JP2012063407A - Optical fiber reconnecting method of optical fiber cable - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an optical fiber reconnecting method of an optical fiber cable capable of connecting cut optical fibers each other and effectively using that, when connection with an optical fiber drop cable becomes unnecessary even if using a small-sized closure.SOLUTION: A sheath 13 of an optical fiber cable 6 near the outside of a closure 7 is partially peeled off, and an optical fiber 8 having the other end 8B is pulled out from the closure 7 to the outside. After connecting a reconnecting optical fiber 24 to the other end 8B of the optical fiber 8 pulled out to the outside of the closure 7, the reconnecting optical fiber 24 is returned into the closure 7 through an optical fiber returning groove 21 formed on a slot core 18 or the sheath 13, and connected to one end 8A of the optical fiber 8 cut in the closure 7.

Description

  In the present invention, when a predetermined optical fiber is taken out from an optical fiber cable in a closure and connected to the optical fiber drop cable, and the connection to the optical fiber drop cable becomes unnecessary, the light to reconnect the cut optical fiber The present invention relates to an optical fiber reconnection method of a fiber cable.

  In recent years, it has become common for optical fibers to be able to transmit and receive large amounts of data to the home. To draw an optical fiber into each home, peel off the optical fiber cable sheath in the closure (junction box), take out the specified optical fiber from the slot core, cut the optical fiber, and attach an optical fiber drop cable to one end. The optical fiber drop cable is connected to each household. By performing this work, FTTH (Fiber To The Home) service is provided.

  By the way, when an optical fiber subscriber cancels a contract with a communication company and the branch wiring (optical fiber drop cable) becomes unnecessary, the work of disconnecting the optical fiber drop cable and reconnecting the cut optical fiber (this The operation is referred to as a lowering operation) (described in, for example, Patent Document 1).

  In Patent Document 1, the length of the closure is increased to 80 cm or more in order to effectively use the optical fiber left after being cut in the closure (the optical fiber remaining without being connected to the optical fiber drop cable). As a result, a working length for reconnecting the remaining optical fiber is secured, and the sheath removed by lengthening the closure and the extra length of the optical fiber can be stored inside.

Japanese Patent Laid-Open No. 2003-21728

  However, in recent years, the size of articles has been reduced for the economical construction of networks, and it has become difficult to secure in advance an optical fiber that can be extended downward. The optical fiber branched in the middle of a small closure is lengthened in order to be connected to the optical fiber drop cable, so the other is inevitably shortened. For this reason, the end of one optical fiber cannot be connected to the end of the short optical fiber, and the cut optical fiber is left as it is.

  Therefore, the present invention provides an optical fiber cable that can be used effectively by connecting the cut optical fibers because the connection with the optical fiber drop cable is unnecessary even when a small closure is used. An object is to provide a connection method.

  According to the first aspect of the present invention, the sheath is peeled off from the optical fiber cable provided in the closure for a predetermined length, and a predetermined optical fiber out of a plurality of fibers stored in the slot groove of the slot core is taken out and cut. Then, after one end of the cut optical fiber is connected to the optical fiber drop cable, when the connection with the optical fiber drop cable becomes unnecessary, the one end of the optical fiber is connected to the other end of the cut optical fiber again. In the optical fiber reconnecting method of the optical fiber cable, a part of the sheath of the optical fiber cable near the outside of the closure is peeled off, and the optical fiber having the cut other end is pulled out from the closure and pulled out of the closure. After connecting the reconnecting optical fiber to the other end of the optical fiber, the reconnecting optical fiber is connected again to the slot. Back through the grooves return optical fiber formed in the core or sheath into the closure, it is characterized by connecting the re-connecting optical fibers to one end of the optical fiber is cleaved in the closure.

  According to the second aspect of the present invention, the sheath is peeled off from the optical fiber cable provided in the closure for a predetermined length, and a predetermined optical fiber out of a plurality of fibers stored in the slot groove of the slot core is taken out and cut. Then, after one end of the cut optical fiber is connected to the optical fiber drop cable, when the connection with the optical fiber drop cable becomes unnecessary, the one end of the optical fiber is connected to the other end of the cut optical fiber again. In the optical fiber reconnecting method of an optical fiber cable, the sheath of the optical fiber cable near the outside of the closure is partially peeled off, and the optical fiber having the cut other end is pulled out from the closure, while the closure A reconnecting optical fiber is connected to one end of the optical fiber cut in the slot, and the reconnecting optical fiber is connected to the slot The optical fiber for return is connected to the other end of the optical fiber cut outside the closure by pulling out the sheath outside the closure through an optical fiber return groove formed in the sheath or sheath. Yes.

  Invention of Claim 3 is the optical fiber reconnection method of the optical fiber cable of Claim 1 or Claim 2, Comprising: After connecting the said optical fiber for reconnection, this optical fiber for reconnection is connected. After removing the slack of the optical fiber which is pulled into the closure and loosened to the site where the predetermined length of the sheath was peeled outside the closure, the sheath where the sheath was peeled is covered with a repair jacket Yes.

  According to the optical fiber reconnecting method of an optical fiber cable of the present invention, an optical fiber having the other end cut off by partially peeling off the sheath of the optical fiber cable in the vicinity of the outside of the closure is pulled out from the closure. After connecting the reconnecting optical fiber to the other end of the drawn optical fiber, the reconnecting optical fiber is returned to the closure through the optical fiber return groove formed in the slot core or sheath, and is cut in the closure. If a reconnection optical fiber is connected to one end of the optical fiber, the cut optical fiber can be connected and reused even with a small closure.

  Further, according to the optical fiber reconnection method of the optical fiber cable, while pulling out the optical fiber having the other end cut off by partially peeling off the sheath of the optical fiber cable near the outside of the closure, An optical fiber for reconnection is connected to one end of the optical fiber cut in the closure, and the optical fiber for reconnection is pulled out to the part where the sheath outside the closure is peeled off through an optical fiber return groove formed in the slot core or sheath. If the reconnection optical fiber is connected to the other end of the optical fiber cut outside the closure, the cut optical fiber can be connected and reused even with a small closure.

FIG. 1 is a wiring diagram schematically showing an example in which an optical fiber drop cable is connected to an optical fiber taken out by branching an optical fiber cable provided in a closure, and the optical fiber is drawn into a home. FIG. 2 is a diagram showing a state in which an optical fiber drop cable is connected to an optical fiber taken out by branching in a closure in the wiring diagram of FIG. FIG. 3 is a perspective view showing a part of an example of an optical fiber cable branched in the middle of the closure. FIG. 4 is a process chart sequentially showing a procedure for partially peeling the sheath of the optical fiber cable near the outside of the closure. FIG. 5 is a process diagram sequentially illustrating a procedure for reconnecting an optical fiber by the first reconnection method. FIG. 6 is a perspective view of the optical fiber cable in the steps (B), (C), and (D) shown in FIG. FIG. 7 is a process diagram sequentially showing a procedure for reconnecting optical fibers by the second reconnection method. FIG. 8 is a perspective view of the optical fiber cable in the steps (B) and (C) shown in FIG. FIG. 9 is an enlarged cross-sectional view of an SZ-type optical fiber cable used to explain that the reconnection method of the present invention can be applied to an SZ-type optical fiber cable.

  Hereinafter, specific embodiments to which the present invention is applied will be described in detail with reference to the drawings.

[Explanation of pulling optical fiber to houses, etc.]
FIG. 1 shows a wiring diagram of a general optical fiber cable of FTTH (Fiber To The Home), and FIG. 2 shows the optical fiber taken out by branching in the middle of the closure in the wiring diagram of FIG. The state where the fiber drop cable is connected is shown.

  To draw the optical fiber from the telecommunications carrier's station 1 to the user's house 2 or office building 3, the optical fiber cable 6 is installed in the underground 4 or the utility pole 5, and the optical fiber cable 6 is intermediately branched in the closure 7. Then, the optical fiber drop cable 9 is connected to the optical fiber 8 (see FIG. 2) taken out, and the optical fiber drop cable 9 is routed to the house 2 or the office building 3.

[Description of optical fiber cable configuration]
As shown in FIG. 3, the optical fiber cable 6 includes a cable portion 10, a support wire portion 11 that supports the cable portion 10, and a neck portion 12 for supporting the cable portion 10 on the support wire portion 11 at an appropriate interval. And is integrated with a sheath 13 formed from a resin such as common polyolefin (PO).

  The support wire portion 11 includes a support wire (generally a steel wire) 14 having a circular cross section and a sheath 13 that covers the support wire 14. The neck portion 12 connects the cable portion 10 and the support wire portion 11 so as to be substantially parallel. The neck portion 12 is provided at an appropriate interval between the cable portion 10 and the support wire portion 11, so that the neck portion 12 is hardly affected by wind due to the action of the window portion 15 formed between the neck portions 12. For example, a phenomenon (galloping phenomenon) in which the cable vibrates violently up and down when strong wind blows with snow or ice attached to the optical fiber cable 6 can be suppressed.

  The cable portion 10 is a sheath covering the entire slot core including a slot core 18 that holds and holds the optical fiber 8 and the water absorbing material 16 in the slot groove 17 and a pressing tape 19 that covers the opening of the slot groove 17. 13 and a strength member 20 embedded in the slot core 18.

  Examples of the optical fiber 8 include an optical fiber, an optical fiber, and an optical fiber tape. The optical fiber is a quartz glass fiber coated with an ultraviolet curable resin. The optical fiber core is a silica glass fiber coated with a plastic resin and has a diameter larger than that of the optical fiber. The optical fiber ribbon is made of several optical fiber strands arranged in parallel and covered with an ultraviolet curable resin. FIG. 3 shows an example in which the optical fiber core wire is accommodated in the slot groove 17.

  The slot core 18 is a holding member that accommodates and holds the optical fiber 8 therein, and has a slot groove 17 that is a circular arc having a center point at a position shifted from the center point of the cable portion 10. The slot core 18 is formed by extrusion molding, and a cross section perpendicular to the longitudinal direction is a C-shaped cross section.

  The slot core 18 is provided with a tensile member that is a tension member in order to prevent the sheath 13 from being thermally contracted by the influence of heat received at the place where the optical fiber cable 6 is laid and the optical fiber cable itself being deformed. 20 is embedded. The strength member 20 is made of, for example, a wire rod such as a steel wire or FRP, and is provided with the longitudinal direction thereof in the longitudinal direction of the optical fiber cable 6.

  The water absorbing material 16 is disposed on the inlet side of the slot groove 17. The water absorbing material 16 is composed of an elongated thread or the like that absorbs moisture present in the slot groove 17. In order to prevent the resin constituting the sheath from entering the slot groove 17 when the entire slot core is covered with the sheath 13, the pressing tape 19 covers the entire inlet portion of the slot groove 17 in the longitudinal direction of the cable. It is provided along.

  In particular, in the optical fiber cable 6 of the present embodiment, an optical fiber return groove 21 described later is formed in the slot core 18. The optical fiber return groove 21 is formed in a portion different from the slot groove 17 and is formed as a groove large enough to accommodate a reconnecting optical fiber 24 and a connecting portion 25 of the optical fiber 6 described later. Yes. In FIG. 3, the optical fiber return groove 21 as a groove having a U-shaped cross section facing the inner surface 13 a of the sheath 13 is continuously provided along the longitudinal direction of the cable at both side positions of the strength member 20 in the slot core 18. Formed.

  Further, the optical fiber return groove 21 can be formed on the inner surface 13a of the sheath 13, although not shown, in addition to being formed in the slot core 18. The optical fiber return groove 21 may use the slot groove 17 itself as an optical fiber return groove if there is room in the internal space of the slot groove 17.

[Description of first reconnection method]
Next, the sheath 13 of the optical fiber cable 6 configured as described above is peeled off by a predetermined length, and a predetermined optical fiber 8 out of a plurality of pieces stored in the slot groove 17 of the slot core 18 is taken out and cut. Then, after one end (station side end) 8A of the cut optical fiber 8 is connected to the optical fiber drop cable 9 (state shown in FIG. 2), the subscriber cancels the contract with the communication company and the like. An optical fiber reconnection method for connecting one end 8A of the optical fiber 8 to the other end (subscriber side end) 8B of the cut optical fiber 8 will be described. FIG. 4 is a process diagram sequentially illustrating a procedure for partially peeling the sheath of the optical fiber cable near the outside of the closure, and FIG. 5 is a process diagram sequentially illustrating a procedure for connecting the optical fibers by the first reconnection method.

  First, a part of the sheath 13 of the cable portion 10 of the optical fiber cable 6 near the outside of the closure 7 is peeled off. At this time, a portion of the sheath 13 in the vicinity of the closure 7 is peeled off as much as possible instead of peeling off the sheath 13 at a portion too far from the closure 7. In order to peel off a part of the sheath 13, first, as shown in FIG. 4A, the cutting edge of the cutter 22 is cut into the sheath 13 until it reaches the slot core 18, and the cutter 22 is cabled as shown by an arrow A. The sheath 13 is rotated in the circumferential direction. Next, as shown in FIG. 4B, the cutter 22 is cut into the sheath 13 from the side opposite to the slot groove 17 so that the sheath 13 is longitudinally split in the cable longitudinal direction.

  Next, as shown in FIG. 4C, a part of the cut sheath 13 is lifted upward. And finally, as shown in FIG. 4D, after cutting the blade edge of the cutter 22 into the sheath 13 to a position reaching the slot core 18 and rotating the cutter 22 in the cable circumferential direction, The sheath 13 is peeled off. As a result, as shown in FIG. 5A, a part of the sheath 13 of the cable portion 10 near the closure 7 is peeled off, and the optical fiber 8 in the slot groove 17 can be taken out. Further, the optical fiber return groove 21 formed in the slot core 18 is exposed at the sheath peeling portion 23 where the sheath 13 is peeled off.

  Next, the optical fiber 8 on the subscriber side remaining after being cut in the closure 7 from the plurality of optical fibers 8 housed in the slot groove 17 from the sheath peeling portion 23 is shown in FIG. As shown in FIG. 3, the slot groove 17 is pulled out. At this time, since a part of the sheath 13 in the vicinity of the closure 7 is peeled off, the drawing operation of the optical fiber 8 out of the slot groove 17 can be easily performed. FIG. 6A is a perspective view of the optical fiber cable 6 when the optical fiber 8 is pulled out of the slot groove 17.

  Next, the reconnection optical fiber 24 is connected to the other end 8B of the optical fiber 8 drawn out of the closure 7, as shown in FIG. The reconnection optical fiber 24 is an optical fiber for connecting the other end 8B of the optical fiber 8 remaining after being cut to the one end 8A of the optical fiber 8 that is no longer required to be connected to the optical fiber drop cable 9. . For this reason, the reconnecting optical fiber 24 may be of a length that allows the optical fibers to be connected to each other. FIG. 6B is a perspective view of the optical fiber cable 6 when the reconnecting optical fiber 24 is connected to the end 8B of the optical fiber 8 outside the closure 7.

  Then, as shown in FIG. 5D, the reconnecting optical fiber 24 is returned into the closure 7 through the optical fiber return groove 21 described above. In order to return the reconnecting optical fiber 24 into the closure 7, the reconnecting optical fiber 24 is inserted into the optical fiber return groove 21 formed in the slot core 18 exposed by peeling off a part of the sheath 13. Push into the closure 7. Since the optical fiber return groove 21 is sized to accommodate the connection portion 25 of the optical fiber 8 and the reconnecting optical fiber 24, the connection portion 25 that is thickest can pass therethrough. Further, since the reconnecting optical fiber 24 is passed through the optical fiber return groove 21 containing nothing, it is smoothly inserted without being caught on the way.

  Next, the other end 8B of the optical fiber 8 drawn back into the closure 7 is connected to one end 8A of the optical fiber 8 cut in the closure 7. Specifically, the reconnection optical fiber 24 connected to the other end 8 </ b> B of the subscriber-side optical fiber 8 is connected in the closure 7 to one end 8 </ b> A of the office-side optical fiber 8. At this time, since the optical fiber 8 for reconnection is connected to the other end 8B of the optical fiber 8 that has been cut and shortened, the optical fibers 8 that have been cut by the optical fiber for reconnection 24 are connected to each other. Reconnection work can be easily performed. FIG. 6C is a perspective view of the optical fiber cable 6 when the cut optical fiber 8 is connected by the reconnection optical fiber 24.

  Next, after the reconnecting optical fiber 24 is connected, the reconnecting optical fiber 24 is pulled into the closure 7 to eliminate the slack of the optical fiber 8 that is loosened to the sheath stripped portion 23 outside the closure 7. Finally, the sheath 26 is covered with a repair jacket 26. For the repair jacket 26, a heat shrinkable member that shrinks when heated, a resin tape excellent in weather resistance, a small case, or the like is used. By covering the sheath stripped portion 23 with the repair jacket 26, the optical fiber 8 at the stripped portion can be protected.

[Explanation of second reconnection method]
The method for reconnecting the optical fiber 8 includes a second reconnection method in addition to the first reconnection method described above. The second reconnection method will be described below. FIG. 7 is a process diagram sequentially showing a procedure for connecting optical fibers by the second reconnection method, and FIG. 8 is a perspective view of the optical fiber cable in the steps (B) and (C) shown in FIG.

  In the second reconnection method, first, as shown in FIG. 7A, a part of the sheath 13 of the cable portion 10 of the optical fiber cable 6 near the outside of the closure 7 is peeled off. Since this step is the same as the step shown in FIG. 5A described above, detailed description thereof is omitted. As a result, as shown in FIG. 7A, a part of the sheath 13 of the cable portion 10 near the closure 7 is peeled off, and the optical fiber 8 in the slot groove 17 can be taken out. Further, the optical fiber return groove 21 formed in the slot core 18 is exposed at the sheath peeling portion 23 where the sheath 13 is peeled off.

  Next, the optical fiber 8 on the subscriber side remaining after being cut in the closure 7 from the optical fiber 8 out of a plurality of pieces accommodated in the slot groove 17 from the sheath peeling portion 23 is shown in FIG. As shown, it is pulled out of the slot groove 17. At this time, since a part of the sheath 13 in the vicinity of the closure 7 is peeled off, the drawing operation of the optical fiber 8 out of the slot groove 17 can be easily performed.

  Further, before or after the optical fiber 8 is pulled out of the closure 7, it is reconnected to one end 8A of the optical fiber 8 which is no longer required to be connected to the optical fiber drop cable 9, as shown in FIG. 7B. The optical fiber 24 is connected. The reconnection optical fiber 24 used here is the same as that used in the first reconnection method. FIG. 8A is a perspective view of the optical fiber cable 6 when the optical fiber 8 is pulled out of the slot groove 17 and the reconnection optical fiber 24 is connected.

  Next, as shown in FIG. 7C, the reconnecting optical fiber 24 is pulled out to the sheath peeling portion 23 outside the closure 7 through the optical fiber return groove 21. In order to pull out the reconnecting optical fiber 24 to the sheath stripping portion 23 outside the closure 7, the reconnecting optical fiber 24 is inserted into the optical fiber return groove 21 and pushed out of the closure 7. At this time, since the reconnecting optical fiber 24 is passed through the optical fiber return groove 21 containing nothing, it is smoothly inserted without being caught in the middle.

  Then, the reconnecting optical fiber 24 drawn out to the sheath peeling portion 23 is connected to the other end 8B of the optical fiber 8 on the subscriber side. Here, since the reconnection optical fiber 24 and the other end 8B of the optical fiber 8 are connected outside the closure 7, there is no obstruction and the connection work can be easily performed. As a result, one end 8 </ b> A of the optical fiber 8 is connected to the other end 8 </ b> B of the optical fiber 8 through the reconnection optical fiber 24. FIG. 8B is a perspective view of the optical fiber cable 6 when the reconnecting optical fiber 24 is connected to the end portion 8B of the optical fiber 8 outside the closure 7.

  Next, as shown in FIG. 7D, the reconnection optical fiber 24 is pulled into the closure 7 to eliminate the slackness of the optical fiber 8 that is loosened to the sheath stripped portion 23 outside the closure 7. At this time, the connecting portion 25 between the other end 8B of the optical fiber 8 and the reconnecting optical fiber 24 is the thickest, but the optical fiber return groove 21 is caught because it is sized to accommodate the connecting portion 25. The connecting portion 25 can be inserted therethrough. Finally, the sheath 26 is covered with a repair jacket 26. The repair jacket 26 is the same as that used in the first reconnection method. By covering the sheath stripped portion 23 with the repair jacket 26, the optical fiber 8 at the stripped portion can be protected.

[Effect of this embodiment]
According to the first reconnection method of the present embodiment, the optical fiber 8 having the other end 8 </ b> B cut off by partially peeling off the sheath 13 of the optical fiber cable 6 near the outside of the closure 7 is removed from the closure 7. And the reconnecting optical fiber 24 is connected to the other end 8B of the drawn optical fiber 8, and then the reconnecting optical fiber 24 is again passed through the optical fiber return groove 21 formed in the slot core 18 or the sheath 13. If the reconnection optical fiber 24 is connected to one end 8A of the optical fiber 8 cut in the closure 7 and returned to the closure 7, the cut optical fiber 8 can be connected even in the small closure 7. Can be reused. Until now, when an optical fiber subscriber cancels a contract with a communication company, the length of the cut optical fiber 8 in the closure 7 is insufficient, so that it is not used as it is. However, in the present invention, it is possible to connect and use the optical fiber 8 that is no longer used due to the contract cancellation. Thereby, the waste of the optical fiber 8 can be eliminated, and then the optical fiber can be drawn into another subscriber's house.

  Further, according to the second reconnection method of the present embodiment, the optical fiber 8 having the other end 8B cut off by partially peeling off the sheath 13 of the optical fiber cable 6 near the outside of the closure 7 is closed. While the optical fiber 8 for reconnection is connected to one end 8A of the optical fiber 8 cut in the closure 7, and the optical fiber return formed in the slot core 18 or the sheath 13 is connected to the optical fiber 8 for reconnection. If the sheath 13 on the outside of the closure 7 is pulled through the groove 21 to the peeled portion and the reconnection optical fiber 24 is connected to the other end 8B of the optical fiber 8 cut outside the closure 7, the small closure 7 can be obtained. However, the cut optical fiber 8 can be connected and reused.

  In addition, according to the first and second reconnection methods of the present embodiment, the portion where the predetermined length of the sheath 13 is stripped outside the closure 7 by pulling the reconnection optical fiber 24 into the closure 7. After the slackness of the optical fiber 8 that is loosened is eliminated, the sheath stripping portion 23 is covered with the repair sheath 26, so that the sheath stripping portion 23 can be restored with the repair sheath 26. .

  Further, according to the optical fiber cable of the present embodiment, the optical fiber return groove 21 is formed in the slot core 18 or the sheath 13, so that the re-connection connected to the other end 8 </ b> B of the optical fiber 8 through the optical fiber return groove 21. The connecting optical fiber 24 or the reconnecting optical fiber 24 connected to one end 8A of the optical fiber 8 cut in the closure 7 can be passed. Thereby, the one end 8A and the other end 8B of the cut optical fiber 8 can be connected via the reconnection optical fiber 24 so that the optical fiber 8 can be reused.

  Further, according to the optical fiber cable of the present embodiment, the optical fiber return groove 21 has a size that can accommodate the connecting portion 25 of the optical fiber 8 and the reconnecting optical fiber 24, so that it is thicker than the optical fiber 8. The formed connection portion 25 can also be passed through the optical fiber return groove 21. Further, according to this optical fiber cable, since the optical fiber return groove 21 is formed at a position different from the slot groove 17, there is no obstacle in the optical fiber return groove 21, so that it can be used for reconnection. The optical fiber 24 can be easily routed.

  In addition, according to the optical fiber cable of the present embodiment, when the slot groove 17 is used as the optical fiber return groove 21, the slot groove 17 can be re-used as it is without the slot core 18 or the sheath 13 being grooved. It can be used as an optical fiber return groove 21 through which the connecting optical fiber 24 is passed.

  The specific embodiment to which the present invention is applied has been described above, but the present invention is not limited to the above-described embodiment. For example, in the above-described embodiment, the present invention has been described by taking the optical fiber cable 6 having the support line portion 11 as an example, but the present invention is also provided for an optical fiber cable having a structure without the support line portion 11. be able to. Moreover, although the present invention is the optical fiber cable 6 having the slot core 18 that is the C-shaped slot groove 17, the present invention is not limited thereto, and the present invention is also applied to, for example, a loose tube cable filled with jelly. Can be applied.

  In addition, the first and second reconnection methods of the present invention can be applied to an SZ type optical fiber cable as shown in FIG. The SZ-type optical fiber cable 30 is formed with five slot grooves 32 having a U-shaped cross section at equal intervals along the cable longitudinal direction on the outer peripheral surface of a slot core 31 having a cylindrical cross section. A plurality of optical fiber ribbons 33 are stacked and arranged inside. In addition, a tension member 34 as a tension member is provided in the center of the slot core 31 in the cable longitudinal direction. Further, the SZ type optical fiber cable 30 has a structure in which a presser winding tape 35 such as a nonwoven fabric is interposed so as to cover the outer peripheral surface of the slot core 31 and the entire slot core 31 is covered with a sheath 36. . Further, the optical fiber return groove 21 is formed in the slot core 31 at a position that does not interfere with each slot groove 32.

  Also in the SZ type optical fiber cable 30 configured in this way, as in the case of the C slot type optical fiber cable, the first reconnection method including the steps shown in FIGS. In the second reconnection method comprising the steps of FIG. 8 and FIG. 8, it becomes possible to reconnect the cut optical fibers by eliminating the need for connection with the optical fiber drop cable.

  INDUSTRIAL APPLICATION This invention can be utilized for the optical fiber reconnection method of the optical fiber cable which connects the optical fibers cut | disconnected since the connection with an optical fiber drop cable becomes unnecessary.

DESCRIPTION OF SYMBOLS 1 ... Station 2 ... House 6 ... Optical fiber cable 7 ... Closure 8 ... Optical fiber 8A ... One end of optical fiber 8B ... The other end of optical fiber 9 ... Optical fiber drop cable 10 ... Cable part 11 ... Support wire part 13 ... Sheath DESCRIPTION OF SYMBOLS 17 ... Slot groove 18 ... Slot core 21 ... Optical fiber return groove 23 ... Sheath stripping part 24 ... Optical fiber for reconnection 25 ... Connection part of optical fiber and optical fiber for reconnection 26 ... Cover for repair

Claims (3)

The sheath is peeled off from the optical fiber cable provided in the closure for a predetermined length, and a predetermined optical fiber out of a plurality of pieces stored in the slot groove of the slot core is taken out and cut, and one end of the cut optical fiber After connecting the optical fiber drop cable to the optical fiber drop cable, when the connection with the optical fiber drop cable becomes unnecessary, the optical fiber cable is reconnected to the other end of the cut optical fiber. In
Part of the sheath of the optical fiber cable near the outside of the closure is partially peeled, the optical fiber having the cut other end is drawn out of the closure, and reconnected to the other end of the optical fiber drawn out of the closure After connecting the optical fiber for use, the optical fiber for reconnection is returned to the closure through the optical fiber return groove formed in the slot core or sheath, and the reconnection is made to one end of the optical fiber cut in the closure. An optical fiber reconnecting method for an optical fiber cable, characterized by connecting an optical fiber for use. The sheath is peeled off from the optical fiber cable provided in the closure for a predetermined length, and a predetermined optical fiber out of a plurality of pieces stored in the slot groove of the slot core is taken out and cut, and one end of the cut optical fiber After connecting the optical fiber drop cable to the optical fiber drop cable, when the connection with the optical fiber drop cable becomes unnecessary, the optical fiber cable is reconnected to the other end of the cut optical fiber. In
A part of the sheath of the optical fiber cable in the vicinity of the outside of the closure is peeled off, and the optical fiber having the cut other end is pulled out from the closure, while being re-applied to one end of the optical fiber cut in the closure. Connecting the optical fiber for connection, drawing the optical fiber for reconnection through the optical fiber return groove formed in the slot core or sheath to the portion where the sheath outside the closure is peeled off, and cutting the optical fiber outside the closure An optical fiber reconnecting method for an optical fiber cable, wherein the reconnecting optical fiber is connected to the other end of the optical fiber cable. An optical fiber reconnection method for an optical fiber cable according to claim 1 or 2,
After connecting the reconnecting optical fiber, the reconnecting optical fiber is pulled into the closure to eliminate the slack of the optical fiber loosened at the site where the predetermined length of the sheath has been peeled off the closure, An optical fiber reconnecting method for an optical fiber cable, characterized in that a sheath for repairing is coated on a portion where the sheath is peeled off.

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