WO2014196699A1

WO2014196699A1 - Multilayered optical core wire storage chest

Info

Publication number: WO2014196699A1
Application number: PCT/KR2013/010036
Authority: WO
Inventors: 임채현
Original assignee: Im Chae Hyeon
Priority date: 2013-06-03
Filing date: 2013-11-06
Publication date: 2014-12-11

Abstract

The present invention relates to a multilayered optical core wire storage chest configured to contain optical core wires and ensure easy connection between the optical core wires and optical jumper cords and easy arrangement and classification of the optical core wires. A multilayered optical core wire storage chest according to the present invention comprises: a chest body comprising a body unit having a containing space and an upper opening and an opening/closing cover rotatably coupled to the body unit to open/close the upper opening of the body unit; and a core wire support unit installed on the body unit to contain and connect optical core wires of optical cables extending into the chest body, the core wire support unit comprising a support plate mounted on the body unit, a cord support unit formed on the support plate to support optical jumper cords for connection of optical core wires, and first and second slack containing units formed on both sides of the cord support unit to support slacks of the optical core wires and the optical jumper cords. The first and second slack containing units have a plurality of first and second containing members for separately containing a plurality of optical core wires and optical jumper cords according to the type.

Description

Double-layer Fiber Cache

The present invention relates to a multi-layer optical fiber storage box, and more particularly to a multi-layer optical fiber storage box formed to facilitate the connection, arrangement and classification of the optical fiber wires.

With the rapid development of the information and telecommunications field, there is a great demand for high-speed telecommunication facilities centered on subscriber networks. To this end, an intermediate cable switching device is installed to efficiently distribute / switch the optical cable from the telephone station to the subscriber. The optical cable intermediate switching device is provided with a connection tray inside the enclosure to selectively distribute / switch the incoming fiber cable and the outgoing fiber cable.

Such an optical cable switching device is disclosed in various ways, such as Korean Patent No. 10-0611823 and Korean Patent No. 10-0808689.

The connection tray applied to the optical cable switching device is composed of a female receiving part receiving the female fiber core on both sides of the cord support part on which the optical jumper cord for connecting the optical core is supported.

However, conventional connection trays are not easy to organize the optical cores by subscriber or function, which makes the distribution / transfer work and maintenance work inconvenient, and effectively protects the optical fibers, jumper cords and trimming of the optical cores. It is difficult to carry out as a disadvantage.

The present invention has been made to solve the above problems, and an object of the present invention is to provide a multi-layered optical fiber storage box which is easy to store and connect the optical fiber wires by type and to maintain the optical fiber wires.

The multi-layer optical fiber storage box according to the present invention includes a housing having an accommodation space and having an open top, and an opening and closing cover rotatably coupled to the main body to open and close the opened top of the main body; A support plate mounted in the receiving space of the main body, a cord support part formed on the support plate and supported by a connector for connection of an optical fiber, and spaced apart from both sides of the cord support part to extend from the cord support part A tray unit having a first and a second female receiving portion supporting the female portion of the optical core, wherein the first female receiving portion includes a plurality of second receiving members so as to individually receive the plurality of optical cores; The second female receiving part has a plurality of second receiving members to individually receive the plurality of optical core lines.

Preferably, the cord support is formed of a plurality of support members hinged to the support plate, respectively, rotatably, and the first and second receiving members are rotatably hinged to the support plate.

In addition, the support plate is formed with a plurality of guide rods for guiding the extending direction of the optical core between the first and second female receiving portion and the cord support portions to protrude upward from the upper surface of the support plate.

The multi-layer fiber core storage box of the present invention can prevent the increase in working time due to the separation of the fiber cores from each other by twisting the fiber cores by entanglement or by twisting the fiber cores. And an efficient optical fiber management.

1 is a perspective view showing an embodiment of a multilayer optical fiber storage box according to the present invention;

FIG. 2 is a partial perspective view illustrating an extract of a tray unit of the multilayer optical fiber storage box of FIG. 1; FIG.

3 is an exploded perspective view showing the cord support;

Figure 4 is an exploded perspective view showing the female accommodating part,

5 is a perspective view illustrating a state in which an optical core and an optical jumper cord are mounted in the multilayer optical core storage box of FIG. 1.

Hereinafter, with reference to the accompanying drawings will be described in more detail the multilayer optical fiber storage box according to the present invention.

1 to 5 illustrate one preferred embodiment of the multilayer optical fiber reservoir 100 of the present invention.

Referring to the drawings, the multilayer optical fiber storage box 100 includes a housing 110 and a tray unit 120 mounted in a receiving space inside the housing 110.

The enclosure 110 provides a housing space for accommodating the optical core line and the optical jumper cords supported by the tray unit 120 and the tray unit 120, and includes a main body 111 and a main body 111. Opening and closing cover 114 is rotatably coupled.

The main body 111 has an accommodation space, an upper portion thereof is opened, a pivot coupling portion is formed at one side, and is formed to mount the tray unit 120 to be described later.

At both ends of the main body 111, an inlet 112 and an outlet 113 are formed so that the optical cable can be drawn in and drawn out.

The opening and closing cover 114 is rotatably coupled to one side of the rotational coupling portion of the main body portion 111, and covers the upper portion of the main body portion 111 to protect the tray unit 120 installed in the main body portion 111. It is supposed to be.

The enclosure 110 may be formed in various forms in addition to the present embodiment as long as the tray unit 120 may be mounted thereon.

The tray unit 120 is arranged to accommodate the optical core and the optical jumper cord to facilitate sorting according to the type.

The tray unit 120 includes a support plate 121 installed on the main body 111, a cord support unit installed on the support plate 121, and first and second dressing accommodation units.

The support plate 121 is a plate shape that is mounted in the receiving space of the main body portion 111, the hinge brackets 122 for supporting the first and second female receiving portion and the code support to be described later on the upper surface rotatably support plate It is formed to protrude perpendicular to the upper surface (121).

The hinge bracket 122 extends along the first direction.

The support plate 121 is formed to protrude upward from the guide rod 123 for guiding the extending direction of the optical core wire and the cable of the optical jumper cord.

In the support plate 121, hinge brackets 122 extending along the first direction are formed to be spaced apart from each other in parallel to each other so that the first female receiving part and the second female part receiving part may be respectively installed on both sides of the cord support part. The plurality of guide rods 123 protrude in a matrix form between the hinge brackets 122.

The cord support part is composed of a plurality of support members 130 rotatably installed at the central hinge bracket 122 of the support plate 121.

The support member 130 is composed of a first base plate 131 and a first skirt portion 132 formed to protrude upward along the edge of the first base plate 131.

A first protrusion member 133 is formed at a lower end of the first skirt portion 132, in which a first pivot shaft protrusion 134 is fitted to the hinge bracket 122.

In addition, a first through hole 135 is formed in the skirt portion 132 corresponding to both the left and right sides of the first base plate 131 so that the optical core can extend through the skirt portion 132.

The upper surface of the first base plate 131 is provided with a connector fixing member 136 formed at the end of the optical jumper cord to fix the connector connected to the optical core wire. The connector fixing member 136 is provided with a support groove 137 corresponding to the shape of the connector so that the connector can be fitted.

As shown in the connector fixing member 136, a plurality of support grooves 137 are formed to be spaced apart from each other along one direction.

Since the connector may be formed in various forms according to a function or a purpose, the connector fixing member 136 is preferably formed to mount connectors of various sizes and shapes.

For example, by installing a connector fixing member 136 in which each of the plurality of support members 130 arranged to be spaced apart along the first direction, which is the width direction of the support plate 121, may be equipped with connectors of different types. It can be constructed to classify and install connectors having various shapes and sizes.

The first skirt 132 is provided with a separation preventing protrusion 138 protruding toward the first base plate 131 at a position spaced upwardly from the upper surface of the first base plate 131.

The anti-separation protrusion 138 is formed to be spaced apart from each other by a predetermined distance along the longitudinal direction of the first skirt portion 132 to guide the optical core lines extending to be fitted to the connector so as not to be separated from the support member 130. The separation prevention protrusion 138 is maintained so that the optical core is caught up so as not to be lifted upward by the departure prevention protrusion 138.

The first female receiving part and the second female receiving part have a plurality of first receiving members 140 and second receiving members 150, respectively.

The first accommodating member 140 and the second accommodating member 150 are formed in the same structure.

Like the support member 130, the first receiving member 140 and the second receiving member 150 have a second skirt portion 141 and a second skirt portion formed along an edge of the second base plate 141. And a second protrusion member 143 provided with a second pivoting shaft 144 to be rotatably connected to the hinge bracket 122 at one side of the skirt 142. A second through hole 145 is formed in the region of the second skirt portion 142 facing each other so that the optical core line can be drawn in and drawn out.

The second base plate 141 is formed with a winding winding portion 146 for winding the winding of the optical core. The female winding unit 146 includes a winding pillar 147 protruding upward from the second base plate 141 so that the optical core wire can be wound, and an expansion unit 148 formed at the upper end of the winding pillar 147. .

The winding pillar 147 is formed in a cylindrical shape having a predetermined height, and the expansion portion 148 is formed of four arms extending along the radial direction from the upper end of the winding pillar 147.

The expansion part 148 is spaced at equal intervals along the circumferential direction of the outer circumferential surface of the winding pillar 147. When the winding of the optical core is wound around the winding pillar 147, the optical core line is first received by the expansion part 148. 140 or the second receiving member 150 is not separated from the upper portion.

The plurality of first receiving members 140 are installed to be spaced apart along the first direction of the support plate 121, and each of the first receiving members 140 is rotatably installed on the hinge bracket 122 to perform a transfer operation. The operation can be performed by easily exposing the optical fiber to be worked upward.

In addition, the second accommodating members 150 constituting the second female accommodating part are also formed in the same shape as the first accommodating member 140 and are installed on the other side of the support plate 121 around the cord support part to form a female part of the optical core. I can accept it.

The multi-layer optical fiber storage box 100 of the present invention configured as described above may classify a plurality of optical fibers by its type, as shown in FIG. 5, and each first receiving member ( The optical core wire wound up and received by the 140 and extending from the first receiving member 140 is separately separated through the guide rod 123 and extended to the cord support part.

The jumper of the optical jumper cord is also individually wound and accommodated in the second receiving member 150 according to its type, and the connector is mounted to the connector fixing member 136 of the supporting member 130.

In this arrangement, as shown in FIG. 5, since the optical fibers are classified and accommodated in the first receiving member 140 and the second receiving member 150 according to types, the optical fibers are prevented from being tangled or twisted with each other. Since the extension direction of each optical core is also extended in the state separated by the guide rod 123, the operator can quickly perform the operation when performing the transfer operation of the optical core later, The breakage of the optical fiber can be prevented.

Although the present invention has been described with reference to the embodiments shown in the drawings, this is merely exemplary, and it will be understood by those skilled in the art that various modifications and equivalent other embodiments are possible. Therefore, the true technical protection scope of the present invention will be defined by the technical spirit of the appended claims.

Claims

A housing having an accommodating space, the main body having an upper portion opened, and an opening and closing cover rotatably coupled to the main body to open and close the opened upper portion of the main body;

A support plate mounted in the receiving space of the main body, a cord support part formed on the support plate and supported by a connector for connection of an optical fiber, and spaced apart from both sides of the cord support part to extend from the cord support part And a tray unit having first and second length receiving parts for supporting the length of the optical core.

The first female receiving portion has a plurality of first receiving members to accommodate a plurality of optical cores individually,

And the second female receiving portion comprises a plurality of second receiving members to individually receive the plurality of optical cores.
The method of claim 1,

The cord support portion is composed of a plurality of support members hinged to each of the support plate rotatably,

And the first and second receiving members are rotatably hinged to the support plate, respectively.
The method of claim 2,

The support plate has a plurality of guide rods and the plurality of guide rods for guiding the extending direction of the optical core between the cord support portion is formed to protrude upward from the upper surface of the support plate is formed spaced apart from each other Multi-layer optical fiber storage box.
The method of claim 2,

The support plate has hinge brackets for rotatably supporting the first and the second female receiving part and the cord support part, respectively, spaced apart from each other side by side,

The support members are rotatably spaced apart from the hinge bracket in a first direction which is an extension direction of the hinge bracket.

The support member

A first base plate, a first skirt portion formed to protrude upwardly along an edge of the first base plate, and a first pivot shaft protrusion formed at a lower end of the first skirt portion to be rotatably fitted to the hinge bracket. A first through hole is formed in the first skirt portion to allow the optical core wire to be drawn in and drawn out, and the connector fixing the connector for fixing the connector connected to the optical core wire on the upper surface of the first base plate. A member is provided, wherein the first skirt portion protrudes toward the first base plate at a position spaced upwardly from the upper surface of the first base plate to prevent the separation of the optical core wire accommodated in the first base plate. Is formed,

The first receiving members are rotatably spaced apart from each other on the hinge bracket in the first direction on one side of the support member,

The second receiving members are rotatably spaced apart from each other on the hinge bracket in the first direction on the other side of the support member,

The first receiving member

A second base plate, a second skirt portion formed along an edge of the second base plate, and a second pivoting shaft protrusion provided at one side of the second skirt portion so as to be rotatably coupled to the hinge bracket. A second protruding member is formed, a second through hole is formed in the second skirt portion so that the optical core wire can be drawn in and drawn out, and the second base plate is wound in the second base plate so as to wind the length of the optical core wire. And a winding winding unit having a winding pillar protruding upwardly from and an extension portion formed at an upper end of the winding pillar to extend than the winding pillar,

The second accommodating member is a multilayer optical fiber storage line, characterized in that formed in the same structure as the first accommodating member.