JP2011075829A - Optical transmission member with connector and optical connector - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a technology by which a fusion splicing work is easily performed in assembling an optical connector, which is configured to house a fusion-spliced part of an optical fiber of an optical transmission body and an optical fiber (built-in optical fiber) inserted and fixed in a ferrule, onto the terminal of the optical transmission body such as an optical fiber cord, and the optical characteristic of the built-in optical fiber is stably kept even when a push-back arises in the ferrule when the connector is connected. <P>SOLUTION: The optical transmission body with connector and an optical connector are provided in which a fusion reinforcement part 20, which protects and reinforces the fusion-spliced part 15 of the back end part of the built-in optical fiber 12 on the side of the ferrule 4 and the optical fiber 22 which is tapped on the terminal of the optical transmission body 21, is integrated with the back end part of a ferrule housing 3 and the terminal of the optical transmission body 21, and a flange abutting part 7b is provided in the ferrule housing 3 to restrict the movement of the ferrule 4 toward the back side of the connector of the ferrule 4 by the abutting of the flange part 14 of the ferrule 4. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention is an optical fiber cord or an optical fiber cable, and the ferrule is formed in a terminal of an optical transmission body in which an optical fiber and a tensile body extending along the longitudinal direction of the optical fiber are covered with an outer sheath. An optical transmission body with a connector provided with an on-site assembly-type optical connector that accommodates and assembles a fusion spliced portion of a short optical fiber (built-in optical fiber) inserted and fixed and an optical fiber of the optical transmission body, Concerning connectors.

  In the case of an optical connector, as an example of a structure that can be assembled at the tip of the optical fiber at the connection site (site where the connector is connected), the optical fiber and a short light inserted and fixed to the ferrule There is a configuration in which a fusion reinforcing portion obtained by reinforcing a fusion splicing portion with a fiber (hereinafter also referred to as a built-in optical fiber) using a heat-shrinkable tube is housed in a housing (for example, Patent Document 1). In FIG. 5 of Patent Document 1 (FIG. 5), a tension member exposed to the optical fiber cord terminal is crimped and fixed to the rear end of the housing using a caulking ring, and an optical connector is assembled to the optical fiber cord terminal. A configuration is disclosed.

JP 2002-82257 A

  The fusion reinforcing portion of the optical connector described in Patent Document 1 is a fusion connection in which the portion of the built-in optical fiber that protrudes to the rear side of the ferrule (the side opposite to the end face for abutment) and the optical fiber are fusion-connected. The part is reinforced with a heat-shrinkable tube, and is provided at a position separated from the ferrule to the rear side. Also, the inner space of the optical connector housing is a variation in the size and shape of the fusion reinforcing part due to the uneven distribution of the reinforcing resin (thermoplastic resin) that is provided inside the heat shrinkable tube and embeds the fusion splicing part. In order to accommodate the fusion reinforcing portion corresponding to the above, and to accommodate the sleeve-like housing so as to be movable in the central axis direction, it is formed to be slightly larger than the expected size of the fusion reinforcing portion. Therefore, the fusion reinforcing portion is often housed in a free (swingable) state in the housing. For this reason, there is a possibility that the built-in optical fiber may be damaged due to repeated action of pulling, bending, or the like on the built-in optical fiber due to the oscillation of the fusion reinforcing portion, resulting in a lack of long-term reliability.

  In the optical connector described in Patent Document 1, the ferrule is elastically biased between the ferrule and the stop ring toward the front side of the connector (the side opposite to the boot at the rear end of the connector through which the optical fiber is passed). The coil spring is housed in a structure, and the ferrule pushes back the coil spring when it is connected. Thus, the configuration in which the coil spring for elastic biasing of the ferrule is accommodated between the ferrule and the stop ring is not limited to the optical connector described in Patent Document 1, but for example, an SC type optical connector (established in JIS C 5972) F04 type optical connector, SC: Single fiber Coupling optical fiber connector (SC) and MU type optical connector (F14 type optical connector established by JIS C 5983, MU: Miniature-Unit coupling optical fiber connector) It is a known configuration that can be seen, and due to its structure, the ferrule can be pushed back to the compression limit of the coil spring. In addition, the amount of ferrule that can be pushed back is usually secured sufficiently larger than the amount of pushback required when the optical connector is fitted to an adapter or the like and connected to another optical connector.

  By the way, in the optical connector described in Patent Document 1, if the fusion reinforcing portion is fixed so as not to move in the housing, the above-described problem caused by the oscillation of the fusion reinforcing portion occurs. Can be prevented. However, in this case, when the ferrule is pushed back, bending deformation (deflection deformation) according to the pushback amount of the ferrule is given to the built-in optical fiber at a relatively short distance between the ferrule and the fusion reinforcing portion. It becomes like this. For this reason, when the connector is connected, if the amount of pushback of the ferrule becomes larger than necessary due to the structure of the mating connector, the loss due to bending deformation of the built-in optical fiber (bending loss) depends on the distance between the ferrule and the fusion reinforcing part. ) There arises a problem that it becomes impossible to avoid the influence of occurrence, deterioration of optical characteristics, and the like.

  The present invention has been made in view of the above circumstances, and stable optical characteristics of an optical fiber (built-in optical fiber) between a fusion reinforcing portion in a housing and a ferrule and an optical fiber in a fusion splicing portion over a long period of time. With a connector that can be maintained (improved long-term reliability) and that can suppress the bending deformation (flexion deformation) of the built-in optical fiber that accompanies the pushback of the ferrule when the connector is connected, thereby avoiding the effects of bending loss. An object is to provide an optical transmission body and an optical connector.

In order to solve the above problems, the present invention provides the following configuration.
A first invention is an optical transmission body with a connector in which an optical connector is assembled at the tip of an optical transmission body in which an optical fiber and a tensile body extending along the longitudinal direction of the optical fiber are covered with an outer sheath. The optical connector has a ferrule and a rear end portion protruding to the rear side opposite to the connection end surface of the ferrule tip of the built-in optical fiber inserted and fixed to the ferrule, to the optical transmitter terminal. A thermoplastic resin provided on the inner side of a reinforcing tube containing the fusion spliced portion, the fusion spliced portion spliced to the distal end of the optical fiber and the tensile body led out to the optical transmission terminal. A fusion reinforcing portion embedded in the reinforcing material is housed in a connector housing, and the connector housing is provided on a fuselage sleeve and on the front end side of the fuselage sleeve. A ferrule housing that houses a boot, and a boot that is attached to a rear end portion of the body sleeve and in which the optical transmission body is inserted. The fusion reinforcing portion has one end of the reinforcing tube at the end. The other end of the ferrule housing is fixed to the tubular tube fixing portion at the rear end, and the other end of the ferrule housing is fixed to the optical transmission body terminal. And a portion extending from the optical transmission terminal of the optical fiber of the optical transmission body is embedded in the reinforcing material together with the fusion splicing portion and the strength member, and is rearward of the ferrule housing. Formed to extend to
A spring that elastically biases the ferrule forward with respect to the ferrule housing is housed in the ferrule housing, and a flange portion of the ferrule abuts on the inner side of the ferrule housing so that the rear side of the connector of the ferrule A flange abutting portion for restricting the movement of the ferrule is provided, and the ferrule is elastically biased by the spring, and the flange portion is disposed at a position separated from the flange abutting portion to the front side. An optical transmission body with a connector is provided.
According to a second aspect of the present invention, the ferrule housing includes a sleeve-like plug frame and a stop ring attached to a rear end side of the plug frame, and has the tube fixing portion at the rear end of the stop ring, The optical transmission body with a connector according to the first aspect of the present invention is characterized in that the flange contact portion is provided at a front end portion attached to the plug frame of the stop ring.
According to a third aspect of the present invention, the ferrule housing is configured by fitting a front end portion of the stop ring into a rear end portion of the plug frame, and an end surface of the front end portion of the stop ring is in contact with a flange portion of the ferrule. A connector-attached optical transmission body according to a second aspect of the present invention is provided, wherein a flange contact surface is provided, and a front end portion of the stop ring functions as the flange contact portion.
A fourth invention is an optical connector that is assembled to a terminal of an optical transmission body in which an optical fiber and a tensile body extending along the longitudinal direction of the optical fiber are covered with an outer sheath, and includes a ferrule, a heat It is formed in a sleeve shape with a thermoplastic resin provided on the inner surface side of the shrinkable reinforcing tube, and protrudes to the rear side opposite to the connection end surface of the ferrule tip of the built-in optical fiber inserted and fixed to the ferrule. A fusion-portion reinforcing sleeve for housing a fusion-splicing portion fusion-bonded to a front-end portion of the optical fiber whose rear end portion is led out to the optical transmission terminal, and heating of the fusion-portion reinforcement sleeve Reinforcing material obtained by solidifying the thermoplastic resin obtained by melting the tensile strength member squeezed out to the fusion splicing portion and the optical transmission body terminal by heating, inside the contracted reinforcing tube A connector housing for storing a fusion reinforcing portion formed by being embedded in the ferrule together with the ferrule, and the connector housing is provided on a body sleeve and a front end side of the body sleeve to store the ferrule A housing and a boot that is extrapolated to the optical transmission body and attached to a rear end portion of the body sleeve;
The fusion reinforcing portion is configured such that one end of the reinforcing tube is externally fixed to the tubular tube fixing portion at the rear end portion of the ferrule housing, and the other end is externally fixed to the optical transmission body terminal, and is inserted into the tube fixing portion. The portion of the built-in optical fiber that protrudes rearward from the ferrule housing and the portion of the optical transmission body that extends from the optical transmission body terminal are joined together with the fusion splicing portion and the tensile body. It is embedded in a thermoplastic resin so as to extend from the ferrule housing to the rear side along the central axis of the body sleeve of the connector housing, and the ferrule is disposed in the ferrule housing. A spring that elastically urges the housing toward the front side is housed, and the ferrule is disposed inside the ferrule housing. A flange contact portion that restricts movement of the ferrule to the rear side of the connector by contact with the flange portion is provided, and the ferrule is elastically biased by the spring so that the flange portion is separated from the flange contact portion. Provided is an optical connector which is disposed at a position separated from the front side.
According to a fifth aspect of the present invention, the ferrule housing includes a sleeve-like plug frame and a stop ring attached to the rear end side of the plug frame, and has the tube fixing portion at the rear end of the stop ring, The optical connector according to a fourth aspect of the present invention is characterized in that the flange contact portion is provided at a front end portion attached to the plug frame of the stop ring.
According to a sixth aspect of the present invention, the ferrule housing is configured such that a front end portion of the stop ring is fitted into a rear end portion of the plug frame, and an end surface of the front end portion of the stop ring is in contact with a flange portion of the ferrule. An optical connector according to a fifth aspect of the present invention is provided, wherein the front end portion of the stop ring functions as the flange contact portion.
A seventh invention is characterized in that the fused portion reinforcing sleeve has a double tube structure in which an inner tube made of the thermoplastic resin is housed inside the reinforcing tube. The optical connector of any one of -6 is provided.

According to the present invention, one end of the reinforcing tube constituting the fusion reinforcing portion housed in the connector housing of the optical connector assembled on the optical transmission terminal is formed in a cylindrical shape at the rear end portion of the ferrule housing that houses the ferrule. The other end of the tube fixing part is extrapolated and fixed to the optical transmission terminal. Since the fusion reinforcing part is integrated with the ferrule housing, there is no problem that the built-in optical fiber is damaged by the oscillation of the fusion reinforcing part in the housing as in the prior art (for example, Patent Document 1). The optical characteristics of the fiber can be maintained stably over a long period of time. As a result, long-term reliability can be improved.
In the present invention, the rear end portion of the built-in optical fiber inserted and fixed to the ferrule may be fusion-bonded to the front end portion of the optical fiber led to the optical transmitter terminal to form the fusion-bonded portion. Therefore, the fusion splicing work can be easily performed at a place separated from the ferrule, and it is easy to ensure the workability of the fusion splicing.

  In addition, in the present invention, a flange abutting portion for restricting movement of the ferrule to the rear side of the connector is provided by abutting the flange portion of the ferrule on the inner side of the ferrule housing. The position in contact with the flange contact portion is the limit position for the rearward movement of the connector. The optical connector assembled in the optical transmission terminal is reduced in distance from the mechanical reference plane to the optical reference plane as the ferrule pushes back when the connector is connected to another optical connector. Ensures that the distance from the mechanical reference surface to the optical reference surface is smaller than the preset minimum value by the structure where the position where the contact with the flange contact portion becomes the limit position of movement to the rear side of the connector. Can be prevented. For this reason, the ferrule housing of the part extended from the rear end of the ferrule of the built-in optical fiber (rear extension part) in association with the rearward movement limit position of the ferrule with respect to the connector housing of the ferrule (pushing) The ferrule of the rear extension part of the pushback built-in optical fiber of the ferrule is set so that the bending deformation (deflection deformation) in the inside can be suppressed to a range that does not affect the optical characteristics of the built-in optical fiber. It is possible to reliably prevent the occurrence of inconveniences such as bending loss in the housing becoming large (the bending radius becomes small), bending loss, and the built-in optical fiber being broken. It goes without saying that this also contributes to the long-term stable maintenance of the optical characteristics of the built-in optical fiber and the improvement of the long-term reliability of the optical connector.

1 is a perspective view showing an appearance of an optical fiber cord with a connector (an optical transmission body with a connector) according to an embodiment of the present invention. (A), (b) is sectional drawing which shows the optical fiber cord with a connector of FIG. It is a disassembled perspective view explaining the structure of the optical fiber cord with a connector of FIG. It is a perspective view which shows the structure of the optical fiber cord used for the optical fiber cord with a connector of FIG. 1, and shows the state which led out the optical fiber and the tension body (strength fiber) to the terminal. It is a general view which shows an example of the structure of the fused part reinforcement sleeve. It is a figure explaining the structure of the sleeve for a fusion | melting part reinforcement of FIG. 5, Comprising: It is a cross-sectional perspective view of the longitudinal direction center part. It is process drawing explaining the assembly method which assembles the optical connector which concerns on this invention in an optical fiber cord terminal, The state which fused and connected the optical fiber of the optical fiber cord to the rear end part of the optical fiber (built-in optical fiber) by the side of a ferrule Indicates. It is process drawing which shows the assembly process (fusing reinforcement part formation process) following a previous figure, (a) is fused in the position which accommodates the fusion splicing part of the optical fibers formed by the fusion splicing of the previous figure. FIG. 8B shows a state in which the fusion reinforcing portion is formed by lowering the temperature after heating the fusion portion reinforcing sleeve of FIG. 8A. It is a figure explaining the fusion reinforcement part formation process using the fusion part reinforcement sleeve of another aspect, Comprising: (a) arrange | positions the said fusion part reinforcement sleeve in the position which accommodates the fusion | fusion connection part of optical fibers. FIG. 9B shows a state where the fusion reinforcing portion is formed by lowering the temperature after heating the fusion portion reinforcing sleeve of FIG. 9A. (A)-(c) is a figure explaining another aspect of the fused part reinforcement sleeve used for the assembly of the optical fiber cord with a connector of FIG. 1, Comprising: Section which shows the cross-section of the longitudinal direction center part It is a perspective view. It is a general view which shows the structure of the sleeve for melt | fusion part reinforcement shown to Fig.10 (a). It is a perspective view which shows an example of the optical fiber cable used as an optical transmission body.

Hereinafter, an embodiment of the present invention will be described with reference to the drawings.
First, an optical fiber cord with a connector (an optical transmission body with a connector) according to an embodiment of the present invention will be described with reference to FIGS. 1 to 8A, 8B and the like.
As shown in FIGS. 1 and 2 (a) and 2 (b), this optical fiber cord with a connector is obtained by assembling the optical connector 1 at the end of an optical fiber cord 21 (optical transmission body).
In the following description, the left side in FIGS. 2A and 2B will be described as the front, and the right side will be described as the rear.

As shown in FIG. 4, the optical fiber cord 21 includes an optical fiber 22 such as an optical fiber core, and a tensile body 23 (tensile fiber) that extends along the longitudinal direction of the optical fiber 22. It is the thing of the structure accommodated in the sheath 24 (exterior coating | cover) which consists of.
As the tensile body 23, an aramid fiber is preferably used, but a glass fiber, a carbon fiber, or the like can also be used.

As shown in FIGS. 1, 2A and 2B, the optical connector 1 terminates an optical fiber 22 so that the connector can be connected.
As shown in FIGS. 2A and 2B, the optical connector 1 includes a ferrule 4, a coil spring 5 (spring) for elastically urging the ferrule 4 forward, and an interpolation fixing to the ferrule 4. An optical fiber in which an end portion (rear end portion 12b) of the short optical fiber 12 (hereinafter also referred to as a built-in optical fiber) extended to the rear side of the ferrule 4 is led out to the end of the optical fiber cord 21 Fusion fusion reinforcement in which a fusion splicing portion 15 fusion-bonded to 22 is embedded in a reinforcing material 11, which is a thermoplastic resin, filled inside a resin-made reinforcing tube 10 extrapolated to the fusion splicing portion 15. The part 20 has a schematic configuration in which it is housed in a connector housing 25 assembled with a coupling 2 (knob).

The illustrated optical connector 1 is a single-core optical connector assembled at the tip of a single-core optical fiber cord 21.
The optical fiber 22 of the optical fiber cord 21 is a single-core optical fiber such as a single-core optical fiber or an optical fiber.

  The ferrule 4 is extrapolated and fixed to a rear end portion 13b opposite to the front end (front end) side on which the cylindrical capillary portion 13 (ferrule main body) and the connecting end surface 13a for abutting the capillary portion 13 are provided. And a flange portion 14 which is a metal ring-shaped member. As the material of the capillary section 13, for example, ceramic such as zirconia, glass or the like can be adopted.

  As the ferrule 4, for example, an SC type optical connector (F04 type optical connector established in JIS C 5973. SC: Single fiber Coupling optical fiber connector), an MU type optical connector (F14 type optical connector established in JIS C 5983). The same ferrule used for a single-fiber optical connector such as MU (Miniature-Unit coupling optical fiber connector) can be used.

  As shown in FIGS. 2A and 2B, the built-in optical fiber 12 is a single-core optical fiber such as a single-core optical fiber or an optical fiber, and one end side (tip side) in the longitudinal direction thereof. Is inserted into an optical fiber introduction hole 13c (fine hole) that is a through hole inside the capillary part 13 of the ferrule 4 and is formed coaxially with the central axis of the capillary part 13, and is inserted into the capillary part 13 by an adhesive 26. Bonded and fixed.

  The built-in optical fiber 12 is a single-core coated optical fiber in which a bare optical fiber 121 is coated with a coating material 122 made of resin. Both ends in the longitudinal direction of the built-in optical fiber 12 are not provided with the covering material 122, and the bare optical fiber 121 is in a state of being led out.

  The optical fiber introduction hole 13c of the capillary section 13 is a fine hole having an inner diameter that is substantially the same as the outer diameter of the bare optical fiber 121 of the built-in optical fiber 12, and the rear end side of the capillary section 13 from the connection end face 13a of the capillary section 13. A fiber hole portion 13c1 extending toward the back, a tapered hole portion 13c2 formed in a tapered shape whose inner diameter increases from the rear end of the fiber hole portion 13c1 toward the rear end side of the capillary portion 13, and the taper hole portion. An extended hole portion 13c3 having the same diameter as the rear end of the tapered hole portion 13c2 and extending coaxially with the fiber hole 13c1 from the rear end of 13c2 so as to reach the rear end of the capillary portion 13 is formed.

The built-in optical fiber 12 has one end of the coated fiber portion 123 covered with the covering material 122 inserted into the expansion hole portion 13c3 of the optical fiber introduction hole 13c of the capillary portion 13, and is inserted into the expansion hole portion 13c3. The distal end portion 12a (the distal end portion of the built-in optical fiber 12) that is the distal end portion of the bare optical fiber 121 led out to the end portion of the coated fiber portion 123 is inserted into the fiber hole portion 13c1 of the optical fiber introduction hole 13c. It is fixed and attached to the ferrule 4 (specifically, the capillary section 13).
Further, the portion of the built-in optical fiber 12 inserted into the tapered hole portion 13c2 and the expanded hole portion 13c3 on the rear side from the fiber hole portion 13c1 of the optical fiber introduction hole 13c is filled in the tapered hole portion 13c2 and the expanded hole portion 13c3. The adhesive 26 is embedded and fixed so as to be embedded in the adhesive 26.

Although not shown, the adhesive 26 is also provided in the fiber hole 13c1, and the insertion and fixing of the tip 12a inserted into the fiber hole 13c1 of the built-in optical fiber 12 is performed through this adhesive. Realized by fixing.
However, the fixing of the built-in optical fiber 12 in the ferrule 4 is not limited as long as it is reliably performed on at least the coated fiber portion 123 of the portion inserted into the optical fiber introduction hole 13c of the built-in optical fiber 12. The tip 12a of the built-in optical fiber 12 in 13c1 may be fixed by press-fitting the tip 12a into the fiber hole 13c1 without using the adhesive 26.

  2A and 2B, the coated fiber portion 123 of the built-in optical fiber 12 is inserted only into the expansion hole portion 13c3 of the optical fiber introduction hole 13c, and the tapered hole portion 13c2 of the optical fiber introduction hole 13c. In the above, a configuration in which only the bare optical fiber 121 constituting the tip portion 12a of the built-in optical fiber 12 is inserted is illustrated, but the present invention is not limited to this. For example, the coated fiber portion 123 of the built-in optical fiber 12 A configuration in which the end portion of the covering material 122 is disposed in the tapered hole portion 13c2 or a configuration in which the end portion of the covering material 122 abuts against the inner surface of the tapered hole portion 13c2 can also be employed.

The built-in optical fiber 12 is inserted and fixed to the ferrule 4 so that the end surface of the tip end portion 12 a is aligned with the polished connection end surface 13 a of the ferrule 4 (connection end surface 13 a of the capillary portion 13).
The end surface of the front end portion 12a of the built-in optical fiber 12 may be a surface perpendicular to the optical axis at the end surface. For example, the connection end surface after the internal optical fiber 12 is fixed to the ferrule 4 (specifically, the capillary portion 13). A polishing surface that is continuous with the connection end surface 13a may be formed by polishing the surface 13a.

  The built-in optical fiber 12 has a length longer than that of the optical fiber introduction hole 13c of the ferrule 4, and a portion of the ferrule 4 that is not inserted and fixed in the optical fiber introduction hole 13c is the ferrule 4 (in detail). It extends to the rear side from the capillary part 13). The built-in optical fiber 12 is a portion (hereinafter also referred to as a rear extension) that extends rearward from the rear end of the ferrule 4 (the rear end of the capillary portion 13c in the case of the ferrule 4 in the illustrated example). The rear end portion 12b (in other words, the rear end portion of the bare optical fiber 121) formed by the bare optical fiber 121 led to the end portion is led to the tip of the optical fiber 22 extended from the end of the optical fiber cord 21. The bare optical fiber 22b is fusion spliced to the tip 22a.

Of the rear extension portion of the built-in optical fiber 12, a portion extending rearward from the ferrule housing 3 is embedded and fixed in the reinforcing material 11 of the fusion reinforcing portion 20.
The coated fiber portion 123 of the built-in optical fiber 12 extends from the ferrule housing 3 to the rear side. Of the rear-side extension portion of the built-in optical fiber 12, the portion located within the ferrule housing 3 has a full length as a coated fiber portion 123.

  The built-in optical fiber 12 is not limited to a configuration in which the bare optical fiber 121 is provided at both ends of the coated optical fiber as described above. For example, a configuration in which the entire length is a bare optical fiber can be adopted. It is.

Next, the connector housing 25 will be described.
As shown in FIGS. 2A, 2B, and 3, the connector housing 25 is assembled to a sleeve-like ferrule housing 3 that houses the ferrule 4 and the coil spring 5, and the rear end side of the ferrule housing 3. A protective cylinder 18 (hereinafter also referred to as a body sleeve) provided so as to extend rearward from the ferrule housing 3, and a boot 19 that is externally fitted to the rear end of the body sleeve 18. It comprises.
The ferrule housing 3 includes a sleeve-like (square tube in the illustrated example) plug frame 6 and a sleeve-like (cylindrical in the illustrated example) stop ring 7 fitted and attached to the rear end portion of the plug frame 6. As a result, it is formed into a sleeve shape as a whole. The stop ring 7 is attached to the plug frame 6 with its front end fitted inside the rear end of the plug frame 6.

As shown in FIGS. 2A and 2B, the optical connector 1 includes a ferrule housing unit 27 in which a ferrule 4 and a coil spring 5 are housed in a ferrule housing 3.
The stop ring 7 includes a sleeve-like (specifically, cylindrical) main body 8 and a tube fixing portion that is formed in a cylindrical shape (cylindrical) having a smaller diameter than the main body 8 and extends rearward from the main body 8. 9. One end (front end) in the longitudinal direction of the reinforcing tube 10 of the fusion reinforcing portion 20 is fixed to the tube fixing portion 9 by extrapolation.

As shown in FIGS. 2A and 2B, the ferrule 4 has a central axis extending along the central axis of the ferrule housing 3 so that the ferrule 4 extends in the front-rear direction (the central axis of the ferrule housing 3 extends). It is stored so as to be movable in the present direction). The flange portion 14 of the ferrule 4 includes a stopper projection 6a projecting inside the longitudinal center (in the direction of the central axis) of the plug frame 6 and a front end of a stop ring 7 fitted in the rear end portion of the plug frame 6. It arrange | positions between these parts (front-end part of the main-body part 8).
A clearance is provided between the stopper projection 6a and the front end of the stop ring 7 so that the flange portion 14 of the ferrule 4 can move in the front-rear direction. Is the movable amount of the ferrule 4 in the front-rear direction in the ferrule housing 3.

In the ferrule 4, the flange portion 14 abuts against the stopper protrusion 6 a (see FIG. 2A), and further movement to the front side is restricted, and the flange portion 14 is the end surface 7 c of the front end portion 7 b of the stop ring 7. Further movement to the rear side is restricted by abutting (see FIG. 2B). The end surface 7c of the front end 7b of the stop ring 7 functions as a flange contact surface according to the present invention.
The front end portion 7b of the stop ring 7 functions as a flange abutting portion that restricts further movement of the ferrule 4 to the rear side by abutment of the flange portion 14 from the front side.

The coil spring 5 is interposed between the flange portion 14 of the ferrule 4 and a locking step portion 8a formed inside the stop ring 7 so that the center axis thereof is in the connector front-rear direction.
A spring accommodating hole for accommodating a rear end portion of the coil spring 5 provided coaxially with the sleeve-like ferrule housing 3 at a front end portion of a through hole (stop ring through hole) penetrating the inside of the stop ring 7 7a is formed as an expansion hole having a larger inner diameter than the portion on the rear side from the spring accommodating hole 7a of the stop ring through hole. Specifically, the locking step portion 8a inside the stop ring 7 is formed by an inner diameter difference between the spring housing hole portion 7a and a portion on the rear side from the spring housing hole portion 7a of the stop ring through hole. It is a stepped surface. In the illustrated stop ring 7, the locking step 8 a (step surface) is formed on the inner surface of the main body 8 of the stop ring 7.

As shown in FIG. 2A, the ferrule 4 is elastically urged toward the front side of the connector by the coil spring 5, and when no pushing force is applied to the rear side of the connector, the flange portion 14 is connected to the plug frame 6 as shown in FIG. A position where the stopper protrusion 6a abuts from the rear side thereof (that is, a movement limit position on the front side), that is, the flange portion 14 is disposed at a position separated from the end surface 7c of the front end portion 7b of the stop ring 7 to the front side of the connector.
As shown in FIGS. 2A and 2B, when the optical connector 1 is inserted and fitted into the optical connector adapter 50 to be connected to the other optical connector 1a, the other optical connector is used. The ferrule 4 abutted against the ferrule 1b of 1a is pushed back against the connector housing 25 (pushback) while the coil spring 5 is compressed against the elastic biasing force of the coil spring 5, whereby the coil The urging force between the other optical connector 1 a and the ferrule 4 can be applied by the elastic biasing force of the spring 5.

  2B shows a state in which the flange portion 14 of the ferrule 4 is in contact with the front end portion 7b of the stop ring 7 (specifically, the end surface 7c of the front end portion 7b) from the front side, that is, the ferrule 4 is on the rear side. Although the movement limit position is shown, there is no need for the ferrule 4 to reach the rear movement limit position when the connector is connected, and the ferrule 4 is positioned between the front movement limit position and the rear movement limit position. You may do it.

However, when the ferrule 4 is pushed back when the optical connector 1 is connected to another optical connector 1a, the position where the flange portion 14 of the ferrule 4 abuts on the front end portion 7b of the stop ring 7 This is the movement limit position.
As shown in FIGS. 2 (a) and 2 (b), the optical connector 1 has a mechanical reference surface S1 (virtual surface) to an optical reference surface S2 (ferrule 4) as the ferrule 4 is pushed back when the connector is connected. Although the distance to the front end (virtual plane perpendicular to the optical axis of the built-in optical fiber 12) at the tip is reduced, the position where the flange portion 14 of the ferrule 4 abuts against the front end portion 7b of the stop ring 7 is the limit of movement toward the rear side of the connector. The minimum value of the distance from the mechanical reference surface S1 to the optical reference surface S2 can be set according to the position structure. Thereby, it is possible to reliably prevent the distance from the mechanical reference surface S1 to the optical reference surface S2 from becoming smaller than a preset minimum value.
Note that the mechanical reference surface S1 and the optical reference surface S2 are also shown in FIG.

The rear movement limit position of the ferrule 4 is a portion of the built-in optical fiber 12 extending from the rear end of the ferrule 4 (rear extension portion) due to the rearward displacement (pushing) of the ferrule 4 with respect to the connector housing 25. The bending deformation (deflection deformation) in the ferrule housing 3 is set so as to be suppressed within a range that does not affect the optical characteristics of the built-in optical fiber 12.
Thereby, the bending deformation in the ferrule housing 3 of the rear side extension part of the built-in optical fiber 12 accompanying the rearward displacement (pushing) of the ferrule 4 with respect to the connector housing 25 increases (the bending radius decreases). ) Inconveniences such as bending loss and breakage of the built-in optical fiber 12 can be prevented.

If it is the structure which sets the movement limit position to the connector rear side of the ferrule 4 by the front-end part 7b of the stop ring 7, the freedom degree of design of the spring accommodation hole part 7a of the stop ring 7 and the freedom degree of selection of the coil spring 5 are raised. There is an advantage that can be.
If the ferrule 4 is configured to be able to be pushed back to the compression limit of the coil spring 5, the deformation of the rear extension portion of the built-in optical fiber 12 due to the pushback of the ferrule 4 within the ferrule housing 3 is deformed. In order to suppress this, a measure such as increasing the axial dimension of the stop ring 7 (for example, increasing the axial dimension of the tube fixing portion 9) can be considered. However, as described above, the ferrule is formed by the front end portion 7b of the stop ring 7. 4 is configured to set the movement limit position to the rear side of the connector, it is easy to keep the axial dimension of the stop ring 7 small compared to the case where measures such as increasing the axial dimension of the stop ring 7 are taken. realizable. In this respect, the configuration in which the movement limit position of the ferrule 4 to the rear side of the connector is set by the front end portion 7b of the stop ring 7 includes the axial dimension of the ferrule housing 3 (dimension in the connector longitudinal direction) and the longitudinal direction of the optical connector 1 as a whole. It also contributes effectively to reducing the size (length).

  Further, as shown in FIGS. 2A and 2B, the ferrule 4 has a key groove 14a formed on the outer peripheral portion of the flange portion 14, and a key 6b protruding from the inner side of the plug frame 6 is inserted. The ferrule housing 3 can be moved back and forth while maintaining a state in which the rotation around the axis with respect to the housing 3 is restricted. By the longitudinal movement of the ferrule 4 relative to the ferrule housing 3, the flange portion 14 is slidable relative to the key 6b inserted in the key groove 14a.

As shown in FIGS. 1 to 3, the optical connector 1 in the illustrated example employs a plug frame and a coupling used in the SC type optical connector as the plug frame 6 and the coupling 2.
The coupling 2 is a rectangular tube-shaped member, and a ferrule housing 3 assembled by fitting a cylindrical stop ring 7 into a rear end portion of the rectangular tube-shaped plug frame 6; A connector, such as an optical connector adapter or an optical connector receptacle, is inserted in a housing body including a body sleeve 18 fitted and attached from the side so as to be slidable with a slight movable range in the front-rear direction. For the positioning housing, in cooperation with the plug frame 6, a slide lock mechanism similar to that provided in a normal SC type optical connector is configured.

Note that the plug frame and coupling are not limited to those used in the SC type optical connector, but may be those used in the MU type optical connector, for example.
The coupling forms a slide lock mechanism for the connector positioning housing in cooperation with the plug frame, that is, the engagement state of the elastic claw in the connector positioning housing with respect to the plug frame by the sliding movement of the plug frame in the front-rear direction. The specific configuration is appropriately changed according to the configurations of the connector positioning housing and the plug frame.

As shown in FIGS. 2 (a), 2 (b), and 3, it is preferable to form an uneven portion 16 on the outer peripheral surface of the tube fixing portion 9 of the ferrule housing 3. The shape of the concavo-convex portion 16 is not particularly limited, but it is preferable to have a shape extending in the circumferential direction of the tube fixing portion 9 or a form in which a plurality of continuous portions are provided in the circumferential direction. In the illustrated example, a plurality of annular convex portions 9 a extending in the circumferential direction of the tube fixing portion 9 are formed at intervals in the front-rear direction. By forming the concavo-convex portion 16 and the annular convex portion 9a, the fixing force between the reinforcing tube 10 and the tube fixing portion 9 can be increased, and the pulling out with respect to the force in the pulling direction (the right side in FIGS. 2A and 2B). Yield can be improved. Further, when the reinforcing tube 10 attached to the tube fixing portion 9 by heat shrinkage has a shape along the irregular shape of the outer peripheral surface of the tube fixing portion 9, the pulling strength (pulling strength) is further increased.
In the illustrated example, the annular convex portion 9a has a rectangular cross section, but the sectional shape of the annular convex portion is not limited thereto, and may be a semicircular shape, an inverted V shape, or the like. The number of annular protrusions may be one or plural.

As shown in FIGS. 2A, 2 </ b> B, and 3, the body sleeve 18 is a cylindrical member that can be extrapolated to the fusion reinforcing portion 20. The body sleeve 18 is formed with a locking hole 18a at the front end portion thereof, into which a locking projection 8b formed on the outer peripheral surface of the main body 8 of the stop ring 7 is fitted. The locking projection 8b is inserted and fitted into the ferrule housing 3 so as to be fitted on the outside.
In the illustrated optical connector 1, the locking holes 18 a of the body sleeve 18 are respectively formed on a pair of locking pieces 18 c that are protrusions protruding forward from the mouth edge portions on both sides through the front end opening of the body sleeve 18. The engaging protrusions 8b are formed on both sides of the outer peripheral surface of the stop ring 7 and protruded in correspondence with the two engaging holes 18a of the body sleeve 18.
The numbers of the locking holes 18a of the body sleeve 18 and the locking projections 8b of the stop ring 7 are not limited to two, and may be three or more.
Further, the locking hole 18a of the body sleeve 18 is not limited to the structure formed in the locking piece 18c of the body sleeve 18, but may be a window hole shape that penetrates the thickness of the front end portion of the sleeve-like portion of the body sleeve 18. May be.

The boot 19 has a tapered cylindrical portion 192 formed in a tapered shape extending from the rear end of the cylindrical mounting cylindrical portion 191 attached to the rear end portion of the body sleeve 18 to the rear end thereof. It is a member of the made structure. The entire boot 19 is integrally formed of a material having high elasticity such as rubber, and the tapered cylindrical portion 192 has flexibility that can be easily bent and deformed.
As shown in FIGS. 2 (a) and 2 (b), in this boot 19, the mounting cylinder portion 191 is fitted with a locking projection 19a projecting on the inside thereof in a locking recess 18b on the outer surface of the body sleeve 18. The taper tube portion 192 is attached to the rear end portion of the body sleeve 18 in a state in which movement in the connector front-rear direction is restricted, and extends from the body sleeve 18 to the rear side.

  In addition, the movable range of the coupling 2 in the front-rear direction is set at a position separated from the mounting cylinder portion 191 of the boot 19 that is externally fitted to the rear end portion of the body sleeve 18 to the front side of the connector. Even if it moves to the rear limit of the connector to the limit of movement, it does not come into contact with the boot 19.

As shown in FIGS. 2A and 2B, the optical fiber cord 21 is inserted in a tapered cylindrical portion through hole 19 b that penetrates the inside of the tapered cylindrical portion 192 of the boot 19.
The tapered tube portion through-hole 19b is formed to have a smaller diameter than the fusion reinforcement portion accommodation hole portion 19b1 on the front end side thereof, and the fusion reinforcement portion accommodation hole portion 19b1, and the rear side of the fusion reinforcement portion accommodation hole portion 19b1. It consists of a transmission body accommodation hole 19b2 penetrating from the end to the rear end of the tapered cylindrical portion 192. The optical fiber cord 21 is not fixed to the boot 19, but is passed through the transmission body housing hole 19 b 2, and its end is pulled into the connector housing 25. The side of the optical fiber cord 21 opposite to the end extends from the rear end of the boot 19 to the rear side.

  The fusion reinforcing portion accommodating hole 19b1 inside the tapered cylindrical portion 192 of the boot 19 is provided in communication with the rear end of the body sleeve inner hole 18d so that the body sleeve inner hole 18d extends to the rear side. .

This optical connector 1 has a fusion reinforcing portion accommodating portion 28 (inner space) formed of a fuselage sleeve inner hole 18d and the fusion reinforcing portion accommodating hole portion 19b1 communicating with the rear side inside the connector housing 25, The fusion reinforcing portion 20 is accommodated in the fusion reinforcing portion accommodating portion 28.
The fusion reinforcing portion accommodating hole 19b1 is formed with a cross-sectional dimension that is sufficiently larger than the cross sectional outline of the fusion reinforcing portion 20 in order to accommodate the fusion reinforcing portion 20.

As shown in FIGS. 2A and 2B, the reinforcing tube 10 of the fusion reinforcing portion 20 is formed in an elongated shape whose dimension in the central axis direction is much larger than the outer diameter of the reinforcing tube 20. It is provided in the fusion reinforcing portion accommodating portion 28 so as to extend along the longitudinal direction of the connector.
One end (front end) of the reinforcing tube 10 is extrapolated and fixed to the tube fixing portion 9 at the rear end of the ferrule housing 3, and the other end (rear end) is extrapolated to the optical fiber cord 21 end (sheath 24 end). Is fixed.

  The fusion reinforcing portion 20 is a portion that extends rearward from the tube fixing portion 9 of the ferrule housing 3 of the built-in optical fiber 12 in the reinforcing material 11 that is a thermoplastic resin filled inside the reinforcing tube 10. The portion of the optical fiber cord 21 that extends from the end of the optical fiber cord 21 is embedded together with the fusion splicing portion 15 between the optical fibers 12 and 22 and the tensile member 23 that extends from the end of the optical fiber cord 21. Thus, it extends from the ferrule housing 3 to the rear side along the central axis of the body sleeve 18 of the connector housing 25.

  In the operation of assembling the optical connector 1 to the end of the optical fiber cord 21, the fusion reinforcing portion 20 extends from the rear end of the ferrule housing 3 of the ferrule housing unit 27, that is, from the rear end of the tube fixing portion 9, as shown in FIG. After the fusion connection between the rear end portion 12b of the built-in optical fiber 12 and the front end portion 22a of the optical fiber 22 led to the end of the optical fiber cord 21, the fusion portion reinforcement as shown in FIGS. 5 and 6, for example, is performed. The reinforcing sleeve 30 (hereinafter also simply referred to as a reinforcing sleeve), that is, the reinforcing sleeve 30 having a structure in which the thermoplastic resin 34 (reinforcing material 11) is provided inside the heat-shrinkable reinforcing tube 10 is formed by the fusion splicing. Extrapolate and cover the formed fusion splicing part 15 (see FIG. 8A), heat the reinforcing sleeve 30, and heat-shrink the reinforcing tube 10. After melting the plastic resin 34, the heating is stopped and the temperature is lowered to room temperature (for example, air cooling) to solidify the molten thermoplastic resin 34, so that the reinforcing tube 11 is filled in the reinforcing material 11 inside the reinforcing tube 10. The fusion splicing portion 15 and the strength member 23 of the optical fiber cord 21 are embedded (see FIG. 8B).

As shown in FIGS. 5 and 6, as described above, the reinforcing sleeve 30 according to the present invention has a thermoplastic resin 34 (reinforcing material 11) on substantially the entire inner surface side of the heat-shrinkable reinforcing tube 10. Is provided. The reinforcing sleeve 30 illustrated in FIGS. 5 and 6 has a double tube structure in which an inner tube 31 that is separate from the reinforcing tube 10 is used as the thermoplastic resin 34 on the inner surface side of the reinforcing tube 10. . However, the thermoplastic resin 34 is not limited to this. For example, a thermoplastic resin layer (reinforcing material layer) formed in an attached state on the inner surface of the reinforcing tube 10 by applying a thermoplastic resin in a heated and melted state. Also good.
The reinforcing tube 10 and the inner tube 31 of the reinforcing sleeve 30 having a double-pipe structure illustrated in FIGS. 5 and 6 are formed in a cylindrical shape.

Further, as shown in FIGS. 5 and 8A, the thermoplastic resin 34 on the inner surface side of the reinforcing tube 10 of the reinforcing sleeve 30 is the inner surface of the section located between the reinforcing tube 10 except for both longitudinal ends. It is provided so as to cover the whole.
In the reinforcing sleeve 30 illustrated in FIG. 5 and FIG. 8A, the extending range (the extending length of the thermoplastic resin) of the thermoplastic resin 34 in the longitudinal direction (central axis direction) of the thermoplastic resin 34 is a built-in optical fiber. 12 substantially coincides with the distance between the rear end of the ferrule housing 3 and the end of the optical fiber cord 21 (the front end surface of the sheath 24) when the fusion splicing of the rear end portion 12b of the optical fiber cord 21 to the optical fiber 22 of the optical fiber cord 21 is completed. Has been.

  Further, as shown in FIGS. 5 and 6, the reinforcing tube 10 of the reinforcing sleeve 30 has a rod-shaped reinforcing core member 33 (metal rod) inserted into the forming resin in the direction of the central axis of the reinforcing tube 10. It is provided so as to extend over substantially the entire length.

As described above, the reinforcing sleeve 30 is used to form the fusion reinforcing portion 20, and fuses the rear end portion 12 b of the built-in optical fiber 12 and the front end portion 22 a of the optical fiber 22 of the optical fiber cord 21. It heats in the state extrapolated to the fusion splicing part 15 formed by a splicing connection.
As the reinforcing sleeve 21, one made of a heat-shrinkable resin is used. For example, a polyolefin resin that shrinks at 100 to 160 ° C. can be used.

As the thermoplastic resin 34, a hot melt resin (hot melt adhesive) can be suitably used. Examples of the hot melt resin include ethylene-vinyl acetate copolymer (EVA), polyethylene, polyisobutylene, polyamide, and ethylene-acrylic acid ester copolymer.
In addition, the thermoplastic resin is preferably softened at the contraction temperature of the reinforcing tube 10. This softening temperature is, for example, 100 to 160 ° C.

  In order to assemble the optical connector 1 into the end of the optical fiber cord 21 (an optical connector assembling method), first, as shown in FIG. 7, the optical connector 1 is inserted and fixed to the ferrule 4 of the ferrule storage unit 27 that has been assembled in advance. The rear end portion 12b, which is the end portion of the built-in optical fiber 12 that extends from the tube fixing portion 9 of the ferrule housing 3, is fusion spliced to the front end portion 22a of the optical fiber 22 led out to the end of the optical fiber cord 21. Then, a fusion process for forming the fusion splicing portion 15 is performed.

  The fusion splicing of the rear end portion 12b of the built-in optical fiber 12 and the optical fiber 22 of the optical fiber cord 21 uses an existing fusion splicer that uses arc discharge between discharge electrode rods provided apart from each other. Can be done. The rear end portion 12 b of the built-in optical fiber 12 is an end portion of the built-in optical fiber 12 that extends from the tube fixing portion 9 of the ferrule housing 3, so that the fusion splice is sufficient from the ferrule 4 to the rear side. This can be done at a distance. For this reason, there is no worry that the ferrule 4 is damaged by the discharge energy, and there is no need to use a special fusion splicer or to set special conditions, and the connection work can be performed using a general-purpose fusion splicer. The fusion work can be performed efficiently.

  Next, the reinforcing sleeve 30 (see FIG. 3) that has been extrapolated to the optical fiber cord 21 is moved to the ferrule housing 3 side, and as shown in FIG. The receiving connection portion 15 and the strength member 23 that has been exposed to the end of the optical fiber cord 21 are accommodated, and one end (front end portion) of the reinforcing sleeve 30 is extrapolated to the tube fixing portion 9 of the ferrule housing 3. The other end (rear end portion) is in a state of being extrapolated to the end of the optical fiber cord 21, and in this state, the reinforcing sleeve 30 is heated and then cooled to form the fusion reinforcing portion 20 for forming the fusion reinforcing portion 20. Perform the process.

  As described above, the extending range (the extending length of the thermoplastic resin) of the thermoplastic resin 34 in the longitudinal direction (center axis direction) of the reinforcing tube 10 is the rear end portion 12b of the built-in optical fiber 12 and the optical fiber cord 21. The distance between the rear end of the ferrule housing 3 and the end of the optical fiber cord 21 (the front end surface of the sheath 24) when the fusion splicing with the optical fiber 22 is completed. As shown in FIG. 8A, the reinforcing sleeve 30 has a built-in optical fiber in which a thermoplastic resin 34 provided inside the reinforcing tube 10 is located between the rear end of the ferrule housing 3 and the end of the optical fiber cord 21. 12, the optical fiber 22, the fusion splicing portion 15, and the strength member 23 are arranged to cover.

In the tube fixing portion 9 of the ferrule housing 3, a portion where the thermoplastic resin 34 is not provided at both ends in the longitudinal direction of the reinforcing sleeve 30, that is, in the longitudinal direction of the reinforcing tube 10, the tube is fixed to both sides from the thermoplastic resin 34. One end (front end portion) of the overhanging portion that is the opposite end portions is extrapolated.
In FIG. 8A, the protruding portion of the reinforcing tube 10 is extrapolated to the tube fixing portion 9 and the end of the optical fiber cord 21 of the ferrule housing 3, and the thermoplastic resin 34 (inner tube 31) is connected to the tube fixing portion 9 and the optical fiber cord 21. A configuration is illustrated in which the tube fixing portion 9 and the optical fiber cord 21 terminal are arranged so as not to overlap with the fiber cord 21 terminal, but with respect to the tube fixing portion 9 and / or the optical fiber cord 21 terminal. Thus, the portion of the reinforcing sleeve 30 where the thermoplastic resin 34 is provided may be extrapolated.

  In this step, the reinforcing sleeve 30 is heated, whereby the reinforcing tube 10 is thermally contracted and the thermoplastic resin 34 is melted. The heat-melted thermoplastic resin 34 is spread over the entire inside of the reinforcing tube 10 and filled so as to embed the entire inside of the reinforcing tube 10. When the thermoplastic resin is solidified by the temperature drop after the heating, as shown in FIG. 8B, the fusion splicing portion 15 inside the reinforcing tube 10, the strength member 23, and the built-in optical fiber 12 from the ferrule housing 3 to the rear side. The protruding portion, the portion of the optical fiber 22 of the optical fiber 21 that extends from the end of the optical fiber cord 21 is embedded and fixed in the reinforcing material 11 formed by solidifying the thermoplastic resin.

Further, in this step, the reinforcing tube 10 is fixed (fixed) to the tube fixing portion 9 and the end of the optical fiber cord 21 in which both ends of the reinforcing sleeve 30 are extrapolated by heating and lowering the temperature of the reinforcing sleeve 30. .
As shown in FIG. 8B, in the illustrated example, the fixing (fixing) of the reinforcing tube 10 to the end of the optical fiber cord 21 is interposed between the outer peripheral surface of the sheath 24 of the optical fiber cord 21 and the reinforcing tube 10. This is realized by adhesive fixing with a thermoplastic resin. Between the outer peripheral surface of the sheath 24 of the optical fiber cord 21 and the reinforcing tube 10, the molten thermoplastic resin is extruded from between the tube fixing portion 9 and the end of the optical fiber cord 21 with the thermal contraction of the reinforcing tube 10. As a result, thermoplastic resin can be introduced.

  In the illustrated example, an optical fiber cord 21 having an outer diameter of the sheath 24 smaller than the outer diameter of the tube fixing portion 9 is employed, and between the outer peripheral surface of the sheath 24 of the optical fiber cord 21 and the reinforcing tube 10. It is easy for the thermoplastic resin in the heated and melted state to enter. The outer diameter of the reinforcing tube 10 of the reinforcing sleeve 30 is constant over the entire length in the longitudinal direction.

On the other hand, the reinforcing tube 10 is fixed (fixed) to the tube fixing portion 9 by pressure-bonding fixing by heat shrinkage of the reinforcing tube 10, but may further be bonded and fixed by a thermoplastic resin.
Bonding and fixing with the thermoplastic resin is realized by the molten thermoplastic resin entering the recesses between the annular convex portions 9a on the outer periphery of the tube fixing portion 9. The recess between the annular convex portions 9a is formed by extruding the molten thermoplastic resin from between the tube fixing portion 9 and the end of the optical fiber cord 21 in accordance with the thermal contraction of the reinforcing tube 10, so that the molten thermoplastic resin is melted. Inflow may occur. When the thermoplastic resin does not flow in, the reinforcing tube 10 is fixed (fixed) to the tube fixing portion 9 only by crimping and fixing by heat shrinkage of the reinforcing tube 10.
The reinforcing tube 10 can obtain a sufficient fixing force with respect to the tube fixing portion 9 only by crimping and fixing due to thermal contraction of the reinforcing tube 10, but is additionally bonded with a thermoplastic resin that has entered the recess between the annular convex portions 9 a. As a result, a higher fixing force can be obtained.

Moreover, in this invention, the structure which implement | achieved fixation with respect to the tube fixing | fixed part 9 of the reinforcement tube 10 only by the adhesive force of a thermoplastic resin can also be employ | adopted.
The reinforcement tube 10 can be fixed to the tube fixing portion 9 by a pressure-bonding force and / or an adhesive force of a thermoplastic resin due to thermal contraction of the reinforcement tube 10.
Further, the reinforcement tube 10 can be fixed (fixed) to the end of the optical fiber cord 21 by a pressure-bonding force due to thermal contraction of the reinforcement tube 10 and / or an adhesive force of a thermoplastic resin.

  Although illustration is omitted, the reinforcing tube 10 may be thinner at a portion located between the tube fixing portion 9 and the end of the optical fiber cord 21 than a portion fixed to the tube fixing portion 9 due to heat shrinkage. Accordingly, when the reinforcing tube 10 is thermally contracted, the molten thermoplastic resin is spread over the entire inside of the portion located between the tube fixing portion 9 and the end of the optical fiber cord 21 of the reinforcing tube 10 to obtain a filled state. This can be easily realized, and a state in which the entire inside of the reinforcing tube 10 after heat shrinkage is filled with the thermoplastic resin without a gap can be easily obtained. It goes without saying that it is easy to insert a molten thermoplastic resin between the outer peripheral surface of the sheath 24 of the optical fiber cord 21 and the reinforcing tube 10.

Further, as shown in FIGS. 8A and 8B, in this step, the reinforcing sleeve 30 causes the one end portion (front end portion) of the reinforcing core member 33 of the reinforcing tube 10 to be along the tube fixing portion 9. The tube fixing portion 9 and the optical fiber are arranged such that the other end portion (rear end portion) of the reinforcing core member 33 is arranged along the front end portion (terminal) of the optical fiber cord 21. Extrapolated to the tip of the cord 21 and heated and cooled in this state. When both ends of the reinforcing tube 10 are fixed to the tube fixing portion 9 and the optical fiber cord 21 end, both ends of the reinforcing core member 33 are fixed to the tube fixing portion 9 and the optical fiber cord 21 end. .
The reinforcing tube 10 is fixed to the optical fiber cord 21 in order to secure the fixing force of the reinforcing tube 10 to the optical fiber cord 21 and to fix the widest possible portion of the portion of the reinforcing tube 10 that is extrapolated to the tip of the optical fiber cord 21. It is preferable to do.

As shown in FIGS. 10A, 10B, and 10C, the reinforcing sleeve 30 includes the reinforcing tube 10, a boundary between the reinforcing tube 10 and the thermoplastic resin 34 (reinforcing material 11), and the thermoplastic resin. Also, a configuration in which linear tensile members 32 extending in the central axis direction (longitudinal direction) of the reinforcing tube 10 are distributed over one or more selected from 34 can be adopted. It is.
Note that the reinforcing sleeve 30 illustrated in FIGS. 5 and 6 specifically illustrates a configuration in which the tensile member 32 is not provided.

The tensile member 32 is a linear member having excellent tensile strength and elasticity such as aramid fiber and FRP.
The tensile member 32 is embedded in the forming resin of the reinforcing tube 10 or the reinforcing material 11 in the fusion reinforcing portion 20, is fixed to and integrated with the forming resin, and a tensile force acting on the fusion reinforcing portion 20. The function of suppressing the elongation of the fusion-bonding reinforcing portion 20 is achieved. Further, the tensile strength member 32 is formed by bending deformation of the fusion reinforcing portion 20 when a bending force is applied to the boot 19 or the connector housing 25 of the optical connector 1 by, for example, a side pull of a portion extending from the boot 19 of the optical fiber cord 21. It also functions to suppress

In the reinforcing tube 30 having a double tube structure including the reinforcing tube 10 and the inner tube 31 inside thereof, the tensile strength member 32 is embedded and fixed in the forming resin of the reinforcing tube 10, and the forming resin of the inner tube 31. It is provided by adopting one or more selected from embedding and fixing inside, and interposition between the reinforcing tube 10 and the inner tube 31.
Further, in the reinforcing sleeve 30 having a configuration in which the thermoplastic resin layer (reinforcing material layer) is formed on the inner surface of the reinforcing tube 10 and the reinforcing tube 10 and the thermoplastic resin layer are integrated, the tensile member 32 is selected from embedded fixing of the reinforcing tube 10 in the forming resin, embedded fixing of the thermoplastic resin layer in the forming resin, and interposition (embedding) between the reinforcing tube 10 and the thermoplastic resin layer. It is provided by adopting one or more.
In any configuration, the tensile members 32 are provided in a distributed manner over the entire circumference of the reinforcing sleeve 30 in the circumferential direction.

  A reinforcing sleeve 30A shown in FIG. 10A has a double tube structure in which an inner tube 31 made of a thermoplastic resin separate from the reinforcing tube 10 is housed inside the reinforcing tube 10, and the reinforcing tube 10, a material in which a linear tensile strength member 32 is embedded in the formed resin so as to extend (longitudinal) over substantially the entire length in the longitudinal direction of the reinforcing tube 10 (reinforcing tube 10A) is employed. The inner tube 31 (indicated by reference numeral 31A in the figure) in which the tensile strength member 32 is not embedded is housed inside.

Further, as a reinforcing sleeve 30 having a double-pipe structure in which an inner tube 31 made of a thermoplastic resin separate from the reinforcing tube 10 is housed inside the reinforcing tube 10, FIGS. An example configuration (reinforcing sleeves 30B and 30C) can also be employed.
The reinforcing sleeve 30B illustrated in FIG. 10B uses the reinforcing sleeve 10 (indicated by reference numeral 10B in the figure) and the inner tube 31A in which the tensile member 32 is not embedded, and the reinforcing sleeve 10B, the inner tube 31A, and the like. The tensile strength member 32 extends between the reinforcing sleeve 10B and the inner tube 31A along the central axis direction of the reinforcing sleeve 10B and the inner tube 31A (longitudinal direction of the reinforcing sleeve 30). It is the structure which interposes.

  The reinforcing sleeve 30C illustrated in FIG. 10C is an inner tube 31 having a structure in which the tensile member 32 is embedded inside the reinforcing sleeve 10B in which the tensile member 32 is not embedded (reference numeral 31B is added in the drawing). It has a configuration that accommodates. The tensile strength member 32 of the inner tube 31B is vertically attached so as to extend along the central axis direction of the inner tube 31B (longitudinal direction of the reinforcing sleeve 30).

  As shown in FIG. 11, the strength member 32 of the reinforcing sleeve 30 is vertically attached over substantially the entire length in the longitudinal direction of the reinforcing sleeve 30 (in other words, approximately the entire length in the longitudinal direction of the reinforcing tube 10). . This is not limited to the double tube structure reinforcing sleeve in which the inner tube 31 made of a thermoplastic resin separate from the reinforcing tube 10 is housed inside the reinforcing tube 10, and is attached to the inner surface of the reinforcing tube 10. This is also a common configuration for a reinforcing sleeve having a thermoplastic resin layer (reinforcing material layer) in a state.

FIG. 11 specifically shows the overall configuration of the reinforcing sleeve 30A illustrated in FIG.
In the reinforcing sleeve 30A, the tensile member 32 embedded in the reinforcing tube 10A is vertically attached over the entire length in the longitudinal direction.
With respect to the reinforcing sleeves 30 </ b> B and 30 </ b> C, the tensile member 32 is vertically attached so as to extend from both ends of the inner tube 31 and to be provided in a range substantially matching the entire length of the reinforcing tube 10.

  Tensile members 32 are provided on the boundary between the reinforcing tube 10 and the thermoplastic resin or on the thermoplastic resin inside the reinforcing tube 10 like the reinforcing sleeves 30B and 30C illustrated in FIGS. In the reinforcing sleeve having the above-described configuration, portions extending from both ends of the thermoplastic resin provided annularly inside the reinforcing tube 10 of the tensile member 32 are stored without being fixed inside the reinforcing tube 10. However, it may be fixed to the inner surface of the reinforcing tube 10 using, for example, an adhesive.

In the fusion reinforcing portion forming step, the fusion reinforcing portion 20 is formed by using the reinforcing sleeve 30 having a structure in which the tensile members 32 are provided in a substantially evenly distributed manner in the circumferential direction. As the adhesion reinforcing portion 20, a structure in which tensile strength members 32 extending over substantially the entire length in the longitudinal direction thereof are distributed substantially evenly in the circumferential direction of the fusion reinforcing portion 20 is obtained.
Moreover, the fusion-strengthening part 20 can ensure high tensile strength by the structure by which the tensile strength member 32 is vertically attached to the substantially full length of the longitudinal direction.

  For example, when the reinforcing sleeve 30A having the configuration shown in FIG. 10A is used, when the fixing of the reinforcing tube 10 to the tube fixing portion 9 and the end of the optical fiber cord 21 is completed by heating and cooling of the reinforcing sleeve 30A, The tensile member 32 embedded in the reinforcing tube 10A and provided in the vertically attached state is also fixed to the tube fixing portion 9 and the end of the optical fiber cord 21.

  For example, like the reinforcing sleeves 30B and 30C configured as shown in FIGS. 10B and 10C, the inner tube 31 is housed inside the reinforcing tube 10, and the boundary between the reinforcing tube 10 and the inner tube 31 is When a reinforcing sleeve having a configuration in which the tensile member 32 is vertically attached to any one or more of the inner tubes 31 is used, the tube fixing portion 9 and the reinforcing tube 10 extrapolated to the tube fixing portion 9 And between the distal end portion (terminal) of the optical fiber cord 21 and the reinforcing tube 10 extrapolated to the distal end portion of the optical fiber cord 21, portions extending from the inner tube 31 of the tensile member 32 to both sides are provided. In this state, the reinforcing sleeve 30 is heated and cooled. Thus, when the fixing of the reinforcing tube 10 to the tube fixing portion 9 and the optical fiber cord 21 end is completed, the tensile member 32 is also fixed to the tube fixing portion 9 and the optical fiber cord 21 end.

  The reinforcing sleeve is a reinforcing sleeve having a structure in which a thermoplastic resin layer is provided on the inner surface side of the reinforcing tube 10, and the tensile strength member 32 is a boundary between the reinforcing tube 10 and the thermoplastic resin layer, and / or a thermoplastic resin. Also in the case of using a reinforcing sleeve structured vertically by embedding in a layer, between the tube fixing portion 9 and the reinforcing tube 10 extrapolated to the tube fixing portion 9 and the distal end portion (terminal) of the optical fiber cord 21 ) And the reinforcing tube 10 extrapolated at the tip of the optical fiber cord 21, the portions extending from the thermoplastic resin layer of the tensile member 32 on both sides are interposed, and in this state, the reinforcing sleeve is heated. Cool down.

  When the fusion reinforcing portion 20 is formed by this fusion reinforcing portion forming step, the ferrule housing 3 and the optical fiber cord 21 are connected by the fusion reinforcing portion 20.

When the fusion reinforcing portion forming step is completed, a housing assembly step for assembling the entire connector housing 25 and storing the fusion reinforcing portion 20 is performed.
As shown in FIG. 2 (a), in the optical connector 1 shown in the drawing, the body sleeve 18 that has been extrapolated in advance to the optical fiber cord 21 is moved to the ferrule housing 3 side, and the front end thereof is moved to the ferrule housing. 3 is assembled, and a connector housing 25 comprising a ferrule housing 3, a body sleeve 18, and a boot 19 attached to the rear end portion of the body sleeve 18 is attached to the inner side (fused). The fusion reinforcing part 20 can be stored in the reinforcing part storage part 28).

As shown in FIGS. 1 and 2A, the optical connector 1 is provided with a coupling 2. In this housing assembly process, the coupling 2 is extrapolated to the plug frame 6 of the ferrule housing 3. Includes assembly process.
The assembly of the optical connector 1 is completed by assembling the entire connector housing 25 and assembling the coupling 2 to the plug frame 6.

  The fuselage sleeve 18 is attached to the ferrule housing 3 by pressing the fuselage sleeve 18 against the ferrule housing 3 from the rear side thereof, and the main body of the stop ring 7 is inserted into the locking hole 18a formed at the front end of the fuselage sleeve 18. This is realized by external fitting to the ferrule housing 3 by projecting on the outer peripheral surface of 8 and engaging the engaging projections 8b provided on both sides of the stop ring 7 so as to be fitted.

  The boot 19 is extrapolated to the optical fiber cord 21 together with the trunk sleeve 18 in a state where the boot 19 is attached to the rear end portion of the trunk sleeve 18 until the fusion reinforcing portion forming process is completed. Thereby, the connector housing 25 can be assembled only by attaching the trunk | drum sleeve 18 to the ferrule housing 3 after completion of a fusion-bonding reinforcement part formation process. The boot 19 is extrapolated to the optical fiber cord 21 without being attached to the fuselage sleeve 18 until the fusion reinforcing portion forming step is completed, and the fuselage sleeve 18 is attached to the ferrule housing 3 and then attached to the fuselage sleeve 18. You may wear it.

In the fusion reinforcing portion forming step, for example, as shown in FIG. 9A, a thermoplastic resin 34 is provided as a reinforcing sleeve so as to cover the entire inner surface excluding one end portion in the longitudinal direction of the reinforcing tube 10 ′. The reinforcing sleeve 30 ′ having the above-described configuration is adopted, and the end portion on the side where the thermoplastic resin (indicated by reference numeral 34 in the figure) is provided on the inner surface of both ends in the longitudinal direction of the reinforcing sleeve 30 ′ ( The resin inner end 35) is extrapolated to the tube fixing portion 9 of the ferrule housing 3, and the opposite end is extrapolated to the optical fiber cord 21, and the reinforcing sleeve 30 'is heated to the contraction temperature of the reinforcing tube 10 Further, the fusion reinforcing portion 20 ′ (see FIG. 9B) may be formed by the subsequent temperature drop.
Heating of the reinforcing sleeve 30 ′ is performed inside the reinforcing sleeve 30 ′ by incorporating the built-in optical fiber 12 and the optical fiber 22 located between the rear end of the ferrule housing 3 (the rear end of the tube fixing portion 9) and the end of the optical fiber cord 21. The fusion splicing portion 15 and the tensile strength member 23 are accommodated.

  Specifically, the reinforcing sleeve 30 illustrated in FIG. 8A employs a reinforcing tube 10 having an inner diameter that is attached to the tube fixing portion 9 by being externally fitted. The reinforcing tube 10 ′ of the reinforcing sleeve 30 ′ in FIG. 9A has a slightly larger inner diameter of the reinforcing tube 10 of the reinforcing sleeve 30 illustrated in FIG. It is possible to interpose a thermoplastic resin 34 in the resin. A material that can be used for the reinforcing tube 10 of the reinforcing sleeve 30 can be adopted as the material of the reinforcing tube 10 ′.

  In FIG. 9A, specifically, the end of one end in the longitudinal direction of the reinforcing tube 10 ′ is removed from the inside of the reinforcing tube 10A ′ in which the inner diameter of the reinforcing tube 10A of the reinforcing sleeve 30A illustrated in FIG. A reinforcing sleeve 30A ′ having a configuration in which an inner tube 31A ′ (thermoplastic resin 34) is provided so as to cover the entire inner surface is illustrated. The reinforcing sleeve 30A ′ has a configuration in which the tensile member 32 is provided only in the reinforcing tube 10A ′. However, the reinforcing sleeve 30 ′ is not limited to this, and the reinforcing tube, the thermoplastic resin inside thereof, and the reinforcing tube It is possible to adopt a configuration in which linear tensile members extending along the central axis of the reinforcing tube are dispersedly arranged over the entire circumference in one or more selected from the boundary between and the thermoplastic resin.

  However, the reinforcing tube 10 of the reinforcing sleeve 30 in FIG. 11 is not necessarily limited to an inner diameter that is fitted on the tube fixing portion 9 and is attached to the tube fixing portion 9 in an loosely inserted state. May be used as it is as the reinforcing tube 10 'of the reinforcing sleeve 30'.

  When the fusion reinforcing portion 20 ′ is formed by using the reinforcing sleeve 30 ′, after the heating and cooling of the reinforcing sleeve 30 ′, the outer periphery of the tube fixing portion 9 (for example, the recess between the annular protrusions 9a). The thermoplastic resin 34 surely enters, and the end of the reinforcing tube 10 ′ is firmly fixed to the tube fixing portion 9 by the crimping force due to the thermal contraction of the reinforcing tube 10 and the adhesive force of the thermoplastic resin 34. Can do.

  Further, in the fusion reinforcing portion forming step, a configuration in which a thermoplastic resin is provided so as to cover the entire inner surface of the reinforcing tube 10 can be adopted as the reinforcing sleeve.

As shown in FIGS. 2 (a) and 2 (b), according to the optical connector 1, the fused optical fiber 12 on the ferrule 4 side and the optical fiber 22 led out to the end of the optical fiber cord 21 are fused. In addition to the incoming connection portion 15, a portion of the built-in optical fiber 12 that extends rearward from the tube fixing portion 9 of the ferrule housing 3, the optical fiber cord 21 of the optical fiber 22 of the optical fiber cord 21 extends from the terminal. This portion (hereinafter also referred to as an extending portion) can be covered and protected by the reinforcing tube 10 of the fusion reinforcing portion 20 and the reinforcing material 11 inside thereof.
In addition, since the fusion reinforcing portion 20 is formed by extrapolating and fixing the front end portion of the reinforcing tube 10 to the tube fixing portion 9, the fusion reinforcing portion 20 is unlikely to swing within the connector housing 25. For this reason, the inconvenience of damaging the built-in optical fiber by repeated swinging of the fusion reinforcing portion as described in Patent Document 1, for example, can be prevented.

  In the optical connector described in Patent Document 1, the portion of the optical fiber led out to the optical fiber cord terminal located between the optical fiber cord terminal and the fusion reinforcing portion is also repeatedly formed in the housing. Although the optical connector 1 according to the present invention may be affected by deterioration of characteristics due to swinging, the rear end portion of the reinforcing tube 10 is fixed by extrapolation to the end of the optical fiber cord 21. With the configuration in which the entire length of the extending portion of the optical fiber 22 is embedded in the reinforcing material 11 inside the fusion reinforcing portion 20, the extending portion of the optical fiber 22 of the optical fiber cord 21 is also fused as in Patent Document 1. The influence of repeated swinging of the reinforcing portion can be avoided.

In addition, the optical connector 1 has the rear end portion of the reinforcing tube 10 fixed to the end of the optical fiber cord 21, and the tensile body 23 led out to the end of the optical fiber cord 21 is attached to the inner side of the fusion reinforcing portion 20. Since the structure is fixed in the reinforcing member 11 in an embedded state, it is possible to secure a high pulling-out resistance against the fusion reinforcing portion 20 in the optical fiber cord 21.
Therefore, in the optical connector 1 according to the present invention, the optical fiber cord 21 is connected to the connector simply by forming the fusion reinforcing portion 20 and connecting the ferrule housing 3 and the optical fiber cord 21 via the fusion reinforcing portion 20. The housing 25 can be secured with a sufficient securing force (fixing force). Therefore, in this optical connector 1, the optical fiber cord 21 has an optical fiber cord 21 as compared with the configuration in which the tensile body exposed to the end of the optical fiber cord is crimped and fixed to the rear end of the housing using a caulking ring as in Patent Document 1 described above. Retention can be performed very easily. As a result, the entire optical connector 1 can be efficiently assembled in a short time, and the number of parts can be reduced and the cost can be reduced.

  In the optical connector 1, as described above, the fusion reinforcing portion 20 is fixed to the ferrule housing 3, so that the tensile force acting on the optical fiber cord 21 is applied to the fusion reinforcing portion of the built-in optical fiber 12. It does not act on the part located on the front side from 20.

In addition, this invention is not limited to the above-mentioned embodiment, In the range which does not deviate from the main point, it can change suitably.
As a flange contact portion provided in the ferrule housing 3, a front end portion 7 b of the stop ring 7 attached by being fitted to the rear end portion of the plug frame 6, that is, a ring-shaped end surface 7 c of the front end of the stop ring 7 is formed. For example, the protrusion may be a protrusion protruding from the front end of the stop ring 7 or a member fixed inside the front end of the stop ring 7. Further, separately from the stop ring 7, it may be configured by a member such as a ring that is fitted in the rear end portion of the plug frame 6 and attached to the front side of the stop ring 7.

  The optical transmission body is not limited to the optical fiber cord 21 as long as the optical fiber and the tensile body extending along the longitudinal direction of the optical fiber are covered with an outer sheath. For example, as shown in FIG. 12, an optical fiber 61 which is a single-core coated optical fiber such as a single-core optical fiber or an optical fiber, and an optical fiber 61 disposed on both sides of the optical fiber 61. It is also possible to employ an optical fiber cable 60 or the like having a configuration in which a tensile body 62 vertically attached along the surface is embedded in a covering material 63 (exterior covering). The optical fiber cable 60 can be used as an optical drop cable, an optical indoor cable, or the like. As the tensile body 62, for example, a tensile member (tensile fiber) excellent in tensile strength and elasticity such as aramid fiber and FRP is employed.

By assembling the optical connector 1 to the end of the optical fiber cable 60, an optical fiber cable with a connector (optical transmission body with a connector) can be obtained.
Assembling the optical connector 1 to the end of the optical fiber cable 60 (an optical connector assembling method) uses the optical fiber cable 60 instead of the optical fiber cord 21, and a fusion part forming step as shown in FIG. In place of storing the strength member 23 exposed at the end of the optical fiber cord 21 inside the reinforcing sleeve 30 disposed at the position where the fusion splicing portion 15 is stored, the optical fiber is stored inside the reinforcing sleeve 30. This can be realized in the same manner except that the pair of strength members 62 exposed at the end of the cable 60 is housed.

A connector housing of an optical connector according to the present invention includes a fuselage sleeve, a ferrule housing provided on the front end side of the fuselage sleeve and housing a ferrule, and a rear end portion of the fuselage sleeve that is inserted into the optical transmission body. It is only necessary to have a boot that can accommodate the fusion reinforcing portion inside, and is not limited to that described in the above embodiment.
For example, a configuration in which the body sleeve is assembled to the ferrule housing so as to be movable while securing a movable range in the front-rear direction of the connector, that is, a configuration in which the body sleeve also serves as a coupling is included.
In addition, as the optical connector according to the present invention, a configuration without a coupling can be employed. In this case, as the plug frame of the ferrule housing, for example, a plug frame of an SC type optical connector, a housing of an LC type optical connector (LC: trademark of Lucent Technology), or the like can be employed.

  DESCRIPTION OF SYMBOLS 1 ... Optical connector, 3 ... Ferrule housing, 4 ... Ferrule, 5 ... Spring (coil spring), 6 ... Plug frame, 7 ... Stop ring, 9 ... Tube fixing part 10, 10A, 10B, 10 ', 10A' ... Reinforcing tube, 11 ... Reinforcing material, 12 ... Built-in optical fiber, 12b ... Rear end of (built-in optical fiber), 13b ... Connection end surface, 18 ... Body sleeve, 18d ... Inner hole in (body sleeve), 19 ... Boot, 192 ... Tapered cylinder part, 19b1 ... Fusing reinforcement part accommodating hole part, 20, 20 '... Fusion reinforcing part, 21 ... Optical transmission body (optical fiber cord), 22 ... Optical fiber, 22a ... (Optical fiber) tip , 23... Strength member (strength fiber), 24. Outer sheath (sheath), 25. Connector housing, 28. Fusing reinforcement storing part (inner space), 30, 30A, 30B. 0C, 30 ', 30A' ... Fusing portion reinforcing sleeve, 31, 31A, 31B ... thermoplastic resin, reinforcing material, inner tube, 34 ... thermoplastic resin, 60 ... optical transmission body (optical fiber cable), 61 ... Optical fiber, 62 ... tensile body, 63 ... exterior coating (coating material).

Claims (7)

An optical transmission body (21, 60) in which an optical fiber (22, 61) and a tensile body (23, 62) extending along the longitudinal direction of the optical fiber are covered with an outer sheath (24, 63). An optical transmission body with a connector in which an optical connector (1) is assembled at the tip,
The optical connector includes a ferrule (4) and a rear end portion (12b) protruding to the rear side opposite to the connection end surface (13a) of the ferrule tip of the built-in optical fiber (12) inserted and fixed to the ferrule. ) And a fusion splicing portion (15) fused and connected to the tip end portion (22a) of the optical fiber led to the optical transmission terminal and the tensile member drawn to the optical transmission terminal. A fusion reinforcing portion (20, 20 ') embedded in a reinforcing material (11), which is a thermoplastic resin, provided inside a reinforcing tube (10, 10A, 10B, 10', 10A ') containing the portion; In the connector housing (25),
The connector housing includes a fuselage sleeve (18), a ferrule housing (3) that is provided on the front end side of the fuselage sleeve and houses the ferrule, and is attached to a rear end portion of the fuselage sleeve. Boots (19) made up,
One end of the reinforcing tube is externally fixed to the tubular tube fixing portion (9) at the rear end portion of the ferrule housing, and the other end is externally fixed to the optical transmission body terminal. The portion of the built-in optical fiber that is inserted into the tube is protruded rearward from the tube fixing portion, and the portion of the optical fiber of the optical transmission body that is extended from the optical transmission body terminal is the fusion splicing portion and the Embedded in the reinforcing material together with the tensile body, and formed to extend from the ferrule housing to the rear side,
A spring that elastically biases the ferrule forward with respect to the ferrule housing is housed in the ferrule housing, and a flange portion of the ferrule abuts on the inner side of the ferrule housing so that the rear side of the connector of the ferrule A flange abutting portion (7a) for restricting movement of the ferrule is provided, and the ferrule is elastically biased by the spring, and the flange portion is disposed at a position separated from the flange abutting portion to the front side. An optical transmission body with a connector as a feature.   The ferrule housing comprises a sleeve-like plug frame (6) and a stop ring (7) attached to the rear end side of the plug frame, and the tube fixing portion (9) is provided at the rear end of the stop ring. The optical transmission body with a connector according to claim 1, wherein the flange abutting portion is provided at a front end portion (7b) attached to the plug frame of the stop ring.   The ferrule housing is configured such that a front end portion of the stop ring is fitted into a rear end portion of the plug frame, and a flange surface of the front end portion of the stop ring (7c) is in contact with the flange portion of the ferrule. The optical transmission body with a connector according to claim 2, wherein the optical transmission body is a contact surface, and a front end portion of the stop ring functions as the flange contact portion. An optical transmission body (21, 60) in which an optical fiber (22, 61) and a tensile body (23, 62) extending along the longitudinal direction of the optical fiber are covered with an outer sheath (24, 63). An optical connector assembled to a terminal,
The ferrule (4) is formed into a sleeve shape in which a thermoplastic resin (11, 34) is provided on the inner surface side of the heat-shrinkable reinforcing tube (10, 10A, 10B, 10 ′, 10A ′). The optical fiber (12b) projecting to the rear side opposite to the connection end face (13a) of the ferrule tip of the internal optical fiber (12), which is inserted and fixed, 22) a fusion-portion reinforcing sleeve (30, 30A, 30B, 30C, 30 ′, 30A ′) for housing the fusion-splice portion (15) that is fusion-spliced to the tip end portion (22a), The thermoplastic resin obtained by melting the tensile strength member squeezed into the fusion spliced portion and the optical transmission body terminal is solidified inside the reinforcing tube contracted by heating the sleeve for reinforcing the fitting portion. Complement A connector housing (25) for housing a fusion reinforcing portion (20, 20 ′) formed by being embedded in a strong material (11) together with the ferrule;
The connector housing includes a fuselage sleeve (18), a ferrule housing (3) provided on the front end side of the fuselage sleeve and housing the ferrule, and an extrapolation to the optical transmission body at a rear end portion of the fuselage sleeve. A boot (19) to be mounted;
The fusion reinforcing portion is configured such that one end of the reinforcing tube is externally fixed to the tubular tube fixing portion (9) at the rear end portion of the ferrule housing, and the other end is externally fixed to the optical transmission body terminal. A portion projecting rearward from the ferrule housing of the built-in optical fiber inserted into the optical fiber, and a portion extending from the optical transmission body end of the optical fiber of the optical transmission body, the fusion splicing portion and the tensile strength Embedded in the thermoplastic resin together with the body, extending from the ferrule housing to the rear side along the central axis of the body sleeve of the connector housing,
A spring (7) for elastically urging the ferrule forward with respect to the ferrule housing is housed in the ferrule housing, and a flange portion (14) of the ferrule is brought into contact with the inner side of the ferrule housing. A flange contact portion (7b) for restricting the movement of the ferrule to the rear side of the connector is provided, and the ferrule is elastically biased by the spring so that the flange portion is separated from the flange contact portion to the front side. An optical connector characterized by being arranged.   The ferrule housing comprises a sleeve-like plug frame (6) and a stop ring (7) attached to the rear end side of the plug frame, and the tube fixing portion (9) is provided at the rear end of the stop ring. 5. The optical connector according to claim 4, wherein the flange abutting portion is provided at a front end portion (7b) attached to the plug frame of the stop ring.   The ferrule housing is configured such that a front end portion of the stop ring is fitted into a rear end portion of the plug frame, and a flange surface of the front end portion of the stop ring (7c) is in contact with the flange portion of the ferrule. The optical connector according to claim 5, wherein the optical connector is a contact surface, and a front end portion of the stop ring functions as the flange contact portion.   7. The fused tube reinforcing sleeve has a double tube structure in which an inner tube made of the thermoplastic resin is housed inside the reinforcing tube. The optical connector as described in.

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