阅读说明：本技术 光纤束结构、光连接器、光纤连接结构、以及光纤束结构的制造方法 (Optical fiber bundle structure, optical connector, optical fiber connection structure, and method for manufacturing optical fiber bundle structure ) 是由 川崎浩平 杉崎隆一 塚本昌义 高桥正典 高坂繁弘 前田幸一 于 2020-03-25 设计创作，主要内容包括：本发明的目的在于提供损耗小的光纤束结构。光纤束结构具备：多根光纤芯线；交叉消除构件,其供多根光纤芯线沿着长度方向贯穿；以及夹握构件,其对交叉消除构件赋予夹握力,多根光纤芯线从前端起依次具有细径部、锥状部、粗径部、以及树脂包覆部,在交叉消除构件形成有狭缝,该狭缝在该交叉消除构件的与长度方向正交的截面中以如下点为中心而具有宽度并从该交叉消除构件的前端延伸至后端侧的中途,该点是将外接于多根光纤芯线的多边形的各边按照与该边相接的光纤芯线的数量进行等分而得到的,位于各边的该狭缝的宽度为在后端侧的狭缝的终端部外接于多根光纤芯线的多边形的一边的长度与在前端侧外接于多根光纤芯线的多边形的一边的长度之间的差量以上。(The invention aims to provide an optical fiber bundle structure with low loss. The optical fiber bundle structure includes: a plurality of optical fiber cores; a crossing eliminating member through which the plurality of optical fiber cores are passed along a longitudinal direction; and a grip member that gives a grip force to the crossover reducing member, the plurality of optical fiber cores having, in order from the front end, a small diameter portion, a tapered portion, a large diameter portion, and a resin coating portion, the crossover reducing member being formed with a slit that has a width centered on a cross section orthogonal to the longitudinal direction of the crossover reducing member and extends from the front end to a halfway of the rear end side of the crossover reducing member, the slit having a width obtained by equally dividing each side of a polygon externally connected to the plurality of optical fiber cores by the number of optical fiber cores connected to the side, the slit having a width on each side that is a difference or more between a length of a side of the polygon externally connected to the plurality of optical fiber cores at an end portion of the slit on the rear end side and a length of a side of the polygon externally connected to the plurality of optical fiber cores at the front end side.)

1. An optical fiber bundle structure, characterized in that,

the optical fiber bundle structure includes:

a plurality of optical fiber cores;

a crossing elimination member through which the plurality of optical fiber cores are penetrated in a longitudinal direction; and

a grip member that imparts a grip force to the crossover eliminating member,

the plurality of optical fiber cores have a glass fiber portion and a resin coating portion for coating the glass fiber with resin in this order from the front end,

the glass fiber part has a small diameter part, a tapered part and a large diameter part in order from the front end,

a slit is formed at the cross elimination member,

the slit has a width in a cross section of the cross cancellation member orthogonal to the longitudinal direction, and extends from a front end of the cross cancellation member to a middle of a rear end side with a point obtained by equally dividing each side of a polygon circumscribing the plurality of optical fiber cores by the number of the optical fiber cores connected to the side,

the width of the slit on each side is equal to or greater than a difference between a length of one side of a polygon circumscribing the plurality of optical fiber cores at a terminal end of the slit on the rear end side and a length of one side of the polygon circumscribing the plurality of optical fiber cores at the front end side.

2. An optical fiber bundle structure, characterized in that,

the optical fiber bundle structure includes:

a plurality of optical fiber cores;

a crossing elimination member through which the plurality of optical fiber cores are penetrated in a longitudinal direction; and

a grip member that imparts a grip force to the crossover eliminating member,

the plurality of optical fiber cores have a glass fiber portion and a resin coating portion for coating the glass fiber with resin in this order from the front end,

the glass fiber part has a small diameter part, a tapered part and a large diameter part in order from the front end,

a slit is formed at the cross elimination member,

the slit has a width in a cross section of the cross cancellation member orthogonal to the longitudinal direction, and extends from a front end to a middle of a rear end side of the cross cancellation member with a center at a point obtained by equally dividing each side of a substantially polygonal shape circumscribing the plurality of optical fiber cores by the number of optical fiber cores in contact with the side,

each vertex of the substantially polygonal shape circumscribed by the slit and the plurality of optical fiber cores has a curved shape, and the sum of the widths of the slits on the respective sides is equal to or greater than a difference between a length of an outer circumference of the slit on a rear end side, which surrounds the plurality of optical fiber cores in a shortest manner, and a length of an outer circumference of the slit on a front end side, which surrounds the plurality of optical fiber cores in a shortest manner.

3. The optical fiber bundle structure according to claim 1 or 2,

the grip member is a ring fitted to the distal end side of the crossover eliminating member.

4. The optical fiber bundle structure according to any one of claims 1 to 3,

the plurality of optical fiber cores are disposed in the small diameter portion in a square shape.

5. The optical fiber bundle structure according to claim 4,

the number of the optical fiber core wires is four or nine.

6. The optical fiber bundle structure according to any one of claims 1 to 3,

the plurality of optical fiber cores are disposed in the hexagonal closest arrangement in the small diameter portion.

7. The optical fiber bundle structure of claim 6,

the plurality of optical fiber core wires are seven or nineteen.

8. An optical connector is characterized in that,

the optical connector comprises the optical fiber bundle structure according to any one of claims 1 to 7,

the grip member is a ferrule formed with a hole portion that imparts grip force to the inserted crossover reducing member.

9. An optical fiber connection structure, characterized in that,

the optical fiber connection structure includes:

the optical fiber bundle structure of any one of claims 1 to 7; and

and a multicore fiber having a plurality of core portions connected to cores of the plurality of optical fiber cores, and a cladding portion formed on an outer periphery of the core portions.

10. An optical fiber connection structure, characterized in that,

the optical fiber connection structure includes:

the optical fiber bundle structure of any one of claims 1 to 7; and

and a plurality of light receiving/emitting units connected to the cores of the plurality of optical fiber cores.

11. A method for manufacturing an optical fiber bundle structure,

the manufacturing method of the optical fiber bundle structure comprises the following steps:

an insertion step of inserting an intersection removal member into an annular guide member, the intersection removal member being configured to allow a plurality of optical fiber cores to pass through in a longitudinal direction, the plurality of optical fiber cores having a glass fiber portion and a resin coating portion in which a glass fiber is coated with a resin in this order from a distal end, into a slit, the slit having a width centered on a cross section orthogonal to the longitudinal direction of the intersection removal member and extending from the distal end to a middle of a rear end side of the intersection removal member, the slit being formed by equally dividing each side of a polygon externally connected to the plurality of optical fiber cores by the number of optical fiber cores connected to the side, the width of the slit located at each side being equal to the length of a side of the polygon externally connected to the plurality of optical fiber cores at a terminal end of the slit located at the rear end side and the multi-core externally connected to the plurality of optical fiber cores at the distal end side being fitted into the slit A difference between lengths of one side of the polygon or more;

a penetrating step of aligning the plurality of optical fiber cores in a predetermined arrangement and penetrating the plurality of optical fiber cores from a front end side to a rear end side of the crossover removal member;

a drawing step of drawing the optical fiber core wire to a rear end side while applying a gripping force to the cross eliminating member until a small diameter portion of the glass fiber portion having the small diameter portion, a tapered portion, and a large diameter portion in this order from a front end is positioned inside the cross eliminating member;

a detaching step of detaching the guide member from the intersection-eliminating member; and

and a ferrule insertion step of inserting the crossover eliminating member into the hole of the ferrule while applying a gripping force to the crossover eliminating member.

12. The method of manufacturing an optical fiber bundle structure according to claim 11,

the drawing step includes:

a first pulling step of pulling the optical fiber core wire to a rear end side until a rear end of the tapered portion of the glass fiber portion is positioned inside the crossover eliminating member; and

a second drawing step of drawing the optical fiber core wire toward a rear end side until the small diameter portion of the glass fiber portion is positioned inside the crossover eliminating member,

the detaching process is performed between the first drawing process and the second drawing process.

13. The method of manufacturing an optical fiber bundle structure according to claim 11 or 12,

the thickness of the convex portion of the guide member is equal to or greater than a difference between a length of one side of the polygon circumscribing the plurality of optical fiber cores at a rear end of the tapered portion of the optical fiber core and a length of one side of the polygon circumscribing the plurality of optical fiber cores at a front end of the tapered portion of the optical fiber core.

Technical Field

The invention relates to an optical fiber bundle structure, an optical connector, an optical fiber connection structure, and a method for manufacturing the optical fiber bundle structure.

Background

An optical fiber having a plurality of fiber cores, i.e., a multicore optical fiber, is known. In order to connect a multicore fiber and a single core fiber, an optical fiber bundle structure in which cores of the single core fibers are arranged at positions corresponding to the cores of the multicore fiber has been proposed (see, for example, patent document 1).

Patent document 1 discloses an optical fiber bundle structure including: a plurality of optical fiber cores having, in order from the front end, a small diameter portion, a tapered portion whose diameter increases toward the rear end, a large diameter portion, and a resin coating portion coated with a resin; and a capillary for accommodating the optical fiber core wires. In this optical fiber bundle structure, the small diameter portion and the resin coating portion of the optical fiber core wire are brought into contact with the inner surface of the capillary, whereby the optical fiber core wire is positioned.

Documents of the prior art

Patent document

Patent document 1: japanese patent laid-open publication No. 2017-181791

Disclosure of Invention

Problems to be solved by the invention

However, in the optical fiber bundle structure of patent document 1, the optical fiber core wire is not positioned at the tapered portion and the large diameter portion of the optical fiber core wire. As a result, in this optical fiber bundle structure, although the optical fiber core wires are positioned at the small diameter portion and the resin coating portion of the optical fiber core wires, the optical fiber core wires may cross at the tapered portion and the large diameter portion. Bending loss occurs when the optical fiber cores cross, and therefore, this is not preferable.

The present invention has been made in view of the above circumstances, and an object thereof is to provide an optical fiber bundle structure with a small loss, an optical connector, an optical fiber connection structure, and a method for manufacturing the optical fiber bundle structure.

Means for solving the problems

In order to solve the above-described problems and achieve the object, an optical fiber bundle structure according to an aspect of the present invention includes: a plurality of optical fiber cores; a crossing elimination member through which the plurality of optical fiber cores are penetrated in a longitudinal direction; and a grip member that gives a grip force to the cross-cancellation member, the plurality of optical fiber core wires having, in order from a distal end, a glass fiber portion and a resin coating portion that coats the glass fiber with a resin, the glass fiber portion having, in order from a distal end, a small diameter portion, a tapered portion, and a large diameter portion, the cross-cancellation member being formed with slits that have a width centered around a point in a cross section of the cross-cancellation member orthogonal to the longitudinal direction and that extend from the distal end to a halfway position on a rear end side of the cross-cancellation member, the point being obtained by equally dividing each side of a polygon that circumscribes the plurality of optical fiber core wires by the number of optical fiber core wires that meet the side, the width of the slit on each side being a length at which a terminal end portion of the slit on the rear end side circumscribes one side of the polygon of the plurality of optical fiber core wires and a length at which the slit circumscribes the plurality of optical fiber core wires on the front end side is one side of the polygon that circumscribes the plurality of optical fiber core wires More than a difference between degrees.

An optical fiber bundle structure according to an aspect of the present invention is characterized by comprising: a plurality of optical fiber cores; a crossing elimination member through which the plurality of optical fiber cores are penetrated in a longitudinal direction; and a grip member that gives a grip force to the cross-cancellation member, wherein the plurality of optical fiber cores have a glass fiber portion and a resin coating portion that coats the glass fiber with a resin in this order from a distal end, the glass fiber portion has a small diameter portion, a tapered portion, and a large diameter portion in this order from a distal end, a slit is formed in the cross-cancellation member, the slit has a width centered on a cross section of the cross-cancellation member orthogonal to the longitudinal direction, and extends from the distal end to a middle of a rear end side of the cross-cancellation member, the slit is obtained by equally dividing each side of a substantially polygonal shape externally connected to the plurality of optical fiber cores by the number of optical fiber cores connected to the side, each vertex portion of the substantially polygonal shape externally connected to the plurality of optical fiber cores has a curved shape, and a total of the widths of the slits on the sides is a terminal portion of the slit on the rear end side, and the plurality of optical fiber cores are connected to a terminal portion of the slit on the rear end side A difference between a length of an outer circumference in which the core wires are shortest and a length of an outer circumference in which the plurality of optical fiber core wires are shortest on a distal end side is not less than a predetermined value.

In addition to the above-described invention, in the optical fiber bundle structure according to one aspect of the present invention, the holding member is a ring fitted to the distal end side of the crossover reducing member.

In addition to the above-described invention, in the optical fiber bundle structure according to one aspect of the present invention, the plurality of optical fiber cores are disposed in the small diameter portion in a square shape.

In addition, in the optical fiber bundle structure according to one aspect of the present invention, the plurality of optical fiber cores are four or nine.

In addition to the above-described invention, in the optical fiber bundle structure according to one aspect of the present invention, the plurality of optical fiber cores are disposed in a hexagonal closest arrangement in the small diameter portion.

In addition to the above-described invention, the optical fiber bundle structure according to one aspect of the present invention is characterized in that the plurality of optical fiber cores are seven or nineteen.

In the optical connector according to one aspect of the present invention, the optical connector includes the optical fiber bundle structure described above, and the holding member is a ferrule having a hole portion that gives a holding force to the inserted crossover reducing member.

In addition, an optical fiber connection structure according to an aspect of the present invention is an optical fiber connection structure including: the above-described optical fiber bundle structure; and a multicore fiber having a plurality of core portions connected to cores of the plurality of optical fiber cores, and a cladding portion formed on an outer periphery of the core portions.

In addition, an optical fiber connection structure according to an aspect of the present invention is an optical fiber connection structure including: the above-described optical fiber bundle structure; and a plurality of light receiving/emitting units connected to cores of the plurality of optical fiber cores.

In addition, a method for manufacturing an optical fiber bundle structure according to an aspect of the present invention is characterized by including: an insertion step of inserting an intersection removal member into an annular guide member, the intersection removal member being configured to allow a plurality of optical fiber cores to pass through in a longitudinal direction, the plurality of optical fiber cores having a glass fiber portion and a resin coating portion in which a glass fiber is coated with a resin in this order from a distal end, into a slit, the slit having a width centered on a cross section orthogonal to the longitudinal direction of the intersection removal member and extending from the distal end to a middle of a rear end side of the intersection removal member, the slit being formed by equally dividing each side of a polygon externally connected to the plurality of optical fiber cores by the number of optical fiber cores connected to the side, the width of the slit located at each side being equal to the length of a side of the polygon externally connected to the plurality of optical fiber cores at a terminal end of the slit located at the rear end side and the multi-core externally connected to the plurality of optical fiber cores at the distal end side being fitted into the slit A difference between lengths of one side of the polygon or more; a penetrating step of aligning the plurality of optical fiber cores in a predetermined arrangement and penetrating the plurality of optical fiber cores from a front end side to a rear end side of the crossover removal member; a drawing step of drawing the optical fiber core wire to a rear end side while applying a gripping force to the cross eliminating member until a small diameter portion of the glass fiber portion having the small diameter portion, a tapered portion, and a large diameter portion in this order from a front end is positioned inside the cross eliminating member; a detaching step of detaching the guide member from the intersection-eliminating member; and a ferrule insertion step of inserting the crossover eliminating member into the hole of the ferrule while applying a gripping force to the crossover eliminating member.

In addition to the above invention, a method for manufacturing an optical fiber bundle structure according to an aspect of the present invention is characterized in that the drawing step includes: a first pulling step of pulling the optical fiber core wire to a rear end side until a rear end of the tapered portion of the glass fiber portion is positioned inside the crossover eliminating member; and a second drawing step of drawing the optical fiber core wire to a rear end side until the small diameter portion of the glass fiber portion is positioned inside the crossover eliminating member, the detaching step being performed between the first drawing step and the second drawing step.

In addition to the above-described invention, in the method for manufacturing an optical fiber bundle structure according to one aspect of the present invention, a thickness of the convex portion of the guide member is equal to or greater than a difference between a length of a side of the polygon circumscribing the plurality of optical fiber core wires at a rear end of the tapered portion of the optical fiber core wires and a length of a side of the polygon circumscribing the plurality of optical fiber core wires at a front end of the tapered portion of the optical fiber core wires.

Effects of the invention

According to the present invention, the optical fiber bundle structure, the optical connector, the optical fiber connection structure, and the method for manufacturing the optical fiber bundle structure, which are low in loss, are achieved.

Drawings

Fig. 1 is a schematic diagram showing the structure of an optical fiber bundle structure according to embodiment 1 of the present invention.

Fig. 2 is a sectional view corresponding to line a-a of fig. 1.

Fig. 3 is a schematic diagram showing the structure of the optical fiber core shown in fig. 1.

Fig. 4 is a schematic view illustrating a structure of the cross elimination member shown in fig. 1.

Fig. 5 is a sectional view corresponding to line E-E of fig. 4.

Fig. 6 is a sectional view corresponding to the line F-F of fig. 4.

Fig. 7 is a sectional view corresponding to line B-B of fig. 1.

Fig. 8 is a sectional view corresponding to the line C-C of fig. 1.

Fig. 9 is a sectional view corresponding to line D-D of fig. 1.

Fig. 10 is a cross-sectional view showing the optical fiber core wire and the crossover eliminating member of modification 1.

Fig. 11 is a cross-sectional view showing an optical fiber core and a crossover eliminating member according to modification 2.

Fig. 12 is a view showing slits of the crossover eliminating member according to modification 2.

Fig. 13 is a cross-sectional view showing an optical fiber core and a crossover eliminating member according to modification 3.

Fig. 14 is a cross-sectional view of the optical fiber core wire and the crossover eliminating member in modification 4, taken along the line B-B in fig. 1.

Fig. 15 is a cross-sectional view of the optical fiber core wire and the crossover eliminating member in modification 4, taken along the line C-C in fig. 1.

Fig. 16 is a schematic diagram showing the structure of an optical connector according to embodiment 2.

FIG. 17 is a view showing a state where the optical fiber core wire of FIG. 16 is pushed into the distal end side.

Fig. 18 is a schematic diagram showing the structure of the optical fiber connection structure according to embodiment 3.

Fig. 19 is a sectional view corresponding to line G-G of fig. 18.

Fig. 20 is a schematic diagram showing the structure of the optical fiber connection structure according to embodiment 4.

Fig. 21 is a sectional view corresponding to line H-H of fig. 20.

Fig. 22 is a flowchart illustrating a method of manufacturing the optical fiber bundle structure.

Fig. 23 is a schematic view showing the structure of the guide member.

Fig. 24 is an I-direction view of fig. 23.

Fig. 25 is a diagram showing a state where the crossover eliminating member is inserted into the guide member.

Fig. 26 is a diagram showing a state where an optical fiber core wire is inserted into the crossover eliminating member.

Fig. 27 is a sectional view corresponding to the line J-J of fig. 26.

Fig. 28 is a view showing a state in which the rear end of the tapered portion of the optical fiber core wire is positioned inside the guide member.

Fig. 29 is a sectional view corresponding to the line K-K of fig. 28.

Fig. 30 is a view showing a state where the crossover eliminating member is inserted into the small diameter portion of the optical fiber core wire.

Fig. 31 is a sectional view corresponding to the line L-L of fig. 30.

Detailed Description

Hereinafter, a mode (hereinafter, embodiment) for carrying out the present invention will be described with reference to the drawings. The present invention is not limited to the embodiments described below. In the description of the drawings, the same reference numerals are given to the same parts. The drawings are schematic, and the relationship between the sizes of the elements, the ratios of the elements, and the like may be different from the actual ones. Further, the drawings may include portions having different dimensional relationships and ratios from each other.

(embodiment mode 1)

[ optical fiber bundle Structure ]

First, the optical fiber bundle structure will be explained. Fig. 1 is a schematic diagram showing the structure of an optical fiber bundle structure according to embodiment 1 of the present invention. Fig. 2 is a sectional view corresponding to line a-a of fig. 1. Hereinafter, the left side is referred to as the front end and the right side is referred to as the rear end along the paper surface of fig. 1.

The optical fiber bundle structure 1 includes: a plurality of optical fiber cores 2 of the same diameter; a crossing elimination member 3 through which the plurality of optical fiber cores 2 pass along the longitudinal direction; and a grip member 4 that imparts a grip force to the crossover reducing member 3.

The optical fiber core 2 includes a core 21, a cladding 22 formed on the outer periphery of the core 21, and a cladding 23 made of resin. The optical fiber cores 2 are held in a predetermined arrangement. In the example shown in fig. 2, the cores 21 of the four optical fiber cores 2 are arranged so as to be at the vertex positions of a square (regular polygon). That is, the cores 21 of the adjacent optical fiber cores 2 are arranged at substantially the same distance from each other. In this way, the square arrangement is an arrangement that becomes a square when the centers of the cores 21 are connected.

The core 21 is made of, for example, quartz glass doped with germanium or the like and having a high refractive index. The refractive indices of the plurality of cores 21 may be the same, but may also be different. The cladding 22 is made of a material having a lower refractive index than the core 21, and is made of, for example, pure silica glass to which a dopant for adjusting the refractive index is not added.

Fig. 3 is a schematic diagram showing the structure of the optical fiber core shown in fig. 1. The optical fiber core wire 2 includes a glass fiber portion 2a and a resin coating portion 2b in order from the distal end, the glass fiber being coated with a resin. The glass fiber part 2a has a small diameter part 2aa, a tapered part 2ab, and a large diameter part 2ac in this order from the distal end.

The diameter of the small diameter portion 2aa is 40 μm in the clad diameter (the diameter of the clad 22), but may be 30 to 80 μm in the clad diameter and 6 to 12 μm in the core diameter (the diameter of the core 21), for example. The core diameters are the same in the glass fiber portion 2a (the small diameter portion 2aa, the tapered portion 2ab, and the large diameter portion 2ac) and the resin coating portion 2 b.

The diameter of the cladding becomes smaller as the taper portion 2ab approaches the front end. For the taper portion 2ab, the cladding diameter at the leading end is, for example, 40 μm, and the cladding diameter at the trailing end is, for example, 80 μm.

The small diameter portion 2aa and the tapered portion 2ab are formed by, for example, removing the coating portion 23 of the resin coating portion 2b to expose the glass fiber inside, and chemically etching a predetermined length of the distal end side of the exposed glass fiber. That is, the small diameter portion 2aa and the tapered portion 2ab are smaller in diameter than the large diameter portion 2 ac. For the large diameter portion 2ac, for example, the cladding diameter is 80 μm.

The resin coating portion 2b has a cladding diameter of, for example, 80 μm, and the outer periphery thereof is covered with the coating portion 23. The resin coating portion 2b has a coating diameter (diameter of the coating portion 23) of 125 μm, for example.

Fig. 4 is a schematic view illustrating a structure of the cross elimination member shown in fig. 1. Fig. 5 is a sectional view corresponding to line E-E of fig. 4. Fig. 6 is a sectional view corresponding to the line F-F of fig. 4. Fig. 4 to 6 are views showing a state where the grip force from the grip member 4 is not applied to the crossover reducing member 3.

The cross elimination member 3 has: a through hole 3a (see fig. 5) formed on the rear end side of the crossover eliminating member 3; a slit 3b (see fig. 4) extending from the front end of the intersection removal member 3 to the middle of the rear end side; and a cutout portion 3c (see fig. 6) formed in a region where the through hole 3a is projected to the distal end side of the crossover eliminating member 3.

As shown in fig. 2, the resin coating 2b of the four optical fiber cores 2 is inserted into the through hole 3 a. The through-hole 3a is a square having one side with a length substantially equal to the length of the two resin coating portions 2b, and for example, has one side with a length of 250 μm.

The slit 3b has a width centered on each side of a polygon circumscribing the plurality of optical fiber cores 2, the polygon having sides equally divided by the number of optical fiber cores 2 contacting the side, in a cross section (cross section orthogonal to the longitudinal direction) corresponding to the line E-E shown in fig. 5. In the case where the optical fiber core 2 shown in fig. 2 is four, the crossover eliminating member 3 has four slits 3b with a width w centered on the middle point of each side of a quadrangle circumscribed to the optical fiber core 2. The width w of the slit 3b is, for example, 170 μm.

The cutout 3c is 40 μm on one side, for example, and the slit 3b and the cutout 3c form a square having the same size as the through hole 3a, i.e., 250 μm on one side, as indicated by a chain line in a state where the grip force from the grip member 4 is not applied to the crossover-canceling member 3.

As shown in fig. 1, the width of the slit 3b is narrowed toward the distal end side by the gripping force applied from the grip member 4 to the crossover eliminating member 3. The gripping force is a force applied in the center direction of the cross section of the crossover-elimination member 3 perpendicular to the longitudinal direction.

Fig. 7 is a sectional view corresponding to line B-B of fig. 1. In fig. 7, since the width w1 of the slit 3b is 170 μm without narrowing, the square formed by the slit 3b and the cut-out portion 3c is a square with a side of 250 μm that is substantially equal to the length of the two resin coating portions 2 b.

Fig. 8 is a sectional view corresponding to the line C-C of fig. 1. In fig. 8, the square formed by the slit 3b and the cutout 3c is a rectangle having a side of 160 μm substantially equal to the length of the cladding diameter at the rear ends of the two tapered portions 2 ab. That is, the width w2 of the slit 3b is 80 μm.

Fig. 9 is a sectional view corresponding to line D-D of fig. 1. In fig. 9, the width of the slit 3b becomes substantially zero. At this time, the quadrangle formed by the cutout portion 3c is a quadrangle having one side of 80 μm substantially equal to the cladding diameter at the tip ends of the two taper portions 2 ab.

The grip member 4 is a ring fitted to the distal end side of the crossover reducing member 3. However, the grip member 4 may be an elastic member that applies elastic force from the outer periphery of the intersection removing member 3 or a hole into which the intersection removing member 3 is fitted, as long as it applies gripping force to the intersection removing member 3.

Here, the width of the slits 3b on each side is preferably equal to or greater than the difference between the length of one side of the polygon circumscribing the plurality of optical fiber cores 2 at the terminal end of the slit 3b on the rear end side and the length of one side of the polygon circumscribing the plurality of optical fiber cores 2 on the front end side. Specifically, in the case where the optical fiber cores 2 shown in fig. 2 are four, the difference between the length of 250 μm, which is the length of one side of a quadrangle circumscribing the four optical fiber cores 2 (resin coating portions 2b) at the end portions of the slits 3b on the rear end side, and the length of 80 μm, which is the length of one side of a quadrangle circumscribing the four optical fiber cores 2 (small diameter portions 2aa) on the front end side, is 170 μm, and the width of the slit 3b of the crossover eliminating member 3 is 170 μm. As a result, the width of the slit 3b is narrowed in accordance with the diameter reduction of the optical fiber 2 from the rear end side toward the front end side, and the crossing preventing member 3 abuts against the optical fiber 2 over the entire region of the optical fiber 2 in the longitudinal direction, thereby preventing the optical fiber 2 from crossing.

(modification 1)

Fig. 10 is a cross-sectional view showing the optical fiber core wire and the crossover eliminating member of modification 1. Fig. 10 is a sectional view corresponding to line a-a of fig. 1. The optical fiber bundle structure of modification 1 includes nine optical fiber cores 2 and a crossover reducing member 3A.

The optical fiber cores 2 are arranged so as to form a square arrangement when the centers of the cores 21 are connected. The crossover reducing member 3A has a rectangular through-hole 3 Aa. In this way, the optical fiber cores 2 can be arranged in a square arrangement of 2 × 2, 3 × 3, 4 × 4, and … …, regardless of the number. In this case, the shape of the through-hole formed in the crossover-canceling member may be substantially square.

(modification 2)

Fig. 11 is a cross-sectional view showing an optical fiber core and a crossover eliminating member according to modification 2. Fig. 11 is a sectional view corresponding to line a-a of fig. 1. The optical fiber bundle structure of modification 2 includes seven optical fiber cores 2 and a crossover reducing member 3B. In addition, the central one of the seven pieces may be treated as a dummy (Japanese: ダミ one), so that the optical fiber cores 2 may be six.

In the optical fiber 2, the optical fiber 2 is arranged in a hexagonal closest-spaced arrangement, and a line obtained by connecting the centers of the outer cores 21 forms a hexagon. The crossover eliminating member 3B has hexagonal through holes 3 Ba.

Fig. 12 is a view showing slits of the crossover eliminating member according to modification 2. Fig. 12 is a sectional view corresponding to the line E-E shown in fig. 5. The cross elimination member 3B has six slits 3Bb centered on the middle point of each side of the hexagon circumscribed with the optical fiber core wire 2. In a state where no gripping force is applied to the crossover eliminating member 3, the slits 3Bb and the cutouts 3Bc form a hexagonal shape having the same size as the through-holes 3Ba as indicated by the chain line.

(modification 3)

Fig. 13 is a cross-sectional view showing an optical fiber core and a crossover eliminating member according to modification 3. Fig. 13 is a sectional view corresponding to line a-a of fig. 1. The optical fiber bundle structure of modification 3 includes nineteen optical fiber cores 2 and a crossover reducing member 3C.

The optical fiber cores 2 are arranged so as to form a hexagonal closest-packed arrangement when the centers of the cores 21 are connected. The crossover eliminating member 3C has hexagonal through holes 3 Ca. In this way, the optical fiber cores 2 can be arranged in a hexagonal close-packed arrangement such as 1+6, 1+6+2 × 6+3 × 6, and … …, regardless of the number of the optical fiber cores. In this case, the shape of the through-hole formed in the crossover-canceling member may be substantially hexagonal.

(modification 4)

Fig. 14 is a cross-sectional view of the optical fiber core wire and the crossover eliminating member in modification 4, taken along the line B-B in fig. 1. As shown in fig. 14, the slit 3Db has a width centered on a point obtained by equally dividing each side of a substantially polygonal shape substantially circumscribed to the plurality of optical fiber cores 2 by the number of optical fiber cores 2 in contact with the side. In the case where the optical fiber core 2 shown in fig. 14 is four, the cross-canceling member 3D has four slits 3Db having widths W11, W12, W13, and W14 centered on the midpoint of each side of a substantially quadrilateral circumscribing the optical fiber core 2. The total width of the slits 3Db (W11+ W12+ W13+ W14) is, for example, 680 μm. The cutout portion 3Dc is formed of a part of a circle having a radius of 40 μm, for example, and has a curved shape substantially circumscribing the optical fiber core wire 2. In the example shown in fig. 14, the cutout portion 3Dc is, for example, an arc. In a state where the grip force from the grip member 4 is not applied to the intersection-canceling member 3D, the slit 3Db and the cutout portion 3Dc form an approximately quadrangular shape having a size equal to that of the through-hole (not shown) and a rounded arc shape with smooth corners, and a side of the substantially quadrangular shape is approximately 250 μm, as indicated by a thick solid line. That is, in fig. 14, since the total width of the slits 3Db (W11+ W12+ W13+ W14) is not narrowed and is, for example, 680 μm, the substantially polygonal shape, that is, the substantially square shape formed by the slits 3Db and the cutout portions 3Dc is a shape in which the four corners of a quadrangle having a side of 250 μm substantially equal to the length of the two resin coating portions 2b are curved.

As shown in fig. 1, the width of the slit 3b is narrowed toward the distal end side by the gripping force applied from the grip member 4 to the crossover eliminating member 3. Fig. 15 is a cross-sectional view of the optical fiber core wire and the crossover eliminating member in modification 4, taken along the line C-C in fig. 1. In fig. 15, the substantially square shape formed by the slit 3Db and the cutout portion 3Dc is a quadrangle having one side of 160 μm substantially equal to the length of the cladding diameter at the rear ends of the two taper portions 2 ab. That is, in fig. 15, the total width of the slits 3Db (W21+ W22+ W23+ W24) is 320 μm.

As shown in fig. 14 and 15, the cutout portions 3Dc, which are the substantially polygonal vertexes circumscribing the plurality of, for example, four optical fiber cores 2, have curved shapes circumscribing the optical fiber cores 2. The total of the widths of the slits 3Db on each side (W11+ W12+ W13+ W14) is equal to or greater than the difference between the length of the outer circumference (thick solid line in fig. 14) that surrounds the plurality of optical fiber cores 2 at the shortest distance at the terminal end of the slit on the rear end side and the length of the outer circumference (thick solid line in fig. 15) that surrounds the plurality of optical fiber cores 2 at the shortest distance on the front end side.

(embodiment mode 2)

[ optical connector ]

Next, an optical connector using the optical fiber bundle structure 1 will be described. Fig. 16 is a schematic diagram showing the structure of an optical connector according to embodiment 2. The optical connector 100 includes an optical fiber bundle structure 1A.

The optical fiber bundle structure 1A includes a ferrule 11 having a hole 11A, and the hole 11A gives a gripping force to the inserted crossover reducing member 3. The ferrule 11 has a fine hole portion 11b into which the small diameter portion 2aa of the optical fiber 2 is inserted.

According to embodiment 2 described above, the optical connector 100 can be connected to a multicore fiber or the like built in a connectable connector with low loss.

FIG. 17 is a view showing a state where the optical fiber core wire of FIG. 16 is pushed into the distal end side. As shown in fig. 17, after the optical fiber bundle structure 1 is inserted into the hole 11a of the ferrule 11, the optical fiber core 2 may be pushed in until the tip of the small diameter portion 2aa reaches the deep portion of the small hole 11 b.

(embodiment mode 3)

[ optical fiber connecting structure ]

Fig. 18 is a schematic diagram showing the structure of the optical fiber connection structure according to embodiment 3. Fig. 19 is a sectional view corresponding to line G-G of fig. 18. The optical fiber connection structure 200 includes the optical fiber bundle structure 1, the multi-core fiber 12, and the capillary 13.

The multi-core fiber 12 has: a plurality of cores 12a as a plurality of core portions; and a cladding 12b as a cladding portion formed on the outer periphery of the core 12 a. As shown in fig. 19, the multicore fiber 12 has, for example, four cores 21, and the cores 21 are arranged in a square arrangement. The cores 21 are connected to the cores 21, respectively.

The bundle structure 1 and the multicore fibers 12 are connected by bonding or fusion. According to embodiment 3 described above, the cores 12a of the multicore fiber 12 and the cores 21 of the optical fiber 2 can be connected with low loss.

(embodiment mode 4)

[ other fiber-optic connection structures ]

Fig. 20 is a schematic diagram showing the structure of the optical fiber connection structure according to embodiment 4. Fig. 21 is a sectional view corresponding to line H-H of fig. 20. The optical fiber connection structure 300 includes the optical fiber bundle structure 1 and the light receiving and emitting element 14.

As shown in fig. 21, the light-receiving and light-emitting element 14 includes, for example, four light-receiving and light-emitting portions 14a as a plurality of light-receiving and light-emitting portions, and the light-receiving and light-emitting portions 14a are arranged in a square arrangement. The light receiving and emitting sections 14a are connected to the cores 21, respectively.

By joining the optical fiber bundle structure 1 and the light receiving/emitting element 14, the light receiving/emitting portions 14a of the light receiving/emitting element 14 and the cores 21 of the optical fiber core 2 can be connected with low loss.

[ method for manufacturing optical fiber bundle Structure ]

Next, a method of manufacturing the optical fiber bundle structure 1 will be explained. Fig. 22 is a flowchart illustrating a method of manufacturing the optical fiber bundle structure.

First, the crossover eliminating member 3 is inserted into the guide member (step S1: insertion process). Fig. 23 is a schematic view showing the structure of the guide member. Fig. 24 is an I-direction view of fig. 23. The guide member 5 is an annular member and has a convex portion 5a having a thickness t protruding in the inner circumferential direction. The thickness t of the projection 5a is, for example, 80 μm.

Fig. 25 is a diagram showing a state where the crossover eliminating member is inserted into the guide member. The intersection-canceling member 3 is inserted into the guide member 5 so that the convex portion 5a of the guide member 5 fits in the slit 3b of the intersection-canceling member 3.

Next, the plurality of optical fiber cores 2 are inserted into the crossover eliminating member 3 (step S2: insertion step). Fig. 26 is a diagram showing a state where an optical fiber core wire is inserted into the cross member. Fig. 27 is a sectional view corresponding to the line J-J of fig. 26. Four optical fiber cores 2 are arranged in a regular pattern so as to be in a square arrangement, and the four optical fiber cores 2 are inserted from the front end side to the rear end side of the crossover eliminating member 3. In the cross section shown in fig. 27, the length L1 of one side of the square formed by the slit 3b and the cutout 3c is 250 μm, which is substantially equal to the length of the two resin coating portions 2 b.

Then, the optical fiber core wire 2 is pulled toward the rear end side while applying a grip force F to the crossover reducing member 3 so that the rear end of the tapered portion 2ab of the glass fiber portion 2a is positioned inside the crossover reducing member 3 (step S3: first pulling step). The grip force F acting on the crossover-elimination member 3 may be applied by the guide member 5, but the grip force F may be applied to the crossover-elimination member 3 by hand.

Fig. 28 is a view showing a state in which the rear end of the tapered portion of the optical fiber core wire is positioned inside the guide member. Fig. 29 is a sectional view corresponding to the line K-K of fig. 28. In the state shown in fig. 28 and 29, the inner surface of the cross member 3 is brought into contact with the optical fiber 2 by the grip force F. In the cross section shown in fig. 29, the length L2 of one side of the square formed by the slit 3b and the cutout portion 3c is 160 μm, which is substantially equal to the length of the two large diameter portions 2 ac. In this state, the gap of the slit 3b matches the thickness of the projection 5 a.

Thereafter, the guide member 5 is detached from the intersection-eliminating member 3 (step S4: detaching process).

Then, the optical fiber core wire 2 is pulled toward the rear end side while applying the grip force F to the crossover eliminating member 3 so that the small diameter portion 2aa of the glass fiber portion 2a is positioned inside the crossover eliminating member 3 (step S5: second pulling step). Fig. 30 is a view showing a state where the crossover eliminating member is inserted into the small diameter portion of the optical fiber core wire. Fig. 31 is a sectional view corresponding to the line L-L of fig. 30. In the state shown in fig. 30 and 31, the inner surface of the cross member 3 is brought into contact with the optical fiber 2 by the grip force F. In the cross section shown in fig. 31, the length L3 of one side of the square formed by the slit 3b and the cutout 3c is 80 μm, which is substantially equal to the length of the two small-diameter portions 2 aa.

Here, the thickness t of the convex portion 5a of the guide member 5 is preferably equal to or more than a difference between a length (160 μm) of one side of a polygon (quadrangle) circumscribing the plurality of optical fiber cores 2 at the rear end of the tapered portion 2ab of the optical fiber core 2 and a length (80 μm) of one side of the polygon (quadrangle) circumscribing the plurality of optical fiber cores 2 at the front end of the tapered portion 2ab of the optical fiber core 2. When this condition is satisfied, when the guide member 5 is detached from the intersection-canceling member 3, a gap corresponding to the thickness t of the projection 5a is generated in the slit 3 b. As a result, the width of the slit 3b is narrowed from the rear end of the tapered portion 2ab toward the front end in accordance with the diameter reduction of the optical fiber core 2, and the crossover eliminating member 3 abuts against the optical fiber core 2 over the entire range of the longitudinal direction of the tapered portion 2ab of the optical fiber core 2, thereby preventing the optical fiber core 2 from being crossed.

Then, the crossover eliminating member 3 is inserted into the hole of the ferrule while applying a grip force F to the crossover eliminating member 3 (step S5: ferrule insertion process). Specifically, for example, the crossover eliminating member 3 is inserted into the hole 11a of the ferrule 11 shown in fig. 16.

Industrial applicability

The present invention is suitably applied to an optical fiber bundle structure in which cores of single-core optical fibers are arranged at positions corresponding to the cores of multi-core optical fibers.

Description of reference numerals:

1. 1A optical fiber bundle structure

2 optical fiber core wire

2a glass fiber part

2aa diameter-reduced part

2ab taper

2ac large diameter part

2b resin coating part

3. 3A, 3B, 3C, 3D cross elimination member

3a, 3Aa, 3Ba, 3Ca through-hole

3b, 3Bb, 3Db slit

3c, 3Bc, 3Dc cut-out portion

4 gripping member

5 guide member

5a convex part

11 inserting core

11a hole part

11b pore part

12 multicore optical fiber

13 capillary tube

14 light receiving and emitting element

14a light receiving/emitting unit

21. 12a core

22. 12b cladding

23 coating part

100 optical connector

200. 300 optical fiber connection structure.