KR101712062B1 - adapter employing attenuator for optical connector having multiple channel - Google Patents

Abstract

The present invention relates to a multichannel optical connector capable of attenuating light by connecting optical fibers forming a plurality of channels so that light can be transmitted for each corresponding channel between two optical connectors mounted on ferrules in a plug housing, A connecting housing mounted in the connecting housing and provided with an attenuation channel corresponding to the channels of the optical connector, the attenuating channel corresponding to the channels of the optical connector, And a multi-channel attenuation block for attenuating and transmitting the light. According to such an adapter for connecting an optical attenuator to a multichannel optical connector, it is possible to connect to a multichannel optical connector and to attenuate and transmit light.

Description

[0001] The present invention relates to an optical attenuator,

The present invention relates to an adapter for connecting an optical attenuator type multichannel optical connector, and more particularly, to an adapter for connecting an optical attenuator type multichannel optical connector capable of attenuating and transmitting light output through an optical connector.

Optical connectors are classified into single fiber optic connectors such as SC, FC, ST, LC and MU, and multi-fiber optic connectors such as MT, MTRJ and MPO depending on the number of optical fibers that can be connected.

Among them, the multi-fiber optical connector is formed in a push-pull coupling manner and is mainly used for transmitting a lot of information such as a data center.

Such multi-fiber optical connectors are variously disclosed in Korean Patent No. 10-0366053, Korean Patent No. 10-1330648, and US Patent No. 7,048,447.

However, the conventional multi-core optical connector merely provides a function of relaying optical transmission connection through multiple channels, and does not provide a function of reducing a signal amplified more than necessary in the course of transmitting light.

It is an object of the present invention to provide an adapter for connecting an optical attenuator-type multichannel optical connector that is capable of attenuating light while allowing optical connection to be achieved.

In order to attain the above object, an optical attenuator-applied multichannel optical connector adapter according to the present invention is characterized in that optical fibers forming a plurality of channels are aligned with ferrules in a plug housing, A connector housing having a receptacle having open ends at both ends so that the plug housing of the optical connector can be inserted and accommodated, respectively; And a multichannel attenuation block mounted in the connection housing and provided with attenuation channels corresponding to the channels of the optical connector to attenuate and transmit the incident light.

The multi-channel damping block includes a block housing mounted at an inner center of the connection housing; And a light attenuating optical fiber having a core provided for each channel in the block housing and doped with a dopant for attenuating incident light.

The light-attenuating optical fiber is obtained by adding at least one dopant of iron, chromium, manganese, nickel, cobalt and vanadium to the core.

The optical attenuation optical fibers of the multi-channel attenuation block may have the same attenuation factor for each channel or different attenuation ratios.

The adapter for connecting an optical attenuator to a multichannel optical connector according to the present invention provides an advantage that it can be connected to a multichannel optical connector while attenuating and transmitting light.

1 is an exploded perspective view showing an optical connector assembly to which an adapter according to the present invention is applied,
FIG. 2 is an enlarged perspective view of the multi-channel damping block of FIG. 1,
FIG. 3 is a longitudinal sectional view of the multi-channel damping block of FIG. 1,
FIG. 4 is a sectional view showing a state where a multi-channel damping block is mounted in the connection housing of FIG. 1. FIG.

Hereinafter, an adapter for connecting an optical attenuator to a multichannel optical connector according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 is an exploded perspective view showing a connector assembly to which an optical attenuator-applied multi-channel optical connector adapter is applied, FIG. 2 is an enlarged perspective view of the multi-channel damping block of FIG. 1, FIG. 4 is a cross-sectional view showing a state where a multi-channel damping block is mounted in the connection housing of FIG. 1. FIG.

Referring to FIGS. 1 to 4, the adapter 100 according to the present invention is capable of physically connecting two multichannel optical connectors 10 and attenuating transmitted light.

The adapter 100 includes a connection housing 110 that can physically connect the multichannel optical connectors 10 and a multichannel damping block 130 that is mounted in the connection housing 110 and is capable of attenuating light on a channel- ).

The multichannel optical connector 10 is structured such that optical fibers 13a to 13n forming a plurality of channels through which light is independently transmitted are aligned in the ferrule 20 in the plug housing 30, .

The multichannel optical connector 10 includes an optical fiber 12 in which a ribbon optical fiber made of a plurality of optical fibers is accommodated, a ferrule 20 in which the ends of the optical fibers of the optical cable 12 are aligned so as to be spaced apart from each other, An elastic protective tube 40 provided to be elastically biased so as to be returned to an initial position in the longitudinal direction of the ferrule 20 while being moved forward and backward from the outside of the plug housing 30; ).

Reference numeral 50 denotes an alignment guide pin to be inserted into the ferrule 20, and an insertion hole into which the alignment guide pin is inserted is formed on the longitudinal end face of the ferrule 20.

The structure of the multi-channel optical connector 10 is variously known, and a detailed description thereof will be omitted.

The connection housing 110 is capable of physically connecting the two multi-channel optical connectors 10 to each other.

The connection housing 110 may include a plurality of first and second optical connectors 10, which are inserted in series so that the first and second optical connectors 10 are opposed to each other, And has a receiving port (111).

On the side surface of the connection housing 110, a hook 112 is formed.

When the plug housing 30 of the optical connector 10 is inserted into the connection housing 110, the plug housing 30 is resiliently inserted into the restricting groove provided on the inside of the guide groove 32 formed on the side surface of the plug housing 30, And a pressing piece 114 for locking the pressing member 30 is formed.

The pressing piece 114 extends in a bendable manner inside the connection housing 110 and has a structure having a triangular hook portion at its end.

The length of the connection housing 110 is such that the plug housing 30 of the two optical connectors 10 is received at both ends to a depth at which it is engaged by the pressing piece 114, As shown in Fig.

The multi-channel attenuation block 130 is mounted in the connection housing 110 and attenuates the channels of the connected optical connector 10 to attenuate and transmit the incident light.

The multichannel damping block 130 includes a block housing 131 formed to be mounted at the center of the connecting housing 110 through the receiving port 111 of the connecting housing 110, And light-attenuating optical fibers 133a to 133n having a core to which a dopant for attenuating incident light is added.

A restricting piece 136 is formed in the side surface of the block housing 131 so as to be inserted into a restricting groove 117 formed in a triangular shape in the connection housing 110.

When the external force is applied in the direction in which the external force is applied to the side surface, the restraint piece 136 may be folded so as not to protrude from the surface and may be resiliently protruded and retracted to protrude when the external force is released.

The block housing 131 is formed with a guide hole 138 into which the alignment guide pin 50 inserted into the ferrule 20 in the forward and backward direction can be inserted.

The block housing 131 may be inserted into the restricting groove 117 of the connection housing 110 until the block housing 131 is restrained.

Further, at the time of separation, it is necessary to move forward in the direction in which the restraint piece 136 is released from restraint.

The block housing 131 may be formed of a synthetic resin material.

The multi-channel damping block 130 may be fixedly installed in the connection housing 110 by an adhesive or other fixing member.

On the other hand, the light-attenuating optical fibers 133a to 133n are formed in a structure having a core 134 and a clad 135 surrounding the core 134. The core 134 is made of iron, chromium, Manganese, nickel, cobalt and vanadium is added.

It is needless to say that the light attenuating optical fibers 133a to 133n of the multi-channel attenuation block 130 may have the same attenuation factor for each channel, or at least some or all of them may have different attenuation rates.

The light attenuating optical fibers 133a to 133n may be single mode or multimode optical fibers.

The adapter 100 described above is provided with a multichannel damping block 130 in a connection housing 110 and a multichannel optical connector 10 at both ends of the connection housing 110 as shown in Fig. The dichroic damping block 130 attenuates the light emitted from the optical connector 10 on one side and transmits the attenuated light to the other optical connector 10.

The multi-channel optical connector connection adapter 100 described above provides an advantage that it can be connected to the multi-channel optical connector 10, while attenuating and transmitting the light.

110: connection housing 130: multi-channel damping block
131: Block housing

Claims (4)

delete An adapter for connecting optical fibers forming a plurality of channels so that light can be transmitted for each corresponding channel between two optical connectors mounted on a ferrule in a plug housing,
A connection housing having a receptacle opened at both ends so that the plug housing of the optical connector can be inserted and accommodated, respectively;
And a multichannel attenuation block mounted in the connection housing and provided with attenuation channels corresponding to the channels of the optical connector to attenuate and transmit the incident light,
The multi-channel attenuation block
A block housing mounted at an inner center of the connection housing;
And a light attenuating optical fiber having a core provided for each channel in the block housing and doped with a dopant for attenuating incident light,
A restraint piece is formed on a side surface of the block housing so as to be inserted into a restricting groove formed in a triangular shape in the connection housing,
Wherein the restraint piece is formed such that when the external force is applied in a direction in which the external force is applied to the side surface of the block housing, the restraint piece is folded without protruding to the surface and resiliently protruded when the external force is released. The optical attenuating optical fiber according to claim 2, wherein the light-attenuating optical fiber is a single-mode or multimode optical fiber, and at least one of iron, chromium, manganese, nickel, cobalt and vanadium is added to the core. Adapter for connector connection. The multi-channel optical connector connection adapter of claim 2, wherein the optical attenuation optical fibers of the multi-channel attenuation block have the same attenuation factor or different attenuation factor for each channel.

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