JP2006313212A - Components and structure for optical branching wiring - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an optical branching wiring component that can be installed by lessening an optical branching component and a wiring space of a coated optical fiber, and to provide an optical branching wiring structure. <P>SOLUTION: The two parallel optical branching wiring component leads in an optical fiber care wire from the input and leads out a tape core wire comprising a plurality of single wires. The wiring component comprises a tape core wine double layer arrangement (A) for juxtaposing two coated optical fibers comprising a plurality of single optical fibers extended from respective output ends of the optical branching component by juxtaposing the two optical branching component, a coated optical fiber recombination (B) for separating the two coated optical fiber tape into the single optical fibers and converting arrangement of the single optical fibers, a coated optical fiber rearrangement (C) for covering the arrangement converted coated optical fiber by a coated material, and a coated optical fiber arrangement branching (D) branched from the coated optical fiber arrangement by making the single optical fiber extended from one optical branching component and the single optical fiber extended from the other branching component a pair. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  In an optical communication, the present invention relates to an optical branch comprising an optical fiber for transmitting video information, an optical fiber for transmitting data information, and an optical branching component for branching and rearranging the video information part and the data information part. The present invention relates to a wiring component and an optical branch wiring structure.

  The feature of optical fiber communication is that it can transmit a large amount of information at high speed, and the ultimate purpose is to transmit a large amount of information with a single optical fiber. , One piece of information is distributed and distributed to many subscribers. In that case, there are (1) a case where video information and data information are transmitted by a single optical fiber, and (2) a case where video information and data information are transmitted by different optical fibers. It is predicted that it will become dominant in the future market. Video information and data information are generally transmitted at high power to an overhead wire closure, branched inside the closure, and an optical fiber called a drop cable comprising video information and data information made up of two tape cores. It is transmitted to the subscriber by cable. Video information and data information are branched from 4 to 32 inside the closure, and the video information and data information are selected one by one, and the two tape cores of the drop cable are separated for each single core. Is fused.

  However, the problems with the above method are that the optical fiber is separated and wired and connected separately, so that the number of protective sleeves for fusion splicing increases, and the optical fiber becomes congested and bulky. As a result, not only is the installation space for the optical fiber and optical components in the closure compressed, but there is a high risk of the optical fiber being hooked and broken.

As a method for facilitating batch fusion of the optical fiber core branched from the branching portion and the two-core tape core of the drop cable, another two-core ribbon is prepared in advance, There is a method of fusing the optical fiber at the output end of the branch part one by one, but if you spend a huge amount of time in advance work and the fusion splicing fails, the optical fiber length will be uneven, There are also problems such as complicated wiring, an increase in the number of reinforcing sleeves, an increase in overall size, and inability to install in a closure using a thin tray in order to increase the wiring density. Patent Document 1 discloses a branch connection structure in a closure that saves wiring and connection and simplifies the addition of a drop cable for branching and connecting to a subscriber line in the closure. Yes.
JP 2003-177254 A

  As described above, the branching part that branches the video information and data information transmitted through the optical fiber and distributes it to each subscriber, that is, the problem of the branching module and the optical fiber wiring is the branching module and the optical fiber wiring. In addition, the space required for connection increases, and time and labor are required for connection work. The present invention is intended to solve these problems, to provide an optical branch wiring component and an optical branch wiring structure that can be installed in various closures by reducing the wiring space of the optical branching component and the optical fiber core wire extending therefrom. To do. Also, if necessary, it is easy to take a structure that branches the required optical fiber at the required number and position, and the optical branch wiring parts and the optical branch wiring that can be easily connected to a two-core tape core wire such as a drop cable. It is intended to provide a structure.

  The optical branch wiring component of the present invention is an optical fiber core wire extending from the input end, and two optical branching components extending in parallel from the output end of the tape core wire composed of a plurality of single core wires. The optical fiber multi-layer arrangement part (A) in which two tape cores composed of a plurality of single cores extending from the respective output ends of the optical branching parts are arranged in parallel, and the two tape cores are An optical fiber core wire recombination section (B) that is separated into single core wires and the arrangement of single core wires is converted, and an optical fiber core wire rearrangement section in which the arrayed optical fiber core wires are covered with a coating material (C) and a single optical fiber extending from one optical branching part and a single optical fiber extending from the other branching part are paired, and an optical fiber core branched from the optical fiber core rearrangement unit. It has an arrangement | sequence branch part (D).

  In the optical fiber core wire recombination part (B) of the optical branch wiring component of the present invention, each single core wire in the two tape core wires may be alternately arranged and converted into a single layer. Moreover, it may be converted so that at least a part of each single-core wire is interchanged, and may be arranged in multiple layers.

  Further, in the optical fiber core rearrangement portion (C) of the optical branching wiring component of the present invention, at least one side of the rearranged optical fiber core wires is covered with a coating material. Further, at least one side of the branched two-core tape core wire in the optical fiber core wire array branch part (D) is covered with a coating material. The covering material is preferably made of silicone rubber.

  Moreover, in the optical fiber core wire arrangement branch part (D), it is preferable that a pair of branched single core wires is covered with a protective tube for each pair.

  The optical branch wiring structure of the present invention is for an optical communication system in which a video signal and a data signal are paired and transmitted by separate optical fibers, and one of the above optical branch wiring components The optical fiber core wire extending from the input end of the optical fiber is connected to the optical fiber core wire transmitting the video signal, and the optical fiber core wire extending from the input end of the other optical branching component transmits the data signal. A single core wire for transmitting a video signal and a single core wire for transmitting a data signal, which are connected to a wire and transmit a video signal branched in pairs in the optical fiber core wire array branch part (D) of the optical branch wiring component, It is characterized by being connected to a two-core tape core.

  In the present invention, the optical branch wiring component may be provided on a tray, and the optical branch wiring structure may be a storage structure. A plurality of optical branch wiring components provided on the tray may be stacked to form a storage structure that is stored in the optical closure.

  Since the optical branch wiring structure using the optical branch wiring component of the present invention has the above structure, the mounting space is narrow and the wiring density of the optical fiber can be increased. The optical branch wiring component of the present invention has an optical fiber core wire recombination section, and can change the arrangement order of the optical fibers. Therefore, it is possible to easily produce an optical fiber core branching structure (optical fiber core array branching portion) required for connecting an optical branch wiring component and other optical components, and image information and data. There is also an advantage that connection work with a two-core tape core such as a drop cable for transmitting information becomes simple. Furthermore, the arrayed optical fiber core wire has a structure coated with a coating material, particularly silicone rubber, which can improve the flexibility of the optical fiber core array branching section, and can be connected in the field. Excellent workability during work.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. FIG. 1 is a schematic perspective view showing an example of the optical branch wiring component of the present invention. In the optical branch wiring component of the present invention shown in FIG. 1, optical fiber core wires 7a and 7b extend from the input end, and optical fiber core wires (5a to 5d and 6a to 6d) are arranged at the output end. Two optical branching parts 1a and 1b having 2b are arranged in parallel. Then, the optical fiber cores are separated into a plurality of tape cores in the state of the tape cores, and the optical fibers in the tape cores are separated into single cores. An optical fiber core rearrangement part (B) in which the arrangement of the optical fiber cores is converted, an optical fiber core rearrangement part (C) in which the recombined optical fiber core wire is coated with the coating agent 3 and rearranged, A single-core wire extending from the optical branch component and an optical fiber core-array branching portion (D) branched from a pair of single-core wires extending from the other branch component. 2A is a cross-sectional view of the tape core multilayer arrangement portion (A), and FIG. 2B is a cross-sectional view of the optical fiber core rearrangement portion (C).

  The number of optical fiber cores in the tape core in the above-described tape core multilayer array portion (A) is not particularly limited as long as it is plural. Moreover, what is necessary is just to determine suitably the tape core wire length of a tape core wire multilayer arrangement | sequence part (A) on design.

  In the optical fiber core recombination section (B), the upper optical fiber cores 5a to 5d (arrangement order is 5a, 5b, 5c, 5d) and the lower optical fiber core cables 6a to 6d (arrangement order is , 6a, 6b, 6c, 6d) are rearranged into the arrangement layer of the single-layer optical fiber. In the case shown in FIG. 1, the arrangement order of the optical fiber cores in the array layer in which the optical fiber cores are arranged in a single layer is the order of 5a, 6a, 5b, 6b, 5c, 6c,. The lower optical fiber cores are alternately arranged. The length in the direction of the optical fiber core wire of the optical fiber core recombination part may be determined as appropriate.

  The optical fiber cores in the optical fiber core rearrangement section (C) are rearranged in a single layer structure and covered with the coating material 3. The covering material covering the optical fiber core rearrangement part (C) is preferably silicone rubber. Silicone rubber has excellent elasticity due to rubber elasticity, and also has excellent elongation and tensile strength. Therefore, it has high flexibility with respect to the movement of the coated optical fiber. Strong against tearing. In addition, since the siloxane bond of silicone rubber is excellent in heat resistance, it has excellent heat resistance retention and excellent adhesive strength even in high temperature and low temperature environments. Furthermore, silicone rubber is excellent in electrical insulation, chemical resistance, weather resistance, and water resistance.

  Moreover, as shown in FIG.2 (b), only one side of the optical fiber core wire of the optical fiber core wire rearrangement section (C) may be covered with a coating material. In the case of silicone rubber, the thickness of the coating material is preferably 50 μm or more and 500 μm or less. This is because the optical fiber core wire needs to be strong enough to maintain flexibility and prevent breakage due to bending.

  In the case shown in FIG. 1, in the optical fiber core arrangement / branch part (D), the eight optical fiber cores integrated in the optical fiber core rearrangement part (C) are connected to the tip side (that is, the optical branch part). 2a and 6b, a pair of optical fibers belonging to the respective optical branching parts, and a pair of two-core tapes 8a to 8d. Branching into 4 groups.

  The number of sets of optical fiber single cores in the optical fiber core array branch part (D) depends on the number of optical fiber cores wired from the optical branching component. Such a branched structure is convenient when the optical fiber is connected to another optical fiber at the tip. It should be noted that only a set that needs to be connected to another optical wiring member may be branched, and the other set may be kept together without being branched. The length of the optical fiber core array branch part (D) in the optical fiber core direction may be determined as appropriate after design.

  FIG. 3 is a schematic perspective view showing another example of the optical branch wiring component of the present invention. In the case of this figure, in the optical fiber core rearrangement section (C), the optical fiber core wires are rearranged in multiple layers. Fig.4 (a) is sectional drawing of a tape core wire multilayered arrangement part. FIG. 4B is a cross-sectional view of the optical fiber core rearrangement section (C), where the single cores are in the order of 5b, 6b, 5d, 6d, and 5a, 6a, 5c, 6c. It has a multilayer structure with the lower layer in the order of, and one side is covered with the covering materials 3a and 3b. In addition, the other code | symbol means the same thing as the case of FIG.

  The optical branch wiring component of the present invention is used in optical communication in which a video signal and a data signal are transmitted through different optical fibers, and the wiring structure is not particularly limited, but the optical fiber wired from the optical cable is not limited thereto. The optical fiber core wire at the input end of the optical branching component is connected, and the optical fiber of the optical fiber core array branching portion (D) at the output end is suitably used for a wiring structure for connecting to the two-core tape core wire at the delivery destination. Can do. For example, as an optical branch wiring structure for an optical communication system in which a video signal and a data signal are paired and transmitted through separate optical fibers, one optical branching component 1a of the optical branching wiring component shown in FIG. 1 or FIG. The optical fiber 7a extending from the input end of the optical fiber 7a is connected to the optical fiber for transmitting the video signal, and the optical fiber 7b extending from the input end of the other optical branching component 1b is connected to the optical fiber for transmitting the data signal. In addition, an optical branch wiring structure in which the two-core tape cores 8a to 8d branched in pairs in the optical fiber core array branch part (D) of the optical branch wiring component are connected to the two-core tape cores, respectively. Can be given.

  In that case, it is preferable to cover the optical fiber core wire array branch (D) with a protective tube. As a result, even when the optical fiber is hooked on a peripheral device during wiring work, extreme bending is unlikely to occur, and the risk of disconnection due to damage to the optical fiber coating material due to friction is reduced.

  In order to configure the wiring structure of the present invention as described above, it is necessary to connect the optical fiber core wire extended from the optical branch wiring component and another optical fiber core wire, but there is a limitation particularly on the connection method. Alternatively, it may be fusion-bonded and the fusion-bonded portion may be reinforced with a protective sleeve, or may be attached to and detached from the optical fiber core wire to be connected. In this case, the optical connector to be used is not particularly limited, but a single-core or multi-core small optical connector is preferably selected. Examples include FC optical connectors, SC optical connectors, MU optical connectors, MPO optical connectors, MT optical connectors, mini-MT optical connectors, and the like.

  The wiring structure of the above-described optical branch wiring component of the present invention is not particularly limited as long as the wiring structure can be stably held. However, in order to store compactly and maintain a stable wiring structure In addition, as shown in FIG. 5, a storage structure in which the above-described optical branch wiring component is provided on the tray 20 is preferable. By storing the optical branch wiring component in the tray 20, when handling the optical branch wiring component, the optical fiber and the optical branching component are not directly gripped or fixed, and the optical branch wiring component is contaminated. There is no risk of damage. In FIG. 5, a protective tube 9 is placed on the optical fiber core wire array branch (D). Further, as shown in FIG. 6, by stacking the trays 20 storing the optical branch wiring parts, a plurality of optical branch wiring parts can be stored in an organized manner, and the assembly workability and maintenance inspection workability of the storage structure can be achieved. Will improve. In addition, 21 is a surplus length storage part for winding and storing the surplus length of the optical fiber cores 7a and 7b, and 22 is a surplus length storage part for winding and storing the surplus length of the 2-core tape core wire.

  In addition, the optical branch wiring components can be installed regardless of indoor or outdoor by storing the tray containing the optical branch wiring components inside an optical fiber storage device such as an optical closure or an optical cabinet. Thus, an optical branch wiring structure can be formed, and video signals and data signals can be easily distributed from a trunk optical cable to a drop cable composed of a two-core tape core.

  EXAMPLES Hereinafter, although an Example demonstrates this invention, this invention is not limited to this.

  The optical fiber cores 5a to 5d and 6a to 6d constituting the 4-core tape cores having a length of 1000 mm provided in the two 1 × 4 port optical branching parts 1a and 1b as shown in FIG. 1 are made of silicone rubber. About an example of manufacturing an optical branch wiring component that is coated and reconfigured into an optical fiber core rearrangement portion (C) of 8 cores, and the tip of the optical fiber core wire splitting portion (D) is branched every two cores. State.

  First, the coating apparatus used for manufacture will be described. A schematic diagram of the coating apparatus is shown in FIG. This coating apparatus is composed of a uniaxial control robot 10 and a material supply apparatus 18, and the uniaxial control robot has a flat substrate 11 on which an optical fiber core wire is placed, and extends along the longitudinal direction. A ball screw shaft 12 is arranged, a drive motor 13 is provided at the end, and the other end is supported by a bearing 14. A movable unit 15 is screwed into the ball screw, and the movable unit is for supplying material. The forming jig 16 is installed perpendicular to the stage surface. The forming jig is connected to the material supply device by a flexible rubber tube 17. The movable unit 15 can move left and right and up and down. The movement up and down adjusts the thickness of the silicone rubber to be applied. Further, the silicone rubber is applied to a desired range by moving the movable unit to the right while supplying the silicone rubber.

  Two 1 × 4 port optical branching parts equipped with a four-core optical fiber ribbon having a length of 1000 mm were prepared. The covering material of the 4-core tape core wire provided in the light branching parts 1a and 1b was left by 40 mm from the end part of the light branching part, and then the tip part was completely removed. The portions of the optical fiber cores 5a to 5d and 6a to 6d where the covering material was removed were in the state of a single optical fiber. Next, the two optical branching parts 1a and 1b were arranged in parallel and arranged so that two four-core ribbons were stacked (tape ribbon multi-layer arrangement portion). Thereafter, the optical fiber cores provided in each of the optical branching parts 1a and 1b are in a two-layer state of four optical fiber cores 5a to 5d and 6a to 6d on the flat substrate 11 of the coating apparatus shown in FIG. To 5a, 6a, 5b, 6b, 5c, 6c, and so on so that there is no gap between the parallel layers, and the position at which coating is started is fastened with a temporary fixing tape 19 and fixed. It was set as the optical fiber core wire recombination part (B). Although the optical branching parts 1a and 1b are not shown in FIG. 7, they are placed in parallel with the left side of the tape core wire A in FIG.

  Next, after moving the movable unit 15 of the coating device to the temporary fixing tape 19, the bottom surface of the forming jig 16 is adjusted to be arranged at a height of 0.35 mm from the surface of the optical fiber core wire, Application was performed from the position of the temporary fixing tape 19 to the surface of the optical fiber core wire. The moving speed of the movable unit 15 at the time of application was set to 50 mm / sec, and room temperature curable silicone rubber (SE9186L made by Toray Dow Corning Silicone) was applied to a range of 300 mm on the surface of the optical fiber core wire. The applied silicone rubber was semi-cured for 30 minutes at room temperature. The optical branch wiring component was peeled off from the flat substrate 11, and the silicone rubber was completely cured under conditions of room temperature for 1 hour. Thereafter, the coated optical fiber core rearrangement part is divided into two cores in pairs, leaving 5 mm on the optical fiber core rearrangement part side (optical fiber core rearrangement part (C)), An optical fiber core array branch (D) was formed. Through the above steps, an optical branch wiring component having the function of a 2 × 8 optical branching component was obtained. The thickness of the silicone rubber was 0.35 mm and had a uniform thickness over a range of 300 mm.

  An optical branch wiring component having the structure shown in FIG. 3 was produced by the same process as in Example 1. In this case, the difference from Example 1 was that the optical fiber core wire rearrangement part (C) had a two-layer structure. That is, as shown in FIG. 4B, the upper layer of the optical fiber core rearrangement portion (C) is arranged in the order of the optical fiber core wires 5b, 6b, 5d, 6d, and the lower layer is 5a, 6a, They were arranged in the order of 5c and 6c. The lower layer optical fiber core rearrangement portion (C) is provided with a silicone rubber coating, and then the upper optical fiber core wire rearrangement portion (C) is provided with a silicone rubber coating, in the same manner as in Example 1. An optical fiber core array branch (D) was formed, and an optical branch wiring component was obtained. In the obtained optical branch wiring component, the optical fiber core rearrangement part (C) has a two-layer structure, so that the optical fiber wiring space can be made more compact and high density can be achieved even for thin closures. It became possible to implement.

  A tray 20 (width 310 mm × depth 100 mm × depth 8 mm) as shown in FIG. 5 was made of ABS resin, and the optical branch wiring component shown in FIG. The optical fiber cores 7a and 7b extending from the input side of the optical branching part are wound around the extra length storage portion 21 of the tray 20 by two turns, and are respectively spliced to the single optical fiber cores outside the tray. And wired. Each of the two-core tape cores of the optical fiber core array branch part (D) is wound around the extra length storage part 22 by one turn, and then a silicone rubber protective tube 9 (inner diameter 1 mmφ, outer diameter 1.5 mmφ). ) And fusion spliced to the two-core tape core outside the tray to form an optical branch wiring storage structure. The optical branch wiring storage structure thus formed is easy to connect to the external two-core tape core because the optical fiber is branched at every two cores at the optical fiber core array branching section (D). Improved. In addition, by covering the optical fiber core array branch with the protective tube, the optical fiber core wire is not damaged by contacting the end of the tray, so that the work yield can be improved and the work can be done safely. I can do it now. Also, by storing in the tray, the wiring structure is stable, and when handling optical branch wiring parts, optical fibers and optical branch parts are not directly gripped or fixed, and the optical branch wiring parts are contaminated. The risk of damage or damage has been eliminated. In addition, the optical fiber wiring was neat and compact, and after installing the optical branch wiring parts on the tray, the maintenance and inspection workability improved.

  Further, as shown in FIG. 6, four trays 20a to 20d storing the optical branch wiring components were stacked to form an optical branch wiring storage structure. In that case, even if the trays are stacked, the optical branch wiring components housed in other trays do not come into contact with the tray, and a large number of optical branch wiring components can be safely housed.

It is a schematic perspective view which shows an example of the optical branch wiring component of this invention. It is sectional drawing which shows the arrangement | sequence and covering state of the tape core multilayer multilayer part (A) and optical fiber core rearrangement part (C) of the optical branch wiring component of FIG. It is a schematic perspective view which shows another example of the optical branch wiring component of this invention. It is sectional drawing which shows the arrangement | sequence and covering state of the tape core wire multilayer arrangement | sequence part (A) and optical fiber core wire rearrangement part (C) of the optical branch wiring component of FIG. It is a top view which shows the storage structure of the optical branch wiring components of this invention. It is a top view which shows the storage structure of the lamination | stacking state of the optical branch wiring component of this invention. It is a perspective view of the coating device used for manufacture of the optical branch wiring component of this invention.

Explanation of symbols

A: Tape fiber multilayer arrangement part B: Optical fiber core wire rearrangement part C: Optical fiber core wire rearrangement part D: Optical fiber core wire arrangement branch part 1a, 1b: Optical branch part 2a, 2b: Tape core wire 3, 3a, 3b: coating materials 5a-5d: optical fiber cores 6a-6d: optical fiber core wires 7a, 7b: optical fiber core wires 8a-8d: two-core tape core wires 9: protective tube 10: uniaxial control robot 11: plane substrate 12: ball screw shaft 13: drive motor 14: bearing 15: movable unit 16: molding jig 17: rubber tube 18: material supply device 19: temporary fixing tapes 20, 20a to 20d: trays 21, 22: Extra length storage

Claims (10)

  In an optical branch wiring component in which two optical branch components in which an optical fiber core wire extends from an input end and a tape core wire composed of a plurality of single core wires extends from an output end are arranged in parallel. A tape core multilayer array (A) in which two tape cores composed of a plurality of single cores extending from the output end are arranged in parallel, and the two tape cores are separated into single cores. An optical fiber core recombination part (B) in which the arrangement of the cores is converted, an optical fiber core rearrangement part (C) in which the arrayed optical fiber cores are covered with a coating material, and one light A single-core wire extended from the branch component and a single-core wire extended from the other branch component have a pair of optical fiber core-wire arrangement branch portions (D) branched from the optical fiber core-wire rearrangement portion An optical branch wiring component characterized by that.   The optical fiber core wire recombination section (B), wherein each single core wire in the two tape core wires is alternately arranged and rearranged into a single layer. Optical branch wiring parts.   The optical fiber core wire recombination section (B) is converted so that at least a part of each single core wire in the two tape core wires is interchanged, and is arranged in multiple layers. The optical branch wiring component according to 1.   4. The optical branch wiring component according to claim 1, wherein one side of the optical fiber core wire of the optical fiber core rearrangement section (C) is covered with a coating material. 5.   5. The optical branch wiring component according to claim 1, wherein one side of the optical fiber core wire of the optical fiber core wire array branch part (D) is covered with a coating material.   The optical branch wiring component according to any one of claims 1 to 5, wherein the covering material is made of silicone rubber.   The optical fiber core line array branching section (D) is characterized in that a pair of branched single core wires is covered with a protective tube for each pair. Optical branch wiring parts.   2. An optical branch wiring structure for an optical communication system in which a video signal and a data signal are paired and transmitted through separate optical fibers, respectively, extending from an input end of one of the optical branch wiring parts according to claim 1. The outgoing optical fiber core wire is connected to the optical fiber core wire transmitting the video signal, and the optical fiber core wire extending from the input end of the other optical branching component is connected to the optical fiber core wire transmitting the data signal, In addition, in the optical fiber core wire array branch part (D) of the optical branch wiring component, a single core wire that transmits a pair of branched video signals and a single core wire that transmits a data signal are two-core tape core wires. Optical branch wiring structure characterized by being connected to.   9. The optical branch wiring structure according to claim 8, wherein the optical branch wiring component according to claim 1 is provided on a tray to form a storage structure. 9. The optical branch wiring structure according to claim 8, wherein a plurality of optical branch wiring components according to claim 1 provided on a tray are stacked to form a storage structure.

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