JPS6349711A - Optical fixing tool and optical connector using same - Google Patents

Abstract

PURPOSE:To easily and speedily connect optical fibers by forming a ferrule of a material which transmits an ultraviolet ray and adhering and fixing the optical fibers. CONSTITUTION:The ferrule 1 is made of the material which transmits ultraviolet rays, preferably, transparent ceramics or light-transmissive plastic such as light- transmissive polycrystal alumina and light-transmissive zirconia and pressed in the facing hole of a ferrule support 2. Then an optical fiber core has its optical fiber coating 4 removed at its tip part and is exposed. The bare part of the fiber 3 is inserted into the center axial hole 6 of the ferrule 1 and allowed to adhere and fixed with ultraviolet-ray setting resin 7, and the part of the coating 4 is run in the center axial hole 8 of the supporting body 2 and allowed to adhere and fixed with the ultraviolet-ray setting resin 9. Further, the hole 6 is reduced in internal diameter so as to position the fiber 3 accurately.

Description

DETAILED DESCRIPTION OF THE INVENTION Field of the Invention The present invention relates to an optical fiber fixing device and an optical connector for optically connecting optical fibers using the same. The present invention relates to an optical fiber fixture and an optical connector that can be connected.

Conventional technology Optical connectors optically connect optical fibers to each other, and are used in optical communication systems where removable optical connections are required, such as for switching equipment, removing transmitter/receiver boards, adjusting equipment, and measuring. Ru.

Optical connectors generally include a plug and an adapter. For example, in a C-type connector, the plug includes a highly precisely machined ferrule, and the optical fiber is inserted and fixed so that the center of the optical fiber coincides with a small hole provided along the central axis of the outer diameter of the ferrule. On the other hand, the adapter includes a sleeve that aligns the axes of the pair of ferrules and connects the optical fibers.

When these two plugs are connected using an adapter, the two optical fibers are connected with their tips abutting each other.

When joining optical fibers using such an optical connector, an epoxy resin adhesive is used to secure the optical fiber in the central shaft hole of the ferrule, thereby achieving relatively strong adhesive strength.

As mentioned above, an epoxy resin adhesive is used to fix the optical fiber within the central shaft hole of the ferrule.

Epoxy resin adhesives have the advantage of relatively strong adhesive strength, but the curing time from application to curing is long, lasting about one day and night at room temperature. Even when curing is accelerated by heating, it takes several hours to obtain stable adhesive properties.

Therefore, there is a drawback that it takes time to assemble the optical connector.

An object of the present invention is to provide an optical fiber fixing device and an optical connector using the same, which can shorten the assembly time of an optical connector by adhesively fixing an optical fiber into the central axis hole of a ferrule in a short time. purpose.

Means for Solving the Problems According to the present invention, there is provided a ferrule having a central axis hole through which an optical fiber is inserted and fixed, and a ferrule support having a central axis hole coaxial with the central axis hole of the ferrule and supporting the ferrule. An optical fiber fixing device comprising a body, wherein the central axis hole of the ferrule and the ferrule support is filled with an ultraviolet curing resin, and the ferrule is made of an ultraviolet-transparent material. An optical fiber fixture is provided.

Further, according to the present invention, the optical fibers are inserted into a pair of optical fiber fixtures, and fixed with the optical fibers exposed at the tips thereof, and the pair of optical fiber fixtures are inserted into the tips of the optical fibers with the optical fibers exposed. An optical connector that joins at least two optical fibers by abutting and holding the optical fibers together, the pair of optical fiber fixing devices each comprising a ferrule having a central axis hole through which the optical fiber is inserted, and a ferrule having a central shaft hole through which the optical fiber is inserted. a ferrule support body having a central axis hole coaxial with the central axis hole of the ferrule and supporting the ferrule, the central axis hole of the ferrule and the ferrule support body being filled with an ultraviolet curing resin; An optical connector is provided, characterized in that the optical connector is made of an ultraviolet-transparent material.

According to one embodiment of the invention, the ultraviolet-transmissive material that makes up the ferrule is a transparent ceramic such as translucent polycrystalline alumina and zirconia. Further, the ferrule support may also be made of these ultraviolet-transparent materials.

Further, according to another aspect of the present invention, the ultraviolet-transparent material constituting the ferrule is preferably a translucent plastic, and the ferrule and the ferrule support are preferably integrally molded from the translucent plastic.

According to the present invention, the ferrule is made of an ultraviolet-transparent material, and an ultraviolet curing resin is used to adhesively fix the optical fiber in the central hole of the ferrule. After inserting the optical fiber into the central shaft hole of the ferrule, if ultraviolet rays are irradiated from the outside of the ferrule, the ultraviolet curing resin inside the ferrule will be cured in a short time. Therefore, the optical fiber and the ferrule can be bonded quickly, making it possible to shorten the time required for assembling the optical connector.

Example The present invention will be described below with reference to the drawings.

FIG. 1 is a sectional view of one embodiment of the optical fiber fixture of the present invention.

This optical fiber fixture includes a ferrule 1 made of transparent ceramics that is transparent to ultraviolet rays, and a ferrule support 2 made of metal.The ferrule 1 is press-fitted into a counterbore hole provided in the ferrule support 2. It is integrated.

On the other hand, at the tip of the optical fiber core 5 consisting of the optical fiber 3 and the optical fiber coating 4, the optical fiber coating 4 is removed and the optical fiber 3 is exposed.

This exposed optical fiber 3 is connected to the center shaft hole 6 of the ferrule 1.
The ferrule is inserted into the center hole 6 of the ferrule and fixed by adhesive using an ultraviolet curing resin 7. The portion of the optical fiber coating 4 where the optical fiber 3 is not exposed is inserted into the central shaft hole 8 of the ferrule support 2, and is also fixed to the central shaft hole 8 of the ferrule support with an ultraviolet curing resin 9.

Although the central axis hole 6 of the ferrule and the central axis hole 8 of the ferrule support are coaxial, the diameters of these central axis holes are different and form a differential plane at the joint.

That is, the central axis hole 6 of the ferrule has an inner diameter such that the gap between the two is minute in order to precisely position the optical fiber 3, whereas the central axis hole 8 of the ferrule and the optical fiber The gap with the coating 7 may be relatively large.

Since the optical fiber fixing device of the present invention has such a structure, the optical fiber 3 is firmly fixed to the central axis hole 6 of the ferrule with the ultraviolet curing resin 7. On the other hand, the optical fiber coating 4 is firmly fixed to the central shaft hole 8 of the ferrule support with an ultraviolet curing resin 9.

Next, the optical fiber 3 in the optical fiber fixture of the present invention
A method of adhesively fixing the ferrule 1 and the ferrule 1 will be briefly explained. First, the central shaft hole 6 of the ferrule and the central shaft hole 8 of the ferrule support are filled with ultraviolet curing resin 7.9. Next, a portion of the optical fiber coating 4 is removed from the optical fiber core 5 to expose the optical fiber 3, and the exposed optical fiber 3 is
Insert the 0 part into the pore 6 of the ferrule. In this state, ultraviolet light 1 is applied from the ultraviolet irradiation device 10 around the ferrule 1.
Irradiate 1. Since the ferrule 1 is made of transparent ceramics, the ultraviolet light 11 passes through the ferrule 1 and irradiates the ultraviolet curing resin 7. Then, the ultraviolet curing resin 7 is cured within several minutes due to a photopolymerization reaction. On the other hand, since the ferrule support 2 is made of metal, the ultraviolet rays 11 do not directly pass therethrough. However, since the gap between the central axis hole 8 of the ferrule support and the optical fiber core 5 is large, the ultraviolet rays 11 go around from both ends of the ferrule support 2 into the center hole 8 of the ferrule support and irradiate the ultraviolet curing resin 9. It also hardens within a few minutes.

As examples of the ultraviolet curing resin 7.9 used in the present invention, "U Rapid EA9497J manufactured by Toshi, rLA-3530J manufactured by Moritex, etc. can be used. As the ultraviolet ray irradiation device 10, for example, Toshiba's
A mercury lamp for photochemistry H-400PJ, "I Cure Light" by Iwasaki Electric, etc. can be used.

The transparent ceramic that is the material of ferrule 1 is used to cure ultraviolet curing resin 7.9 (effective wavelength range 200~
Use a material that is transparent at 400 nm.

Aluminum is a ceramic that is transparent in this wavelength range.
There are translucent polycrystalline aluminas made from materials such as 2O3, Y2O3, and MgO1BeO. Further, as the material of the ferrule 1, it is also possible to use translucent zirconia made of ZrO□. Translucent zirconia is 0.35-6
It is transparent in the μm wavelength range and transmits ultraviolet rays. moreover,
It is also possible to use transparent plastic. 200～
Examples of plastics that are transparent in the wavelength range of 400 nm include transparent plastics made of acrylic, epoxy, polyester, and the like.

FIG. 2 is a schematic cross-sectional view of an example of an optical connector configured using the above-mentioned optical fiber fixture.

This optical connector is composed of a plug 16 and an adapter 19.

First, it can be seen that the plug 16 has the following structure. A spring 13 surrounds the ferrule support 2, and a coupling nut 12 is placed over the spring 13. The coupling nut 12 extends toward the ferrule 1, and is threaded on the inside of that portion. A hood 14 is provided on the opposite side of the ferrule support 2 from where the ferrule 1 is attached, and covers a part of the long optical fiber core 5. A plug housing 15 is constituted by the coupling nut 12 described here, a spring 13, and a hood 14, and a ferrule 1 is located in the center thereof.

Part of the adapter 19 includes a sleeve 17 into which the ferrule 1 is inserted and an adapter housing 18 surrounding the sleeve 17.
Consists of. The surfaces of both ends of the adapter housing 18 are threaded. By fitting the screws of the pair of plugs 16 and adapter 19 into each other, coupling of the optical connectors is completed.

Various modifications of the present invention are possible. For example, in the embodiment shown in FIG. 1, the center hole 8 of the ferrule support and the optical fiber coating 4 are fixed with ultraviolet curing resin 9, but they may be fixed by caulking using a caulking tool. Further, although metal is used for the ferrule support 2, the above-mentioned translucent plastic may also be used. In this case, the ultraviolet rays 11 pass through the ferrule support 2 made of translucent plastic and irradiate the ultraviolet curing resin 9, so that the curing of the ultraviolet curing resin 9 is accelerated and the optical fibers are connected to the center hole 8 of the ferrule support. The coating 4 is fixed faster. Furthermore, the ferrule 1 and the ferrule support 2 may be integrally molded from translucent plastic. In the case of integral molding, the number of parts is reduced and the ferrule becomes cheaper.

As described in detail about the invention, the optical connector of the present invention uses a transparent material as the ferrule and an ultraviolet curing resin as the adhesive. The ultraviolet curing resin filled in it hardens within a few minutes. Therefore, the time required for fixing the optical fiber and the ferrule pore is shortened, and as a result, the time required for assembling the optical connector is significantly shortened.

[Brief explanation of drawings]

FIG. 1 is a schematic cross-sectional view of one embodiment of the optical fiber fixture of the present invention, and FIG. 2 is a schematic cross-sectional view of an optical connector of the present invention. (Main reference numbers) l...ferrule, 2...ferrule support, 3...optical, eyeglass, 5...
- Optical fiber core, 7.9... Ultraviolet curing resin, 10... Ultraviolet irradiation device, 11... Ultraviolet light, 15.
・Plug housing, 16...Plug, 17...Sleeve, 1B...Adapter housing, 1b...Adapter

Claims (14)

[Claims] (1) An optical fiber fixture comprising a ferrule having a central axis hole through which an optical fiber is inserted and fixed, and a ferrule support body having a central axis hole coaxial with the central axis hole of the ferrule and supporting the ferrule. An optical fiber fixing device, characterized in that a central axis hole of the ferrule and the ferrule support is filled with an ultraviolet curing resin, and the ferrule is made of an ultraviolet-transparent material. (2) The optical fiber fixture according to claim 1, wherein the ultraviolet-transparent material is transparent ceramic. (3) The optical fiber fixture according to claim 2, wherein the transparent ceramic is transparent polycrystalline alumina. (4) The optical fiber fixture according to claim 2, wherein the transparent ceramic is transparent zirconia. (5) The optical fiber fixture according to claim 1, wherein the ultraviolet-transparent material is a translucent plastic. (6) The ferrule support is made of an ultraviolet-transparent material, the central hole of the ferrule support is filled with an ultraviolet curing resin, and the optical fiber core is adhesively fixed to the ferrule support. The optical fiber fixture according to item 1. (7) The optical fiber fixture according to claim 6, wherein the ferrule and the ferrule support are integrally molded from transparent plastic. (8) Insert the optical fibers into a pair of optical fiber fixtures and fix them with the optical fibers exposed at the tips,
An optical connector that optically joins at least two optical fibers by connecting and holding the pair of optical fiber fixtures by bringing their exposed tips into contact with each other, the optical connector fixing the pair of optical fibers. Each of the devices includes a ferrule having a central axial hole through which the optical fiber is inserted, and a ferrule support having a central axial hole coaxial with the central axial hole of the ferrule and supporting the ferrule. An optical connector characterized in that a central shaft hole of a ferrule support is filled with an ultraviolet curing resin, and the ferrule is made of an ultraviolet-transparent material. (9) The optical connector according to claim 8, wherein the ultraviolet-transparent material is transparent ceramics. (10) The optical connector according to claim 9, wherein the transparent ceramic is transparent polycrystalline alumina. (11) The optical connector according to claim 9, wherein the transparent ceramic is transparent zirconia. (12) The optical connector according to claim 8, wherein the ultraviolet-transparent material is a translucent plastic. (13) The ferrule support is made of an ultraviolet-transparent material, the central hole of the ferrule support is filled with an ultraviolet curing resin, and the optical fiber core is adhesively fixed to the ferrule support. The optical connector according to item 8. (14) The optical connector according to claim 13, wherein the ferrule and the ferrule support are integrally molded from translucent plastic.