KR101696319B1

KR101696319B1 - Optical cable Winding System

Info

Publication number: KR101696319B1
Application number: KR1020150050028A
Authority: KR
Inventors: 이재수
Original assignee: 주식회사 골드텔
Priority date: 2015-04-09
Filing date: 2015-04-09
Publication date: 2017-01-16
Also published as: WO2016163625A1; KR20160121625A

Abstract

The present invention relates to an optical fiber automatic discharge winding system capable of automatically winding an optical cable, thereby greatly improving work convenience and product productivity. The system includes an optical bobbin having an optical cable, a bobbin motor for rotating the bobbin, ; A roller motor having an extraction roller for rotating reciprocatingly with an optical fiber inserted from the optical fiber feeder interposed therebetween, an encoder for rotating the extraction roller and counting the number of rotation of the extraction roller, and a cutter for cutting the optical cable passing through the extraction roller An automatic cutting unit comprising: A winder for winding an optical cable emitted from the automatic cutting unit; And a control unit for controlling the operation of the cutter to receive the rotation number from the encoder and to cut the optical cable.
According to this embodiment, it is possible to improve the convenience of work by automating a series of processes from the supply of the optical cable to the process of cutting a certain length of the cord on the winding side, and the uniform production of the product and the mass production of the product There is an advantage that can be maximized.

Description

TECHNICAL FIELD [0001] The present invention relates to an optical cable winding system,

The present invention relates to an optical fiber automatic discharge winding system capable of automatically winding an optical cable, thereby greatly improving workability and productivity.

Generally, a winding machine is a device that winds an electric wire drawn through a device such as a drawing machine or a twister, to a bobbin. In the winding method of a winding machine for a wire (or an optical cable) The bobbin is rotated to wind the wire constantly on the outer circumferential surface of the bobbin.

In this case, the operator winds the wire (or optical cable) by a predetermined length and winds it, and then the wire (or optical cable) is wound around the binding bobbin ) Is used to fix the winding so that it is not loosened.

However, since the work has to be manually performed by a worker as described above, the work is inconvenient and the length of the wound wire (or optical cable) is not constant, so that the worker has to depend heavily on the skill of the worker. There was a big problem.

1. Korean Registered Patent No. 10-1188075 (Wire winding machine / 2012.09.26) 2. Korean Registered Patent No. 10-1456884 (Kwon Chokki / 2014.10.27)

An object of the present invention is to provide an optical fiber automatic discharge winding system capable of automatically winding an optical cable, thereby greatly improving the convenience of work and productivity of the product.

According to an aspect of the present invention,

An optical cable feeder comprising a bobbin having an optical cable and a bobbin motor for rotating the bobbin;

A roller motor having an extraction roller for rotating reciprocatingly with an optical fiber inserted from the optical fiber feeder interposed therebetween, an encoder for rotating the extraction roller and counting the number of rotation of the extraction roller, and a cutter for cutting the optical cable passing through the extraction roller An automatic cutting unit comprising:

A winder for winding an optical cable emitted from the automatic cutting unit;

And a control unit for controlling the operation of the cutter to receive the rotation number from the encoder and to cut the optical cable.

Here,

A drum having a tubular shape whose interior is opened upward and a post placed on an inner bottom surface thereof is radially arranged to wind the optical cable;

And a drum motor installed at a lower portion of the drum to rotate the drum.

Here,

A first assembly and a second assembly that are disposed opposite to each other with the optical cable interposed therebetween;

The first / second assembly includes:

A base movably installed via the LM guide,

A reciprocating feed mechanism for reciprocating the base,

A rotating body rotatably installed on the base, a winding bundle composed of a post projected radially on one surface of the rotating body,

And a winding bundle motor for rotating the winding bundle;

In any one of the winding bundles of the first and second assemblies,

And a pushing motor that is rotatably installed on the rotating body and fixes the optical cable together with the post, and a pushing motor that rotates the pushing tool.

Here, the post is provided movably in the rotating body.

Further, in the present invention, a tensioner for applying a constant tension to the optical cable is reinforced between the optical cable feeder and the drawing roller.

Further, in the present invention, a guider for guiding an optical cable is reinforced between the cutter and the winder.

Also, in the present invention, a guider rotator, which rotates the guider and is controlled by the control unit, is reinforced.

Further, the present invention is characterized in that the automatic tape feeder is controlled by the control unit so that the optical cable wound on the winder can be bundled.

According to this embodiment, it is possible to improve the convenience of work by automating a series of processes from the supply of the optical cable to the process of cutting a certain length of the cord on the winding side, and the uniform production of the product and the mass production of the product There is an advantage that can be maximized.

1 and 2 are a front view and a plan view showing a simplified optical fiber automatic discharge winding system according to a first embodiment of the present invention.
FIG. 3 is a perspective view of a winder taken in an optical fiber automatic discharge winding system according to a first embodiment of the present invention. FIG.
FIG. 4 is a block diagram showing the interrelationship between respective components in the optical fiber automatic discharge winding system according to the first embodiment of the present invention. FIG.
5 is a plan view of an optical fiber automatic discharge winding system according to a second embodiment of the present invention.
FIG. 6 and FIG. 7 are perspective views showing a winder taken separately in an optical fiber automatic discharge winding system according to a second embodiment of the present invention. FIG.
8A to 8D are diagrams for explaining the operation relationship of the winder in the optical cable automatic discharge winding system according to the second embodiment of the present invention.
FIG. 9 is a block diagram showing an interrelationship between respective components in an optical fiber automatic discharge winding system according to a second embodiment of the present invention; FIG.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

1 and 2 are a front view and a plan view showing a simplified optical fiber automatic discharge winding system according to a first embodiment of the present invention, and FIG. 3 is a cross-sectional view of the automatic winding discharge system according to the first embodiment of the present invention, And FIG. 4 is a block diagram showing an interrelationship between respective components in the optical cable automatic discharge winding system according to the first embodiment of the present invention.

Referring to FIGS. 1 to 4, the optical fiber automatic discharge winding system according to the first embodiment of the present invention is an apparatus for automatically cutting a continuously supplied optical cable 1 to a predetermined length, 100, an automatic cutting unit 200, a winder 300, and a control unit 600, and may further include an adhesive tape automatic feeder 500.

The optical cable feeder 100 includes a bobbin 110 wound around an optical cable 1 and a bobbin motor 120 for loosening a wound optical cable 1 by rotating the bobbin 110. Here, Is controlled by the controller (600).

The automatic cutting unit 200 includes draw-out rollers 210 and 210 'that rotate with each other with the optical cable 1 pulled in from the optical cable feeder 100 interposed therebetween, and rollers 210 and 210' A roller motor 220 having an encoder 221 for counting the number of rotations of the optical fibers 1 and 2 and a cutter 230 for cutting the optical cable 1 passed through the drawing rollers 210 and 210 '.

In this embodiment, the drawing-out rollers 210 and 210 'are vertically stacked. The drawing-out roller 210' located at the bottom of the drawing rollers 210 is rotated by a roller motor 220 equipped with an encoder 221, The upper drawing roller 210 which is brought into mutual contact due to the rotation of the lower drawing roller 210 'also rotates together so that the optical cable 1 disposed between the drawing rollers 210 and 210' And is naturally drawn toward the winder 300 by the frictional force between them.

In particular, it is preferable that the drawing-out rollers 210 and 210 'can accommodate both of the drawn-out optical fibers 1 regardless of the thickness of the drawn-out optical cable 1. For example, a pressing mechanism 270 such as a pneumatic cylinder, (210, 210 ') to adjust the gap between the take-out rollers (210, 210') and to generate a constant pressing force.

At this time, the number of rotations of the roller motor 220 is counted by the encoder 221, and the number of rotations of the roller motor 220 is controlled by the controller 600 . For reference, the number of revolutions of the roller motor 220 is the total length of the optical cable 1 passing between the drawing rollers 210 and 210 '.

The cutter 230 is a pneumatic cylinder (or a hydraulic cylinder) equipped with a blade. In the present embodiment, the cutter 230 has a function of cutting the optical cable 1 passed through the take-out roller 210 ' do.

Between the bobbin 110 and the drawing rollers 210 and 210 'is provided a tensioner 240 for applying a predetermined tension to the optical cable 1 due to its own weight. A tensioner 240 is provided between the tensioner 240 and the drawing rollers 210 and 210' A guide roller GR for guiding the optical cable 1 that has passed through the optical fiber 240 is provided.

The guider 250 is disposed adjacent to the cutter 230 and guides the optical cable 1 to the inside of the winder 300.

1 to 3, the winder 300 includes a drum 310 and a drum motor 320. In the present embodiment, the optical cable 1 guided by the guider 250 has a length It has a function of winding and storing.

The drum 310 is opened upward. A plurality of posts 311 are radially arranged inside the drum 310, and the optical cable 1 is wound and stored.

The drum motor 320 is controlled by the controller 600 to rotate the drum 310.

The optical cable 1 drawn between the inner surface of the drum 310 and the post 311 is naturally wrapped around the post 311 rotated by the drum motor 320 and stored inside the drum 310 The operator can take out the wound optical cable 1 to the outside, which is advantageous in that the work becomes considerably convenient.

On the other hand, the present embodiment further comprises a known adhesive tape automatic feeder 500 (see Fig. 3) for cutting the adhesive tape T to a predetermined length.

In the present embodiment, the adhesive tape automatic feeder 500 is operated and controlled by the control unit 600, and the operator can easily bind the optical cable 1 drawn out from the winder 300, And maximize the convenience of the operation.

4, the control unit 600 receives the rotation number from the encoder 221 and receives the rotation number of the bobbin motor 120, the roller motor 220, the cutter 230, the drum motor 320, 500).

Hereinafter, the operation of the present invention will be described.

The bobbin 110 of the optical cable feeder 100 is rotated by the bobbin motor 120 so that the optical cable 1 wound on the bobbin 110 is released and the optical cable 1 is released from the tensioner 240 and guide Passes through between the drawing rollers 210 and 210 'which are rotated by the roller motor 220 via the rollers GR and the number of rotations of the roller motor 220 is counted by the encoder 221, 600).

The optical cable 1 having passed through the drawing rollers 210 and 210 'passes through the cutter 230 and the guider 250 and is drawn into the winder 300. The optical cable 1, which is drawn into the winder 300, Is naturally wound on the post 311 of the drum 310 being rotated by the drum motor 320.

The control unit 600 controls the cutter 230 in a state where it stops controlling operations of the bobbin motor 120, the roller motor 220 and the drum motor 320 immediately after a preset number of rotations is sensed The optical cable 1 is cut and the drum motor 320 is operated so that the less wound optical cable 1 is wound around and the adhesive tape automatic feeder 500 is operated to control the adhesive tape T to be discharged.

The operator of the winder of the optical cable 1 is connected to the winder 300 by the adhesive tape T so that the optical cable 1 rolled up in the state of pulling the optical cable 1 out is not loosened, Store and load in box.

When the above-described series of processes is completed, the optical cable automatic discharge winding system according to the present invention operates in accordance with the above-mentioned procedure.

The second embodiment of the present invention is substantially the same as the first embodiment, but differs from the first embodiment only in that the structure of the winder 400 and the guider rotator 260 are further added. Hereinafter, The structure of the winder 400 will be described in detail.

FIG. 5 is a plan view of an optical fiber automatic discharge winding system according to a second embodiment of the present invention, and FIGS. 6 and 7 are perspective views showing a winding machine taken in an optical fiber automatic discharge winding system according to a second embodiment of the present invention 8A to 8D are views for explaining the operation of the winder in the optical fiber automatic discharge winding system according to the second embodiment of the present invention. FIG. 4 is a block diagram illustrating interrelationships among components in the system. FIG.

5, the guider rotator 260 is disposed adjacent to the guider 250 to be operated and controlled by the controller 600, and one end of the optical cable 1, which is discharged through the guider 250, And functions to rotate the guider 250 toward the pushing member 444 so as to be disposed and fixed between the posts 442.

Here, the guider rotator 260 may be a pneumatic cylinder, a hydraulic cylinder, or the like, and any known one can be used as long as it can perform the same function.

The guider 250 is rotated by the guider rotator 260 (see FIGS. 5 and 7) and is disposed between the pressurizing member 444 and the post 442, and is discharged through the guider 250 The optical fiber 1 is fixed by the pushing tool 444 and the post 442 and thereafter is gradually returned to the initial state by the guider rotator 260 again.

6 to 8D, the winder 400 is divided into a first assembly 400A and a second assembly 400B which are disposed opposite to each other with the optical cable 1 interposed therebetween, And automatically discharges it.

The first and second assemblies 400A and 400B include a base 420 and a reciprocating feed mechanism 430. The first and second assemblies 400A and 400B include a winding bundle 440 and a winding bundle motor 450.

The base 420 is a block movably installed via the LM guide 410 and functions to support the winding bundle 440 and the winding bundle motor 450 installed.

The reciprocating feed mechanism 430 includes a screw 431 and a feed member 432 for reciprocally feeding the screw 431 along the longitudinal direction of the screw 431 and a control unit 600 for controlling the screw 431 in a forward or reverse direction And a feed motor 433 for rotating the feed motor 433.

In the present embodiment, the base 420 is installed below the base 420 to reciprocate the base 420.

The winding bundle 440 is composed of a rotating body 441, a post 442, a jaw 443, a pushing tool 444, and a pushing motor 445.

The winding bundle 440 includes a post 442 and a pressurizing hole 444 and a pressurizing hole motor 445 and a pressurizing hole motor 445 on a known pneumatic (air or hydraulic) chuck composed of a rotating body 441 and a plurality of tanks 443. [ Here, the structure of the pneumatic (air or hydraulic) chuck constituted by the rotating body 441 and the trough 443 is a well-known technology, and therefore, a detailed description thereof will be omitted.

The post 442 is a member that is radially arranged to protrude from one surface of the rotating body 441 and winds the optical cable 1. As shown in Fig. 6, a part of the post 442 is attached to the jaw 443 And the remaining part is installed between the tanks 443. [

According to this embodiment, when the tub 443 is moved toward the center in a state that the optical cable 1 is wound around the post 442, the post 442 having an octagonal shape (see FIG. 8C) (See FIG. 8C). As a result, the optical cable 1 wound with a constant tension is loosened, so that the first assembly 400A and the second assembly 400B can be easily separated from each other .

It is preferable that the post 442 is movably installed in the rotating body 441 so that the optical cable 1 having different diameters can be wound. For example, the post 442 may be attached to the plurality of tanks 443 There is an advantage that winding of the optical cable 1 having various diameters becomes possible in accordance with the movement of the jaws 443.

In another embodiment, as a method of moving the posts 442 disposed between the tanks 443, there is a method in which the engaging holes 441a are formed at regular intervals along virtual lines extending from the center of the rotating plate 441 toward the edge, And the post 442 is provided in the coupling hole 441a, the entire size of the post 442 arranged in a radial direction can be reduced or increased so that the winding of the optical cable 1 having a different diameter It becomes possible.

The pushing member 444 is rotatably installed on the rotating body 441 and functions to fix the optical cable 1 together with the post 442 by fixing it.

The pushing motor 445 is an electric motor or is operated by a pneumatic (air or hydraulic) operation. The pushing motor 445 is operated by the control unit 600 to rotate the pushing tool 444, Or a cylinder (actuator) operated by a pneumatic (air or hydraulic) pressure. Any other known means can be applied as long as it can perform the same function.

A spring 446 is installed on the pushing member 444 to increase the pressing force between the pushing member 444 and the post 442 to strongly fix the optical cable 1. In this embodiment, One end is provided in the pushing tool 444 and the other end is provided in the rotating body 441 and pulls the pushing tool 444.

The winding bundle motor 450 is controlled by the controller 600 to rotate the winding bundle 440.

The operation of the optical fiber automatic discharge winding system according to the second embodiment of the present invention will be described as follows.

6 to 8A, the first and second assemblies 400A and 400B of the take-up machine 400 are conveyed by the reciprocating conveying mechanism 430 until the posts 442 come into contact with each other, The control unit 600 controls the operation of the guider rotator 260 so that the optical cable 1 exposed through the distal end of the guider 250 rotates about the first The control unit 600 rotates the guider 250 to the left (see FIGS. 5 and 7) so as to be drawn between the post 442 of the assembly 400A and the pressurizing member 444. At this time, The pusher motor 445 is operated to rotate the pusher 444 so as to hold the optical cable 1 together with the post 442.

When the optical cable 1 is fixed by the pushing part 444 and the post 442 as described above, the control part 600 controls the winding roll motor 450 to gradually rotate the winding roll 440 The guider rotator 260 is operated to return the guider 250 to the home position gradually, so that the optical cable 1 is wound around the post 442 abutting on each other.

For example, the control unit 600 controls the winding bundle motor 450 at three speeds to prevent the optical cable 1 wound on the winding bundle 440 from stretching. As an example, The rotation is performed at a maximum speed in the middle, and the rotation is controlled so as to be slowly rotated again at the end.

The bobbin 110 of the optical cable feeder 100 is rotated by the bobbin motor 120 so that the optical cable 1 wound on the bobbin 110 is released and the unwound optical cable 1 is driven by the tensioner 240 and the guide Passes through between the drawing rollers 210 and 210 'which are rotated by the roller motor 220 via the rollers GR and the number of rotations of the roller motor 220 is counted by the encoder 221, 600).

The optical cable 1 having passed through the drawing rollers 210 and 210 'passes through the cutter 230 and the guider 250 and is wound around the posts 442 of the first and second assemblies 400A and 400B.

The controller 600 controls the cutter 230 to stop the operations of the bobbin motor 120, the roller motor 220 and the winding coiler motor immediately after the preset number of rotations is sensed. Cuts the optical cable 1 and operates the winding bundle motor 450 to wind the less wound optical cable 1 and rotates the pushing tool 444 through the pushing motor 445 to rotate the optical cable 1 And controls the operation of the adhesive tape automatic feeder 500 so that the adhesive tape T is ejected. As shown in FIG.

When the jaws 443 provided with the posts 442 are moved in the center direction as described above, the posts 442 having the octagonal shape (see Fig. 8C) are changed into quadrangular shapes (see Fig. 8C) , So that the optical cable 1 wound with a constant tension is loosened.

The first and second assemblies 400A and 400B are held by the reciprocating conveying mechanism 430 while holding the optical cable 1 wound on the posts 442 of the first and second assemblies 400A and 400B, The optical cables 1 wound from the posts 442 of the first and second assemblies 400A and 400B can be easily separated and the separated optical cables 1 are bound by the adhesive tape T It can be stored and loaded in a separate box.

When the above-described series of processes is completed, the optical cable automatic discharge winding system according to the second embodiment of the present invention operates in accordance with the above-mentioned procedure.

It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the present invention as defined by the appended claims.

1: optical cable 100: optical cable feeder 110: bobbin
120: Bobbin motor 200: Automatic cutting unit 210.210 ': Draw-out roller
220: roller motor 221: encoder 230: cutter
240: tensioner 250: guider 260: guider rotator
270: pressurizing device 300: take-up device 310: drum
311: Post 320: Drum motor 400: Winder
400A, 400B: first and second assemblies 410: LM guide
420: base 430: reciprocating feed mechanism 431: screw
432: feed member 433: feed motor 440: winding bundle
441: Rotor 442: Post 443: Joe
444: pressure applying tool 445: pressure applying motor 446: spring
450: Roll bundle motor 500: Adhesive tape automatic feeder
600:

Claims

An optical cable feeder comprising a bobbin having an optical cable and a bobbin motor for rotating the bobbin; A roller motor having an extraction roller for rotating reciprocatingly with an optical fiber inserted from the optical fiber feeder interposed therebetween, an encoder for rotating the extraction roller and counting the number of rotation of the extraction roller, and a cutter for cutting the optical cable passing through the extraction roller An automatic cutting unit comprising: A winder for winding an optical cable emitted from the automatic cutting unit; And a controller for controlling the operation of the cutter to receive the rotation number from the encoder and to cut the optical cable, the automatic optical winding winding system comprising:
Wherein the winder is divided into a first assembly and a second assembly which are disposed opposite to each other with the optical cable interposed therebetween;
The first and second assemblies include a base movably installed via an LM guide, a reciprocating transport mechanism for reciprocating the base, a rotating body rotatably installed on the base and having a movable tank, A rewinding bundle including a plurality of posts arranged radially so as to protrude from the yarn bundle and a plurality of posts arranged movably between the jaws and a rewinding bundle motor for rotating the winding bundle;
Wherein either one of the winding bundles of the first and second assemblies is provided with a pressing member rotatably installed on the rotating body to fix the optical cable together with the posts and a pressing tool motor for rotating the pressing tool;
And a guider for guiding the optical cable between the cutter and the take-up unit, and a guider rotator for controlling the operation of the guider by the control unit to further rotate the guider rotator.

The method according to claim 1,
And a tensioner is provided between the optical cable feeder and the drawing roller to apply a predetermined tension to the optical cable.

The method according to claim 1,
And an automatic adhesive tape feeder that is controlled by a control unit to bundle the optical cable wound on the winder is further reinforced.

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