JPH09159840A - Optical fiber distribution board - Google Patents

Abstract

PROBLEM TO BE SOLVED: To increase the operation efficiency of switching by arranging a jumper cord storage rack body which has channel-shaped horizontal section between two tray storage rack bodies and storing a jumper cord distribution part which is congested with wires in the independent rack body. SOLUTION: A connector tray storage part 11 is provided at the upper part in a line-side tray storage rack body 1 and a fusion splicing part tray storage part 14 is provided at the lower part. Many optical fiber cords 105 are longitudinally bundled and held inside the right-side wall 2b of a device-side tray storage rack body 2 along the side wall 2b, and a cord support part 9 is provided which consists of cord clamps 17 in many stages for branching a specific number of optical fiber cords from the bundle. Further, the center jumper cord storage rack body 3 has the channel-sectioned horizontal section and an extra-length storage space 3a for jumper chords 106 is formed in its front. Thus, the dedicated rack body 3 which stores the jumper cords 106 is provided to efficiently switch the connections of many jumper cords 106.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical wiring board for an optical fiber cable or an optical fiber cord.

[0002]

2. Description of the Related Art In order to branch and connect an optical fiber cable to an optical fiber core by optical connection, an optical distribution board which terminates a large number of optical fibers to form a group is generally used. In these optical distribution boards, a connector connection part for branch connection of optical fibers, a multi-core single-core branch part, an optical cord for a jumper (hereinafter referred to as a jumper cord), and an extra length of the optical cord are compactly stored. The trays have a high density and are stacked in multiple stages.

[0003]

By the way, in view of the tendency of the number of optical cables to increase in response to the increase in the amount of transmitted information, the optical distribution board, in particular, has a larger number of optical connection parts and It has become important to accommodate the extra connection length in a compact manner. In addition, since the number of optical connection points in the optical distribution board will be enormous, it is desired to develop an optical distribution board that can quickly perform optical connection work, accommodation of optical connection parts, removal work, or connection switching work. ing.

The present invention has been made in view of the above-mentioned problems, and it is necessary to arrange the optical connector, the fusion splicing portion, the multi-core single-core branch portion, the connection extra length, etc. in a plurality of trays and store them compactly. It is an object of the present invention to provide an optical distribution board which can be improved and has improved work efficiency such as storage and removal of an optical connector and a multi-core single-fiber branch portion, and connection switching work.

[0005]

The present invention has the following features to attain the object mentioned above. That is, in the optical distribution board according to claim 1, a plurality of trays for connecting the optical fiber core wire derived from the optical fiber cable on one side to the upper end of the jumper cord by a connector are housed in a stacked state, and the trays are stacked. In a stacked state, a first tray storage frame that supports in the front-rear direction and a tray that connects the other end of the jumper cord to the other end of the jumper cord with the optical fiber cable drawn from the optical fiber cable on the other side in a stacked state A second tray storage frame that stores and supports the tray so that the tray can be freely taken in and out in the front-rear direction, and a first tray arranged on the left and right with a space therebetween.
The above-mentioned problem is solved by including a jumper cord storage frame which is disposed between the tray storage frame and the second tray storage frame and whose inside is a jumper cord extra length storage space.

According to a second aspect of the present invention, there is provided the optical wiring board according to the first aspect, wherein one end side and the other end side of the jumper cord are respectively aligned with the inner surfaces of both side walls of the jumper cord accommodating body facing each other. The provision of the cord supporting portion for clamping is the means for solving the above problems.

[0007]

DESCRIPTION OF THE PREFERRED EMBODIMENTS One embodiment of the present invention will be described below with reference to the drawings. FIG. 1 shows the overall structure of the optical wiring board of this embodiment, (a) is a front view, (b) is AA of FIG.
It is a schematic sectional drawing of an arrow part. This optical distribution board is composed of three adjacent unitized frames 1, 2, 3 and a height adjustment box 4 on which they are mounted. When viewed from the front, the three racks include a line-side tray storage rack (first tray storage rack) 1, a center jumper cord storage rack 3, and a right device-side tray storage rack (first tray storage rack). 2 tray storage frame) 2. These frames form a single box as a whole, and an opening / closing door (not shown) is provided on the front surface of the box.

Above the inside of the line side tray storage frame 1,
A connector tray storage portion 11 is provided, and a fusion portion tray storage portion 13 is provided below the connector tray storage portion 11. A large number of connector trays 31 and a large number of fusion part trays 40 are individually supported in the tray accommodating portions 11 and 13 in a stacked state so that they can be individually taken in and out in the front-rear direction. The connector tray 31 and the fusion portion tray 40 are supported by the rear panel 1a of the line-side tray storage frame 1 so as to be slidable in the front-rear direction.

The fusion tray 40 is provided with each optical fiber core wire 113 led out from the optical fiber cable 101 on the line side.
Is for fusion-splicing with each optical fiber core wire 114 of the connecting cord 104 and for accommodating the extra connection length thereof. The cord clamp 41 and the optical fiber core wires 113, 114 are provided on the tray surface. Of the optical fiber cords 113 and 114, and a temporary fixing fixture 45 for temporarily fixing the fusion spliced portions of the optical fiber core wires 113 and 114. Wiring from the optical fiber cable 101 to the fusion tray 40 is performed as follows.

First, the optical fiber cable 101 on the line side
Peel off the sheath at the end of the working length (about 2 to 2.5 m) and set the tension member to an appropriate length (about 15 mm) from the sheath end.
Cut at 0 mm) and cover the cut end with a protective cap. For cables reinforced with Kevlar, cut the Kevlar according to the tension members. In the case of a slot type cable, a slot is used to make a groove and the slot is peeled off.

Next, the optical fiber core wires 113 drawn out from the respective tubes of the optical fiber cable 101 are collected for each unit, covered with a protective silicone tube having an identification color, and the end portion of the silicone tube is exposed to light. The optical fiber cord 103 is formed by being fitted into each tube end of the fiber cable 101. In the case of a slot type cable, a silicon tube is used to
After grouping 13 into units, the end portion of the silicon tube is fixed with a vinyl tape to form the optical fiber cord 103.

Then, the optical fiber cable 101 is fixed to the line side tray storage frame 1 with the cable clamp 20,
After the optical fiber cable 101 is clamped, the tension member is fixed by the tension member clamp 21. In the case of a cable reinforced with Kevlar, twist the Kevlar and crimp it to the crimp terminal, and fix the crimp terminal and the tension member at the same time.

Then, after the cable end treatment, the optical fiber core wire 113 encoded by the silicon tube is used.
To the fusion unit tray 40. In that case, first, in a state where the fusion tray 40 is pulled out to the front, the introduced optical fiber cord 103 is fixed by the cord clamp 41 so that the optical fiber core wire 113 can secure the minimum radius. Then, the coating (silicon tube) on the tip end side is peeled off from the clamp portion at a predetermined position to secure the extra length of the optical fiber core wire 113 that has been led out, and the extra length portion is locked by the projecting piece 42.

On the other hand, as shown in FIG. 3, the connector tray 31 has an optical fiber core wire 1 drawn from a connecting cord (completed product having an SC type connector plug at one end) 104.
14 for connecting the optical fiber core wire drawn from one end of the jumper cord 106 (see FIG. 1 or FIG. 9) to the connector, and accommodating the extra connection length thereof,
A rising edge 31a is provided on substantially the entire circumference. Connector tray 3
A plurality of connector holders 37 for detachably supporting the optical connectors are arranged in the central portion of the upper surface of 1. The connection cord 104 and the jumper cord 106 are wound around the outer periphery of the connector holder 37 on both sides, and the reels 33 and 34 that maintain their bending radii and the branch portion from the multi-core cord to the single-core cord ( And a branch portion holder 36 for supporting the fan-out portion). Also, the connector tray 3
An inlet 38 for the connecting cord 104 and an inlet 39 for the jumper cord 106 are provided on the left and right of 1.

Cord 10 for connecting to the connector tray 31
The wiring of No. 4 is performed as follows. First, a connection cord 10 for a finished product with a connector plug (not shown) at one end
4 is prepared, and the one with the connector plug of the connecting cord 104 is pulled out in advance to the connector tray 3
It is introduced from the side introduction port 38 to the upper surface of 1. Then, an extra length is secured on the connector tray 31, a connector plug is connected to one end of a connection adapter (not shown), and this is stored in the connector holder 37. In the case of a two-core (four-core) single-core branch cord, the connecting cord 104 composed of a two-core single-core branch cord is pulled into the connector tray 31, and the dam portion is fixed to the dam fixing holder to secure an extra length. After that, connect the connector plug to the connection adapter, and
To be stored.

A center cord tray 14 for mounting an intermediate extra length of the cord 104 for connection is disposed between the connector tray accommodating portion 11 and the fusion portion tray accommodating portion 13 arranged above and below. ing.

A large number of connecting cords 104 are vertically bundled and held along the side wall 1b on the left side of the line side tray storage frame 1, and the connecting cords 104 are also provided.
A cord support portion 6 is provided for branching a predetermined number of connecting cords 104 from the bundle. Cord support 6
As shown in FIGS. 4 (a) and 4 (b), is composed of cord clamps 17 provided in multiple stages in the vertical direction. As shown in FIG. 5, the cord clamps 17 of the respective stages include a strip plate 17a supported by the side wall 1b, a large number of support plates 17b projecting from the strip plate 17a at intervals in the front-rear direction, and a support plate 17b. It is composed of a gripping elastic body (for example, sponge) 17c fixed in between, a slit 17d penetrating vertically is formed in the gripping elastic body 17c, and by inserting the connecting cord 104 into each slit 17d, The connecting cord 104 can be held in a state of extending in the vertical direction. In this case, since a plurality of slits 17d are secured in the front-rear direction by the number of gripping elastic bodies 17c, the connecting cords 10 are sequentially connected to the slits 17d of the cord clamps 17 at each stage.
By inserting the bundle of four, the connecting cord 104 is planarly held along the side wall 1b of the line-side tray storage frame 1.

Here, as shown in FIG. 4B, the connecting cord 104 extended from the connector tray 31.
Is first inserted into the slit 17d at the foremost end of the nearest cord clamp 17, and is sequentially shifted one by one into the slit 17d at the rear end as it goes to the lower cord clamp 17. Then, as a result, the entire connecting cord 104 is held in a state of being diagonally arranged in parallel. The lower end portion of the connecting cord 104 is guided to the opposite side of the fusion portion tray 40 through the center cord tray 14 and introduced to the upper surface of the fusion portion tray 40 as shown in FIG. , And is connected to the optical fiber cord 103 introduced from the opposite side. This connection is made as follows.

First, the connecting cord 104 introduced onto the fusion tray 40 is fixed by the cord clamp 41, the cord coating on the tip side of the clamp portion is peeled off, and the optical fiber core wire 114 is led out. Then, the connecting cord 104
The optical fiber core wire 114 of the optical fiber cord 103 introduced from the opposite side of the fusion-bonding part tray 40 is locked by the projecting piece 42 while securing an extra length.
13 and fusion-splice with each other. Since the fusion-bonding portion is reinforced by the fusion-bonding portion reinforcing sleeve, the fusion-bonding portion is formed into a cylindrical shape, and the fusion-bonding portion is fitted into the temporary fixing fixtures arranged in the center of the fusion-bonding portion tray 40 to fix the fusion-bonding connection portion.

On the other hand, a connector tray accommodating portion 12 is also provided above the inside of the apparatus-side tray accommodating frame 2 arranged on the opposite side.
A large number of connector trays 32 are individually supported in a stacked state so that they can be inserted and removed in the front-rear direction. Connector tray 32
Is supported by the back panel 2a of the apparatus-side tray storage frame 2 so as to be slidable in the front-rear direction. Since the structure of the connector tray 32 is almost the same as that of the connector tray 31 described above, the description thereof will be omitted. Also,
Below the apparatus-side tray storage frame 2, extra length storage sections 15 and 1 are provided.
6 are provided.

As shown in FIG. 8, the optical fiber cord 1 is also provided inside the side wall 2b on the right side of the apparatus side tray storage frame 2.
A number of optical fiber cords 105 extended from 05
Of the optical fiber cords 105 for holding a plurality of the optical fiber cords 105 in the form of a bundle in the vertical direction and branching a predetermined number of the optical fiber cords 105 from the bundle of the optical fiber cords 105. It is provided. As shown in FIG. 8B, the optical fiber cords 105 are also connected to the cord supporting portion 9 in parallel and obliquely held as in the line side.

Further, as shown in FIGS. 6 and 7, an optical fiber cable fixing fitting 51 is provided at an upper portion of the apparatus side tray storage frame 2 at a portion where the optical fiber cable 102 connected to the apparatus is introduced. . The fixing bracket 51 is formed by projecting a plurality of support plates 51b on a back strip 51a, and the optical fiber cable 102 is fixed by an insulation lock 51c.

The jumper cord storage frame 3 in the center
As shown in FIG. 1 (b), the horizontal cross section is U-shaped, the front surface is open, and the inside is the extra length storage space 3 a of the jumper cord 106. Then, the opposite side walls 3
Jumper cord support portions (cord clamps) 7 and 8 are provided on the inner surfaces of b and 3b, respectively. These cord supporting portions 7 and 8 are also the same as the cord supporting portion 6 described above, and are composed of a multi-stage cord clamp 17. Therefore,
A large number of jumper cords 106 can be bundled and housed in parallel with each other in a plane along the front-rear direction (depth direction).

The jumper cord 106 between the connector trays 31 and 32 and the cord supporting portions 7 and 8 is a distribution portion 1 at the front end of both side walls 3b and 3b of the jumper cord housing 3.
It is sorted by 9a. Sorting unit 19a
Attaches the front end of the side wall 3b to the connector tray storage portions 11, 12
It is curved in a semi-circular shape toward the side and has a hook 19b for hooking the cord on the tip end surface. Therefore,
Regardless of when the connector trays 31 and 32 are stored in the connector tray storage portions 11 and 12 or when the connector trays 32 are pulled out, the curvature radius of the jumper cord 106 at the front ends of the side walls 3b and 3b can always be stably ensured.

Then, as shown in FIG. 9, the connector plug at one end of the jumper cord 106 accommodated in the jumper cord accommodating body 3 is branched from the connecting cord 104 on the line side connector tray 31. The connector is connected to the cord via the connection adapter, and the connector on the other end of the jumper cord 106 is connected to the optical fiber cord 105 via the connection adapter on the connector tray 32 on the device side. A pair of the cord 104 on the connector tray 31 accommodated in the line side tray accommodating body 11 and the cord 105 on the connector tray 32 accommodated in the device side tray accommodating body 12 is switchably connected. .

Note that the connection adapter, after connecting the connector,
It is housed in the connector holder 37. Further, the connection cord 104 and the optical fiber cord 105 wired to the connector trays 31, 32 are drawn into the connector trays 31, 32 through the introduction port 38, and then appropriately curved and branched into a single core. Branched optical fiber core wire 11
The extra length is secured by winding 4, 115 around the reel 33, and the jumper cord 106 is provided by an optical connector (not shown) supported by the connector holder 37.
It is connected to the. Similarly, the extra connection length of the jumper cord 106 caused by these optical connections is subjected to a curving process with a curving radius larger than a prescribed value by using the reel 34 on the other side of the connector trays 31, 32.

Then, the connection work is carried out by the connector tray 3
Jumper cord 1 by optical connector on 1, 32
06 is completed by connecting to the mating connector. After the connection is completed, the connector trays 31 and 32 may be slid to a predetermined storage position.

In this optical wiring board, the connection between the connector trays 31 and 32 can be switched by replacing the wiring to the connector trays 31 and 32 of the jumper cord 106 housed in the jumper cord housing 3.
In the switching work, jumper code 10
When changing the position of the cord clamp 17 that holds 6, jumper cord is removed from the original slit 17d,
Slit 17d close to the target connector tray 31, 32
Reinsert into. At this time, the extra length of the jumper cord 106 in the jumper cord housing 3 is used to prevent the jumper cord 106 from being insufficient in length.

According to the optical distribution board of this embodiment, since the dedicated frame 3 for housing the jumper cords 106 is provided, the connection switching work of a large number of jumper cords 106 can be prevented from interfering with other optical fibers. However, it can be performed efficiently, and the switching work efficiency is improved. Further, since the line side tray storage frame 1, the device side tray storage frame 2 and the jumper cord storage frame 3 are unitized respectively, the assembly can be done easily.

[0030]

As described above, according to the optical distribution board of the first aspect, the jumper cord having a horizontal U-shaped cross section between the two tray housings arranged side by side at a distance. Since the storage frame is arranged and the jumper cord wiring part where wiring is crowded is accommodated in an independent frame, it is possible to store a large number of jumper cords in an organized state, making it easier to handle the jumper cords. The connection switching work can be performed while avoiding interference with other optical fibers (for example, entanglement with jumper cords), and the switching work efficiency is improved.

Particularly, according to the optical distribution board of claim 2,
Since a cord support portion for clamping one end side and the other end side of the jumper cord in an aligned state is provided on the inner surfaces of the opposite side walls of the jumper cord storage body, it is possible to store a large number of jumper cords while organizing them. It is possible to improve work efficiency and facilitate post-switching work.

[Brief description of the drawings]

FIG. 1 is an overall configuration diagram of an embodiment of the present invention, in which (a) is a front view and (b) is a schematic cross-sectional view taken along the line AA of FIG.

FIG. 2 is a plan view of a fusion tray according to the embodiment.

FIG. 3 is a plan view of the connector tray in the embodiment.

4A and 4B are configuration diagrams of a line-side tray storage frame in the same embodiment, in which FIG. 4A is a front view and FIG. 4B is a view taken along the line BB in FIG.

5 is a detailed perspective view of the cord support portion shown in FIG. 4 (b).

FIG. 6 is a front view showing the upper structure of the apparatus-side tray storage frame in the embodiment.

FIG. 7 is a detailed perspective view of a C portion of FIG.

8A and 8B are configuration diagrams of a device-side tray storage frame in the embodiment, in which FIG. 8A is a front view and FIG. 8B is a view taken along the line D-D in FIG. 8A.

FIG. 9 is a plan view showing an example of connecting the line-side connector tray and the device-side connector tray with jumper cords in the embodiment.

[Explanation of symbols]

1 ... Track side tray storage frame (first tray storage frame),
2 ... Device side tray storage frame (second tray storage frame),
3 ... jumper cord storage frame, 3a ... extra length storage space, 3
b ... Side wall, 7, 8 ... Cord support (cord clamp),
11, 12 ... Connector tray storage section, 31, 32 ... Connector tray, 101, 102 ... Optical fiber cable, 1
03, 105 ... Optical fiber cord, 104 ... Connection cord, 106 ... Jumper cord

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Hideo Kikuchi 1440 Rokuzaki, Sakura City, Chiba Prefecture Fujikura Ltd. Sakura Factory

Claims (2)

[Claims] 1. An optical fiber cable (101) on one side
An optical distribution board for connecting the optical fiber core wire (113) derived from the optical fiber core wire (113) and the optical fiber core wire (105) derived from the other side optical fiber cable (102) by a jumper cord (106) so as to be switchable. A plurality of trays (31) for connecting the optical fiber cores led out from the optical fiber cable on one side to the upper end of one of the jumper cords and connectors are housed in a stacked state and the trays are supported so that they can be taken out and put in the front-rear direction. 1 tray storage frame (1) and a plurality of trays (32) for connecting the optical fiber cores derived from the optical fiber cable on the other side to the other end of the jumper cord on the upper surface by a connector A second tray storage frame (2) that supports the tray so that it can be freely taken out and in the front-rear direction, and a first tray storage frame and a second tray storage frame that are arranged side by side with a space therebetween. Disposed between the tray accommodating rack body, inside slack storage space (3a) and has been jumper cord storage rack of jumper cord (3) and the optical wiring board, characterized in that it comprises a. 2. The optical distribution board according to claim 1, wherein the opposite side walls (3b, 3b) of the jumper cord storage frame are opposed to each other.
3b) The optical wiring board, wherein the inner surface is provided with cord clamps (7, 8) for clamping one end side and the other end side of the jumper cord in an aligned state, respectively.