KR101895043B1 - MPO type optical distribution device with integrated optical splitter - Google Patents

Abstract

The present invention relates to an MPO type optical distributor having an integrated optical splitter, and more particularly, to an MPO type optical distributor having an integrated optical splitter that is very easy to maintain and repair.
The MPO type optical distribution apparatus having an integrated optical splitter according to the present invention integrates a splitter for distributing an optical signal to a connector itself so that a plurality of optical splitter cards are connected in series and are not used so that the volume is small, So that maintenance is easy.

Description

[0001] The present invention relates to an MPO type optical distributor having an integrated optical splitter,

The present invention relates to an MPO type optical distributor having an integrated optical splitter, and more particularly, to an MPO type optical distributor having an integrated optical splitter that is very easy to maintain and repair.

In the modern information society, the role of the communication network is a very important part. In particular, as the network communication such as the Internet is developed and a large amount of data such as voice or moving picture is transmitted, The expansion of the communication network is urgently required.

In order to satisfy such a demand, optical cable is used instead of the conventional coaxial cable as a means for processing a large amount of information at a high speed, and the use of the optical cable is increasing rapidly.

Recently, optical fiber cables have been introduced into apartment complexes (MDF), and to provide high-quality, high-speed services at the government level by moving away from the conventional system that uses ordinary telephone lines from the administrative office to each household, (Fiber To The Home) network, which is based on the FTTH.

The optical fiber for the construction of the FTTH network uses a passive optical element (optical splitter, wavelength separator) that distributes or combines a single optical signal transmitted to a plurality of optical signals, thereby enabling a PON Passive Optical Network) transmission system.

Accordingly, the optical cable supplied from the telephone company is connected to the distribution shelf installed in the open rack of the unit communication room, and the distribution shelf has a maximum of 32 branched optical connectors, thereby connecting the optical connector and the generation distribution board with the jumper cord, To the generation distribution board.

However, in the conventional case, although the optical subscriber of 32 generations is not secured all at once, the optical cable supplied from the telephone company is already branched from the inside of the optical distribution self and connected to 32 optical connectors, .

In other words, it is necessary to perform the operation of supplying the optical cable independently to the subscribers' households due to the difference in the timing of securing the optical subscriber for the 32 generation, It is not possible to increase the delay due to the increase in the number of subscribers, so that the workability due to the construction work of the optical cable is lowered and the cost is increased.

Furthermore, even if a single-generation optical cable is damaged, it can not be partially repaired or replaced, and the entire optical distributor has to be replaced, thereby complicating maintenance and repair work.

In order to solve the above-mentioned problems, Korean Patent No. 10-0622054 discloses a single-stage optical splitter card for splitting an optical cable supplied from a national corporation into a plurality of circuits using an optical splitter incorporated in a splitter casing; There is disclosed an optical branching device for FTTH comprising a two-stage optical splitter card which again branches an optical fiber branched by the one-stage optical splitter card to a plurality of lines by using an optical splitter incorporated in the splitter casing.

However, in the optical branching device for FTTH as described above, since one branching device is composed only of the first end and the second end, a plurality of optical splitter cards are connected in series when a large number is distributed, The entire optical splitter card needs to be replaced, which makes maintenance difficult.

KR 10-2003-0021199 A KR 10-2007-0059272 A KR 10-2013-0140737 A

SUMMARY OF THE INVENTION The present invention has been made to solve the conventional problems as described above, and it is an object of the present invention to minimize optical loss due to coupling during mode conversion between a single mode optical fiber and a multimode optical fiber optical line, And an object of the present invention is to provide an MPO type optical distribution apparatus having an optical splitter that is easily integrated.

According to an aspect of the present invention, there is provided an MPO-type optical distribution apparatus having an integrated optical splitter, including a first input optical fiber through which an external optical signal is input to one end, A first optical fiber array including an optical splitter for splitting an optical signal into a plurality of optical signals, and a plurality of first output optical fibers for outputting a plurality of optical signals branched by the optical splitter to the outside; A first ferrule aligned and fixed such that an input side end of the first input optical fiber and an output side end of the first output optical fiber are exposed to the outside; And a first housing which houses the first optical fiber array and is fixed to one end of the first optical fiber array so as to expose the first ferrule.

Wherein the optical splitter comprises an optical waveguide provided with an optical waveguide, the optical waveguide includes a single input waveguide into which an optical signal output to an end of the first input optical fiber is inputted, A second branch waveguide branched into a pair by the first branch waveguide and an output waveguide branched by a pair in the second branch waveguide and outputting an optical signal to an end of the first output optical fiber, And the input waveguide and the output waveguide are integrally formed on the optical distribution chip.

Wherein the optical splitter comprises an optical waveguide provided with an optical waveguide, the optical waveguide includes a single input waveguide into which an optical signal output to an end of the first input optical fiber is inputted, A second branch waveguide branched into a pair in the first branch waveguide, a third branch waveguide branched in a pair in the second branch waveguide, and a third branch waveguide branched in a pair in the third branch waveguide, And an output waveguide branched and outputting an optical signal to an end of the first output optical fiber, wherein the input waveguide or the output waveguide is integrally formed on the optical distribution chip.

Wherein the optical splitter comprises an optical waveguide provided with an optical waveguide, the optical waveguide includes a single input waveguide into which an optical signal output to an end of the first input optical fiber is inputted, A second branch waveguide branched into a pair in the first branch waveguide, a third branch waveguide branched in a pair in the second branch waveguide, and a third branch waveguide branched in a pair in the third branch waveguide, And an output waveguide branched from the fourth branch waveguide and outputting an optical signal to an end of the first output optical fiber, wherein the input waveguide or the output waveguide is integrally formed on the optical distribution chip .

A second output optical fiber for receiving the optical signal output from the first output optical fiber and transmitting the optical signal to an LC-type output connector coupled to one end of the optical fiber, and a second input optical fiber for transmitting the optical signal transmitted from the LC- A second optical fiber array including a second input optical fiber for transmitting the optical signal to an optical fiber; A second ferrule which is aligned and fixed so that the other end of the second input optical fiber and the second output optical fiber are exposed to the outside and is engageable with an end of the first ferrule; And a second housing which houses the second optical fiber array and is fixed to one end of the second optical fiber array so that the second ferrule is exposed.

Wherein the optical splitter is disposed in parallel with the first housing at an inner edge of the first housing, and the first housing is provided with an optical splitter for preventing a part of the first input optical fiber from being bent beyond a set curvature, And a plurality of guides guiding the position of the guide member are further provided.

The guide includes an extension protruding a predetermined length from the bottom of the first housing and a bending protrusion bent from the upper end of the extension protrusion to one side so as to prevent the first input optical fiber from being displaced from the initial position .

The MPO type optical distribution apparatus having an integrated optical splitter according to the present invention integrates a splitter for distributing an optical signal to a connector itself so that a plurality of optical splitter cards are connected in series and are not used so that the volume is small, So that maintenance is easy.

1 is a plan view of an MPO type optical distributor having an integrated optical splitter according to the present invention;
2 is an enlarged plan view showing an optical splitter of an MPO type optical distributor having an integrated optical splitter according to the present invention.
3 is an exploded perspective view of a main connector and a sub-connector of an MPO type optical distributor having an integrated optical splitter according to the present invention.
FIG. 4 is a plan view showing that a guide is further provided in a main connector of an MPO type optical distributor having an integrated optical splitter according to the present invention. FIG.
5 is a sectional view showing that the guide shown in Fig. 4 is further provided with a bending rib.

Hereinafter, an MPO type optical distributor including an integrated optical splitter according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 to 3 show an MPO type optical distributor 1 having an integrated optical splitter according to the present invention. 1 to 3, an MPO type optical distributor 1 having an integrated optical splitter includes a main connector 100 and a sub connector 200.

The main connector 100 includes a first input optical fiber 101 to which an external optical signal is inputted to one end and an optical splitter 103 to divide an optical signal transmitted through the first input optical fiber 101 into a plurality of optical signals A first optical fiber array including a plurality of first output optical fibers 109 for outputting a plurality of optical signals branched by the optical splitter 120 to the outside; A first ferrule (130) aligned and fixed so that an input side end of the first input optical fiber (101) and an output side end of the first output optical fiber (109) are exposed to the outside; And a first housing 150 which houses the first optical fiber array and is fixed to one end of the first ferrule 130 so that the first ferrule 130 is exposed.

The optical fiber array includes a first input optical fiber 101 for inputting optical signals and a plurality of first output optical fibers 109 for transmitting the distributed optical signals.

The input side of the first input optical fiber 101 and the output side of the first output optical fiber 109 are fixed to be exposed to the outside by the first ferrule 130.

The optical splitter 120 includes an optical distribution chip provided with an optical waveguide.

The optical waveguide provided in the optical splitter 120 includes a single input waveguide 120a into which an optical signal output to the end of the first input optical fiber 101 is input and a second input waveguide 120b through which a first branch The second branching waveguide 122 and the second branching waveguide 122 are branched into a pair and the first output optical fiber 109 and the second branching waveguide 122 are branched into a pair in the waveguide 121 and the first branching waveguide 121, And an output waveguide 129 for outputting an optical signal to an end of the optical waveguide 129. The input waveguides 120a to 129 are integrally formed on the optical distribution chip.

The optical splitter 120 according to the present embodiment includes a single input waveguide 120a, two first branch waveguides 121, four second branch waveguides 122, and eight output waveguides 129, It is possible to additionally provide an Nth branch waveguide for branching one optical signal into 16, 32, 64, and 128 optical signals, to be.

In one example, the optical splitter 120 includes a single input waveguide 120a, two first branch waveguides 121, four second branch waveguides 122, eight third branch waveguides, sixteen output waveguides 129 , And one optical signal can be branched into sixteen optical waveguides. Alternatively, two optical waveguides including two first branch waveguides 121, four second branch waveguides 122, eight third branch waveguides, A branch waveguide, and 32 output waveguides 129, so that one optical signal can be branched into 32 wavelengths.

The first ferrule 130 is arranged to align and fix the input side end of the first input optical fiber 101 and the output side end of the first output optical fiber 109 to the outside, As shown in Fig.

The first housing 150 is provided with a receiving space for accommodating the first optical fiber array therein. The first ferrule 130 is fixed to the end of the first housing 150 so as to be exposed.

The sub connector 200 is coupled to the first ferrule 130 of the main connector 100 to transmit an external optical signal transmitted through the LC patch cord to the main connector 100 and to be output from the main connector 100 And is connected to the end of the main connector 100 to transmit the optical signal to the LC patch cord.

The sub connector 200 includes a second output optical fiber 209 for receiving an optical signal output from the first output optical fiber 109 and transmitting the optical signal to the LC-type output connector 209a coupled to one end, A second optical fiber array including a second input optical fiber 201 for transmitting the optical signal transmitted from the LC-type input connector 201a to the first input optical fiber 101; A second ferrule 230 that is aligned and fixed so that the other end of the second input optical fiber 201 and the second output optical fiber 209 are exposed to the outside and is connectable to the end of the first ferrule 130; And a second housing 250 which receives the second optical fiber array therein and is fixed at one end thereof with the second ferrule 230 exposed.

One end of the second input optical fiber 201 of the sub connector 200 is provided with an LC type input connector 201a and the other end of the second input optical fiber 201 is arranged to face an end of the first input optical fiber 101. An LC-type output connector 209a is provided at one end of the second output optical fiber 209, and the other end is arranged to face the end of the first output optical fiber 109.

The first input optical fiber 101 and the second input optical fiber 201 are aligned in the first ferrule 130 of the main connector 100 and the second ferrule 230 of the sub connector 200, A coupling protrusion 131 for aligning the first output optical fiber 109 and the second output optical fiber 209 and a coupling groove 132 are provided.

A pair of coupling protrusions 131 are formed on the first ferrule 130 of the main connector 100 so as to be spaced from each other and protrude by a predetermined length. The second ferrule 230 of the sub connector 200 is provided with a pair of coupling grooves 132 at positions corresponding to the coupling projections 131 so that the coupling projections 131 of the main connector 100 can enter. Is formed.

4 and 5 show an example in which a guide is further provided in an MPO type optical distributor having an integrated optical splitter according to the present invention.

Referring to FIG. 4, the optical splitter 120 is disposed in parallel with the first housing 150 at the inner edge of the first housing 150.

A portion of the first input optical fiber 101 input from the first ferrule to the optical splitter 120, that is, a portion between the first ferrule and the optical splitter 120 has a gentle curvature in the first housing 150 A plurality of guides guiding an arrangement position of the first input optical fiber 101 so as to be bent while being bent at a predetermined curvature or more.

The guide includes a plurality of extending projections 101a projecting a predetermined length from the bottom of the first housing 150 and arranged to form a gentle curve. Two of the extending projections 101a are arranged to form a group, and are spaced apart from each other such that the first input optical fiber 101 is positioned between the pair of extending projections 101a.

In the illustrated example, the first input optical fiber 101 is disposed between the pair of extending projections 101a. Alternatively, only one extending projection 101a may be used.

As shown in FIG. 5, the guide may further include a bending protrusion 101b on one of the pair of extending protrusions 101a.

The bending protrusion 101b is formed to be bent from the upper end of the extending projection 101a to one side so as to prevent the first input optical fiber 101 from being displaced from the initial position.

4 and 5 show that the first input optical fiber 101 is bent at a gentle curvature so that loss of the optical signal is reduced compared to a structure in which the first input optical fiber 101 is disposed in an excessively bent state You can.

While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. It is to 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. And other equivalent embodiments are possible.

Accordingly, the true scope of protection of the present invention should be determined only by the technical idea of the appended claims.

1: Optical distributor
100: Main connector
101: first input optical fiber
109: first output optical fiber
120: Optical splitter
130: 1st Ferrule
200: Sub connector
201: second input optical fiber
209: second output optical fiber
230: second ferrule

Claims (7)

An optical splitter for splitting an optical signal transmitted through the first input optical fiber into a plurality of optical signals; and a plurality of optical signals branched by the optical splitter A first optical fiber array including a plurality of first output optical fibers for outputting the first optical fiber to the outside; A first ferrule aligned and fixed such that an input side end of the first input optical fiber and an output side end of the first output optical fiber are exposed to the outside; And a first housing which houses the first optical fiber array and is fixed to one end of the first optical fiber array so that the first ferrule is exposed,
And an LC patch cord coupled to the first ferrule of the main connector for transmitting an external optical signal transmitted through the LC patch cord to the main connector and transmitting the optical signal output from the main connector to the LC patch cord, A second output optical fiber for receiving the optical signal output from the first input optical fiber and transmitting the optical signal to an LC type output connector coupled to one end of the first input optical fiber, A second optical fiber array including a two-input optical fiber; A second ferrule which is aligned and fixed so that the other end of the second input optical fiber and the second output optical fiber are exposed to the outside and is engageable with an end of the first ferrule; And a second housing accommodating the second optical fiber array therein and being fixed to one end of the second housing to expose the second ferrule,
The first housing further includes a plurality of guides guiding a position of the first input optical fiber to prevent a portion of the first input optical fiber from being bent beyond a set curvature,
The guide includes a plurality of extending projections protruding from the bottom of the first housing for a predetermined length and arranged to be curved, and a plurality of projections extending from the top of the extending projections to one side to prevent the first input optical fiber And the first input optical fiber is located between the pair of extending projections. The optical splitter of claim 1,

The method according to claim 1,
Wherein the optical splitter comprises an optical distribution chip provided with an optical waveguide,
Wherein the optical waveguide includes a single input waveguide into which an optical signal output to an end of the first input optical fiber is input, a first branch waveguide branched into a pair in the input waveguide, And an output waveguide branching into a pair in the second branch waveguide and outputting an optical signal to an end of the first output optical fiber,
Wherein the input waveguide and the output waveguide are integrally formed on the optical distribution chip.
The method according to claim 1,
Wherein the optical splitter comprises an optical distribution chip provided with an optical waveguide,
Wherein the optical waveguide includes a single input waveguide into which an optical signal output to an end of the first input optical fiber is input, a first branch waveguide branched into a pair in the input waveguide, A third branch waveguide branched into a pair in the second branch waveguide and a third branch waveguide branched in a pair in the third branch waveguide to output an optical signal to an end of the first output optical fiber, And an output waveguide,
Wherein the input waveguide and the output waveguide are integrally formed on the optical distribution chip.
The method according to claim 1,
Wherein the optical splitter comprises an optical distribution chip provided with an optical waveguide,
Wherein the optical waveguide includes a single input waveguide into which an optical signal output to an end of the first input optical fiber is input, a first branch waveguide branched into a pair in the input waveguide, A third branch waveguide branched into a pair in the second branch waveguide; a fourth branch waveguide branched in a pair in the third branch waveguide; and a fourth branch waveguide branched in the third branch waveguide, And an output waveguide branching and outputting an optical signal to an end of the first output optical fiber,
Wherein the input waveguide and the output waveguide are integrally formed on the optical distribution chip.
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