direction of the guiding device 1 after being subjected to the force of the abutting surface, the guide plate 22 on the transverse rod 19 rotates to drive the push head 23 to be clamped on the optical cable, the guide plate 22 is driven by the cam 14 to move upwards so that the push head 23 pushes the optical cable to move towards the extrusion forming area 2, the motor I6 is started, the rotation of the motor I6 drives the rotation of the rotating shaft 7, so that eight supporting rods 9 at the bottom end of the supporting frame 8 rotate, stirring blades 10 on the supporting rods 9 stir and mix materials, the scraping plates 11 scrape the materials adhered to the inner wall of the stirring bin 4, and screw shafts 12 in the discharge ports 13 rotate along with the rotating shafts 7 to extrude the materials into the extrusion forming area 2, and after the optical cable is coated, the surface of the optical cable is flattened through the flattening roller 3.

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

Claims (8)

1. Optical cable coating processingequipment, including guider (1) and extrusion district (2), its characterized in that: the guiding device is characterized in that the guiding device (1) is matched with a guiding opening of the extrusion forming area (2), a leveling roller (3) is arranged in the extrusion forming area (2), a stirring bin (4) is arranged above one end, far away from the leveling roller (3), of the guiding device (1), a feeding opening (5) is arranged at the top end of the stirring bin (4), a discharging opening (13) is arranged at the bottom end of the stirring bin (4), a stirring structure is arranged inside the stirring bin (4), a pushing head (23) for pushing an optical cable to move is arranged on the extrusion forming area (2), a guide plate (22) is fixedly arranged at the other end of the pushing head (23), a cam (14) for pushing the guide plate (22) to rotate is arranged at the other end of the guide plate, and a pushing structure is arranged between the cam (14) and the pushing head (23).

2. The optical cable coating processing device according to claim 1, wherein: stirring structure includes stirring leaf (10), stirring storehouse (4) top fixed mounting has motor one (6), stirring storehouse (4) fixed mounting is run through to the output of motor one (6) has pivot (7), stirring storehouse (4) inside top is provided with support frame (8), the bottom of support frame (8) is central around stirring storehouse (4) center pin, is annular equidistant fixed mounting and has eight bracing pieces (9), wherein fixed mounting has multiunit stirring leaf (10) on six bracing pieces (9), and fixed mounting has scraper blade (11) on remaining two bracing pieces (9).

3. The optical cable coating processing device according to claim 2, wherein: the bottom of the rotating shaft (7) penetrates through and is fixedly arranged on the supporting frame (8), and a screw shaft (12) is fixedly arranged in the discharging hole (13) at the bottom of the rotating shaft (7).

4. The optical cable coating processing device according to claim 2, wherein: stirring blades (10) on adjacent supporting rods (9) are distributed in a staggered mode, the adjacent stirring blades (10) are not interfered, and the stirring blades (10) are of a four-blade knife-shaped structure.

5. The optical cable coating processing device according to claim 2, wherein: the two scraping plates (11) are of arc plate structures, and the outer surfaces of the scraping plates (11) are attached to the inner wall of the stirring bin (4).

6. The optical cable coating processing device according to claim 1, wherein: the pushing structure comprises a cross rod (19), a motor II (15) is fixedly arranged on one side of the cam (14), a rotary table (16) is fixedly arranged at the center position of the other side of the cam (14), a fixed block (18) is rotationally connected at one side position of the rotary table (16) close to the edge, the cross rod (19) penetrates through two sides of the top end of the fixed block (18), and one end of the cross rod (19) close to the stirring bin (4) is rotationally connected with a guide plate (22).

7. The optical cable coating processing device according to claim 6, wherein: the cross rod (19) is located the both sides fixed mounting who is fixed block (18) and supports touch wheel (20), is kept away from between the conflict wheel (20) and fixed block (18) of stirring storehouse (4) one side fixed mounting spring (21).

8. The optical cable coating processing device according to claim 6, wherein: limiting columns (17) are fixedly mounted at symmetrical ends, close to edges, of the fixed blocks (18) on the rotary table (16), and the limiting columns (17) are in contact with corresponding abutting wheels (20).