JPH02304334A - Water immersion sensing tool - Google Patents

Abstract

PURPOSE:To shorten a water immersion detection time by providing the first water absorbing/expanding material for applying compressive force in the axial direction to a coated optical fiber at the time of water immersion, and the second water absorbing/expanding material for applying pressure in the direction vertical to the axis. CONSTITUTION:When water enter into a closure, the first and the second water absorbing/expanding materials 31, 31b work due to water immersion, and coated optical fibers 5, 5a are bent. In this case, not only compressive force in the axial direction but also pressure from the direction orthogonal to the axis are applied to the coated optical fibers 5, 5a by the second water absorbing/ expanding material 31b, therefore, after the water immersion, the coated optical fibers 5, 5a come to be bent quickly, and shortening of the water immersion detection time can be realized. Also, since bending of the coated optical fibers 5, 5a is controlled by a stopper part 33, such bending as a permanent deformation is generated against the coated optical fibers 5, 5a, and accordingly, this implement can be used repeatedly and becomes a long service life.

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to a water immersion sensor device used to detect water intrusion into a cylindrical closure housing a connecting portion of an optical fiber cable.

[Conventional technology]

Traditional communication networks use copper wire cables, and if the fI wire inside the copper wire gets wet with water, communication will be disrupted, causing damage to the outer surface of the copper wire cable and flooding the inner copper wire. Preventing the situation was an important issue. To prevent the above-mentioned flooding, a measure called the so-called "gas maintenance method" has usually been taken. This is because a certain amount of gas is always sealed inside the cable and kept at a certain pressure, and as the gas flows out of the cable, the above pressure decreases, resulting in damage to the cable (and eventually water intrusion into the cable). This is to detect such a situation.

However, recently, optical fiber cables have been used instead of the copper wire cables mentioned above, and since the optical fiber core wires used for communication in these optical fiber cables are sufficiently protected, water intrusion etc. can only be detected at the connection part. It is now sufficient to carry out maintenance and management.

[Problem that the invention seeks to solve]

This type of fiber optic cable end connection generally uses a cylindrical closure, in which the end of one fiber optic cable is introduced into the closure from one end surface, and the end of the other fiber optic cable is connected from the other end surface. In this method, optical fibers are pulled out from both ends and connected with their ends facing each other. It is not appropriate to use the conventional gas maintenance method for the connection portion of an optical fiber cable having such a structure because of problems such as structural problems and management costs. For this reason, the present inventors have developed and researched a water immersion sensor device that is easy to maintain, has a long life, and can be miniaturized, and has already filed a patent application (Japanese Patent Application No. 1-51768). As shown in FIG. 5, this water immersion sensor device 8 is
a pair of left and right optical fiber cables 1 disposed at the bottom of the cylindrical closure 6 and introduced into the closure 6;
Optical fiber core IJ pulled out from la and butted together
I5.5a is housed inside. In FIG. 5, 2 and 2a are cable gripping parts, 3 and 3a are tension members, 4 and 4a are tension member gripping parts, and 10 is a connection part housing part for optical fiber core wire 5.58 (
7 is an end plate. The water immersion sensor device 8 according to this proposal accommodates the connecting portion of the lowest optical fiber core 5.5a that is not used for optical communication, and is
As shown in FIG. 7 and FIG. 7, the casing 20 is assembled by engaging the rectangular box-shaped casing 20 with a through hole in the bottom, the claws of the four legs 21, and the recesses at the four corners of the casing 20. Lid body 20 with a through hole on the upper surface that can be attached and detached freely
It is equipped with a. The rectangular box-shaped casing 20 is
A chamber block 22 is formed on the left side from the center in the longitudinal direction, and a solid block 23 is formed on the right side. and,
As shown in FIG. 7, inside the chamber block 22 on the left side of the box-shaped casing 20, a central protrusion 25 with a first central groove 24 extends from one longitudinal end to the other end. Now, the inside of the chamber block 22 of the casing is divided into two left and right chambers 26 and 27 by the protrusion 25. Further, a second central groove 28 is formed in the solid block 23 of the casing 20, extending the first central groove 24 of the central protrusion 25 to the end of the casing 20. In this case, one groove wall of the second central groove 28 is greatly hollowed out in an arch shape as shown in the figure, and that portion is formed into a large recess 29. Said second central groove 2
In the inlet side portion 8, the opposing groove walls are hollowed out, and the entire structure is formed into an arch-shaped groove guide portion 30. Further, the outlet side portion of the second central groove 28 is formed into a rectangular fixture housing chamber 31a. In the two left and right chambers 26.27 divided by the central protrusion 25, water-absorbing and expanding materials 31 each having a shape that fits within the two chambers 26.27 are disposed. These water absorption swelling JIIdt31 are:
It is composed of a water-absorbing and expanding rubber that has ethylene-propylene-diene rubber (EPDM) as its main component and has a water-swelling agent and a water-absorbing agent dispersed throughout. Reference numeral 32 denotes a fixing plate which is formed into a substantially U-shape. Both horizontal sides of the U-shape are aligned with the outer surfaces of the left and right re-absorbing inflatable material 31, and the vertical sides of the U-shape are aligned with the outer surfaces of the re-absorbing inflatable material 31. It is disposed within the chamber block 22 along the front end surface and the front end surface of the central protrusion 25. In this chamber block 22, the solid block 2
3 and the chamber block 22 and the U-shaped vertical side of the U-shaped fixing plate 32, the fixing plate 32 is moved to the right side as shown in the figure by the pressing force caused by the water absorption and expansion of the water-absorbing and expanding material 31. It provides a space for movement when moving in one direction. The boundary wall 33 between the solid block 23 and the chamber block 22 serves as a stopper for the movement of the fixed plate 32.

Reference numeral 34 denotes a first fixing metal fitting, which is disposed in the first and second central grooves 24.28 and is inserted at the front end of the water-absorbing and expanding material 31 in the optical fiber core 5.5a inserted across the casing 20. Optical fiber core 5 corresponding to the surface,
The portion 5a is fixed to the front end surface of the water-absorbing and expanding material 31 via the fixing plate 32.

Reference numeral 35 denotes a second fixture for fixing a portion of the optical fiber core 5.5a corresponding to the fixture housing chamber 31a of the solid block 23 to a corner of the inner wall surface of the fixture housing chamber 31. In addition,
36 is a fixing plate 32 for passing the optical fiber core 5°5a.
A cutout hole 37 provided in the housing is a protrusion that fits into the upper part of the fixing device storage chamber 31a to close the lid.

In this configuration, the optical fiber core wires 5, 5a are connected to the first casing 20 as shown in FIG.
positioned within the second central groove 24.28 and a predetermined portion thereof into the first. It is arranged in a fixed state with a second fixture 34,35. In this case, the inlet portion 30 of the second central groove 28
Since the area is wide, installation work is easy.

Next, the box-shaped casing 20 through which the optical fiber core wires 5 and 5a have been passed is covered with a lid 20a, and the water intrusion sensor device 8
This is arranged at the bottom of the closure 6 with the longitudinal direction of the casing 20 aligned with the axial direction of the closure 6 as shown in FIG. In this state, when water enters the closure 6, the water passes through the through holes in the bottom of the box-shaped casing 220 and is absorbed by the water-absorbing and expanding material 31. In this case, the rectangular box-shaped casing 20 is arranged with its longitudinal direction aligned with the longitudinal direction of the cylindrical closure 6 (coaxially), and its longitudinal direction is aligned with the longitudinal direction of the cylindrical closure 6.
Since the bottom surface of the casing 20 is not perpendicular to the longitudinal direction of the cylindrical closure 6
It is relatively close to the bottom of the. Therefore, it is advantageous for early detection of flooding. Due to the water absorption by the water-absorbing and expanding material 31, the water-absorbing and expanding material 31 rapidly swells and pushes the fixing plate 32 from the solid line position in FIG. The optical fiber core wires 5, 5a, which were in a straight state in this state, are bent as shown by the chain line B in the recess 29 of the second central groove 28, thereby increasing the transmission loss of light. Therefore, by detecting this, it is possible to quickly and accurately grasp water intrusion inside the closure 6. In this case, the bending of the optical fiber core wires 5, 5a is caused by the action of the stopper part 33, causing permanent distortion. Since the optical fibers 5 and 5a are regulated at a stage before they occur, and the bending is made along the arch shape of the recess 29, the optical fibers 5, 5a return to their initial state when the water in the closure 6 subsides and returns to normal. It restores its shape and does not cause any problems.

However, the water immersion sensor device 8 according to the proposed method compresses and bends the optical fiber core 5.5a in the axial direction, and since a considerable amount of force is required to compress and bend the optical fiber in the axial direction, a water-absorbing and expanding material is used. Subsequent experiments revealed that the bending of the optical fiber core 5.5a does not occur until a considerable period of time has passed after the optical fiber 5.5a begins to swell, and therefore it takes some time to detect water intrusion. This invention was made in view of the above circumstances, and aims to improve the water immersion sensor device and shorten the water immersion detection time.

[Means for solving problems]

In order to achieve the above object, the water immersion sensor device of the present invention is disposed on the bottom part of a cylindrical closure that coaxially accommodates a connection part that connects the ends of one optical fiber cable and the other end of the optical fiber cable. and a water immersion sensor device that coaxially accommodates any one of the plurality of optical fiber core wires pulled out and connected from the end of the other optical fiber cable so as to come into contact with infiltrating water, and at least the bottom side has a water absorption part. A box-shaped casing formed in
An optical fiber outlet is formed facing each other on both end faces perpendicular to the axial direction of the casing, and an optical fiber outlet is housed in the box-shaped casing with the axial direction aligned, and one end in the axial direction is in contact with one end of the casing. a first end, the other end of which is a free end facing the other end of the casing with a space therebetween;
a water-absorbing expandable material, a stopper portion provided between the other end of the casing and the free end of the water-absorbing expandable material, and a portion corresponding to the free end of the optical fiber core that crosses inside the box-shaped casing. A fixture is provided between the other end of the casing and the stopper part to fix the free end and the part corresponding to the other end of the casing to the other end. and a second water-absorbing expandable material that expands and bends toward the end.

[Effect]

That is, in this water immersion sensor device, a second water-absorbing and expanding material is newly disposed inside the casing of the water immersion sensor device, and a bending pressure is applied to the side of the optical fiber core wire when it absorbs water and expands. There is. Therefore, not only compressive force in the axial direction but also pressure in the direction perpendicular to the axis is applied to the optical fiber, so that the optical fiber becomes bent in a short period of time after being immersed in water. Therefore, it becomes possible to shorten the detection time of water intrusion.

Next, examples will be described.

〔Example〕

1 and 2 show an embodiment of this invention. That is, this water immersion sensor device 8' is provided with a groove-like recess 31c that opens toward the side of the optical fiber core wires 5, 5a in the casing 20 of the water immersion sensor device 8 shown in FIGS. 6 and 7. There, the second water-absorbing and swelling material 31b
has been set up. In this case, the second water-absorbing and swelling material 31b is made of the same material as the first water-absorbing and swelling material 31, and its water-absorbing and swelling speed is equal to or faster than that of the first water-absorbing and swelling material 31. It is set so that The other configurations are the same as the water immersion sensor device 8 shown in FIGS. 6 and 7.

As a result of this configuration, when water floods into the closure 6 (see FIG. 5), the first and second water-absorbing and expanding materials 31 and 31b shown in FIGS.
acts to move the optical fiber core wires 5, 5a along the chain line B shown in the figure.
Bend it like this. In this case, the optical fiber core 5,
As mentioned earlier, not only compressive force in the axial direction but also pressure from the direction perpendicular to the axis is applied by the second water absorbing and swelling material 31b, so that the optical fiber cores 5, 5a are quickly immersed in water. 5a becomes bent, and the water intrusion detection time can be shortened.

By the way, the water immersion sensor tool 8 shown in FIGS. 6 and 7,
The results of investigating the water immersion detection speed with the water immersion sensor device 8' of the present invention shown in FIGS. 1 and 2 are as shown in FIG. In FIG. 3, curve A is the water immersion detection curve of the water immersion sensor 8' of the present invention, and curve B is the water immersion detection curve of the water immersion sensor 8 shown in FIGS. 6 and 7. As is clear from the comparison between curves A and B, it can be seen that the water immersion detection speed of the water immersion sensor device 8' of the present invention is significantly improved compared to that of the devices shown in FIGS. 6 and 7. In FIG. 3, a straight line X is a line indicating the limit of optical transmission loss, and a curve Y is a line indicating a limit of water immersion detection time. The line above the X line is the pass line, and the line to the left of the Y line is the pass line.

FIG. 4 shows another embodiment. That is, this water immersion sensor device substantially corresponds to the first and second grooves 24. of the water immersion sensor device of FIGS. 2 and 3.
28 constitutes a casing 40, and a water-absorbing and expanding material 31 is arranged in 24 corresponding to the first central groove, and the fixing plate 32 is moved to the chain line position C shown in the figure by the water-absorbing and swelling material 31. A water-absorbing and expanding material 31b is disposed in a portion 28 corresponding to the groove 2, and the water-absorbing and expanding material 31b applies a bending pressure to the optical fiber core wires 5, 5a, thereby bending the optical fiber core wires 5, 5a into solid lines. From this state, it is bent as shown by the chain line. 34.35
is the first. The second fixture 33 is a stopper piece. This embodiment not only provides the same effects as the above embodiment, but also has the effect of simplifying the overall structure.

In addition, in the above embodiment, the fixed plate 32 and the water-absorbing expansion material 31
Although these are separate bodies, they may be integrated, for example by making the front surface of the water-absorbing and expanding material 31 a push plate part. Further, the lid 22 of the box-shaped casing 20 may be removed depending on the case.

Furthermore, the entire box-shaped casing 20 may be made of a porous material made of a porous water-absorbing resin whose main component is polyethylene or phenol resin. In this case, it is necessary to provide a through hole in the bottom surface of the casing 20. There isn't.

As described above, in the present invention, the box-shaped casing in which at least the bottom side is formed as a water absorption part includes a case made of a non-porous material with a through hole formed in the bottom surface, and a box-shaped casing made of a non-porous material with a through hole formed in the bottom surface. Includes items made of materials.

〔Effect of the invention〕

As described above, the water immersion sensor device of the present invention applies not only compressive force in the axial direction to the optical fiber core wire (but also pressure in the direction perpendicular to the axis by the second water absorbing and expanding material) when submerged in water. This allows the water intrusion detection time to be shortened.Also, in this water intrusion sensor device, the swelling direction of the water-absorbing and expanding material is set in the axial direction of the casing.
Although the casing requires a considerable length in the axial direction, the length in the direction perpendicular to the axis (width direction) can be shortened. Therefore, when the casing is accommodated in a cylindrical closure, the bottom surface of the casing can be brought close to the bottom surface of the closure by arranging both coaxially. As a result, the effect of disposing the second water-absorbing expansion material and this effect combine to make it possible to quickly detect water intrusion into the cylindrical closure. In addition, the water immersion sensor device of the present invention is provided with a stopper portion that appropriately restricts the bending of the optical fiber core wire, so that bending that would cause permanent distortion to the optical fiber core wire is not applied.
Therefore, it can be used repeatedly and has a long lifespan.

[Brief explanation of the drawing]

Fig. 1 is a plan view of an embodiment of the present invention with the lid removed, Fig. 2 is an exploded perspective view thereof, Fig. 3 is a water immersion detection curve,
Fig. 4 is a configuration diagram of another embodiment of the present invention, Fig. 5 is a vertical cross-sectional view showing the installed state of the water immersion sensor device, and Fig. 6 is a state where the lid of the water immersion sensor device, which is the basis of this invention, is removed. FIG. 7 is a plan view of the water immersion sensor device with the lid removed.

Claims (1)

[Claims] (1) Disposed on the bottom of a cylindrical closure that coaxially accommodates a connection part that connects the ends of one and the other optical fiber cables, and is pulled out and connected from the ends of the one and other optical fiber cables. The water immersion sensor device coaxially accommodates any one of a plurality of optical fiber cores so as to be in contact with infiltrating water, and includes a box-shaped casing in which at least the bottom side is formed as a water absorption part; Optical fiber outlet openings are formed facing each other on both end faces perpendicular to the axial direction, and are housed in the box-shaped casing with their axial directions aligned, one end in the axial direction abutting one end of the casing, and the other. a first water-absorbing expandable material whose end is a free end facing the other end of the casing with a space therebetween; and a stopper provided between the other end of the casing and the free end of the water-absorbing expandable material. and a fixture for fixing a portion corresponding to the free end of the optical fiber core wire crossing inside the box-shaped casing to the free end and fixing a portion corresponding to the other end of the casing to the other end. A water immersion sensor comprising: a second water absorbing and expanding material which is provided between the other end of the casing and the stopper part and expands and bends toward the side of the optical fiber when water is absorbed. Ingredients.