JP2000266958A - Optical data link - Google Patents

Abstract

PROBLEM TO BE SOLVED: To make wide requirement satisfied as to a fixing position in the mounting. SOLUTION: This optical data link 1 is provided with an optical data link main body 10, a receptacle 40, and a connection member 20. The receptacle 40 has supporting parts 40a-40d extended along the main body 10. The connection member 20 has the first engaging parts 22, 24 for specifying a position attached to the receptacle 40. The member 20 has a connection piece 30a to allow electrical connection between the receptacle 40 and a device panel. The receptacle 40 has the second engaging parts 42, 44 in at least either of the supporting parts 40a-40d. The first engaging parts 22, 24 and the second engaging parts 42, 44 specify a relative position of the connection member 20 with respect to the receptacle 40 in plural positions as to a prescribed position.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

TECHNICAL FIELD The present invention relates to an optical data link.

[0002]

2. Description of the Related Art A conventional optical data link has fixing pins (stud pins) for fixing to a mounting substrate and nine lead pins for electrical connection. Some stud and lead pin locations are industry standard.

[0003]

The optical data links from Method and Hewlett-Packard meet the standards used as industry standards. These detailed standards are described in the specifications for Method products (Methode, MDX-19-4-2-XX Optical Ethernet T).
ranceiver), and for Hewlett-Packard products, the standard document (HEWLETT PACKARD, Technical D
ata 1X9 Fiber Optic Tranceiver for Gigabit Etherne
t).

According to these standards, two types of fingers are prepared for electrically connecting an optical data link to a panel (face plate) of a device, and these are used depending on the mounting form. I have. Therefore, when mounting the optical data link by fixing the stud pins to the substrate, two modes as shown in FIGS. 8A and 8B are possible.

[0005] However, these fingers 90a,
Even if 90b is used properly, stud pin 84 and face
8 (a) and 8 (b)
L ₁, L_Two) For implementing optical data links
In some cases, the requirements for the placement position could not be met. like this
Range is 9 mm for Method optical data link
~ 13mm range and Hewlett Packer
DOCOMO's optical data link is in the range of 8mm to 14mm.
You. In the range described above, the fingers 90a and 90b
Is connected to the face plate 88.
Can't touch and secure the electrical connection.
You.

An object of the present invention is to provide an optical data link capable of satisfying a wide range of mounting requirements regarding the above-mentioned arrangement position.

[0007]

By satisfying such mounting requirements, the fingers are brought into contact with the panel of the device to secure the electrical connection. Thereby, unnecessary radiation of the optical data link is reduced. Therefore, an optical data link that can satisfy a wide range of mounting requirements, which is the object of the present application, with an electromagnetic shield properly secured is provided.

An optical data link according to the present invention includes an optical data link main body, a receptacle, and a connecting member. The optical data link main body can be optically coupled to an optical connector plug inserted from a predetermined direction.

The receptacle is attached to the optical data link body, has a support, and guides the direction in which the optical connector plug is to be inserted. The receptacle has an opening for receiving the optical connector plug. The support part is
Extending in a predetermined direction along the outer surface of the optical data link body,
This opening is defined. The receptacle has a second engagement portion at any part of the support portion.

[0010] The connection member is attached to the receptacle, and has a first engagement portion for defining an attachment position to the receptacle. The connection member may include a connection portion that enables an electrical connection with an object to be contacted, such as a shield member of a device including the optical data link. Also, the connecting member can face and can contact any part of the support of the receptacle. By combining the first engagement portion and the second engagement portion, the relative position of the connection member with respect to the receptacle can be defined at a plurality of positions in a predetermined direction.

In the optical data link according to the present invention, the second engaging portions can be provided at a plurality of positions of the receptacle, and the first engaging portions can be provided at a plurality of positions of the connecting member. In addition, one of the first engagement portion and the second engagement portion may have an engagement protrusion, and the other of the first engagement portion and the second engagement portion may have an engagement recess. . By fitting these engagement projections and engagement recesses, the connection member can be arranged at a plurality of positions in the receptacle.
The connection member can be attached to and detached from the receptacle. As described above, the engaging protrusion and the engaging recess can be formed in each of the receptacle and the connection member without causing a mounting problem. For this reason, the optical data link of the present invention can be mounted on a board as in the related art while enjoying the advantages of the present invention.

Further, in the optical data link according to the present invention, one of the first engaging portion and the second engaging portion has a plurality of engaging projections arranged in a predetermined direction, and The other of the engaging portion and the second engaging portion may have a plurality of engaging concave portions arranged in a predetermined direction. By arranging the connection members in a predetermined direction, it is easy to define the relative position of the connection member with respect to the receptacle at a plurality of positions.

In the optical data link according to the present invention, the connecting member has a contact portion that reaches the receiving space of the receptacle. The contacts allow electrical connection to the outer surface of the optical connector plug when the optical connector plug is optically coupled to the optical data link. For this purpose, the contact part is provided with a conductive coating or is formed of a conductive member. By providing the contact portion, a connection path can be secured electrically with respect to the conductive portion for the electromagnetic shield of the optical connector plug. Thus, when the optical connector plug includes a conductive portion for shielding, the electromagnetic shielding effect is effectively exerted. In such an optical connector plug, it is preferable that a conductive coating, for example, plating or the like be applied to the outer surface as a conductive portion to ensure conductivity.

In the optical data link according to the present invention, the receptacle may include an electromagnetic radiation absorbing means for absorbing electromagnetic radiation generated by the optical data link. This makes it possible to reduce electromagnetic radiation generated in the optical data link without depending on whether or not the optical connector plug has a conductive portion. As the electromagnetic radiation absorbing means, for example, a radio wave absorbing member capable of absorbing radio waves in a range from about 30 MHz to about 10 GHz is preferable. When the optical data link has a plurality of channels, such a radio wave absorbing member is preferably disposed between each channel unit. Thereby, the electromagnetic interference between the channels is reduced.

[0015] In the optical data link according to the present invention, the receptacle may have shielding means for reducing unnecessary radiation radiated from the optical data link. When the receptacle is provided with the shield means, an electromagnetic shield in which unnecessary radiation from the face plate opening can be reduced is achieved.

In order to realize the electromagnetic shield, for example, a conductive coating may be provided on the surface of the receptacle, and the receptacle may be formed of a conductive member.

[0017]

Embodiments of the present invention will be described with reference to the drawings. Where possible, identical parts include:
The same reference numerals are given and duplicate descriptions are omitted.

FIG. 1 is a perspective view of an optical data link according to the present invention. The optical data link 1 includes an optical data link main body 10, a connection member 20, and a receptacle 40. FIG. 1 shows a case where the connecting member 20 is not attached to the receptacle 40 in order to represent the surface of the receptacle 40.

The optical data link main body 10 includes the housing 1
2. The housing 12 has a plurality of lead pins 14 on one side. The optical data link body 10 has an optical connector plug receiving surface facing the direction in which the optical connector plug is inserted (arrow A in FIG. 1). The predetermined shaft 2 extends from the optical connector plug receiving surface to the side where the lead pin 14 is provided. Outer surfaces 12a, 1 of optical data link body 10
2b and 12c extend along the predetermined axis 2. The optical data link main body 10 has an optical element that enables optical communication inside the housing 12. The optical element can be at least one of a light emitting element and a light receiving element. Further, the optical data link body 10 has a signal processing element electrically coupled to the optical element. The optical element is connected to the lead pin 14 via a signal processing element.

The receptacle 40 includes support portions 40a, 40
b, 40c, and 40d. Support portions 40a, 40b,
Each of 40c and 40d includes a plate-like member extending along the predetermined axis 2. Supports 40a, 40b, 40c, 4
Od covers the side surface of the optical data link main body 10 when the receptacle 40 is attached to the optical data link 10.
For this reason, the support parts 40a, 40b, 40c, 40d
An opening into which the optical connector plug is inserted is defined. The support portions 40a, 40b, 40c, and 40d extend along the outer walls 12a, 12b, and 12c of the optical data link main body 10, and further extend along the predetermined axis 2 to receive the optical connector plug. 40e is formed. Since the receiving space 40e is formed along the predetermined axis 2, the receptacle 40 serves as a guide in the direction of introduction of the optical connector plug.

The receptacle 40 includes support portions 40a to 40a
The second engaging portions 42 and 44 can be provided on at least one of the parts d. In the optical data link 1 shown in FIG. 1, the second engagement portions 42 (42a to 42c) and 44 (44a to 44) are provided on the surface of the support portion 40b of the receptacle 40.
c) is provided. Each of the second engagement portion 42 and the second engagement portion 44 has one of a plurality of engagement protrusions and engagement recesses. The second engagement portions 42a to 42c may be recesses or grooves formed to extend in the direction of the support portion 40c from the intersection of the support portion 40b and the support portion 40a along the surface of the support portion 40b. it can. Second engaging portion 4
4a to 44c may be recesses or grooves formed so as to extend in the direction of the support portion 40a from the intersection side of the support portion 40b and the support portion 40c along the surface of the support portion 40b. These recesses or grooves are arranged at predetermined intervals along a predetermined axis 2.

A rectangular hole 5 penetrating from the outer surface to the inner surface of the support portion 40b is formed in the support portion 40b of the receptacle 40.
0 and 52. Instead of the rectangular hole, a cutout can be provided on one side of the support portion 40b.

The connecting member 20 has an upper surface 20a and a pair of side surfaces 20b and 20c. When the connection member 20 is attached to the receptacle 40, the support members 40a, 4a
0b, 40c and the receptacle 40 is at least 3
Surround from the direction. Upper surface portion 20a and side surface portions 20b, 20c
Are each composed of a plate-like piece. The upper surface portion 20a and the side surface portions 20b and 20c are formed of an integral plate-shaped member, and can be formed by bending a predetermined portion from a single plate having the developed shape of the connection member 20.

The connecting member 20 has an upper surface portion 20a and a side surface portion 2a.
The first engagement portions 22a and 22b can be provided along the intersection side with 0b. The connection member 20 is provided on the upper surface 2
0a and the first engaging portion 2 along the intersection side of the side surface portion 20c.
4a, 24b. In FIG. 1, the first engagement portions 22a and 22b are formed by a side surface portion 20b and an upper surface portion 20a.
The first engaging portions 24a and 24b are provided so as to face the side of intersection with the side surface 20c and face in the direction of the side surface portion 20c (inside the connecting member 20). 20a
The convex portion is provided facing the side of the intersection with and faces the direction of the side surface portion 20b (the inside of the connection member 20).

The first engaging portions 22a and 22b are connected to the second engaging portions 42a and 42b, as indicated by broken lines B in FIG.
2b. Similarly, the first engagement portions 24a,
24b, as indicated by a broken line C in FIG.
Are fitted to the engaging portions 44a, 44b. In FIG. 1, the second engagement portions 42a to 42c, 44a to 44c
Are arranged along the predetermined axis 2, so that the convex portion of the first engaging portion can be fitted to the concave portion at a position different from that of the second engaging portion shown in FIG. . In this case, the connection member 20 is attached to the receptacle 40 so that the relative position with respect to the receptacle 40 differs in the predetermined two axial directions.

The connecting member 20 includes side portions 20b and 20
c has a pair of connecting portions 30a. The connection unit 30a
When the connection member 20 is attached to the receptacle 40, the connection member 20 is provided at a position sandwiching the receiving space 40e from both sides, and has a surface that can at least partially contact a surface that intersects the predetermined axis 2. Therefore, it is possible to electrically connect the connecting member to the face plate (the panel of the device to which the optical data link is attached). Connection part 3
It is preferable that Oa be a shape and a material that can be elastically deformed by a force from two directions of the predetermined axis in order to surely make an electrical connection with the face plate. As such a material, a metal material for a spring is preferable. The metal material is
This is because it has conductivity and has excellent workability.

As the connecting portion 30a, there is a conductive connecting piece shown in FIG. Hereinafter, the connection piece 30a will be described. The connection piece 30a can be formed by bending a rectangular piece provided on each of the side surfaces 20b and 20c. In order to form this rectangular piece, the side portions 20a,
At 20c, a rectangular window 30b is formed as a result. In this manner, if the connection pieces 30a extending along the predetermined two axial directions are formed by bending a part of the side surfaces 20a and 20c, the connection member 20 including the connection pieces 30a can be formed into a single plate. Can be formed. This makes it possible to make an electrical connection with the face plate, which is the shield member of the device provided with the optical data link.

The connection member 20 has a contact piece 26 for making an electrical connection to the optical connector plug on the upper surface 20a.
b, 28b are provided on the side surfaces 20b, 20c, respectively. The contact pieces 26b and 28b come into contact with the surface of the optical connector plug inserted into the optical data link to reliably perform the electrical connection between the connection member 20 and the optical connector plug. For this purpose, it is preferable that a conductive coating, such as plating, is provided on the outer surface of the optical connector plug.

FIG. 2 is a perspective view of an optical data link according to the present invention. The receptacle 40 is provided with a fixing projection 41 (41a, 41b) such as a stud pin on the supporting portion 40d.
Have on. The optical data link 1 can be fixed to the mounting board using the fixing protrusions 41a and 41b.

On the surface of the supporting portion 40d of the receptacle 40, the second engaging portions 46 (46a to 46c), 48 (48
a to 48c). Second engagement portion 46
Each of a to 46c and the second engagement portions 48a to 48c can have a plurality of engagement protrusions or engagement recesses. The second engaging portions 46a to 46c may be concave portions or grooves provided along the intersection sides of the support portions 40a and 40d and formed to extend in the direction of the support portions 40c. The second engaging portions 48a to 48c are
It may be a concave portion or a groove formed to extend in the direction of the support portion 40a along the intersection side between the c and the support portion 40d. These recesses or grooves extend along the surface of the support portion 40d, and are arranged at predetermined intervals along the predetermined axis 2 similarly to the second engagement portions 42 and 44. The predetermined interval is, for example, about 2 mm.

The connecting member 20 includes first engaging portions 32a to 3 provided along one side (side facing the side connected to the upper surface portion 20a) extending in the predetermined two axial directions of the side surface portion 20b.
2c. Further, the connection member 20 has one side (the upper surface portion 20 c) of the side surface portion 20 c extending in the predetermined two axial directions.
(a side opposite to the side connected to a) can have first engagement portions 34a to 34c. In FIG.
The first engagement portions 32a to 32c are convex pieces extending from one side of the side surface portion 20b in a direction intersecting the predetermined axis 2,
In addition, the first engagement portions 34a to 34c can be convex pieces extending from one side of the side surface portion 20c in a direction intersecting the predetermined axis 2. First engagement portions 32a to 32c, 34
a to 34c extend along the upper surface portion 20a.

The first engaging portions 32a to 32c are, as shown by broken lines D in FIG.
2c. Similarly, the first engagement portions 34a to 34a
34c, as indicated by a broken line E in FIG.
Are fitted to the engaging portions 48a to 48b.

Second engagement portions 46a-46c, 48a-4
8c are arranged along the predetermined axis 2. For this reason, corresponding to the fitting position in the support portion 40b,
The first engagement portion can be fitted with a second engagement portion at a different position from the second engagement portion shown in FIG. Thereby, only one kind of connection member 20 is prepared,
The connecting member 20 can be attached to a plurality of positions of the receptacle 40.

FIG. 3A is a perspective view showing a state in which the connecting member 20 is attached to the receptacle 40 and the optical data link main body 10. FIG. 3B is a front view as viewed from the direction F in FIG. 3A.

Referring to FIG. 3A, the first engaging portion 2
2a, 22b, 24a, and 24b mesh with the corresponding second engagement portions with 42a, 42b, 44a, and 44b, respectively.

Referring to FIG. 3B, the contact pieces 26b,
28b is a rectangular hole 50 of the receptacle 40,
52 extends to the receiving space 40e. Thus, when the optical data link 1 receives the optical connector plug inserted from the direction F, the contact pieces 26b, 28b extending from the rectangular holes 26a, 28a contact the outer surface of the optical connector plug. One end of each of the sleeves 16a and 16b is provided on the optical connector plug receiving surface so as to protrude. At the other end of the sleeves 16a and 16b, an optical element 18 is provided.
a and 18b are arranged. By this arrangement, the ferrule of the optical connector plug is connected to the sleeve 16a, 1
6b. The sleeve and the ferrule extend along a predetermined axis 2. The pair of the sleeve and the optical element is 1
Defines one communication channel. Optical data link 1 of FIG.
Has two communication channels. The optical connector plug is provided with an engaging claw 19a provided in the receiving space 40e.
19d, the optical connector plug can be fixed to the optical data link.

FIG. 4 is a perspective view of the receptacle 40 to which the connecting member 20 is attached as viewed from the bottom side of the optical data link 1. The connecting member 20 is connected to the third of the receptacles 40.
Surround the surfaces 40a, 40b, 40c. The first engaging portions 32a to 32c and 34a to 34c are fitted to the corresponding second engaging portions at 46a to 46b and 48a to 48c, respectively. By this fitting, the connecting member 2
0 is positioned with respect to the receptacle 40 in the predetermined two axial directions. Further, the connection member 20 is prevented from falling off from the receptacle 40.

FIG. 5A is a perspective view showing a position where the radio wave absorber 60 is disposed in the receptacle 40. FIG. FIG.
FIG. 2B is a perspective view showing an optical data link in which the radio wave absorber 60 is disposed in the receptacle 40 and the connection member 20 is fitted. FIG. 6 is a cross-sectional view taken along the line II of FIG. 5B.

Referring to FIGS. 5A and 5B,
The receptacle 40 has a storage section 56 provided to store the radio wave absorber 60. The radio wave absorber 60 is disposed between the sleeves corresponding to each channel of the optical data link 1, and reduces electromagnetic interference generated between the channels. Such a radio wave absorber 60 functions as a means for absorbing unnecessary radiation. The frequency band to be absorbed is about 30 MHz to 10 GHz in the field of optical communication. As the radio wave absorber, for example, there is a flexible shield IP-L made by TDK. When the connection member 20 is attached so as to cover the receptacle 40, the stored radio wave absorber 60 is held in the receptacle 40.

Referring to FIG. 6, the radio wave absorber 60 is sandwiched between a pair of sleeves 16a and 16b. Storage section 5
6 is to divide the receiving space 40e for each channel,
They are provided along a predetermined axis (2 in FIG. 3). The opening of the storage section 56 is closed by the connection member 20. In the cross-sectional view of FIG. 6, the arms 17a to 17d for connecting the engagement claws 19a to 19d (FIG. 3B) of the receptacle 40 and the receptacle main body are shown.

Although the electromagnetic wave absorbing means 60 is provided to properly perform electromagnetic shielding of the optical data link 1, a conductive coating may be provided on the outer surface of the optical connector plug. Also, a conductive coating can be provided on the surface of the receptacle, and the receptacle 40 can be made of metal. As already described, it is preferable to form the connecting member 20 from a metal plate for structural and electrical reasons.

FIG. 7 is a diagram showing a mode in which the optical data link 1 is used. Optical data link 1
The optical connector plug receiving port is aligned with an opening (face plate opening) 63 provided in a panel (face plate) 62 that is disposed in the housing of the apparatus and constitutes the housing of the apparatus so that the opening 63 is closed. It is fixed on the mounting board 64. The position of the connection member 20 with respect to the receptacle 40 is defined by appropriately combining the first engagement portion and the second engagement portion. Distance L ₀ between optical data link 1 and face plate 62
Can be changed according to the combination of the above-mentioned engaging portions. Electrical connection between the optical data link 1 and the face plate 62 can be maintained by using a connection piece (conductive finger) 30 a provided in the connection member 20.

The receptacle 40 of the optical data link 1 fixed to the mounting board 64 is used to reduce unnecessary radiation radiated from the optical data link 1.
May be provided with a conductive coating, and the receptacle may be formed of a conductive member, for example, a metal. Such a receptacle 40 also functions as electromagnetic shielding means. The receptacle 40 is provided so that the shield means closes the face plate opening 63 when the optical data link 1 is mounted on a device such as an optical communication device. Connecting piece 30
a, the unnecessary radiation from other electronic components in the device in which the optical data link 1 is housed is transmitted from the face plate opening 63 to the surface of the device. Leakage to the outside can also be reduced.

The optical connector plug 66 is connected to an optical transmission line 68 having a plurality of optical fibers 68a, 68b. The optical connector plug 66 is inserted into the optical data link 1 in the direction of arrow G. Optical connector plug 66
Ferrule 70 provided in each of the pair of connector ports
a and 70b are sleeves of the optical data link 1 (FIG. 3)
It is inserted into 16a and 16b) of (b).

[0045]

As described above in detail, in the optical data link according to the present invention, the connection member is provided so that the relative position of the connection member with respect to the receptacle can be defined at a plurality of positions in a predetermined direction. A first engaging portion is provided, and a second engaging portion is provided on a support portion of the receptacle.

By combining the first engaging portion and the second engaging portion, the relative position of the connecting member with respect to the receptacle can be defined at a plurality of positions in a predetermined direction.

Accordingly, there has been provided an optical data link capable of satisfying a wide range of mounting requirements.

[Brief description of the drawings]

FIG. 1 is a perspective view of an optical data link according to an embodiment of the present invention.

FIG. 2 is a perspective view of an optical data link according to the embodiment of the present invention.

FIG. 3A is a perspective view showing a state where a connecting member is attached to a receptacle and an optical data link main body. FIG. 3B is a front view as viewed from the direction F in FIG. 3A.

FIG. 4 is a perspective view of the receptacle to which the connecting member is attached and the optical data link main body as viewed from the bottom side of the optical data link.

FIG. 5A is a perspective view showing a position where a radio wave absorber is arranged in a receptacle. FIG. 5B is a perspective view showing an optical data link in which a radio wave absorber is arranged in a receptacle and a connecting member is fitted.

FIG. 6 is a cross-sectional view taken along the line II of FIG. 5B.

FIG. 7 is a diagram illustrating a mode in which an optical data link according to the present invention is used.

8 (a) and 8 (b) are side views showing a form when a conventional optical data link is mounted.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 ... Optical data link, 10 ... Optical data link main body, 12
... Housing, 14 ... Lead pin, 20 ... Connection member, 2
0a: upper surface, 20b: side surface, 22, 24, 32, 3
4 first engagement portion, 26b, 28b contact piece, 30a
Connection piece, 30b: rectangular window, 40: receptacle, 40
a, 40b, 40c, 40d: Supporting parts, 42, 44, 4
6, 48 ... second engaging portion, 50, 52 ... rectangular hole, 60 ...
Radio wave absorber

Claims (7)

[Claims] 1. An optical data link main body optically connectable to an optical connector plug inserted from a predetermined direction, attached to the optical data link main body, in the predetermined direction along the optical data link main body. A receptacle having an extending support portion and guiding the insertion direction of the optical connector plug; and a connection member having a first engagement portion for defining an attachment position to the receptacle, the connection member being attached to the receptacle, An optical data link comprising: the receptacle has a second engagement part on the support part, and the first engagement part and the second engagement part are the connection member with respect to the receptacle. The optical data link is provided so as to define a relative position at a plurality of positions in the predetermined direction. 2. The connection member according to claim 1, wherein the connection member has a contact portion that enables an electrical connection to the optical connector plug when the optical connector plug is optically coupled to the optical data link. Optical data link as described. 3. The optical data link according to claim 1, wherein the receptacle has electromagnetic radiation absorbing means for absorbing electromagnetic radiation generated by the optical data link. 4. One of the first engagement portion and the second engagement portion has an engagement protrusion, and the other of the first engagement portion and the second engagement portion is engaged. The optical data link according to any one of claims 1 to 3, wherein the optical data link has a concave portion. 5. One of the first engagement portion and the second engagement portion has a plurality of engagement protrusions arranged in the predetermined direction. The optical data link according to any one of claims 1 to 4, wherein the other of the second engagement portions has a plurality of engagement recesses arranged in the predetermined direction. 6. The optical data link according to claim 1, wherein the receptacle has a portion provided with a conductive coating. 7. The optical data link according to claim 1, wherein said receptacle is formed of a conductive member.