JP4261455B2 - Optical junction connector - Google Patents

Description

  The present invention relates to a passive device for relaying optical signals to be transmitted and / or optical demultiplexing / multiplexing, and more particularly to optical communication used for wiring of various electrical equipment in automobiles, homes / buildings. The present invention relates to a connector type suitable for optical communication and the like, that is, an optical junction connector.

  In recent years, optical communication has become widespread in automobiles, homes, and buildings, and the diversification of networks is progressing with an increase in the number of nodes (number of terminals) that perform communication using light. Therefore, there is a need for a passive device that corresponds to a junction block in a wire harness and that can demultiplex and multiplex light.

  As this kind of passive device, an optical waveguide module as shown in FIG. 69 is known, and optical coupling is performed through the following steps (for example, see Patent Document 1).

  That is, the optical fiber 3 is aligned in accordance with the arrangement of the optical waveguides 2 of the optical waveguide module 1 to form the aligned optical fibers 4 and 5, and the image includes the light that has passed through the aligned optical fiber 4 and the optical waveguide module 1. The alignment optical fiber 4 and the optical waveguide module 1 are roughly positioned while being monitored by the TV camera 6 and the monitor 7, and the alignment optical fiber 5 is connected to the light quantity measuring device 8, and the alignment optical fiber 4 and the optical waveguide are thereby connected. A process of precisely aligning the optical fibers 4 and 5 and the optical waveguide module 1 while measuring the light passing through the module 1, and bonding optical fibers 4 and 5 to each end face of the optical waveguide module 1 Optical coupling is performed.

In FIG. 69, reference numeral 9 denotes a personal computer, 10 denotes a controller, 11 denotes a laser diode, and 12 denotes a stage. The stage 12 is controlled by the personal computer 9 and the controller 10.
JP-A-8-43676 (pages 3 to 4 and FIG. 4)

  By the way, the above prior art has a problem that an expensive apparatus and time are required for alignment (optical axis alignment) and optical coupling between the optical fiber 3 and the optical waveguide 2. Further, there is a problem that an adhesive is required for fixing the alignment optical fibers 4 and 5 and the optical waveguide module 1, and further, a light source device for curing the adhesive and a curing time are required.

  The present invention has been made in view of the above-described circumstances, and it is an object to provide an optical junction connector that is easy to align and optically couple and does not require an expensive device for aligning and optically coupling. To do.

The optical junction connector of the present invention according to claim 1, which has been made to solve the above problems, includes one optical connector and the other optical connector that are fitted together using a lock portion,
The one optical connector is
One connector housing formed in a rectangular cylindrical shape in which a cross section in a direction perpendicular to the longitudinal direction is a substantially rectangular hollow space;
A plate-like member accommodated in the one connector housing and having a rectangular shape in plan view, and a plurality of planar optical waveguides for light branching or optical merging, and a substrate on which the plurality of planar optical waveguides are arranged A planar optical waveguide member constituted by:
A member mounting base for accommodating the planar optical waveguide member in the one connector housing;
A ferrule of one optical connector attached to the end of the optical fiber and housed in the one connector housing;
One ferrule connection portion formed in a slit shape in accordance with the shape of the convex portion of the ferrule to connect the ferrule of the one optical connector to the rear wall of the member mounting base so as to be detachable;
A pressing member that acts to constantly press the ferrule of the one optical connector toward the one ferrule connection portion of the mounting base;
The other ferrule connection part formed in the shape of a slit according to the shape of the convex part of the ferrule to connect the ferrule of the other optical connector to the front wall of the member mounting base so as to be insertable and removable;
With
The other optical connector is
The other connector housing formed in a rectangular cylindrical shape in which a cross section in a direction perpendicular to the longitudinal direction is a substantially rectangular hollow space;
A ferrule of the other optical connector attached to the end of the optical fiber and housed in the other connector housing, and having a front surface formed with a convex portion to be inserted into the other ferrule connection portion of the member mounting base; ,
A pressing member of the other optical connector that acts to constantly press the ferrule of the other optical connector toward the other ferrule connection portion of the mounting base for the member;
With
The rear wall of the member mounting base functions as a ferrule contact surface that regulates the insertion depth of the convex portion with respect to the ferrule of the one optical connector, and the front wall of the member mounting base is the other Functioning as a ferrule contact surface for restricting the insertion depth of the convex portion with respect to the ferrule of the optical connector
The convex portion of the ferrule of the one optical connector and the convex portion of the ferrule of the other optical connector are inserted into the member mounting base so as to be freely inserted into and removed from the one ferrule connecting portion and the other ferrule connecting portion of the member mounting base. By doing so, the ferrule of the one optical connector, the ferrule of the other optical connector, and the planar optical waveguide are aligned without contacting the end faces.
According to the present invention having such characteristics, when one optical connector and the other optical connector are fitted, the lock portions of each optical connector are fitted to each other, and the planar optical waveguide of the planar optical waveguide member The optical fiber of each optical connector is aligned. Thereby, the relay of the optical signal and / or the optical branching or the optical merging through the planar optical waveguide member is completed.

According to a second aspect of the present invention, there is provided the optical junction connector according to the first aspect, further comprising a pressing member for pressing the planar optical waveguide member attached to the member mounting base. It is said.
According to the present invention having such characteristics, the planar optical waveguide member is pressed by the pressing member. The position of the planar optical waveguide member on the member mounting base is further stabilized. As an alternative to the pressing member, the invention of claim 6 and other mechanisms, specifically, a predetermined alignment mechanism for the planar optical waveguide member may be formed on the member mounting base.

Light Junction connector according to the invention of claim 3, wherein, in the optical junction connector according to claim 2, the pressing portion for pressing said planar optical waveguide member mounted for base the member mounting the connector housing or It is characterized by being provided integrally with the member mounting base.
According to the present invention having such a feature, the planar optical waveguide member is pressed by the pressing portion of the connector housing or the pressing portion of the member mounting base. The position of the planar optical waveguide member on the member mounting base is further stabilized. By integrating the pressing portion into the connector housing or the member mounting base, an increase in the number of parts can be suppressed. Examples of the pressing portion include a piece-like pressing piece that can be elastically deformed, and a locking projection that has a claw portion at an end portion and can be elastically cut.

The optical junction connector of the present invention according to claim 4 is the optical junction connector according to claim 2 or 3 ,
A guide part for guiding the ferrule in the connector fitting direction is formed on the member mounting base, and a guided part guided by the guide part is formed on the ferrule.
According to the present invention having such a feature, the guide portion and the guided portion are used when the ferrule is inserted into the ferrule connection portion of the member mounting base.

According to the first aspect of the present invention, the optical junction connector of the present invention can be provided as a configuration that does not require an expensive device or adhesive. In addition, the optical junction connector of the present invention can be provided as easy alignment and optical coupling. Light Junction connector of the present invention is less composed of an optical signal relay and / or the light fraction 岐又can the optical multiplexer flow.

According to the second and third aspects of the present invention, the position of the planar optical waveguide member on the member mounting base can be further stabilized.

According to the present invention described in claim 4 , alignment between the planar optical waveguide and the optical fiber can be further facilitated.

Hereinafter, description will be given with reference to the drawings.
FIG. 1 is an exploded perspective view showing an embodiment of the optical junction connector of the present invention. 2 is an exploded perspective view of one optical connector, FIG. 3 is an exploded perspective view of the other optical connector, FIG. 4 is a perspective view showing a state before the one and the other optical connectors are fitted, and FIG. And the perspective view which shows the fitting state of the other optical connector, FIG. 6 is a perspective view of an optical waveguide member.

1 to 6, reference numeral 21 indicates an optical junction connector of the present invention used for optical communication in a car, optical communication in a house or a building, and the like. The optical junction connector 21 is interposed between the ends of the optical communication paths of the optical fiber 22 (for example, having a core diameter of about 200 μm or more), and relays optical signals transmitted by the optical fiber 22. / or the light fraction 岐又is configured to be able to the optical multiplexer flow. Specifically, the optical junction connector 21 of the present invention includes one optical connector 24 having an optical waveguide member 23 and the other optical connector 25 fitted to the one optical connector 24. . Hereinafter, each component will be described in detail.

  The one optical connector 24 is a so-called receptacle-type optical connector, and includes a connector housing 26, the optical waveguide member 23 housed in the connector housing 26, and the optical waveguide member 23 inside the connector housing 26. A member mounting base 27 for accommodating the optical fiber member 23, a pressing member 28 mounted on the optical waveguide member 23, a ferrule 29 attached to the end of the optical fiber 22 and accommodated in the connector housing 26, A pressing member 30 that acts to press the ferrule 29 against the member mounting base 27, and a pressing member pressing cap 31 that is attached to the rear portion of the connector housing 26 by attaching the pressing member 30. Yes.

  The connector housing 26 is formed using a synthetic resin material, and is formed in a rectangular cylindrical shape in which a cross section in a direction perpendicular to the longitudinal direction is a substantially rectangular hollow space. A fitting space for inserting the other optical connector 25 is formed inside the connector housing 26 on the front side. A first housing space for housing the member mounting base 27 with the optical waveguide member 23 attached is formed in the middle of the connector housing 26. Further, a second accommodation space for accommodating the ferrule 29 is formed inside the rear surface side of the connector housing 26. The fitting space, the first housing space, and the second housing space are formed as a continuous space. Note that a positioning stopper (not shown) for the member mounting base 27 is formed in the first accommodation space.

  An arm locking portion 32 (lock portion) for hooking a locking arm 50 (described later) of the other optical connector 25 is formed outside the front side of the connector housing 26. The arm locking portion 32 is formed on the upper surface (upper wall) of the connector housing 26. A guide groove 33 for guiding the other optical connector 25 is formed in the arm locking portion 32. The guide groove 33 is formed on the fitting space side.

  A guide projection 34 and a locking projection 35 for guiding the pressing member pressing cap 31 are formed outside the connector housing 26 on the rear surface side. The guide protrusion 34 is formed on the upper surface of the connector housing 26. The locking projection 35 is formed on the side surface (side wall) of the connector housing 26.

  In this embodiment, the optical waveguide member 23 is a plate-like member having a rectangular shape in plan view, and a plurality of optical waveguides for optical demultiplexing (may be used for relay and / or optical multiplexing). 36 and a synthetic resin substrate 37 on which the plurality of optical waveguides 36 are arranged. The optical waveguide member 23 is formed so as to be mounted on the member mounting base 27 without rattling. The optical waveguide 36 has a core and a clad (consisting of an under clad and an over clad described later) having a refractive index lower than that of the core. Such an optical waveguide 36 is arranged along a desired path with respect to the substrate 37 (the arrangement state is not particularly limited). Further, the end face (end part) of the optical waveguide 36 is formed flush with the end face (end part) of the substrate 37 and is disposed so as to be exposed from the end face.

  Here, an example is given and demonstrated about the manufacturing method of the optical waveguide member 23. FIG. The optical waveguide member 23 is manufactured through the following first to third steps. The manufacturing method described below has the advantage of good mass productivity.

  In the first step, for example, an undercladding layer is formed on a substrate 37 made of a silicon substrate, a glass substrate, an acrylic substrate, or the like. The under clad layer is formed over the entire surface of the substrate 37. The undercladding layer is composed of core materials (acrylic UV curable resin: NORALD NOA61n = 1.56, acrylic UV curable resin: NORLANDD NOA68n = 1.54, epoxy UV curable resin: EMI OPTOCAST 3506n = 1.56. Synthetic resin materials (PMMA: Mitsubishi Rayon Acrypet n = 1.49, PP: Sumitomo Mitsui Polypro n = 1.49, etc.) whose refractive index is lower than that of an example. It shall be an example). The underclad layer is formed to have an appropriate thickness. When the substrate 37 is transparent, it may be used as an underclad layer.

  In the second step, the core is formed on the underclad layer. The core is made of core materials (acrylic UV curable resin: NOLAND 61n = 1.56 made by NORLAND, acrylic UV curable resin: NOA 68n = 1.54 made by NORLAND, epoxy UV curable resin: OPTOCAST 3506n = 1.56 made by EMI, etc. It is assumed to be an example) and is formed into a convex shape in a desired path. The core is molded using a core molding die having a core molding recess.

  In the third step, an overcladding layer is formed around the core. The overcladding layer is made of a synthetic resin material (acrylic UV curable resin: NORLAND, NOA65n = 1.52, acrylic UV curable resin: XVL-90n = 1, manufactured by Kyoritsu Chemical Industry), which has a lower refractive index than the core material. .52, epoxy-based UV curable resin: EMI OPTOCAST 3505n = 1.52, etc. (assumed to be an example). The overcladding layer is formed using an overcladding mold having an overcladding recess.

  The member mounting base 27 is formed using a synthetic resin material, and is formed in a shallow, substantially box shape having a bottom wall, a front wall, a rear wall, and a pair of side walls as shown in the figure. The internal space formed by each wall is a mounting portion 38 for mounting the optical waveguide member 23, and is formed in a rectangular shape in plan view. In this embodiment, the optical waveguide member 23 is mounted in a state where the optical waveguide member 23 is fitted to the mounting portion 38 and is aligned without backlash. The member mounting base 27 is formed so as to be housed in the first housing space of the connector housing 26 with the optical waveguide member 23 mounted. The member mounting base 27 comes into contact with the stopper of the first accommodation space to be positioned.

  A ferrule connection portion 39 for connecting the ferrule 29 so as to be insertable / removable is formed on the rear wall of the member mounting base 27. The ferrule connection portion 39 has a slit shape and is formed in accordance with the shape of a convex portion 42 described later of the ferrule 29. Further, a ferrule connection portion 40 is formed on the front wall of the member mounting base 27 for connecting a ferrule 47 (to be described later) of the other optical connector 25 so that it can be inserted and removed. The ferrule connection part 40 is also formed in accordance with the shape of the convex part 54 described later of the ferrule 47 described later, similarly to the ferrule connection part 39 described above.

  The rear wall of the member mounting base 27 has a function as a ferrule contact surface that regulates an insertion depth (an insertion depth of a convex portion 42 described later) with respect to the ferrule 29. Similarly, the front wall of the member mounting base 27 has a function as a ferrule contact surface that regulates an insertion depth (an insertion depth of a convex portion 54 described later) with respect to a ferrule 47 described later. ing.

  In the member mounting base 27, holes are formed from the front wall to the rear wall, more specifically through the side walls. In each hole, a guide portion 41 is formed by inserting a pin for guiding the ferrule 29 and a ferrule 47 described later in the connector fitting direction. The pin is formed longer than the length from the front wall to the rear wall, and a portion protruding from the front wall and the rear wall by a predetermined length is set as the guide portion 41. In addition, the said pin does not need to penetrate a rear wall from a front wall. That is, it may be divided into a front wall pin and a rear wall pin.

  The pressing member 28 is an elastically deformable member for pressing the optical waveguide member 23 from above the optical waveguide member 23 attached to the member mounting base 27, and is formed in a rectangular shape as shown in the figure, for example. ing. The pressing member 28 is made of, for example, rubber, foamed resin, gel, or the like. One surface of the pressing member 28 is in contact with the optical waveguide member 23, and the other surface is in contact with the middle inside of the connector housing 26. Further, the pressing member 28 is designed to undergo some elastic deformation between them. The pressing member 28 is provided to stabilize the position of the optical waveguide member 23 in the member mounting base 27. When a predetermined alignment mechanism for the optical waveguide member 23 is formed on the member mounting base 27, the setting of the pressing member 28 may be arbitrary.

  The ferrule 29 is formed using a synthetic resin material, and is formed in a substantially box shape as illustrated. The ferrule 29 is a member for holding the tip of the optical fiber 22 and optically coupling the optical fiber 22 to the optical waveguide 36 of the optical waveguide member 23. In this embodiment, four ferrules 29 are provided on one optical connector 24. Therefore, the four optical fibers 22 are formed so as to be optically coupled to the optical waveguide member 23 in a state where the four optical fibers 22 are arranged in a horizontal row (a ferrule is provided for each optical fiber 22). Needless to say, the stability, workability, cost, etc. of the optical coupling are improved as compared with the provision of the optical fibers 22. The number of the optical fibers 22 is an example). The ferrule 29 is formed so as to be housed in the second housing space of the connector housing 26.

  The front surface of the ferrule 29 is formed so as to abut against the rear wall of the member mounting base 27 having a function as a ferrule abutting surface. On the front surface of the ferrule 29, a convex portion 42 that is inserted into the ferrule connection portion 39 of the member mounting base 27 is formed. The convex portion 42 is formed as a portion exposing the end faces of the four optical fibers 22. In addition, a hole-shaped guided portion 43 is formed on the front surface of the ferrule 29. The guided portion 43 is formed as a portion guided by a guide portion 41 provided on the member mounting base 27. It should be noted that the arrangement of the guide part 41 and the guided part 43 may be reversed. That is, the member mounting base 27 side may have a hole shape and the ferrule 29 side may have a pin shape.

  The pressing member 30 is a member for pressing the ferrule 29 against the member mounting base 27. In this embodiment, a leaf spring is used (not limited to the leaf spring. For example, a coil spring or a flexible member) Other members may be used as long as they can generate a resilience like a sex member). In response to the action from the pressing member 30, the ferrule 29 is always pressed toward the ferrule connection portion 39 of the member mounting base 27.

  The pressing member pressing cap 31 is formed using a synthetic resin material, and has a bottom wall, a rear wall, and a pair of side walls as shown in the figure, and is formed in a substantially box shape with a front surface and an upper surface released. ing. The pressing member pressing cap 31 is a member for fixing the position of the pressing member 30 and is formed so as to be fitted to the rear portion of the connector housing 26 (corresponding to the outside on the rear surface side).

  Although not particularly shown, a portion for inserting the four optical fibers 22 is formed on the rear wall of the pressing member pressing cap 31. The pressing member 30 is appropriately fixed to the rear wall of the pressing member pressing cap 31 by means. On each side wall of the pressing member pressing cap 31, a concave locking portion 44 that is hooked on the locking protrusion 35 of the connector housing 26 is formed. A guide groove 45 for guiding the guide protrusion 34 of the connector housing 26 is formed at the upper end of each side wall of the pressing member pressing cap 31.

  The other optical connector 25 is a so-called plug type optical connector, and includes a connector housing 46, a ferrule 47 attached to the end of the optical fiber 22 and accommodated in the connector housing 46, and the ferrule 47. A pressing member 48 that acts to press against the member mounting base 27 when the connector is fitted, and a pressing member pressing cap 49 that is attached to the rear portion of the connector housing 46 by attaching the pressing member 48 are configured. Yes.

  The connector housing 46 is formed using a synthetic resin material, and is formed in a rectangular cylindrical shape in which a cross section in a direction perpendicular to the longitudinal direction is a substantially rectangular hollow space. The connector housing 46 is formed in a shape that can be inserted into the fitting space of the one optical connector 24. A housing space for housing the ferrule 47 is formed inside the connector housing 46. On the upper surface (upper wall) of the connector housing 46, a locking arm 50 (locking portion) that is hooked on the arm locking portion 32 of the one optical connector 24 is formed. On the upper surface of the connector housing 46, a guide projection 51 guided by the guide groove 33 of the one optical connector 24 and a guide projection 52 for guiding the pressing member pressing cap 49 are formed. A locking projection 53 for the pressing member pressing cap 49 is formed on the side surface (side wall) of the connector housing 46.

  The ferrule 47 is molded using a synthetic resin material, and is formed in a substantially box shape as shown. The ferrule 47 holds the tip of the optical fiber 22 and optically couples the optical fiber 22 to the optical waveguide 36 of the optical waveguide member 23 when the one optical connector 24 and the other optical connector 25 are fitted. In this embodiment, since one optical fiber 22 is used for the other optical connector 25, the one optical fiber 22 can be optically coupled to the optical waveguide member 23. (The number of optical fibers 22 is an example). The ferrule 47 is formed so as to be accommodated therein from the rear surface side of the connector housing 46.

  The front surface of the ferrule 47 is formed so as to abut against the front wall of the member mounting base 27 having a function as a ferrule abutting surface. On the front surface of such a ferrule 47, a convex portion 54 to be inserted into the ferrule connection portion 40 of the member mounting base 27 is formed. The convex portion 54 is formed as a portion exposing the end face of one optical fiber 22. In addition, a hole-shaped guided portion (not shown; refer to the guided portion 43) is formed on the front surface of the ferrule 47. The guided portion is formed as a portion guided by a guide portion 41 provided on the member mounting base 27. A stopper 55 is formed on the rear surface of the ferrule 47 so as to contact the rear surface of the connector housing 46 for positioning. The optical fiber 22 is drawn from the rear surface of the ferrule 47.

  The pressing member 48 is a member for pressing the ferrule 47 against the member mounting base 27, like the pressing member 30 of the one optical connector 24. In this embodiment, a leaf spring is used (an elastic member). Other members may be used as long as the force can be generated). In response to the action from the pressing member 48, the ferrule 47 is always pressed toward the ferrule connection portion 40 of the member mounting base 27.

  The pressing member pressing cap 49 is formed using a synthetic resin material, and is formed in the same manner as the pressing member pressing cap 31 of the one optical connector 24. The pressing member pressing cap 49 is a member for fixing the position of the pressing member 48 and is formed so as to be fitted to the rear portion (corresponding to the outside on the rear surface side) of the connector housing 46.

  A through hole 56 for inserting one optical fiber 22 is formed in the rear wall of the pressing member pressing cap 49. A pressing member 48 is appropriately fixed to the rear wall of the pressing member pressing cap 49 by means. On each side wall of the pressing member pressing cap 49, a concave locking portion 57 that is hooked on the locking protrusion 53 of the connector housing 46 is formed. In addition, a guide groove 58 that is guided by the guide protrusion 52 of the connector housing 46 is formed at the upper end of each side wall of the pressing member pressing cap 49.

  Based on the above configuration, each assembly of one optical connector 24 and the other optical connector 25 and the assembly of the optical junction connector 21 of the present invention will be described.

  First, the assembly of one optical connector 24 will be described with reference to FIGS. 2 and 4 (assuming an example). In the first step relating to the assembly of one optical connector 24, an operation of fitting the optical waveguide member 23 into the mounting portion 38 of the member mounting base 27 provided with the guide portion 41 is performed. In the second step, an operation of mounting the pressing member 28 on the optical waveguide member 23 is performed. In the third step, the member mounting base 27 with the optical waveguide member 23 and the pressing member 28 mounted thereon is inserted from the rear surface side of the connector housing 26 and accommodated in the first accommodating space.

  In the fourth step, the ferrule 29 attached to the end of the optical fiber 22 is inserted from the rear surface side of the connector housing 26 and accommodated in the second accommodation space. The ferrule 29 is guided toward the member mounting base 27 smoothly and without displacement by the guide portion 41. When the front surface of the ferrule 29 comes into contact with the rear wall of the member mounting base 27 and the convex portion 42 of the ferrule 29 is inserted into the ferrule connecting portion 39 of the member mounting base 27, the optical waveguide 36 of the optical waveguide member 23 and the light Alignment with the fiber 22 is performed. In the fifth step, an operation of fitting the pressing member pressing cap 31 to which the pressing member 30 is fixed in advance to the rear portion of the connector housing 26 is performed. When the pressing member pressing cap 31 is fitted to the rear portion of the connector housing 26, the gap between the optical waveguide 36 and the optical fiber 22 is kept to a minimum due to the action from the pressing member 30. Through the above steps, the assembly of one optical connector 24 is completed.

  Next, assembly of the other optical connector 25 will be described with reference to FIGS. 3 and 4 (assuming an example). In the first step relating to the assembly of the other optical connector 25, an operation of inserting the ferrule 47 attached to the end of the optical fiber 22 from the rear surface side of the connector housing 46 into the accommodating space is performed. In the second step, the pressing member pressing cap 49 to which the pressing member 48 is fixed in advance is engaged with the rear portion of the connector housing 46. Through the above steps, the assembly of the other optical connector 25 is completed.

  Next, assembly of the optical junction connector 21 of the present invention will be described with reference to FIGS. 4 and 5. In the first step relating to the assembly of the optical junction connector 21 of the present invention, an operation of arranging one optical connector 24 and the other optical connector 25 to face each other is performed. In the second step, the other optical connector 25 is inserted into the fitting space of the one optical connector 24, and the one optical connector 24 and the other optical connector 25 are engaged by the arm locking portion 32 and the locking arm 50. Work to fit.

  The other optical connector 25 is guided toward the member mounting base 27 smoothly and without displacement by the guide portion 41. When the front surface of the ferrule 47 comes into contact with the front wall of the member mounting base 27 and the convex portion 54 of the ferrule 47 is inserted into the ferrule connection part 40 of the member mounting base 27, the optical waveguide 36 of the optical waveguide member 23 and the light Alignment with the fiber 22 is performed. Through the above steps, the assembly of the optical junction connector 21 of the present invention is completed.

  As described above with reference to FIGS. 1 to 6, the optical junction connector 21 of the present invention performs optical coupling between one optical connector 24 and the other optical connector 25. Thus, alignment and optical coupling can be made much easier than in the prior art. Further, since an expensive device as used in the conventional example is not required, alignment and optical coupling can be performed at low cost.

  In addition, since the optical junction connector 21 of the present invention is assembled by fitting, it can be assembled more easily than before (the adhesive used in the conventional example is unnecessary). In addition, because of the above configuration and structure, the gap between the optical waveguide 36 and the optical fiber 22 can be kept to a minimum (contact between the optical waveguide 36 and the optical fiber 22 is prevented, and end face damage due to vibration or the like is prevented. Can be prevented). Furthermore, since it is the said structure, component management and an assembly | attachment can be made easy.

  It goes without saying that the present invention can be variously modified without departing from the spirit of the present invention. That is, in the above description, the optical waveguide member 23 is provided in one optical connector 24. However, the optical waveguide member 23 is not limited thereto, and may be provided in the other optical connector 25.

  Next, another embodiment of the optical junction connector of the present invention will be described with reference to FIGS. FIG. 7 is an exploded perspective view showing another embodiment. 8 is a perspective view showing a state before the one and the other optical connectors are fitted, FIG. 9 is a perspective view including a partial cross section showing a state before the one and the other optical connectors are fitted, and FIG. FIG. 11 is a perspective view showing a state in which the optical waveguide member is attached to the member mounting base, and FIG. 12 is a partial view showing a state in which the optical waveguide member is pressed. FIG. 13 is a perspective view showing a state in which the connector housing is turned upside down and turned into a cross section.

7 to 10, reference numeral 61 indicates an optical junction connector of the present invention used for optical communication in a car, optical communication in a house or building, and the like. The optical junction connector 61 is interposed between the end portions of each optical communication path of an optical fiber 62 (for example, having a core diameter of about 200 μm or more), and relays optical signals transmitted by the optical fiber 62. / or the light fraction 岐又is configured to be able to the optical multiplexer flow. Specifically, the optical junction connector 61 of the present invention includes one optical connector 64 having an optical waveguide member 63 and the other optical connector 65 fitted into the one optical connector 64. . Hereinafter, each component will be described in detail.

  The one optical connector 64 is a so-called receptacle-type optical connector, and includes a connector housing 66, the optical waveguide member 63 housed in the connector housing 66, and the optical waveguide member 63 inside the connector housing 66. A member mounting base 67 for housing the optical fiber 62, a ferrule 68 attached to the end of the optical fiber 62 and housed in the connector housing 66, and the ferrule 68 pressed against the member mounting base 67. A pressing member 69 that acts and a pressing member pressing cap 70 that presses the pressing member 69 and fits into the rear portion of the connector housing 66 are configured.

  7 to 13, the connector housing 66 is formed using a synthetic resin material, and is formed in a cylindrical shape whose inside is a hollow space. A fitting space for inserting the other optical connector 65 is formed in the front side of the connector housing 66. An accommodation space for accommodating a member mounting base 67 with the optical waveguide member 63 attached is formed in the rear surface side of the connector housing 66. The fitting space and the accommodation space are formed as a continuous space.

  On the front side of the connector housing 66, an arm locking portion 71 (locking portion) for hooking a locking arm 84 (described later) of the other optical connector 65 is formed. The arm locking portion 71 is formed on the side surface (side wall) of the connector housing 66. In the fitting space, a plurality of guide grooves for guiding the other optical connector 65 are formed, although no reference numerals are given.

  On the rear surface side of the connector housing 66, a stopper 72 for the member mounting base 67 and a locking projection 73 for the pressing member pressing cap 70 are formed. The stopper 72 and the locking projection 73 are formed on both side surfaces (both side walls) of the connector housing 66 and are arranged in the longitudinal direction of the connector housing 66.

  Inside the connector housing 66, a pressing piece 74 (pressing portion) for pressing the optical waveguide member 63 attached to the member mounting base 67 is formed. The pressing piece 74 is a cantilevered piece that can be elastically deformed, and is formed so as to protrude into the accommodation space. By forming the pressing piece 74, there is an advantage that the position of the optical waveguide member 63 in the member mounting base 67 is stabilized.

The optical waveguide member 63, in this embodiment, a plate-like member made of a rectangular in plan view (chip-like member), the relay (light fraction Toki shall may be for optical multiplexing stream) A plurality of optical waveguides (not shown) and a substrate portion (not shown) on which the plurality of optical waveguides are arranged are configured. The optical waveguide is routed to the substrate portion by a desired path. The substrate portion includes an under clad and an over clad having a refractive index lower than that of the optical waveguide. The end face (end part) of the optical waveguide is disposed and formed so as to be exposed from the end face (end part) of the optical waveguide member 63.

  Here, an example is given and demonstrated about the manufacturing method of the optical waveguide member 63. FIG. The optical waveguide member 63 is manufactured through the following first to third steps in sequence (the manufacturing method and form of the optical waveguide member 63 are not particularly limited. The above-described manufacturing method of the optical waveguide member 23 is used. To be manufactured naturally).

  In the first step, an operation for forming a groove for forming an optical waveguide, that is, a plate-like underclad having an optical waveguide groove is performed. The undercladding is made of core materials (acrylic UV curable resin: NORLAND, NOA61n = 1.56, acrylic UV curable resin: NORLAND, NOA68n = 1.54, epoxy UV curable resin: EMI, OPTOCAST 3506n = 1.56, etc. A synthetic resin material having a refractive index lower than that of an example (PMMA: Mitsubishi Rayon Acripet n = 1.49, PP: Mitsui Sumitomo Chemical Sumitomo Mitsui Polypro n = 1.49, etc.) ).

  In the second step, the core material is filled in the optical waveguide groove. The core material is the core material and is filled up to the opening edge of the optical waveguide groove. When the core material filled in the optical waveguide groove is cured, the optical waveguide is formed in the optical waveguide groove.

  In the third step, an operation of forming an overclad layer on the optical waveguide and the underclad is performed. The overcladding layer is made of a synthetic resin material having a lower refractive index than the core material (acrylic UV curable resin: NOLAND NOA65n = 1.52, acrylic UV curable resin: Kyoritsu Chemical Industry XVL-90n = 1. 52, epoxy-based UV curable resin: EMI OPTOCAST 3505n = 1.52, etc. (assumed to be an example).

  The member mounting base 67 is formed using a synthetic resin material, and has a shallow, substantially box-shaped mounting portion 75 having an upper surface opened. The mounting portion 75 is a recess for mounting the optical waveguide member 63 and is formed in a rectangular shape in plan view. In this embodiment, the optical waveguide member 63 is mounted in a state of being fitted to the mounting portion 75 from the upper side and aligned without backlash. The member mounting base 67 is formed so as to be housed in the housing space of the connector housing 66 with the optical waveguide member 63 mounted.

  In addition to the mounting portion 75 for mounting the optical waveguide member 63, ferrule connection portions 76 and 77 and an insertion positioning protrusion 78 are formed on the member mounting base 67. The ferrule connection part 76 is formed in a shape that can guide the ferrule 68 and optically connect the ferrule 68 and the optical waveguide member 63. Specifically, it is formed in a hole shape penetrating from the rear surface of the member mounting base 67 to the mounting portion 75 along the longitudinal direction of the member mounting base 67. The ferrule connection portion 76 is formed in accordance with the shape of the ferrule 68. The ferrule connection portion 76 is formed with a step portion (functioning as a ferrule contact surface) for regulating the insertion depth of the ferrule 68, although not particularly illustrated.

  The ferrule connection portion 77 is formed in a shape that guides a ferrule 81 (to be described later) of the other optical connector 65 so that the ferrule 81 and the optical waveguide member 63 can be optically connected. Specifically, a cylindrical portion that penetrates to the mounting portion 75 is formed on the front surface of the member mounting base 67. The ferrule connection part 77 is formed in accordance with the shape of a ferrule 81 described later. The end surface (end surface of the cylindrical portion) of the ferrule connection portion 77 has a function as a ferrule contact surface that regulates the insertion depth of a ferrule 81 described later.

  The insertion positioning protrusions 78 are protrusions that restrict the insertion depth of the member mounting base 67 accommodated in the housing space of the connector housing 66, and are formed on both side surfaces of the member mounting base 67. The insertion positioning protrusion 78 is disposed and formed so as to contact the stopper 72 of the connector housing 66. The member mounting base 67 is housed in the housing space, and is positioned when the insertion positioning projection 78 abuts against the stopper 72 at that time.

  In this embodiment, the ferrule 68 is molded using a synthetic resin material, and has a substantially cylindrical small-diameter portion and large-diameter portion. The strand portion of the optical fiber 62 is accommodated in the small diameter portion of the ferrule 68, and the covering portion of the optical fiber 62 is accommodated in the large diameter portion. The ferrule 68 and the optical fiber 62 are fixed with an adhesive or the like. The ferrule 68 is fixed so as not to drop off from the end of the optical fiber 62. A pair of bowl-shaped flanges are provided around the large-diameter portion of the ferrule 68 at a predetermined interval. The flange comes into contact with a portion (the stepped portion) that functions as a ferrule contact surface of the ferrule connection portion 76 of the member mounting base 67. The ferrule 68 is not particularly limited, but a ferrule having a known structure is used in this embodiment.

  The pressing member 69 is a coil spring having a predetermined elastic force, and is inserted into the optical fiber 62 and attached before the ferrule 68 is fixed to the end of the optical fiber 62. The pressing member 69 is sandwiched between the flange of the ferrule 68 and the pressing member pressing cap 70. The pressing member 69 presses the ferrule 68 against the member mounting base 67. In response to the action from the pressing member 69, the ferrule 68 is always pressed against the ferrule connection portion 76 of the member mounting base 67.

  The pressing member pressing cap 70 is formed using a synthetic resin material. Specifically, the pressing member pressing cap 70 has an upper wall and a lower wall, left and right side walls, and a rear wall, and is formed in an elongated box shape with the front surface opened as shown. . The pressing member pressing cap 70 is a member for fixing the position of the pressing member 69, and is formed so that a front portion thereof is fitted to a rear portion of the connector housing 66. A through hole (or slit) for inserting the optical fiber 62 is formed in the rear wall of the pressing member pressing cap 70, although not particularly shown. In addition, the edge part of the press member 69 contacts the periphery of a through-hole. On each side wall of the pressing member pressing cap 70, a concave locking portion 79 that is hooked on the locking protrusion 73 of the connector housing 66 is formed.

  The other optical connector 65 is a so-called plug-type optical connector, and includes a connector housing 80, a ferrule 81 attached to the end of the optical fiber 62 and accommodated in the connector housing 80, and the ferrule 81. A ferrule stop pin 82 that restricts the connector housing 80 from dropping off is provided.

    The connector housing 80 is formed using a synthetic resin material, and has a shape that can be inserted into the fitting space of the one optical connector 64. Inside the connector housing 80, an accommodation space 83 for accommodating the ferrule 81 is formed. On the side surface (side wall) of the connector housing 80, a locking arm 84 (lock portion) that is hooked on the arm locking portion 71 of the one optical connector 64 is formed. Further, an insertion locking portion 85 for inserting and locking the ferrule locking pin 82 is formed on the upper surface (upper wall) of the connector housing 80. The insertion locking portion 85 is formed so as to communicate with an accommodation space 83 for accommodating the ferrule 81.

  The same ferrule 81 as the ferrule 68 is used. Therefore, the description is omitted here.

  The ferrule stop pin 82 is formed so as to be able to be restrained from dropping off the ferrule 81 by being hooked on the flange of the ferrule 81 housed in the housing space 83 after being inserted into the insertion lock portion 85 and locked. Has been. The ferrule 81 is housed in the housing space 83 so that the tip of the ferrule 81 can face from the front side of the connector housing 80.

  Based on the above configuration, the assembly of one optical connector 64 and the other optical connector 65 and the assembly of the optical junction connector 61 of the present invention will be described.

  First, assembly of one optical connector 64 will be described (assumed to be an example). In the first step relating to the assembly of one optical connector 64, an operation of mounting the optical waveguide member 63 on the mounting portion 75 of the member mounting base 67 is performed. The optical waveguide member 63 is mounted so as to be fitted from above the mounting portion 75.

  In the second process, the member mounting base 67 with the optical waveguide member 63 mounted is inserted into the housing space of the connector housing 66 from the rear surface side of the connector housing 66 and housed. When the member mounting base 67 is housed in the housing space of the connector housing 66 until the insertion positioning protrusion 78 of the member mounting base 67 contacts the stopper 72 of the connector housing 66, the end face of the ferrule connection portion 77 (the end face of the cylindrical portion). ) Side protrudes into the fitting space of the connector housing 66. The optical waveguide member 63 is pressed by a pressing piece 74 protruding into the housing space of the connector housing 66. When the optical waveguide member 63 is pressed by the pressing piece 74, the position of the optical waveguide member 63 on the member mounting base 67 is stabilized.

  In the third step, an operation of inserting the ferrule 68 into the ferrule connection portion 76 of the member mounting base 67 is performed, and an operation of hooking the pressing member pressing cap 70 on the locking projection 72 of the connector housing 66 to perform locking is performed. . When the pressing member 69 is sandwiched between the flange of the ferrule 68 and the pressing member pressing cap 70 and contracts, the ferrule 68 receives the action from the pressing member 69 and the ferrule connecting portion 76 of the member mounting base 67. It is pushed toward. From the middle to the rear of the member mounting base 67, the pressing member pressing cap 70 is accommodated. Through the above steps, the assembly of one optical connector 64 is completed.

  Next, assembly of the other optical connector 65 will be described (assumed to be an example). In the first step relating to the assembly of the other optical connector 65, the ferrule 81 attached to the end of the optical fiber 62 is inserted from the rear surface side of the connector housing 80 and accommodated in the accommodating space 83. In the second step, the ferrule stop pin 82 is inserted into the insertion locking portion 85 of the connector housing 80. When the ferrule stop pin 82 is locked to the insertion locking portion 85, the ferrule 81 is prevented from dropping from the accommodation space 83. Through the above steps, the assembly of the other optical connector 65 is completed.

  Next, assembly of the optical junction connector 61 of the present invention will be described. In the first step relating to the assembly of the optical junction connector 61 of the present invention, an operation of arranging one optical connector 64 and the other optical connector 65 so as to face each other is performed. In the second step, the other optical connector 65 is inserted into the fitting space of one optical connector 64, and the one optical connector 64 and the other optical connector 65 are engaged by the arm locking portion 71 and the locking arm 84. Work to fit.

  The other optical connector 65 is smoothly guided by the guide groove of the one optical connector 64 toward the member mounting base 67 without being displaced. When the ferrule 81 of the other optical connector 65 is inserted into the ferrule connection portion 77 of the member mounting base 67, alignment between the optical waveguide (not shown) of the optical waveguide member 63 and the optical fiber 62 is performed. Through the above steps, the assembly of the optical junction connector 61 of the present invention is completed.

  As described above with reference to FIGS. 7 to 13, the optical junction connector 61 of the present invention performs optical coupling between one optical connector 64 and the other optical connector 65. Thus, alignment and optical coupling can be made much easier than in the prior art. Further, since an expensive device as used in the conventional example is not required, alignment and optical coupling can be performed at low cost.

  Since the optical junction connector 61 according to the present invention is assembled by fitting, it can be more easily assembled than before (the adhesive used in the conventional example is unnecessary). In addition, because of the above configuration and structure, the gap between the optical waveguide and the optical fiber 62 can be kept to a minimum (the contact between the optical waveguide and the optical fiber 62 is prevented to prevent end face damage caused by vibration or the like. can do). Furthermore, since it is the said structure, component management and an assembly | attachment can be made easy.

  In addition, it goes without saying that the present invention can be variously modified without departing from the spirit of the present invention.

  Here, another example of pressing the optical waveguide member 63 in the optical junction connector 61 will be described. The optical waveguide member 63 is not limited to the pressing piece 74 protruding into the housing space of the connector housing 66, but can be pressed and aligned with the following. The material may be either a synthetic resin material or a metal.

  14 to 18, the optical waveguide member 63 is pressed by a pressing member 86. The pressing member 86 has a U-shape and is formed so as to hold the optical waveguide member 63 and the member mounting base 67. A locking recess 87 for locking the pressing member 86 is formed in the member mounting base 67. A pressing piece 74 that presses the optical waveguide member 63 is formed on the pressing member 86.

  19 to 21, the optical waveguide member 63 is pressed by a pressing portion 88 formed on the member mounting base 67. The pressing portion 88 is a so-called locking projection, and is formed integrally with the opening edge of the mounting portion 75.

  22 to 25, the optical waveguide member 63 is pressed by a pressing member 89. The pressing member 89 has a substantially wedge shape, and is formed so that the edge portion of the optical waveguide member 63 can be pressed when inserted into the through hole 90 of the member mounting base 67.

  26 to 30, the optical waveguide member 63 is pressed by the pressing member 91. The pressing member 91 is a leaf spring having a shape as shown in the figure, and is formed so that one end thereof is inserted into and held in the insertion holding hole 92 of the member mounting base 67. Further, the other end is formed so that the optical waveguide member 63 can be pressed.

  31 to 34, the optical waveguide member 63 is pressed by pressing members 93 and 94. The holding members 93 and 94 are elongate plate springs having different lengths as shown in the figure, and are formed so that one end is inserted into and held in the insertion holding hole 95 of the member mounting base 67. Yes. Further, the other end is formed so that the optical waveguide member 63 can be pressed.

  35 to 38, the optical waveguide member 63 is pressed by a pressing member 96. The holding member 96 is a wide plate spring as shown in the figure, and is formed so that one end is inserted into and held in the insertion holding hole 97 of the member mounting base 67. Further, the other end is formed so that the optical waveguide member 63 can be pressed.

  39 to 42, the optical waveguide member 63 is pressed by a pressing member 98. The pressing member 98 has a U-shape and is formed so as to hold the optical waveguide member 63 and the member mounting base 67. A locking recess 99 for locking the pressing member 86 is formed in the member mounting base 67. The pressing member 98 is formed so that the optical waveguide member 63 can be pressed by the pair of leg portions 100.

  Subsequently, still another embodiment of the optical junction connector of the present invention will be described with reference to FIGS. FIG. 43 is an exploded perspective view showing still another embodiment. 44 is a perspective view showing a state before the one and the other optical connectors are fitted, FIG. 45 is a perspective view including a partial cross section showing a state before the one and the other optical connectors are fitted, and FIG. 47 is a perspective view showing a fitting state of one optical connector and the other optical connector, FIG. 47 is a perspective view showing a state in which the optical waveguide member is attached to a member mounting base, and FIGS. 48 and 49 show a state in which the optical waveguide member is pressed. FIG. 50 is a cross-sectional perspective view of the connector housing.

  Note that the same reference numerals are given to basically the same members as those of the optical junction connector 61 described above, and a detailed description thereof will be omitted.

43 to 46, reference numeral 101 denotes an optical junction connector of the present invention used for optical communication in an automobile, optical communication in a house or a building, and the like. The optical junction connector 101 is interposed between the end portions of each optical communication path of an optical fiber 62 (for example, having a core diameter of about 200 μm or more), and relays optical signals transmitted by the optical fiber 62. / or the light fraction 岐又is configured to be able to the optical multiplexer flow. Specifically, the optical junction connector 101 of the present invention includes one optical connector 102 having an optical waveguide member 63 and the other optical connector 65 fitted to the one optical connector 102. . Hereinafter, one optical connector 102 will be described in detail.

  One optical connector 102 is a so-called receptacle-type optical connector, and includes a connector housing 103, the optical waveguide member 63 accommodated in the connector housing 103, and the optical waveguide member 63 in the connector housing 103. A member mounting base 104 for housing, a ferrule 68 attached to the end of the optical fiber 62 and housed in the connector housing 103, and acting to press the ferrule 68 against the member mounting base 104 And a pressing member pressing cap 70 that presses the pressing member 69 and fits to the rear portion of the connector housing 103.

  43 to 50, the connector housing 103 is molded using a synthetic resin material and is formed in a cylindrical shape having a hollow space inside. A fitting space for inserting the other optical connector 65 is formed in the front side of the connector housing 103. A housing space for housing the member mounting base 104 with the optical waveguide member 63 attached is formed inside the connector housing 103 on the rear surface side. The fitting space and the accommodation space are formed as a continuous space.

  On the front side of the connector housing 103, an arm locking portion 71 (lock portion) for hooking the locking arm 84 of the other optical connector 65 is formed. The arm locking portion 71 is formed on the side surface (side wall) of the connector housing 103. In the fitting space, a plurality of guide grooves for guiding the other optical connector 65 are formed although no reference numerals are given.

  On the rear surface side of the connector housing 103, a stopper 72 for the member mounting base 104 and a locking projection 73 for the pressing member pressing cap 70 are formed. The stopper 72 and the locking projection 73 are formed on both side surfaces (both side walls) of the connector housing 103, and are arranged so as to be aligned in the longitudinal direction of the connector housing 103 (two stoppers 72 in this embodiment). However, only one of them is used (since there is only one insertion positioning protrusion 78 of the member mounting base 104 of this embodiment).

  Inside the connector housing 103, a pressing piece 74 (pressing portion) for pressing the optical waveguide member 63 attached to the member mounting base 104 is formed. The pressing piece 74 is a cantilevered piece that can be elastically deformed, and is formed so as to protrude into the accommodation space. Unlike the above-described embodiment, the pressing piece 74 is formed on the side portion. By forming the pressing piece 74, there is an advantage that the position of the optical waveguide member 63 in the member mounting base 104 is stabilized.

  The member mounting base 104 is molded using a synthetic resin material, and has a slit-shaped mounting portion 75 formed by opening one side surface. The mounting portion 75 is formed for mounting the optical waveguide member 63. In this embodiment, the optical waveguide member 63 is mounted in a state of being fitted to the mounting portion 75 from the side and aligned without backlash. The member mounting base 104 is formed so as to be housed in the housing space of the connector housing 103 with the optical waveguide member 63 mounted.

  In addition to the mounting portion 75 for mounting the optical waveguide member 63, ferrule connection portions 76 and 77 and an insertion positioning protrusion 78 are formed on the member mounting base 104. The ferrule connection part 76 is formed in a shape that can guide the ferrule 68 and optically connect the ferrule 68 and the optical waveguide member 63. Specifically, it is formed in a hole shape penetrating from the rear surface of the member mounting base 67 to the mounting portion 75 along the longitudinal direction of the member mounting base 104. The ferrule connection portion 76 is formed in accordance with the shape of the ferrule 68. The ferrule connection portion 76 is formed with a step portion (functioning as a ferrule contact surface) for regulating the insertion depth of the ferrule 68, although not particularly illustrated.

  The ferrule connection part 77 is formed in a shape capable of guiding the ferrule 81 of the other optical connector 65 and optically connecting the ferrule 81 and the optical waveguide member 63. Specifically, a cylindrical portion that penetrates to the mounting portion 75 is formed on the front surface of the member mounting base 104. The ferrule connection part 77 is formed according to the shape of the ferrule 81. The end surface of the ferrule connection part 77 (end surface of the cylindrical portion) has a function as a ferrule contact surface that regulates the insertion depth of the ferrule 81.

  The insertion positioning projection 78 is a projection that regulates the insertion depth of the member mounting base 104 accommodated in the housing space of the connector housing 103, and is formed on the other side surface of the member mounting base 104 (mounting). The part 75 is formed on the side surface that does not open). The insertion positioning protrusion 78 is disposed and formed so as to contact the stopper 72 of the connector housing 103. The member mounting base 104 is accommodated in the accommodation space, and positioning is performed when the insertion positioning projection 78 abuts against the stopper 72 at that time.

  Based on the above configuration, assembly of one optical connector 102 and assembly of the optical junction connector 101 of the present invention will be described.

  First, assembly of one optical connector 102 will be described (assumed to be an example). In the first step relating to the assembly of one of the optical connectors 102, an operation of mounting the optical waveguide member 63 on the mounting portion 75 of the member mounting base 104 is performed. The optical waveguide member 63 is mounted in a state where it is inserted from the side of the mounting portion 75 and fitted.

  In the second step, the member mounting base 104 with the optical waveguide member 63 mounted is inserted into the housing space of the connector housing 103 from the rear surface side of the connector housing 103 and stored. When the member mounting base 104 is housed in the housing space of the connector housing 103 until the insertion positioning projection 78 of the member mounting base 104 contacts the stopper 72 of the connector housing 103, the end face of the ferrule connection portion 77 (the end face of the cylindrical portion). ) Side protrudes into the fitting space of the connector housing 103. The optical waveguide member 63 is pressed by a pressing piece 74 protruding into the housing space of the connector housing 103. When pressed by the pressing piece 74, the position of the optical waveguide member 63 on the member mounting base 104 is stabilized.

  In the third step, the ferrule 68 is inserted into the ferrule connection portion 76 of the member mounting base 104 and the pressing member pressing cap 70 is hooked on the locking protrusion 72 of the connector housing 103 and locked. . When the pressing member 69 is sandwiched between the flange of the ferrule 68 and the pressing member pressing cap 70 and contracts, the ferrule 68 receives the action from the pressing member 69 and the ferrule 68 is connected to the ferrule connection portion 76 of the member mounting base 104. It is pushed toward. From the middle to the rear of the member mounting base 104, the pressing member pressing cap 70 is accommodated. The assembly of one optical connector 102 is completed through the above steps.

  Next, assembly of the optical junction connector 101 of the present invention will be described. In the first step relating to the assembly of the optical junction connector 101 of the present invention, an operation of arranging one optical connector 102 and the other optical connector 65 to face each other is performed. In the second step, the other optical connector 65 is inserted into the fitting space of one optical connector 102, and the one optical connector 102 and the other optical connector 65 are engaged by the arm locking portion 71 and the locking arm 84. Work to fit.

  The other optical connector 65 is guided smoothly toward the member mounting base 104 by the guide groove of the one optical connector 102 without being displaced. When the ferrule 81 of the other optical connector 65 is inserted into the ferrule connection portion 77 of the member mounting base 104, alignment between the optical waveguide (not shown) of the optical waveguide member 63 and the optical fiber 62 is performed. Through the above steps, the assembly of the optical junction connector 101 of the present invention is completed.

  As described above with reference to FIGS. 43 to 50, the optical junction connector 101 of the present invention performs optical coupling between one optical connector 102 and the other optical connector 65. Thus, alignment and optical coupling can be made much easier than in the prior art. Further, since an expensive device as used in the conventional example is not required, alignment and optical coupling can be performed at low cost.

  Since the optical junction connector 101 of the present invention is assembled by fitting, it can be assembled more easily than the conventional one (the adhesive used in the conventional example is unnecessary). In addition, because of the above configuration and structure, the gap between the optical waveguide and the optical fiber 62 can be kept to a minimum (the contact between the optical waveguide and the optical fiber 62 is prevented to prevent end face damage caused by vibration or the like. can do). Furthermore, since it is the said structure, component management and an assembly | attachment can be made easy.

  In addition, it goes without saying that the present invention can be variously modified without departing from the spirit of the present invention.

  Here, another example of pressing the optical waveguide member 63 in the optical junction connector 101 will be described. The optical waveguide member 63 is not limited to the pressing piece 74 protruding into the housing space of the connector housing 103, and can be pressed and aligned with the following. The material may be either a synthetic resin material or a metal.

  51 to 54, the optical waveguide member 63 is pressed by the pressing member 105. The pressing member 105 has a U shape and is formed so as to hold the optical waveguide member 63 and the member mounting base 104. The member mounting base 104 is formed with a locking recess 106 for locking the pressing member 105. The pressing member 105 is formed so that the optical waveguide member 63 can be pressed by the pair of leg portions 107.

  55 to 59, the optical waveguide member 63 is pressed by the pressing member 108. The pressing member 108 has a substantially wedge shape, and is formed so that the edge portion of the optical waveguide member 63 can be pressed when inserted into the through hole 109 of the member mounting base 104.

  60 to 63, the optical waveguide member 63 is pressed by the pressing member 110. The pressing member 110 is a leaf spring having a shape as shown in the figure, and is formed so that one end thereof is inserted into and held in the insertion holding hole 111 of the member mounting base 104. Further, the other end is formed so that the optical waveguide member 63 can be pressed.

  64 to 68, the optical waveguide member 63 is pressed by the pressing member 112. The pressing member 112 has a U-shape and is formed so as to hold the optical waveguide member 63 and the member mounting base 104. A locking recess 113 for locking the pressing member 112 is formed in the member mounting base 104. A pressing piece 74 that presses the optical waveguide member 63 is formed on the pressing member 112.

  The characteristics of pressing (holding) the optical waveguide member 63 in the optical junction connectors 61 and 101 are summarized below.

(1) One optical connector and another optical connector that are phase-fitted using a lock portion are provided, and in the connector housing of the one optical connector, the relay of an optical signal transmitted via an optical fiber and / or the light fraction 岐又is a holding structure of the optical waveguide member of the optical junction connector having a light waveguide having an optical waveguide for the optical multiplexer flow,
A ferrule connection in which a member mounting base accommodated in the connector housing with the optical waveguide member attached is provided, and the ferrules of the one and the other optical connectors are detachably connected to the member mounting base. In the holding structure of the optical waveguide member in the optical junction connector formed part,
A light having a pressing portion (pressing piece, locking protrusion) for pressing the optical waveguide member attached to the member mounting base is provided integrally with the connector housing or the member mounting base. An optical waveguide member holding structure in a junction connector.

(2) One optical connector and the other optical connector that are phase-fitted using a lock portion are provided, and in the connector housing of the one optical connector, the relay of the optical signal transmitted through the optical fiber and / or the light fraction 岐又is a holding structure of the optical waveguide member of the optical junction connector having a light waveguide having an optical waveguide for the optical multiplexer flow,
A ferrule connection in which a member mounting base accommodated in the connector housing with the optical waveguide member attached is provided, and the ferrules of the one and the other optical connectors are detachably connected to the member mounting base. In the holding structure of the optical waveguide member in the optical junction connector formed part,
A pressing member for pressing the optical waveguide member attached to the member mounting base is provided, and the pressing member is formed in a U-shape that holds the optical waveguide member and the member mounting base. An optical waveguide member holding structure in an optical junction connector.

(3) One optical connector and the other optical connector that are phase-fitted using a lock portion are provided, and in the connector housing of the one optical connector, the relay of the optical signal transmitted through the optical fiber and / or the light fraction 岐又is a holding structure of the optical waveguide member of the optical junction connector having a light waveguide having an optical waveguide for the optical multiplexer flow,
A ferrule connection in which a member mounting base accommodated in the connector housing with the optical waveguide member attached is provided, and the ferrules of the one and the other optical connectors are detachably connected to the member mounting base. In the holding structure of the optical waveguide member in the optical junction connector formed part,
A plate spring-shaped pressing member for pressing the optical waveguide member attached to the member mounting base is provided, and one end side of the pressing member is inserted and held in an insertion holding hole of the member mounting base, and the pressing An optical waveguide member holding structure in an optical junction connector, wherein the optical waveguide member is pressed on the other end side of the member.

(4) One optical connector and the other optical connector that are phase-fitted using a lock portion are provided. In the connector housing of the one optical connector, relaying of an optical signal transmitted through an optical fiber and / or the light fraction 岐又is a holding structure of the optical waveguide member of the optical junction connector having a light waveguide having an optical waveguide for the optical multiplexer flow,
A ferrule connection in which a member mounting base accommodated in the connector housing with the optical waveguide member attached is provided, and the ferrules of the one and the other optical connectors are detachably connected to the member mounting base. In the holding structure of the optical waveguide member in the optical junction connector formed part,
A substantially wedge-shaped pressing member for pressing the optical waveguide member attached to the member mounting base is provided, and one end side of the pressing member is inserted into a through-hole of the member mounting base and held, and the pressing member An optical waveguide member holding structure in an optical junction connector, wherein an edge portion of the optical waveguide member is pressed on the other end side of the optical junction connector.

  The features (1) to (4) have an advantage that the shape stability and handleability as the pressing member can be improved as compared with the pressing member 28 of the optical junction connector 21 described above. That is, since the pressing member 28 is formed of rubber, foamed resin, gel, or the like, there is a fear that the shape stability and handling property as the pressing member may be insufficient. In other words, the pressing members and pressing pieces (pressing portions) described in the optical junction connectors 61 and 101 can solve the above-described problems with the features (1) to (4).

It is a disassembled perspective view which shows one Embodiment of the optical junction connector of this invention. It is a disassembled perspective view of one optical connector. It is a disassembled perspective view of the other optical connector. It is a perspective view which shows the state before the fitting of one and the other optical connector. It is a perspective view which shows the fitting state of one and the other optical connector. It is a perspective view of an optical waveguide member. It is a disassembled perspective view which shows other one Embodiment of the optical junction connector of this invention. It is a perspective view which shows the state before the fitting of one and the other optical connector. It is a perspective view containing the partial cross section which shows the state before the fitting of one and the other optical connector. It is a perspective view which shows the fitting state of one and the other optical connector. It is a perspective view which shows the state which attached the optical waveguide member to the member mounting base. It is a perspective view containing the partial cross section which shows the state which pressed down the optical waveguide member. It is a section perspective view showing the state where the connector housing was turned upside down and made into a section. It is a figure which shows the other example which concerns on pressing of an optical waveguide member, and is a perspective view which shows the state which attached the optical waveguide member to the base for member mounting. It is principal part sectional drawing of FIG. It is a longitudinal cross-sectional view of FIG. FIG. 15 is a perspective view of the member mounting base of FIG. 14. It is a perspective view of the pressing member of FIG. It is a figure which shows the other example which concerns on pressing of an optical waveguide member, and is a perspective view which shows the state which attached the optical waveguide member to the base for member mounting. It is principal part sectional drawing of FIG. FIG. 20 is a perspective view of the member mounting base of FIG. 19. It is a figure which shows the other example which concerns on pressing of an optical waveguide member, and is a perspective view which shows the state which attached the optical waveguide member to the base for member mounting. It is principal part sectional drawing of FIG. FIG. 23 is a perspective view of the member mounting base of FIG. 22. It is a perspective view of the pressing member of FIG. It is a figure which shows the other example which concerns on pressing of an optical waveguide member, and is a perspective view which shows the state which attached the optical waveguide member to the base for member mounting. It is a side view with respect to FIG. It is principal part sectional drawing of FIG. It is a perspective view of the base for member mounting of FIG. It is a perspective view of the pressing member of FIG. It is a figure which shows the other example which concerns on pressing of an optical waveguide member, and is a perspective view which shows the state which attached the optical waveguide member to the base for member mounting. It is principal part sectional drawing of FIG. FIG. 32 is a perspective view of the member mounting base of FIG. 31. (A), (b) is a perspective view of the pressing member of FIG. It is a figure which shows the other example which concerns on pressing of an optical waveguide member, and is a perspective view which shows the state which attached the optical waveguide member to the base for member mounting. It is principal part sectional drawing of FIG. FIG. 36 is a perspective view of the member mounting base of FIG. 35. It is a perspective view of the pressing member of FIG. It is a figure which shows the other example which concerns on pressing of an optical waveguide member, and is a perspective view which shows the state which attached the optical waveguide member to the base for member mounting. It is principal part sectional drawing of FIG. FIG. 40 is a perspective view of the member mounting base of FIG. 39. It is a perspective view of the pressing member of FIG. It is a disassembled perspective view which shows another one Embodiment of the optical junction connector of this invention. It is a perspective view which shows the state before the fitting of one and the other optical connector. It is a perspective view containing the partial cross section which shows the state before the fitting of one and the other optical connector. It is a perspective view which shows the fitting state of one and the other optical connector. It is a perspective view which shows the state which attached the optical waveguide member to the member mounting base. It is a perspective view containing the partial cross section which shows the state which pressed down the optical waveguide member. It is a perspective view containing the partial cross section which shows the state which pressed down the optical waveguide member. It is a cross-sectional perspective view of a connector housing. It is a figure which shows the other example which concerns on pressing of an optical waveguide member, and is a perspective view which shows the state which attached the optical waveguide member to the base for member mounting. It is principal part sectional drawing of FIG. FIG. 52 is a perspective view of the member mounting base of FIG. 51. It is a perspective view of the pressing member of FIG. It is a figure which shows the other example which concerns on pressing of an optical waveguide member, and is a perspective view which shows the state which attached the optical waveguide member to the base for member mounting. FIG. 56 is a cross-sectional perspective view of relevant parts in FIG. 55. It is principal part sectional drawing of FIG. FIG. 56 is a perspective view of the member mounting base of FIG. 55. It is a perspective view of the pressing member of FIG. It is a figure which shows the other example which concerns on pressing of an optical waveguide member, and is a perspective view which shows the state which attached the optical waveguide member to the base for member mounting. It is principal part sectional drawing of FIG. FIG. 61 is a perspective view of the member mounting base of FIG. 60. FIG. 61 is a perspective view of the pressing member of FIG. 60. It is a figure which shows the other example which concerns on pressing of an optical waveguide member, and is a perspective view which shows the state which attached the optical waveguide member to the base for member mounting. FIG. 65 is a cross-sectional perspective view of a main part of FIG. 64. It is principal part sectional drawing of FIG. FIG. 65 is a perspective view of the member mounting base of FIG. 64. It is a perspective view of the pressing member of FIG. It is a perspective view of the optical waveguide module of a prior art example.

Explanation of symbols

DESCRIPTION OF SYMBOLS 21 Optical junction connector 22 Optical fiber 23 Optical waveguide member 24 One optical connector 25 The other optical connector 26 Connector housing 27 Member mounting base 28 Holding member 29 Ferrule 30 Pressing member 31 Pressing member pressing cap 32 Arm locking part (locking) Part)
33 Guide groove 34 Guide protrusion 35 Locking protrusion 36 Optical waveguide 37 Substrate 38 Mounting portion 39, 40 Ferrule connection portion 41 Guide portion 42 Convex portion 43 Guided portion 44 Locking portion 45 Guide groove 46 Connector housing 47 Ferrule 48 Pressing member 49 Pressing member pressing cap 50 Locking arm (locking part)
51, 52 Guide protrusion 53 Locking protrusion 54 Protruding part 55 Stopper 56 Through hole 57 Locking part 58 Guide groove

Claims (4)

One optical connector and the other optical connector that are mated with each other using a lock part,
The one optical connector is
One connector housing formed in a rectangular cylindrical shape in which a cross section in a direction perpendicular to the longitudinal direction is a substantially rectangular hollow space;
A plate-like member accommodated in the one connector housing and having a rectangular shape in plan view, and a plurality of planar optical waveguides for light branching or optical merging, and a substrate on which the plurality of planar optical waveguides are arranged A planar optical waveguide member constituted by:
A member mounting base for accommodating the planar optical waveguide member in the one connector housing;
A ferrule of one optical connector attached to the end of the optical fiber and housed in the one connector housing;
One ferrule connection portion formed in a slit shape in accordance with the shape of the convex portion of the ferrule to connect the ferrule of the one optical connector to the rear wall of the member mounting base so as to be detachable;
A pressing member that acts to constantly press the ferrule of the one optical connector toward the one ferrule connection portion of the mounting base;
The other ferrule connection part formed in the shape of a slit in accordance with the shape of the convex part of the ferrule to connect the ferrule of the other optical connector to the front wall of the member mounting base so as to be detachable;
With
The other optical connector is
The other connector housing formed in a rectangular cylindrical shape in which a cross section in a direction perpendicular to the longitudinal direction is a substantially rectangular hollow space;
A ferrule of the other optical connector, which is attached to the end of the optical fiber and is accommodated in the other connector housing, and has a front surface formed with a convex portion to be inserted into the other ferrule connection portion of the member mounting base. ,
A pressing member of the other optical connector that acts to constantly press the ferrule of the other optical connector toward the other ferrule connection portion of the mounting base for the member;
With
The rear wall of the member mounting base functions as a ferrule contact surface that regulates the insertion depth of the convex portion with respect to the ferrule of the one optical connector, and the front wall of the member mounting base is the other Functioning as a ferrule contact surface for restricting the insertion depth of the convex portion with respect to the ferrule of the optical connector
The convex portion of the ferrule of the one optical connector and the convex portion of the ferrule of the other optical connector are inserted into the member mounting base so as to be removably inserted into the one ferrule connecting portion and the other ferrule connecting portion of the member mounting base. By doing so, the ferrule of the one optical connector, the ferrule of the other optical connector, and the planar optical waveguide are aligned without contacting the end faces. The optical junction connector according to claim 1,
An optical junction connector comprising a pressing member for pressing the planar optical waveguide member attached to the member mounting base. The optical junction connector according to claim 2,
An optical junction connector, wherein a pressing portion for pressing the planar optical waveguide member attached to the member mounting base is provided integrally with the connector housing or the member mounting base. The optical junction connector according to claim 2 or 3,
An optical junction connector characterized in that a guide portion for guiding the ferrule in a connector fitting direction is formed on the member mounting base, and a guided portion guided by the guide portion is formed on the ferrule.

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