JP2023114328A - Optical fiber cable - Google Patents

Abstract

To provide an optical fiber cable capable of suppressing an increase in polarization mode dispersion.SOLUTION: A twisted direction of a plurality of optical fiber ribbons 3 and that of a plurality of optical fiber units 5 are set reverse to each other. Moreover, when a twist pitch of the optical fiber ribbons 3 is defined as P1 and that of the optical fiber units 5 is defined as P2, a twist pitch P of the optical fiber ribbons 3 inside the optical fiber units 5, in an axial direction of a cable in a state of being processed into a cable is represented by P=1/(|(1/P1-1/P2)|), and the pitch P is preferably 833 mm to 1600 mm.SELECTED DRAWING: Figure 1

Description

TECHNICAL FIELD The present invention relates to an optical fiber cable in which a plurality of optical fiber tape core wires are assembled.

In order to increase the amount of information transmission in one optical fiber cable, for example, a large number of optical fiber ribbons are packed in the optical fiber cable at high density to increase the number of optical fibers. As the number of cores stored in an optical fiber cable increases, it becomes difficult to specify the optical fiber core wires. A bundle of such optical fiber ribbons is called an optical fiber unit. When used, the necessary optical fiber tape core wires are taken out from this optical fiber unit and branched.

In such an optical fiber cable, a plurality of optical fiber core wires are usually twisted together to form an optical fiber unit, and the optical fiber units are further twisted together to form an optical fiber cable. By twisting the optical fiber core wires and the like in this way, it is possible to suppress variation due to the positions of the optical fiber core wires.

At this time, there is an optical fiber cable in which the twisting direction of a plurality of optical fibers is different from the twisting direction of a plurality of optical fiber units (Patent Document 1).

Also, there is an optical fiber cable in which the twisting direction of a plurality of optical fibers is the same as the twisting direction of a plurality of optical fiber units (Patent Document 2).

Japanese Patent Application Laid-Open No. 2019-109400 Japanese Patent Application Laid-Open No. 2021-157062

In Patent Document 1, by making the twisting direction of the optical fiber unit and the twisting direction of the optical fibers constituting the optical fiber unit different, the optical fiber unit tends to untwist when a tension is applied. The purpose of this is to cancel out the force of twisting and the force of untwisting the optical fiber.

FIG. 6 is a conceptual diagram showing the twisting of the optical fiber core wires 103 in the optical fiber unit 101 (left diagram) and the twisting of the optical fiber units 101 in the optical fiber cable 100 (right diagram).

As shown in the left diagram of FIG. 6, the optical fiber unit 101 is formed by twisting a plurality of optical fiber core wires 103 together. In the illustrated example, the optical fiber core wires 103 are twisted clockwise. On the other hand, as shown in the right diagram of FIG. 6, the core of the optical fiber cable 100 is formed by twisting a plurality of optical fiber units 101 together. In the illustrated example, the optical fiber units 101 are twisted counterclockwise. That is, the twisting direction of the optical fiber core wires 103 and the twisting direction of the optical fiber unit 101 are opposite. At this time, according to Patent Document 1, by making the twisting pitch of the optical fiber core wire 103 and the twisting pitch of the optical fiber unit 101 opposite to each other and substantially the same, the untwisting force when the tension is applied is mutually increased. can cancel each other out. The optical fiber core wires 103 and the optical fiber unit 101 are both twisted together without twisting. The shape is substantially the same as that in the case of twisting "with return twist". Note that twisting will be described later.

However, since the twisting direction of the optical fiber unit and the twisting direction of the optical fibers constituting the optical fiber unit are opposite to each other, the twisting of the optical fiber core wires inside the optical fiber unit cancels out, resulting in an optical fiber cable. In the state of 100, the optical fiber core wire 103 inside the optical fiber unit 101 is always positioned at a fixed position (upper in the drawing). That is, the twisting of the optical fiber core wires 103 in the optical fiber unit 101 in the axial direction of the cable in a cabled state disappears (twist pitch = infinite), or if the twist pitch of the optical fiber core wires 103 Even if the twist pitch of the optical fiber unit 101 is slightly deviated, the twist pitch of the optical fiber core wires 103 in the optical fiber unit 101 becomes extremely long.

As a result, when the manufactured optical fiber cable is wound on a drum for transportation or when the optical fiber cable is bent in the middle of the laying route, the optical fiber core wires 103 in the optical fiber unit 101 are not separated from each other. There is a risk that some of the optical fiber core wires 103 will be strained excessively without uniform deformation between them. However, if the twist pitch of the optical fiber core wire 103 and the twist pitch of the optical fiber unit 101 are greatly changed, the purpose of Patent Document 1 of canceling each other the untwisting force when tension is applied cannot be achieved.

On the other hand, in Patent Document 2, the twisting direction of the optical fiber unit and the twisting direction of the optical fibers constituting the optical fiber unit are set in the same direction, so that when the optical fiber units are twisted together, the optical fiber core wires The twist is relaxed, and the twist pitch of the optical fiber core wire is intended to be suppressed from becoming a long period.

According to Patent Document 2, since the twisting direction of the optical fiber unit and the twisting direction of the optical fibers constituting the optical fiber unit are the same, even when the cable is formed, the optical fiber core wire inside the optical fiber unit The twist of is never canceled. In addition, the twist pitch of the optical fiber core wire when it is finally cabled is even shorter than the twist pitch of the optical fiber constituting the optical fiber unit, as long as it does not lead to an increase in transmission loss. There was no particular problem.

On the other hand, in Patent Document 2, for example, if the twist pitch between the optical fiber units is increased, the twist between the optical fiber units may not be kept uniform and may be scattered. For this reason, when the coil is vertically attached to the core made by twisting the optical fiber units, the optical fiber unit may pop out from the seam. Therefore, it can be a factor of increase in transmission loss.

Here, in the conventional optical fiber cable, the twisting pitch of the optical fiber core wires and the optical fiber units was set in consideration of the increase in transmission loss, breakage, etc. during winding around the drum and laying. However, the inventors have noticed that polarization mode dispersion (PMD) can be a major cause of degradation of optical signals, especially in optical communication systems exceeding 10 Gbps. PMD is the differential group delay between two orthogonal polarization modes of light propagating in an optical fiber. Therefore, it is not enough to pay attention only to the increase in loss as in the conventional art, and it is necessary to suppress the increase in PMD.

SUMMARY OF THE INVENTION It is an object of the present invention to provide an optical fiber cable capable of suppressing an increase in polarization mode dispersion.

In order to achieve the above object, a first invention comprises a core formed by twisting a plurality of optical fiber units without twisting, and a jacket provided on the outer periphery of the core, wherein the light The fiber unit is formed by twisting and gathering a plurality of optical fiber core wires, the twisting direction of the plurality of optical fiber core wires is opposite to the twisting direction of the optical fiber unit, and the light When the twist pitch of the optical fiber core wire is _P1 and the twist pitch of the optical fiber unit is _P2 , the length of the optical fiber core wire in the optical fiber unit with respect to the axial direction of the cable in a cabled state. The optical fiber cable is characterized in that the twist pitch P=1/(|(1/P ₁ −1/P ₂ )|) is 833 mm to 1600 mm.

A second aspect of the invention comprises a core formed by twisting a plurality of optical fiber units without twisting, and a jacket provided around the outer periphery of the core, wherein the optical fiber units include a plurality of The twist pitch P of the optical fiber core wires in the optical fiber unit with respect to the axial direction of the cable in a cabled state is 833 mm to 1600 mm. An optical fiber cable characterized by

In the first and second inventions, it is desirable that the twist pitch P of the optical fiber core wires in the optical fiber unit with respect to the axial direction of the cable in a cabled state is 1000 mm to 1400 mm.

In the first invention and the second invention, the optical fiber core wire may be an intermittent adhesive type optical fiber tape core wire.

According to the first and second inventions, the twisting direction of the optical fiber core wire and the twisting direction of the optical fiber unit are not the same direction, and the optical fiber with respect to the axial direction of the cable in a cabled state. By setting the twist pitch of the optical fiber core wire within the unit within a predetermined range, it is possible to suppress an increase in loss when the optical fiber cable is bent, and to suppress an increase in PMD due to an increase in lateral pressure. can.

In addition, if the optical fiber core wire is an intermittent adhesive optical fiber tape core wire, it is possible to more efficiently suppress an increase in loss when the optical fiber cable is bent, and suppress an increase in PMD due to an increase in lateral pressure. can do.

According to the present invention, it is possible to provide an optical fiber cable capable of suppressing an increase in polarization mode dispersion.

Sectional drawing which shows the optical fiber cable 1. FIG. The figure which shows the optical fiber tape core wire 3. FIG. FIG. 4 is a diagram showing a process of twisting the optical fiber ribbons 3; (a) is a diagram showing a method of twisting optical fiber units without twisting, and (b) is a diagram showing a method of twisting optical fiber units with twisting. FIG. 4 is a diagram showing a process of twisting the optical fiber units 5; FIG. 2 is a conceptual diagram showing a twisted state of conventional optical fiber core wires 103 and a twisted state of an optical fiber unit 101 .

Hereinafter, embodiments of the present invention will be described with reference to the drawings. FIG. 1 is a cross-sectional view showing an optical fiber cable 1. FIG. The optical fiber cable 1 is a slotless type cable that does not use slots, and is composed of a core 4, a pressure wrap 7, a tension member 9, a tearing string 11, an outer jacket 13 and the like.

The core 4 is formed by twisting a plurality of optical fiber units 5 without twisting. Twisting will be described later. Further, the optical fiber unit 5 is formed by twisting and gathering, for example, a plurality of intermittently bonded optical fiber ribbons 3 .

FIG. 2 is a perspective view showing an intermittent adhesion type optical fiber ribbon 3. FIG. The optical fiber ribbon 3 is formed by arranging a plurality of optical fibers 2a, 2b, 2c, and 2d in parallel and adhering them to each other. Note that the number of optical fibers forming the optical fiber ribbon 3 is not limited to the illustrated example. Further, the optical fiber core wire does not necessarily have to be an intermittent adhesion type optical fiber tape core wire.

As shown in FIG. 2, in this embodiment, adjacent optical fibers 2a, 2b, 2c, and 2d are intermittently bonded at a bonding portion 6 at predetermined intervals in the longitudinal direction of the optical fiber ribbon 3. Glued. Moreover, it is desirable that the adhesive portions 6 adjacent to each other in the width direction are arranged to be shifted with respect to the longitudinal direction of the optical fiber ribbon 3 . For example, it is desirable that the adhesive portions 6 adjacent to each other are formed with a half pitch shift in the longitudinal direction of the optical fiber ribbon 3 . Note that the length and pitch of the bonding portions 6 are not limited to the illustrated example.

By intermittently arranging the bonded portions 6 in the longitudinal direction of the optical fiber ribbon 3 in this manner, the adjacent optical fibers 2a, 2b, 2c, and 2d are bonded to each other in the non-bonded portions. It can be easily folded (bent) with respect to the parallel direction of 2a, 2b, 2c, and 2d.

As shown in FIG. 1, a pressure wrap 7 is provided around the outer periphery of the plurality of optical fiber units 5 . The pressing wrap 7 is a tape-like member, a non-woven fabric, or the like, and is arranged so as to collectively cover the outer circumferences of the plurality of optical fiber units 5 by, for example, vertical wrapping. That is, the longitudinal direction of the pressure wrap 7 substantially coincides with the axial direction of the optical fiber cable 1, and the width direction of the pressure wrap 7 is aligned with the circumferential direction of the optical fiber cable 1. be wound. Note that the presser wrap 7 is not necessarily essential, and the core 4 including the presser wrap 7 may be called.

A jacket 13 is provided on the outer circumference of the core 4 . The jacket 13 is a layer for covering and protecting the optical fiber cable 1 . In a cross section perpendicular to the longitudinal direction of the optical fiber cable 1, a pair of tension members 9 are provided inside the jacket 13 at positions facing each other with the core 4 interposed therebetween. In addition, a tear string 11 is provided so as to face each other with the core 4 interposed therebetween in a direction substantially perpendicular to the facing direction of the tension member 9 . The tension member 9 and tear string 11 are embedded in the jacket 13 .

Next, the twisting of the optical fiber ribbons 3 will be described. FIG. 3 is a conceptual cross-sectional view showing the orientation of each optical fiber tape core wire 3 when the optical fiber tape core wires 3 constituting the optical fiber unit 5 are twisted together. In the following description, for the sake of simplicity, the optical fiber unit 5 is composed of four optical fiber tape core wires 3a, 3b, 3c, and 3d (the optical fiber tape core wires 3a, 3b, 3c, and 3d are combined to form an optical An example consisting of a core wire 3 sometimes called a fiber tape core wire 3 will be described.

3 shows a state in which the optical fiber ribbons 3a, 3b, 3c, and 3d are arranged in a predetermined direction around the twist center Z (black circle) of the optical fiber ribbon 3 (see FIG. 3). hereinafter referred to as state S1). In each of the optical fiber ribbons 3a, 3b, 3c, and 3d, the optical fibers at one end are A1, B1, C1, and D1, respectively.

In state S1, in the illustrated example, all the optical fiber ribbons 3a, 3b, 3c, and 3d are arranged parallel to each other and are all arranged in the same direction. It doesn't have to be a nice arrangement. For example, all may be oriented differently from each other.

In addition, although all the optical fiber ribbons 3a, 3b, 3c, and 3d are arranged in a straight line, such an arrangement is not necessary. For example, each of the optical fiber ribbons 3a, 3b, 3c, 3d may be bent. In this case, as described above, the optical fiber ribbons 3a, 3b, 3c, and 3d in which the adjacent optical fibers are intermittently bonded can be bent into any shape.

For example, in the state S1 of FIG. 3, the optical fiber tape core wires 3a and 3c are bent at the portions where the overall width is widened, such as the optical fiber ribbon core wires 3a and 3c, so that each optical fiber is aligned with the twist center Z. It can be brought closer and can be arranged stably. In the following figures, for the sake of simplification, the bending of the optical fiber ribbon 3 is not taken into consideration, and the optical fiber ribbons 3 are shown arranged on a straight line.

In FIG. 3, there are roughly two methods for twisting the optical fiber ribbons 3 from the state S1. One is a method of twisting in the process of state S2 (left side in the figure and arrow E) and state S3 (arrow F), and the other is a state S4 (right side in the figure and arrow G) and state S5 ( This is a method of twisting in the step of arrow H). The former is a so-called "non-twisted" twist, and the latter is a so-called "with a twisted" twist.

First, the case of twisting the optical fiber ribbon 3 without twisting will be described in detail. State S2 (arrow E) shows a state in which the optical fiber ribbon 3 from state S1 is twisted clockwise at 45° with respect to the twist center Z, and state S3 (arrow F) shows a state in which the optical fiber ribbon 3 is twisted from state S2. The optical fiber ribbons 3 are twisted clockwise at an angle of 45° with respect to the twist center Z. FIG.

In state S2, the arrangement of the optical fiber ribbons 3 in the circumferential direction with respect to the twist center Z is shifted by 45° (arrow Q in the figure), and at this time, the orientation of each optical fiber ribbon 3 is changed to Change. That is, the orientation of the optical fiber ribbon 3 is also rotated by 45° along with the movement of the arrangement. For example, the orientations of A1, B1, C1, and D1 of the optical fiber ribbons 3a, 3b, 3c, and 3d are rotated 45° from state S1 to state S2.

Similarly, in the state S3, the circumferential arrangement of the optical fiber ribbons 3 with respect to the twist center Z is further shifted by 45° from the state S2 (arrow Q in the figure). The orientation of line 3 changes as well. That is, the optical fiber ribbon 3 is twisted at an angle of 90° in states S1 to S3, and the entire optical fiber ribbon 3 rotates about the center Z of the twist.

Next, the case where the optical fiber ribbons 3 are twisted together with twisting will be described in detail. State S4 (arrow G) shows a state in which the optical fiber ribbon 3 from state S1 is twisted clockwise at 45° with respect to the twist center Z, and state S5 (arrow H) shows a state in which the optical fiber ribbon 3 is twisted from state S4. The optical fiber ribbons 3 are twisted clockwise at an angle of 45° with respect to the twist center Z. FIG.

In the state S4, the arrangement of the optical fiber ribbons 3 in the circumferential direction with respect to the twist center Z is shifted by 45° (arrow P in the figure). does not change. That is, the optical fiber ribbons 3 are oriented in substantially the same direction, and only the arrangement in the circumferential direction with respect to the twist center Z changes. For example, the orientations of A1, B1, C1, and D1 of the optical fiber ribbons 3a, 3b, 3c, and 3d do not change from state S1 to state S4 (they all point to the left in the figure).

Similarly, in the state S5, the circumferential arrangement of the optical fiber ribbons 3 with respect to the twist center Z is further shifted by 45° from the state S4 (arrow P in the figure). The orientation of line 3 does not change. That is, the optical fiber ribbons 3 are twisted at an angle of 90° in the processes of states S1, S4, and S5. only changes.

Next, the manufacturing method of each optical fiber unit 5 with and without twisting will be described. FIG. 4(a) is a diagram showing a method of twisting the optical fiber ribbon 3 without twisting. The center of the figure is the twisting center Z, and the twisted optical fiber units 5 are assumed to flow perpendicularly to the plane of the paper. In addition, illustration of a bundle material etc. is abbreviate|omitted.

A plurality of bobbins 15 around which a plurality of optical fiber tape core wires 3 are wound are arranged at predetermined intervals in the circumferential direction with respect to the twist center Z of the optical fiber tape core wires (U1, U2, U3, U4 in the figure). . From each bobbin 15, the optical fiber ribbon 3 is supplied to the twist center Z (Y in the figure), and each bobbin 15 moves around the twist center Z (X in the figure). For example, the bobbin 15 at position U1 is sequentially moved to positions U2, U3, and U4. Therefore, the optical fiber ribbons 3 supplied from the respective bobbins 15 are twisted together.

In this method, the orientation of the bobbin 15 varies depending on the position with respect to the center Z of twist. Specifically, each bobbin 15 moves around the twist center Z while rotating so as to always face the twist center Z. As shown in FIG. Conversely, when viewed from the center Z, the bobbin 15 does not rotate at each position and always rotates around the center Z in a fixed direction. Therefore, the optical fiber ribbons 3 are twisted together without twisting.

On the other hand, FIG. 4(b) is a diagram showing a method of twisting the optical fiber ribbon 3 with twisting.

The bobbins 15 around which a plurality of optical fiber tape core wires 3 are wound are arranged at predetermined intervals in the circumferential direction with respect to the twist center Z of the optical fiber tape core wires (T1, T2, T3, and T4 in the figure), From each bobbin 15, the optical fiber ribbon 3 is supplied to the twist center Z (W in the figure), and each bobbin 15 moves around the twist center Z (V in the figure). is the same as in FIG. 4(a). For example, the bobbin 15 at position T1 is sequentially moved to positions T2, T3, and T4.

In this method, each bobbin 15 moves around the twist center Z while each bobbin 15 faces in a substantially constant direction at any position relative to the twist center Z. That is, the bobbin 15 is moved in the circumferential direction around the twist center Z without changing the orientation of the bobbin 15 . Conversely, when viewed from the center Z, the bobbin 15 rotates (revolves) around the center Z while rotating (revolves) in a direction opposite to the direction of rotation (revolution). By doing so, the optical fiber ribbons 3 can be twisted together with twisting.

By twisting the optical fiber tape core wires 3 with twisting, untwisting of the optical fiber tape core wires 3 can be suppressed. That is, when the optical fiber ribbons 3 are twisted together to form the optical fiber unit 5, the twisting of the optical fiber ribbons 3 is difficult to untwist and handling is easy.

On the other hand, in order to twist the fibers with twisting in this way, a special device is required because it is necessary to control not only the revolution but also the rotation as opposed to the device for twisting without twisting. Therefore, if the optical fiber ribbons 3 are twisted without twisting in consideration of manufacturability, a special twisting device for providing twisting as described above is unnecessary, thereby reducing the manufacturing cost. can do.

Next, a method for twisting the optical fiber units 5 manufactured in this way will be described. In the present invention, the twisting direction of the plurality of optical fiber tape core wires 3 and the twisting direction of the optical fiber units 5 are opposite directions. If the twisting direction of the optical fiber tape core wires 3 and the twisting direction of the optical fiber units 5 are set to be the same, the twisting pitch of the internal optical fiber tape core wires 3 becomes short when the optical fiber units 5 are twisted. Become.

FIG. 5 is a conceptual cross-sectional view showing the orientation of each optical fiber unit 5 when the optical fiber units 5 are twisted together, similar to FIG. In the following description, for the sake of simplicity, four sets of optical fiber units 5a, 5b, 5c and 5d (optical fiber units 5a, 5b, 5c and 5d are collectively referred to as optical fiber units 5a, 5b, 5c and 5d). A description will be given of an example of twisting together. Also, the illustration is made assuming that there is no twisting of the optical fiber core wires inside.

5 shows a state in which the optical fiber units 5a, 5b, 5c, and 5d are arranged in a predetermined direction around the twist center Z of the optical fiber unit 5 (hereinafter referred to as state S11). Also, in each of the optical fiber units 5a, 5b, 5c and 5d, the optical fiber ribbons at one end are denoted by A11, B11, C11 and D11, respectively.

First, a method of twisting the optical fiber unit 5 without twisting will be described. State S22 (arrow I) shows a state in which the optical fiber unit 5 from state S11 is twisted 45° counterclockwise with respect to the twist center Z. State S33 (arrow J) shows a state in which the optical fiber unit 5 is twisted from state S22. A state in which the unit 5 is further twisted counterclockwise by 45° with respect to the twist center Z is shown.

In the state S22 and the state S33, the arrangement of the optical fiber units 5 in the circumferential direction with respect to the twist center Z is shifted by 45° (arrow N in the figure), and at this time, the orientation of the optical fiber units 5 is changed. Change. That is, the orientation of the optical fiber unit 5 also rotates by 45 degrees with the movement of the arrangement. For example, the directions of A11, B11, C11, and D11 of the optical fiber units 5a, 5b, 5c, and 5d are rotated by 45° in states S11 to S33. That is, the optical fiber unit 5 is twisted at an angle of 90° in states S11 to S33, but the entire optical fiber unit 5 rotates about the center Z of the twist.

Next, a method of twisting the optical fiber unit 5 with twisting will be described. Similarly to the above, state S44 (arrow K) shows a state in which the optical fiber units 5 are twisted counterclockwise from state S11 by 45° with respect to the twist center Z, and state S55 (arrow L) A state in which the optical fiber unit 5 is further twisted counterclockwise from the state S44 by 45° with respect to the twist center Z is shown.

In state S44 and state S55, the circumferential arrangement of each optical fiber unit 5 with respect to the twist center Z moves by 45° (arrow M in the figure). does not change. That is, the optical fiber units 5 are oriented in substantially the same direction, and only the arrangement in the circumferential direction with respect to the twist center Z changes. For example, the orientation of each A11, B11, C11, D11 of the optical fiber unit 5 does not change in states S11, S44, S55. That is, the optical fiber units 5 are twisted at an angle of 90° up to the states S11, S44, and S55, but each is oriented in a substantially constant direction, and only the arrangement in the circumferential direction with respect to the twist center Z changes. .

As with the optical fiber ribbon 3, the optical fiber unit 5 can also be twisted with untwisted to reduce untwisted even after twisting. However, in the present invention it is desirable to twist the optical fiber units 5 without untwisting. This is because, as described above, a special device is required for twisting with twisting. In addition, since the number of twisted optical fiber units 5 is often large, if twisting is performed with reverse twisting, the manufacturing cost may increase, such as the size of the apparatus.

Here, when the optical fiber tape core wire 3 and the optical fiber unit 5 are twisted in opposite directions, the twist pitch of the optical fiber tape core wire 3 is _P1 , and the twist pitch of the optical fiber unit 5 _{is P2.} Then, the twist pitch P of the optical fiber ribbon 3 in the optical fiber unit 5 with respect to the axial direction of the cable in the cabled state is
P=1/(|(1/P ₁ −1/P ₂ )|) (Formula 1)
is represented by In the present invention, the twist pitch P of the optical fiber ribbon 3 in the optical fiber unit 5 in a cabled state is preferably 833 mm to 1600 mm, more preferably 1000 mm to 1400 mm. It is desirable to have

If the twist pitch P of the optical fiber tape core wires 3 in the optical fiber unit 5 in a cabled state is too small, the lateral pressure of the optical fiber tape core wires 3 tends to increase. Here, the inventors have found that when the lateral pressure of the optical fiber ribbon 3 increases, even if the effect on the increase in transmission loss is small, it causes an increase in PMD. That is, when the twist pitch P of the optical fiber ribbon 3 in the optical fiber unit 5 in a cabled state becomes smaller, it causes an increase in PMD. On the other hand, if the twist pitch P of the optical fiber tape core wires 3 in the optical fiber unit 5 in the cabled state is too large, the loss especially during the heat cycle increases.

In addition, it is desirable that the twisting pitch of the plurality of optical fiber tape core wires 3 is 500 mm or more. There is no particular upper limit to the twisting pitch of the optical fiber tape core wires 3, and the twisting pitch may be zero (that is, the twist pitch P ₁ of the optical fiber tape core wires 3 is infinite). In this way, even when the optical fiber unit 5 is formed by gathering together a plurality of optical fiber ribbons 3 without twisting them together, the axial direction of the cable in the cabled state within the optical fiber unit 5 It is desirable that the twist pitch P of the optical fiber ribbon 3 is 833 mm to 1600 mm. That is, in this case, P= _P2 , and the twist pitch _P2 of the optical fiber unit 5 should be 833 mm to 1600 mm.

It should be noted that when the plurality of optical fiber ribbons 3 are twisted together, the twisting pitch _P1 is preferably shorter than the twisting pitch _P2 of the plurality of optical fiber units 5 .

As described above, according to the present embodiment, by twisting the optical fiber tape core wire 3 and the optical fiber unit 5 in opposite directions, the twist pitch of the optical fiber tape core wire 3 can be prevented from being excessively shortened. , the twist pitch P of the optical fiber ribbon 3 in the optical fiber unit 5 with respect to the axial direction of the cable in a cabled state can be appropriately set. In addition, since the optical fiber units 5 are twisted together without twisting, a device for twisting the optical fiber units 5 is not required, and the light generated when the optical fiber units 5 are twisted is eliminated. Relaxation of the twist of the fiber tape cable core 3 can be suppressed more reliably.

At this time, by setting the twist pitch P of the optical fiber ribbon 3 in the optical fiber unit 5 with respect to the axial direction of the cable in a cabled state within a predetermined range, an increase in transmission loss is suppressed while suppressing an increase in PMD. can be suppressed.

We created several optical fiber cables and evaluated loss increase. The optical fiber cable had a structure generally shown in FIG. First, ITU-T G.I. 657. Eight optical fibers conforming to A1 were intermittently bonded to prepare an intermittently bonded eight-core optical fiber ribbon. An 80-core optical fiber unit in which 10 of these optical fiber tape core wires are assembled and wrapped with a 2 mm wide plastic tape, and an 80 core optical fiber unit in which 5 optical fiber tape core wires are assembled and wrapped in a 2 mm wide plastic tape. A 40-core optical fiber unit was constructed.

Twelve 80-core optical fiber units and one 40-core optical fiber unit are supplied, twisted together without twisting back, vertically attached with water-absorbing non-woven fabric, rounded with a forming jig, and nylon A core of 1000 fibers was prepared by winding a presser thread made of

The core thus prepared, a tension member using a steel wire of φ1.6 mm, and a tear string for tearing the outer covering were sheathed in a cylindrical shape with an outer covering material to prepare an optical fiber cable. The outer covering material was LLDPE.

Various prototypes were prepared by varying the presence or absence of twisting of the optical fiber tape core wires and the twisting pitch, and the twisting direction and twisting pitch of the optical fiber unit, and various characteristics were confirmed. Tables 1 and 2 show the results.

In the table, "tape fiber twist direction" and "tape fiber twist pitch" are the twist direction and twist pitch of the optical fiber tape fiber, and "unit twist direction" and "unit twist pitch" are the optical fiber unit is the twist direction and twist pitch. The right and left twist directions indicate relative directions, and when the "tape cord twist direction" is "right" and the "unit twist direction" is "left," they are twisted in opposite directions. be. Both the optical fiber ribbon and the optical fiber unit were twisted together without twisting. In addition, when the "tape core wire twisting direction" is "none", the fibers are assembled without being twisted together.

In the table, "strand direction of optical fibers in cable state" and "strand pitch of tape fibers in cable state" refer to the direction of change in the circumferential position of the optical fiber core wires in the optical fiber unit in cable state. Expresses the pitch, and the tape core wire stranding pitch P in the cable state is calculated by Equation 1 (however, if the tape core wires are not twisted, P ₁ =infinity).

PMD was measured by the Jones matrix method with a 1 km cable wound around a drum with a barrel diameter of 1400 mm. "X" when the maximum value of the measured value was 0.15 (ps/√km) or more, and "○" when it was 0.10 (ps/√km) or more and less than 0.15 ps/√km , and less than 0.10 (ps/√km) were marked with “⊚”.

The loss increase during the heat cycle was measured by placing a 1km cable wound around a drum with a diameter of 1400mm in a constant temperature bath, changing the temperature of the constant temperature bath between -30°C and 70°C, and measuring 1550nm with an OTDR. , and the difference was measured. "x" when the maximum value of the measured value was 0.15 (dB/km) or more, "○" when it was 0.10 (dB/km) or more and less than 0.15 (dB/km) , and less than 0.10 (dB/km) were marked with "⊚".

As a result, by setting the twist pitch of the tape core wires in the optical fiber unit to 833 mm to 1600 mm, it was possible to reduce the PMD while suppressing the loss fluctuation in the heat cycle. In particular, the effect was further enhanced by setting the twist pitch of the tape core wires in the optical fiber unit to 1000 mm to 1400 mm. At this time, by reversing the twisting direction of the fiber ribbons in the unit and the direction in which the units are twisted, the twist pitch of the fiber ribbons in the unit can be adjusted to the desired value while appropriately setting the twist pitch of each. It is also possible to adjust the value, making it easier to keep the twist uniform when twisting the units together, and increasing the degree of freedom in designing the twist pitch.

On the other hand, in Comparative Examples 1 and 3, the PMD was "x" because the twist pitch of the tape core wires in the optical fiber unit was small. In addition, in Comparative Examples 2 and 4, the twist pitch of the tape core wires in the optical fiber unit was large, so the loss increase in the heat cycle was "x".

Although the embodiments of the present invention have been described above with reference to the accompanying drawings, the technical scope of the present invention is not influenced by the above-described embodiments. It is obvious that a person skilled in the art can conceive various modifications or modifications within the scope of the technical idea described in the claims, and these are naturally within the technical scope of the present invention. be understood to belong to

For example, a slotless optical fiber cable may have a cross-sectional shape other than that shown in FIG.

1 Optical fiber cables 2a, 2b, 2c, 2d Optical fibers 3, 3a, 3b, 3c, 3d Optical fiber ribbon cores 4 Cores 5, 5a, 5b, 5c, 5d …………Optical fiber unit 6 ……Adhesive portion 7 ……Presser winding 9 ……Tension member 11 ……Tear string 13 ……Outer cover 15 ……Bobbin 100 …………Optical fiber cable 101 …… ……optical fiber unit 103……optical fiber ribbon

Claims (4)

a core formed by twisting a plurality of optical fiber units without twisting;
a jacket provided on the outer periphery of the core;
and
The optical fiber unit is formed by twisting and assembling a plurality of optical fiber core wires,
the twisting direction of the plurality of optical fiber core wires is opposite to the twisting direction of the optical fiber unit,
When the twist pitch of the optical fiber core wire is _P1 and the twist pitch of the optical fiber unit is _P2 ,
The twist pitch P=1/(|(1/P ₁ −1/P ₂ )|) of the optical fiber core wire in the optical fiber unit with respect to the axial direction of the cable in a cabled state is 833 mm to 1600 mm. An optical fiber cable characterized by: a core formed by twisting a plurality of optical fiber units without twisting;
a jacket provided on the outer periphery of the core;
and
The optical fiber unit is formed by gathering a plurality of optical fiber core wires without twisting them together,
An optical fiber cable, wherein a twist pitch P of the optical fiber core wires in the optical fiber unit in the axial direction of the cable in a cabled state is 833 mm to 1600 mm. 3. The optical fiber according to claim 1, wherein a twist pitch P of the optical fiber core wire in the optical fiber unit with respect to the axial direction of the cable in a cabled state is 1000 mm to 1400 mm. cable. 4. The optical fiber cable according to any one of claims 1 to 3, wherein the optical fiber core wire is an intermittent adhesive type optical fiber tape core wire.

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