JP2006215248A - Coding member for optical communication cable and connector connecting structure of optical communication cable - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a coding member for an optical communication cable, a member capable of suppressing loss caused near a connecting part between the optical communication cable and a connector, and also to provide a connector connecting structure of the optical communication cable. <P>SOLUTION: The coding member has a protective tube 20 in which a coated optical fiber 11 is inserted and protected at an end of an optical communication cable 3 when drawn out and exposed therefrom, with a connector 25 for the coated optical fiber attached to the tip end at the same time, and has a box body 16 in which the end of the cable and the end of the tube 20 on the side of optical communication cable are held. The protective tube 20 is composed of a highly slidable material. The box body 16 is provided with a deflection absorbing chamber 28. The chamber 28 is formed between the cable end and the tube end inside the box body 16, while these ends are held away from each other in the box body. When the deflection of the coated optical fiber 11 is generated in the protective tube 20 by connecting the coated optical fiber 11 with other optical devices through the connector 25, the deflection is absorbed by the flexure (deflection) of the coated optical fiber 11 exposed in the deflection absorbing chamber 28. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a coding member and a connection structure for connecting a connector to an end of an optical communication cable.

  Conventionally, a building such as an office building or a factory has been provided with an indoor optical cabinet connected to an optical communication cable drawn from the outside, and the optical communication trunk cable connected to the indoor optical cabinet has a predetermined floor. Each optical cabinet is connected to a device installed on each floor and connected to a personal computer or the like with an optical communication cable (see Patent Document 1).

  When the laying length of the optical communication cable is determined, one end of the existing optical communication cable 50 set to a predetermined length is connected to the optical cabinet 51 as shown in FIG. The other end side of the optical communication cable 50 is branched and coded into each optical fiber core, and a connector is connected to the tip of each optical fiber core. This connector is provided in the device 52. Connected to the other connectors.

  Further, the interval between the optical cabinet 51 and the device 52 differs depending on the installation location. In an unknown connection work site where the installation length has not been determined, as shown in FIG. It was necessary to connect another optical communication cable 53 for length adjustment to the communication cable 50.

  When connecting the optical communication cables 50, 53, the operator cuts another optical communication cable 53 to a predetermined length at the site, connects one end of the optical communication cable 53 to the optical cabinet 51, and the other end It was connected to one end of the optical communication cable via the connection BOX 54. When the connection work between the optical communication cables 50 and 53 is performed using the connection BOX 54, fusion bonding between the optical communication cables is indispensable. Since fusion bonding between the optical communication cables takes time and it is necessary to bring the fusion apparatus to the site, there is a problem in workability and a problem that costs increase.

  In order to solve such a problem, the applicant of the present application has previously devised a coding member for an optical communication cable. The coding member includes a protective cord component including a plurality of protective tubes into which the optical fiber core wires are inserted, a case having an opening for storing the protective cord component, and a cover for closing the opening of the case. Each optical fiber core wire of the optical communication cable is inserted into the protective tube to be branched and coded, and is protected without being exposed to the coded member of the optical communication cable. By attaching a connector connectable to the optical fiber core to each protective tube, each encoded optical fiber core can be connector-connected.

As a result, an optical communication cable cut into a predetermined length can be coded, and a connector can be easily and quickly connected to a device installed at a predetermined location in a building without using a connection BOX for connecting the optical communication cable. Can be connected.
JP 2001-147359 A

  Although the coded optical fiber cores can be connected to the connectors by the above improvements, there is room for improvement in the following points.

  As shown in FIG. 11, a built-in optical fiber core wire (a short optical fiber core wire for connection) 101 is arranged inside a connector 100 connected to an optical fiber. When each encoded optical fiber core wire 102 is connected to the connector 100, the end of the encoded optical fiber core wire 102 is exposed from the front end of the protection tube 103 together with the tip of the protection tube 103. It is inserted into the connector 100. At this time, a built-in optical fiber core 101 is accommodated inside the connector 100 so as to be coaxial with the optical fiber core 102 to be inserted, and the tip of the inserted optical fiber core 102 is at the built-in optical fiber. Attached to the core wire 101. In this state, the tip of the optical fiber core wire 102 is fixed to the connector 100.

  However, by arranging the tip of the optical fiber core 102 in contact with the short optical fiber core 101 for connection, the optical fiber core 102 has a direction opposite to the abutting direction (inward direction in the axial direction of the optical fiber). ) Produces a reaction force. This reaction force causes the optical fiber 102 to bend. The bending causes local bending of the optical fiber core wire 102 in the protective tube 103 or in the vicinity of the tube, and also causes microbending in the optical fiber core wire 102 in the protective tube 103. These phenomena cause the loss increase.

  This invention makes it a subject to suppress the loss which arises in the connection location vicinity of an optical communication cable and a connector.

  In order to solve the above-mentioned problems, the optical fiber cable connector connection structure of the present invention protects the optical fiber core wire that is pulled out from the cable end portion and exposed at the end portion of the optical communication cable, and is protected at the tip thereof. A protective tube to which a connector for optical connection for optically connecting the optical fiber core wire to another optical device is mounted, an end of the optical communication cable, and an end of the protective tube on the side of the optical communication cable With a box. The protective tube is made of a material having high slipperiness. The box body has a bending absorption chamber. The bending absorption chamber is gripped by the box with the optical communication cable end and the protective tube end being separated from each other, so that the cable end and the tube end are inside the box. Is formed between.

  Then, the bending of the optical fiber core that is exposed to the bending absorption chamber is caused by the bending of the optical fiber core that occurs in the protective tube due to the connection between the optical fiber core and the other optical device via the connector. To absorb.

  The protective tube is made of a material having non-charging properties in order to improve the passage of the optical fiber core wire and suppress local bending. Further, the protective tube is made of a material that has a good sliding property (for example, a friction coefficient of 0.18) in order to improve the passage of the optical fiber core and suppress local bending. An example of such a material is polyester elastomer resin.

  In absorbing the local bending of the optical fiber core, the bending absorption chamber has a volume in which the bending of the optical fiber core caused by the bending of the optical fiber core is within (but not less than) the bending radius of 30 mm or more. It is preferable to have.

  ADVANTAGE OF THE INVENTION According to this invention, it becomes possible to suppress the loss which arises in the connection location vicinity of an optical communication cable and a connector.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. First, the structure of the present invention will be described with reference to FIGS. As shown in FIGS. 8 and 9, a building optical cabinet 5 connected to an optical communication cable 3 drawn from the outside is disposed in a building 1 such as an office building or a factory. The optical communication trunk cable 6 connected to the indoor optical cabinet 5 is connected to an optical cabinet 7 installed on each floor (predetermined floor), as well as each optical cabinet 7 and a connection box installed on each floor. A device 8 is connected to the optical communication cable 10. The device 8 includes, for example, means for converting an optical signal from the optical communication cable 10 into an electrical signal, and is connected to an electronic device 9 such as a personal computer. The connection box also includes a termination box that simply connects the optical fiber core wires.

  As the optical communication cable 10, for example, a four-core indoor cable formed by integrating four optical fiber core wires 11 of 0.25 mm in parallel is adopted. A coding member 13 for coding the optical fiber core wire 11 is provided in the middle of the optical communication cable 10.

  As shown in FIGS. 1 to 7, the coding member 13 includes a protective cord component 15 into which the optical fiber core wire 11 is inserted, a case 16 in which the protective cord component 15 is accommodated, and a cover 17.

  The protective cord component 15 includes a resin-made main body portion 19 including a pair of holding portions 19a and 19b, a bottom portion 19c connecting both the holding portions 19a and 19b, and a side portion 19d. A plurality of (four in the illustrated example) protection tubes 20 are attached to the main body 19.

  Each protective tube 20 has an inner and outer double layer structure, and a tensile fiber 22 such as Kevlar is provided between the outer layer 20a and the inner layer 20b and along the axial direction. One end portion of the inner layer 20b protrudes from the outer layer 20a. At this one end portion, the inner and outer double layer portions of the protective tube 20 are inserted into one holding portion 19a, and the inner layer 20b is inserted into the other holding portion 19b. It is inserted. Further, the tensile strength fiber 22 between the inner and outer layers 20a and 20b is exposed to the outside at the end of the outer layer 20a, and the tensile strength fiber 22 is fixed by filling the main body 19 with the resin 23. Immobilization to 19 is attempted. In addition, although the length from one holding | maintenance part 19a of each protection tube 20 is set suitably, it is preferable to set to 0.5-1.5m.

  As shown in FIGS. 1, 2, and 4A to 4C, the case 16 includes a bottom portion 16a and both side portions 16b erected from both edges of the bottom portion 16a so that the upper surface is open. Resin-molded in a rectangular shape in plan view. A peripheral protrusion 24 a is integrally formed at one end edge of the case 16. On the inner surface of the bottom portion 16a, a positioning convex portion 24b for fixing the main body portion 19 of the protective cord component 15 housed in the case 16 between the peripheral convex portion 24a is integrally formed. Further, a thick portion 16d is formed on the other inner surface of the bottom portion 16a, and holding convex portions 16e and 16e are spaced apart from the thick portion 16d so as to hold the optical communication cable 10 from both sides. Are integrally molded. Locking convex portions 16f for fixing the cover 17 are integrally formed on the outer surfaces of the both side portions 16b. The locking projection 16f has an inclined surface that expands toward the bottom 16a as shown in FIG.

  As shown in FIGS. 2 and 5 (a) to 5 (c), the cover 17 is made of a resin molded in the same rectangular shape as the case 16, and is flat from the flat top surface portion 17a and both edges of the top surface portion 17a. And a substantially U-shaped engaging portion 17 b that engages with the locking convex portion 16 f of the case 16. In the present embodiment, the case 16 and the cover 17 constitute an example of a box.

  Next, a method for coding and connecting the optical communication cable 10 using the coding member 13 will be described. Here, a case where an optical communication cable 10 in which four optical fiber cores 11 are arranged in parallel and integrated is used is illustrated. However, the present invention can be similarly applied to an optical communication cable in which other numbers of optical fibers such as two fibers are arranged in parallel and integrated.

  First, at the work site, the operator cuts the optical communication cable 10 into a predetermined length according to the distance between the optical cabinet 7 installed on a predetermined floor and the device 8, and one end side thereof is The optical fiber core wire 11 is taken out except for the outer sheath on the other end side of the optical communication cable 10 while being connected to the optical cabinet 7 as in the conventional case. Each optical fiber core wire 11 taken out is inserted into the protective tube 20 of the coding member 13 (see FIG. 6A). The optical fiber core wire 11 can be easily inserted from the inner layer 20 b of the protective tube 20 protruding from the main body portion 19.

  Next, the protective cord component 15 integrated with the optical fiber core wire 11 is housed in the case 16 from its opening. Specifically, the main body portion 19 is fitted and positioned between the peripheral convex portion 24 a and the positioning convex portion 24 b of the bottom portion 16 a of the case 16. Further, the outer cover of the optical communication cable 10 is fitted between the holding convex portions 16e and 16e provided on the bottom portion 16a of the case 16, and the protective cord component 15 is set in the case 16 (FIGS. 6B and 7A). )reference). The optical communication cable 10 can be fixed by being fitted between the holding convex portions 16e and 16e, but can also be firmly fixed with an adhesive or a resin. In addition, as shown in FIG. 6C, a pair of cable gripping members 30a and 30b are provided, and the end portions of the optical communication cable 10 are gripped by these cable gripping members 30a and 30b. The optical communication cable 10 may be held in the case 16 by inserting the cable gripping members 30 a and 30 b into the case 16 and fixing them in the case 16.

  Further, the engaging portion 17 b of the cover 17 is engaged with the locking convex portion 16 f of the case 16 to close the opening of the case 16. When the cover 17 is attached to the case 16, when the cover 17 is pushed into the case 16, the engaging convex portion 16 f of the case 16 has an inclined surface. The cover 17 can be easily attached to the case 16 with one touch by sliding on the inclined surface of the locking protrusion 16f. By closing the opening of the case 16 with the cover 17 in this way, each branched optical fiber core wire 11 is protected by the coding member 13 without being exposed.

  Further, the connector 25 is attached to the tip of each protection tube 20 in a state of being connected to the optical fiber core wire 11, the tip of each protection tube 20 is introduced into the device 8, and each connector 25 is inserted into the device 8. Each is connected to the provided connector 25. The connector 25 can be divided into two along the axial direction, and an optical fiber insertion hole 26 is formed in the connector 25 as shown in FIGS. The optical fiber insertion hole 26 is provided with hole areas 26a, 26b, and 26c. These hole areas 26a, 26b, and 26c are sequentially formed in the connector 25 coaxially. The hole area 26 c is open to an axially outer end (hereinafter referred to as a connection end) 25 a of the connector 25. The hole area 26 a opens at the inner end 25 b in the axial direction of the connector 25. The hole area 26b is located between the hole areas 26a and 26c and communicates with both. The hole area 26a has an inner diameter equivalent to the outer diameter of the outer layer 20a of the protective tube 20, and the outer layer 20a is inserted therethrough. The hole area 26b has an inner diameter equivalent to the outer diameter of the inner layer 20b of the protective tube 20, and the inner layer 20b is inserted therethrough. The hole region 26c has an inner diameter equivalent to the diameter of the optical fiber core wire 11, and the optical fiber core wire 11 is inserted therein. A built-in optical fiber (connecting short optical fiber) 27 is fixedly accommodated in the hole area 26c in advance. One end of the built-in optical fiber 27 is exposed at the connection end 25a of the connector 25, and the other end is located at the longitudinal center of the hole area 26c.

  Next, details of the connection structure between the optical fiber core wire 11 and the connector 25 will be described. The outer layer 20 a is peeled off at the tip of the protective tube 20. The peeling length of the outer layer 20a is the sum of the hole area 26b, the length, and the length of the hole area 26c (however, the length of the hole area 26c where the built-in optical fiber 27 does not exist). Next, the inner layer 20 b is peeled off at the tip of the protective tube 20 to expose the optical fiber core wire 11. The peeling length of the inner layer 20b (the exposed length of the optical fiber core wire 11) is the length of the hole area 26c (however, the length of the hole area 26c where the built-in optical fiber 27 does not exist).

  The tip end of the optical fiber core wire 11 (with the protective tube 20) subjected to the above terminal processing is inserted into the connector 25 from the hole area 26a. At this time, the connector 25 is divided into two along the axial direction to facilitate the insertion of the optical fiber core wire 11. Then, the tip of the outer layer 20a of the protective tube 20 is inserted into the hole region 26a, the tip of the exposed inner layer 20b is inserted into the hole region 26b, and the tip of the exposed optical fiber core 11 is further inserted into the hole 26b. It inserts in the area | region 26c, and is faced | matched coaxially with the edge part of the internal optical fiber 27. In FIG. 1 and FIG. 2, a cross mark is drawn at the abutting portion between the optical fiber core wire 11 and the built-in optical fiber 27. In this state, the connector 25 divided into two is integrated. The integration is performed, for example, by engaging and fixing the split members of the connector 25 with an engaging member (not shown). Thus, the optical fiber core wire 11 and the protective tube 20 are sandwiched between the connectors 25, and the three members (the optical fiber core wire 11, the protective tube 20, and the connector 25) are fixed integrally, and the optical fiber core wire 11 and the built-in optical fiber core 11 are built in. The optical fiber 27 is optically connected.

  As described above, even if the distance between the optical cabinet 7 and the device 8 is arbitrary and the installation length of the optical communication cable 10 is not determined, an inexpensive indoor cable using a 0.25 mm core wire is used. A connector can be connected without using a connection box that has been used conventionally. As a result, the cost of the parts can be reduced, and the laying length confirmation design is not required. A series of laying operations including the optical communication cable connecting operation can be easily and quickly performed, and the degree of freedom in construction is improved.

  When the coding member 13 is fixed at a predetermined position of the building 1 or the like, the protection tube 20 through which the optical fiber core wire 11 is inserted is fixed to the main body portion 19. Even if tension is applied in the direction indicated by the arrow 2 (the direction in which the optical fiber core 11 is inserted), the optical fiber core 11 is protected without being affected. Further, when the optical communication cable 10 is firmly fixed to the case 16, the optical communication cable 10 does not come out of the case 16, so that the coding member 13 does not have to be fixed to the building 1 or the like. Similarly to the above, the optical fiber core wire 11 can be protected from the tension of the protective tube 20.

  The optical communication cable 10 is exemplified by four optical fiber cores, but may be two cores or other. The number of protective tubes 20 of the encoding member 13 is also set as appropriate according to the number of optical fiber cores.

  Next, a configuration that characterizes the embodiment will be described. The protective tube 20 is made of a material having high slipperiness. An example of such a material is a polyester elastomer resin having a friction coefficient of 0.18. If the material is highly slippery, a polyether ether ketone resin (typically registered trademark PEEK), Other materials such as tetrafluoroethylene resin (PTFE, typically registered trademark Teflon), tetrafluoroethylene hexafluoropropylene copolymer resin (FET) may be used. In this case, a material having non-charging characteristics is more preferable.

  The case 16 has a bending absorption chamber 28. The bending absorption chamber 28 is gripped by the case 16 with the end of the optical communication cable 10 and the end of the protective tube 20 being separated from each other, whereby the end of the optical communication cable 10 and the protective tube 20 are inside the case 16. Is formed between. The bending absorption chamber 28 has such a size (volume) that the bending of the optical fiber core wire 11 generated in the bending absorption chamber 28 due to the bending of the optical fiber core wire 11 falls within (but does not become) a bending radius of 30 mm or more.

  Hereinafter, the effect by providing the said structure is demonstrated. When the tip of the optical fiber core 11 (with the protective tube 20) is inserted into the connector 25 from the hole area 26a and the optical fiber core 11 and the short optical fiber 27 for connection are abutted and optically connected, A reaction force is generated in the fiber core wire 11 in a direction opposite to the abutting direction (an inner side in the axial direction of the optical fiber). This reaction force presses the optical fiber core wire 11 toward the inner side in the fiber axis direction (the direction opposite to the connector connection end side), and thereby the optical fiber core wire 11 is bent. The bending causes local bending of the optical fiber core wire 11 in the protective tube 20 and in the vicinity of the tube. Furthermore, as a result of the optical fiber core wire 11 being pressed against the inner wall of the protective tube 20 due to the bending, the optical fiber core wire 11 is caused to be microbending. These phenomena cause the loss increase.

  Therefore, in this embodiment, the protective tube 20 is made of a material having high slipperiness. Thereby, the slip between the inner surface of the tube and the optical fiber core wire 11 is improved inside the protective tube 20, and local bending of the optical fiber core wire 11 in the protective tube 20 or in the vicinity of the tube is suppressed. Furthermore, since local bending does not occur in the optical fiber core wire 11 in the protective tube 20 or in the vicinity of the tube, the optical fiber core wire 11 subjected to the reaction force by the connector 25 moves to the case 16 side as a whole. become. Here, the fiber region of the moved optical fiber core wire 11 is housed as a bend 29 in the bend absorption chamber 28. By bending and storing the optical fiber core wire 11 in the bending absorption chamber 28, the reaction force generated in the optical fiber core wire 11 is absorbed by the connector 25. Therefore, local bending and microbending of the optical fiber core wire 11 are prevented.

  In the configuration of the present embodiment, the reaction force is absorbed by positively bending the optical fiber core wire 11 in the bending absorption chamber 28. However, the problem cannot be solved if the fiber bending here is a local bending. Therefore, the bending absorption chamber 28 of the case 16 of the present embodiment has a volume that does not cause local bending of the optical fiber core wire 11 that receives the reaction force from the connector 25 and is bent in the chamber.

  Specifically, the volume of the bending absorption chamber 28 is defined as follows. In the optical fiber manufacturing standard, the maximum bending radius of the optical fiber is defined as 30 mm, and according to this, a state bent to a radius of less than 30 mm can be regarded as “local bending” in the optical fiber. Therefore, in the present invention, by absorbing the reaction force generated at the connector connecting portion, the bending 29 of the optical fiber core wire 11 generated in the bending absorption chamber 28 has a radius of 30 mm or more. The volume is set large enough. However, when the volume of the flexure absorbing chamber 28 is increased unnecessarily, the volume of the entire case 16 is increased and the storage capacity of the case 16 is unnecessarily increased. Therefore, the size of the bending absorption chamber 28 is preferably set to the minimum size in which the bending (deflection) of the optical fiber core wire 11 is 30 mm or more in the bending absorption chamber 28.

  When static electricity is generated between the protective tube 20 and the optical fiber core wire 11, the protective tube 20 and the optical fiber core wire 11 are brought into close contact with each other due to static electricity, and light caused by the reaction force at the contact portion. There is a possibility that local bending or microbending of the fiber core 11 occurs. In order to prevent such static electricity, the protective tube 20 is made of a material having non-charging characteristics.

  As described above, in this embodiment, the reaction force generated in the optical fiber core wire 11 when the optical fiber core wire 11 and the connector 25 are optically connected is absorbed by the bending 29 of the optical fiber core wire 11 in the bending absorption chamber 28.

  In the above description, the connector 25 having the built-in optical fiber 27 is used, and the reaction force generated by the butt connection between the built-in optical fiber 27 and the optical fiber core wire 11 is absorbed by the bending absorption chamber 28. It was. However, some connectors 25 do not have the built-in optical fiber 27. In the case of the connector 25 having such a configuration, the tip of the optical fiber core wire 11 is extended to the connection end 25 a of the connector 25. When the connector 25 is connected to another optical device, the end of the optical fiber core wire 11 positioned at the connection end 25a of the connector 25 is abutted against the connector portion of the other optical device, so that the connector 25 (optical fiber core wire) is connected. 11) and another optical device are optically connected. Also in this case, a reaction force is generated in the optical fiber core wire 11 due to the abutment of the tip of the optical fiber core wire 11 on the connector 25 side with the connector portion of another optical device. The reaction force generated in this way also causes local bending and microbending of the optical fiber core wire 11, which is a subject of the present invention. The configuration of the present invention exhibits the same effect even in the configuration of such a connector 25.

The top view containing the partial cross section of the coding member which concerns on embodiment of this invention. The cross-sectional side view of the coding member which concerns on embodiment of this invention. Sectional side view which shows the principal part of the coding member which concerns on embodiment of this invention. The case of the encoding member which concerns on embodiment of this invention is shown, (a) is a top view, (b) is a side view, (c) is a front view. The cover of the coding member which concerns on embodiment of this invention is shown, (a) is a top view, (b) is a side view, (c) is a front view. (A) is a perspective view which shows the state which inserted the optical fiber core wire of the optical communication cable in the protective cord component of the coding member based on Embodiment of this invention, (b) accommodates a protective cord component in a case The perspective view which shows a state, (c) is a perspective view which shows the other form which accommodates a protection cord component in a case. (A) is a perspective view of the state where the case where the protection code | cord | chord part of the encoding member which concerns on embodiment of this invention was accommodated is closed with a cover, (b) is a perspective view of an encoding member. Sectional drawing which shows the outline of the installation state of an optical communication cable. Explanatory drawing which shows the connection state of an optical communication cable. (A) And (b) is explanatory drawing which shows the connection state of the optical communication cable which shows a prior art example. Sectional drawing which shows the connector connection part of a prior art example.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Building 3 Optical communication cable 5 On-site optical cabinet 6 Optical communication trunk cable 7 Optical cabinet 8 Equipment 9 Electronic equipment 10 Optical communication cable 11 Optical fiber core wire
13 Coded member 15 Protective code member 16 Case 16a Bottom part 16b Both side parts 16d Thick part 16e Holding convex part 16f Locking convex part 17 Cover 17a Top surface part 17b Engaging part 19 Main body part 19a, 19b Holding part 19c Bottom part 19d Side part 20 Protective tube 20a Outer layer 20b Inner layer 22 Tensile fiber 23 Resin 24a Periphery convex part 24b Positioning convex part 25 Connector 25a Connection end 26 Optical fiber insertion hole 26a, 26b, 26c Hole area 27 Built-in optical fiber 28 Deflection absorption chamber
50 Optical Communication Cable 51 Optical Cabinet 52 Equipment 53 Optical Communication Cable 54 Connection Box

Claims (5)

An optical fiber core wire that is drawn out from the cable end portion and exposed at the end portion of the optical communication cable is inserted and protected, and at the tip thereof, the optical fiber core wire is optically connected to another optical device. A protective tube to which the connector is attached;
A box that holds the end of the optical communication cable and the end of the protective tube on the side of the optical communication cable;
The protective tube is made of a highly slippery material,
The box body has a bending absorption chamber, and the bending absorption chamber is held by the box body with the optical communication cable end portion and the protective tube end portion being separated from each other. Formed inside the body between the cable end and the tube end,
Absorption of the bending of the optical fiber in the protective tube due to the connection between the optical fiber and the other optical device via the connector is absorbed by the bending of the optical fiber exposed in the bending absorption chamber. To
An optical communication cable coding member. The protective tube is made of a material having non-charging characteristics,
The coding member of the optical communication cable according to claim 1. The protective tube is made of polyester elastomer resin,
The coding member of the optical communication cable according to claim 1 or 2. The bending absorption chamber has a volume in which the bending of the optical fiber core caused by the bending of the optical fiber core falls within a bending radius of 30 mm or more.
The coding member of the optical communication cable according to any one of claims 1 to 3. A protective tube for inserting and protecting an optical fiber core wire that is drawn out from the cable end and exposed at the end of the optical communication cable; and
A connector for optical connection that is attached to the tip of the protective tube and connects the optical fiber core wire passing through the tube to another optical device;
A box that holds the end of the optical communication cable and the end of the protective tube on the side of the optical communication cable;
With
The protective tube is made of a highly slippery material,
The box body has a bending absorption chamber, and the bending absorption chamber is held by the box body with the optical communication cable end portion and the protective tube end portion being separated from each other. Formed inside the body between the cable end and the tube end,
Absorption of the bending of the optical fiber in the protective tube due to the connection between the optical fiber and the other optical device via the connector is absorbed by the bending of the optical fiber exposed in the bending absorption chamber. To
A connector connection structure of an optical communication cable characterized by the above.

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