JP2019078860A - Terminal structure of optical fiber bundle - Google Patents

Abstract

To provide a terminal structure of an optical fiber bundle that has a high inclination accuracy of optical axes of a plurality of optical fibers constituting an optical fiber bundle.SOLUTION: A terminal structure A of an optical fiber bundle is configured such that a terminal member 20 is attached to an optical fiber bundle B constituted by a plurality of optical fibers 11. The terminal member 20 comprises: a member body 21 in which a bundle insertion hole 211 into which the optical fiber bundle B is inserted is formed; a clearance material 22 that is inserted into a clearance other than a portion, into which the optical fiber bundle B is inserted, in the bundle insertion hole 211 of the member body 21; and a pressing material 23 that presses the optical fiber bundle B through the clearance material 22 against an inner wall surface of the bundle insertion hole 211 of the member body 21.SELECTED DRAWING: Figure 3B

Description

  The present invention relates to a fiber optic bundle termination structure.

  Some optical devices have a structure in which a plurality of optical fibers constitute an optical fiber bundle, and the optical fibers form a predetermined arrangement pattern at the end face of the bundle. For example, in Patent Document 1, a plurality of optical fibers constituting an optical fiber bundle are formed in a matrix at the end face of a bundle by laminating V-groove substrates in which optical fibers are arranged and supported in a plurality of V-grooves formed on the surface. An optical fiber bundle terminal structure having an array pattern of Further, according to Patent Document 2, by sandwiching a plurality of optical fibers provided to extend in parallel with a pair of members, a plurality of optical fibers constituting an optical fiber bundle are arranged in a row at the end face of the bundle. A fiber optic bundle termination structure having an array pattern is disclosed.

JP 2001-330759 A JP 2017-111318 A

  An object of the present invention is to provide an optical fiber bundle terminal structure in which the optical axis inclination accuracy of a plurality of optical fibers constituting an optical fiber bundle is high.

  The present invention is an optical fiber bundle terminal structure in which a terminal member is attached to an optical fiber bundle composed of a plurality of optical fibers, and the terminal member is formed with a bundle insertion hole into which the optical fiber bundle is inserted. The optical fiber bundle through the gap member, the gap member inserted in the gap other than the portion of the bundle insertion hole of the member body through which the optical fiber bundle is inserted, and the optical fiber bundle And a pressing member for pressing the inner wall surface of the bundle insertion hole.

  According to the present invention, the optical fiber bundle is pressed by the pressing member against the wall surface of the bundle insertion hole of the member main body through the gap material, and from the uniformity of the shape of the optical fiber, a plurality of light beams constituting the optical fiber bundle The fibers are arranged to form a predetermined arrangement pattern at the end face of the bundle, whereby high optical axis tilt accuracy of the outgoing light or incident light of the plurality of optical fibers 11 can be obtained.

1 is a plan view of an optical fiber cable including an optical fiber bundle terminal structure according to Embodiment 1. FIG. It is a perspective view of an optical fiber core wire. 1 is a perspective view of an optical fiber bundle terminal structure according to Embodiment 1. FIG. It is IIIB-IIIB sectional drawing in FIG. 3A. FIG. 10 is a front view of an end face of a first modified example of the optical fiber bundle terminal structure according to Embodiment 1. It is a front view of the end face of the 2nd modification of the optical fiber bundle terminal structure concerning Embodiment 1. FIG. It is a front view of the end surface of the 3rd modification of the optical fiber bundle terminal structure concerning Embodiment 1. FIG. It is a front view of the end surface of the 4th modification of the optical fiber bundle terminal structure concerning Embodiment 1. FIG. FIG. 10 is a front view of the end face of the optical fiber bundle terminal structure according to Embodiment 2. FIG. 16 is a front view of the end face of the optical fiber bundle terminal structure according to Embodiment 3. FIG. 16 is a front view of the end face of the optical fiber bundle terminal structure according to Embodiment 4. FIG. 16 is a front view of the end face of the optical fiber bundle terminal structure according to Embodiment 5.

  Hereinafter, embodiments will be described in detail based on the drawings. In the following description, for convenience, upper, lower, left, and right directions in the drawings are used.

(Embodiment 1)
FIG. 1 shows an optical fiber cable C in which the optical fiber bundle terminal structure A according to the first embodiment is configured. FIG. 2 shows an optical fiber core 10.

  The optical fiber cable C includes a plurality of optical fiber cores 10. The optical fiber 10 comprises an optical fiber 11 and a jacket 12 covering the same. The outer diameter of the optical fiber 10 is, for example, 0.3 mm. The optical fiber 11 has a relatively high refractive index core 111 and a relatively low refractive index cladding 112 covering it. In the optical fiber 11, for example, the core 111 is formed of pure quartz, and the cladding 112 is formed of quartz doped with a dopant that lowers the refractive index. The outer diameter of the optical fiber 11 is, for example, 250 μm. The diameter of the core 111 is, for example, 200 μm. The optical fiber 11 may have a support layer that further covers the outside of the cladding 112. The jacket 12 is generally formed of a resin, and may be formed of a single layer formed of an ultraviolet curable resin, a thermosetting resin or the like, or, for example, an inner buffer layer of silicone resin and the like May be composed of two layers with an outer covering layer of nylon resin.

  In the middle portion of the optical fiber cable C, the core wire bundle of the plurality of optical fiber cores 10 is covered with a resin tube to form a cable main body C ′, and at one end side, the plurality of optical fiber cores 10 branches, and an optical connector c is attached to each end. Then, on the other end side of the optical fiber cable C, the optical fiber bundle terminal structure A according to the first embodiment is configured at the end of the cable main body C ′. The optical fiber cable C transmits laser light from a plurality of laser light sources through the optical connector c through the optical fiber core wire 10, for example, in a printing apparatus etc., and the optical fiber bundle terminal structure according to the first embodiment It is an optical transmission device used for intensively irradiating in A.

  3A and 3B show an optical fiber bundle terminal structure A according to Embodiment 1. FIG.

  In the optical fiber bundle terminal structure A according to the first embodiment, the jackets 12 at the tip portions of the plurality of optical fiber cores 10 extending from the cable main body C ′ of the optical fiber cable C are peeled off and exposed (in FIG. 3A The optical fiber bundle B is composed of nine optical fibers 11 and the end member 20 is attached to the optical fiber bundle B.

  The terminal member 20 includes a member main body 21, a gap member 22 and a pressing member 23.

  The member main body 21 is formed of, for example, a cylindrical member formed of stainless steel or the like, and a bundle insertion hole 211 for inserting the optical fiber bundle B is formed so as to penetrate in the axial direction by processing by wire cutting or the like. The outer shape of the bundle insertion hole 211 is a horizontally long rectangular shape, and the width of the left and right is a multiple of the outer diameter of the optical fiber 11 corresponding to the maximum number of optical fibers 11 (five in FIG. 3A). It is set to. In the member main body 21, screw holes 212 which are bored from the outer peripheral surface to the upper inner wall surface of the bundle insertion hole 211 are formed.

  In the member main body 21, an optical fiber bundle B composed of a plurality of optical fibers 11 is inserted into the bundle insertion hole 211 from the rear, and the end face of the bundle is exposed at the end face. The optical fiber bundle B is provided in parallel with the group of the optical fibers 11 of the first layer L1 provided to extend in parallel with and in contact with the lower inner wall surface of the bundle insertion hole 211, respectively. And a group of optical fibers 11 of the second layer L2 provided to extend.

  In the first layer L1, the optical fiber 11 at the left end contacts the lower inner wall surface and the left inner wall surface of the bundle insertion hole 211 and the optical fiber 11 adjacent to the right side of the first layer L1, and the optical fiber 11 at the right end , The lower inner wall surface and the right inner wall surface of the bundle insertion hole 211, and the optical fiber 11 adjacent to the left side of the first layer L1, and the intermediate optical fiber 11 is the lower inner wall surface of the bundle insertion hole 211; It is in contact with the optical fiber 11 adjacent to the diagonal left and right upper sides of the second layer L2.

  In the second layer L2, the optical fiber 11 at the left end is stacked between the optical fiber 11 at the left end of the first layer L1 at the lower left and the optical fiber 11 at the lower right adjacent to the right thereof. Of the first layer L1 and the optical fiber 11 adjacent to the right side of the second layer L2, and the optical fiber 11 at the right end is the right end of the first layer L1 diagonally lower right Of the first layer L1 and the left side of the second layer L2 of the first layer L1. The intermediate optical fibers 11 are provided so as to be stacked between the intermediate optical fibers 11 of the first layer L1 obliquely below the left and right of the first layer L1. Pair of optical fibers 11 and second layer L2 It is in contact with the optical fiber 11 adjacent to the left and right sides.

  Therefore, in the optical fiber bundle terminal structure A according to the first embodiment, a plurality of optical fibers 11 constituting the optical fiber bundle B have a stacked array pattern in which the end faces of the bundle are substantially most closely packed. They are arranged in piles to form. In addition, the plurality of optical fibers 11 constituting the optical fiber bundle B are in contact with two adjacent optical fibers 11, one in contact with three adjacent optical fibers 11, and four adjacent light beams. Including those that contact fiber 11. That is, the plurality of optical fibers 11 constituting the optical fiber bundle B are in contact with the plurality of adjacent optical fibers 11.

  The gap member 22 is formed of, for example, a flat rectangular prismatic member having a rectangular cross section and made of stainless steel or the like. The width of the space member 22 is set equal to the width of the bundle insertion hole 211 on the left and right. The gap member 22 is inserted into the upper gap of the bundle insertion hole 211 of the member main body 21 other than the portion through which the optical fiber bundle B is inserted, and the lower surface is in contact with each optical fiber 11 of the second layer L2 of the optical fiber bundle B It is provided to do.

  The pressing member 23 is configured by a screw that is screwed into the screw hole 212 of the member main body 21. The pressing member 23 is screwed into the screw hole 212 of the member main body 21 and protrudes from the upper inner wall surface of the bundle insertion hole 211, and the tip is in contact with the upper surface of the gap member 22 to press the gap member 22 downward. There is. Thus, the pressing member 23 vertically presses the optical fiber bundle B against the lower inner wall surface of the bundle insertion hole 211 of the member main body 21 via the gap member 22.

  In the optical fiber bundle terminal structure A according to the first embodiment, the gap of the bundle insertion hole 211 of the member main body 21 in the terminal member 20 may be filled with an adhesive.

  FIG. 4A shows a first modification of the optical fiber bundle terminal structure A according to the first embodiment.

  In the first modification, the optical fiber bundle B includes only the group of the optical fibers 11 of the first layer L1 provided in contact with the lower inner wall surface of the bundle insertion hole 211 and extending in parallel.

  In the first layer L1, the optical fiber 11 at the left end contacts the lower inner wall surface and the left inner wall surface of the bundle insertion hole 211 and the optical fiber 11 adjacent to the right side of the first layer L1, and the optical fiber 11 at the right end , The lower inner wall surface and the right inner wall surface of the bundle insertion hole 211, and the optical fiber 11 adjacent to the left side of the first layer L1, and the intermediate optical fiber 11 is the lower inner wall surface of the bundle insertion hole 211; It is in contact with the optical fiber 11 adjacent to the left and right sides of the first layer L1. Each optical fiber 11 of the first layer L 1 is in contact with the lower surface of the gap member 22.

  Therefore, in the first modified example, the plurality of optical fibers 11 constituting the optical fiber bundle B are arranged at the bundle end face so as to form an array pattern arranged in a horizontal row. Further, the plurality of optical fibers 11 constituting the optical fiber bundle B includes one that contacts one adjacent optical fiber 11 and one that contacts two adjacent optical fibers 11.

  FIG. 4B shows a second modification of the optical fiber bundle terminal structure A according to the first embodiment.

  In the second modification, in addition to the group of optical fibers 11 in the first and second layers L1 and L2, the optical fiber bundle B is provided so as to extend in parallel, each stacked on the second layer L2 And the group of optical fibers 11 of the third layer L3.

  The third layer L3 has the same arrangement as the first layer L1, but the optical fiber 11 at the left end is the left inner wall surface of the bundle insertion hole 211 and the optical fiber 11 at the left end of the second layer L2 obliquely lower right and The rightmost optical fiber 11 in contact with the optical fiber 11 adjacent to the right side of the third layer L3 is the right inner wall surface of the bundle insertion hole 211 and the optical fiber 11 of the right end of the second layer L2 diagonally lower left and the third The optical fibers 11 adjacent to the left side of the layer L3 are in contact with the optical fibers 11, and the middle optical fibers 11 are provided so as to be stacked between the optical fibers 11 of the second layer L2 obliquely lower right and left. It is in contact with the optical fiber 11 adjacent to the left and right sides of the pair of optical fibers 11 of L2 and the third layer L3. Each optical fiber 11 of the third layer L3 is in contact with the lower surface of the gap member 22.

  Therefore, in the second modification, the plurality of optical fibers 11 constituting the optical fiber bundle B are stacked so that a substantially close-packed packed array pattern can be formed substantially at the bundle end face. Are located in In addition, the plurality of optical fibers 11 constituting the optical fiber bundle B are in contact with two adjacent optical fibers 11, one in contact with three adjacent optical fibers 11, and four adjacent optical fibers A contact with 11, a contact with five adjacent optical fibers 11, and a contact with six adjacent optical fibers 11 are included. That is, the plurality of optical fibers 11 constituting the optical fiber bundle B are in contact with the plurality of adjacent optical fibers 11.

  FIG. 4C shows a third modification of the optical fiber bundle terminal structure A according to Embodiment 1.

  In the third modification, the optical fiber bundle B includes the group of the optical fibers 11 of the first and second layers L1 and L2, but the second layer L2 has the same arrangement as the first layer L1, and the light at the left end is The fiber 11 contacts the left inner wall surface of the bundle insertion hole 211 and the optical fiber 11 at the left end of the lower first layer L1 and the optical fiber 11 adjacent to the right side of the second layer L2, and the right end optical fiber 11 The middle optical fiber 11 is in contact with the right inner wall surface of the bundle insertion hole 211 and the optical fiber 11 adjacent to the left side of the right end of the lower first layer L1 and the left side of the second layer L2; It is provided on the optical fiber 11 of the layer L1, and is in contact with the optical fiber 11 of the first layer L1 and the optical fiber 11 adjacent to the left and right sides of the second layer L2. Each optical fiber 11 of the second layer L 2 is in contact with the lower surface of the gap member 22.

  Therefore, in the third modification, the plurality of optical fibers 11 constituting the optical fiber bundle B are arranged to form a matrix-like array pattern in which the optical fibers 11 are arrayed respectively on the top, bottom, left and right at the bundle end face It is set up. Further, the plurality of optical fibers 11 constituting the optical fiber bundle B include ones in contact with two adjacent optical fibers 11 and ones in contact with three adjacent optical fibers 11. That is, the plurality of optical fibers 11 constituting the optical fiber bundle B are in contact with the plurality of adjacent optical fibers 11.

  FIG. 4D shows a fourth modification of the optical fiber bundle terminal structure A according to the first embodiment.

  The fourth modification, in addition to the group of optical fibers 11 of the first and second layers L1 and L2 having the same configuration as that of the third modification, is stacked on the second layer L2 and extends in parallel, respectively. It further comprises a group of optical fibers 11 of the third layer L3 provided as such.

  The third layer L3 has the same arrangement as the first and second layers L1 and L2, but the optical fiber 11 at the left end is the left inner wall surface of the bundle insertion hole 211 and the light at the left end of the lower second layer L2. The optical fiber 11 adjacent to the right side of the fiber 11 and the third layer L3 is in contact with the optical fiber 11 at the right end, the right inner wall surface of the bundle insertion hole 211 and the optical fiber 11 at the right end of the lower second layer L2 and The optical fiber 11 adjacent to the left side of the three-layer L3 is in contact with the optical fiber 11, and the intermediate optical fiber 11 is provided on the optical fiber 11 of the lower second layer L2, and the optical fiber 11 and the third layer of the second layer L2 are provided. It is in contact with the optical fiber 11 adjacent to the left and right sides of L3. Each optical fiber 11 of the third layer L3 is in contact with the lower surface of the gap member 22.

  Therefore, in the fourth modification, the plurality of optical fibers 11 constituting the optical fiber bundle B are arranged to form a matrix-like array pattern in which the optical fibers 11 are arrayed respectively on the top, bottom, left and right at the bundle end face It is set up. In addition, the plurality of optical fibers 11 constituting the optical fiber bundle B are in contact with two adjacent optical fibers 11, one in contact with three adjacent optical fibers 11, and four adjacent light beams. Including those that contact fiber 11. That is, the plurality of optical fibers 11 constituting the optical fiber bundle B are in contact with the plurality of adjacent optical fibers 11.

  According to the optical fiber bundle terminal structure A according to Embodiment 1 of the above configuration, the optical fiber bundle B is pressed by the pressing member 23 against the lower inner wall surface of the bundle insertion hole 211 of the member main body 21 via the gap member 22. Because of the uniformity of the shape of the optical fibers 11, the plurality of optical fibers 11 constituting the optical fiber bundle B are disposed to form a predetermined arrangement pattern at the end face of the bundle, thereby a plurality of optical fibers It is possible to obtain high optical axis tilt accuracy of the 11 outgoing light or incident light. Specifically, an optical axis tilt accuracy of 1.5 ° or less can be obtained. Also, high positional accuracy of the plurality of optical fibers 11 can be obtained. Furthermore, the optical fiber bundle B is inserted into the bundle insertion hole 211 of the member main body 21 of the terminal member 20, and the gap member 22 is inserted into the gap of the bundle insertion hole 211. From the uniformity of the shape of the optical fiber 11 by pressing the optical fiber bundle B against the lower inner wall surface of the bundle insertion hole 211 of the member main body 21 with the pressing member 23 via the gap member 22 while adjusting the position of 11 The plurality of optical fibers 11 constituting the optical fiber bundle B can be easily disposed so as to form a predetermined arrangement pattern on the end face of the bundle, so that excellent assembly workability can be obtained. Further, the optical fiber bundle B is permanently pressed and held by physically pressing the optical fiber bundle B against the lower inner wall surface of the bundle insertion hole 211 of the member main body 21 via the gap member 22 by the pressing member 23. Can. Moreover, the cost is low because it is not necessary to form V-grooves with high precision.

Second Embodiment
FIG. 5 shows an optical fiber bundle terminal structure A according to the second embodiment. In addition, the part of the same name as Embodiment 1 is shown with the same code as Embodiment 1.

  In the optical fiber bundle terminal structure A according to the second embodiment, a V-groove 22 a opened downward is formed on the lower surface of the space member 22. Then, the optical fiber bundle B is a portion surrounded by the lower inner wall surface of the bundle insertion hole 211, the lower portion of the left inner wall surface, the lower portion of the right inner wall surface, and the left and right side surfaces of the V groove 22a of the gap member 22. It is inserted in the

  The optical fiber bundle B includes a group of the optical fibers 11 of the first layer L1 provided to extend in parallel with and in contact with the lower inner wall surface of the bundle insertion hole 211 and the layers stacked in order on each other in parallel A group of optical fibers 11 of the second to fourth layers L2 to L4 provided so as to extend in the above, and one optical fiber 11 of the fifth layer L5 provided thereon.

  In the first layer L1, the optical fiber 11 at the left end contacts the lower inner wall surface and the left inner wall surface of the bundle insertion hole 211 and the optical fiber 11 adjacent to the right side of the first layer L1, and the optical fiber 11 at the right end , The lower inner wall surface and the right inner wall surface of the bundle insertion hole 211, and the optical fiber 11 adjacent to the left side of the first layer L1, and the intermediate optical fiber 11 is the lower inner wall surface of the bundle insertion hole 211; It is in contact with the optical fiber 11 adjacent to the left and right sides of the first layer L1.

  In the second layer L2, the optical fiber 11 at the left end is stacked between the optical fiber 11 at the left end of the first layer L1 at the lower left and the optical fiber 11 at the lower right adjacent to the right thereof. Of the first layer L1 and the optical fiber 11 adjacent to the right side of the second layer L2, and the optical fiber 11 at the right end is the right end of the first layer L1 diagonally lower right Of the first layer L1 and the left side of the second layer L2 of the first layer L1. The intermediate optical fibers 11 are provided so as to be stacked between the intermediate optical fibers 11 of the first layer L1 obliquely below the left and right of the first layer L1. Pair of optical fibers 11 and second layer L2 It is in contact with the optical fiber 11 adjacent to the left and right sides.

  In the third layer L3, the optical fiber 11 at the left end is piled between the optical fiber 11 at the left end of the second layer L2 at the lower left and the optical fiber 11 at the lower right adjacent to the right side thereof. Of the second layer L2 and the optical fiber 11 adjacent to the right of the third layer L3 and the optical fiber 11 at the right end are the right Of the second optical fiber 11 and the left lower optical fiber 11 adjacent to the left side of the second optical fiber 11 and the left optical fiber 11 of the second layer L2 and the left side of the third layer L3. The intermediate optical fibers 11 are provided so as to be stacked between the intermediate optical fibers 11 of the second layer L2 obliquely below the left and right, A pair of optical fibers 11 and the third layer L3 In contact with the left and right ends of the optical fiber 11 adjacent to the left and right sides.

  In the fourth layer L4, the optical fiber 11 at the left end is piled between the optical fiber 11 at the left end of the third layer L3 at the lower left and the optical fiber 11 at the lower right adjacent to the right side thereof. Of the third layer L3 and the optical fiber 11 at the right end of the fourth layer L4, and the optical fiber 11 at the right end is the light at the right end of the third layer L3 obliquely downward right It is provided so as to form a stack between the fiber 11 and the left lower lower optical fiber 11 adjacent to the left side, and the light at the left end of the pair of optical fibers 11 of the third layer L3 and the fourth layer L4. It is in contact with the fiber 11.

  In the fifth layer L5, the optical fiber 11 is piled up between the optical fiber 11 at the left end of the fourth layer L4 at the lower left and the optical fiber 11 at the right end of the fourth layer L4 at the lower right. , And are in contact with the left and right side surfaces of the pair of optical fibers 11 of the fourth layer L4 and the V groove 22a.

  In each of the first to fourth layers L1 to L4, the optical fiber 11 at the left end contacts the left side surface of the V groove 22a of the space member 22, and the optical fiber 11 at the right end is the right side of the V groove 22a of the space member 22. It is in contact with the surface. The optical fiber 11 of the fifth layer L5 is in contact with both left and right side surfaces of the V groove 22a of the space member 22.

  Therefore, in the optical fiber bundle terminal structure A according to the second embodiment, a plurality of optical fibers 11 constituting the optical fiber bundle B have a stacked arrangement pattern in which the end faces of the bundle are substantially most closely packed. They are arranged in piles to form. In addition, a plurality of optical fibers 11 constituting the optical fiber bundle B are in contact with two adjacent optical fibers 11, one in contact with four adjacent optical fibers 11, and six adjacent light beams. Including those that contact fiber 11. That is, the plurality of optical fibers 11 constituting the optical fiber bundle B are in contact with the plurality of even numbered adjacent optical fibers 11.

  The other configuration and operational effects are the same as in the first embodiment.

(Embodiment 3)
FIG. 6 shows an optical fiber bundle terminal structure A according to the third embodiment. In addition, the part of the same name as Embodiment 1 is shown with the same code as Embodiment 1.

  In the optical fiber bundle terminal structure A according to the third embodiment, the outer shape of the bundle insertion hole 211 formed in the member main body 21 is the first insertion hole portion 2111 of the horizontally long rectangle at the top and the triangular third pointed downward The two insertion holes 2112 are combined with each other, and the flat plate-like gap member 22 is inserted into the first insertion hole 2111 in the upper part of the bundle insertion hole 211. The optical fiber bundle B is inserted through the left and right inner wall surfaces of the lower triangular portion of the bundle insertion hole 211 and a portion surrounded by the lower surface of the space member 22.

  The optical fiber bundle B is sequentially laminated on one optical fiber 11 of the first layer L1 provided so as to extend in contact with the left and right sides of the lower triangular portion of the bundle insertion hole 211, and Each includes a group of optical fibers 11 of the second and third layers L2, L3 provided to extend in parallel.

  In the first layer L 1, the optical fiber 11 is in contact with both left and right side surfaces of the lower triangular portion of the bundle insertion hole 211.

  In the second layer L2, the optical fiber 11 at the left end contacts the left side surface of the lower triangular portion of the bundle insertion hole 211 and the optical fiber 11 at the first layer L1 and the optical fiber 11 at the right end of the second layer L2, The optical fiber 11 at the right end is in contact with the right side surface of the lower triangular portion of the bundle insertion hole 211, and the optical fiber 11 of the first layer L1 and the optical fiber 11 at the left end of the second layer L2.

  In the third layer L3, the optical fiber 11 at the left end is adjacent to the left side of the lower triangular portion of the bundle insertion hole 211 and to the right of the optical fiber 11 at the left end of the second layer L2 obliquely lower right and the third layer L3. The optical fiber 11 at the right end is in contact with the right side surface of the lower triangular portion of the bundle insertion hole 211 and the left side of the optical fiber 11 at the right end of the second layer L2 diagonally lower left and the third layer L3. The middle optical fiber 11 is in contact with the left end and the right end of the pair of optical fibers 11 of the second layer L2 and the left end and the right end optical fiber 11 adjacent to the left and right sides of the third layer L3. It is in contact. Each optical fiber 11 of the third layer L3 is in contact with the lower surface of the gap member 22.

  Therefore, in the optical fiber bundle terminal structure A according to the third embodiment, a plurality of optical fibers 11 constituting the optical fiber bundle B have a stacked arrangement pattern in which the end faces of the bundle are substantially most closely packed. They are arranged in piles to form. Further, the plurality of optical fibers 11 constituting the optical fiber bundle B include ones in contact with two adjacent optical fibers 11 and ones in contact with four adjacent optical fibers 11. That is, the plurality of optical fibers 11 constituting the optical fiber bundle B are in contact with the plurality of even numbered adjacent optical fibers 11.

  The other configuration and operational effects are the same as in the first embodiment.

(Embodiment 4)
FIG. 7 shows an optical fiber bundle terminal structure A according to the fourth embodiment. In addition, the part of the same name as Embodiment 1 and 3 is shown with the same code | symbol as Embodiment 1 and 3. FIG.

  In the optical fiber bundle terminal structure A according to the fourth embodiment, the outer shape of the bundle insertion hole 211 formed in the member main body 21 is larger than the first horizontally extending rectangular first insertion hole portion 2111 and the first insertion hole portion 2111 in the upper part. An L-shaped configuration is formed by combining the lower horizontal elongated rectangular second insertion hole portion 2112 having a smaller horizontal width and a smaller vertical height. The member main body 21 has a first screw hole 2121 drilled from the outer peripheral surface to the upper inner wall surface of the first insertion hole portion 2111 in the bundle insertion hole 211, and the second screw hole in the bundle insertion hole 211 from the outer peripheral surface. A second screw hole 2122 drilled to the right inner wall surface of the insertion hole portion 2112 is formed.

  The space member 22 is integrally formed so as to extend to a horizontally long rectangular first space member portion 221 whose cross-sectional shape is slightly smaller than the first insertion hole portion 2111 of the bundle insertion hole 211 and the left end of the first space member portion 221 on the lower surface side. The L-shaped columnar member has a cross-sectional shape having a rectangular second gap material portion 222 slightly smaller than the second insertion hole portion 2112 of the bundle insertion hole 211. The gap material 22 is inserted into the bundle insertion hole 211 such that the first gap material portion 221 is disposed in the first insertion hole portion 2111 and the second gap material portion 222 is disposed in the second insertion hole portion 2112 respectively.

  The optical fiber bundle B includes the lower inner wall surface and the left inner wall surface of the first insertion hole portion 2111 of the bundle insertion hole 211 and the lower surface of the first gap member portion 221 of the gap member 22 and the second gap member portion 222 It is inserted in the part surrounded by the right side.

  The optical fiber bundle B is stacked on the group of the optical fibers 11 of the first layer L1 provided so as to extend in contact with the lower inner wall surface of the first insertion hole portion 2111 of the bundle insertion hole 211 and And a group of optical fibers 11 of the second layer L2 provided to extend in parallel.

  In the first layer L1, the optical fiber 11 at the left end is on the lower inner wall surface and the left inner wall surface of the first insertion hole portion 2111 of the bundle insertion hole 211 and the optical fiber 11 at the right end adjacent to the right side of the first layer L1. The rightmost optical fiber 11 is in contact with the lower inner wall surface of the first insertion hole portion 2111 of the bundle insertion hole 211 and the left end optical fiber 11 adjacent to the left side of the first layer L1. Also, the optical fiber 11 at the right end of the first layer L1 is in contact with the left side surface of the second gap material portion 222 of the gap material 22.

  In the second layer L2, the optical fiber 11 at the left end is on the left inner wall surface of the first insertion hole portion 2111 of the bundle insertion hole 211, and on the right side of the optical fiber 11 at the left end of the first layer L1 below and the second layer L2. The rightmost optical fiber 11 in contact with the adjacent right end optical fiber 11 is in contact with the rightmost optical fiber 11 of the lower first layer L1 and the leftmost optical fiber 11 adjacent to the left side of the second layer L2 . In addition, each optical fiber 11 of the second layer L2 contacts the lower surface of the first space member portion 221 of the space member 22, and the optical fiber 11 at the right end is on the left side surface of the second space member portion 222 of the space member 22. It is in contact.

  Therefore, in the optical fiber bundle terminal structure A according to the fourth embodiment, a plurality of optical fibers 11 constituting the optical fiber bundle B are arranged in a matrix in which the optical fibers 11 are arranged at the upper and lower and right and left sides at the bundle end face. It is arranged to form a pattern. Further, the plurality of optical fibers 11 constituting the optical fiber bundle B includes only those which come in contact with two adjacent optical fibers 11. That is, the plurality of optical fibers 11 constituting the optical fiber bundle B are in contact with the plurality of adjacent optical fibers 11.

  In a first screw hole 2121 of the member main body 21, a first pressing member 231 configured by a screw is tightened. The first pressing member 231 protrudes from the upper inner wall surface of the first insertion hole portion 2111 of the bundle insertion hole 211 and the tip is in contact with the upper surface of the first gap member portion 221 of the gap member 22 to lower the gap member 22. It is pressed to. Thereby, the first pressing member 231 vertically presses the optical fiber bundle B against the lower inner wall surface of the second insertion hole portion 2112 of the bundle insertion hole 211 of the member main body 21 via the gap member 22.

  A second pressing member 232 constituted by a screw is tightened in the second screw hole 2122 of the member main body 21. The second pressing member 232 protrudes from the right inner wall surface of the second insertion hole portion 2112 of the bundle insertion hole 211, and the tip is in contact with the right side surface of the second gap member portion 222 of the gap member 22 to make the gap member 22 It is pushing to the left side. Thus, the second pressing member 232 presses the optical fiber bundle B in the left-right direction to the left inner wall surface of the second insertion hole portion 2112 of the bundle insertion hole 211 of the member main body 21 via the gap member 22. That is, the second pressing member 232 is different from the vertical direction in which the first pressing member 231 presses the left inner wall surface in the direction different from the lower inner wall surface pressing the optical fiber bundle B by the first pressing member 231. It is pressed to the left and right of the direction.

  In the optical fiber bundle terminal structure A according to the fourth embodiment, the first and second pressing members 231 and 232 are provided. However, the present invention is not particularly limited thereto, and the vertical direction of the gap member 22 The first screw hole 2121 and the first pressing member 231 of the member main body 21 do not necessarily have to be provided if the largest dimension of the same as the dimension of the bundle insertion hole 211 in the vertical direction. The second screw hole 2122 and the second pressing member 232 of the member main body 21 do not necessarily have to be provided when the maximum dimension in the left-right direction matches the maximum dimension in the left-right direction of the bundle insertion hole 211.

  The other configuration and operational effects are the same as in the first embodiment.

Embodiment 5
FIG. 8 shows an optical fiber bundle terminal structure A according to the fifth embodiment. In addition, the part of the same name as Embodiment 1 and 4 is shown with the same code | symbol as Embodiment 1 and 4. FIG.

  In the optical fiber bundle terminal structure A according to the fifth embodiment, the optical fiber bundle B is provided so as to extend in contact with the lower inner wall surface of the first insertion hole portion 2111 of the bundle insertion hole 211. It includes a group of optical fibers 11 and a group of optical fibers 11 of the second layer L2 provided thereon and provided to extend in parallel.

  In the first layer L1, the optical fiber 11 at the left end contacts the lower inner wall surface and the left inner wall surface of the first insertion hole portion 2111 of the bundle insertion hole 211 and the optical fiber 11 adjacent to the right side of the first layer L1. The optical fiber 11 at the right end contacts the lower inner wall surface of the first insertion hole portion 2111 of the bundle insertion hole 211 and the optical fiber 11 adjacent to the left side of the first layer L1, and the intermediate optical fiber 11 is a bundle The lower inner wall surface of the first insertion hole portion 2111 of the insertion hole 211 is in contact with the optical fiber 11 adjacent to the left and right sides of the first layer L1. Also, the optical fiber 11 at the right end of the first layer L1 is in contact with the left side surface of the second gap material portion 222 of the gap material 22.

  In the second layer L2, the optical fiber 11 at the left end is on the left inner wall surface of the first insertion hole portion 2111 of the bundle insertion hole 211, and on the right side of the optical fiber 11 at the left end of the first layer L1 below and the second layer L2. The optical fiber 11 at the right end in contact with the adjacent optical fiber 11 is in contact with the optical fiber 11 at the right end of the lower first layer L1 and the optical fiber 11 adjacent to the left side of the second layer L2; Is in contact with the optical fiber 11 of the lower first layer L1 and the optical fibers 11 adjacent to the left and right sides of the second layer L2. In addition, each optical fiber 11 of the second layer L2 contacts the lower surface of the first space member portion 221 of the space member 22, and the optical fiber 11 at the right end is on the left side surface of the second space member portion 222 of the space member 22. It is in contact.

  Therefore, in the optical fiber bundle terminal structure A according to the fifth embodiment, a plurality of optical fibers 11 constituting the optical fiber bundle B are arranged in a matrix in which the optical fibers 11 are arranged at the upper and lower sides and the left and right at the bundle end face. It is arranged to form a pattern. Further, the plurality of optical fibers 11 constituting the optical fiber bundle B include ones in contact with two adjacent optical fibers 11 and ones in contact with three adjacent optical fibers 11. That is, the plurality of optical fibers 11 constituting the optical fiber bundle B are in contact with the plurality of adjacent optical fibers 11.

  The other configurations and effects are the same as in the first and fourth embodiments.

  The invention is useful in the technical field of fiber optic bundle termination structures.

A optical fiber bundle terminal structure B optical fiber bundle C optical fiber cable C 'cable main body c optical connectors L1 to L5 first to fifth layers 10 optical fiber core wire 11 optical fiber 111 core 112 clad 12 jacket 20 terminal member 21 member main body 211 bundle insertion hole 2111 first insertion hole portion 2112 second insertion hole portion 212, 2121, 2122 (first and second) screw holes 22 space member 22a V groove 221 first space member portion 222 second space member portion 23, 231, 232 (first and second) pressing material

Claims (3)

An optical fiber bundle terminal structure in which an end member is attached to an optical fiber bundle composed of a plurality of optical fibers, comprising:
The terminal member is a member main body in which a bundle insertion hole into which the optical fiber bundle is inserted is formed, and a gap inserted in a gap other than the part through which the optical fiber bundle is inserted in the bundle insertion hole of the member main body An optical fiber bundle terminal structure comprising: a material; and a pressing material for pressing the optical fiber bundle against the inner wall surface of the bundle insertion hole of the member main body via the gap material. In the optical fiber bundle terminal structure according to claim 1,
An optical fiber bundle terminal structure in which any one of the plurality of optical fibers constituting the optical fiber bundle is in contact with a plurality of adjacent optical fibers. The optical fiber bundle terminal structure according to claim 1 or 2
An optical fiber bundle terminal structure in which the plurality of optical fibers constituting the optical fiber bundle are packed in a stack.

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