KR101962412B1 - Multi-core optical fiber alignment apparatus - Google Patents

Abstract

The present invention relates to a multi-core optical fiber core aligning apparatus, and more particularly, to a multi-core optical fiber core aligning apparatus in a connector ferrule for a cable including a plurality of cores.
A multi-core optical fiber core aligning apparatus according to the present invention includes: a main frame part; A base plate installed on the main frame part; Core ferrule; a ferrule assembly mounted on the base plate and including a multi-core optical fiber, a ferrule for accommodating the multi-core optical fiber, and a fixed socket portion for covering one end of the ferrule; Wealth; A fixing jig provided in front of the mounting portion and configured to fix a ferrule flange portion coupled to the outside of the ferrule; A support portion provided at the front of the fixing jig and passing through the first hollow portion of the ferrule flange portion fixed to the fixing jig to support the other end portion of the ferrule exposed to the outside of the ferrule flange from below; A rotation part for contacting the one end of the ferrule fixed to the support part at the upper part of the support part to rotate the ferrule; A photographing unit disposed at a position facing one side end of the ferrule fixed to the support unit and photographing an image of one end of the ferrule; And a control unit for controlling operation of the rotation unit.

Description

[0001] The present invention relates to a multi-core optical fiber alignment apparatus,

The present invention relates to a multi-core optical fiber core aligning apparatus, and more particularly, to a multi-core optical fiber core aligning apparatus in a connector ferrule for a cable including a plurality of cores.

A basic connection method of a generally used optical fiber connector is based on a structure in which a core is held in contact with a shaft and a mechanism that protects and maintains a state in contact with the core.

Since the core diameter of such an optical fiber is as small as about 10 to 500 占 퐉, it is the most important problem that the optical axis is well-matched in the connector connection. Currently, a ferrule-type connector having a small number of components and a relatively low connection loss is used.

The ferrule-type connector has a minute diameter slightly larger than the outer diameter of the optical fiber at the center of the ferrule, and it is important to secure the accurate positional accuracy by fixing the optical fiber in the hole with an adhesive or the like, It uses FC connector with one stainless ferrule, SC connector which can be detached with one touch with zirconia ferrule, and D connector suitable for printed circuit board mounting.

A brief description of the structure of an optical fiber connector using such a ferrule is as follows. A general optical fiber is composed of a fiber clad, a buffer tube that protects the fiber clad and functions as a buffer, a Kevlar, and an outer jacket. The end portion of the optical fiber is bonded to the ferrule and the ferrule flange portion with the buffer tube, the Kevlar and the jacket being peeled off, and the ferrule and the ferrule flange portion are configured to fix and protect various components to constitute the optical fiber connector.

In other words, after the cover is removed to expose the optical fiber clad to a predetermined length, the adhesive is injected into the ferrule flange portion bonded to the ferrule, and then the fiber clad with the cover removed is inserted. At this time, the ferrule has a fiber cladding insertion portion in which only a fiber clad can be inserted at the center portion, a ferrule flange portion is inserted at one side and bonded, and a fiber clad and a buffer tube of the optical fiber are inserted into the other side The inner diameters of the ferrule flange portions are different from each other.

Therefore, the fiber clad is inserted through the fiber clad insertion portion of the ferrule, and the optical fiber with the buffer tube is inserted and bonded to the ferrule flange portion. After that, a spring and a stop ring are inserted on the optical fiber side, and a Kevlar is placed on the end portion of the stop ring. Then, the stop ring is crimped by caulking to fix the Kevlar. Then, after the jacket is put on the end portion of the caulking again, the jacket is fixed by pressing with the ring. Finally, the optical fiber connector is assembled by combining the frame and the connector housing to protect the ferrule and give a certain elasticity.

Meanwhile, when the conventional optical fiber connector is applied to a single-core optical fiber having a single core, it is not required to align the core with respect to the ferrule flange portion. However, when multi-core optical fibers having multiple cores are applied, The alignment of the cores of the optical fiber connector is required to be performed at a predetermined position.

KR 10-2013-0120624 A KR 10-2007-0115468 A KR 10-1038195 B1

SUMMARY OF THE INVENTION The present invention has been made in view of the above problems, and it is an object of the present invention to provide an optical fiber connector using a multi-core optical fiber having multiple cores, which is capable of easily aligning a plurality of cores with respect to a ferrule flange, Core optical fiber core alignment apparatus.

According to another aspect of the present invention, there is provided a multi-core optical fiber core aligning apparatus including: a main frame; A base plate installed on the main frame part; Core ferrule; a ferrule assembly mounted on the base plate and including a multi-core optical fiber, a ferrule for accommodating the multi-core optical fiber, and a fixed socket portion for covering one end of the ferrule; Wealth; A fixing jig provided in front of the mounting portion and configured to fix a ferrule flange portion coupled to the outside of the ferrule; A support portion provided at the front of the fixing jig and passing through the first hollow portion of the ferrule flange portion fixed to the fixing jig to support the other end portion of the ferrule exposed to the outside of the ferrule flange from below; A rotation part for contacting the one end of the ferrule fixed to the support part at the upper part of the support part to rotate the ferrule; A photographing unit disposed at a position facing one side end of the ferrule fixed to the support unit and photographing an image of one end of the ferrule; And a control unit for controlling the operation of the rotation unit.

A first hollow portion formed inside the ferrule flange portion so as to have an inner diameter corresponding to the outer diameter of the ferrule so that the ferrule can be inserted thereinto; and a second hollow portion formed to communicate with the first hollow portion, A second hollow portion formed so as to have an inner diameter corresponding to the outer diameter of the fixed socket portion so as to be inserted into the ferrule flange portion and inserted into a predetermined depth toward the center of the first hollow portion or the second hollow portion, At least one key groove spaced apart along the edge of the flange portion is formed, an insertion hole is formed in the fixing jig so that the ferrule flange portion can be inserted therein, and an inner circumferential surface of the insertion hole is formed with an inner circumferential surface And a protruded key-house entry protrusion is formed.

The mounting portion may further include a movement supporting portion for pressing the fixing socket portion of the ferrule assembly in a direction toward the fixing jig.

And an ultraviolet ray irradiating unit for irradiating the ultraviolet ray to the boundary between the ferrule flange portion fixed to the fixing jig and the fixing socket portion of the ferrule assembly.

A multi-core optical fiber core aligning apparatus according to the present invention is a multi-core optical fiber core aligning apparatus capable of easily aligning a plurality of cores with respect to a ferrule flange portion at a predetermined position in manufacturing an optical fiber connector using an optical fiber having multi- The purpose is to provide.

1 is a perspective view of a multi-core optical fiber core aligning apparatus according to the present invention.
BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a multi-core optical fiber core aligning apparatus.
3 is a front view of a multi-core optical fiber core aligning apparatus according to the present invention.
4 is an exploded perspective view illustrating a part of a multi-core optical fiber core aligning apparatus according to the present invention.
5 is a view showing a core arrangement image of a multi-core optical fiber photographed using a camera of a multicore optical fiber core aligning apparatus according to the present invention.
6 is a view illustrating a state in which a core is arranged at a predetermined position by rotating a ferrule through a rotation part of a multicore optical fiber core aligning device according to the present invention.

Hereinafter, a multi-core optical fiber core aligner according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 to 6 show a multi-core optical fiber core aligning apparatus according to the present invention. 1 to 6, a multi-core optical fiber core aligning apparatus 1 according to the present invention includes a main frame part 100, a base plate 200, a mounting part 300, a fixing jig 400, A support unit 500, a rotation unit 600, a photographing unit 700, and a control unit.

1 and 2, the main frame unit 100 includes a main body 110 formed in a rectangular box shape having an open top and having a space portion therein, And a sliding plate (120) for movably supporting the base plate (200).

The base plate 200 is slidably mounted on the sliding plate 120 and is reciprocatable along the longitudinal direction of the main frame 100. Although not shown in the drawings, a jackscrew or an actuator can be applied as moving means for reciprocating the base plate 200 with respect to the main frame portion 100. [

The mounting portion 300 is installed on the first stand 310 installed and fixed on the base plate 200 so as to protrude upward and is formed to mount the ferrule assembly 10 thereon. 3, a ferrule assembly 10 according to the present invention includes a multi-core optical fiber 11, a ferrule 13 for accommodating the multi-core optical fiber 11 therein, And a fixed socket portion 15 which is coupled to surround the end portion. The upper surface of the mounting part 300 is formed with a lead-in groove 301 which is downwardly received so as to partially accommodate the multi-core optical fiber 11.

The mounting portion 300 is further provided with a moving support portion 500 capable of pressing the fixing socket portion 15 of the ferrule assembly 10 in the direction toward the fixing jig 400. The movable supporting part 500 is interposed between the first stand 310 and the mounting part 300 so that the lower part thereof is fixed to the first stand 310 and the upper part is fixed to the moving support part 500 in the longitudinal direction As shown in Fig.

The fixing jig 400 is installed on a second stand 410 installed and fixed on the front side base plate 200 of the mounting portion 300 and has a ferrule flange portion 20 can be inserted and fixed inward.

An ultraviolet ray irradiating unit (not shown) for irradiating ultraviolet rays at a boundary between the ferrule flange unit 20 fixed to the fixing jig 400 and the fixed socket unit 15 of the ferrule assembly 10 ). The ultraviolet ray irradiating portion is formed by applying an ultraviolet curing agent to the outer circumferential surface of the ferrule flange portion 20 and more specifically to the outer circumferential surface of the fixed socket portion 15 adjacent to the ferrule 13 and fixing the fixed socket portion 15 to the ferrule flange portion The fixed socket portion 15 and the ferrule flange portion 20 are fixed to the primary fixing portion 15 by irradiating ultraviolet rays to the boundary where the fixed socket portion 15 and the ferrule flange portion 20 meet, .

The ferrule flange portion 20 is formed in a circular shape as shown in FIG. 3 and has a first hollow portion (not shown) having an inner diameter corresponding to the outer diameter of the ferrule 13 so that the ferrule 13 can be inserted from one side The fixed socket portion 15 is formed so as to communicate with the first hollow portion 21 and has one end portion of the fixed socket portion 15 coupled to the end portion of the ferrule 13, And a second hollow portion 22 formed to have an inner diameter corresponding to the outer diameter is formed. At this time, the first hollow portion 21 is formed to be smaller than the outer diameter of the second hollow portion 22 so that the interior of the ferrule flange portion 20 is stepped. By this stepped structure, the fixed socket portion 15 It is blocked from entering the first hollow portion 21.

The edge of the ferrule flange portion 20 is drawn to a predetermined depth toward the center of the first hollow portion 21 or the second hollow portion 22 and is separated from the edge of the ferrule flange portion 20 by at least one A key groove 23 is formed.

The fixing jig 400 has an insertion hole 401 formed therein so that the ferrule flange portion 20 can be inserted therein and an insertion hole 401 The protruding protrusion 402 protruding from the inner circumferential surface of the protrusion 402 is formed. The entry protrusions 402 may be formed in a number corresponding to the number of the keyways 23 formed in the ferrule flange portion 20, or may be formed in a smaller number.

The support part 500 is installed on the second stand 410 on the front side of the fixing jig 400 and supports the first hollow part 21 of the ferrule flange part 20 fixed to the fixing jig 400, And the other end of the ferrule 13 exposed through the hollow portion 22 and exposed to the outside of the ferrule flange portion 20 is supported from below. V 'or U' shaped support grooves 501 are formed on the upper surface of the support part 500 so as to receive a part of the ferrule 13.

The rotation part 600 contacts the one end of the ferrule 13 mounted on the supporter 500 at the upper part of the support part 500 to rotate the ferrule 13, A third stand 610 protruding upward above the upper portions of the first stand 310 and the second stand 410 and a rotating frame 620 rotatably installed at the end of the third stand 610, A rotating motor 630 fixed to the rotating frame 620 and a rotating plate 640 rotated by the rotating shaft of the rotating motor 630 and rotating the ferrule 13 while the edge is in contact with the ferrule 13 .

When the rotary plate 640 is rotated toward the support portion 500 and contacts and rotates with the ferrule 13 in the rotary frame 620 of the rotary portion 600, the ferrule 13 is rotated by the weight of the rotary plate 640 and the rotary motor 630, On the side opposite to the rotary motor 630 on the basis of the third stand 610 so as to prevent damage or the ferrules 13 from being stopped without being rotated while being pressed by a predetermined pressure or more, (Not shown) may be further provided. It is preferable that the weight portion is formed so as to be able to increase or decrease the weight.

The rotating plate 640 is provided with a contact ring extending along the edge of the rotating plate 640 and contacting the outer circumferential surface of the ferrule 13. The contact ring may be formed of a rubber material or the like having elasticity so as to elastically press the outer circumferential surface of the ferrule 13, and one or more of them may be arranged and provided in parallel to each other.

The photographing unit 700 is disposed on one side of the main frame so as to face one end of the ferrule 13 held on the support unit 500 and is adapted to photograph an image of one end of the ferrule 13. The photographing unit 700 includes a camera 710 provided with an image pickup device and a camera 710 installed in the main frame so as to move the camera 710 in the X axis direction, the Y axis direction, and the Z axis direction. (Not shown).

The control unit controls the operation of the rotation unit 600 and receives an image photographed by the camera 710 and causes the display unit to display the image output through the image processing unit.

A method of aligning cores of the multi-core optical fiber 11 through the multi-core optical fiber core aligning apparatus 1 having the above-described structure will be described in detail.

First, a multi-core optical fiber 11 in which a plurality of cores C are arranged and accommodated so as to be spaced apart from each other at a predetermined interval, a ferrule 13 in which a multi-core optical fiber 11 is accommodated, The ferrule assembly 10 including the fixed socket portion 15 that is coupled to the side end portion of the ferrule assembly 10 is mounted on the mounting portion 300. The ultraviolet hardening agent is applied to the outer peripheral surface of one side of the fixed socket portion 15 before the ferrule assembly 10 is mounted on the mounting portion 300. [

Thereafter, the ferrule flange portion 20 for engaging the ferrule assembly 10 is inserted and fixed in the fixing jig 400, and the ferrule 13 of the ferrule assembly 10, which is fixed to the mounting portion 300, The ferrule assembly 10 and the ferrule flange portion 20 are passed through the first hollow portion 21 and the second hollow portion 22 of the ferrule flange portion 20 fixed to the fixing jig 400, I agree. At this time, the ferrule assembly 10 and the ferrule flange portion 20 are closely contacted by pressing the rear end of the fixed socket portion 15 toward the fixing jig 400 through the movable support portion 500, The end portion of the ferrule 13 passing through the ferrule flange portion 20 is seated on the supporter 500.

The photographing unit 700 moves the position of the camera 710 through the moving stage unit 720 and focuses the camera 710 on the multi-core optical fiber 11 housed in the ferrule 13, . Since the ferrule 13 and the core C are not distinguished from each other in the image obtained by the camera 710, light is irradiated to the other end of the ferrule assembly 10 for distinguishing between the ferrule 13 and the core C, To emit light only at the portion corresponding to the light-emitting layer.

5, the images captured by the camera 710 may be displayed such that a plurality of cores C are shifted in one direction by a predetermined angle around a core C disposed at the center, The control unit operates the rotation unit 600 to rotate the ferrule 13 until the core C at the center and any one of the cores C around the core C are positioned in the vertical direction as shown in FIG.

6, when the cores C around the central core C are disposed at predetermined positions, the operation of the rotation unit 600 is stopped and the ferrules 13 The ultraviolet hardening agent coated on the outer circumferential surface of the fixed socket section 15 is hardened and the ferrule flange section 20 is fixed to the fixed socket section 15 15).

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the invention. It is understandable. Accordingly, the true scope of protection of the present invention should be determined only by the technical idea of the appended claims.

10: ferrule assembly 11: multi-core optical fiber
13: ferrule 15: fixed socket part
20: ferrule flange portion 21: first hollow portion
22: second hollow part 23: keyway
100: main frame unit 110: main body
120: sliding plate 200: base plate
300: mounting part 310: first stand
320: moving support part 400: fixing jig
410: second stand 500: support
600: rotating part 610: third stand
620: rotating frame 630: rotating motor
640: rotating plate 700: photographing unit
710: Camera 720: Moving stage part

Claims (4)

A main frame unit;
A base plate installed on the main frame part;
Core ferrule; a ferrule assembly mounted on the base plate and including a multi-core optical fiber, a ferrule for accommodating the multi-core optical fiber, and a fixed socket portion for covering one end of the ferrule; Wealth;
A fixing jig provided in front of the mounting portion and configured to fix a ferrule flange portion coupled to the outside of the ferrule;
A supporting portion provided in front of the fixing jig and passing through the first hollow portion of the ferrule flange portion fixed to the fixing jig to support the other end portion of the ferrule exposed to the outside of the ferrule flange from below;
A rotation part for contacting the one end of the ferrule fixed to the support part at the upper part of the support part to rotate the ferrule;
A photographing unit disposed at a position facing one side end of the ferrule fixed to the support unit and photographing an image of one end of the ferrule;
And a control unit for controlling operation of the rotation unit,
A first hollow portion formed inside the ferrule flange portion so as to have an inner diameter corresponding to the outer diameter of the ferrule so that the ferrule can be inserted thereinto; and a second hollow portion formed to communicate with the first hollow portion, A second hollow portion formed to have an inner diameter corresponding to the outer diameter of the fixed socket portion so as to be inserted,
At least one key groove is formed on the outer side of the ferrule flange portion to extend toward the center of the first hollow portion or the second hollow portion to a predetermined depth and is spaced along the edge of the ferrule flange portion,
Wherein the fixing jig is formed with an insertion hole to allow the ferrule flange portion to be inserted therein and a key groove entry protrusion is formed on the inner circumferential surface of the insertion hole so as to protrude from the inner circumferential surface of the insertion hole to enter the key groove. Device.
delete A main frame unit;
A base plate installed on the main frame part;
Core ferrule; a ferrule assembly mounted on the base plate and including a multi-core optical fiber, a ferrule for accommodating the multi-core optical fiber, and a fixed socket portion for covering one end of the ferrule; Wealth;
A fixing jig provided in front of the mounting portion and configured to fix a ferrule flange portion coupled to the outside of the ferrule;
A supporting portion provided in front of the fixing jig and passing through the first hollow portion of the ferrule flange portion fixed to the fixing jig to support the other end portion of the ferrule exposed to the outside of the ferrule flange from below;
A rotation part for contacting the one end of the ferrule fixed to the support part at the upper part of the support part to rotate the ferrule;
A photographing unit disposed at a position facing one side end of the ferrule fixed to the support unit and photographing an image of one end of the ferrule;
And a control unit for controlling operation of the rotation unit,
Wherein the mounting portion further comprises a movement supporting portion for supporting the fixed socket portion of the ferrule assembly so as to be pressed in the direction toward the fixing jig.
A main frame unit;
A base plate installed on the main frame part;
Core ferrule; a ferrule assembly mounted on the base plate and including a multi-core optical fiber, a ferrule for accommodating the multi-core optical fiber, and a fixed socket portion for covering one end of the ferrule; Wealth;
A fixing jig provided in front of the mounting portion and configured to fix a ferrule flange portion coupled to the outside of the ferrule;
A supporting portion provided in front of the fixing jig and passing through the first hollow portion of the ferrule flange portion fixed to the fixing jig to support the other end portion of the ferrule exposed to the outside of the ferrule flange from below;
A rotation part for contacting the one end of the ferrule fixed to the support part at the upper part of the support part to rotate the ferrule;
A photographing unit disposed at a position facing one side end of the ferrule fixed to the support unit and photographing an image of one end of the ferrule;
And a control unit for controlling operation of the rotation unit,
Further comprising an ultraviolet irradiation unit for irradiating ultraviolet rays at a boundary between a ferrule flange portion fixed to the fixing jig and a fixing socket portion of the ferrule assembly.

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