JPH1184177A - Multifiber optical connector - Google Patents

Abstract

PROBLEM TO BE SOLVED: To facilitate the insertion of optical fibers into fiber holes of a ferrule by projecting shelves into the internal space of a main body from the front part of the main body between adjacent fiber hole arrays of an odd numbered stage and on even numbered stage from the top and providing the front surfaces and rear surfaces of these shelves with guide grooves, respectively. SOLUTION: A shelf 32 is projected into the internal space 16 from the front part 120 of the main body between the fiber hole arrays 21 of an odd numbered stage (first step for example) and an even numbered stage (for example, second step) from the top. The front surfaces and rear surfaces thereof are respectively provided with the guide grooves 24. The optical fibers inserted into the fiber hole arrays 21 of the odd numbered stage are guided by the guide grooves 24 of the front surfaces of the shelves 32 and the optical fibers inserted into the fiber hole arrays 21 of the even numbered stage are guided by the guide grooves 24 of the rear surfaces. As a result, the insertion of the optical fibers into the fiber holes 20 of all the fiber hole arrays 2 is facilitated.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION The present invention relates to a fiber hole
The present invention relates to an optical ferrule used in a multi-core optical connector, which includes ferrules arranged two-dimensionally in the vertical and horizontal directions.

[0002]

2. Description of the Related Art FIG. 4 shows a conventional two-dimensionally arranged multi-core optical connector ferrule. This multi-core optical ferrule is an MT connector (JIS C5981) of a positioning pin connection type.
F12 type multi-core optical fiber connector specified in
The shape and the internal structure are similar, and the MT connector has multiple fiber holes. 2A is a perspective view of the ferrule, and FIG.
Side view of the ferrule at the center of
(C section), (c) is a CC sectional view of (b), (d) is an explanatory view of the core 26, (e) is an explanatory view in which a part of the ferrule is cut away.

[0003] Reference numeral 10 denotes an entire plastic molded hollow ferrule, reference numeral 12 denotes a main body thereof, and reference numeral 14 denotes a guide pin hole into which a guide pin to be bridged between both ferrules at the time of positioning is inserted. 16 is the internal space, 160 is its bottom, 1
62 is a front wall. Reference numeral 18 denotes a window for checking the insertion state of the optical fiber and injecting an adhesive.

A large number of fiber holes 20 are provided in a front part 120 of the main body.
Are provided in multiple stages. For convenience of description, in this specification, the fiber holes 20 arranged in one row in a horizontal row will be referred to as a “fiber hole row” 21. Fiber hole 20
The optical fiber has a large diameter of about several μm. FIG.
This is an example in which fiber hole arrays 21 are provided in two stages. Each fiber hole 20 has a tapered portion 22 at a portion that opens into the internal space 16. In only the lower fiber hole row 21, the guide groove 24 is provided on the bottom 160 of the internal space 16 following each tapered portion 22.

FIG. 4D schematically shows a core 26 used for molding the ferrule 10. The core 26 includes a molding pin 28 and a spacer 30. The molding pin 28
It comprises a thin part 280 (for molding the fiber hole 20), a tapered part 282 (for molding the tapered part 22) and a thick part 284 (for molding the guide groove 24). The guide groove 24 is formed by the portion A of the thick portion 284 of the lower forming pin 28 which is not covered by the spacer 30. Also the thick part 284
Forms an internal space 16 in combination with the spacer 30. In the figure, reference numeral 31 denotes a mold. The window 18 is formed not by the spacer 30 but by a convex portion of a mold.

Each fiber hole 2 in the lower fiber hole row 21
The optical fiber inserted into the zero can be smoothly advanced by being guided by the guide groove 24 and the tapered portion 22.
In the case of the upper row of fiber holes 21, since there is no guide groove 24, the fiber is inserted into the tapered portion 22 while being viewed from the window 18 and fed.

[0007]

SUMMARY OF THE INVENTION
In the case of No. 1, since there is no guide groove 24, it is difficult to insert, for example, a multi-core optical fiber tape tip into the fiber hole 20 at a time. The tip of the optical fiber is the front wall 162
Sometimes it hits. Similar difficulties arise when inserting optical fibers not only in multiple cores but also in single cores.

[0008]

According to the first aspect of the present invention, a shelf 3 is provided between fiber hole rows 21 so as to partition a step.
2 is projected, and the invention according to claim 2 is
The fiber hole array 21 has an even number of stages (two, four, six,.
In the case of −), as illustrated in FIGS. 1 and 2, between adjacent adjacent odd-numbered (eg, first) and even-numbered (eg, second) fiber hole rows 21 from above. A shelf 32 projects from the main body front portion 120 into the internal space 16 of the main body 12, and guide grooves 24 are provided on the upper surface and the lower surface of the shelf 32, respectively. The optical fibers guided by the guide grooves 24 on the upper surface of the shelf 32 and inserted into the even-numbered fiber hole rows 21 are guided by the guide grooves 24 on the lower surface of the shelf 32. It is characterized by.

1 and 2, since the fiber hole array 21 has two stages, the upper stage is an odd stage and the lower stage is an even stage.

[0010] "The optical fiber inserted into the even-numbered fiber hole row 21 is guided by the guide groove 24 on the lower surface of the shelf 32."
4 as well as the guide groove 24 formed in the bottom 160 of the internal space 16 as shown in FIG.
Including the case of guiding in collaboration with

Further, the invention according to claim 3 is a case where the fiber hole array 21 has an odd number of stages (3 stages, 5 stages, 7 stages, ---), and as shown in FIG. The steps up to the even-numbered stage (for example, the fourth stage) are the same as those in the above-described claim 1, but the lowermost (for example, the fifth stage) fiber hole row 2
The optical fiber inserted into the ferrule 1 is the internal space 1 of the ferrule.
6 is guided by the guide groove 24 formed in the bottom part 160 of the sixth embodiment.

[0012]

BEST MODE FOR CARRYING OUT THE INVENTION

[FIG. 1] This is an example in which the fiber hole array 21 has two stages. 2A is a perspective view of the ferrule, FIG. 2B is a vertical sectional side view of the ferrule at the center of the fiber hole 20 (BB section of FIG. 1C), and FIG. 1C is a CC section of FIG. Figure, (d)
Is an explanatory view of the core 26, and (e) is an explanatory view in which a part of the ferrule is cut out.

[Object itself] This is a structure in which a shelf 32 is added to the conventional thing shown in FIG. That is, the upper fiber hole row 2
A shelf 32 projects from the front part 120 of the main body into the internal space 16 of the main body 12 between the first and lower fiber hole rows 21. A guide groove 24 having a uniform cross section and a uniform thickness is provided on each of the upper surface and the lower surface of the shelf 32. Each of these guide grooves 24 is formed in the fiber hole 2 through the tapered portion 22.
Connects smoothly to 0. Also, as in the case of the conventional FIG. 4,
The guide groove 24 on the bottom 160 remains as it is, and smoothly connects to the lower fiber hole 20 via the tapered portion 22 whose diameter gradually decreases toward the tip. The width (pitch) of the guide groove 24 is made substantially equal to the fiber pitch of the optical fiber (normally, a multi-core tape fiber) to be inserted.

[Manufacturing Method] A core 26 for manufacturing the ferrule 10 in this case is schematically shown in FIG.
Compared with the conventional one shown in FIG. 4, the middle spacer 30 is shorter, thereby forming a shelf 32. The guide grooves 24 on the upper surface and the lower surface of the shelf 32 are formed by the portions B and C that are not in contact with the spacer 30 in the thick portion 284 of the molding pin 28.

[Usage Method] The optical fiber inserted into the upper fiber hole row 21 is guided by the guide groove 24 on the upper surface of the shelf 32. The optical fiber inserted into the lower fiber hole row 21 is guided by the guide groove 24 on the lower surface of the shelf 32 and the bottom 1.
Guided by both guide grooves 24 on 60. As the optical fiber, generally, a multi-core tape fiber is used, and a multi-core tape fiber that is drawn out is inserted in multiple stages.

[Case of FIG. 2] Guide groove 2 on bottom 160
There is no 4. Others are the same as the case of FIG. 1 described above.

For this reason, of the spacers 30 of the core 26, the lower ones having the same length as the upper ones are used.

The optical fiber inserted into the lower fiber hole row 21 is guided only by the guide groove 24 on the lower surface of the shelf 32.

In this case, compared to the case of FIG.
There is an advantage that the mold structure is simplified.

[Case of FIG. 3] This is the case of the invention of claim 2 in which five (odd number) fiber hole rows 21 are provided. The shelf 32 projects between the first and second tiers and the third and fourth tiers from above. Then, guide grooves 24 are provided on the upper surface and the lower surface, respectively. A guide groove 24 is formed at the bottom 160 of the inner space 16 of the ferrule for the lowermost fiber hole row 21.

Although the thickness of the guide groove is determined by the thick portion 284 of the forming pin 28, the shape of the forming pin 28 reaching the thin portion 280 is not limited to this embodiment. For example, the cross section of the thick portion 284 may not be uniform, and may be any shape that smoothly guides the optical fiber tip to the fiber hole.

The method of use is as described above.

[0023]

According to the present invention, the shelf 32 projects from the main body front portion 120 into the internal space 16 of the main body 12 between the adjacent odd-numbered and even-numbered fiber hole rows 21 from above. The provision of the guide grooves 24 facilitates insertion of the optical fiber into the fiber hole 20 of the ferrule.

[Brief description of the drawings]

FIG. 1 is an explanatory view of an embodiment of the present invention according to claim 1,
(A) is a perspective view of a ferrule, (b) is a fiber hole 20
Side view of the ferrule at the center of
(C section), (c) is a CC sectional view of (b), (d) is an explanatory view of the core 26, (e) is an explanatory view in which a part of the ferrule is cut away.

2 (a) is a perspective view of a ferrule, FIG. 2 (b) is a vertical sectional side view of the ferrule at the center of a fiber hole 20, and FIG. (C section), (c) is a CC section view of (b), (d)
FIG. 4 is an explanatory view of a core 26, and FIG.

FIG. 3 is an explanatory view of an embodiment of the present invention according to claim 2,
(A) is a perspective view of a ferrule, (b) is a fiber hole 20
FIG. 4 is a vertical side view of the ferrule at the center of FIG.

4 (a) is a perspective view of a ferrule, FIG. 4 (b) is a longitudinal side view of the ferrule at the center of a fiber hole 20 (BB section of FIG. 4 (c)), and FIG. (B) is a sectional view taken along line CC, (d) is an explanatory view of the core 26,
(E) is an explanatory view in which a part of a ferrule is cut out.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 10 Ferrule 12 Ferrule main body 120 Main body front part 14 Guide pin hole 16 Internal space of ferrule 160 Bottom part of space 162 Front wall of space 18 Window 20 Fiber hole 21 Fiber hole row 22 Tapered part 24 Guide groove 26 Core 28 Mold pin 280 Thin Part 282 Tapered part 284 Thick part 30 Spacer 31 Mold 32 Shelf

Claims (3)

[Claims] 1. In a main body front part 120 of an MT ferrule,
In the multi-core optical connector in which the fiber hole rows 21 in which the fiber holes 20 are arranged in one row are provided in multiple stages, the main body front portion 120 is provided between adjacent fiber hole rows 21.
A multi-core optical connector characterized in that a shelf 32 protrudes into the internal space 16 from the inside. 2. In a multi-core optical connector, an even number of fiber hole rows 21 in which fiber holes 20 are arranged in one row are provided in a front part 120 of the main body of the optical ferrule. Between the fiber hole rows 21 of the odd and even stages from the main body front portion 120 to the internal space 1.
6, the guide grooves 24 are provided on the upper surface and the lower surface of the shelf 32, respectively. 2. The multi-core optical fiber according to claim 1, wherein the optical fibers guided and inserted into the even-numbered fiber hole rows 21 are guided by guide grooves 24 on the lower surface of the shelf 32. 3. Optical connector. 3. A multi-core optical connector in which a plurality of odd-numbered fiber hole rows 21 in which fiber holes 20 are arranged in a horizontal row are provided in a front part 120 of a main body of an optical ferrule. Between the odd-numbered and even-numbered fiber hole rows 21, a shelf 32 protrudes from the main body front portion 120 into the internal space 16 of the main body 12, and guide grooves 24 are provided on the upper and lower surfaces of the shelf 32, respectively. The optical fiber inserted into the odd-numbered fiber hole row 21 is
The optical fibers guided by the guide grooves 24 on the upper surface of the rack 2 and inserted into the even-numbered fiber hole rows 21 are guided by the guide grooves 24 on the lower surface of the shelf 32, and are inserted into the lowermost fiber hole rows 21. 2. The multi-fiber optical connector according to claim 1, wherein the inserted optical fiber is guided by a guide groove formed in a bottom portion of the inner space of the ferrule.