JP2009204947A - Optical cable - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an optical cable for safely, simply and easily cutting and peeling press-winding tape without using a tool such as a cutter at a working site. <P>SOLUTION: The optical cable is formed by winding press-winding tape 15 about a plurality of optical fiber core wires 13 to cover them, and covering the outside with a sheath 16. As the press-winding tape 15, a tape substrate 15a easy-to-cut in the axial direction is used. The press-winding tape 15 may have a constitution so that a resin material welded with the sheath is applied to the surface side coming into contact with the sheath 16 and it is welded with the sheath. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to an optical cable in which a plurality of optical fiber core wires are covered with press-wound tape and the outside is covered with a sheath.

  With the recent expansion of broadband services such as video distribution, IP telephony, and data communications, the number of subscribers to home-use data communications services (FTTH: Fiber To The Home) using optical fibers is increasing. In this FTTH, a drop optical cable is used to drop from an imaginary trunk optical cable to a subscriber's house. For example, an optical fiber is pulled down to a subscriber's home, for example, a trunk optical cable laid on a utility pole in a city is branched by a connection box usually called a closure, and a drop optical cable is dropped on the branched optical fiber core. Are connected using fusion splicing or an optical connector.

  As the trunk optical cable, as shown in FIGS. 3A and 3B, for example, a spacer 2 (also called a slot rod) made of a resin rod having a plurality of grooves 4 formed in an SZ shape is used. Many optical cables are used. In this optical cable, a plurality of single-core optical fiber cores or multi-core tape core wires 3 are accommodated in the grooves 4, and a presser winding tape 5 (also referred to as an upper tape) is wound around the outer periphery of the spacer 2. The fiber core wire and the tape core wire 3 are covered. And the thing of the shape which coat | covered the outer side of the press-wound tape 5 with the sheath 6 (it is also called a jacket) formed by extrusion molding is common.

In order to draw an optical fiber from a middle portion of the trunk optical cable 1 as described above to a subscriber's house or the like, one to several optical fibers are selected from a plurality of optical fiber cores housed in the cable. A branching operation for drawing the fiber core is performed. In this branching (also referred to as intermediate branching) operation, for example, as disclosed in Patent Document 1, the sheath 6 at the branching portion of the optical cable is removed by a certain length (about 20 cm to 50 cm). In the portion where the sheath 6 is removed, the presser winding tape 5 is exposed. As shown in FIG. 3C, the presser winding tape 5 is cut by a nipper 7 or the like to form a cut. Cut from. Next, the presser winding tape 5 is unwound from the spacer and peeled off, and the optical fiber core wire inside is taken out.
JP-A-8-220393

  The presser winding tape 5 wound on the spacer 2 is such that the resin material forming the sheath 6 falls into the groove 4 of the spacer and cannot be taken out in close contact with the optical fiber core wire or the tape core wire 3. It can function as heat insulation for preventing an increase in transmission loss of the optical fiber core wire or tape core wire 3 due to heat, and further for water absorption for water stoppage in the optical cable. Further, the presser winding tape 5 prevents the optical fiber core wire or the tape core wire 3 from jumping out of the groove 4 after the optical fiber core wire or the tape core wire 3 is accommodated in the groove 4 of the spacer 2. .

  The presser winding tape 5 is usually a tape made of unemployed cloth or resin, and has a relatively high breaking tension so that it does not break with the tension when wound on the spacer 2. It may not be possible to cut. Therefore, when the intermediate branch of the optical fiber is performed, it is sometimes not easy to cut the presser winding tape 5 even if a tear cut is formed in the presser winding tape 5. In such a case, the presser tape 5 is torn with a cutter or the like. However, if the work is mistaken, the optical fiber core wire or the tape core wire 3 in the spacer 2 may be damaged. Further, the branching operation of the optical fiber core wire is often performed in a poor working environment such as on a power pole or a bucket car, and it is desired to be as simple and as short as possible.

  The present invention has been made in view of the above-described circumstances, and is an optical cable capable of safely and easily cutting and stripping a presser winding tape without using a tool such as a knife at a work site. For the purpose of provision.

  The optical cable according to the present invention is an optical cable in which a plurality of optical fiber cores are covered with a press-wound tape and covered with a sheath, and the outer surface of the optical cable is covered with a sheath. It is characterized by using. Further, the press-wound tape may be configured to be coated with a resin material that is welded to the sheath on the surface side in contact with the sheath.

  According to the present invention, the sheath of the optical cable can be removed and the exposed presser tape can be peeled off by tearing by hand in the width direction without using a special tool. As a result, the presser winding tape can be efficiently and quickly removed without damaging the optical fiber core in the cable. Alternatively, the presser tape may be removed simultaneously with the removal of the sheath by welding the sheath and the presser tape.

  Embodiments of the present invention will be described with reference to the drawings. FIG. 1 is a diagram for explaining the outline of an optical cable according to the present invention. In the figure, 11 is an optical cable, 12 is a spacer, 13 is a tape core, 14 is a groove, 15 is a press-wound tape, 15a is a tape substrate, 16 is a sheath, 17a is a warp, and 17b is a weft.

  For example, as shown in FIG. 1A, the optical cable 11 according to the present invention can be an optical cable similar to that described in FIG. 3, and has a plurality of grooves 14 formed in an SZ shape. A spacer 12 made of a resin rod is used. In the groove 14 of the spacer 12, a plurality of single-core optical fiber cores or multi-core tape core wires 13 are stored, and a presser winding tape 15 is wound around the outer periphery of the spacer 12 to store the tape core wires 13. Retained. And the outer periphery of the presser winding tape 15 is coat | covered with the sheath 16 by extrusion molding.

  In some cases, the outer periphery of the spacer 12 and the inside of the presser winding tape 15 may be subjected to rough winding such as nylon thread or plastic tape. This rough winding is performed for the purpose of preventing the optical fiber core wire or the tape core wire 13 from jumping out of the groove 14 during the manufacture, but is generally wound at intervals, and the optical fiber core wire or tape It does not protect the core 13 from the blade.

  In the present invention, the presser winding tape 15 exhibits a relatively strong breaking tension with respect to the tension applied in the longitudinal direction, but can be easily cut by a human hand in the width direction. A tape base material 15a is used. For example, it is possible to use a cloth adhesive tape base material used for packaging or the like, which is called a sfumos base material that can be easily cut by hand along the fiber direction. it can. In addition, there are also those using sufu yarn for warp and PET fiber for weft.

  FIG. 1B is a diagram illustrating an example of a tape base material simulating a sufumos base material. For example, the tape base material 15a is obtained by weaving warp yarns 17a made of reinforcing fibers intermittently in the longitudinal direction of the weft yarns 17b and integrating them into a tape shape. The tape base material 15a can have a predetermined breaking tension by uniformly applying tension to the tape width. However, since the warp 17a is intermittently inserted, it can be easily cut (manually cut) by a human hand in the width direction of the tape.

  When such a tape base material 15a is used as the press-winding tape 15 of an optical cable, for example, when the tape width of the press-winding tape 15 is 10 cm to 50 cm, the breaking tension in the longitudinal direction may be 9.8 N or more. desirable. Further, the breaking tension in the width direction of the tape is preferably 9.8 N or less so that it can be easily cut by hand. The presser winding tape 15 may be an open winding with a gap between winding turns of the tape, or may be a lap winding wound with no gap.

  The outer periphery of the presser winding tape 15 is covered with a thermoplastic resin such as polyethylene by extrusion molding to form a sheath 16. The sheath 16 is wound around a drum or the like after the presser tape 15 is wound around the outer periphery of the spacer 12, and then formed through an extruder. Following the presser tape 15, It may be formed continuously.

  As described above, when the press-wound tape 15 that can be easily cut in the tape width direction is used and the optical cable 11 whose outer periphery is coated with the sheath 16 is subjected to intermediate branching, first, as in the conventional case, first, the sheath 16 is removed in a predetermined range (for example, about 50 cm). Next, at an arbitrary position of the presser winding tape 15 exposed by the removal of the sheath 16, the side edge portion in the tape width direction is picked by hand and is cut and cut in the tape width direction. Thereafter, the optical fiber core wire or the tape core wire 13 housed in the sheath 16 is pulled out and the branching operation is performed.

  FIG. 2 is a diagram for explaining another embodiment of the present invention. The reference numerals in the figure are the same as those used in FIG. FIG. 2A is a diagram showing an outline of the optical cable, and the configuration other than the presser winding tape 15 ′ is the same as the configuration described in FIG. To do.

  In this embodiment, as shown in FIGS. 2B and 2C, a tape base material 15a ′ in which a resin material 18 is coated on one surface of the tape base material 15a of the presser winding tape 15 described in FIG. This is characterized by a presser wound tape 15 '. That is, a relatively strong breaking tension is exhibited with respect to the tension applied in the longitudinal direction, but the resin material 18 is applied to the tape base material 15a that can be easily cut by a human hand in the width direction. And a tape base material 15a ′ having a two-layer structure is used. As the tape base material 15a, a Sufmos base material can be used as in the example of FIG. 1, and the resin material 18 coated on one surface thereof is formed of a material that can be welded to the sheath 16 of the optical cable 11, and the sheath It is desirable to form with the same or the same kind of resin material as 16.

  As in the example of FIG. 1, after a plurality of single-core optical fiber cores or multi-core tape core wires 13 are accommodated in the groove 14 of the spacer 12, the resin material coated with the tape base material 15a ′ is coated. The presser winding tape 15 'is wound around the outer periphery of the spacer 12 so that 18 is an outer surface, and the tape core wire 13 is stored and held. Then, the outer periphery of the presser winding tape 15 ′ is coated with a thermoplastic resin such as polyethylene by extrusion molding to form a sheath 16. At this time, the inner surface of the sheath 16 is welded and integrated with the resin material 18 coated with the presser winding tape 15 ′ by heat during molding.

  When the intermediate branching of the optical cable 11 configured as described above is performed, the sheath 16 is removed within a predetermined range (for example, about 50 cm) as in the example of FIG. At this time, the presser winding tape 15 ′ is welded to and integrated with the inner surface of the sheath 16, so that the presser winding tape 15 ′ is simultaneously subjected to breaking tension as the sheath 16 is removed. As described above, the presser winding tape 15 ′ is formed of a tape base material that can be easily cut in the tape width direction, and can be easily broken and peeled off by removing the sheath 16. Therefore, the presser winding tape 15 ′ is integrated with the removal of the sheath 16, and the workability of the intermediate branch can be further improved.

It is a figure explaining an example of an embodiment of an optical cable by the present invention. It is a figure explaining the example of other embodiment of the optical cable by this invention. It is a figure explaining the prior art.

Explanation of symbols

DESCRIPTION OF SYMBOLS 11 ... Optical cable, 12 ... Spacer, 13 ... Tape core wire, 14 ... Groove, 15, 15 '... Press-wound tape, 15a, 15a' ... Tape base material, 16 ... Sheath, 17a ... Warp, 17b ... Weft, 18 ... Resin material.

Claims (2)

  An optical cable in which a plurality of optical fiber cores are covered with a press-wound tape and covered with a sheath, and a tape base material that is easy to cut in the width direction is used for the press-wound tape. An optical cable characterized by that.   The optical cable according to claim 1, wherein a resin material that can be welded to the sheath is coated on a surface side of the presser tape that contacts the sheath and is welded to the sheath.

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