JP5200054B2 - Fiber optic cable - Google Patents

Description

  The present invention relates to an optical fiber cable in which an optical fiber is covered with a jacket (sheath).

  Optical fiber cables used in optical communications include overhead aggregating drop optical fiber cables installed as subscriber optical fiber cables and branching from aerial aggregated drop optical fiber cables to lead them into subscribers' homes Are used as overhead drop optical fiber cables.

  As an aerial drop optical fiber cable for drawing and wiring to an apartment house such as an apartment or a condominium, as shown in FIG. 5, a self-wire unit 101 and a cable main body 102 are connected via a neck 103. Support structure fiber optic cables are used. Note that an optical fiber cable used in a subscriber's house, a building, a condominium, or the like is an optical fiber cable having a structure including only a cable main body portion 102 that does not have the support wire portion 101.

  A support wire 104 made of steel wire is built in the support wire portion 101. An optical fiber core wire 105 and a tensile body 106 are built in the cable main body 102. The optical fiber core wire 105 of such an optical fiber cable is configured by coating the outer circumference of a silica glass fiber with a coating material made of an ultraviolet curable resin or the like. A non-halogen flame retardant sheath is used as the jacket (sheath) 107.

  In recent years, a so-called “low bending loss optical fiber” has been developed which has a small increase in loss even when bent so that the radius of curvature is 15 mm or less, and is applied to an optical fiber cable used for lead-in wiring to a subscriber's house. However, when a conventional optical fiber cable is bent, the following behavior is exhibited.

  In this optical fiber cable, since the strength member 106 and the optical fiber core wire 105 are arranged on one plane (on a straight line in the cross section of the cable), the bending direction is as shown in FIG. The direction is perpendicular to the plane including the body 106 and the optical fiber core 105, that is, the direction in which the two strength members 106 draw an equal arc. At this time, compressive stress is applied to the inside of the bend, and tensile stress is applied to the outside of the bend.

  That is, when this optical fiber cable is bent, as shown in FIG. 7, a compressive stress is applied to the inner side of the stress neutral line 108 in the AA cross section in FIG. 6, and a tensile stress is applied to the outer side. At this time, also in the optical fiber core wire 105, a tensile stress is applied to the glass surface outside the bend, and when this tensile stress is large, the tensile strain on the glass surface increases. When fixed in such a small-diameter bending state, there is a problem that the fracture life of the optical fiber core 105 is shortened and long-term reliability is lowered.

  As an optical fiber cable in which bending strain applied to the optical fiber core wire is reduced when the optical fiber cable is bent, Patent Document 1 discloses that the outer diameter of the tensile body 106 is 0.2 mm or more and 1.0 mm or less. By setting the tensile elastic modulus of the tensile body 106 to 2.1 times or more and 1.14 times or less of the compression elastic modulus, when the optical fiber cable is bent, the stress neutral line becomes the center line of the tensile body 106. A fiber optic cable is described which is adapted to shift out of the bend.

  Further, in Patent Document 2, a pair of strength members 106 are disposed so as to sandwich the optical fiber wire 105 as shown in FIG. 8 as an optical fiber cable that prevents the optical fiber core wire 105 from being displaced relative to the strength member 106. An optical fiber cable in which these members are integrated by a holding member 108 to form an assembly 109 and the assembly 109 is covered with a jacket 107 is described.

  In Patent Document 3, as shown in FIG. 9, a high-bend optical fiber core 105 having an allowable bending radius of a curvature radius of 7.5 mm to 15 mm is used as the optical fiber core 105, and a glass fiber is used as the tensile body 106. An optical fiber cable using a composite material in which a polyester fiber 106b is arranged on the outer periphery of a core material 106a made of and integrated with an alicyclic epoxy resin is described.

  In Patent Document 4, as shown in FIG. 10, a plurality of optical fiber core wires 105 are twisted together in the SZ direction around a core material (inclusion) 105a to be assembled into a core wire assembly portion 105b. An optical fiber cable is described in which a wire assembly portion 105b and a tensile body 106 are collectively covered with an outer jacket 107.

Japanese Patent No. 4268075 JP 2006-91336 A Japanese Patent No. 4234670 JP 2006-171527 A

  By the way, in the optical fiber cable described in Patent Document 1, it is assumed that the tensile body 106 and the optical fiber core wire 105 are arranged in a straight line. If the position is displaced with respect to the tensile strength member 106, there is a problem that the tensile strain in the fiber core wire 105 when the optical fiber cable is bent increases.

  The optical fiber cable described in Patent Document 2 is intended to prevent such positional displacement of the optical fiber core wire 105 with respect to the tensile body 106. However, the holding member 108 is used to prevent the optical fiber core wire 105 and There is a problem that a process for manufacturing the assembly 109 including the tensile body 106 is required, and the manufacturing becomes complicated.

  The optical fiber cable described in Patent Document 3 has a problem that the tensile body 106 becomes thicker than the aramid fiber reinforced plastic used as the tensile body 106 in the other optical fiber cables described above.

  In order to manufacture the optical fiber cable described in Patent Document 4, a process of assembling the optical fiber core wire 105 into the SZ twist on the core material (inclusion) 105a is required, and there is a problem that the manufacturing becomes complicated. .

  Accordingly, the present invention has been proposed in view of the above-described circumstances, and in an optical fiber cable in which an optical fiber core wire and a tensile body are covered with an outer sheath, the production of the tensile body is not complicated. It is an object of the present invention to provide an optical fiber cable in which bending strain applied to the optical fiber core when bent is reduced without increasing the thickness of the optical fiber cable.

  In order to solve the above-described problems and achieve the above object, an optical fiber cable according to the present invention has any one of the following configurations.

[Configuration 1]
An optical fiber cable in which an optical fiber core and a pair of strength members are covered with a jacket made of a thermoplastic synthetic resin material, and the pair of strength members are fiber reinforced having a higher tensile elastic force than compression elastic force. It is made of plastic and each is formed into a long, substantially flat plate shape. Each main plane portion is opposed to each other, the optical fiber core wire is sandwiched between these main plane portions, and both side edges are in contact with each other. It is a feature.

[Configuration 2]
In the optical fiber cable having the configuration 1, the pair of strength members are formed such that the main plane portions sandwiching the optical fiber core wires are concavely curved, and the outer surfaces of the pair of strength members excluding the mutual contact portions are It is characterized in that it is adhered to the outer jacket with an adhesive resin.

[Configuration 3]
In the optical fiber cable having the configuration 1 or the configuration 2, the jacket is formed with a pair of V-shaped notches, and these notches are arranged with the bottoms close to the edges of the pair of strength members. It is characterized by being formed.

[Configuration 4]
In the optical fiber cable having any one of Configurations 1 to 3, the jacket includes a support wire and is self-supporting.

Since the optical fiber cable according to the present invention has the configuration 1, the pair of strength members are made of fiber reinforced plastic having a property that the tensile elastic force is higher than the compressive elastic force , and each has a long, substantially flat plate shape. Formed, facing each other's main plane portions, sandwiching the optical fiber core wire by these main plane portions, and making both side edges contact each other, so when bent without having to make the strength member thicker Bending strain applied to the optical fiber core wire can be reduced. Further, the production is not complicated.

Since the optical fiber cable according to the present invention has the configuration 2, the pair of strength members have the main plane portions sandwiching the optical fiber core wires curved in a concave shape, and the pair of strength members are mutually connected . Since the outer surface excluding the contact part is bonded to the jacket with an adhesive resin, the optical fiber core wire and the tensile body are projected and pulled into the cable end by the thermal expansion and contraction of the jacket. Is prevented.

  Since the optical fiber cable according to the present invention has the configuration 3, the jacket is formed with a pair of V-shaped notches, and these notches are close to the edges of the pair of strength members. Therefore, at the end portion of the cable, the outer sheath can be torn from the notch and the optical fiber core wire can be easily taken out.

  That is, the present invention relates to an optical fiber cable in which an optical fiber core wire and a tensile strength member are covered with an outer sheath, when the optical fiber core is bent without making the strength member thick and without making the strength member thick. It is possible to provide an optical fiber cable in which bending strain applied to a wire is reduced.

It is sectional drawing which shows the structure of the optical fiber cable which concerns on embodiment of this invention. It is a top view which shows the state of the stress neutral line in the optical fiber cable which concerns on embodiment of this invention. It is sectional drawing which shows the other example of a structure of the optical fiber cable which concerns on embodiment of this invention. In the optical fiber cable which concerns on embodiment of this invention, it is sectional drawing which shows the state which teared the jacket. It is sectional drawing which shows the structure of the conventional optical fiber cable. It is a perspective view which shows the state which bent the cable part main body of the optical fiber cable shown in FIG. It is a top view which shows the state of the stress neutral line in the AA cross section in FIG. It is sectional drawing which shows the other example of a structure of the conventional optical fiber cable. It is sectional drawing which shows the further another example of a structure of the conventional optical fiber cable. It is sectional drawing which shows the further another example of a structure of the conventional optical fiber cable.

  Hereinafter, embodiments for carrying out the present invention will be described in detail with reference to the drawings.

  FIG. 1 is a cross-sectional view showing a configuration of an optical fiber cable according to an embodiment of the present invention.

  As shown in FIG. 1, the optical fiber cable according to the embodiment of the present invention is configured by covering an optical fiber core wire 1 with a sheath (sheath) 3 made of a synthetic resin material.

  The optical fiber core 1 is configured by coating the outer periphery of a silica glass fiber with a coating material made of an ultraviolet curable resin or the like. The jacket 3 is made of a thermoplastic synthetic resin material.

  The outer cover 3 includes a pair of strength members (tension members) 5 and 5 made of fiber reinforced plastic such as aramid FRP and glass FRP together with the optical fiber core 1. These strength members 5 and 5 are arranged in parallel to the optical fiber core wire 1. Each of these strength members 5 and 5 is formed in a long and substantially flat plate shape, the main plane portions thereof are opposed to each other, and the optical fiber core wire 1 is sandwiched between these main plane portions.

  Further, the pair of strength members 5 and 5 have main plane portions sandwiching the optical fiber core wires 1 curved in a concave shape, and both side edges are in contact with each other. And it is desirable for the pair of strength members 5 and 5 to adhere the outer surfaces except the mutual contact portions to the outer jacket 3 with an adhesive resin.

  The optical fiber cable may be configured as a self-supporting type in which the support wire 2 is included in the jacket 3. In this case, the main body portion 1 a including the optical fiber core wire 1 and the support wire portion 2 a including the support wire 2 are connected by the narrow neck portion 4. The outer cover 3 of the main body 1a and the support wire 2a and the neck 4 are integrally formed of the same material.

  In this optical fiber cable, since the strength members 5 and 5 are flat, it is difficult to bend in the longitudinal direction of the cross section of the strength members 5 and 5 indicated by the arrow X in FIG. 1, and the cross section indicated by the arrow Y in FIG. It is easy to bend in the minor axis direction. That is, like the conventional optical fiber cable, the bending direction is regulated in the minor axis direction of the main body 1a.

  FIG. 2 is a plan view showing a state of a stress neutral line in the optical fiber cable according to the embodiment of the present invention.

  The fiber reinforced plastic that forms the tensile strength members 5 and 5 is made by hardening a large number of thin fibers such as aramid fibers and glass fibers with an epoxy resin or the like. Therefore, the strength members 5 and 5 have a characteristic that the tensile elastic force is higher than the compression elastic force, that is, a characteristic that it is difficult to be pulled and is easily compressed. Therefore, as shown in FIG. 2, when the optical fiber cable is bent, the stress neutral line 6 is shifted to the outside of the center line 7 of the strength members 5 and 5, and as a result, the optical fiber core 1 Tensile strain on the outside of the glass surface bend is reduced.

  Moreover, since the optical fiber core wire 1 is sandwiched between the two flat plate-shaped tensile strength members 5 and 5, the center line of the optical fiber core wire 1 is located inside the bending stress neutral wire 6 in the bending direction. become. Therefore, the bending strain applied to the optical fiber core wire 1 becomes a strain in the compression direction at the center line of the optical fiber core wire 1, and the strain applied to the glass surface of the optical fiber core wire 1 is greatly reduced.

  Further, in this optical fiber cable, when the tensile strength is equal (the cross-sectional areas of the strength members 5 and 5 are equal) compared to the conventional optical fiber cable, there is a merit that the major axis of the main body 1a can be reduced. is there. Furthermore, in this optical fiber cable, since the optical fiber core wire 1 is covered with the strength members 5 and 5, the strength materials 5 and 5 serve as a protective material, and the optical fiber from the spawning tube of the bearfish The core wire 1 can be protected.

  By the way, since the thermal expansion coefficients of the tensile bodies 5, 5 (aramid FRP) and the optical fiber core wire 1 are lower than those of the jacket 3 (a thermoplastic resin such as flame retardant polyolefin), the temperature expansion / contraction of the jacket 3 is low. When the temperature is large, when the temperature change is applied to the optical fiber cable, the tensile strength members 5 and 5 and the protruding portion of the optical fiber core wire 1 with respect to the jacket 3 occur at the end portion of the optical fiber cable. Then, there is a possibility that problems such as the optical fiber core wire 1 being disconnected from the connector or bending locally increasing loss.

  Therefore, it is preferable to cover the strength members 5 and 5 with an adhesive resin and adhere to the outer cover 3. At this time, if the tensile strength members 5 and 5 are bonded to each other and the peelability is deteriorated, the workability of taking out the optical fiber core wire 1 is deteriorated. Do not wrap around.

  FIG. 3 is a sectional view showing another example of the configuration of the optical fiber cable according to the embodiment of the present invention.

  As shown in FIG. 3, a pair of parallel groove-shaped notches 6, 6 are formed in the outer jacket 3 on both side surfaces facing each other with the optical fiber core 1 interposed therebetween, and the bottoms of these notches 6, 6 Is preferably formed close to the edge of the pair of strength members 5 and 5.

  FIG. 4 is a cross-sectional view showing a state where the jacket is torn in the optical fiber cable according to the embodiment of the present invention.

  The jacket 3 can be easily torn at the notches 6 and 6. As shown in FIG. 4, by tearing the outer cover 3 of the end portion from these notches 6, 6, the tensile strength members 5, 5 are separated together with the outer cover 3, and a so-called lead-out operation for taking out the optical fiber core 1 is performed. It can be performed easily and can be connected to the optical fiber core of another optical fiber cable.

  As an example of the present invention, an optical fiber cable was produced using a flat aramid fiber reinforced plastic (aramid FRP) having a cross section of about 0.2 mm × 1 mm as the strength members 5 and 5. The tensile strength members 5 and 5 have a cross-sectional area equal to φ0.5 mm aramid PRP used as a tensile strength member in the conventional optical fiber cable shown in FIG. 5, and have the same tensile strength. The dimensions of the strength members 5 and 5 are not particularly limited, but are composed of 300 cN / dtex or higher strength fibers, 1500 dtex or more, based on the tensile strength of the optical fiber cable and the cable dimensions. It is preferable to use fiber reinforced plastic, and the minor axis of the cross section is 0.1 mm to 0.3 mm, and the major axis is 0.2 mm to 2.0 mm.

  The strength members 5 and 5 are molded into a flat plate shape so that the main plane portion sandwiching each optical fiber core wire 1 is concave, and the epoxy resin is cured to have a predetermined shape.

  As the optical fiber core 1, an optical fiber core wire of φ0.25 mm was used. The jacket 3 was made of flame retardant polyolefin. The size of the main body 1a was about 1.6 mm × 2.0 mm. The support wire 2 was a galvanized steel wire having a diameter of 1.2 mm.

When the main body portion 1a of the optical fiber cable was bent in the minor axis direction, the strain applied to the optical fiber core wire 1 was measured by a pulse method. Before and after bending, the optical path length was precisely measured with an optical pulse, and the strain at the center of the optical fiber core 1 due to bending was measured from the difference in optical path length before and after bending. The strain on the glass surface of the optical fiber core 1 is that the glass diameter (cladding diameter) of the optical fiber is 125 μm, and the glass surface is 62.5 μm outside from the center of the optical fiber core 1. It was determined by adding the strain for the radius to the strain at the center of 1. The results are shown in [Table 1] below. A negative numerical value indicates that the distortion is in the compression direction. As shown in [Table 1], all were compressive strains, and it was confirmed that the long-term reliability of the optical fiber core 1 was not impaired.

  The present invention is applied to an optical fiber cable in which an optical fiber is covered with a jacket (sheath).

1 Optical fiber core wire 3 Outer sheath (sheath)
3a Inner layer 3b Outer layer 5 Strength member (tension member)

Claims (4)

An optical fiber cable in which an optical fiber core and a pair of strength members are covered with a jacket made of a thermoplastic synthetic resin material,
The pair of strength members are made of fiber reinforced plastic having a higher tensile elastic force than that of the compression elastic force , each is formed in a long and substantially flat plate shape, and the main plane portions thereof are opposed to each other. The optical fiber cable is characterized in that the optical fiber core wire is sandwiched by the portions , and both side edges are in contact with each other . In the pair of strength members, the main plane portions sandwiching the optical fiber core wires are curved in a concave shape, and the outer surfaces of the pair of strength members excluding the mutual contact portions are against the outer jacket. The optical fiber cable according to claim 1, wherein the optical fiber cable is bonded with an adhesive resin. A pair of V-groove notches are formed in the outer jacket,
The optical fiber cable according to claim 1 or 2, wherein the notches are formed such that bottom portions are close to edges of the pair of strength members. The optical fiber cable according to any one of claims 1 to 3, wherein a support wire is included in the jacket and is a self-supporting type.

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