KR20150046603A - integrated optical splitter - Google Patents

Abstract

An integrated optical splitter according to the present invention comprises: a main body casing forming an exterior of the integrated optical splitter; an input light adaptor which is installed on the main body casing, wherein an input light connector is inserted into the input light adaptor from outside; a plurality of output light adaptors which are installed on the main body casing, wherein an output light connector is separately inserted into the output light adaptors from outside; and an optical splitter module which is installed inside the main body casing and splits an optical signal received through an input line to a plurality of output setting optical fibers, wherein one side of the optical splitter module is connected to the input light adaptor through the input line, and the other side of the optical splitter module is connected to the output optical adaptor through the output setting optical fibers. The output optical adaptor is characterized in comprising: a fixing stand which is fixed on the main body casing, wherein an insertion tube into which a ferrule is inserted is formed on the fixing stand, and an end of the output setting optical fiber connected to the optical splitter module is directly inserted into the ferrule; two or more grippers which protrude toward an inner portion of the main body casing from the fixing mount around the insertion tube and are arranged to be parallel with the insertion tube, wherein the gripper includes a bump, which protrudes toward the insertion tube, at one end thereof; and a socket which is provided to be opposed to the grippers with the fixing stand between them such that the socket is connected to the output optical connector which is inserted from outside of the main body casing. According to the present invention, spatial efficiency is improved by preventing optical lines from being tangled within an optical terminal box, in which the integrated optical splitter is installed, and a size of the optical terminal box can be reduced. Also, a maintenance process of the integrated optical splitter can be performed simply, overall costs such as material costs and labor costs can be reduced during connecting and splitting operations of external optical lines, and operation efficiency can be improved by reducing operation times.

Description

[0001] INTEGRATED OPTICAL SPLITTER [0002]

The present invention relates to an integrated optical splitter, and more particularly, to an integrated optical splitter installed in an optical terminal box so that an external optical line can be easily connected and distributed and an optical signal is transmitted to an individual subscriber.

2. Description of the Related Art In recent years, a demand for a large-capacity line has been demanded as the demand for optical communication rapidly increases. Accordingly, ribbon-type multi-core optical fibers in which a plurality of single-core optical fibers are arranged in a strip shape are widely used. In order to connect a ribbon-type multi-core optical fiber connected to the optical fiber introduced into the interior of the room to a system or a facility, To be branched into a plurality of single-core optical fibers. Therefore, an optical splitter is used for branching in the connection housing and sending to the optical subscriber side.

An example of such an optical splitter is disclosed in Korean Utility Model Registration No. 20-0463882 (registered on Nov. 23, 2012, hereinafter referred to as "Patent Document 1").

As shown in FIG. 1, the optical splitter 10 according to the related art is provided with a ribbon-type multi-core optical fiber 9 in which the input-coated optical fiber 1 connected to the optical base station or the optical repeater is drawn, Is provided between the input-coated optical fiber (1) and the ribbon-shaped multicore optical fiber (9) so that the optical signal is distributed. On the other hand, the ribbon-type multi-core optical fiber 9 is connected to a fan-out unit 20 so as to branch to an output-coated optical fiber 5 which is a plurality of single-core optical fibers connected to individual subscriber sides.

However, since the optical splitter 10 according to the related art has to be physically branched into the output-covered optical fiber 5 through the fan-out 20, the ribbon-type multicore optical fiber 9 has to be branched in the optical terminal box, Tangled, and the inner space efficiency of the optical terminal box is lowered, thereby enlarging the size of the optical terminal box.

In addition, since the input-coated optical fiber 1 is connected to one side of the optical splitter 10 and the ribbon-like multi-core optical fiber 9 whose outer surface is peeled is connected to the other side of the optical splitter 10, There is a problem that maintenance or repair may be difficult at the time of failure or breakage of the battery 10.

In addition, since the ribbon-type multi-core optical fiber 9 is branched to the plurality of output-coated optical fibers 5 through the fan-out 20, the overall cost such as the material cost and the labor cost can be increased. There is a problem that it may be deteriorated.

Korea Utility Model Registration No. 20-0463882 (registered on November 23, 2012)

SUMMARY OF THE INVENTION It is an object of the present invention to provide an integrated optical splitter capable of preventing the optical lines from being entangled in the optical terminal box, thereby increasing the space efficiency and downsizing the size of the optical terminal box.

In addition, it is an object of the present invention to provide an integrated optical splitter that can be easily performed in maintenance work.

In addition, it is an object of the present invention to provide an integrated optical splitter that can reduce various costs such as material costs and labor costs, and can shorten work time and improve work efficiency.

According to an aspect of the present invention, there is provided an integrated optical splitter comprising: a main body casing forming an outer appearance; An input optical adapter installed in the main body casing to receive an input optical connector from the outside; A plurality of output optical adapters provided in the main body casing, the output optical connectors being individually fitted from the outside; And an output optical adapter which is installed inside the main body casing and has one side connected to the input optical adapter through an input line and the other side connected to the output optical adapter through a plurality of output setting optical fibers, Wherein the output optical adapter is fixed to the main body casing and includes a ferrule directly fitted with the end of the output setting optical fiber connected to the optical distribution module, A gripper protruding toward the inside of the main body casing from the fixing table and disposed in parallel to the insertion tube and having a protrusion protruding toward the insertion tube at a distal end thereof; And an output optical connector inserted from the outside of the main body casing, And a socket provided to be oriented in the gripper.

Wherein the input line is an input setting optical fiber stripped of an outer surface of an input coated optical fiber so as to be directly connected to the ferrule fitted to the input optical adapter, the input optical adapter being fixed to the main body casing, Wherein the ferrule has a ferrule to which an end of the input setting optical fiber is directly connected, the ferrule being inserted into the ferrule; and two or more projections protruding from the ferrule toward the inside of the main casing, A gripper having a protrusion protruding toward the insertion tube at a distal end thereof and a socket provided to be oriented to the gripper with the fixing base interposed therebetween so as to be connected to an input optical connector fitted from the outside of the main body casing .

The output setting optical fiber is inserted into the ferrule in a state where the end portion of the output setting optical fiber is enclosed by the protective sleeve and is directly connected to the output optical adapter from the inside of the main casing to prevent the ferrule from rotating And when the distal end of the ferrule has an angle, a direction projection protruding in the longitudinal direction is further formed at the distal end of the insertion tube so as to distinguish the direction of engagement of the distal end of the ferrule.

According to the present invention, it is possible to provide an integrated optical splitter that can prevent the optical lines from being entangled in the optical terminal box, thereby increasing the space efficiency and downsizing the size of the optical terminal box.

Further, it is possible to provide an integrated optical splitter in which the maintenance work can be performed easily.

In addition, it is possible to provide an integrated optical splitter that can reduce costs such as material costs and labor costs during connection and distribution of external optical lines, and can reduce work time and improve work efficiency.

1 is a view showing an optical splitter according to the prior art,
2 shows an internal configuration of an integrated optical splitter according to the present invention,
FIG. 3 is a perspective view showing a lower base of the main body casing of FIG. 2,
4 is a perspective view showing that a lower base and an upper cover of a body casing according to the present invention are coupled to each other,
FIG. 5 is a simplified view of an input setting optical fiber and an output setting optical fiber wired through the optical distribution module of FIG. 2;
Figure 6 is a perspective view of the input optical adapter of Figure 2,
FIG. 7 is a perspective view showing another embodiment of the input optical adapter of FIG. 6;
FIG. 8 is a plan view showing a process of connecting an output setting optical fiber to the output optical adapter of FIG. 2;
FIG. 9 shows another embodiment of FIG. 2,
FIG. 10 is a perspective view showing another embodiment of FIG. 3; FIG.

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

2, the integrated optical splitter 100 according to the present invention includes a main body casing 110 forming an external appearance, an input optical adapter 140, a plurality of output optical adapters 150, A distribution module 170, an input setting optical fiber 180, and a plurality of output setting optical fibers 190.

As shown in FIG. 4, the main body casing 110 is configured such that the lower base 120 and the upper cover 130 are coupled to each other to form a thin flat plate shape. As shown in FIGS. 2 and 3, A module mounting portion 121 is integrally formed in the main body casing 110 to mount the optical distribution module 170 thereon and is provided with a plurality of pads for stably supporting the wiring of the input setting optical fiber 180 and the output setting optical fiber 190 The module mounting portion 121 and the support 123 are formed on the lower base 120 so that the earth 123 is integrally formed.

3, an adapter mounting portion 125 is coupled to the lower base 120 of the main body casing 110 so that the input optical adapter 140 and the output optical adapter 150 are engaged with each other in an interference fit manner And a casing coupling portion 127 formed integrally with the upper cover 130 and formed with a fastening hole to be coupled with the upper cover 130 by a screw fastening method are integrally formed.

The module mounting portion 121 protrudes from the surface of the lower base 120 to correspond to the shape of the optical distribution module 170 so that the optical distribution module 170 is detachably coupled to the module.

The support base 123 is formed by bending and extending a plate surface spaced apart from a part of the plate surface of the lower base 120 so that the input setting optical fiber 180 and the output setting optical fiber 190 are not exposed in the direction of the upper cover 130 Respectively.

The adapter mounting portion 125 is formed on one side of the lower base 120 so as to have a plurality of sections defined corresponding to the shapes of the input optical adapter 140 and the output optical adapter 150.

The casing coupling portion 127 is provided for coupling between the lower base 120 and the upper cover 130. However, when the length of the fastening screw is sufficient, a plurality of integrated optical splitters 100 according to the present invention And may be provided in the interior of the optical terminal box.

Accordingly, all the components constituting the integrated optical splitter 100 according to the present invention are constructed as an assembly module type, so that when the integrated optical splitter 100 breaks down or breaks, the main casing 110 is easily disassembled and only the corresponding components are repaired So that the maintenance work of the integrated optical splitter 100 can be performed easily.

In addition, it is not necessary to expose the optical fiber to the outside of the main casing 110 inside the optical terminal box without the need of exposing the optical fiber connected to the splitter to the outside of the optical fiber terminal box, so that breakdown or breakage can be prevented, The number of inspections performed prior to installation can be reduced by two to one.

2, the input optical adapter 140 is installed on one side of the main body casing 110 so that the input optical connector 3 to which the input coated optical fiber 1 is connected is fitted from the outside.

A plurality of output optical adapters 150 are arranged in a line on one side of the input optical adapter 140 such that a plurality of output optical connectors 7 each connected to a plurality of output coated optical fibers 5 are fitted from the outside.

Thus, the process of dividing the ribbon-type multi-core optical fiber 9 into the plurality of output-coated optical fibers 5 through the fan-out 20 is omitted, and the output-coated optical fiber 5 and the input By easily detachably connecting the coated optical fiber 1 to the main body casing 110, it is possible to reduce various costs such as the material cost and the labor cost in connection and distribution of the external optical line, and to shorten the working time and improve the working efficiency .

In the conventional method, any one of the envelopes of the output-coated optical fibers 5 branched in the course of branching the ribbon-type multi-core optical fiber 9 to the plurality of output coated optical fibers 5 through the fan- All the other output coated optical fibers 5 need to be discarded. However, according to the present invention, if the output coated optical fibers 5 already completed are inserted into the output optical adapter 150 of the integrated optical splitter 100 The occurrence of defects can be prevented, and the operation can be performed easily.

However, according to the integrated optical splitter 100 of the present invention, when the input optical adapter 9 is connected to the output optical connector 7, The output optical adapter 150 and the output optical adapter 150 are detachably mounted on the main body casing 110 so as to be fixedly mounted so that the occurrence of an error in connection can be prevented and the external and internal optical lines need to be separately cleaned And it is also possible to prevent the external and internal optical lines from becoming entangled with each other in the main body casing 110.

Accordingly, when the integrated optical splitter 100 according to the present invention is installed inside the optical terminal box, the optical lines are prevented from entangling in the optical terminal box and the space efficiency is increased, and the size of the optical terminal box can be also miniaturized.

An internal optical line such as an input setting optical fiber 180 and an output setting optical fiber 190 is connected to the input optical adapter 140 and the output optical adapter 150 through the ferrule 300 And the input optical connector 140 and the output optical adapter 150 are directly connected to the input optical connector 3 and the output optical connector 7 from the outside of the main body casing 110, Can be minimized.

The input optical adapter 140 and the output optical adapter 150 are preferably arranged in a line in a lower region of the upper and lower portions when the main casing 110 is viewed from above in a front view Do. The number of output optical adapters 150 is preferably 2 ^n, such as 2, 4, 8, 16, 32, and so on. As an embodiment of the present invention, it is preferable that the number of the output optical adapters 150 is eight arranged on the left side of the input optical adapter 140.

The optical distribution module 170 is installed inside the main body casing 110 and has one side connected to the input optical adapter 140 through an input line such as an input setting optical fiber 180 and a plurality of output setting optical fibers 190 to the output optical adapter 150 and distributes the optical signal input through the input line to a plurality of output setting optical fibers 190. [ Although not shown, a splitter chip is provided inside the optical distribution module 170.

As an embodiment of the present invention, as shown in FIG. 2, the input line is described as an input setting optical fiber 180, but as another embodiment of the present invention, as shown in FIG. 9, Or may be a coated optical fiber 180 'coated with an envelope.

2 and 5, one end of the input setting optical fiber 180 is connected to the input optical adapter 140 and the other end of the input setting optical fiber 180 is connected to the input end of the optical distribution module 170, (171). At this time, the input setting optical fiber 180 is inserted into the ferrule 300 while being enclosed by the protective sleeve 200, and is directly connected to the input optical adapter 140 from inside the main body casing 110.

The input setting optical fiber 180 according to the present invention peels only the outer covering of the input coated optical fiber 1 so as to be directly connected to the ferrule 300 inserted into the input optical adapter 140 inside the main casing 110, 110, and the plastic coating layer is left as it is to prevent the optical signal from leaking to the outside.

2 and 5, one side of the output setting optical fiber 190 is connected to a plurality of output terminals 173 of the optical distribution module 170, and the other side of the output setting optical fiber 190 is connected to a plurality Output optical adapters 150, respectively.

The output setting optical fiber 190 according to the present invention peels only the outer surface of the output coated optical fiber 5 so as to be directly connected to the ferrule 300 inserted into the output optical adapter 150 inside the main casing 110, 110, and the plastic coating layer is left as it is to prevent the optical signal from leaking to the outside.

Accordingly, since the input setting optical fiber 180 and the output setting optical fiber 190 are installed and set in the main casing 110 in advance, there is no need to separately perform work in the field during connection and distribution of the external optical line, The time can be shortened and the working efficiency can be improved.

In an embodiment of the present invention, the number of the output setting optical fibers 190 is preferably 2 ^{n, which} is the same as the number of the output optical adapters 150.

2 and 8, the other ends of the plurality of output setting optical fibers 190 are protected by a protective sleeve 200, respectively, and a plurality of output optical fibers 190 are connected via a ferrule 300, Respectively.

That is, the output setting optical fiber 190 is inserted into the ferrule 300 while being enclosed by the protective sleeve 200, and is directly connected to the output optical adapter 150 from inside the main body casing 110.

2 and 6, the input optical adapter 140 includes an input setting optical fiber 180 fixed to the main body casing 110 and connected to the optical distribution module 170, A fixing table 160 having an insertion tube 161 into which a ferrule 300 directly inserted in the insertion tube 161 is inserted and two or more insertion tubes 161 extending from the fixing table 160 to the inside of the main casing 110 A gripper 163 protruding toward the insertion tube 161 and aligned with the insertion tube 161 and having a protrusion 165 protruding toward the insertion tube 161 at an end thereof; And a socket 167 arranged to be oriented in the gripper 163 with the fixing table 160 interposed therebetween so as to be optically connected to the optical connector 3.

The ferrule 300 includes a flange 310 that protrudes around the body and engages the jaw 165 when inserted between two or more grippers 163, as shown in FIG.

In an embodiment of the present invention, when the ferrule 300 is inserted into the insertion tube 161, rotation of the ferrule 300 prevents the coupling direction from being changed, and when the distal end of the ferrule 300 has an angle, A directional protrusion 162 protruding in the longitudinal direction is further formed at the distal end of the insertion tube 161 so as to distinguish the direction of the distal end of the insertion tube 161. A guide groove 311) are preferably recessed.

When the ferrule 300 fitted with the input setting optical fiber 180 is attached to or detached from the insertion tube 161 of the fixing table 160, the direction distinguishing protrusion 162 is engaged with the guide groove 311, The input setting optical fiber 180 fitted to the input optical adapter 140 can be stably connected without being distorted by an external force.

Meanwhile, it is preferable that the direction distinguishing protrusion 162 is also applied to the output optical adapter 150 as well.

8, when the ferrule 300 coupled to the output optical adapter 150 is inserted into the insertion tube 161 of the output optical adapter 150, The end of the insertion tube 161 of the output optical adapter 150 is provided with a protruding direction in the longitudinal direction so as to distinguish the coupling direction of the distal end of the ferrule 300 when the distal end of the ferrule 300 has an angle, Distinctive protrusions 162 are further formed.

For example, as shown in FIG. 8 (C), when the distal end of the ferrule 300 is in a diagonal rather than vertical direction, when the direction of engagement of the ferrule 300 is not inserted into the insertion tube 161 in a predetermined direction The guide groove 311 of the ferrule 300 is engaged with and guided by the direction distinguishing protrusion 162 so that the coupling direction of the distal end of the ferrule 300 is distinguished in a predetermined direction, To be inserted into the insertion tube 161 in a correct position.

7, the input optical adapter 140 may further include a screw coupling portion 169 extending from left and right ends of the fixing table 160 and having fastening holes formed therein. The same can be applied to the output optical adapter 150 as well.

8, the output optical adapter 150 is also provided so as to have the same configuration as the input optical adapter 140. [ That is, the output optical adapter 150 includes an insertion tube (not shown) in which the ferrule 300, which is fixed to the main body casing 110 and is directly connected to the end of the output setting optical fiber 190 connected to the optical distribution module 170, And two or more projections 160 protruding toward the inside of the main casing 110 are arranged side by side with the insertion tube 161 and the insertion tube 161 is inserted into the insertion tube 161, A gripper 163 having a protruding protrusion 165 protruding toward the protruding portion 161 and a gripper 160 interposed between the gripper 163 and the output optical connector 7 inserted from the outside of the main casing 110 to be optically connected 163, respectively.

The input optical adapter 140 and the output optical adapter 150 are provided in the main casing 110 in a structure in which the ferrule 300 is directly connected to the inside of the main casing 110, The installed and set input setting optical fibers 180 and the output setting optical fibers 190 can be connected directly to the input optical adapter 140 and the output optical adapter 150 via the ferrules 300, The configuration of the integrated optical splitter 100 according to the present invention, which has an appearance through the main body casing 110, can be configured compactly.

In addition, since the input optical adapter 140 and the output optical adapter 150 are provided in a structure in which the ferrule 300 is directly connected to the inside of the main body casing 110 instead of the optical connector, the cost is reduced while the durability is further increased .

8A is a view showing a state before the output setting optical fiber 190 is connected to the output optical adapter 150 and FIG. 8B is a view showing the output setting optical fiber 190 Are connected to each other.

10, an input setting optical fiber 180 and an output setting optical fiber 190 are provided in the main casing 110 in advance in the main casing 110. In this embodiment, A plurality of wire guiding rotation guide portions 129 may be further provided to prevent mutual wiring from becoming entangled when installed and set.

The wiring guide rotation guide portion 129 is provided in each of the sections where a plurality of output setting optical fibers 190 are branched and wired in the lower base 120 of the main casing 110, Is rotated by the output setting optical fiber 190 which is fixed and rotatably provided with the rotation axis and is in contact with the output setting optical fiber 190, and guides the wiring of the output setting optical fiber 190.

For example, if the number of the output setting optical fibers 190 is eight, the number of the wire guiding rotation guide sections 129 may be seven, which is one less than the number.

On the other hand, the shape in which the wiring guide rotation guide portion 129 is arranged in the lower base 120 of the main casing 110 is preferably arranged in the form of a roughly rectangular pole.

Accordingly, the plurality of output setting optical fibers 190 guided and guided by the wire guiding rotation guide portion 129 can be uniformly wired and smoothly wired in the main casing 110 without mutual entanglement.

Thus, according to the present invention, it is possible to easily perform the maintenance work of the integrated optical splitter, to reduce the costs such as the material cost and the labor cost in connection and distribution of the external optical line, The efficiency can be improved.

While the invention has been described in connection with what is presently considered to be practical exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined in the appended claims.

110: main body casing 121: module mounting portion
123: ground 140: input optical adapter
150: Output optical adapter 160: Fixture
161: insertion tube 163: gripper
162: direction distinguishing projection 165: chin
167: Socket 170: Optical distribution module
171: input terminal 173: output terminal
180: input setting optical fiber 190: output setting optical fiber
200: protective sleeve 300: ferrule

Claims (3)

A main body casing forming an outer appearance;
An input optical adapter installed in the main body casing to receive an input optical connector from the outside;
A plurality of output optical adapters provided in the main body casing, the output optical connectors being individually fitted from the outside; And
And an output optical adapter connected to the output optical adapter through a plurality of output setting optical fibers, wherein the output optical adapter is connected to the input optical adapter through an input line, An optical distribution module for distributing a plurality of output setting optical fibers;
≪ / RTI >
The output optical adapter includes:
A fixing table fixed to the main body casing and formed with an insertion tube into which a ferrule directly fitted with the end of the output setting optical fiber connected to the optical distribution module is inserted,
A gripper protruding toward the inside of the main body casing from the fixing table and disposed parallel to the insertion tube and having a protrusion protruding toward the insertion tube at an end thereof;
And a socket provided to be oriented to the gripper with the fixing base interposed therebetween so as to be connected to an output optical connector fitted from the outside of the main body casing. The method according to claim 1,
The input line is an input setting optical fiber stripped of the sheath of the input coated optical fiber so that it is directly connected to the ferrule fitted to the input optical adapter,
Wherein the input optical adapter includes a fixing base fixed to the main body casing and formed with an insertion tube into which a ferrule having a distal end of the input setting optical fiber directly connected to the optical distribution module is inserted, A gripper protruding from the fixing base toward the inside of the main casing and arranged side by side with the insertion tube and having a protruding end protruding toward the insertion tube at an end thereof; And a socket provided to be oriented to the gripper with a gap therebetween. The method according to claim 1,
The output setting optical fiber is inserted into the ferrule with its end portion enclosed by the protective sleeve, and is directly connected to the output optical adapter from the inside of the main body casing, preventing the ferrule from rotating due to rotation of the ferrule Further comprising a direction projection protruding in the longitudinal direction at the distal end of the insertion tube so as to distinguish the direction of engagement of the distal end of the ferrule when the distal end of the ferrule has an angle.

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