KR20000015283U - Ribbon Ultra-Multicore Optical Cable - Google Patents

Abstract

The present invention relates to a ribbon-type super multi-core optical cable, the purpose of which is to significantly increase the optical fiber density by minimizing the space of the space between the rows and columns of the optical fiber ribbon in which a plurality of optical fiber ribbons are stacked.

The present invention is characterized in that in a conventional ultra-multi-core optical cable having a center tensile line, a plurality of optical fiber ribbon rows formed by stacking a plurality of optical fiber ribbons are arranged in a spiral so as to be in close contact with each other on the outer peripheral surface of the center tensile line.

When the present invention is applied, the ribbon type multi-core optical cable does not need a separate space between the rows and columns of the optical fiber ribbon, the optical fiber density of the optical cable is significantly increased, the optical fiber ribbon freely in the space inside the optical cable Since it flows, intensive side pressure is prevented from occurring in any part of the optical fiber ribbon.

Description

Ribbon Ultra-Multicore Optical Cable

The present invention relates to a ribbon type super multi-core optical cable, and more particularly, a plurality of optical fiber ribbon strings in which a plurality of optical fiber ribbons are stacked are arranged to be in close contact with each other on the peripheral surface of the center tension line, and thus the optical fiber density is very high. It relates to an optical cable.

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 narrow space pipe, the diameter of the optical cable must be made smaller and lighter.

1 is a cross-sectional view of a conventional ultra-core optical cable.

Referring to this, in the multi-slot optical cable, a plurality of grooves 32 having a predetermined depth are spirally formed along the outer circumferential surface of the multi-slot rod 30, and a plurality of optical fiber ribbons 11 are formed in the grooves 32. It is inserted to be stacked, and the central tensile line 31 of steel wire or high strength synthetic fiber is inserted on the central axis is configured to correspond to the external force.

In addition, a predetermined waterproofing layer 33 is formed on the outer circumferential surface of the multi-slot rod 30, and a plurality of U grooves 40 are disposed to be in close contact with each other on the outer surface of the waterproofing layer 33 to be installed in a spiral along the longitudinal direction. do.

The outer circumferential surface of the U groove 40 has a waterproof layer 34 coated with a waterproof tape to prevent moisture penetration, and is made of aluminum or steel to relieve moisture penetration and external impact on the outer circumferential surface of the waterproof layer 34. The metal coating layer 35 is formed, and a polystyrene (PE) coating layer 36 is formed on the outermost layer.

At this time, since the grooves 32 and the U grooves 40 of the multi-slot core should be formed with a predetermined width and depth so that a plurality of optical fiber ribbons 11 can be stacked to be stacked, the grooves 32 and grooves adjacent to each other are formed. The space between the 32 or the U groove 40 and the U groove 40 is essentially required to have a dead zone of a predetermined margin, and this space is a major factor for lowering the optical fiber density of the ultra multi-core optical cable.

In addition, since the grooves 32 or the U grooves 40 are inserted into the plurality of optical fiber ribbons 11 stacked therein in a spirally arranged state along the longitudinal direction of the optical cable, such grooves 32 or the U grooves. Any portion of the optical fiber ribbon 11 in contact with the inner wall surface of the 40 has a problem that the intensive side pressure is generated to leak the optical signal.

The main purpose of the present invention is to arrange a plurality of optical fiber ribbon strings in which a plurality of optical fiber ribbons are stacked so as to be in close contact with each other on the circumferential tension line of the optical fiber ribbon, so that a space of a separate margin is unnecessary between the columns and the rows of the optical fiber ribbons. It is to provide a ribbon type ultra-high fiber cable.

Another object of the present invention is to provide a ribbon-type super multi-core optical cable that is installed so that a plurality of optical fiber ribbons freely flow in the space inside the optical cable to prevent intensive side pressure from occurring in any part of the optical fiber ribbon.

Another object of the present invention is to provide a ribbon-type super multi-core optical cable that is very easy to peel off because a plurality of built-in optical fiber ribbon is exposed to the outside when only the outer skin of the optical cable is peeled off.

1 is a cross-sectional view of a conventional multi-core optical cable,

Figure 2 is a perspective view of a ribbon type multicore optical cable according to the present invention,

3 is a cross-sectional view of a ribbon-type super multi-core optical cable according to the present invention.

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

10 fiber optic ribbon column 11 fiber optic ribbon

21: center tensile line 24: waterproofing layer

25 metal coating layer 26 polystyrene coating layer

The present invention is characterized in that in a conventional ultra-multi-core optical cable having a center tensile line, a plurality of optical fiber ribbon rows formed by stacking a plurality of optical fiber ribbons are arranged in a spiral so as to be in close contact with each other on the outer peripheral surface of the center tensile line.

Hereinafter, with reference to the accompanying drawings for a preferred embodiment of the ribbon-type multi-core optical cable according to the present invention in detail as follows.

Figure 2 is a perspective view of a ribbon-type super multi-core optical cable according to the present invention.

Referring to this, the optical cable is arranged in a spiral along the longitudinal direction in a state in which a plurality of optical fiber ribbon columns 10 formed by stacking a plurality of optical fiber ribbons 11 are arranged to be in close contact with each other on the peripheral surface of the center tension line 21. The outer peripheral surface of the optical fiber ribbon row 10 is formed with a predetermined outer skin layer.

The outer layer of the optical cable has a waterproof layer 24 coated with a waterproof tape to prevent moisture penetration therein, and a metal coating layer 25 made of aluminum or steel on the outer circumferential surface of the waterproof layer 24 to correspond to external impact force. In addition, a polystyrene (PE) coating layer 26 is formed on the outermost layer.

At this time, the metal coating layer 25 is made sufficiently large as compared with the conventional metal coating layer, so that the external force or impact force applied from the outside is not transmitted to the internal optical fiber ribbon 11.

When described in detail based on the accompanying drawings for the working example of the present invention by the above configuration as follows.

3 is a cross-sectional view of a ribbon-type super multi-core optical cable according to the present invention.

Referring to this, the ribbon type ultra-multi-core optical cable is formed of a plurality of optical fiber ribbon columns 10 formed by stacking a plurality of optical fiber ribbons 11 in close contact with each other on the peripheral surface of the center tension line 21, and thus, the optical fiber ribbon columns Since no extra space is required between 10 and the column, the optical fiber density of the optical cable is significantly increased.

In addition, since the optical cable is made so as not to exceed several tens of millimeters in diameter, even when a plurality of optical fiber ribbons 11 are arranged in a spiral in a state in which the optical fiber ribbons 11 are stacked on each other, in the state where the optical fiber ribbons 11 are stacked, It will not fall to the side.

In addition, since the optical cable is installed so that the plurality of optical fiber ribbons 11 are not inserted into separate grooves or the like, the optical cables are freely flown in the space inside the optical cable, thereby preventing intensive side pressure from occurring in any part of the optical fiber ribbon 11. do.

In addition, since the optical cable is not surrounded by a separate groove or coating layer, but is arranged inside the outer layer of the optical cable, the optical fiber ribbon 11 is exposed to the outside when only the outer skin of the optical cable is peeled off when branching or connecting. It is very easy to strip the optical cable.

According to the present invention, the ribbon-type multi-core optical cable is arranged so that a plurality of optical fiber ribbon strings formed by stacking a plurality of optical fiber ribbons closely adhere to each other on the peripheral surface of a center tension line, and thus separate the rows and columns of the optical fiber ribbons. Since the space of the margin is unnecessary, the optical fiber density of the optical cable is significantly increased.

In addition, since the ribbon-type super multi-core optical cable is installed so that a plurality of optical fiber ribbons freely flow in the space inside the optical cable, intensive side pressure is prevented from occurring in any part of the optical fiber ribbon.

In addition, the ribbon-type super multi-core optical cable is very easy to peel off because the plurality of built-in optical fiber ribbon is exposed to the outside when only the outer skin of the optical cable is peeled off.

Claims (1)

In a conventional super multi-core optical cable having a center tension line 21, Ribbon-type super multi-core optical cable, characterized in that the plurality of optical fiber ribbons (11) are stacked in a spiral arrangement to be in close contact with each other on the outer peripheral surface of the center tension line (21).