KR100342592B1 - Tight bound fluorescent cable - Google Patents

Abstract

The present invention relates to a tight bound optical cable, the object of which can be manufactured by a simple manufacturing equipment, to increase the optical fiber density inside such optical cable.

According to the present invention, in a conventional ultra-core fiber cable having a center tensile line, a predetermined coating portion is provided on the outer circumferential surface of a plurality of single-core optical fibers, and a predetermined neck portion is formed between the coating portion and the coating portion of adjacent single-core optical fibers. And a plurality of tight buffer optical fibers consisting of a plurality of tight buffer optical fibers integrally formed by a predetermined coating layer and spirally arranged along the longitudinal direction on the outer peripheral surface of the center tension line. Have

According to the present invention, since a plurality of single-fiber optical fibers are formed integrally by a predetermined coating layer in a linearly positioned state, a separate stranding device for spirally arranging the single-fiber optical fibers is unnecessary. In the space between the single optical fibers inside the unit, a tensile chamber made of high strength aramid yarn is inserted so that a separate sub-tension line is unnecessary, thereby increasing the optical fiber density of the optical cable.

Description

Tight bound optical cable

The present invention relates to an ultra multi-core tight bound optical cable, and more particularly, a plurality of single-core optical fibers are integrally connected by a predetermined neck portion to form a predetermined coating layer on the circumferential surface thereof in a state of stacking a plurality of single optical fibers. The present invention relates to a tight bound optical cable in which a plurality of bundled optical fiber units are spirally arranged on a peripheral surface of a central tensile line to form an optical cable, whereby optical fiber density is high and manufacturing equipment is simplified.

In general, the demand for optical cables is gradually increasing due to the spread of subscriber networks related to various communication services such as LAN, LOCAL AREA NETWORK, bidirectional communication, and video call.

There are various types of such optical fiber cables, depending on the use, and are largely divided into a cable installed outdoors, a cable installed indoors and a cable for entry installed between the outdoors and indoors.

Among these optical cables, outdoor cables may be installed for several tens of kilometers or thousands of kilometers, and when they are buried underground, they are dug into the ground and buried in soil. When an abnormality occurs in a track, it is very difficult to check and repair and replace cables. There is a very difficult disadvantage.

Therefore, to compensate for these disadvantages, a communication tunnel is artificially installed underground and a cable is installed in the tunnel (communication port).

In this case, the maintenance and replacement of the cable is easy, but there is a problem that the overall construction cost is enormous.

Therefore, in recent years, the optical cable construction method is mainly used to install a hollow pipe (Pipe) having a constant diameter in the ground and then insert the cable into the pipe.

The pipelines are installed between manholes and manholes at regular intervals because they are buried in lengths of hundreds to thousands of kilometers.

In this case, the rope is inserted into the pipeline, and the pipeline is buried underground, and the cable is installed in the pipeline by pulling and connecting the optical cable to the end of the rope.

In addition, in the case of the incoming optical cable, since the cable from the outdoor cable to the terminal box inside the building must be installed, a predetermined pipeline is formed through the wall of the building and drawn into the building.

Therefore, in order to install the optical cable into a conduit having a narrow space, it is a problem that has recently been significantly highlighted in recent years that the diameter of the optical cable should be reduced.

1 is a perspective view of an optical cable having a conventional tight buffer optical fiber.

Referring to this, the optical cable has a central tensile line 31 made of a steel wire or a high strength synthetic resin is disposed on the central axis line, a plurality of tight buffer type optical fiber 40 unit is in close contact with each other on the outer peripheral surface of the central tensile line 31 It is positioned so as to be covered by a predetermined coating layer 45 in a spirally twisted state along the longitudinal direction.

Each of the tight buffer optical fiber 40 units has a sub-tension line 41 made of steel wire or high strength synthetic resin disposed on a center axis line, and a plurality of single-core optical fibers 43 closely adhere to each other on the outer circumferential surface of the sub-tension line 41. It is placed so as to be in close contact with each other by a predetermined coating layer 45 in a spirally twisted state along the longitudinal direction.

Thus, each tight buffer optical fiber 40 unit is arranged by twisting spirally around the center tensile line 31, and the single core optical fiber 43 in each tight buffer optical fiber 40 unit is sub-tension line 41 The reason for the helical twisting on the circumferential surface is that the material of the center tensile wire 31 or the sub tension wire 41 and the material of the optical fiber 43 are different from each other, so that the coefficient of thermal expansion is different. This is because when the coefficient is different, stress due to thermal expansion is generated inside the optical fiber 43, thereby shortening the life of the optical fiber and changing optical characteristics.

The coating layer of the outer surface of the optical cable is made of aluminum or steel to mitigate moisture penetration and external impact force on the waterproof layer 34 coated with a waterproof tape to prevent moisture penetration therein, and the outer peripheral surface of the waterproof layer 34. The formed metal coating layer 35 is formed, and in the outermost layer, a polystyrene (PE) coating layer 36 is formed.

Accordingly, in order to manufacture the optical cable, a plurality of tight buffer type optical fiber 40 units are spirally arranged on the peripheral surface of the center tensile line 31, and a plurality of single core optical fibers 43 are formed in each tight buffer type optical fiber 40 unit. Since expensive stranding equipment for twisting the spirals must be provided separately, there is a problem that the manufacturing equipment of the optical cable is complicated.

In addition, in the optical cable having the above structure, since the tight buffer type optical fiber 40 unit has to be provided with a subtension line 41 made of steel wire or high strength synthetic fiber therein, there is a problem that the optical fiber density of the optical cable is lowered.

The main object of the present invention is to provide a predetermined coating layer on the circumferential surface of a plurality of single-fiber fibers in the form of a bundle, so that no separate stranding equipment for spirally arranging the single-fiber fibers is provided. The manufacturing equipment that is not required provides a simple tight bound optical cable.

In addition, by inserting a tension chamber made of high-strength aramid yarn in the space between the single optical fiber inside the unit to correspond to the external tensile force, it is possible to increase the optical fiber density by reducing the space occupied by the sub-tension line, etc. It is to provide a tight bound optical cable.

1 is a perspective view of an optical cable having a conventional tight-buffered optical fiber,

2 is a cross-sectional view of a tight-bound optical cable according to the present invention;

3 is a cross-sectional view of a modification of the tight bound optical cable according to the present invention.

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

10: bundled optical fiber 11: single core optical fiber

13 coating layer 15 neck portion

17: coating layer 19: tight bound optical fiber

29: tension chamber 31: center tensile

According to the present invention, in a conventional ultra-core fiber cable having a center tensile line, a predetermined coating portion is provided on the outer circumferential surface of a plurality of single-core optical fibers, and a predetermined neck portion is formed between the coating portion and the coating portion of adjacent single-core optical fibers. And a plurality of tight buffer optical fibers consisting of a plurality of tight buffer optical fibers integrally formed by a predetermined coating layer and spirally arranged along the longitudinal direction on the outer peripheral surface of the center tension line. Have

In the present invention, the bundle-type optical fiber has a feature in which a plurality of strands of tension chamber are inserted.

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

2 is a cross-sectional view of a tight bound optical cable according to the present invention, Figure 3 is a cross-sectional view showing a modification of the tight bound optical cable according to the present invention.

Referring to this, the optical cable has a central tensile line 31 made of steel wire or high strength synthetic resin is disposed on the central axis, and the plurality of bundled optical fiber 10 units are in close contact with each other on the outer peripheral surface of the central tensile line 31. And covered by a predetermined outer skin layer in a spirally twisted state along the longitudinal direction.

At this time, each of the bundled optical fiber 10 is a plurality of tight bound optical fiber 19 is built, the tight-bound optical fiber 19 is a predetermined coating portion on the outer peripheral surface of the plurality of single-core optical fiber (11) 13 is formed, and a predetermined neck portion 15 is formed between the coating portions 13 of the single-core optical fibers adjacent to each other to form a single body.

Further, in the modification of the optical cable, by placing the tension chamber 29 made of a plurality of strands of aramid yarn between each tight bound optical fiber 19 in the bundled optical fiber 10, it is made to correspond to the external tensile force.

The coating layer of the outer surface of the optical cable is made of aluminum or steel to mitigate moisture penetration and external impact force on the waterproof layer 34 coated with a waterproof tape to prevent moisture penetration therein, and the outer peripheral surface of the waterproof layer 34. The formed metal coating layer 35 is formed, and in the outermost layer, a polystyrene (PE) coating layer 36 is formed.

When described in detail with reference to the accompanying drawings for the working example of the present invention by the above configuration as follows.

The optical cable is composed of a plurality of bundled optical fiber 10 units in close contact with each other on the outer peripheral surface of the center tensile line 31, each of the bundled optical fiber 10 unit is a plurality of single-core optical fibers 11 in a linear position In this state, a predetermined coating layer 17 is formed on the circumferential surface thereof in a state where a plurality of tight bound optical fibers 19 are integrally formed by a predetermined neck portion 15.

Therefore, each bundle type optical fiber 10 unit is made so as to correspond to the external force by inserting a high-strength tension chamber 29 in the extra space in a state in which a plurality of single-fiber optical fibers 11 are arranged in close contact with each other. No subtension line or the like is necessary.

In addition, since the bundle type optical fiber 10 unit is manufactured by being coated with a predetermined coating layer 17 in a state where a plurality of single-core optical fibers 11 are linearly placed, to arrange each single-core optical fibers 11 in a spiral manner. There is no need for a separate stranding device.

According to the present invention, since a plurality of single-core optical fibers are manufactured in one piece by a predetermined coating layer in a linearly positioned state, separate stranding equipment for disposing each single-fiber optical fibers in a spiral manner as in the related art. Is unnecessary, which simplifies the manufacturing equipment.

In addition, by inserting a tension chamber made of high-strength aramid yarn into the space inside the unit so as to cope with the external tensile force, the space occupied by a separate sub-tension line is unnecessary as in the prior art, so that the optical fiber density of the optical cable is increased. do.

Claims (2)

In a conventional super multi-core optical cable having a center tension line 31 A predetermined coating part 13 is provided on an outer circumferential surface of the plurality of single core optical fibers 11, and a predetermined neck part 15 is formed between the coating part 13 and the coating part 13 of the adjacent single core optical fiber. A plurality of tight bound optical fibers 19 integrally formed; And a plurality of bundled optical fibers 10 in which the plurality of tight buffer optical fibers are integrally formed by a predetermined coating layer 17 on the outer peripheral surface of the central tension line 31 in a spiral manner. Tight bound optical fiber cable. The method of claim 1, Tight bound optical cable, characterized in that the bundle of the tension chamber 29 is inserted into a plurality of strands in the optical fiber 10.