JPH0566321A - Optical connector - Google Patents

Abstract

PURPOSE:To prevent the core of the optical fiber cord of the optical connector from being broken by absorbing the bending of the optical fiber cord by the connection part between the optical fiber cord and ferrule. CONSTITUTION:A bend allowable part 34 is provided between a sleeve 26 which connects the optical fiber cord 1 to the ferrule 14 and the ferrule 14. This deflection allowing part 34 consists of a spherical external surface 30 provided to the rear end of the ferrule 14 and a spherical engagement part 32 which is provided at the front end of the joining sleeve 26 and engages the spherical external surface 30 of the ferrule 14. The optical connector 10 has no discontinuous part because of the bend allowable part 34 and the core 2 of the optical fiber cord 1 is never broken.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an improvement of an optical connector for connecting an optical fiber cord, for example.

[0002]

2. Description of the Related Art Generally, an optical fiber cord has an optical fiber 4 including a core 2 and a clad 3, as shown in FIG.
And a plastic sheath 6 provided on the optical fiber 4 via a reinforcing layer 5 made of a material having a high tensile strength such as Kepler (trademark).

On the other hand, the optical connector is equipped with a ferrule whose tip surfaces abut against each other when the male coupling and the female coupling are joined. One of the prior art optical connectors, for example the female connector portion, is shown in FIG. The ferrule 14 has a ferrule base 16 having an optical fiber through hole 16a through which the optical fiber 4 penetrates, and a ferrule base 18a having a core through hole 18a through which the core 2 of the optical fiber 4 penetrates, which is press-fitted and fixed to the tip of the ferrule base 16. It comprises a tip portion 18. The tip surface of the core 2 of the optical fiber 4 is exposed at the tip surface of the ferrule tip portion 18.
The female coupling 12 is slidably attached to the ferrule base 16 and is retained by a retaining ring 20.

The female coupling 12 is a ferrule base 1.
The coil spring 22 provided between the No. 6 and the collar 18b presses the snap ring 20. This coil spring 22
When the male and female couplings of the optical connector are coupled, the ferrule tip portion 18 is pressed through the ferrule 14 so that the tip surface of the ferrule tip portion 18 elastically abuts against the tip surface of the other ferrule tip portion. Have a function.

The optical connector further includes a metal backing sleeve 24 interposed between the cladding 3 and the sheath 6 of the optical fiber cord 1 extending from the base end of the ferrule 14.
And a sleeve 2 for a metal joint which is attached across the ferrule 14 and the sheath 6 of the optical fiber cord 1.
6 and 6. This short sleeve 26 is
The ferrule base 16 and the sheath portion of the optical fiber cord 1 backed by the backing sleeve are respectively crimped and the tension applied to the optical fiber cord is received by the ferrule through the reinforcing layer 6 and the sleeve for the short fiber, and the optical fiber cord 1 is received. I'm trying not to hit the core 2.

[0006]

However, in this prior art optical connector, as shown in the area A of FIG. 12, a long immovable portion is formed over the ferrule base 16 and the joint sleeve. There is a drawback that the discontinuous portion B at the boundary between the immovable portion and the optical fiber cord 1 is extremely bent to break the core 2 of the optical fiber cord 1.

An object of the present invention is to avoid the above-mentioned drawbacks and to make it possible to absorb bending at the connecting portion between the optical fiber cord and the ferrule so that the core of the optical fiber cord is not broken. To provide.

[0008]

One of the means for solving the problems of the present invention is to provide a core of an optical fiber cord in which a sheath is provided on an optical fiber via a reinforcing layer so that the tip of the core is exposed on the end face. The penetrating ferrule, the backing sleeve interposed between the clad and the sheath of the optical fiber cord derived from the proximal end of the ferrule, the ferrule and the sheath of the optical fiber cord, and the external tension applied to the core. An optical connector comprising a joint sleeve squeezed so as not to be covered with a spherical outer surface at the rear end of the ferrule, and the joint sleeve slidably engages with the spherical outer surface of the ferrule. The ferrule and the optical fiber cord have a spherical engagement part, and the spherical outer surface of the ferrule and the spherical engagement part of the joint sleeve slide. To provide an optical connector which is characterized in that it has a bend allowing portion that bends freely movable.

Another means for solving the problems of the present invention is the optical connector described above, wherein the joint sleeve has a divergence-permitting slit for allowing divergence so that it can be covered on the spherical outer surface of the ferrule. To provide an optical connector, wherein the joint sleeve is compressed and closely adhered to the spherical outer surface of the ferrule and the reinforcing layer of the optical fiber cord while being covered with the spherical outer surface of the ferrule. is there.

Yet another means of solving the problem of the present invention is the above-mentioned optical connector, wherein the joint sleeve has an elastic imparting slit for elastically expanding so that the spherical outer surface of the ferrule can be press-fitted. The present invention provides an optical connector characterized in that the joint sleeve is tightened by a retaining ring that suppresses the expansion of the elasticity imparting slit while being covered by the ferrule.

[0011]

As described above, when the bending allowance portion is provided between the ferrule and the joint sleeve for connecting the optical fiber cord and the ferrule, a discontinuous portion does not occur, and therefore the core of the optical fiber cord is disconnected. It never happens. Further, if the joint sleeve has a splaying allowance slit, the spherical engagement portion can be engaged with the spherical outer surface of the ferrule. Since the portion engages with the spherical outer surface of the ferrule with a constant surface pressure, the optical connector can be bent with an appropriate resistance. Furthermore, if the joint sleeve has a slit for imparting elasticity, the spherical outer surface of the ferrule can be press-fitted and connected to the joint sleeve. In this case, the tightening force is set by the retaining ring that suppresses the spread of this slit. By doing so, an appropriate bending resistance can be obtained.

[0012]

1 and 2 show an optical connector 10 according to the present invention. The optical fiber cord 1 to be connected by the optical connector 10 is shown in FIG. Similar to the prior art shown in FIG. 12, an optical fiber 4 including a core 2 and a clad 3 and a reinforcing layer 5 made of a material having high tensile strength such as Kepler under the trade name are provided on the optical fiber 4. It comprises a plastic sheath 6 provided.

Further, the optical connector 10 of the present invention is also provided with ferrules whose tip surfaces abut each other when the male coupling and the female coupling are joined, as in the case of the prior art. 2, only the female connector portion is shown. As can be seen from FIGS. 3 and 4, the ferrule 1
4 is an optical fiber through hole 14a through which the optical fiber 4 passes.
And a core through hole 14b which is provided continuously to the optical fiber through hole 14a and through which the core 2 of the optical fiber 4 penetrates, and the front end surface of the core 2 of the optical fiber 4 has a ferrule 14
Exposed on the tip surface of. The female coupling 12 is slidably attached to the body of the ferrule 14 and is retained by a retaining ring 20.

The female coupling 12 is pressed against the retaining ring 20 by a coil spring 22 provided between the female coupling 12 and the collar 14c of the ferrule 14. The coil spring 22 has a function of pressing the ferrule 14 so that the tip end surface of the ferrule 14 resiliently abuts the tip end surface of the other ferrule when the male and female couplings of the optical connector are coupled.

The optical connector further includes a metal backing sleeve 24 interposed between the sheath 3 and the clad 3 of the optical fiber cord 1 extending from the base end of the ferrule 14.
And a sleeve 2 for a metal joint which is attached across the ferrule 14 and the sheath 6 of the optical fiber cord 1.
6 and 6. This short sleeve 26 is
The tension applied to the optical fiber cord 1 by the ferrule 14 and the sheath portion backed by the backing sleeve 24 of the optical fiber cord 1 is clamped through the caulking sleeve 44, and the tension applied to the reinforcing layer 6 and the shorting sleeve 26. It is received by the ferrule 14 via the optical fiber cord 1 so as not to be applied to the core 2 of the optical fiber cord 1. still,
1 to 4, reference numeral 28 is a heat-shrinkable sleeve which is covered over the joint sleeve 26 and the end portion of the optical fiber cord 1 from a portion of the ferrule 14 rearward of the retaining ring 20.

The ferrule 14 has a spherical outer surface 30 formed at its rear end and also has a joint sleeve 26.
Has a spherical engagement portion 32 provided at its front end so as to slidably engage with the spherical outer surface of the ferrule. The ferrule 14 and the optical fiber cord 1 are connected by a bending allowance portion 34 that is bendably movable by sliding between the spherical outer surface 30 of the ferrule 14 and the spherical engagement portion 32 of the joint sleeve 26. In the illustrated embodiment, the joint sleeve 26 has a cutout groove 3 into which a detent protrusion 36 protruding from the outer peripheral surface of the ferrule 14 is fitted at its tip.
8 is provided to prevent the bend permitting portion 34 from rotating around the axis of the optical fiber cord 1 and twisting the optical fiber cord 1.

As described above, when the bend permitting portion 34 is provided between the ferrule 14 and the joint sleeve 26 for connecting the optical fiber cord 1 and the ferrule 14, the connecting portion between the optical fiber cord 1 and the ferrule 14 is unsatisfactory. No continuous portion is generated, and therefore, the core 2 of the optical fiber cord 1 is not broken. The range of the bending angle θ of the bending allowance portion 34 is, as shown in FIG.
It can be set up to about 30 °.

In the embodiment of FIGS. 1 and 2, the joint sleeve 26, as shown in FIG. 5, has a divergence-permitting slit 40 which permits divergence to allow it to cover the spherical outer surface 30 of the ferrule 14. Have. In the embodiment shown in FIG. 5, the expansion allowance slit 40 of the joint sleeve 26 is formed long so that the sleeve 26 can be divided into almost two parts, leaving a slight connecting portion 42. The long sleeve 40 expands the joint sleeve 26 to cover the spherical outer surface 30 of the ferrule 14 so that the spherical engagement portion 32 forms an opening larger than the diameter of the spherical outer surface 30 of the ferrule 14. ..
After that, the joint sleeve 26 is crushed so as to close the slit 36, and a separate crimping sleeve 44 is put on the joint sleeve 26 and crimped.

In this way, the joint sleeve 26 is compressed and attached so that the gap of the expansion allowing slit 40 is eliminated. A constant surface pressure is applied to the bending permitting portion 34 by the tightening action of the crimping sleeve 44, and a moderate resistance to bending is generated. As can be seen from FIG. 2, the optical connector 10 is provided with the bending allowance portion 3
When bending at 4, the optical fiber 4 of the optical fiber cord 1
It is preferable to provide an enlarged portion 14d for escape at the rear end of the optical fiber through hole 14a so as not to be locally bent.

6 to 11 show a joint sleeve 2
6 shows another embodiment of the present invention in which 6 is modified. In this embodiment, the joint sleeve 26 has an elasticity imparting slit 46 and is deformed to such an extent that only the spherical engagement portion 32 can be expanded. It is formed so that In this embodiment, the spherical outer surface 30 of the ferrule 14 is slit 46 in the spherical engagement portion 32 of the joint sleeve 26.
The ferrule 14 and the joint sleeve 26 are connected so that they are forcibly expanded while being press-fitted. The joint sleeve 26 is clamped with the sheath portion backed by the backing sleeve 24, and the tension applied to the optical fiber cord 1 is received by the ferrule 14 via the reinforcing layer 6 and the joint sleeve 26, and the optical fiber is then received. I'm trying not to hit the core 2 of code 1. Then, in order to suppress the expansion of the elasticity imparting slits 46 of the joint sleeve 26, a retaining ring 48 is attached to the outer peripheral surface of the portion having the slits 42.
The slit part of is tightened. The bending resistance of the optical connector 10 is appropriately set by the tightening force of the retaining ring 48 that suppresses the expansion of the elasticity imparting slit 46.

[0021]

According to the present invention, as described above, since the bending permitting portion is provided between the joint sleeve for connecting the optical fiber cord and the ferrule and the ferrule, a discontinuous portion of the optical connector is generated. In addition, the core of the optical fiber cord is not broken. Further, the joint sleeve can have its spherical engagement portion engaged with the spherical outer surface of the ferrule by the expansion allowance slit or the elasticity imparting slit. The tightening force of the snap ring has the practical advantage of being able to bend the optical connector with an appropriate resistance.

[Brief description of drawings]

FIG. 1 is a sectional view of an embodiment of an optical connector according to the present invention.

FIG. 2 is a sectional view of the optical connector of FIG. 1 in a bent state.

FIG. 3 is a top view of a combination state of components of the optical connector of FIG.

FIG. 4 is a cross-sectional view of a combined state of components of the optical connector of FIG.

5 is a side view showing a part of the joint sleeve used in the optical connector of FIG. 1 in an expanded state in a sectional view.

FIG. 6 is a sectional view of another embodiment of the optical connector according to the present invention.

7 is a sectional view of the optical connector of FIG. 6 in a bent state.

FIG. 8 is a top view of a combination state of components of the optical connector of FIG.

9 is a cross-sectional view of a combined state of components of the optical connector of FIG.

10 is a side view showing a part of a joint sleeve used in the optical connector of FIG. 6 in section.

11 is a front view of the joint sleeve of FIG.

FIG. 12 is a cross-sectional view of a conventional optical connector.

[Explanation of symbols]

 1 optical fiber cord 2 core 3 clad 4 optical fiber 5 reinforcing layer 6 sheath 10 optical connector 12 female coupling 14 ferrule 14a optical fiber through hole 14b core through hole 14c collar 20 snap ring 22 coil spring 24 backing sleeve 26 joint sleeve 28 Heat-shrinkable sleeve 30 Spherical outer surface 32 Spherical engagement part 34 Bending allowance part 36 Anti-rotation protrusion 38 Notch groove 40 Spreading allowance slit 42 Connecting part 44 Caulking sleeve 46 Elasticity imparting slit 48 Retaining ring

Claims (3)

[Claims] 1. A ferrule through which the core of an optical fiber cord, in which a sheath is provided on an optical fiber via a reinforcing layer so that the tip of the core is exposed to the end face, and a base end of the ferrule. A backing sleeve interposed between a clad of an optical fiber cord and a sheath, a sleeve for joint which is arranged so as to straddle the ferrule and the sheath of the optical fiber cord, and is crimped so that external tension is not applied to the core. In the optical connector consisting of, the ferrule has a spherical outer surface at the rear end thereof, and the joint sleeve has a spherical engaging portion slidably engaged with the spherical outer surface of the ferrule, The ferrule and the optical fiber cord are freely bendable by sliding between the spherical outer surface of the ferrule and the spherical engagement portion of the joint sleeve. An optical connector having a movable bendable portion. 2. The optical connector according to claim 1, wherein
The joint sleeve has a divergence allowing slit that allows divergence so that the spherical outer surface of the ferrule can be covered, and the joint sleeve is covered with the spherical outer surface of the ferrule so that the ferrule can be covered. An optical connector, wherein the spherical outer surface and the reinforcing layer of the optical fiber cord are respectively compressed and closely attached. 3. The optical connector according to claim 1, wherein
The joint sleeve has an elastic imparting slit that elastically allows expansion so that the spherical outer surface of the ferrule can be press-fitted, and the joint sleeve imparts the elastic force while being covered by the ferrule. An optical connector, characterized in that it is tightened by a retaining ring that suppresses the spread of the slit for use.