KR19990057674A - Nonmetal Self Supporting Optical Cable - Google Patents

Abstract

The present invention relates to a non-metallic self-supporting optical cable, the present invention relates to a cable core, at least one tube having at least one strand of optical fiber is twisted about a center line, to wrap the host wire and the host cable in close contact with the cable core An optical cable comprising an outer sheath, the optical cable further comprising a film of a predetermined material positioned between the owner and the outer sheath to prevent slippage between the owner and the outer sheath when a tensile force is applied to the optical cable.

According to the present invention, the sliding phenomenon can be suppressed by increasing the frictional force by inserting a polymer-based film between the host ship and the outer coating.

Description

Nonmetal Self Supporting Optical Cable

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a nonmetallic self supporting optical cable, and more particularly, to a nonmetal self supporting optical cable having a predetermined film between the host wire and the outer sheath and not slipping even at high tensile force.

An optical cable is a cable for receiving an optical fiber through which a signal passes, and serves to protect the optical fiber during installation and operation, and has various structures depending on the core bow or indoor / outdoor use.

Among them, non-metallic self-supporting fiber optic cable is a type of cable with a high tensile strength, and generally tends to have a much higher tensile force in a long span of more than 1000 m between the pylon and the pylon.

1 is a cross-sectional view of a conventional non-metal self-supporting optical cable, wherein the optical cable according to FIG. 1 is twisted about a center tensile line 104 with a tube 102 having at least one optical fiber 100. It consists of a cable core consisting of a film 106 and an inner sheath 108, a lead wire 110 and an outer sheath 112, which surround the tubes to protect them. The host ship 110 is formed using high-strength tensile fibers separately from the central tension line 104 to secure the required tensile strength in the long span.

However, in the cable of high tensile strength required in the long span, the external load applied to the cable after installation is transferred to the host ship 110 due to the slip phenomenon between the host ship 110 and the outer sheath 112 in its strength. This becomes impossible and results in the outer covering breaking down.

In order to solve this problem, conventionally, the binding line 110 is closely attached to the cable core by using a binding thread between the owner line 110 and the outer sheath 112.

However, the use of the bind fibers described above causes some problems. In other words, in order to realize the high-strength optical cable required in the long span, it is necessary to apply the bind fiber very tightly to prevent the sliding phenomenon between the tensile line and the sheath at high tensile strength. Down is inevitable, and productivity is reduced. In addition, there is a limit to the production of the product due to the limitation of the production equipment.

The technical problem to be achieved by the present invention is to provide a non-metallic self-supporting optical cable that is equipped with a binding film between the host and the outer sheath in order for the host to be in close contact with the cable core.

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

2 is a cross-sectional view of a nonmetallic self-supporting optical cable according to the present invention.

In order to achieve the above technical problem, the present invention provides a cable core having at least one tube having at least one strand of optical fiber twisted about a center line, a host wire in close contact with the cable core and an outer sheath surrounding the host wire. In the optical cable comprising, the film further comprises a film of a predetermined material which is located between the host cable and the outer sheath, and prevents the slip between the host cable and the outer sheath when a tensile force is applied to the optical cable.

Hereinafter, an embodiment of the present invention will be described in detail with reference to the accompanying drawings. 2 is a cross-sectional view of a non-metal self-supporting optical cable according to the present invention, in which the tube 202 having at least one optical fiber 200 is twisted about a center tensile line 204. A cable core, a lead 210, a binding film 212, and an outer sheath 214, which are made of a film 206 and an inner sheath 208 that surround and protect the tubes 202.

The jelly compound provided to prevent moisture penetration into the tube 202 prevents friction between the optical fibers 200. At this time, each optical fiber 200 is preferably an acrylic coated optical fiber without conductivity. The material of the tube 202 is preferably a high strength plastic to protect the internal optical fiber 200, and is preferably filled with a jelly compound between each tube 202 and the central tensile line 206 to prevent moisture penetration. The center tensile line 204 is preferably a glass fiber reinforced plastics or GRP-based material that serves as a center line of the tube 202 arrangement and prevents bending. The film 206 prevents the outflow of the jelly compound. The inner sheath 208 protects the inside of the cable core from the outside and serves as the underlay of the host ship 210.

Ownership 210 is composed of aramid (aramid) fibers to support the tensile force acting on the optical cable, it is formed in a double layer to prevent the optical cable from rotating during or after installation. At this time, at least 20% of waterproof aramid fibers are used in the whole aramid fibers to prevent water penetration into the aramid fibers. Typically, the optical cable has a high tensile force because the weight of the optical cable itself, the wind pressure load by the wind, the ice snow load by the ice snow, etc. are combined. At this time, the aramid fibers have a very smooth surface due to their characteristics, so that the aramid fibers rub against the outer coating 214 to cause slippage. Therefore, even if a high tensile force acts on the optical cable, a medium capable of suppressing the above-mentioned slippage phenomenon is required. In the present invention, a polymer-based film is used as the binding film 212.

The binding film 212 is a polymer-based film that closely adheres to the host cable 210 to the cable core, and suppresses the sliding phenomenon between the outer sheath 214 and the cable holder 210 when a high tensile force is applied to the optical cable. That is, the polymer-based film is easily softened by the heat acting upon the extrusion of the outer coating, and becomes a state of mutual adhesion, and remains at the interface between the outer coating member 214 and the main conductor 210, so that the optical cable is laid. When high tensile strength is applied, it prevents possible slipping around and around the bracket. The material of the outer sheath 214 is preferably a material capable of withstanding degradation due to a tracking current.

According to the present invention, the sliding phenomenon can be suppressed by increasing the frictional force by inserting a polymer-based film between the host ship and the outer coating. In addition, since the film can be easily bonded even when produced using a long production equipment, it is possible to produce a long length of the optical cable, thereby reducing the cost.

Claims (3)

An optical cable comprising: a cable core having at least one tube having at least one strand of optical fiber twisted about a center line, a host cable in close contact with the cable core, and an outer sheath surrounding the host cable; And a film of a predetermined material positioned between the host wire and the outer sheath to prevent slippage between the owner and the outer sheath when a tensile force is applied to the optical cable. The method of claim 1, wherein the material of the film Non-metal self-supporting optical cable, characterized in that the material is softened by the heat acting during the extrusion of the outer sheath changes to a state capable of mutual adhesion. The method of claim 2, wherein the film Non-metal self-supporting optical cable characterized by a polymer-based material.