WO2014157363A1

WO2014157363A1 - Optical transmission module, photoelectric composite transmission module, and optical connector

Info

Publication number: WO2014157363A1
Application number: PCT/JP2014/058588
Authority: WO
Inventors: 松原　孝宏; 直希高橋; 和美中水流
Original assignee: 京セラ株式会社; 京セラコネクタプロダクツ株式会社
Priority date: 2013-03-27
Filing date: 2014-03-26
Publication date: 2014-10-02

Abstract

An optical transmission module (3) has a waveguide substrate (25) having an optical waveguide (33) provided to a first main surface (25a), a midplane (21) disposed opposite the waveguide substrate (25), an optical fiber (31) optically connected to the waveguide (33), and a light receptacle (19) fixed to the waveguide substrate (25). The optical transmission module (3) also has an optical plug (17) for holding the optical fiber (31) and fitting into the light receptacle (19), the optical plug (17) being fixed to the midplane (21) with play in the x, y, and z directions relative to the midplane (21).

Description

Optical transmission module, photoelectric composite transmission module, and optical connector

The present invention relates to an optical transmission module, an optical composite transmission module, and an optical connector that connect optical transmission paths.

As the amount of information increases, there is a need for improved server system functionality. Therefore, it has been studied to use an optical transmission line instead of an electric transmission line. Here, for example, a technique for connecting an optical transmission line in connection between a midplane substrate and a blade substrate is known. Patent Document 1 discloses a technique for connecting a waveguide base having an optical waveguide formed to a midplane.

JP 2012-231461 A

However, as in the technique disclosed in Patent Document 1, in the structure in which the module (204) is connected to the connector on the midplane board (202) located on the back side of the server system or the like, for example, the module is inserted. If the connector is completely fixed so as not to move with respect to the midplane board, various disadvantages occur when the blade board is inserted into the connector. For example, the relative fixed position of the midplane board or each module in the system may vary. If the accuracy of the connector mounting position on the midplane board is low, or if the connector is not sufficiently inserted into the module, the module cannot be inserted into the connector or the connector or The module may buckle or break.

Furthermore, if the connector and the module are inserted with a slight misalignment, a long-term load (stress) is applied to the connector or module, and the connector or connector mounting part (generally a soldering part), Furthermore, the module may be deformed or damaged, and the reliability may be lowered.

Therefore, it is desirable to provide a new type of optical transmission module, optical / electrical composite module, and optical connector that can suitably perform optical connection between substrates or have excellent long-term reliability.

An optical transmission module according to an aspect of the present invention is optically connected to a waveguide base having an optical waveguide provided on a main surface thereof, a connection base disposed with respect to the waveguide base, and the optical waveguide. An optical fiber, an optical receptacle fixed to the waveguide base, and the optical fiber is held and fitted to the optical receptacle, and is fixed to the connection base with play with respect to the connection base. And an optical plug.

An optical / electrical composite transmission module according to an aspect of the present invention includes a wiring base provided with electrical wiring, a connection base provided with electrical wiring, a first electrical connector component fixed to the wiring base, and the connection A second electrical connector part fixed to the base and coupled to the first electrical connector part, thereby electrically connecting the wiring base and the connection base, and positioning the wiring base and the connection base; A waveguide base fixed on the wiring base and provided with an optical waveguide on a main surface; an optical fiber optically connected to the optical waveguide; an optical receptacle fixed to the waveguide base; An optical plug that holds the optical fiber, fits into the optical receptacle, and is fixed to the connection base in a state having play with respect to the connection base.

An optical connector according to an aspect of the present invention is an optical connector that connects an optical transmission path between a waveguide substrate and a coupling substrate that are arranged to each other, and the optical connector provided on a main surface of the waveguide substrate. An optical receptacle that can be fixed to the waveguide base body with the waveguide exposed, and an optical fiber connector part that can hold the optical fiber and can be movably attached to the connecting base body. Yes.

According to the above configuration, the long-term reliability of the optical receptacle or the optical plug can be improved.

It is a perspective view which shows the photoelectric composite transmission module which concerns on embodiment of this invention, an optical transmission module, and an optical connector in a non-connection state. It is the figure which looked at a part of Drawing 1 in the z direction. It is a perspective view which shows the optical plug of the optical transmission module of FIG. 4A and 4B are perspective views of the optical plug of FIG. 3 with some members removed. It is the perspective view which looked at the optical plug of FIG. 3 from another angle. 6A and 6B are cross-sectional views taken along line VIa-VIa in FIG. 5, and FIG. 6C is a cross-sectional view taken along line VIc-VIc in FIG. 6B. FIG. 7A is a perspective view showing the optical receptacle of the optical transmission module of FIG. 1, and FIG. 7B is a perspective view of the optical receptacle with some members removed. FIG. 8A is a perspective view showing the waveguide substrate on which the positioning member of FIG. 7B is placed, and FIG. 8B is a waveguide substrate on which the positioning member is not placed. FIG. FIGS. 9A to 9D are views showing how the optical plug is inserted into the optical receptacle. It is a perspective view which shows the to-be-positioned member and positioning member in the state of FIG.9 (d). Fig.11 (a) and FIG.11 (b) are schematic diagrams which show a modification. 12A is a cross-sectional view taken along line XIIa-XIIa in FIG. 9D, and FIG. 12B is a cross-sectional view taken along line XIIb-XIIb in FIG.

FIG. 1 is a perspective view showing an optical / electrical composite transmission module 1, an optical transmission module 3, and an optical connector 5 according to an embodiment of the present invention in a disconnected state. FIG. 2 is a view of a part of FIG. 1 viewed in the z direction.

The opto-electric composite module including the opto-electric composite transmission module 1 is composed of a structure in which a plurality of substrate assemblies configured by providing electronic components and the like on a substrate are connected to each other. Signal transmission between the substrate assemblies is performed by electrical signals and optical signals. Such a photoelectric composite module constitutes, for example, a computer system.

The photoelectric composite transmission module 1 indicates a configuration related to signal transmission in the photoelectric composite module. In the present embodiment, the components are substantially the same as the components of the photoelectric composite module. Moreover, although the optical transmission module 3 refers to the structure which concerns on transmission of an optical signal among the photoelectric composite transmission modules 1, the optical transmission module 3 may be defined including the structure which concerns on transmission of an electrical signal. Hereinafter, the term “optical transmission module 3” is mainly used.

The optical transmission module 3 includes a midplane assembly 7 and a plurality of blade assemblies 9 (only one is shown in FIG. 1) connected perpendicularly to the midplane assembly 7 as a substrate assembly. The midplane assembly 7 and the blade assembly 9 are connected by an electrical connector 11 that connects electrical transmission paths and an optical connector 5 that connects optical transmission paths.

The dimensions of each part of the optical transmission module 3 may be appropriately set. For example, in the example illustrated in FIGS. 1 and 2, the length of one side of the midplane 21 or the blade assembly 9 is, for example, 5 cm or more and 20 cm. The following can be set.

The blade assembly 9 may be provided on both sides of the midplane 21, but in the description of the present embodiment, only the configuration relating to one surface will be described, and the configuration relating to the other surface will be omitted. It shall be.

The midplane assembly 7 is provided on the midplane 21, the main surface of the midplane 21, the electric plug 13 constituting the electric connector 11, and the optical plug provided on the main surface of the midplane 21 and constituting the optical connector 5. 17 and a plurality of optical cables 27 held by the optical plug 17.

The blade assembly 9 is provided on the blade 23, the waveguide substrate 25 fixed to the blade 23 in a stacked manner, the electrical receptacle 15 that is provided on the blade 23 and constitutes the electrical connector 11, and the waveguide substrate 25. And an optical receptacle 19 constituting the optical connector 5. An optical waveguide band 29 (FIG. 1) connected to the optical cable 27 is provided on the waveguide substrate 25.

Although not particularly illustrated, the blade 23 is mounted with an electronic component such as an IC (including a photoelectric conversion element). An electronic component such as an IC may also be mounted on the midplane 21 and the waveguide substrate 25.

In addition, as shown in FIG. 1, at the end of the optical cable 27 opposite to the side connected to the optical waveguide band 29 and the end of the optical waveguide band 29 opposite to the side connected to the optical cable 27. Are connected to the light emitting element 101 and / or the light receiving element 103 (photoelectric conversion element). The light emitting element 101 and the light receiving element 103 may be provided on any of the midplane 21, the blade 23, and the waveguide substrate 25.

The midplane 21 and the blade 23 are constituted by, for example, a rigid printed wiring board. The midplane 21 has a first main surface 21a and a second main surface 21b on the back surface thereof. The blade 23 has a first main surface 23a and a second main surface 23b on the back surface thereof. Although not particularly illustrated, electrical wiring is provided on the first main surface, the second main surface and / or the inside of these substrates.

For example, the waveguide substrate 25 may be mainly composed of an insulating base similar to a rigid printed wiring board. The waveguide substrate 25 has a first main surface 25a and a second main surface 25b on the back surface thereof. Also in the waveguide substrate 25, electrical wiring may be provided on the first main surface, the second main surface, and / or inside.

The waveguide substrate 25 is provided as a so-called mezzanine board, is arranged in a stacked manner with respect to the blade 23, and is fixed to the blade 23 with screws or the like. Signal transmission between the waveguide substrate 25 and the blade 23 is performed by light and / or electricity. The electrical or optical connection may be made in the same manner as a known method, for example. For example, the optical connection between the waveguide substrate 25 and the blade 23 may be made by an optical cable connected to these substrates via a known connector.

The electrical plug 13 is provided on the first main surface 21 a of the midplane 21. On the other hand, the electrical receptacle 15 is provided at the connection side end 23 f of the blade 23. With the blade 23 oriented perpendicular to the first main surface 21 a of the midplane 21, the electrical receptacle 15 is inserted into and fitted into the electrical plug 13 in the direction along the blade 23 (y direction). As a result, the electrical receptacle 15 and the electrical plug 13 are mechanically coupled, and the terminals inside the electrical receptacle 15 and the electrical plug 13 are electrically connected to each other. As a result, the midplane 21 and the blade 23 are positioned and electrically connected to each other. The direction in which the blade 23 is inserted into the midplane 21 is not limited to a case where the blade 23 is perpendicular to the midplane 21 (90 °). For example, the blade 23 may be inserted at 60 ° or more and 130 ° or less, and is perpendicular to the midplane 21. Just plug it in from any direction.

Note that the specific configuration of the electrical connector 11 may be the same as the configuration of a known board-to-board electrical connector. It is also possible to provide the electrical plug 13 on the blade 23 and the electrical receptacle 15 on the midplane 21.

The optical plug 17 is provided on the first main surface 21 a of the midplane 21. On the other hand, the optical receptacle 19 is provided at the connection side end portion 25 f of the waveguide substrate 25. When the electrical receptacle 15 is inserted into the electrical plug 13 as described above, the optical plug 17 is also inserted in the y direction with respect to the optical receptacle 19 and is fitted. As a result, the optical cable 27 and the optical waveguide band 29 are optically connected.

The waveguide substrate 25 is constituted by a mezzanine (mezzanine floor) board. In other words, the optical waveguide band 29 or the like is not directly disposed on the blade 23. Therefore, the waveguide substrate 25 is disposed away from the blade 23 in the x direction, or the waveguide substrate 25 is disposed away from the midplane 21 in the y direction in a state where the blade 23 is connected to the midplane 21. can do.

The waveguide substrate 25 can be separated from the midplane 21 by adjusting the position in the connection direction (y direction) of the optical connector 5 with respect to the blade 23. As a result, it is easy to secure a space for arranging the optical connector 5 between the connection-side end portion 25f of the waveguide substrate 25 and the first main surface 21a of the midplane 21.

The arrangement of the electrical connector 11 and the optical plug 17 may be set as appropriate. FIG. 1 illustrates an arrangement in which the optical plug 17 is positioned at the center of the end portion (one side) of the blade 23 and the electrical connector 11 is positioned on both sides thereof. Moreover, the case where the arrangement | positioning of the optical plug 17 and the electrical connector 11 is the same among the some braid | blades 23 is illustrated.

The optical plug 17 holds the ends of a plurality (four in this embodiment) of optical cables 27. The waveguide substrate 25 is provided with a plurality of (four in this embodiment) optical waveguide bands 29. The optical connector 5 can connect the plurality of optical cables 27 and the plurality of optical waveguide bands 29 simultaneously. The plurality of optical cables 27 and the plurality of optical waveguide bands 29 are arranged in a direction in which the connection side end portion 25f (one side) of the waveguide substrate 25 extends at least in the connection portion. The arrangement interval is uniform, for example.

The end portion of the optical cable 27 connected to the optical waveguide band 29 is held by the optical plug 17 so as to be orthogonal to the first main surface 21a of the midplane 21. Further, the portion of the optical cable 27 that extends from the optical plug 17 to the rear side (the side opposite to the connection side) is curved so as to draw an arc, and then extends along the first main surface 21a. The curvature of the optical cable 27 is set to be larger than the minimum allowable bending radius of the optical cable.

The connection-side end 25f of the waveguide substrate 25 is further away from the first main surface 21a of the midplane 21 in the y direction than the connection-side end 23f of the blade 23. Therefore, a sufficient distance between the tip of the optical cable 27 (tip of the optical plug 17) and the first main surface 21a is secured. As a result, the radius of the curved portion of the optical cable 27 is large, and the influence of the curvature on the light transmission is suppressed.

Each optical cable 27 has a plurality of optical fibers 31 (see FIG. 10). The optical fiber 31 may have a core and a clad as is well known. Each optical fiber 31 may have a coating as necessary. The plurality of optical fibers 31 may be covered and bundled with a sheath, or may not be bundled. The optical cable 27 includes a film-like one having a core and a clad. For example, the plurality of optical fibers 31 are arranged in a line in the width direction (z direction) of the optical plug 17 at least inside the optical plug 17.

The plurality of optical waveguide bands 29 are provided on the first main surface 25 a of the waveguide substrate 25. The plurality of optical waveguide bands 29 extend, for example, linearly over the whole, and are arranged in parallel with each other and evenly. However, the plurality of optical waveguide bands 29 may be appropriately bent or unevenly arranged.

Each optical waveguide band 29 has a plurality of optical waveguides 33 (see FIG. 10). As is well known, each optical waveguide 33 has the same configuration as an optical fiber, and has a core and a clad (not shown). The optical waveguide 33 may be an appropriate type such as a slab type, a buried type, or a semi-buried type. Each optical waveguide 33 may be covered with a film or the like and not visible. The plurality of optical waveguides 33 extend, for example, linearly over the whole and are arranged in parallel and evenly with each other. However, the plurality of optical waveguides 33 may be appropriately bent or unevenly arranged.

FIG. 3 is a perspective view showing the optical plug 17.

The optical plug 17 has a plug main body portion 17m that holds the optical cable 27, and guide pins 17c provided in parallel to the plug main body portion 17m. These are all inserted into holes (described later) of the optical receptacle 19 and used for positioning (connection) between the optical cable 27 and the optical waveguide band 29.

The plug body 17m has a base 17a and a plurality of protrusions 17b protruding from the tip of the base 17a. The tip of the optical cable 27 is held by the protrusion 17b and exposed from the tip of the protrusion 17b.

The base portion 17a is formed in a substantially rectangular parallelepiped shape, for example. The corner of the tip of the base portion 17a is chamfered so that the insertion of the optical receptacle 19 into the hole is facilitated.

The plurality of protrusions 17b are arranged in the width direction (z direction) of the base portion 17a. Each protrusion 17b is smaller than the base 17a not only in the width direction but also in the thickness direction (x direction), for example. Although not particularly illustrated, the tip of the protrusion 17b may be chamfered so as to facilitate the insertion of the optical receptacle 19 into the hole, similarly to the tip of the base 17a.

The guide pins 17c are provided, for example, as a pair on both sides in the width direction (z direction) of the base portion 17a, and protrude to the same position as the tip of the base portion 17a. The tip of the guide pin 17c is tapered so that insertion into the hole of the optical receptacle 19 is facilitated.

The optical cable 27 extends from the middle of the height direction (y direction) to the outside of the optical plug 17 on the one side surface in the thickness direction (x direction) of the base portion 17 a, and the first main surface 21 a of the midplane 21. It extends toward.

A plurality of grooves 17e extending in the insertion direction of the base portion 17a are formed on the surface of the base portion 17a in the thickness direction. The plurality of grooves 17e are also formed on the side opposite to the side from which the optical cable 27 extends (see FIG. 5). The plurality of grooves 17 e function as a guide when the base portion 17 a is inserted into the optical receptacle 19 and contribute to positioning of the optical cable 27.

4 (a) and 4 (b) are perspective views of the optical plug 17 with some members removed.

As shown in FIGS. 3 and 4, the optical plug 17 includes, for example, a positioned member 39 that constitutes the protrusion 17b, a holding member 34 that holds the positioned member 39, and an elastic member that is interposed therebetween. 43 (FIG. 4B).

The holding member 34 includes, for example, a root-side member 35 that constitutes a root-side portion of the base portion 17a, a tip-side member 37 (FIG. 3) that constitutes a tip-side portion of the base portion 17a, and a pin member 41 having a guide pin 17c. have.

The positioned member 39 holds the tip of the optical cable 27. The positioned member 39 is configured by, for example, adhering two members that sandwich the tip of the optical cable 27 (the plurality of optical fibers 31), and sandwiches the optical cable 27 and is adhered to the optical cable 27.

The root side member 35 and the tip side member 37 are coupled to each other to hold the positioned member 39 therebetween. Specifically, for example, the distal end side member 37 accommodates substantially the entire positioned member 39 in a space opened to the root side member 35 side, and the root side member 35 closes the space. However, the distal end (projecting portion 17 b) of the positioned member 39 projects from the distal end opening of the distal end side member 37.

The base side member 35 and the tip side member 37 are coupled by, for example, engagement. In the present embodiment, a claw portion 35f is formed in the root side member 35, and a hole portion 37f (FIG. 3) in which the claw portion 35f is engaged is formed in the distal end side member 37.

The root side member 35 and the tip side member 37 are allowed to move within a predetermined range in the connection direction (y direction) of the positioned member 39. Further, the root side member 35 and the tip side member 37 permit the movement of the positioned member 39 within a relatively small range of play even in the direction (z direction and x direction) orthogonal to the connection direction.

The root side member 35 and the tip side member 37 can hold any number of positioned members 39 within a predetermined number (four in the present embodiment).

The pin member 41 includes a guide pin 17c and a pedestal portion 41a that supports the guide pin 17c. The pedestal portion 41 a is positioned on the root side member 35. For example, the root side member 35 has a bottom surface portion 35 a that is overlapped with the first main surface 21 a of the midplane 21. The pedestal portion 41a is placed on a portion of the bottom surface portion 35a protruding in a flange shape. The pedestal portion 41a and the bottom surface portion 35a are positioned in a direction (xy direction) along the first main surface 21a by forming protrusions and grooves on the contact surfaces.

The elastic member 43 urges the positioned member 39 toward the distal end side with respect to the root side member 35. As a result, the contact pressure between the positioned member 39 and the waveguide substrate 25 is adjusted. As a result, the optical cable 27 can be stably urged toward the optical waveguide band 29 with a predetermined force, and the optical connection loss can be reduced. The biased force can be set to be 4N or more and 20N or less, for example. Furthermore, in the connection between the optical fiber and the optical waveguide, if the urging force is set to be, for example, 10N or more and 14N or less, the optical connection loss can be minimized. Further, even before the optical connector 5 is fitted, the positioning member 39 is prevented from rattling, the posture is maintained, and the alignment is improved, which contributes to workability and high-precision connection. The elastic member 43 is, for example, a compression coil spring, and is generally accommodated in the root side member 35.

FIG. 5 is a perspective view of the optical plug 17 as viewed from the second main surface 21b side of the midplane 21. FIG.

As shown in this figure, the optical plug 17 is held on the midplane 21 by a washer 47 superimposed on the second main surface 21b and a screw 45 inserted through the washer 47 and the midplane 21.

6 (a) and 6 (b) are cross-sectional views taken along the line VIa-VIa in FIG. 5, and show different states. FIG. 6C is a cross-sectional view taken along the line VIc-VIc in FIG.

The optical plug 17 is attached to the midplane 21 so as to be movable in the direction along the first main surface 21a with respect to the midplane 21. That is, the optical plug 17 is attached using a so-called floating structure. Specifically, it is as follows.

The root side member 35 has a boss 35 b that protrudes from the bottom surface portion 35 a to the midplane 21 side and is inserted into a hole portion 21 h formed in the midplane 21. A nut 49 is accommodated in the pedestal portion 41 a of the pin member 41. The nut 49 is inserted into the pedestal portion 41a from a slit (not shown) formed on the side surface of the pedestal portion 41a, for example. The screw 45 is inserted into a hole formed in the boss 35 b and is screwed into the nut 49. The pedestal 41a itself may be internally threaded.

Here, the protruding amount of the boss 35b from the bottom surface portion 35a is larger than the thickness of the midplane 21. Accordingly, when the screws 45 are screwed together, the washer 47 comes into contact with the boss 35b and is clamped between the boss 35b and the screw head of the screw 45 before the midplane 21 is clamped with the bottom surface portion 35a. Therefore, the optical plug 17 is not fixed to the midplane 21 by the screw 45 and the washer 47.

Since the diameter of the bottom surface portion 35 a and the washer 47 is larger than the diameter of the hole portion 21 h of the midplane 21, the vertical movement (y direction) of the optical plug 17 with respect to the midplane 21 causes the bottom surface portion 35 a and the washer 47 to move. The clearance is regulated within the range of the difference between the clearance and the thickness of the midplane 21. In other words, by increasing the clearance with respect to the thickness of the midplane 21, the optical plug 17 can be moved in the y direction. Thereby, for example, looseness in fitting in the y direction can be reduced. Therefore, for example, the optical plug 17 may be movable only in the y direction.

Further, a cushioning material may be arranged between the bottom surface portion 35a and the midplane 21 or between the washer 47 and the midplane 21 to further enhance the effect of alleviating the looseness of fitting in the y direction. As the buffer material, for example, a urethane resin or a coil spring can be used. By disposing such a buffer material, if movement in the xz direction is possible, movement in the xz direction can be suppressed, and unnecessary rattling of the optical plug 17 can be suppressed. it can.

The diameter of the boss 35b is set smaller than the diameter of the hole 21h of the midplane 21. Accordingly, the optical plug 17 is movable with respect to the midplane 21 in the direction along the first main surface 21a of the midplane 21 within a range of the difference between the diameter of the boss 35b and the diameter of the hole 21h. In addition, the shape in the cross section of FIG.6 (c) of the boss | hub 35b and the hole 21h may be set suitably. FIG. 6C illustrates a circular case.

FIG. 7A is a perspective view showing the optical receptacle 19. FIG. 7B is a perspective view showing the optical receptacle 19 with some members removed.

As already described, the optical plug 17 has the plug main body portion 17m and the guide pin 17c. Correspondingly, the optical receptacle 19 includes a body hole 19m (FIG. 7A) into which the plug body 17m is fitted, and a pin hole 19c (FIG. 7A) into which the guide pin 17c is fitted. )have.

The main body hole 19m includes a base hole 19a (FIG. 7A) corresponding to the base 17a and a plurality of protrusion holes 19b (FIG. 7) located on the back side and corresponding to the plurality of protrusions 17b. (B)). An end portion of the optical waveguide band 29 connected to the optical cable 27 is exposed to the outside of the optical receptacle 19 through the projection hole 19b and the base hole 19a.

From another viewpoint, the optical receptacle 19 includes a fixing member 51 (FIG. 7A) having a base hole 19a and a pin hole 19c, and a plurality of positioning members 53 (FIG. 7) each having a protrusion hole 19b. 7 (b)).

The shape of the base hole 19 a corresponds to the shape of the base portion 17 a of the optical plug 17. That is, the base hole 19a has a substantially rectangular parallelepiped shape, and a plurality of rails 19e guided by the plurality of grooves 17e of the base portion 17a are formed on the inner peripheral surface thereof. The opening end (end on the negative side in the y direction) of the base hole 19a is enlarged toward the edge side (the negative side in the y direction) so that the base 17a can be easily inserted (the inclined surface 19aa is formed). )

The cross-sectional shape of the pin hole 19c corresponds to the cross-sectional shape of the guide pin 17c, and is circular in this embodiment. The opening end of the pin hole 19c (the end on the negative side in the y direction) is enlarged toward the edge (the negative side in the y direction) so that the guide pin 17c can be easily inserted (the inclined surface 19ca is formed). ing.).

The pin hole 19c is formed in a portion of the optical receptacle 19 (fixing member 51) that is configured to protrude to the optical plug 17 side (y direction negative side), and an opening end on the optical plug 17 side. Is located closer to the optical plug 17 than the opening end of the base hole 19a on the optical plug 17 side.

The fixing member 51 includes, for example, a hollow portion 51a in which a base hole 19a is formed, and an extending portion 51b extending from the upper surface side (x direction positive side) portion of the hollow portion 51a to the root side (y direction positive side). Have.

The hollow portion 51a is formed, for example, in a generally cylindrical shape with a rectangular cross section. The extending portion 51b is a portion that contributes to fixing the fixing member 51 and is formed in a plate shape that is generally overlapped with the waveguide substrate 25, for example. In addition, in order to make the thickness of the hollow part 51a thin, the groove | channel and the recessed part are provided in the outer surface of the fixing member 51 suitably.

The fixing member 51 causes the rear end surface (surface facing the y-direction positive side) of the hollow portion 51a to abut on the end surface 25fa (surface facing the y-direction negative side) of the waveguide substrate 25 and the extending portion 51b. Is positioned so as to overlap the first main surface 25a of the waveguide substrate 25. The screw 55 (FIG. 1) is inserted into the insertion hole 51h formed in the extending portion 51b and the insertion hole (not shown) formed in the optical waveguide substrate 25, and the second main surface of the waveguide substrate 25. The fixing member 51 is fixed to the waveguide substrate 25 by screwing with a nut (not shown) arranged on the 25b side.

The positioning member 53 is disposed on the first main surface 25 a of the waveguide substrate 25 and is fixed to the waveguide substrate 25 by being pressed by the fixing member 51. Therefore, the positioning member 53 does not need to be directly fixed to the waveguide substrate 25 with a screw or an adhesive. The fixing members 51 can fix the positioning members 53 to the waveguide substrate 25 by an arbitrary number within a predetermined number (four in the present embodiment).

The elastic member 57 is interposed between the positioning member 53 and the fixing member 51. The elastic member 57 is a leaf spring, for example. Therefore, the force for pressing the positioning member 53 by the fixing member 51 is kept substantially constant regardless of the processing accuracy of the fixing member 51 and the tightening strength of the screw 55.

FIG. 8A is a perspective view showing the waveguide substrate 25 in a state where the positioning member 53 is placed, and FIG. 8B is a waveguide substrate 25 in which the positioning member 53 is not placed. FIG.

The positioning member 53 includes a hollow portion 53a in which the protrusion hole 19b is formed, and an extending portion 53b extending from the upper surface side (x direction positive side) portion of the hollow portion 53a to the root side (y direction positive side). is doing.

The hollow portion 53a is formed in a generally rectangular frame shape, for example. The end of the optical waveguide band 29 is exposed inside (in the protrusion hole 19b). The extending part 51b is a part that contributes to the positioning of the positioning member 53, and is formed, for example, in a plate shape that is generally overlapped with the waveguide substrate 25.

The cross-sectional shape of the protrusion hole 19 b corresponds to the cross-sectional shape of the protrusion 17 b of the optical plug 17. That is, the projection hole 19b has a substantially rectangular parallelepiped shape. However, the opening end portion (end portion on the negative side in the y direction) of the protrusion hole 19b is increased in diameter toward the edge side (negative direction side in the y direction) so that the protrusion portion 17b can be easily inserted (the inclined surface 19ba). Is formed.)

A plurality of protrusions 53c are formed on the inner peripheral surface of the protrusion hole 19b. The protrusion 17b of the optical plug 17 is positioned by a plurality of protrusions 53c coming into contact with the outer periphery thereof.

Therefore, for example, the positioning member 53 does not need to be formed with high accuracy over the entire circumference of the projection hole 19b, and may be formed with high accuracy only at the projection 53c. Further, the thermal deformation in the portion between the projections 53c of the positioning member 53 does not directly affect the positioning accuracy. Further, the sliding area between the projecting portion 17b of the optical plug 17 and the projecting portion hole 19b is reduced, and as a result, the sliding resistance is reduced.

In the positioning member 53, a relief groove 53e (see also FIG. 10) is formed at a corner between a surface that is superimposed on the first main surface 25a of the waveguide substrate 25 and a surface that is in contact with the end surface 25fa of the waveguide substrate 25. Yes.

Therefore, the corners of the first main surface 25a and the end surface 25fa of the waveguide substrate 25 are less likely to affect the positioning of the positioning member 53. For example, when the waveguide substrate 25 is cut out from the mother substrate (wafer), the positioning accuracy is maintained even if uncut portions are left at the corners of the first main surface 25a and the end surface 25fa due to dicing.

The positioning member 53 is positioned in the connection direction (y direction) by bringing the rear end surface (surface facing the y direction positive side) of the hollow portion 53 a into contact with the end surface 25 fa of the waveguide substrate 25. The positioning member 53 is positioned in the thickness direction (z direction) by overlapping the extending portion 53 b on the first main surface 25 a of the waveguide substrate 25.

Further, a protrusion 59 is provided on the first main surface 25a, and the positioning member 53 is fitted by fitting the protrusion 59 into a hole (not shown) formed in the extending portion 53b of the positioning member 53. Positioning in the width direction (z direction) is performed.

The protrusion 59 may be formed of an appropriate material such as resin, metal, or ceramic, and is fixed to the waveguide substrate 25 by an appropriate method such as being fixed by an adhesive or being welded to the waveguide substrate 25. May be fixed. A hole (not shown) of the positioning member 53 into which the protrusion 59 is fitted may be fitted not only in the z direction but also in the y direction, and is formed in a long hole shape in the y direction. The position adjustment of 53 in the y direction may be allowed.

The base side member 35, the distal end side member 37, the positioned member 39 and the pin member 41 constituting the optical plug 17, and the positioning member 53 and the fixing member 51 constituting the optical receptacle 19 are made of resin, ceramics, metal or the like. You may comprise with an appropriate material.

In addition, since the base side member 35, the front end side member 37, and the fixing member 51 are likely to be applied with a larger force than the positioned member 39 and the positioning member 53, the strength is higher than the material of the positioned member 39 and the positioning member 53. It is preferably composed of a high material. For example, the former is composed of PBT and the latter is composed of PPS.

In addition, the pin member 41 is easily applied with a large force, and since the secondary moment of the cross section of the guide pin 17c is small, the pin member 41 is made of a material having higher strength than the materials of the root side member 35 and the tip side member 37. It is preferable. For example, the root side member 35 and the tip side member 37 are made of resin, and the pin member 41 is made of resin or metal having higher strength than the resin.

Further, the material of the positioned member 39 and the positioning member 53 may be a material having a lower coefficient of thermal expansion than other materials. As will be described later, since it is the positioned member 39 and the positioning member 53 that contribute to the final positioning of the optical fiber 31 and the optical waveguide 33, by configuring these members with a material having a low thermal expansion coefficient, The optical connector 5 as a whole can be made inexpensive while reducing the influence of heat on positioning.

Dimension of each member may be set appropriately. As an example, one side of the outer shape of the positioned member 39 and the positioning member 53 is about several millimeters.

The operation (action) at the time of connection in the optical transmission module 3 having the above configuration will be described.

FIGS. 9A to 9D are views showing how the optical plug 17 is inserted into the optical receptacle 19. These drawings are plan views of the optical plug 17 and the optical receptacle 19 as viewed from the second main surface 23b side of the waveguide substrate 25, and the waveguide substrate 25 and the midplane 21 are not shown.

FIG. 9A shows a state immediately before the optical plug 17 is inserted into the optical receptacle 19. As shown by the deviation between the center line CL1 of the optical plug 17 and the center line CL2 of the optical receptacle 19, immediately before insertion, the optical plug 17 is in a direction perpendicular to the insertion direction with respect to the optical receptacle 19 (x direction and In the z direction), parallel displacement and rotational displacement may occur.

As described above, in the optical plug 17, the guide pin 17c extends to the same position as the tip of the base portion 17a. On the other hand, in the optical receptacle 19, the open end of the pin hole 19c (FIG. 7A) is It is located closer to the optical plug 17 than the opening end of the base hole 19a (main body hole 19m, FIG. 7A).

Accordingly, as shown in FIG. 9B, when the optical plug 17 is brought closer to the optical receptacle 19, the tip of the guide pin 17c is moved before the plug main body portion 17m is inserted into the main body hole 19m. It is inserted into the pin hole 19c of the optical receptacle 19 (primary positioning).

Here, as described above, the tip of the guide pin 17c is tapered, and the opening end of the pin hole 19c is enlarged toward the edge (inclined surface 19ca). In another aspect, there is a clearance in the direction orthogonal to the insertion direction between the tip of the guide pin 17c and the opening edge of the pin hole 19c.

Therefore, as long as the deviation between the optical plug 17 and the optical receptacle 19 is within the clearance, the tip of the guide pin 17c is inserted into the pin hole 19c. This clearance may be equal to or greater than the moving width of the floating structure (clearance between the boss 35b and the hole 21h).

As a result, the optical receptacle 19 is inserted and inserted into the optical plug 17 with a large clearance in relation to the optical plug 17, so that insertion workability is improved and defects such as buckling and breakage are reduced. it can.

Thereafter, as the insertion of the guide pin 17c into the pin hole 19c proceeds, the clearance decreases. That is, the guide pin 17c is guided by the pin hole 19c. As a result, as indicated by the arrow y1, the deviation between the optical plug 17 and the optical receptacle 19 is reduced.

Then, as shown in FIG. 9C, the deviation between the optical plug 17 and the optical receptacle 19 is almost eliminated. At substantially the same time, insertion of the plug main body 17m into the main body hole 19m is started (secondary positioning).

In this insertion, the base 17a slides in the base hole 19a, and the movement of the base 17a in the xz direction is restricted. The guide pin 17c and the pin hole 19c may also contribute to the secondary positioning following the primary positioning. As can be understood from the description so far, the play (rattle) between the base portion 17a and the base portion hole 19a is based on the clearance (initial value) at the start of insertion of the guide pin 17c and the pin hole 19c. Is also small.

Thereafter, as shown in FIG. 9 (d), the plug main body 17m is inserted into the main body hole 19m as far as it will go.

FIG. 10 is a perspective view showing the positioned member 39 and the positioning member 53 in the state of FIG. FIG. 12A is a cross-sectional view taken along line XIIa-XIIa in FIG. FIG. 12B is a cross-sectional view taken along line XIIb-XIIb in FIG.

As shown in these drawings, the protrusion 17b is fitted into the protrusion hole 19b (tertiary positioning). By this positioning, the optical fiber 31 and the optical waveguide 33 are finally positioned with high accuracy in the xz direction.

The movement of the optical plug 17 in the insertion direction of the holding member 34 is regulated by the holding member 34 coming into contact with the fixing member 51 of the optical receptacle 19. Specifically, for example, as shown in FIGS. 9D and 12B, the pedestal portion 41 a of the holding member 34 comes into contact with a portion where the pin hole 19 c of the fixing member 51 is formed. Regulations are made.

On the other hand, the movement of the optical plug 17 in the insertion direction of the positioned member 39 is restricted, for example, when the positioned member 39 comes into contact with the end face 25fa (FIG. 10) of the waveguide substrate 25. As described above, the contact pressure is defined by the elastic member 43.

As described above, in the present embodiment, the optical transmission module 3 includes the waveguide substrate 25 in which the optical waveguide 33 is provided on the first main surface 25a, the midplane 21 positioned on the waveguide substrate 25, and the optical waveguide 33. And an optical receptacle 19 fixed to the waveguide substrate 25. In addition, the optical transmission module 3 holds the optical fiber 31 and is fitted to the optical receptacle 19, whereby the optical waveguide 33 and the optical fiber 31 can be aligned in a direction (xz direction) orthogonal to the connection direction. The optical plug 17 is held by the midplane 21 so as to be movable in the xz direction. In the present embodiment, the optical plug 17 is held so as to be movable in the y direction.

In addition, since the optical plug 17 can move with respect to the midplane 21 even after the optical receptacle 19 is inserted, it is possible to prevent the optical connector 5 from being loaded. Therefore, the optical plug 17 has excellent long-term reliability and a highly accurate connection state. Can be maintained. Specifically, when physical vibration, impact, or thermal change is applied to the optical / electrical composite transmission module 1, or when maintenance work such as replacement of the blade 23 is performed, the blade with respect to the midplane 21 is used. However, since the movement of the blade 23 is absorbed by the movement of the optical plug 17 with respect to the midplane 21, no load is applied to the optical connector 5 and a stable fitting state can be maintained.

Further, even if the number of optical transmission lines is increased, a large number of optical cables do not float on the first main surface 23a of the blade 23, and simplification and downsizing of the structure are expected. Also, mechanical damage due to movement of the optical cable is reduced. Since the optical waveguide 33 is fixed to the waveguide substrate 25, if the positional deviation between the substrates occurs, the connection between the optical waveguide 33 and the optical fiber 31 is not preferably made or unnecessary for the waveguide substrate 25 or the like. There is a risk of stress. However, in the present embodiment, such a fear is reduced by the floating structure. As a result, for example, the influence of the connection of the electrical connector 11 with relatively low positioning accuracy on the connection of the optical connector 5 is reduced.

In this embodiment, the optical receptacle 19 has a pin hole 19c, the optical plug 17 has a guide pin 17c, and one of the pin hole 19c and the guide pin 17c is connected to the other in the connecting direction (y The clearance in the direction (xz direction) perpendicular to the connection direction between the two becomes smaller as the insertion proceeds.

Therefore, the floating structure is preferably used. That is, as already described, even if the initial displacement between the optical plug 17 and the optical receptacle 19 is relatively large, the guide pin 17c can be inserted into the pin hole 19c, and the position thereof can be reduced by the guiding action. Deviation can be reduced. As a result, for example, connection workability is improved.

Further, in the present embodiment, the optical receptacle 19 focuses only on the main body hole 19m (the protrusion hole 19b or the base hole 19a that exposes the optical waveguide 33 and is provided in parallel to the pin hole 19c. You may have). On the other hand, the optical plug 17 has a plug body portion 17m that is provided in parallel to the guide pin 17c and holds the optical fiber 31 and fits into the body portion hole 19m. After the insertion of the pin hole 19c and the guide pin 17c has progressed and the clearance between the two has decreased to a predetermined size, the plug body portion 17m is fitted into the body portion hole 19m.

That is, the optical receptacle 19 does not invite the plug main body portion 17m that holds the optical fiber 31, but does not hold the optical fiber 31 before the plug main body portion 17m is inserted into the main body hole 19m ( Guide pin 17c) is guided. Accordingly, it is possible to prevent the tip of the plug main body portion 17m (the tip of the optical fiber 31) from coming into contact with the peripheral portion of the main body hole 19m of the optical receptacle 19, and the optical fiber 31 is protected.

Further, in the present embodiment, the optical receptacle 19 is a separate member from the member (fixing member 51) constituting the pin hole 19c, and is used for a protrusion that constitutes at least a part on the back side of the body portion hole 19m. It has a positioning member 53 in which a hole 19b is formed. On the other hand, the optical plug 17 is a separate member from the member (pin member 41) constituting the guide pin 17c, and has a positioned member 39 that fits into the projection hole 19b.

Therefore, compared to the case where the entire optical plug 17 or the entire optical receptacle 19 is integrally formed, the members (positioning member 53 and positioned member 39) that contribute to the final positioning are reduced in size. When miniaturized, high-precision processing is facilitated. As a result, the optical fiber 31 and the optical waveguide 33 are aligned with high accuracy. Furthermore, such high-accuracy positioning can be realized with a single action simply and by protecting the tip of the optical fiber 31 by the above-described guiding action of the guide pin 17c.

Further, in this embodiment, the optical receptacle 19 has a base hole 19a that constitutes an inlet side of the protrusion hole 19b in the main body hole 19m. On the other hand, the optical plug 17 has a holding member 34 that holds the positioned member 39 so as to be movable within a predetermined play range in a direction orthogonal to the connection direction (xz direction) and fits into the base hole 19a. ing.

Therefore, after the leading action (primary positioning) by the pin hole 19c, the positioning member 39 (projecting part 17b) is not suddenly fitted into the projecting hole 19b (tertiary positioning) but held. The fitting of the member to be positioned 39 is started after the fitting (secondary positioning) of the member 34 (base 17a) to the base hole 19a is started.

As a result, when fitting, it is suppressed that a large force is applied to the positioned member 39, the inner peripheral surface of the protrusion hole 19b (positioning member 53), and the waveguide substrate 25. Even after the fitting, a large force is supported on the inner peripheral surface (fixing member 51) of the holding member 34 and the base hole 19a, and a large force is applied to the inner peripheral surface of the positioned member 39 and the protrusion hole 19b. Is suppressed. As a result, the optical fiber 31 and the optical waveguide 33 are protected.

On the other hand, the positioned member 39 is held by the holding member 34 so as to be movable within a predetermined play range, and therefore, the positioning member 39 and the positioned member 39 are projected to the positioning accuracy of the holding hole 34a. It is suppressed that the positioning accuracy with the part hole 19b is affected.

In the present embodiment, the optical receptacle 19 has the fixing member 51 that is fixed to the waveguide substrate 25 by the screw 55 and fixes the positioning member 53 to the waveguide substrate 25.

Therefore, it is possible to reduce the size of the positioning member 53 that contributes to the final positioning of the optical fiber 31 while securing the member volume necessary for fixing the positioning member 53 in the fixing member 51. As a result, the processing accuracy can be improved, and the positioning accuracy between the optical fiber 31 and the optical waveguide 33 can be improved.

In the present embodiment, the optical plug 17 is held by the midplane 21 so as to be movable in a direction (xz direction) orthogonal to the connection direction, and has a holding member 34 that holds the positioned member 39. .

Therefore, the member to be positioned 39 that contributes to the final positioning of the optical fiber 31 can be reduced in size while securing the volume of the member necessary for realizing the floating structure in the holding member 34. As a result, as a result, the processing accuracy is improved, and the positioning accuracy between the optical fiber 31 and the optical waveguide 33 is improved.

Further, in this embodiment, the optical receptacle 19 can have an arbitrary number of positioning members 53 within a predetermined number (predetermined number> 1, four in this embodiment). It is possible to have any number of positioning members 39 within the predetermined number.

Therefore, a plurality of optical cables 27 and a plurality of optical waveguide bands 29 can be connected. In such a case, the effects of simplification and miniaturization of the structure described above work more advantageously. In addition, since the optical connector 5 can connect any number of optical transmission lines, it is highly versatile and is expected to reduce costs by mass production.

In this embodiment, the waveguide substrate 25 is connected to the first main surface 21a of the midplane 21 with the first main surface 25a orthogonal to the first main surface 21a of the midplane 21. The optical plug 17 is provided on the first main surface 21 a of the midplane 21, holds the tip of the optical fiber 31 so as to extend in a direction perpendicular to the first main surface 21 a of the midplane 21, and the midplane 21. It is possible to move in the direction along the first main surface 21a.

Therefore, instead of connecting the optical transmission paths on the two blades orthogonal to the principal surfaces on both sides of the midplane (see Patent Document 1), the optical fiber 31 on the midplane 21 and the optical waveguide 33 on the blade 23 Can be connected. As a result, the degree of freedom of the optical wiring of the optical transmission module 3 is improved. Moreover, since the optical plug 17 should just be movable in the direction along the 1st main surface 21a, the movement range can be restrict | limited by the setting of the hole 21h (FIG.6 (c)). As a result, for example, the floating structure of this embodiment has a moving range defined as compared with a floating structure that needs to be movable in one direction along the blade and in a direction perpendicular to the blade (see Patent Document 1). Easy.

In the above embodiment, the waveguide substrate 25 is an example of the waveguide substrate of the present invention. The midplane 21 is an example of the connection base of the present invention. The pin hole 19c is an example of the guide portion of the present invention. The guide pin 17c is an example of the guided portion of the present invention. The protrusion hole 19b is an example of the first hole of the present invention. The base hole 19a is an example of the second hole of the present invention. The blade 23 is an example of the wiring substrate of the present invention. The electrical receptacle 15 is an example of the second electrical connector component of the present invention. The electrical plug 13 is an example of the first electrical connector component of the present invention.

The present invention is not limited to the above embodiments and modifications, and may be implemented in various modes.

The light transmission module may not have an electrical connector. In this case, the positioning of the waveguide base and the connection base may be performed by, for example, a housing that accommodates the substrate assembly.

The connecting substrate is not limited to the midplane, and the wiring substrate is not limited to the blade. For example, the connection base may be a backplane. Further, the connection between the connection base and the waveguide base is not limited to the connection in which the waveguide base is orthogonal to the main surface of the connection base. For example, the connection base and the waveguide base may be arranged along the main surface and the ends may be connected to each other. Also, for example, if a mirror is provided at the end of the optical waveguide, it is possible to connect the optical fiber in a direction orthogonal to the optical waveguide, and thus connect the connecting base to the main surface of the waveguide substrate. It is also possible to make them orthogonal.

The optical receptacle and the optical plug are not limited to those performing the three-stage positioning (first to third positioning) described with reference to FIGS.

For example, the guide portion and the guided portion (the pin hole 19c and the guide pin 17c) are not provided, only the secondary positioning by the base portion 17a and the base hole 19a and the tertiary positioning by the protrusion 17b and the protrusion hole 19b. It may be done. Even in this case, the floating structure can be used by manually adjusting the position of the optical plug with respect to the connection base.

In addition, for example, the plug body portion 17m is integrally formed, and therefore, after the primary positioning by the pin hole 19c and the guide pin 17c, it is fitted once (corresponding to the secondary positioning or the tertiary positioning). May be performed. Even in this case, effects such as improvement in workability by fitting after the guiding action are exhibited.

In the embodiment, the guided portion (side provided on the optical receptacle) is inserted into the guide portion (side provided on the optical plug), but the guide portion may be inserted into the guided portion. In the embodiment, the plug main body portion and the guided portion are separate parts in parallel, and the main body hole and the guide part are separate parallel holes. However, the plug body portion and the body portion hole may function as the guided portion and the guide portion.

The optical receptacle and the optical plug may be configured by an appropriate number of members. For example, in the embodiment, the root side member 35 and the pin member 41 are separate members, but they may be integrally formed. Further, for example, the guided portion and the plug body portion that are parallel to each other may be integrally formed, and the guide portion and the body portion hole that are parallel to each other may be integrally formed.

The optical connector may connect one optical cable and an optical waveguide band. For example, in the optical receptacle, the fixing member may fix only one positioning member, and in the optical plug, the holding member may hold only one positioned member. Furthermore, the optical connector may connect one optical fiber and one optical waveguide. For example, one optical cable may have only one optical fiber, and one optical waveguide band may have only one optical waveguide.

The optical cable extending from the optical plug may be routed in any direction. For example, the optical cable 27 may be routed as in the modification shown in FIG. In this modification, the optical cable 27 extending from the optical plug 217 extends linearly and penetrates the midplane 21.

Further, when a plurality of optical plugs are provided on the connection base, the arrangement thereof may be changed as appropriate. For example, the optical plug 17 may be arranged as in the modification shown in FIG. In this modification, the optical cable 27 extends along the first main surface 21a of the midplane 21 after extending from the optical plug 17 as in the embodiment. The optical plugs 17 are arranged so as to be displaced from each other in the direction orthogonal to the direction in which the optical cable 27 extends. By being arranged in this manner, the optical cable 27 extending from the adjacent optical plug 17 can be arranged in a state where it is difficult to bend.

Further, in the above description, the case where the connecting base is a midplane and the waveguide base is a blade has been described, but the present invention is not particularly limited thereto. For example, the connection base may be a backplane for connecting the midplane, and in that case, the waveguide base may be a midplane. That is, the connection base and the waveguide base can be appropriately selected from backplanes, midplanes and blades in equipment such as servers.

DESCRIPTION OF SYMBOLS 1 ... Photoelectric composite transmission module, 3 ... Optical transmission module, 17 ... Optical plug, 19 ... Optical receptacle, 21 ... Mid plane (connection base | substrate), 25 ... Waveguide board | substrate (waveguide base | substrate), 31 ... Optical fiber, 33 ... optical waveguide.

Claims

A waveguide base body provided with an optical waveguide on the main surface;
A coupling substrate disposed with respect to the waveguide substrate;
An optical fiber optically connected to the optical waveguide;
An optical receptacle fixed to the waveguide substrate;
An optical plug that holds the optical fiber and fits into the optical receptacle, and is fixed to the connection base in a state having play with respect to the connection base;
An optical transmission module having
The optical transmission module according to claim 1, wherein the optical plug is movable in a direction orthogonal to a direction in which the optical plug is fitted to the optical receptacle.
The optical receptacle has a guide part,
The optical plug has a guided portion,
The optical transmission module according to claim 1, wherein the guide portion and the guided portion have a shape in which a gap between the guide portion and the guided portion becomes smaller in a direction orthogonal to a fitting direction as insertion proceeds.
The optical receptacle has a hole for a main body part that is provided in parallel to the guide part and exposes the optical waveguide;
The optical plug is provided in parallel to the guided portion, has a plug body portion that holds the optical fiber and fits into the body portion hole,
The optical transmission module according to claim 3, wherein the plug main body portion is fitted into the main body portion hole after insertion of the guide portion and the guided portion proceeds and the gap is reduced to a predetermined size.
The optical receptacle is a member separate from the member constituting the guide portion, and has a positioning member in which a first hole constituting at least a part of the back side of the body portion hole is formed,
The optical transmission module according to claim 4, wherein the optical plug is a member different from a member constituting the guided portion and has a positioned member that fits into the first hole.
The optical receptacle has a second hole that constitutes an inlet side of the main body part hole than the first hole,
The optical transmission module according to claim 5, wherein the optical plug includes a holding member that holds the member to be positioned so as to be movable in the orthogonal direction and fits into the second hole.
The optical transmission module according to claim 5, wherein the optical receptacle includes a fixing member that is fixed to the waveguide base with a screw and that fixes the positioning member to the waveguide base.
The optical transmission module according to claim 5, wherein the optical plug is held by the connection base so as to be movable in the orthogonal direction, and has a holding member that holds the positioned member.
The optical receptacle can have any number of positioning members within a predetermined number (> 1),
The optical transmission module according to any one of claims 5 to 8, wherein the optical plug can have any number of the positioned members within the predetermined number.
The waveguide base is connected to the main surface of the connection base so that the main surface provided with the optical waveguide is orthogonal to the main surface of the connection base;
The optical plug is provided on a main surface of the connection base, holds a tip portion connected to the optical waveguide of the optical fiber so as to extend in a direction perpendicular to the main surface of the connection base, and the connection base The optical transmission module according to any one of claims 1 to 9, wherein the optical transmission module is movable in a direction along a main surface of the optical transmission module.
A wiring substrate provided with electrical wiring;
A connecting base provided with electrical wiring;
A first electrical connector component fixed to the wiring substrate;
A second electrical connector fixed to the connection base and coupled to the first electrical connector component, thereby electrically connecting the wiring base and the connection base and positioning the wiring base and the connection base. Parts,
A waveguide base fixed on the wiring base and provided with an optical waveguide on the main surface;
An optical fiber optically connected to the optical waveguide;
An optical receptacle fixed to the waveguide substrate;
An optical plug that holds the optical fiber and fits into the optical receptacle, and is fixed to the connection base in a state having play with respect to the connection base;
An opto-electric composite transmission module.
An optical connector for connecting an optical transmission line between a waveguide substrate and a coupling substrate disposed to each other,
An optical receptacle that can be fixed to the waveguide substrate in a state in which the optical waveguide provided on the main surface of the waveguide substrate is exposed;
An optical fiber connector part capable of holding an optical fiber and movably attached to the connection base;
With optical connector.