KR101882960B1 - Multi-Opticalfiber connector structure having a mobility of ferrule - Google Patents

Abstract

The present invention relates to an optical connector structure, and more particularly, to an optical connector structure in which a clearance space through which a ferrule can flow is formed in an inner housing to stably maintain contact with an optical fiber during an optical connector connection operation To a multi-core optical connector structure having fluidity of a ferrule configured to maintain a connection state.
To this end, the inner housing of the optical connector structure is formed with a tapered opening extending from the front to the back so as to form a clearance space between the ferrule and the ferrule by external force.

Description

TECHNICAL FIELD [0001] The present invention relates to a multi-optical fiber connector having a ferrule fluidity,

The present invention relates to a multi-core optical connector structure, and more particularly, to a multi-core optical connector structure in which a clearance is formed in an inner housing so as to allow a ferrule to flow therethrough to stably contact an optical fiber during an operation of connecting a pair of multi- To a multi-core optical connector structure having fluidity of a ferrule configured to maintain a connection state.

Recently, a fiber to the home (FTTH) system has been proposed, which can provide various information including broadcasting and communication by connecting an optical cable to a general household.

In order to connect to the optical transmission device, an optical connector must be attached to the optical cable and terminated. In this way, a pigtail having an optical fiber assembled to the optical connector is fused and connected to the optical cable.

Another method is to directly attach an optical connector on the spot.

Meanwhile, as shown in FIG. 1A, the optical connector 10 includes a ferrule 12 (see FIG. 1 (a)) and a ferrule 12 and a ferrule is movably inserted into the ferrule 12, and a multi-core optical fiber 11 is inserted into the ferrule 12.

An elastic member (not shown) is provided at the rear of the ferrule 12 so as to be pressed forward.

And a housing 13 for covering and fixing each single ferrule 12 and accommodating the optical fiber 11 and the ferrule 12 so as to be connectable with each other.

The multi-core optical connector 10 configured as described above is connected to the other optical connector through the adapter 20 and is connected to the corresponding optical fiber 11 through a pair of ferrules 12 .

At this time, the pair of ferrules 12 are combined and aligned by fitting a guide pin (not shown) on one side and a pin hole (not shown) on the other side .

Such a guide pin and pin hole are formed through a separate pin clamp (not shown) coupled to the ferrule 12. [

As described above, the ferrule 12 protruded by inserting the pair of optical connectors at both sides of the optical connector adapter 20 connects the optical fiber 11 by the elastic force of the rear elastic member (not shown) Characteristics and connection workability can be obtained.

However, in the related art, when the optical fiber 11 connected to the rear end of the optical connector 10 on one side is pulled so that a tensile force acts in the lateral direction or a side pressure acts between the ferrules 12 of the optical connector 10 in the connected state, The connection of the ferrule 12, that is, the connection is deviated.

In addition, when the optical connector 10 is coupled through the adapter, the guide pin and the pin hole of the both-side ferrule 12 do not fit exactly in accordance with the difference in angle of the pair of optical connectors 10 to be drawn, There is a problem that the connecting operation becomes difficult.

Specifically, when the ferrule 12 protruding from the housing 13 is connected to the optical connector 10, the polished ends of the optical fiber 11 exposed at the joint end face of the ferrule 12 are precisely pressed to a predetermined pressure When the ferrule 12 is slightly connected to the ferrule 12 by the external force applied to the ferrule 12 and the ferrule 12 is slightly displaced after the completion of the connection, There is a problem that the normal connection state can not be maintained and a connection loss between the cores of the optical fibers 11 occurs.

1 (b), there is a technique of forming a constant clearance space 14 between the housing 13 and the ferrule 12 so that the ferrule 12 can be moved to some extent by an external force, Has been conventionally developed.

However, since the clearance 14 is formed with a certain gap, when the optical connector 10 is connected while grasping the positions of the ferrules 12 on both sides where the ferrules 12 are in contact with each other, There is a problem that it is difficult to precisely align the fitting positions of the guide pin and the pin hole.

2, a ferrule 12 is provided between the housing 13 and the ferrule 12 in a conventional technique such as an optical connector disclosed in Korean Patent Publication No. 10-0364082. And the opening of the housing 13 forms a gap 14a having a tapered shape extending toward the front in the connecting direction.

That is, the housing 13, into which the ferrule 12 is inserted, is provided with a plurality of clearances through which the ferrule 12 can move, as in the case of the ferrule 12 and the housing 13, As shown in Fig.

In other words, we proposed a structure in which the ferrule can flow by the gap A around the point B.

According to such an optical connector structure, when the pair of optical connectors 10 are connected, the ferrule 12 does not move much due to the guide pin 16 and the pin hole 16a, so that it is easy to fit, The flow of the ferrule 12 is made possible to some extent through the gap 14a shown at A to make the connection stable and ensure stable connection after connection.

However, in such a conventional optical connector structure, since the gap 14a formed by the ferrule 12 and the housing 13 is formed so as to be wide at the opening of the opening of the housing 13, There is a problem that the ferrule 12 penetrates into the housing 13 through which the ferrule 12 is inserted through the ferrule 14a. This may cause foreign matter to accumulate in the gap 14a or cause an abnormal connection of the optical fiber.

When the optical connector 10 is detached and attached, the end of the ferrule 12 and the inner surface of the housing 13 are in contact with each other and rubbed inside the housing 13 due to the applied force, Damage to the inside of the housing 13 can not be confirmed outside the housing 13, and breakage can not be grasped.

In addition, most of the elastic members 15 that apply an elastic force to the ferrule 12 are coil springs. The coil spring has a curved shape. When a flow of the ferrule 12 occurs due to an external force, The portion C of the ferrule 12 contacting the ferrule 12 is slightly displaced due to the movement of the ferrule 12 and the ferrule 12 is not stably supported at the rear by the elastic member 15.

Accordingly, the connection of the optical fiber 11 is not stable and a connection loss occurs.

When the ferrule 12 is coupled to the housing 13, the distal end of the ferrule 12 protrudes from the front end of the housing by the elastic force of the elastic member 15. The coupling of the adapter 20 of the optical connector 10 The ferrule 12 is pushed rearward from the inside of the housing 13 and has free displacement due to the internal clearance so that the ferrule 12 may not be fixed in position within the housing 13 and may be twisted. There is a problem in that the connection C of the optical fiber 11 is shifted, the connection of the optical fiber 11 is not stable, and the connection loss between the cores of the optical fiber 11 is generated.

Therefore, there is a desperate need for an optical connector structure capable of obtaining stable optical connection characteristics while solving the above-described problems.

Korea Patent Registration Bulletin 10-0364082 (registered on November 26, 2002)

SUMMARY OF THE INVENTION The present invention has been made to solve the above-described problems, and it is an object of the present invention to provide a ferrule having fluidity of a ferrule configured to stably secure the connection stability in a fixed position, It is an object of the present invention to provide an optical connector structure.

It is also an object of the present invention to provide a multi-fiber optical connector structure having fluidity of a ferrule configured to prevent a deviation between a ferrule and an elastic member even during a connection operation or after completing a connection in an inner housing of an optical connector.

In order to accomplish the above object, a multi-fiber optical connector structure having fluidity of a ferrule according to the present invention includes a pin clamp at the rear, a ferrule having an optical fiber inserted therein movably inserted into an inner housing, To press the ferrule forward to connect the corresponding optical fiber.

At this time, the inner housing is formed with a tapered opening extending from the front to the back, and a clearance space is formed between the ferrule and the ferrule by an external force.

On the other hand, the ferrule is composed of a body having a size that can be inserted into the opening portion and a flange portion integrally formed with a locking protrusion at the rear of the body. The opening portion of the housing includes a first opening portion in which the body is located, As shown in Fig.

The first opening and the second opening each have a taper shape extending from the front to the rear.

On the other hand, the pin clamp includes a fitting protrusion protruding rearward on the rear surface. The fitting protrusion is fitted in the tip end of the elastic member with a semicircular shape convex in the lateral direction, so as to be engaged with the tip of the elastic member. .

Further, the inner housing has guide grooves formed on its inner circumferential surface in the longitudinal direction.

The pin clamp includes a side surface protruding sideways on the side surface. The side surface protrusion has a semicircular shape with a convex shape forward, and moves along the guide groove according to the flow of the ferrule to prevent the ferrule from being released .

On the other hand, the guide groove has the same shape as that of the side surface portion, and the side surface portion of the guide groove has a tip end tapered to be positioned and fixed. The width of the guide groove at the tip end side is smaller than the width of the back side, Thereby forming a free space.

As described above, the multichip optical connector structure having the fluidity of the ferrule according to the present invention has the following advantages. First, since the opening of the inner housing into which the ferrule is inserted has a tapered shape extending from the front to the back, The ferrule is supported on the rear side and the ferrule has fluidity on the rear side, so that the guide pin and the pin hole can be coupled with each other at the predetermined position, thereby stably connecting the optical connector.

Second, since the opening of the inner housing into which the ferrule is inserted has a tapered shape extending from the front to the rear, the ferrule has fluidity even after the connection of the optical connector is completed, thereby maintaining a stable connection state.

Third, the ferrule is stably supported by the elastic member as the fitting projecting portion of the pin clamp and the elastic member are engaged with each other, so that the ferrule and the elastic member can be prevented from being displaced even if the ferrule flows during the connection operation or after completion of connection .

Fourth, the ferrule is stably supported according to the guide groove structure of the side wall of the pin clamp and the inner housing, so that the ferrule can maintain a stable position even when the ferrule flows upward and downward.

1 and 2 are schematic views showing a multi-core optical connector structure according to the prior art.
3 and 4 are a perspective view and an exploded perspective view showing a multi-fiber optical connector structure according to the present invention.
FIG. 5 is a cross-sectional perspective view showing an inner housing applied to a multi-fiber optical connector structure according to the present invention.
6 and 7 are cross-sectional views of AA 'and B-B' of the inner housing shown in FIG.
8 is a perspective view showing a coupling state of a ferrule, a pin clamp, and an optical fiber applied to a multi-fiber optical connector structure according to the present invention.
9 is a view showing a pin clamp applied to a multi-fiber optical connector structure according to the present invention.
10 is a schematic diagram showing the left-right fluidity of the ferrule according to the multi-fiber optical connector structure of the present invention.
11 is a schematic state diagram showing the up-down fluidity of the ferrule according to the multi-fiber optical connector structure of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Reference will now be made in detail to the preferred embodiments of the present invention, examples of which are illustrated in the accompanying drawings.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted so as to avoid obscuring the subject matter of the present invention.

In the following description of the present invention, the front indicates the opening portion or the direction of the optical connector, and the rear indicates the rear portion or the direction of the optical connector.

3 and 4, a multi-fiber optic connector structure 100 having fluidity of a ferrule according to the present invention includes a ferrule 110 having a pin clamp 170 inserted in the rear and an optical fiber 140 inserted therein, A ferrule 130 is movably inserted into the inner housing 110 and an elastic member 180 is provided behind the ferrule 130 to press the ferrule 130 forward.

The multi-fiber optical connector structure 100 has a structure in which an optical fiber 140 protruding from the front end surface of the ferrule 130 when a pair of optical connectors are connected using a known adapter (not shown) And the optical fibers 140 provided in the ferrule of the ferrule.

An external housing 120 is provided at an upper portion of the inner housing 110 so as to facilitate connection of the multichip optical connector structure 100 along the outer surface of the inner housing 110, A stopper 150 for supporting the position of the elastic member 180 by being fitted and fixed at the rear end of the optical connector 180 and an engagement support portion 160 for fixing the optical connector including the stopper 150 do.

Further, in the pin clamp 170, a guide pin 170a is formed in the ferrule in the optical connector on one side of the pair of optical connectors, and a pin hole (not shown) is formed in the ferrule on the other side And is configured such that the ferrule and the ferrule are in contact with and engaged with each other by fitting the guide pin 170a and the pin hole (not shown).

Each of the above-described components has a known function and a detailed description thereof will be omitted in order to avoid obscuring the gist of the present invention.

The multi-fiber optical connector structure 100 according to the present invention configured as described above can stably maintain the contact of the optical fiber 140 or maintain the connected state even when an external force is generated during a pair of optical connector connecting operations or after completion of connection A clearance S is formed between the inner housing 110 and the ferrule 130 so that when the ferrule 130 flows in the inner housing 110, So that stable bonding can be maintained.

To this end, referring to FIG. 4 and FIGS. 5 to 7, the inner housing 110 applied to the multi-fiber optical connector structure 100 of the present invention will be described in detail.

The inner housing 110 has a rectangular tubular shape having an inner space in which the ferrule 130 inserted therein is inserted into the inner housing 110 with the pin clamp 170 inserted therein and the optical fiber 140 inserted therein.

The inner housing 110 forms a tapered opening 111 extending from the front to the rear in the inner space.

The tapered opening 111 has a narrow space at the entrance side and a wide space at the inside, thereby forming a predetermined clearance space S between the tapered opening 111 and the outer surface of the ferrule 130.

The opening 111 preferably includes a first opening 111a in which the body 131 of the ferrule 130 is positioned and a second opening 111b in which the ferrule 130 is disposed, according to the shapes of the ferrule 130 and the pin clamp 170, And a second opening 111b in which the flange portion 132 is located.

The first opening 111a and the second opening 111b each have a taper shape extending from the front to the rear.

Referring to FIG. 6, the inner housing 110 has a front opening 111a and a front opening 111b extending in the width direction of the first opening 111a and the second opening 111b to form a tapered opening 111 extending from the front to the rear, a, a ') is smaller than the rear width (b, b').

The clearance? Between the front and rear widths forms a clearance S between itself and the ferrule 130. When the external force is generated, the ferrule 130 has fluidity in the interior of the inner housing 110 I will.

More specifically, when an external force is generated, the ferrule is supported at the front of the opening 111 of the inner housing 110, and the ferrule can have fluidity at the rear, so that stable connection can be achieved.

7, the inner housing 110 includes a first opening 111a and a second opening 111b which are formed in the front of the first opening 111a and the second opening 111b, respectively, to form a tapered opening 111 extending from the front to the rear. , And the height (c, c ') is smaller than the rear height (d, d').

The gap? Between the front and rear heights forms the clearance S and allows the ferrule 130 to have fluidity in the interior of the inner housing 110 by external force.

In other words, the opening 111 of the inner housing 110 has a tapered shape extending from the front to the rear, and forms a clearance space S in which the ferrule 130 can flow inside the inner housing 110.

The inner housing 110 is provided with guide grooves 114 in the longitudinal direction on both sides of the corresponding inner circumferential surface so that the side surface protrusion 173 of the pin clamp 170 can be stably moved along with the movement of the ferrule 130 .

Accordingly, when the ferrule 130 flows, the side surface protrusion 173 of the pin clamp 170 prevents the release of the ferrule 130 by the guide groove 114 and maintains stability.

More specifically, the guide groove 114 forms a tip end step 114a in which the side surface protrusion 173 is fitted and fixed in the same shape as that of the side surface protrusion 173, The width e on the side of the distal end stop 114a is smaller than the width f on the rear side of the guide groove 114. [

The gap? Of the difference in height between the tip end stop 114a and the rear end of the ferrule 130 is equal to the difference between the height of the side protrusion 173 when the ferrule 130 is pushed back by an external force for engagement with the ferrule of another optical connector. Thereby forming a free space S1 as much as possible.

Therefore, when the ferrule 130 is pressed by the elastic member 180, the side surface protrusion 173 is fixed to the tip end stop 114a so that the ferrule 130 can be stably fixed in the correct position, When the ferrule is pushed back by an external force for the coupling, the ferrule has fluidity by the clearance space S1.

8 and 9, the ferrule 130 and the pin clamp 170 applied to the optical connector structure 100 of the present invention will be described in more detail as follows .

As shown in the figure, the ferrule 130 has a shape that can be inserted and moved into the inner space of the inner housing 110. Preferably, the ferrule 130 has a size that can be inserted into the opening 111 of the inner housing 110 And a flange 132 formed integrally with the body 131 and having an engagement protrusion 133 at the rear of the body 131.

The optical fiber 140 is inserted into the flange 132 and the body 131 in a penetrating manner.

A pin clamp 170 having a guide pin 170a or a pin hole (not shown) is fitted to the rear of the flange portion 132 to be engaged. At this time, the pin clamp 170 having the guide pin 170a includes a fitting hole 171 so that one end of the guide pin 170a can be inserted and fixed.

If necessary, the pin clamp 170 may be formed integrally with the ferrule 130, and may be formed to have the same height and width as the flange portion 132.

9, the pin clamp 170 includes a fitting protrusion 172 protruding rearward from the rear surface and a side protruding protrusion 173 protruding laterally from the side surface.

The fitting protrusions 172 and the side protrusions 173 preferably have a semicircular sectional shape in which the fitting protrusions 172 have a semicircular shape having a laterally convex shape and the side protrusions 173 Sectional shape of a convex semi-circle.
At this time, the fitting protrusions 172 are spaced apart from the rear surface of the pin clamp 170 and are formed on the left and right sides, that is, on both sides thereof.

The fitting protrusion 172 of the pin clamp 170 is fitted into the tip of the elastic member 180 so that the elastic member 180 and the ferrule 130 are detached or deviated from each other ≪ / RTI >

Preferably, the elastic member 180 is composed of a coil spring.

The side surface protrusion 173 of the pin clamp 170 moves along the guide groove 114 formed on the inner side surface of the inner housing 110 according to the flow of the ferrule 130, .

The multi-fiber optical connector structure 100 having the fluidity of the ferrule according to the present invention structured as described above forms a free space in which the ferrule can move due to external force during connection operation or connection operation of the optical connector, thereby achieving stable connection.

In addition, penetration of the external fine dust is prevented, and even when the ferrule 130 is driven, each component can be maintained in a correct position without being deviated or deviated.

Referring to FIGS. 10 and 11, the schematic usage of the multi-fiber optical connector structure 100 having the fluidity of the ferrule according to the present invention will be described below.

Although the gap between the ferrule 130 and the inner housing 110, that is, the clearance S, is shown to be larger in order to clarify the present invention, And the inner space formed by the inner housing 110 have a micro gap.

10 (a) and 11 (a), a multi-fiber optic connector structure 100 according to the present invention has a structure in which a ferrule 130 is fixed by an elastic member 180 inside an inner housing 110 And is urged forward.

The fitting protrusion 172 of the pin clamp 170 formed at the rear of the ferrule 130 is engaged with the distal end of the elastic member 180 and the side protrusion 173 is inserted into the guide groove of the inner housing 110 The ferrule 130 is caught by the leading end stop 114a of the ferrule 114 to support the correct position of the ferrule 130. [

The flange 132 of the ferrule 130 is engaged with the flange jaw 113 of the inner housing 110.

On the other hand, when coupling the pair of optical connectors 100, the ferrule 130 and the ferrule 130 are coupled by the coupling of the guide pin (not shown) and the pin hole (not shown) Referring to FIGS. 10 (b) and 11 (b), the ferrule 130 is pushed rearward by the ferrule 130 of another optical connector that is in contact with the ferrule 130 .

6 and 10 (b), when the ferrule 130 is pushed rearward to engage with the ferrule on the other side and is moved into the interior of the inner housing 110, the ferrule 130 ) And the ferrule are difficult to precisely align in parallel and slightly shake to the left and right sides.

The opening 111 of the inner housing 110 in which the ferrule 130 is located has a tapered shape extending from the front to the rear so that the ferrule 130 is pushed rearward and moved to the inside of the inner housing 110 The ferrule is supported at the front of the opening by the clearance S with respect to the ferrule and the ferrule has fluidity at the rear, so that the guide pin and the pinhole can be coupled at the correct position.

The elastic member 180 having a structure in which the fitting protrusions 172 of the pin clamp 170 are fitted and engaged when the ferrule 130 flows also flows so that the ferrule 130 and the elastic member 180 are shifted So that a stable connection can be made.

7 and 11 (b), when the ferrule 130 is pushed rearward to engage with the ferrule on the other side and is moved to the inside of the inner housing 110, the ferrule 130 ) And the ferrule are shaken even finely up and down.

The opening 111 of the inner housing 110 in which the ferrule 130 is positioned also has a taper shape extending from the front to the back so that the ferrule 130 is pushed rearward, The ferrule is supported at the front of the opening by the clearance space S with the ferrule and the ferrule has fluidity at the rear, so that the guide pin and the pinhole can be engaged at the correct position, Connection can be made.

The side projections 173 of the pin clamp 170 are moved along the guide grooves 114 of the inner housing. When the ferrule is pushed rearward, the side projections 173 of the pin clamp 170 are disengaged from the tip ends 114a of the guide grooves 114, (114).

At this time, the rear portion of the guide groove 114 has a height and a clearance of the tip end stop 114a to form a clearance S1, and the ferrule is stably supported with fluidity.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention. It is not.

100: optical connector structure 110: inner housing
111: opening 113: flange jaw
114: guide groove 114a:
130: ferrule 131: body
132: flange portion 133:
140: optical fiber 170: pin clamp
170a: guide pin 171:
172: fit-in projection 173:
180: elastic member S, S1: free space

Claims (5)

A ferrule 130 having a pin clamp 170 at the rear and having an optical fiber 140 inserted therein is movably inserted into the inner housing 110 and the ferrule 130 is moved forward And a corresponding optical fiber (140) is connected to the multi-core optical connector structure,
The inner housing 110 is formed with a tapered opening 111 extending from the front to the rear so as to form a clearance S between the ferrule 130 and the ferrule 130, And forming a guide groove (114) in the longitudinal direction on the inner peripheral surface;
The pin clamp (170)
The elastic member 180 is inserted into the elastic member 180 so as to engage with the distal end of the elastic member 180 and has a semicircular cross-sectional shape that is laterally convex so as to protrude rearward A plurality of fitting protrusions 172,
And a side surface protrusion 173 protruding laterally from both sides of the ferrule 130 and having a sectional shape of a convex semicircle protruding forwardly and moving along the guide groove 114 so as to prevent the ferrule 130 from being released when the ferrule 130 flows.
The guide groove (114) of the inner housing (110)
A width e of the front end protrusion 114a is set to be equal to a width of the rear protrusion 173 in the same direction as the shape of the side protrusion 173, f) of the ferrule (130) to form a clearance (S1) of the side surface protrusion (173) when the ferrule (130) is moved by an external force.
The method according to claim 1,
The ferrule 130 includes a body 131 sized to be inserted into the opening 111 and a flange 132 formed integrally with the body 131 and having a locking protrusion 133 at the rear of the body 131 And,
The opening 111 of the housing 110 includes a first opening 111a in which the body 131 is located and a second opening 111b in which the engaging jaw 133 is engaged with the flange jaw 113, Lt; / RTI >
Wherein the first opening (111a) and the second opening (111b) each have a taper shape extending from the front to the back.
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