JPH0339910A - Optical sleeve - Google Patents

Abstract

PURPOSE:To facilitate the transmission of signals between fibers and to enhance the quality of the light signals by applying a resin which is cured by UV rays, etc., on the inside of a transparent body, inserting the optical fibers into the transparent body from both ends and fixing the resin by the irradiation with the UV rays from the outside. CONSTITUTION:The optical sleeve 1 consists of the transparent body consisting of a cylinder, etc., of transparent glass and the resin 5 which is applied on the inside of this transparent body and is cured by UV rays, etc. The optical fibers of a multimode or single mode or both thereof are inserted into the transparent body from both ends thereof and the resin 5 is fixed by the irradiation with the UV rays from the outside, by which the optical fibers of the multimode and single mode are converted and connected without splicing. The return light is blocked in this way and the quality of the light signals is maintained high.

Description

DETAILED DESCRIPTION OF THE INVENTION Field of Industrial Application The present invention relates to an optical sleeve inserted into an optical transmission line used in optical communications, etc. Emitted optical power exchange Claw propagated through optical fiber as a transmission path Return light reflected from various reflection points (connection points of connectors, etc.) existing in the transmission path caused communication problems.This problem An optical isolator was inserted inside the semiconductor laser module, which is the light emitting end, to prevent light from returning from the reflection point in the transmission path. There are two types of optical fibers: multi-mode and single-mode, but connecting each optical fiber is complicated and difficult. Problems occur in communication due to return light reflected from various reflection points (connection points of optical fiber connectors, etc.) existing in the optical transmission path. First convert the light from the optical fiber into an electrical signal?!l!L... Then convert the electrical signal into an optical signal and connect the single mode optical fiber. Or inside the semiconductor laser module which is the light output end. However, the former method is extremely complicated, inefficient, and therefore expensive, etc. As a result, the equipment and systems themselves have become expensive.Furthermore, due to these signal processing, return light is produced at various points on the transmission path, such as at optical connection points, which can cause deterioration in image quality. In order to avoid this, the latter method of inserting an optical isolator is difficult to fabricate a semiconductor laser module with an optical isolator inserted, and the equipment system itself is expensive. The aim is to make it possible to connect several optical fiber cables in the middle of an optical transmission line, thereby making it easier to transmit signals between each fiber and maintaining high quality of optical signals, and reducing equipment and installation costs. The present invention also improves the quality of optical signals by easily inserting an optical isolator in the middle of a conventional optical fiber cable to prevent returning light. The aim is to provide optical isolators and reduce equipment and installation costs.

Means for Solving the Problems In order to solve the above problems, the present invention (advanced) provides an optical sleeve for conversion in the middle of an optical fiber transmission line, and inserts an optical fiber whose tip is processed into a self-locked tip, for example. This light sleeve (top) consists of a transparent body made of a transparent glass tube, etc., and a resin that is cured by ultraviolet light applied to the inside of this transparent body. By inserting multi-mode, single-mode, or both optical fibers from both ends of a transparent body and fixing the resin by external ultraviolet irradiation, multi-mode and single-mode optical fibers can be connected without splicing. The above-mentioned disadvantages can be overcome with a simple structure by having a structure in which an optical isolator is inserted inside the glass tube. Amo Also, the present invention (top) An optical isolator sleeve (top, transparent It has a transparent body made of a glass tube, etc., and an optical isolator sandwiched between the transparent body.The inside of the transparent body is coated with a resin that hardens with ultraviolet rays, etc., and optical fibers are connected from both ends of the transparent body. An optical isolator can be inserted in the middle of an optical fiber without splicing, by inserting an optical fiber and fixing the resin by irradiating it with ultraviolet light from the outside, or by fixing the resin by passing ultraviolet light through the optical fiber. According to the structure of the present invention, it is possible to efficiently connect two types of conventionally used optical fibers or insert an optical isolator in the middle of an optical fiber transmission line. According to the configuration of the present invention, since an optical isolator is inserted in the middle of the optical fiber transmission line, it is possible to prevent the return light by a simple connection, and therefore, the quality of the optical signal can be maintained at a high level. By simply installing and connecting an optical isolator sleeve, the return light can be blocked and the quality of the optical signal can therefore be maintained at a high level. 1 shows the structure of a multi-mode to single-mode optical fiber conversion sleeve 1 according to an embodiment of the present invention.The diameter of the cylindrical sleeve 2, which is made of transparent quartz glass or the like, with which optical fibers (not shown) are inserted into both ends is shown. 126 micrometer holes 3 and 4
Multi-mode fibers and single-mode fibers (not shown) with self-locked tips are inserted into the holes 3 and 4 respectively.In the center of the cylindrical sleeve 2 (
A resin 5 that is cured by ultraviolet rays is arranged, and an optical fiber (not shown) is fixed in the cylindrical sleeve 2 by irradiating ultraviolet rays from outside the cylindrical sleeve 2 or by irradiating ultraviolet rays from inside the optical fiber. The sleeve 21 may be constructed of a material such as glass that allows ultraviolet rays to pass therethrough.FIG. 2 shows another embodiment of the sleeve 11 for multi-mode to single-mode optical fiber conversion according to the present invention. Holes 13 and 14 with a diameter of 126 micrometers are provided at both ends of the cylindrical sleeve 12 made of transparent quartz glass or the like, into which optical fibers (not shown) are inserted.
Multi-mode fibers and single-mode fibers (not shown) each having a spherical self-locked tip are inserted into the holes 13 and 14. An optical isolator 15 is placed in the center of the cylindrical sleeve 12 as shown in the figure. A resin 16 that is cured by ultraviolet rays is arranged at both ends of the optical isolator 15, and an optical fiber (not shown) is connected to the cylindrical sleeve 12 by irradiation of ultraviolet rays from outside the cylindrical sleeve 12.
The optical isolator 15 can be easily inserted into the optical transmission line.

With this configuration, the light emitted from the semiconductor laser (upper
A high-quality optical signal that is less susceptible to the influence of returned light can be obtained. According to experiments, the optimum hardness of the ultraviolet curable resin is 100 to 10 centiboise, and the refractive index is 1 or higher, and when ordinary optical fiber is used, it is 1.0 to 1.0.
The optimum resistor isolator is about 1.33.
(Using a single crystal such as L YIG\Samarium cobalt magnet) Also, the tip shape of an optical fiber (
Top Selfocc processed tip has high coupling efficiency and less return light t4 Material of cylindrical sleeve 41
It has been found that although the curing conditions of the ultraviolet resin are slightly different when using force pulling using other glasses or hard resins in addition to quartz glass, there is no major difference. The number and arrangement of optical isolators may be used for any type of long wave.Also, the number and arrangement of optical isolators are not particularly particular about the embodiment.Also, it is normal practice to fill this sleeve with matting oil to reduce optical connection loss. Figure 3 shows the structure of an optical isolator sleeve 21 according to another embodiment of the present invention.A cylindrical sleeve 22 made of transparent quartz glass or the like has a diameter 126 in which optical fibers (not shown) are inserted at both ends. Micrometer holes 23 and 24 are provided in the center of the cylindrical sleeve 22 (upper).An optical isolator 25 is placed as shown in the figure.A resin 26 that is cured by ultraviolet rays is placed at both ends of the optical isolator 25. With this configuration, an optical fiber (not shown) can be fixed in the cylindrical sleeve 22 by irradiating ultraviolet light from outside the sleeve 22, and the optical isolator 25 can be easily inserted into the optical transmission path.
The light emitted from the semiconductor laser (it is less susceptible to the effects of returning light, and a high-quality optical signal can be obtained.

According to experiments, the hardness of the above ultraviolet curing resin is 100 to 10.
A refractive index of 1.0 to 1.33 is optimal for the isolator 25 (if a normal optical fiber is used).

For use with single crystals such as YIG, for use with samarium cobalt magnets, and for the tip shape of optical fibers (with an inclination angle of 7~
The experimental results for the 10° oblique polished surface and the PC polished surface showed that there was no significant difference, but there was some light return compared to the smooth polished surface (above). Although there were many cases, it was not to the extent that it caused a practical problem.Furthermore, almost the same results were obtained when other glasses, hard resins, etc. were used as the glass tube.The optical isolator sleeve used in this example The optical sleeve 4 of the present invention constructed in this way can be used as a high-quality optical communication device. It has extremely high utility value, is inexpensive, and can be easily installed in terms of system configuration.It has industrial value as a key device for information transmission in the future information society.

[Brief explanation of drawings]

Figures 1 and 2 (Friend) are schematic diagrams of multimode-single mode optical fiber conversion sleeves according to embodiments of the present invention.
FIG. 3 is a schematic diagram of an optical isolator sleeve according to another embodiment of the present invention.

Claims (7)

[Claims] (1) By coating the inside of a transparent body with a resin that is cured by ultraviolet rays, etc., inserting optical fibers from both ends of the transparent body, and fixing the resin by irradiating ultraviolet rays from the outside, it is possible to avoid splicing. , an optical sleeve to which the optical fibers are connected. (2) It has an optical isolator provided in the middle part of the transparent body, and a resin that is cured by ultraviolet rays etc. applied to the inside of the transparent body, and optical fibers are inserted from both ends of the transparent body, and ultraviolet rays from the outside are applied. An optical sleeve characterized in that optical fibers can be connected without splicing by fixing the resin by irradiation with the resin, thereby reducing return light between the optical fibers. (3) An optical isolator is sandwiched within a transparent body, and the inside of the transparent body is coated with a resin that is cured by ultraviolet rays, etc., and optical fibers are inserted from both ends of the transparent body, and ultraviolet rays are irradiated from the outside. An optical sleeve characterized in that an optical isolator can be inserted in the middle of the optical fiber without splicing by fixing the resin. (4) The optical sleeve according to claim 1, 2, or 3, characterized in that the ultraviolet curing resin has a hardness in the range of 100 to 1000 centipose. (5) The optical sleeve according to claim 1, 2, or 3, characterized in that the ultraviolet curing resin has a refractive index in the range of 1.0 to 1.33. (6) The optical sleeve according to claim 3, characterized in that the tip of the optical fiber inserted into the transparent body is smooth, PC polished, or obliquely polished. (7) The optical sleeve according to claim 1 or 2, characterized in that the tip of the optical fiber inserted into the transparent body has a self-locked tip.