JP2007133368A - Ferrule tip end protective structure in optical connector - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a structure capable of protecting a ferrule tip end better in an optical connector. <P>SOLUTION: With a ferrule 4 stored in a rear holder 8, and with temporary locking performed while the rear holder 8 with this ferrule 4 stored is housed in a housing 11, an optical connector 1 is made ready in a state before it is fitted to an optical connector 2 of the opposite side. In the optical connector 1 of this state, the tip end of the ferrule 4 is in the rear holder storing chamber 9 of the housing 11, wherein the tip end of the ferrule 4 is protected against the outside. After the optical connector 1 is fitted to the opposite optical connector, the rear holder 8 with the ferrule 4 stored is moved to the regular locking position; then, the tip end of the ferrule 4 is projected to an optical connecting spatial part 10. As a result, optical connection is performed. The locking mechanism is composed of a temporary locking part 20 on the rear holder side, a regular locking part 21 on the rear holder side, a temporary locking part 27 on the housing side, and a regular locking part 28 on the housing side. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to an optical connector for optical connection using an optical fiber, and more particularly to a ferrule tip protection structure for protecting the tip of a ferrule.

  The optical connector disclosed in Patent Document 1 below has the following structure, although not particularly shown. That is, the optical connector has a structure in which a ferrule provided on the optical fiber terminal is accommodated in the housing. The optical connector has a structure for optically connecting a ferrule housed in the housing by fitting with the counterpart optical connector. Furthermore, the optical connector has a structure in which a slide member that is pushed by the mating optical connector and retracts in the axial direction is provided on the mating surface with the mating optical connector serving as the front surface.

  The slide member is provided as a member for protecting the tip of the ferrule. The slide member is a separate member from the housing, and is provided in a state of protruding from the front surface of the housing and in a state of being hidden in the housing when retracted in the axial direction. Such a slide member has a through hole that exposes the tip of the ferrule when retracted in the axial direction. The housing and the slide member have a structure for preventing the slide member from retreating into the housing unintentionally.

The optical connector has a structure in which the ferrule is fixed and mated with the counterpart optical connector without changing the tip position. The optical connector has a structure in which the tip of the ferrule is exposed only when the slide member is pushed by the counterpart optical connector. In other words, it has a structure in which the tip of the ferrule is exposed during fitting with the counterpart optical connector.
JP 2002-90577 A

  By the way, in the above prior art, since the tip of the ferrule is exposed during the mating with the mating optical connector, the mating optical connector is fitted by, for example, rattling during the mating. If the misalignment occurs in the mating direction, there is a risk that the tip of the ferrule will be twisted by the slide member or the counterpart optical connector. Since the end surface of the optical fiber (optical surface: light transmission surface) is present on the front end surface of the ferrule, there is a problem that the optical connection is affected. In addition, the prior art has a problem that the structure of the optical connector is complicated.

  This invention is made | formed in view of the situation mentioned above, and makes it a subject to provide the structure which can protect the ferrule tip in an optical connector better.

  The ferrule tip protection structure in the optical connector of the present invention according to claim 1 made to solve the above-mentioned problems is a ferrule attached to an optical fiber terminal, a rear holder having a ferrule storage chamber, a rear holder storage chamber, and an optical connection A housing having a space, and the ferrule storage chamber has a structure in which a front end side of the ferrule is exposed when the ferrule is stored, and the rear holder and the housing are temporarily locked by the rear holder in the storing process. The rear holder storage chamber is a structure in which the front end side of the ferrule is in a storage state when the rear holder is temporarily locked. In the optical connection space, the front end of the ferrule protrudes when the rear holder is fully locked. It is characterized in that it is granulated.

  According to the present invention having such a feature, when the ferrule is stored in the rear holder, and the rear holder storing the ferrule is temporarily locked while being stored in the housing, the ferrule before being fitted to the counterpart optical connector can be obtained. The optical connector is ready. In the optical connector in this state, the front end side of the ferrule is in a state where it exists in the rear holder housing chamber of the housing, and the front end side of the ferrule is protected from the outside. When the rear holder containing the ferrule is moved to the final locking position and finally locked after the optical connector is fitted to the counterpart optical connector, the tip of the ferrule protrudes into the optical connection space. As a result, an optical connection is made.

  The ferrule tip protection structure in the optical connector of the present invention according to claim 2 is the ferrule tip protection structure in the optical connector according to claim 1, wherein the housing further has a release mechanism for the main locking, An elastic body that moves the housing and the ferrule toward the temporary locking side by releasing the main locking is provided in the rear holder storage chamber of the housing.

  According to the present invention having such a feature, the main locking of the rear holder containing the ferrule is released by operating the release mechanism. When the main locking is released, the rear holder storing the ferrule is automatically moved to the temporary locking side by the action of the elastic body. In the optical connector in this state, the front end side of the ferrule is in a state of being present in the rear holder housing chamber of the housing.

  A ferrule tip protection structure for an optical connector according to a third aspect of the present invention is the ferrule tip protection structure for an optical connector according to claim 2, wherein the housing is for fitting and unfitting with a mating optical connector. And a structure further having a locking arm that acts on the release mechanism.

  According to the present invention having such a feature, by operating the locking arm, the fitting with the counterpart optical connector is released, and the main locking of the rear holder housing the ferrule is released. In the optical connector in the mating release state with the mating optical connector and in the final locking release state, the distal end side of the ferrule is stored in the rear holder storage chamber of the housing and is protected from the outside.

  The ferrule tip protection structure in the optical connector of the present invention according to claim 4 made to solve the above-mentioned problems is a ferrule attached to an optical fiber terminal, a rear holder having a ferrule storage chamber, a rear holder storage chamber, and an optical connection A housing having a space, and an elastic body that is interposed between the housing and the rear holder and biases the rear holder, and the ferrule storage chamber is exposed in a state where the ferrule is stored. The rear holder and the housing further include a plurality of locking mechanisms for temporarily locking the rear holder during the storage process in the rear holder storage chamber, and the rear holder storage chamber Is a structure in which the front end side of the ferrule is stored when the rear holder is temporarily locked. The rear holder has a structure that further includes a locking arm for fitting and releasing the mating with the counterpart optical connector and forming a final locking state of the rear holder. The ferrule has a structure in which the protrusion on the front end side is generated when the rear holder is fully locked.

  According to the present invention having such a feature, when the ferrule is housed in the rear holder and the rear holder housing the ferrule is housed in the housing together with the elastic body and temporarily locked, the mating with the mating optical connector is achieved. The optical connector in the state before being made is completed. In the optical connector in this state, the front end side of the ferrule is in a state where it exists in the rear holder housing chamber of the housing, and the front end side of the ferrule is protected from the outside. While the housing of the optical connector is housed in the mating optical connector, the rear holder housing the ferrule is moved to the final locking position, fitted into the mating optical connector via the locking arm, and the rear holder main handle When the stop state is formed, the tip of the ferrule protrudes into the optical connection space. As a result, an optical connection is made.

  The ferrule tip protection structure for an optical connector according to a fifth aspect of the present invention is the ferrule tip protection structure for an optical connector according to the fourth aspect, wherein the housing is temporarily attached to the ferrule that receives a biasing force by the elastic body. A first ferrule holding portion for restricting movement of the ferrule in the locked state; and the rear holder has a second ferrule holding portion for restricting movement of the ferrule instead of the housing in the main locked state. It is a feature.

  According to the present invention having such characteristics, when the rear holder is temporarily locked, the ferrule biased by the elastic body is received and held by the first ferrule holding portion of the housing. This restricts the movement of the ferrule. Then, when the rear holder is moved to the final locking position to form the final locking state for fitting with the counterpart optical connector, the ferrule is moved from the first ferrule holding portion of the housing to the rear as the rear holder moves. The receiving position is switched to the second ferrule holding part of the holder. According to the present invention, the extra urging force by the elastic body does not act on the rear holder via the ferrule before fitting with the counterpart optical connector.

  The ferrule tip protection structure in the optical connector of the present invention according to claim 6 is the ferrule tip protection structure in the optical connector according to claim 5, wherein the first ferrule holding portion and the second ferrule holding portion are flexible. It is characterized by being a lance-like structure having

  According to the present invention having such a feature, when the ferrule is stored in the rear holder, the second ferrule holding portion functions as a ferrule retaining member. And if the rear holder which accommodated this ferrule is accommodated in a housing with an elastic body, the 1st ferrule holding part will receive the ferrule urged | biased by an elastic body. The first ferrule holding part functions as a retaining ferrule. Due to this structure, the first ferrule holding part and the second ferrule holding part do not hinder the storage of the ferrule and the storage of the rear holder.

  According to the first aspect of the present invention, the ferrule tip in the optical connector can be better protected. Further, according to the present invention described in claims 2 and 3, there is an effect that the tip of the ferrule can be more reliably protected.

  According to the fourth aspect of the present invention, there is an effect that the tip of the ferrule in the optical connector can be better protected. Further, according to the present invention described in claim 5, there is an effect that it is possible to prevent an extra force from acting on the rear holder before the mating with the counterpart optical connector. Further, according to the present invention described in claim 6, in addition to not applying an excessive force to the rear holder, there is an effect that it can also function as a ferrule retaining member.

  Hereinafter, description will be given with reference to the drawings. FIG. 1 is an exploded perspective view of an optical connector showing an embodiment of the present invention and a mating optical connector into which the optical connector is fitted. 2 is a perspective view of the optical connector (temporary locking state) shown in FIG. 1 with the orientation changed, FIG. 3 is a cross-sectional view showing the optical connector temporarily locking state, and FIG. 4 is the main connector of the optical connector. It is sectional drawing which shows a stop state.

  In FIG. 1, reference numeral 1 indicates an optical connector. Reference numeral 2 indicates a mating optical connector which is a mating partner of the optical connector 1. The optical connector 1 includes a ferrule 4 provided at the end of an optical fiber 3, a spring 6 attached to a tip portion 5 of the ferrule 4, a rear holder 8 having a ferrule storage chamber 7, a rear holder storage chamber 9, and an optical connector. And a housing 11 having a connection space 10. The counterpart optical connector 2 is mounted on the outside of the counterpart housing 12, a FOT (Fiber Optic Transceiver) 13 (see FIGS. 3 and 4) housed in the counterpart housing 12, and the counterpart housing 12. And a shield case 14. Hereinafter, each component will be described with reference to FIGS. 1 to 4.

  The ferrule 4 is formed in a substantially cylindrical shape having an optical fiber storage chamber 15 therein. The ferrule 4 is formed so that the end face of the optical fiber 3 is exposed from the tip face 16. An annular intermediate flange 17 is formed in the outer middle of the ferrule 4. A rear flange 18 wider than the intermediate flange 17 is formed at the rear. The ferrule 4 is fixed to the end of the optical fiber 3 by caulking or an adhesive. The ferrule 4 may be made of metal or synthetic resin.

  The spring 6 is provided as an elastic body attached to the tip portion 5 of the ferrule 4. When the spring 6 is compressed, an urging force is generated in the restoring direction (if such an urging force is generated, an elastic body (such as rubber) other than the spring may be used), and one end of the spring 6 is While being in contact with a partition wall 30 described later of the housing 11, the other end is in contact with the intermediate flange 17 of the ferrule 4 (the contact with the rear holder 8 is also possible).

  The rear holder 8 is a member made of synthetic resin and has a shape as shown in the figure having a main body portion 19, a pair of rear holder side temporary locking portions 20, and a pair of rear holder side main locking portions 21. Is formed. The main body 19 has a ferrule storage chamber 7 and is formed in a substantially cylindrical shape. The main body 19 and the ferrule storage chamber 7 are formed such that the tip portion 5 (tip side) of the ferrule 4 is exposed when the ferrule 4 is stored. The main body 19 has a lance 23 with a locking projection 22 protruding into the ferrule storage chamber 7. The lance 23 is flexible and is adapted to hook the intermediate flange 17 of the ferrule 4 to prevent the ferrule 4 from coming off from the ferrule storage chamber 7. The rear portion 24 of the main body 19 is formed in a frame shape as shown in the figure.

  The pair of rear holder-side temporary locking portions 20 have flexibility and are formed in a U-shaped frame shape that extends along the axial direction of the rear holder 8. The pair of rear holder-side temporary locking portions 20 are formed so as to sandwich the main body portion 19 and continue to the rear portion 24. On the other hand, the pair of rear holder side main locking portions 21 have rigidity and are formed on the side of the housing 11 where a locking arm 25 described later is present. The pair of rear holder side main locking portions 21 are formed so as to be continuous with the rear portion 24 of the main body portion 19. In this embodiment, the pair of rear holder side main locking portions 21 are formed at positions orthogonal to the pair of rear holder side temporary locking portions 20 and at positions opposite to the lance 23. The pair of rear holder side main locking portions 21 are formed in a shape as shown in the figure having a recess.

  The housing 11 is a member made of synthetic resin, and includes a main body portion 26, a pair of housing side temporary locking portions 27, a pair of housing side main locking portions 28, and a locking arm 25 as illustrated. It is formed into a shape. The main body 26 has a rear holder storage chamber 9 and an optical connection space 10 and is formed in a cylindrical shape. The rear holder storage chamber 9 and the optical connection space 10 are separated by a partition 30 having a through hole 29. The size of the through hole 29 is set according to the diameter of the tip portion 5 of the ferrule 4. The size of the through hole 29 is set in accordance with the diameter of the spring 6.

  The pair of housing side temporary locking portions 27 are formed at predetermined positions outside the housing 11. Specifically, the rear holder 8 is formed at a position corresponding to the pair of rear holder-side temporary locking portions 20. The pair of housing-side temporary locking portions 27 are protrusions and are not particularly designated, but have a sliding inclined surface and a locking plane for the pair of rear holder-side temporary locking portions 20. A guide portion 31 is formed on the surface of the housing 11 where the pair of housing side temporary locking portions 27 are present. The guide portion 31 is formed to guide the pair of U-shaped rear holder side temporary locking portions 20. The rear holder 8 is guided by the guide portion 31 and stored in the housing 11 without rattling.

  The pair of housing side main locking portions 28 are formed at positions corresponding to the pair of rear holder side main locking portions 21 of the rear holder 8. The pair of housing side main locking portions 28 are protrusions and are not particularly denoted by reference numerals, but have a sliding inclined surface and a locking plane for the pair of rear holder side main locking portions 21. A portion of the housing 11 where the pair of housing side main locking portions 28 exist and the vicinity thereof are walls 32 as shown in the figure, and have flexibility to bend toward the rear holder storage chamber 9 side. The wall 32 is formed to have flexibility by slits (reference numerals omitted) on both sides. The wall 32 is configured to be a flexible release mechanism that will be described later.

  The locking arm 25 is formed on the side where the wall 32 is present. The locking arm 25 is a cantilever portion having flexibility. In this embodiment, the locking arm 25 is formed such that the base end portion is continuous around a position outside the optical connection space portion 10. Such a locking arm 25 includes a locking projection 33 that is hooked on the mating housing 12 of the mating optical connector 2, an operating portion 34 for operation, and a pressing-shaped pressing portion 35 that presses down the wall 32. Yes. The pressing part 35 is formed at a position opposite to the operation part 34. The pressing portion 35 is formed as a portion that acts on a release mechanism (wall 32) for permanent locking described later. Each part of the locking arm 25 excluding the pressing part 35 is formed for fitting / releasing the mating optical connector 2.

  The mating housing 12 constituting the mating optical connector 2 is formed into a box-like shape as shown in the figure by an insulating synthetic resin material. The mating housing 12 has a fitting space 36 and a fitting portion 37 for the optical connector 1, and a mounting portion 38 for the FOT 13. The counterpart housing 12 is formed so that the shield case 14 is attached to the outside. The fitting space 36 is formed in a size that allows the optical connector 1 to be inserted. The fitting portion 37 is formed so as to hook the locking arm 25 of the optical connector 1. The counterpart housing 12 is formed so as to be mounted on a circuit board, although not particularly shown.

  The FOT 13 is a member called a light emitting element module or a light receiving element module, for example, and is formed so that an element (not shown) exists behind the cylindrical guide portion 39. The element is mounted on the lead frame 40, and the periphery of the element is covered with a light transmissive resin 41. The lead frame 40 is electrically connected to the circuit board (not shown).

  The shield case 14 is formed by pressing a conductive metal plate. The shield case 14 has a function of electromagnetically shielding the FOT 13 from the outside. The shield case 14 is electrically connected to the circuit board (not shown) via a plurality of leg portions 42.

  In the above configuration, the ferrule 4 is fixed to the end of the optical fiber 3, the spring 6 is attached to the tip portion 5 of the ferrule 4, and the ferrule 4 is stored in the ferrule storage chamber 7 of the rear holder 8 in this state. Further, when the rear holder 8 storing the ferrule 4 is temporarily locked while being stored in the rear holder storage chamber 9 of the housing 11, the optical connector 1 before being fitted to the counterpart optical connector 2 is completed.

  The temporary locking will be described by the rear holder-side temporary locking portion 20 of the rear holder 8 passing over the housing-side temporary locking portion 27 of the housing 11 and passing therethrough. Specifically, the rear holder-side temporary locking portion 20 slides on the sliding inclined surface of the housing-side temporary locking portion 27 and is hooked on the locking plane immediately after getting over, thereby temporarily locking. When temporarily locked, the removal of the rear holder 8 housing the ferrule 4 is restricted.

  In the optical connector 1 in a state before being fitted to the counterpart optical connector 2, the spring 6 exists in the rear holder storage chamber 9. Therefore, the tip portion 5 of the ferrule 4 does not protrude into the optical connection space 10 in an unintended state. Further, in the optical connector 1 in a state before being fitted to the counterpart optical connector 2, the distal end portion 5 of the ferrule 4 exists in the rear holder storage chamber 9 of the housing 11. Therefore, the tip portion 5 of the ferrule 4 is protected against the outside.

  The counterpart optical connector 2 is attached to the circuit board (not shown), the optical connector 1 is inserted into the fitting space 36 in the counterpart housing 12 of the counterpart optical connector 2, and the optical connector 1 is inserted into the fitting portion 37 of the counterpart housing 12. When the locking arm 25 is hooked and locked, the fitting between the optical connectors is completed. Thereafter, in the optical connector 1, when the rear holder 8 housing the ferrule 4 is moved to the final locking position to perform the final locking, the tip portion 5 of the ferrule 4 protrudes into the optical connection space portion 10. The distal end portion 5 protruding into the optical connection space portion 10 is inserted into the guide portion 39 of the FOT 13, thereby completing the optical connection between the optical connectors.

  The main locking is performed when the rear holder side main locking portion 21 of the rear holder 8 passes over and passes over the housing side main locking portion 28 of the housing 11. Specifically, the rear holder side main locking portion 21 slides on the sliding inclined surface of the housing side main locking portion 28 and pushes down the wall 32, and immediately after getting over the locking plane of the housing side main locking portion 28. The main locking is achieved by being caught on. When the main locking is performed, the movement of the rear holder 8 housing the ferrule 4 is restricted (at this time, the ferrule 4 receives the action of the compressed spring 6).

  In the case of releasing the fitting between the optical connectors, when the operating portion 34 of the locking arm 25 is pressed with a finger, the fitting between the fitting portion 37 of the counterpart housing 12 and the locking arm 25 of the optical connector 1 is released. At this time, the pressing portion 35 of the locking arm 25 abuts against the wall 32 and pushes it down. Then, the main locking of the rear holder side main locking portion 21 of the rear holder 8 and the housing side main locking portion 28 of the housing 11 is released, and the rear holder 8 storing the ferrule 4 is temporarily moved by the action of the spring 6. Moves automatically to the locking side. In the optical connector 1 in this state, the tip portion 5 of the ferrule 4 exists in the rear holder storage chamber 9 of the housing 11. Therefore, the tip portion 5 of the ferrule 4 is protected against the outside.

  As described above with reference to FIGS. 1 to 4, according to the present invention, the tip of the ferrule 4 in the optical connector 1 can be better and more reliably protected.

  Next, another embodiment of the present invention will be described with reference to FIGS. 5 is an exploded perspective view of an optical connector showing another embodiment and a mating optical connector into which the optical connector is fitted, FIG. 6 is an exploded perspective view of the optical connector, and FIG. 7 is an exploded perspective view of the mating optical connector. FIG. 8 is a cross-sectional view of the optical connector (temporary locking state) showing a state immediately before being fitted to the mating optical connector, and FIG. 9 is an optical connector (main locking) showing a state of being fitted to the mating optical connector. It is sectional drawing of a state.

  In FIG. 5, reference numeral 51 indicates an optical connector. Reference numeral 52 indicates a mating optical connector to which the optical connector 51 is fitted. The optical connector 51 includes a ferrule 54 provided at the end of the optical fiber 53, a spring 56 attached to a tip portion 55 of the ferrule 54, a rear holder 58 having a ferrule storage chamber 57, a rear holder storage chamber 59 and an optical connector. And a housing 61 having a connection space 60. The counterpart optical connector 52 includes a counterpart housing 62, a FOT (Fiber Optic Transceiver) 63 accommodated in the counterpart housing 62, and a shield case 64 attached to the outside of the counterpart housing 62. It is configured.

  Regarding the names of the constituent members, for example, the whole shown in FIG. 5 is replaced with an optical connector (that is, both the optical connector 51 and the counterpart optical connector 52 are replaced with optical connectors), and the rear holder 58 is replaced with a female housing. 61 may be read as a front cover, and the counterpart housing 62 may be read as a header housing.

  Hereinafter, each component will be described with reference to FIGS. Here, an arrow P in the figure is defined as an up-down direction, an arrow Q is defined as a left-right direction, and an arrow R is defined as a front-rear direction.

  The ferrule 54 is formed in a substantially cylindrical shape having an optical fiber storage chamber 65 therein. The ferrule 54 is formed so that the end face of the optical fiber 53 is exposed from the tip face 66. An annular intermediate flange 67 is formed in the outer middle of the ferrule 54. A rear flange 68 wider than the intermediate flange 67 is formed at the rear. The ferrule 54 may be made of metal or synthetic resin. When the ferrule 54 is made of metal, the ferrule 54 is fixed to the end of the optical fiber 53 by caulking. On the other hand, in the case of a synthetic resin, it is fixed to the end of the optical fiber 53 by an adhesive or laser welding.

  The spring 56 is provided as an elastic body attached to the tip portion 55 of the ferrule 54 (corresponding to an elastic body described in claims). The spring 56 generates an urging force in the restoring direction when compressed (if such an urging force is generated, it may be an elastic body (for example, rubber) other than the spring), and one end thereof is While abutting against a partition wall 85 (to be described later) of the housing 61, the other end is in contact with an intermediate flange 67 of the ferrule 54. The spring 56 is provided to urge the ferrule 54. In this embodiment, the spring 56 has a shorter length than the tip portion 55 of the ferrule 54.

  The rear holder 58 is a synthetic resin member, and includes a cylindrical portion 69 extending in the front-rear direction, a frame-shaped portion 70 coupled to the rear portion of the cylindrical portion 69, and upper and lower portions of the frame-shaped portion 70. A pair of rear holder side temporary locking portions 71, 71 extending forward from the front, a wall portion 72 extending forward from the left portion of the frame-like portion 70, and locking extending to the rear by being coupled to the front end of the wall portion 72. Arm 73. In the rear holder 58, a ferrule storage chamber 57 is formed across the cylindrical portion 69 and the frame-like portion 70.

  The cylindrical portion 69 is formed in a substantially cylindrical shape. In such a cylindrical portion 69, slits 74 and 75 are formed. The slit 74 is formed so as to cut out the right part of the cylindrical part 69 straight. Further, the slit 74 is formed with a predetermined width (formed with a width that allows insertion of a first ferrule holding portion 82 described later). The slit 74 is formed so as to cut out the right part of the frame-like part 70. A slit 75 is formed on the opposite side of the slit 74. The slit 75 is disposed at the left side of the cylindrical portion 69 and is formed to be parallel to the slit 74. The slit 75 is formed for a second ferrule holding portion 76 described later.

  The frame-like portion 70 is formed in a substantially rectangular shape. A round through-hole is formed in the center of the frame-like portion 70. The round through hole is formed so as to communicate with the internal space of the cylindrical portion 69. The ferrule storage chamber 57 includes such a round through hole and an internal space. The ferrule storage chamber 57 is formed so that the tip end portion 55 (tip end side) of the ferrule 54 is exposed when the ferrule 54 is stored. That is, the ferrule storage chamber 57 is formed to be shorter than the entire length of the ferrule 54.

  The rear holder-side temporary locking portions 71 and 71 have flexibility. The rear holder side temporary locking portions 71 and 71 are formed to have a U-shaped frame shape extending forward. The rear holder side temporary locking portions 71 and 71 are arranged and formed so as to be spaced from the cylindrical portion 69 (between the rear holder side temporary locking portions 71 and 71 and the cylindrical portion 69. , A part of the housing 61 is inserted). The rear holder side temporary locking portions 71, 71 are formed so that projecting housing side temporary locking portions 81, 81 (to be described later) of the housing 61 are hooked on the inner ends of the rear holder side. The rear holder-side temporary locking portions 71, 71 are formed on the inner side so that protruding housing-side temporary locking portions 81, 81 described later can move in the front-rear direction. The rear holder side temporary locking portions 71 and 71 are formed to have the necessary flexibility when getting over the protruding housing side temporary locking portions 81 and 81 described later.

  The wall portion 72 has a flat plate shape and is formed to be continuous with the cylindrical portion 69 at the slit 75 portion. The wall portion 72 is formed to be longer forward than the tubular portion 69. The wall 72 is formed so as to cover an opening 83 described later of the housing 61. In such a wall portion 72, a flexible lance-shaped second ferrule holding portion 76 is formed. The second ferrule holding portion 76 is arranged and formed so that the base end portion is located in the vicinity of the frame-like portion 70 and the tip end portion passes through the slit 57 and protrudes into the internal space of the cylindrical portion 69. . The second ferrule holding portion 76 is formed so as to be inclined with respect to the wall portion 72, in other words, the tip portion is directed obliquely forward.

  When the ferrule 54 is stored in the ferrule storage chamber 57, the second ferrule holding unit 76 is able to restrict the movement of the second ferrule holding unit 76 in the pull-out direction by being caught by the intermediate flange 67 of the ferrule 54. It has become. Further, the second ferrule holding portion 76 can receive the intermediate flange 67 of the ferrule 54 biased by the spring 56 when a later-described final locking state of the rear holder 58 is formed.

  The locking arm 73 is formed in a cantilever shape having flexibility. The locking arm 73 is formed with a locking projection 77 that is hooked on the mating housing 62 of the mating optical connector 52 and an operation portion 78 that is an operation portion. The locking arm 73 is formed for fitting / releasing the optical connector 51 and the mating optical connector 52. The locking arm 73 is also used when a rear locking state of the rear holder 58 described later is formed.

  The locking arm 73 is protected by a pair of protective walls 79 and 79 (only one is shown) protruding from the outer surface of the wall portion 72. One of the pair of protective walls 79, 79 is inserted into and guided by a guide portion 90, which will be described later, of the counterpart housing 62 when mated with the counterpart optical connector 52.

  The housing 61 is a synthetic resin member, and includes a main body 80 having a rear holder storage chamber 59 and an optical connection space 60 that open in the front-rear direction, and a pair of housing-side temporary members formed in the main body 80. Stop portions 81, 81 and a first ferrule holding portion 82 that is also formed in the main body portion 80 are included. The main body 80 is formed in a rectangular cylindrical shape. The main body 80 is formed so that the rear holder storage chamber 59 and the optical connection space 60 are continuous therewithin. The main body 80 is formed in a stepped shape by the rear holder storage chamber 59 and the optical connection space 60.

  The portion where the rear holder storage chamber 59 exists is formed in a substantially large cylindrical shape having an opening 83 that opens the left wall. Further, the portion where the optical connection space 60 exists is formed in a substantially small cylindrical shape. When the cylindrical portion 69 of the rear holder 58 is inserted into the rear holder storage chamber 59 and stored, the opening 83 is covered with the wall portion 72 of the rear holder 58.

  The rear holder storage chamber 59 and the optical connection space 60 are formed to be separated by a partition wall 85 having a through hole 84. The size of the through hole 84 is set in accordance with the diameter of the tip portion 55 of the ferrule 54. The size of the through hole 84 is set in accordance with the diameter of the spring 56. The rear holder storage chamber 59 is formed as a portion in which the cylindrical portion 69 of the rear holder 58 that stores the ferrule 54 is inserted and stored. Further, the optical connection space 60 is formed as a portion in which the tip portion 55 of the ferrule 54 protrudes through the through-hole 84 in the final locking state of the rear holder 58 described later.

  The pair of housing-side temporary locking portions 81, 81 has a protruding shape, and is formed on the upper wall and the lower wall of the main body 80 one by one. The pair of housing-side temporary locking portions 81, 81 are portions for forming a temporary locking state of the rear holder 58, and are arranged in consideration of the shape and position of the rear holder-side temporary locking portions 71, 71. Is formed. The pair of housing side temporary locking portions 81, 81 have no particular reference numerals, but have a sliding inclined surface and a locking plane for the pair of rear holder side temporary locking portions 71, 71.

  A guide portion 86 is formed on the surface where the pair of housing side temporary locking portions 81, 81 are present. The guide portion 86 is formed to guide the U-shaped rear holder side temporary locking portions 71, 71. The rear holder 58 is guided by the guide portion 86, and the cylindrical portion 69 of the rear holder 58 is guided by the entrance (rear opening) of the rear holder storage chamber 59 so that the rear holder 58 is stored in the housing 61 without rattling. It has become.

  The first ferrule holding part 82 is formed on the right wall of the main body part 80. The first ferrule holding part 82 is formed in a flexible lance shape. The first ferrule holding portion 82 is formed with a claw-like protrusion that protrudes toward the rear holder storage chamber 59. This protruding portion is formed at the tip of the first ferrule holding portion 82 and can be hooked on the intermediate flange 67 of the ferrule 54 to restrict movement in the removal direction. The protruding portion is arranged at the position of the rear opening of the rear holder storage chamber 59.

  The first ferrule holding part 82 is arranged in accordance with the position of the slit 74 of the rear holder 58. The first ferrule holding part 82 has a sliding inclined surface with respect to the intermediate flange 67 of the ferrule 54 and a locking flat surface, although not particularly designated. In the first ferrule holding part 82, when the rear holder 58 is housed in the housing 61 as shown in the drawing together with the spring 56 to form a temporary locking state, the protruding portion receives the intermediate flange 67 of the ferrule 54. The ferrule 54 biased by the spring 56 is received by the intermediate flange 67 by the protruding portion of the first ferrule holding portion 82.

  The mating housing 62 constituting the mating optical connector 52 is formed into a box-like shape as shown in the figure by an insulating synthetic resin material. The mating housing 62 includes a fitting space 87 and a fitting portion 88 for the optical connector 51, and a mounting portion 89 for the FOT 63. The counterpart housing 62 is formed so that the shield case 64 can be attached to the outside. The fitting space 87 is formed in a size that allows the optical connector 51 to be inserted. In the fitting space 87, a guide portion 90 that guides the protective wall 79 of the rear holder 58 is formed. The fitting portion 88 is formed so that the locking arm 73 of the optical connector 51 is hooked. The counterpart housing 62 is formed so as to be mounted on a circuit board, although not particularly shown.

  The FOT 63 is a member called a light emitting element module or a light receiving element module, for example, and is formed so that an element (not shown) exists behind the cylindrical guide portion 91. The element is mounted on a lead frame 92, and the periphery of the element is covered with a light transmissive resin 93. The lead frame 92 is electrically connected to the circuit board (not shown).

  The shield case 64 is formed by pressing a conductive metal plate. The shield case 64 has a function of electromagnetically shielding the FOT 63 from the outside. The shield case 64 is electrically connected to the circuit board (not shown) via a plurality of leg portions 94.

  In the above configuration, the ferrule 54 is fixed to the end of the optical fiber 53, the spring 56 is attached to the tip portion 55 of the ferrule 54, and in this state, the ferrule 54 is stored in the ferrule storage chamber 57 of the rear holder 58, Further, when the rear holder 58 storing the ferrule 54 is temporarily locked while being stored in the rear holder storage chamber 59 of the housing 61, the optical connector 51 before being fitted to the counterpart optical connector 52 is completed.

  The temporary locking will be described by the rear holder side temporary locking portions 71 and 71 of the rear holder 58 getting over the housing side temporary locking portions 81 and 81 of the housing 61 and passing through. Specifically, the rear holder side temporary locking portions 71, 71 slide on the sliding inclined surfaces of the housing side temporary locking portions 81, 81 and are hooked on the locking plane immediately after getting over, thereby temporarily locking. The When temporarily locked, the removal of the rear holder 58 containing the ferrule 54 is restricted.

  In the process of temporary locking, the intermediate flange 67 of the ferrule 54 housed in the rear holder 58 abuts on the protruding portion of the first ferrule holding portion 82 of the housing 61 to bend the first ferrule holding portion 82. . When the intermediate flange 67 passes through the protruding portion of the first ferrule holding portion 82, the ferrule 54 itself is also locked by the housing 61. Since the spring 56 exists, the ferrule 54 biased by the spring 56 is received and held by the first ferrule holding portion 82 of the housing 61. The movement of the ferrule 54 in the front-rear direction is restricted by the spring 56 and the first ferrule holding portion 82.

  In the optical connector 51 in a state before being fitted to the counterpart optical connector 52, the spring 56 is present in the rear holder storage chamber 59. Therefore, the optical connection space portion 60 without the distal end portion 55 of the ferrule 54 being intended. It does not protrude into. Further, in the optical connector 51 in a state before being fitted to the counterpart optical connector 52, the tip portion 55 of the ferrule 54 exists in the rear holder storage chamber 59 of the housing 61. Protected against the outside.

  The counterpart optical connector 52 is attached to the circuit board (not shown), the optical connector 51 is inserted into the fitting space 87 in the counterpart housing 62 of the counterpart optical connector 52, and the counterpart holder is moved while moving the rear holder 58 forward. When the locking arm 73 (of the rear holder 58) of the optical connector 51 is hooked and engaged with the fitting portion 88 of the housing 62, the final locking state of the rear holder 58 is formed and the optical connectors are fitted together. Complete.

  The main locking state of the rear holder 58 will be described. The locking position of the locking arm 73 is the main locking position of the rear holder 58. When the rear holder 58 is moved to this position while the spring 56 is compressed, the ferrule 54 in which the tip portion 55 has been protected from the outside so far is optically connected to the tip portion 55 as the rear holder 58 moves. Project into the space 60. When the distal end portion 55 of the ferrule 54 protrudes into the optical connection space portion 60, the distal end portion 55 is inserted into the cylindrical guide portion 91 of the FOT 63, and the end face of the optical fiber 53 faces the element existing in the back. Thereby, the optical connection between the optical connectors is completed.

  In the movement of the rear holder 58 to the final locking position, the receiving position of the ferrule 54 is switched from the first ferrule holding portion 82 of the housing 61 to the second ferrule holding portion 76 of the rear holder 58. This means that before the optical connector 51 is engaged with the mating optical connector 52, the extra urging force by the spring 56 does not act on the rear holder 58 via the ferrule 54. Therefore, in the rear holder 58 before the optical connectors are fitted to each other, the occurrence of breakage due to the urging force of the spring 56 is prevented. This point will be described later with reference to a comparative example.

  In the case of releasing the fitting between the optical connectors, when the operating portion 78 of the locking arm 73 is pressed with a finger, the fitting between the fitting portion 88 of the counterpart housing 62 and the locking arm 73 of the optical connector 51 is released. When the fitting is released, the rear holder 58 in which the ferrule 54 is housed automatically moves to the side that forms the temporarily locked state by the action of the spring 56. In the optical connector 51 in this state, the tip portion 55 of the ferrule 54 exists in the rear holder storage chamber 59 of the housing 61. Therefore, the tip portion 55 of the ferrule 54 is protected against the outside.

  As described above with reference to FIGS. 5 to 9, according to the present invention, the tip of the ferrule 54 in the optical connector 51 can be better and more reliably protected.

  Subsequently, the receiving position of the ferrule 54 is switched from the first ferrule holding portion 82 of the housing 61 to the second ferrule holding portion 76 of the rear holder 58, so that an excessive biasing force does not act on the rear holder 58. The effect will be supplementarily described with reference to FIGS. 10 is a cross-sectional view showing a state immediately before fitting an optical connector as a comparative example (temporary locking state), and FIG. 11 is a cross-sectional view showing a state when the optical connector is fitting as a comparative example (finally locked state). FIG. It should be noted that basically the same components and portions as those described above are denoted by the same reference numerals, and description thereof is omitted.

  10 and 11, an optical connector 101 as a comparative example is fitted to the above-described counterpart optical connector 52, and includes a ferrule 54 provided at the end of the optical fiber 53 and a tip portion of the ferrule 54. 55, a rear holder 103 having a ferrule storage chamber 102, and a housing 105 having a rear holder storage chamber 104 and an optical connection space 60.

  The rear holder 103 is different from the above-described rear holder 58 (see FIGS. 5 to 9; hereinafter, refer to FIGS. 5 to 9 as necessary) in the following points. That is, as can be seen by referring to the drawing, the slit 74 is present in the rear holder 58 described above, but the rear holder 103 in the comparative example is not present. Further, the above-described rear holder 58 has the second ferrule holding portion 76, but the rear holder 103 in the comparative example is different in that it does not exist. On the other hand, the rear holder 103 in the comparative example has a lance 23 (see FIGS. 1, 3 and 4, which has the same function), and the locking projection 22 of the lance 23 is a ferrule storage chamber 102. The point that protrudes is different.

  The housing 105 is also different from the above-described housing 61 (see FIGS. 5 to 9, hereinafter referring to FIGS. 5 to 9 as necessary) in the following points. That is, as can be seen from the drawing, the first ferrule holding portion 82 is present in the housing 61 described above, but the housing 105 in the comparative example is not present. The rear holder storage chamber 104 in the comparative example does not have a portion for locking the ferrule 54.

  In the above configuration, the spring 56 is attached to the tip portion 55 of the ferrule 54, and in this state, the ferrule 54 is stored in the ferrule storage chamber 102 of the rear holder 103 and locked by the lance 23, and further the ferrule 54 is stored. When the rear holder 103 is temporarily locked while the locked rear holder 103 is housed in the rear holder storage chamber 104 of the housing 105, the light as a comparative example is in a state before being fitted to the counterpart optical connector 52. The connector 101 is completed.

  The temporary locking of the rear holder 103 will be described. The rear holder-side temporary locking portions 71 and 71 (see FIG. 6) of the rear holder 103 get over the housing-side temporary locking portions 81 and 81 (see FIG. 6) of the housing 105. It is done by passing.

  The optical connector 101 as a comparative example has a structure in which the ferrule 54 biased by the spring 56 is received by the lance 23 of the rear holder 103. That is, in the optical connector 101 as a comparative example, an extra urging force by the spring 56 acts on the rear holder 103 from the time when this is completed.

  The counterpart optical connector 52 is attached to the circuit board (not shown), the optical connector 101 as a comparative example is inserted into the fitting space 87 in the counterpart housing 62 of the counterpart optical connector 52, and the rear holder 103 is moved forward. When the locking arm 73 of the rear holder 103 is hooked and locked to the fitting portion 88 of the mating housing 62 while being moved, the final locking state of the rear holder 103 is formed and the fitting between the optical connectors is completed. To do.

  In the optical connector 101 as a comparative example, when the final locking state of the rear holder 103 is formed, the spring 56 is compressed more than in the temporary locking state, whereby a larger urging force acts on the lance 23. It will be.

  What is worrisome here is that the optical connector 101 as a comparative example may be assembled immediately after being assembled with the counterpart optical connector 52, but the optical fiber 101 as the comparative example is assembled for a while and then the counterpart optical When fitting with the connector 52, there is a concern that the load applied to the lance 23 increases. If an attempt is made to increase the shape of the lance 23 in consideration of the load, it is difficult to secure a space in the rear holder 103 and the housing 105, and in some cases, it is necessary to consider increasing the size of the entire optical connector. Is also a concern.

  In the optical connector 51 according to the present invention (the optical connector 51 described with reference to FIGS. 5 to 9), before the mating with the counterpart optical connector 52, an excessive biasing force by the spring 56 is passed through the ferrule 54. Since the structure is such that the ferrule 54 does not act on the rear holder 58, that is, the receiving position of the ferrule 54 is switched from the first ferrule holding part 82 of the housing 61 to the second ferrule holding part 76 of the rear holder 58, the spring Problems caused by the urging force of 56 (for example, occurrence of breakage) are significantly reduced compared to the comparative example.

  As described above, the optical connector 51 of the present invention has two major features: better protection of the tip portion 55 of the ferrule 54 and prevention of excessive force from acting on the rear holder 58.

  In addition, it goes without saying that the present invention can be variously modified without departing from the spirit of the present invention.

It is a disassembled perspective view of the optical connector which shows one embodiment of this invention, and the other party optical connector which this optical connector fits. It is a perspective view in the state where the direction of the optical connector (temporary locking state) of Drawing 1 was changed. It is sectional drawing which shows the temporary latching state of an optical connector. It is sectional drawing which shows the main latching state of an optical connector. It is a disassembled perspective view of the optical connector which shows other one Embodiment of this invention, and the other party optical connector which this optical connector fits. It is a disassembled perspective view of an optical connector. It is a disassembled perspective view of the other party optical connector. It is sectional drawing of the optical connector (temporary latching state) which shows the state just before fitting to the other party optical connector. It is sectional drawing of the optical connector (this latching state) which shows the state fitted to the other party optical connector. It is sectional drawing which shows the state (temporary latching state) just before fitting of the optical connector as a comparative example. It is sectional drawing which shows the state at the time of the fitting of the optical connector as a comparative example (main locking state).

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Optical connector 2 Opposite side optical connector 3 Optical fiber 4 Ferrule 5 Tip part (tip side)
6 Spring (elastic body)
7 Ferrule storage room 8 Rear holder 9 Rear holder storage room 10 Optical connection space part 11 Housing 12 Opposite side housing 13 FOT
14 Shield case 20 Rear holder side temporary locking part (locking mechanism)
21 Rear holder side main locking part (locking mechanism)
23 Lance 25 Locking arm 27 Housing side temporary locking part (locking mechanism)
28 Housing side main locking part (locking mechanism)
29 Through-hole 30 Bulkhead 32 Wall (Release mechanism)
35 Pressing part 39 Guide part 40 Lead frame 41 Light transmissive resin 42 Leg part 51 Optical connector 52 Opposite side optical connector 53 Optical fiber 54 Ferrule 55 Tip part (tip side)
56 Spring (elastic body)
57 Ferrule storage chamber 58 Rear holder 59 Rear holder storage chamber 60 Optical connection space 61 Housing 62 Mating housing 63 FOT
64 Shield case 69 Cylindrical portion 70 Frame-shaped portion 71 Rear holder side temporary locking portion (locking mechanism)
72 Wall part 73 Locking arm 74, 75 Slit 76 Second ferrule holding part 77 Locking projection 78 Operation part 80 Body part 81 Housing side temporary lock part (locking mechanism)
82 First ferrule holding part 87 Fitting space 88 Fitting part 89 Mounting part 91 Guide part

Claims (6)

A ferrule to be attached to the optical fiber terminal, a rear holder having a ferrule storage chamber, and a housing having a rear holder storage chamber and an optical connection space,
The ferrule storage chamber has a structure in which the tip end side of the ferrule is exposed in the storage state of the ferrule,
The rear holder and the housing have a structure further including a plurality of locking mechanisms for temporarily locking and permanently locking the rear holder in the storing process,
The rear holder storage chamber has a structure in which the tip side of the ferrule is in a storage state in a temporarily locked state of the rear holder,
The ferrule tip protection structure in an optical connector, wherein the optical connection space portion has a structure in which the tip of the ferrule protrudes when the rear holder is fully locked. In the ferrule tip protection structure in the optical connector according to claim 1,
The housing further includes a release mechanism for the main locking, and the housing and the ferrule are temporarily locked by releasing the main locking in the rear holder storage chamber of the housing. A ferrule tip protection structure in an optical connector, characterized in that an elastic body is provided to move to the side. In the ferrule tip protection structure in the optical connector according to claim 2,
The ferrule tip protection structure for an optical connector, wherein the housing is a structure for fitting / releasing the mating optical connector and further having a locking arm acting on the releasing mechanism. A ferrule to be attached to the optical fiber terminal, a rear holder having a ferrule storage chamber, a housing having a rear holder storage chamber and an optical connection space, and a biasing force of the rear holder interposed between the housing and the rear holder With an elastic body,
The ferrule storage chamber has a structure in which the tip end side of the ferrule is exposed in the storage state of the ferrule,
The rear holder and the housing have a structure further having a plurality of locking mechanisms for temporarily locking the rear holder during the storage process in the rear holder storage chamber.
The rear holder storage chamber has a structure in which the tip side of the ferrule is in a storage state in a temporarily locked state of the rear holder,
The rear holder is a structure that further includes a locking arm for fitting and releasing the mating with the counterpart optical connector and for forming a final locking state of the rear holder,
The ferrule tip protection structure in an optical connector, wherein the optical connection space portion has a structure in which the tip of the ferrule protrudes when the rear holder is fully locked. In the ferrule tip protection structure in the optical connector according to claim 4,
The housing has a first ferrule holding portion for restricting movement of the ferrule in the temporarily locked state with respect to the ferrule that receives an urging force from the elastic body, and the rear holder is in the main locked state in the housing. A ferrule tip protection structure for an optical connector, comprising: a second ferrule holding part that restricts the movement of the ferrule instead. In the ferrule tip protection structure in the optical connector according to claim 5,
The ferrule tip protection structure in an optical connector, wherein the first ferrule holding part and the second ferrule holding part have a flexible lance structure.

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