JPH0440172Y2 - - Google Patents

Description

[Detailed Description of the Invention] [Industrial Application Field] This invention relates to an optical connector plug using a ferrule, and particularly relates to the ferrule.

[Conventional technology] FIG. 7 shows an example of a conventional ferrule.

10 is an optical fiber wire, 12 is a covering part, 1
4 is the entire optical fiber core wire, 16 is the reinforcing fiber, 1
8 is a jacket, and 20 is the entire optical fiber cord.

22 is a ferrule. The optical fiber core 14 is inserted into this and fixed with adhesive 24. Note that 26 is a glass tube.

[Problem that the invention attempts to solve] It takes time for the adhesive 24 to harden (it takes a long time to harden)
30 minutes, usually about 2 hours).

When assembling connectors at the installation site, the long bonding time is an obstacle.

[Means for Solving the Problems] This invention aims to solve the above problems by making it possible to assemble the ferrule without using adhesive.

[Example 1] FIG. 1 shows only the ferrule 30 in an exploded manner.

The ferrule 30 consists of a sleeve 32 and a fiber holder 40 inserted therein.

- Description of the sleeve 32: 34 is the main body of the sleeve 32, which is made of stainless steel, for example, and its outer surface is precisely finished into a cylinder.

Reference numeral 36 designates an insert made of, for example, plastic, and a portion of its inner surface 38 is tapered.

This insert 36 is inserted into the tip of the main body 34 and integrated, for example, by gluing (see FIG. 3).

- Description of the fiber presser foot 40: The fiber presser foot 40 has a generally elongated, generally cylindrical shape, and is made of, for example, plastic.

At its tip is a tapered section 42, followed by a parallel section 44, behind which is a large diameter section 46, which is provided with a collar 48.

The fiber presser 40 is divided into upper and lower halves, as shown in FIG. 2, for example.

The large diameter portion 46 is bisected by a plane passing through the central axis. Figure 1 also shows the cross section.

The parallel portion 44 and the tapered portion 42 are bisected, for example, by two planes that intersect at an angle of 120° on the axis. Figure 1 also shows their cross sections.

Slots 52 and 54 are provided along the upper and lower dividing surfaces of the tapered portion 42, and a slot 50 is also provided in the upper half of the tapered portion 42.
is separated into three segments 42A, 42B, and 42C.

a groove 56 for accommodating the fiber strand 10 along the central axis of the parallel portion 44 and the large diameter portion 46;
A groove 58 is provided for receiving the covering portion 12. The rear portions 60 and 62 of the groove 58 are particularly thick, which will be discussed later.

- Assembly structure of only the ferrule 30: The end of the optical fiber core 14 is sandwiched between them, and the two halves of the fiber presser 40 are brought together.

As mentioned above, the covering portion 12 is within the groove 58. Further, the fiber strand 10 partially enters the groove 56, and the tip thereof enters the gap formed between the tops of the three segments.

The sleeve 3 is attached to the fiber presser 40 thus constructed.
Cover with 2.

Sleeve 32 overlays parallel portion 44 .

The tapered inner surface 38 of the insert 36 pushes the tapered portion 42 inwardly. Three segments of tapered portion 42 clamp fiber strand 10.

Note that the portion of each segment that corresponds to the fiber wire 10 is flat.

Then, the rear part of the main body 34 (indicated by 35 in FIG. 3) is swaged, and the sleeve 32 and fiber retainer 4
0 and prevents separation.

- Assembly structure of the entire plug: 64 in FIG. 3 is an internal sleeve, which is always inserted into the groove 62 when assembling the ferrule 30 described above. Collar 66 enters groove 60.

A portion of the sleeve 64 that protrudes to the rear of the ferrule 30 is inserted into the outer sheath 18 of the optical fiber cord 20.

An outer sleeve 68 is placed over the end of the jacket 18 and swaged to firmly connect the optical fiber cord 20 (including the reinforcing fibers 16) and the ferrule 30 via the inner sleeve 64.

70 is a plug frame, 72 is a cap nut for fixing it, and 74 is a coupling ring, which are the same as those used in conventional plugs.

[Function] (1) By precision machining the sleeve 32, the insert 36, and the tapered portion 42 of the fiber holder 40, the central axes of the fiber wire 10 and the sleeve 32 can be accurately aligned.

(2) The usage of this plug is the same as before.

That is, for example, the ferrule 30 is inserted from both sides of an adapter (not shown) and fixed with a coupling ring 74.

(3) Even if a tensile force is applied to the optical fiber cord 20, since the reinforcing fibers 16 are connected to the plug frame 70, no tensile force is applied to the optical fiber core wire 14.

[Example 2] As shown in FIG. 4a, two slots 52 and 54 are provided in the tapered portion 42 of the fiber presser 40 to separate it into two segments 42A and 42B.

Then, the fiber wire 10 is clamped by the V-groove 53 provided in the center.

In addition, as shown in FIG. 4b, the V-groove 53 is provided only on one segment, and the other side is left flat.
The fiber wire 10 may also be clamped.

Note that the number of slots can also be four or more.

[Example 3] In this case, the sleeve 32 and the insert 36 are not bonded together as follows.

That is, as shown in FIGS. 5 and 6, the sleeve 3
A stepped portion 33 is provided on the inner surface of the main body 34 of No. 2. Then, when the insert 36 is inserted from the rear, its tip engages with the stepped portion 33.

In this case, the main body 34 of the sleeve 32 and the plug frame 70 are integrated. However, this point is a structure known as an optical connector.

The fiber presser 40 has a structure of upper and lower halves, as in the case of the second embodiment, and a rib 59 is provided in the groove 58 for the covering portion 12. This rib 59 is
For example, the groove 58 has a triangular mountain shape in cross section and is provided so as to cross the bottom of the groove 58 at right angles to the longitudinal direction.

45 is a sleeve. It is cylindrical, and its inner diameter is approximately equal to the outer diameter of the parallel portion 44 of the fiber presser 40.

76 is the rear body. This is connected by screwing into the rear part of the plug frame 70. Note that this structure is also the same as a known structure.

- Assembly structure in this case: The end of the optical fiber core wire 14 is sandwiched between them, and the two halves of the fiber presser 40 are put together.

At this time, the covering portion 12 fits into the groove 58, but because of the rib 59, it is raised from the bottom, and the fiber presser 40 does not fit snugly.

At this time, the sleeve 45 is forced to cover the parallel portion 44 of the fiber presser 40. Then, the ribs 59 are embedded in the covering portion 12, and the upper and lower fiber pressers 40 are tightly fitted together.

In this case, the sleeve 45 may be made larger and then clamped after assembly.

As described above, the sleeve 32 into which the insert 36 is inserted is placed over the fiber presser 40, and the rear body 76 is screwed into the rear part of the plug frame 70.
Then, the fiber presser 40 is pushed by the rear body 76 and moves forward. Therefore, the inner surface 38 of the insert 36 pushes the tapered portion 42 of the fiber holder 40 inward, and the tapered portion 42 clamps the fiber strand 10.

The other parts are the same as in "Example 1".

[Effects of the invention] (1) In order to connect optical fibers with low loss, it is most important to align the central axis of the ferrule sleeve 32 with the fiber strand 10.

In the present invention, since the tapered portion 42 of the fiber holder 40 fitted into the sleeve 32 clamps the fiber strand 10 of the optical core, the sleeve 32 and the fiber holder 40 cannot be processed accurately. For example, the central axis of the sleeve 32 and the fiber strand 10 should coincide.

The sleeve 32 of the present invention has a cylindrical body 34
Since an insert having a tapered inner surface 38 is fitted into the inside of the insert, processing is easy. Further, since the fiber presser 40 is divided into upper and lower halves, its processing is easy.

Therefore, the sleeve 32 and the fiber holder 40 can be easily and accurately processed (without increasing costs too much), and the central axis of the sleeve 32 and the fiber strand 10 can be aligned.

(2) As described above, since the fiber strands 10 of the fiber core wire 14 are clamped by the fiber presser 40, the strands 10 do not move in the axial direction within the ferrule.

Therefore, from the tip of the ferrule, there are 10 strands of wire.
This prevents the parts from protruding and being damaged when butted against each other.

(3) Since no adhesive is used, it is possible to shorten the work time when assembling on site.

[Brief explanation of the drawing]

1 to 3 are explanatory diagrams of the first embodiment of the present invention, in which FIG. 1 shows a state in which the ferrule 30 is disassembled, FIG. 2 shows a state in which only the fiber presser 40 is separated, and FIG. The entire assembled state is shown. 4a and b are explanatory diagrams of different aspects of the second embodiment, and FIG. 5 is an explanatory diagram of the main parts of the third embodiment,
FIG. 6 is an exploded explanatory diagram thereof, and FIG. 7 is an explanatory diagram of a conventional ferrule. 10...Fiber wire, 12...Coated portion, 1
4...Optical fiber core wire, 16...Reinforcement fiber, 18
...Sheath, 20...Optical fiber cord, 30...
Ferrule, 32...Sleeve, 34...Body,
36...Insert, 38...Inner surface, 40...Fiber holder, 42...Tapered portion, 44...Parallel portion, 46...Large diameter portion, 48...Brim, 50,
52, 54...slot, 53...V groove, 56,
58...Groove, 64...Inner sleeve, 68...Outer sleeve, 70...Plug frame, 72...
Fukuro Natsuto, 74...Katsupring.

Claims (1)

[Claims for Utility Model Registration] (1) An optical connector that uses a ferrule 30 and is characterized in that the ferrule 30 has the following structure. - Consists of a sleeve 32 and a fiber presser 40. - The sleeve 32 has an insert having a tapered inner surface 38 fitted inside a cylindrical main body 34. - The fiber presser 40 has a cylindrical shape as a whole, has at least a tapered portion 42 at the tip and a parallel portion 44 following it, and is divided into upper and lower halves, and at least the tapered portion 42 has two slots. is provided,
Tapered portion 42 is thereby separated into two or more segments. - The fiber presser foot 40 is located on the internal central axis,
The optical fiber core wire 14 is fitted into the sleeve 32 with the fiber strand 10 and the coated portion 12 arranged, and the tapered portion 42 is pushed inward by the tapered inner surface 38 to clamp the fiber strand 10. ing. (2) The sleeve 32 includes an insert 36 having a tapered inner surface 38 inside the cylindrical body 34.
2. The optical connector according to claim 1, wherein the optical connector is fitted with and adhered to. (3) Claim 1, characterized in that the inner surface of the cylindrical main body 34 of the sleeve 32 is provided with a stepped portion, and the tip of the insert 36 having the tapered inner surface 38 is engaged with the stepped portion. Optical connector described in .