JP5484836B2 - Optical connector installation tool - Google Patents

Description

  The present invention relates to an optical connector mounting tool.

  In the optical connector attaching tool described in Patent Document 1, the optical connector is attached to the insertion assisting tool, and the attachment tool is slid with respect to the insertion assisting tool with the optical fiber attached to the attachment tool. An optical fiber is inserted into the optical connector, and this optical fiber is connected to the built-in optical fiber provided inside the optical connector.

JP 2007-121863 A

  However, in the optical connector mounting tool described in Patent Document 1, a deflection is formed in a part of the optical fiber so that the optical fiber and the built-in optical fiber are abutted with a predetermined abutting force. It has become. However, even when the types of optical fibers (outer diameter and rigidity) are different, if a certain length of deflection is formed, the abutting force may be excessive or insufficient. If the abutting force is excessive, the optical fiber or the built-in optical fiber may be chipped, and if the abutting force is insufficient, there may be a disadvantage that desired optical characteristics cannot be obtained. There is.

  Accordingly, when the types of optical fibers (outer diameter and rigidity) are different, it is necessary to adjust the length of the deflection to an appropriate length according to this, but the optical connector mounting tool described in Patent Document 1 above When using the optical connector, it is necessary to prepare this optical connector mounting tool for each type of optical fiber.

  The present invention has been made in view of the above problems, and an object of the present invention is to provide an optical connector mounting tool that can eliminate the need to prepare an optical connector mounting tool for each type of optical fiber. .

  In order to solve the above-mentioned problem, the optical connector mounting tool according to claim 1, wherein the tip of the optical fiber is inserted into a groove formed inside the optical connector, and the built-in optical fiber held in the groove is inserted. An optical connector mounting tool for fixing the optical connector to the distal end portion of the optical fiber in a state in which a rear end and the distal end of the optical fiber are butted, and an optical connector setting portion for setting the optical connector And a slide part that is slidable in the axial direction of the optical connector with respect to the optical connector set part, and that supports a rear end side of the optical fiber relative to the tip part, The optical fiber is guided in the axial direction with respect to the slide portion while restricting the optical fiber from moving in a direction other than the axial direction in one region, and the A first holding state in which the optical fiber is fixed to the slide portion in a second region on the rear end side of the optical fiber relative to the first region in the id portion, and the optical fiber in the first region A fiber holding portion that can be in a second holding state to be fixed to the slide portion, and the optical connector is set in the optical connector set portion, and the slide portion is positioned at a movement limit on the optical connector set portion side. The distance between the insertion slot of the groove and the first area and the distance between the first area and the second area are set differently.

  According to this optical connector mounting tool, for example, the optical connector can be fixed to the tip of the optical fiber in the following manner. That is, first, an optical connector is set in the optical connector setting section. The rear end side of the optical fiber is supported on the slide part, and the rear end side of the optical fiber is held on the slide part by the fiber holding part. In this state, the slide portion is slid toward the optical connector, and the tip end portion of the optical fiber is inserted into the groove inside the optical connector.

  Next, the optical fiber is slid to the optical connector side together with the slide portion until the rear end of the built-in optical fiber and the front end of the optical fiber are abutted to form a deflection on the rear end side of the front end portion of the optical fiber. Then, when the optical fiber and the built-in optical fiber are brought into contact with each other and the deflection is formed on the rear end side with respect to the front end portion of the optical fiber, the slide portion is stopped and the optical connector is fixed to the front end portion of the optical fiber. . The optical connector can be fixed to the tip of the optical fiber in the manner described above.

  Here, in this optical connector mounting tool, the fiber holding portion can be switched between the first holding state and the second holding state. That is, when the fiber holding portion is in the first holding state, the optical fiber is guided in the axial direction with respect to the slide portion while being restricted from moving in a direction other than the axial direction in the first region of the slide portion. At the same time, the second portion of the slide portion is fixed to the slide portion. Therefore, when the fiber holding portion is in the first holding state, when the rear end of the built-in optical fiber and the front end of the optical fiber are abutted to form a deflection on the rear end side from the front end portion of the optical fiber, A deflection is formed between the first region and the second region.

  On the other hand, when the fiber holding portion is in the second holding state, the optical fiber is fixed to the slide portion in the first region of the slide portion. Therefore, when the fiber holding portion is in the second holding state, when the rear end of the built-in optical fiber and the front end of the optical fiber are abutted to form a deflection on the rear end side from the front end portion of the optical fiber, Deflection is formed between the slot opening and the first region.

  And, in this optical connector mounting tool, when the optical connector is set in the optical connector set portion and the slide portion is positioned at the movement limit on the optical connector set portion side, the groove insertion port and the first region And the distance between the first region and the second region are set differently. Therefore, the length of the flexure formed between the first region and the second region can be made different from the length of the flexure formed between the groove insertion opening and the first region.

  Thus, according to this optical connector mounting tool, the length of the deflection can be made different, so even when the type of optical fiber (outer diameter and rigidity) is different, the deflection according to the type of optical fiber is different. By making the lengths of the optical fibers different from each other, the optical fiber and the built-in optical fiber can be butt-connected with an appropriate butting force. Thereby, it is possible to eliminate the necessity of preparing an optical connector mounting tool for each type of optical fiber.

  The optical connector attachment tool according to claim 2 is the optical connector attachment tool according to claim 1, wherein the fiber holding portion is attachable to the first region, and is attached to the first region. And a fiber guide for guiding the optical fiber in the axial direction with respect to the slide portion while restricting the optical fiber from moving in a direction other than the axial direction. And when attached to the first area, the first fiber fixing part for fixing the optical fiber to the slide part, and attachable to the second area, A second fiber fixing portion that fixes the optical fiber to the slide portion when attached, and the fiber guide portion is attached to the first region and the second region to the second region. Second Become a the first holding state by Aiba fixing unit is attached, and is configured to be the second holding state by the first fiber fixing portion is attached to the first region.

  According to this optical connector mounting tool, a state in which the fiber guide portion is attached to the first region of the slide portion and the first fiber fixing portion is attached to the second region of the slide portion; By switching to the state where the second fiber fixing portion is attached to the region, the length of the deflection can be made different.

The optical connector attachment tool according to claim 3 is the optical connector attachment tool according to claim 1, wherein the fiber holding portion is attachable to the first region, and is attached to the first region. A fiber guide portion that guides the optical fiber in the axial direction with respect to the slide portion while restricting the optical fiber from moving in a direction other than the axial direction, the first region, and the first region. A fiber fixing portion that is selectively attachable to a second region and fixes the optical fiber to the slide portion when attached to the first region or the second region, and The first holding state is achieved by attaching the fiber guide portion to the first region and attaching the fiber fixing portion to the second region,
The second holding state is achieved by attaching the fiber fixing portion to the first region.

  According to this optical connector mounting tool, the fiber guide portion is attached to the first region of the slide portion and the fiber fixing portion is attached to the second region of the slide portion, and the fiber is attached to the first region of the slide portion. By switching to the state where the fixing portion is attached, the length of the deflection can be varied.

  The optical connector attachment tool according to claim 4 is the optical connector attachment tool according to any one of claims 1 to 3, wherein the rear end of the slide portion is more than the distal end portion of the optical fiber. The support surface supporting the side is configured such that a convex portion is formed between the first region and the second region.

  According to this optical connector mounting tool, when the deflection is formed on the rear end side with respect to the front end portion of the optical fiber as described above, the formation direction of the deflection can be defined by the convex portion, and the built-in optical fiber It is possible to suppress an excessive force from acting on the rear end and the front end of the optical fiber.

The optical connector mounting tool according to claim 5 , wherein a front end of an optical fiber is inserted into a groove formed inside the optical connector, and the rear end of the built-in optical fiber held in the groove and the front end of the optical fiber. And an optical connector mounting tool for fixing the optical connector to the distal end portion of the optical fiber in a state where the optical connector is abutted with the optical connector set portion for setting the optical connector, and the optical connector set portion. The optical connector is slidable in the axial direction of the optical connector, and has a slide portion for supporting the rear end side of the optical fiber from the front end portion, and the rear end side of the optical fiber is pivoted from the front end portion. A fiber guide for guiding the optical fiber in the axial direction with respect to the slide portion while restricting movement in a direction other than the direction, and the optical fiber rather than the fiber guide Comprising a fiber fixing portion for fixing the optical fiber to the slide portion at the rear end side, the at least one of the fiber guide section and said fiber fixing portion is provided in plurality in the axial direction of the optical fiber, said fiber guide The distance between the position where the optical fiber is guided by the portion and the position where the optical fiber is fixed by the fiber fixing portion is a fiber guide portion that guides the optical fiber among the plurality of fiber guide portions. Or a fiber fixing part that fixes the optical fiber among the plurality of fiber fixing parts is changed.

  According to this optical connector mounting tool, by switching a fiber guide for guiding an optical fiber among a plurality of fiber guides, or by switching a fiber fixing for fixing an optical fiber among a plurality of fiber fixings. The length of deflection can be changed.

The optical connector mounting tool according to claim 6 is the optical connector mounting tool according to claim 5 , wherein the support surface that supports the rear end side of the optical fiber in the slide portion from the front end portion includes: A convex portion is formed between the fiber guide portion and the fiber fixing portion.

  According to this optical connector mounting tool, when the deflection is formed on the rear end side with respect to the front end portion of the optical fiber as described above, the formation direction of the deflection can be defined by the convex portion, and the built-in optical fiber It is possible to suppress an excessive force from acting on the rear end and the front end of the optical fiber.

The optical connector mounting tool according to claim 7 is the optical connector mounting tool according to claim 5 or 6 , wherein the fiber fixing portion is made of plastic and is elastically deformed. The fiber is configured to be sandwiched between the slide portions.

  According to this optical connector mounting tool, the optical fiber can be sandwiched between the main body portion and the slide portion with the elastic deformation of the main body portion, so that the holding force for holding the optical fiber on the slide portion can be ensured. it can.

  As described above in detail, according to the present invention, it is possible to eliminate the necessity of preparing an optical connector mounting tool for each type of optical fiber.

It is a figure which shows the state which applied the optical connector attachment tool which concerns on 1st embodiment of this invention to the optical fiber with a large outer diameter. It is a figure which shows the state which applied the optical connector attachment tool shown by FIG. 1 to the optical fiber with a small outer diameter. It is a perspective view of the optical fiber holder shown in FIG. 1, (A) is the figure which made the 1st fiber guide part and the 2nd fiber fixing | fixed part an open state, (B) is a 1st fiber guide part and a 2nd fiber. It is the figure which made the fixing | fixed part the closed state. FIGS. 3A and 3B are perspective views of the optical fiber holder shown in FIG. 2, in which FIG. 2A shows the first fiber fixing portion and the second fiber guide portion in an open state, and FIG. 2B shows the first fiber fixing portion and the second fiber. It is the figure which made the guide part the closed state. It is front sectional drawing of the optical fiber holder shown by FIG. 1, (A) is the state which has not set the optical fiber to the base, (B) is a figure which shows the state which set the optical fiber to the base. . FIG. 2 is a plan sectional view of the optical connector shown in FIG. 1. It is a figure which shows the modification of the tool for optical connector attachment which concerns on 1st embodiment of this invention. It is a figure which shows the state which applied the optical connector attachment tool which concerns on 2nd embodiment of this invention to the optical fiber with a large outer diameter. It is a figure which shows the state which applied the optical connector attachment tool shown by FIG. 8 to the optical fiber with a small outer diameter. It is a figure which shows the state which applied the optical connector attachment tool which concerns on 3rd embodiment of this invention to the optical fiber with a large outer diameter. It is a figure which shows the state which applied the optical connector attachment tool shown by FIG. 10 to the optical fiber with a small outer diameter. It is a figure which shows the modification of the tool for optical connector attachment which concerns on 3rd embodiment of this invention. It is a figure which shows the state which applied the optical connector attachment tool which concerns on 4th embodiment of this invention to the optical fiber with a large outer diameter. It is a figure which shows the state which applied the optical connector attachment tool shown by FIG. 13 to the optical fiber with a small outer diameter. It is a figure which shows the state which applied the optical connector attachment tool which concerns on 5th embodiment of this invention to the optical fiber with a large outer diameter. It is a figure which shows the state which applied the optical connector attachment tool shown by FIG. 15 to the optical fiber with a small outer diameter.

[First embodiment]
First, a first embodiment of the present invention will be described.

  As shown in FIGS. 1 and 2, the optical connector mounting tool 10 according to the first embodiment of the present invention includes an optical connector holder 12 and an optical fiber holder 14.

  The optical connector holder 12 is formed in a long shape, and an optical connector set portion 16 for setting the optical connector 50 is formed on one side in the longitudinal direction, and will be described later on the other side in the longitudinal direction. A slide support portion 18 is formed for supporting the base 20 so as to be slidable.

  The optical fiber holder 14 includes a base 20 as a slide portion formed in an elongated shape, a first fiber guide portion 22, a second fiber guide portion 24, and a first fiber fixing portion, all of which are made of plastic. 26 and a second fiber fixing portion 28.

  The base 20 has a groove 30 (see also FIG. 3 and FIG. 4) for supporting the rear end side of the front end portion of the optical fiber 80. When the base 20 is set on the slide support portion 18, It is configured to be slidably supported in the axial direction of the optical connector 50 with respect to the slide support portion 18. In addition, as shown in FIGS. 1 to 4, the base 20 includes a first fixing portion 32 as a first region, and a second end closer to the rear end of the optical fiber 80 than the first fixing portion 32. And a second fixing portion 34 as a region.

  The first fiber guide portion 22 and the first fiber fixing portion 26 are selectively attached to the first fixing portion 32, and the second fiber guide portion 24 and the second fiber fixing portion 28 are second fixed. A portion 34 is selectively attached.

  That is, in FIGS. 1 and 3, the first fiber guide portion 22 is attached to the first fixing portion 32 and the second fiber fixing portion 28 is attached to the second fixing portion 34. 1, the first fiber fixing portion 26 is attached to the first fixing portion 32, and the second fiber guide portion 24 can be attached to the second fixing portion 34.

  The first fiber guide portion 22 and the second fiber fixing portion 28 have rotating portions 36 and 38 that are rotatably attached to the first fixing portion 32 and the second fixing portion 34, respectively. 20 can be in the open state shown in FIG. 3 (A) and the closed state shown in FIG. 3 (B). Similarly, the first fiber fixing portion 26 and the second fiber guide portion 24 also have rotating portions 36 and 38 that are rotatably attached to the first fixing portion 32 and the second fixing portion 34, respectively. The base 20 can be in an open state shown in FIG. 4 (A) and a closed state shown in FIG. 4 (B).

  Further, when the first fiber guide part 22, the first fiber fixing part 26, the second fiber guide part 24, and the second fiber fixing part 28 are closed with respect to the base 20, the base 20 It has fixing | fixed part 40,42 fixed to each.

  Further, the first fiber guide portion 22 and the second fiber guide portion 24 have a guide groove 44, and when the first fiber guide portion 22 and the second fiber guide portion 24 are attached to the base 20 and closed, the optical fiber 80 moves in a direction other than the axial direction. The optical fiber 80 is guided in the axial direction with respect to the base 20 while restricting movement.

  On the other hand, as shown in FIG. 5, the second fiber fixing portion 28 has a main body portion 46 between the rotating portion 38 and the fixing portion 42. The clearance between the main body 46 and the groove 30 is set to be smaller than the outer diameter of the optical fiber 80 inserted into the groove 30.

  As a result, when the second fiber fixing portion 28 is attached to the base 20 and closed, the main body portion 46 holds the optical fiber 80 with the base 20 with elastic deformation. The optical fiber 80 is fixed to the base 20 so as not to move in the axial direction. The first fiber fixing portion 26 is configured in the same manner as the second fiber fixing portion 28.

  Further, as shown in FIGS. 1 and 2, in this optical connector mounting tool 10, the optical connector 50 is set in the optical connector set portion 16 and the base 20 is limited to the movement limit on the optical connector set portion 16 side. The distance L1 between the rear end 50A of the optical connector 50 when it is positioned (an insertion port 69A of a groove 69 described later) and the first fixing portion 32, and the first fixing portion 32 and the second fixing portion 34 The distance L2 between them is set differently. That is, the distance L1 is set shorter than the distance L2.

  In the present embodiment, the first fiber guide portion 22, the first fiber fixing portion 26, the second fiber guide portion 24, and the second fiber fixing portion 28 constitute a fiber holding portion in the present invention.

  As shown in FIGS. 1 and 3, the state in which the rear end side of the optical fiber 80 is held on the base 20 by the first fiber guide portion 22 and the second fiber fixing portion 28 is the present invention. 2 and 4, the rear end side of the optical fiber 80 is moved by the first fiber fixing portion 26 and the second fiber guide portion 24 as shown in FIGS. The state held on the base 20 corresponds to the second holding state of the fiber holding portion in the present invention.

  As shown in FIG. 6, the optical connector 50 is a so-called mechanical connection type, and includes a plug 52, a spring 54, a frame 56, a support member 58, and a slider 60. Yes.

  The plug 52 includes a ferrule 62 and a fiber connection part 64. The ferrule 62 has a built-in optical fiber 66 and is integrally assembled with a substrate 68 of a fiber connection portion 64 described later.

  The fiber connection part 64 includes a substrate 68, a pair of lid members 70, and a pressing member 72. A groove 69 having a V-shaped cross section is formed in the surface portion of the substrate 68 along the axial direction of the optical connector 50, and the rear end side of the above-described built-in optical fiber 66 is inserted into the groove 69. .

  The pair of lid members 70 are arranged side by side in the longitudinal direction of the groove 69 and are configured to have a size and a shape that cover the surface portion of the substrate 68 on which the groove 69 is formed. The pair of lid members 70 are pressed toward the substrate 68 by a pair of pressing pieces 72 </ b> A formed on the pressing member 72.

  The substrate 68 and the pair of lid members 70 are formed with recesses (both not shown) into which the protrusions formed on the wedge 74 shown in FIGS. 1 and 2 can be inserted. The pair of lid members 70 can be separated from the substrate 68 against the pressing force of the pressing member 72 by inserting convex portions into the concave portions.

  The frame 56 accommodates the plug 52 so as to be slidable in the axial direction, and the spring 54 is provided inside the frame 56 and urges the plug 52 toward the distal end side with respect to the frame 56. The support member 58 is assembled to the outer periphery of the frame 56, and the slider 60 is provided outside the support member 58 and is slidably supported by the support member 58.

  Next, the operation and effect will be described together with a method of fixing the optical connector 50 to the tip end portion of the optical fiber 80 using the optical connector mounting tool 10.

  First, a method of fixing the optical connector 50 to the tip of the optical fiber 80 when the outer diameter of the optical fiber 80 is φ0.9 mm and the coating material is nylon (registered trademark) will be described. First, as shown in FIG. 3A, the coating on the tip side of the tip portion of the optical fiber 80 is removed to expose the bare fiber 82, and the tip of the bare fiber 82 is cut.

  Further, the first fiber guide portion 22 and the second fiber fixing portion 28 are attached to the base 20 to be opened, and the rear end side of the optical fiber 80 is inserted into the groove 30 of the base 20.

  Then, as shown in FIG. 3B, the first fiber guide portion 22 and the second fiber fixing portion 28 are closed, and the rear end side of the front end portion of the optical fiber 80 is placed on the first fiber guide portion 22. And it hold | maintains at the base 20 by the 2nd fiber fixing | fixed part 28. FIG.

  Further, as shown in FIG. 1, the optical connector 50 is set in the optical connector setting unit 16. In this state, the base 20 is slid toward the optical connector 50, and the tip end portion of the optical fiber 80 is inserted into the groove 69 inside the optical connector 50.

  Next, the rear end of the built-in optical fiber 66 and the tip of the optical fiber 80 are brought into contact with each other, and the optical fiber 80 is interposed between the first fiber guide portion 22 and the second fiber fixing portion 28 as shown in FIG. The optical fiber 80 is slid together with the base 20 toward the optical connector 50 until the deflection 84 is formed.

  Then, at the stage where the optical fiber 80 and the built-in optical fiber 66 are abutted and the deflection 84 is formed in the optical fiber 80, the base 20 is stopped and the wedge 74 is removed from the optical connector 50. As a result, as shown in FIG. 6, the lid member 70 is pressed toward the substrate 68 by the pressing member 72, and the distal end portion of the optical fiber 80 is fixed to the fiber connection portion 64. The optical connector 50 can be fixed to the distal end portion of the optical fiber 80 in the manner described above.

  Next, a method of fixing the optical connector 50 to the distal end portion of the optical fiber 80 when the outer diameter of the optical fiber 80 is φ0.25 mm and the coating material is an ultraviolet curable resin will be described. First, similarly to the above, as shown in FIG. 4A, the coating on the tip side of the tip of the optical fiber 80 is removed to expose the bare fiber 82, and the tip of the bare fiber 82 is cut. .

  In addition, the first fiber fixing portion 26 and the second fiber guide portion 24 are attached to the base 20 to be opened, and the rear end side of the optical fiber 80 is inserted into the groove 30 of the base 20.

  Then, as shown in FIG. 4B, the first fiber fixing portion 26 and the second fiber guide portion 24 are closed, and the rear end side of the optical fiber 80 is positioned closer to the first fiber fixing portion 26. And it hold | maintains at the base 20 by the 2nd fiber guide part 24. FIG.

  Further, as shown in FIG. 2, the optical connector 50 is set in the optical connector setting unit 16. In this state, the base 20 is slid toward the optical connector 50, and the tip end portion of the optical fiber 80 is inserted into the groove 69 inside the optical connector 50.

  Next, the rear end of the built-in optical fiber 66 and the front end of the optical fiber 80 are abutted, and as shown in FIG. 2, the rear end 50A of the optical connector 50 (the insertion port 69A of the groove 69) and the first fiber fixing The optical fiber 80 is slid to the optical connector 50 side together with the base 20 until the deflection 84 is formed in the optical fiber 80 with the portion 26.

  Then, at the stage where the optical fiber 80 and the built-in optical fiber 66 are abutted and the deflection 84 is formed in the optical fiber 80, the base 20 is stopped and the wedge 74 is removed from the optical connector 50. As a result, as shown in FIG. 6, the lid member 70 is pressed toward the substrate 68 by the pressing member 72, and the distal end portion of the optical fiber 80 is fixed to the fiber connection portion 64. The optical connector 50 can be fixed to the distal end portion of the optical fiber 80 in the manner described above.

  Here, in this optical connector mounting tool 10, as shown in FIG. 1, the rear end side of the optical fiber 80 is placed on the base 20 by the first fiber guide portion 22 and the second fiber fixing portion 28. When held, a deflection 84 is formed between the first fiber guide portion 22 and the second fiber fixing portion 28, that is, between the first fixing portion 32 and the second fixing portion 34.

  On the other hand, as shown in FIG. 2, when the rear end side of the optical fiber 80 is held on the base 20 by the first fiber fixing portion 26 and the second fiber guide portion 24, the rear end of the optical connector 50 is obtained. A deflection 84 is formed between 50A (the insertion opening 69A of the groove 69) and the first fiber fixing portion 26, that is, between the rear end 50A of the optical connector 50 and the first fixing portion 32.

  In this optical connector mounting tool 10, the optical connector 50 is set on the optical connector set portion 16, and the optical connector 50 is positioned behind the optical connector 50 when the base 20 is positioned at the movement limit on the optical connector set portion 16 side. A distance L1 between the end 50A (insertion opening 69A of the groove 69) and the first fixing portion 32 is set to be shorter than a distance L2 between the first fixing portion 32 and the second fixing portion 34. . For this reason, the deflection 84 formed between the rear end 50 </ b> A of the optical connector 50 and the first fixing portion 32 is longer than the length of the deflection 84 formed between the first fixing portion 32 and the second fixing portion 34. Can be shortened.

  Therefore, as described above, when the outer diameter of the optical fiber 80 is large or the rigidity is high, the rear end side of the optical fiber 80 is based on the first fiber guide portion 22 and the second fiber fixing portion 28. If held on the table 20, the deflection 84 can be formed between the first fixed part 32 and the second fixed part 34 having a long distance. As a result, a sufficient length of the deflection 84 can be ensured, so that it is possible to prevent the abutment force from becoming excessive and the optical fiber 80 and the built-in optical fiber 66 from being chipped.

  On the other hand, as described above, when the outer diameter of the optical fiber 80 is small or the rigidity is low, the rear end side of the optical fiber 80 is based on the first fiber fixing portion 26 and the second fiber guide portion 24. If held on the base 20, the flexure 84 can be formed between the rear end 50 </ b> A of the optical connector 50 with a short distance and the first fixing portion 32. As a result, the length of the deflection 84 can be shortened, so that it is possible to suppress the occurrence of inconveniences such as insufficient abutting force and inability to obtain desired optical characteristics.

  As described above, according to the optical connector mounting tool 10, the optical fiber 80 and the built-in optical fiber 66 are butt-connected with an appropriate butting force even when the types (outer diameter and rigidity) of the optical fiber 80 are different. be able to. Thereby, the necessity for preparing the optical connector mounting tool 10 for each type of the optical fiber 80 can be eliminated.

  Further, according to the optical connector mounting tool 10, the first fiber fixing portion 26 and the second fiber fixing portion 28 sandwich the optical fiber 80 between the main body portion 46 and the base 20 with the elastic deformation of the main body portion 46. Therefore, the holding force for holding the optical fiber 80 to the base 20 can be ensured.

  In this embodiment, as shown in FIGS. 2 and 4, the second fiber guide portion 24 is attached to the second fixing portion 34 when the outer diameter of the optical fiber 80 is small or the rigidity is low. However, the second fiber fixing portion 28 may be attached to the second fixing portion 34. Even in this case, the deflection 84 can be formed between the rear end 50 </ b> A of the optical connector 50 having a short distance and the first fixing portion 32.

  In the present embodiment, the optical fiber holder 14 can switch the length of the flexure 84 between a short state and a long state. However, the optical fiber holder 14 has a plurality of fixing portions, a fiber guide portion attached to these, and a fiber fixing portion. By having the portion, the length of the deflection 84 may be switched to three or more states.

  In the present embodiment, the bottom surface of the groove 30 formed in the base 20 (the support surface that supports the rear end side with respect to the front end portion of the optical fiber 80) is fixed first as shown in FIG. The convex portion 31 may be formed between the portion 32 and the second fixing portion 34. With such a configuration, when the deflection 84 is formed on the rear end side with respect to the front end portion of the optical fiber 80 as described above, the direction in which the deflection 84 is formed can be defined by the convex portion 31. It is possible to suppress an excessive force from acting on the rear end of the optical fiber 66 and the front end of the optical fiber 80.

[Second Embodiment]
Next, a second embodiment of the present invention will be described.

  The optical connector mounting tool 90 according to the second embodiment of the present invention shown in FIGS. 8 and 9 has the following configuration with respect to the optical connector mounting tool 10 according to the first embodiment of the present invention described above. has been changed.

  That is, the optical connector mounting tool 90 has one fiber guide portion 92 and one fiber fixing portion 98. The fiber guide portion 92 can be selectively attached to both the first fixing portion 32 and the second fixing portion 34. Similarly, the fiber fixing portion 98 is also the first fixing portion 32 and the second fixing portion. It is possible to selectively attach to any of 34.

  The fiber guide portion 92 and the fiber fixing portion 98 in the first embodiment of the present invention described above except that the fiber guide portion 92 and the fiber fixing portion 98 can be selectively attached to both the first fixing portion 32 and the second fixing portion 34. The first fiber guide portion 22 and the second fiber fixing portion 28 have the same configuration.

  In this optical connector mounting tool 90, as shown in FIG. 8, when the fiber guide portion 92 is fixed to the first fixing portion 32 and the fiber fixing portion 98 is fixed to the second fixing portion 34, the fiber is fixed. A deflection 84 is formed between the guide portion 92 and the fiber fixing portion 98, that is, between the first fixing portion 32 and the second fixing portion 34.

  On the other hand, as shown in FIG. 9, when the fiber fixing portion 98 is fixed to the first fixing portion 32 and the fiber guide portion 92 is fixed to the second fixing portion 34, the rear end 50A (groove 69) of the optical connector 50 is obtained. In this case, a deflection 84 is formed between the insertion port 69A) and the fiber fixing portion 98, that is, between the rear end 50A of the optical connector 50 and the first fixing portion 32.

  Therefore, when the outer diameter of the optical fiber 80 is large or when the rigidity is high, the fiber guide portion 92 is fixed to the first fixing portion 32 and the fiber fixing portion 98 is fixed to the second fixing portion 34. If the rear end side of the optical fiber 80 is held on the base 20 by the base 92 and the fiber fixing portion 98, a deflection 84 is formed between the first fixing portion 32 and the second fixing portion 34 having a long distance. be able to. As a result, a sufficient length of the deflection 84 can be ensured, so that it is possible to prevent the abutment force from becoming excessive and the optical fiber 80 and the built-in optical fiber 66 from being chipped.

  On the other hand, when the outer diameter of the optical fiber 80 is small or the rigidity is low, the fiber fixing portion 98 is fixed to the first fixing portion 32 and the fiber guide portion 92 is fixed to the second fixing portion 34. If the rear end side of the optical fiber 80 is held on the base 20 by the optical fiber 98 and the fiber guide portion 92, the deflection 84 is caused between the rear end 50A of the optical connector 50 having a short distance and the first fixing portion 32. Can be formed. As a result, the length of the deflection 84 can be shortened, so that it is possible to suppress the occurrence of inconveniences such as insufficient abutting force and inability to obtain desired optical characteristics.

  As described above, according to the optical connector mounting tool 90, the optical fiber 80 and the built-in optical fiber 66 are butt-connected with an appropriate abutting force even when the types (outer diameter and rigidity) of the optical fiber 80 are different. be able to. This eliminates the need to prepare the optical connector mounting tool 90 for each type of optical fiber 80.

  In the present embodiment, as shown in FIG. 9, the fiber guide portion 92 is attached to the second fixing portion 34 when the outer diameter of the optical fiber 80 is small or the rigidity is low. A fiber fixing part similar to the fiber fixing part 98 may be attached to the fixing part 34. Even in this case, the deflection 84 can be formed between the rear end 50 </ b> A of the optical connector 50 having a short distance and the first fixing portion 32.

  In the present embodiment, the optical fiber holder 14 can switch the length of the flexure 84 between a short state and a long state. However, the optical fiber holder 14 has a plurality of fixing portions, a fiber guide portion attached to these, and a fiber fixing portion. By having the portion, the length of the deflection 84 may be switched to three or more states.

  Although not particularly illustrated, also in the present embodiment, a convex portion 31 is formed between the first fixing portion 32 and the second fixing portion 34 on the bottom surface of the groove 30 formed in the base 20. (See FIG. 7). With such a configuration, when the deflection 84 is formed on the rear end side with respect to the front end portion of the optical fiber 80 as described above, the direction in which the deflection 84 is formed can be defined by the convex portion 31. It is possible to suppress an excessive force from acting on the rear end of the optical fiber 66 and the front end of the optical fiber 80.

[Third embodiment]
Next, a third embodiment of the present invention will be described.

  The optical connector mounting tool 100 according to the third embodiment of the present invention shown in FIGS. 10 and 11 has the following configuration with respect to the optical connector mounting tool 10 according to the first embodiment of the present invention described above. has been changed.

  That is, the optical connector attaching tool 100 has one fiber guide portion 102 and one fiber fixing portion 108. Further, the first fixing portion 32 holds the fiber guide portion 102 so as to be slidable in the longitudinal direction of the base 20.

  The fiber guide portion 102 and the fiber fixing portion 108 have the same configurations as the first fiber guide portion 22 and the second fiber fixing portion 28 in the first embodiment of the present invention. The first fixing portion 32 is also configured in the same manner as the first embodiment of the present invention described above except that the fiber guide portion 102 is slidably held in the longitudinal direction of the base 20.

  In the optical connector mounting tool 100, as shown in FIGS. 10 and 11, the fiber guide portion 102 is slid with respect to the base 20 to slide the fiber guide portion 102 in the optical fiber 80. The distance L3 between the fixing position by the fiber fixing portion 108 can be changed. As a result, the length of the flexure 84 formed during this period can be changed.

  Therefore, as shown in FIG. 10, when the outer diameter of the optical fiber 80 is large or the rigidity is high, if the fiber guide portion 102 is brought close to the optical connector 50, the length of the deflection 84 is sufficiently secured. Therefore, it is possible to suppress the occurrence of chipping or the like in the optical fiber 80 or the built-in optical fiber 66 due to an excessive butting force.

  On the other hand, as shown in FIG. 11, when the outer diameter of the optical fiber 80 is small or the rigidity is low, the length of the flexure 84 can be shortened by moving the fiber guide portion 102 away from the optical connector 50. Therefore, it is possible to suppress the occurrence of inconveniences such as insufficient abutting force and inability to obtain desired optical characteristics.

  As described above, according to the optical connector mounting tool 100, the optical fiber 80 and the built-in optical fiber 66 are butt-connected with an appropriate butting force even when the type (outer diameter or rigidity) of the optical fiber 80 is different. be able to. This eliminates the need to prepare the optical connector mounting tool 100 for each type of optical fiber 80.

  In this embodiment, the length of the flexure 84 has been changed by sliding the fiber guide 102 in the longitudinal direction of the base 20, but both the fiber guide 102 and the fiber fixing portion 108 are based. The length of the deflection 84 may be changed by sliding in the longitudinal direction of the base 20 or by sliding the fiber fixing portion 108 in the longitudinal direction of the base 20.

  In the present embodiment, the bottom surface of the groove 30 formed in the base 20 (the support surface that supports the rear end side with respect to the front end portion of the optical fiber 80) is fixed first as shown in FIG. The convex portion 31 may be formed between the portion 32 and the second fixing portion 34 (between the fiber guide portion 102 and the fiber fixing portion 108). With such a configuration, when the deflection 84 is formed on the rear end side with respect to the front end portion of the optical fiber 80 as described above, the direction in which the deflection 84 is formed can be defined by the convex portion 31. It is possible to suppress an excessive force from acting on the rear end of the optical fiber 66 and the front end of the optical fiber 80.

[Fourth embodiment]
Next, a fourth embodiment of the present invention will be described.

  The optical connector mounting tool 110 according to the fourth embodiment of the present invention shown in FIGS. 13 and 14 has the following configuration with respect to the optical connector mounting tool 10 according to the first embodiment of the present invention described above. has been changed.

  That is, the optical connector attaching tool 110 has a pair of fiber guide portions 112A and 112B and a fiber fixing portion 118. The pair of fiber guide portions 112 </ b> A and 112 </ b> B are arranged side by side in the longitudinal direction of the base 20.

  The pair of fiber guide portions 112A and 112B and the fiber fixing portion 118 have the same configuration as the first fiber guide portion 22 and the second fiber fixing portion 28 in the first embodiment of the present invention described above.

  And in this optical connector attachment tool 110, as shown in FIG. 13 and FIG. 14, by switching the fiber guide portion that is closed among the pair of fiber guide portions 112A and 112B, this closed state and The distance L4 between the position where the optical fiber 80 is guided by the optical fiber guide portion and the position where the optical fiber 80 is fixed by the fiber fixing portion 118 is changed. As a result, the length of the flexure 84 formed during this period can be changed.

  Therefore, as shown in FIG. 13, when the outer diameter of the optical fiber 80 is large or the rigidity is high, if the fiber guide portion 112A on the side close to the optical connector 50 is closed, the length of the deflection 84 is reduced. Since it can be ensured sufficiently, it is possible to suppress the occurrence of chipping or the like in the optical fiber 80 or the built-in optical fiber 66 due to excessive butting force.

  On the other hand, as shown in FIG. 14, when the outer diameter of the optical fiber 80 is small or the rigidity is low, if the fiber guide portion 112B on the side far from the optical connector 50 is closed, the length of the flexure 84 is reduced. Since the length can be shortened, it is possible to suppress the occurrence of inconveniences such as insufficient abutting force and inability to obtain desired optical characteristics.

  As described above, according to the optical connector mounting tool 110, the optical fiber 80 and the built-in optical fiber 66 are butt-connected with an appropriate butting force even when the types (outer diameter and rigidity) of the optical fiber 80 are different. be able to. This eliminates the need to prepare the optical connector mounting tool 110 for each type of optical fiber 80.

  Although not particularly illustrated, also in this embodiment, the bottom surface of the groove 30 formed in the base 20 is provided between the first fixing portion 32 and the second fixing portion 34 (the fiber guide portion 112B and the fiber fixing portion). The convex part 31 may be formed in between (refer to FIG. 12). With such a configuration, when the deflection 84 is formed on the rear end side with respect to the front end portion of the optical fiber 80 as described above, the direction in which the deflection 84 is formed can be defined by the convex portion 31. It is possible to suppress an excessive force from acting on the rear end of the optical fiber 66 and the front end of the optical fiber 80.

[Fifth embodiment]
Next, a fifth embodiment of the present invention will be described.

  The optical connector mounting tool 120 according to the fifth embodiment of the present invention shown in FIGS. 15 and 16 has the following configuration with respect to the optical connector mounting tool 10 according to the first embodiment of the present invention described above. has been changed.

  In other words, the optical connector mounting tool 120 includes a fiber guide portion 112 and a pair of fiber fixing portions 118A and 118B. Further, the pair of fiber fixing portions 118 </ b> A and 118 </ b> B are arranged side by side in the longitudinal direction of the base 20.

  The fiber guide part 112 and the pair of fiber fixing parts 118A and 118B have the same configuration as the first fiber guide part 22 and the second fiber fixing part 28 in the first embodiment of the present invention.

  In the optical connector mounting tool 120, as shown in FIGS. 15 and 16, the fiber guide portion 112 is switched by switching the fiber fixing portion that is closed among the pair of fiber fixing portions 118A and 118B. The distance L5 between the position where the optical fiber 80 is guided by the position and the position where the optical fiber 80 is fixed by the closed fiber fixing portion is changed. As a result, the length of the flexure 84 formed during this period can be changed.

  Therefore, as shown in FIG. 15, when the outer diameter of the optical fiber 80 is large or the rigidity is high, the length of the deflection 84 can be obtained by closing the fiber fixing portion 118B far from the fiber guide portion 112. Therefore, it is possible to suppress the occurrence of chipping or the like in the optical fiber 80 or the built-in optical fiber 66 due to an excessive butting force.

  On the other hand, as shown in FIG. 16, when the outer diameter of the optical fiber 80 is small or the rigidity is low, the length of the deflection 84 can be obtained by closing the fiber fixing portion 118A closer to the fiber guide portion 112. Therefore, it is possible to suppress the occurrence of inconveniences such as a failure to obtain desired optical characteristics due to insufficient abutting force.

  As described above, according to the optical connector mounting tool 120, the optical fiber 80 and the built-in optical fiber 66 are butt-connected with an appropriate butting force even when the types (outer diameter and rigidity) of the optical fiber 80 are different. be able to. This eliminates the need to prepare the optical connector mounting tool 120 for each type of optical fiber 80.

  In this embodiment, as in the fourth embodiment of the present invention, a pair of fiber guides 112A and 112B are provided instead of the fiber guide 112, and the pair of fiber guides 112A and 112B is closed. The length of the flexure 84 may be changed by switching the fiber guide portion to be in the state and switching the fiber fixing portion in the closed state among the pair of fiber fixing portions 118A and 118B.

  Although not particularly illustrated, also in this embodiment, the bottom surface of the groove 30 formed in the base 20 is provided between the first fixing portion 32 and the second fixing portion 34 (the fiber guide portion 112 and the fiber fixing portion). The convex part 31 may be formed between 118B (refer FIG. 12). With such a configuration, when the deflection 84 is formed on the rear end side with respect to the front end portion of the optical fiber 80 as described above, the direction in which the deflection 84 is formed can be defined by the convex portion 31. It is possible to suppress an excessive force from acting on the rear end of the optical fiber 66 and the front end of the optical fiber 80.

  Although one embodiment of the present invention has been described above, the present invention is not limited to the above, and other various modifications can be made without departing from the spirit of the present invention. It is.

10 Optical Connector Mounting Tool 16 Optical Connector Set Part 20 Base (Slide Part)
22 First fiber guide (fiber guide)
24 2nd fiber guide part 26 1st fiber fixing | fixed part (1st fiber fixing | fixed part)
28 Second fiber fixing part (second fiber fixing part)
31 convex part 32 1st fixing | fixed part (1st area | region)
34 Second fixing part (second region)
90 Optical connector mounting tool 92 Fiber guide section 98 Fiber fixing section 100 Optical connector mounting tool 102 Fiber guide section 108 Fiber fixing section 110 Optical connector mounting tools 112, 112A, 112B Fiber guide sections 118, 118A, 118B Fiber fixing section 120 Optical connector mounting tool

Claims (7)

An optical fiber tip is inserted into a groove formed inside the optical connector, and the rear end of the built-in optical fiber held in the groove is in contact with the tip of the optical fiber. An optical connector mounting tool for fixing the optical connector,
An optical connector set part for setting the optical connector;
A slide part for supporting the rear end side of the optical fiber with respect to the optical connector set part so as to be slidable in the axial direction of the optical connector;
The optical fiber is guided in the axial direction with respect to the slide portion while restricting the optical fiber from moving in a direction other than the axial direction in the first region in the slide portion, and the first in the slide portion A first holding state in which the optical fiber is fixed to the slide portion in a second region on the rear end side of the optical fiber relative to the region, and a first state in which the optical fiber is fixed to the slide portion in the first region. A fiber holder that can be in two holding states;
With
The distance between the insertion slot of the groove and the first region when the optical connector is set in the optical connector set portion and the slide portion is positioned at the movement limit on the optical connector set portion side And an optical connector mounting tool in which the distance between the first region and the second region is set differently. The fiber holder is
The optical fiber can be attached to the first region, and when the optical fiber is attached to the first region, the optical fiber is moved relative to the slide portion while restricting the optical fiber from moving in a direction other than the axial direction. A fiber guide for guiding in the axial direction;
A first fiber fixing portion that is attachable to the first region and fixes the optical fiber to the slide portion when attached to the first region;
A second fiber fixing portion that is attachable to the second region and fixes the optical fiber to the slide portion when attached to the second region;
Have
The first holding state is achieved by attaching the fiber guide portion to the first region and attaching the second fiber fixing portion to the second region,
The second holding state is achieved by attaching the first fiber fixing portion to the first region.
The optical connector mounting tool according to claim 1. The fiber holder is
The optical fiber can be attached to the first region, and when the optical fiber is attached to the first region, the optical fiber is moved relative to the slide portion while restricting the optical fiber from moving in a direction other than the axial direction. A fiber guide for guiding in the axial direction;
Fiber fixing that is selectively attachable to the first region and the second region, and fixes the optical fiber to the slide portion when attached to the first region or the second region. And
Have
The first holding state is achieved by attaching the fiber guide portion to the first region and attaching the fiber fixing portion to the second region,
The second holding state is achieved by attaching the fiber fixing portion to the first region.
The optical connector mounting tool according to claim 1. A convex portion is formed between the first region and the second region on the support surface that supports the rear end side of the slide portion with respect to the front end portion of the optical fiber.
The optical connector mounting tool according to any one of claims 1 to 3. An optical fiber tip is inserted into a groove formed inside the optical connector, and the rear end of the built-in optical fiber held in the groove is in contact with the tip of the optical fiber. An optical connector mounting tool for fixing the optical connector,
An optical connector set part for setting the optical connector;
A slide part for supporting the rear end side of the optical fiber with respect to the optical connector set part so as to be slidable in the axial direction of the optical connector;
A fiber guide portion that guides the optical fiber in the axial direction with respect to the slide portion while restricting the rear end side of the optical fiber from moving in a direction other than the axial direction from the tip portion;
A fiber fixing part for fixing the optical fiber to the slide part on the rear end side of the optical fiber from the fiber guide part;
With
At least one of the fiber guide part and the fiber fixing part is provided in a plurality in the axial direction of the optical fiber,
The distance between the position where the optical fiber is guided by the fiber guide part and the position where the optical fiber is fixed by the fiber fixing part guides the optical fiber among the plurality of fiber guide parts. The fiber guide is switched or changed by switching the fiber fixing part that fixes the optical fiber among the plurality of fiber fixing parts.
Optical connector installation tool. On the support surface supporting the rear end side of the optical fiber in the slide portion, a convex portion is formed between the fiber guide portion and the fiber fixing portion.
The optical connector mounting tool according to claim 5. The fiber fixing portion is formed of plastic and is configured to sandwich the optical fiber with the slide portion with elastic deformation.
The optical connector mounting tool according to claim 5 or 6.

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