JP7068131B2 - Fiber optic cable - Google Patents

Description

The present invention relates to an optical fiber cable.

Conventionally, an optical fiber cable in which inclusions are arranged around the optical fiber unit has been used.
For example, in the optical fiber cable of Patent Document 1, a plurality of tape core wires are laminated and a unit coating layer is provided around the tape core wires to form an optical fiber unit. By providing inclusions around the optical fiber unit, it is easy to make the shape of the optical fiber cable circular.
Further, in the optical fiber cable of Patent Document 2, by arranging inclusions so as to be sandwiched between the optical fiber units, the movement of the optical fiber unit in the optical fiber cable is suppressed.

Japanese Unexamined Patent Publication No. 2001-51169 Japanese Patent No. 6255120

In this type of optical fiber cable, the optical fiber unit may be twisted in an SZ shape. Here, when the optical fiber units are twisted in an SZ shape, "untwisting" occurs in which the optical fiber unit moves in the direction in which the twist is canceled. In the conventional optical fiber cable, the suppression of untwisting may be insufficient.

The present invention has been made in consideration of such circumstances, and an object of the present invention is to provide an optical fiber cable in which untwisting is suppressed.

In order to solve the above problems, the optical fiber cable according to the first aspect of the present invention includes a plurality of optical fiber units each having a plurality of optical fibers, a presser winding for wrapping the plurality of optical fiber units, and the presser. A plurality of outer units located in the outermost layer of the plurality of optical fiber units comprising at least one inclusions arranged inside the winding and a sheath covering the presser winding are centered on the cable center axis. The inclusions are sandwiched between the outer unit and the presser winding in a cross-sectional view.

Further, the optical fiber cable according to the second aspect of the present invention is arranged inside the plurality of optical fiber units having each of the plurality of optical fibers, the presser winding for wrapping the plurality of optical fiber units, and the presser winding. A plurality of outer units located in the outermost layer of the plurality of optical fiber units, comprising at least one inclusion and a sheath covering the presser foot, are twisted in an SZ shape around a cable center axis. In cross-sectional view, the inclusions are sandwiched between at least one outer unit and the presser winding, and the inclusions are on a straight line passing through the cable center axis and the center point of the one outer unit. Is located.

According to the first or second aspect of the present invention, the force of the outer unit to bulge outward in the radial direction is used between the outer unit and the inclusions, and between the inclusions and the presser roll. Can generate frictional force. This makes it possible to provide an optical fiber cable in which untwisting is suppressed.

It is sectional drawing of the optical fiber cable which concerns on this embodiment. It is sectional drawing of the optical fiber cable which concerns on the modification of this Embodiment. It is sectional drawing of the optical fiber cable which concerns on other modification of this embodiment.

Hereinafter, the optical fiber cable of this embodiment will be described with reference to the drawings.
As shown in FIG. 1, the optical fiber cable 100 includes a core 20 having a plurality of optical fiber units 10, a sheath 55 accommodating the core 20 inside, and a pair of tensile strength bodies 56 (tension members) embedded in the sheath 55. ) And a pair of striatum 57. The core 20 has a presser winding 54 that encloses a plurality of optical fiber units 10.

(Direction definition)
In the present embodiment, the central axis of the optical fiber cable 100 is referred to as the cable central axis O. Further, the direction along the cable center axis O is called the longitudinal direction. A cross section orthogonal to the cable center axis O is called a cross section. In the cross-sectional view (FIG. 1), the direction that intersects the cable center axis O is called the radial direction, and the direction that orbits around the cable center axis O is called the circumferential direction.
When the optical fiber cable 100 is non-circular in the cross-sectional view, the cable center axis O is located at the center of the optical fiber cable 100.

The sheath 55 is formed in a cylindrical shape centered on the cable center axis O. The material of the sheath 55 is a polyolefin (PO) such as polyethylene (PE), polypropylene (PP), ethylene ethyl acrylate copolymer (EEA), ethylene vinyl acetate copolymer (EVA), and ethylene propylene copolymer (EP). ) Resin, polyvinyl chloride (PVC) and the like can be used.

As the material of the striatum 57, a columnar rod made of PP or nylon can be used. Further, the striatum 57 may be formed by twisting fibers such as PP and polyester to make the striatum 57 water-absorbent.
The pair of striatum 57s are arranged so as to sandwich the core 20 in the radial direction. Each strip 57 is in contact with the outer peripheral surface of the core 20 (the outer peripheral surface of the presser winding 54). The number of striatum 57 embedded in the sheath 55 may be 1 or 3 or more.

As the material of the tensile strength body 56, for example, a metal wire (steel wire or the like), a tensile strength fiber (aramid fiber or the like), FRP or the like can be used.
The pair of tensile strength bodies 56 are arranged so as to sandwich the core 20 in the radial direction. Further, the pair of tensile strength bodies 56 are arranged at intervals in the radial direction from the core 20. The number of tensile strength bodies 56 embedded in the sheath 55 may be 1 or 3 or more. Further, the tensile strength body 56 does not have to be embedded in the sheath 55.

A pair of protrusions 58 extending along the longitudinal direction are formed on the outer peripheral surface of the sheath 55. The protrusion 58 and the striatum 57 are arranged at the same positions in the circumferential direction. The protrusion 58 serves as a mark when the sheath 55 is incised in order to take out the striatum 57. Instead of the protrusion 58, a mark indicating the position of the striatum 57 may be provided, for example, by making the color of a part of the sheath 55 different from that of other parts.

The core 20 includes a plurality of optical fiber units 10, a plurality of inclusions 3a to 3c, and a holding winding 54 that encloses the optical fiber unit 10 and inclusions 3a to 3c. Each of the optical fiber units 10 has a plurality of optical fiber core wires or optical fiber strands (hereinafter, simply referred to as optical fiber 1), and a bundling material 2 for bundling the optical fibers 1. The optical fiber unit 10 and inclusions 3a to 3c extend along the longitudinal direction.

The optical fiber unit 10 of the present embodiment is a so-called intermittent adhesive tape core wire, and when a plurality of optical fibers 1 are pulled in a direction orthogonal to the longitudinal direction, they adhere to each other so as to spread in a mesh shape (spider web shape). Has been done. Specifically, one optical fiber 1 is adhered to the adjacent optical fibers 1 at different positions in the longitudinal direction, and the adjacent optical fibers 1 are spaced apart from each other in the longitudinal direction. Are glued to each other.
The mode of the optical fiber unit 10 is not limited to the intermittent adhesive tape core wire, and may be appropriately changed. For example, the optical fiber unit 10 may be simply a bundle of a plurality of optical fibers 1 with a binding material 2.

As shown in FIG. 1, the optical fiber unit 10 is divided into two layers, a radial inner layer and a radial outer layer. Hereinafter, the optical fiber unit 10 located in the outermost layer is referred to as an outer unit 10A. Further, the optical fiber unit 10 other than the outer unit 10A is referred to as an inner unit 10B. That is, the outer unit 10A and the inner unit 10B are included in the plurality of optical fiber units 10.

In the example of FIG. 1, the three inner units 10B are twisted together in an SZ shape or a spiral shape around the cable center axis O. Further, the nine outer units 10A are twisted in an SZ shape around the cable center axis O so as to surround the three inner units 10B. The number of optical fiber units 10 can be changed as appropriate.

In the cross-sectional view, the inner unit 10B located in the inner layer is formed in a fan shape, and the outer unit 10A located in the outermost layer is formed in a quadrangle shape. Not limited to the illustrated example, an optical fiber unit 10 having a circular, elliptical, or polygonal cross section may be used. Further, the cross-sectional shape of the optical fiber unit 10 may be deformed. Further, the core 20 may be composed of one layer (layer of the outer unit 10A) without the inner unit 10B.

The binding material 2 has an elongated string shape and is wound around a plurality of optical fibers 1. The optical fiber 1 is partially exposed from the gap of the binding material 2. Therefore, when the sheath 55 is incised and the presser winding 54 is removed, the optical fiber 1 can be visually recognized from the gap of the binding material 2. The binding material 2 is made of a thin and highly flexible material such as a resin. Therefore, even if the optical fiber 1 is bundled by the binding material 2, the optical fiber 1 appropriately moves to an empty space in the sheath 55 while deforming the binding material 2. Therefore, the cross-sectional shape of the optical fiber unit 10 in an actual product may not be arranged as shown in FIG.

The presser winding 54 is formed in a cylindrical shape centered on the cable center axis O. The inner peripheral surface of the presser foot 54 is in contact with the radial outer end of the outer unit 10A. Further, the inner peripheral surface of the presser winding 54 is in contact with the inclusions 3b and 3c. As the presser roll 54, a non-woven fabric, a plastic tape member, or the like can be used. The presser winding 54 may be formed of a material having water absorption such as a water absorbing tape.

The inclusions 3a to 3c are formed of a fibrous material made of polyester fiber, aramid fiber, glass fiber, or the like. The inclusions 3a to 3c may be yarns having water absorption. In this case, the waterproof performance inside the optical fiber cable 100 can be enhanced.

In cross-sectional view, the inclusions 3a are sandwiched between the outer unit 10A and the inner unit 10B. The inclusions 3b are sandwiched between the outer units 10A adjacent to each other in the circumferential direction, and are in contact with the presser winding 54. The inclusions 3c are sandwiched between one outer unit 10A and the presser winding 54. The inclusions 3a are twisted together with the inner unit 10B. The inclusions 3b and 3c are twisted together with the outer unit 10A.

The inclusions 3b and 3c are in contact with the outer unit 10A. The inclusions 3a are in contact with the outer unit 10A and the inner unit 10B. Here, the binding material 2 has an elongated string shape, and is spirally wound around a bundle of optical fibers 1, for example. Therefore, the portion of the optical fiber 1 that is not covered with the string-shaped binding material 2 partially comes into contact with the inclusions 3a to 3c.

The optical fiber 1 usually has a structure in which a coating material such as resin is coated around an optical fiber bare wire formed of glass. Therefore, the surface of the optical fiber 1 is smooth, and the coefficient of friction when the optical fibers 1 come into contact with each other is relatively small. On the other hand, the inclusions 3a to 3c are formed of a fibrous material. Therefore, the coefficient of friction when the inclusions 3a to 3c come into contact with each other is larger than the coefficient of friction when the optical fibers 1 come into contact with each other.

From the above, by arranging the inclusions 3a to 3c so as to be sandwiched between the plurality of optical fiber units 10, the frictional resistance when these optical fiber units 10 move relative to each other can be increased. This makes it possible to suppress the movement of the optical fiber unit 10 in the optical fiber cable 100.

By the way, the plurality of optical fiber units 10 are twisted together about the cable center axis O. When the optical fiber unit 10 tries to untwist, the bundle of the optical fiber unit 10 tends to expand radially outward. That is, the outer unit 10A is pressed against the presser winding 54 by the force trying to untwist. Here, in the present embodiment, the inclusion 3c is sandwiched between the outer unit 10A and the presser winding 54 in the cross-sectional view.

According to this configuration, when the bundle of the optical fiber unit 10 tries to expand radially outward, the inclusions 3c are compressed radially outward between the outer unit 10A and the presser winding 54. Since the inclusions 3c are formed of a fibrous material, the friction coefficient between the optical fiber 1 and the presser winding 54 is more than the coefficient of friction between the optical fiber 1 and the inclusions 3c, and the inclusions 3c and the presser. The coefficient of friction with the winding 54 is larger. Therefore, the frictional force generated when the outer unit 10A is pressed against the pressing winding 54 with the inclusion 3c sandwiched is larger than the frictional force generated when the outer unit 10A is directly pressed against the pressing winding 54. .. That is, in the present embodiment, when the outer unit 10A tries to swell outward in the radial direction, the inclusions 3c generate a large frictional force. Due to this frictional force, the outer unit 10A is less likely to move with respect to the presser winding 54, and it is possible to suppress the untwisting of the outer unit 10A.

Further, in the present embodiment, the inclusions 3c are located on the straight line L passing through the center point A of the outer unit 10A and the cable center axis O in the cross-sectional view. With this configuration, the force that the outer unit 10A tends to swell toward the outer side in the radial direction can be more efficiently converted into a frictional force. Therefore, it is possible to more reliably suppress the untwisting of the outer unit 10A.

Further, in the present embodiment, in the cross-sectional view, the inclusions 3c are surrounded by one outer unit 10A and the presser winding 54. Therefore, when the bundle of the optical fiber unit 10 tries to expand outward in the radial direction, the inclusions 3c are more reliably sandwiched between the outer unit 10A and the presser winding 54. Therefore, the frictional force due to the inclusions 3c can be generated more reliably, and the untwisting can be suppressed.

The center point A in the present specification is the center of gravity of the outer unit 10A in a cross-sectional view. Since the outer unit 10A is twisted around the cable center axis O, the outer unit 10A tends to swell outward in the radial direction due to untwisting. The direction in which the outer unit 10A swells is the direction in which the cable center axis O is the starting point and passes through the center point A (the center of gravity of the outer unit 10A). Therefore, by locating the inclusions 3c on the straight line L passing through the cable center axis O and the center point A, the frictional force generated by the inclusions 3c due to the force that the outer unit 10A tries to inflate becomes large. Untwisting can be effectively suppressed.

Hereinafter, the above embodiment will be described with reference to specific examples. The present invention is not limited to the following examples.

(Example 1)
As Example 1, an optical fiber cable having a cross-sectional structure as shown in FIG. 1 was produced. The number of optical fibers 1 included in the optical fiber unit 10 is 144. Three inner units 10B were twisted in an SZ shape, and nine outer units 10A were twisted in an SZ shape on the outer periphery thereof. That is, the total number of optical fiber units 10 is 12, and the total number of optical fibers 1 is 1728. Water-absorbent yarns were used as inclusions 3a, 3b and 3c. Three inclusions 3a, eight inclusions 3b, and one inclusion 3c were arranged.

The setting angle of the twisting device (oscillator) when twisting the optical fiber unit 10 was adjusted so that the twist angle (introduction angle) actually introduced was ± 150 °. The "set angle" is a range of angles that cause the oscillator to swing. For example, when the set angle is ± 500 °, the oscillator repeats the operation of swinging 500 ° in the CW direction and then swinging 500 ° in the CCW direction.

As for the introduction angle, after the cable is formed, the optical fiber cable is cut at a predetermined interval in the longitudinal direction, and the position on each cut surface of the specific outer unit 10A or the optical fiber 1 included in the outer unit 10A is confirmed. Measure with. The larger the difference between the set angle and the introduction angle, the larger the outer unit 10A is untwisted.
An optical fiber cable is made by wrapping the twisted optical fiber unit 10 with a presser winding 54 and further covering it with a sheath 55.

(Example 2)
As the second embodiment, an optical fiber cable in which the number of inclusions 3b and 3c was changed from that of the first embodiment was prepared. Three inclusions 3a, six inclusions 3b, and three inclusions 3c were arranged. Other conditions are the same as in Example 1.

(Example 3)
As the third embodiment, an optical fiber cable in which the number of inclusions 3a, 3b, and 3c was changed from that of the first embodiment was prepared. No inclusions 3a and 3b were arranged, and only six inclusions 3c were arranged. Other conditions are the same as in Example 1.

(Example 4)
As Example 4, an optical fiber cable in which the number of inclusions 3a, 3b, and 3c was changed from that of Example 1 was prepared. The inclusions 3a were not arranged, and six inclusions 3b and three inclusions 3c were arranged. Further, three inclusions 3d as shown in FIG. 2 were arranged. The inclusions 3d are radially sandwiched between the inner unit 10B and the outer unit A. Other conditions are the same as in Example 1.

(Example 5)
As Example 5, an optical fiber cable in which the number of inclusions 3a, 3b, and 3c was changed from that of Example 1 was prepared. The inclusions 3b were not arranged, and three inclusions 3a and nine inclusions 3c were arranged. Other conditions are the same as in Example 1.

(Comparative Example 1)
As Comparative Example 1, an optical fiber cable 100 provided with inclusions 3a and 3b without inclusions 3c was produced. Three inclusions 3a and nine inclusions 3b were arranged. Other conditions were the same as in Example 1.

Table 1 shows the results of confirming the introduction angle and sheath twist of the optical fiber cables of Examples 1 to 5 and Comparative Example 1.

The “sheath twist” in Table 1 indicates the degree of sheath twist in the produced optical fiber cable. More specifically, it shows how much the position of the protrusion 58 in the circumferential direction changes along the longitudinal direction. For example, when the sheath twist is ± 10 °, the position of the protrusion 58 in the circumferential direction changes within a range of ± 10 ° about the cable center axis O. If the degree of sheath twist is large, the optical fiber cable will meander, leading to a decrease in laying workability and a decrease in the length that can be wound around the drum.

In the "judgment" column, the result was good (OK) when the sheath twist was ± 10 ° or less, and the result was insufficient (NG) when the sheath twist exceeded ± 10 °. The sheath twist increases as the set angle increases. This is because the larger the set angle, the stronger the twisted optical fiber unit 10 tries to untwist, and the sheath 55 is twisted around the cable center axis O.

As shown in Table 1, in Examples 1 to 5, the sheath twist was ± 10 ° or less, and good results were obtained. On the other hand, in Comparative Example 1 in which the inclusions 3c were not arranged, the sheath twist was ± 45 °, and the result was insufficient.

The reason why good results were obtained in Examples 1 to 5 is that the set angle for setting the introduction angle to ± 150 ° is ± 500 ° or less, which is considered to be relatively small. The reason why the set angle could be reduced in this way is that the inclusions 3c could reduce the untwisting of the outer unit 10A. That is, when the optical fiber unit 10 including the outer unit 10A tries to untwist and expands radially outward, the inclusion 3c is sandwiched between the outer unit 10A and the presser winding 54 to generate a frictional force. It depends on what you let me do.

On the other hand, in Comparative Example 1, since the inclusions 3c are not provided, the frictional force generated between the outer unit 10A and the presser winding 54 when the optical fiber unit 10 tries to untwist is relatively small. For this reason, untwisting is likely to occur, and the set angle for setting the introduction angle to ± 150 ° is ± 700 °, which is relatively large. It is considered that the larger the set angle, the stronger the force with which the outer unit 10A twists the sheath 55, so that the value of the sheath twist becomes larger.

From the above results, it was confirmed that the untwisting of the outer unit 10A can be reduced by providing at least one inclusion 3c on the straight line L passing through the cable center axis O and the outer unit 10A. Further, it was found that as a result of reducing the untwisting of the outer unit 10A, the set angle can be reduced and the twist generated in the sheath 55 can be suppressed.

Further, when the second embodiment and the fifth embodiment are compared, the total number of inclusions 3b and 3c in contact with the presser winding 54 is the same, but the setting angle for setting the introduction angle to ± 150 ° is the example. 5 is smaller. That is, Example 5 suppresses untwisting more effectively than Example 2. This is because the inclusions 3c are located on a straight line passing through the center point of the cable center axis O and the outer unit 10A, so that the outer unit 10A effectively exerts a frictional force to expand outward in the radial direction. It is thought that this is because it was possible to convert to.

Further, in Example 3, good results were obtained even if the total number of inclusions was small as compared with the other Examples 1, 2, 4, and 5. And in Example 3, only inclusions 3c are arranged. From this result, it was confirmed that the effect of suppressing untwisting by the inclusions 3c was larger than that of other inclusions.

The technical scope of the present invention is not limited to the above-described embodiment, and various modifications can be made without departing from the spirit of the present invention.

For example, in the example of FIG. 1, the core 20 includes a two-layer optical fiber unit 10. However, the number of layers of the optical fiber unit included in the core 20 may be 1 or 3 or more.
Further, when the core 20 includes a plurality of layers of the optical fiber unit, no inclusions are arranged between the optical fiber units (inner unit 10B in the example of FIG. 1) included in the layers other than the outermost layer. May be good.

Further, in the above embodiment, the inclusions 3c are sandwiched between one outer unit 10A and the presser winding 54. However, as shown in FIG. 3, the inclusions 3c may be sandwiched between the plurality of outer units 10A and the presser winding 54. Even in this case, the force of the outer unit 10A to inflate outward in the radial direction is used between the outer unit 10A and the inclusions 3c, and between the inclusions 3c and the presser winding 54. Friction force can be generated. Further, since the inclusions 3c are located on the straight line L passing through the cable center axis O and the center point A of the outer unit 10A, the outer unit 10A exerts a force to expand outward in the radial direction. , Can be converted into frictional force more efficiently. Therefore, it is possible to more reliably suppress the untwisting of the outer unit 10A.

In addition, it is possible to appropriately replace the components in the above-described embodiment with well-known components without departing from the spirit of the present invention, and the above-described embodiments and modifications may be appropriately combined.

1 ... Optical fiber 2 ... Bundling material 3a to 3c ... Inclusion 10 ... Optical fiber unit 10A ... Outer unit 20 ... Core 54 ... Press winding 55 ... Sheath A ... Outer unit center point L ... Straight line O ... Cable center axis

Claims (3)

Multiple optical fiber units each having multiple optical fibers,
The presser winding that wraps the plurality of optical fiber units and
With at least one inclusions placed inside the presser roll,
With a sheath covering the presser foot,
The plurality of outer units located in the outermost layer of the plurality of optical fiber units are twisted in an SZ shape around the cable center axis.
In a cross-sectional view, the inclusions are located inside a recess formed at the radially outer end of one outer unit, and the recess is formed between the outer unit and the presser winding. The inclusions are pinched ,
An optical fiber cable in which the inclusions are located on a straight line passing through the center point of the outer unit in which the recess is formed and the cable center axis in a cross-sectional view . The optical fiber cable according to claim 1, wherein the inclusions are made of a fibrous material. The optical fiber cable according to claim 1 or 2 , wherein the inclusions are twisted together with the plurality of outer units in an SZ shape about the cable center axis.

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