JP2003302561A - Optical fiber component and method of manufacturing the same - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an optical fiber component having high durability, reliability and improved transmission characteristics, and also to provide a method for manufacturing such optical fiber component easily and with a high yield. <P>SOLUTION: The optical fiber component 1 is equipped with a plurality of optical fiber cords 2 which include a coated optical fiber 21, a reinforcing material 22 and a skin 23 covering the fiber 21 and the material 22, a tape-like fiber part 3 in which the coated optical fibers 21 exposed from the plurality of optical fiber cords 2 are arrayed/integrated, and a branch fixing part 4 having one end part 41a which fixes the end 23a of the skin 23 of each optical fiber cord 2, and the other end part 41b which fixes the tape-like fiber part 3 and the tip end 22a of the reinforcing material 22 exposed from each optical fiber cord 2, and for storing each coated optical fiber 21 and reinforcing material 22 which are in a state exposed from each optical fiber cord 2 between the one end part 41a and the other end part 41b. <P>COPYRIGHT: (C)2004,JPO

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical fiber component used for optical communication and a manufacturing method thereof, and more particularly to an optical fiber component provided with a tape fiber portion in which optical fiber cores are aligned and integrated and a manufacturing method thereof. .

[0002]

2. Description of the Related Art Conventionally, as a typical optical component used in optical communication, an arrayed waveguide grating type optical multiplexer / demultiplexer circuit (Arrayed Waveguide Grain) is used.
g), Mach-Zehnder interferometer circuit, etc. are known.
These optical components are planar optical waveguide circuits (PLC: Planar L) having a substrate made of silicon or quartz and an optical waveguide including a core and a clad structure formed on the substrate.
It includes an optical element such as a lightwave circuit. Such an optical component includes a large number of optical fibers forming an optical circuit, and a multi-core tape fiber (ribbon fiber) is generally used to connect the optical component and another optical fiber.

A multi-core tape fiber connected to an optical component is fusion-spliced to another multi-core tape fiber or MT.
It may be connected to a multi-fiber optical connector such as a connector. However, generally, the multi-core tape fiber connected to the optical component is separated for each single-core optical fiber core, and a single-core optical connector is attached to each of the separated optical fiber cores. Here, a structure in which the tape fiber is separated for each single optical fiber core wire is called a fan-out structure because of its shape.

FIG. 11 shows a conventional optical fiber component having a fan-out structure. The optical fiber component 100 shown in the figure includes a tape fiber 102 in which eight optical fiber core wires 101 are aligned and integrated. The tape fiber 102 is inserted into the protective casing 103, and inside the protective casing 103, the tape fiber 102 is removed from the middle.
The optical fiber core wire 101 of the book is separated. The tape fiber 102 is composed of eight separated optical fiber core wires 10.
It is fixed to the protective casing 103 at the root portion of 1. On the other hand, eight individually separated optical fiber core wires 10
Each of 1 is inserted in the reinforcing tube 104. The eight reinforcing tubes 104 are stacked in two stages of four, and the end of each reinforcing tube 104 is fixed to the protective casing 103.

Tape fiber 102 and each reinforcing tube 1
A fan-out portion 105 is formed between the end portion 04 and the optical fiber core wire 101 so as to be individually separated. The fan-out part 105 is provided in the protective casing 103.
It is housed inside. Further, two screw insertion portions 107 are fixed to the side portion of the protection casing 103, and the protection casing 103 can be fixed at a predetermined position by using each screw insertion portion 107. In the example shown in FIG. 11, the SC type optical connector 10 is attached to the tip of each optical fiber core wire 101 protruding from the reinforcing tube 104.
6 is installed.

As described above, the optical fiber component 100 has the branch fixing portion 108 which is a position for fixing the integrated optical fiber core wires 101 individually and fixing the entire component at a predetermined position. Then, the branch fixing part 10 is formed by using a fixing screw (not shown) and each screw insertion part 107.
By fixing 8 (protective casing 103) to a predetermined position and connecting each optical connector 106 to another optical component, a predetermined optical communication network or optical communication module can be formed.

The above-mentioned optical fiber component shown in FIG. 11 is manufactured by the following procedures (1) to (6). (1) The outer cover is removed from one end of a long multi-core tape fiber over a certain length to expose a plurality of optical fiber cores by a predetermined length. (2) Insert the separated optical fiber cores into a plurality of reinforcing tubes prepared in advance. (3) The separated optical fiber cores are cut into a predetermined length. (4) An optical connector or the like is directly attached to the front end of the cut and aligned optical fiber core wire by a normal manufacturing process. Alternatively, another assembled optical component is connected to the tip of the cut optical fiber core wire by fusion splicing or the like. (5) The fan-out portion is housed in the protective casing, and the ends of the tape fibers and the ends of the reinforcing tubes are aligned in the protective casing. (6) The tape fiber, the end of each reinforcing tube, and the fanout portion are fixed to the protective case.

[0008]

In the optical fiber component as described above, the length of the optical fiber core wire between the branch fixing portion (protective casing) and each optical connector is determined by the length of each optical connector and the connection target. Must be at least equal to or greater than the distance to other optical components. For this reason, if the optical connector or the like is not properly attached to any one of the plurality of optical fiber cores separated from the tape fiber, the optical fiber cores are truncated to shorten the optical fiber core. I have to do it.

In such a case, for example, if the lengths of the optical fiber cores between the branch fixing portion (protective casing) and the optical connector must be the same for all the optical fiber cores, Therefore, it becomes necessary to redo the adjustment of the separation length from the tape fiber and the mounting of the optical connector and the like. In addition, even if the optical connector or the like is physically attached to the optical fiber core properly, in a test after completion, a predetermined transmission characteristic cannot be obtained for any one optical fiber core. Similarly, it may be necessary to redo the adjustment of the separation length from the tape fiber and the mounting of the optical connector or the like for all the optical fiber cores. From these points, conventional optical fiber parts are
There is a problem in yield etc.

Further, in the above-mentioned optical fiber component, since each optical fiber core wire separated from the tape fiber is merely accommodated in the reinforcing tube, the optical fiber core wire in the reinforcing tube is caused by some external cause. Bending stress or tensile stress may be added to the. In such a case, a so-called microbend occurs in the optical fiber core wire, which causes an increase in transmission loss. From this point, conventional optical fiber parts have room for improvement in terms of durability and reliability.

Therefore, the present invention makes it possible to easily manufacture an optical fiber component having high durability, reliability, and good transmission characteristics, and to manufacture such an optical fiber component easily and at a high yield. An object of the present invention is to provide a method for manufacturing an optical fiber component.

[0012]

One aspect of the present invention relates to an optical fiber component used for optical communication, and this optical fiber component includes an optical fiber core wire, a reinforcing material, and an optical fiber core wire and a reinforcing material. A plurality of optical fiber cords including a covering outer cover, a tape fiber portion in which optical fiber cores exposed from the plurality of optical fiber cords are aligned and integrated, and one end where the outer cover of each optical fiber cord is fixed, Also, the tape fiber portion and the end of the reinforcing material exposed from each optical fiber cord have the other end fixed, and are exposed from each optical fiber cord between the one end and the other end. The optical fiber core wire in a state and a branch fixing portion that accommodates the reinforcing material are provided.

In this optical fiber part, various optical parts are connected to the respective optical fiber cords extending from one end of the casing and the tape fiber part extending from the other end of the casing, so that predetermined optical components can be obtained. The optical communication network and the optical communication module can be configured. Like the conventional optical fiber component, the optical fiber component includes a tape fiber including a plurality of optical fiber core wires and a single-fiber optical fiber core wire separated from the tape fiber into a plurality of tensile strength fibers, etc. A plurality of optical fiber cords in which the reinforcing material of (1) is previously incorporated. Then, in this optical fiber component, the single-core optical fiber cores stripped from the respective optical fiber cords are aligned and integrated to form a tape fiber portion. As a result, the reinforcing material included in the optical fiber cord in advance plays a role of reinforcing and buffering the entire fiber, so that the durability against bending stress and tensile stress of each optical fiber core is improved, and the bending stress and tensile stress are improved. Transmission loss and the like caused by microbends and the like caused by the above are significantly reduced. Therefore, the optical fiber component according to the present invention has high durability and reliability, and good transmission characteristics.

When a plurality of optical fiber cords having optical components such as an optical connector, a semiconductor laser, a photodiode, etc. are already attached to one end of the optical fiber component when the optical fiber component is constructed, the outer cover of the optical fiber cord is used. The remaining length, that is, the length of the optical fiber cord extending from the casing can be adjusted to an arbitrary or fixed length, and the optical characteristics of the optical fiber cords (optical components) are predetermined in advance. The optical fiber component can be constructed after confirming whether or not the conditions are satisfied. Therefore, in the optical fiber component according to the present invention, the optical characteristics of all the optical fiber cords (and the optical components) are well maintained under desired conditions. Also in this case,
After the parts are completed, the characteristics of any one of the optical fiber cords (the optical parts attached to them) do not satisfy the conditions, so that it is basically impossible to remanufacture the whole parts. The yield of optical fiber parts is dramatically improved.

As described above, a single-core or multi-core optical connector, a semiconductor laser (LD), a photodiode (PD) is provided on at least one of the plurality of optical fiber cords and at least one of the tape fiber portions. ), A planar optical waveguide circuit (PLC), a fiber block, and other optical components are preferably connected.

Another aspect of the present invention relates to a method of manufacturing an optical fiber component used for optical communication, which method includes (a)
By removing the outer cover over a predetermined length from one end side of a plurality of optical fiber cords including the optical fiber core wire, the reinforcing material, and the outer cover covering these, the optical fiber core wire and the reinforcing material are exposed from each optical fiber cord. A step, (b) a step of forming a tape fiber portion by aligning and integrating the respective optical fiber cores exposed from the respective optical fiber cords, and (c) a casing for the outer skin of the respective optical fiber cords. While fixing the tape fiber portion and the tip of the reinforcing material stripped from each optical fiber cord to the other end portion of the casing while being fixed to one end portion of the And a step of fixing the existing optical fiber core wire and the reinforcing material between one end portion and the other end portion of the casing.

According to such a method, an optical fiber component having high durability, reliability and good transmission characteristics can be easily manufactured with a high yield.

In this case, it is preferable to attach an optical component to at least one of the plurality of optical fiber cords prior to the step (a).

[0019]

BEST MODE FOR CARRYING OUT THE INVENTION Preferred embodiments of an optical fiber component and a method for manufacturing the same according to the present invention will be described below in detail with reference to the drawings.

FIG. 1 is a perspective view showing an optical fiber component according to the present invention. The optical fiber component 1 shown in these drawings includes a plurality (eight in this embodiment) of optical fiber cords 2, a tape fiber portion (in this embodiment, eight-core tape fiber) 3, and a branch fixing portion. Have 4. The plurality of optical fiber cords 2 extend outward from one end of the branch fixing portion 4. Further, the tape fiber portion 3 extends from the other end of the branch fixing portion 4 to the side opposite to the optical fiber cords 2 and outward. The branch fixing part 4 includes two screw insertion parts 5. In this embodiment, an optical connector (SC type optical connector) 6 is attached to the tip of each optical fiber cord 2. Further, as shown in FIG. 1, in the present embodiment, among the plurality of optical fiber cords 2 extending from the branch fixing portion 4, four optical fiber cords 2 have the same length and are set to be relatively short. The lengths of the other four optical fiber cords 2 are set to be the same and relatively long.

2 to 5 show the detailed structure of the above-mentioned optical fiber component 1. As shown in FIG. Each optical fiber cord 2 included in the optical fiber component 1 includes an optical fiber core wire 21, a reinforcing member 22 made of tensile strength fiber such as Kevlar (trademark), and an outer cover 23. As shown most clearly in FIG. 4, the reinforcing material 22 is gathered around the optical fiber core wire 21 (twisted together), and the outer cover 23 is the reinforcing material 22.
Is further formed on the outer circumference.

In the optical fiber component 1, a plurality of these (8
By removing a part of the outer cover 23 from each of the optical fiber cords 2), the optical fiber core wires 21 are exposed, and the plurality of (8) optical fiber core wires 2 that are exposed are removed.
The tape fiber portion 3 is formed by aligning the 1 and integrating them by using a resin or the like. Also,
As shown in FIG. 2 and FIG. 3, each optical fiber cord 2, that is, the end 23a of the outer sheath 23 that remains,
Between the tape fiber portion 3 and each optical fiber core wire 21
Further, the fan-out portion 20 that exists in a state where the reinforcing material 22 is exposed from each optical fiber cord 2 is formed.

The end 2 of the outer cover 23 of each optical fiber cord 2
3a and the end of the tape fiber part 3 are connected to the branch fixing part 4
The fan-out section 20 is housed in the branch fixing section 4. The branch fixing portion 4 has a casing body 41 and a protective cover 42. Casing body 4
Reference numeral 1 is made of metal or the like and basically has a substantially U-shaped cross section. One end 4 of the casing body 41
1a has internal dimensions (internal width and internal height) determined so that eight optical fiber cords 2 each having an outer cover 23 can be arranged in a stack of 4 rows × 2 stages (FIG. 4). reference). At one end 41a of the casing body 41, eight optical fiber cords 2 arranged in 4 rows × 2 stages are arranged.
An end 23a of the outer skin 23 is fixed by an adhesive. On the other hand, the other end 41b of the casing body 41
As can be seen from FIGS. 2 and 5, the width is smaller than that of the one end portion 41a. Two fixing members 44 made of a rubber material or the like are used for the other end portion 41b of the casing body 41, and the end portion (the fan-out portion 20) of the tape fiber portion 3 is used.
Side end) is fixed.

On the other hand, the protective cover 42 constituting the branch fixing portion 4 also has a substantially U-shaped cross section. Protective cover 4
The internal dimensions (internal width and internal height) of 2 substantially match the external dimensions (external width and external height) of the one end portion 41a of the casing body 41. The protective cover 42 is fixed to the casing body 41 with an adhesive so as to cover the end 23a of the outer cover 23 of each optical fiber cord 2, the fan-out part 20, and the end (upper fixing member 44) of the tape fiber part 3. It

Further, in the optical fiber component 1, as shown in FIGS. 2 and 5, the end portion 22a of the reinforcing member 22 is the other end portion 41b of the casing body 41 (the other end of the branch fixing portion 4).
Fixed to. As a result, external force such as tension or bending applied to each of the separated optical fiber cords 2 is applied to the reinforcing material 22, and the optical fiber core wire 2 in each optical fiber cord 2 is applied.
Direct application of external force to 1 will be significantly reduced. Further, each optical fiber core wire 21 and the reinforcing member 2 which are in a state of being stripped from each optical fiber cord 2.
2, that is, the fan-out part 20 is accommodated in the branch fixing part 4 (between one end and the other end of the branch fixing part 4) including the casing body 41 and the protective cover 42.

In the present embodiment, one reinforcing member fixing member 45 is arranged between both outer side surfaces of the other end portion 41b of the casing body 41 and the inner side surface of the protective cover 42. Reinforcement material 22 exposed from each optical fiber cord 2
As shown in FIG. 2, the tips 22a of the reinforcing members 45 and the casing main body 41 are collected into two bundles.
It is held / fixed between the other end portion 41b and the outer side surface thereof by using an adhesive. The other end 41 of the casing body 41
The width of b is set to be slightly smaller than the inner width of the protective cover 42, and the tip of the reinforcing member 22 exposed from each optical fiber cord 2 is provided between the other end 41b of the casing body 41 and the protective cover 42. 22a may be sandwiched and fixed by an adhesive.

Next, a method of manufacturing the above-mentioned optical fiber component 1 will be described with reference to FIGS.

When manufacturing the optical fiber component 1,
First, a plurality of long optical fiber cords 2 (eight in the case of the present embodiment) including the optical fiber core wire 21, the reinforcing material 22, and the outer cover 23 covering these are prepared (S10). Then, as shown in FIG. 7 and FIG. 8, the outer cover 23 is removed from one end side of the prepared plurality of optical fiber cords 2 over a predetermined length, and the optical fiber cords 21 and the reinforcing material are removed from each optical fiber cord 2. 22 and are exposed (S12).

Next, the respective optical fiber cords 2 are cut as appropriate, and the outer sheath remaining length of each optical fiber cord 2 is set to a predetermined value (S14). In the case of the present embodiment, of the eight optical fiber cords 2, the lengths of the four optical fiber cords 2 are set to be the same and relatively short, and the lengths of the other four optical fiber cords 2 are set. Set the same and relatively long.
The optical fiber core wire 21 and the reinforcing material 22 exposed from each optical fiber cord 2 are separated to facilitate the subsequent work, and the reinforcing material 22 is put together for each optical fiber cord 2 (S16, (See FIG. 8).

When the processing up to S16 is completed, each optical fiber core wire 21 exposed from each optical fiber cord 2
The tape fiber portion 3 is formed by aligning and integrating (S18). In the step of forming the tape fiber portion in S18, for example, Japanese Unexamined Patent Publication
The optical fiber tape forming device described in Japanese Patent No. 54074 can be used. In the device described in this publication, a plurality of optical fiber core wires are aligned in a fiber alignment section, and then conveyed to a resin application section, and an ultraviolet curing resin is applied to each optical fiber core wire, followed by resin curing. The resin cures the resin by ultraviolet rays.

When the tape fiber portion 3 is formed,
The end 2 of the outer skin 23 of each optical fiber cord 2
3a, the end portion of the tape fiber portion 3 and the optical fiber core wire 21 and the reinforcing material 22 which are in a state of being stripped from each optical fiber cord 2 are fixed to the casing body 41, and the fan-out portion 20 is casing. It is housed in the main body 41 and the protective case 42 (S20).

The fixing / accommodating step will be described in detail. The end 23a of the outer sheath 23 of each optical fiber cord 2 is an even numbered wire (in the present embodiment, 2, 4) in the tape fiber portion 3. Optical fiber cord 2 (end portion 23a) including the optical fiber core wire 21 to be the 6th and 8th wires)
So that the optical fiber cord 2 (the end portion 23a) including the optical fiber core wire 21 which is the odd numbered wire (the wires 1, 3, 5 and 7 in the present embodiment) in the tape fiber portion 3 is located in the lower row. At one end 4 of the casing body 41
Multiple rows and multiple stages in 1a (4 rows and 2 rows in this embodiment)
Lanes) and fixed with an adhesive. When fixing the end portion 23a of the outer cover 23 of each optical fiber cord 2 to the one end portion 41a of the casing body 41, the end portions 23a are aligned in a plurality of rows in advance and fixed by an adhesive, and then the one end portion is fixed. It may be arranged and fixed in 41a.

Further, the end portion of the tape fiber portion 3 (end portion on the fan-out portion 20 side) is sandwiched between two fixing members 44 made of a rubber material or the like, and these fixing members 44 are provided in the casing body 41. Is inserted into the other end portion 41b of the. As a result, the end portion of the tape fiber portion 3 is moved to the casing body 4
It is held and fixed at 1. Further, in the present embodiment, the reinforcing material 22 exposed from each optical fiber cord 2 is collected into two bundles, and the other end portion 41 is provided outside the casing body 41.
Each bundle is pulled out from both sides of b. Each bundle of the reinforcing material 22 that has been pulled out is pressed against each outer side surface of the other end portion 41b of the casing body 41 with the reinforcing material fixing member 45 interposed, and is firmly fixed by an adhesive. As a result, the fan-out portion 20 is housed between the one end portion 41a and the other end portion 41b of the casing body 41.

Thereafter, an adhesive is applied to an appropriate portion on the casing body 41 side, such as the end 23a (the upper surface) of the outer cover 23 of each optical fiber core wire 21 located on the upper stage and the upper surface of the fixing member 44 on the upper stage. The coating is applied, and the casing body 41 is covered with the protective cover 42 to adhere and fix the both. As a result, the fan-out part 20 is housed in the branch fixing part 4 (between one end and the other end of the branch fixing part 4) including the casing body 41 and the protective cover 42. Then, as illustrated in FIG. 5, on both sides of the other end portion 41b,
The position of the reinforcing member 22 is adjusted so that the end portion 22a of the reinforcing member 22 is located substantially in the center of the gap defined between the casing main body 41 and the reinforcing member fixing member 45, and the casing main body 41 and the protective cover 42. The surplus reinforcing material 22 drawn out of the (branch fixing part 4) is cut.

In this embodiment, after the protective cover 42 is attached to the casing body 41, both outer side surfaces of the other end 41b of the casing body 41 and the protective cover 4 are attached.
Even if the reinforcing material fixing member 45 is inserted between the inner side surface of the second reinforcing member 22 and the tip 22a of each reinforcing material 22 (the tip of the bundle of the reinforcing material 22) is firmly fixed to the casing body 41 (the branch fixing portion 4). Good. Further, as described above, after the front end of the bundle of the reinforcing material 22 is sandwiched between both outer side surfaces of the other end portion 41b of the casing body 41 and the reinforcing material fixing member 45, the protective cover 42 is attached to the casing body 41. May be. In addition, the bundle of the reinforcing members 22 is composed of the two fixing members 4 that hold the tape fiber portion 3.
4 and the inner surface of the other end portion 41b of the casing body 41 may be sandwiched between the casing body 4 and the casing body 4 as described above.
Alternatively, it may be sandwiched in the gap between the other end portion 41b of 1 and the protective cover 42 and fixed by an adhesive.

The optical fiber component 1 manufactured by the method as described above is, like a conventional optical fiber component, a tape fiber including a plurality of optical fiber core wires and a single fiber separated from the tape fiber. Instead of including the optical fiber core wire, a plurality of optical fiber cords 2 in which a reinforcing material 22 such as Kevlar fiber is incorporated are included. Then, in the optical fiber component 1, the single optical fiber core wires 21 exposed from the respective optical fiber cords 2 are aligned and integrated to form the tape fiber portion 3.

As a result, the reinforcing material 22 contained in the optical fiber cord 2 in advance plays a role of reinforcing and buffering the whole, and the durability of each optical fiber core wire 21 against bending stress and tensile stress is improved. Transmission loss and the like caused by microbends and the like due to bending stress, tensile stress, and the like are significantly reduced. Therefore, the optical fiber component 1 according to the present invention has high durability and reliability, and good transmission characteristics. Further, according to the above-described method of manufacturing an optical fiber component of the present invention, it becomes possible to easily manufacture the optical fiber component 1 having high durability, reliability and good transmission characteristics with a high yield.

By the way, in the above-mentioned S10, for example, a single-fiber optical connector and a semiconductor laser (L) are required in the finally constructed optical communication network or optical communication module.
It is preferable to prepare an optical fiber cord 2 to which optical components such as D) and a photodiode (PD) are attached in advance. That is, an optical component such as the optical connector 6 (see FIG. 7) or the laser diode module 9 (see FIG. 8) to be attached to at least one of the plurality of optical fiber cords 2 of the optical fiber component 1 is S12. It is preferable that the optical fiber cord 2 is attached to the target optical fiber cord 2 before the outer cover 23 is removed from each optical fiber cord 2 and the optical fiber core wire 21 and the reinforcing material 22 are exposed.

By manufacturing the optical fiber component 1 according to the above procedure, the remaining length of the outer cover of the optical fiber cord 2,
That is, the lengths of the optical fiber cords 2 extending from the end portions of the branch fixing portions 4 can be adjusted to arbitrary or constant lengths, and of course, the optical fibers of the optical fiber cords 2 (optical components) can be previously prepared. The optical fiber component 1 can be constructed after confirming whether or not the characteristics satisfy predetermined conditions. As a result, the optical characteristics of all the optical fiber cords 2 (and the optical components) are favorably maintained under desired conditions. Further, in this case, any one of the optical fiber cords 2 (optical components attached thereto) after the components are completed.
Since the characteristic of No. 1 does not satisfy the predetermined condition, there is basically no need to remanufacture the entire optical fiber component 1, so that the yield of the optical fiber component 1 is dramatically improved.

The optical fiber component 1 according to the present invention described above.
Are used, for example, in a manner as shown in FIG. 9 to configure a predetermined optical communication network or the like. In the example shown in FIG. 9, the branch fixing portion 4 of the optical fiber component 1 is fixed to the mounting board 7 by using the screw insertion portion 5 and a fixing screw or the like. In this case, each optical connector 6 mounted on each optical fiber cord 2 extending from the branch fixing portion 4 is connected to a corresponding receptacle portion of an adapter 8 arranged above and below the mounting board 7. . Further, the end portion of the tape fiber portion 3 is connected to other optical components such as an optical connector, a semiconductor laser, a photodiode (not shown).

In the optical communication module 10 shown in FIG. 10, the tape fiber portion 3 of the optical fiber component 1 is connected to the fiber block 11, and the planar optical waveguide circuit (PLC) is further provided via the fiber block 10. It is connected to 12. Here, the fiber block 11 includes the optical fiber core wires 2 that are stripped from the tape fiber portion 3.
1 includes a substrate having V-grooves aligned. In the optical communication module 10 including the optical fiber component 1 as described above, since there is no fusion splicing of optical fiber core wires or a connecting portion of optical connectors in the module, transmission loss and reflectance in the module are reduced. It can be significantly reduced. In addition, since the optical fiber component 1 has high durability and reliability as described above, the module 10 as a whole also has high durability and reliability.

[0042]

As described above, according to the present invention, it is possible to easily improve the durability, reliability and transmission characteristics of an optical fiber component and to manufacture such an optical fiber component easily and at a high yield. It becomes possible to do.

[Brief description of drawings]

FIG. 1 is a perspective view showing an optical fiber component according to the present invention.

FIG. 2 is an enlarged partial sectional view of an essential part of the optical fiber component of FIG.

FIG. 3 is an enlarged partial sectional view of a main part of the optical fiber component of FIG.

FIG. 4 is a cross-sectional view showing the optical fiber component of FIG.

5 is a cross-sectional view showing the optical fiber component of FIG.

6 is a flow chart for explaining a method for manufacturing the optical fiber component shown in FIG.

FIG. 7 is a perspective view for explaining a procedure for manufacturing the optical fiber component of FIG.

FIG. 8 is a perspective view for explaining a procedure for manufacturing the optical fiber component of FIG.

9 is a perspective view showing one usage mode of the optical fiber component of FIG. 1. FIG.

10 is a perspective view showing another usage mode of the optical fiber component of FIG. 1. FIG.

FIG. 11 is a perspective view showing a conventional optical fiber component.

[Explanation of symbols]

1 Optical fiber parts 2 optical fiber cord 3 Tape fiber part 4 Branch fixed part 5 screw insertion part 6 Optical connector 20 Fan-out section 21 Optical fiber core 22 Reinforcement material 23 outer skin 23a end 41 casing body 41a One end 41b the other end 42 Protective cover 44 fixing member 45 Reinforcing material fixing member

   ─────────────────────────────────────────────────── ─── Continued front page    (72) Inventor Koichi Arishima             1-12-1 Dogenzaka, Shibuya-ku, Tokyo             Titi Electronics Co., Ltd. (72) Inventor Masaru Kobayashi             1-12-1 Dogenzaka, Shibuya-ku, Tokyo             Titi Electronics Co., Ltd. (72) Inventor Takashi Yoshida             1-12-1 Dogenzaka, Shibuya-ku, Tokyo             Titi Electronics Co., Ltd. F term (reference) 2H001 BB18 BB27 DD06 DD10 FF07                       HH01                 2H036 JA02 KA02 QA59 RA14 RA31

Claims (4)

[Claims] 1. An optical fiber component used for optical communication, a plurality of optical fiber cords including an optical fiber core wire, a reinforcing material, and an outer cover that covers the optical fiber core wire and the reinforcing material, and the plurality of optical fibers. A tape fiber portion in which the optical fiber cores stripped from the cord are aligned and integrated, one end portion to which the outer cover of each of the optical fiber cords is fixed, and the tape fiber portion and each of the optical fiber cords are stripped. Each optical fiber core has the other end to which the tip of the reinforcing material is fixed and is exposed from the optical fiber cord between the one end and the other end. An optical fiber component, comprising: a branch fixing portion that accommodates a wire and a reinforcing material. 2. The optical component according to claim 1, wherein an optical component is connected to at least one of the plurality of optical fiber cords and at least one of the tape fiber portions. Fiber parts. 3. A method for manufacturing an optical fiber component used for optical communication, comprising: (a) covering a predetermined length from one end side of a plurality of optical fiber cords including an optical fiber core wire, a reinforcing material, and an outer cover covering these. Removing the optical fiber core wires and the reinforcing material from the optical fiber cords by removing them; and (b) aligning and integrating the optical fiber core wires exposed from the optical fiber cords. The step of forming a tape fiber portion by (c) fixing the outer skin of each of the optical fiber cords to one end of the casing while reinforcing the tape fiber portion and the optical fiber cords. The tip of the material is fixed to the other end of the casing, and the optical fiber core wire that is exposed from each of the optical fiber cords. And a step of housing a reinforcing material between the one end and the other end of the casing. 4. The method of manufacturing an optical fiber component according to claim 3, wherein an optical component is attached to at least one of the plurality of optical fiber cords prior to the step (a).