JP2015176993A - optical amplifier module - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an optical amplifier module which can be made compact while ensuring heat dissipation.SOLUTION: An optical amplifier module 3 includes a rectangular parallelepiped housing 33 having first and second heat sinks 331, 332, arranged oppositely, as side plates, and a booster amplifier units 15, 16 housed between the first and second heat sinks 331, 332 in the housing 33. The booster amplifier unit 15 is attached to the first heat sink 331, and the heat generated is dissipated therefrom by heat transfer. The booster amplifier unit 16 is attached to the second heat sink 332, and the heat generated is dissipated therefrom by heat transfer. The booster amplifier units 15, 16 are partially overlapped in the facing direction of the first and second heat sinks 331, 332.

Description

  The present invention relates to an optical amplifier module that amplifies an optical signal propagating through an optical fiber.

  2. Description of the Related Art Conventionally, an optical transmission apparatus that is disposed at a relay station that is interposed in an optical transmission line having a transmission distance of, for example, 100 km or more and that amplifies an attenuated optical signal and transmits it downstream is used for wide area network communication. The optical transmission device includes a plurality of optical amplifier units having an optical signal amplification function (see, for example, Patent Document 1).

  The optical transmission device described in Patent Literature 1 includes an upstream processing unit that amplifies an upstream optical signal and a downstream processing unit that amplifies a downstream optical signal, and each processing unit includes an optical amplifier unit. Has been placed. The plurality of optical amplifiers in the optical transmission apparatus configured as described above are arranged in a casing together with peripheral circuit components, and are cooled by forced air cooling using a cooling fan.

JP 2003-163642 A

  In view of the recent increase in communication speed and capacity in communication networks such as the Internet, the need to arrange a large number of optical transmission devices in a limited installation space in a relay station or the like requires a reduction in the size of the optical transmission device. ing. The downsizing of the device and the heat dissipation of the optical amplifier unit are contradictory issues. If the device is simply downsized, the heat dissipation of the optical amplifier unit is lost, and the characteristics of the optical amplifier unit due to the heat degradation of There is a risk of causing damage.

  Therefore, an object of the present invention is to provide an optical amplifier module that can be reduced in size while ensuring heat dissipation.

  In order to solve the above-described problems, the present invention provides a rectangular parallelepiped housing having first and second heat radiating plates disposed as opposed to each other as side plates, and the first and second housings in the housing. First and second amplifier units housed between heat sinks, wherein the first amplifier unit is attached to the first heat sink and the generated heat is thermally transferred to the first heat sink. The second amplifier unit is attached to the second heat radiating plate, and the generated heat is radiated from the second heat radiating plate by heat conduction, and the first and second amplifier units are An optical amplifier module is provided in which the first heat radiating plate and the second heat radiating plate are partially overlapped with each other in a facing direction.

  With the optical amplifier module according to the present invention, it is possible to reduce the size while ensuring heat dissipation.

It is a perspective view which shows the external appearance of the optical transmission apparatus with which the optical amplifier module which concerns on embodiment of this invention is mounted. It is the sectional view on the AA line of FIG. It is the perspective view which looked at the optical amplifier module from diagonally upward. It is the perspective view which looked at the optical amplifier module from the opposite side to FIG. The housing | casing which abbreviate | omitted the front panel is shown, (a) is the perspective view seen from the 1st heat sink side, (b) is the perspective view seen from the 2nd heat sink side. It is the side view which removed the side plate and looked at the inside of a case. It is the top view which showed the optical amplifier module of the state which arranged the some optical fiber, and looked at the 1st heat sink side from the 2nd heat sink side. It is the top view which showed the optical amplifier module of the state which arranged the some optical fiber and the some connection cable, removed the 1st heat sink and looked at the 2nd heat sink side. It is the top view which showed the optical amplifier module of the state which arranged the some optical fiber and the some connection cable, removed the 2nd heat sink, and looked at the 1st heat sink side.

[Embodiment]
An optical transmission device equipped with an optical amplifier module according to an embodiment of the present invention is installed, for example, in a terminal station or a relay station of an optical transmission line having a transmission distance of 100 km or more.

(Configuration of optical transmission device 1)
First, the configuration of the optical transmission device 1 will be described with reference to FIGS. 1 and 2.

  FIG. 1 is a perspective view showing an external appearance of an optical transmission device 1 on which an optical amplifier module 3 according to an embodiment of the present invention is mounted. 2 is a cross-sectional view taken along line AA in FIG.

  The optical transmission device 1 includes a substantially box-shaped chassis 2, and a plurality (two in the present embodiment) of optical amplifier modules 3 (seconds) in an accommodation space 20 (shown in FIG. 2) formed in the chassis 2. The first optical amplifier module 3a and the second optical amplifier module 3b) and various modules 10 necessary for optical transmission are detachably accommodated. The optical transmission device 1 can flexibly cope with required communication specifications by appropriately selecting a module to be mounted on the chassis 2.

  An optical signal transmitted from one terminal station is input to the first optical amplifier module 3a, amplified in the first optical amplifier module 3a, and then input to a dispersion compensator (not shown). The optical signal distorted by the chromatic dispersion of the optical fiber in the optical transmission line is compensated for the distortion by the dispersion compensator having the inverse chromatic dispersion characteristic. The optical signal output from the dispersion compensator is the second optical amplifier. After being amplified in the module 3b, it is sent to the other terminal station side.

  The optical signal transmitted from the other terminal station is transmitted to the one terminal station via the second optical amplifier module 3b, the dispersion compensator, and the first optical amplifier module 3a.

  The optical amplifier module 3 includes a rectangular parallelepiped housing 33 having first and second heat radiating plates 331 and 332 arranged as opposed to each other as side plates. More specifically, the housing 33 has a rectangular parallelepiped shape elongated in the depth direction of the chassis 2 (the direction of arrow B in FIG. 2). In FIG. 2, the first and second heat radiating plates 331 and 332 face each other in the height direction orthogonal to the depth direction of the chassis 2.

  In addition, the housing 33 includes a side plate 333 that connects the first heat radiating plate 331 and the second heat radiating plate 332 in the height direction of the chassis 2, and a front panel formed of a conductive metal plate such as aluminum. 34. The front panel 34 is provided on one end side in the longitudinal direction of the housing 33 (in the direction of arrow B in FIG. 2), and includes a plurality of optical connector adapters (only the optical connector adapter 120A is shown in FIG. 2) and the housing 33 as a chassis. A screw 32 for fixing to 2 is attached.

  The optical amplifier module 3 is inserted by being slid into the accommodation space 20 from the side opposite to the front panel 34 in the longitudinal direction of the housing 33. When the mounting of the optical amplifier module 3 to the chassis 2 is completed, the module-side connector 18 provided at one end on the opposite side of the front panel 34 in the longitudinal direction of the housing 33 is located on the back side in the housing space 20 of the chassis 2. The chassis side connector 6 provided is fitted.

  The chassis side connector 6 is mounted on the mother board 5 attached in the accommodation space 20 via the attachment plate 4. The optical amplifier module 3 receives power supply through the mother board 5 and the chassis side connector 6 and transmits and receives various electric signals.

  The chassis 2 has an opening 2c formed in a rear wall 2b provided on the side opposite to the insertion port 2a for inserting the optical amplifier module 3, and air in the chassis 2 is exposed to the outside in the vicinity of the opening 2c. A fan 7 for discharging is attached. Thereby, the optical amplifier module 3 is air-cooled in the housing space 20 of the chassis 2.

(Configuration of optical amplifier module 3)
Next, the configuration of the optical amplifier module 3 will be described with reference to FIGS.

  FIG. 3 is a perspective view of the optical amplifier module 3 as viewed obliquely from above. FIG. 4 is a perspective view of the optical amplifier module 3 as viewed from the opposite side to FIG. 5 shows the housing 33 from which the front panel 34 is omitted, FIG. 5A is a perspective view seen from the first heat radiating plate 331 side, and FIG. 5B is the second heat radiating plate 332 side. It is the perspective view seen from.

  The optical amplifier module 3 is formed in a rectangular parallelepiped box shape by a housing 33 and a substrate 31 extending in the depth direction of the chassis 2 (the direction of arrow B in FIG. 2). Therefore, the substrate 31 has a function as a side plate of the housing 33.

  The housing 33 includes a front panel 34, a first heat radiating plate 331, a second heat radiating plate 332, a side plate 333, a back plate 334, and a front plate 335 (shown in FIG. 5). .

  The back plate 334 is disposed so as to face the front panel 34 in the depth direction of the chassis 2. The front plate 335 is disposed between the front panel 34 and the back plate 334 in the depth direction of the chassis 2. That is, the back plate 334 is disposed so as to face the front panel 34 and the front plate 335 in the depth direction of the chassis 2.

  The first heat radiating plate 331 and the second heat radiating plate 332 are arranged so as to connect the back plate 334 and the front plate 335 in the depth direction of the chassis 2 and face each other in the height direction of the chassis 2 so as to be parallel to each other. Has been.

  As shown in FIGS. 5A and 5B, the first heat radiating plate 331, the second heat radiating plate 332, and the side plate 333 have one end in the longitudinal direction on the back plate 334 and the other end on the other end. Each is fixed to the front plate 335 by a plurality of screws 117. In the present embodiment, as shown in FIG. 5B, the second heat radiating plate 332 and the side plate 333 are integrated perpendicularly to each other.

  The substrate 31 is a rigid substrate formed of, for example, a glass epoxy resin that has been subjected to thermosetting treatment, faces the side plate 333 of the housing 33, and is opposed to the first and second heat radiating plates 331 and 332. It arrange | positions so that it may orthogonally cross. Various electronic components 311 such as a CPU and a connector 312 for data transfer are mounted on a mounting surface 31 a opposite to the mounting surface facing the side plate 333 in the substrate 31.

  As shown in FIG. 4, the substrate 31 is provided with a module-side connector 18 connected to the chassis-side connector 6 (see FIG. 2) at an end portion on the back plate 334 side in the longitudinal direction, and the end portion includes two screws. 19 is fixed to the back plate 334. Further, as shown in FIGS. 5A and 5B, the back plate 334 is formed with a recess 334 a for projecting the module-side connector 18 to the outside of the optical amplifier module 3.

  As shown in FIG. 3, a first rail member 131 extending from the front panel 34 side toward the back plate 334 side is attached to the first heat radiating plate 331. The first rail member 131 includes a horizontal member 131a parallel to the first heat radiating plate 331 and a vertical member 131b orthogonal to the first heat radiating plate 331, and the cross section has an L shape. .

  As shown in FIG. 4, a second rail member 132 extending from the front panel 34 side toward the back plate 334 side is attached to the second heat radiating plate 332. Similar to the first rail member 131, the second rail member 132 includes a horizontal member 132a and a vertical member 132b, and has a L-shaped cross section.

  As shown in FIG. 3, the front panel 34 includes a main body 34a to which a plurality of (six in this embodiment) optical connector adapters 120A to 120F are attached, and a side plate 333 side of the housing 33 in the main body 34a. It has flange portions 34b and 34c formed by folding the end portion and the end portion on the substrate 31 side toward the back plate 334 side.

  As shown in FIG. 3, the flange 34 b on the side plate 333 side is fixed to the side plate 333 by a plurality (six in this embodiment) of screws 340 b. As shown in FIG. 4, a columnar spacer 340 c is fixed to the flange portion 34 c on the substrate 31 side, and the spacer 340 c is screwed to the substrate 31 from the inside of the housing 33.

  As shown in FIG. 3, the optical connector adapters 120A to 120F attached to the main body 34a of the front panel 34 are optical connector adapters 120A, 120B, 120C, 120D, 120E, from the substrate 31 side toward the side plate 333 side. Parallel in order of 120F.

  A first outside air introduction portion 101 and a second outside air introduction portion 102 including a plurality of round holes 340 a are formed in the main body portion 34 a of the front panel 34. The first outside air introduction portion 101 is formed on the first heat dissipation plate 331 side of the main body portion 34a, and the second outside air introduction portion 102 is formed on the second heat dissipation plate 332 side of the main body portion 34a. That is, the first outside air introduction part 101 and the second outside air introduction part 102 are formed so as to sandwich the optical connector adapters 120A to 120F in a direction perpendicular to the arrangement direction.

  As shown in FIG. 5A, in the front plate 335, the portions of the optical connector adapters 120A to 120F that protrude from the main body 34a of the front panel 34 toward the inside (the back plate 334 side) are collectively inserted. For this purpose, an insertion hole 335a is formed.

(Internal configuration of optical amplifier module 3)
Next, the internal configuration of the optical amplifier module 3 will be described with reference to FIGS.

  FIG. 6 is a side view of the inside of the housing 33 with the side plate 333 removed.

  The optical amplifier module 3 includes a booster amplifier unit 15 and a preamplifier unit 16 as first and second amplifier units housed between a first heat radiating plate 331 and a second heat radiating plate 332 in a housing 33. ing.

  The booster amplifier unit 15 is attached to the first heat radiating plate 331, and heat generated from a heat generating component such as a booster amplifier is radiated from the first heat radiating plate 331 by heat conduction. In the present embodiment, the booster amplifier unit 15 is disposed on the back plate 334 side in the longitudinal direction of the first heat radiating plate 331 and is fixed to the first heat radiating plate 331 with a plurality of screws.

  The booster amplifier unit 15 is provided with a heat dissipation sheet 153 on the surface of the first heat dissipation plate 331, and the booster amplifier unit 15 and the first heat dissipation plate 331 are thermally coupled via the heat dissipation sheet 153. Yes. As a result, heat generated from the heat generating components inside the booster amplifier unit 15 can be radiated from the first heat radiating plate 331.

  The preamplifier unit 16 is attached to the second heat radiating plate 332, and heat generated from a heat generating component such as a preamplifier is radiated from the second heat radiating plate 332 by heat conduction. In the present embodiment, the preamplifier unit 16 is disposed on the front plate 335 side in the longitudinal direction of the second heat radiating plate 332 and is fixed to the second heat radiating plate 332 with a plurality of screws.

  Similarly to the booster amplifier unit 15, the preamplifier unit 16 is provided with a heat radiating sheet 163 on the surface on the second heat radiating plate 332 side, and the preamplifier unit 16, the second heat radiating plate 332, and the like via the heat radiating sheet 163. Are thermally coupled. As a result, the heat generated from the heat generating components inside the preamplifier unit 16 can be radiated from the second heat radiating plate 332.

  As shown in FIG. 6, the booster amplifier unit 15 and the preamplifier unit 16 partially overlap in the direction in which the first heat radiating plate 331 and the second heat radiating plate 332 face each other. In other words, when viewed from the front panel 34 side, the booster amplifier unit 15 partially overlaps the preamplifier unit 16, and when viewed from the back plate 334 side, the preamplifier unit 16 is partially boosted. It overlaps with the amplifier unit 15. In FIG. 6, the booster amplifier unit 15 and the preamplifier unit 16 overlap each other by the dimension H in the height direction of the housing 33.

  On the other hand, the booster amplifier unit 15 and the preamplifier unit 16 are spaced apart from each other in the longitudinal direction of the housing 33 and are connected to the booster amplifier unit 15 and the preamplifier unit 16 between the booster amplifier unit 15 and the preamplifier unit 16, respectively. A gap 330 through which the optical fiber 130 can pass is formed.

  In the housing 33, a first portion that accommodates a part of the extra length of the plurality of optical fibers 130 in a wound state between the front plate 335 and the booster amplifier unit 15 in the longitudinal direction thereof. The extra length storage portion 33c is provided. Similarly, in the casing 33, an extra length portion of the other part of the plurality of optical fibers 130 is wound between the back plate 334 and the preamplifier unit 16 in the longitudinal direction. The second surplus length storage portion 33d is provided.

  More specifically, the extra length portion of the optical fiber 130 connected to the booster amplifier unit 15 among the plurality of optical fibers 130 is provided at a position facing the preamplifier unit 16 on the inner surface 331a of the first heat radiating plate 331. Further, it is stored in the first extra length storage portion 33c while being held by a plurality of holding members 143 (only two are shown in FIG. 6).

  Of the plurality of optical fibers 130, the extra length of the optical fiber 130 connected to the preamplifier unit 16 is a part of the preamplifier unit 16 opposite to the surface on which the heat dissipation sheet 163 is provided (first heat dissipation plate). 331, and the other part is stored in the first extra length storage portion 33c while being held by a plurality of (only two are shown in FIG. 6) holding members 145. The heat dissipation plate 332 is stored in the second extra length storage portion 33d while being held by a plurality of (only two shown in FIG. 6) holding members 146 provided at positions facing the booster amplifier unit 15.

  In addition, a board-side connector 172 corresponding to the amplifier-side connector 151 provided in the booster amplifier unit 15 and a board-side connector 171 corresponding to the amplifier-side connector 161 provided in the preamplifier unit 16 are mounted on the board 31. Yes. By connecting the amplifier-side connectors 151 and 161 and the board-side connectors 171 and 172, respectively, power is supplied and signals are transmitted to the booster amplifier unit 15 and the preamplifier unit 16.

  Next, the connection configuration of the plurality of optical fibers 130 and the connection configuration between the amplifier-side connectors 151 and 161 and the board-side connectors 171 and 172 will be described in more detail below with reference to FIGS.

  FIG. 7 shows the optical amplifier module 3 in a state where a plurality of optical fibers 130 are arranged, and is a plan view of the first heat radiating plate 331 viewed from the second heat radiating plate 332 side. FIG. 8 shows the optical amplifier module 3 in a state where a plurality of optical fibers 130 and a plurality of connection cables 17a are arranged, and is a plan view of the second heat radiating plate 332 side with the first heat radiating plate 331 removed. is there. FIG. 9 shows the optical amplifier module 3 in a state in which a plurality of optical fibers 130 and a plurality of connection cables 17b are arranged, and is a plan view of the first heat radiating plate 331 side with the second heat radiating plate 332 removed. is there.

In the following description, among the plurality of optical fibers 130, the plurality of optical fibers 130 arranged inside the housing 33 are referred to as optical fibers 131 </ b> A to 131 </ b> E, 131 </ b> F ₁ , 131 </ b> F _2. optical fiber 132A~132E a plurality of optical fibers 130 connected _to, and 132F 1, 132F _2.

Optical connector 12A~12F includes an optical connector adapter 120 a to 120 f, the optical fiber _131A~131E, 131F _1, 131F ₂ is connected to internal side plug _121A～121E, and 121F 1, 121F _2, optical fiber 132A～132E, 132F _1, 132F ₂ is connected external side plug _122a-122e, and is configured and a 122F 1, 122F _2.

As shown in FIGS. 7 and 8, the optical connectors 12 </ b> A to 12 </ b> F are arranged over the inside and the outside of the housing 33. More specifically, the inner side plugs 121 </ b> A to 121 </ b> E, 121 </ b> F ₁ , 121 </ b> F ₂ protrude from the front plate 335 toward the inside of the housing 33. One end portions of the optical connector adapters 120 </ b> A to 120 </ b> F and the external side plugs 122 </ b> A to 122 </ b> E, 122 </ b> F ₁ , 122 </ b> F ₂ protrude from the main body 34 a of the front panel 34 toward the outside of the housing 33.

  The optical connector adapters 120A to 120F include an optical connector adapter for input to the booster amplifier unit 15 and the preamplifier unit 16, and an optical connector adapter for output from the booster amplifier unit 15 and the preamplifier unit 16. That is, the optical connectors 12A to 12F include an optical connector for input to the booster amplifier unit 15 and the preamplifier unit 16, and an optical connector for output from the booster amplifier unit 15 and the preamplifier unit 16. Hereinafter, each of the optical connectors 12A to 12F will be described in detail.

  The optical connector 12A is an optical connector for input to the preamplifier unit 16, and includes an internal plug 121A, an external plug 122A, and an optical connector adapter 120A into which the internal plug 121A and the external plug 122A are fitted. It is configured.

  As shown in FIGS. 8 and 9, the inner plug 121A of the optical connector 12A is connected to the input port 16a of the preamplifier unit 16 by an optical fiber 131A.

  More specifically, after the optical fiber 131A led out from the internal plug 121A is annularly wound around a plurality of (four in this embodiment) holding members 145 provided in the preamplifier unit 16. Then, it passes through the gap 330 and is wound around the plurality of (four in this embodiment) holding members 146 provided on the second heat radiating plate 332 so as to be connected to the input port 16a of the preamplifier unit 16. It is connected.

  The external plug 122A of the optical connector 12A is connected to an external device by an optical fiber 132A. The inner side plug 121A and the outer side plug 122A are optically coupled via the optical connector adapter 120A.

  The optical connector 12B is an optical connector for output from the preamplifier unit 16, and includes an internal plug 121B, an external plug 122B, and an optical connector adapter 120B into which the internal plug 121B and the external plug 122B are fitted. It is configured.

  As shown in FIGS. 8 and 9, the inner plug 121B of the optical connector 12B is connected to the output port 16b of the preamplifier unit 16 by an optical fiber 131B.

  More specifically, the optical fiber 131 </ b> B led out from the inner plug 121 </ b> B is annularly wound around the plurality of holding members 145 provided in the preamplifier unit 16, and then passes through the gap 330 to be second. A plurality of holding members 146 provided on the heat radiation plate 332 are annularly wound and connected to the output port 16 b of the preamplifier unit 16.

  The external plug 122B of the optical connector 12B is connected to an external device by an optical fiber 132B. The inner side plug 121B and the outer side plug 122B are optically coupled via the optical connector adapter 120B.

  The optical connector 12C is an optical connector for input to the booster amplifier unit 15, and includes an internal plug 121C, an external plug 122C, and an optical connector adapter 120C into which the internal plug 121C and the external plug 122C are fitted. It is composed of

  As shown in FIG. 7, the internal plug 121C of the optical connector 12C is connected to the input port 15a of the booster amplifier unit 15 by an optical fiber 131C.

  More specifically, the optical fiber 131 </ b> C led out from the inner plug 121 </ b> C is annularly wound around a plurality of (four in this embodiment) holding members 143 provided on the first heat radiating plate 331. The booster amplifier unit 15 is connected to the input port 15a.

  The external plug 122C of the optical connector 12C is connected to an external device by an optical fiber 132C. The inner side plug 121C and the outer side plug 122C are optically coupled via the optical connector adapter 120C.

  The optical connector 12D is an optical connector for output from the booster amplifier unit 15, and includes an internal plug 121D, an external plug 122D, and an optical connector adapter 120D into which the internal plug 121D and the external plug 122D are fitted. It is composed of

  As shown in FIG. 7, the internal plug 121D of the optical connector 12D is connected to the output port 15b of the booster amplifier unit 15 by an optical fiber 131D.

  More specifically, the optical fiber 131 </ b> D led out from the inner plug 121 </ b> D is wound around the plurality of holding members 143 provided on the first heat radiating plate 331 in an annular manner, and the output of the booster amplifier unit 15. Connected to the service port 15b.

  The external plug 122D of the optical connector 12D is connected to an external device by an optical fiber 132D. The inner side plug 121D and the outer side plug 122D are optically coupled via the optical connector adapter 120D.

  The optical connector 12E is an optical connector for confirming the output of the booster amplifier unit 15, and includes an internal plug 121E, an external plug 122E, and an optical connector adapter 120E into which the internal plug 121E and the external plug 122E are fitted. It is composed of

  As shown in FIG. 7, the inner plug 121E of the optical connector 12E is connected to the output port 15b of the booster amplifier unit 15 by an optical fiber 131E.

  More specifically, the optical fiber 131 </ b> E led out from the inner plug 121 </ b> E is wound around the plurality of holding members 143 provided on the first heat radiating plate 331 in an annular manner, and the output of the booster amplifier unit 15. Connected to the service port 15b.

  The external plug 122E of the optical connector 12E is connected to an external monitor by an optical fiber 132E. The inner side plug 121E and the outer side plug 122E are optically coupled via the optical connector adapter 120E.

The optical connector 12F is an optical connector for monitoring the booster amplifier unit 15 and the preamplifier unit 16, and includes internal plugs 121F ₁ and 121F ₂ , external plugs 122F ₁ and 122F ₂ , and internal plugs 121F ₁ and 121F _2. And the optical connector adapter 120F into which the external side plugs 122F ₁ and 122F ₂ are fitted.

Optically coupled through the internal side plug 121F ₁ and the outer side plug 122F ₁ Hikari Toga connector adapter 120F, has a DEMUX port outputting separates the monitoring signal from the optical signal input to the preamplifier unit 16. Further, the internal side plug 121F ₂ and the external side plug 122F ₂ are optically coupled via the optical connector adapter 120F, and become a MUX port for multiplexing the monitoring signal with the optical signal output from the booster amplifier unit 15. ing.

Internal side plug 121F ₁ is the optical fiber 131F ₁ is connected to an input port 16a of the pre-amplifier unit 16, the internal side plug 121F ₂ is connected to the output port 15b of the booster amplifier unit 15 by the optical fiber 131F ₂ . The external side plugs 122F ₁ and 122F ₂ are connected to an external device by optical fibers 132F ₁ and 132F ₂ .

More specifically, as shown in FIGS. 8 and 9, inner side plug 121F ₁ optical fiber 131F ₁ derived from, Kai wound annularly on a plurality of retaining members 145 provided on the preamplifier unit 16 Then, it passes through the gap 330 and is wound around the plurality of holding members 146 provided on the second heat radiating plate 332 in an annular shape, and is connected to the input port 16 a of the preamplifier unit 16.

In addition, as shown in FIG. 7, the optical fiber 131F ₂ led out from the inner side plug 121F ₂ is wound around the plurality of holding members 143 provided on the first heat radiating plate 331 in a ring shape, and booster It is connected to the output port 15 b of the amplifier unit 15.

Provided above, the optical fiber 131A, 131B, 131F ₁ is, after having been wound annularly on a plurality of retaining members 145 provided to the pre-amplifier unit 16, the second heat radiating plate 332 through the gap 330 The plurality of holding members 146 wound around the plurality of holding members 146 are connected to the preamplifier unit 16 and the optical fibers 131C, 131D, 131E, and 131F ₂ are provided on the first heat radiation plate 331. 143 is wound in a ring shape and connected to the booster amplifier unit 15.

Each of the plurality of holding members 143,145,146 are optical fiber _131A～131E, in response to 131F 1, 131F ₂ each wrapping direction are arranged at equal intervals.

The optical fiber 131A, 131B, 131F ₁ is not necessarily wound for each of the plurality of holding members 145 and 146, by the extra length of each Kai wound for a plurality of retaining members 146 Instead, it may be wound only around the plurality of holding members 145.

  The board-side connector 171 provided on the board 31 and the amplifier-side connector 161 provided on the preamplifier unit 16 are connected by a flexible connection cable 17a such as a flat cable.

The connection cable 17a has first and second connectors 171a and 161a at both ends thereof. The first connector 171a is fitted to the board side connector 171 and the second connector 161a is fitted to the amplifier side connector 161. Match. In the present embodiment, as shown in FIG. 8, the connection cable 17a is routed across the optical fibers 131A, 131B, 131F ₁ wound around the plurality of holding members 145 provided in the preamplifier unit 16. Has been.

  Similarly, the board-side connector 172 provided on the board 31 and the amplifier-side connector 151 provided on the booster amplifier unit 15 are connected by a connection cable 17b having flexibility.

The connection cable 17b has first and second connectors 172a and 151a at both ends thereof, the first connector 172a is fitted to the board side connector 172, and the second connector 151a is fitted to the amplifier side connector 151. Match. In the present embodiment, as shown in FIG. 9, the connection cable 17 b is an optical fiber 131 </ b> C, 131 </ b> D, 131 </ b> E, 131 </ b> F ₂ wound around a plurality of holding members 146 provided on the second heat radiating plate 332. It has been arranged across.

  The board-side connectors 171 and 172 and the amplifier-side connectors 151 and 161 do not necessarily have to be connected by flexible connection cables 17a and 17b, but may be any flexible connection member. For example, it may be electrically connected via a flexible substrate.

(Operation and effect of the embodiment)
According to the embodiment described above, the following operations and effects can be obtained.

(1) In the booster amplifier unit 15 attached to the first heat radiating plate 331 and the preamplifier unit 16 attached to the second heat radiating plate 332, the first heat radiating plate 331 and the second heat radiating plate 332 are opposed to each other. Since the portions overlap in the direction, the first heat radiating plate while efficiently radiating the heat generated in each of the booster amplifier unit 15 and the preamplifier unit 16 from the first heat radiating plate 331 and the second heat radiating plate 332. 331 and the second heat radiating plate 332 can be made smaller by a dimension H (see FIG. 6) in the height direction of the housing 33, that is, the height of the housing 33, and the preamplifier unit 16, The optical amplifier module 3 can be reduced in size as compared with the case where the booster amplifier units 15 are arranged so as to be stacked in order.

(2) In the longitudinal direction of the housing 33, a gap 330 is formed between the booster amplifier unit 15 and the preamplifier unit 16 so that a plurality of optical fibers 130 can pass therethrough. However, the arrangement of the optical fiber 130 can be simplified.

(3) The board side connectors 171 and 172 provided on the board 31 and the amplifier side connectors 151 and 161 provided on the booster amplifier unit 15 and the preamplifier unit 16 are flexible connection cables 17a and 17b or flexible boards. Therefore, it is possible to allow the positional deviation between the substrate 31 and the booster amplifier unit 15 and the preamplifier unit 16 to allow connection.

(Summary of embodiment)
Next, the technical idea grasped from the embodiment described above will be described with reference to the reference numerals in the embodiment. However, the reference numerals and the like in the following description are not intended to limit the constituent elements in the claims to the members and the like specifically shown in the embodiments.

[1] A rectangular parallelepiped housing (33) having first and second heat radiating plates (331, 332) arranged opposite to each other as side plates, and first and second heat radiation in the housing (33). The first and second amplifier units (booster amplifier unit 15 and preamplifier unit 16) housed between the plates (331, 332), and the first amplifier unit (booster amplifier unit 15 or preamplifier unit 16) In addition to being attached to the first heat radiating plate (331), the generated heat is radiated from the first heat radiating plate (331) by heat conduction, and the second amplifier unit (preamplifier unit 16 or booster amplifier unit 15) is Attached to the second heat radiating plate (332), the generated heat is radiated from the second heat radiating plate (332) by heat conduction, and the booster Amplifier unit (15) and the pre-amplifier unit (16) includes a first heat radiating plate (331) and the second heat radiating plate (332) and an optical amplifier module partially overlap in opposite directions (3).

[2] Optical fiber (130) connected to booster amplifier unit (15) or preamplifier unit (16) between booster amplifier unit (15) and preamplifier unit (16) in the longitudinal direction of housing (33) The optical amplifier module (3) according to [1], wherein a gap (330) through which light can pass is formed.

[3] A board-side connector (171, 172) provided on the board (31), further comprising a board (31) arranged so as to be orthogonal to the first and second heat radiating plates (331, 332). And the amplifier side connectors (151, 161) provided in the booster amplifier unit (15) and the preamplifier unit (16) are connected via flexible connection members (connection cables 17a, 17b). The optical amplifier module (3) according to [1] or [2].

  While the embodiments of the present invention have been described above, the embodiments described above do not limit the invention according to the claims. In addition, it should be noted that not all the combinations of features described in the embodiments are essential to the means for solving the problems of the invention.

  The present invention can be appropriately modified and implemented without departing from the spirit of the present invention. For example, in the above-described embodiment, the case where the booster amplifier unit 15 is used as the first amplifier unit and the preamplifier unit 16 is used as the second amplifier unit is described. On the contrary, the first amplifier unit is used. A preamplifier unit may be used, and a booster amplifier unit may be used as the second amplifier unit. Further, both the first and second amplifier units may be preamplifier units or booster amplifier units.

  In the above embodiment, the optical transmission device 1 in which the optical amplifier module 3 is detachably attached to the chassis 2 has been described. However, the present invention is not limited to this, and the present invention may be applied to an optical amplifier module that is used alone. .

3, 3a, 3b ... Optical amplifier module 15 ... Booster amplifier unit (first amplifier unit)
16: Preamplifier unit (second amplifier unit)
17a, 17b ... Connection cable (connection member)
31 ... substrate 33 ... housing _{130,131A~131E, 131F 1, 131F 2,} 132A~132E, 132F 1, 132F 2 ... optical fiber 151, 161 ... amplifier side connector 171, 172 ... board connector 330 ... gap 331, 332 ... 1st and 2nd heat sink

Claims (3)

A rectangular parallelepiped housing having first and second heat radiating plates arranged opposite to each other as side plates;
A first amplifier unit and a second amplifier unit housed between the first and second heat sinks in the housing;
The first amplifier unit is attached to the first heat radiating plate, and the generated heat is radiated from the first heat radiating plate by heat conduction,
The second amplifier unit is attached to the second heat radiating plate, and the generated heat is radiated from the second heat radiating plate by heat conduction,
The first and second amplifier units are optical amplifier modules that are partially overlapped in a direction in which the first heat radiating plate and the second heat radiating plate are opposed to each other. In the longitudinal direction of the housing, a gap is formed between the first amplifier unit and the second amplifier unit so that an optical fiber connected to the first or second amplifier unit can pass therethrough. Being
The optical amplifier module according to claim 1. A substrate disposed to be orthogonal to the first and second heat sinks;
The board-side connector provided on the board and the amplifier-side connector provided on the first and second amplifier units are connected via a flexible connection cable or flexible board,
The optical amplifier module according to claim 1 or 2.

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