JP5351825B2 - Optical communication module - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an optical communication module that has a simple structure and yet allows a laser beam to be shaded when an external line connector is removed therefrom without being limited in incorporation. <P>SOLUTION: A ferrule physically contacting with an external line connector is internally mounted via a sleeve 43 in the optical communication module 57. The ferrule is constituted by a first divided ferrule 45 physically contacting with the external line connector, and a second divided ferrule 47 which is formed as a separated piece from the first divided ferrule 45 and brought into contact with the axis aligned therewith. Further, the first divided ferrule 45 and the sleeve 43 for holding the ferrule 45 are arranged to be movable in conjunction with insertion or withdrawal of the external line connector. With this comprisal, a clearance 55 is generated between the first divided ferrule 45 and the second divided ferrule 47 when the external line connector is inserted or withdrawn, and thereby a shaded state is provided. <P>COPYRIGHT: (C)2012,JPO&amp;INPIT

Description

  The present invention relates to an optical communication module used for optical communication or the like.

  2. Description of the Related Art Conventionally, in an optical communication system, a bidirectional optical communication module is used for an optical subscriber system such as telephone communication.

FIG. 9 shows a receptacle structure of this type of optical communication module .
This optical communication module 1 includes an optical fiber 3, an LD-CAN 9 with a ball lens 7 having a light emitting element (LD) 5, a PD-CAN 15 with a ball lens 13 having a light receiving element (PD) 11, and a metal. A multilayer filter 19 fixed to a module body (mounting member) 17 is provided, and the optical fiber 3 is inserted into the center hole of one ferrule 21.

The module body 17, the receptacle housing (mounting member) 27 via a connecting member 23 and the Z-axis adjustment part 25 is attached. The ferrule 21 connecting member 23 is held in one end 29 side is loosely inserted into the receptacle housing 27 through the split sleeve 31.
When connecting the external line connector to the receptacle housing 27 distal connector opening 3 3, ferrule 35 of the external connector is pressed into the split sleeve 31 is optically connected external line connector to the optical communication module 1 It has become so.

  Thus, conventionally, when connecting an external line connector to the optical communication module 1, the ferrule 35 is press-fitted into the split sleeve 31 to make physical contact with the ferrule 21. In the figure, reference numeral 37 denotes an optical fiber inserted into the center of the ferrule 35.

  However, the receptacle structure has a problem that when the external connector is detached from the receptacle housing 27, the laser light is emitted to the outside from the connector opening 33, and the laser light enters the human eye. It was.

Patent Document 1 proposes an optical communication module in which a shutter that closes a connector opening and its opening / closing mechanism are mounted outside the module case . In this conventional example, when the external line connector is detached from the connector opening, the shutter is automatically rotated in the closing direction by the opening / closing mechanism to close the connector opening .

JP 2005-345985 A

However乍Ra, if Such be mounted shutter and the opening and closing mechanism to the outside of the module case, the optical communication module overall structure have want becomes complicated, when mounting in the apparatus optical communication module, the module case There is a problem in that there are restrictions on mounting due to the shutter and the opening / closing mechanism protruding outside.

  The present invention has been devised in view of such circumstances, and provides an optical communication module that is designed to shield laser light when an external line connector is detached, with a simple structure, without being restricted in mounting. With the goal.

To achieve such objects, according to one aspect, the ferrule of the external line connector physical contact At a communication module mounted on the inside through the sleeve, said ferrule is physical contact with the external line connector a first split ferrule, thereby constituted by the said first dividing ferrule and is formed separately in contact by matching the axial center to the first split ferrule second split ferrule, said first split a sleeve for holding the ferrule and the first split ferrule fixed with an adhesive, the first split ferrule and said sleeve and movable in conjunction with the insertion and removal of the external line connector, when withdrawal of the external line connector, and wherein the generating a gap between the first split ferrule and the second split ferrule.

According to another aspect, in an optical communication module in which a ferrule that physically contacts an external connector is mounted via a sleeve, the ferrule is physically contacted to the external connector, a first divided ferrule, The first divided ferrule is formed separately from the first divided ferrule, and is configured to be in contact with the first divided ferrule so that the axial center coincides with the first divided ferrule, and the first divided ferrule and the first divided ferrule The sleeve holding the ferrule is movable in conjunction with the insertion / removal of the external line connector, and when the external line connector is detached, a gap is formed between the first divided ferrule and the second divided ferrule. A matching oil is filled between the first divided ferrule and the second divided ferrule, and the first divided ferrule is filled. The sleeve between the rule and the second split ferrule, characterized by providing an air hole.

Furthermore, according to another aspect, in an optical communication module in which a ferrule that is physically contacted with an external line connector is mounted via a sleeve, the first split ferrule that is physically contacted with the external line connector; The first divided ferrule is formed separately from the first divided ferrule, and is configured to be in contact with the first divided ferrule so that the axial center coincides with the first divided ferrule, and the first divided ferrule and the first divided ferrule The sleeve holding the ferrule is movable in conjunction with the insertion / removal of the external line connector, and when the external line connector is detached, a gap is formed between the first divided ferrule and the second divided ferrule. The matching oil is filled between the first divided ferrule and the second divided ferrule, and the first divided ferrule and the second divided ferrule are in contact with each other. At least one of the divided ferrule and the second divided ferrule is formed into an eccentric shape that eccentrically matches the matching oil adhering to the end when the external line connector is detached, so that the first divided ferrule An air hole is provided in a sleeve between the first and second divided ferrules .

According to the optical communication module of the present disclosure, since the laser light is diffused within the interval between the divided ferrules when the external line connector is detached, the laser light is shielded without leaking to the outside. Further, even if the laser beam leaks to the outside, the laser beam is significantly attenuated, so that it has an advantage of excellent safety. However, as compared with the conventional case, assembly is possible without being restricted in mounting.

Further, by fixing the first divided ferrule and the sleeve that holds the first divided ferrule with an adhesive, an interval can be reliably generated between the divided ferrules.

If the matching oil is filled between the first divided ferrule and the second divided ferrule, the laser light is diffused by the interval between the divided ferrules and the matching oil attached to the end of each divided ferrule. Thus, the laser beam can be shielded more reliably.
In addition, by providing an air hole in the sleeve between the split ferrules, for example, when using a precision sleeve, the end of the split ferrule can be securely joined when the external line connector is connected, and matching is performed when the external line connector is detached. that have a advantage of being able to oil is reliably attached to the ends of the split ferrule.

Furthermore, if at least one end of the first divided ferrule and the second divided ferrule has an eccentric shape that eccentrically matches the matching oil adhering to the end, the matching oil is placed at the end when the external line connector is detached. not adhere to the lens shape by a surface tension, as a result, that have a benefit that can be achieved the shielding without the laser beam is condensed in the interval.

It is sectional drawing of one Embodiment of the receptacle structure of an optical communication module . It is sectional drawing of the receptacle structure of the optical communication module of FIG. 1 at the time of detachment | leave of an external line connector. It is sectional drawing of other embodiment of the receptacle structure of an optical communication module . FIG. 4 is a cross-sectional view of the receptacle structure of the optical communication module of FIG. 3 when the external line connector is detached. It is an expanded sectional view of the contact state of the 1st, 2nd division | segmentation ferrule . It is an expanded sectional view of the separation state of the 1st, 2nd division | segmentation ferrule at the time of detachment | leave of an external line connector. It is sectional drawing of the division | segmentation ferrule used for other embodiment of an optical communication module . It is a positive plane view of an end portion of the split ferrule shown in FIG. It is sectional drawing of the receptacle structure of the conventional optical communication module.

Hereinafter, embodiments will be described with reference to the drawings. In addition, the same code | symbol is attached | subjected to the same thing as the prior art example shown in FIG. 9, and those description is abbreviate | omitted.

1 and 2 show an embodiment of a receptacle structure of an optical communication module. In the figure, 61 is a ferrule incorporated in the receptacle housing 27 via a split sleeve 43, and the ferrule 61 includes a first split ferrule 59 that physically contacts an unillustrated external connector ferrule, and a shaft match the heart that consists of the second split ferrule 47 abutting.

The first divided ferrule 59 and the second divided ferrule 47 have the same diameter.
The second split ferrule 47 is held by the receptacle casing 27 via the connecting member 23, and the tip 49 side is always loosely inserted into the split sleeve 43. The centers of the split ferrule 59,47 that have optical fiber 3 is inserted.

The first split ferrule 59 is held in the split sleeve 43 and fixed with the split sleeve 43 and the adhesive 63. The ferrule of external connectors, that is the same diameter as split ferrule 59.

As shown in FIG. 1, a storage portion 51 that stores the split sleeve 43 along the outer shape of the split sleeve 43 is formed in the longitudinal direction of the receptacle housing 27 along the outer shape of the split sleeve 43. 51 that it is a relative long the split sleeve 43.

When the external line connector ferrule is press-fitted into the split sleeve 43 when the external line connector is connected to the connector opening 33, as shown in FIG. Move in the direction (arrow A direction in the figure). When the end of the split sleeve 43 comes into contact with the connecting member 23, the divided ferrule 59 comes into contact with the divided ferrule 47, and the optical fibers 3 of both the divided ferrules 59 and 47 are joined without axial displacement.
As a result, the ferrule of the external line connector comes into physical contact with the divided ferrule 59.

On the other hand, when the connected external line connector is detached from the connector opening 33, the split sleeve 43 and the split ferrule 59 move outward (in the direction of arrow B in the figure) by pulling out the external line connector as shown in FIG. To do. When the end portion of the split sleeve 43 comes into contact with the wall portion 53 of the storage portion 51, the movement of the split sleeve 43 and the split ferrule 59 is restricted, and a gap 55 is generated between the split ferrules 59 and 47. Tei Ru.

If the external connector is connected again in this state, the split sleeve 43 and the split ferrule 59 move in the direction of arrow A in FIG. 1 as described above, and the split ferrule 59 comes into contact with the split ferrule 47, so that both optical fiber 3 of the split ferrule 59,47 is you joined without axial displacement.

Since the optical communication module 65 according to the present embodiment is configured as described above, when the external line connector ferrule is press-fitted into the split sleeve 43 from the connector opening 33 when the external line connector is connected, as shown in FIG. The split sleeve 43 and the split ferrule 59 move in the direction of arrow A.
When the end of the split sleeve 43 comes into contact with the connecting member 23, the split ferrule 59 comes into contact with the split ferrule 47, the optical fibers 3 of both split ferrules 59 and 47 are joined without axial misalignment, and the ferrule of the external line connector , you physical contact and split ferrule 59.

On the other hand, when the connected external line connector is detached from the connector opening 33, the split sleeve 43 and the split ferrule 59 move in the direction of arrow B as shown in FIG. Then, the ends of the split sleeve 43 is in contact with the wall 53 of the housing portion 51, the movement of the split sleeve 43 and the split ferrule 59 is restricted, the gap 55 arising between both split ferrule 59,47.

Thus, when the gap 55 is generated between the two ferrules 59 and 47, the laser light is diffused in the gap 55, so that an optical loss occurs in the laser light leaking outside from the connector opening 33. the light-shielding state and ing.

Therefore, according to this embodiment, when the external line connector is detached from the optical communication module 65, the laser light is shielded without leaking from the connector opening 33 to the outside. Even if the laser beam leaks from the connector opening 33, it is safe because the laser beam is significantly attenuated .

In addition, unlike the conventional example disclosed in Patent Document 1, the present embodiment does not include a shutter or the like on the outer periphery of the receptacle housing 27. Therefore, when mounting the optical communication module 65 inside the apparatus, Assembly is possible without any restrictions.

In the present embodiment, the ferrule 61 is composed of a first divided ferrule 59 that physically contacts the external connector and a second divided ferrule 47 that abuts with the axial center aligned therewith. With a simple structure in which the split sleeve 43 is fixed by the adhesive 63, it is possible to reliably shield the laser beam when the external line connector is detached.
Furthermore, according to the present embodiment, it is possible to reliably shield the laser light with a simple structure that simply improves the ferrule of the existing optical communication module, and the split ferrule 59 and the split sleeve 43 are bonded to the adhesive 63. Therefore, the gap 55 having the same length can always be secured, and there is an advantage that reliable light shielding can be achieved.
Since the amount of light leaking to the outside line side can be changed by changing the length of the gap 55, for example, the light shielding amount is changed by adjusting the length dimension of the storage portion 51 according to specifications. it is Ru can.

3 to 6 show another embodiment of the receptacle structure of the optical communication module.
In FIG. 3, reference numeral 43-1 denotes a precision sleeve housed in the housing portion 51 of the receptacle housing 27, and a ferrule 41-1 is incorporated into the receptacle housing 27 via the precision sleeve 43-1.
As with the ferrule 61 of FIG. 1, the ferrule 41-1 has a first divided ferrule 45-1 that makes physical contact with the ferrule of the external line connector, and a second divided ferrule 47-1 that makes contact with the same center axis. The divided ferrule 45-1 is pressure-held in the precision sleeve 43-1.
As shown in FIGS. 5 and 6, the split ferrule 45-1 is formed in a substantially convex lens shape in cross section, and both end portions 45-1a thereof are formed in a convex spherical shape.
On the other hand, the split ferrule 47-1 has an end 47-1a with which the split ferrule 45-1 abuts in a convex spherical shape. A conventional well-known matching oil (refractive index matching oil, refractive index matching liquid) 115 used for the measurement of the refractive index is filled between the two divided ferrules 45-1 and 47-1, and the matching oil 115 is a gel. It has the characteristics of the shape.

Thus, the end portions 45-1a and 47-1a of the two divided ferrules 45-1 and 47-1 have convex spherical shapes so that the end portions 45-1a and 47-1a are in contact with each other. This is because the optical fiber 3 is bonded well without axial displacement, and a predetermined amount of matching oil 115 is secured and filled between the two divided ferrules 45-1 and 47-1.

Further, as shown in FIG. 5, an air hole 119 is provided in the precision sleeve 43-1 between the divided ferrule 45-1 and the divided ferrule 47-1. A funnel-shaped oil reservoir 121 is provided at the opening of the air hole 119 on the inner peripheral side of the precision sleeve 43-1, and extra matching is required when the two divided ferrules 45-1 and 47-1 are joined. oil 115 that has become as accumulated in the oil reservoir 121.
The other configurations are the same as those in the embodiment of FIG. 1, their descriptions are denoted by the same reference numerals to the same thing you omitted.

Since the optical communication module 117 according to the present embodiment is configured in this way, when the external line connector ferrule is press-fitted into the precision sleeve 43-1 from the connector opening 33 when the external line connector is connected, FIG. 3 and FIG. As shown in FIG. 5, the precision sleeve 43-1 and the split ferrule 45-1 move in the direction of arrow A. When the end of the precision sleeve 43-1 contacts the connecting member 23, the end 45-1a of the split ferrule 45-1 contacts the end 47-1a of the split ferrule 47, and both split ferrules 45-1 , 47-1 are joined without axial misalignment, and the ferrule of the external line connector is in physical contact with the end 45-1a of the split ferrule 45-1.
Then, at the time of bonding the split ferrule 45-1,47-1, accumulated extra matching oil 115 oil reservoir 121, split ferrule 45-1,47-1 are you reliably joined.

When the connected external line connector is detached from the connector opening 33, the precision sleeve 43-1 and the split ferrule 45-1 move in the direction of arrow B as shown in FIG. When the end of the precision sleeve 43-1 comes into contact with the wall 53 of the storage portion 51, the movement of the precision sleeve 43-1 and the divided ferrule 45-1 is restricted, and both the divided ferrules 45-1 and 47-1 are controlled. gap 55 arising between.

Thus, as shown in FIG. 6, when a gap 55 is generated between the two divided ferrules 45-1, 47-1, the gel-like matching oil 115 filled between the divided ferrules 45-1, 47-1 is separated. Then, the shape is irregularly changed and attached to the respective end portions 45-1a and 47-1a. For this reason, the laser light is diffused in the gap 55, and the laser light is further diffused by the matching oil 115 adhering to both end portions 45-1a and 47-1a, and leaks to the outside from the connector opening 33. light loss occurs in the light-shielding state and ing to.

As described above, in the present embodiment, when the external line connector is detached from the optical communication module 117, the gap 55 formed between the two divided ferrules 45-1 and 47-1 and the respective end portions 45-1a and 47-1a are provided. since laser light is diffused by the matching oil 115 randomly deposited, Ru Hakare reliably laser light shading than compared to the embodiment of FIG.

Also, in the present embodiment, when the optical communication module 117 is mounted inside the apparatus, it can be assembled without being restricted in mounting.
Then, as a result of making the end portions 45-1a and 47-1a of both split ferrules 45-1 and 47-1 into a convex spherical shape, the end portions 45-1a and 47-1a are brought into contact with each other to pivot the optical fiber 3. deviation without notwithstanding et al is well bonded, Ru can der filling a predetermined amount of matching oil 115 between split ferrule 459-1,47-1 in contact with.

In addition, since the funnel-shaped oil reservoir 121 is provided at the opening of the air hole 119 on the inner peripheral side of the precision sleeve 43-1, the extra matching oil 115 is removed when the two divided ferrules 45-1 and 47-1 are joined. It accumulates in the oil reservoir 121. Therefore, compared with the embodiment of FIG. 1, both end portions 45-1a, that Do is possible to reliably joined condition of 47-1A.

7 and 8 show another embodiment of the split ferrule used for the optical communication module.
In the present embodiment, instead of the gel-like matching oil 115 in FIG. 5, a sol-like matching oil (not shown) is filled between the first and second divided ferrules 45-1 and 47-2. .
In the present embodiment, the end portion 47-2a of the split ferrule 47-2 with which the split ferrule 45-1 abuts has an eccentric shape that eccentrically matches the matching oil attached to the end portion 47-2a when the external line connector is detached. in which the, by cutting the periphery of the end 47-2A of the split ferrule 47-2 as shown in FIG. 8 as an example, that have provided the convex portions 123 in plan view watery eyes shaped end 47-2A.
Since other configurations are the same as those in the embodiment of FIG. 3, their descriptions are omitted.

Thus, according to such a structure, when the external line connector is detached, the sol-like matching oil is eccentrically attached on the convex portion 123 due to the surface tension, so that the matching oil is attached to the end 47-2a due to the surface tension. Jo without adhering, as a result, that have a benefit that can be achieved the shielding without laser beam is condensed by the gap.

In the present embodiment, the convex portion 123 is provided at the end portion 47-2a of the divided ferrule 47-2. However, the convex portion 123 may be provided at the end portion of the divided ferrule 45-1, and the convex portion 123 may be provided at both ends. May be provided.

Further, the eccentric shape to decenter the matching oil, it is Ru course der not limited to the shape of the convex portion 123.

3 Optical fiber
23 Connecting member
27 Receptacle housing
33 Connector opening
41, 41-1, ferrule
43 split sleeve
43-1 Precision sleeve
45-1, 59 First split ferrule
47, 47-1, 47-2 Second split ferrule
51 storage
55 gap
65, 117 Optical communication module
63 Adhesive
115 matching oil
119 Air hole
121 Oil sump
123 Convex

Claims (3)

In an optical communication module in which a ferrule that physically contacts an external line connector is mounted via a sleeve,
Said ferrule, a first split ferrule physical contact with the external line connector,
The second divided ferrule is formed separately from the first divided ferrule and is in contact with the first divided ferrule so that the axis coincides with the first divided ferrule ,
A sleeve for holding said first split ferrule and the first split ferrule fixed with adhesive, and the first split ferrule and the sleeve can be moved in conjunction with the insertion and removal of the external line connector,
Wherein when separation of external line connector, the optical communication module, characterized in that to produce a gap between the first split ferrule and the second split ferrule. In an optical communication module in which a ferrule that physically contacts an external line connector is mounted via a sleeve,
A first divided ferrule that physically contacts the outer wire connector, and a second divided ferrule formed separately from the first divided ferrule and abutting with the first divided ferrule with the axis aligned Composed of ferrules,
The first divided ferrule and a sleeve holding the first divided ferrule are movable in conjunction with insertion / removal of the external line connector,
Creating a gap between the first divided ferrule and the second divided ferrule when the external line connector is detached;
Filling the matching oil between the first divided ferrule and the second divided ferrule,
An optical communication module , wherein an air hole is provided in a sleeve between the first divided ferrule and the second divided ferrule . In an optical communication module in which a ferrule that physically contacts an external line connector is mounted via a sleeve,
A first divided ferrule that physically contacts the outer wire connector, and a second divided ferrule formed separately from the first divided ferrule and abutting with the first divided ferrule with the axis aligned Composed of ferrules,
The first divided ferrule and a sleeve holding the first divided ferrule are movable in conjunction with insertion / removal of the external line connector,
Creating a gap between the first divided ferrule and the second divided ferrule when the external line connector is detached;
Filling the matching oil between the first divided ferrule and the second divided ferrule,
At least one end of the first split ferrule and the second split ferrule that are in contact with each other is formed in an eccentric shape that eccentrically matches the matching oil attached to the end when the external line connector is detached,
An optical communication module , wherein an air hole is provided in a sleeve between the first divided ferrule and the second divided ferrule .