KR101583798B1 - Apparatus and method for recoating optical fiber - Google Patents

Abstract

The present invention provides an apparatus and a method for recoating an optical fiber capable of quickly recoating the optical fiber without respect to a shape and a type of the optical fiber. The apparatus comprises: a support unit supporting a fiber; a solution supply unit supplying recoating solution to an optical fiber; a light source irradiating an ultraviolet ray from a lower side of the optical fiber toward the optical fiber; and a transfer unit connected to the light source and transferring the light source to the optical fiber horizontally. Therefore, quick recoating about an optical fiber is enabled without respect to a shape and a type of the optical fiber so that recoating work efficiency is improved.

Description

TECHNICAL FIELD [0001] The present invention relates to an optical fiber recoating apparatus,

The present invention relates to a recoating device and a recoating method, and more particularly, to an optical fiber recoating device and a recoating method.

Generally, an optical fiber means an optical fiber that prevents light passing through the center from being totally reflected based on different refractive indexes of the center and the edge. Fiber optics has the advantage of low loss of data transmitted and received due to low energy loss and is not affected by external conditions.

Such an optical fiber may be damaged depending on the use environment and conditions, so that the damaged portion of the cloth is repaired by a method of recoating. Recoating is also performed in the re-bonding of optical fibers or in the production of optical fiber elements.

The prior art for optical fiber recoating has already been disclosed in Korean Patent Laid-Open Publication No. 2001-0011668 (Long Coating Fiber Bragg Grating Recoating Apparatus and Method). The present invention is characterized in that the optical fiber is supported in a vertical state and irradiated with ultraviolet rays to perform recoating of the optical fiber.

On the other hand, the optical fiber recoating method can be classified into a high refractive index recoating method and a low refractive index recoating method. In case of the high refractive index recoating method, it can be realized as a low intensity ultraviolet light source as a technology for application to a general communication optical fiber. In general, most conventional optical fiber recoating devices are intended to perform a high refractive index recoating method and have a configuration that is difficult to implement a low refractive index recoating method. The low refractive index recoating method is applied to optical fiber lasers and special optical fiber recoating, and there is a problem that it is difficult to perform in a conventional optical fiber recoating device because a high intensity ultraviolet light source is required.

As described above, in the conventional optical fiber re-coating technique, there is a problem that the efficiency of the recoating operation is lowered due to the limited recoating method and the optical fiber re-coating operation for a specific use due to the limited ultraviolet ray irradiation area and the limited intensity of the light source.

Korean Patent Laid-Open Publication No. 2001-0011668 (Recording apparatus and method for a long-period fiber grating)

An object of the present invention is to provide an optical fiber recoating device and a recoating method which can be applied to a high-refractive index recoating method and a low-refraction recoating method regardless of a specific recoating method.

It is another object of the present invention to provide an optical fiber recoating device and a recoating method capable of rapid re-coating of an optical fiber regardless of the type and kind of the optical fiber.

The optical fiber re-coating apparatus according to the present invention comprises a support for supporting an optical fiber, a solution supply part for supplying a coating solution to the optical fiber, a light source for emitting light toward the optical fiber, and a light source, As shown in Fig.

The supporting portion may include an optical fiber holder for supporting the edge of the optical fiber, and a light transmitting portion for introducing the recoating liquid from the solution supplying portion and forming a recoating portion of the optical fiber.

The light source may be provided in a cylindrical shape for irradiating ultraviolet rays toward the optical fiber.

The transfer unit may include a light source support unit for supporting the light source, a support frame connected to the light source support unit, and a driving unit connected to the support frame to reciprocate the light source support unit in parallel with the optical fiber.

The transfer unit may further include a guide unit connected to the light source support unit and guiding the transfer of the light source.

The optical fiber recoating device may further include a controller for controlling the light amount of the light source, the transfer speed of the light source, and the irradiation time.

The control unit may compare the light amount of the light source with the conveyance speed of the light source to adjust the light amount of the light source or the conveyance speed of the light source.

The transporting unit may adjust the transport distance of the light source to set the recoating period of the optical fiber.

According to another aspect of the present invention, there is provided an optical fiber re-coating method comprising: a supporting step for supporting an optical fiber; a solution supplying step for supplying a coating solution to the optical fiber; and a light source for irradiating light toward the optical fiber in a longitudinal direction of the optical fiber, And a recoating step of carrying out recoating of the coating film.

The light source is provided in a cylindrical shape for irradiating ultraviolet rays toward the optical fiber, and the re-coating step may reciprocate the light source in parallel to the optical fiber.

The recoating step may adjust the light amount of the light source or the transport speed of the light source by comparing the light amount of the light source with the transport speed of the light source.

The recoating step adjusts the intensity of the light source to a lower level when the light source is conveyed at a speed higher than a predetermined speed and adjusts the intensity of the light source to be higher when the conveyance speed of the light source is slower than the predetermined speed.

The recoating step may adjust the transport distance of the light source to set the recoating interval of the optical fiber.

The optical fiber recoating apparatus and the recoating method according to the present invention can rapidly re-coat an optical fiber without depending on the type and type of the optical fiber, thereby improving the recoating operation efficiency.

The technical effects of the present invention are not limited to the effects mentioned above, and other technical effects not mentioned can be clearly understood by those skilled in the art from the following description.

1 is a perspective view of an optical fiber recoating apparatus according to an embodiment of the present invention,
2 is a perspective view illustrating a connection between a light source and a light source support unit according to the present embodiment,
3 is a block diagram showing a recoating unit of the optical fiber recoating apparatus according to the present embodiment,
4 is a flowchart illustrating an optical fiber re-coating method according to the present embodiment.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, it should be understood that the present invention is not limited to the disclosed embodiments, but may be implemented in various forms, and the present embodiments are not intended to be exhaustive or to limit the scope of the invention to those skilled in the art. It is provided to let you know completely. The shape and the like of the elements in the drawings may be exaggerated for clarity, and the same reference numerals denote the same elements in the drawings.

FIG. 1 is a perspective view of an optical fiber recoating apparatus according to an embodiment of the present invention, FIG. 2 is a perspective view illustrating a connection between a light source and a light source supporting unit according to the present embodiment, FIG. 3 is a cross- Coating unit.

1 to 3, an optical fiber recoating apparatus 100 (hereinafter, referred to as a recoating apparatus) according to the present embodiment includes a main body 110.

The main body 110 forms an outer shape of the recoating unit 100 and the main body 110 is provided with a receiving unit 130, an input unit 150 and a recoating unit 170.

First, the receiving unit 130 is disposed on the upper portion of the main body 110. Here, the receiving unit 130 forms a space for accommodating the optical fiber 10 to be recoated, and is provided to include the cover 131 so that the optical fiber 10 can be received therein.

The input unit 150 is disposed in the main body 110. A control signal related to the recoating process may be input to the input unit 150 from the outside. The input unit 150 may be provided as a touchable display module. However, the input unit 150 does not limit the type and the method of the input unit 150, as one embodiment for explaining the present embodiment.

On the other hand, the recoating unit 170 is disposed in the main body 110 and performs recoating on the optical fiber 10. The recoating unit 170 may include a support 171, a solution supply unit 173, a light source 175, a transfer unit 177, and a control unit 179.

First, the support portion 171 supports the optical fiber 10 that is brought into the receiving unit 130. [ Here, the supporting portion 171 may include an optical fiber holder 171a and a light transmitting portion 171b.

The optical fiber holder 171a is disposed inside the receiving unit 130. [ The optical fiber holder 171a supports the edge of the optical fiber 10 and is provided with a pair of frames or substantially a frame of the type in which both ends of the optical fiber 10 can be supported so that the edge of the optical fiber 10 .

The light transmitting portion 171b may be disposed to support the center of the optical fiber 10 or to be adjacent to the center of the optical fiber 10 supported by the optical fiber holder 171a. At this time, the center of the optical fiber 10 may be a region where recoating is to be performed. The light transmitting portion 171b may be formed of a quartz material to transmit the light from the light source 175 disposed on the lower side to the optical fiber 10. [

On the other hand, the solution supply unit 173 allows the coating solution to be supplied to the optical fiber 10. Here, the solution supply part 173 may include a recoating solution storage part 173a and a supply pump 173b.

The recoating liquid reservoir 173a may be incorporated in the main body 110. [ Here, the recoating liquid reservoir 173a may include a cover (not shown) that forms a space for storing the recoating liquid and is disposed on the outer wall of the main body 110 so that the recoating liquid may be introduced from the outside.

The supply pump 173b may be embedded in the main body 110. [ The supplying pump 173b supplies the recoating liquid stored in the recoating liquid reservoir 173a to the light transmitting portion 171b or the optical fiber 10 to apply the recoating liquid to the optical fiber 10. [ For this purpose, the light transmitting portion 171b or the optical fiber holder 171a may be provided with an inflow path of the recoating liquid, which is connected to the supply pump 173b and is supplied to the optical fiber 10 from the supply pump 173b.

On the other hand, the light source 175 may be disposed on the inner side of the main body 110 and below the light transmitting portion 171b. Here, the light source 175 may be provided as an ultraviolet LED that supplies ultraviolet rays to perform a recoating process of the optical fiber 10 coated with the recoating liquid. The light source 175 may be cylindrical in order to maximize the amount of light directed toward the optical fiber 10.

In this embodiment, the light source 175 is provided as an ultraviolet LED. However, the light source 175 may be an ultraviolet lamp.

However, the ultraviolet LED has a longer lifetime than the ultraviolet lamp, has the advantage of being able to regulate the distance and amount of light to be coated, and has little heat generation during recoating. In addition, since it is easy to control the re-coating time and has the advantage of being applicable to both the high-refraction coating method and the low-refraction coating method, the light source 175 is preferably provided as an ultraviolet LED.

Meanwhile, the transfer unit 177 allows the light source 175 to be transferred from the inside of the main body 110 in the horizontal direction, that is, parallel to the optical fiber 10. Here, the transfer unit 177 may include a light source support unit 177a, a support frame 177b, a drive unit 177c, and a guide unit 177d.

The light source support 177a supports the light source 175. Here, the light source support 177a is provided in a bar shape. The light source support 177a may have a slit-shaped groove corresponding to the outer diameter of the light source 175 to support the light source 175. [ Accordingly, the light source 175 may be disposed such that the lower portion thereof is connected to the light source support portion 177a and the upper portion thereof is directed to the light transmission portion 171b.

The support frame 177b is connected to the light source support 177a. Here, the support frame 177b may supply the power provided from the driver 177c to the light source support 177a so that the light source support 177a may be linearly transported. For this purpose, the support frame 177b and the light source support 177a may be connected by a ballscrew method, and a plurality of light source supports 177a provided in a bar shape may be stably supported and transported.

The driving portion 177c is connected to one end of the support frame 177b to provide power to the support frame 177b. Here, the stepping motor may be used as the driving unit 177c, but this is only one example for explaining the present embodiment, and the type of the driving unit 177c is not limited.

The guide portion 177d is connected to the light source support portion 177a so as to penetrate the light source support portion 177a. Both ends of the guide portion 177d may be supported by the main body 110 and may be provided in the same manner as the support frame 177b. In addition, the guide portion 177d may be provided in a plurality of such that the conveyance of the light source support portion 177a is stably guided.

On the other hand, the control unit 179 can perform overall control of the recoating unit 170. Here, the control unit 179 may include a main control unit 179a, a supply solution control unit 179b, a light control unit 179c, and a transfer control unit 179d.

The main control unit 179a performs overall control of the recoating unit 170 and performs a recoating process for the optical fiber 10 based on the input through the input unit 150 in conjunction with the input unit 150 .

The supply solution control unit 179b controls the operation of the supply pump 173b in accordance with a signal provided from the main control unit 179a. Here, the supply solution control unit 179b may cause the recoating liquid to be supplied to the optical fiber 10 based on an external signal, and when the set amount is supplied to the optical fiber 10, the supply of the recoating liquid to the optical fiber 10 is stopped .

The light control unit 179c controls the operation of the light source 175 according to a signal provided from the main control unit 179a. Here, the light controller 179c may control the amount of light, that is, the intensity of light, provided from the light source 175 to the optical fiber 10. In this case, when the light source 175 is driven by the direct current method, the light control unit 179c can adjust the light amount by adjusting the magnitude of the current value according to the driving method of the light source 175, The light amount can be adjusted by the pulse width control.

The transfer control unit 179d controls the operation of the driving unit 177c in accordance with a signal provided from the main control unit 179a. Here, the transport control unit 179d can cause the light source 175 to be reciprocated and transported by the driving unit 177c. The feed control unit 179d controls the reciprocating distance of the light source 175 by controlling the operation of the driving unit 177c so that the light source 175 can be moved in the reciprocating direction .

The main control unit 179a may vary the intensity of the light source 175 or the conveyance speed of the light source 175 based on a signal provided from the light control unit 179c and the conveyance control unit 179d. That is, the amount of light of the light source 175 or the conveying speed of the light source 175 can be controlled by comparing the light amount of the light source 175 with the conveying speed of the light source 175. For example, when the feeding speed of the light source 175 is higher than the predetermined speed, the intensity of the light source 175 can be relatively lowered. When the feeding speed of the light source 175 is slower than the predetermined speed, Can be controlled relatively strongly.

Hereinafter, an optical fiber re-coating method according to the present embodiment will be described in detail with reference to the accompanying drawings. However, for the sake of better understanding of the explanation, the detailed description of the components described above will be omitted, and the same reference numerals will be given.

4 is a flowchart illustrating an optical fiber re-coating method according to the present embodiment.

4, in the optical fiber re-coating method according to this practical example, the optical fiber 10 is carried into and supported by the receiving unit 130 with the cover 131 of the receiving unit 130 being opened, (131) is closed (S100).

Thereafter, a recoating process for the optical fiber 10 is initiated based on the signal provided through the input unit 150.

First, the supply pump 173b is operated and the recoating solution previously stored in the solution supply unit 173 is provided to the optical fiber 10, and the operation of the supply pump 173b may be stopped when the set capacity is injected (S200) . The optical control unit 179c controls the operation of the light source 175 so that light is irradiated from the light source 175 and the transfer control unit 179d controls the operation of the driving unit 177c The operation is controlled so that the light source 175 is transferred in the horizontal direction with respect to the optical fiber 10 and re-coating is performed (S300).

At this time, the driving unit 177c adjusts the reciprocating distance of the light source 175 based on the signal from the feed control unit 179d, so that the distance of re-coating of the optical fiber 10 can be set. The control unit 179 may control the amount of light of the light source 175 or the conveying speed of the light source 175 by comparing the light amount of the light source 175 and the conveying speed of the light source 175 with each other.

Finally, when the re-coating of the optical fiber 10 is completed, the light control unit 179c stops the operation of the light source 175, and the feed control unit 179d stops the operation of the driving unit 177c. Thereafter, the lid of the receiving unit 130 is opened to release the optical fiber 10 from the receiving unit 130, and the re-coating process can be completed.

As described above, the optical fiber recoating device and the recoating method are capable of rapidly re-coating the optical fiber regardless of the type and the type of the optical fiber, thereby improving the efficiency of the recoating operation.

An embodiment of the present invention described above and shown in the drawings should not be construed as limiting the technical idea of the present invention. The scope of protection of the present invention is limited only by the matters described in the claims, and those skilled in the art will be able to modify the technical idea of the present invention in various forms. Accordingly, such improvements and modifications will fall within the scope of the present invention as long as they are obvious to those skilled in the art.

10: Optical fiber
100: Recoating device
110:
130:
150: input unit
170: recoating unit

Claims (13)

A supporting part for supporting the optical fiber;
A solution supply part for supplying the recoating solution to the optical fiber;
A light source for irradiating light from the lower side of the support toward the optical fiber; And
A conveying unit connected to the light source for conveying the light source in the longitudinal direction of the optical fiber;
A supply solution supply unit for supplying the predetermined amount of the repo coating solution to the optical fiber;
A transfer control unit for controlling an operation of the transfer unit to adjust a transfer distance of the light source to set a recoating interval of the optical fiber;
And a main control unit for comparing a light amount of the light source with a transfer speed of the light source to adjust a light amount of the light source or a transfer speed of the light source,
The support
An optical fiber holder capable of supporting an edge of the optical fiber,
And a light transmitting portion for supporting the recoating region of the optical fiber and supplied with the recoating liquid from the solution supplying portion.
delete The method according to claim 1,
The light source
Wherein the optical fiber re-coating device is provided in a cylindrical shape for irradiating ultraviolet rays toward the optical fiber.
The method according to claim 1,
The conveying portion
A light source support for supporting the light source;
A support frame connected to the light source support,
And a driving unit connected to the support frame to reciprocate the light source support unit in parallel with the optical fiber.
5. The method of claim 4,
The conveying portion
Further comprising a guide part connected to the light source support part and guiding the conveyance of the light source.
delete delete delete A supporting step of supporting an edge of the optical fiber on an optical fiber holder and supporting a recoating-performing area of the optical fiber on the light transmitting part;
A solution supplying step of supplying a recoating solution to the light transmitting part; And
And a recoating step of transporting a light source for irradiating light toward the optical fiber from the lower side of the light transmission part in the longitudinal direction of the optical fiber to recoat the optical fiber,
The solution supply step
A predetermined amount of the recoating liquid is supplied to the optical fiber,
The re-coating step
Adjusting a transport distance of the light source to set a recoating interval of the optical fiber;
And comparing the light amount of the light source with the transfer speed of the light source to control the light amount of the light source or the transfer speed of the light source.
10. The method of claim 9,
The light source
The optical fiber being arranged in a cylindrical shape for irradiating ultraviolet rays toward the optical fiber,
The re-coating step
Wherein the light source is reciprocated parallel to the optical fiber.
delete 10. The method of claim 9,
The re-coating step
And controlling the intensity of the light source to be lower when the feeding speed of the light source is faster than a predetermined speed,
Wherein the intensity of the light source is adjusted to be higher when the light source is conveyed at a speed slower than the predetermined speed.
delete

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