KR100436851B1 - Connection Shelf for Ribbon Tpye Optical Fiber Cable - Google Patents

Abstract

The present invention has a drawer-type structure that is moved by the rail from the inside of the enclosure (1) to be assembled and mounted on the optical distribution panel, the folding doors are detachably installed at the front and rear ends, respectively, and the inlet is formed on one side of the rear end ( 2) and; A connection tray (3) installed at the inner bottom surface of the slide to fusion-connect and filter the ribbon optical fiber that is inserted into the ribbon optical fiber protected by the protection tube from the external optical fiber cable with the ribbon optical fiber of the multi-core optical fiber separation type optical cord; A branch mounting unit (4) installed on one side of the connection tray to align and mount the multi-core optical fiber separation type optical cord; A storage mandrel (5) installed close to the branch mount and configured to process the single-core optical cord branched through the multicore optical fiber split type optical cord of the branch mount; A guide for the single core optical cord 6 which can maintain the curvature of the single core optical cord branched from the multi-core optical fiber split optical cord between the branch mount mount and the storage mandrel; A distribution plate 7 having an optical adapter attached to the front side of the slide so that the single-core optical cord and the external optical jumper cord branched through the multi-fiber optical split type optical cord mounted on the branch mount stand can be coupled; It is characterized by providing an optical connection self for a ribbon type optical fiber cable.

Description

Connection Shelf for Ribbon Tpye Optical Fiber Cable

The present invention relates to an optical connection self for a ribbon optical fiber cable, and more particularly, to enable the ribbon optical fiber cable to be efficiently applied using a multi-core optical fiber detachable optical cord, while the conventional optical connection self is connected and arranged, etc. The present invention relates to an optical fiber connection for a ribbon type optical fiber cable which has innovatively improved the problem of poor space utilization in the workability.

In general, optical communication transmits light and exchanges information, and optical fiber made of glass fiber is used as a medium to transmit tens of thousands of times more information than electric communication by current coaxial cable.

In addition, since the state of information transmission is good because it is not influenced by external radio waves and magnetic fields at all, it is widely used in the communication field, and its use range is gradually expanding to other fields.

As such, the demand for fiber optic cables using fiber optics is increasing in accordance with the spread of subscriber networks related to various communication services such as local area network (LAN), bidirectional communication, and video call. to be.

There are various types of optical fiber cables according to the use, and are classified into outdoor optical cables installed outdoors, indoor optical cables installed indoors, and optical fiber cables for entering installed outdoors and indoors.

Here, the indoor optical cable is an optical cable installed in an interior of a building such as a building, that is, a ceiling, a floor, a wall, and the like, and the incoming optical cable is an optical cable connecting the outdoor optical cable and the indoor optical cable, and is used for connection between short distances.

However, since the optical fiber cable using the optical fiber is installed at a distance of hundreds of kilometers or more, when a connection and branching of the optical fiber are required in the middle, a splitter, an optical fiber amplifier or an optical cord connection method or welding is performed. The connection method is used.

That is, the optical connection self is used to connect the optical cable to the transmission device and the intermediate terminal to enable connection, distribution and transfer.

In particular, the incoming optical cable is branched into a plurality of optical cords in an optical distribution panel in a narrow space installed in a telephone station or a distribution center, and the optical cords are connected to a predetermined jumper cord and branched into a plurality of single-core optical cords.

In this case, since the optical cord and the jumper cord branched from the optical fiber cable have a considerable length, the optical cord and the jumper cord are wound inside the optical distribution board and appropriately dressed, and at the same time, the optical fiber cable is connected to the jumper cord so as to be connected to the respective equipment. In the narrow interior space of the space for the processing space and the connection tray is to be secured separately, for this purpose is to use the optical connection self.

As such, the optical splice is located inside the optical distribution panel and is connected to each optical cord, and thus, the connection enclosure for appropriately dressing process, and the conventional optical splice is mainly used in the loose tube type optical fiber cable.

That is, one embodiment of the optical connection self mainly applied to the conventional loose tube type optical fiber cable is shown in Figs. This is briefly described as follows.

First, the main configuration of the optical connection shelf is installed on the bottom surface 101 of the shelf 100, a pair of mandrel processing means which is rotated in place and the mandrel 200 to be located in front of the mandrel 200 When installed, the adapter mounting plate 500 and the connection tray 400 is fixedly installed on the upper surface, and when folded, the adapter mounting plate 500 is folded and positioned so as to be positioned at the upper portion of the filtering processing means. It is made up of the connection tray mounting means to be positioned to be spaced apart a predetermined distance from the top of the dressing processing means while being flipped back.

Here, the mandrel 200 has a cylindrical body 201 to which the one-sided cord is wound and dressed, and protrudes radially outward to the upper end of the body 201 to prevent the one-sided cord from being wound upward. Two flanges 203 are provided.

The connection tray attaching means is a pair of support members 301 installed on both sides of the dressing processing means, and a plurality of connection pieces are connected to be folded to each other, and a pair of connections fixedly installed on an upper end of the support member 301. The connecting member 302 and the connecting piece at the end of the connecting member 302 are connected in the transverse direction, and the upper surface is formed of a mounting table 307 to which the connection tray 400 is bundled and fixed.

The support member 301 is a member of the form of 'dimpleza' which is set slightly higher than the mandrel 200, the lower end of which is fixed to the bottom surface 101 of the shelf 100, and the upper end of the mandrel 200 Located at the top to fix the connection member 302 is installed.

The connecting member 302 is a lower connecting piece 303 is fixedly installed so as to be positioned in the front and rear direction on the upper end of the support member 301, and the intermediate connecting piece 304, the front end is hinged to the front end of the lower connection piece 303 and The upper connecting piece 305 has a rear end hinged to the rear end of the intermediate connecting piece 304, and the intermediate connecting piece 304 when the connecting member 302 is unfolded by protruding from one side of the upper connecting piece 305. It is made of a stopper 306 in contact with the upper surface of the support to maintain the connection member 302 in an unfolded state.

Therefore, when the connection member 302 is extended forward, the connection tray 400 is unfolded so as to be positioned at the upper end of the adapter mounting plate 500, and the stopper 306 of one side of the upper connection piece 305 is connected to the middle connection piece 304. The connection tray 400 is prevented from falling back while being in contact with the upper surface.

In addition, the permanent magnet 308 is fixedly installed in the center of the upper surface of the support member 301, the permanent magnet 308 is passed through the center of the lower connecting piece 303 and the intermediate connecting piece 304 of the connecting member 302. When the through hole 309 is formed to fold the connection member 302, the upper connection piece 305 is attached to the permanent magnet 308 to maintain the folded state.

The connection tray 400 is disposed so that a plurality of trays are stacked on each other and tied to the mounting table 307 by a predetermined band.

Both ends of the connection tray 400 are provided with an inlet through which the optical end cable is inserted, and an inside of the mechanical connector and an organizer for mounting it are provided such that the optical end cable and the one end cord are connected to each other.

The adapter mounting plate 500 is installed on the bottom surface 101 of the shelf 100 so as to be located in front of the pair of mandrel 200, and the adapter mounting holes 501 are provided as many as one end cord.

The rear end of both sides of the shelf 100 is provided with an inlet 102 through which the optical end cable is introduced.

An example of the use of the optical connection self having the above configuration will be described in detail with reference to FIGS. 1 and 2 as follows.

After fixing the optical end cable 600 introduced into the interior through the inlet 102 of the optical connection self to the back plate with a cable tie, the plurality of loose tubes 601 are exposed to the outside by removing the cover over a suitable length. Be sure to

Subsequently, when the loose tube 601 is spirally bundled into the band 603 over an appropriate length, the radius of curvature is maintained by the elasticity of the loose tube 601 itself, which is bundled by the band 603, and thus the self The pulling of the optical cable 100 is prevented when the 100 is drawn out.

When the drawing of the optical fiber cable 600 is completed, the optical connection self is drawn out, and the connection member 302 is unfolded so that the connection tray 400 extends over the top of the adapter mounting plate 500. Inside the tray 400, a loose tube and a plurality of single end cords are connected to each other by a mechanical connector or a fusion connector.

Subsequently, the connection tray 400 is bundled and fixed to the mounting table 307 at the upper end of the connection member 302.

Then, when only the upper connecting piece 305 is folded back while the connecting member 302 is folded, the connection tray 400 is spaced a predetermined distance from the upper part of the mandrel 200 and is located at the rear of the shelf 100. .

In this way, the mandrel 200 is wound up by splitting and winding the one-sided cord having a considerable length to the two mandrel 200 in an open state.

Subsequently, the single-core optical connector of the one end cord end is connected to be connected to the equipment through an adapter fixed to the adapter mounting plate 500.

However, in recent years, due to the rapid spread of information, more optical cable lines are required, and ribbon type multi-core optical fibers (ribbon type optical fiber cables) in which a plurality of optical fiber core wires are integrated into a band shape have been manufactured and used.

When the ribbon multicore optical fiber is drawn indoors from the cable and connected to the system, the ribbon multicore optical fiber must be branched into a plurality of single core optical fibers at any one point because the multicore optical fiber has to be branched and connected to the system or facility. do.

Therefore, at the point where the multicore optical fibers are branched, a multicore optical fiber split optical cord is used to protect the optical fiber.

However, in the related art, there has been no optical connection self applicable to the ribbon-type optical fiber cable using the multi-core optical fiber separation type optical cord as described above.

This is because when the ribbon-type multi-core optical fiber is required to connect and branch, it is inserted only in the horizontal direction when entering the inlet, there is a problem that can not flexibly respond even if the torsional stress occurs on the ribbon-shaped multi-core optical fiber, Because the part and the discharged part were easily disconnected by the external bending stress, there was a problem that the reliability of the product was deteriorated. Therefore, the optical connection self applied with the conventional loose tube type fiber optic cable could not be used.

Accordingly, the present invention is conceived to be applied to the ribbon-type optical fiber cable that was conventionally applied to the loose tube type optical fiber cable, the object of the present invention is a ribbon-type optical fiber cable using a multi-core optical fiber separation type optical cord The present invention provides an optical fiber cable for ribbon type fiber optic cable that has been innovatively improved in that the conventional optical fiber cable has a low space utilization in workability such as connection and arrangement.

That is, in the present invention, the ribbon optical fiber of the ribbon optical fiber cable is introduced into the optical connection self, and is connected to the ribbon optical fiber and the fusion splicing of the multi-core optical fiber separation type optical cord, and the mechanical optical connector or the multi-core optical connector, and the single fiber of the multi-core fiber separation type optical cord The cord is designed to allow a connector to be connected to the optical adapter of the optically connected self front distribution plate.

In addition, the present invention by forming the optical connection shelf in the drawer type structure, the slide can be removed and put in to ensure a wide space during work, by manufacturing the front and rear of the optical connection self in the folding door structure, It is to provide an optical connection shelf for a ribbon type optical fiber cable having a structure that can secure the working space by opening the folding door and to protect the interior of the shelf by closing the door.

In addition, the present invention can easily connect, mount, and filter the multicore optical fiber separation type optical cord by using a structure such as a connection tray, a branch mount stand, a guide, a storage mandrel, etc. In addition, the present invention provides a fiber optic cable for ribbon type fiber optic cable, in which each structure can be stacked to expand the receiving core.

1 is an exploded perspective view illustrating an optical connection self applied to a conventional loose tube optical fiber cable;

2 is an exemplary view showing the state of use of the optical connection self applied to the conventional loose tube type optical fiber cable,

3 is a view showing a state in which the ribbon-type optical fiber cable is substantially applied to the optical connection self according to the present invention,

4 is a plan view illustrating an optical connection self according to the present invention;

5 is a perspective view showing a branch mounting bracket installed in the optical connection self according to the present invention,

6 and 7 are a perspective view showing a storage mandrel installed in the optical connection self according to the invention,

8 is a usage example showing a state in which a ribbon optical fiber cable is connected and arranged in the optical connection self according to the present invention.

* Description of the symbols for the main parts of the drawings *

1: enclosure 1a: fixed support

2: slide 2a: inlet

2b: Folding door 2c: Shade for single core cord

2d: fiber optic cable fixing groove 3: connection tray

3a: array plate 3b: connection part

4: Branch Mount 5: Storage Mandrel

6: guide for single-core optical cord 7: distribution plate

7a: optical adapter 8: fiber optic cable

8a: ribbon optical fiber 8b: single-core optical cord

9: optical jumper cord t: protective tube

Ribbon-type optical fiber cable for connection according to the present invention for achieving the above object has a drawer-type structure that is moved by the rail from the inside of the enclosure that is assembled to the optical distribution panel while being detachable to the front and rear end foldable A slide installed at the door and having an inlet formed at one side of the rear end thereof; A ribbon optical fiber, which is installed on the inner bottom surface of the slide and protected by a protective tube from an optical fiber cable, can be fusion-bonded with a ribbon optical fiber of a multi-fiber optical fiber split type optical cord, a mechanical optical connector or a multi-core optical connector connection, and a connecting connection A tray; A branch mounting stand installed at one side of the connection tray to align and mount the multi-fiber optical fiber separating type optical cord; A storage mandrel installed close to the branch mount unit and configured to process the single-core optical cord branched through the multicore optical fiber split type optical cord of the branch mount unit; A guide for a single core optical cord capable of maintaining the curvature of the single core optical cord branched from the multi-core optical fiber separation type optical cord between the branch mount mount and the storage mandrel; And a distribution plate provided with an optical adapter on the front side of the slide such that the single-core optical cord branched through the multi-core optical fiber separating optical cord mounted on the branch mounting bracket and the external optical jumper cord can be coupled to each other. It features.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

3 is a view showing a state in which a ribbon type optical fiber cable is substantially applied to the optical connection self according to the present invention, Figure 4 is a plan view showing the optical connection self according to the present invention, Figure 5 is in accordance with the present invention 6 and 7 are perspective views illustrating a storage mandrel installed in an optical splice according to the present invention, and FIG. 8 is an optical splice according to the present invention. This is an example of usage showing the usage status of ribbon fiber optic cable connected and arranged.

As shown, the optical connection self to which the present invention is applied has a structure in which the slide (or self; 2) can be pulled in and out of the inside of the enclosure 1 so as to be able to move smoothly by rails not shown. The enclosure 1 has a fixed support 1a attached thereto so as to be assembled to the optical distribution panel FDF with screws.

At this time, the slide (2) is open in the upper shape, such as a drawer, the front and rear are shown in the figure on the bottom inner side of the bottom surface of the bottom bottom so that it is stored in the drawer (1) of the rectangular cylinder open. The rail groove which is not formed is formed, and the inlet port 2a through which the optical fiber cable is introduced and the optical fiber cable fixing groove 2d are provided on the side of the rear end portion.

In addition, the front surface of the slide (2) has a distribution plate (7) to which the optical adapter (7a) is attached so that the multi-core optical fiber separation type optical cord and the external optical jumper cord (9) installed inside the optical connection self is coupled. The front end of the slide 2 is equipped with an acrylic front folding door (not shown) to protect the optical jumper cord 9 from the outside.

At this time, the folding door is easily removable up and down by the permanent magnet.

In addition, the rear end of the slide (2) is equipped with a rear folding door (2b) of the same shape as the front, this rear folding door (2b) is also possible to be easily removable up and down by a permanent magnet At the time of work, the folding door 2b is opened and the slide 2 is pulled out lightly.

On the other hand, various structures are attached to the inner bottom surface of the slide (2) to easily accommodate the ribbon optical fiber, the detailed structure and function thereof are as follows.

That is, the ribbon optical fiber 8a is introduced from the optical fiber cable 8 into one side of the inner bottom surface of the slide 2, and the fusion splicing, the mechanical optical splicer or the multicore optical splicer connection and the coupling of the multi-fiber optical fiber separating type are described above. The connection tray 3 which can be processed is provided, and on one side of the connection tray 3, the branch mounting table 4 to which the above-mentioned multi-core optical fiber separation type optical cord is mounted is fixedly installed.

Further, a storage mandrel 5 capable of carrying out the processing of the single-core optical cord 8b branched from the multi-fiber optical split type optical cord of the branch mounting table 4 is provided on the side of the branch mounting table 4, A guide 6 for a single core optical cord is provided between the branch mount base 4 and the storage mandrel 5 to maintain the curvature of the single core optical cord 8b branched from the multicore optical fiber split optical cord. .

And, in front of the storage mandrel (5) is installed vertically from the bottom surface of the slide (2) is connected to a plurality of single-core optical cord (8b) branched through the multi-fiber optical fiber separation type optical cord of the branch mounting base (4) The distribution plate 7 in which the optical adapter 7a to be provided is provided.

Here, the connection tray (3) is a structure that can be laminated, the ribbon optical fiber from the optical fiber cable (8) by the ribbon fiber optical split type optical cord and fusion splicing, mechanical optical connector or multi-core optical connector connection and the structure that can process The ribbon connecting portion (heat shrink sleeve) 3b can be fixed to the array plate 3a.

As shown in FIG. 5, the branch mount mounting unit 4 is screwed to the bottom surface of the slide 2 and has a branched portion of the multi-fiber optical fiber split type optical cord as a slot 4b structure which is divided into a plurality. It is a structure that can be inserted and plugged in, and is capable of opening and closing the lid 4a of the branch mount stand 4 from above.

At this time, when extending the shim athletes can be laminated using a supporter not shown.

The single core optical cord guide 6 installed in connection with the storage mandrel 5 at one side of the branch mount stand 4 maintains the curvature of the single core optical cord 8b of the multi-fiber optical fiber split type optical cord and stores the storage mandrel ( Induce to 5).

6 and 7, the storage mandrel 5 has a structure capable of processing the single-core optical cord 8b of the multi-fiber optical split type optical cord mounted on the branch mount 4. The storage mandrel 5 has a cylindrical body 5a in which the single core optical cord 8b is wound and dressed, and a single core optical cord wound in a radially outward direction at an upper end of the body 5a ( 8b) has a cord storage protrusion 5b provided in a zigzag form from the inside and the outside in order to facilitate the rearranging of the single core optical cord 8b while preventing the top 8b from being separated from the upper portion, and a fixing groove 5c at the bottom thereof. And fixing protrusions 5d, which can be laminated.

A single core cord shadle 2c is provided so that the cord portion is arranged before the single core optical cord 8b of the multicore fiber split type optical cord is mounted on the distribution plate 7.

On the other hand, the inside of the slide 2, the ribbon optical fiber (8a) is protected from the optical fiber cable (8) to the protective tube (t) is introduced through the protective tube inlet, fixed by a cable tie or the like in the protective tube fixing groove. It is guided by the protective tube shadle and introduced into the connection tray (3).

The method of applying the ribbon-type optical fiber cable to the optical connection self according to the present invention configured as described above will be described in detail.

The ribbon type optical fiber cable 8 is fixed to the external optical distribution panel (FDF) of the optical connection shelf, the unit slot protective tube (S) is mounted on the optical fiber cable (8), and the ribbon optical fiber (8a) for each slot is protected by the protective tube (t). The ribbon optical fiber 8a is led into the optical connection self via the inlet 2a formed on one side of the slide 2 in the inserted state.

At this time, a few strands of the protective tube (t) is fixed to the fixing groove (2d) located on the bottom surface of the slide (2) by a cable tie or the like.

After fixing the protective tube (t) to the protective support plate inlet, the ribbon optical fiber (8a) is secured to the length of the appropriate length in the protective support plate.

On the other hand, after attaching the above-mentioned multi-core optical fiber separation type optical cord to the branch mounting table 4, the single-core optical cord 8b is appropriately wound on the storage mandrel 5 for the single-core optical cord and the optical adapter of the distribution plate 7 ( 7a), the ribbon optical fiber 8a is led through the other inlet of the protective support plate to secure the length to the appropriate length.

The ribbon optical fiber 8a of the ribbon optical fiber cable 8 and the ribbon optical fiber 8a of the multicore optical fiber split type optical cord are fusion-spliced, and the connecting portion (heat shrink sleeve 3b) is connected to the array plate 3a of the connection tray 3. Fix it.

Then, the optical jumper cord 9 is connected to the external device in front of the distribution plate 7 to finish.

As described above, according to the present invention, by installing a structure such as a connection tray, a branch mounting base, a guide, a storage mandrel, etc., inside the slide of the optical connection self, and by using the multi-core optical fiber separation type optical cord, The ribbon fiber of the ribbon fiber optic cable is introduced into the optical splice, and the spliced connection with the ribbon fiber of the multifiber optical split type optical cord is connected to a mechanical fiber connector or a multi-conductor optical connector. As the connector can be connected to the optical adapter of the distribution plate, the ribbon type fiber optic cable can be applied to the optical connection self.

In addition, the present invention by forming the optical connection shelf in the drawer type structure, the slide can be removed and put in to ensure a wide space during work, by manufacturing the front and rear of the optical connection self in the folding door structure, By opening and working the folding door to secure the working space, there is an effect to protect the interior of the self by closing the door in normal times.

In addition, there is an effect that can be expanded by stacking each of the above structure.

Claims (5)

A slide having a drawer structure which is moved by a rail from the inside of the enclosure to be assembled and mounted on the optical distribution panel, and having a folding door detachably attached to the front and rear ends, and having an inlet formed at one side of the rear end; Ribbon optical fiber, which is installed on the inner bottom surface of the slide and protected by the protection tube from the external optical fiber cable, can be fused and connected with the ribbon optical fiber of the multi-core optical fiber split optical cord, mechanical optical connector or multi-core optical connector A connection tray; A branch mounting stand installed at one side of the connection tray to align and mount the multi-fiber optical fiber separating type optical cord; A storage mandrel installed close to the branch mount unit and configured to process the single-core optical cord branched through the multicore optical fiber split type optical cord of the branch mount unit; A guide for a single core optical cord capable of maintaining the curvature of the single core optical cord branched from the multi-core optical fiber separation type optical cord between the branch mount mount and the storage mandrel; A distribution plate having an optical adapter attached to the front side of the slide such that the single-core optical cord and the external optical jumper cord branched through the multi-core optical fiber separating optical cord mounted on the branch mounting bracket are coupled to each other; Optical connection self for a ribbon type optical fiber cable comprising a. The method of claim 1, The foldable doors respectively installed at the front and rear end portions of the slide are made using acrylic material and are detachable through a permanent magnet. The method of claim 1, The connection tray is a stackable structure, the fusion splicing portion, a mechanical optical connector or an optical connection self for a ribbon type optical fiber cable, characterized in that the array plate is fixed to the multi-core optical connector is provided. The method of claim 1, The branch mounting unit is a slot structure that can be mounted by mounting the multi-fiber optical fiber separation type optical cord, open the top cover, the optical fiber connection for the ribbon type optical fiber cable, characterized in that it can be closed after mounting the multi-fiber optical fiber separation type optical cord. The method of claim 1, The storage mandrel has a cylindrical body in which a single core optical cord branched through a multi-core optical fiber split optical cord is wound and dressed, and protrudes radially outward at an upper end of the body to prevent the single core optical cord from being wound upward. Ribbon type fiber optic cable optical fiber having a cord storage protrusion provided in a zigzag from inside and outside to facilitate the rearranging of single-core optical cord, and having a fixing groove and a fixing protrusion at the bottom to enable stacking. Connection Self.