JP2002139634A - Water stop structure for cable hole of optical closure - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a water stop structure for cable holes of an optical closure of proper workability by which optical fiber cables are sealed and fixed surely. SOLUTION: The structure is provided with a sleeve 33, which is opened in the end surface plate 3 of the optical closure storing the optical connection part of optical fibers drawn from the optical fiber cables 10 and into which two optical fiber cables 10 are inserted, clamping blocks 5, which clamp respective optical fiber cables 10 inserted into the sleeve 33 and collectively fix them, and a heat-shrinkable tube (connecting and sealing means) 6, which envelopes and seals the gap between the sleeve 33 and the clamping blocks 5, and connects the gap between the sleeve 33 and the clamping blocks 5.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a water blocking structure for a cable hole of an optical closure.

[0002]

2. Description of the Related Art An optical closure for accommodating an optical component such as an optical connection portion between optical fibers drawn from an optical fiber cable and a surplus length is used, for example, in a manhole, a handhole, and an overhead installation of an optical fiber cable. Since it is used, it must be waterproof against the environment exposed to groundwater and wind and rain.

FIGS. 8A and 8B show an example of an optical closure. Optical closure 1 shown in FIGS. 8A and 8B
Includes a cylindrical closure sleeve 2 with a bottom, and an end face plate 3 that opens and closes the opening 2 a of the closure sleeve 2. Two optical fiber cables 10 are inserted into the cable holes 31 opened in the end face plate 3 and drawn into the optical closure 1. The cable hole 31 is a hole penetrating the sleeve 3 a protruding from the end face plate 3. In this optical closure 1, the optical fiber 12 (optical fiber core wire or the like) which has been exposed by removing the outer sheath in the longitudinal direction of one optical fiber cable is bent, and the optical fiber cable is folded back to form one cable hole. By inserting the optical fiber cable 31 into the optical fiber cable 31, the optical fiber cable 10 can be introduced inside without cutting the optical fiber 12. An optical fiber cable for branching (not shown) is introduced from a cable hole 32 separately opened in the end face plate 3, and the optical fiber of the optical fiber cable for branching and the optical fiber cable 10
By connecting the optical fiber 12 on the side, a branch optical fiber cable can be branched and connected to the optical fiber cable 10. The optical connection portion between the optical fibers and the excess length are accommodated inside the optical closure 1 while ensuring waterproofness.

In the optical closure 1, the cable holes 31 and 32 are holes that penetrate through the sleeves 3a and 3b protruding from the end face plate 3 and communicate with the inside of the optical closure 1. In order to ensure waterproofness inside, the water blocking structure of the cable holes 31 and 32 becomes a problem. Conventionally, there are the following two water blocking structures for the cable holes 31 and 32. Each optical fiber cable is fixed to the cable hole with the adhesive filled in the cable hole, and the inside of the cable hole is sealed. As shown in FIG. 9, the end face plate 3 has a divided structure sandwiching a cable hole, and rings 3c and 3d made of rubber or the like are interposed between the cable hole and the optical fiber cable, and each optical fiber cable is tightened and fixed. And seal the inside of the cable hole. The ring 3c fitted in the cable hole 31 has a configuration in which the two optical fiber cables 10 inserted into the cable hole 31 are collectively used.

[0005]

However, in the water-stop structure as described above, it is relatively easy to ensure the waterproofness of the cable hole 32 through which only one optical fiber cable is inserted, and in particular, it is preferable to use the two-way structure. In the cable hole 31 through which the optical fiber cable 10 is inserted, long-term reliability and sealing workability are not satisfactory. That is, in the conventional water blocking structure applied to the cable hole 31, in the example, since each optical fiber cable 10 is fixed via a large amount of adhesive, the gripping force on the optical fiber cable 10 is large. Is difficult to maintain over a long period of time, requiring maintenance. In the example, when the optical fiber cable 10 is fixed to the cable hole 31, the assembling work of the end face plate 3 is troublesome and the workability is poor.

SUMMARY OF THE INVENTION The present invention has been made in view of the above problems, and can securely seal and fix an optical fiber cable.
Moreover, an object of the present invention is to provide a water blocking structure for a cable hole of an optical closure which can secure the workability of a fixing work.

[0007]

SUMMARY OF THE INVENTION According to the present invention, there is provided a watertight structure for a cable hole of an optical closure, which is formed in an end face plate of an optical closure accommodating an optical connection portion between optical fibers drawn from an optical fiber cable. A cable hole through which the optical fiber cable is inserted, a grip block for fixing the optical fiber cables in a lump, and coupling sealing means for wrapping and sealing between the end face plate and the grip block. did. According to the water blocking structure of the optical closure cable, the two optical fiber cables are fastened between the gripping blocks and fixed collectively, so that each optical fiber cable is securely fixed without depending on the adhesive. Thus, the seal between the grip block and each cable is maintained for a long time. Then, the connection sealing means that wraps and seals and connects between the end face plate and the grip block is securely retained so that the grip block does not separate from the end face plate, and the sealed state between the sleeve and the grip block is reliably maintained. You. Also, unlike the conventional device, the end plate does not need to be divided, and the structure can be simplified.
The workability of assembling the optical fiber cable can be improved.

The present invention more preferably employs the following configuration. According to a second aspect of the present invention, in the water blocking structure of the optical hole of the optical closure according to the first aspect, the cable hole is opened in a sleeve protruding from the end face plate, and the cable hole is opened from the end face plate of the sleeve. And a heat-shrinkable tube as the connecting and sealing means provided so as to cover the grip block provided from the outside thereof. According to a third aspect of the present invention, in the water blocking structure of the optical hole of the optical closure according to the first or second aspect, the two optical fiber cables passing through the one cable hole are folded back in the optical closure. It is characterized by comprising an optical fiber cable.

[0009]

Embodiments of the present invention will be described below with reference to the accompanying drawings. FIG. 1A shows an optical closure 1.
(B) is a front view of the same. The pot-shaped light closure 1 includes a cylindrical closure sleeve 2 with a bottom,
A disk-shaped end plate 3 for removably closing the opening 2a of the closure sleeve 2 and a band 4 for tightening and fixing the end plate 3 in accordance with the opening 2a of the closure sleeve 2 are provided, and these can be opened and closed. Make up the container. The band 4 is tightened and fixed and released by operation of the tying tool 4a. When the tightening force of the band 4 is released, the end face plate 3 can be removed from the closure sleeve 2.

From the end face plate 3, a cylindrical sleeve 33 in which a cable hole 31 through which two optical fiber cables 10 are inserted is opened, and a cable hole 32 in which one optical fiber cable 10a is opened. A plurality of (four in the figure) sleeves 34 are formed to protrude, respectively. As shown in FIGS. 1 (b), 2 (a) (b), and 3 (a) (b), the optical fiber cable 10 for two wires that is inserted through one cable hole 31 and pulled in 1 curved in closure 1
The optical fiber cable 10 is constituted. In this optical closure 1, an optical fiber 12 (an optical fiber core wire or the like) which has been exposed by removing an outer sheath in the longitudinal direction of one optical fiber cable is bent and folded, and the two cable portions are converted into one. By being inserted into the cable hole 31, the optical fiber cable 10 can be cut without cutting the optical fiber 12.
Can be introduced inside. The tension members (tensile wires) 11 exposed at the ends of the respective optical fiber cables 10 are fixed by tension member fixing tools 21. The tension member 11 is cut between the optical fiber cables 10 formed by folding. In FIG. 4, reference numeral 32a denotes a cap for sealing the cable hole 32 of the sleeve 34 in a watertight manner. When the optical fiber cable 10a for branching is inserted into the cable hole 32 of the sleeve 34, the cap 32a is removed and the cable hole 32 is removed. Open.

In this optical closure 1, an optical fiber cable 10a for branching is introduced from a cable hole 32 separately opened in the end face plate 3, and an optical fiber 12a led out from a terminal of the optical fiber cable 10a for branching is connected to the optical fiber 12a. By connecting the optical fiber 12 on the optical fiber cable 10 side, a branch optical fiber cable can be branched and connected to the optical fiber cable 10. The optical fiber cable 10a is also retained by fixing the tension member exposed to the terminal to the tension member fixing member 21. Of the many optical fibers 12 exposed from the end of the optical fiber cable 10, those that pass through without cutting are
It is curved as if it is wound inside the optical closure 1, and is processed for extra length. Each optical fiber 12 curved in the optical closure 1
Can be bound by the binding tool 22 attached to the fixing plate 24.

As shown in FIGS. 2A, 2B, and 3A, the optical fiber 12 exposed from the end of the optical fiber cable 10 and the optical fiber 12a of the branching optical fiber cable 10a are connected. The optical connection parts (optical connector, fusion splicing part, etc.) are accommodated in the tray 23 stacked in plurals (four in the figure) in the optical closure 1 together with the surplus lengths of these optical fibers 12, 12a. Each tray 23 is connected to be openable and closable via a hinge 27, and is locked at a closed position via a claw 28. Each tray 23 is provided with a pair of openings (not shown) near the hinge 27, and the optical fiber 12,
12a enters the tray 23 through each opening.

A stacking unit formed by stacking a plurality of trays 23 is rotatably connected to a fixed plate 24 fixed to the end face plate 3 via a hinge 25. Optical fiber (not shown) drawn into optical closure 1 from each cable hole 32
Is drawn into each tray 23 through a gap 26 between the fixing plate 24 and the tray 23, for example.

Next, the gist of the present invention is as follows.
The water blocking structure of the cable hole 31 will be described. As shown in FIG. 4, the water blocking structure includes a holding block 5 that collectively fixes the optical fiber cables 10 therebetween, a sleeve 33 of the end plate 3 and the holding block 5, and the sleeve 33 and the holding block 5. A heat-shrinkable tube 6 is provided to connect between the two.

As shown in FIG. 6, the plastic holding block 5 is formed in a plate shape having a split structure.
Each gripping block 5 has a rib-shaped joining flange portion 55 arranged on both left and right sides facing each other, and two cable engaging grooves 51 for accommodating the optical fiber cable 10 between both joining flange portions 55. The pair of gripping blocks 5 are integrated by fastening a total of four bolts 7 and nuts inserted into bolt holes 57 formed at the four corners of each joint flange portion 55 (see FIG. 7). The two optical fiber cables 10 housed in the mating groove 51 are gripped and fixed. Here, the space between the joining flange portions 55 of the gripping blocks 5 is sealed with a sealing agent (similar to the sealing agent filled into the inside of the gripping block 5) described later. The joining surfaces 56 are made to coincide with each other, the movement of the sealing agent can be prevented by the waveform of the joining surfaces 56, and the sealed state can be reliably maintained. In addition, since the displacement between the gripping blocks 5 is prevented by the engagement between the corrugated joining surfaces 56, the integrated state of the gripping blocks 5 and the gripping and fixing state of the two optical fiber cables 10 can be stably performed. Can be maintained.

At both ends of the cable engaging groove 51 in the extending direction (the longitudinal direction of the optical fiber cable 10 accommodated therein), a plurality of protruding projections 53 are formed so as to protrude. When integrated, the onion projections 53 of both gripping blocks 5 bite from both sides facing the outer sheath of each optical fiber cable 10, and each optical fiber cable 10 is securely fixed to the gripping block 5.

A sealant made of a mixture of butyl rubber and the like is applied between each optical fiber cable 10 and the gripping block 5 to ensure the sealing performance. This sealant is filled between the end walls 51a protruding from both ends of the cable engaging groove 51 of the grip block 5 in the extending direction, and is prevented from leaking outside by the end walls 51a. . Further, since the free flow of the sealing agent is regulated by the ribs 52 protruding at a plurality of positions in the extending direction of the cable engaging groove 51, the sealing agent is wrapped around each optical fiber cable 10 without any gap. Is maintained stably. The onion projection 53 is protruded from the end wall 51a.

As shown in FIG. 4, the heat-shrinkable tube 6 provided as the connecting and sealing means of the present invention is heat-shrinked with the sleeve 33 and the gripping block 5 inserted so as to be wrapped from the outside. The sleeve 33 and the grip block 5 are fixed and integrated with each other by closely adhering to the surface of the grip block 5. The solid line in FIG. 4 shows a state in which a part of the heat-shrinkable tube 6 is broken, but the state in which the sleeve 33 and the gripping block 5 are fixed and integrated by the heat-shrinkable tube 6 4 covers the sleeve 33 and the grip block 5 from outside, including the imaginary line portion in FIG.

The outer shape of the grip block 5 is formed in a flat cylindrical shape like the outer shape of the sleeve 33. A large number of depressions 58 are formed on the surface of the grip block 5 to enhance the adhesion to the heat-shrinkable tube 6. In addition, a number of depressions may be formed on the surface of the sleeve 33 to enhance the adhesion to the heat-shrinkable tube 6.

An example of a procedure for stopping water in the cable hole 31 will be described. 1. The optical fiber 12 exposed by removing the coating in the longitudinal direction of one optical fiber cable is bent, and the heat-shrinkable tube 6 is preliminarily attached to the two (two wires) optical fiber cables 10 arranged side by side. Insert it, as shown in FIG.
Each gripping block 5 sandwiches each optical fiber cable 10,
The bolts 7 and the nuts are collectively tightened and fixed. Here, the sealant (such as the above-mentioned butyl rubber admixture) filled on the inner surface side of the gripping block 5 by coating or the like allows the space between the pair of gripping blocks 5 including the space between the two optical fiber cables 10, Sealed without gaps. 2. The two optical fiber cables 10 collectively fixed by the respective gripping blocks 5 are inserted into the cable holes 31 of the end face plate 3. Each tension member 11 exposed at the terminal is fixed to the tension member fixing tool 21. As a result, the holding block 5 fixed to the optical fiber cable 10 is set in a state in which it comes into contact with the sleeve 33. 3. The optical fiber 12 connected to the terminal of the optical fiber cable 10 and the optical fiber 12a connected to the terminal of the branching optical fiber cable 10a drawn into the optical closure 1 from each cable hole 32 are connected.
The optical connection portion between the 2 and 12a and the excess length are accommodated in each tray 23. The remaining optical fibers 12 are bundled by each binding tool 22 and fixed to the fixing plate 24. 4. The heat-shrinkable tube 6 is heat-shrinked, and the sleeve 33 and the grip block 5 are integrated. Thereby, the water stopping process of the cable hole 31 is completed.

Therefore, unlike the conventional apparatus, it is not necessary to disassemble and assemble the end plate 3 as a divided structure, so that the water stopping operation of the cable hole 31 can be facilitated and the structure of the end plate 3 is simplified. And the cost of the product can be reduced. The optical fiber cable 10a inserted into the cable hole 32 is fixed by filling the cable hole 32 with an adhesive or the like.

The work of fixing the end face plate 3 to the closure sleeve 2 is performed by using the optical fiber cables 10a, 10a, and 10b.
After completion of the fixing operation of the tension member of FIG. And 4. Between
Or, 4. After the completion of. Also, the cable hole 31
The water stopping procedure is not limited to the one described above. For example, after the tension member 11 of each optical fiber cable 10 is fixed to the tension member fixing tool 21, the grip block 5
2. the optical fiber cable 10 can be fixed collectively by The procedure can be appropriately changed, for example, by heat-shrinking the heat-shrinkable tube 6 to integrate the sleeve 33 and the gripping block 5 before the procedure (1).

According to this water stopping structure, the two optical fiber cables 10 are collectively tightened between the holding blocks 5, so that both are securely fixed. That is, since each of the optical fiber cables 10 is fixed so that each of the projections 53 bites into its outer skin, the fixing of the optical fiber cable 10 does not depend on the adhesive and the sealing between the holding block 5 and each of the cables 10 can be performed. Maintained for a long time. Since the heat-shrinkable tube 6 wraps and seals the sleeve 33 and the grip block 5, the space between the sleeve 33 and the grip block 5 is securely sealed. Therefore, even when the optical closure 1 is installed in a manhole, a handhole, or the like where there is a possibility of inundation, or when installed in an environment exposed to wind and rain, the waterproofness of the cable hole 31 is stable for a long time. To prevent the light closure 1 from being flooded.

The two optical fiber cables 10 passing through one cable hole 31 are curved in the optical closure 1.
The optical fiber cable 10 has a structure in which a large number of optical fibers 12 exposed from the end of the optical fiber cable 10 are bent and stored in the optical closure 1, so that the extra length of the optical fiber cable 10 can be easily stored. . And
Since the optical fiber 12 can be taken out of the optical closure 1 without cutting it (the target tray 23 can be opened by opening the trays 23 by the hinge 27), it is possible to cope with rear branching.

The present invention is not limited to the above-described embodiment, and various changes can be made. For example, cable hole 31
The two optical fiber cables to be inserted into the optical fiber cable are not limited to those that are bent by bending one optical fiber cable, but may be two different optical fiber cables. However, it goes without saying that the effect of the present invention is remarkable when applied to a case where two optical fiber cables are formed from the same one optical fiber cable.
Further, as the connection sealing means of the present invention, various configurations can be adopted, such as a configuration in which a tube that is not thermally shrunk over the sleeve of the end face plate and the holding block, and a band that fastens and fixes the tube from the outside. is there.

[0026]

As described above, according to the optical closure water blocking structure of the optical closure of the present invention, the grip block for fixing the two optical fiber cables together and the space between the end face plate and the grip block are wrapped. The optical fiber cable is securely fixed without depending on the adhesive, and the seal between the grip block and each cable is maintained for a long time. As a result, even when the optical closure is installed in a manhole or handhole where there is a possibility of flooding, or when installed in an environment exposed to wind and rain, the waterproofness of the cable hole is stably maintained for a long time. It can be maintained and the light closure can be reliably prevented from being flooded. Further, unlike the conventional apparatus, the end plate does not need to have a divided structure, and the structure can be simplified to reduce the cost of the product and improve the workability. According to the water blocking structure for the cable hole of the optical closure according to the second aspect, since the heat-shrinkable tube is used as the connecting and sealing means, the waterproof property of the cable hole can be secured by a very simple operation, and the workability can be improved. According to the water blocking structure of the optical hole of the optical closure according to the third aspect, even if two optical fiber cables formed by folding one optical fiber cable are inserted into the cable hole, cost reduction can be achieved. Workability can be improved. It goes without saying that the optical fiber of the optical fiber cable can be accommodated in the optical closure without being cut, and can be adapted to a later branch.

[Brief description of the drawings]

FIG. 1 shows an embodiment of the present invention, in which (a) is a side view of an optical closure and (b) is a front view.

2A is a cross-sectional view taken along line AA of FIG. 1B, and FIG. 2B is a cross-sectional view taken along line CC of FIG. 2A.

3A is a cross-sectional view taken along line BB of FIG. 1B, and FIG. 3B is a cross-sectional view taken along line DD of FIG. 3A.

FIG. 4 is a perspective view showing a water-stop structure according to the embodiment of the present invention, showing a state in which a part of the heat-shrinkable tube is broken.

FIG. 5 is a perspective view showing a state where a grip block is installed near an end face plate.

FIG. 6 is an exploded perspective view of the grip block.

FIG. 7 is a perspective view showing a state where an optical fiber cable is fixed by integrating a holding block.

8A and 8B show a conventional example, in which FIG. 8A is a side view of an optical closure, and FIG. 8B is a front view.

FIG. 9 is a view showing a conventional example, and is a front view showing an optical closure including an end plate having a structure divided into a plurality of parts.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 ... Optical closure, 2 ... Closure sleeve, 3 ... End plate, 5 ... Grip block, 6 ... Connection sealing means, Heat shrinkable tube, 7 ... Bolt, 10 ... Optical fiber cable, 12 ...
Optical fiber, 31 ... cable hole, 33 ... sleeve, 51
... Cable engagement groove, 53 ... Die projection, 55 ... Joint flange, 56 ... Joint surface, 58 ... Indent

 ──────────────────────────────────────────────────続 き Continued on the front page F term (reference) 2H036 RA12 2H038 CA38 CA42 CA48 5G375 AA18 BA02 BB10 BB43 DB24 DB41

Claims (3)

[Claims] 2. An optical fiber cable comprising: an optical fiber cable having an open end face plate for accommodating an optical connection portion between optical fibers drawn from an optical fiber cable; Cable hole (31)
A grip block (5) for fixing the optical fiber cables inserted through the cable holes in a lump, and wrapping and sealing between the end face plate and the grip block;
A watertight structure for a cable hole of an optical closure, comprising: a connection sealing means (6) for connecting between the end face plate and the grip block. 2. A sleeve (3) protruding from said end face plate.
In 3), the cable hole is opened, and the heat as the connection sealing means provided so as to cover the sleeve and the gripping block installed at the tip of the sleeve protruding from the end face plate from the outside. The watertight structure for a cable hole of an optical closure according to claim 1, wherein the structure is integrated by a shrinkable tube (6). 3. The optical fiber cable according to claim 1, wherein the two optical fiber cables passing through the one cable hole are formed of one optical fiber cable that is folded back in the optical closure. Water-proof structure for cable hole of light closure.