JP3403573B2 - Optical branch module - Google Patents

Description

Description: BACKGROUND OF THE INVENTION [0001] 1. Field of the Invention [0002] The present invention relates to an optical branching module for sending test light to an optical fiber for communication. 2. Description of the Related Art In an optical fiber network, for example, in order to branch and connect an optical cable to an optical fiber core by connecting an optical connector, a large number of optical fibers inside and outside the office are terminated to form an optical wiring frame. Is used. In particular, as an optical wiring frame used for a subscriber transmission line, an FTM (Fib
er Termination Module) is used. 3 and 4 are views showing a conventional optical wiring rack applied to the FTM. In FIG. 3 and FIG.
, A terminal plate; 3, an optical connector; and 4, an optical branch module. [0003] The frame 1 is formed in a shelf shape divided into a plurality of steps at equal intervals by horizontally arranged partition plates 5, and a plurality of steps for accommodating the optical branching module 4 are formed. . A terminal plate 2 that substantially covers the opening is fixed to the same side opening of each stage of the frame 1.
The end plate 2 has a hole 6 for mounting the optical connector 3.
A plurality of SC optical connectors 3 are arranged and fixed in the hole 6 two by two. The optical connector 3 is provided with a plurality of SC-type terminals (not shown) to which an intra-office optical fiber core 7 is connected on the outside, and a plurality of SC-type terminals (not shown) to which an external optical fiber core is connected inside. It is arranged at a position corresponding to the terminal for the optical fiber 7. Hereinafter, the basic configuration of the optical branching module 4 will be described.
FIG . As shown in FIG. 7 , an optical coupler 9, an optical filter 4d, and an optical fiber
An optical component such as an optical connector 10 for switching and connecting c is housed. To test and manage the optical line, first,
An optical branching module that accommodates a core to be tested is selected by the core selection device 4a, and the test light (optical pulse) transmitted from the optical pulse test device 4b is connected to the measurement target via the optical coupler 9. To the optical fiber 4c outside the station, and further receives the backscattered light generated in the optical fiber 4c via the optical coupler 9 at the light receiving section of the optical pulse test device 4b. The loss abnormality of the optical line is monitored by analyzing the light waveform. Referring to FIGS. 5 and 6 , a conventional four-core optical branching module will be described. This optical branching module is a thin plate package as a whole, and can be opened and closed by an open / close lid (not shown). On the rear side (the left side in FIGS. 5 and 6 ) of the optical branching module 4, a four-core tape cord 8a derived from an external optical cable (terminated cable) K and one of the eight cords derived from the core selection device are provided. Heart tape code 8b
Is introduced. Four fiber-type optical couplers 9 are housed in the optical branching module 4, and the tape cord 8 b on the optical fiber selecting device side is changed to an 8-core tape code on the optical coupler 9 side by the 8-core MT connector 10. Connected. Next, the tape cord 8a on the external optical cable (terminated cable) side is connected to the 4-core MT connector 10 by using a four-core MT connector 10.
It is connected to a tape cord (not shown) on the optical coupler 9 side. On the other hand, one four-core tape cord derived from the port inside the optical coupler 9 is led out of the package as an optical code 8w, and is further divided by a single-core single-fiber splitter F fixed to a side plate. The optical fiber is branched into the optical fiber 8y. The tip of each of the branched single-core optical fibers 8y is terminated to an SC-type plug, and is fixed to the terminal plate 2 of the frame 1.
Connected to C-shaped optical adapter 3. [0007] About 50 optical branching modules 4 are provided in each stage of the frame 1 with a width of, for example, 13.5 mm. Inside the optical branch module 4, an optical cord 8w, an optical coupler 9 connected to the optical cord 8w,
An MT connector 10 (Mechani) for optically connecting the tape cords 8a, 8b and the optical cord 8w so as to be switchable.
cally transferable) is stored. A suspending member 12 for suspending from the suspending rail 11 erected above each step of the frame 1 is attached to the upper suburb when the optical branching module 4 is stored. [0008] Incidentally, in the case of the optical branching module 4 as described above, the number of parts is large, and in view of the demand for an increase in the number of accommodated core wires and an increase in mounting density, each stage is required. Therefore, the work of attaching the optical components such as the optical connector 3 has to be performed in a narrow space, and the workability is extremely poor. Also, when replacing one specific optical branching module 4, it is necessary to remove the optical branching module 4 near the optical branching module 4 to secure a space where a worker can enter. Work has become more difficult with the increase in density. [0009] That is, when using the optical fiber switching connection system to switch the MT connector 10 upon switching of the cord is housed in the optical branching module 4, as shown in FIG. 6, the corresponding optical branch module 4 is pulled out of the frame 1 and placed on a shelf, and the inside of the drawn out optical branching module 4 is opened, and the MT connector 1 is opened from the inside.
When the MT connector 10 in the optical branching module 4 is pulled out, the optical components such as the optical coupler 9 and a filter (not shown) connected to the optical cord 8w and the like are also pulled out. In the line state, it has been difficult to perform work without affecting optical communication. [0010] In the optical wiring rack, there is a demand for a further improvement in mounting density with an increase in the number of accommodated core wires, but the space between each optical branching module for extracting the optical branching module 4 and the MT. Since it is necessary to secure a work place for switching the connection by the connector 10, there is a limit in improving the mounting density. SUMMARY OF THE INVENTION The present invention has been made in view of the above-mentioned problems, and it is possible to reduce a drawer work space for mounting an optical branching module to improve a mounting density, and to improve connection density and the like. It is an object of the present invention to provide an optical branching module capable of minimizing the effect on optical communication during work. According to the present invention, there is provided an optical branching module for branching and connecting a multi-core optical fiber to a single-core optical fiber by connecting an optical connector. a is a branched connecting optical connector supported at one end, a body for housing the optical component attached to the optical fiber and the optical fiber, separated from the main body at the other end of the body, it can be integrated Provided in the front
End of an optical fiber in said body drawn out of said body
And a drawer case provided with a connector holder for detachably supporting a switching optical connector for switchably optically connecting a multi-core optical fiber to the outside of the main body. An opening for inserting the multi-core optical fiber into and out of the drawer case is opened, and the optical fiber in the main body is opened by the switching optical connector.
At least one or more optical fibers optically connected to the fiber are selection optical fibers into which test light oscillated by an optical pulse test apparatus is transmitted by being selected by an optical switch, and the selection optical fibers are: Arranged under the optical switch
For each row of optical branch module connector holders
The optical fiber for selection is introduced from the upper side.
The external multi-core optical fiber other than the
It is to be introduced from the entrance along the opening
The selection optical fiber is connected to the optical fiber in the main body.
Switching optical connector to continue takes out with excess length required for connection work optical fiber from the lead case, being adapted to perform a connection switching between the selected optical fiber and the optical fiber, after the connection switching , The light for selection
For switching between the fiber and the optical fiber in the main unit
Return the optical connector connected to the optical connector to the connector holder.
The optical fiber inside the main body
The optical fiber for selection and the optical fiber other than the optical fiber for selection.
Switchable connection to external multi-core optical fiber
It is characterized by having. An embodiment of an optical branching module according to the present invention will be described below with reference to FIGS . 1 and 2 . Reference numeral 20 in the figure denotes an optical branching module (hereinafter, referred to as an optical branching module) of the present embodiment.
"Abbreviated as" optical branching module "). As shown in FIGS . 1 and 2 , the optical branching module 20 supports a branch connection optical connector 30 at one end, and a plurality of 4-core or 8-core tape cords 36 and 37 (optical fibers, coded fibers). Optical fiber tape) and the tape code 3
6 and 37, a thin plate-shaped main body 28 for storing an optical component (not shown), and a main body 28 at the other end of the main body 28.
An MT connector 34 as a switching optical connector for optically connecting the termination-side tape cord 35 to the tape cord 36 so as to be switchable, and an optical switch 38 to the tape cord 37. A drawer case 22 provided with a connector holder 24 for detachably supporting an MT connector 40 for optically connecting a selection tape cord 39 (selection optical fiber) is provided. Are arranged in a plurality. At the rear end (left side in FIG. 2 ) of the optical branching module 20, the optical branching module 20 is manually operated in the front-rear direction of the optical wiring rack 25 (from the lower left to the upper right in FIG. 1, the horizontal direction in FIG. 2). A stopper 27 which is movable and can be engaged with and disengaged from a fixing portion 26 provided on the optical wiring frame 25 is provided in a protruding manner. When the tip is inserted into a not-shown stop hole of the fixing part 26 when the optical branching module 20 is inserted into the optical wiring frame 25, the stopper 27 further expands the diameter by pushing the tip into the fixing part 26. And the optical branch module 20 is temporarily fixed. The front half of the optical branch module 20 is a main body 28 that houses optical components such as tape cords 36 and 37 and an optical connector (not shown). On the front surface of the main body 28, a well-known SC type optical adapter 30 as a branch connection optical connector for connecting the single-branched tape cords 36 and 37 in the main body 28 to the single-core optical fiber 29.
Is attached. This optical adapter 30 has eight connection terminals for a single-core fiber in which a positioning ring sleeve is built-in.
When the “0” is stored in the optical wiring frame 25, it is exposed to the front of the optical wiring frame 25. At the rear of the main body 28, the drawer case 22 is provided.
A rail 31a is provided protruding from the main body 28 so as to approach and separate from the main body 28. The rail 31a is installed so as to be parallel to the front-rear direction of the optical wiring frame 25 when the optical branch module 20 is stored in the optical wiring frame 25.
The rail 31a is attached to the upper part of the drawer case 22 (FIG. 1,
The engaging projection 31b protruding from the upper side of FIG. 2 is suspended so as to be slidable in the front-rear direction of the main body 28. The rail 31a also functions as a suspending member that slidably suspends the main body 28 on a guide member 25c attached to a lower part of a switch support plate 25b that is installed at each stage of the optical wiring frame 25 and supports the optical switch 38. . Also,
A claw 32 protrudes from a rear portion of the main body 28. The claw 32 engages with and disengages from a hole 33 opened at the front of the drawer case 22, thereby restricting and permitting the movement of the drawer case 22 with respect to the main body 28. On the inner surface of one side plate 22a of the drawer case 22, a substantially semicircular radius maintaining plate 22b for maintaining the extra length of the tape cord 36 at a curved radius equal to or greater than a specified value is provided. The connector holder 24 is provided at a portion where one side plate 22 a protrudes from the rear end of the drawer case 22. The connector holder 24 supports two MT connectors 34 (or MT connectors 40) in a row. Connector holder 24
Is located at the center of the insertion port 23 (see FIG. 1 ). Insertion opening 2 opening on both sides of connector holder 24
3 is a case that is always open and pulls out the tape cord 36.
2 can be inserted and pulled out inside. MT connectors are supported by the connector holder 24 so as to be adjacent to each other. The support region between the MT connectors 34 and the support region between the MT connectors 40 may be partitioned by a partition wall or the like. The selection tape code 39 is used for the optical switch 3.
By selecting at 8, the test light oscillated by the optical pulse test apparatus is transmitted. Optical switch 3
8 is connected to a selection tape code 39 of each of the optical branching modules 20 arranged in the same stage of the optical wiring frame 25. The optical switch 38 is mounted on the switch support plate 25b, and a selection tape cord 39 is connected from the rear surface. Each selection tape cord 39 is connected to the optical branch module 20 arranged below the optical switch 38. Therefore, since the selection tape code 39 is introduced from the upper side of the connector holder 24, the tape code 37 connected to the selection tape code 39 is inserted into a portion of the insertion opening 23 which is opened below the connector holder 24. I have. Since the tape cord 35 on the termination side is introduced into the connector holder 24 from below, the tape cord 36 connected to the tape cord 35 is inserted into the insertion port 23.
Of the connector holder 24. The tape cords 36 and 37 are led out of the main body 28 via a boot 41 fixed to the rear surface of the main body 28. An external force such as a tensile force is supported by the boot 41, and the tape cords 36 and 37 are applied to the optical components in the main body 28. No external force is applied. Further, the tape cords 36 and 37 stored in the drawer case 22 have a function as a surplus connection length in the MT connectors 34 and 40 and a function as a surplus drawer length when the drawer case 22 is pulled out from the main body 28. It has become. Hereinafter, the optical branch module 2 of the present embodiment will be described.
The operation and effect of 0 will be described. The optical branching module 20 is configured such that the optical adapter 30 is inserted into the optical wiring frame 25 from the rear side of the optical wiring frame 25 with the optical adapter 30 as the front side of the optical wiring frame 25. To switch the connection between the tape cord 37 and the selection tape cord 39 in the optical branch module 20 housed in the optical wiring frame 25, first, the MT is moved from the connector holder 24 to the rear of the optical wiring frame 25 from the connector holder 24. The connector 40 is detached. At this time, the extra length of the tape cord 37 necessary for the connection operation is set to the connector holder 24 of the MT connector 40.
Withdrawal from the drawer case 22 with the separation from the drawer. When the drawer case 22 is pulled out, a tensile force acts on the tape cord 36 and the tape cord 37. Since these tensile forces are supported by the boot 41, the optical components in the main body 28 and the optical adapter 30 have a tensile force. Does not work. Note that the drawer case 22 is pulled out to the rear side of the optical wiring frame 25,
Further, by taking out the tape cords 36 and 37 together with the MT connectors 34 and 40 from the drawer case 22, the workability can be further improved. Next, after the set of the target tape code 37 and the selection tape code 39 is connected by the MT connector 40, the MT connector 40 is returned to the connector holder 24 again, and the extra length of the pulled-out tape code 37 is inserted. Mouth 23
And into the drawer case 22. By doing so, the tape cord 37 inserted into the drawer case 22 is appropriately curved and stored while maintaining a curvature radius equal to or greater than a specified value by the inner surface shape of the drawer case 22 and the radius maintaining plate 22b. When the drawer case 22 is pulled out from the main body 28 when the MT connector 40 is taken out, the main body 28 and the drawer case 22 can be easily integrated simply by engaging the claw 32 and the hole 33. it can. An MT connector 34 for connecting and terminating the connection between the termination-side tape cord 35 and the tape cord 36.
When the connection is switched or the like, the MT connector 34 is detached from the connector holder 24 and the tape cord 36 is pulled out of the drawer case 22. After the work is completed, the MT connector 34 is reattached to the connector holder 24 and the tape cord 36 is attached. It is pushed into the drawer case 22 from the insertion opening 23 and stored again. Therefore, the optical branch module 2 of the present invention
0, the tape cords 36, 37 are in the drawer case 22.
The optical branch module 20 can be pulled out from the optical wiring frame 25 because the MT connectors 34 and 40 supported by the connector holder 24 can switch the connection between the tape cords 36 and 37. It can be performed without pulling out, greatly improving work efficiency, and performing work without affecting optical components in the main body 28 and optical connection in the optical adapter 30. In addition, especially when the work is performed on the tape cord 37, the pulling out and re-storage of the tape cord 37 is extremely easy, so that the work efficiency is improved. On the rear surface of the optical wiring frame 25, the connector holders 24 of the respective optical branching modules 20 are aligned, and the tape cords 35 and 36 on the termination side are connected to the connector holders 24 from the opposite direction. Since the set to be introduced is formed, and the MT connectors 34 and 40 are arranged and supported side by side on the connector holder 24, the selection of the target tape cords 35, 36, 37 and 39 is easy,
The work efficiency of assembling the optical wiring rack 25 and switching connections is further improved. Therefore, some MT connectors 34, 4
When the connection is switched for 0, it is possible to prevent the remaining MT connectors 34 and 40 from being affected by vibration or the like. The optical switch 38 and the optical branching module 20 optically connected to the optical switch 38 via the selection tape cord 39 are disposed adjacent to each other.
The selection tape cord 39 can be shortened, and the entire optical wiring frame 25 can be saved in space. In addition, the connection between the selection tape cord 39 and the tape cord 37 to be tested can be easily understood, and the efficiency of the optical test can be improved. Is improved. The connector holder may be provided at a location other than the rear end of the drawer case as long as the connector holder can be easily operated from the outer surface of the optical wiring rack. As described above, according to the optical branching module of the present invention, an optical branching module for branching and connecting a multi-core optical fiber to a single-core optical fiber by optical connector connection. An optical connector for branch connection supported at one end, a main body for storing an optical fiber and an optical component attached to the optical fiber, and provided at the other end of the main body so as to be separable and integral with the main body, A drawer case provided with a connector holder for detachably supporting a switching optical connector for optically switching optical fibers to each other, and inserting an optical fiber into and out of the drawer case near the connector holder of the drawer case. The opening for insertion of the switching optical connector is easy to attach and detach to and from the connector holder, and the extra connection length is drawn through the insertion opening. Since it can be pulled out and stored again, there is an excellent effect that the work efficiency of connection switching is improved. Furthermore, at least one or more optical fibers optically connected by the switching optical connector are selection optical fibers to which test light oscillated by the optical pulse test apparatus is transmitted by being selected by the optical switch. By arranging the optical switch connected via the selection optical fiber adjacent to the main body, the connection work between the selection optical fiber and the optical fiber to be tested becomes easy, and the selection optical fiber is shortened. This makes it possible to reduce the installation space for the optical branching module and the optical switch.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a perspective view showing an embodiment of an optical branch module according to the present invention. FIG. 2 is a front view showing an embodiment of the optical branch module of the present invention. FIG. 3 is a side view showing an optical wiring rack. FIG. 4 is a front view showing an optical wiring rack. FIG. 5 is a side view showing a conventional optical branch module. FIG. 6 is a diagram showing a conventional optical branch module,
It is a side view which shows connection switching in an MT connector. FIG. 7 is a schematic diagram showing a basic configuration of an optical branching module. [Description of Signs] 20 ... optical branch module (optical branch module), 21 ...
Optical fiber, 22 ... drawer case, 23 ... insertion port, 24 ...
Connector holder, 29 single-core optical fiber, 32 switching optical connector (MT connector), 35 multi-core optical fiber (tape cord), 36 optical fiber (tape cord), 37 optical fiber (tape cord) 39, optical fiber (tape cord for selection), 40, optical connector for switching (MT connector).

──────────────────────────────────────────────────の Continuing on the front page (72) Inventor Shigenori Goto 1440 Mutsuzaki, Sakura City, Chiba Prefecture Inside Fujikura Sakura Plant (72) Inventor Hideyuki Hosoya 1440 Mutsuzaki, Sakura City, Chiba Prefecture Fujikura Sakura Plant (72) Inventor Takashi Mima 3-19-2 Nishishinjuku, Shinjuku-ku, Tokyo Nippon Telegraph and Telephone Corporation (72) Inventor Masato Kuroiwa 3- 19-2 Nishishinjuku, Shinjuku-ku, Tokyo Nippon Telegraph and Telephone Stock In-company (72) Inventor Naoki Nakao 3-192-2 Nishi-Shinjuku, Shinjuku-ku, Tokyo Nippon Telegraph and Telephone Corporation (72) Inventor Takashi Ebihara 3- 19-2 Nishi-Shinjuku, Shinjuku-ku, Tokyo Nippon Telegraph Telephone Co., Ltd. (56) References JP-A-9-197143 (JP, A) JP-A-9-197142 (JP, A) JP-A-9-5532 (JP, A) JP-A-2-111104 (J (P, U) (58) Field surveyed (Int. Cl. ⁷ , DB name) G02B 6/00 G02B 6/38

Claims (1)

(1) An optical branching module (20) for branching and connecting a multi-core optical fiber ( 36, 37 ) to a single-core optical fiber (29) by optical connector connection. Te, branched connecting optical connectors supported on one end portion (30), before
A body (28) for housing the serial optical fiber (36, 37) and an optical component attached to the optical fiber, separated from the main body at the other end of the body provided to be integrated,
The end of the optical fiber in the body that is drawn from the body
Switching optical connectors (34, 4 ) for switchably optically connecting the unit and the multi-core optical fibers (35, 39) outside the main body.
0) removably a pull-out case supporting connector holder (24) is provided (22) a multi-fiber body outside near the connector holder of the drawer casing
An opening (23) for inserting the optical fiber into and out of the drawer case is opened , and the optical fiber in the main body is opened by the switching optical connector.
The selection optical fiber (3) to which the test light oscillated by the optical pulse test apparatus is transmitted by selecting at least one or more optical fibers optically connected to the optical switch (38).
9), wherein the selection optical fiber is arranged below the optical switch.
Above the connector holder of each optical branch module
From the selection optical fiber.
The outer multi-core optical fiber (35) is a connector holder
It has been introduced from the entrance along the lower side.
Connecting the selection optical fiber and the optical fiber in the main body.
Switching optical connector to continue takes out with excess length required for connection work optical fiber from the lead case, being adapted to perform a connection switching between the selected optical fiber and the optical fiber, after the connection switching , The light for selection
For switching between the fiber and the optical fiber in the main unit
Return the optical connector connected to the optical connector to the connector holder.
The optical fiber inside the main body
The optical fiber for selection and the optical fiber other than the optical fiber for selection.
Switchable to multi-core optical fiber (35) outside
An optical branching module characterized in that it is capable of functioning .