JP5325244B2 - Boots, optical connectors and jigs - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To shorten an entire length of an optical connector. <P>SOLUTION: A boot is provided to protect an optical fiber extending from the rear side of an optical connector and includes a fixing part for fixing the boot to a boot attachment member in an optical connector body and a pair of flexible parts disposed to sandwich the optical fiber therebetween and deformed in accordance with curvature of the optical fiber, and one end on the front side of each flexible part is a fixed end fixed to the fixing part, and the other end on the rear side is a free end, and the flexible parts are disposed so that the fixing ends are forwarder than the rearmost part of the fixing part. <P>COPYRIGHT: (C)2012,JPO&amp;INPIT

Description

  The present invention relates to a boot, an optical connector, and a jig.

  Conventionally, a boot, which is a flexible cylindrical member, is attached to the rear end side of the optical connector (the side opposite to the front end portion where the joining end face is disposed). For example, a cylindrical boot made of synthetic rubber is attached to the rear end side of an MPO type optical connector (F13 type optical connector established in JIS C 5982; MPO: Multi-fiber Push On) (non-patent document). 1).

  By attaching a boot to the rear end of the optical connector, the bending of the optical fiber (including the optical fiber contained in the optical fiber ribbon, the optical fiber cord, the optical fiber tube, etc.) becomes gentle and the light is transmitted. Loss is reduced or the optical fiber itself is protected.

Japan Standards Association, “F13 type multi-fiber optical fiber connector C 5982: 1997”, JIS Handbook Electronic Test Methods / Optoelectronics Edition, Publisher: Japan Standards Association, April 24, 1998.

  Conventionally, the boot has a structure that extends from the optical connector main body (the part obtained by removing the boot from the optical connector) to the rear side. The conventional boot structure has caused the total length of the optical connector to increase.

  An object of this invention is to provide the boot which can shorten the full length of an optical connector. Moreover, it aims at providing the jig | tool suitable for the optical connector using such a boot, and the optical connector using such a boot.

  A main invention for achieving the above object is a boot for protecting an optical fiber extending from the rear side of an optical connector, the fixing portion for fixing to a boot mounting member in an optical connector body, A pair of flexible portions arranged so as to sandwich the optical fiber and deforming according to the curvature of the optical fiber, and one end on the front side of the flexible portion becomes a fixed end supported by the fixed portion The other end on the rear side is a free end, and the fixed end is arranged so as to be on the front side with respect to the rearmost part of the fixed portion.

  Other characteristics of the present invention will be made clear by the description and drawings described later.

  According to the present invention, the total length of the optical connector can be shortened.

FIG. 1 is a perspective view of the optical connector 10 of the first embodiment. FIG. 2 is an exploded view of the optical connector 10 of the first embodiment. FIG. 3A is a perspective view of the boot 60 according to the first embodiment as viewed obliquely from the front. FIG. 3B is a perspective view of the boot 60 as viewed obliquely from behind. FIG. 4 is an explanatory view of a state when the boot 60 is attached to the spring push 40. FIG. 5 is an explanatory diagram of the deformation of the flexible portion 65. FIG. 6A is a perspective view of the jig 80 used for the optical connector 10 of the first embodiment when viewed obliquely from the front. FIG. 6B is a perspective view of the jig 80 viewed obliquely from behind. FIG. 7A and FIG. 7B are explanatory views of a state during the connection work of the optical connector 10 using the jig 80. FIG. 8 is an explanatory diagram illustrating a state in which the optical connector 210 according to the second embodiment is connected to the receiving optical connector 310. FIG. 9 is an explanatory diagram of a state in which the optical connector 210 according to the second embodiment is connected to the receiving optical connector 310. FIG. 10 is a perspective view of the optical connector 210 according to the second embodiment viewed obliquely from behind. FIG. 11 is an exploded view of the optical connector of the second embodiment. FIG. 12A is a cross-sectional view of the optical connector 210. FIG. 12B is an enlarged view of the vicinity of the contact portion 246b. FIGS. 13A to 13C are explanatory diagrams of the internal state of the optical connector 210 at the time of connection. FIG. 14A is a perspective view of the boot 260 according to the second embodiment as viewed obliquely from the front. FIG. 14B is a perspective view of the boot 260 as viewed obliquely. FIG. 15 is an explanatory diagram of a state when the boot 260 is attached to the engaging member 240. FIG. 16 is an explanatory diagram of a boot according to a first modification. FIG. 17 is an explanatory diagram of a boot according to a second modification. FIG. 18 is an explanatory diagram of the flexible portion of the third modification. FIG. 19 is an explanatory diagram of an optical connector of a comparative example.

  At least the following matters will be apparent from the description and drawings described below.

A boot for protecting an optical fiber extending from the rear side of the optical connector, the fixing portion for fixing the optical fiber to a boot mounting member in the optical connector main body, and the optical fiber. A pair of flexible portions that deform according to the curvature of the fiber, one end on the front side of the flexible portion is a fixed end supported by the fixed portion, and the other end on the rear side is a free end. The boot is characterized in that the fixed end is arranged so as to be in front of the rearmost part of the fixed part.
According to such a boot, the total length of the optical connector attached to the tip of an optical fiber (including an optical fiber contained in an optical fiber ribbon, an optical fiber cord, an optical fiber tube, etc.) can be shortened.

  It is desirable that the other end be disposed so as to be at the same position in the front-rear direction as the last part of the optical connector body or at a position ahead of the last part. Further, it is desirable that a concave space is formed in the fixed portion, and a length in the front-rear direction of the concave space is equal to or longer than a length in the front-rear direction of the flexible portion. Thereby, all the parts of a flexible part can be arrange | positioned inside an optical connector main body.

  It is desirable that the inner surface of the flexible portion is inclined so that the interval between the inner surfaces of the flexible portion increases toward the rear side. Thereby, the contact angle of an optical fiber and a flexible part can be made small, and it becomes easy to suppress the excessive curve of an optical fiber.

  It is desirable that the thickness of the flexible part decreases toward the rear side of the flexible part. Thereby, the contact part of an optical fiber and a flexible part can be increased, and it becomes easy to suppress the excessive curve of an optical fiber.

  The optical fiber is included in an optical fiber ribbon, and a pair of the flexible portions are arranged so as to sandwich the optical fiber from the normal direction of the optical fiber array surface of the optical fiber ribbon. It is desirable. Thereby, a flexible part can be arrange | positioned in the direction in which an optical fiber is easy to bend.

  An optical connector comprising an optical connector main body and a boot, wherein the boot protects an optical fiber extending from a rear side, the boot being a fixing portion for fixing to a boot mounting member in the optical connector main body; A pair of flexible portions arranged so as to sandwich the optical fiber and deforming according to the curvature of the optical fiber, and one end on the front side of the flexible portion is a fixed end supported by the fixed portion The optical connector is characterized in that the other end on the rear side is a free end, and the fixed end is disposed inside the optical connector main body. Thereby, an optical connector with a short overall length can be provided.

  A pair of positioning projections for insertion into a gap provided outside the flexible portion on the front end surface that contacts the optical connector, and has a C-shape having an opening for passing the optical fiber The jig characterized in that is formed is clarified. Thereby, the jig | tool suitable for the connection of the above-mentioned optical connector can be provided.

=== Comparative Example ===
FIG. 19 is an explanatory diagram of an optical connector of a comparative example. A boot for gradual bending of the optical fiber is provided at the rear end of the optical connector. In this comparative example, the boot extends long from the optical connector main body to the rear side. That is, in the comparative example, the flexible portion of the boot (the portion that makes the bending of the optical fiber gentle by bending together with the optical fiber) is arranged outside from the rear side of the optical connector body. As a result, in the comparative example, the total length of the optical connector is long.

  On the other hand, in the embodiment described below, the flexible portion of the boot is disposed inside the optical connector main body (the portion obtained by removing the boot from the optical connector). This shortens the total length of the optical connector.

=== First Embodiment ===
<Overall configuration>
FIG. 1 is a perspective view of the optical connector 10 of the first embodiment. FIG. 2 is an exploded view of the optical connector 10 of the first embodiment. As shown in the figure, the optical connector 10 of the first embodiment differs from the boot of the comparative example in that the flexible portion 65 of the boot 60 is disposed inside the optical connector body.

  In the following description, front and rear, top and bottom, and left and right are defined as shown in the figure. That is, the “front-rear direction” is defined along the optical axis of the optical fiber 1, and the end face side as viewed from the optical fiber 1 is “front” and the opposite side is “rear”. The direction in which the plurality of optical fibers 1 of the optical fiber ribbon are arranged is defined as “left-right direction”, and “right” and “left” are defined when viewed from the front side. Also, the front-rear direction and the direction perpendicular to the left-right direction are defined as “up-down direction”, and “upper” and “lower” are defined as shown in the figure.

  The optical connector 10 is assembled at the tip of the optical fiber 1. Specifically, the optical fiber 1 is an optical fiber ribbon. Here, a 12-core optical fiber ribbon is employed, but the number of optical fiber ribbons is not limited to 12. In addition, although four optical fiber ribbons (a total of 48 optical fibers) are used here, the number of optical fiber ribbons is not limited to four.

  The optical connector 10 mainly includes a ferrule 20, a coil spring 33, a spring push 40, a housing 50, and a boot 60. In addition, the optical connector 10 also includes a guide pin 31 and a pin clamp 32.

  The ferrule 20 is attached to the tip of the optical fiber 1 and holds the tip of the optical fiber 1. Here, the ferrule 20 is an MT type optical connector (F12 type optical connector established in JIS C5981. MT: Mechanically Transferable). The ferrule 20 has a front end surface for butt joining on the front side. On the front end face, a plurality of optical fibers 1 of the optical fiber ribbon are arranged in the left-right direction, and the end faces of the bare optical fibers exposed from the respective optical fibers 1 are exposed. A pair of guide pins 31 are inserted into the guide pin holes of the ferrule 20 so as to sandwich the plurality of optical fibers 1 arranged in the left-right direction at the distal end surface, and the distal ends of the guide pins 31 protrude from the distal end surface of the ferrule 20. ing. The flange of the guide pin 31 is disposed between the rear end surface of the ferrule 20 and the front end surface of the pin clamp 32, so that the guide pin 31 is prevented from coming off in the front-rear direction.

  The ferrule 20 is biased to the front side via the pin clamp 32 by the repulsive force of the coil spring 33. On the rear side of the ferrule 20, a flange portion having an outer periphery projecting is formed, and the front end surface of the flange portion contacts a projecting portion (not shown) formed on the inner surface of the housing 50, so that the further. The movement of the ferrule 20 to the front side is restricted (the front drop of the ferrule 20 is restricted).

  The spring push 40 is a member for accommodating the coil spring 33 in the housing 50 in a state of being elastically deformed (compressed). Thus, the ferrule 20 is accommodated in the housing 50 so as to be movable rearward while being urged forward by the repulsive force of the coil spring 33. By accommodating the ferrule 20 in this way, when the optical connector 10 is connected, it is possible to maintain a state where the end faces of the optical fibers are physically abutted with a predetermined force.

  The spring push 40 includes a frame-shaped main body 41 and a pair of fitting protruding wall portions 42. The frame-shaped main body 41 is formed with a fiber insertion hole for inserting an optical fiber. The pair of fitting projecting wall portions 42 are portions that are formed to project from the left and right sides of the frame-shaped main body 41 toward the front side. A locking claw 42a protruding outward is formed on the fitting protruding wall portion 42. By fitting the locking claw 42a into a locking hole (not shown) formed on the inner surface of the housing 50, the spring The push 40 is fixed to the housing 50. At this time, the coil spring 22 is accommodated in a state of being compressed and deformed between the pin clamp 32 and the spring push 40. However, when the catch pawl 42a is fitted into the catch hole of the housing 50, the spring push 40 is moved. It is prevented from coming out from the rear side of the housing 50.

  The spring push 40 also functions as an attachment member for attaching the boot 60. A boot 60 is attached to the rear side of the spring push 40. A method for attaching the boot 60 will be described later.

  The housing 50 is a cylindrical member, and is a member for housing other members (ferrule 20, pin clamp 32, coil spring 33, spring push 40, boot 60). A coupling 51 that can move back and forth is attached to the housing 50. From the front side of the housing 50, a part of the front side of the ferrule 20, the guide pins 31, and the like protrude. On the inner surface of the housing 50, a locking hole (not shown) for fitting the locking claw 42a of the spring push 40 and a projecting portion (not shown) for restricting the movement of the ferrule 20 to the front side are formed. Has been.

  The boot 60 is a member for relaxing the bending of the optical fiber 1. The boot 60 reduces light transmission loss or protects the optical fiber itself. The boot 60 of the first embodiment has a flexible portion 65 that bends and deforms as the optical fiber 1 contacts. The boot 60 is integrally formed of rubber or the like so that the flexible portion 65 can be deformed. The configuration of the boot 60 and how to attach the boot 60 will be described later.

  The optical connector 10 is optically connected to another optical connector via an adapter by a plug-adapter-plug coupling method.

<Attachment structure of boot 60>
FIG. 3A is a perspective view of the boot 60 according to the first embodiment as viewed obliquely from the front. FIG. 3B is a perspective view of the boot 60 as viewed obliquely from behind.

  The boot 60 is mainly composed of a fixed portion 61 and a pair of flexible portions 65. Here, the fixing portion 61 will be described, and the configuration and function of the flexible portion 65 will be described later.

The fixing part 61 is a part for fixing the boot 60 to the spring push 40 which is a boot attachment member. For this reason, the fixing | fixed part 61 is a site | part which does not deform | transform even if the optical fiber 1 curves. The fixing part 61 has a protrusion 62 formed on the front side and a rear end part 63 formed on the rear side.
The protrusion 62 has a head 62a, a neck 62b, and a pair of protrusions 62c, and is formed with an insertion hole 62d through which an optical fiber is inserted. The head 62a is disposed on the front side of the neck 62b. The head portion 62a is formed so as to protrude to the left and right sides of the neck portion 62b in order to prevent the boot 60 from coming off from the rear side of the optical connector 10. Protruding portions 62c are arranged on both upper and lower sides of the head portion 62a and the neck portion 62b. The protruding portion 62c is a portion that protrudes up and down. The protrusions 62 c come into contact with the pressing surface 52 (see FIG. 2) of the housing 50, so that the boot 60 and the spring push 40 are positioned with respect to the housing 50.
The rear end 63 is a part that closes the rear opening of the housing 50. The boot 60 and the spring push 40 are positioned with respect to the housing 50 by the peripheral surface of the rear end portion 63 being in contact with the inner surface of the housing 50. The rear end portion 63 is formed so as to protrude to the left and right sides of the neck portion 62b. A positioning projection 63 a is formed on the front end face of the rear end 63. The rear end surface of the rear end portion 63 is located at the same position as the rear end surface of the housing 50 after the optical connector 10 is assembled (see FIG. 1).

  FIG. 4 is an explanatory view of a state when the boot 60 is attached to the spring push 40.

  A pair of rear side wall portions 43 and a pair of rear wall portions 44 are provided on the rear side of the spring push 40. The pair of rear side wall portions 43 are formed from the left and right sides of the frame-shaped main body 41 toward the rear side. Further, the rear wall portion 44 is a wall portion that protrudes inward from the rear side of each rear side wall portion 43. The pair of rear wall portions 44 are provided apart from each other in the left-right direction, and an optical fiber is disposed therebetween. Further, the rear wall portion 44 is provided at a position away from the frame-shaped main body 41 in the front-rear direction. The frame-shaped main body 41, the pair of rear side wall portions 43, and the pair of rear wall portions 44 form a protrusion storage portion 46 for storing the protrusion 62 provided on the front side of the boot 60. Further, the rear wall portion 44 is formed with a fitting hole 44a for fitting with the positioning projection 63a of the boot 60. By having such a structure, the spring push 40 functions as an attachment member for attaching the boot.

  The boot 60 is attached to the spring pusher 40 from above and below so that the protrusion 62 is housed in the protrusion housing part 46 of the spring pusher 40. Then, the positioning protrusion 63a of the boot 60 is engaged with the fitting hole 44a of the spring push 40, whereby the boot 60 is prevented from coming off the spring push 40 in the vertical direction. Further, the rear end surface of the head portion 62a of the boot 60 is in contact with the front end surface of the rear wall portion 44 of the spring push 40, and the boot 60 is prevented from coming out of the spring push 40 to the rear side.

  An operator who assembles the optical connector 10 attaches the boot 60 to the spring push 40 from above and below to form an integral unit, and then attaches the unit, the spring push 40, the coil spring 33, and the pin clamp 32 to the optical fiber. Insert into. Thereafter, the ferrule 20 is attached by processing the tip of the optical fiber, and other members are accommodated from the rear side of the housing 50 as shown in FIG. That is, since the boot 60 is attached to the spring push 40 from the vertical direction and unitized, the unit is accommodated in the housing 50 from the front and rear directions, so that the boot after being accommodated in the housing 50 cannot be removed from the optical connector body. It is like that.

<Flexible portion 65 of boot 60>
Next, the flexible part 65 of the boot 60 will be described with reference to FIG. 3B.

  The flexible part 65 is a part that bends and deforms according to the curvature of the optical fiber 1. The flexible part 65 is formed in a plate shape, and the pair of flexible parts 65 are arranged so as to face each other in the vertical direction. The optical fiber 1 is disposed between the pair of flexible portions 65. Here, an optical fiber ribbon is adopted. The plate-like flexible portion 65 is disposed so as to face the optical fiber tape core wire, and the pair of flexible portions 65 is in the normal direction (vertical direction) of the optical fiber array surface of the optical fiber tape core wire. Are arranged so as to sandwich the optical fiber. The vertical distance between the pair of flexible portions 65 is substantially the same as the vertical dimension of the insertion hole 62 d of the boot 60.

  The flexible portion 65 is supported from the fixed portion 61 by a fixed end 65a located at the front end. Other ends (left and right ends and rear ends) other than the fixed end 65a are not in contact with other members and parts (for example, the side surface 64b) and are free ends. That is, the flexible part 65 is supported from the fixed part 61 in a cantilever state. For this reason, the flexible part 65 has a structure that is easily bent in the vertical direction. Further, the rear end of the flexible portion 65 serving as a free end has a structure that is easily displaced in the vertical direction.

  A concave space 64 is formed on the rear side of the fixed portion 61, and a flexible portion 65 is disposed in the concave space 64. More specifically, the concave space 64 is a space surrounded by the deepest surface 64a and the pair of side surfaces 64b, and the fixed end 65a of the flexible portion 65 is supported by the deepest surface 64a. That is, the flexible portion 65 is a plate-like portion (tongue-like portion) that protrudes rearward from the deepest surface 64 a that forms the concave space 64.

  The deepest surface 64a that forms the concave space 64 is positioned in front of the rearmost part of the fixing part 61 of the boot 60 (rear end face of the rear end part 63) and the rearmost part of the optical connector body (rear end face of the housing 50). doing. For this reason, the fixed end 65a of the flexible part 65 is located in front of the last part of the fixed part 61 of the boot 60 and the last part of the optical connector body. As a result, the flexible portion 65 is deformed in front of the last portion of the fixing portion 61 of the boot 60 and the last portion of the optical connector body. In other words, the flexible part 65 is deformed inside the connector body. Thereby, the full length of the optical connector 10 can be shortened, ensuring the function of a boot.

  In the present embodiment, the rear end (free end) of the flexible portion 65 is the rearmost portion of the fixing portion 61 of the boot 60 (the rear end surface of the rear end portion 63) or the rearmost portion of the optical connector body (the rear side of the housing 50). End position) and the front-rear direction or the front side. For this reason, all the parts of the flexible part 65 are accommodated in the connector main body. That is, the boot 60 can be structured not to protrude from the rear side of the optical connector 10.

  In the present embodiment, the length of the concave space 64 in the front-rear direction (the dimension of the side surface 64 b in the front-rear direction) is greater than or equal to the length of the flexible portion 65 in the front-rear direction. That is, the length of the concave space 64 in the front-rear direction may be greater than or coincide with the length of the flexible portion 65 in the front-rear direction. By forming the concave space 64 in this way, it is possible to make a structure in which all the portions of the flexible portion 65 are accommodated in the connector main body.

FIG. 5 is an explanatory diagram of the deformation of the flexible portion 65. Here, the state when the optical fiber 1 is bent upward is indicated by a dotted line.
When the optical fiber 1 is bent, it comes into contact with the inner surface 65b of the flexible portion 65, and the flexible portion 65 is deformed. By deforming the flexible portion 65 together with the optical fiber 1, the bending radius of the optical fiber 1 is ensured, and excessive bending of the optical fiber 1 is suppressed. As a result, the bending of the optical fiber becomes gentle, the light transmission loss of the optical fiber 1 is reduced, or the optical fiber itself is protected.

  In the present embodiment, the inner surface 65b is slightly inclined so that the vertical interval between the inner surfaces 65b of the flexible portion 65 increases toward the rear side. Thereby, the contact angle of the optical fiber 1 and the flexible part 65 can be set small, and it becomes easy to suppress the excessive curve of an optical fiber.

  Furthermore, in this embodiment, the flexible portion 65 is configured such that the thickness of the flexible portion 65 decreases toward the rear side. In other words, the flexible portion 65 is tapered. As a result, the rear side of the flexible portion 65 is greatly displaced, so that the optical fiber 1 is in surface contact with the flexible portion 65 or point-contacted at a plurality of points even if the deformation amount of the flexible portion 65 is small. It becomes easy to suppress the excessive bending of an optical fiber.

  In the present embodiment, the outer surface 65c of the flexible portion 65 is positioned on the inner side of the outermost surface in the vertical direction of the deepest surface 64a of the flexible portion 65. A gap 65d is formed between the inner surface and the inner surface. Since there is a gap 65d on the outer side of the flexible part 65, deformation to the outer side of the flexible part 65 is allowed. Then, an alignment protrusion 85 of the jig 80 described later enters the gap 65d.

  In the present embodiment, since the optical fiber tape core wire in which a plurality of optical fibers are arranged in the left-right direction is employed, the optical fiber is mainly bent in the up-down direction. Therefore, in the present embodiment, the pair of flexible portions 65 are arranged so as to sandwich the optical fiber from the normal direction (vertical direction) of the optical fiber array surface of the optical fiber ribbon. In other words, in the present embodiment, the pair of flexible portions 65 are provided in the up-down direction so as to face the optical fiber ribbon. Thereby, excessive bending of the optical fiber 1 can be suppressed. In other words, when an optical fiber ribbon with a plurality of optical fibers arranged in the left-right direction is employed, the optical fiber is difficult to bend in the left-right direction, so a pair of flexible portions that face in the left-right direction are provided. It is not necessary.

<Jig>
FIG. 6A is a perspective view of the jig 80 used for the optical connector 10 of the first embodiment when viewed obliquely from the front. FIG. 6B is a perspective view of the jig 80 viewed obliquely from behind.

  In the following explanation, as shown in the figure, the front, back, top, bottom, left and right of the jig are defined. The definition of this direction follows the front-rear, up-down, left-right directions defined when the optical connector 10 is described. When the optical connector 10 is connected, the direction of the optical connector 10 described above coincides with the direction of the jig shown in the drawing.

  The jig 80 is an instrument for pushing the optical connector 10 toward the adapter when the optical connector 10 is connected. The jig 80 has an upper surface grip portion 81, a lower surface grip portion 82, and a connecting portion 83, and is a C-shaped member. The operator operates the jig 80 by holding the upper surface gripping portion 81 and the lower surface gripping portion 82 with fingers.

  The vertical distance between the inner surfaces of the upper surface gripping portion 81 and the lower surface gripping portion 82 is set to be at least larger than the inner dimension in the vertical direction of the insertion hole 62d of the boot 60. In this embodiment, the flexibility of the boot 60 is set. The outer dimension of the outer surface 65c of the portion 65 is set to be larger than the outer dimension in the vertical direction. Thereby, the optical fiber extending from the insertion hole 62 d of the boot 60 can be disposed between the upper surface gripping portion 81 and the lower surface gripping portion 82.

  An opening 84 is provided on the right side of the jig 80 (opposite side of the connecting portion 83). When the optical connector 10 is connected, the optical fiber 1 extending from the rear side of the optical connector 10 is passed through the opening 84 and positioned between the upper surface gripping portion 81 and the lower surface gripping portion 82.

  The front end surfaces (C-shaped front end surfaces) of the upper surface gripping portion 81, the lower surface gripping portion 82, and the connecting portion 83 come into contact with the boot 60 and the rear end surface of the housing 50 when the optical connector 10 is connected. It has become. However, each of the upper surface gripping portion 81 and the lower surface gripping portion 82 is formed with an alignment protrusion 85 that protrudes toward the front side. The interval in the vertical direction of the pair of alignment projections 85 corresponds to the interval between the pair of upper and lower gaps 65d (see FIG. 5) outside the flexible portion 65.

  FIG. 7A and FIG. 7B are explanatory views of a state during the connection work of the optical connector 10 using the jig 80.

  First, an operator passes the optical fiber 1 extending from the rear side of the optical connector 10 through the opening 84 while grasping the upper surface gripping portion 81 and the lower surface gripping portion 82 with a finger, and the upper surface gripping portion 81 and the lower surface gripping portion. 82 (see FIG. 7A). Thereafter, the operator moves the jig 80 forward while maintaining the state in which the optical fiber 1 is disposed between the upper surface gripping portion 81 and the lower surface gripping portion 82, and the upper surface gripping portion 81, the lower surface gripping portion 82, and The front end face (C-shaped front end face) of the connecting portion 83 is brought into contact with the boot 60 of the optical connector 10 and the rear end face (see FIG. 1) of the housing 50 (see FIG. 7B). At this time, the pair of alignment protrusions 85 of the jig 80 are inserted into the pair of upper and lower gaps 65 d outside the flexible portion 65. Thereby, the jig 80 is positioned with respect to the optical connector 10. Then, the operator connects the optical connector 10 to the adapter while pushing the optical connector 10 forward with the jig 80 as shown in FIG. 7B.

  When the alignment projection 85 of the jig 80 is inserted into the gap 65d outside the flexible part 65 (see FIG. 7B), the front side of the jig 80 (upper surface gripping portion 81, lower surface gripping portion 82, and connecting portion 83). The front side of the optical fiber 1 is not in contact with the optical fiber 1, so that the optical fiber 1 is hardly curved. Due to such a state, when the operator pushes the optical connector 10 forward toward the adapter via the jig 80, it is not necessary to apply an excessive bending load to the optical fiber 1. On the other hand, when the operator performs the connecting operation of the optical connector 10 by manually pushing the rear end face of the boot 60 or the housing 50 without using the jig 80, the optical connector 10 is extended from the rear side. An operator's hand may touch the existing optical fiber 1, and an excessive bending load may be applied to the optical fiber 1.

=== Second Embodiment ===
<Outline of optical connector>
8 and 9 are explanatory diagrams when the optical connector of the second embodiment is connected. FIG. 8 is an explanatory diagram of a state in which the optical connector 210 is connected to the receiving optical connector 310. FIG. 9 is an explanatory diagram showing a state where the optical connector 210 is connected to the receiving optical connector 310.

  In the following description, front and rear, top and bottom, and left and right are defined as shown in the figure. That is, the “front-rear direction” is defined along the optical axis of the optical fiber 1, and the end face side as viewed from the optical fiber 1 is “front” and the opposite side is “rear”. The direction in which the plurality of optical fibers 1 of the optical fiber ribbon are arranged is defined as “left-right direction”, and “right” and “left” are defined when viewed from the front side. Further, the front-rear direction and the direction perpendicular to the left-right direction are referred to as “vertical direction”, and the side on which the operation convex portion 254 is provided when viewed from the housing 250 is “upper”, and the opposite side is “lower”.

  In the following description, the position of the housing 250 in FIG. 8 may be referred to as a “release position”. In addition, the state where the housing 250 is in the release position may be referred to as a “release state”. Further, the position of the housing 250 in FIG. 9 may be referred to as a “restraint position”. The state in which the housing 250 is in the restrained position may be referred to as a “restraint state”.

  The side surface 314 of the receiving optical connector 310 is provided with a locking portion 315 formed in a concave shape. In a state where the claw portion 245 of the optical connector 210 is positioned at the locking portion 315, the housing 250 becomes a “restraining position” that is positioned on the most front side with respect to the engaging member 240, so that the claw portion 245 becomes the locking portion 315. The claw portion 245 and the locking portion 315 are engaged, and the optical connector 210 and the receiving side optical connector 310 are fastened. In the restrained state, the inner surface of the housing 250 is in a state of restraining the outside of the claw portion 245.

<Overall configuration>
FIG. 10 is a perspective view of the optical connector 210 according to the second embodiment viewed obliquely from behind. FIG. 11 is an exploded view of the optical connector of the second embodiment.

  The optical connector 210 is assembled at the tip of the optical fiber 1. Specifically, the optical fiber 1 is an optical fiber ribbon. Here, a 12-core optical fiber ribbon is employed, but the number of optical fiber ribbons is not limited to 12.

  The optical connector 210 mainly includes a ferrule 220, a coil spring 233, an engagement member 240, a housing 250, and a boot 260. In addition, the optical connector 210 also includes guide pins 231 and pin clamps 232.

  The ferrule 220 is attached to the tip of the optical fiber 1 and holds the tip of the optical fiber 1. A pair of guide pins 231 are inserted into the guide pin holes of the ferrule 220 so as to sandwich the plurality of optical fibers 1 arranged in the left-right direction at the distal end surface, and the distal ends of the guide pins 231 protrude from the distal end surface of the ferrule 220. ing. The flange of the guide pin 231 is disposed so as to be sandwiched between the rear end face of the ferrule 220 and the front end face of the pin clamp 232, and the guide pin 231 is prevented from coming off in the front-rear direction.

  The engaging member 240 is a U-shaped member having a receiving portion 241 and a pair of elastic pieces 242 extending from the left and right sides of the receiving portion 241 to the front side. The engaging member 240 accommodates the ferrule 220 so as to be movable rearward while urging the ferrule 220 forward by the repulsive force of the coil spring 233. When the engaging member 240 accommodates the ferrule 220 in this manner, when the optical connector 210 is connected to the receiving-side optical connector 310, the end surfaces of the optical fibers are physically abutted with a predetermined force. Can be held. A boot 260 is attached to the rear side of the engaging member 240. For this reason, the engaging member 240 is an attachment member for attaching the boot 260.

  The elastic piece 242 is a portion that extends forward from the receiving portion 241 and is a portion that elastically deforms in the left-right direction. A claw portion 245 is provided at the distal end portion (front end portion) of the elastic piece 242 so as to protrude inward. Note that the ferrule 220 is disposed on the rear side of the claw portion 245. The claw portion 245 is a portion that engages with the locking portion 315 of the receiving side optical connector 310 connected to the optical connector 210. A concave portion 246 is provided on the outer surface of the elastic piece 242. A step portion 246 a is formed at the rear edge of the recess 246, and a contact portion 246 b is formed at the front edge of the recess 246. The functions of the step portion 246a and the contact portion 246b will be described later.

  The housing 250 is a flat rectangular tube-shaped member, and is a member that can move in the front-rear direction with respect to the engaging member 240. The housing 250 is a member for moving to the front side with respect to the engaging member 240 to bring the outer side of the elastic piece 242 into a constrained state constrained by the inner surface. The housing 250 accommodates the ferrule 220 and the like inside. However, the front end portion of the elastic piece 242 including the claw portion 245 protrudes from the front side of the housing 250. A stopper 256 is formed on the inner surface of the side wall of the housing 250 as will be described later.

  On the upper surface of the housing 250 and the upper outer periphery of the side wall, a U-shaped operation convex portion 254 is provided so as to protrude outward. By providing the operation convex portion 254, the operator can easily work.

  The boot 260 is a member for gradual bending of the optical fiber 1. The boot 260 reduces light transmission loss or protects the optical fiber itself. The boot 260 of the second embodiment also has a pair of flexible portions 265 (described later) that bend and deform according to the curvature of the optical fiber 1. The boot 260 is integrally formed of rubber or the like so that the flexible portion 265 can be deformed. The configuration of the boot 260 and how to attach the boot 260 will be described later.

  FIG. 12A is a cross-sectional view of the optical connector 210. In this figure, the housing 250 is in the release position (the optical connector 210 is in the release state).

  As shown in the drawing, the flange portion of the ferrule 220, the pin clamp 232, and the coil spring 233 are accommodated in the internal space of the U-shaped engaging member 240. The coil spring 233 is accommodated in an elastically deformed state, and biases the ferrule 220 forward against the engaging member 240 by a repulsive force. Note that when the front end surface of the ferrule 220 is pushed rearward when the optical connector 210 is connected, the coil spring 233 is slightly contracted, and the ferrule 220 moves rearward relative to the engaging member 240.

  A stopper 256 is formed on the inner surface of the housing 250 so as to protrude inward. The stopper 256 is disposed at a position where the stopper 256 enters the recess 246 of the engagement member 240. As shown in the drawing, when the housing 250 is in the release position, the stopper 256 is in contact with the stepped portion 246a that is the rear edge of the recess 246. Thereby, the rearward movement of the housing 250 with respect to the engaging member 240 is restricted, and the rearward removal of the housing 250 is prevented. When the housing 250 is in the restraining position, the stopper 256 comes into contact with the contact portion 246b that is the front edge of the recess 246. Thereby, the movement to the front side of the housing 250 with respect to the engaging member 240 is restricted, and the front removal of the housing 250 is prevented. Thus, the recess 246 of the engagement member 240 restricts the movement of the housing 250 in the front-rear direction. Further, the movable range of the housing 250 with respect to the engaging member 240 is set by the size of the recess 246 in the front-rear direction.

  When the housing 250 is in the release position, a portion on the front side of the contact portion 246b protrudes from the front side of the housing 250 and is exposed. In particular, since the claw portion 245 is on the front side of the concave portion 246, when the housing 250 is in the release position, all the portions of the claw portion 245 protrude from the front side of the housing 250 and are exposed.

  The interval between the front end portions of the front inclined surface 245 a of the left and right claw portions 245 is set to be wider than the left and right widths of the receiving side optical connector 310. This is because if the distance between the front end portions of the front inclined surface 245a is narrower than the left and right widths of the receiving optical connector, the receiving optical connector cannot be inserted between the left and right claw portions 245. The distance between the top portions 245 b of the left and right claw portions 245 is set to be substantially the same as the left and right widths of the receiving side optical connector 310. However, the interval between the top portions 245b of the left and right claw portions 245 may be set slightly wider than the left and right widths of the receiving side optical connector 310, or conversely, may be set slightly narrower.

FIG. 12B is an enlarged view of the vicinity of the contact portion 246b.
When the housing 250 is in the release position, the contact portion 246b of the engagement member 240 is in contact with the front edge 253c (the front corner of the side wall) of the inner surface of the housing 250. The outer side of the elastic piece 42 (the claw portion 245) positioned on the front side of the contact portion 246 b is positioned on the outer side of the inner wall of the housing 250. That is, the elastic pieces 242 of the left and right engaging members 240 are opened outward (extruded) from the opening of the housing 250. Thus, even when the operator holds the optical connector 210 when the housing 250 is in the release position, the release state can be maintained without the housing 250 moving relative to the front side with respect to the engagement member 240.

  Next, the state of the optical connector 210 when the optical connector 210 is connected (from the state shown in FIG. 8 to the state shown in FIG. 9) will be described. Here, it is assumed that the operation of connecting the optical connector 210 is performed while the operator grasps the operation convex portion 254 of the housing 250 of the optical connector 210 with a finger.

  FIGS. 13A to 13C are explanatory diagrams of the internal state of the optical connector 210 at the time of connection. FIG. 13A is an explanatory diagram showing a state when the receiving side optical connector 310 is inserted between the claw portions 245. FIG. 13B is an explanatory diagram showing a state when the ferrule 220 of the optical connector 210 comes into contact with the end face of the receiving optical connector 310. FIG. 13C is an explanatory diagram showing a state where the claw portion 245 reaches the position of the locking portion 315 and the housing 250 has moved to the restraining position.

  As shown in FIG. 13A, the operator picks the operation convex portion 254 of the housing 250 of the optical connector 210 in the released state with his / her finger, advances the optical connector 210 toward the receiving optical connector 310, and the left and right nail portions The receiving side optical connector 310 is inserted between H.245. Even when the position of the optical connector 210 is slightly shifted in the left-right direction with respect to the receiving-side optical connector 310 at the time of insertion, the receiving-side optical connector 310 is guided between the left and right top portions 245b by the front inclined surface 245a. Is done.

  When the receiving side optical connector 310 comes into contact with the distal end portion of the claw portion 245 or the front inclined surface 245a, the engaging member 240 receives a force directed from the receiving side optical connector 310 toward the rear side. At this time, since the operator holds the operation convex portion 254 of the housing 250, the engaging member 240 receives a rearward force with respect to the housing 250. However, since the contact portion 246 b of the engaging member 240 is in contact with the front edge 253 c of the housing 250, the housing 250 does not move even if the tip portion of the claw portion 245 or the front inclined surface 245 a contacts the receiving side optical connector 310. It does not move forward relative to the engaging member 240.

  When the operator further advances the optical connector 210 toward the receiving optical connector 310, the guide pins 231 of the optical connector 210 are inserted into the guide pin holes of the receiving optical connector 310, and as shown in FIG. The ferrule 220 of 210 is positioned and butt-connected to the receiving side optical connector 310 with high accuracy.

  Further, from the state shown in FIG. 13B, the operator advances the optical connector 210 toward the receiving optical connector 310. At this time, since the contact portion 246b of the engagement member 240 is in contact with the front edge 253c of the housing 250, the engagement member 240 also moves forward together with the housing 250 held by the operator. However, since the ferrule 220 is in contact with the receiving side optical connector 310, it cannot move to the front side. For this reason, while the position of the ferrule 220 is fixed, the engaging member 240 and the housing 250 move to the front side while the coil spring 233 is contracted (while the operator resists the repulsive force of the coil spring 233, The engaging member 240 and the housing 250 are moved to the front side). In other words, the ferrule 220 moves rearward relative to the engaging member 240 and the housing 250 while contracting the coil spring 233. Then, when the operator further advances the optical connector 210 toward the receiving optical connector 310 from the state shown in FIG. 13B, the claw portion 245 reaches the position of the locking portion 115 of the receiving optical connector 310.

  When the claw portion 245 reaches the position of the locking portion 315 of the receiving side optical connector 310, the contact portion 246b of the engaging member 240 is in contact with the front edge 253c of the housing 250. Get in. When the claw portion 245 enters the locking portion 315, the contact between the contact portion 246 b and the front edge 253 c is released, and the housing 250 can move relative to the engagement member 240 to the front side. On the other hand, the engaging member 240 cannot move in the front-rear direction when the claw portion 245 engages with the locking portion 315. Therefore, when the operator advances the optical connector 210 toward the receiving optical connector 310, only the housing 250 moves forward as shown in FIG. 13C.

  When the housing 250 moves to the front side, as shown in FIG. 13C, the stopper 256 of the housing 250 comes into contact with the contact portion 246b of the engaging member 240, and the housing 250 cannot move to the front side with respect to the engaging member 240. The operation of the operator to advance the housing 250 is finished when the housing 250 reaches the “restraint position”.

  When the housing 250 reaches the “restraint position” as shown in FIG. 13C, the elastic piece of the engaging member 240 is engaged with the claw portion 245 of the engaging member 240 engaged with the engaging portion 315 of the receiving side optical connector 310. The outer side of 242 (claw portion 245) is restrained by the inner surface of the housing 250. As a result, even if a repulsive force of the coil spring 233 is generated between the ferrule 220 and the engaging member 240, the claw portion 245 does not come off from the locking portion 315, and the engaging member 240 is pulled out to the rear side. Nor. Further, since the housing 250 does not receive a force in the front-rear direction from the engaging member 240, the housing 250 does not move from the “restraint position” even if the operator removes his / her hand from the housing 250. That is, the restraint state in which the claw portion 245 is engaged with the engaging portion 315 of the receiving side optical connector 310 is maintained, and the state in which the optical connector 210 is connected to the receiving side optical connector 310 is maintained.

  When the optical connector 210 is removed from the receiving optical connector 310, the operator grasps the operation convex portion 254 of the housing 250 of the optical connector 210 with a finger from the state shown in FIG. (The housing 250 is pulled rearward). As a result, the housing 250 is moved from the restraining position to the releasing position by following the reverse procedure of the connection, and the engagement between the claw portion 245 of the engaging member 240 and the engaging portion 315 of the receiving side optical connector 310 is released. Thus, the optical connector 210 is removed from the receiving side optical connector 310.

  As described above, according to the optical connector 210 of the second embodiment, it can be easily attached to and detached from the receiving side optical connector 310 by a push-pull method.

<Boots 260>
FIG. 14A is a perspective view of the boot 260 according to the second embodiment as viewed obliquely from the front. FIG. 14B is a perspective view of the boot 260 as viewed obliquely.
The boot 260 mainly includes a fixed portion 261 and a pair of flexible portions 265.

  The fixing part 261 is a part for fixing the boot 260 to the engaging member 240 which is a boot mounting member. The fixing part 261 has a front fixing part 262 formed on the front side and a pair of rear fixing parts 263 formed on the rear side. The front side fixing portion 262 is a block-shaped part in which an insertion hole for inserting an optical fiber is formed. The rear fixing portion 263 is fixed to the rear end face of the front fixing portion 262, and is arranged so as to sandwich the optical fiber from the left and right directions.

  The flexible portion 265 is a portion that bends and deforms according to the curvature of the optical fiber 1. The flexible part 265 is formed in a plate shape, and the pair of flexible parts 265 are arranged to face each other in the vertical direction. The optical fiber 1 is disposed between the pair of flexible portions 265. Here, an optical fiber ribbon is adopted. The flexible portion 265 is disposed so as to face the optical fiber ribbon, and the pair of flexible portions 265 is an optical fiber from the normal direction (vertical direction) of the optical fiber array surface of the optical fiber ribbon. It is arranged so that The vertical distance between the pair of flexible portions 265 is substantially the same as the vertical dimension of the insertion hole of the boot 260.

  The front side of the flexible portion 265 is a fixed end supported by the rear end surface of the front side fixed portion 262. Other ends (left and right ends and rear end) other than the fixed end are not in contact with other members and parts (for example, the rear side fixing portion 263) and are free ends. That is, the flexible part 265 is supported from the front side fixing part 262 in a state like a cantilever. For this reason, the flexible part 265 has a structure that is easily bent in the vertical direction.

  The upper flexible portion 265 slightly protrudes upward with respect to the front fixing portion 262. This protrusion amount is set to be smaller than the thickness in the vertical direction of the rear upper wall portion 247a (described later) of the engaging member 240. As a result, as in the first embodiment, when the optical connector 210 is assembled, a gap is formed between the outside of the flexible portion 265 and the housing 250 (of the flexible portion 265). A gap is formed on the outside). Thereby, the flexible portion 265 can be deformed outward according to the curvature of the optical fiber.

  However, even if there is no gap between the flexible portion 265 and the housing 250 in the released state, according to the optical connector 210 of the second embodiment, the housing 250 is positioned at the front restraint position in the restrained state. In the restrained state, the outside of the flexible portion 265 is opened, and the flexible portion 265 can be deformed.

FIG. 15 is an explanatory diagram of a state when the boot 260 is attached to the engaging member 240.
A rear upper wall portion 247a, a pair of rear side wall portions 247b, and a pair of rear wall portions 248 are provided on the rear side of the engaging member 240, and the front side fixing portion 262 is accommodated by the inner surfaces of these portions. A storage portion 249 is formed for this purpose. The rear upper wall portion 247a is located above the storage portion 249. The pair of rear side wall portions 247 b are located on the left and right sides of the storage portion 249. The distance between the opposing inner surfaces of the pair of rear side wall portions 247b (inner dimensions in the left-right direction) is substantially the same as the outer dimensions in the left-right direction of the front side fixing portion 262 of the boot 260.

  The distance between the inner surfaces of the pair of rear wall portions 248 facing each other (the inner dimension in the left-right direction) is substantially the same as the outer dimension in the left-right direction of the rear fixing portion 263 of the boot 260. When the boot 260 is attached to the engagement member 240, the rear fixing portion 263 of the boot 260 is disposed between the pair of rear wall portions 248. The thickness in the front-rear direction of the rear wall portion 248 is substantially the same as the dimension in the front-rear direction of the rear side fixing portion 263 of the boot 260. For this reason, when the boot 260 is attached to the engaging member 240, the rear end surface of the engaging member 240 (the rear end surface of the rear wall portion 248) is connected to the rear end surface of the rear fixing portion 263 of the boot 260 and the front and rear. The direction position is almost the same.

  On the lower side of the rear wall portion 248, a holding projection 248a projecting inward is formed. The distance in the left-right direction between the pair of holding projections 248 a is set to be narrower than the outer dimension in the left-right direction of the rear fixing portion 263 of the boot 260. For this reason, when the boot 260 is attached to the engaging member 240, the holding protrusion 248a holds the lower surface of the rear fixing portion 263 of the boot 260 from below.

  When the boot 260 is stored in the storage portion 249 of the engagement member 240, the upper surface of the front fixing portion 262 of the boot 260 and the lower surface of the rear upper wall portion 247 a of the engagement member 240 come into contact with each other. Movement to is regulated. Further, when the outer surface of the rear fixing portion 263 of the boot 260 comes into contact with the inner surface of the rear wall portion 248 of the engagement member 240, the movement of the boot 260 in the left-right direction is restricted. Further, when the lower surface of the rear fixing portion 263 of the boot 260 and the holding projection 248a of the engaging member 240 are in contact with each other, the downward movement of the boot 260 is restricted (this causes the boot 260 to fall off). Is prevented). Further, the rear end surface of the front fixing portion 262 of the boot 260 and the front end surface of the rear wall portion 248 of the engagement member 240 are in contact with each other, thereby restricting the rearward movement of the boot 260 (thereby 260 is prevented from falling behind). Since the engaging member 240 has the above-described configuration, the engaging member 240 functions as an attachment member for attaching the boot.

  Also in the second embodiment, the fixed end of the flexible portion 265 is the rearmost portion of the fixed portion 261 of the boot 260 (the rear end surface of the rear-side fixed portion 263) or the rearmost portion of the optical connector body (the rear of the engaging member 240). It is located in front of the side end face. As a result, the flexible part 265 is deformed in front of the last part of the fixing part 261 of the boot 260 and the last part of the optical connector body. In other words, the flexible portion 265 is deformed inside the connector body. Thereby, the full length of the optical connector 210 can be shortened, ensuring the function of a boot.

  Also in the second embodiment, the rear end (free end) of the flexible portion 265 is the rearmost portion (rear end surface of the rear-side fixing portion 263) of the boot 260 or the rearmost portion (engagement) of the optical connector body. It is desirable to be located in front of the rear end surface of the member 240. Thereby, all the parts of the flexible part 265 are accommodated in the connector main body. That is, the boot 260 can be structured not to protrude from the rear side of the optical connector 210.

  In the second embodiment, chamfering is performed so that the rear side (free end side) of the inner surface of the flexible portion 265 is rounded. As a result, on the rear side of the flexible portion 265, the inner surface is inclined so that the vertical interval between the inner surfaces increases toward the rear side. Thereby, the contact angle of the optical fiber 1 and the flexible part 265 can be set small, and it becomes easy to suppress the excessive curve of an optical fiber.

  Furthermore, in the second embodiment, since the upper and lower surfaces of the flexible portion 265 are chamfered so as to be rounded on the rear side, the thickness of the flexible portion 265 decreases toward the rear side. As a result, the rear side of the flexible portion 265 is greatly deformed. Therefore, even if the deformation amount of the flexible portion 265 is small, the optical fiber 1 is in surface contact with the flexible portion 265 or in point contact at a plurality of points. It becomes easy to suppress the excessive bending of an optical fiber.

=== Other Embodiments ===
The above-described embodiments are for facilitating the understanding of the present invention, and are not intended to limit the present invention. The present invention can be modified and improved as follows, for example, without departing from the gist thereof, and it is needless to say that the present invention includes equivalents thereof.

<How to install boots>
According to the first embodiment, a structure for attaching the boot 60 to the rear side of the spring push 40 is formed (see FIG. 4). Moreover, according to 2nd Embodiment, the structure for attaching the boot 260 to the rear side of the engaging member 240 was formed (refer FIG. 15). According to these embodiments, it was possible to attach the boot without using an adhesive. However, the method of attaching the boot is not limited to this.

  FIG. 16 is an explanatory diagram of a boot according to a first modification. The boot of the first modified example has a shape of a fixing portion different from the fixing portion of the boot 60 of the first embodiment, and therefore, the mounting method is also different.

  The boot according to the first modification is a cylindrical member in which an insertion hole for inserting an optical fiber is formed. On the rear side, a concave space is formed as in the first embodiment, and a flexible portion is formed as in the first embodiment.

  In the first modification, the outer peripheral portion of the boot is bonded and fixed to the inner peripheral surface of the housing of the first embodiment. For this reason, the outer peripheral part of the boot of a 1st modification is corresponded to the fixing | fixed part for fixing a boot. In the first modification, the housing corresponds to the boot mounting member of the optical connector body. In the case of this first modification, the above-described spring push 40 does not require a structure for attaching a boot.

  Even in the boot according to the first modified example, the fixed end of the flexible portion is disposed in front of the rearmost portion of the boot. For this reason, the total length of the optical connector can be shortened. However, it is necessary to attach the boot using an adhesive.

<About the flexible part 1>
According to 1st Embodiment and 2nd Embodiment, a pair of flexible part was arrange | positioned in the up-down direction. However, a pair of flexible portions may be arranged also in the left-right direction.
FIG. 17 is an explanatory diagram of a boot according to a second modification. The boot according to the second modified example has not only a pair of flexible portions arranged in the vertical direction but also a pair of flexible portions arranged in the left-right direction.
In particular, when the optical fiber ribbon is not used or when the optical fiber may be bent in the left-right direction, it is effective to dispose the pair of flexible portions also in the left-right direction. For example, when an optical connector is attached to the tip of an optical fiber contained in a single-core round optical fiber cord or a round optical fiber tube containing a plurality of strands, Since there is a possibility of bending in the left-right direction, it is effective to dispose a pair of flexible portions also in the left-right direction. Thus, the flexible part may be arrange | positioned in another direction, and 2 or more pairs may be provided.

<About the flexible part 2>
According to 1st Embodiment and 2nd Embodiment, all the parts of the flexible part were accommodated in the inside of an optical connector main body. However, the rear end of the flexible portion may protrude rearward from the rearmost portion of the optical connector body.
FIG. 18 is an explanatory diagram of the flexible portion of the third modification. In the third modified example, the rear end (free end) of the flexible portion slightly protrudes rearward from the rearmost portion of the boot. Even in such a boot, since the fixed end of the flexible portion is disposed in front of the rearmost portion of the boot, the length of the flexible portion protruding from the rear side of the optical connector body can be shortened. The total length of the connector can be shortened.

<About optical fiber>
In the above-described embodiment, a 12-fiber optical fiber ribbon is used. However, the number of cores of the optical fiber ribbon may be other numbers. Moreover, the optical fiber tape core wire may be plural or one. Also, the number of optical fibers may be one instead of a plurality. Further, the optical fiber to be protected by the boot of this embodiment is not limited to the optical fiber included in the optical fiber ribbon, and a plurality of single-core round optical fiber cords or strands are used. It may be an optical fiber contained in a stored round optical fiber tube or the like.

1 optical fiber, 10 optical connector, 20 ferrule,
31 guide pin, 32 pink lamp, 33 coil spring,
40 Spring push (boot mounting member),
41 frame-shaped main body, 42 projecting wall for fitting, 42a locking claw,
43 rear side wall part, 44 rear wall part, 44a fitting hole, 46 protrusion housing part,
50 housing, 51 coupling, 52 holding surface,
60 boots, 61 fixing parts,
62 Projection, 62a Head, 62b Neck, 62c Projection, 62d Insertion hole,
63 rear end, 63a positioning protrusion,
64 concave space, 64a deepest surface, 64b side surface,
65 flexible part, 65a fixed end, 65b inner surface, 65c outer surface, 65d gap,
80 jig, 81 upper surface gripping part, 82 lower surface gripping part,
83 connecting part, 84 opening, 85 alignment protrusion,
210 optical connector, 220 ferrule,
231 guide pin, 232 pink lamp, 233 coil spring,
240 engaging member (boot mounting member), 241 receiving portion, 242 elastic piece,
245 claw part, 245a front side inclined surface, 245b top part,
246 recessed portion, 246a stepped portion, 246b contact portion,
247a rear upper wall part, 247b rear side wall part,
248 rear wall portion, 248a holding projection, 249 storage portion,
250 housing, 253c leading edge,
254 Operation convex part, 256 stopper,
260 boots, 261 fixing parts,
262 front side fixing part, 263 rear side fixing part, 265 flexible part,
310 receiving side optical connector, 314 side surface, 315 locking portion

Claims (8)

A boot for protecting an optical fiber extending from the rear side of the optical connector,
A fixing portion for fixing to a boot mounting member in the optical connector body;
A pair of flexible parts arranged so as to sandwich the optical fiber and deformed according to the curvature of the optical fiber;
With
One end on the front side of the flexible part is a fixed end supported by the fixed part, and the other end on the rear side is a free end,
The boot, wherein the fixed end is arranged so as to be in front of the rearmost part of the fixed part. The boot according to claim 1,
A boot characterized in that the other end is arranged so as to be in the same position in the front-rear direction as the rearmost part of the optical connector body or in a position in front of the rearmost part. The boot according to claim 2,
A concave space is formed in the fixed portion,
A boot characterized in that the length of the concave space in the front-rear direction is equal to or longer than the length of the flexible part in the front-rear direction. The boot according to any one of claims 1 to 3,
A boot characterized in that the inner surface of the flexible portion is inclined so that the interval between the inner surfaces of the flexible portion increases toward the rear side. The boot according to any one of claims 1 to 4,
A boot characterized in that the thickness of the flexible part decreases toward the rear side of the flexible part. The boot according to any one of claims 1 to 5,
The optical fiber is included in an optical fiber ribbon.
A boot having a pair of flexible portions arranged so as to sandwich the optical fiber from a normal direction of an optical fiber arrangement surface of the optical fiber ribbon. An optical connector comprising an optical connector body and a boot, wherein the boot protects the optical fiber extending from the rear side,
The boots
A fixing portion for fixing to a boot mounting member in the optical connector body;
A pair of flexible parts arranged so as to sandwich the optical fiber and deformed according to the curvature of the optical fiber;
With
One end on the front side of the flexible part is a fixed end supported by the fixed part, and the other end on the rear side is a free end,
The optical connector is characterized in that the fixed end is disposed inside the optical connector body. A jig used for connecting the optical connector according to claim 7,
C-shaped with an opening for passing the optical fiber,
A jig characterized in that a pair of positioning projections for insertion into a gap provided outside the flexible portion is formed on a front end surface in contact with the optical connector.

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