JP7161314B2 - Optical connector and method for assembling optical connector - Google Patents

Description

The present invention relates to an easy-to-assemble optical connector and an optical connector assembly method.

Conventionally, when connecting an optical connector to the tip of an optical cord, an optical fiber of the optical cord is connected to an optical fiber built in a ferrule, and a member such as a housing is assembled so as to accommodate this connecting portion. was

As for the structure of such an optical connector, an optical fiber core wire contained in a ferrule and an optical fiber core wire pulled out from an optical cord are fusion-spliced, and then the ferrule is inserted into a plug housing and connected to a rear housing. A method of fixing and forming an optical connector has been proposed (for example, Patent Documents 1 and 2).

JP 2011-95410 A JP 2011-118348 A

However, as in Patent Documents 1 and 2, after connecting the optical fiber core wire built in the ferrule and the optical fiber core wire of the optical cord, the work of inserting this ferrule into the plug housing is complicated and workability is poor. bad.

On the other hand, a method of integrally constructing the ferrule and the plug housing is also conceivable. However, the so-called LC connector may interfere with the fusion splicer because the plug housing has a latch for connecting with the adapter. In addition, if the length of the optical fiber core wire incorporated in the ferrule is increased in order to avoid this interference, the size of the connector increases.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a compact optical connector with good assembling workability and a method for assembling the same.

In order to achieve the above object, a first invention is an optical connector in which a built-in optical fiber held by a ferrule and an optical fiber inside an optical cord are connected, comprising a first housing that accommodates the ferrule; , a second housing that is joined to the first housing, and a transfer cap, wherein a latch for performing an operation for attaching and detaching an optical connector to and from a connection target is not formed in the first housing, and the second housing is provided with a latch. a portion of the ferrule is inserted into the transfer cap, and a portion of the transfer cap is inserted into the first housing to integrate the ferrule and the first housing, and the transfer The optical connector is characterized in that the cap has a flange, and the flange of the transfer cap is in contact with the tip of the first housing .

The ferrule may have a ferrule body and a flange portion joined to the ferrule body, and the rear end of the first housing may be located forward of the rear end of the flange portion.

It is desirable that a jacket pressing member for pressing the jacket of the optical cord is disposed behind the second housing, and the jacket pressing member and the second housing do not overlap in the radial direction.

According to the first invention, the first housing does not interfere with the fusing operation because the latch is not formed on the first housing. For this reason, the ferrule and the first housing can be fused in a state in which they have been assembled in advance, and there is no need to put the ferrule through the first housing on site. Therefore, assembly work is easy.

In particular, by positioning the rear end of the first housing forward of the rear end of the flange portion of the ferrule, the first housing does not protrude rearward of the ferrule, and fusion can be performed without increasing the length of the built-in optical fiber. can be done.

In addition, an outer cover pressing member for pressing the outer cover of the optical cord is arranged behind the second housing so that the outer cover pressing member and the second housing do not overlap in the radial direction. The diameter of the connector can be reduced as compared with the case where the connector is fitted around the outer circumference of the second housing.

A second invention is a method for assembling an optical connector in which a built-in optical fiber held by a ferrule and an optical fiber inside an optical cord are connected, wherein the optical connector includes a first housing that accommodates the ferrule. , a second housing that is joined to the first housing, and a transfer cap , wherein a latch for performing an operation for attaching and detaching the connection target of the optical connector is not formed in the first housing, and the second housing is provided with the second housing. The ferrule is formed only on the housing, a part of the ferrule is inserted into the transfer cap, and a part of the transfer cap is inserted into the first housing, thereby integrating the ferrule and the first housing. a step of fusion splicing the built-in optical fiber and the optical fiber of the optical cord between the first housing and the second housing in a state in which the ferrule and the first housing are integrated in advance; and joining the second housing and the first housing together.

According to the second invention, it is possible to obtain a compact optical code with excellent workability.

In addition, the ferrule and the first housing are integrated by inserting the transfer cap into the first housing, and the ferrule is prevented from falling behind the first housing. Also, the transfer cap allows the center axis of the ferrule to be aligned with the center axis of the first housing.

Advantageous Effects of Invention According to the present invention, it is possible to provide an optical connector that is easy to assemble and is compact, and a method for assembling the same.

2 is an exploded perspective view of the optical connector 1; FIG. FIG. 2 is an assembled sectional view of the optical connector 1; FIG. 4 is an assembled cross-sectional view of the ferrule unit 7; 4A and 4B are diagrams showing an assembly process of the optical connector 1; FIG. 4A and 4B are diagrams showing an assembly process of the optical connector 1; FIG.

An optical connector 1 according to an embodiment of the present invention will be described below. 1 is an exploded perspective view of the optical connector 1, and FIG. 2 is an assembled sectional view of the optical connector 1. FIG. The optical connector 1 is a so-called LC connector, and is mainly composed of a ferrule 3, a first housing 5, a spring 9, a protective sleeve 11, a second housing 13, a jacket holding member 17, a fixing member 19, a boot 21 and the like. be done.

As shown in FIG. 2, the optical connector 1 is formed at the tip of the optical cord 27 . An optical fiber 29 is built in the optical cord 27, and a tensile strength fiber (not shown) is formed on the outer circumference of the optical fiber 29, and a jacket is formed on the outer circumference. The details of the optical code 27 will be described later.

A built-in optical fiber 25 is held inside the ferrule 3 . The built-in optical fiber 25 is connected to the optical fiber 29 of the optical cord 27 described above. That is, inside the optical connector 1 , the built-in optical fiber 25 held by the ferrule 3 and the optical fiber 29 inside the optical cord 27 are connected, and the connection is reinforced by the protective sleeve 11 .

The ferrule 3 is housed in the first housing 5 and constitutes a ferrule unit 7 . 3 is a sectional view of the ferrule unit 7. FIG. The ferrule 3 is composed of a ferrule body 3a and a flange portion 3b, and the built-in optical fiber 25 described above is held in the ferrule body 3a. A flange portion 3b is connected and fixed to the rear end portion of the ferrule body 3a.

As shown in FIG. 2, a spring 9 is arranged behind the ferrule 3 (flange portion). Ferrule 3 is pressed against first housing 5 by spring 9 . Therefore, when the ferrule 3 is pressed against the first housing 5, the ferrule 3 is positioned deepest (forward) with respect to the first housing 5, and when the ferrule 3 is pushed backward against the spring 9, the ferrule 3 , is slidable rearwardly with respect to the first housing 5 .

The rear end of the first housing 5 is located forward of the rear end of the flange portion 3b. That is, the first housing 5 does not protrude rearward beyond the rear end of the ferrule 3 .

As shown in FIG. 3, a transfer cap 23 is attached to the tip of the ferrule 3 . The transfer cap 23 functions to protect the tip of the ferrule 3 during assembly and handling and as a handle during work. The tip of the ferrule body 3 a is inserted into the transfer cap 23 , and part of the transfer cap 23 is inserted into the first housing 5 .

A part of the transfer cap 23 is inserted into the first housing 5 to integrate the ferrule 3 and the first housing 5 . In addition, the ferrule 3 can be prevented from dropping rearward from the first housing 5 by contacting the flange portion of the transfer cap 23 with the tip of the first housing 5 . Further, the center axis of the ferrule 3 and the center axis of the first housing 5 can be aligned by the transfer cap 23 .

A second housing 13 is joined to the rear of the first housing 5 . A latch 15 is provided on the second housing 13 . The latch 15 is a portion for performing an operation for attaching and detaching the adapter to which the optical connector 1 is connected. That is, in the optical connector 1 , the latch 15 is not formed on the first housing 5 but is formed only on the second housing 13 . The connecting portion between the built-in optical fiber 25 of the ferrule 3 and the optical fiber 29 of the optical cord 27 is arranged inside the second housing 13 .

At the rear of the second housing 13, a jacket pressing member 17 for pressing the jacket of the optical cord is arranged. A fixing member 19 is arranged on the outer circumference of the jacket pressing member 17 and behind the second housing 13 .

The jacket pressing member 17 is a ring-shaped member that presses the jacket of the optical cord 27 . The fixing member 19 is a member that presses the jacket pressing member 17 against the rear end of the second housing 13 and fixes the tensile strength fibers of the optical cord 27 . The fixing structure of the optical cord 27 by the jacket pressing member 17 and the fixing member 19 will be described later in detail.

In addition, the jacket pressing member 17 is arranged behind the second housing 13 , and a part of the second housing 13 is not inserted into the jacket pressing member 17 . That is, the jacket pressing member 17 is not arranged on the outer periphery of the second housing 13, and the jacket pressing member 17 and the second housing 13 do not overlap in the radial direction.

A boot 21 is joined to the rear of the fixing member 19 . The boot 21 is made of flexible resin, is a member that suppresses sudden bending of the optical cord 27 , and is arranged on the outer circumference of the optical cord 27 .

Next, a method for assembling the optical connector will be described. First, as shown in FIG. 4A, the built-in optical fiber 25 of the ferrule 3 and the optical fiber 29 of the optical cord 27 are fusion-spliced between the first housing 5 and the second housing 13 . At this time, the ferrule unit 7 is pre-assembled and integrated, and the transfer cap 23 is connected.

At the end of the optical cord 27, the jacket 31 is peeled off in advance by a predetermined length, and the internal tensile strength fiber 33 and the optical fiber 29 are pulled out. At this time, the distal end portion of the jacket 31 is torn by a predetermined length, for example, into two parts in the circumferential direction.

With the protective sleeve 11 retracted to the optical cord 27, the optical fiber 29 of the optical cord 27 and the built-in optical fiber 25 of the ferrule 3 are set in a fusion splicer and spliced. At this time, since the ferrule 3 and the first housing 5 are fixed by the transfer cap 23 so that their central axes are aligned, misalignment of the built-in optical fiber 25 is suppressed, and fusion work is facilitated.

After the optical fiber 29 and the built-in optical fiber 25 are fused, the protective sleeve 11 is moved to the connecting portion and fixed. The protective sleeve 11 has, for example, a heat-shrinkable member and a core material, and by heating the connecting portion between the optical fiber 29 and the built-in optical fiber 25, the protective sleeve 11 can be fixed to the connecting portion.

Next, as shown in FIG. 4B, the spring 9 and the second housing 13 that have been retracted to the optical cord 27 are moved to join the rear end of the first housing 5 and the second housing 13 together. The first housing 5 and the second housing 13 can be joined by, for example, a latch (not shown) or the like.

In addition, when the second housing 13 is connected to the first housing 5 , the jacket 31 and the tensile strength fibers 33 near the tip of the optical cord 27 are arranged outside the second housing 13 . For example, the outer cover 31 that has been torn and divided into two pieces is spread at the rear end of the second housing 13 .

Next, as shown in FIG. 5( a ), the jacket holding member 17 that has been retracted to the optical cord 27 is moved and placed at the rear end of the second housing 13 . The inner diameter of the jacket pressing member 17 is smaller than the outer diameter of the rear end of the second housing 13, and the outer diameter of the jacket pressing member 17 is larger than the inner diameter of the rear end of the second housing 13. The pressed member 17 and the second housing 13 are butted against each other without being fitted.

At this time, the outer cover 31 split into two and spread is sandwiched between the tip of the outer cover pressing member 17 and the rear end of the second housing 13 . Also, the tensile strength fibers 33 are taken out from between the jacket 31 and the second housing 13 .

Next, as shown in FIG. 5( b ), the fixing member 19 that has been retracted to the optical cord 27 is moved and joined to the second housing 13 . For example, a male threaded portion is formed on the outer peripheral portion of the second housing 13 and is screwed with a female threaded portion formed on the inner surface of the fixing member 19 . In this case, the fixing member 19 can be fixed to the second housing 13 by screwing the fixing member 19 into the second housing 13 .

At this time, when the fixing member 19 is screwed into the second housing 13, a portion of the inner surface of the fixing member 19 comes into contact with a portion of the jacket pressing member 17 from behind. That is, the front end of the reduced-diameter portion of the fixing member 19 contacts the rear of the enlarged-diameter portion of the jacket pressing member 17 . Therefore, the fixing member 19 can press the jacket pressing member 17 toward the second housing 13 . Therefore, the outer cover 31 is strongly sandwiched between the outer cover pressing member 17 and the second housing 13, and the outer cover 31 can be fixed.

Also, the tensile strength fibers 33 arranged along the outer circumference of the second housing 13 are sandwiched between the male threaded portion and the female threaded portion between the second housing 13 and the fixing member 19 . That is, a slight gap is formed between the male threaded portion and the female threaded portion between the second housing 13 and the fixing member 19, and the tensile strength fibers 33 are sandwiched in this gap. For this reason, the tensile strength fibers 33 can be retained and fixed to the outer circumference of the second housing 13 .

Finally, the boot 21 retracted to the optical cord 27 is moved to join the boot 21 to the rear end portion of the fixing member 19 . For example, a portion of the rear end portion of the fixing member 19 is inserted into the boot 21 and joined. The optical connector 1 can be assembled by the above. The fixing member 19 and the boot 21 may be integrated in advance.

When the optical connector 1 is used, the tip of the built-in optical fiber 25 is exposed at the tip of the ferrule 3 by removing the transfer cap 23, and can be optically connected to the optical fiber of the adapter to be connected. At this time, since the ferrule 3 is pushed forward by the spring 9, when the ferrule 3 is pushed into contact with the object to be connected, physical contact can be reliably made. Incidentally, at this time, by operating the latch 15, it is possible to perform the connection/disconnection operation with respect to the connection target.

According to this embodiment, the first housing 5 and the second housing 13 are separated, and the ferrule 3 is integrated with the first housing 5 in advance. There is no need to work to fix it. At this time, since the assembly can be performed with the transfer cap 23 attached, the work is easy.

Also, the latch 15 for attaching and detaching to and from the adapter to be connected is formed only on the second housing. Therefore, the size of the first housing 5 can be reduced, and the latch does not interfere with fusion splicing work.

In particular, since the first housing 5 does not protrude backward beyond the flange portion 3b of the ferrule 3, it does not interfere with the fusion splicer and the built-in optical fiber 25 does not need to be lengthened.

Further, the outer cover of the optical cord 27 is sandwiched and fixed between the tip of the outer cover pressing member 17 and the rear end of the second housing 13 . That is, the jacket pressing members 17 do not overlap in the radial direction of the second housing 13 . Therefore, the optical connector 1 with a small diameter can be achieved without increasing the diameter by overlapping the jacket pressing member 17 and the second housing 13 .

Although the embodiments of the present invention have been described above with reference to the accompanying drawings, the technical scope of the present invention is not influenced by the above-described embodiments. It is obvious that a person skilled in the art can conceive various modifications or modifications within the scope of the technical idea described in the claims, and these are naturally within the technical scope of the present invention. be understood to belong to

For example, the shape of each part constituting the optical connector 1 is not limited to the illustrated example.

Reference Signs List 1 Optical connector 3 Ferrule 3a Ferrule body 3b Flange 5 First housing 7 Ferrule unit 9 Spring 11 Protective sleeve 13 Second housing 15 Latch 17 Jacket pressing member 19 Fixing member 21 Boot 23 Conveying cap 25 Built-in optical fiber 27 Optical cord 29 ... Optical fiber 31 ... Jacket 33 ... Tensile strength fiber

Claims (4)

An optical connector with a transfer cap in which a built-in optical fiber held by a ferrule and an optical fiber inside an optical cord are connected,
a first housing that accommodates the ferrule;
a second housing joined to the first housing;
a transport cap;
and
a latch for attaching and detaching the optical connector to and from a connection target is formed only on the second housing without being formed on the first housing;
A portion of the ferrule is inserted into the transfer cap, and a portion of the transfer cap is inserted into the first housing to integrate the ferrule and the first housing ,
The optical connector , wherein the transfer cap has a flange, and the flange of the transfer cap is in contact with the tip of the first housing . The ferrule has a ferrule body and a flange portion joined to the ferrule body,
2. The optical connector according to claim 1, wherein the rear end of said first housing is located forward of the rear end of said flange portion. A jacket holding member for holding the jacket of the optical cord is disposed behind the second housing,
3. The optical connector according to claim 1, wherein the jacket pressing member and the second housing do not overlap in the radial direction. A method for assembling an optical connector in which a built-in optical fiber held by a ferrule and an optical fiber inside an optical cord are connected,
The optical connector is
a first housing that accommodates the ferrule;
a second housing joined to the first housing;
a transport cap;
and
a latch for attaching and detaching the optical connector to and from a connection target is not formed in the first housing but is formed only in the second housing;
A part of the ferrule is inserted into the transfer cap, and a part of the transfer cap is inserted into the first housing, whereby the ferrule and the first housing are integrated,
a step of fusion splicing the built-in optical fiber and the optical fiber of the optical cord between the first housing and the second housing in a state in which the ferrule and the first housing are integrated in advance; ,
joining the second housing and the first housing;
A method for assembling an optical connector, comprising:

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