JP6755754B2 - Optical module and optical transmission device - Google Patents

Description

The present invention relates to an optical module and an optical transmission device.

As an optical module used for optical fiber communication, a module having a removable pluggable structure is known in order to facilitate replacement due to breakage or performance deterioration (see Patent Documents 1 and 2). Such an optical module can be attached to and detached from a cage mounted on a circuit board having an electronic circuit, and an engaging portion that is hooked on a claw formed in the cage is used to prevent the optical module from coming off the cage. ing. The retaining is released by the slider of the optical module.

Japanese Unexamined Patent Publication No. 2008-257235 Japanese Unexamined Patent Publication No. 2008-23645

In recent years, in addition to an increase in the amount of signal transmission, the transmission speed has increased, and the operating frequency of electric signals has increased. When the operating frequency was low, it was possible to suppress electromagnetic interference even if the gap between the optical module and the cage was slightly large. However, when the operating frequency becomes high, even if the gap between the optical module and the cage is small, electromagnetic waves are emitted to the outside of the host device through this gap.

An object of the present invention is to enhance the shielding function against electromagnetic interference.

(1) The optical module according to the present invention is an optical module that can be attached to and detached from a cage, and includes a module case and a slider that is attached to the outside of the module case to release the retaining from the cage. It is characterized by having a leakage reduction layer that is interposed between the module case and the slider to reduce leakage of electromagnetic waves. According to the present invention, the electromagnetic wave leaking between the module case and the slider can be reduced by the leakage reduction layer, so that the shielding function against electromagnetic interference can be enhanced.

(2) The optical module according to (1), wherein the leakage reduction layer has higher elasticity than the surface of the electromagnetic wave absorber that converts the energy of the electromagnetic wave into thermal energy and the surface of the module case. It may be characterized in that it is configured as described above and is composed of one of the conductors that shield the electromagnetic wave.

(3) The optical module according to (2), wherein the electromagnetic wave absorber absorbs the electromagnetic wave by a resistor that absorbs a current generated by the electromagnetic wave and a dielectric loss caused by a polarization reaction of a molecule. It may be characterized by being one substance selected from the group consisting of a dielectric material that absorbs the electromagnetic wave and a magnetic material that absorbs the electromagnetic wave due to the magnetic loss of the magnetic material.

(4) The optical module according to (2), wherein the conductor may be a metal cloth.

(5) The optical module according to (3), wherein the resistor may have a conductivity of 1 S / m or more and 1000 S / m or less.

(6) The optical module according to any one of (1) to (5), wherein the cage has a shield finger provided so as to come into contact with the optical module and electromagnetically shield it. However, the leakage reduction layer may be characterized in that, when the optical module is mounted on the cage, at least a part thereof is provided at a position facing the contact portion between the shield finger and the optical module.

(7) The optical module according to (6), wherein the cage has an insertion port for inserting the optical module, and the shield finger is adjacent to the insertion port and inside the cage. It may be characterized by being provided in.

(8) The optical module according to (7), characterized in that the leakage reduction layer is provided so as to have a portion extending in a direction from the position facing the contact portion toward the insertion port. May be.

(9) In the optical module according to (7) or (8), the leakage reduction layer is provided so as to have a portion extending in a direction away from the insertion port from the position facing the contact portion. It may be characterized by being

(10) The optical transmission device according to the present invention has an optical module and a first shield finger provided so as to contact and electromagnetically shield the optical module so that the optical module can be attached and detached. The optical module has a configured cage, the optical module is mounted on a module case, a slider attached to the outside of the module case to release the retaining from the cage, and the optical module mounted on the cage. When this is done, it is characterized by having a leakage reduction layer that is interposed between the module case and the slider at a position facing the first shield finger to reduce leakage of electromagnetic waves. According to the present invention, the electromagnetic wave leaking between the module case and the slider can be reduced by the leakage reduction layer, so that the shielding function against electromagnetic interference can be enhanced.

(11) The optical transmission device according to (10), further comprising a circuit board on which the cage is mounted and a front plate having a hole into which an end portion of the cage is inserted. It may be characterized by having a second shield finger provided so as to come into contact with the edge of the hole in the front plate and electromagnetically shield it.

(12) The optical transmission device according to (11) may be characterized in that the first shield finger and the second shield finger are in overlapping positions.

It is a perspective view which shows a part of the optical transmission apparatus which concerns on embodiment of this invention. It is a side view of the optical transmission apparatus shown in FIG. FIG. 3 is a sectional view taken along line III-III of the optical transmission device shown in FIG. FIG. 3 is an enlarged schematic view of a part of the optical transmission device shown in FIG. It is a perspective view which shows the optical module which concerns on embodiment of this invention. It is an exploded perspective view of the optical module shown in FIG. It is the schematic of the VII-VII line cross section of the optical module shown in FIG. It is a figure which shows the modification 1 of the optical transmission apparatus and an optical module which concerns on embodiment of this invention. It is a figure which shows the modification 2 of the optical transmission apparatus and an optical module which concerns on embodiment of this invention. It is a figure which shows the modification 3 of the optical transmission apparatus and the optical module which concerns on embodiment of this invention. It is a figure which shows the modification 4 of the optical transmission apparatus and an optical module which concerns on embodiment of this invention. It is a figure which shows the modification 5 of the optical transmission apparatus and an optical module which concerns on embodiment of this invention. It is a figure which shows the modification 6 of the optical transmission apparatus and an optical module which concerns on embodiment of this invention.

Hereinafter, embodiments of the present invention will be described with reference to the drawings. FIG. 1 is a perspective view showing a part of an optical transmission device according to an embodiment of the present invention. FIG. 2 is a side view of the optical transmission device shown in FIG. FIG. 3 is a sectional view taken along line III-III of the optical transmission device shown in FIG.

The optical transmission device has a circuit board 10. A large number of cages 12 are mounted on the circuit board 10, and one of them is shown in FIG. The end of the cage 12 is inserted into the hole 16 of the front plate 14. Since the front plate 14 is the frame of the cage 12, it is also called a bezel. The cage 12 has an insertion port 20 (see FIG. 4) for inserting the optical module 18, and is hollow so that the optical module 18 can be attached and detached. The cage 12 is made of a conductor such as metal, and is connected to the ground potential by the circuit board 10. Although not particularly limited, here, one cage 12 accommodates one optical module 18. In the insertion direction of the optical module 18, an electric connector (not shown) fixed to the circuit board 10 and electrically connected is arranged behind the cage 12 to serve as a guide for the optical module 18. .. A heat spreader 22 is attached to the cage 12 in order to enhance the heat dissipation effect, so that the heat of the optical module 18 is dissipated.

FIG. 4 is an enlarged schematic view of a part of the optical transmission device shown in FIG. The cage 12 has a first shield finger 24. The first shield finger 24 is provided so as to come into contact with the optical module 18 and electromagnetically shield it. The first shield finger 24 is provided inside the cage 12 adjacent to the insertion port 20 of the cage 12. FIG. 4 shows a pair of first shield fingers 24 that sandwich the optical module 18 in the horizontal direction, and may further provide a pair of first shield fingers (not shown) that sandwich the optical module 18 in the vertical direction. The first shield finger 24 is formed of, for example, a piece of metal.

The cage 12 has a second shield finger 26. The second shield finger 26 is provided so as to come into contact with the edge (inner surface) of the hole 16 of the front plate 14 and electromagnetically shield it. FIG. 4 shows a pair of second shield fingers 26 projecting in opposite directions in the lateral direction, and a pair of second shield fingers 26 projecting in opposite directions in the vertical direction (see FIG. 1). May be provided. The second shield finger 26 is formed of, for example, a piece of metal.

The first shield finger 24 and the second shield finger 26 are in overlapping positions as shown in FIG. Therefore, the positions for shielding electromagnetic waves overlap on the inside and outside of the cage 12, and the effect is high. The first shield finger 24 and the second shield finger 26 are bent so as to project in opposite directions from the inner surface and the outer surface of the cage 12, respectively. In the example shown in FIG. 4, the first shield finger 24 and the second shield finger 26 are integrated to form a clip, and are fixed by sandwiching the end portion of the cage 12.

FIG. 5 is a perspective view showing an optical module 18 according to an embodiment of the present invention. FIG. 6 is an exploded perspective view of the optical module 18 shown in FIG. The optical module 18 has an internal optical subassembly (not shown) for converting at least one optical signal and an electrical signal from the other. As an optical subassembly, an optical transmitter module (TOSA; Transmitter Optical Subassembly) that has a light emitting element such as a semiconductor laser inside and converts an electric signal into an optical signal and transmits it, and a light receiving element represented by a photodiode inside. There is an optical receiver module (ROSA; Receiver Optical Subassembly) that converts the received optical signal into an electric signal, and BOSA (Bidirectional Optical Subassembly) that includes both of these functions. The optical module 18 includes a QSFP (Quad Small Form-Factor Pluggable) type and a CFP (C Form-Factor Pluggable) type. The optical module 18 is inserted into the cage 12 of the optical transmission device and can be plugged (pluggable).

The optical module 18 has a module case 30 including an optical port 28. The optical port 28 is adapted to insert an optical fiber (not shown). When the optical module 18 is attached to the cage 12, it is prevented from coming off. Specifically, the cage 12 has a lock tab 32 (see FIG. 2) that projects to the side where the optical module 18 is arranged (inside the cage 12). On the other hand, the optical module 18 has a lock portion 34 with a lock tab 32 (FIGS. 5 and 6).

A groove 36 is formed on the side surface of the module case 30. The groove 36 extends in the insertion direction of the optical module 18, and the end surface on the back side when inserted is the lock portion 34. The lock portion 34 is arranged behind the lock tab 32 (FIG. 2) when the optical module 18 is attached to the cage 12. As a result, the lock tab 32 and the lock portion 34 are engaged with each other, and the optical module 18 can be prevented from coming off.

The optical module 18 has a slider 38 for releasing the retaining from the cage 12. A pair of sliders 38 are attached to both sides of the module case 30. The slider 38 can be moved between the module case 30 and the cage 12 along the mounting direction of the optical module 18 to the cage 12. Each of the pair of sliders 38 is guided by the groove 36 of the module case 30 and arranged so as to be slidable in the length direction. The moving direction of the slider 38 is regulated by the groove 36. The slider 38 has a convex portion 40 that projects outward.

When removing the optical module 18, the slider 38 is slid. A handle 42 made of rubber or the like is fixed to the slider 38, and the slider 38 can be slid by pulling the handle 42. The pulling direction is the pulling direction of the optical module 18. Then, the convex portion 40 of the slider 38 pushes and expands the lock tab 32 (FIG. 2) from the inside to the outside to unlock the lock tab 32 and the lock portion 34. In this way, the optical module 18 can be removed from the cage 12.

The module case 30 is made of a conductor such as metal, and shields most of the electromagnetic waves generated from the parts housed inside the module case 30. However, electromagnetic waves are radiated to the outside of the module case 30 from an opening for connecting to an electric connector (not shown). A part of this electromagnetic wave is transmitted through the gap between the module case 30 and the cage 12, and the electromagnetic wave is also transmitted between the module case 30 and the slider 38. This electromagnetic wave passes between the module case 30 and the slider 38 and is emitted to the outside of the front plate 14, causing an increase in the amount of electromagnetic wave emitted by the optical transmission device as a whole.

FIG. 7 is a schematic view of a cross section of the optical module 18 shown in FIG. 5 along lines VII-VII. The optical module 18 has a leakage reduction layer 44. The leakage reduction layer 44 is interposed between the module case 30 and the slider 38 to reduce the leakage of electromagnetic waves. For example, electromagnetic waves can be blocked or absorbed. The leakage reduction layer 44 may be attached to the module case 30 with an adhesive (for example, double-sided tape) (not shown). In the example of FIG. 7, there is a groove 36 on the side surface of the module case 30, and a leakage reduction layer 44 is provided between the bottom surface of the groove 36 and the slider 38. As a modification, if a leakage reduction layer can be provided in a narrow region between the inner surface 37 rising from the bottom surface of the groove 36 and the end surface of the slider 38, the leakage of electromagnetic waves can be further reduced.

The leakage reduction layer 44 may be an electromagnetic wave absorber that converts electromagnetic wave energy into thermal energy. Alternatively, the electromagnetic wave absorber may be a resistor that absorbs the current generated by the electromagnetic wave by a resistor. For example, a resistor having a conductivity of 1 S / m or more and 1000 S / m or less can be used. Alternatively, the leakage reduction layer 44 may be a dielectric material that absorbs electromagnetic waves due to a dielectric loss caused by a polarization reaction of molecules, or may be a magnetic material that absorbs electromagnetic waves due to a magnetic loss of a magnetic material. The leakage reduction layer 44 may be a conductor that shields electromagnetic waves. If the conductor is configured to have higher elasticity than the surface of the module case 30, the contact area with the slide becomes large, so that the effect of shielding electromagnetic waves is enhanced. An example of the leakage reduction layer 44 made of a conductor is a metal cloth (a knitted metal thread or a non-woven fabric made of metal). As another example, the fibers of the insulator are metal-plated or metal-deposited. Not limited to these examples, any cloth having conductivity can obtain the effect of the present invention.

Further, the leakage reduction layer 44 made of a conductor may be a conductive resin or a conductive paste containing a conductive filler such as metal powder or carbon powder inside.

As shown in FIG. 4, the leakage reduction layer 44 is provided at a position where at least a part of the leakage reduction layer 44 faces the contact portion between the first shield finger 24 and the optical module 18 when the optical module 18 is mounted on the cage 12. .. The leakage reduction layer 44 has a portion facing the inner surface of the hole 16 of the front plate 14. Further, the leakage reduction layer 44 has a portion extending in a direction away from the insertion port 20 from a position facing the contact portion between the first shield finger 24 and the optical module 18. The leakage reduction layer 44 extends slightly in the opposite direction (direction toward the insertion port 20), but this portion may be omitted. That is, the leakage reduction layer 44 may be formed so as not to have a portion extending in the direction of the insertion port 20 from the position facing the contact portion between the first shield finger 24 and the optical module 18.

According to the present embodiment, the electromagnetic wave leaking between the module case 30 and the slider 38 can be reduced by the leakage reduction layer 44, so that the shielding function against electromagnetic interference can be enhanced.

FIG. 8 is a diagram showing a modification 1 of the optical transmission device and the optical module according to the embodiment of the present invention. In this example, the portion of the leakage reduction layer 144 extending in the direction opposite to the insertion port 120 is shorter than that in the example of FIG. For example, the leakage reduction layer 144 may be provided only at a position facing the contact portion between the first shield finger 124 and the optical module 118. In that case, the leakage reduction layer 144 does not have a portion extending in a direction away from the insertion port 120 from a position facing the contact portion between the first shield finger 124 and the optical module 118. Other contents are as described in the above embodiment, and the optical transmission device according to the first modification includes the optical module 118 of the first modification.

FIG. 9 is a diagram showing a modification 2 of the optical transmission device and the optical module according to the embodiment of the present invention. In this example, the leakage reduction layer 244 has a portion extending in the direction approaching the insertion port 220 longer than that in the example of FIG. 4 or FIG. The leakage reduction layer 244 has a portion extending in the direction toward the insertion port 220 from a position facing the contact portion between the first shield finger 224 and the optical module 218. Further, the leakage reduction layer 244 has a portion facing the hole 216 of the front plate 214, and extends so as to reach the outside of the front plate 214. Other contents are as described in the above embodiment, and the optical transmission device according to the modified example 2 includes the optical module 218 of the modified example 2.

FIG. 10 is a diagram showing a modification 3 of the optical transmission device and the optical module according to the embodiment of the present invention. In this example, the first shield finger 324 and the second shield finger 326 are in non-overlapping positions. Specifically, the first shield finger 324 in contact with the optical module 318 is farther from the insertion port 320 of the cage 312 than the second shield finger 326. Alternatively, the second shield finger 326 that contacts the edge of the hole 316 of the front plate 314 is closer to the insertion port 320 of the cage 312 than the first shield finger 324. The leakage reduction layer 344 is located at a position facing the contact portion between the first shield finger 324 and the optical module 318, without facing the second shield finger 326. Other contents are as described in the above embodiment, and the optical transmission device according to the modified example 3 includes the optical module 318 of the modified example 3.

FIG. 11 is a diagram showing a modified example 4 of the optical transmission device and the optical module according to the embodiment of the present invention. This example differs from the structure shown in FIG. 4 in that the cage 412 does not have a second shield finger. Specifically, the cage 412 is arranged so as to be adjacent to the back surface of the cage 412 without being inserted into the hole 416 of the front plate 414 so that the insertion port 420 and the hole 416 of the front plate 414 communicate with each other. A gasket 446 is interposed between the cage 412 and the front plate 414. A conductive sponge or the like (not shown) may be arranged between the gasket 446 and the front plate 414. The gasket 446 is fixed to the end of the cage 412. Other contents are as described in the above embodiment.

FIG. 12 is a diagram showing a modified example 5 of the optical transmission device and the optical module according to the embodiment of the present invention. In this example, the leakage reduction layer 544 is farther from the insertion port 520 and the insertion port 520 from the position facing the contact portion between the first shield finger 524 and the optical module 518, as compared with the modification 4 shown in FIG. Each length extending in the direction is short.

FIG. 13 is a diagram showing a modification 6 of the optical transmission device and the optical module according to the embodiment of the present invention. In this example, the leakage reduction layer 644 is separated from the insertion port 620 and the insertion port 620 from the position facing the contact portion between the first shield finger 624 and the optical module 618, as compared with the modification 5 shown in FIG. The length extending in the direction is even shorter. The leakage reduction layer 644 may be provided only at a position facing the contact portion between the first shield finger 624 and the optical module 618.

The present invention is not limited to the above-described embodiment, and various modifications are possible. For example, the configurations described in the embodiments can be replaced with substantially the same configurations, configurations that exhibit the same effects, or configurations that can achieve the same objectives.

10 Circuit board, 12 cages, 14 front plates, 16 holes, 18 optical modules, 20 insertion holes, 22 heat spreaders, 24 1st shield fingers, 26 2nd shield fingers, 28 optical ports, 30 module cases, 32 lock tabs, 34 locks Part, 36 groove, 38 slider, 40 convex part, 42 handle, 44 leakage reduction layer, 118 optical module, 120 insertion port, 124 1st shield finger, 144 leakage reduction layer, 218 optical module, 220 insertion port, 224 1st Shield finger, 244 leak reduction layer, 312 cage, 314 front plate, 316 hole, 318 optical module, 320 insertion port, 324 first shield finger, 326 second shield finger, 344 leak reduction layer, 421 cage, 414 front plate, 416 holes, 420 insertion holes, 446 gaskets, 518 optical modules, 520 insertion ports, 524 first shield fingers, 544 leak reduction layers, 618 optical modules, 620 insertion ports, 624 first shield fingers, 644 leak reduction layers.

Claims (12)

An optical module that can be attached to and detached from the cage.
Module case and
A slider attached to the outside of the module case to release the retainer from the cage,
A leakage reduction layer that is interposed between the module case and the slider to reduce leakage of electromagnetic waves,
Have,
The leakage reduction layer has a plate shape and is attached so as not to move with respect to the module case.
The optical module is characterized in that the slider is movable with respect to the leakage reduction layer. The optical module according to claim 1.
The leakage reduction layer is composed of an electromagnetic wave absorber that converts the energy of the electromagnetic wave into heat energy, or a conductor that is configured to have higher elasticity than the surface of the module case and shields the electromagnetic wave. An optical module characterized by that. The optical module according to claim 2.
The electromagnetic wave absorber absorbs the electromagnetic wave by a resistor that absorbs the current generated by the electromagnetic wave by a resistor, a dielectric that absorbs the electromagnetic wave by a dielectric loss due to a polarization reaction of molecules, and a magnetic loss of a magnetic material. An optical module characterized by being a magnetic material and a substance selected from the group consisting of. The optical module according to claim 2.
An optical module characterized in that the conductor is a metal cloth. The optical module according to claim 3.
The resistor is an optical module having a conductivity of 1 S / m or more and 1000 S / m or less. The optical module according to any one of claims 1 to 5.
The cage has a shield finger provided to contact and electromagnetically shield the optical module.
The optical module is characterized in that, when the optical module is mounted on the cage, at least a part of the leakage reduction layer is provided at a position facing a contact portion between the shield finger and the optical module. The optical module according to claim 6.
The cage has an insertion slot for inserting the optical module.
The shield finger is an optical module characterized in that it is provided inside the cage adjacent to the insertion port. The optical module according to claim 7.
The optical module is characterized in that the leakage reduction layer is provided so as to have a portion extending in a direction toward the insertion port from the position facing the contact portion. The optical module according to claim 7 or 8.
The optical module is characterized in that the leakage reduction layer is provided so as to have a portion extending in a direction away from the insertion port from the position facing the contact portion. Optical module and
A cage having a first shield finger provided so as to come into contact with the optical module and electromagnetically shield the optical module so that the optical module can be attached and detached.
Have,
The optical module
Module case and
A slider attached to the outside of the module case to release the retainer from the cage,
When the optical module is mounted on the cage, a leakage reduction layer that is interposed between the module case and the slider at a position facing the first shield finger to reduce the leakage of electromagnetic waves.
Have,
The leakage reduction layer has a plate shape and is attached so as not to move with respect to the module case.
An optical transmission device characterized in that the slider is movable with respect to the leakage reduction layer. The optical transmission device according to claim 10.
The circuit board on which the cage is mounted and
A front plate with a hole into which the end of the cage is inserted,
Have more
An optical transmission device, wherein the cage has a second shield finger provided so as to come into contact with the edge of the hole in the front plate and electromagnetically shield the cage. The optical transmission device according to claim 11.
An optical transmission device characterized in that the first shield finger and the second shield finger are located at overlapping positions.

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