JP2020042175A - Optical fiber cable - Google Patents

Abstract

To provide an optical fiber cable suppressing untwisting.SOLUTION: An optical fiber cable 100 includes: a plurality of optical fiber units 10A respectively having a plurality of optical fibers 1, and twisted with each other in an SZ shape; a wrapping tape 54 for wrapping the plurality of optical fiber units 10A; at least one first interposed article 3a and at least one second interposed article 3b positioned between the adjacent optical fiber units 10A; and a sheath 55 for coating the wrapping tape 54. The first interposed article 3a contacts with the wrapping tape 54, and the second interposed article 3b is positioned on the inner side than the first interposed article 3a in a diametrical direction.SELECTED DRAWING: Figure 1

Description

  The present invention relates to an optical fiber cable.

2. Description of the Related Art Conventionally, an optical fiber cable in which an inclusion is arranged around an optical fiber unit is used.
For example, in the optical fiber cable of Patent Literature 1, a plurality of tape cores are stacked and a unit coating layer is provided around the cores to form an optical fiber unit. By providing an intervening object 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, the movement of the optical fiber unit in the optical fiber cable is suppressed by arranging an intervening object so as to be sandwiched between the optical fiber units.

JP 2001-51169 A Japanese Patent No. 6255120

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

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

  In order to solve the above problems, an optical fiber cable according to a first aspect of the present invention includes a plurality of optical fiber units each having a plurality of optical fibers, twisted in an SZ shape with each other, and the plurality of optical fibers. A presser winding enclosing a unit, at least one first inclusion and at least one second inclusion located between adjacent optical fiber units, and a sheath covering the presser winding; One inclusion is in contact with the presser winding, and the second inclusion is located radially inward of the first inclusion.

  According to the above aspect of the present invention, it is 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. FIG. 2 is a schematic diagram for explaining dimensions of each part in the optical fiber cable of FIG. 1.

Hereinafter, the optical fiber cable of the present 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 10A and 10B, a sheath 55 for housing the core 20 therein, and a pair of strength members 56 embedded in the sheath 55 ( Tension member) and a pair of striated bodies 57. The core 20 has a presser winding 54 that wraps the plurality of optical fiber units 10A and 10B.

(Direction definition)
In the present embodiment, the central axis of the optical fiber cable 100 is referred to as a central axis O. The longitudinal direction of the optical fiber cable 100 (the longitudinal direction of the optical fiber units 10A and 10B) is simply referred to as the longitudinal direction. A cross section orthogonal to the longitudinal direction is called a cross section. In a cross-sectional view (FIG. 1), a direction intersecting with the central axis O is referred to as a radial direction, and a direction orbiting around the central axis O is referred to as a circumferential direction.
When the optical fiber cable 100 is non-circular in a cross-sectional view, the central axis O is located at the center of the optical fiber cable 100.

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

As the material of the striated body 57, a cylindrical rod made of PP or nylon can be used. Further, the striated body 57 may be formed of a yarn (yarn) in which fibers such as PP and polyester are twisted, and the striated body 57 may be made to have water absorbency.
The pair of filaments 57 are arranged so as to sandwich the core 20 in the radial direction. Each striated body 57 is in contact with the outer peripheral surface of the core 20 (the outer peripheral surface of the presser winding 54). In addition, the number of the linear bodies 57 embedded in the sheath 55 may be one or three or more.

As the material of the tensile strength member 56, for example, a metal wire (such as a steel wire), a tensile strength fiber (such as an aramid fiber), and FRP can be used.
The pair of strength members 56 are arranged so as to sandwich the core 20 in the radial direction. Further, the pair of tensile members 56 are arranged at a distance from the core 20 in the radial direction. The number of the tensile members 56 embedded in the sheath 55 may be one or three or more. Further, the strength member 56 does not have to be embedded in the sheath 55.

  A pair of protrusions 58 extending in the longitudinal direction are formed on the outer peripheral surface of the sheath 55. The projection 58 and the striated body 57 are arranged at the same position in the circumferential direction. The protrusion 58 serves as a mark when the sheath 55 is cut to remove the striated body 57. Instead of the protrusion 58, a mark indicating the position of the striated body 57 may be provided, for example, by making a part of the sheath 55 different in color from other parts.

  The core 20 includes a plurality of optical fiber units 10A and 10B, a plurality of inclusions 3a to 3c, and a presser winding 54 surrounding the optical fiber units 10A and 10B and the inclusions 3a to 3c. Each of the optical fiber units 10A and 10B has a plurality of optical fiber cores or optical fiber strands (hereinafter simply referred to as optical fiber 1) and a binding material 2 for binding the optical fiber 1. The optical fiber units 10A and 10B and the inclusions 3a to 3c extend along the longitudinal direction.

The optical fiber units 10A and 10B of the present embodiment are so-called intermittent adhesive tape ribbons. When the plurality of optical fibers 1 are pulled in a direction orthogonal to the longitudinal direction, they spread in a mesh shape (spider web shape). Glued to each other. Specifically, one optical fiber 1 is bonded to the adjacent two optical fibers 1 at different positions in the longitudinal direction, and the adjacent optical fibers 1 are spaced apart from each other by a certain distance in the longitudinal direction. Are glued together.
In addition, the aspect of the optical fiber units 10A and 10B is not limited to the intermittent adhesive tape ribbon, and may be appropriately changed. For example, the optical fiber units 10A and 10B may be obtained by simply bundling a plurality of optical fibers 1 with a binding material 2.

  As shown in FIG. 1, the optical fiber units 10A and 10B are arranged in two layers, a radially inner layer and a radially outer layer. The optical fiber unit 10A is located on the outermost layer. The optical fiber unit 10B is located in a layer (hereinafter, referred to as an inner layer) inside the outermost layer. The optical fiber unit 10B is located radially inside the optical fiber unit 10A. In the example of FIG. 1, three optical fiber units 10B are mutually twisted in an SZ shape or a spiral shape. The nine optical fiber units 10A are twisted in an SZ shape so as to surround the three optical fiber units 10B. Note that the number of optical fiber units 10A and 10B can be changed as appropriate.

  In a cross-sectional view, the optical fiber unit 10B located in the inner layer is formed in a fan shape, and the optical fiber unit 10A located in the outermost layer is formed in a square shape. The optical fiber units 10A and 10B having a circular, elliptical, or polygonal cross section are not limited to the illustrated example. Further, the core 20 may be constituted by one layer (the layer of the optical fiber unit 10A) without the optical fiber unit 10B.

  The binding material 2 is in the form of an elongated string, and is wound around the plurality of optical fibers 1. The optical fiber 1 is partially exposed from the gap of the binding material 2. For this reason, when the sheath 55 is incised and the holding roll 54 is removed, the optical fiber 1 can be visually recognized from the gap between the binding materials 2. The binding material 2 is formed of a thin and flexible material such as resin. Therefore, even when the optical fibers 1 are bundled with the binding material 2, the optical fibers 1 are appropriately moved to an empty space in the sheath 55 while deforming the binding material 2. Therefore, the cross-sectional shapes of the optical fiber units 10A and 10B in the actual product may not be as shown in FIG.

  The presser winding 54 is formed in a cylindrical shape with the center axis O as the center. The inner peripheral surface of the presser winding 54 is in contact with the radially outer end of the optical fiber unit 10A. Further, the inner peripheral surface of the presser winding 54 is in contact with the inclusion 3a. As the holding roll 54, a non-woven fabric, a tape member made of plastic, or the like can be used. The holding roll 54 may be formed of a material having a water absorbing property 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. In addition, the inclusions 3a to 3c may be a yarn having a water absorbing property. In this case, the waterproof performance inside the optical fiber cable 100 can be improved.

In the cross-sectional view, the inclusion 3a is sandwiched between the optical fiber units 10A that are adjacent in the circumferential direction, and is in contact with the inner peripheral surface of the presser winding 54.
The inclusion 3b is sandwiched between the optical fiber units 10A adjacent in the circumferential direction. The inclusion 3b is located radially inward of the inclusion 3a, and is not in contact with the inner peripheral surface of the holding roll 54. The inclusions 3a and 3b are twisted in an SZ shape together with the optical fiber unit 10A. The inclusions 3a and the inclusions 3b are arranged at equivalent positions in the circumferential direction. However, the position of the inclusion 3b in the circumferential direction may be different from the position of the inclusion 3a in the circumferential direction.

  The inclusion 3c is sandwiched between the optical fiber units 10B adjacent in the circumferential direction. The inclusion 3c is located radially inward of the inclusions 3a and 3b, and is not in contact with the inner peripheral surface of the presser winding 54. The inclusion 3c is twisted together with the optical fiber unit 10B in an SZ shape or a spiral shape. In addition, the inclusion 3c does not need to be arranged.

  The inclusions 3a and 3b are in contact with the optical fiber unit 10A. The inclusion 3c is in contact with the optical fiber unit 10B. Here, the binding material 2 is in the form of an elongated cord, and is wound around the bundle of optical fibers 1 in a spiral shape, for example. For this reason, the part of the optical fiber 1 that is not covered with the string-shaped binding material 2 partially contacts the inclusions 3a to 3c.

  The optical fiber 1 usually has a structure in which a coating material such as a resin is coated around an optical fiber bare wire formed of glass. For this reason, the surface of the optical fiber 1 is smooth, and the friction coefficient when the optical fibers 1 contact each other is relatively small. On the other hand, the inclusions 3a to 3c are formed of a fibrous material. For this reason, the friction coefficient when the inclusions 3a to 3c and the optical fiber 1 come into contact is larger than the friction coefficient 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 10A and 10B, it is possible to increase the frictional resistance when the optical fiber units 10A and 10B move relative to each other. it can. This makes it possible to suppress the movement of the optical fiber units 10A and 10B in the optical fiber cable 100.

By the way, in the present embodiment, the optical fiber unit 10A is twisted in an SZ shape. Thereby, when the optical fiber cable 100 is bent, the workability of the intermediate rear branch can be improved while suppressing the tension acting on the optical fiber 1 included in the optical fiber unit 10A.
On the other hand, when the optical fiber unit 10A is twisted in an SZ shape, it becomes a problem to suppress untwisting of the optical fiber unit 10A. It is also required to suppress the side pressure acting on the optical fiber unit 10A when a compressive force acts on the optical fiber cable 100.

  Therefore, in the present embodiment, the inclusion 3a (first inclusion) and the inclusion 3b (second inclusion) are twisted together with the optical fiber unit 10A. The inclusion 3a is in contact with the holding roll 54 while being sandwiched between the optical fiber units 10A, and the inclusion 3b is located between the optical fiber units 10A radially inward of the inclusion 3a. ing.

  According to this configuration, since the inclusion 3a is in contact with the holding roll 54, the untwisting is less likely to occur as compared with the case where only the optical fiber unit 10A is in contact with the holding roll 54. This is because the frictional force acting between the inclusion 3a and the presser winding 54 is larger than the frictional force acting between the optical fiber unit 10A and the presser winding 54. More specifically, since the inclusion 3a is formed of a fibrous material, the friction coefficient between the inclusion 3a and the presser winding 54 is high.

In addition to the inclusions 3a, the inclusions 3b are arranged between the optical fiber units 10A. The presence of the inclusion 3b makes it difficult for the inclusion 3a to move inward in the radial direction, so that the state where the inclusion 3a is in contact with the presser winding 54 can be maintained more reliably. Therefore, the effect of suppressing the untwisting by the inclusions 3a can be more reliably exerted.
The inclusions 3a and 3b are arranged at the same position in the circumferential direction. With this configuration, it is possible to more reliably suppress the movement of the inclusion 3a toward the inside in the radial direction. Further, the inclusions 3a and 3b are arranged between the optical fiber units 10A in a well-balanced manner. As a result, when a compressive force acts on the optical fiber cable 100, the inclusions 3a and 3b act as cushioning members, and the lateral pressure acting on the optical fiber 1 included in the optical fiber unit 10A can be reduced.

  The optical fiber unit 10 </ b> A has a binding material 2 wound around the optical fiber 1, and the optical fiber 1 is partially exposed from a gap between the binding materials 2. For this reason, at the time of the intermediate rear branching operation, the optical fiber 1 can be easily visually recognized by incising the sheath 55 and removing the presser winding 54, thereby improving the workability.

Hereinafter, the above embodiment will be described using specific examples. Note that the present invention is not limited to the following embodiments.
In this example, the optimal arrangement and amount of inclusions were examined.

(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 units 10A and 10B was 144. Three optical fiber units 10B were twisted in an SZ shape, and nine optical fiber units 10A were twisted in an SZ shape on the outer periphery thereof. That is, the total number of the optical fiber units 10A and 10B is 12, and the total number of the optical fibers 1 is 1728. Water absorbing yarn was used as the inclusions 3a, 3b, 3c. One inclusion 3a, eight inclusions 3b, and three inclusions 3c were arranged.

  The optical fiber units 10A and 10B were twisted at a setting angle of a twisting device (oscillator) of ± 600 °. The “set angle” is a range of an angle at which the oscillator swings. For example, when the set angle is ± 600 °, the oscillator repeats the operation of swinging 600 ° in the CCW direction after swinging 600 ° in the CW direction. The optical fiber units 10A and 10B thus twisted were wrapped with a presser winding 54, and further covered with a sheath 55, thereby producing an optical fiber cable.

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

(Comparative Example 1)
As Comparative Example 1, an optical fiber cable 100 having the inclusions 3b and 3c was provided without the inclusion 3a. Nine inclusions 3b and three inclusions 3c were arranged. Other conditions were the same as in Example 1.

  Table 1 shows the results of confirming the angle (introduction angle) of the SZ twist actually introduced into the optical fiber unit 10A for the optical fiber cables of Examples 1 and 2 and Comparative Example 1. The introduction angle was measured by cutting the optical fiber cable at predetermined intervals in the longitudinal direction after making the cable, and confirming the position of each specific optical fiber or optical fiber unit on each cut surface. The larger the difference between the set angle and the introduction angle, the greater the twist of the optical fiber unit 10A.

  In the column of "Judgment" in Table 1, the results were good (OK) when the introduction angle was ± 135 ° or more, and the results were insufficient (NG) when the introduction angle was less than ± 135 °. The fact that the introduction angle is ± 135 ° or more means that when the optical fiber cable is bent, one optical fiber unit 10A surely straddles both the part where the optical fiber cable is compressed and the part where the optical fiber cable is pulled. This is the condition for placement. By satisfying this condition, the tension and the compression acting on the optical fiber unit 10A are canceled each other, so that the tension acting on the optical fiber 1 can be suppressed.

As shown in Table 1, the introduction angles of Examples 1 and 2 were larger than those of Comparative Example 1. In Examples 1 and 2, the introduction angle was ± 135 ° or more, and good results were obtained. This is because the inclusion 3a is in contact with the holding roll 54, so that the optical fiber unit 10A can be prevented from untwisting due to the frictional force between the inclusion 3a and the holding roll 54.
From a comparison between Examples 1 and 2 and Comparative Example 1, it was confirmed that the inclusion 3a in contact with the presser winding 54 can suppress the untwisting of the optical fiber unit 10A located at the outermost layer. Further, from a comparison between Example 1 and Comparative Example 1, it was confirmed that an appropriate introduction angle could be obtained by arranging at least one inclusion 3a in contact with the presser winding 54.

Next, a description will be given of a result of study on an optimum density when providing the inclusions 3a and 3b.
Here, the parameter of “outer layer interposition density D” is used. The outer layer interposition density D is the density of inclusions interposed between the optical fiber units located in the outermost layer among the plurality of optical fiber units included in the core.

  Here, the outer layer interposition density D will be described in more detail with reference to FIG. The virtual circle C1 shown in FIG. 2 is an arc connecting the radially inner ends of the plurality of optical fiber units 10A located on the outermost layer. The virtual circle C2 is an arc connecting the radially outer ends of the plurality of optical fiber units 10A located on the outermost layer. The virtual circle C2 substantially overlaps with the inner peripheral surface of the holding roll 54.

  The dimension r1 is the radius of the virtual circle C1, and the dimension r2 is the radius of the virtual circle C2. In other words, the dimension r1 is the distance between the radially inner end of the optical fiber unit 10A located at the outermost layer and the central axis O. The dimension r2 is the distance between the radially outer end of the optical fiber unit 10A located on the outermost layer (the inner peripheral surface of the presser winding 54) and the center axis O.

  Note that, for the plurality of optical fiber units 10A located in the outermost layer, the positions of the radially inner ends may be non-uniform (the virtual circle C1 in FIG. 2 may be non-circular). In this case, the average value of the distance between the radially inner end of each optical fiber unit 10A and the central axis O is defined as a dimension r1. The same applies when the virtual circle C2 is non-circular. That is, the average value of the distance between the radially outer end of each optical fiber unit 10A and the central axis O is defined as the dimension r2.

  Here, the twisted state is different between the outermost layer (the layer of the optical fiber unit 10A) and the inner layer (the layer of the optical fiber unit 10B). Also, the role of the inclusions 3a and 3b located in the outermost layer is different from the role of the inclusion 3c located in the inner layer. More specifically, the inclusion 3a is in contact with the presser winding 54 to suppress untwisting, and the inclusion 3b suppresses the inclusion 3a from moving inward in the radial direction. Therefore, for the inclusions 3a and 3b arranged in the outermost layer, it is preferable to set the density in the outermost layer to an appropriate value.

Therefore, the cross-sectional area A of the outermost layer is defined by the following equation (1). In other words, the sectional area A is the area of a region surrounded by the virtual circles C1 and C2.
^{_{A = π × r 2 2 -π}} × r 1 2 ... (1)
The outer layer interposition density D is defined by the following equation (2).
D = S ÷ A (2)
In Expression (2), S is the total value of the cross-sectional areas of the inclusions 3a and 3b arranged in the region between the virtual circles C1 and C2.

Equation (2) can also be expressed as equation (2) ′ below.
_{D = s ÷ (π × r} 2 2 -π × r 1 2) ... (2) '

  Table 2 shows the results of producing a plurality of optical fiber cables by changing the outer layer interposition density D. The conditions other than the amounts of the inclusions 3a and 3b are the same as in the first embodiment. In addition, the inclusions 3a and 3b were arranged such that the amounts became equal to each other.

“Transmission loss” in Table 2 indicates a measurement result according to ICEA S-87-640-2016. More specifically, for a single mode optical fiber, the result was good (OK) when the transmission loss at a wavelength of 1550 nm was less than 0.30 dB / km, and the result was insufficient (NG) when the transmission loss was more than 0.30 dB / km.
“Comprehensive judgment” in Table 2 was judged as good (OK) when the results of both the introduction angle and the transmission loss were good. In addition, the criterion of the introduction angle was determined to be good when ± 135 ° or more, as in the description of the first embodiment.

As shown in Table 2, when 0.05 ≦ D ≦ 0.20, the overall judgment was good.
On the other hand, when D = 0.00, the transmission loss was good, but since the introduction angle was less than the reference value (± 135 °), the comprehensive judgment was insufficient. This is because the inclusions 3a and 3b were not arranged and the untwisting could not be suppressed.
In the case of D = 0.25, the introduction angle was good, but the transmission loss was equal to or more than the reference value (0.30 dB / km), so the overall judgment was insufficient. This is because the side pressure acting on the optical fiber 1 of the optical fiber unit 10A has increased due to the excessive arrangement of the inclusions 3a and 3b.

  From the above results, it was found that the side pressure acting on the optical fiber 1 can be suppressed to a small value while suppressing the untwisting of the optical fiber unit 10A by setting the outer layer interposition density D to 0.05 or more and 0.20 or less. .

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

For example, in the example of FIG. 1, the core 20 includes two layers of optical fiber units 10A and 10B. However, the number of layers of the optical fiber unit included in the core 20 may be one, or may be three or more.
Further, when the core 20 includes a plurality of layers of the optical fiber unit, no inclusion is arranged between the optical fiber units (the optical fiber unit 10B in the example of FIG. 1) included in the layers other than the outermost layer. You may.

  In addition, the components in the above-described embodiments can be appropriately replaced with known components without departing from the spirit of the present invention, and the above-described embodiments and modified examples may be appropriately combined.

  DESCRIPTION OF SYMBOLS 1 ... Optical fiber 2 ... Bundling material 3a ... 1st inclusion 3b ... 2nd inclusion 10A, 10B ... Optical fiber unit 20 ... Core 54 ... Holding winding 55 ... Sheath O ... Central axis

Claims (4)

A plurality of optical fiber units each having a plurality of optical fibers, and twisted in an SZ shape with each other;
Holding down the plurality of optical fiber units,
At least one first inclusion and at least one second inclusion located between adjacent optical fiber units;
A sheath covering the presser winding,
The first inclusion is in contact with the presser winding;
The optical fiber cable, wherein the second inclusion is located radially inward of the first inclusion.   The optical fiber cable according to claim 1, wherein the first inclusion and the second inclusion are arranged at equivalent positions in a circumferential direction around a central axis of the optical fiber cable. The optical fiber unit has a binding material wound around the plurality of optical fibers,
The optical fiber cable according to claim 1, wherein the optical fiber is partially exposed from a gap between the binding members. The distance between the radially inner end of the optical fiber unit located in the outermost layer and the central axis of the optical fiber cable is r1,
The distance between the radially outer end of the optical fiber unit located in the outermost layer and the central axis is r2,
When the total value of the cross-sectional area of the first inclusion and the second inclusion is S,
_{D = s ÷ (π × r} 2 2 -π × r 1 2) the outer layer interposed density D represented by is 0.05 to 0.20, according to any one of claims 1 3 Fiber optic cable.

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