JP2019090928A - Optical code, tension member-attached optical fiber tape, and method for manufacturing tension member-attached optical fiber tape - Google Patents

Abstract

To provide an optical code capable of restraining a tension member from meandering therein.SOLUTION: An optical code of the present disclosure comprises: an intermittently-coupled type optical fiber tape that has a plurality of optical fibers formed by intermittently coupling adjacent optical fibers in a lengthwise direction; a tension member; and a sheath for housing the optical fiber tape and the tension member. The optical fiber and the tension member are intermittently coupled together in the lengthwise direction, and the plurality of optical fibers making up the optical fiber tape are spirally disposed along the tension member. The optical fiber tape and the tension member are housed in the sheath with the optical fiber tape wound around an outer periphery of the tension member.SELECTED DRAWING: Figure 3

Description

  The present invention relates to an optical cord, a tensile strength optical fiber tape, and a method of manufacturing a tensile strength optical fiber tape.

  Patent Documents 1 and 2 describe an optical fiber tape (intermittent connection type optical fiber tape) in which optical fibers of three or more cores arranged in parallel are intermittently connected. Further, in Patent Document 3, an optical fiber strand and a metal wire are disposed in parallel, and a partially joined coupling portion and a separated non-coupling portion are repeated in the length direction (longitudinal direction). It describes that it provides. Further, Patent Documents 4 to 7 describe an optical cable, an optical fiber tape (optical fiber ribbon) and the like provided with a tensile strength member and a metal wire together with a plurality of optical fibers.

Patent No. 4143651 Patent No. 4619424 gazette JP, 2008-192399, A JP, 2009-244589, A Unexamined-Japanese-Patent No. 2014-21439 JP, 2014-109751, A Japanese Patent Application Laid-Open No. 11-53959

  Patent Document 1 describes a configuration in which an intermittent connection type optical fiber tape is rolled and accommodated in a jacket. When the optical cord with such a configuration is tensioned, if the optical fiber is tensioned, the optical fiber may be damaged. For this reason, it is desirable to accommodate not only the optical fiber but also the tensile member inside the optical cord.

  However, when the tensile member is accommodated in a meandering manner in the inside of the optical cord (the accommodation space inside the outer jacket), the tensile body having a surplus length will be accommodated in the optical cord. As a result, when a tension is applied to the optical cord, the optical cord is stretched by the extra length without resisting the tension, and the tension may be applied to the optical fiber inside the optical cord.

  An object of the present invention is to suppress the meandering of a tensile strength body inside an optical cord.

  The main invention for achieving the above object is an intermittent connection type optical fiber tape having a plurality of optical fibers in which adjacent optical fibers are intermittently connected in the longitudinal direction, a tensile member, the optical fiber tape, and And a sheath for containing the tensile strength member, wherein the optical fiber and the tensile strength member are intermittently connected in the longitudinal direction, and a plurality of the optical fibers constituting the optical fiber tape are along the tensile strength member. And the optical fiber tape and the tensile body are accommodated in the sheath in a state where the optical fiber tape is wound around the outer periphery of the tensile body. .

  Other features of the present invention will become apparent from the description of the specification and the drawings described below.

  According to the present invention, it is possible to suppress the meandering of the tensile strength body inside the optical cord.

FIG. 1A is a cross-sectional view of the optical code 10 of the first embodiment. FIG. 1B is an explanatory view of the connector-equipped cord 1 of the first embodiment. 2A to 2C are explanatory views of the optical fiber tape 12 and the tensile strength body 15 (optical fiber tape 11 with tensile strength body) according to the first embodiment. FIG. 2B is a cross-sectional view taken along line AA of FIG. 2A. FIG. 2C is a cross-sectional view taken along line B-B of FIG. 2A. FIGS. 3A and 3B are other explanatory views of the optical fiber tape 12 and the tensile strength member 15 (optical fiber tape 11 with tensile strength member) of the first embodiment. FIG. 4A is an explanatory view of a tape manufacturing apparatus 30 for manufacturing the tension-member-equipped optical fiber tape 11 of the first embodiment. FIG. 4B is an explanatory view of a cord manufacturing device 40 for manufacturing the optical code 10 of the first embodiment. 5A and 5B are explanatory diagrams of the tape forming device 33. FIG. FIG. 6A is an explanatory view of a tape manufacturing apparatus 30 according to a modification. FIG. 6B is an explanatory view of a cord manufacturing device 40 according to a modification. 7A and 7B are explanatory diagrams of the tensile-fiber-attached optical fiber tape 11 according to the second embodiment. FIG. 8 is an explanatory view of a tape manufacturing apparatus for manufacturing the tension-member-equipped optical fiber tape 11 of the third embodiment. FIG. 9 is an explanatory view of another rotation method of the drum (the drum around which the optical fiber 13 is wound) in the supply source 31A of the third embodiment. FIG. 10 is an explanatory view of another tape manufacturing apparatus according to the third embodiment. 11A to 11C are explanatory diagrams of comparative examples.

  At least the following matters will be clear from the description of the specification and drawings to be described later.

  An intermittent connection type optical fiber tape having a plurality of optical fibers in which adjacent optical fibers are intermittently connected in the longitudinal direction; a tensile strength member; and an outer jacket for accommodating the optical fiber tape and the tensile strength member; The optical fiber and the tensile strength body are intermittently connected in the longitudinal direction, and a plurality of the optical fibers constituting the optical fiber tape are disposed in a spiral along the tensile strength body, and the optical fiber tape In a state in which the optical fiber tape and the tensile strength body are accommodated in the outer cover, the optical cord becomes apparent. According to such an optical cord, it is possible to suppress the meandering of the tensile strength body inside the optical cord.

  It is desirable that a notch be formed in the outer cover along the longitudinal direction. In the case of an optical cord in which the optical fiber is disposed outside the tensile strength member, it is particularly effective to form a notch in the jacket.

  The optical cord preferably comprises two sheets of the optical fiber tape, and the tensile member is preferably connected to the respective optical fibers located at the ends of the two sheets of the optical fiber tape . Thereby, a plurality of optical fiber tapes can be accommodated in the optical cord.

  The two optical fiber tapes respectively have a plurality of optical fibers colored in the same color scheme, and the color of the optical fiber connected to the tensile member in one of the optical fiber tapes, and the other Preferably, the color of the optical fiber coupled to the tensile member in the optical fiber tape is different. This makes it possible to distinguish between the two optical fiber tapes.

  An intermittent connection type optical fiber tape having a plurality of optical fibers in which adjacent optical fibers are intermittently connected in the longitudinal direction, and a tensile strength member, wherein the optical fiber and the tensile strength member are intermittent in the longitudinal direction The optical fiber tape is wound around the outer periphery of the tensile strength member in a state where the plurality of optical fibers constituting the optical fiber tape are helically arranged along the tensile strength member. An optical fiber tape with a tensile strength characterized by the above is revealed. According to such an optical fiber tape with a tensile member, it is possible to suppress the meandering of the tensile member.

  An intermittent connection type optical fiber tape having a plurality of optical fibers in which adjacent optical fibers are intermittently connected in the longitudinal direction, and a tensile strength member, wherein the optical fiber and the tensile strength member are intermittent in the longitudinal direction A plurality of the optical fibers constituting the optical fiber tape and the tensile strength members are arranged side by side in the width direction in a state where the tensile strength members are connected to each other and the torsional tension is applied to the tensile strength members. A tensile-fiber-containing optical fiber tape is revealed. According to such an optical fiber tape with a tensile member, it is possible to suppress the meandering of the tensile member.

  The plurality of optical fibers constituting the optical fiber tape and the tensile body are arranged in the width direction in a state in which the torsional strain is applied to the tensile body and the extension strain is applied to the tensile body. It is desirable to be placed at. Thereby, when releasing the torsional strain of the tensile member, it is possible to suppress the application of tension to the optical fiber.

  The plurality of optical fibers constituting the optical fiber tape and the tensile body are arranged in the width direction in a state in which the torsional strain is applied to the tensile body and the torsional strain is applied to the optical fiber. It is desirable to be placed at. Thereby, when releasing the torsional strain of the tensile strength member, it is possible to suppress the application of the twisting force to the optical fiber.

  Supplying a plurality of optical fibers to the tape forming apparatus, supplying a torsionally strained tensile strength member to the tape forming apparatus, and intermittently connecting the adjacent optical fibers in the longitudinal direction in the tape forming apparatus And intermittently connecting the optical fiber and the tensile member in the longitudinal direction, and releasing the torsional strain to form a plurality of optical fibers constituting an optical fiber tape along the tensile member. A method for producing an optical fiber tape with a tensile body characterized in that an optical fiber tape with a tensile body is produced by winding the optical fiber tape around the outer periphery of the tensile body in a state of being arranged in a spiral is performed. It becomes. Thereby, the meandering of the tensile body can be suppressed.

  When the tensile body is supplied to the tape forming apparatus, the torsional strain is applied to the tensile body, and an elongation strain is applied to the tensile body, and the tensile strain is released when the torsional strain is released. It is desirable to Thereby, when releasing the torsional strain of the tensile member, it is possible to suppress the application of tension to the optical fiber.

Applying a torsional strain to the optical fibers when supplying the plurality of optical fibers to the tape forming device;
It is desirable to release the torsional strain of the optical fiber when releasing the torsional strain of the tensile member. Thereby, when releasing the torsional strain of the tensile strength member, it is possible to suppress the application of the twisting force to the optical fiber.

=== First Embodiment ===
First, the configuration of the comparative example will be described, and then the configuration of the present embodiment will be described.

<Configuration of Comparative Example>
11A to 11C are explanatory diagrams of comparative examples.

  As shown in FIG. 11A, the optical code 10 of the comparative example has a plurality of optical fibers 13 and fibrous tensile strength members 15 '. The plurality of optical fibers 13 and the fibrous tension members 15 ′ are accommodated inside the jacket 21. In general, the fibrous tensile body 15 ′ is disposed inside the jacket 21 so as to wrap the outside of the plurality of optical fibers 13.

  However, when the fibrous tension member 15 'is accommodated in the jacket 21 without any restraint, the tension member 15' moves inside the jacket 21. As a result, as shown in FIG. 11B Thus, in the cross section of the optical cord 10, the tensile strength member 15 'may be biased to one side of the inner space of the jacket 21 in some cases. Furthermore, the direction of deflection of the tensile member 15 ′ may differ depending on the longitudinal position of the light cord 10. As a result, as shown in FIG. 11C, the tensile member 15 'is accommodated in the optical cord 10 in a meandering manner and accommodated therein, and the tensile member 15' having the extra length is accommodated in the optical cord 10 It will be.

  As shown in FIG. 11C, the tensile member 15 'of the optical cord 10 is to be fixed to the fixing portion 5A of the housing 5 of the connector 3 (the tensile member 15' is to be held by the housing 5 of the connector 3). ). Usually, when the connector 3 is pulled and tension is applied to the optical cord 10, the tension member 15 'resists the tension, thereby suppressing the application of tension to the optical fiber 13 of the optical cord 10. .

  However, as shown in FIG. 11C, when the tensile member 15 'is accommodated in the optical cord 10 in a meandering manner, when the optical cord 10 is tensioned, the tensile member 15' is extended by the extra length. The optical cord 10 is stretched without resisting the tension, and the optical fiber 13 inside the optical cord 10 is tensioned.

<About the configuration of the first embodiment>
FIG. 1A is a cross-sectional view of the optical code 10 of the first embodiment.

  The optical cord 10 of the present embodiment has an intermittent connection type optical fiber tape 12, a tensile strength member 15, and a jacket 21. The optical cord 10 is not limited to one used indoors, but may be used outdoors or may be called an optical cable.

  The optical fiber tape 12 here is a 12-fiber intermittent connection type optical fiber tape. In the figure, inside the circle representing the optical fiber 13, the identification number (No. 1 to 12) of the optical fiber 13 is shown. The intermittent connection type optical fiber tape 12 is composed of a plurality of optical fibers 13 in which adjacent optical fibers 13 are intermittently connected in the longitudinal direction (described later). Unlike the optical fiber tape in which a plurality of optical fibers are collectively coated, the intermittent connection type optical fiber tape 12 can round the tape width direction, and the optical fiber tape 12 can be rolled into a tubular or spiral shape. It is possible. In the present embodiment, an optical fiber is arranged such that the plurality of optical fibers 13 constituting the optical fiber tape 12 are disposed on the outer periphery of the tensile strength member 15 by utilizing such properties of the intermittent connection type optical fiber tape 12. A tape 12 is wound around the outer periphery of the tensile member 15. Here, twelve optical fibers 13 are spirally wound around the outer periphery of the tensile strength member 15 as indicated by the identification numbers (Nos. 1 to 12) of the optical fibers 13 in the figure.

  The tensile strength member 15 is a member that suppresses the application of tension to the optical fiber 13. When the optical cord 10 is tensioned, the tensile force applied to the optical fiber 13 is suppressed by the tensile member 15 receiving the tension. The tensile member 15 is a linear member extending in the longitudinal direction. As a material of the tensile body 15, non-metallic materials and metallic materials can be used. As non-metallic materials, for example, fiber reinforced plastic (FRP) such as glass FRP (GFRP), aramid fiber reinforced plastic reinforced with Kevlar (registered trademark) (KFRP), polyethylene fiber reinforced plastic with polyethylene fiber, etc. can be used is there. As the metallic material, metal wires such as steel wires can be used. As described later, it is desirable that the strength member 15 have elasticity in the twisting direction. Here, the tensile body 15 is made of a steel wire.

  The jacket 21 is a member for housing the optical fiber tape 12 and the tensile strength member 15. In other words, the jacket 21 is a member that covers the optical fiber tape 12 and the tensile strength member 15. A housing space 22 for housing the optical fiber tape 12 and the tensile strength member 15 is formed inside the jacket 21. As a material of the jacket 21, for example, a resin such as polyvinyl chloride (PVC), polyethylene (PE), nylon (registered trademark), fluorinated ethylene or polypropylene (PP) can be used.

  In the optical cord 10 of the present embodiment, since the optical fiber 13 is disposed outside the tensile strength member 15, there is a risk that the optical fiber 13 may be damaged by a blade when the outer cover 21 is torn by a blade of a tool. For this reason, it is desirable that the jacket 21 of the present embodiment is configured to be tearable by hand. Here, the jacket 21 is made of silicone resin which is easy to tear by hand.

  Further, in the present embodiment, a notch 23 is formed on the outer side of the outer covering 21 along the longitudinal direction. The notch 23 is a portion for tearing the sheath 21 by hand, and is a portion formed on the outer surface of the sheath 21 in the shape of a V groove. The notch 23 may not be formed in the outer cover 21. However, as described above, since the optical fiber 13 may be damaged by the blade when the jacket 21 is torn by the blade of the tool, the optical fiber 13 is disposed outside the tensile member 15 as in the present embodiment. In the case of the optical code 10, forming the notch 23 in the outer cover 21 is particularly effective.

  FIG. 1B is an explanatory view of the connector-equipped cord 1 of the first embodiment. The cord with connector 1 of the present embodiment has the optical cord 10 of the above configuration and the connectors 3 attached to both ends of the optical cord 10.

The connector 3 has a connection portion 4 and a housing 5.
The connection part 4 is a part connected to another connector, and is a part which inputs and outputs a signal. When the signal input / output at the connection unit 4 is an optical signal, the connection unit 4 is formed of, for example, a ferrule that holds the end of the optical fiber 13. Further, when the signal input / output at the connection unit 4 is an electric signal, the connection unit 4 is configured by a connection terminal such as a USB terminal, for example.
The housing 5 is a member that accommodates the connection portion 4. The housing 5 of the present embodiment is provided with a fixing portion 5A for fixing the tensile strength member 15 of the optical cord 10.

  In the present embodiment, as shown in FIG. 1A, since the optical fiber tape 12 is accommodated in the jacket 21 in a state of being wound around the outer periphery of the tensile member 15, the tensile member 15 of the present embodiment is a comparative example. As described above, the inner space of the outer jacket 21 is not disposed on one side, and the inner space of the outer jacket 21 is located at the center of the housing space 22. As a result, in the present embodiment, as shown in FIG. 1B, since the tensile body 15 is located at the central portion of the accommodation space 22 of the jacket 21 in the longitudinal direction, the tensile body 15 meanders inside the optical cord 10. Can be suppressed.

  Moreover, in the present embodiment, since the tensile strength member 15 is hard to meander inside the optical cord 10, the tensile strength member 15 is fixed to the housing 5 of the connector 3 in a state in which the remaining length is suppressed as compared with the comparative example. (The tensile body 15 is to be held in the housing 5 of the connector 3). As a result, when the connector 3 is pulled and tension is applied to the optical cord 10, the tensile body 15 can be subjected to the tension (because the tensile body 15 can resist the tension). It is possible to suppress the application of tension.

<About the optical fiber tape 11 with tensile strength>
2A to 2C are explanatory views of the optical fiber tape 12 and the tensile strength body 15 (optical fiber tape 11 with tensile strength body) according to the first embodiment. FIG. 2B is a cross-sectional view taken along line AA of FIG. 2A. FIG. 2C is a cross-sectional view taken along line B-B of FIG. 2A. In the following description, a member in which the optical fiber tape 12 and the tensile member 15 are connected may be referred to as the “optical fiber tape 11 with a tensile member”.
The tensile-member-attached optical fiber tape 11 may be called an "optical fiber unit".

  As described above, the optical fiber tape 12 of the present embodiment is configured as an intermittent connection type optical fiber tape. The intermittent connection type optical fiber tape 12 has a plurality of optical fibers 13 in which adjacent optical fibers 13 are intermittently connected in the longitudinal direction. Adjacent two-core optical fibers 13 are connected by a connecting portion 17. A plurality of connecting portions 17 connecting adjacent two optical fibers 13 are intermittently arranged in the longitudinal direction. Further, the plurality of connecting portions 17 of the intermittent connection type optical fiber tape 12 are intermittently arranged two-dimensionally in the longitudinal direction and the tape width direction. The connecting portion 17 is formed by applying an ultraviolet curing resin as an adhesive and then irradiating the ultraviolet curing to cure the resin. In addition, it is also possible to comprise the connection part 17 with a thermoplastic resin. A region other than the connection portion 17 between the two adjacent optical fibers 13 is a non-connection portion 19 (separation portion). In the non-coupling portion 19, adjacent two optical fibers 13 are not constrained. As a result, it becomes possible to round the intermittent connection type optical fiber tape 12 into a tubular shape (bundle shape) or to fold it.

  In the present embodiment, as shown in FIG. 2B, the optical fiber 13 and the tensile strength member 15 are connected by the connecting portion 17. As a result, since the tensile strength member 15 is restrained from the optical fiber 13 of the optical fiber tape 12, the state in which the optical fiber tape 12 is wound around the tensile strength member 15 can be stabilized. In addition, since the optical fiber 13 and the tensile strength member 15 are connected by the connecting portion 17, the position of the tensile strength member 15 inside the optical cord 10 is stabilized over the longitudinal direction, so the tensile strength member inside the optical cord 10 15 becomes more difficult to meander.

  Further, in the present embodiment, as shown in FIG. 2C, the connecting portion 17 for connecting the optical fiber 13 and the tensile strength member 15 is intermittently arranged in the longitudinal direction. In other words, in the present embodiment, the non-connecting portion 19 (separation portion) is formed between the connecting portion 17 connecting the optical fiber 13 and the tensile strength member 15 and the connecting portion 17. This makes it possible to arrange the optical fiber 13 in a spiral along the tensile member 15 by using the optical fiber tape 11 with a tensile member configured as shown in FIG. 2A as described below. (See Figure 3B).

  FIGS. 3A and 3B are other explanatory views of the optical fiber tape 12 and the tensile strength member 15 (optical fiber tape 11 with tensile strength member) of the first embodiment.

  In the present embodiment, in the state shown in FIG. 3A, a torsional force (torsion strain) is applied to the tensile strength member 15 in advance. Then, by releasing the torsional strain applied to the tensile strength body 15 in advance, the optical fiber tape 11 with tensile strength body is changed from the state (sheet shape) shown in FIG. 3A to the state (bundle shape) shown in FIG. In the state shown in FIG. 3A, a twisting force (torsion strain) is applied to the tensile strength body 15 in advance, so when making the state (sheet form) shown in FIG. 3A into the state (bundle shape) shown in FIG. Even if 15 is twisted in the longitudinal direction, in the state shown in FIG. 3B, almost no torsional strain remains in the tensile strength member 15.

  When a plurality of optical fibers 13 of the optical fiber tape 12 and the tensile strength members 15 are aligned in the width direction, the tensile strength members 15 are twisted around the longitudinal direction as shown in FIG. The No. 1 optical fiber 13 at the end portion is spirally wound along the outer circumference of the tensile member 15. When the No. 1 optical fiber 13 is disposed in a spiral along the tensile strength member 15, the No. 2 optical fiber 13 is connected to the No. 1 optical fiber 13, so It will be arranged in a spiral. At this time, since the optical fiber 13 of No. 2 is configured to have the same length as the optical fiber 13 of No. 1, the optical fiber 13 of No. 1 and the optical fiber 13 of No. 1 are not drawn. It will be spirally wound along the outer periphery of the tensile member 15 so as to keep the same length. Thus, since the other optical fiber 13 (the second to twelfth optical fibers 13) is configured to have the same length as the first optical fiber 13, the same length as the first optical fiber 13 is used. In order to keep it, it will be spirally wound as inside as possible along the outer circumference of the tensile member 15. As a result, as shown in FIG. 1A, twelve optical fibers 13 are arranged in a spiral along the outer periphery of the tensile member 15 while the optical fiber tape 12 is wound around the outer periphery of the tensile member 15 in a spiral manner. become.

  As shown in FIG. 3B, in a state in which the tensile strength member 15 is linearly arranged in the longitudinal direction, in a state in which the optical fiber 13 is spirally arranged along the outer periphery of the tensile strength member 15, the length of the optical fiber 13 is The length needs to be longer than that of the tensile body 15. Therefore, when the state shown in FIG. 3A is changed to the state shown in FIG. 3B, it is desirable that the tensile strength member 15 be compressively deformed along the longitudinal direction (see the arrow in FIG. 3A). Thus, as shown in FIG. 3A, from the state where the optical fiber 13 is connected to the tensile strength body 15 along the longitudinal direction, the optical fiber 13 is helically arranged along the outer circumference of the tensile strength body 15 as shown in FIG. It is possible to suppress the application of tension to the optical fiber 13 when shifting to the above state.

  For this reason, in the optical fiber tape 11 with a tensile-strength body of this embodiment, tension is given to the tensile-strength body 15 previously in the state shown to FIG. 3A. That is, in the present embodiment, in the state shown in FIG. 3A, the elongation strain is given to the tensile strength body 15 in advance.

  According to the first embodiment described above, as shown in FIG. 1A, the intermittent connection type is such that the plurality of optical fibers 13 constituting the intermittent connection type optical fiber tape 12 are disposed on the outer periphery of the tensile strength member 15. The optical fiber tape 12 is accommodated in the outer cover 21 in a state of being wound around the outer periphery of the tensile strength member 15. As a result, the tensile strength member 15 does not have to be biased to one side of the internal space of the jacket 21 as in the comparative example, and is positioned at the central portion of the housing space 22 of the jacket 21. As a result, according to the present embodiment, meandering of the tensile strength member 15 inside the optical cord 10 can be suppressed.

  Moreover, according to said 1st Embodiment, as shown to FIG. 3B, each optical fiber 13 of the optical fiber tape 12 is helically arrange | positioned along the tensile-strength body 15. As shown in FIG. As a result, the length of the optical fiber 13 becomes longer than that of the tensile strength member 15, and since the optical fiber 13 has an extra length than the tensile strength member 15 inside the optical cord 10, tension is applied to the optical cord 10. At the same time, the tensile member 15 is likely to be subjected to the tension, and the tension applied to the optical fiber 13 can be suppressed. Further, by arranging the plurality of optical fibers 13 in a spiral shape along the tensile strength member 15, the tensile strength member 15 is further less likely to be biased to one side of the housing space 22 of the jacket 21, and the housing space 22 of the jacket 21 It also has the advantage of being easier to locate at the center of the

<Manufacturing method 1>
FIG. 4A is an explanatory view of a tape manufacturing apparatus 30 for manufacturing the tension-member-equipped optical fiber tape 11 of the first embodiment.

  The tape manufacturing apparatus 30 is an apparatus for manufacturing the tensile-fiber-attached optical fiber tape 11 (sheet-like tensile-fiber-attached optical fiber tape 11) shown in FIG. 3A. In addition, the tape manufacturing apparatus 30 of 1st Embodiment manufactures the optical fiber tape 11 with a tensile-strength body in the state which applied tension | tensile_strength (elongation distortion) and torsional force (torsion distortion) to the tensile-strength body 15 previously. The tape manufacturing apparatus 30 has a fiber supply unit 31, a tensile strength member supply unit 32, a tape forming device 33, a take-out device 37, and a tape drum 38.

  The fiber supply unit 31 is a device (supply source) for supplying the optical fiber 13 to the tape processing device 33. In the case of manufacturing the twelve-fiber optical fiber tape 12, twelve fiber supply units 31 are required, but here, four fiber supply units 31 are provided for simplification.

  The tensile body supply unit 32 is a device for supplying the tensile body 15 to the tape forming device 33. The tensile strength body supply unit 32 has a supply source 32A and a delivery unit 32B. The supply source 32A supplies the tensile strength member 15 while rotating about the longitudinal direction of the tensile strength member 15. The rotation of the supply source 32A with respect to the delivery portion 32B applies a twisting force (torsion strain) to the tensile strength member 15. The delivery portion 32B is a device for delivering the tensile strength member 15 to the tape forming device 33 in a state where tension (elongation strain) and twisting force (torsion strain) are applied. Note that tension (elongation strain) is applied to the tensile strength member 15 between the delivery portion 32B and the take-up device 37 provided on the downstream side of the tape forming device 33.

  The tape forming device 33 is a device for forming the connection portion 17 intermittently to form the intermittent connection type optical fiber tape 12. 5A and 5B are explanatory diagrams of the tape forming device 33. FIG. The tape forming device 33 includes an application unit 34, a removal unit 35, and a light source 36.

  The application unit 34 is an apparatus for applying a connecting material. The connecting material is, for example, an ultraviolet curable resin, and the connecting part 17 is formed by curing the connecting material. The coating unit 34 applies a coupling material between the adjacent optical fibers 13. Further, the coating unit 34 of the present embodiment also coats the coupling material between the tensile strength member 15 and the optical fiber 13. The coating unit 34 is made by inserting a plurality of optical fibers 13 and the tensile strength member 15 into a coating die filled with a liquid coupling material, so that the tension between the optical fibers 13 and the tensile strength between adjacent optical fibers 13 in the longitudinal direction. A liquid connecting material is applied to the body 15. In the present embodiment, the tensile strength member 15 is inserted into the coating die in a state where tension (elongation strain) and twisting force (torsion strain) are applied. Further, in the present embodiment, the tensile strength member 15 is coated with the coupling material between the adjacent optical fibers 13 in a state in which tension (elongation strain) and twisting force (torsion strain) are applied.

  The removal unit 35 is a device that removes a part of the connection material applied by the application unit 34 while leaving a part of the connection material. The removing unit 35 has a rotary blade 351 having a recess 351A (see FIG. 5A), and rotates the rotary blade 351 in accordance with the supply speed of the optical fiber 13 and the tensile strength member 15. The connecting material applied by the application unit 34 is removed by the outer edge of the rotary blade 351, but the connecting material remains in the recess 351A of the rotary blade 351. In addition, the site | part which the connection material remained becomes the connection part 17 (refer FIG. 2A-FIG. 2C), and the site | part from which the connection material was removed becomes the non-connection part 19. FIG.

  The light source 36 is a device that irradiates the connecting material made of an ultraviolet curable resin with ultraviolet light. The light source 36 includes a temporary curing light source 36A and a main curing light source 36B. The temporary curing light source 36A is disposed upstream of the main curing light source 36B. The coupling material is temporarily cured when irradiated with ultraviolet light from the temporary curing light source 36A. Although the temporarily cured connecting material is not completely cured, curing is progressed on the surface. The main curing light source 36B irradiates ultraviolet rays stronger than the temporary curing light source 36A to perform main curing of the connecting member. The main curing UV curable resin is in a state cured to the inside (however, the main curing connecting member (connecting portion 17) has appropriate elasticity, and the intermittent connection type optical fiber tape 12 is rolled up to form a cylinder It is possible to

  As shown in FIG. 5B, the optical fiber 13 and the tensile member 15 immediately after coming out of the coating unit 34 and the removing unit 35 are spaced from each other. In this state, the temporary curing light source 36A irradiates the connecting material with ultraviolet light to temporarily cure the connecting material. The tape forming device 33 gradually narrows the distance between the optical fiber 13 and the tensile strength member 15 after temporary curing of the coupling material, aligns the plurality of optical fibers 13 and the tensile strength member 15 in parallel, and collects them in a tape shape. In addition, since the connection material is temporarily cured, even if the removed parts (separation parts) of the connection material are in contact with each other, the connection is not required. Moreover, since it is before main curing, it is possible to narrow the distance between the optical fibers 13 (condensed lines) also in the area connected by the connecting material. When the main curing light source 36B irradiates ultraviolet light and the coupling material is main curing, the tensile-fiber-attached optical fiber tape 11 shown in FIG. 2A is manufactured. In the present embodiment, the tension member 15 of the tension-member-attached optical fiber tape 11 is an optical fiber by the coupling portion 17 formed intermittently in a state where tension (elongation strain) and twisting force (torsion strain) are applied. It will be intermittently connected with 13 (optical fiber 13 at the end).

  The pick-up device 37 (see FIG. 4A) is a device that picks up the tensioned optical fiber tape 11 from the tape unit 33. As described above, tension (elongation strain) and twisting force (torsion strain) are applied to the tensile strength member 15 between the delivery portion 32B and the pulling device 37. The pulling device 37 pulls the tension member 15 in a tension (elongation strain) state from the tape forming device 33 and sends it out to the tape drum 38. Further, the pulling device 37 pulls the tensile strength member 15 in a state in which a twisting force (torsion strain) is applied from the tape forming device 33 and sends it out to the tape drum 38.

  The tape drum 38 is a member for winding the tensile strength object optical fiber tape 11. The tension-barrier optical fiber tape 11 shown in FIG. 2A is wound around the tape drum 38 of the present embodiment. That is, an optical fiber tape with a tensile strength member in a shape in which the tensile strength member 15 and the intermittent connection type optical fiber tape 12 in a state where tension (elongation strain) and torsional force (torsion strain) are applied are arranged in the tape width direction. 11 is wound around a tape drum 38. That is, the thin sheet-like tension-bearing optical fiber tape 11 as shown in FIG. 3A is wound around the tape drum 38.

  FIG. 4B is an explanatory view of a cord manufacturing device 40 for manufacturing the optical code 10 of the first embodiment.

  The cord manufacturing apparatus 40 is an apparatus for manufacturing the optical code 10 shown in FIG. 1A. In the present embodiment, the optical cord 10 housed in the jacket 21 is manufactured in a state in which the intermittently coupled optical fiber tape 12 is wound around the outer periphery of the tensile strength member 15 (see FIG. 3B). The cord manufacturing apparatus 40 has a tape supply unit 41, a take-out device 42, an extruder 43, a cooler 44, and a cord drum 45.

  The tape supply unit 41 is a device for supplying the tensile strength-attached optical fiber tape 11. The tape supply unit 41 has a tape drum 41A and a delivery unit 41B. The tape drum 41A of the tape supply unit 41 is the tape drum 38 shown in FIG. 4A, and the tape drum 41A is made of the optical fiber tape 11 with tensile material shown in FIG. 2A (sheet-like optical fiber tape with tensile material 11) is wound. The delivery unit 41B is a device for delivering the tensile strength-equipped optical fiber tape 11 shown in FIG. 2A to the downstream side. The tape supply unit 41 (the tape drum 41A and the delivery unit 41B) supplies the optical fiber tape 11 with a tensile strength member to the downstream side while rotating about the longitudinal direction of the tensile strength member 15 as an axis.

  The take-up device 42 is a device for taking out the tensile strength-equipped optical fiber tape 11 from the tape supply unit 41 and sending it out to the extruder 43. The take-up device 42 takes out the tensile-fiber-attached optical fiber tape 11 from the delivery unit 41 B and releases it to the extruder 43 so as to release the tension (elongation strain) applied to the tensile member 15. Also, when the tape supply unit 41 rotates with respect to the take-up device 42, the take-out device 42 is attached with a tensile force member from the delivery unit 41B so as to release the twisting force (torsion strain) applied to the tensile force member 15. The optical fiber tape 11 is taken up and sent to the extruder 43. As a result, the tension-carrying optical fiber tape 11 is changed from the state shown in FIG. 3A (sheet-like) to the state shown in FIG. 3B (bundle-like), and the tension-carrying optical fiber tape 11 shown in FIG. It is delivered to the extruder 43. That is, the tensile strength member-attached optical fiber tape 11 (see FIG. 3B) in which the intermittent connection type optical fiber tape 12 is wound around the tensile strength member 15 is delivered from the take-up device 42 to the extruder 43.

  The extruder 43 is an apparatus for extruding the sheath 21 of the optical cord 10. The extruder 43 is supplied with the tensioned optical fiber tape 11 (see FIG. 3B) in which the intermittent connection type optical fiber tape 12 is wound around the outer periphery of the tensile strength body 15. Since the intermittent connection type optical fiber tape 12 is wound around the outer periphery of the tensile strength member 15, the diameter of the tensile strength member-attached optical fiber tape 11 is small, the extruder 43 through which the tensile strength member-attached optical fiber tape 11 is inserted. The die hole can also be small, and the diameter of the optical cord 10 can be reduced.

  The cooler 44 is a device for cooling the sheath 21 of the optical cord 10. The cord drum 45 is a member for winding the optical cord 10. The optical cord 10 shown in FIG. 1A is wound around the cord drum 45 of the present embodiment. The manufactured optical cord 10 is shipped in a state of being wound around the cord drum 45.

<Manufacturing method 2>
FIG. 6A is an explanatory view of a tape manufacturing apparatus 30 according to a modification.

  The tape manufacturing apparatus 30 of a modification is an apparatus for manufacturing the optical fiber tape 11 with a tensile-strength body shown to FIG. 3B. That is, the tape manufacturing apparatus 30 of the modified example manufactures the tension-member-attached optical fiber tape 11 in which the intermittent connection-type optical fiber tape 12 is wound around the outer periphery of the tension member 15. The tape manufacturing apparatus 30 of the modified example has a fiber supply unit 31, a tensile strength member supply unit 32, a tape forming device 33, a take-out device 37, and a tape drum 38. The fiber supply unit 31, the tensile strength member supply unit 32, and the tape forming device 33 are the same as those described above, and thus the description thereof is omitted. Here, the pulling device 37 and the tape drum 38 will be described.

  In a modification, the pulling device 37 pulls the tensioned optical fiber tape 11 from the tape forming device 33 and releases it to the tape drum 38 so as to release the tension (elongation strain) applied to the tension member 15. Also, when the tape drum 38 rotates with respect to the take-off device 37, the take-out device 37 can release the twisting force (torsion strain) applied to the tensile force member 15 from the tape-forming device 33. The attached optical fiber tape 11 is taken up and sent out to the tape drum 38. The tape drum 38 of the modified example rotates in synchronization with the rotation of the supply source 32A of the tensile strength member supply unit 32 (rotation around the longitudinal direction of the tensile strength member 15).

  In a modification, the tension-member-attached optical fiber tape 11 (a bundle of tension-member-attached optical fiber tapes 11) shown in FIG. 3B is wound around the tape drum 38. That is, the tensioned optical fiber tape 11 in a state in which the intermittent connection type optical fiber tape 12 is wound around the outer periphery of the tensile strength body 15 is wound around the tape drum 38.

  FIG. 6B is an explanatory view of a cord manufacturing device 40 according to a modification.

  The cord manufacturing device 40 of the modified example has a tape supply unit 41, a take-out device 42, an extruder 43, a cooler 44, and a cord drum 45. The tape drum 41A of the tape supply unit 41 of the modified example is the tape drum 38 shown in FIG. 6A, and the tape drum 41A is provided with the optical fiber tape 11 with tensile strength shown in FIG. 3B (on the outer periphery of the tensile strength 15 The tensioned optical fiber tape 11) wound with the intermittent connection type optical fiber tape 12 is wound. For this reason, in the modification, the optical fiber tape 11 with a tensile strength member is drawn out from the tape drum 41A as it is and supplied to the extruder 43. The extruder 43, the cooler 44, and the cord drum 45 are the same as those described above, and thus the description thereof is omitted. Also in the above modification, the optical cord 10 shown in FIG. 1A is wound around the cord drum 45. In the modification, the configuration of the code manufacturing apparatus 40 can be simplified.

=== Second Embodiment ===
7A and 7B are explanatory diagrams of the tensile-fiber-attached optical fiber tape 11 according to the second embodiment.

  The tension-member-attached optical fiber tape 11 of the second embodiment has two intermittent connection type optical fiber tapes 12 and a tension member 15. Each optical fiber 13 located at the end of the two optical fiber tapes 12 is connected to the tensile member 15. Thus, a plurality of optical fiber tapes 12 may be connected to the tensile member 15. Even when two sheets of the intermittent connection type optical fiber tape 12 are connected to the tensile strength member 15, as shown in FIG. 7A, the tensile strength member-containing optical fiber tape 11 can be formed into a sheet.

  The two intermittent connection type optical fiber tapes 12 according to the second embodiment each have a plurality of optical fibers 13 colored in the same color scheme. Here, each of the intermittent connection type optical fiber tapes 12 has four lights colored in blue (No. 1), white (No. 2), brown (No. 3), and gray (No. 4) in the order of identification numbers. It has a fiber 13. In the drawing, the optical fiber 13 (identification number 1) colored in blue is shown in the darkest color.

  As described above, when two optical fiber tapes 12 colored in the same color combination are connected to the tensile strength member 15, the color of the optical fiber 13 connected to the tensile strength member 15 in one optical fiber tape 12. It is desirable that the color of the optical fiber 13 connected to the tensile member 15 in the other optical fiber tape 12 be different. This allows the worker to distinguish between the two optical fiber tapes 12 connected to the tensile strength member 15. For example, when the optical fiber tape 12 to which the blue optical fiber 13 is connected is "tape number 1" and the optical fiber tape 12 to which the gray optical fiber 13 is connected is "tape number 2", the worker 7A can recognize that the optical fiber tape 12 on the right side in the drawing is “tape number 1”.

  Also in the second embodiment, in the state shown in FIG. 7A, tension (elongation strain) is given to the tensile strength body 15 in advance. Further, also in the second embodiment, in the state shown in FIG. 7A, a torsional force (torsion strain) is applied to the tensile strength member 15 in advance. As a result, the tension (elongation strain) of the tensile body 15 is released, and the tensile body 15 is compressed and deformed in the longitudinal direction, and the torsional force (torsion strain) of the tensile body 15 is released, and the tensile body 15 extends in the longitudinal direction. As shown in FIG. 7B, two intermittent connection optical fiber tapes 12 are respectively wound around the outer periphery of the tensile strength member 15 as shown in FIG. It will be in the state of being arranged in a spiral.

  Also in the second embodiment, as shown in FIG. 7B, since the plurality of optical fibers 13 are disposed along the outer periphery of the tensile strength member 15, such an optical fiber tape 11 with such tensile strength members is used as a jacket of the optical cord 10. When housed in the housing 21, the tensile body 15 is located at the central portion of the housing space 22 of the sheath 21. As a result, also in the second embodiment, since it is located at the central portion of the accommodation space 22 of the outer covering 21 in the longitudinal direction, the tensioning member 15 can be prevented from meandering inside the optical cord 10.

=== Third Embodiment ===
<Strength body-attached optical fiber tape of the third embodiment>
In the embodiment described above, as shown in FIG. 3A, the optical fiber 13 in the tape processing apparatus 33 (see FIG. 4 or FIG. 6) in a state in which the torsional strain (and elongation strain) is applied to the tensile strength body 15 in advance. And the tensile strength member 15 are intermittently connected side by side in the width direction, and then the tension-resistant optical fiber tape 11 is shown in FIG. 3A by releasing the torsional strain applied to the tensile strength member 15 (sheet State (bundle shape) shown in FIG. 3B. In the embodiment described above, since no torsional strain is applied to the optical fiber 13 in the state shown in FIG. 3A, the state shown in FIG. 3A from the state (sheet-like) shown in FIG. 3A When it is made (in a bundle), a twisting force (torsion strain) is applied to the optical fiber 13. However, when it comes to the state shown in FIG. 3B, it may be desirable to reduce the twisting force applied to the optical fiber 13. In other words, it may be desirable to suppress the torsional strain of the optical fiber 13 in the state shown in FIG. 3B.

  Therefore, in the third embodiment, in the state shown in FIG. 3A (sheet-like), not only the tensile strength member 15 but also the optical fiber 13 is given a torsional strain in advance. That is, in the third embodiment, in the state shown in FIG. 3A (in the form of a sheet), a plurality of optical fibers are applied in a state in which a torsional strain is applied to the tensile strength member 15 in advance and a torsional strain is applied to the optical fiber. 13 and the tensile strength member 15 are arranged side by side in the width direction (note that, between the two adjacent optical fibers 13 or between the optical fiber 13 and the tensile strength member 15, the connection portion 17 intermittently cuts in between) Linked together). In the third embodiment, when releasing the torsional strain of the tensile strength member 15, the optical fiber tape 11 with tensile strength member is released from the state (sheet shape) shown in FIG. 3A by releasing the torsional strain of the optical fiber 13. The state (bundle shape) shown in FIG. 3B is obtained. Thereby, the twist distortion of the optical fiber 13 in the state shown to FIG. 3B can be suppressed.

  Also in the third embodiment, as shown in FIG. 3B, since the plurality of optical fibers 13 are disposed along the outer periphery of the tensile strength member 15, such an optical fiber tape 11 with such tensile strength members is used as a jacket of the optical cord 10. When housed in the housing 21, the tensile body 15 is located at the central portion of the housing space 22 of the sheath 21. As a result, also in the third embodiment, since it is located at the central portion of the housing space 22 of the outer covering 21 in the longitudinal direction, the tensioning member 15 can be prevented from meandering inside the optical code 10.

<The tape manufacturing apparatus 1 of the third embodiment>
FIG. 8 is an explanatory view of a tape manufacturing apparatus for manufacturing the tension-member-equipped optical fiber tape 11 of the third embodiment. The tape manufacturing apparatus according to the third embodiment applies the torsional strength (torsional strain) to the tensile strength member 15 in advance, and also applies the optical fiber tape 11 with the tensile strength member to which the torsional force (torsional strain) is applied to the optical fiber 13. Manufacture.

  The fiber supply unit 31 of the third embodiment has a supply source 31A and a delivery unit 31B. The supply source 31A supplies the optical fiber 13 from the drum while rotating the drum (the drum around which the optical fiber 13 is wound) around the longitudinal direction of the optical fiber 13. The rotation of the supply source 31A with respect to the delivery unit 31B imparts a twisting force (torsion strain) to the optical fiber 13. The delivery unit 31 B delivers the optical fiber 13 to the tape forming device 33 in a state in which a twisting force (torsion strain) is applied.

  The respective sources 31A of the four fiber suppliers 31 rotate in the same direction. Thereby, a twisting force (torsion strain) in the same direction is applied to each of the optical fibers 13. This makes it possible to release the torsional strain of each optical fiber 13 together. Further, the supply source 31A of the fiber supply unit 31 and the supply source 32A of the tensile strength member supply unit 32 rotate in the same direction. This makes it possible to release the torsional strain applied to the optical fiber 13 and the tensile member 15 together.

  The tape forming device 33 is supplied with the optical fiber 13 in a state of being subjected to a twisting force (torsion strain) from the fiber supply unit 31, and the tensile member 15 in a state of being given a twisting force (torsion strain) has a tensile strength. It is supplied from the body supply unit 32. The configuration of the tensile strength member supply unit 32 (the supply source 32A, the delivery unit 32B, and the like) is the same as that of the above-described embodiment. In the tape forming device 33, the connecting portions 17 are intermittently formed in the longitudinal direction between the adjacent two optical fibers 13 or between the optical fiber 13 and the tensile strength member 15. As a result, in a state in which a torsional strain is applied to the tensile member 15 and a torsional strain is applied to the optical fiber, a sheet-like tensile force in which a plurality of optical fibers 13 and the tensile member 15 are arranged side by side in the width direction. The body-mounted optical fiber tape 11 is manufactured.

  The sheet-like optical tensile member-attached optical fiber tape 11 produced by the tape forming device 33 is wound around a tape drum (not shown). At this time, the sheet-like tension-carrying optical fiber tape 11 may be wound on a drum, or the tension-carrying optical fiber tape may be formed into a bundle by releasing the torsional strain applied to the optical fiber 13 and the tensile body 15. 11 may be wound on a drum.

  By the way, in the above description, by rotating the supply source 31A of the fiber supply unit 31 (the drum around which the optical fiber 13 is wound) about the longitudinal direction of the optical fiber 13, the longitudinal direction of the optical fiber 13 is taken as the central axis. The drum shaft is pivoted to apply a torsional strain to the optical fiber 13. However, the method of applying the torsional strain to the optical fiber 13 is not limited to this. For example, as shown in FIG. 9, the drum shaft of the drum around which the optical fiber 13 is wound is made orthogonal to the rotation axis, and the drum axis is rotated about the rotation axis to apply a torsional strain to the optical fiber 13 It is good. Also in the drum of the tension member supply unit 32 (the drum around which the tension member 22 is wound: see FIG. 4A) and the drum 38 for tape (see FIG. 4B, FIG. 6A), Instead of turning, the drum shaft may be rotated about a rotation axis orthogonal to the drum shaft. Further, as described below, the method of applying a torsional strain to the optical fiber 13 is not limited to the method of rotating a drum around which the optical fiber 13 is wound.

<The tape manufacturing apparatus 2 of the third embodiment>
FIG. 10 is an explanatory view of another tape manufacturing apparatus according to the third embodiment. Here, a torsional strain is applied to the optical fiber 13 in the spinning process (drawing process).

  The fiber supply unit 31 includes a preform 311, a heating furnace 312, a coating device 313, a curing device 314, and a plurality of guide rollers 315 (315A to 315D). The preform 311 is a base material (glass rod) of the optical fiber 13. The heating furnace 312 is a furnace for heating the preform 311 in order to melt and stretch the preform 311, and is, for example, an electric furnace. The coating device 313 is a device for coating a resin on the optical fiber immediately after spinning. The optical fiber is cooled between the heating furnace 312 and the coating device 313. The curing device 314 is a device for curing the resin coated by the coating device 313, and is, for example, an ultraviolet radiation device. The guide roller 315 is a roller that constitutes an optical fiber path.

  The first guide roller 315 </ b> A disposed on the most upstream side of the plurality of guide rollers 315 is a member with which the optical fiber spun from the preform 311 first contacts. In the dotted line frame of FIG. 10, an explanatory view of the vicinity of the first guide roller 315A is shown. The first guide roller 315A is arranged such that the rotation axis is inclined with respect to the path of the optical fiber 13. Thereby, a twisting force (torque) is applied to the optical fiber 13 at the first guide roller 315A. That is, the first guide roller 315A serves as a torque applying member that applies a twisting force (torque) to the optical fiber 13.

  Since there is nothing upstream of the first guide roller 315A that contacts the spun optical fiber, when the first guide roller 315A applies a twisting force to the optical fiber 13, the fiber immediately after being spun from the preform 311 The optical fiber (optical fiber between the preform 311 and the first guide roller 315A) is in a twisted state. In other words, the optical fiber 13 is manufactured through the coating process (coating apparatus 313) and the curing process (curing apparatus 314) in a twisted state. Torsional strain remains in the optical fiber 13 manufactured in this manner.

  Note that the method for applying a torsional strain to the optical fiber 13 in the spinning step (drawing step) is not limited to the method shown in FIG. For example, instead of applying a torque to the optical fiber 13 by the first guide roller 315A, the twist distortion of the optical fiber 13 in the spinning process (drawing process) is performed by rotating the preform 311 about the longitudinal direction of the optical fiber 13 as an axis. May be given.

  Thus, the optical fiber 13 to which the torsional strain is applied is supplied from the fiber supply unit 31 to the tape processing device 33. And while the optical fiber 13 in the state to which the twisting force (torsion distortion) was given is supplied from the fiber supply part 31 to the tape-forming apparatus 33, the tension member 15 in the state to which the twisting force (torsion strain) is given. Is supplied from the tensile strength body supply unit 32. In the tape forming device 33, the connecting portions 17 are intermittently formed in the longitudinal direction between the adjacent two optical fibers 13 or between the optical fiber 13 and the tensile strength member 15. As a result, in a state in which a torsional strain is applied to the tensile member 15 and a torsional strain is applied to the optical fiber, a sheet-like tensile force in which a plurality of optical fibers 13 and the tensile member 15 are arranged side by side in the width direction. The body-mounted optical fiber tape 11 is manufactured.

=== Others ===
The above embodiments are for the purpose of facilitating the understanding of the present invention, and are not for the purpose of limiting the present invention. It goes without saying that the present invention can be modified and improved without departing from the gist thereof, and that the present invention includes equivalents thereof.

1 connector cord, 3 connector,
4 connection parts, 5 housings, 5A fixing parts,
10 optical cords, 11 tensile strength optical fiber tapes,
12 optical fiber tapes, 13 optical fibers,
15 tensile body, 15 'fibrous tensile body,
17 connected parts, 19 non connected parts,
21 casing, 22 accommodation space, 23 notches,
30 tape manufacturing equipment, 31 fiber supply,
31A source, 31B delivery unit,
311 preform, 312 heating furnace,
313 coating equipment, 314 curing equipment,
315 (315A-315D) Guide roller,
315A first guide roller,
32 tensile body supply unit, 32A supply source, 32B delivery unit,
33 Tapeing device, 34 coating units, 35 removing units,
351 rotary blade, 351A recess,
36 light source, 36A temporary curing light source, 36B main curing light source,
37 pick-up device, drum for 38 tapes,
40 cord manufacturing equipment, 41 tape supply units,
Drum for 41A tape, 41B delivery unit,
42 take-up device, 43 extruder,
44 chillers, drums for 45 cords

Claims (11)

An intermittent connection type optical fiber tape having a plurality of optical fibers in which adjacent optical fibers are intermittently connected in the longitudinal direction;
A tensile body,
And a jacket for housing the optical fiber tape and the tensile member.
The optical fiber and the tensile member are intermittently connected in the longitudinal direction,
The optical fiber tape and the tensile body in a state where the plurality of optical fibers constituting the optical fiber tape are arranged in a spiral along the tensile body, and the optical fiber tape is wound around the outer periphery of the tensile body. Is accommodated in the jacket. The optical code according to claim 1, wherein
A light code characterized in that a notch is formed along the longitudinal direction in the jacket. An optical code according to claim 1 or 2,
The optical code comprises two pieces of the optical fiber tape,
An optical cord characterized in that the tensile member is connected to the respective optical fibers located at the ends of the two optical fiber tapes. The optical code according to claim 3, wherein
Each of the two optical fiber tapes has a plurality of optical fibers colored in the same color scheme,
The color of the optical fiber connected to the tensile member in one of the optical fiber tapes is different from the color of the optical fiber connected to the tensile member in the other optical fiber tape. Light code. An intermittent connection type optical fiber tape having a plurality of optical fibers in which adjacent optical fibers are intermittently connected in the longitudinal direction;
A tensile body,
Equipped with
The optical fiber and the tensile member are intermittently connected in the longitudinal direction,
A tensile body characterized in that the optical fiber tape is wound around the outer periphery of the tensile strength body in a state where the plurality of optical fibers constituting the optical fiber tape are arranged in a spiral along the tensile strength body. Optical fiber tape. An intermittent connection type optical fiber tape having a plurality of optical fibers in which adjacent optical fibers are intermittently connected in the longitudinal direction;
A tensile body,
Equipped with
The optical fiber and the tensile member are intermittently connected in the longitudinal direction,
A plurality of the optical fibers constituting the optical fiber tape and the tensile body are arranged side by side in the width direction in a state in which a torsional strain is applied to the tensile body. Fiber optic tape. The tensile-fiber-containing optical fiber tape according to claim 6, wherein
The plurality of optical fibers constituting the optical fiber tape and the tensile body are arranged in the width direction in a state in which the torsional strain is applied to the tensile body and the extension strain is applied to the tensile body. An optical fiber tape with a tensile member, characterized in that it is disposed at. A tensile-fiber-attached optical fiber tape according to claim 6 or 7,
The plurality of optical fibers constituting the optical fiber tape and the tensile body are arranged in the width direction in a state in which the torsional strain is applied to the tensile body and the torsional strain is applied to the optical fiber. An optical fiber tape with a tensile member, characterized in that it is disposed at. Supplying a plurality of optical fibers to the tape processing device;
Supplying a torsionally strained tensile body to the tape forming device;
In the tape forming apparatus, while the adjacent optical fibers are intermittently connected in the longitudinal direction, the optical fiber and the tensile strength member are intermittently connected in the longitudinal direction;
A tensile body in which the optical fiber tape is wound around the outer periphery of the tensile strength body in a state where the plurality of optical fibers constituting the optical fiber tape are disposed in a spiral along the tensile strength body by releasing the torsional strain. A method of producing a tensile-fiber-attached optical fiber tape, comprising producing an optical fiber tape. 10. A method of manufacturing a tensile strength-attached optical fiber tape according to claim 9.
When the tensile body is supplied to the tape forming apparatus, the torsional strain is applied to the tensile body, and an elongation strain is applied to the tensile body,
A method of manufacturing a tensile-fiber-containing optical fiber tape, characterized in that the elongation strain is released when the torsion strain is released. A method of manufacturing a tensile-fiber-attached optical fiber tape according to claim 9 or 10, wherein
Applying a torsional strain to the optical fibers when supplying the plurality of optical fibers to the tape forming device;
A method of manufacturing an optical fiber tape with a tensile member characterized in that the torsional strain of the optical fiber is released when the torsional strain of the tensile member is released.

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