KR101165060B1 - Structure of Fiber Distribution Frame without Slack - Google Patents

Abstract

The present invention relates to a structure of a no-disc treatment light distribution panel.

To this end, the present invention, a field-mounted optical jumper cord for connecting between a plurality of unprocessed light distribution box self, a plurality of unprocessed light distribution box self, accommodating the system optical cable and the outdoor optical cable, the site connected horizontally Provides a non-processing optical distribution panel including a horizontal wiring route guide for receiving and supporting an assembled optical jumper cord and a system optical cable, an outdoor optical cable, and a vertical wiring route guide for receiving a vertically connected field assembled optical jumper cord. .

According to the present invention, as the optical jumper cord manufactured to the required length in the field is used directly, and no dressing is made, the configuration becomes simple, and the wiring operation of the front optical jumper cord is possible, and the operation according to the dressing process and Inefficiencies and economics of management can be greatly improved.

Optical communication, sheath, optical distribution board, optical cable, optical jumper cord, optical transmission

Description

Structure of Fiber Distribution Frame without Slack}

1 is a view briefly showing the structure of a light distribution panel that is conventionally used;

Figure 2 is a simplified view showing a conventional light distribution box self,

3 is a view showing a method of processing a light distribution panel used in the prior art,

4 is a view briefly showing a structure of a no-coated light distributor according to an embodiment of the present invention;

5 is a view briefly showing a no-coarse processing light distribution bin according to an embodiment of the present invention;

FIG. 6 is a view briefly showing a vertical wiring route guide of a no-coated light distribution board according to an embodiment of the present invention; FIG.

7 is a view showing the field assembly optical connector and the optical jumper cord used in the present invention,

8 is a view for explaining the operating system of the armless processing light distribution panel according to an embodiment of the present invention.

The present invention relates to a structure of a no-disc treatment light distribution panel. More specifically, in the optical distribution panel, which is an optical fiber facility for performing functions such as connection, distribution and switching between the optical transmission system and the external optical cable network, the optical distribution panel for processing the length of the optical jumper cord generated along a uniform length It's about structure.

As the demand for the Internet and the demand for the provision of high-speed Internet services by Internet subscribers have increased, the installation of optical cables has increased due to the spread of the Internet using optical cables. Accordingly, in order to easily distribute or connect the optical cable to each optical subscriber and transmission equipment in the vicinity of the optical subscriber in the optical network, a fiber distribution frame (FDF) is used in the telephone company.

In general, an optical distribution panel refers to a subscriber optical transmission system or a device installed and operated in a telephone company to perform a connection, distribution, and transfer function between an intermediate terminal and an external optical cable network so as to freely change and register an optical subscriber.

1 is a view briefly showing the structure of a light distribution panel used in the related art. Here, FIG. 1A is a front view of the light distribution panel, and (b) is a side view of the light distribution panel.

The light distribution panel is configured to include a light distribution panel rack 110, a plurality of light distribution box self 120 and the optical jumper code insertion processing unit 130.

The light distribution panel rack 110 is a frame for supporting the light distribution panel and accommodates and supports a plurality of light distribution boxes 120.

Optical fiber distribution (OFD) shelf 120 is a part for accommodating optical jumper codes such as 72 cores and 144 cores, and performing operations such as connection, distribution, and switching between the optical jumper cords.

The optical jumper code dressing processing unit 130 is a part for winding and storing the dressing of the optical jumper cord, which has a margin during optical wiring work.

2 is a view briefly showing a light distribution box self conventionally used.

The light distribution box 120 includes an optical jumper cord holder 210, an optical jumper draw-out hole 220, and an adapter 230.

The optical jumper cord holder 210 is a part for fixing a plurality of optical jumper cords respectively connected to the plurality of adapters 230 so as not to move.

The optical jumper draw-out hole 220 is a hole in which a plurality of optical jumper cords connected to the adapter 230 are input or output to the light distribution box 120, or are formed at the side, top, or bottom of the light distribution box Self. .

The adapter 230 is a portion in which the optical jumper cord is directly connected, and is a portion in which operations such as connection, distribution, and transfer are actually executed.

The optical distribution panel is configured to operate the optical distribution panel through the optical wiring operation of connecting the optical distribution box self 120 and the optical transmission system with the optical jumper cord.

Currently used optical distribution boards are the Inter-Connection method and the Cross-Connection method.

In the interconnection method, an optical connector is connected to the ends of all optical fibers of an outdoor optical cable, and an optical connector is connected to the rear side of the adapter 230 of the self-container 120, and between the optical transmission system and the optical distribution panel. The connection is a method of connecting to the front of the adapter 230 of the optical distribution box self 120 using an optical jumper cord or a connector of a specific length.

In the cross connection method, an optical fiber cable and an optical fiber cable of an optical transmission system are connected to an optical connector, and are respectively connected to the rear surface of the adapter 230 of the optical distribution panel self 120, and using an optical jumper cord having a specific specific length. This is a method of connecting an adapter connected to an optical transmission system and an adapter connected to an outdoor optical cable at the front of the optical distribution panel.

According to such an interconnection method or a cross-connection method, an optical communication service between an optical transmission system in a telephone station and a square ratio of subscribers connected through an external optical cable network becomes possible.

As such, the optical jumper cord used to connect the outdoor optical cable, the optical transmission system, and the optical distribution box self 120 of the optical distribution panel uses unit lengths set in advance such as 1M, 2M, 3M, 5M, and 10M. Accordingly, when the optical wiring operation for connecting the optical jumper cord between the adapter 230 of the optical distribution box 120 and the optical transmission system and the outdoor optical cable is left, an extra length (length) is left in the optical jumper cord. In order to process such an extra optical jumper code, the optical jumper code as much as the remaining length in the optical jumper code insertion processing unit 130 is wound.

3 is a view showing a method of processing the light distribution panel conventionally used.

As shown in FIG. 3, when the optical jumper is wound with the extra optical jumper code in the optical jumper code filtering processor 130, the number of optical jumper codes accommodated in the optical distribution board increases as the optical communication service request increases. Accordingly, it becomes difficult to identify the optical jumper code, so that the optical distribution panel operator has a problem in that the optical wiring work for installation / maintenance of wiring, dismantling, etc. becomes difficult. In addition, as the optical jumper cord increases, stacks, and accumulates, failures may occur due to occurrence of bending, compression, or the like, in which the radius of curvature of the optical core that the optical jumper cord must maintain for optical communication becomes narrower than a reference value. There is a problem.

In particular, when the facilities of the external optical cable network and the optical transmission system proliferate in accordance with the spread of the ultra high speed optical subscriber network, the number of optical jumper codes to be accommodated in the optical distribution panel increases rapidly, such a problem becomes more serious.

In order to solve such a problem, the present invention provides an optical jumper cord that can be adjusted in length by using a field-assembled optical connector in the optical distribution panel for connection of the optical cable transmitted from the optical transmission system and the optical cable transmitted from the external optical cable network. By providing the shortest distance by using the direct wiring, it provides a structure and operation method of the optical distribution panel for removing the length of the optical jumper cord.

In order to achieve the above technical problem, the present invention, in the optical distribution panel for eliminating the length of the optical jumper cord connecting the optical transmission system that provides the optical communication service and the external optical cable network that is connected to the subscriber equipment as a non-processing optical distribution panel. A first sheer processing fiber distribution box for receiving an optical cable for a system coupled with the optical transmission system; At least one second sheered processing fiber distributor for receiving an outdoor optical cable connected to an external optical fiber network; An on-site assembled optical jumper cord whose length is adjusted according to a distance between the first unpacked light distributor and the second unpacked light distributor; A horizontal wiring route guide for receiving and supporting an on-site assembled optical jumper cord that is horizontally connected between the first unpacked light distribution box shelf and the second unpacked light distribution box shelf; And field-mounted optical jumper cords connected vertically between the optical fiber for the system connected to the optical transmission system, the outdoor optical cable connected to the external optical fiber network, and the first unprocessed fiber distributor and the second unprocessed fiber distributor. It includes a vertical wiring route guide.

In addition, in order to achieve the second technical problem, the present invention provides an optical distribution panel operating system, an optical transmission system for providing an optical communication service, and an optical transmission panel for connecting one or more external optical cable networks connected to a plurality of subscriber equipments. Claims [1] An optical distribution board operating system for removing an optical jumper cord linking a system and a plurality of subscriber equipments, the optical distribution panel operating system comprising: an optical distribution panel for a system connected to the optical transmission system to connect the optical transmission system and one or more external optical cable networks; An optical cable for a system connecting the optical transmission system and the optical distribution panel for the system; An optical distribution panel for at least one optical cable connected with the external optical cable network, for connecting the optical transmission system and at least one external optical cable network; An outdoor optical cable connecting the external optical cable network with the optical distribution panel for the optical cable; A field-assembled optical jumper cord that adjusts the length according to the distance between the optical distribution panel for the system and the optical distribution panel for connecting the optical distribution panel for the system and the optical distribution panel for the optical cable; A vertical wiring route guide for receiving a field-assembled optical jumper cord vertically connected between a system optical cable, an outdoor optical cable, and a system optical distribution panel and a system optical distribution panel; And a horizontal wiring route guide for receiving and supporting the field-assembled optical jumper cord that is horizontally connected between the optical distribution panel for the system and the optical distribution panel for the optical cable.

DETAILED DESCRIPTION Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. In the drawings, parts irrelevant to the description are omitted in order to clearly describe the present invention, and like reference numerals designate like parts throughout the specification.

In addition, when a part is said to "include" a certain component, it means that it may further include other components, without excluding other components unless otherwise stated.

4 is a view schematically showing the structure of a no-coated light distributor according to an embodiment of the present invention.

The non-processing light distribution panel according to the present invention includes a non-processing light distribution box self 410, a horizontal wire route guide 420 of a field-assembled optical jumper cord, and a vertical wire route guide 430. Here, the non-coated processing light distribution box 410 and the horizontal wiring route guide 420 will be described in detail with reference to FIG. 5 and the vertical wiring route guide 430 will be described in detail with reference to FIG. 6.

5 is a view briefly illustrating a no-coating light distribution bin itself according to an embodiment of the present invention.

Redundant Processing Optical Distribution Box Self 410 is a part that handles the connection, distribution and transfer between optical cables (optical cable connected to optical transmission system and optical cable connected to external optical cable network). It includes an optical connector for connecting the adapter 510, and a horizontal wiring route guide 420 of the field-assembled optical jumper cord.

The optical connector connection adapter 510 is a part to which the optical connector of the field assembly type optical jumper cord is connected, and connects the optical connector of the optical jumper cord input to the front and the optical connector of the optical jumper cord input to the rear. This is the part that plays a role.

The horizontal wiring route guide 420 is a duct sufficient to accommodate not only the optical jumper cord accommodated in the non-processing light distribution box 410 but also the optical jumper cord passing through the other non-processing light distribution box self. Is the root guide of the form. Here, the horizontal wiring route guide 420 is an optical connector of the unloaded light distribution box 410 in order to facilitate connection and handling of the field-assembled optical jumper cord in the unloading light distribution box 410. It is installed at a sufficient distance from the vertical plate of the adapter 510 for connection.

FIG. 6 is a view briefly showing a vertical wiring route guide of a non-coated optical splitter according to an embodiment of the present invention. FIG.

The vertical wiring route guide 430 is classified into an optical jumper cord vertical wiring route guide and an optical cable vertical wiring route guide.

The optical jumper cord vertical wiring route guide serves to vertically wire a plurality of field-assembled optical jumper cords that have been routed through the horizontal wiring route guide 420 at the front of the unmanned processing optical distribution panel.

Optical cable vertical routing The route guide is located at the rear of the no-distribution optical distributor, the optical cable for the system responsible for the wiring between the optical transmission system and the optical distributor, bundles of multiple field-assembled optical jumper cords, and the wiring between the external optical cable network and the optical distributor. It includes an optical fiber tube for the outdoor and the optical fiber tube or optical fiber inside the optical cable, and performs the optical fiber distribution function to the vertical and left and right unprocessed optical distribution box self 410.

Here, the vertical wire route guide 430 including the optical jumper cord vertical wire route guide and the optical cable vertical wire route guide is configured as a separate expansion rack 610, so that it can be freely extended in the armed process light distribution panel. have.

At this time, the expansion rack 610 including the vertical wiring route guide 430 can be pulled in and out of the optical cable at the top or bottom, and from the optical cable vertical wiring route guide to the left and right unprocessed optical distribution box self 410. The wiring sufficiently maintains the radius of curvature of the optical cable. In addition, it may be composed of a curved guide that can sufficiently maintain the radius of curvature of the optical cable at the boundary point between the horizontal wiring route guide 420 and the vertical wiring route guide 430.

7 is a view showing the field assembly optical connector and the optical jumper cord used in the present invention.

According to the present invention, in order to connect with the optical connector connection adapter 510 of the light distribution box self-410, without using an optical jumper cord having an optical connector at the end of a predetermined unit length, which is conventionally used, Use field-assembled optical jumper cords to create the length of the optical jumper cord.

The field-assembled optical jumper cord 710 can be assembled on-site directly to the various components of the field-mounted optical connector 720 at the end of the ordinary optical fiber core wire, thereby making the field-assembled optical jumper cord 710 of the desired length Therefore, unnecessary redemption can be eliminated accordingly.

The field assembled optical connector 720 located at the end of the field assembled optical jumper cord 710 consists of a ferrule 722, a protective housing 724, a crimp ring 726, and a protective cover 728.

Ferrule 720 is a component used for the alignment of the optical cores in the connection to the adapter 510 for connecting the optical connector. Ferrule 720 is strong in deformation and must maintain accurate shape, so it is made of stainless steel, polymer or ceramic based alumina (Al ₂ O ₃ ) or zirconia (zirconia, ZrO ₂ ). do. In the form of a cylinder, one minute hole penetrating therein can accommodate the optical fiber.

Ceramic ferrules have superior advantages over polymer or stainless steel in optical transmission. Polymer ferrules have lower performance than ceramic ferrules, but have superior advantages in terms of price. Stainless steel ferrules, on the other hand, have a very high strength, do not break easily, and are widely used in applications requiring frequent repeated bonding because of their high durability. For the construction of the field assembly type optical connector 720 according to the present invention, it is preferable to use a ceramic ferrule having excellent performance.

The protective housing 724 is a portion which is covered to protect the ferrule 720, and is formed of an inner housing and an outer housing.

The crimp ring 726 is added to secure the ferrule 720 in order to prevent breakage of the ferrule 720 and accurate connection with the adapter 510 for connecting the optical connector.

The protective cover (Rubber Boot) is a portion that is once again covered on the protective housing 724 in order to protect the connection portion of the optical fiber and the ferrule 720.

By using the field-assembled optical jumper cord configured as described above, it is possible to operate the armless processing light distribution board.

8 is a view for explaining the operating system of the armless processing light distribution panel according to an embodiment of the present invention.

The non-processing optical splitter operation system according to the present invention includes an optical transmission system 810, an optical cable 820 for a system, an external optical cable network 830, an optical fiber cable 840, an optical fiber distributor 850, an optical fiber for an outdoor optical cable. A betrayal 860 and a vertical wire route guide 430.

In order to configure such a no-coated light distribution board operating system, an unloaded light distribution board rack is installed, and an expansion rack including a vertical wiring route guide 430 is installed for expansion. At this time, the expansion rack for the vertical wiring route guide 430 is provided on the left side or the right side of the armless process light distribution boards 850 and 860. Here, the no-distribution processing optical splitter 850 is an optical splitter for outdoor optical cables connected to an external optical cable network 830 through a system optical splitter 850 connected to an optical transmission system 410 and an outdoor optical cable 840. 860).

In addition, the outdoor optical cable 840 introduced from the external optical cable network 830 is connected to the rear surfaces of the unprocessed optical distribution boards 850 and 860 through a ceiling duct or a grid or a bottom of the floor. At this time, the incoming outdoor optical cable 840 is fixed to the vertical wiring route guide 430, the optical connector connection of the unmanned processing light distribution box Self 410 inserted into the unprocessed optical distribution panel (850, 860). It is connected to the rear of the adapter 510.

At this time, the radius of curvature is sufficiently set when the optical jumper cord is connected from the vertical wiring route guide 430 to the unmanned light distribution bin 410.

The connection method between the optical transmission system 810 and the non-processing optical distribution panel 850, 860 connects one end of the optical cable 820 for the system to the optical transmission system 410, and the other end is connected to the vertical route route guide 430. Through) connects to the rear of the process-distributed light distribution box self 410. At this time, the optical cable 820 for the system may be an optical jumper cord having an optical connector at both ends, or may be a cable bundled with the optical jumper cord. The system optical cable 820 may be led to the vertical wiring route guide 430 through the ceiling duct or grid or bottom of the floor, similar to the outdoor optical cable 840.

As described above, when the system optical cable 820 is introduced from the optical transmission system 810 and the outdoor optical cable 840 is introduced from the external optical cable network 830, the system optical cable 820 and the outdoor optical cable 840 should be connected to each other. do.

For connection, first, the system optical cable 820 introduced from the optical transmission system 810 is connected to the rear surface of the adapter 510 for connecting the optical connector of the unprocessed optical distribution box self 410 in the optical distribution panel 850 for the system. Star cluster.

Then, the outdoor optical cable 840 introduced from the external optical cable network 830 is clustered on the rear surface of the optical connector connection adapter 510 of the unprocessed optical distribution box self 410 in the optical fiber distribution panel 860. .

Then, matching between the no-mounted processing light distribution box self in the system optical distribution panel 850 and the no-mounting processing light distribution box self in the optical cable distribution panel 860 is set. When the setting is completed, one end of the optical jumper cord with the optical connector is clustered in front of the adapter for the optical connector of the optical distribution panel 850 in the system, and the field-assembled optical jumper cord is connected. Through the horizontal wiring route guide 420, wiring is performed to the front surface of the adapter for connecting the optical connector of the no-disposing process optical distribution box self in the optical distribution panel 860 for the optical cable. When the wiring is completed, cut the optical jumper cord on the side of the optical distribution box self-distribution in the optical distribution panel 860 for the optical cable, attach the field assembly type optical connector 720, and then attach the star to the front of the adapter for connecting the optical connector. do.

At this time, the process-distributed light distribution box self side in the optical distribution panel 850 for the system can use the existing optical connector, which is attached to the optical jumper cord, as it is, and can also attach the field-assembled optical connector 720. .

In this case, the outdoor optical cable 840 introduced from the external optical cable network 830 may be directly connected from the optical transmission system 810 to the unprocessed optical distribution box self connected to the system optical cable 820.

According to such a method, operation of a no-mount process light distribution board using an on-site assembly type optical jumper cord becomes possible.

The embodiments of the present invention described above are not only implemented by the apparatus and method but may be implemented through a program for realizing the function corresponding to the configuration of the embodiment of the present invention or a recording medium on which the program is recorded, The embodiments can be easily implemented by those skilled in the art from the description of the embodiments described above.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, It belongs to the scope of right.

By the above-described configuration, the optical jumper cord manufactured to the required length directly in the field is used, and thus, the unswitched processing light distribution board having no length is provided, thereby simplifying the configuration and enabling wiring of the front optical jumper cord. In addition, the inefficiency and economic efficiency of operation and management in accordance with dressing can be greatly improved.

Accordingly, FTTC (Fiber To The Curb) network that provides optical communication service to the box installed on the road in front of the house, FTTP (Fiber To The Pole) network that provides optical communication service to the Jeonju near the house, and the optical fiber service to the house In the FTTH (Fiber To The Home) network, it is expected to greatly increase the efficiency of the work of the optical cable cluster and the optical jumper cords and the maintenance work of the optical cable cluster in the optical distribution panel, which can be complicated by the increase in the number of subscribers.

Claims (13)

Claims [1] An optical distribution panel for removing an optical jumper cord connecting an optical transmission system providing an optical communication service and an external optical cable network connected to subscriber equipment. A first sheer processing optical splitter shelf for receiving an optical cable for a system connected with said optical transmission system; At least one second no-banding processing optical splitter shelf for receiving an outdoor optical cable connected to the external optical cable network; An on-site assembled optical jumper cord whose length is adjusted according to a distance between the first unpacked light distributor and the second unpacked light distributor; A horizontal wiring route guide for receiving and supporting an on-site assembled optical jumper cord that is horizontally connected between a first batch-processing light distribution box shelf and the second batch-processing light distribution box shelf; And Field-mounted optical jumpers vertically connected between the system optical cable connected to the optical transmission system, the outdoor optical cable connected to the external optical cable network, and the first no-packing optical distribution box self and the second no-processing optical distribution box self. Vertical route route guide to accommodate cord Sheathed light distribution panel characterized in that it comprises a. The method of claim 1, The first no-packing optical splitter shelf and the second no-treatment optical splitter shelf are connected to the system optical cable, the outdoor optical cable, and the field-assembled optical jumper cord through an optical connector connection adapter. Sheathed light distribution panel made with. 3. The method of claim 2, The system optical cable and the outdoor optical cable are connected to the rear of the optical connector connection adapter, and the field-assembled optical jumper cord is connected to the front of the optical connector connection adapter, characterized in that the process-free distribution panel. The method of claim 1, wherein the field assembly optical jumper cord, At the end of the optical fiber by the distance between the first unpacked light splitter and the second unpacked light splitter, the first unpacked light splitter and the second blanked process An armed process light distribution panel characterized in that the length is adjusted by assembling an optical connector for connection with a self. The method of claim 4, wherein the optical connector, A ferrule for aligning an optical core wire connected with the optical connector connection adapter; A protective housing for protecting the ferrule; A crimp ring for fixing the ferrule for accurate connection with the optical connector connection adapter and prevention of breakage; And Protective cover overlaid to protect the ferrule and the crimp ring Sheathed light distribution panel characterized in that it comprises a. The method of claim 1, wherein the horizontal wiring route guide, And the second unpacked light splitter and the second unpacked light splitter. The method of claim 1, wherein the vertical wiring route guide, An optical jumper cord vertical wiring route guide for receiving an on-site assembled optical jumper cord that is vertically connected between the first no-packing light distribution bin and the second no-packing light distribution bin; And Optical cable vertical wiring route guide for receiving the optical fiber for the system connected to the optical transmission system, the optical fiber for outdoor use connected to the external optical cable network Sheathed light distribution panel characterized in that it comprises a. The method of claim 7, wherein the optical jumper cord vertical wiring route guide, Located at the front of the vertical wiring route guide, the first non-mounted processing light distribution box self and the second non-processing light distribution box Self are connected using the field-assembled optical jumper cord. Sheathing processing distribution panel. The method of claim 7, wherein the optical cable vertical wiring route guide, Located in the rear of the vertical route route guide, the system optical cable and the outdoor optical cable is connected to the rear of the first non-processing optical distribution box self and the second non-processing optical distribution box self. Sheathed light distribution panel. The method of claim 1, wherein the optical cable vertical wiring route guide, The field-assembled type when the connection between the first no-packing light distribution box self and the second no-packing light distribution box self using the field-mounted optical jumper cord and the system optical cable or the outdoor optical cable is connected The optical jumper cord, characterized in that the curved structure is configured to maintain the radius of curvature of the optical cable and the optical fiber for outdoor use. In the optical distribution panel that connects the optical transmission system for providing an optical communication service and at least one external optical cable network connected to a plurality of subscriber equipment, the optical powder for removing the margin of the optical jumper cord connecting the optical transmission system and the plurality of subscriber equipment In the betrayal operation system, An optical distribution panel for the system connected with the optical transmission system to connect the optical transmission system and the at least one external optical cable network; A system optical cable connecting the optical transmission system and the optical distribution panel for the system; An optical distribution panel for at least one optical cable connected with the external optical cable network to connect the optical transmission system and the at least one external optical cable network; An outdoor optical cable connecting the external optical cable network with the optical distribution panel for the optical cable; A field-assembled optical jumper cord that adjusts a length according to a distance between the optical distribution panel for the system and the optical distribution panel for connecting the optical distribution panel for the system and the optical distribution panel for the optical cable; A vertical wiring route guide accommodating the system optical cable, the outdoor optical cable, and a field-assembled optical jumper cord vertically connected between the system optical distribution panel and the optical distribution panel for the optical cable; And Horizontal wiring route guide for receiving and supporting the field-assembled optical jumper cord connected horizontally between the optical distribution panel for the system and the optical distribution panel for the optical cable Light distribution board operating system comprising a. The optical distribution panel for the system and the optical distribution panel for the optical cable, And at least one non-processed optical splitter shelf for connection with the system optical cable, the outdoor optical cable, and the field-assembled optical jumper cord. The method of claim 11, wherein the vertical wiring route guide, Optical distribution panel operating system, characterized in that located between the optical distribution panel for the system and the optical distribution panel for the optical cable, or between one optical cable distribution panel and another optical cable distribution panel.

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