JP2009230032A - Optical module - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an optical module, capable of eliminating in which the occurrence of stresses or the degradation of characteristic due to the dislocation of a sleeve part which optically couples the body part of an OSA (optical subassembly), in which an optical element is housed, with an optical fiber transmission path, and handling the main body part and the sleeve part integrally as a unit. <P>SOLUTION: The optical module 21 is equipped with the optical subassembly (OSA) 22 provided with the main body part 35, in which the optical element 27 is housed, and the sleeve part 36 including a fiber stub, which optically couples the optical element to the optical fiber transmission path, and has an optical connection part 25, in which an electronic circuit mounting part 24 to which the optical element is connected and a sleeve part are arranged. One end of a short optical fiber 29, optically coupled to the optical element 27, is held in the body part 35 of the optical subassembly 22, and another end of the short optical fiber 29 is inserted and held in the fiber stub 32 in the sleeve part 36; and the main body part and the sleeve part 36 are connected as a unit by an elastic member 34, which is disposed at the outside of the short optical fiber and is elastically deformable. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to an optical module including an optical element such as a light emitting element that emits signal light, a light receiving element that receives signal light, and an optical connection portion that optically couples the optical element and an optical fiber.

As an optical module used for optical communication, there is an optical transmission module that transmits signal light, an optical reception module that receives signal light, or an optical transmission / reception module that has both functions of transmission and reception of signal light.
FIG. 4A is a diagram schematically illustrating an example of a conventional optical module. The optical module 1 is equipped with an optical subassembly 2 (OSA Optical sub-assembly) that transmits and receives signal light, and an optical component transmission portion 4 on which an electronic circuit device 3 is mounted and an optical fiber transmission line. And a housing portion 6 that stores and holds them (see, for example, Patent Document 1).

  The OSA 2 is a light emitting element that emits signal light or a light receiving element that receives signal light, a lens 8a, 8b that optically couples the optical element 7 to an optical fiber transmission line, A fiber stub 9a, a sleeve 9b, and an auxiliary sleeve 9c are provided for connecting the optical fiber transmission line by a connector. Further, when the OSA 2 is viewed from a structural aspect, the optical element 7 and the main body portion 10 on which the photoelectric conversion means is mounted, the sleeve portion 11 that forms a connection with the optical fiber, the main body portion 10 and the sleeve portion 11 are arranged. It consists of the coupling | bond part 12 couple | bonded. Each of these parts is configured as one integrated part by adjusting the positional relationship with each other so as to obtain an optimum optical coupling.

  Further, when a laser diode (LD) is mounted on the OSA 2 as the optical element 7, consideration is given to heat dissipation in order to suppress deterioration of optical characteristics due to the heat generation and to ensure communication quality. For example, the housing of the OSA 2 is disposed so as to be in contact with the inner surface of the casing portion 6 that forms the outer shell of the optical module 1, and forms a heat radiation path to the outside. Further, between the OSA 2 housing and the carrier substrate on which the optical element 7 is mounted, a thermo module (for example, TEC Thermo Electrical Cooler) that is electronically cooled using a thermoelectric conversion element is mounted to cool the optical element 7. The method to do is also used.

  The OSA 2 has an optical fiber transmission line provided on the front side of the optical module 1 while the main body 10 is electrically connected to the electronic circuit device 3 at the electronic circuit mounting portion 4 of the optical module 1. The sleeve portion 11 for aligning and connecting the optical connector is held and fixed to the optical connection portion 5 (also referred to as a receptacle). Then, an optical connector (not shown) attached to the end of an optical fiber cord or the like is inserted into the optical connection portion 5 of the optical module 1, and the ferrule of the optical connector is inserted into the sleeve 9b, Optically coupled. The optical element 7 and the optical connector are optically coupled through an optical system including a lens (for example, a collimating lens 8a and a condensing lens 8b) and a fiber stub 9a, and are adjusted in position so as to obtain an optimal optical coupling. Thus, it is assembled so that signal light can be transmitted and received.

  However, the position in the optical axis direction of the optical element 7 related to optical coupling is deviated from the optimum position for optical coupling to the fiber stub 9b due to variations in the accuracy of the optical element 7 and the lenses 8a and 8b. The position may be different. The housing of the OSA 2 is disposed so as to come into contact with the module housing 6 for heat dissipation, while the sleeve portion 11 has a surface perpendicular to the optical axis, such as a holding position determined by the dimensional accuracy of the optical connection portion 5. There are also variations in direction.

  Various methods for adjusting the positions of the lenses 8a and 8b have been proposed in order to eliminate misalignment and the like due to these variations. However, since the holding mechanism for the lenses 8a and 8b is complicated and the housing of the OSA 2 is required to be downsized, this is not a very effective method, and it is not possible to avoid axial misalignment between the optical element 7 and the fiber stub 9b. Not easy. However, if these variations and misalignments remain unresolved, stress is generated in each part, causing damage and deterioration of characteristics, and also causing deterioration of optical transmission characteristics, thereby impairing reliability.

On the other hand, as shown in FIG. 5, the optical module 13 including the transmission circuit unit 14a and the reception circuit unit 14b is optically connected to the light emitting element 15a, the light receiving element 15b, and the optical fiber transmission line for transmitting and receiving signal light. A method of optically coupling optical connectors 17a and 17b coupled to each other using optical fiber members 18a and 18b is known (see, for example, Patent Document 2). The optical elements 15a and 15b and one ends 19a and 19b of the optical fiber members 18a and 18b are accurately coupled and fixed by the submounts 16a and 16b. The optical connectors 17a and 17b and the other ends of the optical fiber members 18a and 18b are ferrules. They are fixedly coupled using 20a and 20b.
JP 2004-151686 A US Pat. No. 5,943,461

  As shown in FIG. 5, the optical element and the optical connector for transmission / reception are optically coupled by using a flexible optical fiber member, so that the axis deviation between the optical element and the fiber stub described in FIG. Can be eliminated. However, with the spread and miniaturization of optical transmission devices and the standardization of the shape of optical modules used there, the OSA structure as shown in FIG. 5 (optical device mounting portion and optical connection portion to the optical fiber transmission line) Is not integrated, there is a problem in miniaturization of the optical module and handling of the optical fiber member in mass production.

  The present invention has been made in view of the above-described circumstances, and eliminates the occurrence of stress and deterioration in characteristics due to the displacement of the sleeve portion that is optically coupled to the optical fiber transmission path with respect to the OSA main body portion in which the optical element is accommodated. In addition, an object of the present invention is to provide an optical module capable of handling the main body portion and the sleeve portion integrally.

  An optical module according to the present invention is mounted with an optical subassembly (OSA) including a main body that stores an optical element that receives or emits light, and a sleeve that includes a fiber stub that optically couples the optical element to an optical fiber transmission line. An optical module having an electronic circuit mounting portion to which an optical element is connected and an optical connection portion for arranging a sleeve portion. One end of a short optical fiber optically coupled to the optical element is held in the main body portion of the optical subassembly, and the other end of the short optical fiber is held through the fiber stub in the sleeve portion, and the main body portion and the sleeve portion are They are integrally coupled by an elastic member capable of elastic deformation disposed outside the short optical fiber.

The elastic member is formed in a cylindrical shape that surrounds the outside of the short optical fiber, and is formed of, for example, a coil spring. Moreover, you may make it form with at least a pair of leaf | plate spring which opposes on both sides of a short optical fiber.
In addition, the main body portion of the optical subassembly may include a laser diode and means for electronically cooling the laser diode, and may be configured to be in contact with the optical module housing.

  According to the present invention, the sleeve part into which the ferrule of the optical connector of the optical fiber transmission line is inserted is optically coupled to the main body part in which the optical element is accommodated by the short optical fiber. High-precision position adjustment with the fiber stub becomes unnecessary. In addition, it is possible to eliminate the occurrence of stress due to positional deviation due to dimensional error, temperature change, etc. when mounting to the optical module housing, and the main body portion and the sleeve portion are integrally formed by an elastic member. It can be handled in the same manner and can be miniaturized.

  Embodiments of the present invention will be described with reference to the drawings. FIG. 1 is a diagram for explaining the outline of the present invention, FIG. 1 (A) is a diagram for explaining the overall structure of an optical module, and FIG. 1 (B) is a configuration example of an optical subassembly mounted on the optical module of the present invention. FIG. 1C is a diagram showing an example of optical element and optical fiber coupling. In the figure, 21 is an optical module, 22 is an optical subassembly, 23 is an electronic circuit device, 24 is an electronic circuit mounting part, 25 is an optical connection part, 26 is an optical module housing, 27 is an optical element, 28 is a lens, 29 Is a short optical fiber, 30 is a carrier substrate, 31 is a body housing, 32 is a fiber stub, 33 is a sleeve, 34 is an elastic member (spring coil), 35 is a body portion, 36 is a sleeve portion, and 37 is a coupling portion. .

The optical module according to the present invention can be applied to an optical transmission module for transmitting signal light, an optical reception module for receiving signal light, or an optical transmission / reception module having both functions of signal light transmission and reception.
FIG. 1A schematically shows an example of an optical module according to the present invention. The optical module 21 includes an optical subassembly 22 (hereinafter referred to as OSA) that transmits and receives signal light, and an electronic device for that purpose. An electronic component mounting portion 24 on which the circuit device 23 is mounted, an optical connection portion 25 that forms optical coupling with the optical fiber transmission line, and a module housing portion 26 that stores and holds them are provided.

  As shown in FIG. 1B, the OSA 22 used in the present invention is a light emitting element such as a laser diode that emits signal light or an optical element 27 that is a light receiving element such as a photodiode that receives signal light. It is mounted on the carrier substrate 30 to be formed. Then, one end of a short optical fiber 29 is optically coupled to the optical element 27 on a carrier substrate 30 via a lens 28, for example. The other end of the optically coupled short optical fiber 29 is penetrated and held and fixed to a fiber stub 32 coupled to an optical connector (not shown) of the optical fiber transmission line.

  The fiber stub 32 is held and fixed in the sleeve 33. A ferrule of an optical connector of the optical fiber transmission line is inserted into the sleeve 33 after being aligned and positioned. The optical fiber at the center of the ferrule tip of the optical connector inserted into the sleeve 33 and the end of the fiber stub 32 abut each other, the optical element 6 and the optical fiber transmission line are optically optically coupled, and the signal Light is transmitted and received.

  The OSA 22 is a fiber in which the optical element 28 and its photoelectric conversion means (not shown) are mounted and a connection between the main body 35 surrounded by the housing 31 and the optical fiber transmission line is seen from the structural aspect. It comprises a sleeve portion 36 having a stub 32 and a sleeve 33, and a connecting portion 37 that connects the main body portion 35 and the sleeve portion 36. The main body portion 35 and the sleeve portion 36 are in a state of being connected by a short optical fiber 29, but an elastic member 34 such as a spring coil is attached as a coupling portion 37 so as to surround the short optical fiber 29, The main body portion 35 and the sleeve portion 36 are mechanically connected and fixed.

  FIG. 1C shows an example of a configuration in which the optical element 27 in the OSA 22 and the short optical fiber 29 are optically coupled, and optically coupled via a lens 28. The lens 28 is formed, for example, by covering the outer side of the convex lens element 28a with an outer cover 28b having an elliptical outer diameter. For example, a silicon crystal substrate is used as the carrier substrate 30, the optical element 27 is mounted on the surface thereof, and a V-groove 30 a for positioning and fixing the short optical fiber 29 is formed on the optical path. In this V-groove 30a, a lens 28 is disposed between the optical element 27 and the short optical fiber 29, and the optical axis is adjusted to an optimum state and fixed by adjusting the rotational position thereof.

  Further, when a laser diode (LD) is mounted as the optical element 27 in the main body portion 35 of the OSA 22, for example, the housing 31 of the OSA 22 is used in order to suppress the deterioration of the optical characteristics due to the heat generation and ensure the communication quality. And a carrier substrate 30 on which the optical element 27 is mounted, a thermomodule (TEC) that is electronically cooled using a thermoelectric conversion element is mounted to cool the optical element 27. Further, the housing 31 of the OSA 22 is disposed so as to be in contact with the inner surface of the casing portion 26 that forms the outer shell of the optical module 21 to form a heat radiation path.

  The OSA 22 has an optical fiber transmission line provided on the front side of the optical module 21 while its main body 35 is electrically connected to the electronic circuit device 23 by the electronic circuit mounting portion 24 of the optical module 21. A sleeve portion 36 that forms an optical connection with the optical connector is held and fixed to the optical connection portion 25 (receptacle). Then, an optical connector attached to the end of an optical fiber cord or the like is inserted into the optical connection portion 25 of the optical module 21, and a ferrule of the optical connector is inserted into the sleeve portion 36, and light is transmitted through the short optical fiber 29. Optically coupled to element 27.

  FIG. 2 is a diagram for explaining the usage form of the OSA 22 described above. FIG. 2A shows a state in which the main body 35 and the sleeve 36 are optically connected by a short optical fiber 29, and FIG. FIG. 2C shows a state where the main body portion 35 and the ferrule portion 36 are mechanically connected by the elastic member 34, and FIG.

  As shown in FIG. 2A, if the main body portion 35 and the sleeve portion 36 are merely optically connected with the short optical fiber 29, the mechanical strength is substantially the same as that described with reference to FIG. Handling is necessary so that the short optical fiber 29 that does not have is damaged or broken. For this reason, it is necessary to incorporate both the main body portion 35 and the sleeve portion 36 into the optical module 21, and the handleability is poor and the productivity is poor.

In the present invention, as shown in FIG. 2B, the main body portion 35 and the sleeve portion 36 are mechanically connected to the main body portion 35 and the sleeve portion 36 by attaching an elastic member 34 so as to surround the short optical fiber 29. It is constructed so that it can be handled as a single part by being connected and fixed to each other.
The elastic member 34 has a cylindrical shape in which the short optical fiber 29 penetrates the hollow portion. In addition to the spring coil shown in the drawing, the elastic member 34 has a tube made of elastic rubber or resin, a bending rod such as a bellows pipe, or the like. It can also be used.

  FIG. 2C shows a state where the storage position of the main body portion 35 and the storage position of the sleeve portion 36 are misaligned when the OSA 22 configured as described above is assembled in the optical module housing 26. In this case, the elastic member 34 is elastically bent, and the main body portion 35 and the sleeve portion 36 can be stored and held in a predetermined storage portion without causing stress. Further, even if the positional relationship between the optical element in the main body 35 and the fiber stub of the sleeve portion 36 is slightly shifted, it is not necessary to adjust the optical coupling state again, and the predetermined optical fiber 29 is adjusted in advance by the short optical fiber 29. Maintained at optical coupling rate. Furthermore, since the short optical fiber 29 is protected by the elastic member 34, it can be handled in the same manner as a conventional rigid OSA.

  FIG. 3 is a diagram illustrating an example of another embodiment. In this embodiment, the configuration in which the OSA 22 is optically coupled to the main body portion 35 and the sleeve portion 36 by the short optical fiber 29 is the same as the example of FIGS. However, the difference is that at least a pair of leaf springs 38 is used for the elastic member described above, and the short optical fiber 29 is sandwiched from both sides. The leaf spring 38 can be easily manufactured at low cost because the bent pieces 38a at both ends can be easily attached to the end surfaces of the main body portion 35 and the sleeve portion 36 by welding or bonding.

  In the embodiment of FIG. 3, the entire length of the short optical fiber 29 is not covered, but there is no problem in strength because it is sandwiched between a pair of leaf springs 38, and in normal handling, There is no contact with hands or external forces, and there is no damage or breakage. Compared to the examples of FIGS. 1 and 2, the alignment allowance direction is directional, but when it is assembled in an optical module housing, it is specified in a direction in which a dimensional error is likely to occur (for example, the vertical direction). By setting it as the structure which set the bending possible direction, it can become useful like the example of FIGS.

It is a figure explaining the outline of the present invention. It is a figure explaining the usage form of the optical subassembly by this invention. It is a figure explaining other embodiment of this invention. It is a figure explaining the prior art. It is a figure explaining other conventional techniques.

Explanation of symbols

DESCRIPTION OF SYMBOLS 21 ... Optical module, 22 ... Optical subassembly, 23 ... Electronic circuit apparatus, 24 ... Electronic circuit mounting part, 25 ... Optical connection part, 26 ... Optical module housing | casing, 27 ... Optical element, 28 ... Lens, 29 ... Short light Fibers 30... Carrier substrate 31. Body housing 32, fiber stub 33 33 sleeve 34 34 elastic member (spring coil) 35 body body 36 sleeve portion 37 coupling portion 38 leaf spring 38a ... bent piece.

Claims (5)

An electronic circuit in which an optical subassembly including a main body portion that stores an optical element that receives or emits light and a sleeve portion that includes a fiber stub that optically couples the optical element to an optical fiber transmission line is mounted and to which the optical element is connected An optical module having an optical connection part for disposing a mounting part and the sleeve part,
One end of a short optical fiber optically coupled to the optical element is held in the main body portion of the optical subassembly, and the other end of the short optical fiber is passed through and held in the fiber stub in the sleeve portion, and the main body portion An optical module, wherein the sleeve portion and the sleeve portion are integrally coupled by an elastic member capable of elastic deformation disposed outside the short optical fiber.   The optical module according to claim 1, wherein the elastic member is formed in a cylindrical shape that surrounds the outside of the short optical fiber.   The optical module according to claim 2, wherein the elastic member is formed of a coil spring.   The optical module according to claim 1, wherein the elastic member is formed of at least a pair of leaf springs facing each other with the short optical fiber interposed therebetween.   The main body of the optical subassembly includes a laser diode and means for electronically cooling the laser diode, and is disposed in contact with the optical module housing. The optical module according to item.

Images