JP5475533B2 - Fiber optic bundle - Google Patents

Description

  The present invention relates to an optical fiber bundle including a bundle portion configured by bundling a plurality of long materials including one end portions of a plurality of optical fibers.

  An optical fiber bundle including a bundle portion configured by bundling one end portions of a plurality of optical fibers has been put into practical use as an optical transmission device. For example, when an optical fiber bundle is used as a laser guide, an output in which laser beams from a plurality of laser light sources are collected can be obtained.

  Patent Document 1 discloses a light guide for an optical fiber bundle in which a large number of optical fibers are aligned and ends of these optical fibers are fixed in a fixing member by a heat-resistant transparent adhesive having predetermined heat resistance and transparency. Is disclosed.

  Patent Document 2 discloses an optical fiber bundle composed of a large number of optical fibers surrounded by a solid silica sol binder layer.

  In Patent Document 3, a large number of optical fiber tips are packed in a sleeve, and the tip of the sleeve is covered with a split sleeve, and the split sleeve is heated to uniformly heat the entire terminal portion. An optical fiber bundle in which a fiber tip portion and a sleeve are fused and integrated is disclosed.

  In Patent Document 4, a plurality of optical fibers are inserted into a sleeve, and a heat resistant member made of metal or glass is filled between the optical fibers in a region of a certain length along the longitudinal direction from the emission end face of the sleeve. An optical fiber bundle is disclosed.

  Patent Document 5 discloses an optical fiber bundle in which a plurality of optical fibers are inserted into an alignment member and integrated by heating.

  Patent Document 6 discloses an optical fiber bundle in which a nylon resin protective layer is provided outside a plurality of plastic optical fibers.

Japanese Patent No. 2705830 Japanese Patent No. 2780143 Japanese Patent No. 3819054 JP 2008-83690 A JP 2008-277582 A JP 2010-32641 A

  By the way, when an optical fiber bundle using a large-diameter optical fiber is used as a laser guide for obtaining a high power output by combining laser beams from a plurality of laser light sources, the optical fiber bundle has high heat resistance. Required.

  An object of the present invention is to obtain high heat resistance in an optical fiber bundle.

The present invention is an optical fiber bundle including a bundle portion configured by bundling a plurality of long materials including one end portions of a plurality of optical fibers,
The bundle portion is integrated with the plurality of long materials by fusing the long materials to the adjacent long materials at the outer peripheral contact portion along the length direction. Is formed so that the gap extends along the length direction in the portion surrounded by the non-contact portion of the outer periphery ,
Further, the bundle part has a pipe material that accommodates the bundle of the plurality of long materials in an inscribed state,
Among the plurality of long materials, the long material contacting the pipe material is fused to the pipe material along the length direction, whereby the bundle of the plurality of long materials and the pipe material are integrated. In addition, the gap is formed so as to extend along the length direction in a portion surrounded by the outer peripheral non-contact portion of each long material and the inner wall of the pipe material .

  According to the present invention, in the bundle portion, a plurality of long materials including one end portions of the plurality of optical fibers are integrated, and the gap is long in the portion surrounded by the outer peripheral non-contact portion of each long material. Since it is formed so as to extend along the direction, heat dissipation of the bundle portion can be enhanced by arranging a cooling medium such as air or water in the gap, and as a result, high heat resistance can be obtained. .

It is a perspective view of the optical fiber bundle which concerns on embodiment. It is a perspective view of an optical fiber core wire. It is a front view of the end surface of a bundle part. It is a front partial enlarged view of a bundle part end surface. (A)-(d) is explanatory drawing which shows the accommodation aspect to the pipe material of the bundle of optical fibers.

  Hereinafter, embodiments will be described in detail based on the drawings.

  FIG. 1 shows an optical fiber bundle 100 according to this embodiment. The optical fiber bundle 100 of this embodiment is used as, for example, a laser guide for collecting laser light from a plurality of laser light sources to obtain a high power output.

  The optical fiber bundle 100 of the present embodiment includes a plurality of optical fiber cores 110. The plurality of optical fiber cores 110 may be configured by the same optical fiber core 110, or may be configured by mixing different optical fiber cores 110.

  Each of the plurality of optical fiber cores 110 has a configuration in which an optical fiber 111 is coated with a coating layer 112 as shown in FIG.

  The optical fiber 111 includes a core 111a having a relatively high refractive index provided at the center of the fiber and a clad 111b having a relatively low refractive index provided concentrically so as to cover the core 111a. Have. The optical fiber 111 may further include a support layer provided so as to cover the clad 111b. The fiber diameter of the optical fiber 111 is, for example, 125 to 1500 μm.

  The core 111a is preferably made of quartz. The quartz core 111a may be quartz doped with a dopant such as germanium (Ge) for increasing the refractive index, or may be non-doped quartz not doped with a dopant. The softening temperature of the core 111a is 1600-1700 degreeC, for example. The core diameter is, for example, 50 to 1200 μm.

  The clad 111b is preferably made of quartz. The quartz cladding 111b may be non-doped quartz that is not doped with a dopant, or may be quartz that is doped with a dopant such as fluorine (F) or boron (B) that lowers the refractive index. The softening temperature of the clad 111b is, for example, 1300 to 1400 ° C., but the viewpoint of suppressing deformation of the core 111a when the bundle part 120 is formed by heat-sealing the clad 111b of the optical fiber 111 as will be described later. Therefore, the temperature is preferably lower than the softening temperature of the core 111a. The clad 111b has a relatively low refractive index and a lower refractive index than the core 111a. The thickness of the clad 111b is, for example, 3 to 60 μm.

  The covering layer 112 may be composed of a single layer, or may be composed of a plurality of layers such as a double layer in which a silicon resin layer and a polyamide resin layer are sequentially laminated from the inside. .

  In the optical fiber bundle 100 according to the present embodiment, one end portion (long material) of the plurality of optical fibers 111 from which the coating layer 112 is peeled is bundled at one end portion of the plurality of optical fiber cores 110. Thus, the bundle unit 120 is configured.

  FIG. 3 shows the end face of the bundle part 120.

  The number of one end portions of the optical fiber 111 constituting the bundle portion 120 is, for example, 2 to 49. In addition, although the elongate material which comprises the bundle part 120 may be comprised only by the one end part of the some optical fiber 111 like the optical fiber bundle 100 which concerns on this embodiment, one end of the some optical fiber 111 may be comprised. In addition to the portion, a quartz capillary, a hollow pipe, or a rod material may be included.

  As shown in FIG. 4, the bundle unit 120 has one end portion of the plurality of optical fibers 111 fused to each other along the length direction at the outer peripheral contact portion 121. In addition to being integrated, a gap 123 having a substantially triangular cross section is formed so as to extend along the length direction in a portion surrounded by the outer peripheral non-contact portion 122 of each optical fiber 111. In addition, the gap 124 is formed so as to extend along the length direction in a portion surrounded by the outer peripheral non-contact portion 122 of each optical fiber 111 and the inner wall of the pipe material 130.

  In general, in an optical fiber bundle in which a bundle portion is configured by bundling one end portions of a plurality of optical fibers and fixing with an adhesive, when the heat resistance is required, an adhesive having a high heat resistance is used. However, organic adhesives such as epoxies have a heat resistance of about 300 ° C. at most, and also have the disadvantages of burning and generating unnecessary substances with respect to light having a short wavelength. In addition, an inorganic adhesive such as alumina has a problem that even if the heat resistance is sufficient, the end face of the optical fiber is damaged by the peeled piece of the adhesive when the end face of the bundle portion is polished. On the other hand, in the optical fiber bundle 100 according to the present embodiment, in the bundle portion 120, one end portions of the plurality of optical fibers 111 are integrated and a portion surrounded by the outer peripheral non-contact portion 122 of each optical fiber 111. Since the gaps 123 and 124 are formed so as to extend along the length direction in the portion surrounded by the outer peripheral non-contact portion 122 of each optical fiber 111 and the inner wall of the pipe material 130, the gaps 123 and 124 are formed in the gaps 123 and 124. By disposing a cooling medium such as air or water, the heat dissipation of the bundle part 120 can be improved, and while contributing to cooling and dustproofing of the irradiation target, debris adhesion to the end face of the bundle part 120 can be prevented, As a result, high heat resistance can be obtained. In addition, since no adhesive is used for the bundle portion 120, burning or generation of unnecessary substances does not occur due to the transmitted short wavelength laser light, and high light resistance can be obtained.

  In the bundle unit 120, one end portions of the plurality of optical fibers 111 are bundled in a close-packed manner and integrated. Thereby, the high space factor of the core 111a can be obtained. The space factor of the core 111a at the end face of the bundle part 120 is, for example, 65 to 78%, and the space factor of the gaps 123 and 124 is, for example, 22 to 35%. In addition, the bundle part 120 may be integrated in such a manner that one end parts of the plurality of optical fibers 111 are randomly bundled.

  The bundle unit 120 includes a pipe member 130 that accommodates a bundle of one end portions of the plurality of optical fibers 111 in an inscribed state. As a result, it is possible to obtain a high form-retaining property including prevention of deformation of the core 111a when heating and integrating one end of the optical fiber 111, and it is possible to suppress deterioration in the quality of the transmitted laser light. In particular, when one end of a plurality of optical fibers 111 is bundled in a plurality of layers in a close-packed manner so as to form a concentric cross section, the outermost optical fiber 111 is formed of the pipe material 130. By designing so as to be in contact with the inner wall, an equal force acts on the bundle of one end portions of the plurality of optical fibers 111 from the pipe material 130, and higher form retainability can be obtained. Specifically, for example, as shown in FIG. 5A, when one end of seven optical fibers 111 is bundled in a close-packed state, it may be accommodated in the pipe material 130 as it is. As shown in FIG. 5B, in the case where the end portions of the 19 optical fibers 111 are bundled in a close-packed manner, the 6 outermost layers that do not contact the inner wall of the pipe material 130 (the phantom in the middle figure). What is necessary is just to accommodate 13 pieces except the thing drawn by the line in the pipe material 130. FIG. As shown in FIG. 5 (c), in the case of one end of 37 optical fibers 111 bundled in a close-packed state, six outermost layers that do not contact the inner wall of the pipe material 130 (the phantom in the middle figure). What is necessary is just to accommodate 31 pipes except the thing drawn with the line in the pipe material 130. FIG. As shown in FIG. 5D, in the case where one end of 61 optical fibers 111 are bundled in a close-packed state, 12 outermost layers that do not contact the inner wall of the pipe material 130 (the virtual in the middle diagram). 49 pipes excluding those drawn with lines may be accommodated in the pipe material 130. Note that the bundle unit 120 may not have the pipe material 130 and may have a configuration in which a plurality of optical fibers 111 are bundled and integrated.

  Examples of the pipe material 130 include a quartz pipe, a metal pipe, and a ceramic pipe. Among these, a quartz pipe is preferable. The pipe material 130 is preferably formed of the same material as the optical fiber 111. For example, the pipe member 130 has a length of 5 to 100 mm, an outer diameter of 1.8 to 15 mm, and an inner diameter of 1.3 to 14 mm. The thickness of the pipe material 130 is preferably thin from the viewpoint of suppressing deformation of the optical fiber 111 when the one end portion of the optical fiber 111 accommodated in the pipe material 130 is heated and integrated. It is preferable that it is 2-1 mm.

  The pipe member 130 bundles one end portions of the plurality of optical fibers 111 and heats them from the outside, so that the pipe material 130 is softened and melted at an early stage and prevented from flowing between the optical fibers 111. It is preferably formed of a material that softens at a higher temperature than the outer periphery. Thus, for example, in the optical fiber 111, the core 111a is formed of non-doped quartz that is not doped with a dopant, and the cladding 111b is formed of quartz doped with a dopant that lowers the refractive index, such as F (fluorine) or B (boron). In such a case, the pipe member 130 is preferably formed of non-doped quartz that is softened at a higher temperature than the clad 111b.

  In the optical fiber bundle 100 according to the present embodiment, the coating layer 112 is peeled off at one end portion of the plurality of optical fiber cores 110, and one end portion of the plurality of optical fibers 111 is inserted into the pipe member 130 and bundled. For example, the pipe member 130 is heated to, for example, 1200 to 2000 ° C. by a torch, carbonic acid laser, or the like, thereby integrating one end portions of the plurality of optical fibers 111 to form the bundle portion 120, and then cleaving that portion. Thus, it can be manufactured by forming the end face and polishing the end face. At this time, the pipe material 130 may be contracted by depressurizing the inside of the pipe material 130 or pressurizing the outside of the pipe material 130. When the bundle portion 120 is the optical fiber bundle 100 that does not have the pipe material 130, the coating layer 112 is peeled off at one end portion of the plurality of optical fiber cores 110, and one end portion of the plurality of optical fibers 111 is bundled. It can be manufactured by heating in a state, thereby integrating them to form the bundle part 120 and cleaving the part to form an end face and polishing the end face.

  In the optical fiber bundle 100 of the present embodiment described above, for example, a laser light source such as a semiconductor laser is connected to the other end of each of the plurality of optical fiber cores 110, and the laser light from the plurality of laser light sources is bundled 120. In summary, it can be used as a laser guide to obtain high power output from its end face.

  As described above, the present invention is useful for an optical fiber bundle including a bundle portion configured by bundling a plurality of long materials including one end portions of a plurality of optical fibers.

DESCRIPTION OF SYMBOLS 100 Optical fiber bundle 110 Optical fiber core wire 111 Optical fiber 111a Core 111b Cladding 112 Coating layer 120 Bundle part 121 Outer periphery contact part 122 Outer periphery non-contact part 123, 124 Air gap 130 Pipe material

Claims (5)

An optical fiber bundle comprising a bundle portion configured by bundling a plurality of long materials including one end portions of a plurality of optical fibers,
The bundle portion is integrated with the plurality of long materials by fusing the long materials to the adjacent long materials at the outer peripheral contact portion along the length direction. Is formed so that the gap extends along the length direction in the portion surrounded by the non-contact portion of the outer periphery ,
Further, the bundle part has a pipe material that accommodates the bundle of the plurality of long materials in an inscribed state,
Among the plurality of long materials, the long material contacting the pipe material is fused to the pipe material along the length direction, whereby the bundle of the plurality of long materials and the pipe material are integrated. And an optical fiber bundle formed such that a gap extends along the length direction in a portion surrounded by the outer peripheral non-contact portion of each long material and the inner wall of the pipe material . The optical fiber bundle according to claim 1 ,
The said pipe material is an optical fiber bundle formed with the material softened at high temperature rather than each outer peripheral part of said several elongate material. In the optical fiber bundle according to claim 1 or 2 ,
An optical fiber bundle in which the plurality of long materials are bundled in a plurality of layers in a close-packed manner so as to form a concentric cross section, and the longest material of the outermost layer is in contact with the inner wall of the pipe material. In the optical fiber bundle according to any one of claims 1 to 3 ,
An optical fiber bundle in which the pipe material is a quartz pipe. In the optical fiber bundle according to any one of claims 1 to 4 ,
An optical fiber bundle in which the plurality of long materials are configured by only one end portions of a plurality of optical fibers.

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