JP2006184491A - Field assembly optical connector - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To realize alignment and holding of optical fibers at the same time without using an external tool for assembly. <P>SOLUTION: In the field assembly optical connector, by being installed onto a frame 5, a bush 3 is moved to a holding member 4 side where a cable clamp unit 21 can be mounted so that mutual contact between a chuck 7 and the bush 3 is released. On the other hand, a lock member 11 is provided so that by removing from the frame 5, the bush 3 is moved to a ferrule 2 side to make a mutual contact between the chuck 7 and the bush 3. A knob section 6 having an opening section, into which the lock member 11 can be inserted, is externally fixed to the frame 5. An engagement section main body 31, which has a cover body 32 that can be opened and closed to confirm the deflecting condition of a secondary coated optical fiber P core after mounting a cable clamp unit 21, is provided on the back tip part side of the holding member 4 that is mounted to the back tip side of the frame 5 to which the knob section 6 is externally mounted. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a field-assembled optical connector that employs a mechanical splicing system that abuts the end faces of two bare fibers in connection of optical fibers and presses and fixes the vicinity of the butt joint portion from the side of the bare fibers. About.

In the conventional mechanical splice method, an optical fiber core wire is introduced into the splice member from the rear, the first optical fiber and the second optical fiber exposed from the tip of the optical fiber core wire are abutted, and the splice member is clamped. In the case of fixing to the optical fiber core wire, a first refractive index matching material is injected into a region where the rear end face of the first optical fiber and the front end face of the second optical fiber are abutted, and a second splicing member provided on the splice member A technique is provided in which a second refractive index matching material is injected into the light introducing portion, and a wedge insertion slit is formed on one side surface of a splice member including a base member and a cover member.
JP-A-11-160563

  However, in the conventional optical fiber connection, the refractive index matching material is incorporated in two dispersed states, and the wedge is inserted and fixed in the wedge insertion slit of the splice member in this state. In addition to being troublesome, since it is necessary to push open the splice member against the pressing force of the clamp member, a dedicated external tool for pushing open is required at this time.

  Therefore, the present invention was created in view of the existing circumstances as described above, so that alignment between both optical fibers and fiber holding can be performed simultaneously without using an external tool for assembly. Thus, an object of the present invention is to provide an on-site assembly optical connector that can be easily assembled in a short time.

  In order to achieve the above object, according to the present invention, the bush is moved to the holding member side where the cable clamp unit can be mounted by inserting it into the frame to release the close contact between the chuck and the bush. It is a field assembly optical connector that includes a locking member that moves the bush to the ferrule side by being removed from the chuck and makes the bush and the bush come into close contact with each other, and the frame has an opening through which the locking member can be inserted. It is characterized in that the knob is fixed to the exterior.

  The lock member may include bifurcated legs that can be inserted into the insertion holes of the frame on both sides of the lock plate.

  On the rear end side of the holding member attached to the rear end side of the frame on which the knob portion is externally mounted, the fitting portion has an openable / closable lid for confirming the bending state of the optical fiber core wire after the cable clamp unit is attached. It can comprise a main body.

  The cable clamp unit is composed of a body part having a guide groove for an optical fiber core and a cover part that can be opened and closed with a guide groove facing the guide groove of the body part, and either the body part or the cover part. Can be provided with a protrusion for holding the optical fiber cable.

  Specifically, a ferrule having a fiber hole having both ends opened in the axial direction and having a recess reaching the fiber hole on the side where the butt connection part of the inserted optical fiber is located, and the butt connection A chuck that has a tapered surface on the upper surface side from the front to the rear, and a fitting hole that has a partially tapered inner surface so as to be in close contact with the tapered surface of the chuck from the outside. Is formed at the front end, and a bushing formed with a guide fiber hole coaxially communicating with the fiber hole of the ferrule, and a fitting hole fitted into the bush from the outside is formed at the front end, and the guide fiber hole of the bush A tapered fiber hole that is coaxially connected to the rear end portion is formed at the rear end portion, and a holding member that can be attached to the cable clamp unit is provided at the rear end portion. Move to the member side to release the close contact between the taper surface of the chuck and the taper inner surface of the fitting hole of the bush, while moving the bush to the ferrule side by removing the taper surface of the chuck and the fitting hole of the bush. A field assembly optical connector comprising a lock member for bringing taper inner surfaces into close contact with each other, wherein a grip portion having an opening through which the lock member can be inserted is externally fixed to the frame.

  In the field assembly optical connector according to the present invention configured as described above, the lock member is inserted between the frame and the bush through the opening of the knob to move the bush toward the holding member. Release the clamping force on the chuck. Then, after inserting and abutting the optical fiber, the lock member is pulled out to move the bush toward the ferrule side, thereby applying a tightening force to the chuck, and the taper surface of the chuck and the taper of the fitting hole of the bush. The inner surfaces are brought into close contact with each other and the abutting connection portion is pressed on the lower surface side of the chuck, and fiber alignment and fiber holding are performed simultaneously.

  That is, inside the bush, one side is in contact with the ferrule and the other side is in contact with the taper surface of the chuck so that the fiber can be tightened. At this time, since the ferrule pressing, the fiber alignment and the fiber fixing are performed simultaneously, the movement of the optical fiber due to the ferrule back can be absorbed in the rear space.

  Since the present invention is configured as described above, the optical fiber can be aligned and held at the same time without using an external tool for assembly. Assembly can be performed. Further, since the lock member can be inserted / removed with the knob part externally attached to the frame, the work of attaching the knob part in the field can be omitted, and the workability can be improved.

  That is, this is because the present invention moves the bush to the holding member side where the cable clamp unit can be attached by inserting it into the frame to release the chuck and the bush from each other, while removing it from the frame. It is a field assembly optical connector that includes a lock member that moves the bushing toward the ferrule side to bring the chuck and the bush into close contact with each other, and the frame has a knob with an opening that allows the locking member to be inserted. As a result, it is easy to align the cores of both optical fibers without removing the knob, and at the same time, it is related to variations in the thickness of the cores inserted into the fiber holes. The core wire can always be held with a constant pressing force.

  In addition, the lock member is provided with bifurcated legs that can be inserted into the insertion hole of the frame without interfering with the bush or chuck on both sides of the lock plate, so that the bush, chuck, and holding member are each processed. Therefore, the connector can be manufactured at a low cost with a reduced material cost.

  On the rear end side of the holding member attached to the rear end side of the frame on which the knob portion is externally mounted, the fitting portion has an openable / closable lid for confirming the bending state of the optical fiber core wire after the cable clamp unit is attached. Since the main body is provided, the bending state of the optical fiber core wire after the cable clamp unit is mounted can be easily confirmed.

  The cable clamp unit is composed of a body part having a guide groove for an optical fiber core and a cover part that can be opened and closed with a guide groove facing the guide groove of the body part, and either the body part or the cover part. Is provided with a protrusion for holding the optical fiber cable, so that the optical fiber can be easily attached to the cable clamp unit, and the optical fiber can be firmly fixed. In addition, the cable clamp unit can be manufactured at a low cost with a reduced material cost.

  DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The best mode for carrying out the present invention will be described below with reference to the drawings. Reference numeral 1 shown in the figure is a light that is inserted into a ferrule 2 by being abutted against a counterpart ferrule (not shown). This is an on-site assembling type optical connector having a substantially rectangular shape for connection with the fiber P. As shown in FIG. 1, the optical connector 1 includes a bush 3 into which the distal end portion of the ferrule 2 is inserted, a holding member 4 inserted so that the bush 3 is slightly movable in the front-rear direction, and a holding member 4. The frame 5 is generally composed of a frame 5 and a knob 6 that covers the outside of the frame 5.

  As shown in FIGS. 1 and 7, the ferrule 2 has a fiber hole 2 </ b> A having both ends opened in a rectangular shape in the axial direction, and is located at the abutting connection portion C of the optical fiber P to be inserted. A rectangular recess 8 reaching the fiber hole 2A is provided on the rear side. In the fiber hole 2A, the optical fiber P 'is inserted in advance on the front side of the optical fiber P to the butting connection portion C, and the front end of the ferrule 2 is polished.

  A plate-like chuck 7 having a tapered surface 7A inclined forward from the front part toward the rear part on the upper surface side is placed so as to coincide with the concave part 8, so that the core wire butting connection part C of the optical fiber P is applied. Is pressed on the lower surface side so that the optical fiber P ′ inserted in the fiber hole 2A in advance and the optical fiber P to be inserted can be aligned and held. At the rear end of the ferrule 2, a diverging guide fiber hole 2B having a diameter larger than that of the fiber hole 2A is formed.

  Further, the bush 3 is provided with a bush 3 formed with a guide fiber hole 3A having a diameter larger than that of the fiber hole 2A of the ferrule 2 and widening toward the opening end on the rear end side. A rectangular fitting hole 9 having a tapered inner surface 9A in part is formed in the front end portion so as to be in close contact with the tapered surface 7A from the outside, and communicates coaxially with the fiber hole 2A of the ferrule 2 after assembly. It is.

  Further, the holding member 4 having a substantially rectangular shape having a tapered fiber hole 4A having a diameter larger than that of the fiber hole 2A and further widening toward the opening end on the rear end side is formed at the rear end. The member 4 is formed with a rectangular fitting hole 4 </ b> C that fits into the bush 3 from the outside, and communicates coaxially with the guiding fiber hole 3 </ b> A of the bush 3 after assembly. . A cable clamp unit 21 to be described later can be attached to the rear end of the holding member 4.

  In the rectangular annular space S1 formed between the front end portion of the holding member 4 and the flange-like engaging portion 3B formed on the outer surface side of the front end portion of the bush 3, for example, a coil spring as the elastic member 10 is provided. The bush 3 is disposed in a state of being wound.

  The frame 5 is formed in a rectangular tube shape so that the rectangular holding member 4 can be inserted, and a flange-like locking projection 4B is formed on the front side of the holding member 4 on the outer surface side. A tongue-like engagement claw piece 5A slightly inclined toward the cylinder inner side of the frame 5 so as to be held in a suspended manner is provided on the rear side. In addition, a pair of two lock member insertion holes 5C penetrating vertically are provided at predetermined intervals on the left and right sides of the frame 5 on the slightly forward side.

    The knob portion 6 includes an opening 6 </ b> A through which the lock member 11 can be inserted at an upper and lower position that matches a lock member insertion hole 5 </ b> C formed in the frame 5, and is attached and fixed to the outer periphery of the frame 5. The rear end portion side of the knob 6 is attached to the frame 5 so that it cannot be removed by being locked and held by the front end opening edge of the cable clamp unit 21.

  Further, by inserting the lock member 11 into the lock member insertion hole 5C through the opening 6A of the knob 6, the bush 3 is moved to the holding member 4 side, and the taper surface 7A of the chuck 7 and the fitting of the bush 3 are fitted. While releasing the close contact between the tapered inner surfaces 9A of the joint hole 9, the bush 3 is moved to the ferrule 2 side by removing the lock member 11 from the lock member insertion hole 5C through the opening 6A of the knob 6. The tapered surface 7A of the chuck 7 and the tapered inner surface 9A of the fitting hole 9 of the bush 3 are brought into close contact with each other.

  As shown in FIGS. 1 and 7, the lock member 11 is inserted into the insertion hole 5C of the frame 5 while passing through the lock plate 12 and a predetermined interval on both sides of the lock plate 12, that is, both sides of the ferrule 2. A bifurcated leg portion 13 is provided with a possible interval. Each bifurcated leg portion 13 is formed with a thick base at the base side and a narrow width at the tip end via a tapered portion 13a.

  Thus, when the bifurcated leg portion 13 of the lock member 11 is inserted from one insertion hole 5C of the frame 5, an inward projection 5B projecting from the cylinder inner wall surface of the frame 5 and the bush 3 outer surface side are formed. Further, it is inserted into the other insertion hole 5C through both sides of the ferrule 2 of the space portion S2 formed between the flange-shaped locking portions 3B, and the narrow end protrudes outward from the frame 5 and is held.

  When the bifurcated leg portion 13 of the lock member 11 is inserted into the insertion hole 5C of the frame 5 through the opening portion 6A of the knob portion 6 in this way, the expansion elastic force of the coil spring which is the elastic member 10 is resisted. The bush 3 is pressed toward the holding member 4 so as to be pushed away, and the taper surface 7A of the chuck 7 and the taper inner surface 9A of the fitting hole 9 of the bush 3 are released. In the middle of this insertion, the bush 3 is gradually pressed and moved toward the holding member 4 side when the locking portion 3B slides from the tapered portion 13a of the bifurcated leg portion 13 toward the base portion having a large width.

  On the other hand, when the bifurcated leg portion 13 of the lock member 11 is removed from the insertion hole 5C of the frame 5 through the opening 6A of the knob portion 6, the bushing is caused by the pressure expansion elastic force of the coil spring which is the elastic member 10. 3 is urged and moved toward the ferrule 2 side, and the taper surface 7A of the chuck 7 and the taper inner surface 9A of the fitting hole 9 of the bush 3 are brought into close contact with each other, thereby pressing the abutting connection portion C on the lower surface side of the chuck 7. wear.

  As shown in FIG. 7, the ferrule 2 has a fiber hole facing the space S2 formed between the inward projection 5B of the frame 5 and the flange-like locking portion 3B on the outer surface side of the bush 3. A rectangular groove 14 is provided to a depth in the vicinity of 2A. In addition, a slit 15 for mounting the filter is formed in the groove 14 from the bottom to a position where the optical fiber P ′ in the fiber hole 2 </ b> A is cut and reaches the ferrule 2. The groove 14 is covered with a metal cylindrical holder 16 with a flange. At this time, the filter mounting slit portion 15 is disposed so as to be located directly below the intermediate portion of the holder 16.

  As shown in FIG. 4 to FIG. 7, the optical fiber core wire after the cable clamp unit 21 is mounted is bent on the rear end side of the holding member 4 mounted on the rear end side of the frame 5 on which the knob portion 6 is sheathed. The fitting part main body 31 which has the cover body 32 which can be opened and closed for confirming a state is provided. That is, the fitting portion main body 31 has a substantially half-divided shape of the rectangular tube body, and the protrusion formed on the front end opening side inner wall portion is formed on one side surface of the rear end portion of the holding member 4. The support shaft 32A formed at the end of the lid 32 is fitted into the concave bearing portion 32B formed at the other side of the rear end of the holding member 4 and fitted at the same time. A locking projection 33 </ b> A protruding from the center of the locking plate formed on the rear end opening side of the joint body 31 is engaged with a locking hole 33 </ b> B formed on both side surfaces of the lid body 32. Further, as shown in FIG. 7, a locking projection 38 protrudes from the center inner wall surface of each of the fitting portion main body 31 and the lid body 32, and the cable clamp unit 21 is mounted in the fitting portion main body 31. When the lid 32 is closed, the locking projection 38 is engaged with a locking hole 27B (described later) of the cable clamp unit 21.

  The locking projection 33A of the locking plate and the locking hole 33B of the lid 32 are such that when the lid 32 is opened from the fitting portion main body 31, the fitted state of both is released. Then, the base 34 of the presser 36 having two pairs of locking claws 35 protruding from the opposite ends of the base 34 is attached to the holding member 4 so as to cover the support shaft 32A of the lid 32. FIG. 4 and FIG. 5 show engagement holes 35A formed in each of the pawl portions 35 with engagement protrusions 37 formed on the front end opening side outer wall portion of the fitting portion main body 31. As described above, the fitting portion main body 31 is attached to the holding member 4 side so that the lid 32 can be opened and closed with respect to the fitting portion main body 31.

  On the other hand, as shown in FIGS. 2, 3, and 9 to 11, the cable clamp unit 21 is opposed to the body portion 25 provided with the guide groove 22A of the optical fiber core wire and the guide groove 22A of the body portion 25. Thus, it is configured with an openable / closable lid portion 26 formed with a guide groove 22B. The lid 26 is provided with a two-step claw-shaped pressing protrusion 26B for pressing the optical fiber cable. In other words, the cable clamp unit 21 has a lid portion 26 rotatably attached to the upper end of one end of a substantially U-shaped body portion 25 via a support shaft 26A. The locking projections 27A are formed, and the locking projections 27A are engaged with the locking holes 27B respectively formed on the left and right wall surfaces of the body part 25 so that the closed state can be maintained.

  The central optical fiber through hole 22 is formed in the closed state by the guide grooves 22A and 22B between the body portion 25 and the lid portion 26 so as to allow the optical fiber P to pass therethrough, and as shown in FIGS. And a jacket insertion path 23 branched into left and right bifurcations on the inner bottom surface of the body portion 25 so as to be able to insert and hold the jacket Q that is torn into the left and right with respect to the optical fiber P. A two-step claw-like pressing projection 26B for pressing the optical fiber cable is formed on the support shaft 26A. That is, a structure is adopted in which the two-core jacket Q is suppressed by the cable clamp unit 21 so as to absorb the bending of the optical fiber P, and the jacket Q divided into two branches is firmly held by the pressing protrusion 26B. As a thing.

  Note that the cable clamp unit 21 is formed of two molded parts including a body portion 25 having an optical fiber through hole 22 and a jacket insertion groove 23, respectively, and a lid portion 26 formed of a transparent member. Also good. By forming the lid portion 26 with a transparent member in this way, the state of the space portion and the state of the optical fiber P and the jacket Q can be seen through the transparent member, and connection work, maintenance, etc. are easy. can do.

  Further, not only the lid part 26 but also the body part 25 may be formed of a transparent material. Further, both the body part 25 and the lid part 26 may be formed of an opaque material, and a window hole for internal viewing may be provided at a predetermined site. good. On the other hand, as shown in FIG. 11, an eccentric cam-like pressing projection 26 </ b> B is provided on the lid portion 26, and an uneven slip stopper 23 </ b> A is provided on the upper surface of the outer jacket insertion path 23 so as to correspond to this. It can also be provided.

  By the way, although the optical fiber P ′ inserted in advance in the ferrule 2 shown in the above embodiment has a structure dedicated to a general-purpose optical fiber, the optical connector 1 can be used for other optical fibers. Applicable. For example, a fiber for a fiber grating, a doped fiber (a fiber for an optical subtractor) or the like can be used, and the type of optical fiber to be incorporated is not limited.

  Next, in order to explain an example of use and assembly of the best mode configured as described above, first, the optical fiber P is attached to the cable clamp unit 21. That is, as shown in FIGS. 8A to 8C, when the lid portion 26 is opened from the body portion 25 of the cable clamp unit 21 and the core of the optical fiber P is inserted into the guide groove 22A of the body portion 25. At the same time, after the outer cover Q that is torn into the left and right is inserted into the outer cover insertion path 23 branched into the left and right branches, the cover portion 26 is closed and fixed to the body portion 25. . At this time, the core of the optical fiber P was passed through the central optical fiber through hole 22, and at the same time, the outer cover insertion path 23 branched to the left and right was forked to the left and right with respect to the optical fiber P. The jacket Q is inserted, and the jacket Q is fixed by the pressing protrusions 26B or 26C. In this way, since the bifurcated outer jacket Q is fixed by the left and right outer jacket insertion paths 23, a long degree of freedom is imparted to give the optical fiber P that has exited from the central optical fiber through hole 22 a deflection. It is.

Next, the cable clamp unit 21 is connected to the optical connector 1.
That is, as shown in FIGS. 8D to 8G, the bifurcated leg portion 13 of the lock member 11 is inserted into the insertion hole 5C of the frame 5 through the opening 6A of the knob portion 6 in advance. At this time, when the bifurcated leg portion 13 is inserted into the space S2 between the frame 5 and the bush 3, the bush 3 is moved to the holding member 4 side, and the tightening force to the chuck 7 is released.

  Then, when connecting the cable clamp unit 21 to the optical connector 1, the lid 32 is opened from the fitting portion main body 31, and the bending state of the optical fiber P core wire inserted into the fiber hole 2 </ b> A of the ferrule 2 is confirmed. Then, after correcting and adjusting this, the lid 32 is closed. As a result, the locking protrusions 38 on the center inner wall surface of each of the fitting portion main body 31 and the lid body 32 are firmly fixed so that they are engaged with the locking holes 27B of the cable clamp unit 21 and are not pulled out.

  After abutment at the connection portion C of the core wire into which the optical fiber P after being connected is abutted, the bifurcated leg portion 13 of the lock member 11 is removed from the insertion hole 5C of the frame 5, thereby expanding the pressure of the elastic member 10. The bush 3 is biased and moved toward the ferrule 2 by elastic force, and a clamping force is applied to the chuck 7 so that the taper surface 7A of the chuck 7 and the taper inner surface 9A of the fitting hole 9 of the bush 3 are brought into close contact with each other. The abutting connection portion C and the vicinity thereof are pressed on the lower surface side of the chuck 7.

  Thus, the alignment and holding of the core of the optical fiber P are performed simultaneously. That is, one side of the bush 3 contacts the ferrule 2 and the other side contacts the tapered surface 7A of the chuck 7 to convert the elastic force of the elastic member 10 into the fiber tightening direction. Thereafter, a boot (not shown) is fitted on the outer periphery of the cable clamp unit 21 as necessary.

It is a disassembled perspective view which shows the optical connector in the best form for implementing this invention. It is a perspective view which shows the state which similarly opened the cover part when attaching an optical fiber to a cable clamp unit. It is a perspective view which shows the state which closed the cover part, after similarly assembling | attaching an optical fiber to a cable clamp unit. It is a perspective view which shows the state in the middle of connecting a cable clamp unit to an optical connector in the state which opened the cover body. It is a perspective view which shows the state which connected the cable clamp unit to the optical connector. The state which connected the cable clamp unit to the optical connector is shown, (a) is a top view, (b) is a side view. The optical connector is shown similarly, (a) is sectional drawing seen from the plane side, (b) is the partially notched sectional drawing seen from the side surface side. (A) thru | or (g) show the work procedure which assembles | attaches a cable clamp unit to an optical connector. It is a disassembled perspective view of a cable clamp unit similarly. It is a perspective view which shows the state which the cover part of the cable clamp unit opened similarly. It is a disassembled perspective view of the partial cross section of the cable clamp unit which shows other embodiment.

Explanation of symbols

P Optical fiber Q Outer sheath S1, S2 Space 1 Optical connector 2 Ferrule 2A Fiber hole 3 Bush 3A Guide fiber hole 4 Holding member 4A Tapered fiber hole 4B Locking protrusion 5 Frame 5A Inward protrusion 6 Picking part 7 Chuck 7A Tapered surface 8 Recess 9 Fitting hole 9A Tapered inner surface 10 Elastic member 11 Lock member 12 Lock plate 13 Forked leg portion 14 Groove portion 15 Slit portion 16 Holder 21 Cable clamp unit 22 Optical fiber through-holes 22A and 22B Guide groove 23 Cover insertion path 25 Body part 26 Lid part 26B Pressing protrusion 26C Pressing protrusion 31 Fitting part main body 32 Lid 32A Support shaft 32B Bearing part 34 Base part 35 Locking claw part 35A Locking hole 36 Holding tool 37 Locking protrusion 38 Locking protrusion

Claims (4)

  The bush is moved to the holding member side where the cable clamp unit can be mounted by inserting it into the frame to release the chuck and bush from each other, while the bush is moved to the ferrule side by removing it from the frame. An on-site assembly optical connector comprising a lock member for bringing a chuck and a bush into close contact with each other, wherein a frame is provided with a knob portion having an opening through which the lock member can be inserted. Field assembly optical connector.   2. The field assembly optical connector according to claim 1, wherein the lock member includes bifurcated leg portions that can be inserted into the insertion holes of the frame on both sides of the lock plate.   On the rear end side of the holding member attached to the rear end side of the frame on which the knob portion is externally mounted, the fitting portion has an openable / closable lid for confirming the bending state of the optical fiber core wire after the cable clamp unit is attached. The field assembly optical connector according to claim 1, further comprising a main body.   The cable clamp unit is composed of a body part having a guide groove for an optical fiber core and a cover part that can be opened and closed with a guide groove facing the guide groove of the body part, and either the body part or the cover part. The field assembly optical connector according to claim 1, further comprising a protrusion for holding the optical fiber cable.

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