JP3173962B2 - Optical distribution frame - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION The present invention relates to an optical fiber cable,
Alternatively, the present invention relates to an optical distribution board for optical fiber cords.

[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. These optical distribution boards are trays in which a connector connection section for branch connection of an optical fiber, a multi-core single-fiber branch section, an optical cord for a jumper, and an extra length associated with the optical connection of the optical cord are compactly stored. Is a multi-layered structure with high density.

[0003]

In view of the fact that optical fibers tend to be multi-core in response to an increase in the amount of transmission information, the distribution board is particularly required to have a larger number of optical connection portions and connection portions. It has become important to store extra length compactly. In addition, since the number of optical connection points in the wiring board becomes enormous, it is desired to develop an optical wiring board that can quickly perform optical connection work, storage and removal work of optical connection parts, or connection switching work. I have.

SUMMARY OF THE INVENTION The present invention has been made in view of the above-mentioned problems, and is intended to arrange an optical connector, a fusion splicing part, a multi-fiber single-fiber branch part, a connection extra length, etc. into a plurality of trays and compactly store them. It is another object of the present invention to provide an optical wiring board which can improve the working efficiency of storing and taking out an optical connector and a multi-fiber single-fiber branching section, and connection switching work.

[0005]

The present invention has the following features to attain the object mentioned above. That is, in the optical wiring board according to claim 1, a box, and disposed in the box,
A plurality of first trays that connect the optical fiber cores derived from the respective optical fiber cables to each other through the optical connection portion inside are housed in a stacked state, and are supported so that they can be freely put in and out in the front-rear direction of the box. A first tray accommodating portion, and a plurality of second trays internally connecting the optical fiber cores to each other via an optical connection portion different from the first tray, the first tray in the first tray accommodating portion; And a second tray storage portion that is stored in a stacked state following the stacking of the first and second tray storage portions and is supported so as to be able to be freely taken in and out in the front-rear direction of the box, and is disposed between the first and second tray storage portions. 1, first stored in the second tray storing unit, and the connection cord for connecting the second tray each other, and a center cord tray for accommodating the intermediate portion of the connecting cord, the first tray storage
The first tray at the top of the tray and the second tray at the top
An upper layer second tray is connected by the connection cord,
Hereinafter, the first tray below the uppermost first tray and the first tray below
The second tray below the upper second tray is the first tray.
That are sequentially connected by a connecting cord in the same stack <br/> rank among the array receiving unit and the second tray storing unit and the solutions of the problems.

According to a second aspect of the present invention, there is provided the optical distribution board according to the first aspect, wherein a cord supporting portion for supporting a connection cord is provided on a side portion of the first and second tray storage sections.
First fastener to be parallel to a plane holding the code for multiple connections to the cord support portion provided with a plurality at predetermined intervals, the nearest to the second tray the connecting cord that is itself connected Of the first fixture, and
The plurality of connection cords held by the fixing device are wired in parallel to the center code tray without intersecting with each other.

In the optical wiring board according to a third aspect, in the optical wiring board according to the second aspect, the first fixing member has a configuration in which the connecting cord is arranged in parallel on one plane along the front-rear direction of the box. , the second tray the connecting cord that is itself connected, is gripped at the front end of the first tray or the nearest first fastener to the second tray, and, approaching the center cord tray According to the above, the wiring is inclined to the rear side of the box as a means for solving the above problem.

According to a fourth aspect of the present invention, in the optical distribution board according to the second or third aspect, the center code tray is provided with a plurality of connection cords arranged in parallel with each other along one plane. A solution to the above-described problem is that a pair of second fixing tools that are gripped and fixed in parallel are provided, and the arrangement order of the connecting cords is reversed between the second fixing tools.

[0009]

According to the optical distribution board of the first aspect, the first and second optical distribution boards are provided.
The first and second trays stored in the tray storage unit are connected by a connection cord wired via a center code tray. At this time, the connection code is
Wiring is performed from one side of the first and second trays that are continuously laminated to the other side through the center code tray, compared with a case where the wiring is routed outside the first and second trays. The wiring length is shortened. Further, since the same stacking order of the first and second trays is connected to each other by the connection cord and is regular, workability particularly when optically connecting a larger number of optical fiber cores is improved. .

According to the optical wiring board of the second aspect, the plurality of connection cords are gripped by the first fixture and wired in parallel, so that the relative arrangement order of these connection cords is established. Is constant at any place of the cord supporting portion, so that entanglement with each other can be prevented, and the wiring of the optical fiber core wire and the connection cord in the casing can be efficiently performed.

According to the optical wiring board of the third aspect, the first fixing device is connected to the connection cord held at the front end.
When the second tray is pulled out to the front of the box , the connection length of the connection cord between the second tray and the front end of the first fixture is within a range in which the connection length can be moved within the range of the first fixture. It can be withdrawn. Also, the wiring portion of the connection cord from the second tray to the first fixture and the wiring portion of the connection cord from the first fixture to the center code tray are relatively bent at the first fixture. Since the wiring portion from the first fixing tool to the center code tray is inclined toward the rear side of the box so as to go from the first fixing tool to the center code tray , the second tray is moved from the second tray storing portion to the box. The angle of bending when pulled out to the front side is reduced, and the bending radius of the connecting cord is maintained.

According to the optical wiring board of the fourth aspect, the arrangement order of the connecting cords is reversed between the pair of second fixing members of the center code tray, so that the first and second optical wiring boards are arranged.
The arrangement order of the connecting cords in the cord supporting portions installed adjacent to the respective tray storage portions has a symmetrical relationship.

[0013]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS One embodiment of the optical wiring board according to the present invention will be described below with reference to FIGS. As shown in FIG. 1, the optical distribution board includes an optical fiber cable 2 that rises from the lower part of the box 1 inside a box 1 fixedly installed at a predetermined position.
A branch portion 4a for laying a bundle of optical fiber cords 3a (optical fiber core wires) upward from the outlet portion of the branch portion;
The optical fiber cord 3a pulled out from the optical fiber cable 1 is connected to the connection cord 3b via a fusion splicing reinforcing part (not shown), and the fusion splicing part tray 6 (the first splicing part tray 6) that accommodates the fusion splicing reinforcement part. Tray storage section T1 for storing a large number of trays) in a stacked state on the lower side of the box 1.
(First tray storage section) and a number of connection cords 3b provided on the left side inside the box 1 and pulled out from each fusion section tray 6 are bundled in the vertical direction inside the box 1. A cord supporting portion 4 that supports and branches a predetermined number of connecting cords 3b from the bundle of connecting cords 3b, and an optical adapter 5 (optical Connector; see FIG. 5) and a branch connection tray 8 for storing a branch connection tray 8 (second tray) that is branched and connected via a multi-fiber single-core branch portion 7 (see FIG. 5) in the upper part of the box 1. A storage section T2 (second tray storage section), a jumper cord j wired on the inner side of the right side of the frame 1 for switching jumpers between the branch connection trays 8, and an intermediate portion of the connection cord 3b. Center cord tray to store -9.

An openable and closable door (not shown) is attached to the front of the box 1 (on the front side in FIG. 1). From the central part of the box 1 to the upper part, a plurality of back connection panels 8 constituting a branch connection tray storage T2 by supporting a plurality of the branch connection trays 8 in a vertically stacked state are provided on the back wall of the box 1. Fixed. On the back wall at the bottom of the box 1, a back panel 1 formed smaller than the back panel 10
1 is fixed. The rear panel 11 forms a fusion part tray storage T1 together with the plurality of fusion part trays 6 . These fused portion tray housing portion T1 and the branch connection tray housing section fusion part tray 6 which is supported by the T2 and branch connection tray 8, the clearance between the fused portion tray housing portion T1 and the branch connection tray housing section T2 , Are substantially continuously laminated.

The cord support 4 extends inside the left and right (left and right in FIG. 1) side walls 12 of the box 1 along the vertical direction of the box 1. The cord supporting portion 4 includes an optical fiber cord 3a and a connection cord 3 on the side of the fusion portion tray storage portion T1 and the branch connection tray storage portion T2.
b and the jumper cord j are supported and stored in a bundle. The cord support portion 4 is provided with a plurality of protrusions at predetermined intervals on the inner surface side of the both side walls 12 and holds a plurality of connection cords 3b or jumper cords j to form a box 1
First fixture 4 to be arranged in a plane along the front-back direction
b is provided. In the cord supporting section 4, the connecting cord 3b and the jumper cord j connected to the fusion section tray 6 or the branch connection tray 8 are connected to the first or closest fusion section tray 6 or the branch connection tray 8, respectively. Is held by the fixture 4b.

As shown in FIG. 2, the first fixture 4b comprises a support plate 4c projecting from the side wall 12 and a plurality of elastic members 4d for gripping fixed to the support plate 4c. And is fixed along the front-back direction of the housing 1. The gripping elastic body 4d is formed of a sponge or the like, and the connection cord 3b and the jumper cord j are inserted into a slit 4s formed from the front end to the central portion.
These are gripped.

In the cord supporting portion 4, the cord supporting portion 4 on one side (left side in FIG. 1) of the branch connection tray storage portion T2.
In FIG. 3e, as shown in FIG.
Is gripped by the front end of the first fixing tool 4b closest to the branch connection tray 8 to which the terminal is connected, and is inclined and wired to the rear side of the box as the center code tray 9 is approached. . In addition, the plurality of connection cords 3b wired to the cord support portion 4e are wired in parallel to the center code tray 9 without crossing each other. In the cord support portion 4f on the other side of the branch connection tray storage portion T2, a large number of jumper cords j are wired,
The branch connection trays 8 are mutually wired. These jumper cords j are also arranged and wired by being gripped by the first fixture 4b. A part of the jumper cord j may be led out of the box 1 via the jumper cord storage tray 9a installed at the upper end of the branch connection tray storage part T2. In addition, jumper code j
May be led out from the lower end of the box 1.

One side of the fusing section tray storage section T1 (FIG. 1)
In the cord supporting portion 4g at the middle left side, the optical fiber cord 3 branched from the optical fiber cable 2 at the branching portion 4a.
a is directly wired to the target fusion part tray 6. Cord support 4h on the other side of the fusion tray tray storage T1
As shown in FIG. 4, the connection cord 3b is
The wire is wired without using the fixing tool 4b, and is directly connected to the fusion portion tray 6. The cord supporting portion 4h connects the connecting cord 3b connected to the uppermost fusion portion tray 6 of the fusion portion tray storage portion T1 to the front end (left side in FIG. 4) of the center code tray 9, Hereinafter, the fusion tray 6 below the uppermost fusion tray 6
Are connected in sequence to the rear side of the center code tray 9.

As shown in FIG. 1, the branch portion 4a extends inside the one side wall 12 at the lower portion of the box 1, and is adjacent to the cord support portion 4g of the fusion tray tray storage portion T1. I have. The branch portion 4a is configured to fix two optical fiber cables 2 connected to each other by a fixing member 13 projecting from the inner surface of the side wall 12.

As shown in FIG. 5, mounting members 14 extending substantially over the entire vertical direction of the rear panel 10 are opposed to each other at the left and right ends when the rear panel 10 is installed on the box 1. Have been. A plurality of guide rods 15 for supporting the branch connection tray 8 are fixed to the mounting member 14 in a direction projecting vertically from the back panel 10. These guide rods 15 are arranged on the left and right mounting members 14 so as to form a pair in which the vertical positions coincide with each other on the back panel 10. The guide rod 15 includes a straw-shaped outer guide 16 and the outer guide 16.
Rod-shaped inner guide 17 slidably fitted inside
By changing the amount of projection of the inner guide 17 from the tip of the outer guide 16, the inner guide 17 can be extended and contracted. At the tip of the inner guide 17, as shown in FIG.
A screw 18 is screwed. A guide bar 15 is provided on the back panel 11 for the fusion tray 6 in the same manner as the back panel 10.

As shown in FIG. 5, the branch connection tray 8 is mainly composed of a tray body 21 having a side wall 20 over the entire periphery of an edge of a rectangular flat bottom plate 19. At the center of the bottom plate 19, there is provided a connector support band 23 in which a plurality of connector holders 22 for detachably supporting the optical adapter 5 are arranged in one direction.

The connector holder 22 is formed of an elastic body such as plastic or rubber. As shown in FIGS. 5 and 7, two L-shaped projections 24 projecting from the bottom plate 19 are combined. It is configured.
A clearance 26 having an opening shape into which the flange 25 of the optical adapter 5 can be fitted is provided between the two projections 24 constituting the same connector holder 22. An optical fiber core h1 branched from the jumper cord j and an optical fiber core h2 branched from the connection cord 3b are connected to the optical adapter 5 via plugs 34, respectively. At both ends in the extending direction of the connector support band 23, end holders 22a that support the optical adapter 5 are provided between the connector holders 22 and the connector holders 22 located at both ends of the row. The optical adapter 5 has a built-in positioning ring of a zirconia ferrule of an SC type optical connector, and has a single core SC.
This is an SC type optical adapter constituting an intermediate portion of the type connector.

As shown in FIG. 5, on both sides of the connector support band 23 on the bottom plate 19, jumper cords j are provided on the outer periphery.
A total of three reels 27 for maintaining the bending radius of the jumper cord j and the connection cord 3b by winding the connection cord 3b, and a branch for holding the multi-core single core branch 7 (fan-out part). The holder 28 is attached. In the vicinity of the connector support band 23 on the bottom plate 19, a display plate P for displaying a storage line or the like in the branch connection tray 8 is mounted. In the vicinity of the branch portion holder 28 of the bottom plate 19, a fixture S for fixing the jumper cord j or the connection cord 3b wired on the bottom plate 19 is provided in a protruding manner.

At the center of each short side wall 20 on both short sides of the bottom plate 19, an entrance 30 for a jumper cord j and a connection cord 3b is provided. Further, a first engagement piece 31 that engages with the outer guide 16 of the guide rod 15 is fixed to the outer side of the outer surface of the side wall 20 (the right rear side of the paper in FIG. 5), and is located on the near side (the left front side in FIG. 5). Is fixed to a second engagement piece 32 that engages with the inner guide 17. As shown in FIG. 6, the second engagement piece 32 is mounted on the screw 18 screwed to the tip of the inner guide 17 so that the screw 18
And the inner guide 17 is fastened and fixed.

The fusion splicing tray 6 accommodates a fusion splicing reinforcing portion (not shown) and an extra connection length. The storage structure of the fusion part tray 6 in the fusion part tray storage part T1 is the same as the storage structure of the branch connection tray 8 in the branch connection tray storage part T2. The inlet 6a of the connection cord 3b into the fusion tray 6 is opened at the front end (front side in FIG. 1; left side in FIG. 4) of the fusion tray 6.

As shown in FIGS. 1 and 8, the center code tray 9 is a flat shelf whose axis is parallel to the left-right direction of the box 1. A second fixture 33 for lightly grasping and fixing a plurality of connection cords 3b in parallel along one plane is arranged opposite each other. The second fixing member 33 has a structure in which a plurality of elastic bodies (not shown) such as sponges with slits for gripping the connection cord 3b are arranged. The connection cord 3b penetrates through the center cord tray 9, and an extra length is secured between the pair of second fixing portions 33. The connection cord 3b placed and stored in the center cord tray 9 is
A curved portion 3d is formed between the pair of the second fixing members 33, and is wired so as to cross each other so that the arrangement order of the second fixing members 33 is reversed. Moreover, the center cord tray 9 is designed such that the curved portions 3d are arranged to be displaced in the axial direction of the center cord tray 9, so that the thickness dimension does not increase.

In the optical distribution board, the optical fiber cable 2 is introduced and fixed to the branch portion 4a from below the box 1, and the optical fiber cable led out from the tip of the optical fiber cable 2 led out at the branch portion 4a. The bundle of the optical fiber cords 3a is branched, and a predetermined number of these optical fiber cords 3a are wired to one of the fusion trays 6, respectively. In the fusion tray 6, the optical fiber cord 3a is connected to the connection cord 3b via a fusion splicing reinforcement (not shown).
Connected to The connection cord 3b passes above the center code tray 9 located between the fusion part tray storage part T1 and the branch connection tray T2 and passes through the cord support part 4e on the side of the branch connection tray storage part T2. Then, each tip is wired to the branch connection tray 8. In the cord supporting portion 4e on the left side of the branch connection tray storage T2 and along the inner surface of the left side wall 12 of the box 1, the connecting cord 3
b is temporarily fixed to the fixing member 13 of the cord.

On the inner surface of the right side wall 12 of the box 1 and on the right cord support portion 4f of the branch connection tray storage portion T2,
A plurality of jumper codes j for jumper-connecting the branch connection trays 8 are wired. This jumper code j
The side wall 12 of the box 1 is
Is temporarily fixed along. A part of the jumper cord j is used as an optical connector cable for an external jumper via an opening (not shown) opened at the upper end of the branch connection tray storage portion T2 or the lower end of the box 1. Box 1
Is derived outside. The extra length of the jumper cord j is wired so as to hang down along the inner surface of the right side wall 12, so that an extra length for connection or an extra length is secured.

The connection cord 3b wired to the branch connection tray 8 is drawn into the inside of the branch connection tray 8 through the entrance 30 on one side (the left side in FIG. 5), and is appropriately stopped through the retaining portion by the fixture S. The wire is routed in the direction of returning to the entrance 30 while being curved, and is branched at the multi-fiber single-branch portion 7. The core wire of the optical fiber core wire 3j branched from the connection cord 3b by a single core is wound around the reel 27 so as to have an extra length, and is further jumpered in the optical adapter 5 supported by the connector holder 22. The connector is connected to the code j.

As shown in FIG. 7, the optical connection of the optical adapter 5 is performed by connecting the optical fiber core 3j of the connection cord 3b to be connected.
The plug 34 is provided by terminating the end of the jumper cord j with a connector, and the plug 34 is inserted from the end of the optical adapter 5 to connect the connection cord 3b and the jumper cord j. The optical adapter 5 is fitted between the connector holders 22, and the multi-fiber single-fiber branch part 7 is
8 The extra connection length of the jumper code j generated by these optical connections is 2
By using the reels 27 arranged in the base, the bending process is performed with a bending radius equal to or larger than a specified value. With respect to these extra connection lengths, extra extension lengths that are pulled out when the branch connection tray 8 is pulled out from the back panel 9 are secured near the entrance 30.

After the storage of the optical adapter 5 and the multi-core single-fiber branch unit 7 and the extra length processing in the branch connection tray 8 are completed,
The branch connection tray 8 is supported by the guide rod 15 and stored in a predetermined place in the box 1. At this time, the first engagement piece 31 of the branch connection tray 8 is attached to the outer guide 16.
6 is slidably supported in the longitudinal direction, and the second engagement piece 32
Is fixed to the end of the inner guide 17, but since the inner guide 17 is slidable with respect to the outer guide 16,
By being pulled out to the near side, it is stably drawn out while being supported by the guide rod 15.

According to the optical wiring board of the present invention, since the fusion part tray 6 and the branch connection tray 8 are regularly connected by the connection cord 3b, the light in the fusion part tray 6 and the branch connection tray 8 can be adjusted. The work efficiency of the optical connection between the fiber cables 2 is improved. That is, the fusion tray 6
Since the same stacking order in the fusion part tray storage part T1 and the branch connection tray storage part T2 is connected to each other by the connection cord 3b and the branch connection tray 8 is regular, a large number of Although the optical fiber cord 3a, the connecting cord 3b, and the jumper cord j are wired, it is easy to connect the target optical fiber cords 3a to each other, and the connecting operation can be performed efficiently. When the corresponding trays 6, 8 are pulled out and the jumper cord j is replaced with the connection cord 3b to switch the connection of the optical fiber cord 3a, the fusion part tray storage part T1 and the branch connection tray storage part are switched. Because the same stacking order in T2 is regular, the target trays 6 and 8 can be easily found, the target optical fiber cords 3a can be easily connected, and the work efficiency is improved.

The jumper cord j wired to the branch connection tray 8 has an illustration for pulling out the branch connection tray 8 between the entrance 30 of the branch connection tray 8 and each of the first fixtures 4b of the cord support 4f. No withdrawal margin is secured. On the other hand, in the connection cord 3b, the connection length 3 between the entrance / exit 30 of the branch connection tray 8 and the cord support portion 4e.
c functions as the extra drawer length. That is, the connection length 3c of the connection cord 3b is set such that when the branch connection tray 8 is inserted into and removed from the branch connection tray storage portion T2, the connection length is substantially rotated about the fixed portion of the first fixture 4b. Move to allow the branch connection tray 8 to move. Therefore, the branch connection tray 8 has the connection length 3 of the connection cord 3b.
It can be pulled out within the movable range of c.

As a result, the entrance 3 of the connection cord 3b
Since the connection length 3c between the 0 and the first fixture 4b does not need to have any extra slack as an extra draw-out length, it is possible to prevent the connection cords 3b from being entangled due to the insertion and removal of the branch connection tray 8. be able to. Further, since the connecting cord 3b is wired from the upper front side to the lower rear side in the cord supporting portion 4e, the fixing position of each connection length 3c can be secured at the front end of each first fixture 4b. In addition, entanglement can be prevented for all the connection cords 3b.

The fixing portion of the connection cord 3b in the first fixing member 4b is bent at the bending angle θ (see FIG. 4) when the branch connection tray 8 is pulled out due to the inclined wiring of the connection cord 3b in the cord support portion 4e. Tend to be large, and when the branch connection tray 8 is pulled out at the maximum, the branch connection tray 8 becomes substantially linear, so that the bending radius of the connection cord 3b is secured. Therefore, the branch connection tray 8 can be stably pulled out in a live state. Further, the connection cord 3b is gradually drawn into the rear part of the box 1 as it approaches the center code tray 9 by the inclined wiring and moves away from the front part of the box 1, so that the branch connection tray 8 can be taken in and out. Interference can be prevented.

[0036] In the cord supporting portion 4h, fusion part tray 6 of the top layer closer to the center cord tray 9 is connected to the connection cord 3b wired to the front end of the center cord tray 9, most center cord tray 9 Since the farthest lowermost fusion part tray 6 is connected to the connection cord 3b wired at the rearmost end of the center code tray 9, the connection dimension of the connection cord 3b required to pull out the fusion part tray 6 is reduced. Each of the fusion trays 6 is appropriately secured.

The second fixture 3 of the center code tray 9
The inversion of the arrangement order of the connection cords 3b between the pairs 3 makes the distribution of the wiring lengths of the connection cords 3b in the cord support portions 4e and 4h symmetrical, and the branch connection tray 8 and the fusion The connection cord 3b is prevented from interfering with the loading / unloading of the attachment part tray 6. In other words, the connection cord 3b wired between the second fixing member 33 and the fusion tray 6 and the branch connection tray 8 can be connected to the second fixing member 33 by any of the cord supporting portions 4e and 4h. The one connected to the front has a short wiring length,
The wire connected to the rear part of the second fixture 33 has a longer wiring length. As a result, all the long wiring portions of the connection cord 3b are wired to the rear part of the case 1 and are kept away from the front part of the case 1, so that the branch connection tray 8 and the fusion part tray 6 Interference with taking in and out is prevented.

Further, by reversing the arrangement order of the connecting cords 3b between the pair of the second fixing members 33 of the center cord tray 9, the length of the connecting cords 3b can be made substantially constant. That is, for example, the connection cord 3b having one end wired to the uppermost branch connection tray 8 has a central portion behind the second fixing member 33 on one side of the center code tray 9 (the left side in FIGS. 1 and 8). The other end is fixed to the front end of the second fixture 33, and the other end is wired to the uppermost fusion tray 6. Hereinafter, the branch connection tray 8 below the uppermost branch connection tray 8 and the fusion part tray 6 below the uppermost fusion part tray 6 are sequentially connected via the connection cord 3b. . Moreover,
It is necessary to secure a connection length to the connection cord 3b wired to the lower fusion part tray 6 such that the fusion part tray 6 can be pulled out.

As a result, the linear distance between the lower layer of the fusion section tray 6 and the branch connection tray 8 is shorter than that of the upper layer, but it is necessary to secure the connection length to the connecting cord 3b of the cord supporting section 4h. In any combination of the fusion tray 6 and the branch connection tray 8, the connection cord 3b having substantially the same length is used, so that it is possible to improve wiring work efficiency and reduce cost during assembly.

In the center cord tray 9, the curved portions 3d of the connecting cords 3b are arranged so as to be shifted from each other, and the thickness of the center cord tray 9 is suppressed. The branch connection tray 8 can be installed, and the storage density of the optical adapter 5 and the multi-fiber single-fiber branch portion 7 in the box 1 can be improved.

In the above embodiment, the fusion tray 6
As the branch connection tray 8, the one in which the fusion splicing reinforcing portion and the optical connector are mounted as optical connections is applied, but the content of the optical components mounted on the first and second trays is not limited to this. Not something. This optical distribution board can also be applied to an optical termination frame, a wiring board, a termination box, and a connection box for accommodating a plurality of cords with optical connectors and fan-out cords.

[0042]

As described above, according to the optical distribution board of the first aspect, a plurality of optical fiber cores derived from an optical fiber cable are internally connected to each other through the optical connection part. The first to store one tray in a stacked state
And a plurality of second trays for connecting optical fiber cores to each other through an optical connection portion different from the first tray inside the first tray storage portion. The first and second tray storage sections are disposed between a second tray storage section for storing the first and second tray storage sections successively in a stacked state, and are disposed between the first and second tray storage sections. A connecting cord for connecting the second trays to each other;
A center code tray for storing an intermediate portion of the connection cord, wherein the first tray at the top of the first tray storage and the second tray at the top of the second tray storage are provided; Connect using the connection cord, and
1st tray below the upper layer and 2nd tray below the uppermost layer
A second tray of layers with a first tray storage and a second tray.
Connection cord for the same stacking order in the tray storage
By sequentially connected by, can be summarized efficiently multiple connection cord in center cord tray, moreover, the connection cord first, it is not necessary to route above or below the second tray storing unit, The wiring length of the connection cord can be averaged and shortened. Further, since the same stacking order of the first and second trays is connected to each other by the connection cord and is regular, the work efficiency particularly when connecting a larger number of optical fiber cores, and An excellent effect is obtained such that the work efficiency of switching the connection of the fiber core is improved.

According to the optical wiring board of the present invention, a plurality of first fixing members for holding a plurality of connection cords and arranging the plurality of connection cords in a plane are provided at predetermined intervals in the cord support portion. itself is grasped first fastener nearest to the second tray that is connected, and without crossing each other a plurality of connecting cord is gripped in the first fastener to said center cord tray Wiring in parallel prevents connection cords from getting tangled with each other. In addition, since the relative arrangement order of these connection cords is fixed, the wiring is easy to understand, and the optical fiber An excellent effect is achieved such that it is possible to cope with connection of fiber core wires and switching of connection.

In the optical wiring board according to the third aspect, the first fixing member has a configuration in which the connecting cords are arranged in parallel on one plane along the front-rear direction of the box, and the connecting cords are connected to themselves. gripped by the second front end of the first fastener nearest to the tray that, and so are wired inclined a box body rear side as close to the center cord tray, the second tray of the connection cord If the connection length between the first fixture to function as pull-out excess length of the second tray, specially it is not necessary to provide a pull-out excess length to the connecting cord, for connection by loading and unloading of the second tray It is possible to prevent the cords from becoming entangled with each other, and the inclination of the connection cords secures the initial fixing position of all the connection lengths at the front end of each first fixing tool. Can prevent entanglement, etc. That.

In addition, in the fixing portion of the connection cord in the first fixture, the bent angle of the connection length becomes large when the first and second trays are pulled out due to the inclined wiring of the connection cord. Since the bending radius of the cord is ensured, the first and second trays can be pulled out in a live state. Furthermore, as the connecting cords are slopingly wired to the rear of the box as they approach the center code tray, they are distant from the front of the box, so they interfere with the insertion and removal of the first and second trays. An excellent effect is obtained that it can be prevented.

According to a fourth aspect of the present invention, in the case where the first and second trays having the same stacking order are connected to each other by connection cords wired in parallel with each other, the optical distribution board is parallel to the center code tray. And a pair of second fixing devices arranged in parallel to hold and fix a plurality of connection cords in parallel along one plane, and the arrangement order of the connection codes is inverted between these second fixing devices. Since the arrangement order of the connection cords on both sides of the center code tray is symmetrical, the regularity of connection of the first and second tray storage sections can be maintained in accordance with various wiring methods.

[Brief description of the drawings]

FIG. 1 is a front view showing one embodiment of an optical wiring board of the present invention.

FIG. 2 is a view showing one embodiment of the optical wiring board of the present invention, and is a perspective view showing a first fixture.

FIG. 3 is a view showing one embodiment of the optical wiring board of the present invention, and is a side view showing a connection cord in a cord supporting portion installed on a side portion of a first tray storage portion.

FIG. 4 is a view showing an embodiment of the optical wiring board of the present invention, and is a side view showing a connecting cord in a cord supporting portion installed on a side portion of a second tray accommodating portion.

FIG. 5 is a view showing an embodiment of the optical wiring board of the present invention, and is a perspective view showing a tray storage section.

FIG. 6 is a view showing one embodiment of the optical wiring board of the present invention, and is an enlarged perspective view showing a tip of an inner guide.

FIG. 7 is a view showing one embodiment of the optical wiring board of the present invention, and is an enlarged plan view showing a connector holder.

FIG. 8 is a plan view showing an embodiment of the optical wiring board according to the present invention, and is a plan sectional view showing a center code tray.

[Description of Signs] 1 ... Box, 2 ... Optical fiber cable, 3a ... Optical fiber cord (optical fiber cord), 3b ... Optical fiber cord (connection cord), 4b ... First fixture, 4e ... Cord support portion, 4h Cord support portion, 5 optical connector (optical adapter), 6 first tray (fused portion tray), 7 multi-core single core branch portion, 8 second tray (branch connection) Tray), 9 ...
Center cord tray, 33: second fixing tool, T1: first tray storage section (fused section tray storage section), T2: second
Tray storage section (branch connection tray storage section).

──────────────────────────────────────────────────続 き Continuation of the front page (56) References JP-A-7-294750 (JP, A) JP-A-4-33002 (JP, U) (58) Fields investigated (Int. Cl. ⁷ , DB name) G02B 6/00

Claims (4)

(57) [Claims] An optical distribution board for branching and connecting to an optical fiber cable (2) or an optical fiber cable of an optical fiber cord, comprising: a box (1); A plurality of first trays (6) for connecting the derived optical fiber cores (3a) to each other via optical connection parts (5, 7) are housed in a stacked state, and are arranged in the front-back direction of the box. First tray storage unit (T
1) and a plurality of second trays (8) for internally connecting the optical fiber cores to each other through an optical connection portion different from the first tray. A second tray storage part (T2) which is stored in a stacked state continuously to the stacking and is supported so as to be able to be taken in and out in the front-rear direction of the box, and is disposed between the first and second tray storage parts; A connecting cord (3) for connecting the first and second trays stored in the first and second tray storage sections to each other.
b) and a center code tray (9) for storing an intermediate portion of the connection cord, wherein a first tray in the uppermost layer of the first tray storage portion and a center tray in the second layer of the second tray storage portion are provided. A second tray is connected by the connection cord, and hereinafter, a lower layer than the uppermost first tray
The first tray and the second tray below the uppermost second tray
And a first tray storage unit and a second tray storage unit.
Optical wiring board, characterized by being sequentially connected by a connecting cord in the same stacking order with each other in. 2. The optical wiring board according to claim 1, further comprising a cord supporting portion (4e, 4h) for supporting a connection cord on a side portion of the first and second tray storage portions. A plurality of first fixtures (4b) for holding a plurality of connecting cords and arranging them in parallel on one plane are provided at predetermined intervals;
The connecting cord is gripped in its connection has been that has a second first fastener tray nearest and mutually plurality of connecting cord is gripped in the first fastener to said center cord tray An optical distribution board characterized by being wired in parallel without crossing. 3. The optical wiring board according to claim 2, wherein the first fixing member has a configuration in which the connection cord is arranged in parallel on one plane along the front-rear direction of the box. light, characterized in that are wired inclined a box body rear side as held by the front end of the nearest first fastener to the second tray that is connected, and, approaching the center cord tray Wiring board. 4. The optical distribution board according to claim 2, wherein the center code trays are arranged in parallel with each other, and respectively hold and fix a plurality of connection cords in parallel along one plane. An optical wiring board, comprising a pair of fixtures (33), wherein the arrangement order of connection cords is reversed between these second fixtures.