JP2000098138A - Optical termination stand - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an optical termination stand which improves the efficiency of the installation space of an extra length housing tray while facilitating the taking out of optical connectors in particular. SOLUTION: The optical termination stand 1 is the optical termination stand 1 constituted as an optical branching module group 10 by arranging optical branching modules 8 on the connection line between an optical cable 2 on a first side and an optical cable 4 on a second side in order to branch and connect multiple optical fibers 3 extending from the optical cable 2 on the first side to glass-fiber cords 5 extending from an optical cable 4 on a second side by optical fiber connection and disposing the optical branching modules 8 in juxtaposition within a frame 6. An extra length housing tray 16, which houses the optical connectors 13, 14 by connecting the optical fiber cords 12 led out of the optical branching modules 8 and the multiple optical fibers 3 extending from the optical cable 2 on the first side via the optical connectors 13, 14 and houses the extra lengths of the optical fiber cods 12 extending from the optical connectors 13, 14 and the multiple optical fibers 3, is arranged above or below the optical branching module group 10 within the frame 6. The extra length housing tray 16 is mounted within the frame 6 via drawing out means 33.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical termination for use in connection of an optical connector between an optical cable on one side (for example, a subscriber side) and an optical cable on the other side (for example, an office side) in an optical fiber network. It is about.

[0002]

2. Description of the Related Art Conventionally, there is JP-A-9-5533 as a technique in such a field. On the upper side of the optical termination described in this publication, a number of optical branching modules are arranged side by side, and on the lower side, an optical fiber cord and an optical cable discharged from each optical branching module are provided. An optical connector housing case for housing an MT connector used for optical connection with an optical fiber extending from the optical connector is arranged. A large number of MT connectors are accommodated in a box-shaped optical connector accommodating case in a stacked state, and a large number of optical fiber cords and optical cable-side optical fibers are looped in the optical connector accommodating case. It is housed in an extra length so as to be wound. Therefore, when such a box-shaped optical connector housing case is used, M
When switching the connection of the T connector, a desired MT connector can be easily taken out, and the extra length of the optical fiber can be formed in the case, so that the connection switching operation of the MT connector can be efficiently and reliably performed. It can be carried out.

[0003]

However, the above-mentioned conventional optical termination has the following problems. That is, the optical branching module disposed in the optical termination frame is configured to be able to be pulled out, but the optical connector housing case is installed and fixed in the optical termination frame. Therefore, a desired MT can be obtained from the optical connector housing case.
In consideration of taking out the connector, it is necessary to provide a working space above the case where the hand of the worker can enter, and it is necessary to dispose the optical branching module and the optical connector housing case separately. Space utilization efficiency deteriorates.
This has a problem in that when the optical branching module and the optical connector accommodating case are formed in a multi-stage structure in the rack, the optical termination frame becomes large.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and in particular, has an optical termination that facilitates taking out of an optical connector and also makes the installation space for an extra-length storage tray more efficient. The purpose is to provide a rack.

[0005]

According to a first aspect of the present invention, there is provided an optical termination according to the present invention, wherein a multi-core optical fiber extending from an optical cable on a first side is connected to an optical connector and a single optical fiber extending from an optical cable on a second side is connected. In order to branch and connect to the optical fiber, the optical branching module is arranged on the connection between the optical cable on the first side and the optical cable on the second side, and the optical branching modules are juxtaposed in the frame to form an optical branching module group. In the configured optical termination, the optical fiber cord derived from the optical branching module and the multi-core optical fiber extending from the optical cable on the first side are connected via an optical connector, and the optical connector is accommodated at the same time. An extra length storage tray that also accommodates the extra length of the optical fiber cord and the multi-core optical fiber extending from the connector is arranged above or below the optical branching module group in the frame, and the extra length is collected. Tray, characterized in that mounted in the frame body through the drawer unit.

In this optical termination frame, optical branching modules are arranged side by side in a frame, and optical fiber cords are led out from each optical branching module, and each optical fiber cord is led into an extra length storage tray. The multi-core optical fiber extending from the optical cable on the first side is also guided into the extra length storage tray. Further, an optical connector for connecting the optical fiber cord and the multi-core optical fiber is accommodated in each extra length accommodation tray. Such an extra length storage tray is disposed either above or below the optical branching module. However, even if the optical branching module and the extra length storage tray are brought close to each other, the extra length storage tray is pulled out. Therefore, the optical connector in the extra length storage tray can be easily taken out to the outside. This facilitates the connection switching work of the optical connector and improves the work efficiency, and is an effective means for increasing the efficiency of the installation space for the extra-length storage tray. In particular, the above-described configuration is useful for optical terminations in which optical branching modules and extra length storage trays are stacked in multiple stages.

In the optical terminal frame according to the second aspect, the first extra length path for the optical fiber cord formed by the partition and the second extra length path for the multi-core optical fiber are provided in the extra length storage tray. Preferably, a long path is provided. When such a configuration is adopted, each extra length path is formed by a partition piece, so that the optical fiber cord and the multi-core optical fiber are appropriately separated and accommodated, routed on another path, and accommodated in the extra length path. Contributes to preventing cross-talk in the tray. Therefore, it contributes to improvement of workability when taking out the optical connector from the extra-length storage tray or returning the optical connector into the extra-length storage tray.

According to a third aspect of the present invention, the extra length storage tray includes an optical connector accommodating portion for accommodating a plurality of optical connectors side by side, and the first extra length path cord discharge. It is preferable to dispose an R-shaped guide located at one end of the optical connector housing at the outlet. When such a configuration is adopted, the bending radius of the optical fiber cord discharged from the first extra length path in the state where the optical connector is loaded in the optical connector accommodating section is set near the end of the optical connector accommodating section. , R-shaped guide portions.
Therefore, even when the optical fiber cord led out from the cord outlet is guided to the optical fiber housing near the cord outlet, a stable bent shape of the optical fiber can be ensured.

In the optical terminal rack according to the fourth aspect, optical fiber insertion grooves are formed in a front portion of the extra length storage tray in a line corresponding to the positions of the respective optical branching modules in the frame. In the extra length storage tray, the optical connector storage portion extends parallel to the arrangement direction of the optical fiber insertion grooves,
The first extra length path is crawled around the rear side of the optical connector accommodating portion from the cord introduction port located on one of the alignment end sides of the optical fiber insertion groove, and is located on the other alignment end side of the optical fiber insertion groove. Preferably, the cord extends toward the cord outlet. When such a configuration is adopted, by inserting each optical fiber cord into each optical fiber insertion groove, it is possible to align the optical fiber cords one by one at the front of the extra length storage tray. In addition, the optical connectors of the optical fiber cords can be sequentially arranged from the end of the optical connector housing closest to the cord outlet, in order from the optical fiber cord inserted into the optical fiber insertion groove farthest from the cord inlet. Becomes That is, in order from the optical fiber cord inserted into the optical fiber insertion groove near the cord outlet, each optical connector extends from each optical branching module when sequentially housed from the side near the cord outlet of the optical connector housing. Also, even when the lengths of the respective optical fiber cords are made equal, each optical fiber cord can be accommodated in the extra length accommodation tray without difficulty. As a result, the lengths of the optical fiber cords to be led out of the optical branching modules are made uniform. As a result, uniformization of a large number of optical branching modules employed in the optical termination frame is achieved, and each optical branching module is mounted on the optical termination frame. Is extremely easy to assemble.

[0010] In the optical terminal frame according to the fifth aspect, it is preferable that an R-shaped guide portion located on the other end side of the optical connector accommodating portion is arranged at the multicore optical fiber outlet of the second extra length path. . When such a configuration is adopted, the bending radius of the multi-core optical fiber discharged from the second extra length path in the state where the optical connector is loaded in the optical connector housing portion is set to be close to the end of the optical connector housing portion. Thus, it can be secured by the R-shaped guide portion. Therefore, even when the multi-core optical fiber led out from the tape outlet is guided to the optical fiber housing near the tape outlet, a stable bent shape of the optical fiber can be ensured.

According to a sixth aspect of the present invention, the pull-out means is provided between the extra-length storage tray and the frame so that the front end of the extracted extra-length storage tray rotates downward. Is preferable. When such a configuration is adopted, when the extra length storage tray is pulled out, the front end thereof rotates downward, so that the upper surface of the extra length storage tray can be turned to the worker side, and the extra length storage tray can be inserted into the extra length storage tray. Access to the accommodated optical connector is facilitated.

[0012]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Preferred embodiments of an optical termination according to the present invention will be described below in detail with reference to the drawings.

FIG. 1 is a front view showing an optical termination according to the present invention. The optical termination frame 1 shown in FIG. 1 is called an optical wiring module (FTM).
Is a multi-fiber optical fiber (hereinafter referred to as "tape fiber") 3 derived from an optical cable 2 on the subscriber side (first side) and a large number of optical fibers 4 derived from an optical cable 4 on the office side (second side). This is for connecting the single-core optical fibers 5 in correspondence with each other.

The frame (cabinet) 6 of the optical termination 1
1 and 2, an optical branching module 8 containing a coupler 7 and the like is disposed therein, and the optical branching modules 8 are arranged side by side on a shelf 9a. Form group 10. Further, for example, 50 optical branching modules 8 are arranged on the shelf 9a, and are housed in the frame 6 via a guide rail (not shown) so as to be able to be pulled out. An optical switch (core selection means) S is provided below the optical branching module group 10 on the shelf 9c, and guides the branch core G connected to the coupler 7 into the optical switch S. The optical switch S is connected to a measuring device K such as an OTDR.

As shown in FIG. 2, each optical branching module 8
Each single-core optical fiber 5 of the optical cable 4 is
Is provided with a connector insertion portion C for inserting the optical connector 11 provided at the tip of the connector. Each optical branching module 8 has four single-core optical fiber cords 12 extending from the connector insertion portion C, and each optical fiber cord 12 passes through the inside of the optical branching module 8 and is led out from the front end 8a. Each of the optical fiber cords 12 led out from the optical branching module 8 is attached to the first optical connector (MT connector) 13 in a collective state. Therefore,
One optical branching module 8 has one optical connector 13, and in the above-described optical branching module group 10, the number of optical branching modules 8 (for example, 50).
Is present in the first optical connector 13.

Each first optical connector 13 is connected to each second optical connector (MT connector) 14 provided at the tip of the tape fiber 3 of the optical cable 2 on the subscriber side.
They are connected via guide pins (not shown). The first
The optical connection between the optical connector 13 and the second optical connector 14 is performed outside the optical branching module 8 because of the simplification of the connection switching operation between the optical connectors 13 and 14 and the connection switching operation. This is to avoid damage to components in the optical branching module 8 by not touching the coupler 7 and the like in the optical branching module 8 at the time.

As described above, the first optical connector 13 and the second
Since the optical connection unit 15 including the optical connector 14 is located outside the optical branching module 8, the frame 6 of the optical termination 1 has an extra space for accommodating a large number of optical connectors 13 and 14 collectively. A long storage tray 16 is provided. As shown in FIGS. 1 and 3, the extra length storage tray 16
It is installed above the optical branching module group 10 above.
Then, a large number (for example, 50
(Set) of optical connection units 15 are arranged in a horizontal row.
The extra length storage tray 16 accommodates the extra lengths of the optical fiber cord 12 extending from the optical connector 13 and the tape fiber 3 extending from the optical connector 14, as well as the optical connectors 13 and 14. is there.

As shown in FIGS. 3 and 4, the front end of the extra length storage tray 16 is provided with optical fiber drawers aligned in a row corresponding to the arrangement direction of the optical branching modules 8 in the frame 6. A hanging piece 18 is provided. The optical fiber insertion grooves 19 formed between the adjacent optical fiber hook pieces 18 are aligned so as to correspond to the respective optical branching modules 8 on a one-to-one basis. On the bottom plate 16A of the extra length storage tray 16, a first extra length path P for securing the extra length of the optical fiber cord 12 and a second extra length path for securing the extra length of the tape fiber 3 are provided. A long path Q is provided.
Further, on the bottom plate 16A of the extra-length storage tray 16, a box-shaped optical connector housing portion 20 for aligning and arranging the optical connector 13 of each optical fiber cord 12 and the optical connector 14 of each tape fiber 3 is provided. The optical connector housing 20 extends in parallel to the direction in which the optical fiber insertion grooves 19 are arranged. And although the upper surface of the extra length storage tray 16 is open, it may have a lid.

On the bottom plate 16A of the extra length storage tray 16, the first extra length path P is
Code inlet 22 located at one end in the alignment direction of
From the rear side of the optical connector accommodating portion 20 to the cord outlet 23 located at the other end in the alignment direction of the optical fiber insertion grooves 19. And the code outlet 23
Faces the cord housing space A formed in front of the optical connector housing 20. In this case, the extra length path P includes an outer partition 24 extending along the contour of the bottom plate 16A of the extra length storage tray 16 and an inner partition extending at a predetermined distance from the outer partition 24. Formed between the cord inlet 22 and the cord outlet 23,
It is substantially U-shaped on the bottom plate 16A. On the bottom plate 16 </ b> A of the extra length storage tray 16, the cord outlet 23 is provided with an R
A guide portion 26 having a shape is provided. This guide part 2
By setting the radius of No. 6 to 30 mm or more, the minimum bending radius of the optical fiber cord 12 is secured.

When such a configuration is adopted, the optical fiber cord 12A inserted into the optical fiber insertion groove 19 farthest from the cord introduction port 22 is inserted into the optical fiber insertion groove 19.
Is guided to the cord introduction port 22 along a partition 27 extending in parallel to the arrangement direction. Then, after the optical fiber cord 12A is routed to the cord outlet 23 along the first extra length path P, the optical connector accommodating portion closest to the cord outlet 23 is arranged along the guide portion 26. Guided to the end of 20. And the optical fiber cord 1
The 2A optical connector 13A is mounted on the end of the optical connector housing 20 on the cord outlet 23 side.

On the other hand, the optical fiber cord 12B inserted into the optical fiber insertion groove 19 closest to the cord inlet 22 is guided to the cord inlet 22 in the shortest time. Then, after the optical fiber cord 12B is routed to the cord outlet 23 along the first extra length path P, the guide section 2
6 is guided to the end of the optical connector housing portion 20 farthest from the cord outlet 23. Then, the optical connector 13B of the optical fiber cord 12B is mounted on the end of the optical connector accommodating portion 20 on the cord introduction port 22 side.

That is, when the lengths of the optical fiber cords 12 led out from the respective optical branching modules 8 are equalized, each optical fiber cord 1 inserted into the optical fiber insertion groove 19 is
The two optical connectors 13 are arranged in order from the end on the cord outlet 23 side of the optical connector accommodating part 20 in the order farther from the cord inlet 22. Therefore, each optical fiber cord 12 having a uniform length can be accommodated in the extra length accommodation tray 16 without difficulty. As a result, the lengths of the optical fiber cords 12 to be led out of the optical branching module 8 are made uniform. As a result, all of the many optical branching modules 8 employed in the optical termination 1 can be standardized. The work efficiency when assembling the optical branching module 8 to the end frame 1 is improved.

A second extra length path Q for securing the extra length of the tape fiber 3 is provided at one end of the optical fiber insertion groove 19 in the direction of alignment of the optical fiber insertion groove 19 so as to face the cord introduction port 22. A tape outlet (multi-core optical fiber outlet) 29 located at the other end side in the alignment direction of the optical fiber insertion groove 19 opposite to the port 28 and the cord outlet 23.
And extends in a substantially L-shape. The tape outlet 29 faces the tape housing space B formed behind the optical connector housing 20, and the tape outlet 29 of the second extra length path Q is connected to the other end of the optical connector housing 20. , An R-shaped guide portion 30 is provided.

By setting the radius of the guide portion 30 to 30 mm or more, the minimum bending radius of the tape fiber 3 is ensured. The extra length path Q is created by the above-described partition piece 27 and the partition piece 31 which extends in parallel to the partition piece 27 and is bent into an L-shape. When the optical connector 14 provided on each tape fiber 3 is accommodated in the optical connector accommodating section 20, each tape fiber 3 is routed in the second extra length path Q and discharged to the outside. Is done.

Here, as shown in FIGS. 5 and 6, between the extra length storage tray 16 and the frame 6, there is provided a drawing means for improving the efficiency of connection switching between the optical connectors 13 and 14. 33 are provided. The drawer means 33 includes a pair of left and right sliders 34 protruding from both side surfaces 16a of the extra-length storage tray 16 and extending in the horizontal direction, and protruding from the frame 6 so as to sandwich the sliders 34 from above and below. It comprises a pair of left and right guide rails 35 extending.
Therefore, the extra length storage tray 16 is pulled out in the horizontal direction by the cooperation of the slider 34 and the guide rail 35. In this manner, as a result of the extra-length storage tray 16 being pulled out to the worker side, access to the optical connectors 13 and 14 from the open end side of the extra-length storage tray 16 is facilitated.

As shown in FIG. 7, the other drawer means 37 has a structure in which the front end thereof is rotated downward with the extra length storage tray 16 pulled out. Enables leaning arrangement. Specifically, as shown in FIGS. 8 and 9, the drawer means 37 includes a pair of left and right rollers 38 provided on both side surfaces 16 a of the extra length storage tray 16 and a horizontal direction so as to sandwich the rollers 38 from above and below. And a pair of left and right guide rails 39 extending to the frame body 6 and fixed to the frame body 6. Further, the roller 38 is
a, an intermediate roller 38b, and a rear roller 38c,
Each of the rollers 38a, 38b, 38c is horizontally arranged along a guide rail 39, and the guide rail 39
Are the upper guide rail 39a and the lower guide rail 3
The roller 38 moves between the upper and lower guide rails 39a and 39b.

In the lower guide rail 39b, a drop hole 40 is provided at the front end thereof so that the intermediate roller 38b can be dropped, and a rear roller 38c is received behind the drop hole 40. Rear roller 3
A bearing portion 41 for supporting the rotation of 8c is provided. The bearing 41 has a semi-cylindrical shape and functions as a tray for the rear roller 38c. Further, stopper pieces 42a and 42b protruding inward are provided at the tips of the upper and lower guide rails 39a and 39b, respectively. Is provided with a roller entrance / exit 43 that allows the passage of the roller. Therefore, the stopper pieces 42a and 4
2b, the front roller 38a does not easily protrude from the guide rail 39, and contributes to preventing the extra length storage tray 16 from falling off.
Reference numeral 50 denotes a rear end stopper.

Therefore, as shown in FIGS. 10 and 11,
When the extra length storage tray 16 is pulled out to the front, each roller 38
The front roller 38a jumps out of the roller entrance 43 while moving along the guide rail 39. Subsequently, at the same time when the intermediate roller 38b falls from the drop hole 40,
The rear roller 38c falls into the bearing 41. As a result, the extra length storage tray 1 with the rear roller 38c as the rotation axis.
As a result, as shown in FIG. 7, a leaning arrangement is achieved in which the open upper surface of the extra length storage tray 16 faces the operator.

The optical termination according to the present invention is not limited to the embodiment described above, and the extra length storage tray 16 may be arranged below the optical branching module group 10. In this case, the extra length As a result, the storage tray 16 is configured to be freely drawn out, so that the extra-length storage tray 16 can be arranged close to the optical branching module group 10.

[0030]

Since the optical termination according to the present invention is constructed as described above, the following effects can be obtained. That is, a multi-core optical fiber extending from the first-side optical cable is branched and connected to a single-core optical fiber extending from the second-side optical cable by an optical connector connection. The optical branching module is disposed on the connection with the optical branching module, and the optical branching module is arranged side by side within the frame to form an optical branching module group. A multi-core optical fiber extending from the optical cable on one side is connected via an optical connector to accommodate the optical connector and, at the same time, to accommodate the extra length of the optical fiber cord extending from the optical connector and the multi-core optical fiber. The storage tray is disposed above or below the optical branching module group in the frame, and the extra-length storage tray is mounted in the frame via a drawer. Because, while allowing ease of removal of the optical connector, allowing the efficiency of the installation space of the extra length accommodating tray.

[Brief description of the drawings]

FIG. 1 is a front view showing an embodiment of an optical termination frame according to the present invention.

FIG. 2 is a schematic diagram showing a connection state in the optical termination frame shown in FIG. 1;

FIG. 3 is a perspective view showing a state in which the three members of an extra-length storage tray, an optical branching module group, and an optical switch are arranged as one unit and are vertically stacked in a frame.

FIG. 4 is a plan view showing an extra length storage tray.

FIG. 5 is a side view showing a state in which the extra length storage tray is pulled out in a horizontal direction.

FIG. 6 is an enlarged view of a main part showing a first modified example of the drawing means.

FIG. 7 is a side view showing a state in which the extra length storage tray is leaned obliquely.

FIG. 8 is a perspective view showing a second modification of the drawer.

FIG. 9 is an enlarged side view of a main part of FIG. 8;

FIG. 10 is a perspective view showing a state where the extra-length storage tray shown in FIG. 8 is pulled out.

11 is an essential part enlarged side view showing a state when the extra length storage tray shown in FIG. 9 is inclined obliquely from a horizontal state.

[Explanation of symbols]

P: first extra length path, Q: second extra length path, 1 ... optical termination, 2 ... first side optical cable, 3 ... tape fiber (multi-core optical fiber), 4 ... second side Optical cable, 5: single-core optical fiber, 6: frame, 8: optical branch module, 10: optical branch module group, 12: optical fiber cord, 13, 1
4 optical connector, 16 extra length accommodation tray, 19 optical fiber insertion groove, 20 optical connector accommodation part, 22 cord inlet, 23 cord outlet, 24, 25, 27, 31 ...
Partition pieces, 26, 30: Guide section, 29: Tape outlet (multi-fiber optical fiber outlet), 33, 37 ... Pull-out means.

 ──────────────────────────────────────────────────続 き Continuing on the front page (72) Inventor Kazuto Saito 1 Tayacho, Sakae-ku, Yokohama-shi, Kanagawa Prefecture Inside the Yokohama Works, Sumitomo Electric Industries, Ltd. (72) Inventor Toshiyuki Watanabe 7-6 Omori Nishi, Ota-ku, Tokyo No. 31 Sumiden Opcom Co., Ltd. F-term (reference) 2H038 AA61 CA37 CA38

Claims (6)

[Claims] 1. A multi-core optical fiber extending from an optical cable on a first side is branched and connected to a single-core optical fiber extending from an optical cable on a second side by an optical connector connection.
In an optical termination, an optical branching module is arranged on a connection between an optical cable on a first side and an optical cable on a second side, and the optical branching modules are arranged side by side in a frame to constitute an optical branching module group. The optical fiber cord derived from the optical branch module and the multi-core optical fiber extending from the optical cable on the first side are connected via an optical connector, and the optical connector is accommodated at the same time as extending from the optical connector. An extra length storage tray that also stores the extra length of the optical fiber cord and the multi-core optical fiber is arranged above or below the optical branching module group in the frame, and the extra length accommodation tray includes a drawer. An optical terminal frame attached to the frame body via a frame. 2. A first extra-length path for the optical fiber cord and a second extra-length path for the multi-core optical fiber are formed in the extra length storage tray. The optical termination according to claim 1, wherein: 3. An optical connector accommodating portion for accommodating a plurality of said optical connectors side by side in said extra length accommodation tray, wherein said optical connector is provided at a cord outlet of said first extra length path. The optical termination according to claim 2, wherein an R-shaped guide portion located at one end of the housing portion is arranged. 4. An optical fiber insertion groove, which is aligned in a line corresponding to the position of each of the optical branching modules in the frame, is formed at a front portion of the extra length storage tray. The optical connector receiving portion extends in parallel with the arrangement direction of the optical fiber insertion grooves, and the first extra length path is a cord located on one of the aligned end sides of the optical fiber insertion grooves. 4. The optical fiber connector according to claim 3, wherein the optical connector accommodating portion is crawled from a rear side of the optical connector accommodating portion and extends toward the cord outlet located on the other alignment end side of the optical fiber insertion groove. Light termination. 5. An R-shaped guide located at the other end of the optical connector accommodating portion is disposed at a multicore optical fiber outlet of the second extra length path. ~
5. The optical terminal frame according to claim 4. 6. The drawer is provided between the extra-length storage tray and the frame so that a front end of the extra-length storage tray pulled out rotates downward. The optical termination according to any one of claims 1 to 5.