JP4121526B2 - Optical cable with branch - Google Patents

Description

  The present invention relates to an optical cable with a branching section, and more specifically, with a branching section that has a branching section in a part of the length direction of the optical cable and can connect the fiber core of the branching optical cable to the optical fiber core drawn from the branching section. Related to optical cable.

  For example, in a high-rise building, an optical prefabricated cable described in the specification of Patent Document 1 is known as an optical communication trunk cable that runs through an EPS that houses a power supply line. The optical prefabricated cable is provided with a branching portion for branching the optical fiber core wire in the cable for each section (each floor) where branching is planned in advance. In the optical prefabricated cable, after laying, the fiber core wire of the branch optical cable wired to each floor is connected to the optical fiber core wire drawn out at each branch portion. In this way, with optical prefabricated cables, it is only necessary to perform connection work at the branching section after laying, and the workability of branching connection is improved, so that complicated optical lines such as laying optical lines on each floor of high-rise buildings It is widely used for laying.

A specific method for connecting the optical fiber cores at each branch will be described. That is, after laying the optical prefabricated cable, the optical fiber core wire is pulled out from the branching portion while securing a predetermined extra length. Next, an optical connector is attached to the tip of the optical fiber core, and an optical connector adapter to which the optical connector is connected is fixed to a building pillar (fixed structure). The optical connector adapter is connected to an optical connector of a fiber core drawn from the branch optical cable. Accordingly, the fiber core wire on the branch optical cable side is connected to the target optical fiber core on the optical prefab cable side by a connector. Then, after the extra length of the optical fiber core is processed, the optical connector is covered with a protective cover and taped. The above work is performed on site by the worker.
JP 2000-258672 A

  However, in the optical cable with a branching part of Patent Document 1, as described above, an operator brings a large number of parts to the work site on each floor, and the fiber core of the branching optical cable is connected to the optical fiber core drawn from the branching part. I was connected. After that, it was necessary to perform extra length processing of the optical fiber core, storage of the optical connector and the optical connector adapter by the protective cover, and tape fastening of the protective cover. In addition, the work space on each floor is narrow, making it difficult to work.

SUMMARY OF THE INVENTION Accordingly, an object of the present invention is to provide an optical cable branching portion structure that can improve the workability of connection between optical fiber cores at a branching portion and that can efficiently perform the connection work even in a narrow work space. To do.
Moreover, this invention aims at providing the optical cable with a branch part which can improve workability | operativity at the time of penetrating an optical cable in a building.
Another object of the present invention is to provide an optical cable with a branching portion that can prevent damage to a connector connection portion and damage to a fiber core of an optical cable when laying a cable.
And this invention aims at providing the optical cable with a branch part which can process the extra length part of the optical fiber core line pulled out from the optical cable.

According to the first aspect of the present invention, a branching portion capable of connecting the fiber core of the branch optical cable to a predetermined portion in the length direction of the optical cable vertically running through the building with respect to the optical fiber core branched from the optical cable. However , in the optical cable with a branch part provided in the factory in advance , the branch part is provided in the optical cable, and is installed in a casing of a rectangular box body that is long in the length direction of the optical cable , and in a lower end part of the casing. A connector connecting portion capable of connecting one end of the optical fiber core wire and one end of the fiber core wire of the branch optical cable via an optical connector, and the casing has a tapered portion at an upper end portion of the casing. while being formed, the casing in the longitudinal direction of the intermediate portion to the tapered portion is inclined portion cross-sectional area gradually downward continuously increases formation branch portion with light Ke It is a bull.

According to the first aspect of the present invention, since the optical connector and the optical adapter on the optical cable side are fixed at fixed positions on the casing in the connector connecting portion, the optical connector at the tip of the branched optical cable is connected to the optical adapter on the optical cable side. By doing so, both optical fiber cores can be easily optically connected. In addition, even in a narrow work space, this connection work can be performed efficiently.
In addition, since the tapered portion is formed at the upper end portion of the casing, when the optical cable is suspended in a longitudinal manner in, for example, an EPS of a building (a high-rise building or the like), this suspension operation is performed with the tapered side of the casing facing upward. As a result, the optical cable can be smoothly pulled up while passing through obstacles in the EPS.
The taper of the casing may be performed gradually (slowly) or stepwise so as not to cause a step.

As the type of optical cable, for example, a tape slot type optical cable, a cord assembly type optical cable, an optical prefabricated cable in which optical cable single wires are assembled, and the like can be adopted.
As a kind of branching optical cable, for example, an optical cord cable, an optical drop cable, an optical indoor cable, or the like can be employed.
The type and number of optical fiber cores installed in the optical cable are not limited. For example, a single core wire, a 2-core tape core wire, a 4-core tape core wire, an 8-core tape core wire, etc. are employable.
The number of branch portions in the optical cable is not limited. Further, when there are a plurality of branch portions in the optical cable, the distance between the branch portions of the optical cable may be uniform (constant pitch) or non-uniform.

As the casing material, various synthetic resins, various metals, and the like can be used.
The shape and size of the casing are not limited.
The casing may be integrally formed with the optical cable in an inseparable state, or may be provided detachably with respect to the optical cable.

The connector connecting portion includes, for example, an optical connector provided at one end of the optical fiber core, and an optical connector adapter that is fixed to the casing and that is hooked to the one end. A branch optical connector provided at one end of the branch optical cable is hooked to the other end of the optical connector adapter.
The number of optical connectors and optical connector adapters installed is changed according to the number of optical fiber cores built in the optical cable and the number of cores desired to be output at the branching section.

Movement of the optical cable during cable laying (eg hanging cable into EPS) is the moving direction of the optical cable (traveling direction), it shall be made towards tapered side of the casing (the upper end portion side).

  The casing may be provided with an extra length storage portion for storing the extra length portion of the optical fiber core wire drawn from the optical cable in a curved state.
  In this way, by storing the optical fiber core drawn from the optical cable in a curved state in advance in the extra length storage portion, the optical fiber core can be connected at the time of connector connection with the fiber core of the branch optical cable in the field. It is not necessary to perform a bending process again, and the workability of connector connection can be improved.
  In the bending process of the optical fiber core wire, the work space to be secured around the connection site is large compared to other work. For example, if the extra length of the optical fiber is long, a larger working space is required to bend it. However, according to the present invention, since such a bending process work is not required, connector connection between optical fiber cores can be performed even if the work space is narrow.

  The extra length of the optical fiber core drawn from the optical cable refers to the position of the optical fiber core drawn from the optical cable and the optical fiber core of the connector connecting portion. This is the remaining part that is unnecessary for this connection when the connected positions are connected at the extreme end distance.
  The shape of the extra length storage part is, for example, a disk container shape, an elliptic container shape, a cubic container shape, a rectangular container shape, or the like.
  The size (internal volume) of the extra length storage part is not limited.

According to a second aspect of the present invention, a protective cover that covers at least the upper end portion of the connector connecting portion is detachably provided at the lower end portion of the casing, and the end plate of the lower end portion of the protective cover includes the The optical cable with a branching portion according to claim 1 , wherein an insertion port for a fiber core wire of the branching optical cable is formed .

According to the second aspect of the present invention, when the optical cable is suspended in, for example, an EPS of a building, a branch portion formed in a bulging state at an intermediate portion of the optical cable collides with an inner wall of the EPS or an obstacle in the EPS. There is a case. However, since the connector connecting portion is covered with the protective cover, damage to the connector connecting portion caused by this collision can be prevented. Further, by covering the connector connecting portion with the protective cover in this way, it is possible to prevent dust from adhering to the connector connecting portion. When inserting (connecting) the branch optical connector, it can be easily inserted by removing the protective cover.
Moreover, fiber of the branch optical cables is connected to the connector connecting portion through an insertion port formed in the end plate of the lower end portion of the protective cover. Therefore, for example, when an earthquake occurs after laying the cable, the optical cable is shaken in the EPS, and the fiber core of the branch optical cable is between the branch part and the inner wall of the EPS, or the obstacle in the branch part and the EPS. The risk of being caught between the two is reduced. Therefore, it is possible to suppress the frequency of occurrence of damage (including disconnection) of the fiber core wire of the branch optical cable due to such a situation.

Connector coupler here is a provided under end of the casing, for example during cable laying, when the moving direction of the optical cable toward the tapered side of the casing to move the optical cable, the side opposite to the moving direction of the casing The connector connecting portion is provided in the casing so that the connector connecting portion is disposed at the end of the casing.
As a material for the protective cover, for example, various synthetic resins and various metals can be employed.
Detachable structure of the protective cover to the lower end of the casing is not limited. For example, a bolt and nut fastening structure, a screw fastening structure, a screwing structure, for example, a male-female fitting structure including a planar fastener locking structure, and the like can be employed.
The shape and size of the protective cover are not limited as long as the connector connecting portion can be covered from the outside. For example, the shape of the protective cover may be a cylindrical shape or a bowl shape.

Covering the connector connecting portion with at least the upper end portion of the protective cover may cover only the one end portion of the protective cover or only the region from one end portion to the central portion of the protective cover. Furthermore, you may cover a connector connection part over the full length of a protective cover.
The shape and size of the fiber core wire insertion port of the branch optical cable are not limited as long as the fiber core wires (branch optical connectors) of the corresponding number of branch optical cables can be taken in and out.

According to the first aspect of the present invention, as the optical cable branching portion, the casing having the connector connecting portion is adopted, so the optical connector at the tip of the fiber core of the branched optical cable is connected to the optical adapter on the optical cable side. By doing so, both optical fiber cores can be easily optically connected. In addition, even in a narrow work space, this connection work can be performed efficiently.
In addition, a tapered portion is formed at the upper end portion of the casing, and an inclined portion with a gradually increasing cross-sectional area is formed in the middle portion in the longitudinal direction of the casing, so that an optical cable can be passed through the building. When doing so, the optical cable can be suspended in the building while passing through the obstacles. As a result, the workability at the time of laying the optical cable can be further enhanced.

According to the second aspect of the present invention, since the connector connecting portion is covered with the protective cover, the inner wall of the cable laying passage in the building and the optical cable are in contact with each other when the cable is laid. Can prevent damage to the connector connecting portion.
And, since there is provided the insertion opening of the fiber of the branched optical cable to an end plate of the lower end portion of the protective cover, while fiber of the branch optical cables and the inner wall of the bifurcation and EPS for some reason, or bifurcation And the obstacle between the EPS and the like can be reduced, and the frequency of damage to the fiber core of the branch optical cable can be suppressed.

  Examples of the present invention will be specifically described below. Here, an optical prefabricated cable installed in a suspended manner in an EPS of an office building is taken as an example.

  1 and 2, reference numeral 10 denotes an optical cable with a branching part according to Embodiment 1 of the present invention. The optical cable with a branching part 10 has four cores branched from the optical cable 11 at a predetermined portion in the length direction of the optical cable 11. Each of the single fiber cores (optical fiber cores) 12a constituting the tape core wire 12 is provided with a branch portion 14 to which one optical cord (fiber core wire) 13 of the branch optical cable can be connected. It is.

Hereinafter, the components of the optical cable 10 with a branch part will be described in detail.
The optical cable 10 with a branching part is connected to the optical MDF 15 installed on the ground, while the substantially half of the front side is suspended from the EPS 16 of the high-rise office building via the hanging part 17. This is an optical communication trunk cable.
The optical cable 10 with a branch part has a main body of a slot rod 19 in which five strips 18 are arranged on the outer peripheral surface (FIG. 2). In each groove 18, five layers of four-core tape core wires 12 are stored. The 4-core tape core wire 12 is obtained by integrating four fiber single core wires 12a with a tape material. On the outer periphery of the slot rod 19, a press-winding layer 20 and a covering layer 21 are sequentially formed. A tension member 22 is provided at the center of the slot rod 19.

Hereinafter, the branching unit 14 will be described in detail with reference to FIGS. 1 and 3 to 6.
As shown in FIG. 1, the branching unit 14 is provided for each section (each floor) where branching is planned in the factory in advance in the optical cable 10 with branching unit.
That is, as shown in FIGS. 3 to 5, the branch portion 14 is provided in the optical cable 11 and is a box body that is long in the length direction of the optical cable 11, and one end portion in the length direction is tapered. And one end of the four optical fiber cores 12a and one end of the corresponding four optical cords 13 can be connected via the optical connector 24 and the branch optical connector 24A. And a connector connecting portion 25.

The casing 23 includes a base body 26 having a substantially rectangular dish shape when viewed from the front, and a lid body 27 having a substantially rectangular dish shape when viewed from the front, with the outer peripheral edges of the base body 26 being matched with each other. And a protective cover 28 that is detachably coupled to the base body 26 and the lid body 27 and covers the connector connecting portion 25 at one end.
The base body 26 is slightly longer than the lid body 27, and is inserted into the base body 26 via fitting protrusions 26 a that protrude from both side plates of the base body 26 and end plates on one end side in the length direction of the base body 26. When the body 26 is matched with the lid body 27, the other end of the base body 26 is configured to protrude slightly outward from that of the lid body 27 (FIG. 5). In addition, a fitting groove 27a corresponding to the fitting protrusion 26a is formed inside each edge on both side plates of the lid body 27 and an end plate on one end side in the length direction of the base body 26. Yes.
An insertion hole 23 a for the optical cable 11 is formed between the end plates on one end side in the length direction of the base body 26 and the lid body 27. On the other hand, there are no end plates at the other ends in the length direction of the base body 26 and the lid body 27, and the base body 26 and the lid body 27 are in an open state. The base body 26 and the lid body 27 can be attached to and detached from the casing 23 by screwing so as to be able to cope with troubles.

  Further, on both side plates of the base body 26, short fitting grooves 26b extending in the thickness direction of the base body 26 are formed inside the other end portions in the length direction. In both fitting grooves 26b, a sheath fixing member 29 having a T-shape in a side view and fixing a part of the optical cable 11 is detachably fitted. A rectangular plate-shaped adapter fixing member 31 for fixing the optical connector adapter 30 is detachably connected to the sheath fixing member 29 (FIG. 6). The adapter fixing member 31 has four adapter fixing holes 31a. The corresponding optical connector adapter 30 is fixed to each adapter fixing hole 31a. In addition, corresponding ones of the optical connectors 24 arranged at the ends of the four fiber single-core wires 12a are connected to the inner portions of the casings of the optical connector adapters 30, respectively. The connector connecting portion 25 is composed of these four pairs of optical connectors 24 and an optical connector adapter 30.

The optical connector 24 on the optical cable side is connected to one end portion of each optical connector adapter 30 disposed in the internal space of the lid 27. On the other hand, a branch optical connector 24A on the optical cord 13 side is connected to the other end portion of each optical connector adapter 30 disposed in the internal space of the protective cover 28.
A guide groove 27b of the adapter fixing member 31 is formed in the vicinity of the other end of the lid 27 in the length direction (FIG. 5). A mounting guide 27c of the protective cover 28 having a U-shape when viewed from the bottom is projected from the entire area of the other end of the lid 27 in the length direction.

In the base body 26, a part of the slot rod 19 exposed by peeling off the holding winding layer 20 and the covering layer 21 in advance at the factory is disposed inside the one end portion in the length direction with respect to the base body 26. In addition, a slot gripping portion 32 is provided for securing the head firmly. Thereby, the exposed part of the slot rod 19 is always arranged in the internal space of the casing 23.
Further, the base body 26 and the lid body 27 are formed so that one end portions in the length direction thereof are gradually narrowed in front view. Moreover, the lid 27 is also formed so that the thickness of one end portion in the lengthwise direction is tapered (thinned). That is, the lid 27 is configured to be gradually thinned from the other end portion in the length direction to the middle portion, and thereafter, the thickness is maintained from the middle portion to the tip portion in the length direction.

  On the lid side of the inner space of the casing 23, an extra length storage portion 33 is provided for storing the extra length portions 12b of the four fiber single core wires 12a drawn from the optical cable 11 in a curved state. The surplus length storage portion 33 has an elliptical shape that is long in the length direction of the casing 23 when viewed from the front. In this surplus length storage section 33, the surplus length portion 12b of the four fiber single core wires 12a drawn out from the optical cable 11 is stored with a bend radius (R15 or more) exceeding a specified value that does not endure the optical characteristics. Has been. An optical connector in which another fiber single fiber is connected to the optical connector in advance can also be used. In this case, what is accommodated in the surplus length accommodating portion 33 is not only the surplus length portion 12b of the fiber single core wire 12a drawn from the optical cable 11, but also the other fiber spliced to the fiber single core wire 12a. Also includes single fiber.

The protective cover 28 is a short bowl-shaped member, and the other end in the length direction of the lid 27 and the base body via the mounting groove 28c at one end in the length direction and the mounting guide 27c. It is latched by the other end part of the length direction of 26, respectively. The protective cover 28 and the base body 26 are connected to each other by a pair of fitting grooves formed in a half region on one end side in the length direction of the protective cover 28 in the edge portions of both side plates of the protective cover 28. 28 b and a part of the fitting protrusion 26 a on both side plates of the base body 26 are fitted together.
The other end portion in the length direction of the protective cover 28 is gradually tapered toward the other end. An insertion port 28a through which the four optical cords 13 can be taken in and out is formed in the end plate at the other end of the protective cover 28 in the length direction.

Next, the usage method of the optical cable 10 with a branch part which concerns on Example 1 of this invention is demonstrated.
As shown in FIG. 1, the branching optical cable 10 is connected to the optical MDF 15 with the base part thereof being connected to the EPS 16 of the high-rise office building with the hanging part 17. It is hung through. In the optical cable 10 with a branching section, a branching section 14 is provided for each section (each floor) where branching is planned in advance in a factory. Therefore, each branch part 14 will be arrange | positioned on a corresponding floor.

  Next, as shown in FIG. 3 and FIG. 4, the optical connector 24 at the tip of each of the four fiber single-core wires 12 a arranged in the branching section 14 is connected to the other end of the corresponding optical connector adapter 30. Connect each one. At this time, in the connector connecting portion 25, a total of four optical connector adapters 30 in which the optical connectors 24 of the corresponding fiber single-core wires 12 a are respectively connected to one end portions are fixed at fixed positions on the casing 23. Therefore, by simply connecting the branch optical connector 24A provided at one end of each optical cord 13 to the other end of the corresponding optical connector adapter 30, the corresponding fiber single-core wire 12a and the optical cord 13 can be easily optically connected. Can be connected. In addition, even in a narrow work space, this connection work can be performed efficiently.

  And since the one end part of the length direction of the casing 23 was made into the taper shape, when suspending the optical cable 10 with a branch part in the said EPS16 in the vertical penetration state, this taper side of the casing 23 is turned upwards, and this suspending operation | work is performed. . As a result, it is possible to smoothly pull up the optical cable 10 with a branching part while passing through an obstacle in the EPS 16 (for example, a slab penetrating part or another installed cable).

Furthermore, when the optical cable 10 with a branch part is suspended from the EPS 16, the branch part 14 formed in a bulged state in the middle part of the optical cable 11 may collide with an inner wall of the EPS 16 or an obstacle in the EPS 16. However, since the connector connecting portion 25 is covered with the protective cover 28, the connector connecting portion 25 can be prevented from being damaged due to this collision. Further, by covering the connector connecting portion 25 with the protective cover 28 in this way, it is possible to prevent dust from adhering to the connector connecting portion 25.
The optical cord 13 is connected to the connector connecting portion 25 through an insertion port 28a formed in the end plate at the other end of the protective cover 28. Therefore, for example, when an earthquake occurs after the cable is laid, the optical cable 10 with a branching portion in the EPS 16 is shaken, and the optical cord 13 is between the branching portion 14 and the inner wall of the EPS 16 or between the branching portion 14 and the EPS 16. The possibility of getting caught between obstacles is reduced. Therefore, the occurrence frequency of damage (including disconnection) of the optical cord 13 caused by such a situation can be suppressed.

Furthermore, since the fiber single-core wire 12a pulled out from the optical cable 11 is stored in the extra length storage portion 33 in a curved state in advance, each fiber single-core wire 12a is re-applied when the connector is connected to the optical cord 13 in the field. It is not necessary to perform a bending process, and the workability of connector connection can be improved.
In the bending process of the fiber single-core wire 12a, the work space to be secured around the connection site is large compared to other work. For example, if the extra length portion 12b of the fiber single-core wire 12a is long, a larger working space is required to bend the fiber. However, in the first embodiment, such a bending process work is not necessary, so that the corresponding fiber single-core wire 12a and the optical cord 13 can be connected to each other even if the work space is narrow.

It is a perspective view which shows the construction state of the optical cable with a branch part which concerns on Example 1 of this invention. It is an expanded sectional view orthogonal to the length direction of the optical cable incorporated in the optical cable with a branch part which concerns on Example 1 of this invention. It is an enlarged front view of the branch part of the optical cable with a branch part which concerns on Example 1 of this invention. It is an enlarged side view of the branch part of the optical cable with a branch part which concerns on Example 1 of this invention. It is an expansion disassembled side view of the casing integrated in the optical cable with a branch part which concerns on Example 1 of this invention. It is an expanded bottom view of the use condition of the casing integrated in the optical cable with a branch part which concerns on Example 1 of this invention.

Explanation of symbols

10 Optical cable with branch,
11 Optical cable,
12a Fiber single core (optical fiber core),
12b extra length part,
13 Optical cord (fiber core),
14 branching section,
23 casing,
24 optical connectors,
25 Connector connection,
28 protective cover,
28a insertion slot,
30 optical connector adapter,
33 Extra length storage.

Claims (2)

A branching section that can connect the fiber core of the branch optical cable to the optical fiber core branched from the optical cable is provided in the factory in advance in a predetermined portion of the length of the optical cable that runs through the building . In an optical cable with a branching section,
The branch portion is
A rectangular box casing provided in the optical cable and long in the length direction of the optical cable ;
A connector connecting portion provided in a lower end portion of the casing and capable of connecting one end of the optical fiber core and one end of the fiber core of the branch optical cable via an optical connector;
In the casing , a tapered portion is formed at the upper end portion of the casing , and an inclined portion having a gradually increasing cross-sectional area is formed continuously downward from the tapered portion at an intermediate portion in the longitudinal direction of the casing. branch unit with an optical cable. A protective cover that covers at least the upper end portion of the connector connecting portion is detachably provided at the lower end portion of the casing,
The end plate of the lower end portion of the protective cover, the branch portion with an optical cable according to claim 1, fiber insertion opening is formed in the branch optical cable.

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