JP2830143B2 - Optical cable - Google Patents

Description

Description: TECHNICAL FIELD The present invention relates to an optical cable having an optical unit such as an optical fiber housed in an outer sheath such as a metal pipe.

<Prior Art> Conventionally, an optical cable in which an optical unit in which a plurality of optical fiber strands are twisted underneath is housed in a protective member such as a metal pipe is known. When laying the optical cable, a so-called strength member having a high tensile modulus is provided along the axial direction in the outer sheath so as not to apply an excessive tension to the optical fiber.

A typical example of this conventional optical cable is shown in FIGS.
Shown in the figure.

First, in the optical cable 100 shown in FIG. 4, a strength member 101 made of a steel wire or an FRP rod is disposed at the center of the optical cable 100, and an optical fiber 102, a cushion layer 103, and an inner sheath 104 are provided on the outer periphery thereof. The tape is wound vertically with a tape 105, and the integrated body is covered with an outer sheath 106.

On the other hand, in the optical cable 110 for a loose tube type optical fiber shown in FIG. 5, the strength member 111 is arranged at the center of the optical cable 110 and the optical fiber 112
A fibrous strength member 113 such as Kevlar or yarn is also provided on the outer periphery where the optical fiber 112 is disposed to protect the optical fiber 112 from applying excessive tension.

Further, in the optical cable 120 shown in FIG. 6, since the optical fiber 121 is arranged at the center, two strength members 122 having a high tensile modulus are vertically attached in the same direction as the axial direction. Is protected.

The steel tape used in the optical cables 100, 110, and 120, which is wrapped vertically for bundling the optical fibers and the like, always has wrinkles and does not serve as a strength member.

<Problems to be solved by the invention> However, the conventional optical cable has the following problems.

In the case where the strength member is provided at the center of the optical cable 100 shown in FIG. 4, the strength member is made thicker to increase the strength, so that there are problems such as an increase in the cable outer diameter and rigidity, which makes it difficult to bend.

Also in the optical cables 110 and 120 shown in FIGS. 5 and 6, the outer diameter of the strength member or the outer diameter of the cable is increased due to the thickness of the fiber layer, and a plurality of expensive supply devices are required for the strength member. There is a problem that there is.

Further, since the diameter of the optical cable is large, there is a drawback that handling is difficult.

In view of the circumstances described above, the present invention is thin and easy to bend,
An object of the present invention is to provide an economical optical cable suitable for direct burying.

<Means for Solving the Problems> A first optical cable of the present invention for achieving the above object is an optical cable in which an optical fiber and a strength member are arranged inside an outer sheath, and at least one of the strength members is provided. The tape-shaped material is provided with an adhesive layer provided on at least one surface of the tape-shaped material without corrugations.

The second optical cable is an optical cable in which an optical fiber and a strength member are arranged inside an outer sheath, and at least a part of the strength member is a vertically attached tape-like material that is not corrugated. Wherein the tape-shaped material is disposed between a plastic pipe and the outer sheath via an adhesive layer.

The third optical cable is an optical cable in which an optical fiber and a strength member are disposed inside an outer sheath, and at least a part of the strength member is a vertically attached tape-like material that is not corrugated. Wherein the tape-shaped material is made of a super-stretched synthetic resin.

A fourth optical cable is characterized in that in the third optical cable, the super-stretched synthetic resin is polyethylene, polyacetal, or polyester.

The fifth optical cable is an optical cable in which an optical fiber and a strength member are arranged inside an outer sheath, and at least a part of the strength member is a vertically attached tape-like material that is not corrugated. In the above, the tape-shaped material is a steel tape.

The sixth optical cable is an optical cable in which an optical fiber and a strength member are disposed inside an outer sheath, and at least a part of the strength member is a vertically attached tape-like material that is not corrugated. , The tape-shaped object is characterized by comprising a steel tape coated on both sides with a polymer and a tape made of a super-stretched synthetic resin.

The seventh optical cable is an optical cable in which an optical fiber and a strength member are arranged inside an outer sheath, and at least a part of the strength member is a vertically attached tape-like material that is not corrugated. Wherein the tape-shaped material is polymer-coated on both sides.

<Operation> In the optical cable having the above configuration, since the optical fiber is vertically attached by a tape-like material, when the cable is pulled, the tape-like material acts as a strength member,
Protect optical fiber.

<Embodiment> Hereinafter, a preferred embodiment of the present invention will be described in detail.

FIG. 1 is a configuration diagram of an optical cable according to the present embodiment. As shown in the figure, a tape-like material having a high elastic modulus is provided vertically on the outer periphery of a plastic pipe 12 having a moisture-proof mixture 10 and an optical fiber 11 via an adhesive resin layer 14, and a tape layer 13 is provided. A steel tape 15 having a polymer coating on both sides on the outer periphery of the tape layer 13 is provided via an adhesive resin layer 14, and the outer periphery of the steel tape 15 is covered with an outer sheath 16 as a protective member. To give an optical cable.

The optical fiber placed at the center is plastic pipe 12
It does not need to be disposed inside, and any device may be used as long as it holds an optical fiber of another configuration.

In addition, the laminating order of the tape layer 13 made of the tape-like material and the steel tape 15 is reversed, and the steel tape 15 is vertically attached to the outer periphery of the plastic pipe 12, and thereafter the tape-like material is vertically attached to the outer periphery of the steel tape 15. Alternatively, the tape layer 13 may be formed.

In the present embodiment, the tape-like material is a super-stretched addition-polymerized plastic such as polyethylene (PE), a ring-opening polymer-based plastic such as polyacetal, a polycondensation-based plastic such as polyethylene terephthalate (PET), etc. And its tensile modulus is preferably 1 to 30 × 10 ³ kg / mm ² .

The tape-shaped material may be used together with a conventional small-diameter strength member.

In addition, the steel tape which is longitudinally added together with the tape-shaped material is provided with a polymer coating such as a synthetic resin on both surfaces thereof and is not corrugated, so that when the optical cable is pulled, the steel tape has It shows elongation according to the tensile modulus and plays a role of a strength member for protecting the optical fiber. Needless to say, only the steel tape may be used as the strength member instead of the tape-like material.

Since the strength of the super-stretched tape is limited, a desired strength can be obtained by vertically wrapping a plurality of tapes if necessary.

<Test Example> Using the optical cable 20 having the configuration shown in FIG. 2, a test was performed on the relationship between the elongation of the optical cable and the tensile strength.

The method of forming the optical cable 20 is as follows. A plastic pipe (outer diameter of about 4 mm) 12 having a six-core optical fiber 11 held through an elastic body 10 A tape-like material (0.1 mm thick x 18 mm wide) is longitudinally applied to form a tape layer 13, and a wrinkle-free steel tape (thickness: 0.1 mm) coated with a polymer on both sides via an adhesive 14.
15 mm x 28 mm width) 15 are applied vertically, and then an outer sheath 16 made of polyethylene is applied as a protective member. The width of the obtained optical cable was 9.0 mm.

The tape-shaped material used had a tensile modulus of 10 × 10 ³ kgf / mm ² .

Using the obtained optical cable, the relation between the elongation of the cable and the tensile strength was examined. FIG. 3 shows the results. As shown in the figure, a proportional relationship was obtained between the elongation and the tensile load of the cable, which were almost equal to the calculated values.

<Effect of the Invention> As described above, the optical cable according to the present invention
Since at least a part of the strength member is a vertically attached tape-like material, it is possible to greatly reduce the diameter of the optical cable while maintaining the same strength as before, and it is economical,
Since the diameter is small, it is easy to handle.

[Brief description of the drawings]

FIG. 1 is a configuration diagram of an optical cable showing an embodiment of the present invention, FIG. 2 is a configuration diagram of an optical cable according to a test example, FIG. 3 is a graph showing a relationship between elongation of the cable and tensile load, FIGS. FIG. 6 is a configuration diagram of an optical cable according to a conventional example. In the drawing, 10 is a moisture-proof compound, 11 is an optical fiber, 12 is a plastic pipe, 13 is a tape layer formed by vertically attaching a tape, 14 is an adhesive resin layer, 15 is a steel tape, and 16 is an outer sheath. is there.

──────────────────────────────────────────────────続 き Continued on the front page (58) Field surveyed (Int.Cl. ⁶ , DB name) G02B 6/44 366

Claims (7)

(57) [Claims] 1. An optical cable having an optical fiber and a strength member disposed inside an outer sheath, wherein at least a part of the strength member is a non-corrugated longitudinally attached tape-like material, An optical cable, wherein an adhesive layer is provided on at least one surface of a tape-shaped object. 2. An optical cable in which an optical fiber and a strength member are disposed inside an outer sheath, wherein at least a part of the strength member is an uncorrugated longitudinally attached tape-like material. An optical cable, wherein the tape-shaped material is disposed between a plastic pipe and the outer sheath via an adhesive layer. 3. An optical cable in which an optical fiber and a strength member are disposed inside an outer sheath, wherein at least a part of the strength member is an uncorrugated longitudinally attached tape-like material. An optical cable, wherein the tape-like material is made of a super-stretched synthetic resin. 4. The optical cable according to claim 3, wherein the super-stretched synthetic resin is polyethylene, polyacetal, or polyester. 5. An optical cable in which an optical fiber and a strength member are arranged inside an outer sheath, wherein at least a part of the strength member is an uncorrugated longitudinally attached tape-like material. The optical cable, wherein the tape-shaped object is a steel tape. 6. An optical cable in which an optical fiber and a strength member are disposed inside an outer sheath, wherein at least a part of the strength member is an uncorrugated longitudinally attached tape-like material. An optical cable, wherein the tape-shaped object comprises a steel tape coated on both sides with a polymer and a tape made of a super-stretched synthetic resin. 7. An optical cable in which an optical fiber and a strength member are arranged inside an outer sheath, wherein at least a part of the strength member is an uncorrugated longitudinally attached tape-like material. An optical cable, wherein the tape-shaped object is polymer-coated on both sides.