JP2002267852A - Method for wiring optical fiber sheet and optical fiber sheet - Google Patents

Abstract

PROBLEM TO BE SOLVED: To facilitate the design of a wiring pattern which does not cause the multiplex cross of optical fibers during manufacturing the optical fiber sheer of a cross connection wiring structure. SOLUTION: The cross connection wiring structure is a wiring structure in which a plurality of multiple optical fibers 11 at one end edge 12a side of a sheet 12 are separated into single optical fibers 13 inside the sheet 12, and the separated single optical fibers 13 are assembled at the other end edge 12b side of the sheet 12 to form a plurality of multiple optical fibers 14 again. The positions of multiple optical fibers 11 at one end edge side and the multiple optical fibers 14 at the other end edge side are shifted with each other in a direction orthogonal to the facing direction of both end edges, and each single optical fiber 13 is wired in an intermediate part so as to form a shape of stair approximately parallel with each other. The wiring pattern which does not cause the multiplex cross in which three or more optical fibers are crossed at the same part or at a proximate part can easily be realized only by determining a wiring pattern according to a simplified procedure.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical fiber wiring method for producing an optical fiber sheet having a so-called cross-connect wiring structure, and an optical fiber sheet produced by the optical fiber wiring method.

[0002]

2. Description of the Related Art As an optical fiber wiring structure of an optical fiber sheet, as shown in FIG. 6 showing a conventional example, a plurality of multi-core optical fibers 1 on an input side (one edge side) are converted into a single-core optical fiber 3 inside a sheet 2. In some cases, a so-called cross-connect wiring structure, in which the separated single-core optical fibers 3 are gathered on the output side (the other end side) and form a plurality of multi-core optical fibers 4 again, is formed. As shown in the drawing, a conventional optical fiber sheet 5 of this type has a wiring structure in which an input side and an output side face each other, that is,
A wiring structure is adopted in which the arrangement of the multi-core optical fiber 1 on the input side and the arrangement of the multi-core optical fiber 4 on the output side face the front. The optical fiber sheet has a structure in which a plurality of optical fibers are usually wired on the sheet surface, for example, by bonding two sheets with an adhesive across the optical fiber. The optical fiber wired on the sheet is usually a so-called UV ray (250 μm in diameter) obtained by coating a bare fiber with a UV resin coating, and the sheet is made of polyimide, polyethylene terephthalate, polyethylene, polypropylene, polyester, or the like. Can be

[0003]

In the optical fiber sheet 5 having the above-described cross-connect wiring structure, the optical fibers 3 always cross each other in the sheet 2. However, when the number of the optical fibers 3 increases, the number of crossing points increases. And the wiring pattern becomes complicated in a crossed manner. Although the optical fiber 3 is bent at the intersection of the optical fibers 3, it is generally acceptable if only two optical fibers intersect (intersect in two layers). However, in an intersecting mode of three or more layers in which three or more optical fibers intersect at the same location or a close location (referred to as multiple intersection), the load (bending force) acting on the optical fiber may exceed an allowable range. is there. Therefore, it is necessary to perform wiring so that multiple intersections of optical fibers do not occur. When designing this optical fiber wiring pattern by, for example, CAD, when the number of optical fibers increases, the design of the wiring pattern becomes extremely complicated. For example, in the region (a) of FIG. It is not easy to construct a wiring pattern in which multiple intersections of three or more layers do not occur. Further, when the wiring pattern becomes complicated, the work itself of actually arranging the optical fibers on the sheet becomes difficult.

SUMMARY OF THE INVENTION The present invention has been made in view of the above circumstances, and when manufacturing an optical fiber sheet having a cross-connect wiring structure, a wiring method for an optical fiber sheet that can easily realize a wiring pattern that does not cause multiple crossing of optical fibers. And an optical fiber sheet.

[0005]

According to the present invention, a plurality of multi-core optical fibers on one edge side of a sheet are separated into single-core optical fibers inside the sheet. An optical fiber wiring method for producing an optical fiber sheet that forms a plurality of multi-core optical fibers again by gathering at the other end side of the optical fiber, wherein each of the multi-core optical fibers at the one end side is separated into single-core optical fibers. In doing so, each single-core optical fiber is separated from the multi-core optical fiber so as to be sequentially branched in the same direction, all of the separated optical fibers are made parallel to each other, and this parallel single-core optical fiber is placed on the other end side. At the time of collection, the single-core optical fibers are sequentially collected from the same direction to form a multi-core optical fiber.

According to a second aspect, the plurality of multi-core optical fibers on one edge side of the sheet are separated into single-core optical fibers inside the sheet,
An optical fiber wiring method for producing an optical fiber sheet in which the separated single-core optical fibers are gathered at the other end side of the sheet to form a plurality of multi-core optical fibers again. The multi-core optical fibers on the other end edge side are displaced from each other in a direction orthogonal to the opposing direction of the both end edges, and at the intermediate portion, the wiring is performed so that each single-core optical fiber forms a generally parallel stepped shape. Features.

According to a third aspect of the present invention, in the optical fiber wiring method according to the first aspect, when collecting the optical fibers at the other end side,
A group of several optical fibers having a smaller number of optical fibers than the number of optical fibers of the multi-core optical connector on the one edge side is formed.

According to a fourth aspect, the plurality of multi-core optical fibers on one edge side of the sheet are separated into single-core optical fibers inside the sheet.
An optical fiber sheet in which the separated single-core optical fibers are gathered at the other end side of the sheet to form a plurality of multi-core optical fibers again. In a mode in which the multi-core optical fibers are sequentially branched in the same direction, the optical fibers are separated into single-core optical fibers, all of the separated optical fibers are made parallel to each other, and the parallel single-core optical fibers are sequentially gathered from the same direction and multiplied. The multi-core optical fibers on the other end edge side are formed by collecting the multi-core optical fibers in a manner that forms a core optical fiber.

[0009]

FIG. 1 is a block diagram showing an embodiment of the present invention.
This will be described with reference to FIGS. FIG. 1 shows an optical fiber sheet 15 according to one embodiment of the present invention. In the optical fiber sheet 15, a plurality of multi-core optical fibers 11 on the input side (one edge side) of the sheet 12 are separated into single-core optical fibers 13 inside the sheet 12, and the separated single-core optical fibers 13 The plurality of multi-core optical fibers 14 are formed again on the output side (the other end edge side). In addition, the multi-core optical fibers 11 on the input side and the output side,
Reference numeral 14 may be an optical fiber tape, or may simply be a group of a plurality of optical fibers (including not only a case where they are bonded but also a case where they are not bonded). The illustrated optical fiber sheet 15 is a case where the input side has four eight-core multi-core optical fibers 11 and the output side also has four eight-core multi-core optical fibers 14. Also, sheet 1
2, the input side edge 12a and the output side edge 12b are parallel, and the input side multicore optical fiber 11 and the output side multicore optical fiber 14 are parallel.

[0010] The optical fiber wiring of the optical fiber sheet 15 is such that the multi-core optical fiber 11 on the input side and the multi-core optical fiber 14 on the output side are formed at both end edges 12.
The positions are displaced from each other in a direction (vertical direction in FIG. 1) orthogonal to the facing direction of a and 12b (dimensions of positions are indicated by a and b).
In addition, in the intermediate portion, each single-core optical fiber 13 has a generally parallel stepped shape. In other words, when the multi-core optical fibers 11 on the input side are separated into single-core optical fibers 13, the single-core optical fibers 13 are sequentially branched from the multi-core optical fiber 11 in the same direction. So that they are separated. The separated single-core optical fibers 13 are all parallel to each other. Here, the term “parallel” refers not only to geometrical parallelism but also to traveling side by side, that is, traveling in substantially the same direction without intersecting even if the mutual interval varies. In the case shown in the figure, a part of the parallel wiring (the position of the PQ line in the drawing) is substantially parallel (interval is constant). When the parallel single-core optical fibers 13 are collected on the output side, each single-core optical fiber 1
3 are gathered sequentially from the same direction to form a multi-core optical fiber 14.

More specifically, the first multi-core optical fiber 11A on the input side and the second multi-core optical fiber 1
1B, the third multi-core optical fiber 11C, and the fourth multi-core optical fiber 11D, each of which is initially separated from each other, a total of eight single-core optical fibers 13 are parallel to the diagonally lower right in FIG. After being extended, they are sequentially collected two by two to form a fourth multicore optical fiber 14D on the output side. Also,
Each input multi-core optical fiber 11A, 11B, 11
A total of eight single-core optical fibers 13 each of which is secondly separated from each of C and 11D are similarly sequentially collected two by two to form a third multi-core optical fiber 14C on the output side.
Is formed. In addition, each of the multi-core optical fibers 11A, 11B, 11C, and 11D on the input side is separated into thirds from the respective multi-core optical fibers 11A, 11B, 11C, and 11D.
Are similarly sequentially collected two by two to form a second multi-core optical fiber 14B on the output side. Also, each of the multi-core optical fibers 11A, 11B, 11C on the input side,
The remaining two single-core optical fibers 13 of each of the 11Ds, which are a total of eight single-core optical fibers 13, go straight in a straight line and then extend diagonally in the lower right direction. The multi-core optical fiber 14A is formed.

The optical fiber sheet 15 does not have multiple intersections in which three or more optical fibers intersect at the same location or adjacent locations. However, such wiring is performed only by wiring according to the above-described procedure. It is possible to obtain a wiring pattern in which multiple intersections of fibers do not occur. Also, since it is only necessary to design according to a fixed procedure, even if the number of multi-core optical fibers increases, and even if the number of multi-core optical fibers increases, the wiring pattern is simple without being complicated, Easy to design.

Although the above embodiment is applied to the entire wiring of one optical fiber sheet, the optical fiber wiring method of the present invention is applied to one area in one optical fiber sheet. You can also. That is, for example, in FIG. 2, a portion of a region 15 ′ of one optical fiber sheet 25 surrounded by a dashed line is a wiring pattern like the optical fiber sheet 15 of FIG. 1. In this case, the periphery of the area 15 'corresponds to the sheet edge. In addition, the optical fiber wiring method of the present invention can be applied to a plurality of regions in one optical fiber sheet.

In the embodiment described with reference to FIG. 1, the input side edge 12a and the output side edge 12b of the sheet 12 are parallel, and the input side multicore optical fiber 11 and the output side multifiber. The optical fiber sheet 15A shown in FIG.
And the input side edge 12a and the output side edge 12b of the sheet 12 are non-parallel, and the input side multi-core optical fiber 11 and the output side multi-core optical fiber 14 are non-parallel. The present invention can also be applied to

Further, the optical fiber sheet 15 shown in FIG.
B, the edge 12a on the input side and the edge 12b on the output side of the sheet 12 are at right angles to each other,
The present invention can also be applied to a case where the multi-core optical fiber 11 on the input side and the multi-core optical fiber 14 on the output side are at right angles to each other.

The optical fiber sheet 15C shown in FIG.
Like the fourth multi-core optical fiber 11D on the input side.
And the first multi-core optical fiber 14A on the output side are not displaced (in the illustrated example, they are linearly opposed).
It is also possible to use a wiring pattern.

The number and the number of the multi-core optical fibers 11 and 14 on the input side and the output side are not limited to the above-described embodiment, and are arbitrary. A desired number of optical fibers can be provided. For example, one multi-core optical fiber is not limited to eight cores and may have four or other cores, or multi-core optical fibers having different core numbers such as four cores and eight cores may be mixed. The number of multi-core optical fibers may be the same or different on the input side and the output side. In this way, when collecting the optical fibers on the output side, a group of several optical fibers having a smaller number of optical fibers than the number of optical fibers of the multi-core optical connector on the input side can be formed. This does not exclude the presence of a single-core optical fiber in combination with the optical fiber.

[0018]

According to the present invention, when manufacturing an optical fiber sheet having a so-called cross-connect wiring structure,
It is possible to easily realize a wiring pattern that does not cause multiple intersections in which more than one optical fiber intersects at the same place or a close place. In addition, since the wiring pattern can be designed according to a simplified procedure, the wiring pattern is complicated even if the number of multi-core optical fibers increases or the number of multi-core optical fibers increases. Because it is simple without conversion, it can be easily designed. Further, since the wiring pattern is simple, there is no problem that the work of arranging the optical fiber on the sheet itself becomes difficult.

[Brief description of the drawings]

FIG. 1 is a plan view of an optical fiber sheet according to an embodiment of the present invention.

FIG. 2 is a plan view of an optical fiber sheet according to another embodiment of the present invention.

FIG. 3 is a plan view of an optical fiber sheet according to still another embodiment of the present invention.

FIG. 4 is a plan view of an optical fiber sheet according to still another embodiment of the present invention.

FIG. 5 is a plan view of an optical fiber sheet according to still another embodiment of the present invention.

FIG. 6 is a plan view of a conventional optical fiber sheet.

[Explanation of symbols]

11 (11A, 1B, 11C, 11D, 11E) Multi-core optical fiber on input side (one edge side) 12 Sheet 12a Edge on input side of sheet 12b Edge on output side of sheet 13 Single-core optical fiber (optical fiber 14 (14A, 14B, 14C, 14D, 14E) Multi-core optical fiber on output side (other end side) 15, 15 ', 15A, 15B, 15C Optical fiber sheet 25 Optical fiber sheet

 ──────────────────────────────────────────────────続 き Continuing on the front page (72) Inventor Takeshi Shimichi 1440, Mukurosaki, Sakura City, Chiba Prefecture Inside Fujikura Sakura Office (72) Inventor Kazuhiro Takizawa 1440, Musaki, Sakura City, Chiba Prefecture Inside Fujikura Sakura Office F term (reference) 2H038 AA25 CA52 5G363 AA16 BA10 BB04 DA20 DC08

Claims (4)

[Claims] 1. A plurality of multi-core optical fibers on one end side of a sheet are separated into single-core optical fibers inside the sheet, and the separated single-core optical fibers are gathered on the other end side of the sheet to form a plurality of multi-core optical fibers again. An optical fiber wiring method for producing an optical fiber sheet for forming a fiber, wherein each single-core optical fiber is a multi-core optical fiber when each of the multi-core optical fibers on the one end edge side is separated into a single-core optical fiber. From the same direction, and all the separated optical fibers are made parallel to each other.When the parallel single-core optical fibers are collected at the other end, the single-core optical fibers are sequentially separated from the same direction. An optical fiber sheet wiring method, wherein the optical fibers are collected so as to form a multi-core optical fiber. 2. A plurality of multi-core optical fibers on one end side of the sheet are separated into single-core optical fibers inside the sheet, and the separated single-core optical fibers are gathered on the other end side of the sheet to form a plurality of multi-core optical fibers again. An optical fiber wiring method for producing an optical fiber sheet for forming a fiber, wherein the multi-core optical fiber on one end side and the multi-core optical fiber on the other end side are mutually connected in a direction orthogonal to the facing direction of both end edges. A wiring method for an optical fiber sheet, wherein the optical fiber sheet is displaced, and the single-core optical fibers are wired so as to be substantially parallel to each other in a stepped shape in an intermediate portion. 3. The method according to claim 1, wherein when collecting the optical fibers at the other end side, a group of several optical fibers having a smaller number of optical fibers than the number of optical fibers of the multi-core optical connector at the one end side is formed. 2. The method for wiring an optical fiber sheet according to claim 1. 4. A plurality of multi-core optical fibers on one end side of the sheet are separated into single-core optical fibers inside the sheet, and the separated single-core optical fibers are gathered on the other end side of the sheet to form a plurality of multi-core optical fibers again. An optical fiber sheet forming a fiber, wherein each multi-core optical fiber on the one end edge side is a mode in which each single-core optical fiber is sequentially branched in the same direction from the multi-core optical fiber,
Separated into single-core optical fibers, all of the separated optical fibers are made parallel to each other, and the parallel single-core optical fibers are sequentially gathered from the same direction to form a multi-core optical fiber, and are collected at the other end edge side. An optical fiber sheet wherein each multi-core optical fiber is formed.