CN112051651A - Full-automatic processing banding device of optical cable coating - Google Patents

Abstract

The invention discloses a full-automatic processing and edge sealing device for an optical cable coating layer, which comprises edge sealing equipment, wherein a processing cavity with a forward opening is arranged in the edge sealing equipment, the upper side of the processing cavity is provided with a driving cavity, one side of the processing cavity, which is far away from each other, is provided with two transmission cavities, the two transmission cavities are symmetrically distributed and arranged in a left-right mode by taking the central line of the processing cavity as a symmetry center, the invention can fully automatically process the optical core and the coating layer at the outer back of the optical cable in the optical cable processing process so as to improve the working efficiency of optical cable processing, in the common optical cable processing, defects such as flash and the like often occur on the coating layer, so that the flash needs to be removed manually or by special equipment, the invention can carry out real-time deburring operation on the coating layer after the optical cable is coated, thereby achieving full-automatic improvement of the working efficiency.

Description

Full-automatic processing banding device of optical cable coating

Technical Field

The invention relates to the field of optical cables, in particular to a full-automatic processing and edge sealing device for an optical cable coating layer.

Background

In the common optical cable processing process, the optical core and the outer back coating layer in the optical cable generally need to use different equipment to coat the outer peripheral surface of the optical cable after the previous process is completed, so that the working efficiency of the whole optical cable processing is greatly reduced by the independent process, the processing working hour is increased, in the common optical cable processing, a series of flaws often appear on the coating layer, the flaws of the optical cable coating layer are needed at the moment, the integral cost is increased invisibly, and the full-automatic processing edge sealing device for the optical cable coating layer, disclosed by the invention, can solve the problems.

Disclosure of Invention

In order to solve the problems, the embodiment designs a full-automatic processing edge sealing device for an optical cable coating layer, which comprises edge sealing equipment, wherein a processing cavity with a forward opening is arranged in the edge sealing equipment, a driving cavity is arranged at the upper side of the processing cavity, two transmission cavities are arranged at one side of the processing cavity, which is away from each other, the two transmission cavities are arranged in a bilateral symmetry mode by taking the center line of the processing cavity as a symmetry center, a moving motor is fixedly connected to the rear wall of the processing cavity, two embedding shafts are rotationally connected to the rear wall of the processing cavity, the two embedding shafts are arranged in a vertical symmetry mode by taking the center line of the processing cavity as a symmetry center, a driven belt pulley is fixedly connected to the outer peripheral surface of the embedding shaft, the front end of the moving motor is in power connection with a transmission shaft, and a moving belt, a movable belt is rotatably connected between the movable belt pulley and the driven belt pulley, a rear screw is fixedly connected to the front end of the driven belt pulley, a movable thread block is connected to the outer peripheral surface of the rear screw in a threaded manner, the movable thread block is vertically and mutually close to one end of a fixedly connected material container, the material container is mutually close to one end of a fixedly connected heater, an injector is arranged in the heater, one end of the injector which is mutually far away from is fixedly connected to one end of the material container which is mutually close to, one end of the material container is mutually close to is fixedly connected with two stabilizing springs, the two stabilizing springs are arranged in a bilateral symmetry manner by taking the central line of the material container as the symmetry center, one end of the stabilizing spring which is mutually close to is fixedly connected with a swinging rod, the front end of the swinging rod, fixedly connected with encircles on the leading torsional spring outer peripheral face, encircle and be close to one end fixedly connected with banding board each other around the axle, the banding board keep away from one end each other with the injector is close to one end contact connection each other, the process chamber is kept away from each other and is equipped with the sliding tray that the opening carried on the back mutually in the lateral wall, the sliding tray intercommunication the process chamber with the transmission chamber, it is connected with horizontal screw thread piece to rotate on the sliding tray inner wall, be equipped with the horizontal screw thread chamber that the opening is relative in the horizontal screw thread piece, horizontal screw thread chamber inner wall threaded connection has and is close to the screw rod, it is close to one end fixedly connected with pivot pole each other to be close to the screw rod, the pivot pole is close to one end fixedly connected with splint each other, when needing to add man-hour to the optical cable, the coating of optical cable is in the, The movable belt pulley rotates to drive the movable belt and the rear screw rod to rotate so as to drive the movable thread block, the material container, the heater, the injector, the stabilizing spring, the swinging rod, the front torsion spring, the front shaft, the edge sealing plate and the surrounding shaft to move along with the coating layer, at the moment, the edge sealing material in the material container enters the injector, at the moment, the heater is started to heat and melt the edge sealing material in the injector so that the edge sealing material can carry out edge sealing treatment on the upper part and the lower part of the clamping plate at the upper position and the lower position of the clamping plate, at the moment, the transverse thread block rotates to drive the approaching screw rods to move close to each other so as to drive the central rod and the clamping plate to move close to each other, and the clamping plate clamps the coating layer so that the clamping plate can be mutually attached to ensure that the edge sealing material cannot leak in the process of edge sealing, at the moment, the edge sealing plate is close to one end pair each other and the gap between the upper end and the lower end of the coating layer is troweled, along with the following movement of the movable thread block removes and cuts redundant edge sealing materials, the edge sealing plate swings and then drives the front torsion spring, the front shaft and the surrounding shaft rotate and further drive the swing rod to swing and further compress the stabilizing spring, the stabilizing spring is right the vibration of the coating layer in the edge sealing process is absorbed and buffered, and the processing edge sealing of the optical cable is completed at the moment.

Preferably, four sliding cavities are arranged in the side walls which are far away from each other on the left and right sides of the processing cavity, the four sliding cavities are distributed symmetrically up and down and left and right by taking the center line of the processing cavity as the symmetric center, the inner wall of each sliding cavity is rotationally connected with a sliding threaded shaft, the threaded cavities with opposite openings are arranged in the sliding threaded shaft, the inner wall of each threaded cavity is in threaded connection with a screw rod, the screw rods are close to each other, one ends of the moving blocks are fixedly connected with moving blocks, one ends of the moving blocks are close to each other, two size openings with opposite openings are arranged, the size openings are provided with opposite openings, one ends of the size openings far away from each other are fixedly connected with size springs, one ends of the size springs close to each other are fixedly connected with sliding plates, one ends of the sliding plates close to each, the optical cable comprises a placing opening, a moving block, a placing block, a size spring, a sliding plate, a clamping wheel, a screw rod, a clamping torsion spring, a clamping shaft and a size spring, wherein the inner peripheral surface of the clamping torsion spring is fixedly connected with a clamping shaft, one end of the clamping wheel, which is close to each other, is fixedly connected with a clamp holder, the inner wall of the placing opening is connected with an optical fiber in a contact manner, when the optical fiber in the optical cable needs to be placed between coating layers, the screw rod rotates at the moment, and then the moving block, the placing block, the size spring, the sliding plate, the clamping wheel, the clamping torsion spring, the clamp holder and the clamping shaft are driven to move close to each other, the clamp holder swings and clamps the optical fiber, and then the clamping torsion spring, the clamping wheel and the clamping shaft are driven.

Preferably, a coupling shaft is rotatably connected to the lower wall of the transmission cavity, a side bevel gear is fixedly connected to the outer peripheral surface of the coupling shaft at the lower side, an overhead bevel gear is fixedly connected to the outer peripheral surface of the coupling shaft at the upper side, a fixed shaft is fixedly connected to the end of the sliding threaded shaft away from each other, a bevel gear is fixedly connected to the end of the fixed shaft away from each other, the end of the side bevel gear close to each other is meshed with the end of the bevel gear at the lower side, the end of the overhead bevel gear close to each other is meshed with the end of the bevel gear at the upper side close to each other, the end of the transverse threaded block far away from each other is fixedly connected to a transverse shaft, the end of the transverse shaft far away from each other is fixedly connected to a transverse bevel gear, a middle bevel gear is fixedly connected to the, when the optical fibers in the optical cable need to move close to each other, the rotation of the linkage shaft drives the side bevel gears, the top bevel gears, the fixed shaft, the bevel gears, the top bevel gears, the transverse thread block, the transverse shaft, the transverse bevel gears and the middle bevel gears to rotate, the rotation of the transverse bevel gears and the transverse shaft further enables the coating layers to move close to each other so that the coating layers are attached to each other and then edge sealing is performed, and the rotation of the side bevel gears, the fixed shaft and the top bevel gears enables the optical fibers to move close to each other and place the optical fibers between the coating layers.

Preferably, a rotating opening with an upward opening is formed in the upper wall of the transmission cavity, the rotating opening is communicated with the transmission cavity and the outside, the linkage shaft extends upwards to the outside, a driving motor is fixedly connected to the upper wall of the driving cavity, the lower end of the driving motor is in power connection with a driving shaft, a driving belt pulley is fixedly connected to the outer peripheral surface of the driving shaft, an external belt pulley is fixedly connected to the outer peripheral surface of the linkage shaft, belt openings with back-to-back openings are formed in the left side wall and the right side wall of the driving cavity, a driving belt is rotatably connected between the external belt pulley and the driving belt pulley, the outer peripheral surface of the driving belt is in sliding connection with the inner wall of the belt opening, when the optical fiber and the coating in the optical cable need to be subjected to full-automatic processing, the driving motor is started at, The external belt pulley rotates to enable the optical cable to be processed and sealed to carry out next transmission.

Preferably, the processing chamber upper wall fixedly connected with air pump, air pump lower extreme fixedly connected with elasticity pipe, be equipped with the trachea in the elasticity pipe, trachea downwardly extending to in the removal piece just the trachea is in the removal piece, the trachea be close to each other one end adsorb connect in one end is kept away from each other to optic fibre, the elasticity pipe continues downwardly extending to the centre pivoted lever, in the centre pivoted lever the trachea be close to each other one end adsorb and be connected with the coating, will optic fibre with the coating is arranged in when the processing intracavity, start this moment the air pump, and then right optic fibre with the coating adsorbs, makes the coating can be located between the splint, makes optic fibre can be located place in the mouth.

The invention has the beneficial effects that: the optical core and the outer back coating of the optical cable can be fully automatically processed in the optical cable processing process, so that the optical cable processing working efficiency is improved, defects such as flash and the like often appear in the coating in the common optical cable processing, the flash needs to be removed manually or by specific equipment, and the full-automatic optical cable processing device can be used for removing the flash in real time after the optical cable is coated, so that the full-automatic optical cable processing working efficiency is improved.

Drawings

In order to more clearly illustrate the embodiments of the invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the invention, and it is obvious for those skilled in the art that other drawings can be obtained based on these drawings without creative efforts.

The invention is further illustrated with reference to the following figures and examples.

Fig. 1 is a schematic overall structure diagram of a full-automatic processing edge sealing device for an optical cable coating layer according to the invention.

Fig. 2 is a schematic view of the structure a-a in fig. 1.

Fig. 3 is an enlarged schematic view of B in fig. 1.

Fig. 4 is an enlarged schematic view of C in fig. 1.

Fig. 5 is an enlarged schematic view of D in fig. 1.

Detailed Description

The invention will now be described in detail with reference to fig. 1-5, wherein for ease of description the orientations described hereinafter are now defined as follows: the up, down, left, right, and front-back directions described below correspond to the up, down, left, right, and front-back directions in the projection relationship of fig. 1 itself.

The invention relates to a full-automatic processing and edge sealing device for an optical cable coating layer, which comprises edge sealing equipment 11, wherein a processing cavity 12 with a forward opening is arranged in the edge sealing equipment 11, a driving cavity 14 is arranged at the upper side of the processing cavity 12, two transmission cavities 13 are arranged at the sides of the processing cavities 12 far away from each other, the two transmission cavities 13 are symmetrically distributed and arranged from left to right by taking the central line of the processing cavity 12 as the symmetric center, a moving motor 36 is fixedly connected to the rear wall of the processing cavity 12, two embedding shafts 40 are rotatably connected to the rear wall of the processing cavity 12, the two embedding shafts 40 are symmetrically distributed and arranged up and down by taking the central line of the processing cavity 12 as the symmetric center, a driven belt pulley 41 is fixedly connected to the outer peripheral surface of each embedding shaft 40, a transmission shaft 39 is dynamically connected to the front end of each moving motor 36, a moving belt pulley 37 is fixedly connected to the outer, the front end of the driven pulley 41 is fixedly connected with a rear screw rod 42, the peripheral surface of the rear screw rod 42 is in threaded connection with a movable threaded block 53, the movable threaded block 53 is vertically close to one end of a material container 52, the end of the material container 52 close to one end of a heater 43 is fixedly connected, an injector 44 is arranged in the heater 43, the end of the injector 44 far away from each other is fixedly connected to the end of the material container 52 close to one end of the material container 52, the end of the material container 52 close to one end is fixedly connected with two stabilizing springs 51, the two stabilizing springs 51 are distributed and arranged in bilateral symmetry with the central line of the material container 52 as the symmetry center, the end of the stabilizing spring 51 close to one end is fixedly connected with a swing rod 50, the front end of the swing rod 50 is rotatably connected with a front shaft 47, and, the outer peripheral surface of the preposed torsion spring 45 is fixedly connected with an encircling shaft 49, the encircling shaft 49 is close to one end of the edging plate 48, which is far away from the injector 44, is in contact connection with one end of the injector, the processing cavity 12 is far away from one side wall of the processing cavity 66, which is provided with a sliding groove 66 with an opening back to the other side, the sliding groove 66 is communicated with the processing cavity 12 and the transmission cavity 13, the inner wall of the sliding groove 66 is rotatably connected with a horizontal thread block 67, a horizontal thread cavity 71 with opposite openings is arranged in the horizontal thread block 67, the inner wall of the horizontal thread cavity 71 is in threaded connection with a close screw rod 65, the close screw rod 65 is close to one end of the close screw rod 31, the pivot rod 31 is close to one end of the clamp plate 15, when the optical cable needs to be processed, the coating layer 16 of the, at this time, the moving motor 36 is started to drive the moving motor 36 and the moving belt pulley 37 to rotate, and further drive the moving belt 38 and the rear screw 42 to rotate, and further drive the moving screw block 53, the material container 52, the heater 43, the injector 44, the stabilizing spring 51, the swing rod 50, the front torsion spring 45, the front shaft 47, the edge sealing plate 48, and the surrounding shaft 49 to move along with the coating layer 16, at this time, the edge sealing material in the material container 52 enters the injector 44, at this time, the heater 43 is started to heat and melt the edge sealing material in the injector 44, so that the edge sealing material can perform edge sealing treatment on the upper and lower sides of the clamping plate 15 at the upper and lower positions of the clamping plate 15, and at this time, the horizontal screw block 67 rotates to drive the approaching screws 65 to move close to each other, and then drive central spindle 31 splint 15 is close to the removal each other, splint 15 will coating 16 presss from both sides tightly makes splint 15 can laminate each other and has guaranteed that the in-process of carrying out the banding can not appear leaking the banding material, this moment the banding board 48 is close to one end each other right the gap is smeared and is handled between the upper and lower end of coating 16, along with remove the removal cutting with unnecessary banding material along with the following of removal screw block 53, and the swing of banding board 48 and then drive leading torsional spring 45 leading axle 47 the ring axle 49 rotates, and then drives the swinging arms 50 swing, and then compress stabilizing spring 51, stabilizing spring 51 is right the vibrations of coating 16 in carrying out the banding in-process absorb the bradyseism, the processing banding of optical cable is accomplished this moment.

Beneficially, four sliding cavities 100 are arranged in the side walls of the processing cavity 12 which are far away from each other from the left and right, the four sliding cavities 100 are symmetrically distributed up and down and left and right with the center line of the processing cavity 12 as the symmetric center, a sliding threaded shaft 35 is rotatably connected to the inner wall of the sliding cavity 100, a threaded cavity 33 with opposite openings is arranged in the sliding threaded shaft 35, a threaded rod 32 is connected to the inner wall of the threaded cavity 33 in a threaded manner, a moving block 54 is fixedly connected to the end, which is close to each other, of the threaded rod 32, a placing block 64 is fixedly connected to the end, which is close to each other, of the placing block 64, two size openings 57 with opposite openings are arranged at the end, a placing opening 55 with opposite openings is arranged between the size openings 57, a size spring 56 is fixedly connected to the end, which is far away from each other, a sliding plate 63 is, the inner peripheral surface of the clamping wheel 62 is rotatably connected with a clamping torsion spring 61, the inner peripheral surface of the clamping torsion spring 61 is fixedly connected with a clamping shaft 58, one end of the clamping wheel 62, which is close to each other, is fixedly connected with a clamp 60, the inner wall of the placing opening 55 is connected with an optical fiber 59 in a contact manner, when the optical fiber 59 in the optical cable needs to be placed between the coating layers 16, the rotation of the screw rod 32 drives the moving block 54, the placing block 64, the dimension spring 56, the sliding plate 63, the clamping wheel 62, the clamping torsion spring 61, the clamp 60 and the clamping shaft 58 to move close to each other, and the clamp 60 swings and clamps the optical fiber 59, further drives the clamping torsion spring 61, the clamping wheel 62 and the clamping shaft 58 to rotate, further drives the sliding plate 63 to move away from each other, and further compresses the dimension spring 56, the size spring 56 adjusts the use of different sizes of the optical fiber 59 to clamp different sizes of the optical fiber 59.

Beneficially, a coupling shaft 17 is rotatably connected to the lower wall of the transmission cavity 13, a side bevel gear 34 is fixedly connected to the outer peripheral surface of the coupling shaft 17 at the lower side, a top bevel gear 18 is fixedly connected to the outer peripheral surface of the coupling shaft 17 at the upper side, a fixed shaft 30 is fixedly connected to the end of the sliding threaded shaft 35 away from each other, a bevel gear 29 is fixedly connected to the end of the fixed shaft 30 away from each other, the end of the side bevel gear 34 close to each other is engaged with the end of the bevel gear 29 at the lower side, the end of the top bevel gear 18 close to each other is engaged with the end of the bevel gear 29 at the upper side close to each other, a transverse shaft 70 is fixedly connected to the end of the transverse threaded block 67 far from each other, a transverse bevel gear 68 is fixedly connected to the end of the transverse shaft 70 far, one ends of the intermediate bevel gears 69 close to each other are in meshed connection with the upper ends of the transverse bevel gears 68, when it is desired to move the optical fibers 59 in the optical cable closer to each other, the rotation of the linking shaft 17 at this time, thereby driving the side bevel gears 34, the top bevel gear 18, the fixed shaft 30, the bevel gear 29, the top bevel gear 18, the horizontal screw block 67, the horizontal shaft 70, the horizontal bevel gear 68, and the middle bevel gear 69 to rotate, the rotation of the transverse bevel gear 68 and the transverse shaft 70 further moves the coating layers 16 toward each other so that the coating layers 16 are attached to each other and then edge sealed, the rotation of the side bevel gear 34, the bevel gear 29, the fixed shaft 30, and the overhead bevel gear 18 allows the optical fibers 59 to move closer to each other and place the optical fibers 59 between the cladding layers 16.

Beneficially, a rotating port 19 with an upward opening is arranged in the upper wall of the transmission cavity 13, the rotating port 19 is communicated with the transmission cavity 13 and the outside, the linkage shaft 17 extends upward to the outside, the upper wall of the driving cavity 14 is fixedly connected with a driving motor 23, the lower end of the driving motor 23 is in power connection with a driving shaft 24, the outer peripheral surface of the driving shaft 24 is fixedly connected with a driving belt pulley 22, the outer peripheral surface of the linkage shaft 17 in the outside is fixedly connected with an external belt pulley 28, belt ports 26 with opposite openings are arranged in the left and right side walls of the driving cavity 14, a driving belt 20 is rotatably connected between the external belt pulley 28 and the driving belt pulley 22, the outer peripheral surface of the driving belt 20 is slidably connected to the inner wall of the belt port 26, when the optical fiber 59 and the coating layer 16 in the optical cable need to be subjected to full, and then the driving shaft 24, the driving belt pulley 22, the driving belt 20 and the external belt pulley 28 are driven to rotate, so that the optical cable processing sealed edge can be subjected to the next transmission.

Advantageously, an air pump 25 is fixedly connected to the upper wall of the processing chamber 12, an elastic tube 27 is fixedly connected to the lower end of the air pump 25, an air tube 21 is disposed in the elastic tube 27, the air tube 21 extends downward into the moving block 54 and the air tube 21 is disposed in the moving block 54, the ends of the air tubes 21 close to each other are connected to the ends of the optical fibers 59 away from each other in an adsorption manner, the elastic tube 27 continues to extend downward to the central rod 31, the ends of the air tubes 21 close to each other in the central rod 31 are connected to the coating layer 16 in an adsorption manner, when the optical fibers 59 and the coating layer 16 are disposed in the processing chamber 12, the air pump 25 is activated, and the optical fibers 59 and the coating layer 16 are adsorbed, so that the coating layer 16 can be disposed between the clamping plates 15, and the optical fibers 59 can be disposed in the disposing.

The following detailed description of the steps of the fully automatic edge sealing device for processing the optical cable coating layer in the present disclosure is provided with reference to fig. 1 to 5:

initially, the air pump 25, the moving motor 36, the driving motor 23, and the heater 43 are in the off state, the coating layer 16 and the chucking plate 15 are in the mutually distant positions, the material container 52, the moving screw block 53, the heater 43, the injector 44, the swing lever 50, and the stabilizing spring 51 are in the rear side in the processing chamber 12, and the moving block 54, the screw 32, the placing block 64, the optical fiber 59, the dimension spring 56, the sliding plate 63, and the clamper 60 are in the mutually distant positions.

During the use, when optic fibre 59 and coating 16 in the optical cable need carry out full automatic processing, start driving motor 23 this moment, and then drive shaft 24, drive pulley 22, driving belt 20, external belt pulley 28 rotate and make the optical cable processing banding can carry out transmission on next step, when placing optic fibre 59 and coating 16 in the process chamber 12, start air pump 25 this moment, and then adsorb optic fibre 59 and coating 16, make coating 16 can be located between splint 15, make optic fibre 59 can be located and place the mouth 55.

When the optical fibers 59 in the optical cable need to move close to each other, the rotation of the coupling shaft 17 drives the side bevel gear 34, the top bevel gear 18, the fixing shaft 30, the bevel gear 29, the top bevel gear 18, the transverse screw block 67, the transverse shaft 70, the transverse bevel gear 68 and the intermediate bevel gear 69 to rotate, the rotation of the transverse bevel gear 68 and the transverse shaft 70 further drives the coating layers 16 to move close to each other so that the coating layers 16 are attached to each other and then sealed, the rotation of the side bevel gear 34, the bevel gear 29, the fixing shaft 30 and the top bevel gear 18 enables the optical fibers 59 to move close to each other and place the optical fibers 59 between the coating layers 16, and when the optical fibers 59 in the optical cable need to be placed between the coating layers 16, the rotation of the screw 32 drives the moving block 54, the placing block 64, the size spring 56, the sliding plate 63 and the clamping wheel 62 to, The clamping torsion spring 61, the clamping device 60 and the clamping shaft 58 move close to each other, the clamping device 60 swings and clamps the optical fiber 59, the clamping torsion spring 61, the clamping wheel 62 and the clamping shaft 58 are driven to rotate, the sliding plate 63 is driven to move away from each other, the size spring 56 is compressed, and the size spring 56 adjusts the optical fiber 59 using different sizes to clamp the optical fiber 59 of different sizes.

When the optical cable needs to be processed, the coating layer 16 of the optical cable is in the middle of the processing cavity 12, the moving motor 36 is started at the moment, the moving motor 36 and the moving belt pulley 37 are further driven to rotate, the moving belt 38 and the rear screw rod 42 are further driven to rotate, the moving thread block 53, the material container 52, the heater 43, the injector 44, the stabilizing spring 51, the swinging rod 50, the front torsion spring 45, the front shaft 47, the edge sealing plate 48 and the surrounding shaft 49 are further driven to move along with the coating layer 16, the edge sealing material in the material container 52 enters the injector 44 at the moment, the heater 43 is started at the moment to heat and melt the edge sealing material in the injector 44, so that the edge sealing material can perform edge sealing treatment on the upper part and the lower part of the splint 15 at the upper part and the lower part of the splint 15, and the transverse thread block 67 rotates to drive the approaching screw rods, Splint 15 is close to the removal each other, splint 15 presss from both sides tightly the coating 16 and makes splint 15 can laminate each other and guarantee that the in-process of carrying out the banding can not appear leaking the banding material, banding board 48 is close to one end each other and is carried out floating treatment to the gap between the upper and lower end of coating 16 this moment, remove the cutting with unnecessary banding material along with the following removal of removing screw thread piece 53, and the swing of banding board 48 and then drive leading torsional spring 45, leading axle 47, encircle the axle 49 rotation, and then drive the swing arm 50 swing, and then compression stabilizing spring 51, stabilizing spring 51 absorbs the bradyseism to the vibrations of coating 16 at the in-process of carrying out the banding, the processing banding of optical cable is accomplished this moment.

The invention has the beneficial effects that: the optical cable processing device can fully automatically process the optical core and the coating layer on the outer back surface of the optical cable in the optical cable processing process so as to improve the working efficiency of optical cable processing, while in common optical cable processing, the coating layer often has defects such as flash and the like, so that the flash needs to be removed manually or by specific equipment, and the optical cable processing device can perform real-time flash removing operation on the coating layer after the optical cable is coated so as to fully automatically improve the working efficiency.

The above embodiments are merely illustrative of the technical ideas and features of the present invention, and the purpose thereof is to enable those skilled in the art to understand the contents of the present invention and implement the present invention, and not to limit the protection scope of the present invention. All equivalent changes and modifications made according to the spirit of the present invention should be covered within the protection scope of the present invention.

Claims (5)

1. The utility model provides a full automatic processing banding device of optical cable coating, includes banding equipment, its characterized in that: a processing cavity with a forward opening is arranged in the edge sealing equipment, a driving cavity is arranged on the upper side of the processing cavity, two transmission cavities are arranged on one side of the processing cavity away from each other, the two transmission cavities are arranged in a bilateral symmetry mode by taking the center line of the processing cavity as a symmetry center, a moving motor is fixedly connected to the rear wall of the processing cavity, two embedding shafts are rotationally connected to the rear wall of the processing cavity, the two embedding shafts are arranged in a vertical symmetry mode by taking the center line of the processing cavity as the symmetry center, a driven belt pulley is fixedly connected to the outer peripheral surface of the embedding shafts, a transmission shaft is in power connection with the front end of the moving motor, a moving belt pulley is fixedly connected to the outer peripheral surface of the transmission shaft, a moving belt is rotationally connected between the moving belt pulley and the driven belt pulley, a rear screw is fixedly connected, the movable thread block is vertically close to one end of a fixedly connected material container, the material container is close to one end of a fixedly connected heater, an injector is arranged in the heater, one end, away from each other, of the injector is fixedly connected to one end, close to each other, of the material container, the material container is close to one end of the material container, two stabilizing springs are fixedly connected to the other end of the material container, the two stabilizing springs are distributed and arranged in a bilateral symmetry mode by taking the center line of the material container as the center of symmetry, the stabilizing springs are close to one end of the oscillating rod, the front end of the oscillating rod is rotatably connected with a front shaft, a front torsion spring is fixedly connected to the outer peripheral surface of the front shaft, an encircling shaft is fixedly connected to the outer peripheral surface of the front torsion spring, one end, close to each other, of the, the processing chamber keeps away from each other and is equipped with the sliding tray that the opening carried on the back mutually in the lateral wall, the sliding tray intercommunication the processing chamber with the transmission chamber, it is connected with horizontal screw thread piece to rotate on the sliding tray inner wall, be equipped with the horizontal screw thread chamber that the opening is relative in the horizontal screw thread piece, horizontal screw thread intracavity wall threaded connection has and is close to the screw rod, it is close to one end fixedly connected with pivot pole each other to be close to the screw rod, the pivot pole is close to one end fixedly connected with splint each other.

2. The full-automatic edge sealing device for the optical cable coating layer according to claim 1, wherein: the machining cavity is internally provided with four sliding cavities which are mutually far away from the left side and the right side, the four sliding cavities are symmetrically distributed up and down and left side and right side by taking the center line of the machining cavity as a symmetric center, the inner wall of the sliding cavity is rotationally connected with a sliding threaded shaft, the sliding threaded shaft is internally provided with a threaded cavity with opposite openings, the inner wall of the threaded cavity is in threaded connection with a screw rod, the screw rod is mutually close to one end and is fixedly connected with a moving block, the moving block is mutually close to one end and is fixedly connected with a placing block, one end of the placing block is mutually close to one end and is provided with two size openings with opposite openings, a placing opening with opposite openings is arranged between the size openings, one end of the size openings mutually far away from one end is fixedly connected with a size spring, one end, the inner peripheral surface of the clamping torsion spring is fixedly connected with a clamping shaft, the clamping wheels are mutually close to one end of the clamping shaft and fixedly connected with a clamping device, and the inner wall of the placing opening is in contact connection with an optical fiber.

3. The full-automatic edge sealing device for the optical cable coating layer according to claim 1, wherein: a coupling shaft is rotationally connected with the lower wall of the transmission cavity, a side bevel gear is fixedly connected with the outer peripheral surface of the coupling shaft at the lower side, an overhead bevel gear is fixedly connected with the outer peripheral surface of the coupling shaft at the upper side, one end of the sliding threaded shaft, which is far away from each other, is fixedly connected with a fixed shaft, one end of the fixed shaft, which is far away from each other, is fixedly connected with a bevel gear, one end of the side bevel gear close to each other is meshed and connected with one end of the bevel gear far away from each other on the lower side, one end of the overhead bevel gear close to each other is meshed and connected with one end of the bevel gear on the upper side close to each other, one ends of the transverse threaded blocks, which are far away from each other, are fixedly connected with transverse shafts, one ends of the transverse shafts, which are far away from each other, are fixedly connected with transverse bevel gears, and the outer peripheral surface of the middle of the linkage shaft is fixedly connected with a middle bevel gear, and one end of the middle bevel gear, which is close to each other, is meshed with the upper end of the transverse bevel gear.

4. The full-automatic edge sealing device for the optical cable coating layer according to claim 1, wherein: be equipped with the ascending rotation mouth of opening in the transmission chamber upper wall, rotate a mouthful intercommunication transmission chamber and external, the interlock is upwards extended to the external world, drive chamber upper wall fixedly connected with driving motor, driving motor lower extreme power is connected with the drive shaft, fixedly connected with drive pulley on the drive shaft outer peripheral face, external fixedly connected with external belt pulley on the interlock axle outer peripheral face, be equipped with the belt mouth that the opening was carried on the back mutually in the lateral wall about the drive chamber, external belt pulley with it is connected with driving belt to rotate between the drive pulley, driving belt outer peripheral face sliding connection in on the belt mouth inner wall.

5. The full-automatic edge sealing device for the optical cable coating layer according to claim 1, wherein: processing chamber upper wall fixedly connected with air pump, air pump lower extreme fixedly connected with elasticity pipe, be equipped with the trachea in the elasticity pipe, trachea downwardly extending extremely in the removal piece just the trachea is in the removal piece, the trachea be close to each other one end adsorb connect in the one end is kept away from each other to optic fibre, the elasticity pipe continues downwardly extending to the pivot pole, in the pivot pole the trachea is close to one end each other and adsorbs and is connected with the coating.

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