KR102525785B1 - Optical Distribution Box - Google Patents

Abstract

The present invention relates to an optical distribution system in which optical fibers of an incoming optical cable are branched and drawn out into an outgoing optical cable, which minimizes the overall volume, provides improved watertightness, and improves workability.

Description

Optical Distribution Box {Optical Distribution Box}

The present invention relates to an optical distribution box. More particularly, the present invention relates to an optical distribution system in which an optical fiber of an incoming optical cable is branched and drawn out to an outgoing optical cable, minimizing the overall volume, providing an improved watertight function, and improving workability.

Recently, the spread of optical communication is expanding and the amount of communication by optical communication is rapidly increasing. In many cases, an optical communication network is provided from a backbone network to an end user to improve communication speed.

For example, in recent years, FTTH (FTTH), which installs optical cables to each house for the purpose of providing high-quality, high-speed service, breaking away from the conventional system in which optical cables come only to the management building of an apartment complex and use general telephone lines from the management building to each home. Fiber to the home) network construction is expanding. In addition, in order to build such an FTTH network, an optical distribution box is used to distribute multi-core optical cables to each consumer.

In general, an optical distribution box performs a connection and distribution function between an external optical fiber and a subscriber transmission device, and an optical fiber and an optical fiber of an optical cable in which some of the internal optical fibers of an optical fiber drawn into the optical distribution box are connected to subscribers in a short distance. It is connected to establish an optical network up to the transmission device of the subscriber. In this case, the rest of the optical fibers of the optical line can be drawn out again in the form of optical cables and distributed to transmission devices of other subscribers.

As the number of optical fibers accommodated in one multi-core optical cable increases due to the increase in demand for optical communication and the improvement of optical cable manufacturing technology, the number of optical cables diverging from one optical distribution box increases, so the volume of the optical distribution box providing branch space also increases. However, since the number of optical distribution boxes also increases, a method of reducing the volume or size of individual optical distribution boxes is required, and a method of preventing deterioration in workability that may occur as the size of optical distribution boxes is reduced is also required. In addition, these light distribution boxes often require a waterproof function due to the nature of the space where they are installed, such as outdoors or inside a manhole.

An object of the present invention is to provide an optical distribution box that minimizes the overall volume, provides an improved watertight function, and improves workability in an optical distribution box in which optical fibers of an incoming optical cable are branched and drawn out into an outgoing optical cable.

In order to solve the above problems, the present invention is a rear housing formed with an inlet through which the incoming optical cable is drawn into the inside and an outgoing port through which the optical fiber of the incoming optical cable is branched and connected to the outside. a front housing rotatably connected to the rear housing and providing a space for optical connection and branching of the incoming optical cable and the outgoing optical cable between the front housing and the rear housing; a locking part fixed toward the rear housing so that the front housing is not opened; an inner housing detachably connected to the bottom of the rear housing to fix the incoming optical cable and the outgoing optical cable, and providing a space for cross-dressing of the incoming and outgoing optical cables; an optical connection tray rotatably connected to the inner housing to connect the optical fibers of the incoming optical cable and the outgoing optical cable to each other, provided with at least one optical tray, and capable of being stacked when a plurality of optical fibers are provided; and a sealing member formed of an elastic material provided along edges of the front housing and the rear housing to seal between the front housing and the rear housing.

In addition, the optical connection tray may include a connector arrangement unit having a slot to which the optical fiber is connected, and at least one protective sleeve provided to support the optical fiber connected inside the slot.

In this case, the protective sleeve may be one of a regular sleeve having an outer diameter of 3.0 mm to 3.5 mm and a length of 40 mm to 70 mm or a micro sleeve having an outer diameter of 1.2 mm to 1.8 mm and a length of 10 mm to 40 mm.

Further, when the width of the slot is a size capable of accommodating the general sleeves in one row and there are 'n' slots in the optical connection tray, up to '2n' optical fibers when the general sleeve is applied to one optical connection tray. can be connected.

Here, when 'k' optical connection trays are stacked and provided, when the general sleeve is applied, up to '2nk' optical fibers can be connected.

In this case, when the width of the slot is such that the micro sleeve can be accommodated in two rows and the number of slots is 'n' in the optical connection tray, when the micro sleeve is applied to one optical connection tray, one optical connection tray At maximum '4n' number of optical fibers can be connected.

In addition, when 'k' optical connection trays are stacked and provided, when the micro-sleeve is applied, up to '4nk' optical fibers can be connected.

In addition, when the number 'k' of the optical connection trays is 2 and the number n of the slots is 12, the volume of the optical distribution box to which up to 48 or 96 optical fibers are connected may satisfy 2L or less.

In this case, when the number 'k' of the optical connection trays is 2, the number n of the slots is 24, and the width of the slots is a size capable of accommodating the micro sleeves in one row, up to 96 optical fibers are connected. The volume of the optical distribution box may satisfy 2L or less.

Also, the inlet and the outlet may be formed on surfaces of the rear housing facing each other.

Here, an insertion groove into which a sealing member made of the elastic material is inserted may be formed along an edge of the rear housing.

In this case, an inner wall spaced apart from the outer wall of the rear housing by a predetermined distance may be further provided, and the insertion groove may be formed between the inner wall and the outer wall.

In addition, the inlet and outlet may be formed on the outer wall and the inner wall, respectively.

In addition, a fixing bracket may be further provided on an outer bottom of the rear housing.

In this case, the sealing member made of the elastic material may have an inlet groove through which the incoming optical cable is introduced and an outgoing groove through which the outgoing optical cable is drawn out.

Further, the sealing member made of the elastic material may be formed on both surfaces of the inlet and outlet grooves facing each other.

Here, a sealing member disposed in place of the outgoing optical cable may be further provided in the outgoing groove where the outgoing optical cable is not disposed.

In this case, a pressing unit for pressing the sealing member made of the elastic material may be further provided along an edge of the front housing.

In addition, the pressure unit presses both sides of the inlet groove to seal the inlet groove by deformation of the sealing member made of the elastic material, and presses both sides of the withdrawal groove to form the elastic material. It may be provided with a pull-out pressing portion for sealing the draw-out groove by deformation of the sealing member.

In addition, when the sealing member made of the elastic material is pressed by the lead-in pressurizer to the front housing, a lead-in cable movement prevention unit for preventing movement of the lead-in optical cable disposed in the lead-in groove, and the pull-out and pressurizer. When the sealing member made of the elastic material is pressed by the unit, a movement preventing unit for the outgoing cable to prevent movement of the outgoing optical cable disposed in the outgoing groove may be further provided.

Here, a protective cover provided between the optical connection tray and the inner housing to protect the optical cable overlaid in the inner housing may be further included.

In this case, the inner housing, the protective cover, and the optical connection tray may be stacked in the forward and backward directions.

In addition, it is disposed along the edges of the front housing and the rear housing, and the sealing member may be integrally configured in a square ring shape.

According to the optical distribution box according to the present invention, the total volume is remarkably reduced, and the installation area and volume are reduced, so that the operator can easily work, reduce work time, and improve work efficiency.

In addition, according to the present invention, by providing a watertight function by completely sealing the inner space of the optical distribution box, it is possible to prevent damage or breakage of optical fibers and optical cables inside the optical distribution box.

1 is a perspective view of an optical distribution box according to an embodiment of the present invention.
2 is an exploded perspective view of the optical distribution box.
3 is a perspective view illustrating a rear housing of the optical distribution box.
4 is a perspective view of a sealing member made of an elastic material.
5 is a perspective view illustrating a front housing of the optical distribution box.
6 is a perspective view illustrating a locking part;
FIG. 7 is a perspective view illustrating a state in which the front housing is omitted from the optical distribution box of FIG. 1 .
8 is a perspective view of an optical connection tray provided inside the optical distribution box.
9 is a perspective view of an inner housing provided inside the optical distribution box.
10 and 11 are diagrams showing the deformation of the sealing member made of the elastic material when the front housing is rotated and closed.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, the present invention is not limited to the embodiments described herein and may be embodied in other forms. Rather, the embodiments introduced herein are provided so that the disclosed content will be thorough and complete, and the spirit of the present invention will be sufficiently conveyed to those skilled in the art. Like reference numbers indicate like elements throughout the specification.

1 is a perspective view of an optical distribution box 1000 according to an embodiment of the present invention, and FIG. 2 is an exploded perspective view of the optical distribution box 1000.

Referring to FIGS. 1 and 2, the optical distribution box 1000 has inlet ports 512 and 532 through which incoming optical cables are drawn into the interior, and outlet ports 514 through which the optical cables branched and connected thereto are drawn out. , 534) is formed, is rotatably connected to the rear housing 500, and provides a space for optical connection and branching of the incoming optical cable and the outgoing optical cable between the rear housing 500 and the rear housing 500. A front housing 100 that is detachably connected to the bottom of the front housing 100, locking parts 600 and 700 that are fixed toward the rear housing 500 so that the front housing 100 is not opened, and the rear housing 500. The fixing parts 310 and 320 for fixing the incoming optical cable and the outgoing optical cable, the inner housing 300 providing a space for overdressing the incoming optical cable and the outgoing optical cable, and rotatably connected to the inner housing 300, Optical fibers of the incoming optical cable and outgoing optical cable are connected to each other, and at least one or more are provided, and when a plurality of optical fibers are provided, an optical connection tray 200 that can be stacked and edges of the front housing 100 and the rear housing 500 are provided. A sealing member 400 made of an elastic material for sealing between the front housing 100 and the rear housing 500 may be provided.

The sealing member 400 is disposed along the edges of the front housing 100 and the rear housing 500 and integrally formed in a square ring shape to improve airtightness between the front housing 100 and the rear housing 500. can

3 is a perspective view showing the rear housing 500 of the light distribution box 1000. Figure 3 (A) is a perspective view viewed from the top, Figure 3 (B) is a perspective view viewed from the bottom.

Referring to FIG. 3 , the rear housing 500 is illustrated as having a hexahedron shape with an open top, but is not limited thereto, and may provide a suitable space for optical connection and branching of an incoming optical cable and an outgoing optical cable. can be transformed into shapes.

The rear housing 500 may be made of a material having appropriate strength to protect the inner optical cable and maintain watertightness with the front housing 100 . For example, the rear housing 500 and the front housing 100 may be made of synthetic resin, but are not limited thereto and may be appropriately modified.

The rear housing 500 includes an inlet 512 through which an external optical cable, that is, an incoming optical cable (10, see FIGS. 4 and 10) introduced into the rear housing 500 passes through, and the rear housing ( 500) may be provided with an outlet 514 through which the outgoing optical cable (12, see FIGS. 4 and 10) is drawn out.

The incoming optical cable 10 is introduced through the inlet 512, the optical fiber is branched inside the optical distribution box 1000 and connected to the outgoing optical cable, and the outgoing optical cable passes through the outlet 514 to distribute the light. It is drawn out to the outside of the box 1000.

In this case, the inlet 512 and the outlet 514 may be composed of at least one or more, for example, a plurality as shown in the drawing.

At this time, the inlet 512 and the outlet 514 may be provided on surfaces of the rear housing 500 facing each other. Therefore, the incoming optical cable drawn into the rear housing 500 may be connected to the outgoing optical cable of the outlet 514 on the same side or the outgoing optical cable of the outlet 514 on the opposite side.

Meanwhile, the diameter of the incoming optical cable passing through the inlet 512 is relatively larger than the diameter of the outgoing optical cable passing through the outlet 514 . Therefore, when the inlet 512 and the outlet 514 are disposed, a pair of inlets 512 may be provided, and a plurality of outlets 514 may be disposed between the pair of inlets 512 .

Although the number of outlets 514 is shown as six in this embodiment, this is merely an example, and may be appropriately modified according to the number of optical fibers included in the incoming optical cable, the installation location of the optical distribution box, and the like.

Meanwhile, the aforementioned front housing 100 may be rotatably connected to the rear housing 500 . By rotating and opening the front housing 100, the inside of the light distribution box 1000 can be opened, and by rotating and closing the front housing 100, the inside of the light distribution box 1000 can be sealed. there is.

In this case, the rear housing 500 may include a rotation part 560 for rotation of the front housing 100 .

Specifically, one side of the rear housing 500 may include a pivoting shaft 564 to which the front housing 100 is rotatably connected and a support 562 supporting the pivoting shaft 564 .

Two or more supporters 562 are provided so that the front housing 100 can rotate stably.

In addition, a plurality of locking protrusions 570 are formed in the rear housing 500, which are connected to the above-described locking parts 600 and 700 to close the front housing 100 and the rear housing 500 to distribute the light. It serves to seal (1000). This will be reviewed together when the locking parts 600 and 700 are described.

Meanwhile, a bracket connection part 511 to which the fixing brackets 800A and 800B are detachably connected may be provided on the outer bottom of the rear housing 500 .

The bracket connection part 511 may be composed of a plurality, and as shown in the drawing, it may be provided in four corner regions of the outer bottom of the rear housing 500.

The fixing bracket 800 is connected through the bracket connection part 511, and the optical distribution box 1000 can be fixed to a desired position or place through the fixing bracket 800.

On the other hand, as described above, between the front housing 100 and the rear housing 500 is composed of an elastic material that seals and seals the inner space of the light distribution box 1000 when the front housing 100 is closed. A sealing member 400 may be provided.

In this case, at least one of the rear housing 500 and the front housing 100 may be provided with an insertion groove 550 into which the sealing member 400 made of the elastic material is inserted.

In this embodiment, the sealing member 400 made of the elastic material is inserted into the rear housing 500 and provided, but is not limited thereto and may be provided to the front housing 100.

At this time, an insertion groove 550 into which the sealing member 400 made of the elastic material is inserted may be provided along an edge of the rear housing 500 .

The insertion groove 550 may be provided along the entire edge of the rear housing 500 . That is, when the sealing member 400 made of the elastic material is inserted into the insertion groove 550, it is disposed along the entire edge of the rear housing 500, and when the front housing 100 is closed, the light The inside of the distribution box 1000 is firmly sealed and watertight.

The insertion groove 550 may be configured in various forms. In the case of the present embodiment, it further includes an inner wall 530 spaced apart from the outer wall 510 of the rear housing 500 at a predetermined distance, , The insertion groove 550 is formed in the space between the outer wall 510 and the inner wall 530.

That is, an inner wall 530 spaced apart by a predetermined distance may be formed inside the outer wall 510 of the rear housing 500. In this case, the space between the inner wall 530 and the outer wall 510 The insertion groove 550 is formed.

In this case, the distance between the outer wall 510 and the inner wall 530 may be determined in advance, corresponding to the thickness of the sealing member 400 made of the elastic material inserted into the insertion groove 550, or the It may be smaller than the thickness of the sealing member 400 made of an elastic material. This is because when the sealing member 400 made of the elastic material is inserted into the insertion groove 550, the watertight effect can be improved by inserting and fixing the sealing member 400 in an interference fit method.

When the rear housing 500 has the outer wall 510 and the inner wall 530 as described above, the inlet 512 and the outlet 514 are provided on both the outer wall 510 and the inner wall 530. may be provided.

That is, the outer inlet 512 formed on the outer wall 510 is disposed parallel to the inner inlet 532 formed on the inner wall 530, and the outer outlet 514 formed on the outer wall 510. may be disposed in parallel with the inner outlet 534 formed on the inner wall 530.

In this case, the outer inlet 512 is formed by the first outer protrusion 522, and the outer outlet 514 is also formed by the second outer protrusion 524 formed on both sides. Also, in this case, the inner inlet 532 is formed by the first inner protrusion 542, and the inner outlet 534 is also formed by the second inner protrusion 544 formed on both sides.

4 is a perspective view showing the sealing member 400 made of an elastic material inserted into the insertion groove 550 of the rear housing 500. Figure 4 (A) is an upper perspective view of the sealing member 400 made of the elastic material, Figure 4 (B) is a side view of the sealing member 400 made of the elastic material viewed from the side.

Referring to FIG. 4 , the sealing member 400 made of the elastic material may have a shape corresponding to the edge shape of the rear housing 500 . That is, when the rear housing 500 has a rectangular parallelepiped shape, the sealing member 400 made of the elastic material may have a rectangular shape correspondingly as shown in the drawings.

The sealing member 400 made of the elastic material may be made of a material having a predetermined elastic force, deformed when force is applied, and restored to its original state when the force is removed. For example, the sealing member 400 made of the elastic material may be made of rubber or synthetic resin, but the specific material is not limited and may be appropriately deformed.

Meanwhile, the sealing member 400 made of the elastic material may include inlet grooves 410A and 410B through which the incoming optical cable is introduced, and an outgoing groove 420 through which the outgoing optical cable is drawn out.

The inlet grooves 410A and 410B and the outlet groove 420 may be provided in a form cut from an upper surface of the sealing member 400 made of the elastic material toward a lower portion.

In this case, the lead-in grooves 410A and 410B are divided by the lead-out groove 420 and the first wall 440, and the plurality of lead-out grooves 420 are each separated by the second wall 430 located therebetween. Separated.

On the other hand, since the diameter of the incoming optical cable 10 is relatively larger than the diameter of the outgoing optical cable 12, the lower part of the sealing member 400 made of the elastic material in which the inlet grooves 410A and 410B are formed Curved protrusions 412A and 412B may be provided.

In addition, when the inlet grooves 410A 410B and the outlet groove 420 are disposed, a pair of the inlet grooves 410A and 410B are provided, and a plurality of outlet grooves ( 420) can be placed.

In this case, the inlet grooves 410A and 410B communicate with the inlets 512 and 532 of the rear housing 500, and the outlet groove 420 communicates with the outlets 514 and 534 of the rear housing 500. communicate with each other

Specifically, when the sealing member 400 made of the elastic material is inserted into the insertion groove 550 between the outer wall 510 and the inner wall 530 of the rear housing 500, the inlet groove 410A 410B ) communicates with both the outer inlet 512 formed on the outer wall 510 and the inner inlet 532 formed on the inner wall 530. Similarly, the drawing groove 420 is in communication with both the outer outlet 514 formed on the outer wall 510 and the inner outlet 534 formed on the inner wall 530 .

Therefore, the incoming optical cable 10 is provided through the outer inlet 512 of the rear housing 500, the inlet grooves 410A and 410B of the sealing member 400 made of the elastic material, and the rear housing 500. It is introduced into the light distribution box 1000 through the inner inlet 532 .

In addition, the outgoing optical cable 12 is connected to the inner outlet 514 of the rear housing 500, the outlet groove 420 of the sealing member 400 made of the elastic material, and the outer side of the rear housing 500. It is drawn out to the outside of the light distribution box 1000 through the lead-out port 534.

Meanwhile, the sealing member 400 made of the elastic material may be provided on both surfaces where the inlet grooves 410A and 410B and the outlet grooves 420 face each other. Therefore, the incoming optical cable drawn inside the sealing member 400 made of the elastic material is connected to the outgoing optical cable of the outlet 514 on the same side or the outgoing optical cable of the outlet 514 on the opposite side. Can be connected.

5 is a perspective view showing the front housing 100 of the optical distribution box 1000. FIG. 5 (A) is an upper perspective view of the front housing 100, and FIG. 5 (B) is a lower perspective view of the front housing 100.

Referring to FIG. 5, the front housing 100 is rotatably connected to the rear housing 500, and a space between the rear housing 500 and the optical connection and branching of the incoming optical cable and the outgoing optical cable will provide

The front housing 100 may have a shape corresponding to the aforementioned rear housing 500 . That is, when the rear housing 500 has a rectangular shape, the front housing 100 may also have a correspondingly rectangular shape.

Meanwhile, the front housing 100 may be made of a material having appropriate strength to seal or watertight the inner space of the optical distribution box 1000 . For example, the front housing 100 may be made of synthetic resin, but is not limited thereto and may be appropriately modified.

A hinge part 110 rotatably connected to the rotation shaft 564 of the rear housing 500 may be provided on one side of the front housing 100. The hinge unit 110 is connected to the rotation shaft 564. ) so that the front housing 100 can rotate with respect to the rear housing 500.

Meanwhile, the front housing 100 may be provided with mounting portions 120A and 120B on which the aforementioned locking portions 600 and 700 are seated. That is, in a state where the locking parts 600 and 700 are seated on the seating parts 120A and 120B, they are firmly connected to the rear housing 500 and apply force to the front housing 100 and the rear housing 500. ) in close contact with each other to provide watertight performance.

In this way, when the front housing 100 receives force toward the rear housing 500 by the locking parts 600 and 700, the front housing 100 has a sealing member 400 made of the aforementioned elastic material. ) may be provided. The sealing member 400 made of the elastic material is pressurized and deformed by the pressing part 130, thereby forming the sealing member 400 made of the elastic material. It is possible to seal the inlet groove (410A 410B) and the outlet groove (420) of the.

For example, the pressing part 130 may be formed along the edge of the front housing 100, and may protrude downward along the edge, that is, toward the rear housing 500 by a predetermined length. there is.

At this time, the pressing part 130 presses both sides of the inlet groove of the sealing member 400 made of the elastic material, and the inlet groove 410A 410B is deformed by the sealing member 400 made of the elastic material. ) and the inlet pressing parts 134A and 134B that seal the drawing groove 420, and the drawing groove 420 is sealed by the deformation of the sealing member 400 composed of the elastic material by pressing both sides of the drawing groove 420. A pressing unit 132 may be provided.

In addition, when the above-described inlet pressing parts 134A and 134B and the withdrawal pressing part 132 are formed on surfaces facing each other, additional pressing parts 136 and 138 connecting them to each other may be provided.

Furthermore, when the sealing member 400 made of the elastic material is pressed by the inlet pressing parts 134A and 134B, the incoming optical cables disposed in the inlet grooves 410A and 410B can be pushed and moved upward. there is. In order to prevent this, the front housing 100 may further include lead-in cable movement prevention units 144 and 146 for preventing movement of the lead-in optical cable 10 disposed in the lead-in grooves 410A and 410B.

Similarly, when the sealing member 400 made of the elastic material is pressed by the drawing-out pressing unit 132, the drawing-out optical cable disposed in the drawing-out groove 420 may be pushed and moved upward. To prevent this, the front housing 100 may further include an outgoing cable movement prevention unit 142 that prevents movement of the outgoing optical cable 12 disposed in the outgoing groove 420 .

10 and 11 show the deformation of the sealing member 400 made of the elastic material by the pressing part 130 when the front housing 100 having the above configuration is rotated and closed. 10 and 11 show only the front housing 100 and the sealing member 400 made of an elastic material for convenience of illustration.

As shown in FIG. 10, when the front housing 100 is in an open state, both the inlet grooves 412A and 412B and the outlet groove 420 of the sealing member 400 made of the elastic material correspond to an open state. . That is, upper portions of the inlet grooves 412A and 412B and the outlet groove 420 are all open.

At this time, the incoming optical cable 10 is disposed in the inlet grooves 412A and 412B, and the outgoing optical cable 12 is disposed in the outgoing groove 420.

On the other hand, since the number of outgoing optical cables 12 drawn out through the outgoing grooves 420 may vary depending on the number of consumers requiring optical communication, some of the outgoing optical cables 12 are disposed in the outgoing grooves 420. It may not be. In this case, if the corresponding lead-out groove 420 is left without the lead-out optical cable 12, the watertight effect is reduced even when the sealing member 400 made of the elastic material is pressed by the front housing 100. .

Therefore, in the case of the outgoing groove 420 where the outgoing optical cable 12 is not disposed, the sealing member 14 may be disposed instead of the outgoing optical cable 12 . The sealing member 14 may be made of synthetic resin or the like and may have a diameter corresponding to that of the outgoing optical cable 12 .

In this state, when the front housing 100 is rotated and closed, the state shown in FIG. 11 is obtained. Referring to FIG. 11 , a state in which the sealing member 400 made of the elastic material is deformed by the pressing part 130 of the front housing 100 in a closed state of the front housing 100 is shown.

That is, the lead-in pressing parts 134A and 134B press and deform the first walls 440 on both sides of the lead-in grooves 410A and 410B, thereby removing the lead-in optical cable 10 disposed in the lead-in grooves 410A and 410B. Except for the remaining areas, all areas are sealed and watertight.

In addition, the drawing out pressing part 132 similarly presses and deforms the second walls 430 on both sides of the drawing groove 420 so that the drawing optical cable 12 disposed in the drawing groove 420 or the sealing member ( Except for 14), all other areas are sealed and watertight.

In this way, sealing and watertight effects can be improved by pressing the sealing member 400 made of the elastic material by the front housing 100, and in particular, the sealing member 400 made of the elastic material It is arranged to seal the entire edge between the 100 and the rear housing 500 to further improve the watertight effect.

Meanwhile, FIG. 6 shows a locking part 600 for applying force so that the front housing 100 and the rear housing 500 come into close contact with each other when the front housing 100 rotates toward the rear housing 500 and is closed. 700) is a perspective view showing.

Referring to FIG. 6 , a pair of locking parts 600 and 700 is provided to apply force from both sides of the front housing 100 and the rear housing 500 to separate the front housing 100 and the rear housing 500. It can be sealed and kept locked.

In this case, the locking parts 600 and 700 may include body parts 610 and 710 extending a predetermined length and pivoting bars 620 and 720 rotatably connected to the body parts 610 and 710 .

The body parts 610 and 710 may be seated on the mounting parts 120A and 120B of the front housing 100 described above. In a state in which the body parts 610 and 710 are seated on the seating parts 120A and 120B, the rotation bars 620 and 720 are rotated and fastened to the locking jaws 570 of the rear housing 500 so that the front The housing 100 may be brought into close contact with the rear housing 500 to maintain a locked state.

Since the front housing 100 is brought into close contact with the rear housing 500 by the locking parts 600 and 700, the sealing member made of the elastic material by the pressing part 130 of the front housing 100 ( 400) can be pressed more strongly, and the watertight effect can be improved by the sealing member 400 made of the elastic material.

Meanwhile, FIG. 7 is a perspective view showing the internal structure of the optical distribution box 1000 according to the present invention in which the front housing 100 is omitted.

Referring to FIG. 7 , an inner housing 300 and an optical connection tray 200 are sequentially disposed from the rear side of the rear housing 500 toward the front side of the optical distribution box 1000 .

That is, the inner housing 300, the protective cover 900, and the optical connection tray 200 may be stacked in the front and rear directions inside the front housing 100 and the rear housing 500.

In this way, when the inner housing 300 and the optical connection tray 200 are stacked in the forward and backward directions inside the optical distribution box 1000, the inside of the optical distribution box 1000 is compact. Therefore, the overall volume of the light distribution box 1000 can be reduced as much as possible.

For example, the optical distribution box according to the present embodiment may have a volume of approximately 2L or less, and in this case, it is possible to connect up to 48 optical fibers. In this way, if the volume of the optical distribution box is reduced as much as possible in the case of connecting a large number of optical fibers, the installation volume can be greatly reduced when the optical distribution box is installed in a place such as outdoors, and thus work performance is improved. Can increase work efficiency.

FIG. 8 is a perspective view illustrating the optical connection tray 200 in FIG. 7 described above.

Referring to FIG. 8 , the optical connection tray 200 is rotatably connected to the inner housing 300 to connect optical fibers of the incoming optical cable and outgoing optical cable to each other, and two or more of them may be stacked.

The optical connection tray 200 has a hinge part 250 on one side thereof, so that the lowermost optical connection tray 200 can be rotatably connected to the inner housing 300 . In addition, optical connection trays 200 may be additionally stacked on top of the lowermost optical connection tray 200, and in this case, the connection trays 200 may be rotatably connected to each other.

On the other hand, the optical connection tray 200 has a protection tube guide groove 212 into which a protection tube (not shown) for protecting the sheathed optical fibers is drawn in or out, and a guide groove 212 for the optical fiber to be drawn in/out to be overlaid. A crossover processing unit 210 and a connector arranging unit 260 for accommodating fusion splicers may be provided. In addition, the optical connection tray 200 may include a plurality of guide parts 220 and 230 for preventing and guiding the overlaid optical fibers from being separated.

In this case, the connector arranging unit 260 may include a slot 262 for connecting an optical fiber.

For example, as shown in FIG. 8, the connector arranging unit 260 includes a first slot array 260A having n first slots 262A and similarly having n second slots 262B. A second slot array 260B may be provided.

At this time, the first slot 262A and the second slot 262B are provided with the same number, and a protective sleeve (not shown) for protecting the optical fiber is provided between the first slot 262A and the second slot 262B. can be placed.

The protective sleeve is configured to be installed in each slot while supporting optically connected optical fibers, and has a pipe-shaped configuration with an opening formed in the center or cut.

The protective sleeve may be one of a regular sleeve having an outer diameter of 3.0 mm to 3.5 mm and a length of 40 mm to 70 mm or a micro sleeve having an outer diameter of 1.2 mm to 1.8 mm and a length of 10 mm to 40 mm.

The micro sleeve may be applied to increase the number of optical fibers connected inside the optical distribution box. The outer diameter of the micro sleeve is approximately 1.2 mm to 1.8 mm, and the length is 10 mm to 40 mm, and it can be seen that the outer diameter and length are about half the size of the protective sleeve.

Also, the width of the slot provided in the optical connection tray to which the protection sleeve is mounted may be large enough to accommodate one column of the general sleeve or two or one column of micro sleeves.

In addition, it is common that protective sleeves or micro sleeves are disposed up to two layers in each slot provided in the connector arrangement unit 260 .

In the case of the present invention, by disposing the protective sleeve between the first slot 262A and the second slot 262B, the number of the first slot 262A and the second slot 262B is greater than the number (n). A number of optical fibers can be connected.

For example, when the general sleeves are stacked in two rows X one column between the first slot 262A and the second slot 262B, that is, in each slot in two layers, one optical connection tray 200 In all, '2n' optical fibers can be connected.

In addition, when a micro sleeve is applied, since the micro sleeve can be arranged in 2 rows X 2 columns in a space where a general sleeve can be arranged in 2 rows X 1 column, maximum '4n' optical fibers can be connected. More specifically, 1 row X 1 column, 1 row X 2 columns, 2 rows X 1 column, or 2 rows X 2 columns or 3 micro sleeves are placed in a 'Δ' shape in the slot for placing a regular sleeve. Thus, the number of accommodated micro sleeves can be increased.

In addition, in the case of applying the micro sleeve, the optical connection tray 200 having slots of a size for applying the general sleeve is replaced with an optical connection tray configured with a small width of the slot for the micro sleeve, and 1 row X is formed in each slot. A method of arranging the micro sleeves in one column or two rows X one column can also be applied.

Therefore, as shown in FIG. 8, when the first slot array 260A and the second slot array 260B have, for example, 12 first slots 262A and 2 second slots 262B ( In the case of n = 12), up to 24 optical fibers can be connected in one optical connection tray 200 when the normal sleeves are stacked in 1 column X 2 rows, and in the case of applying the micro sleeve, as described above Up to 48 optical fibers can be connected together.

Furthermore, when a plurality of optical connection trays 200 are provided and stacked, the number of connected optical fibers may increase corresponding to the number of optical connection trays 200 .

That is, when the optical connection trays 200 are stacked and the number of optical connection trays is 'k', the number of connected optical fibers is a general sleeve between the first slot 262A and the second slot 262B. In the case of applying, it becomes a maximum of '2nk', and in case of applying a micro sleeve, it corresponds to a maximum of '4nk'.

For example, the first slot array 260A and the second slot array 260B include 12 first slots 262A and 12 second slots 262B (when n = 12), and the optical When the connection tray 200 is two (k = 2), up to 48 optical fibers can be connected when a general sleeve is applied, and up to 96 optical fibers can be connected when a micro sleeve is applied. .

In this case, when the number 'k' of the stacked optical connection trays 200 is 2 and the number n of the slots is 12, up to 48 or up to 96 optical fibers can be connected, and one optical distribution Even when the number of optical fibers connected to the box reached 48 or 96, it was confirmed that the volume of the optical distribution box could satisfy 2L or less.

As a result, in the case of the optical distribution box 1000 according to the present invention, the volume of the optical distribution box 1000 is stacked and disposed between the first slot 262A and the second slot 262B to connect the optical fiber with protective sleeves. It is possible to increase the number of connected optical fibers as much as possible while maintaining the minimum volume without increasing the volume.

In addition, when the optical connection tray is configured exclusively for micro-sleeves so that the width of the slots can be applied in one column, the micro-sleeves can be arranged in 1 column X 1 row or 1 column X 2 rows in each slot, , In this case, the number of slots can be secured up to 24 in the same area.

In this case, similarly, when the number 'k' of the optical connection trays is 2, the number n of the slots is 24, and the width of the slots is a size capable of accommodating the micro sleeves in one row, up to 96 optical fibers are connected. However, it was confirmed that the volume of the optical distribution box could satisfy 2L or less.

In summary, a method of stacking and arranging protective sleeves in each slot of the optical connection tray 200 is used, and the number of optical connection trays 200 does not exceed a maximum of four, preferably a maximum of two. Up to 48 cores or 96 cores of optical fiber can be connected, and in this case, the total volume of the optical distribution box is less than 2L, so the installation space of the optical distribution box can be used efficiently despite the increasing demand for optical communication.

Meanwhile, FIG. 9 shows the inner housing 300 detachably connected to the bottom of the rear housing 500 .

Referring to FIG. 9 , the inner housing 300 includes fixing parts 310 and 320 detachably connected to the bottom of the rear housing 500 to fix the incoming optical cable and the outgoing optical cable, and the incoming optical cable and the outgoing optical cable. It is possible to provide a space for cross-dressing of the optical cable.

Specifically, the inner housing 300 may be provided with a fixing reinforcing part 330 that strengthens the tensile force by terminating the inner tension member of the incoming optical cable 10 .

In addition, the fixing parts 310 and 320 may include a retracting fixing part 310 for fixing the incoming optical cable and an outgoing fixing part 320 for fixing the outgoing optical cable 12 .

The inlet fixing part 310 and the withdrawing fixing part 320 may be provided to correspond to the inlet 512 and the outlet 514 of the rear housing 500 described above. That is, in the inner housing 300, both the retracting fixing part 310 and the retracting fixing part 320 may be provided on both surfaces facing each other.

On the other hand, one side of the inner housing 300 may be provided with a hinge connection portion 340 to which the aforementioned optical connection tray 200 is rotatably connected.

That is, the hinge part 250 of the optical connection tray 200 is rotatably connected to the hinge connection part 340 of the inner housing 300, so that the optical connection tray 200 can rotate with respect to the inner housing 300. can rotate.

Since it becomes possible to rotate the optical connection tray 200 with respect to the inner housing 300 , the optical cable overrunning operation can be more easily performed inside the inner housing 300 .

Meanwhile, a fixing part for fixing the optical connection tray 200 may be provided on the opposite side of the hinge connecting part 340 . The fixing part may include a fixing support part 380 and a pair of protrusions 382 .

In this case, the locking chain 270 of the optical connection tray 200 is fixed between the pair of protrusions 382 to prevent rotation of the optical connection tray 200 . When the optical connection tray 200 is to be rotated, the locking chain 270 is separated between the pair of protrusions 382 .

On the other hand, after the overlaid optical cable is disposed in the inner housing 300, there are cases in which the number of consumers requiring optical communication increases or maintenance is required. In this case, maintenance is performed on the optical connection tray 200 located above the inner housing 300 or the optical connection tray 200 is added to perform the work.

In this case, the inner housing 300 may be over-dressed and damage or breakage may occur to an already disposed optical cable. Accordingly, a protective cover 900 may be provided to prevent damage and breakage of the optical cable.

The protective cover 900 is disposed between the optical connection tray 200 and the inner housing 300 to protect an optical cable that is overlaid and disposed on the inner housing 300 or to protect the optical connection tray 200. It can perform a role of being rotatably mounted via a hinge.

The protective cover 900 is provided to cover the upper portion of the inner housing 300 and may be made of synthetic resin or the like. The protective cover 900 may cover all or part of the inner housing 300 .

In this case, the inner housing 300 may be provided with cover connection parts 350 and 360 to which the protective cover 900 is fixedly connected.

For example, a pair of first cover connection parts 350 and a pair of second cover connection parts 360 may be provided.

The pair of first cover connection parts 350 are formed on the bottom of the inner housing 300 to face each other at a predetermined distance apart. At this time, the first cover connection part 350 is formed by bending the first extension part 352 extending upward from the bottom of the inner housing 300 and the upper end of the first extension part 352. A first locking jaw 356 protruding upward from the portion 354 and the first bent portion 354 may be provided.

In addition, the pair of second cover connection parts 360 are formed at the bottom of the inner housing 300 to face each other at a predetermined distance apart. At this time, the second cover connection part 360 is formed by bending the second extension part 362 extending upward from the bottom of the inner housing 300 and the upper end of the second extension part 362. A first locking jaw 366 protruding upward from the portion 364 and the second bent portion 364 may be provided.

Therefore, the protective cover 900 is placed between the first locking protrusions 356 of the pair of first cover connection parts 350 and between the second locking protrusions 366 of the pair of second cover connection parts 360. The protective cover 900 can be disposed by being inserted into the .

Although this specification has been described with reference to preferred embodiments of the present invention, those skilled in the art can variously modify and change the present invention within the scope not departing from the spirit and scope of the present invention described in the claims described below. will be able to carry out Therefore, if the modified implementation basically includes the elements of the claims of the present invention, all of them should be considered to be included in the technical scope of the present invention.

100: front housing
200: optical connection tray
300: inner housing
400: sealing member
500: rear housing
600: locking part
800: fixed bracket
900: protective cover

Claims (23)

a rear housing formed with an inlet through which an incoming optical cable is drawn into the interior and an outflow through which an outgoing optical cable through which an optical fiber of the incoming optical cable is branched and connected is drawn out;
a front housing rotatably connected to the rear housing and providing a space for optical connection and branching of the incoming optical cable and the outgoing optical cable between the front housing and the rear housing;
a locking part fixed toward the rear housing so that the front housing is not opened;
an inner housing detachably connected to the bottom of the rear housing to fix the incoming optical cable and the outgoing optical cable, and providing a space for cross-dressing of the incoming and outgoing optical cables;
an optical connection tray rotatably connected to the inner housing to connect the optical fibers of the incoming optical cable and the outgoing optical cable to each other, provided with at least one optical tray, and capable of being stacked when a plurality of optical fibers are provided; and,
A sealing member made of an elastic material provided along the edges of the front housing and the rear housing to seal between the front housing and the rear housing;
The optical connection tray has a connector arrangement unit having a slot to which the optical fiber is connected, and at least one protective sleeve provided to support the optical fiber connected inside the slot is disposed,
The protective sleeve is a micro sleeve having an outer diameter of 1.2 mm to 1.8 mm and a length of 10 mm to 40 mm,
When the width of the slot is a size capable of accommodating the micro sleeves in two rows, and the number of slots is 'n' in the optical connection tray, when the micro sleeve is applied to one optical connection tray, the maximum ' An optical distribution box characterized by connecting 4n' optical fibers. delete delete delete delete delete According to claim 1,
An optical distribution box characterized in that when 'k' optical connection trays are stacked and provided, up to '4nk' optical fibers are connected when the micro sleeve is applied. According to claim 7,
When the number 'k' of the optical connection trays is 2 and the number n of the slots is 12, the volume of the optical distribution box to which up to 48 or 96 optical fibers are connected satisfies 2L or less. distributed. According to claim 7,
When the number 'k' of the optical connection trays is 2, the number n of the slots is 24, and the width of the slots is large enough to accommodate the micro sleeves in one row, the optical distribution in which up to 96 optical fibers are connected An optical distribution box, characterized in that the volume of the box satisfies 2L or less. a rear housing formed with an inlet through which an incoming optical cable is drawn into the interior and an outflow through which an outgoing optical cable through which an optical fiber of the incoming optical cable is branched and connected is drawn out;
a front housing rotatably connected to the rear housing and providing a space for optical connection and branching of the incoming optical cable and the outgoing optical cable between the front housing and the rear housing;
a locking part fixed toward the rear housing so that the front housing is not opened;
an inner housing detachably connected to the bottom of the rear housing to fix the incoming optical cable and the outgoing optical cable, and providing a space for cross-dressing of the incoming and outgoing optical cables;
an optical connection tray rotatably connected to the inner housing to connect the optical fibers of the incoming optical cable and the outgoing optical cable to each other, provided with at least one optical tray, and capable of being stacked when a plurality of optical fibers are provided; and,
A sealing member made of an elastic material provided along the edges of the front housing and the rear housing to seal between the front housing and the rear housing;
The inlet and the outlet are both formed on surfaces of the rear housing facing each other. a rear housing formed with an inlet through which an incoming optical cable is drawn into the interior and an outflow through which an outgoing optical cable through which an optical fiber of the incoming optical cable is branched and connected is drawn out;
a front housing rotatably connected to the rear housing and providing a space for optical connection and branching of the incoming optical cable and the outgoing optical cable between the front housing and the rear housing;
a locking part fixed toward the rear housing so that the front housing is not opened;
an inner housing detachably connected to the bottom of the rear housing to fix the incoming optical cable and the outgoing optical cable, and providing a space for cross-dressing of the incoming and outgoing optical cables;
an optical connection tray rotatably connected to the inner housing to connect the optical fibers of the incoming optical cable and the outgoing optical cable to each other, provided with at least one optical tray, and capable of being stacked when a plurality of optical fibers are provided; and,
A sealing member made of an elastic material provided along the edges of the front housing and the rear housing to seal between the front housing and the rear housing;
The optical distribution box further comprises a protective cover provided between the optical connection tray and the inner housing to protect an optical cable overlaid in the inner housing. According to claim 11,
Inside the front housing and the rear housing
The optical distribution box, characterized in that the inner housing, the protective cover and the optical connection tray are stacked in the front and rear directions. The method of any one of claims 1, 10 and 11,
A light distribution box characterized in that an insertion groove into which the sealing member made of the elastic material is inserted is formed along the edge of the rear housing. According to claim 13,
The optical distribution box further comprises an inner wall spaced apart from an outer wall of the rear housing by a predetermined distance, and the insertion groove is formed between the inner wall and the outer wall. According to claim 14,
The inlet and outlet are respectively formed on the outer and inner walls of the optical distribution box. The method of any one of claims 1, 10 and 11,
The optical distribution box, characterized in that a fixing bracket is further provided on the outer bottom of the rear housing. The method of any one of claims 1, 10 and 11,
The optical distribution box according to claim 1 , wherein the sealing member made of an elastic material has an inlet groove through which the incoming optical cable is introduced and an outgoing groove through which the outgoing optical cable is drawn out. According to claim 17,
The sealing member made of an elastic material is a light distribution box, characterized in that both the inlet groove and the outlet groove are formed on surfaces facing each other. According to claim 17,
The optical distribution box further comprises a sealing member disposed in place of the outgoing optical cable in the outgoing groove where the outgoing optical cable is not disposed. According to claim 17,
The light distribution box further comprises a pressing unit for pressing the sealing member made of the elastic material along an edge of the front housing. According to claim 20,
The pressing part
An inlet pressing unit that presses both sides of the inlet groove to seal the inlet groove by deformation of the sealing member made of the elastic material;
The light distribution box characterized in that it comprises a drawing-out pressurizing part which presses both sides of the drawing-out groove and closes the drawing-out groove by deformation of the sealing member made of the elastic material. According to claim 21,
to the front housing
When the sealing member made of the elastic material is pressed by the inlet pressing part, an inlet cable movement preventing part which prevents the movement of the inlet optical cable disposed in the inlet groove, and the elastic material by the outgoing pressing part An optical distribution box further comprising an outgoing cable movement prevention unit for preventing movement of the outgoing optical cable disposed in the outgoing groove when the sealing member composed of is pressed. The method of any one of claims 1, 10 and 11,
Distributed along the edges of the front housing and the rear housing, characterized in that the sealing member is integrally formed in a square ring shape.

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