JP3543074B2 - Optical fiber holding member and optical wiring rack - Google Patents

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to an optical fiber holding member that holds an optical fiber core connected to an optical connection module, and an optical wiring rack that houses the optical connection module.
[0002]
[Prior art]
As a conventional optical wiring frame, for example, one described in Japanese Patent Application Laid-Open No. 9-258035 is known. The optical wiring frame described in this publication has a frame divided into a plurality of stages by a partition plate, and a plurality of optical branching modules are housed side by side in each stage of the frame. At one end of the optical branching module, an optical connector to which a central office optical fiber core is connected is provided. The intra-office optical fiber core is guided and connected to an optical branch module to be connected via a tray provided at each stage of the frame.
[0003]
[Problems to be solved by the invention]
In the optical distribution rack, when the optical fiber in the office is preliminarily wired in the rack in advance, conventionally, the optical fiber in the office is not bundled or fixed, but is simply bundled on a tray. I had left it. If there are many optical fiber cores left on such a tray, when connecting the office optical fiber core to the optical branch module housed in the frame, the connection should be made from a large number of optical fiber cores. It is necessary to find and take out the optical fiber. In this case, not only is it time-consuming, but also there is a possibility that the optical fiber core wire itself or the optical connector provided at the tip of the optical fiber core wire may be damaged in an attempt to pull out the optical fiber core wire by force. there were.
[0004]
SUMMARY OF THE INVENTION An object of the present invention is to provide an optical fiber holding member and an optical wiring rack that can prevent breakage of an optical fiber core wire, an optical connector, and the like that have been wired in advance.
[0005]
[Means for Solving the Problems]
In order to achieve the above object, the present invention provides an optical fiber cable detachably attached to a module storage frame of an optical wiring rack or an optical connection module stored in the module storage frame and connected to the optical connection module. An optical fiber holding member for holding the optical connector provided at the end of the optical fiber core on the front surface, and fixed to the holding portion to engage with the module storage frame or the optical connection module. An engaging portion , the holding portion and the engaging portion are integrally formed of an elastic body, the holding portion has a holding concave portion into which the optical connector is fitted, and the engaging portion has a lower surface of the holding portion. And a protrusion fixed to the hole or groove formed in the module housing frame or the optical connection module, and a portion fixed to the front side from the protrusion on the lower surface of the holding portion and extending to the protrusion side. And a substantially L-shaped locking piece for locking the Lumpur housing frame or optical connection module, with the protrusion and the locking piece, that constitutes a restraining portion for restraining the holding unit with respect to the longitudinal direction It is a feature.
[0006]
In the present invention configured as described above, for example, first, the optical fiber holding member is attached to the module storage frame, and the optical connector at the tip of the optical fiber core wire previously wired in the optical wiring rack is attached to the holding portion of the optical fiber holding member. Keep it. Then, at the stage when the optical connection module is stored in the module storage frame, the optical fiber holding member is temporarily removed from the module storage frame, and the optical connection module stored in the module storage frame holds the optical fiber core wire. Attach the fiber holding member. Therefore, it is not necessary to leave the pre-wired optical fiber core on the tray, and when connecting the optical fiber core to the optical connection module, the optical fiber required from a large number of optical fiber cores is required. There is no need to forcibly pull out the fiber core. This prevents breakage of the optical fiber core itself, the optical connector, and the like. Further, since there is no need to search for and take out an optical fiber core to be connected from a large number of optical fiber cores, workability relating to connection of the optical fiber core is improved.
Further, by forming the holding portion and the engaging portion integrally with an elastic body, the optical connector is held by the holding portion only by the elastic force of the holding portion, so that the structure of the optical fiber holding member is simplified, The production cost is also reduced. Further, by providing the holding concave portion in the holding portion, when holding the optical fiber core wire in the holding portion, it is only necessary to insert the optical connector into the holding concave portion, so that the optical fiber core wire can be easily held.
Further, by providing a projection and a locking piece constituting an engagement section on the lower surface of the holding section, when attaching the optical fiber holding member to the module storage frame or the optical connection module, the projection is attached to the module storage frame or the optical connection module. The optical fiber holding member can be easily attached and detached because it is only necessary to insert the optical fiber holding member into the hole or the groove formed in the optical fiber.
Further, by forming the restraining portion by the projection and the locking piece, when the optical connector is inserted into or removed from the holding recess of the optical fiber holding member attached to the module housing frame or the optical connection module, the optical fiber holding portion is held. Since movement of the member in the front-rear direction is restricted, it becomes easy to insert and remove the optical connector. Further, when the optical connector is inserted into the holding recess, the optical fiber holding member is prevented from being inclined in the pushing direction and coming off the module storage frame or the optical connection module. Further, the restraining portion can be realized with a relatively simple structure.
[0008]
In this case, it is preferable that the holding concave portion has a tapered cross-sectional shape that expands toward the opening side. This makes it easier to insert the optical connector into the holding recess, so that the optical fiber core can be held more easily.
[0012]
Further, preferably, a knob is provided on the front surface of the holding unit. Thus, even when a plurality of optical fiber holding members are attached to the module housing frame or the optical connection module in the left-right direction, the optical fiber holding member can be easily attached to and detached from the module housing frame and the optical connection module. I can do it.
[0013]
In order to achieve the above object, the present invention provides an optical wiring for switchably connecting a first optical fiber core and a second optical fiber core via an optical connection module housed in a module housing frame. In the frame, a first support portion for detachably supporting the optical fiber holding member is provided on the module storage frame.
[0014]
In the present invention configured as described above, the optical fiber holding member is attached to the first support portion of the module storage frame, and the optical connector of the optical fiber core wire previously wired in the optical wiring rack is connected to the holding portion of the optical fiber holding member. Therefore, there is no need to leave a large number of optical fibers on the tray. Thus, when the optical fiber core is connected to the optical connection module, it is possible to prevent the optical fiber core itself and the optical connector from being damaged.
[0015]
Preferably, the optical connection module is provided with a second supporting portion for detachably supporting the optical fiber holding member. When the optical connection module is stored in the module storage frame, if the optical fiber holding member cannot be attached to the module storage frame due to space or the like, the second support portion of the optical connection module stored in the module storage frame. By attaching an optical fiber holding member to the tray, a large number of optical fiber cores need not be left on the tray in this case as well.
[0016]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, preferred embodiments of an optical fiber holding member and an optical wiring rack according to the present invention will be described with reference to the drawings.
[0017]
FIG. 1 is a front view of an optical wiring rack according to the present invention, and FIG. 2 is a rear view of the optical wiring rack. In these figures, an optical distribution rack 1 extends from a plurality of in-house optical fiber core wires 3 extending from an in-house optical cable 2 connected to a transmission device and an out-of-site optical cable 4 connected to a subscriber side. A plurality of out-of-site optical fiber cores 5 are switchably connected via jumper cords 6.
[0018]
The optical wiring frame 1 has a frame 7, and on the right side (right side when viewed from the front) on the frame 7, an optical cable housing section 8 for housing a plurality of in-house optical cables 2 and a plurality of out-of-office optical cables 4. Is installed. In the optical cable housing 8, the in-site optical cable 2 and the out-of-site optical cable 4 are fixed by an optical cable stopper 9.
[0019]
A splitter module storage frame 11 that stores a plurality of splitter modules 10 is installed below the optical cable storage unit 8 in the frame 7. In the splitter module storage frame 11, splitter modules 10 are stored in a stacked state so as to be able to be taken in and out freely. The splitter module 10 distributes light from a single optical fiber to a plurality of optical fibers by an optical distribution element (not shown). Taken out. The optical fiber core 3 is connected to the optical connector 10a provided on the rear surface of the splitter module 10, and the optical fiber core 3 is connected to the jumper cord 6 via the light distribution element.
[0020]
On the front side of the splitter module storage frame 11, a plurality of alignment elements 12 are arranged in a stacked state. The alignment element 12 holds a plurality of jumper cords 6 extending from each splitter module 10 in an aligned state.
[0021]
A plurality of (for example, four) optical coupler module storage frames 14 for storing a plurality of optical coupler modules 13 are provided on the left side of the frame 7. The optical coupler module storage frame 14 has a plurality of storage portions 14a arranged side by side in the left-right direction, and the optical coupler module 13 is stored in each storage portion 14a so as to be freely taken in and out. The jumper cord 6 from the splitter module 10 is connected to the optical connector 13a provided on the front part of the optical coupler module 13, and the optical connector 13b arranged on the rear side of the optical coupler module 13 is not connected. The optical fiber core 5 is connected. An optical coupler (not shown) is provided in the optical coupler module 13, and the external optical fiber core 5 and the jumper cord 6 are connected via the optical coupler. A test optical fiber (not shown) branches off from the optical coupler, and the test optical fiber is connected to an optical test device 15 disposed below the optical coupler module housing frame 14.
[0022]
A wiring tray 16 is arranged on the front side of each optical coupler module storage frame 14, and the jumper cord 6 is guided to the optical coupler module 13 to be connected via the wiring tray 16, and is connected to the optical connector 13a. You. In addition, a core extra length storage member 17 is provided at a position adjacent to each optical coupler module storage frame 14, and a wiring tray 18 is disposed on the rear side of each optical coupler module storage frame 14. The optical fiber core wire 5 is guided onto the wiring tray 18 in a state where the extra length is absorbed by the extra fiber length accommodation member 17, and is connected to the optical connector 13b of the optical coupler module 13 to be connected.
[0023]
In the optical wiring frame 1 configured as described above, when the out-of-office optical cable 4 is installed in the optical cable accommodating section 8, the out-of-office optical module 4 is installed before the optical coupler module 13 is accommodated in the optical coupler module accommodating frame 14. A plurality of out-of-site optical fiber cores 5 extending from the optical cable 4 are preliminarily wired in the frame 7. The configuration for processing the pre-wired out-of-site optical fiber core 5 will be described below.
[0024]
FIG. 3 is a perspective view showing an optical fiber holding member according to the present invention, which is used for processing the pre-wired out-of-site optical fiber core 5. In FIG. 1, an optical fiber holding member 20 holds an external optical fiber core wire (here, a tape core wire) 5 wired in advance, and is formed of an elastic body such as rubber. The optical fiber holding member 20 has a holding portion 21 for holding an optical connector (here, an MT connector) attached to the tip of the tape core wire 5 on the front surface. The holding portion 21 has an optical connector 5a. Two holding concave portions 22 having a rectangular cross section to be fitted are formed vertically.
[0025]
As shown in FIG. 4, the holding recess 22 has a tapered shape that expands toward the opening side. The width (width in the horizontal direction) Wa of the bottom surface of the holding concave portion 22 is configured to be slightly smaller than the width W of the optical connector 5a. The member 21 is elastically deformable and can hold the optical connector 5a. The width Wb of the holding recess 22 in the vicinity of the opening surface is slightly larger than the width W of the optical connector 5a, so that the optical connector 5a can be easily inserted into the holding recess 22. In this manner, the tape core 5 can be held by the optical fiber holding member 21 only by inserting the optical connector 5a into the holding recess 22, so that the structure of the optical fiber holding member 21 is simple and the cost of the product is low.
[0026]
The holding recess 22 has a rectangular cross section in conformity with the outer shape of the optical connector (MT connector) 5a. However, the shape of the holding recess is not particularly limited thereto, and may be a circular cross section or a substantially elliptical cross section. Is also good.
[0027]
Returning to FIG. 3, a projection 23 having a rectangular cross section is fixed to the rear end of the lower surface of the holding unit 21, and the front end of the lower surface of the holding unit 21 has an extension 24 a extending toward the projection 23. An L-shaped locking piece 24 is fixed. The projections 23 and the locking pieces 24 form an engaging portion that engages with the optical coupler module housing frame 14 and the optical coupler module 13, and also form a restraining portion that restrains the holding portion 21 in the front-rear direction. I do. A knob 25 is provided on the front surface of the holding unit 21.
[0028]
The optical fiber holding member 20 configured as described above is detachably attached to the optical coupler module storage frame 14 and the optical coupler module 13. FIG. 5 is a side view showing a state where the optical fiber holding member 20 is attached to the optical coupler module housing frame 14, and FIG. 6 is an enlarged sectional view thereof.
[0029]
In these figures, a frame 30 extending in the front-rear direction is disposed above the optical coupler module storage frame 14, and a support portion 31 for supporting the optical fiber holding member 20 is provided at the end of the frame 30. Is provided. As shown in FIG. 7, the support portion 31 has a plurality of rectangular holes 32 formed in the left-right direction corresponding to the respective storage portions 14 a of the optical coupler module storage frame 14. The projection 23 of the optical fiber holding member 20 is fitted.
[0030]
When the optical fiber holding member 20 is attached to such a support portion 31, the projection 23 is fitted into the hole 32, and the tip of the support portion 31 is locked by the locking piece 24. Become. At this time, the projection 23 is fitted into the hole 32 in an elastically deformed state, and the movement of the optical fiber holding member 20 in the left-right direction and the front-back direction is restricted. Thus, the optical fiber holding member 20 hardly moves when the optical connector 5a is inserted into or removed from the holding recess 22. Further, since the support portion 31 is locked by the locking piece 24, when the optical connector 5a is inserted into the holding recess 22, the holding portion 21 is pushed in the pushing direction (left side in FIG. 5) by the force at that time. The optical fiber holding member 20 can be prevented from falling down and falling out of the hole 32.
[0031]
FIG. 8 is a diagram showing a state where the optical fiber holding member 20 is attached to the optical coupler module 13 housed in the optical coupler module housing frame 14, and FIG. 9 is an enlarged sectional view thereof.
[0032]
In these figures, a support portion 33 is provided above the optical coupler module 13 and extends rearward (to the right in FIG. 8) and supports the optical fiber holding member 20. The support portion 33 is configured to protrude from the front end of the frame 30 when the optical coupler module 13 is stored in the optical coupler module storage frame 14. A stepped groove portion 34 as shown in FIG. 10 is formed at the tip of the support portion 33. A pair of projecting pieces 35 are provided on both side walls of the stepped groove 34 that form the groove lower step 34a. The projecting piece 35 is formed such that the upper surface thereof is flush with the upper surface of the support portion 33 and the side surfaces thereof are flush with both side walls forming the groove upper step portion 34b.
[0033]
When the optical fiber holding member 20 is attached to such a support portion 33, the protrusion 23 is fitted into the upper groove portion 34b, and the gap between the bottom surface of the lower groove portion 34a and the pair of protrusions 35 is formed. The extending portion 24a of the locking piece 24 enters the space S, and the pair of protrusions 35 is locked by the locking piece 24. At this time, the projection 23 is fitted into the upper groove portion 34b in an elastically deformed state, and the extending portion 24a enters the space S in an elastically deformed state. Therefore, the movement of the optical fiber holding member 20 in the left-right direction and the front-rear direction is restricted by the protrusions 23 and the locking pieces 24. In addition, since the projection piece 35 is locked by the locking piece 24, when the optical connector 5a is inserted into the insertion concave portion 22, the optical fiber holding member 20 is prevented from falling in the pushing direction and coming off the support portion 33. it can.
[0034]
Next, a procedure for holding the out-of-site optical fiber core wire 5 previously wired in the frame 7 on the optical fiber holding member 20 will be described. The storage section 14a of the optical coupler module storage frame 14 in which the optical coupler module 13 to which the pre-wired external optical fiber core 5 is connected is previously determined.
[0035]
First, the plurality of optical fiber holding members 20 are attached to the support portions 31 of the optical coupler module housing frame 14. The optical connector 5a at the end of the pre-wired out-of-site optical fiber core 5 is connected to the holding recess of the optical fiber holding member 20 disposed on the front surface of the housing 14a in which the optical coupler module 13 to be connected is housed. 22.
[0036]
Thereafter, when the optical coupler module 13 is stored in the optical coupler module storage frame 14, the optical fiber holding member 20 is removed from the support portion 31, and then the optical coupler module 13 is stored in the storage portion 14a. Then, the optical fiber holding member 20 holding the outside optical fiber core 5 is attached to the support portion 33 of the optical coupler module 13.
[0037]
The reason why the optical fiber holding member 20 is replaced from the optical coupler module housing frame 14 to the optical coupler module 13 is that the optical fiber holding member 20 is attached to the support portion 31 of the optical coupler module housing frame 14 so that the optical coupler is replaced. This is in consideration of the fact that the support portion 33 of the module 13 hits the locking piece 24 of the optical fiber holding member 20 and the optical coupler module 13 cannot be stored in the optical coupler module storage frame 14. Therefore, when such a space problem does not occur, the optical fiber holding member 20 may be left attached to the optical coupler module housing frame 14.
[0038]
Thereafter, when connecting the out-of-site optical fiber core 5 to the optical connector 13b of the optical coupler module 13, the optical connector 5a is pulled out from the holding recess 22 of the optical fiber holding member 20, and is connected to the optical connector 13b.
[0039]
As described above, in the present embodiment, the optical fiber holding member 20 is attached to the optical coupler module storage frame 14 and the optical coupler module 13, and the optical fiber previously wired is held in the holding concave portion 22 of the optical fiber holding member 20. Since the fiber core 5 is held neatly, the leading end of the optical fiber 5 wired in advance is not left on the tray 18. Therefore, when connecting the optical fiber core 5 to the optical connection module 13 housed in the optical coupler module housing frame 14, the optical fiber core 5 to be connected is forcibly out of many optical fiber cores 5. There is no need to pull it out. This can prevent the optical fiber core 5 itself and the optical connector 5a from being damaged.
[0040]
Further, as described above, it is not only necessary to search for and remove a necessary optical fiber core wire 5 from the large number of optical fiber core wires 5 but also to store the extra length of the optical fiber core wire 5 in advance. By accommodating the optical fiber core 5 in the member 17, the work of absorbing the extra length when connecting the optical fiber core 5 can be omitted. Thereby, the work time for connecting the optical fiber core 5 is shortened, and the workability is improved.
[0041]
Furthermore, since one optical fiber holding member 20 can be attached to both the optical coupler module storage frame 14 and the optical coupler module 13, it is extremely effective in terms of cost.
[0042]
Further, since the optical fiber holding member 20 is made of an elastic material, the optical fiber core 5 can be easily held on the optical fiber holding member 20. Further, since the knob 25 is provided on the front surface of the optical fiber holding member 20, the optical fiber holding member 20 can be easily attached and detached even when a plurality of optical fiber holding members 20 are installed close to each other.
[0043]
As mentioned above, although one Embodiment of the optical wiring frame concerning this invention was described, it cannot be overemphasized that this invention is not limited to the said embodiment. For example, in the above-described embodiment, the structure for supporting the optical fiber holding member 20 is different between the optical coupler module housing frame 14 and the optical coupler module 13, but may be the same structure.
[0044]
Further, in the above embodiment, the optical fiber holding member is formed of an elastic body, and the optical fiber holding member 5 is held by the elastic force alone, and the optical fiber holding member is attached to the optical coupler module 13 and the optical coupler module housing frame 14. Although the attachment / detachment is performed, the optical fiber holding member is not particularly limited thereto, and may be of another type, such as one that holds the optical fiber core wire 5 using a screw or the like and attaches / detaches the optical fiber holding member. You may.
[0045]
Further, the optical wiring frame of the above-described embodiment has the splitter module 10, the alignment element 12, and the optical coupler module 13 housed in the frame 7. The present invention is applicable to all optical wiring racks that switchably connect a fiber core wire via optical connection modules arranged in the left-right direction.
[0046]
【The invention's effect】
According to the present invention, the optical fiber holding member is attached to the module storage frame or the optical connection module, and the optical fiber core wire previously wired is held in the holding portion of the optical fiber holding member. It is not necessary to leave it on the tray, which can prevent damage to the optical fiber core itself and the optical connector.
[Brief description of the drawings]
FIG. 1 is a front view showing an optical wiring rack according to the present invention.
FIG. 2 is a rear view showing an optical wiring rack according to the present invention.
FIG. 3 is a perspective view showing an optical fiber holding member according to the present invention.
FIG. 4 is a diagram illustrating a dimensional relationship between a holding recess formed in an optical fiber holding member and an optical connector;
FIG. 5 is a side view showing a state where the optical fiber holding member is attached to the optical coupler module housing frame.
FIG. 6 is an enlarged sectional view showing a state where an optical fiber holding member is attached to an optical coupler module housing frame.
FIG. 7 is a plan view showing a support provided on the optical coupler module housing frame.
FIG. 8 is a side view showing a state where the optical fiber holding member is attached to the optical coupler module.
FIG. 9 is an enlarged cross-sectional view showing a state where an optical fiber holding member is attached to the optical coupler module.
FIG. 10 is a perspective view showing a support provided on the optical coupler module.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 ... Optical wiring rack, 3 ... In-house optical fiber core (first optical fiber), 5 ... Outside optical fiber core (second optical fiber), 5a ... Optical connector, 13 ... Optical coupler module ( Optical connection module), 14: Optical coupler module storage frame (module storage frame), 20: Optical fiber holding member, 21: Holding section, 22: Holding concave section, 23: Projection (engaging section, restraining section), 24 ... Locking pieces (engaging portions, restricting portions), 25 knobs, 31 support portions (first support portions), 32 hole portions, 33 support portions (second support portions) 34b upper groove portions.

Claims (5)

An optical fiber holding member detachably attached to a module storage frame of an optical wiring rack or an optical connection module housed in the module storage frame, and holding an optical fiber core wire connected to the optical connection module,
A holding portion that holds an optical connector provided at the front end of the optical fiber core wire on the front surface, and an engaging portion fixed to the holding portion and engaged with the module storage frame or the optical connection module ,
The holding portion and the engagement portion are integrally formed of an elastic body,
The holding unit has a holding recess into which the optical connector is fitted,
The engaging portion is fixed to a lower surface of the holding portion, and a projection fitted into a hole or a groove formed in the module housing frame or the optical connection module, and a front side of the lower surface of the holding portion with respect to the projection. Has a portion extending toward the protrusion side, and has a substantially L-shaped locking piece for locking the module storage frame or the optical connection module,
An optical fiber holding member, wherein the projection and the locking piece constitute a restraining portion for restraining the holding portion in the front-rear direction . The holding recess, the optical fiber holding member according to claim 1, characterized in that it has a cross-sectional tapered shape spreading to the opening side. Claim 1 or 2 optical fiber holding member according to characterized in that a knob on the front surface of the holding portion. In an optical wiring rack for switchably connecting the first optical fiber core and the second optical fiber core via an optical connection module housed in a module housing frame,
An optical wiring rack, wherein a first support portion for detachably supporting the optical fiber holding member according to any one of claims 1 to 3 is provided on the module storage frame. The optical wiring rack according to claim 4 , wherein the optical connection module is provided with a second support portion that detachably supports the optical fiber holding member.

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