KR200301971Y1 - Shelf for wiring optical cable - Google Patents

Abstract

The present invention mounts a unit in which an electronic component is disposed, and in an optical cable wiring shelf for inserting an optical cable into the unit and connecting it to the unit, the front face is opened and both side plates are extended to the bottom and are formed in a rectangular parallelepiped shape. An opening portion is formed in a portion of the lower side of the side plate, and a unit mounting part in which a unit guide pin for guiding the insertion of the unit is formed on the inner side of the bottom plate and the inner side of the top plate; An insertion plate guide part provided on the inner side surfaces of the lower end portions of both side plates of the unit mounting part and having slits formed in a horizontal direction; A coupling plate formed to have a '-' side shape and positioned such that the vertical plate faces the front surface, and the horizontal plate is coupled to be spaced apart from the bottom plate outer surface of the unit mounting unit; It is formed to have a side shape of the 'c' shape, and both ends of the lower plate are formed with an insertion plate extending in the horizontal direction to be inserted into the slit of the insertion plate guide portion, and the size of the upper plate and the front plate to pass the optical cable It is an object of the present invention to provide an optical cable wiring self formed comprising an optical cable laying portion formed with at least one optical cable outlet.

Description

Shelf for wiring optical cable}

The present invention relates to a shelf for wiring an optical cable, and more particularly, a shelf for mounting a unit and a shelf for installing an optical cable are integrated into one shelf, and a shelf for mounting a unit and a shelf for laying an optical cable are not separated. It relates to an optical cable wiring self formed in a structure capable of wiring an optical cable without.

An optical cable is also called an optical fiber cable, and its shape is cylindrical and consists of a core, a clad, a jacket, and the like.

The seam is an optical fiber made of very thin glass or plastic, and the clad is a kevlar fiber that can withstand strong forces around the glass fiber. The main component is the light pulse of glass fiber, which is not disturbed by the external current, and is covered with glass, plastic, etc., which has different optical characteristics from the core.

The jacket is the outermost layer around the bundle of fibers and is made of a material such as plastic to prevent moisture, abrasion and damage.

The optical fiber transmits the signal-coded rays to the internal reflection, which has a higher data rate than the other wired transmission media due to its wider bandwidth. In addition, since the size and weight are small, the supporting structure can be reduced in size and transmitted in the form of light, thereby preventing external interference such as impact noise and crosstalk.

In addition, the data transmission rate is about 1Gbit, and is widely used in local and wide area networks, long distance communication, military use, and subscriber lines.

Due to such advantages, as the use of optical cables has become widespread in recent years, various types of wiring self connecting optical cables to units have also been manufactured.

Hereinafter, with reference to the accompanying drawings will be described with respect to the conventional optical cable wiring self.

1 shows an exploded view of a conventional self-wiring for optical cable wiring.

As shown in FIG. 1, the conventional self-wiring for the optical cable wiring includes a unit mounting self 10 for introducing and coupling the unit 40 to the inside, and the optical cable 30 to be inserted from the outside and connected to the unit 40. It is divided into an optical cable laying self 20 which sets the installation position of the optical cable 30.

A plurality of slots are formed in the unit mounting self 10 to allow the plurality of units 40 to be plugged in, and the user plugs the unit 40 into a slot formed in the unit mounting self 10. 1 shows a shape in which the unit 40 is connected to all the slots.

The optical cable laying self is formed in a box shape with an open upper end, and has one or more inlets 22 formed in a hole shape in order to introduce the optical cable 30 into the rear side, and the optical cable 30 inserted into the front side. One or more outlets 24 formed in a slit shape to be connected to the ground groove 420 of the unit 40 is provided.

In addition, in order to facilitate the operation when the optical cable 30 is wired, the optical cable 30 having a sufficient length to have an excess of a predetermined length is used, the extra optical cable 30 remaining after the wiring work is installed in the self-assembly ( 20) inside. At this time, the optical cable 30 should be loaded while maintaining a curvature of a predetermined size or more to reflect the light rays from the inside to proceed in a predetermined direction, in order to maintain the curvature of the optical cable 30 in the optical cable laying self 20 A plurality of guide pins 26 for guiding the loading of the optical cable 30 are provided.

The guide pins 26 are positioned in a circle, and the user loads the optical cables 30 roundly along the guide pins 26 so that the optical cables 30 are not folded or disconnected.

In the conventional optical cable wiring self, when the new optical cable 30 is to be newly wired, as shown in FIG. 1, the unit mounting self 10 and the optical cable laying self 20 are separated and then wired, and the optical cable ( 30) When the wiring work is completed, the unit mounting self 10 and the optical cable laying self 20 are combined again.

However, the conventional self-wiring for the optical cable structured as described above is inconvenient in work because the unit mounting self 10 and the optical cable laying self 20 must be separated each time the optical cable 30 is wired. It is difficult to distinguish which optical cable 30 is coupled to which unit 40 because the plurality of optical cables 30 are drawn out and coupled to the plurality of units 40 through the outlet 24, which makes it difficult to manage the optical cable 30. There is a disadvantage, because the extra optical cable 30 is loaded inside the optical cable laying self 20 is not a smooth discharge of heat generated therein.

In addition, when forming the individual outlet 24 in accordance with the position of the unit 40 to be mounted in order to effectively manage the optical cable 30, the user must form the outlet 24 for each position where the unit 40 is mounted The disadvantage is that the work is cumbersome.

In addition, since the unit mounting self and the optical cable laying self must be manufactured separately, there is a disadvantage that the production cost increases.

The present invention has been made to solve the above-mentioned problems, by lowering the production cost by integrating the unit mounting self and the optical cable laying self, and the optical cable can be wired without separating the unit mounting self and the optical cable laying self, An object of the present invention is to provide a self-supporting cable for the optical cable management.

1 shows an exploded view of a conventional self-wiring for optical cable wiring.

Figure 2 shows the shape of coupling the optical cable to the unit by using an optical cable wiring self according to the present invention.

3A is a front view of an optical cable wiring shelf according to the present invention.

3B is a plan view of an optical cable wiring shelf according to the present invention.

3c is a right side view of an optical cable wiring shelf according to the present invention.

4A is a front view of the optical cable laying portion.

4B is a plan view of the optical cable laying portion.

4C is a right side view of the optical cable laying portion.

FIG. 5A is a cross-sectional view of an optical cable wiring shelf according to the present invention cut along the line A-A of FIG. 3A.

5B is an enlarged view of a portion B of FIG. 5A.

FIG. 5C shows a shape in which the optical cable laying portion is drawn out from the unit mounting portion in the state shown in FIG. 5B.

FIG. 5D illustrates a shape in which the unit mounting portion and the optical cable laying portion are separated in the state of FIG. 5C.

Explanation of symbols on the main parts of the drawings

100: unit mounting unit 110: unit guide pin

120: coupling plate 122: coupling hole

130: first heat dissipation hole 140: opening part

150: insertion plate guide portion 152: slit

200: optical cable laying portion 210: insertion plate

220: optical cable outlet 230: coupling bolt

The optical cable wiring shelf according to the present invention for achieving the above object is an optical cable wiring shelf for mounting a unit in which an electronic component is disposed, and connecting the optical cable to the unit, the front of which is open and both side panels of which are lower. A unit mounting part which is formed to have an extended rectangular parallelepiped shape, openings are formed in a lower portion of both side plates, and a unit guide pin is formed on the inner surface of the bottom plate and the inner surface of the top plate to guide the insertion of the unit; An insertion plate guide part provided on the inner side surfaces of the lower end portions of both side plates of the unit mounting part and having slits formed in a horizontal direction; A coupling plate formed to have a '-' side shape and positioned such that the vertical plate faces the front surface, and the horizontal plate is coupled to be spaced apart from the bottom plate outer surface of the unit mounting unit; It is formed to have a side shape of the 'c' shape, and both ends of the lower plate are formed with an insertion plate extending in the horizontal direction to be inserted into the slit of the insertion plate guide portion, and the size of the upper plate and the front plate to pass the optical cable It is configured to include an optical cable laying portion formed with at least one optical cable outlet.

The upper plate of the optical cable placing portion is inserted between the bottom plate of the unit mounting portion and the upper surface of the coupling plate, and the lower plate of the optical cable placing portion is inserted into the slit of the insertion plate guide so that the optical cable laying portion is coupled to the unit mounting portion, and the external optical cable is connected to both side plates. Through the opening of the fiber cable is led into the interior of the installation portion, and then through the fiber cable outlet again to the outside is coupled to the unit.

In order to guide the mounting position of the optical cable inserted into the optical cable laying portion, the optical cable laying portion is provided with the optical cable guide plate formed in the vertical direction at the rear center of the lower plate, and the optical cable laying portion can be combined to distinguish the optical cables connected to each unit. The number of optical cable outlets is formed.

In addition, in order to fix the optical cable installation portion coupled to the unit mounting portion, the coupling plate is formed in the vertical plate with a hole-shaped coupling hole, the optical cable guide plate has a coupling bolt that is coupled to the coupling hole through the front plate.

Hereinafter, embodiments of an optical cable wiring self according to the present invention will be described with reference to the accompanying drawings.

Figure 2 shows the shape of coupling the optical cable to the unit by using an optical cable wiring self according to the present invention.

As shown in FIG. 2, the self-wiring for an optical cable according to the present invention includes a unit mounting unit 100 for inserting and mounting a unit 300 in which a large number of electronic components are disposed, and an optical cable 400. 300 is composed of an optical cable laying unit 200 connected to.

The unit mounting portion 100 is formed in a rectangular parallelepiped shape in which part of the front and top surfaces are open and both side plates extend to the bottom and protrude, and a portion of the bottom of both side plates is formed with an opening (not shown), and the bottom Unit guide pins 110 are formed on the inner surface of the plate and the inner surface of the upper plate to guide the insertion position of the unit 100 so that the unit 100 is inserted into and coupled to the designated position.

In addition, in order to discharge heat generated from various electronic devices including the unit 300, the bottom plate includes a plurality of first heat dissipation holes 130 formed in a hole shape.

The openings are formed on the front sides of both side plates so as to easily pull out the optical cable 400 inserted therein through the openings and connect them to the unit 300.

The optical cable laying part 200 is formed to have a side shape of a 'c' shape, and at both ends of the lower plate, an insertion plate 210 extending in the horizontal direction to be inserted into the slit of the insertion plate guide part is formed, and the upper plate and A portion of the front plate is formed with one or more optical cable outlet 220 formed in a size that can pass through the optical cable.

The optical cable laying unit 200 includes an optical cable guide plate 230 formed in a vertical direction on the lower plate to guide the mounting position of the optical cable 400. Since the optical cable 400 introduced into the optical cable laying unit 200 is arranged to one side by the guide plate, there is no fear of tangling or twisting.

In addition, in order to separately distinguish the optical cable 400 connected to each unit 300, the optical cable laying unit 200 forms an optical cable outlet 220 as many as the number of units 300 can be combined.

Under the bottom plate of the unit mounting unit 100 is a coupling plate 120 of the 'b' shape consisting of a horizontal plate and a vertical plate is coupled. The coupling plate 120 is positioned so that the vertical plate faces the front and is spaced apart from the outer surface of the bottom plate by a predetermined distance.

In addition, the coupling plate 120 forms a hole-shaped coupling hole 122 in the vertical plate, the optical cable laying portion 200 is provided with a coupling bolt 240 is coupled to the coupling hole 122 through the front plate. do.

By inserting the top plate of the optical cable laying portion 200 between the bottom surface of the unit mounting portion 100 and the horizontal surface of the coupling plate 120, and coupling the coupling bolt 240 to the coupling hole 122, the optical cable laying portion 200 ) Is coupled to the unit mounting unit (100).

Therefore, the optical cable wiring self according to the present invention introduces the optical cable 400 through the openings formed in both side plates of the unit mounting unit 100 and installs the optical cable through the king cable outlet 220 formed in the optical cable laying unit 200. After drawing to the front of the unit 200 is configured to couple the ground terminal 410 provided at the end of the optical cable 400 to the ground groove 310 formed in the unit 300, as shown in FIG. As described above, the optical cable 400 can be wired even when the optical cable laying unit 200 is pulled out a predetermined distance without being completely separated from the unit mounting unit 100.

3A is a front view of an optical cable wiring shelf according to the present invention.

3A illustrates a shape in which the optical cable laying unit 200 is completely coupled to the unit mounting unit 100.

Unit guide pins 110 for guiding the insertion position of the unit are provided in pairs inside the upper and lower surfaces of the unit mounting unit 100, and the position of the unit is inserted into the front plate of the optical cable laying unit 200. Each optical cable outlet 220 is formed one by one.

The optical cable outlet 220 is formed to have a size through which the optical cable can pass, but the ground terminal (see FIG. 2) provided at the end of the optical cable cannot pass therethrough, and thus, when the optical cable is wired, as shown in FIG. After drawing the installation unit 200 by a predetermined distance, the ground terminal 410 is pulled out of the optical cable installation unit 200 and the optical cable 400 is positioned at the optical cable outlet 220, and then the optical cable is laid as shown in FIG. 3A. The unit 200 is inserted into and coupled to the unit mounting unit 100.

3B is a plan view of an optical cable wiring shelf according to the present invention.

In this embodiment, since a part of the upper end surface of the unit mounting unit 100 is open, the first heat dissipation port 130 formed on the bottom surface is shown in plan view.

In addition, the coupling plate 130 of the optical cable laying portion 200 located at the bottom of the bottom surface of the unit mounting portion 100 through the first heat dissipation port 130 is shown.

3c is a right side view of an optical cable wiring shelf according to the present invention.

As shown in FIG. 3C, an opening 140 having a size through which an optical cable and a ground terminal provided at an end of the optical cable may be formed at a lower portion of both side plates of the unit mounting unit 100.

In addition, in order to facilitate the drawing operation of the optical cable when the optical cable drawn into the unit mounting unit 100 through the opening 140 to the front of the unit mounting unit 100, the opening 140 is a unit mounting unit ( It is formed at the front end of 100).

4 shows the shape of the optical cable laying portion separated from the unit mounting portion.

4A is a front view of the optical cable laying portion.

When the optical cable laying portion 200 is inserted into the unit mounting portion, the optical cable guide plate 230 is formed of the optical cable laying portion 200 so that the optical cable guide plate 230 provided perpendicularly to the lower end of the optical cable laying portion 200 does not interfere with the unit mounting portion. It is formed at a height lower than the faceplate. Therefore, when the optical cable laying portion 200 is viewed from the front, the optical cable guide plate is hidden from the front plate as shown in FIG. 4A.

4B is a plan view of the optical cable laying portion.

As shown in Figure 4b, both ends of the lower plate is formed with a coupling plate 210 formed long in the horizontal direction, the coupling plate 210 has a plurality of second heat dissipation holes 130 for discharging the internal heat to the outside Equipped.

The optical cable guide plate 230 provided perpendicularly to the rear end of the lower plate is provided at the center of the lower plate so as not to interfere with the coupling plate when inserted into the unit mounting unit.

4C is a right side view of the optical cable laying portion.

As shown in FIG. 4C, the coupling bolt 240 is formed at right angles to the front plate of the optical cable laying unit 200, and the optical cable guide plate 230 is provided in a direction perpendicular to the lower plate.

In addition, the coupling plate 120 formed to be rearward is formed to form a single layer in the middle, the configuration thereof will be described with reference to Figure 5b.

FIG. 5A is a cross-sectional view of an optical cable wiring shelf according to the present invention cut along the line A-A of FIG. 3A.

Self-optical cable wiring self according to the present invention to maintain the vertical height of the insertion plate 210 when the optical cable laying portion 200 is inserted into the unit mounting portion 100, both side panels of the unit mounting portion 100 The insertion plate guide part 150 provided on the inner side of the lower end and formed with the slit 152 in the horizontal direction is further provided.

In addition, since the openings 140 formed on both side plates of the unit mounting unit 100 remain open even when the optical cable laying unit 200 is coupled, the optical cable introduced through the opening 140 is not damaged.

5B is an enlarged view of a portion B of FIG. 5A.

As shown in FIG. 5B, the upper plate of the optical cable laying unit 200 is inserted between the bottom plate of the unit mounting unit 100 and the horizontal plate of the coupling plate 120, and the lower plate of the optical cable laying unit 200 is inserted. It is inserted into the horizontal slit formed in the plate guide portion 150.

In addition, since the vertical height of the slit 152 formed on the lower side surface portion of the unit mounting portion 100 and the insertion plate guide portion 150 is different, the lower plate of the optical cable laying portion 200 of the portion inserted into the slit 152 is a slit. It is formed to form a monolayer according to the vertical height of (152).

FIG. 5C shows a shape in which the optical cable laying portion is drawn out from the unit mounting portion in the state shown in FIG. 5B.

When the coupling bolt 230 coupled to the coupling hole (not shown) of the coupling plate 120 is pulled in the state of FIG. 5B and the optical cable laying portion 200 is pulled to the front direction, the optical cable laying portion as shown in FIG. 5C. 200 is drawn out, and the optical cable wiring is possible.

In the state of FIG. 5C, the optical cable is led into the opening 140 and is led to the optical cable outlet (not shown) between the front plate of the optical cable laying unit 200 and the optical cable guide plate 230.

As described above, the conventional self-wiring for the optical cable wiring has the trouble of separating the unit mounting self and the optical cable laying self for wiring the optical cable, and having to recombine the unit mounting self and the optical cable laying self after the completion of the optical cable wiring work. Self-optical cable wiring by itself has the advantage that it is very convenient because the optical cable wiring work is possible only by drawing a certain distance to the optical cable laying portion.

FIG. 5D illustrates a shape in which the unit mounting portion and the optical cable laying portion are separated in the state of FIG. 5C.

When it is necessary to separate the optical cable laying portion 200 from the unit mounting portion for replacing the optical cable laying portion 200 and repairing other parts, the optical cable laying portion 200 is pulled out to the end in the front direction in the state of FIG. 5C. By doing so, as shown in FIG. 5d, the optical cable laying unit 200 is separated.

In addition, when the optical cable laying portion 200 is coupled to the unit mounting portion 100, the upper plate of the optical cable laying portion 200 is connected to the bottom plate of the unit mounting portion 100 and the coupling plate 120 in the state of FIG. 5D. Located between the horizontal plate and the end of the lower plate is placed in the slit 152 formed in the insertion plate guide portion 150, and then push the coupling bolt 240 to the coupling hole formed in the coupling plate 120.

The present invention has been described in detail using the preferred embodiments, but the scope of the present invention is not limited to the specific embodiments, and should be interpreted by the appended claims. In addition, those of ordinary skill in the art should understand that many modifications and variations are possible without departing from the scope of the present invention.

By using the optical cable wiring self according to the present invention, it is possible to reduce the production cost by combining the unit mounting self and the optical cable laying self, and the optical cable can be wired without separating the unit mounting self and the optical cable laying self. This facilitates and separates and lays the wired optical cables so that the management of the optical cables is easy.

Claims (4)

In an optical cable wiring shelf which mounts a unit in which an electronic component is disposed and draws an optical cable inside and connects to the unit, The front is open and both side plates are extended to the bottom to form a rectangular parallelepiped shape. An opening is formed in the lower part of both side plates, and the unit guide guides the insertion of the unit on the inner side of the bottom plate and the inner side of the top plate. A unit mounting portion in which pins are formed; An insertion plate guide part provided at inner sides of lower ends of both side plates of the unit mounting part and having slits in a horizontal direction; A coupling plate which is formed to have a side shape of a '-' shape, the vertical plate is positioned to face the front surface, and the horizontal plate is coupled to be spaced apart from the outer surface of the bottom plate of the unit by a predetermined distance; It is formed to have a side shape of the 'c' shape, the both ends of the lower plate is formed with an insertion plate extending in the horizontal direction to be inserted into the slit of the insertion plate guide portion, the upper plate and a portion of the front plate to pass the optical cable An optical cable laying portion formed with at least one optical cable outlet; Self for optical cable wiring, characterized in that comprises a. The method of claim 1, The bonding plate, Forming a hole-shaped engaging hole in the vertical plate; The optical cable guide plate, And a coupling bolt coupled to the coupling hole through the front plate. The method according to claim 1 or 2, The optical cable outlet, Self-optical cable wiring characterized in that formed by the number of units that can be combined. The method according to claim 1 or 2, The optical cable outlet, And an optical cable guide plate formed in a vertical direction at a rear center portion of the lower plate.