JPS5811906A - Clamping part of nonmetallic optical cable incorporated with optical fiber core coated with frp - Google Patents

Abstract

PURPOSE:To prevent optical fibers from the increment of transmission loss by adhering optical fiber cores coated with thermosetting resin reinforced by glass fiber which constitute a nonmetallic optical cable with fillers at the inside of a mold member to clamp the optical fiber cores without using a mechanical clamp. CONSTITUTION:A clamping part 10 of a nonmetallic optical cable incorporated with fiber cores coated with thermosetting resin (FRP) reinforced by glass fiber consists of a cable constituting member 14 composed of fiber cores coated with FRP and high tension fiber flux or FRP tension members and a plastic sheath 16. The clamping part 10 is fitted to the sheath of a clamping end of a nonmetallic optical cable 12 and composed of a sleeve-like mold member 20 with which the exposed part of the cable constituting member 14 is coated, fillers 20 with which the inside of the mold member 18 is filled so as to bury the cable constituting member 14 and a protective sleeve 22 expanded along the sheath 16 of the nonmetallic optical cable.

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a retaining group for a non-metallic optical cable containing F'RP combed optical fiber cores.

Recently, FRP elliptical fiber cores with FRP (glass fiber-reinforced thermosetting paulownia resin) coated around the optical fibers have been developed.
A non-metallic optical cable was developed in which a number of f:yr fibers were assembled and a non-metallic sheath was sheathed thereon. In this optical cable, the protective sheath for the optical fiber is made of FRP, so it is strong against tension and is suitable for aerial installation. As a means of securing such a non-metallic optical cable to a steel tower, etc., it is generally considered to use a clamp fitting, but if such an optical cable is firmly tightened with a clamp fitting, the F'RP coating of the core wire may be damaged. Furthermore, if the cable is simply tightened with a clamp fitting, there is a risk that the cable will be damaged by one clamp per clamp when the cable vibrates due to wind, making it impossible to maintain reliability over a long period of time. .

The purpose of the present invention is to develop a non-metallic optical fiber cable containing F'RI) coated optical fiber, which can maintain the retaining force over a long period of time without completely damaging the FIIP coated optical fiber core. All stops are provided.

Refer to all the drawings for the embodiments of the present invention (2 and 1 and 1)
The drawing shows a retaining part 10 of a non-metallic optical cable containing an FRP broken optical fiber core according to the present invention, and the non-metallic optical cable 12 has a 14P coated optical fiber core and M!/M force delicate fiber depending on the number of fibers. Alternatively, the non-metallic optical cable 12 is separated from the cable component 14 which is made of FRP and a plastic sheath 16 coated with VC. The cable component 14 is unrolled.

The retainer g 1.0 is placed 11) on the sheath of the retainer end of the non-metallic optical cable 12 and is attached to the cable component 14.
The sleeve-shaped mold member 18 that covers the exposed part of rO, the cable structure ↑ ] Port 1 with sheath 16 at the pulling end of the optical cable
A protective sleeve 22 is attached to the cable and extends along the sheath 16 of the non-metallic optical cable.

The mold member 18il'j' can be made of metal or plastic and has a greasy inlet 18a in its part, through which the filling material 20 is injected.

The filler 20 can be made of epoxy resin, unsaturated polyester resin, etc., and when this filler is injected into the mold member 18 and hardens, the mold member 18 and the pull component 1
4 to create a retaining force.

Reference numeral 24 in the figure is a spacer that facilitates the flow of the filler into the exposed cable component.

The protective sleeve 22 is made of rubber or the like, and its thickness decreases as it moves away from the mold member 18, and its rigidity decreases. As shown in the figure, it is preferable for this protective sleeve to have pleated protrusions 22a on the outer surface of the protective sleeve.If this is done, the creepage distance will be increased and the insulation resistance value will be reduced due to icing and salt damage. Since the protective sleeve 22 and the mold member 18 engage with each other at the protrusions 22a, the strength of the connection is increased. Further, the protection sleeve 22 may be in contact with the sheath 16 or may not be bonded to the sheath 16.

According to the present invention, as described above, the FRP-coated optical fiber cores constituting the non-metallic optical cable are mechanically held in place by adhesion to the filler in the member, so a large amount of tightening is required. will not be challenged by force,
Also, when filling and curing the filler, a certain amount of heat and pressure is applied to the optical fiber core wire, but since the core wire has class a F)tP, it can withstand this for a light amount of time, which increases the transmission loss of the optical fiber. Nor. 1. Since the mold member and cable sheath are covered with a protective sheath, there is no risk of damage to the retaining part due to vibration, and a stable retaining part can be formed over a long period of time.

[Brief explanation of the drawing]

The drawing is a cross-sectional view of an FRP-coated optical fiber cored metal optical cable according to the present invention. lO...Retaining capital, 12...Non-metal optical cable, 14...Cable component 4"
A'% 16... Sheath, 18...
Mold member, 2υ...Filling material, 22...Protective sleeve, 22a...Protrusion.

Claims (3)

[Claims] (1) The cable component that is exposed by peeling off the sheath of the non-metallic optical cable, which has several cracks in the sheath at the retaining end of the non-metallic optical fiber containing FRP optical fiber core, is used as a core-shaped member and the cable component as described above. a thermosetting resin filler filled into the mold member so as to embed the member;
A retaining portion for a non-metallic optical cable containing an FRP covered optical fiber core, comprising an insurance sleeve attached between the mold member and a sheath at the retaining end of the non-metallic optical cable and extending along the sheath of the non-metallic optical cable. (2) The retainer M for a non-metallic optical cable containing an FRP-covered optical fiber core according to claim 1, wherein the bending rigidity of the protective sleeve decreases as it moves away from the mold member. (3) The retainer for a non-metallic optical cable containing an Ii'' RP coated optical fiber core according to claim 1, wherein the protective sleeve has pleated projections on its outer surface.