KR100272771B1 - Preconnectionized cable assembly for multi cored optical fiber - Google Patents

Abstract

PURPOSE: A pre-connected cable assembly of an external extension line type optical cable is provided to be capable of being frequently used when installed in locations receiving a great tension force by effectively anchoring the external extension line to a main body using an extension line anchoring device having clamp holes. CONSTITUTION: The external extension line type optical cable(10) is coupled on one side of a cable anchor(20), which comprises passages for inserting optical fibers(13) and a plurality of clamp holes(21) for inserting extension lines(11). A tapered main body(30) is connected to the cable anchor(20) and through which the optical fibers(13) pass. A plurality of optical connectors(S) are respectively coupled to one ends of the optical fibers(13). A cap(40) is coupled to be dismounted to the main body(30) for protecting the optical connectors(S).

Description

Cluster Assembly of Externally Drawn Linear Optical Cable

The present invention relates to a multi-core optical fiber cable coupled to a branched optical connector to protect the optical fiber from damage in the process of laying it when wiring the outdoor multi-core optical cable for the construction of the optical subscriber line. More particularly, the present invention relates to a star cluster assembly of an external tensile linear optical cable for coupling an external tensile linear optical cable of an optical cable to an incoming optical cable.

In general, the demand for fiber optic cable is gradually increasing due to the spread of subscriber networks related to various communication services such as local area network (LAN), bidirectional communication, and video call.

There are various kinds of optical fiber cables according to the use, and are classified into a cable installed outdoors, a cable installed indoors, and a cable for entry installed outdoors and indoors. 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.

As described above, the outdoor optical fiber cable has a tensile wire inside or outside to sufficiently endure the external environment, that is, natural phenomenon, that is, wind, snow, rain, impact, or tensile force, and according to the position of the tension wire, It is divided into tensile linear (ISM) or external tensile linear (ESM).

In particular, the external tensile linear (ESM) is mainly used in the air installation where the tension cable is embedded in the outside of the cable, the optical cable is subjected to a high tensile force.

On the other hand, the multi-core optical fiber cable is wired indoors by optically connecting optical fibers using a connector or a splicing or fusion splicing, etc. to quickly open the optical path after completing the installation. When installing indoors, the space for installation is often small. Therefore, it is not necessary to grind the connector plug by grinding the optical fiber in the field and connect it with the connector or splicing in advance. There is a need.

Such a star cable assembly is disclosed in detail in Korean Patent Application No. 97-51191. Briefly describing the prior art, a wedging member having a passage through which each optical fiber penetrates and a clamp hole into which a tension line is inserted, fastening means for fixing the wedging member to the optical fiber cable, and coupled to an end of the optical fiber penetrating the passage. And a cap coupled to the wedging member to protect the optical connector.

However, the conventional star cluster cable assembly as described above is mainly for connecting the internal tensile linear optical cable, there is a structural difficulty in the connection of the external tensile linear optical cable having a tension line on the outside.

Therefore, the present invention has been devised to solve the above problems.

It is an object of the present invention to provide a star assembly of an external tensile linear optical cable which is mainly used during air laying because the tension cable is embedded in the outside of the cable and the optical cable receives a lot of tensile force.

1 is a perspective view schematically illustrating a star cluster assembly of an external tensile linear optical cable coupled with a cable anchor according to the present invention.

Figure 2 is a cross-sectional view showing the star cluster assembly of the external tension linear optical cable coupled to the cable anchoring according to the present invention.

3A is a perspective view of a cable anchor in accordance with the present invention.

Figure 3b is a partially exploded perspective view schematically showing a state in which the optical cable is coupled to the cable anchor according to the present invention.

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

10: optical cable 11: tensile

13: optical fiber 20: cable holder

21: Clamp hole 22a, 22b, 22c: Threaded

23: Through hole 24: Screw

30: Body 40: Cap

41: Drag ring S: Accessor

According to an object of the present invention, there is provided a means for implementing a cluster assembly of an external tensile linear optical cable, comprising: a cable anchor having a passage through which each optical fiber penetrates and a plurality of clamp holes through which tension lines are inserted and fixed;

A main body having the cable fixing unit coupled to one side and having an optical fiber penetrating therebetween, the diameter of the other side being large;

An optical connector coupled to an end of the optical fiber passing through the main body;

It may be implemented as a cap detachably coupled to the main body to protect the optical connector, the interior having an empty space.

According to the present invention according to the above configuration by protecting the single-core or multi-core optical coupler coupled to each end of the multi-core optical fiber fixed to the main body by a cable fastener so that the connector together with the piping pipe or communication when laying the optical cable The optical connection is very easy because it can be inserted and immediately connected with each communication system through the optical connector.

Hereinafter, with reference to the accompanying drawings, a preferred embodiment of a star assembly for a multi-core optical fiber cable according to the present invention will be described in detail.

Referring to FIG. 1, FIG. 1 is a perspective view schematically illustrating a star cluster assembly of an external tensile linear optical cable coupled to a cable anchoring device according to the present invention.

As can be seen in the figure, reference numeral 10 is an external tensile linear optical cable with a tension line embedded in the outside, 20 is a cable anchor coupled to the end of the optical fiber cable, 30 is a body through which the optical fiber passes, and 40 is a body The cap that surrounds.

For reference, the multi-core optical fiber cable defined in the present specification is used to include both a loose tube type or a slot type cable when the optical fiber is cabled, and is a cable having a tension line on the outside of the cable.

When functionally divided components according to the present invention, first, a cable anchor for fixing one end of the external tensile linear optical cable, a body to which the optical cable fixed in the second cable anchor is inserted, and a connector coupled to the end of the third optical fiber It can be divided into a cap that blocks it from the outside for protection.

Referring to Figure 2, Figure 2 is a cross-sectional view showing the star cluster assembly of the external tension linear optical cable coupled to the cable anchor according to the present invention.

The cable holder 20 is formed in a cylindrical shape to have a plurality of clamp holes 21 integrally formed in the axial direction at the top. A thread 22a is formed in the inner diameter of the hole formed at the center to be coupled to the main body 30. The clamp hole 21 is fixed to the external tension line is inserted.

A through hole 23 for fastening the screw 24 is formed at one upper end of each of the clamp holes 21, and the tension line 11 of the optical cable 10 is inserted into the clamp hole 21 on one side. Then, the tension line 11 is bent and inserted into the clamp hole 21 on the other side, and the inserted tension line 11 is fixed by the screw 24 in the through-hole 23 above each clamp hole 21. do. The cable holder 20 is coupled to the main body 30. The main body 30 has a hollow cylindrical shape and corresponds to a screw thread 22a formed on the cable holder 20 on one side thereof. 22b is formed, and the diameter of the other side is formed larger than the inner diameter of the side couple | bonded with the said cable anchor 20, and the thread 22b is formed also in the other end.

The cap 40 is coupled to one end of the main body 30 to protect the optical fiber 13 and the connector S placed in the main body 30. A thread 22c is formed at an inner diameter of one side of the cap 40 so that the main body 30 is coupled thereto.

Although the cap 40 is not shown in the drawing, it is preferable that the aluminum material be manufactured in the form of a corrugated pipe to have flexibility. In addition, a drag ring 41 may be attached to the free end of the cap 40.

The corrugated pipe is intended to be inserted into the pipe well as the shape of the pipe 40 is deformed according to the bend of the pipe when the pipe 40 passes through the bent in the course of entering the pipe, the drag ring 41 is an optical cable (10) ) Is useful when pulling the main body 30 with a rope or the like when entering the piping pipe.

Referring to the accompanying drawings, the working example and the process of laying the optical fiber cable of the star assembly of the external tensile linear optical cable coupled to the branched optical connector (S) according to the present invention as follows.

First, a process of assembling the cable holder 20 at the end of the external tension linear optical cable 10 will be described. Stripping the jacket of the optical cable 10 to expose the tension line 11 and the optical fiber 13 to a predetermined length to expose the tension line 11 of the cable holder 20 to the clamp hole 21 and the optical fiber 13 It is inserted into the inner diameter hole of the cable holder (20).

The exposed tension line 11 is inserted into the clamp hole 21 on one side and bent and inserted into the clamp hole 21 on the other side. Then, the tension line 11 inserted is directly fixed by screw 24.

Then, when the main body 30 is screwed and coupled to the cable holder 20, the optical fiber 13 passes through the inside of the main body 30. After that, the optical connector S, that is, the splicer is connected to each end of each optical fiber 13, and the cap 40 is screwed with the main body 30 to seal it.

When the cluster assembly is assembled at the end of the optical cable 10, the rope or wire is tied to the drag ring 41 of the cap 40, the rope or wire is first inserted into the pipe pipe, and the rope or wire is pulled out. An external tension line type optical cable can be installed into the pipe, and the installed optical cable 10 can remove the cap 40 and connect the optical connector S directly to the system or the other optical fiber 13 to quickly open the line. Will be.

As described above, the star cluster assembly of the external tension line type optical cable according to the present invention effectively fixes the external tension line to the main body by a tension line fixing device having a clamp hole, and receives a lot of tensile force. The composition of star clusters is to be made.

Claims (2)

A cable anchor 20 having a passage through which the external tensile linear optical cable 10 is coupled to one side and a passage through which each optical fiber 13 passes, and a plurality of clamp holes 21 into which the tension lines 11 are inserted and fixed; ; A main body 30 having one side coupled to the cable holder 20 and having an optical fiber 13 therethrough but having a larger diameter at the other side; An optical connector S coupled to an end of the optical fiber 13 penetrating the main body 30; A star assembly of an externally stretchable optical cable, characterized in that the cap 40 is detachably coupled to the main body 30 to protect the optical connector S and has an empty space therein. The tension line of claim 1, wherein the fixing line 11 is formed with a through hole 23 formed at an upper side of each clamp hole 21 and a clamp hole 21 on one side. After inserting 11, the tension line 11 is bent and inserted into the clamp hole 21 on the other side, so that the inserted tension line 11 is fixed with a screw 24. Assembly.

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