KR100320408B1 - Optical cable branching device and its use - Google Patents

Abstract

The present invention relates to an optical cable branching apparatus and a method of using the same, and an object thereof is to reduce the size of the outer diameter of the branching member and the whole branching apparatus so that it can be easily installed even in a narrow space such as a pipeline.

The present invention is a housing having a branch member coupling portion formed with a spiral groove in a predetermined section of the inner peripheral surface of the cylindrical member, and screwed to the branch member coupling portion of the housing in a state fixed to the central tension line of the optical cable at a predetermined interval, A branch portion having a plurality of alignment holes for branching some optical fibers extending from the optical cable into single fiber or a plurality of multi-fiber fibers is provided, and the remaining optical fibers of the optical cable which do not branch through the alignment holes are collectively arranged outside the branch. A communication part provided to pass through is provided with a plurality of branch members which sequentially branch the optical fiber extending from the optical cable, and a plurality of flash tubes which protect the plurality of single-core or multi-core optical fibers branched from the optical cable introduced into the housing. Has

According to the present invention, since the optical cable branching device and its use method sequentially branch the plurality of optical fibers embedded in the optical cable by several branching members, the outer diameter of the branching member and the whole branching apparatus is reduced, and the conduit It can be easily laid even in narrow spaces such as inside.

Description

Optical cable branching device and its use

The present invention relates to an optical cable branching apparatus and a method of using the same. More particularly, the present invention relates to an optical cable branching apparatus and a method of using the optical cable branching apparatus which can sequentially branch a plurality of optical fibers embedded in the optical cable by several branching members. .

In general, optical communication transmits light and exchanges information, and optical fibers made of glass fibers serve as mediators, which can transmit tens of thousands of times more information than electric communication by current coaxial cable.

Such optical cables are classified into outdoor cables installed outdoors, indoor cables connected from indoor terminal boxes to equipment, and cable for entering cables from outdoor junction boxes to indoor terminal boxes.

The outdoor cable is again classified into a cable installed in the air, a cable buried underground, and a cable installed on the sea floor. Indoor cables are cables installed inside buildings such as buildings, such as ceilings, floors, walls, and the like. Cables for connecting cables between outdoor cables and indoor cables are used for connection between short distances.

The incoming cable is an optical cable that is connected to the terminal box of the indoor from the junction box of the outdoor cable is used a lot of optical end cable, such optical end cable so that each optical fiber built therein corresponds to the connection terminal of the terminal box in the premises one to one. Since it must be connected, it must be branched into a plurality of single-fiber fibers at some point, and a branching device of a certain type is installed to protect the optical fiber at the point where the multi-fiber fibers branch to the single-fiber fibers.

1 is an exploded perspective view of a conventional optical cable branching device, and FIG. 2 is a cross-sectional view of a conventional optical cable branching device.

Referring to this, the optical cable branching device has a plurality of protective tubes corresponding to the number of optical fibers 53 embedded in the optical housing 50 in a state in which the spiral housing 10 and the spiral housing inside the cylindrical housing 10 are coupled to each other. The branch member 60 is provided with a 64, the leading member 30 and the cap 40 for holding the outer shell 52 of the optical cable.

The housing 10 is provided with an inlet 15 through which the optical cable 50 is introduced at one end thereof, and an outlet 17 through which the incoming optical cable 50 is constantly branched and provided at the other end thereof. A branch member engaging portion 12 having a spiral groove is provided at a predetermined position on the inner circumferential surface, and an incoming member engaging portion 13 having a spiral groove is formed on the inner circumferential surface toward the inlet 15 from the end portion over a predetermined section. Is formed.

Branch member 60 is provided with a center tension line coupling hole 61 penetrated on the center axis in the state that helix is coupled to the branch member coupling portion 12 of the housing 10, the center tension line coupling A plurality of alignment holes 63 formed in the direction parallel to the ball 61 is provided.

At this time, each of the plurality of alignment holes 63, one protective tube 64 is inserted into each of the fixing is fixed with an adhesive, in each of the protective tube 64, the optical fiber 53 is extended from the optical cable 50 to extend Is inserted and inserted.

The inlet member 30 is provided with a screw portion 33 coupled to the inlet member coupling portion 13 of the housing 10 on the outer circumferential surface of the distal end portion, and from the rear surface of the screw portion 33 in the direction opposite to the inlet of the optical cable 50. A protruding clamp portion is provided.

The clamp part is tapered at a predetermined angle so as to protrude in the direction opposite to the optical cable 50 entry from the rear surface of the screw part 33 and tapers at a predetermined angle, and extends in the center line direction from the end of the inclined surface 35. In the center thereof is in contact with the outer circumferential surface of the optical cable 50 is extended in the inward direction of the housing 10 from the flange 36 and the inlet opening 37 is formed in the inlet 37 which the optical cable 50 is introduced It consists of the boss 38.

In addition, the clamp portion is formed with a plurality of incision groove 39 is cut in the longitudinal direction is made so that the cap 40 is retracted in the center line direction while constantly elastically deformed when pressing the clamp portion in the center line direction.

The cap 40 is provided with a screw portion 43 that is helically coupled to the lead member engaging portion 13 of the housing 10 on the outer peripheral surface of the tip portion, the inclined surface 35 of the lead member from the tip of the screw portion 43 Tightening portion 45 forming a taper corresponding to the formed.

A bolt head-shaped pivoting portion 44 is provided on the outer circumferential surface behind the screw portion 43 of the cap 40 so as to easily couple the cap 40 to the housing 10, and is rearward from the pivoting portion 44. As an extension, the extension part 47 which retracts in the center line direction is provided. At the end of the extension part 47, a predetermined inlet 48 through which the optical cable 50 is introduced into the housing 10 is formed.

Therefore, when the cap 40 is coupled with a constant force to be in close contact with the inlet member 30, the tightening portion 45 of the cap 40 is pressed to retract the clamp portion of the inlet member in the center line direction of the optical cable The outer shell 52 is fixed.

However, in order to branch the optical cable 50 by using the optical cable branching device of the above structure, alignment holes 63 must be formed on the branch members 60 as many as the number of optical fibers 53 embedded in the optical cable 50. However, when the number of optical fibers 53 embedded in the optical cable 50 increases, the outer diameter sizes of the branch member 60 and the whole branching device increase, so that the branching device passes through a narrow space such as a pipeline. There is a problem that is difficult to install.

In particular, recently, an optical cable 50 having more optical cores is required. In order to branch and install such an optical cable 50 into a conduit, there is a problem that an outer diameter of the optical cable branching device must be necessarily reduced.

The main object of the present invention is to branch the optical fiber embedded in the optical cable sequentially by several branching members, thereby reducing the outer diameter of the branching member and the whole branching device, thereby easily laying them in a narrow space such as a pipeline. It is to provide an optical cable branching device and a method of using the same.

1 is an exploded perspective view of a conventional optical cable branching device,

2 is a cross-sectional view of a conventional optical cable branching device,

3 is an exploded perspective view of an optical cable branching apparatus according to the present invention;

4 is a cross-sectional view of an optical cable branching apparatus according to the present invention;

5 is a flowchart illustrating a method of using an optical cable branching device according to the present invention.

*** Explanation of symbols for the main parts of the drawing ***

10 housing 12 branch member coupling portion

13: incoming member coupler 20: branch member

21: tension line coupling hole 23: alignment hole

24: protective tube 25: communication part

30: drawing member 40: cap

50: optical cable 53: optical fiber

An optical cable branching device according to the present invention is a branching device in which a multi-core optical cable is introduced and branched into a single-core optical fiber or several multi-core optical fibers, comprising: a housing having a branch member coupling part having a spiral groove formed in a predetermined section on the inner circumferential surface of the cylindrical member, and the optical cable A branch having a plurality of alignment holes which are screwed to the branch member coupling portion of the housing at fixed intervals at a center tension line of the optical fiber, and on the face of which some optical fibers extending from the optical cable branch into single or multiple multi-fiber fibers; A plurality of branching members are provided on the outer side of the branch portion, and a communication portion for collectively passing the remaining optical fibers of the optical cable not branched through the alignment holes is provided so as to sequentially branch the optical fiber extending from the optical cable, and the housing. From the optical cable It characterized gidoen a plurality of block flash tube to protect the plurality of single-core or multi-core optical fiber provided with optical fibers.

In the optical cable branching device according to the present invention, the protective tube is inserted into the alignment hole of the branching member and is fixed with a curing agent.

In the optical cable branching device according to the present invention, the branching member is fitted to the outer peripheral surface of the center tension line and is fixed with an adhesive.

In the optical cable branching method according to the present invention, in the conventional optical cable branching method for branching a plurality of single-core optical fibers extending from the optical cable, a plurality of protective tube is inserted to pass through the communication portion and the alignment hole of the branch member spaced at regular intervals. However, each protective tube is a flexible tube installation step of being installed to be fixed to pass through any one of the branch member alignment holes of the plurality of branch members, and each of the single fiber or a plurality of single fiber optical fibers extending from the optical cable to the protective tube And inserting the optical fiber insertion step and inserting the plurality of branch members into the outer peripheral surface of the center tension line of the optical cable at a predetermined interval and then installing the branch member for coupling to the branch member coupling part of the housing.

Hereinafter, with reference to the accompanying drawings for a preferred embodiment of the optical cable branching apparatus according to the present invention will be described in detail.

3 is an exploded perspective view of the optical cable branching apparatus according to the present invention.

Referring to this, the branching device is screwed into the cylindrical housing 10 and the plurality of branch members 20 to sequentially divide the plurality of optical fibers 53 built in the optical cable 50 in several steps and It is installed on the inlet 15 side of the housing 10 is composed of a retracting member 30 and the cap 40 to hold the outer shell of the optical cable 50.

The housing 10 is provided with an inlet 15 through which the optical cable 50 is introduced at one end thereof, and an outlet 17 through which the incoming optical cable 50 is constantly branched and provided at the other end thereof. A branch member engaging portion 12 having a spiral groove is provided at a predetermined position on the inner circumferential surface, and an incoming member engaging portion 13 having a spiral groove is formed on the inner circumferential surface toward the inlet 15 from the end portion over a predetermined section. Is formed.

Branch member 20 is a plurality of members for sequentially branching the optical fiber 53 embedded in the optical cable 50 in several steps, the center tension line coupling hole coupled to the center tension line 51 on the center axis A branch 21 is formed, and a branch portion 22 in which a plurality of alignment holes 23 are formed within a predetermined radius is provided around the center tensile line coupling hole 21, and the branch portion 22 is the same from the center line. A plurality of communication portions 25 formed at regular intervals on a radius are provided, and a coupling portion 27 that is spirally coupled to the branch member coupling portion 12 of the housing is provided around the communication portion 25.

Therefore, the plurality of branch members 20 are spirally coupled to the branch member coupling portion 12 of the housing in a state of being fixed at a predetermined interval on the center tensile line 51, and the alignment holes 23 of the branch members. One protective tube 24 is installed in each of the one protective tube 24 is inserted and installed only in the alignment holes 23 of any one of the branch members 20 of the plurality of branch members 20 installed spaced apart a predetermined interval. When passing through the other branch member 20, it passes through the communication portion (25).

At this time, the protective tube 24 is fixed with a special adhesive in the state of being inserted into any one of the branch member alignment holes 23, the optical fiber 53 extending from the optical cable 50 is inserted into the protective tube 24. do.

For example, if there are 100 protective tubes 24 and they are installed as three branch members 20, only 33 protective tubes 24 are inserted into the alignment holes 23 in each branch member 20. The rest is inserted into the other branch member 20 through the communication portion 25, as a result, only 33 protection tubes 24 in one place compared to 100 protection tubes 24 in one place By reducing the diameter, the diameter can be reduced.

That is, in the past, 100 protective tubes 24 were inserted into only one branch member, so that the diameter was required. However, in the present invention, only the diameter divided by the number of the branch members 20 is required, thereby reducing the overall diameter. It becomes possible.

The inlet member 30 is provided with a screw portion 33 coupled to the inlet member coupling portion 13 of the housing 10 on the outer circumferential surface of the distal end portion, and from the rear surface of the screw portion 33 in the direction opposite to the inlet of the optical cable 50. A protruding clamp portion is provided.

The clamp portion protrudes from the rear surface of the screw portion 33 in the opposite direction to the inlet of the optical cable 50 and forms an inclined surface 35 of which taper is formed at a predetermined angle so as to retract in the center line direction, and extends in the center line direction from the end of the inclined surface 35. In the center thereof is in contact with the outer circumferential surface of the optical cable 50 is extended in the inward direction of the housing 10 from the flange 36 and the inlet opening 37 is formed in the inlet 37 which the optical cable 50 is introduced It consists of the boss 38.

In addition, the clamp portion is formed with a plurality of incision groove 39 is cut in the longitudinal direction is made so that the cap 40 is retracted in the center line direction while constantly elastically deformed when pressing the clamp portion in the center line direction.

The cap 40 is provided with a screw portion 43 that is helically coupled to the lead member engaging portion 13 of the housing 10 on the outer peripheral surface of the tip portion, the inclined surface 35 of the lead member from the tip of the screw portion 43 Tightening portion 45 forming a taper corresponding to the formed.

A bolt head-shaped pivoting portion 44 is provided on the outer circumferential surface behind the screw portion 43 of the cap 40 so as to easily couple the cap 40 to the housing 10, and is rearward from the pivoting portion 44. As an extension, the extension part 47 which retracts in the center line direction is provided. At the end of the extension part 47, a predetermined inlet 48 through which the optical end cable 50 is introduced into the housing 10 is formed.

Therefore, when the cap 40 is coupled with a constant force so as to be in close contact with the inlet member 30, the pressing portion 45 of the cap 40 is pressed to retract the clamp portion of the inlet member 30 in the center line direction. The outer shell 52 of the optical cable is fixed.

The method of using the optical cable branch member and its working example according to the present invention having the above configuration will be described in detail with reference to the accompanying drawings.

4 is a cross-sectional view of an optical cable branching apparatus according to the present invention, Figure 5 is a flow chart showing a method of using the optical cable branching apparatus according to the present invention.

Referring to this, first, the cap 40 and the leading member 30 are sequentially inserted on the outer circumferential surface of the optical cable 50 so as to be positioned inside a predetermined length, and a plurality of branch members (c) are formed at the center tensile line 51 of the optical cable. 20) to be spaced apart at regular intervals (ST-1).

Subsequently, the protective tube 24 is fixed with a special adhesive in such a state that the protective tube 24 is inserted into any one of the branch member alignment holes 23 of the plurality of branch members 20, and the communicating portion is passed through the remaining branch members 20. It is installed to pass through the (25) (ST-2).

A plurality of optical fibers 53 extending from the optical cable 50 are sequentially inserted into the protective tube 24 to branch (ST-3).

As such, when the optical cable branching operation is completed, the plurality of branch members 20 and the pulling member 30 are spirally coupled to the branch member coupling portion 12 and the lead member coupling portion 13 of the housing 10, respectively ( ST-4).

Subsequently, when the cap 40 is tightened to be in close contact with the inlet member 30, the cap 45 of the cap is pressed and fixed to be in close contact with the inclined surface 35 of the inlet member. The clamp portion of the while holding in the direction of the center line to hold the shell of the optical cable 50 (ST-5).

According to the present invention, since the optical cable branching device and the method of using the same are sequentially branched by a plurality of branching members with a plurality of optical fibers embedded in the optical cable, the outer diameter of the branching member and the whole branching device is reduced, Therefore, such a branching device can be easily installed even in a narrow space such as a pipeline.

Claims (4)

In the optical cable splitting device comprising a housing 10 configured to be introduced into the multi-core optical cable 50 is branched into a single fiber (53) or several multi-fiber fiber, A protective tube 24 is formed so as to penetrate through the center tension line 51 of the optical cable in the center and is screwed at a predetermined interval in the coupling portion formed on the inner surface of the housing 10 and the optical fiber is inserted therein. A plurality of alignment holes 23 are formed so as not to overlap and includes a plurality of branch members 20 in which a communication portion 25 is formed so that a plurality of protection tubes 24 can pass through the outer periphery of the alignment holes 23 at the same time. Optical cable splitter. The method of claim 1, The protective tube (24) is inserted into the alignment hole (23) of the branch member is fixed to the optical cable, characterized in that fixed with a curing agent. The method of claim 1, The branch member 20 is inserted into the outer peripheral surface of the center tension line 51, the optical cable branching device, characterized in that installed fixed with an adhesive. In the optical cable branching method of branching a plurality of single-core optical fibers 53 extending from the optical cable 50 by a branching member provided in the housing 10, Fixing the plurality of branch members 20 having the alignment holes 23 and the communication portions 25 formed in the housing 10 at regular intervals; The communication tube 25 and the alignment holes 23 formed in the plurality of branch members 20 are inserted to pass through each of the protective tubes 24, and each of the protective tubes 24 includes a plurality of branch members 20. A protective tube installation step of being installed to be fixed by passing through any one of the branch member alignment holes 23; And inserting each single core fiber (53) or a plurality of single core fibers (53) extending from the optical cable (50) into the protective tube (24).