JPH0236626A - Packaging structure of optical submarine repeater unit - Google Patents

Abstract

PURPOSE:To prevent damage to an optical fiber by forming a horse shoe type slot to a step formed to an outer face of an end face plate so as to allow the optical fiber to keep a prescribed radius of curvature or over in the slot. CONSTITUTION:A step 30 swollen outward is formed to the outer face of an end face plate 13, a semi-circular or horse shoe type slot 31 is formed to the step 30, and means 34, 35 are provided, which places optical fibers 20, 21, 22 drawn from the end face plate 13 once from one end of the slot 31 to the other end and hold the optical fibers into the slot 31. while the optical fibers from the end face plate 13 are guided at least till the other end of the slot 31, the optical fibers keep a prescribed radius of curvature or over. Thus, no excess tension is exerted to a part of the optical fiber just after being drawn from the end face plate 13 of the unit, having been most susceptible to a tensile strength or a stress. Thus, damage to the optical fiber such as a broken optical fiber is prevented.

Description

[Detailed Description of the Invention] [Summary] Regarding the unit mounting structure of an optical submarine repeater that has a structure in which an optical fiber is pulled out from an internal unit to the outside of an end plate, the optical fiber pulled out from the unit during assembly is In order to prevent damage such as wire breakage due to excessive tension or stress, a step is formed on the outer surface of the end plate that rises outward from the wave surface. and a means for forming a semicircular or horse-shaped groove in the stepped portion, causing the optical fiber pulled out from the end plate to once run along from one end of the groove to the other end, and holding the optical fiber in the wave groove. an optical submarine repeater unit mounting structure characterized in that the optical fiber maintains a radius of curvature of a certain value or more while the optical fiber exits from the end plate and is guided to the other end of the groove. do.

[Industrial application field]

The present invention relates to the structure of an optical submarine repeater used in optical communications, and particularly to a unit mounting structure of an optical submarine repeater having a structure in which optical fibers are drawn out from an internal unit to the outside of an end plate.

Optical submarine repeaters are connected to optical cables and installed on the seabed at predetermined intervals.This type of optical submarine repeater requires assembly and assembly, such as assembling the units housed inside and routing the optical fibers. Improvements in workability in manufacturing are required. In particular, since optical fibers are handled as transmission media, it is necessary to handle them with care so as not to damage the optical fibers drawn out from the internal unit.

[Conventional technology]

FIG. 7 is a perspective view showing the unit structure of a conventional optical submarine repeater, and FIG. 8 is a sectional view of the unit structure of the conventional optical submarine repeater. In these figures, an internal unit 10 of the optical submarine repeater is inserted and mounted in a vibrator 11 made of resin such as polyethylene (PAL), and both end surfaces of a pipe 110 (only one side is shown) are made of brass (BS) or the like. It is sealed by an end plate 12 and an end plate 13 made of resin such as polyethylene (PIE).

14 is a polyethylene (PE) welding part that seals and welds the end plate 13 to the vibrator 11 over the entire circumference.

A plurality of, for example, four, optical fiber reinforcement cords 21 pulled out from the internal unit 10 are made of resin such as polyethylene (PH) and have silicone rubber (not shown) inside to protect these cords 21 themselves. It is supported by a holder 15 and pulled out to the outside of the unit via a pair of half bushes 16. This half bush 16 is similarly made of resin such as polyethylene (PE), and supports the four optical fiber reinforcing cords 21 between them, and is attached to the fiber extraction hole 17 that passes through the end plate 12 and the end plate 13. . The reinforcing cord 21 comes out from the end plate 13, and the optical fiber 20 is exposed from a short distance. The diameter of the optical fiber reinforcing cord 21 is approximately 2.8 mm, and the diameter of the exposed optical fiber portion 20 is approximately 0.9 mm.

[Problem to be solved by the invention]

As described above, according to the conventional optical submarine repeater unit mounting structure, the only place holding the unit terminal fibers 20 and 21 is the holder 1501 inside the unit. If an excessive tensile action occurs on the extra length pulled out from the optical fiber, there is a possibility that the optical fiber will break, so there is a problem in that the optical fiber must be handled extremely carefully during work.

Incidentally, the allowable tensile strength of the optical fiber reinforcement cord 210 portion is approximately 10 kg, and the allowable tensile strength of the optical fiber 20 portion is approximately 1 kg.

Therefore, the present invention provides an optical submarine system that prevents the optical fibers pulled out from the unit from being subjected to excessive tensile action or excessive stress during assembly work, etc., and from being damaged such as wire breakage. The purpose is to provide a repeater unit mounting structure.

[Means to solve the problem]

In order to solve such problems, according to the present invention, in an optical submarine repeater unit mounting structure that has a structure in which an optical fiber is pulled out from an internal unit to the outside of an end plate, a wire is provided on the outer surface of the end plate from the core to the outside. A raised step is formed, a semicircular or horse-shaped groove is formed in the step, and the optical fiber pulled out from the end plate is once run along from one end of the groove to the other, and the optical fiber An optical submarine characterized in that a means for holding the optical fiber in the wave groove is provided so that the optical fiber maintains a radius of curvature of a certain value or more at least while the optical fiber exits the end plate and is guided to the other end of the groove. Repeater unit mounting structure.

[For production]

While the optical fiber exits the end plate of the unit and enters the semicircular or horse-shaped groove, and while it is guided in this groove,
Since the optical fiber maintains a radius of curvature above a certain level, excessive tension is not applied to the portion of the optical fiber immediately after being pulled out from the end plate of the optical fiber unit, which has conventionally been most susceptible to tensile force and stress.

〔Example〕

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a perspective view of a unit of an optical submarine repeater according to an embodiment of the present invention, FIG. 2 is a side view of the same unit, and FIG.
Figure 4 is a cross-sectional view of the optical fiber reinforcement cord, Figure 5 is a cross-sectional view of the exposed optical fiber, and Figure 6 is a cross-sectional view of the optical fiber coated with a spiral nylon tube. It is.

Internal unit 10 (Fig. 8), vibrator 11, end plate 12 (Fig. 8), polyethylene (PE) welded part 14,
The structure of the holder 15 (FIG. 8), half pusher 516, etc. is the same as the conventional structure. In the present invention, a horse-shaped stepped portion 30 is formed on the outer surface of the end plate 13 made of a resin such as polyethylene, which swells outward by about 40 m+n from this surface. This stepped portion 30 starts from a portion slightly wider than the portion of the half-split pusher 516 from which the optical fiber reinforcing cord 21 is drawn out, and extends in an arc-shaped manner around the center of the end plate 13 in an area on the opposite side. Molded integrally with the face plate 13, a horse-shaped groove 31 having a minimum radius of curvature of about 43 mm is formed on the upper surface (a surface substantially parallel to the end plate 13) of this stepped portion 30.

The four optical fiber reinforcement cords 21 pulled out from the internal unit 0 and coming out of the pair of half-split pushers Li2 of the end plate 13 are introduced into one end of the horse-shaped groove 31, and
1 (Part A). And Ma Taigata ditch 31
The outer covering portion of each optical fiber reinforcing cord 21 is peeled off from the middle of the optical fiber 20, resulting in a relatively short exposed portion of the optical fiber 20 (portion B). Further, the four optical fibers 20 from the middle are combined into one nylon tube 22 having a spiral (section C).

The spiral nylon tube 22 is then pulled out from the other end of the horse-shaped groove 31.

The tip of the spiral nylon tube 22 is once again an exposed portion of the optical fiber 20.

The A and C portions of the horse-shaped groove 31 are covered by gluing substantially arcuate plates 33, 34 made of glass epoxy or the like to the stepped portion 30 with a suitable adhesive. As a result, the portion of the four optical fiber reinforcement cords 21 (part A)
and one nylon tube 22 (section C) is held within the groove 31.

As shown in FIG. 3, silicone rubber 35 is disposed at the bottom of at least parts A and C of the horse-shaped groove 31, and the optical fiber reinforcing cord 21 or the optical fiber 20 is protected by the groove 31. Also, the depth of the groove 31 is t* =
6.4 (0,-0,1) mm t at section 5C.

・6゜8 (0, -0,1) mm, and the diameter of one optical fiber reinforcement cord 21 in section A is approximately 2.8 mm as before.
The diameter of the nylon tube 22 at the C portion is approximately 6 mm. In this way, the optical fiber reinforcing cord 21 and the optical fiber 20 are held with some pressure. Note that the diameter of the optical fiber exposed portion 20 in the B section is about 0.9+nm, and this B section occupies an area of about 30 degrees.

4, 5, and 6 each show one optical fiber reinforcement cord 21 (section A), one exposed optical fiber 20 (section B), and four optical fibers 20. 24 is a fiber core wire, 25 is a resin part, 26 is a Kevlar part, 27 is a rubber protective tube part, and 28 is a cross-sectional view of the spiral nylon tube 22 (part C).
is a nylon part, and 29 is a spiral wound around the outer periphery of the nylon.

In the above embodiment, the end plate 13 (half pusher 51
6) The optical fiber reinforcement cord 21 that comes out of the
1, the optical fiber is maintained at an allowable radius of curvature of 30 mm or more, and the radius of curvature of the optical fiber is maintained at approximately 43+n+n at portions A, B, and C of the groove 31.

In addition, the C part of the groove and the part coming out from it are strongly protected by the spiral nylon tube 22, so the optical fiber will not be subjected to stress or tensile force that would cause the permissible radius of curvature to be less than 30 mm. .

〔Effect of the invention〕

According to the present invention, as described above, the optical fiber is not allowed to move until it exits the end plate of the unit and enters the semicircular or horse-shaped groove, and while it is being guided in this groove. Since the radius of curvature is maintained above a certain level, excessive tension will not be applied to the part of the optical fiber immediately after it is pulled out from the end plate of the unit, and the optical fiber will not be damaged during assembly, such as breakage. I won't receive it. Therefore, assembly can be performed easily and quickly.

[Brief explanation of the drawing]

FIG. 1 is a perspective view of a unit of an optical submarine repeater according to an embodiment of the present invention, FIG. 2 is a front view of the same unit, and FIG.
4 is a sectional view of the optical fiber reinforcement cord, FIG. 5 is a sectional view of the exposed optical fiber,
Figure 6 is a cross-sectional view of an optical fiber coated with a spiral nylon tube, Figure 7 is a perspective view of a conventional submarine optical repeater unit, and Figure 8 is a cross-sectional view of a conventional optical submarine repeater unit. It is a diagram. DESCRIPTION OF SYMBOLS 10... Internal unit, 13... End plate, 20... Optical fiber exposed part, 21... Optical fiber reinforcement cord, 22... Nylon spiral tube, 30...
- Stepped portion, 31... Groove shaped like a horse, 33.34... Cover plate, 35... Silicone rubber. Structure of the example (perspective view) End plate Fully welded Optical fiber exposed part Original fiber reinforcement cord Nylon snowflakes

Claims (1)

[Claims] 1. In an optical submarine repeater unit mounting structure that has a structure in which an optical fiber is pulled out from an internal unit (10) to the outside of an end plate (13), a stepped portion on the outer surface of the end plate (13) is raised outward from the surface. (30), and a semicircular or horse-shaped groove (31) is formed in the stepped portion, and the optical fibers (21, 20, 22) drawn out from the end plate are temporarily passed from one end of the groove to the other end. means (34, 35) for holding the optical fiber along the groove and holding the optical fiber in the groove, the optical fiber having a radius of curvature of a certain value or more at least while the optical fiber exits the end plate and is guided to the other end of the groove. An optical submarine repeater unit mounting structure characterized by maintaining the following characteristics.