JP4371793B2 - Optical junction block manufacturing method and optical junction block - Google Patents

Description

The present invention relates to an optical junction block that relays optical signals to be transmitted and / or performs optical demultiplexing and optical multiplexing, and in particular, optical communication used for wiring of various electrical equipment in automobiles, in-houses and buildings. manufacturing method of a preferred optical junction block for optical communications or the like, and an optical junction block

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, corresponds to the junction block of a wire harness, passive devices such as perform a branch-coupling of light is needed.

  As this type of passive device, an optical waveguide module as shown in FIG. 13 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. 13, reference numeral 9 is a personal computer, 10 is a controller, 11 is a laser diode, and 12 is 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 is made in view of the above-described circumstances, and it is an object to provide an optical junction block that is easy to align and optically couple and that does not require an expensive device for aligning and optically coupling. To do.

It is another object of the present invention to provide a method for manufacturing an optical waveguide member used for an optical junction block that is preferably used for an optical junction block .

The method of manufacturing an optical junction block according to claim 1, which has been made to solve the above problems, includes an optical waveguide member, a housing, and a plurality of connectors straddling them.
Used in an optical junction block configured to be capable of relaying and / or optical branching and optical coupling of optical signals transmitted by an optical fiber, and provided between end portions of optical communication paths of the optical fiber. , A method of manufacturing an optical junction block for relaying and / or optical branching / optical coupling of an optical signal transmitted by the optical fiber,
A first step of forming an underclad layer on or under the substrate using a synthetic resin material having a refractive index lower than that of the core material constituting the optical waveguide;
A convex core is formed in a predetermined path on the undercladding layer using a light-transmitting synthetic resin material, and a projection or convex shape is mounted on the substrate. A second step in which the guide is made of the same material as the core and is simultaneously molded with the core;
Forming the optical waveguide by forming an overcladding layer using a synthetic resin material having a refractive index lower than that of the core material using an overcladding mold having a recess for overcladding molding around the core A third step to
Consists of
The mounting guides formed based on the second step are respectively inserted into the guide fixing grooves of the optical axis adjusting sleeve, and the overcladding layer manufactured based on the third step is optically aligned. It is characterized by being manufactured so as to be inserted into the optical waveguide groove of the core sleeve.
According to the present invention having such characteristics, a manufacturing method including the first to third steps is employed to manufacture an optical junction block having an optical waveguide. By including the above steps, an optical waveguide member suitable for use in an optical junction block is easily manufactured. The optical junction block of the present invention has good mass productivity as can be seen from the above steps.

According to a second aspect of the present invention, there is provided a method for manufacturing an optical junction block according to the first aspect of the present invention, in which the core is formed in the second step of the optical waveguide member manufacturing method according to the first aspect. Using a core mold having a guide hole guided by
An overcladding mold is used to mold the overcladding layer in the third step,
In the first step, a protrusion or a convex member of a jig for forming the underclad layer on the substrate or under the substrate is used as a guide member for the core mold and the overcladding mold. It is characterized by doing so.

The optical junction block of the present invention according to claim 3 is an optical junction block that relays and / or splits and couples an optical signal transmitted by an optical fiber,
The optical signal transmitted by the optical fiber is relayed and / or optically branched and optically coupled, formed as a substantially T-shaped projection in plan view, and a plurality of mounting and fixing guides are formed. An optical junction block manufactured by the method of manufacturing an optical junction block described above;
A casing made of synthetic resin, and including a casing main body that houses the optical waveguide member, and a lid that fits into the casing main body and covers the optical waveguide member with an appropriate interval;
A plurality of connectors that optically couple the end portions of the optical waveguide and the end portions of the optical communication paths while aligning the optical waveguide member and the housing; and
It is characterized by comprising.

According to the present invention described in claim 1, an effect that an optical junction block suitable for use in an optical junction block can be manufactured by employing a manufacturing method including a first process to a third process. Play.

According to the second aspect of the present invention, it is possible to provide an optical junction block that facilitates alignment and optical coupling. Further, there is an effect that an optical junction block that does not require an expensive device for alignment and optical coupling can be provided .

According to the third aspect of the present invention, the connector is provided with the optical axis alignment sleeve and the hood portion, so that the optical waveguide end portion and the optical communication path end portion are optically connected. There is an effect that good coupling can be performed satisfactorily .

Hereinafter, description will be given with reference to the drawings.
FIG. 1 is an exploded perspective view showing an embodiment of an optical junction block of the present invention and an optical connector optically coupled thereto. 2 is an exploded perspective view of the optical junction block, FIG. 3 is a perspective view of the optical waveguide member, FIG. 4 is a diagram schematically illustrating a method of manufacturing the optical waveguide member, and FIG. 5 is an optical axis alignment sleeve. FIG. 6 is a perspective view of an optical junction block, and FIG. 7 is a perspective view of an optical junction block and an optical connector in an optically coupled state.

In FIG. 1, reference numeral 21 indicates an optical junction block used for optical communication in a car, optical communication in a house or a building, and the like. The optical junction block 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 is configured to be able to light fraction Toki-optical coupling. The optical junction block 21 of the present invention includes an optical waveguide member 23, a casing 24, and a plurality of connectors 25 straddling them. Hereinafter, each component will be described in detail.

1 to 3, the optical waveguide member 23 is a plate-shaped member in a plan view a rectangular shape (rectangular shape. Assumed to be an example), in a light fraction Toki (relay and / or optical coupling A plurality of optical waveguides 26, and a synthetic resin substrate 27 on which the plurality of optical waveguides 26 are disposed. The optical waveguide member 23 is formed so as to be detachable with respect to the casing 24 and the connector 25.

  The optical waveguide 26 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 26 is arranged along a desired path with respect to the substrate 27 (the arrangement state is not particularly limited). The end face (end part) of the optical waveguide 26 is flush with the end face (end part) of the substrate 27 and is disposed so as to be exposed from the end face.

  A plurality of mounting and fixing guides 28 are formed on the optical waveguide member 23. In this embodiment, the guide 28 is formed as a substantially T-shaped projection in plan view. One guide 28 is formed near each of the four corners of the optical waveguide member 23. The guide 28 is not limited to the above shape, and may be formed in a round pin shape, a linear convex shape, or the like. In addition, the number of guides 28 is not limited to the number illustrated, and four or more guides 28 may be formed. The guide 28 only needs to be positioned accurately.

  Here, a manufacturing method of the optical waveguide member 23 will be described with reference to FIGS. 3 and 4. 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, an operation of forming an underclad layer 29 on the substrate 27 is performed (see FIG. 4A). The undercladding layer 29 is formed over the entire surface of the substrate 27. The under-cladding layer 29 is composed 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.) (PMMA: Acrypet n = 1.49 manufactured by Mitsubishi Rayon, PP: Sumitomo Mitsui Polypro n = 1.49 manufactured by Sumitomo Mitsui Chemicals, etc.). The undercladding layer 29 has an appropriate thickness. When the substrate 27 is transparent, it may be used as the underclad layer 29.

  In the second step, the core 30 is formed on the under-cladding layer 29 (see FIGS. 4A and 4B). A core mold 31 is used for the core 30 and is formed into a convex shape by a desired path using the core material (the path in FIG. 3 is an example). The core molding die 31 has a core molding recess 32 and a guide molding recess 33, and the guide 28 is molded on the undercladding layer 29 simultaneously with the molding of the core 30 (the undercladding layer 29 is formed). If the entire surface of the substrate 27 is not formed, a guide 28 is formed on the substrate 27). The core 30 and the guide 28 are not particularly limited, but are simultaneously formed of the same material in consideration of cost, man-hours, and the like.

  In the third step, an operation of forming the overcladding layer 34 around the core 30 is performed (see FIGS. 4C and 4D). As the overcladding layer 34, an overcladding mold 36 having an overcladding molding recess 35 is used, and a synthetic resin material (acrylic UV curable resin: NOLAD NOA65n = 1 made by NORLAND) having a refractive index lower than that of the core material. .52, acrylic UV curable resin: XVL-90n = 1.52 manufactured by Kyoritsu Chemical Industry, epoxy UV curable resin: OPTOCAST 3505n = 1.52 manufactured by EMI, etc.). The over clad layer 34 is formed in accordance with the shape of an optical waveguide groove 60 described later.

  When the overcladding layer 34 is cured, the manufacture of the optical waveguide member 23 having the optical waveguide 26 is completed (see FIG. 4D). The manufactured optical waveguide member 23 is attached to optical axis alignment sleeves 50 and 51, which will be described later, in an inverted state (see FIG. 4E). The optical waveguide 26 of the optical waveguide member 23 is inserted into the optical waveguide groove 60 of the optical axis alignment sleeves 50 and 51, and the guide 28 is inserted into the guide fixing groove 61 of the optical axis alignment sleeves 50 and 51, respectively. It is.

  1 and 2, the casing 24 is made of a synthetic resin, and includes a casing main body 37 that houses the optical waveguide member 23, and an optical waveguide member that is fitted to the casing main body 37 and is appropriately spaced. 23 and a cover 38 that covers the cover 23.

  The housing body 37 includes a substrate 39 having a flat surface and a pair of side walls 40 and 40 along the transmission direction of the optical signal. Further, the housing body 37 includes a storage portion 41 for the optical waveguide member 23 and sleeve mounting portions 42 and 42 for optical axis alignment sleeves 50 and 51 to be described later. Further, the housing body 37 has lower hood portions 44 and 44 for forming fitting spaces 43 and 43. The fitting spaces 43 and 43 are used when fitting optical connectors 66 and 67 (optical coupling partners) having the optical communication path to the optical axis alignment sleeves 50 and 51, which will be described later. .

  In this embodiment, the casing body 37 is formed in a rectangular shape (rectangular shape) in plan view that is slightly larger and longer than the optical waveguide member 23. Further, the storage portion 41 of the housing body 37 is formed so as to be surrounded by the substrate 39, the side walls 40 and 40, and the sleeve attachment portions 42 and 42.

  The sleeve mounting portions 42 and 42 are portions for detachably mounting optical axis alignment sleeves 50 and 51, which will be described later. In this embodiment, the sleeve mounting portions 42 and 42 are formed on the respective end portions of the housing 24. Yes. The sleeve mounting portions 42 and 42 are formed so that the optical axis alignment sleeves 50 and 51 can be positioned. The optical axis alignment sleeves 50 and 51 after being positioned by the sleeve mounting portions 42 and 42 are pressed by the lid 38 fitted to the housing body 37 so that they do not fall off unless the lid 38 is removed. It has become.

  The lower hood portions 44, 44 are arranged and formed so as to be continuous with the sleeve attaching portions 42, 42, respectively. The lower hood portions 44 and 44 are formed in accordance with the shape of the optical connectors 66 and 67 (optical coupling partner) (the same applies to the upper hood portions 47 and 47 described later. The hood portions 47 and 47 constitute the hood portion described in the claims).

  A plurality of locking portions 45 for the lid 38 are formed on the side walls 40, 40. The plurality of locking portions 45 are formed on both sides of the storage portion 41 in this embodiment. The sleeve mounting portions 42 and 42 are formed so as to be continuous with the plurality of locking portions 45.

  The lid 38 is formed with side walls 46, 46 facing the side walls 40, 40 of the housing body 37 and upper hood portions 47, 47 facing the lower hood portions 44, 44 of the housing body 37. On the side walls 46, 46, a plurality of locking projections 48 that are hooked on the locking portions 45 of the side walls 40, 40 are formed. The upper hood portions 47 and 47 are formed with lock portions 49 and 49 for the optical connectors 66 and 67 (optical coupling partners). Locking arms 74, 74 described later formed on the optical connectors 66, 67 are engaged with the lock portions 49, 49.

  The connector 25 is a member for optically coupling the end portion of the optical waveguide 26 and the end portion of each of the optical communication paths (a ferrule 68 described later) while aligning, and an optical axis alignment sleeve 50, a sleeve mounting portion 42, a lower hood portion 44, and an upper hood portion 47 (configuration on the optical connector 66 side). Further, the connector 25 includes an optical axis alignment sleeve 51, a sleeve mounting portion 42, a lower hood portion 44, and an upper hood portion 47 (configuration on the optical connector 67 side).

  The optical axis alignment sleeves 50 and 51 include sleeve bodies 52 and 53 made of synthetic resin and sleeve covers 54 and 54, respectively. The optical axis alignment sleeves 50 and 51 have a split structure (fixing means for retrofitting) in which the end portions of the optical waveguide member 23 are sandwiched and fixed using the sleeve main bodies 52 and 53 and the sleeve covers 54 and 54. is doing. It should be noted that the optical axis alignment sleeves 50 and 51 can be combined into a single member. However, it is easier to position the optical waveguide member 23 in this embodiment divided into two.

  In FIG. 5, the sleeve main bodies 52 and 53 have sleeves 55 and 56 for protecting the optical coupling portion, and bases 57 and 58 on which the end portions of the optical waveguide member 23 are placed. In this embodiment, the sleeve 55 is formed so as to correspond to one core. That is, a through hole 59 into which a ferrule 68 described later is inserted is formed. On the other hand, the sleeve 56 is formed to correspond to four cores. That is, four through holes 59 into which ferrules 68 described later are respectively inserted are formed in a horizontal row.

  Sleeves 55 and 56 are coupled to the bases 57 and 58, respectively. An optical waveguide groove 60 and a guide fixing groove 61 are formed on the mounting surface of the bases 57 and 58 with respect to the end of the optical waveguide member 23. As described above, the optical waveguide 26 of the optical waveguide member 23 is inserted into the optical waveguide groove 60. Similarly, the guide 28 of the optical waveguide member 23 is inserted into the guide fixing groove 61. A pair of locking portions 62 and 62 for the sleeve covers 54 and 54 are formed on the sides of the bases 57 and 58. Further, concave portions 63 and 63 into which the sleeve mounting portions 42 and 42 are inserted are formed on the back surfaces of the bases 57 and 58.

  In FIG. 2, sleeve covers 54 and 54 are plate-like members that cover the ends of the optical waveguide member 23 placed on the bases 57 and 58, and a pair of locking portions are provided on the side portions thereof. A pair of locking projections 64 and 64 are formed to be locked to 62 and 62. Further, buffer members 65, 65 are provided on the surface facing the end of the optical waveguide member 23. The buffer members 65 and 65 are rubber, foamed resin, gel, or the like, and are set so that the position of the optical waveguide 26 can be fixed. The buffer members 65 and 65 of this embodiment are set to have a thickness of about 50% of the original thickness when fitted (assumed to be an example).

  A member (interval holding member: for example, a rod-shaped member) is provided between the optical axis alignment sleeves 50 and 51 to prevent the optical axis alignment sleeves 50 and 51 from moving in the proximity direction. It may be. The member can relieve stress concentration on the optical waveguide member 23 when a connector is connected by optical connectors 66 and 67 (optical coupling partners) described later.

  In FIG. 1, optical connectors 66 and 67 are optical coupling partners for the optical junction block 21 and are provided at the ends of the respective optical communication paths. The optical connector 66 is set for one core, and the optical connector 67 is set for four cores. A ferrule 68 provided at the end of the optical fiber 22, housings 69 and 70 for slidably housing the ferrule 68, and a housing 69 , 70 and spring caps 71, 72 fitted to the rear part, and a spring 73 inserted through the optical fiber 22 and interposed between the ferrule 68 and the spring caps 71, 72.

  The housings 69 and 70 are formed so as to be inserted and fitted into the fitting spaces 43 and 43 of the optical junction block 21. Locking arms 74 and 74 are formed on the upper portions of the housings 69 and 70. The specific functions and the like of the optical connectors 66 and 67, such as the ferrule 68 being abutted against the sleeves 55 and 56 by the force of the spring 73 at the time of optical coupling, are the actual fairness 5-10626 previously proposed by the present applicant. The description is omitted here since it is disclosed in this publication.

  In the above configuration, the optical junction block 21 according to the present invention is assembled, for example, through the following procedure. First, an operation for manufacturing the optical waveguide member 23 is performed as described with reference to FIG. Next, an operation of preparing the casing 24 and the optical axis alignment sleeves 50 and 51 together with the manufactured optical waveguide member 23 is performed. When such preparation is completed, the end portion of the optical waveguide member 23 is placed on the bases 57 and 58 of the sleeve main bodies 52 and 53 and sandwiched between the sleeve covers 54 and 54 to align the optical waveguide member 23 and the optical axis. The work of fixing the sleeves 50 and 51 for retrofitting is performed.

  Subsequently, the optical axis aligning sleeves 50 and 51 are respectively attached to the sleeve attaching portions 42 and 42 of the housing 24, and the optical waveguide member 23 is accommodated in the accommodating portion 41. Finally, the lid 38 is fitted to the housing main body 37 to cover the optical waveguide member 23 without any backlash. Thereby, a series of assembly is completed, and the optical junction block 21 as shown in FIG. 6 is completed. When the optical connectors 66 and 67 are optically coupled to the optical junction block 21, the state shown in FIG. 7 is obtained.

  As described above with reference to FIGS. 1 to 7, the optical junction block 21 can optically couple with the optical connectors 66 and 67 through the connector 25. Compared to the example, alignment and optical coupling can be made much easier. 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 connector 25 has the sleeves 55 and 56, the end of the optical waveguide 26 and the end of the optical communication path (ferrule 68) can be easily aligned and protected. Further, since the connector 25 has the lock portion 49, the positional relationship between the optical waveguide member 23 and the optical connectors 66 and 67 can be maintained. In addition, since the optical junction block 21 according to the present invention is assembled by fitting, it can be assembled more easily than in the past (the adhesive used in the conventional example is unnecessary).

  Next, another embodiment of the optical junction block according to the present invention will be described with reference to FIGS. FIG. 8 is an exploded perspective view showing another embodiment, FIG. 9 is an exploded perspective view of an optical junction block, FIG. 10 is a perspective view of an optical waveguide member, and FIG. 11 schematically illustrates a method for manufacturing the optical waveguide member. FIG. 12 is a perspective view of the optical axis alignment sleeve. Note that the same components as those described above are denoted by the same reference numerals, and detailed description thereof is omitted.

In FIG. 8, reference numeral 81 denotes an optical junction block used for optical communication in a car, optical communication in a house / building, etc., as in the above-described embodiment. The optical junction block 81 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 is configured to be able to light fraction Toki-optical coupling. The optical junction block 81 of the present invention includes an optical waveguide member 82, a housing 24, and a plurality of connectors 83 straddling them. Hereinafter, each component will be described in detail.

8 through 10, the optical waveguide member 82 is a plate-shaped member in a plan view a rectangular shape (rectangular shape. Assumed to be an example), a light fraction Toki (in relay and / or optical coupling A plurality of optical waveguides 84, and a synthetic resin substrate 85 on which the plurality of optical waveguides 84 are arranged. The optical waveguide member 82 is formed so as to be detachable from the housing 24 and the connector 83.

  The optical waveguide 84 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 84 is arranged along a desired path with respect to the substrate 85 (an arrangement state is not particularly limited). The end face (end part) of the optical waveguide 84 is flush with the end face (end part) of the substrate 85 and is disposed so as to be exposed from the end face.

  A plurality of through-holes 86 for mounting and fixing are formed in the optical waveguide member 82. In this embodiment, the through hole 86 is formed in a circular shape in plan view. The through holes 86 are formed one by one near the four corners of the optical waveguide member 82. The through hole 86 is not limited to the above shape, and may be formed in a long hole shape or the like. In addition, the number of through holes 86 is not limited to the number illustrated, and four or more through holes 86 may be formed. The through-hole 86 is only required to be accurately positioned.

  Here, a method for manufacturing the optical waveguide member 82 will be described with reference to FIGS. 10 and 11. The optical waveguide member 82 is manufactured through the following first to third steps in order using a jig 88 having a plurality of round pin-shaped protrusions 87 (not limited to this may be convex (projections)). Is done. In addition, the manufacturing method of the optical waveguide member 82 has the advantage that mass productivity is good.

  In the first step, as shown in FIG. 11A, an operation of forming an underclad layer 89 on a substrate 85 set on a jig 88 is performed (see FIG. 11B). The underclad layer 89 is formed over the entire surface of the substrate 85. The under-cladding layer 89 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 OPTOCAST3506n = 1. 56, etc.) (PMMA: Acrypet n = 1.49 manufactured by Mitsubishi Rayon, PP: Sumitomo Mitsui Polypro n = 1.49 manufactured by Sumitomo Mitsui Chemicals, etc.). The underclad layer 89 has an appropriate thickness. When the substrate 85 is transparent, it may be used as the underclad layer 89.

  In the second step, the core 90 is formed on the underclad layer 89 (see FIGS. 11C and 11D). A core molding die 91 is used for the core 90, and the core 90 is formed into a convex shape by a desired path using the core material (the path in FIG. 10 is an example). The core molding die 91 has a core molding recess 92 and a guide hole 93 guided by the protrusion 87 of the jig 88.

  In the third step, for example, an overcladding layer 94 as shown in FIG. 11E is formed around the core 90. The over-cladding layer 94 uses an over-cladding mold (not shown) and has a refractive index lower than that of the core material (acrylic UV curable resin: NORALD NOA65n = 1.52, acrylic UV curable). Resin: XVL-90n = 1.52 manufactured by Kyoritsu Chemical Industry, epoxy-based UV curable resin: OPTOCAST 3505n = 1.52 manufactured by EMI, etc.).

  When the overclad layer 94 is cured, the manufacture of the optical waveguide member 82 having the optical waveguide 84 is completed. The manufactured optical waveguide member 82 is detached from the jig 88 and attached to optical axis alignment sleeves 95 and 96 described later (see FIG. 11F). Since the optical waveguide member 82 is a plate-like member having a flat surface as shown in the drawing, it is placed on the bases 99 and 100 of the optical axis alignment sleeves 95 and 96 and is formed by the protrusions 87. The through-hole 86 is inserted into the through-hole fixing pins 101 and 101 of the bases 99 and 100 of the optical axis alignment sleeves 95 and 96.

  8 and 9, the connector 83 is a member for optically coupling the end of the optical waveguide 84 and the end of each optical communication path (ferrule 68) while aligning them. The shaft alignment sleeve 95, the sleeve mounting portion 42, the lower hood portion 44, and the upper hood portion 47 are provided (configuration on the optical connector 66 side). The connector 83 includes an optical axis alignment sleeve 96, a sleeve mounting portion 42, a lower hood portion 44, and an upper hood portion 47 (configuration on the optical connector 67 side).

  The optical axis aligning sleeves 95 and 96 include sleeve bodies 97 and 98 made of synthetic resin and sleeve covers 54 and 54, respectively. The optical axis alignment sleeves 95 and 96 have a split structure (fixing means for retrofitting) in which the end portions of the optical waveguide member 82 are sandwiched and fixed using the sleeve main bodies 97 and 98 and the sleeve covers 54 and 54. is doing.

  In FIG. 12, the sleeve main bodies 97 and 98 have sleeves 55 and 56 for protecting the optical coupling portion, and bases 99 and 100 on which the ends of the optical waveguide member 82 are placed. Sleeves 55 and 56 are coupled to the bases 99 and 100, respectively. A through-hole fixing pin 101 is formed on the mounting surface of the bases 99 and 100 with respect to the end of the optical waveguide member 82. As described above, the through hole 86 of the optical waveguide member 82 is inserted into the through hole fixing pin 101. A pair of locking portions 62 and 62 for the sleeve covers 54 and 54 are formed on the sides of the bases 99 and 100. Further, concave portions 63 and 63 into which the sleeve mounting portions 42 and 42 are inserted are formed on the back surfaces of the bases 99 and 100.

  A member (interval holding member: for example, a rod-shaped member) is provided between the optical axis alignment sleeves 95 and 96 to prevent the optical axis alignment sleeves 95 and 96 from moving in the proximity direction. It may be. The member can relieve stress concentration on the optical waveguide member 82 when the connectors are connected by the optical connectors 66 and 67 (optical coupling partners).

  In the above configuration, the optical junction block 81 according to the present invention is assembled, for example, through the following procedure. First, as described with reference to FIG. 11, an operation for manufacturing the optical waveguide member 82 is performed. Next, an operation of preparing the casing 24 and the optical axis alignment sleeves 95 and 96 together with the manufactured optical waveguide member 82 is performed. When such preparation is completed, the end portion of the optical waveguide member 82 is placed on the bases 99 and 100 of the sleeve main bodies 97 and 98 and sandwiched between the sleeve covers 54 and 54 to align the optical waveguide member 82 and the optical axis. The work of fixing the sleeves 95 and 96 for retrofitting is performed.

  Subsequently, the optical axis aligning sleeves 95 and 96 are respectively attached to the sleeve attaching portions 42 and 42 of the housing 24, and the optical waveguide member 82 is accommodated in the accommodating portion 41. Finally, the lid 38 is fitted to the housing body 37 to cover the optical waveguide member 82 without rattling. Thereby, a series of assembly is completed, and the optical junction block 81 as shown in FIG. 6 is completed. When the optical connectors 66 and 67 are optically coupled to the optical junction block 81, the state shown in FIG. 7 is obtained.

  As described above with reference to FIGS. 8 to 12, the optical junction block 81 can optically couple with the optical connectors 66 and 67 through the connector 83. Compared to the example, alignment and optical coupling can be made much easier. 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 connector 83 includes the sleeves 55 and 56, the end of the optical waveguide 84 and the end of the optical communication path (ferrule 68) can be easily aligned and protected. Further, since the connector 83 has the lock portion 49, the positional relationship between the optical waveguide member 82 and the optical connectors 66 and 67 can be maintained. In addition, since the optical junction block 81 according to the present invention is assembled by fitting, it can be assembled more easily than in the past (the adhesive used in the conventional example is unnecessary).

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

1 is an exploded perspective view showing an embodiment of an optical junction block according to the present invention and an optical connector optically coupled thereto. FIG. It is a disassembled perspective view of the optical junction block of FIG. It is a perspective view of the optical waveguide member of FIG. It is a figure which illustrates typically the manufacturing method of the optical waveguide member of FIG. It is a perspective view of the sleeve for optical axis alignment of FIG. It is a perspective view of an optical junction block. It is a perspective view of the optical junction block and optical connector of an optical coupling state. It is a disassembled perspective view which shows other one Embodiment of the optical junction block by this invention and the optical connector optically coupled to this. It is a disassembled perspective view of the optical junction block of FIG. It is a perspective view of the optical waveguide member of FIG. It is a figure which illustrates typically the manufacturing method of the optical waveguide member of FIG. It is a perspective view of the sleeve for optical axis alignment of FIG. It is a perspective view of the optical waveguide module of a prior art example.

Explanation of symbols

21 Optical Junction Block 22 Optical Fiber 23 Optical Waveguide Member 24 Housing 25 Connector 26 Optical Waveguide 27 Substrate 28 Guide 29 Undercladding Layer 30 Core 34 Overcladding Layer 37 Housing Body 38 Lid 41 Storage Portion 42 Sleeve Mounting Portion 43 Fit Space 44 Lower hood 47 Upper hood 50, 51 Optical axis alignment sleeve 52, 53 Sleeve body 54 Sleeve cover 55, 56 Sleeve 57, 58 Base 59 Through-hole 60 Optical waveguide groove 61 Guide fixing groove 65 Buffer member 66, 67 Optical connector 68 Ferrule 81 Optical junction block 82 Optical waveguide member 83 Connector 84 Optical waveguide 85 Substrate 86 Through hole 87 Protrusion 88 Jig 89 Under clad layer 90 Core 94 Over clad layer 95, 96 Sleeve for axial alignment 97, 98 the sleeve body 99, 100 base 101 through hole fixing pin

Claims (3)

An optical waveguide member, a housing, and a plurality of connectors straddling these,
Used in an optical junction block configured to be capable of relaying and / or optical branching and optical coupling of optical signals transmitted by an optical fiber, and provided between end portions of optical communication paths of the optical fiber. , A method of manufacturing an optical junction block for relaying and / or optical branching / optical coupling of an optical signal transmitted by the optical fiber,
A first step of forming an underclad layer on or under the substrate using a synthetic resin material having a refractive index lower than that of the core material constituting the optical waveguide;
A convex core is formed in a predetermined path on the undercladding layer using a light-transmitting synthetic resin material, and a projection or convex shape is mounted on the substrate. A second step in which the guide is made of the same material as the core and is simultaneously molded with the core;
Forming the optical waveguide by forming an overcladding layer using a synthetic resin material having a refractive index lower than that of the core material using an overcladding mold having a recess for overcladding molding around the core A third step to
Consists of
The mounting guides formed based on the second step are respectively inserted into the guide fixing grooves of the optical axis adjusting sleeve, and the overcladding layer manufactured based on the third step is optically aligned. A method for manufacturing an optical junction block , characterized by being manufactured so as to be inserted into an optical waveguide groove of a core sleeve. For forming the core in the second step,
Using a core molding die having a core molding recess and a guide hole guided by the projection of the jig,
For forming the overclad layer in the third step,
Using a mold for overclad,
In the first step, a protrusion or a convex member of a jig for forming the underclad layer on the substrate or under the substrate is used as a guide member for the core mold and the overclad mold. The manufacturing method of the optical junction block of Claim 1 characterized by the above-mentioned. An optical junction block that relays and / or splits and couples optical signals transmitted by an optical fiber,
The optical signal transmitted by the optical fiber is relayed and / or optically branched and optically coupled, formed as a substantially T-shaped projection in plan view, and a plurality of mounting and fixing guides are formed. An optical junction block manufactured by the method of manufacturing an optical junction block described above;
A casing made of synthetic resin, and including a casing main body that houses the optical waveguide member, and a lid that fits into the casing main body and covers the optical waveguide member with an appropriate interval;
A plurality of connectors that optically couple the end portions of the optical waveguide and the end portions of the optical communication paths while aligning the optical waveguide member and the housing; and
An optical junction block characterized by comprising the above.

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