KR20060111757A - Fiber distribution panel of building for information super highway - Google Patents

Abstract

A fiber distribution panel for a building implementing an ISH(Information Super Highway) is provided to facilitate maintenance of optical fibers for receiver sides by separating receiver distributing boards for plural receivers from one another. A fiber distribution panel a building implementing an ISH includes a receiver distributing board, a distribution panel box, and a receiver distributing board fixing unit. Plural optical adapters, which are connected to plural receivers, are installed on one side of an optical cable. The optical cable is selectively connected to the optical adapters. The distribution panel box is fixed on an open rack(9), so that the receiver distributing boards are laminated in plural layers and arranged in plural columns. The receiver distributing board fixing unit removably fixes the receiver distributing board, which is inserted into an insertion portion(203), on a board fixing plate.

Description

Fiber distribution panel of Building for Information Super highway}

Figure 1 is an exploded perspective view of the installation state of the optical distribution panel of the present invention

Figure 2 is a perspective view of the generation distribution board of the present invention

Figure 3 is a front view of the installation state of the present invention

Figure 4 is a front view of the part of the installed state of the generation distribution board of the present invention

5 is a front view of the distribution box of the present invention;

Figure 6 is a plan view of the generation distribution board of the present invention

Figure 7 is a fixed state cross-sectional view of the generation distribution board of the present invention

8 is a fixed state diagram of the generation distribution board by the generation distribution board fixing means of the present invention

9 is a front view of another embodiment of the present invention enclosure.

10 is a front view of a conventional optical distribution panel.

11 is a side cross-sectional view of a conventional optical distribution panel.

[Explanation of symbols on the main parts of the drawings]

2, 200: distribution enclosure 7, 107: optical adapter

9: Open Rack 100: Generation Distribution Board

106: optical cable 108: optical jumper cord

201: fixed end 202: board fixing plate

203: inserting portion 206: through hole

300: generation distribution board fixing means 302: fastening plate

The present invention relates to a subscriber optical distribution panel (S-FDF) installed in the same unit communication room of the apartment, and more particularly, an optical cable (2 to 4 lines) distributed to each subscriber is mounted on an independent generation distribution board. It is possible to work without damaging other generations' optical cables by separating the generation distribution board alone when performing clustering, inspection, test confirmation, and expansion of optical cables, as well as reducing maintenance costs due to maintenance and repair. The present invention relates to an optical distribution board for ultra-high-speed information and communication buildings, which can reduce cost by slimming the betrayal.

In today's information society, the role of communication network is very important. Especially, as network communication such as the Internet is developed and a large amount of data is transmitted such as video or voice, an increase in information throughput and processing speed is required. The expansion of the network is urgently needed.

In order to satisfy this demand, an optical cable is used instead of a conventional coaxial cable in order to process a large amount of information at high speed, and the use of the optical cable is increasing rapidly.

In particular, in recent years, optical cables enter only the MDF of apartment complexes, and from the management premises to each home to provide high-quality, high-speed services at a government-wide level, breaking away from conventional systems that used regular telephone lines. FTTH (Fiber to the home) network laying fiber is being built.

In order to build the above FTTH network, the number of optical cables installed in the main trunk is increased from the existing two lines to four lines, and in particular, an optical distribution board (FDF) must be installed for the cluster operation of the optical cables in the same unit communication room of the apartment. do.

The conventional optical distribution panel 1 has a mainstream shape as shown in FIGS. 10 to 11, and a plurality of trays 3 for forming a large-capacity optical cable 144 lines in the distribution enclosure 2. ) Is laminated, and the tray 3 has an optical jumper cord 8 coupled with a plurality of optical adapters 7 installed on the front plate 6 of the distribution box 2 and an optical cable introduced from the outside. It is made up of a connected configuration.

In the case of the conventional optical distribution panel, the operator directly distributes the optical fiber in the field to supply 2 to 4 lines per household, and the supply method is sequentially according to the arrangement order of the optical adapters 7 installed in a row in succession as shown in FIG. Allocate 2 ~ 4 lines for each household of subscribers.

Therefore, in this case, the optical cables distributed and supplied by each subscriber are not divided by independent households, but are sequentially assigned according to the order of subscribers to join, which makes it difficult to add and change by subscribers.

That is, as an example, when subscribers of household 101 subscribe first, two to four lines are first supplied according to the arrangement order of optical adapters 7 installed in a row. Next, when subscribers of household 1001 subscribe, By supplying the optical cables of 1001 household subscribers in succession to the household generation, each household is in a mess and has difficulty in expansion, modification and maintenance.

Therefore, in order to solve this problem, in the above-described case, the extension of the optical cable extension work of non-subscribers located between Nos. 101 and 1001 is delayed, that is, 1001 without the optical adapter 7 corresponding to 102 to 1000 households. The optical cable of household subscribers should be supplied first, but the conventional distribution panel is not divided by independent households, so delayed expansion work due to the increase of subscribers has not been performed smoothly.

As a result, if a fiber of one generation subscriber is damaged, it cannot be easily understood, and the worker has to check the fiber of another generation subscriber one by one, which is not only troublesome, but also causes a problem of touching another subscriber line.

Moreover, each additional star cluster work is performed every time during expansion and test work due to the increase of subscribers, but at this time, the space inside the distribution enclosure 2 is very narrow, which increases the difficulty of work and also contacts other subscriber ships during the star cluster work. This results in damage.

As a result, it is very difficult to manage each generation during maintenance and repair because the optical fibers distributed by each subscriber are not classified by generation, which leads to an increase in management costs.

In addition, in the case of the optical distribution panel, despite the distribution and supply of up to 144 lines, the overall size is very large, resulting in an increase in cost due to manufacturing, thereby lowering the price competitiveness and productivity.

The present invention is to provide an optimal light distribution panel that can actively solve the above problems.

To this end, an optical cable composed of 2 to 4 lines per household is selectively mounted on an independent generation distribution board with an optical jumper cord connected to an optical adapter to enable individual optical fiber management per generation, and the cardized generation The distribution board can be selectively inserted into the distribution box installed in the open rack of the equipment room so that the delay expansion is increased according to the increase of subscribers, and the generation distribution board can be used alone during the inspection, expansion, test, and cluster work of the optical fiber. The best technical problem is to make it easy to carry out the separation.

The configuration of the preferred embodiment for effectively achieving the object of the present invention will be described.

According to the present invention, the optical cable 106 supplied for each generation is mounted on each generation distribution board 100 so as to facilitate the management of the optical fiber according to each generation, and the generation distribution board 100 is open. The dominant feature of the present invention is to be detachably installed in the distribution box 200 installed in the rack (9) to provide convenience for the delay extension operation and the maintenance and management of the optical fiber according to the increase of subscribers.

The overall configuration of the present invention to achieve the above-mentioned characteristic gist is an optical jumper cord 108 connected to a plurality of optical adapters 107 connected to the subscriber generation and externally drawn as shown in FIGS. Generation distribution board 100 having a star end portion 109 to which the optical cable 106 is connected, and a distribution enclosure fixed to the open rack 9 so that the generation distribution board 100 is stacked and inserted in multiple stages. (200) and the generation distribution board fixing means (300) for fixing the generation distribution board (100) to allow selective separation inside the distribution enclosure (200).

Hereinafter, the present invention having the schematic configuration will be described in more detail.

Generation distribution board 100, which is a key technical component of the present invention, is a carded independent entity supplied for each subscriber generation, which is formed in a rectangular plate shape as a whole, and is bent upwards at four edges, respectively. The rear portion 101 (102) and both side portions 103 are integrally formed to form an inner space 104 capable of drawing in and out of the optical cable 106 therein.

Therefore, through the cable entry path 105 formed on one side of the rear portion 102, the optical cable 106 for each generation can be introduced into the internal space 104 from the outside, the optical cable 106 is usually 2 to 4 lines of optical fiber An optical cable may be applied, and the optical cable 106 and the other front part 101 corresponding to the optical cable 106 are installed in parallel with a plurality of optical adapters 107 connected to the subscriber generation.

In this case, the optical cable 106 may be connected to the respective optical jumper cords 108 connected to the optical adapter 107 at the end portion 109 formed in the center of the internal space 104, the optical jumper cord 108 And the optical cable 106 is maintained in a neat and tidy state without being tangled by the guide member 110 attached to the inner bottom surface.

In addition, the optical cable 106 is not limited to the method of connecting the optical cable 106 by the optical jumper cord 108 at the end portion 109, and the optical cable 106 is mechanically connected to the optical adapter 107 by a field assembly optical connector. You can connect directly. In this case, a separate star portion 109 and the optical jumper cord 108 are unnecessary, thereby reducing the manufacturing cost.

The distribution box 200 into which the generation distribution board 100 is selectively detachably installed is fixedly installed in the open rack 9 installed in the equipment room.

To this end, fixed front ends 201 are installed at both front ends to fasten the distribution enclosure 200 to the open rack 9 using fasteners 303, and are spaced equally between the fixed ends 201. A plurality of board fixing plates 202 are installed to fix the plurality of generation distribution boards 100 without flow, and the generation boards 100 are stacked in multiple stages at the back of the board fixing plate 202. A plurality of inserts 203 are formed that can be inserted.

The insertion part 203 may be partitioned into the same area by the diaphragm 204 as a plurality of diaphragms 204 are installed at equal intervals while the rear and upper sides of the distribution enclosure 200 are opened.

In addition, the fixed end portion 201 has a plurality of long grooves 205 are formed at equal intervals up and down so that the distribution enclosure 200 is fixed to the open rack 9 by the fastener 303 to the outside. On the other side of the long groove 205, a plurality of through holes 206 for fixing the generation distribution board 100 are formed at equal intervals up and down.

In addition, the board fixing plate 202 located between the fixed end portions 201 has a plurality of through holes 206 for fixing the generation distribution board 100 on both sides, formed at equal intervals up and down.

Therefore, in the present invention, the carded generation distribution board 100 can be stacked in multiple stages in the distribution enclosure 200 without even a small gap, as shown in FIG. It is possible to drastically reduce the cost of production.

That is, the light distribution panel can be more compactly configured even in managing the same generation number as the conventional light distribution panel.

Meanwhile, the generation distribution board fixing means 300 for detachably fixing the generation distribution board 100 in the inserted state in the inserting portion 203 is shown in FIGS. 7 to 8 of the generation distribution board 100. A fastening plate 302 having fastening holes 301 formed in front of both side portions 103 is integrally attached, while a fastener 303 opens the through hole 206 of the fixed end 201 and the board fixing plate 202. It is made of a configuration that is screwed through the fastening hole 301.

Therefore, the generation distribution board 100 is firmly fixed to the distribution enclosure 200 according to the selective fastening and dismantling of the fastener 303, or is separated by a single optical fiber is damaged by a single generation of the corresponding generation of By separating the generation board alone 100 can be maintained, repaired without damaging the fiber of the other generation can reduce the management cost.

After the fastening of the generation distribution board 100 by the fastener 303 is completed, the front of the fixed end portion 201 and the board fixing plate 202 through which the fastener 303 passes, as shown in FIG. 3. A name plate 304 in which each generation lake is marked may be attached to facilitate identification and identification of the distribution board 100.

The present invention made of such a configuration is very compact when fixed installation in the open rack (9) as shown in Figure 3 to reduce the occupied area to attract more generations of subscribers, as well as the corresponding generation during the expansion of the new generation It is possible to separate the generation distribution board 100 to perform the cluster work alone to secure a wide working space according to the cluster work, there is no inconvenience in the work.

Furthermore, since the space in which each generation distribution board 100 is installed is sequentially allocated to the distribution enclosure 200, the subscriber increased in the space corresponding to each generation specified in the nameplate 304 even if the subscriber increases unspecified. It is possible to provide a convenience that can be installed preferentially the generation distribution board 100.

In other words, the expansion of subscriber generation can be performed preferentially in the state of delaying the expansion of non-subscriber households located in the middle of the expansion work according to the increase of subscribers.

On the other hand, the present invention can be installed in a horizontal state of the generation distribution board 100 installed in the open rack (9), as well as insert the generation distribution board 100 in the vertical distribution box 200 as shown in Figure 9 You can also

The distribution box 200 for this configuration is provided with a fixed end portion 201 for fixing the distribution enclosure 200 to the open rack (9) on both front ends as shown in Figure 9, between the fixed end portion 201 There are a plurality of board fixing plate 202 is installed in the vertical distribution board 100 is fixed vertically at equal intervals, a plurality of inserting portion is installed in the rear of the board fixing plate 202 is installed generation board 100 203 is partitioned to the left and right through the diaphragm 204 in the state in which the rear surface is opened, so that the generation distribution board 100 can be inserted and installed in a vertical state.

According to the present invention, since the optical fiber distributed for each generation is mounted in an independent generation distribution board, it is possible to easily grasp when one generation of optical fiber is damaged, as well as separate generation distribution boards of the corresponding generations separately from other generations. It can be repaired and repaired without damaging the optical fiber of the fiber, which provides convenience for maintenance and management while reducing the cost dramatically.

In addition, the delayed expansion work according to the increase of subscriber generation is very flexible, and the work space is very easy to secure a larger working space during the clustering work according to the expansion and test work, and there is no fear of damaging other generation optical fibers.

In addition, even though the same number of households are managed, the overall size of the optical distribution board is slimmer than the existing one, and thus, the cost of manufacturing is drastically reduced, thereby improving productivity, economy and competitiveness.

Claims (9)

A generation distribution board 100 having a plurality of optical adapters 107 connected to subscriber generations on the other side of the optical cable 106 introduced from the outside, and the optical cables 106 selectively connected to the optical adapters 107; A distribution enclosure 200 fixedly installed in the open rack 9 so that the generation distribution board 100 is stacked in multiple stages and inserted in a plurality of rows; Optical distribution board for ultra-high speed information and communication building, characterized in that the generation distribution board 100 is inserted into the inserting portion 203 in a state that is detachably fixed to the board fixing plate (202) . The method of claim 1, Optical cable 106 is an optical fiber for the high-speed information and communication building, characterized in that connected using the optical jumper cord 108 connected to a plurality of optical adapters 107 in the cluster 109 formed in the generation distribution board 100 betrayal. The method of claim 1, Optical cable 106 is an optical distribution panel for ultra-high-speed information and communication buildings, characterized in that directly connected to a plurality of optical adapters 107 by the field assembly optical connector inside the generation distribution board (100). The method according to any one of claims 1 to 3, Optical cable 106 is introduced into the independent generation distribution board 100 is an optical distribution panel for ultra-high speed information and communication building, characterized in that composed of 2 to 4 lines of optical fiber for each generation. The method according to any one of claims 1 to 3, The distribution enclosure 200 has fixed end portions 201 for fixing the distribution enclosure 200 to the open rack 9 at both ends of the front, and the generation distribution board 100 at equal intervals between the fixed end portions 201. A plurality of board fixing plate 202 is installed horizontally fixed, the rear of the board fixing plate 202 is a plurality of inserting portion 203 is inserted into the generation distribution board 100 is installed in the rear open state The optical distribution panel for ultra-high-speed information and communication buildings, characterized in that partitioned up and down via the partition plate (204). The method according to any one of claims 1 to 3, The distribution enclosure 200 has fixed end portions 201 for fixing the distribution enclosure 200 to the open rack 9 at both ends of the front, and the generation distribution board 100 at equal intervals between the fixed end portions 201. A plurality of board fixing plate 202 is installed is fixed vertically, the rear of the board fixing plate 202 a plurality of inserting portion 203 is inserted into the generation distribution board 100 is installed in the rear The optical distribution panel for ultra-high-speed information and communication buildings, characterized in that partitioned to the left and right through the diaphragm (204). The method of claim 5, On the inside of the fixed end 201 and both sides of the board fixing plate 202, a plurality of through-holes 206 for fixing the generation distribution board 100, characterized in that formed in the high-speed information communication building, characterized in that the upper and lower intervals betrayal. The method according to any one of claims 1 to 3, Generation distribution board fixing means 300 fastening plate 303 through the fixing end 201 and the through hole 206 of the board fixing plate 202 fastening plate installed on both side portions 103 of the generation distribution board 100 The optical distribution panel for ultra-high-speed information and communication building, characterized in that the screw is detachably coupled to the (302) to secure the generation distribution board 100. The method of claim 8, The front end of the fixing end 201 and the board fixing plate 202 through which the fastener 303 penetrates is characterized in that the name plate 304 marked with the lake of each generation is attached to facilitate the identification and identification of the generation distribution board 100. Optical distribution board for high-speed information and communication building.

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