JPWO2019244388A1 - Optical connection parts, optical connectors and optical connection structures - Google Patents

Abstract

The optical connection component according to one embodiment includes a first end portion and a second end portion located on the opposite side of the first end portion. The first end portion has a first contact surface, a first recess, and a first bottom surface that come into contact with the mating connector. The second end portion has a second contact surface, a second recess, and a second bottom surface that abut the MT ferrule. The first bottom surface and the second bottom surface face the optical fiber holding hole of the MT ferrule. This optical connection component further includes a guide hole through which a guide pin can be inserted. The resin constituting the optical connection component has a transmittance of 80% or more and 100% or less with respect to light having a wavelength of 1210 nm or more and 1650 nm or less.

Description

One aspect of the present disclosure relates to optical connection components, optical connectors and optical connection structures.
This application claims priority based on Japanese Application No. 2018-117090 of June 20, 2018, and incorporates all the contents described in the Japanese application.

Conventionally, various optical connection components, optical connectors, and optical connection structures have been known. Patent Document 1 describes an optical connector including a ferrule, a lens fiber, and a plate, and an optical connection structure in which a pair of connectors are optically connected to each other. The ferrule has a fiber hole for holding the inserted lens fiber, and the lens fiber includes a single mode fiber and a GRIN lens.

The ferrule has an end face facing the mating optical connector, a GRIN lens is provided on the end face side, and a single mode fiber is provided on the opposite side of the end face. Further, Patent Document 1 describes an optical connection structure in which the end face of the ferrule has a concave structure. A plate is provided on the end face of the ferrule, and a refractive index adjusting agent is provided between the end face and the plate. Of the pair of optical connectors forming an optical connection structure, the tip surface of the GRIN lens of one optical connector and the tip surface of the GRIN lens of the other optical connector are optically connected to each other via a plate.

U.S. Patent Application Publication No. 2016/0282562

The optical connection component according to one embodiment is an optical connection component which is a resin spacer used for a space-coupled optical connection, and faces the mating connector along a connection direction in which the mating connector is connected. It includes one end and a second end located on the opposite side of the first end in the connecting direction. The first end portion has a first contact surface that contacts the mating connector, a first recess surrounded by the first contact surface, and a first bottom surface that is the bottom of the first recess. The second end portion has a second contact surface that contacts the MT ferrule, a second recess surrounded by the second contact surface, and a second bottom surface that is the bottom of the second recess. The first bottom surface and the second bottom surface face a plurality of optical fiber holding holes provided in the MT ferrule. The optical connection component is capable of inserting at least a pair of guide pins inserted into the mating connector and the MT ferrule, and further includes at least a pair of guide holes penetrating from the first contact surface to the second contact surface. The resin constituting the spacer has a transmittance of 80% or more and 100% or less with respect to light having a wavelength of 1210 nm or more and 1650 nm or less.

The optical connector according to one embodiment includes the above-mentioned optical connection component, a plurality of optical fibers, and an MT ferrule. A GRIN lens is fused and connected to the tip of each of the plurality of optical fibers. The MT ferrule has an end face facing the second end of the optical connection component, a plurality of optical fiber holding holes having an opening in the end face, extending in the connection direction, and holding each of the plurality of optical fibers, and an opening in the end face. And at least a pair of guide holes into which at least a pair of guide pins are inserted. The tip surface of the GRIN lens is exposed from the opening of the optical fiber holding hole. The second contact surface of the optical connection component is fixed to the end surface with an adhesive in a state where the guide hole of the MT ferrule and the guide hole of the optical connection component are aligned with each other.

In the optical connection structure according to one embodiment, the first contact surface of the first optical connector described above and the first contact surface of the second optical connector described above are in contact with each other. The first optical connector and the second optical connector are positioned by inserting guide pins into the guide holes of the MT ferrule and the guide holes of the optical connection component.

FIG. 1 is a perspective view showing an optical connector according to the first embodiment. FIG. 2 is a side sectional view showing an optical connection structure according to the first embodiment. FIG. 3 is a front view showing the optical connection component according to the first embodiment. FIG. 4 is a rear view showing the optical connection component of FIG. FIG. 5 is a sectional view taken along line VV of FIG. FIG. 6 is a side sectional view showing a part of the optical connector according to the second embodiment. FIG. 7 is a side sectional view showing a part of the optical connector according to the third embodiment. FIG. 8 is a side sectional view showing a part of the optical connector according to the fourth embodiment. FIG. 9 is a side sectional view showing a part of the optical connector according to the fifth embodiment.

[Issues to be solved by this disclosure]
Since the above-mentioned optical connection structure requires a ferrule having a special shape having a concave structure, there is a concern that the cost will increase. Further, for example, when the normal of the tip surface of the GRIN lens is inclined with respect to the optical axis, it is necessary to perform polishing in order to align the tip surface of the GRIN lens with the end face of the ferrule. Since this polishing needs to be performed while changing the particle size of the polishing paper, there may be a problem that it takes time.

One aspect of the present disclosure is to provide an optical connection component, an optical connector and an optical connection structure that can eliminate the need for specially shaped ferrules and the need for polishing.

[Effect of the present disclosure]
According to one aspect of the present disclosure, a ferrule having a special shape can be eliminated and polishing can be eliminated.

[Explanation of Embodiment]
First, the contents of the embodiments of the present disclosure will be listed and described. The optical connection component according to one embodiment is an optical connection component which is a resin spacer used for a space-coupled optical connection, and faces the mating connector along a connection direction in which the mating connector is connected. It includes one end and a second end located on the opposite side of the first end in the connecting direction. The first end portion has a first contact surface that contacts the mating connector, a first recess surrounded by the first contact surface, and a first bottom surface that is the bottom of the first recess. The second end portion has a second contact surface that contacts the MT ferrule, a second recess surrounded by the second contact surface, and a second bottom surface that is the bottom of the second recess. The first bottom surface and the second bottom surface face a plurality of optical fiber holding holes provided in the MT ferrule. The optical connection component is capable of inserting at least a pair of guide pins inserted into the mating connector and the MT ferrule, and further includes at least a pair of guide holes penetrating from the first contact surface to the second contact surface. The resin constituting the spacer has a transmittance of 80% or more and 100% or less with respect to light having a wavelength of 1210 nm or more and 1650 nm or less.

The optical connection component according to one embodiment is a spacer used for space-coupled optical connection, and has a first end portion facing the mating connector and a second end portion having a second contact portion that contacts the MT ferrule. It has a part. Therefore, by interposing the resin optical connection component between the MT ferrule and the mating connector, it is possible to eliminate the need for polishing the end face of the MT ferrule. Further, since the optical connection component has the first recess, a space-coupled connection can be realized, and when the optical connection component has the second recess, the adhesive can be put into the second recess. Further, since the MT ferrule itself does not require special processing or the like, it is possible to eliminate the need for a ferrule having a special shape.

The first recess may be surrounded on all sides by the first contact surface. In this case, when the first contact surface comes into contact with the mating connector, the first recess is sealed and the connection can be stabilized. In addition, it is possible to prevent dirt from entering the inside of the first recess after connection.

The second recess may be surrounded on three sides by the second contact surface. In this case, since the second recess is surrounded from three sides, the adhesive can be injected into the second recess from the unenclosed portion. In addition, air bubbles inside the adhesive can be released from a portion not surrounded by the second recess.

The depth from the first contact surface to the first bottom surface may be 90 μm or more and 110 μm or less. In this case, the occurrence of dew condensation inside the first recess can be suppressed, and the invasion of dirt into the inside of the first recess can be suppressed.

The depth from the second contact surface to the second bottom surface may be 90 μm or more and 110 μm or less. In this case, the adhesive can be more reliably injected into the second recess.

In the above-mentioned optical connection component, the first angle, which is the angle of the normal of the first bottom surface with respect to the connection direction, and the second angle, which is the angle of the normal line of the second bottom surface with respect to the connection direction, are both 0 ° or more and 1 It is less than ° and the first bottom surface may be AR coated. In this case, the optical loss due to reflection can be suppressed by AR coating the first bottom surface of the first recess.

In the above-mentioned optical connection component, the first angle, which is the angle of the normal of the first bottom surface with respect to the connection direction, and the second angle, which is the angle of the normal line of the second bottom surface with respect to the connection direction, are both 1 ° or more and 8 It may be less than or equal to °. In this case, since the normal of the first bottom surface and the normal of the second bottom surface are inclined from the connection direction, the reflected return light can be suppressed even if the AR coating is not applied.

The guide hole may have a taper that expands in diameter toward the second contact surface side. In this case, it is possible to prevent the adhesive from passing through the guide hole when manufacturing an optical connector or the like.

The optical connector according to one embodiment includes the above-mentioned optical connection component, a plurality of optical fibers, and an MT ferrule. A GRIN lens is fused and connected to the tip of each of the plurality of optical fibers. The MT ferrule has an end face facing the second end of the optical connection component, a plurality of optical fiber holding holes having an opening in the end face, extending in the connection direction, and holding each of the plurality of optical fibers, and an opening in the end face. And at least a pair of guide holes into which at least a pair of guide pins are inserted. The tip surface of the GRIN lens is exposed from the opening of the optical fiber holding hole. The second contact surface of the optical connection component is fixed to the end surface with an adhesive in a state where the guide hole of the MT ferrule and the guide hole of the optical connection component are aligned with each other.

In the optical connection structure according to one embodiment, the first contact surface of the first optical connector described above and the first contact surface of the second optical connector described above are in contact with each other. The first optical connector and the second optical connector are positioned by inserting guide pins into the guide holes of the MT ferrule and the guide holes of the optical connection component.

Since the optical connector and the optical connection structure according to the embodiment include the above-mentioned optical connection component, the same function and effect as those of the optical connection component can be obtained. Further, in the optical connector and the optical connection structure according to the embodiment, the GRIN lens is connected to the optical fiber by fusion splicing. Therefore, it is possible to suppress the peeling of the GRIN lens from the optical fiber and also to suppress the deviation of the optical axis. Further, since the tip surface of the GRIN lens is exposed at the opening of the optical fiber holding hole, it is possible to realize a beam expansion type spatial coupling.

Each of the plurality of optical fibers may be fixed in a state where the tip surface of the GRIN lens is in contact with the second bottom surface. In this case, since the air layer does not intervene between the tip surface of the GRIN lens and the optical connection component, the optical loss can be suppressed more reliably.

The difference between the refractive index of the GRIN lens and the refractive index of the adhesive is 0.001 or less, and the second angle, which is the normal angle of the second bottom surface of the optical connection component with respect to the connection direction, is 1 ° or more and 8 °. It may be as follows. In this case, the reflected return light can be suppressed by tilting the normal of the second bottom surface of the optical connection component with respect to the optical axis. Further, since the difference between the refractive index of the GRIN lens and the refractive index of the adhesive is small, it is possible to suppress the optical loss that occurs between the GRIN lens and the adhesive without tilting the tip surface of the GRIN lens. .. Therefore, it is possible to save the trouble of tilting the tip surface of the GRIN lens and to further reliably suppress the optical loss.

The material of the optical connection component and the material of the MT ferrule are the same as each other, and the optical connection component and the MT ferrule may be welded to each other. In this case, since the material of the optical connection component is the same as that of the MT ferrule, the optical connection component can be integrated with the MT ferrule. Further, the optical loss between the MT ferrule and the optical connection component can be suppressed.

[Details of Embodiment]
Hereinafter, specific examples of the optical connection component, the optical connector, and the optical connection structure according to the embodiment will be described with reference to the drawings. The present disclosure is not limited to the following examples, but is shown in the claims and is intended to include all modifications within the scope of the claims. In the description of the drawings, the same or corresponding elements are designated by the same reference numerals, and duplicate description will be omitted as appropriate. In addition, the drawings are partially simplified or exaggerated to facilitate understanding, and the dimensions and the like are not limited to those described in the drawings.

(First Embodiment)
FIG. 1 is a perspective view showing an optical connector 10 provided with an optical connector 11 according to the first embodiment. FIG. 2 is a side sectional view showing an optical connection structure 1 provided with an optical connector 10. As shown in FIGS. 1 and 2, the optical connection structure 1 is, for example, a structure in which the optical connector 10 and the mating connector are connected to each other. The mating connector may be the same as the optical connector 10, or may be an optical connector different from the optical connector 10. FIG. 2 shows an example in which the mating connector is the optical connector 10.

The optical connector 10 is connected to, for example, a mating connector having the same configuration as the optical connector 10 along the connection direction D1. The optical connector 10 includes an optical connector 11, an MT ferrule 12, an optical waveguide member 13, and a guide pin 16. The optical waveguide member 13 includes an optical fiber 14 and a GRIN lens 15. The guide pin 16 is provided to position the optical connector 10 and the mating connector.

The optical connection component 11 is a resin spacer interposed between the MT ferrule 12 and the mating connector. The optical connection component 11 is transparent at the optical communication wavelength handled by the optical connector 10. The resin constituting the optical connection component 11 has a transmittance of 80% or more and 100% or less with respect to light having a wavelength of 1210 nm or more and 1650 nm or less. The optical connection component 11 includes a first end portion 11a that abuts on the mating connector, a second end portion 11b that faces the opposite side of the connection direction D1 of the first end portion 11a, and the first end portion 11a and the second end portion. It has a pair of side portions 11c, 11d that connect the 11b to each other, and an upper portion 11e and a lower portion 11f. The first end portion 11a includes a first contact surface 11g that contacts the mating connector, a first recess 11h surrounded by the first contact surface 11g, and a first bottom surface 11j that is the bottom of the first recess 11h. Has.

The optical connection component 11 has a pair of guide holes 11 m. In FIG. 2, the guide pin 16 is not shown for the sake of simplification. An opening of each guide hole 11m is formed in the first contact surface 11g, and a guide pin 16 projects from each of the openings of the guide hole 11m in the connection direction D1. In the optical connection structure 1, for example, the first contact surface 11 g of the first optical connector 10 and the first contact surface 11 g of the second optical connector 10 come into contact with each other. In this case, the first optical connector 10 and the second optical connector 10 are positioned by inserting the guide pin 16 into the guide hole 12j of the MT ferrule 12 and the guide hole 11m of the optical connection component 11.

The MT ferrule 12 is composed of, for example, a resin such as polyphenylene sulfide (PPS) containing glass. The main component of the material of MT ferrule 12 is PPS. The MT ferrule 12 has an end surface 12a provided at one end of the connection direction D1 facing the optical connection component 11, a rear end surface 12b provided at the other end of the connection direction D1, and a pair of sides extending along the connection direction D1. It has a portion 12c, an upper surface 12e, and a lower surface 12f.

A window hole 12g is formed on the upper surface 12e so that the optical waveguide member 13 inside the MT ferrule 12 can be visually recognized. In FIG. 2, the window hole 12g is not shown for the sake of simplification. The window hole 12g is an introduction hole for the adhesive 17 described later. Therefore, when the adhesive 17 is introduced into the MT ferrule 12 from the window hole 12g with the optical waveguide member 13 arranged inside the MT ferrule 12, the optical waveguide member 13 is adhesively fixed inside the MT ferrule 12. Will be done.

The MT ferrule 12 has a plurality of optical fiber holding holes 12h in which the optical fiber 14 is held, and a pair of guide holes 12j into which each guide pin 16 is inserted. Both the optical fiber holding hole 12h and the guide hole 12j are open to the end face 12a of the MT ferrule 12, and extend from the end face 12a to the inside of the MT ferrule 12. The pair of guide holes 12j of the MT ferrule 12 are located on the opposite side of each guide hole 11m from the first end portion 11a. The pair of guide holes 12j are arranged so as to line up along the direction D2 intersecting the connection direction D1. The direction D2 is, for example, a direction intersecting the connection direction D1, a longitudinal direction of the first end portion 11a, and a direction orthogonal to the side portions 11c and 12c. The pair of guide holes 12j of the MT ferrule 12 are arranged on both ends in the direction D2 of the tip surface 15a of the GRIN lens 15.

The tip surface 15a of the GRIN lens 15 is exposed at the opening of the optical fiber holding hole 12h. Each of the plurality of optical fibers 14 is inserted into and held in the optical fiber holding hole 12h. The optical fiber 14 is, for example, a single mode fiber. Each of the plurality of optical fiber holding holes 12h penetrates from the rear end surface 12b to the end surface 12a along the connection direction D1. The central axis direction of each optical fiber holding hole 12h and the optical axis direction of the optical fiber 14 coincide with, for example, the connection direction D1.

The optical fiber 14 has a core 14a and a clad 14b. The optical fiber 14 and the GRIN lens 15 both contain quartz glass, for example. The core 14a and the GRIN lens 15 may contain gallium. In this case, the refractive index of the optical fiber 14 and the GRIN lens 15 can be adjusted. The optical fiber 14 and the GRIN lens 15 have a linear shape extending in the connection direction D1. The GRIN lens 15 is located on the tip side (the other side connector side, the optical connection component 11 side) of the optical fiber 14. The optical fiber 14 and the GRIN lens 15 are joined to each other by fusion. Both the optical fiber 14 and the GRIN lens 15 are formed in a round bar shape. The diameter of the optical fiber 14 and the diameter of the GRIN lens 15 are substantially the same as each other.

The front end surfaces 15a of the plurality of GRIN lenses 15 are aligned in the end surface 12a along the direction D2. The front end surface 15a of each GRIN lens 15 is flush with, for example, the end surface 12a. The tip surface 15a of the GRIN lens 15 is formed, for example, by cutting a mechanical cutter or a laser cutter. The GRIN lens 15 on which the front end surface 15a is formed is inserted into the optical fiber holding hole 12h from the rear end surface 12b of the MT ferrule 12 and comes into contact with the optical connection component 11 via the adhesive 17. In the present embodiment, neither the tip surface 15a of the GRIN lens 15 nor the end surface 12a of the MT ferrule 12 is polished. On the end face 12a, for example, a plurality of tip faces 15a are arranged at equal intervals along the direction D2.

The second end 11b of the optical connection component 11 comes into contact with the MT ferrule 12. The second end portion 11b has a second contact surface 11n that contacts the MT ferrule 12, a second recess 11p that is surrounded by the second contact surface 11n from three sides, and a second bottom surface 11q that is the bottom of the second recess 11p. And have. The adhesive 17 is introduced into the second recess 11p. The adhesive 17 is applied to the inside of the MT ferrule 12 from the window hole 12g, for example, and enters the second recess 11p to be cured. The adhesive 17 fixes the optical connection component 11, the MT ferrule 12, and the optical waveguide member 13 to each other. For example, the adhesive 17 adheres and fixes the optical connection component 11, the MT ferrule 12, and the optical waveguide member 13 to each other in a state where the guide hole 11m of the optical connection component 11 and the guide hole 12j of the MT ferrule 12 coincide with each other.

The adhesive 17 may be a refractive index matching member that matches the refractive index. In this case, the adhesive 17 matches the refractive index between the optical connection component 11 and the GRIN lens 15. That is, an air layer having a large difference in refractive index is not included between the optical connection component 11 and the GRIN lens 15. Therefore, the refractive index of the adhesive 17 is preferably, for example, the same as the refractive index of the GRIN lens 15, and more preferably the same as the refractive index of the optical connection component 11.

FIG. 3 is a front view showing the first end portion 11a of the optical connection component 11. FIG. 4 is a rear view showing the second end portion 11b of the optical connection component 11. FIG. 5 is a sectional view taken along line VV of the optical connection component 11. As shown in FIGS. 3 to 5, the optical connection component 11 exhibits a substantially rectangular parallelepiped appearance. As described above, the first end portion 11a has a first contact surface 11g, a first recess 11h, and a first bottom surface 11j. The first bottom surface 11j is surrounded by the first contact surface 11g from all sides.

As a result, a space S is formed between the optical connection component 11 of the optical connector 10 and the mating connector (optical connecting component 11 of the mating connector), so that a space-coupled optical connection is possible. For example, the first recess 11h and the first bottom surface 11j have a rectangular shape extending in the direction D2 and having rounded corners.

The depth H1 from the first contact surface 11g to the first bottom surface 11j is, for example, 10 μm or more and 110 μm or less, preferably 90 μm or more and 110 μm or less, and 100 μm as an example. The angle (first angle) of the normal L1 of the first bottom surface 11j with respect to the connection direction D1 is 0 ° or more and less than 1 °. The first bottom surface 11j is AR coated. Therefore, the reflection of light on the first bottom surface 11j is prevented.

As described above, the second end portion 11b has a second contact surface 11n, a second recess 11p, and a second bottom surface 11q. The second bottom surface 11q is surrounded by the second contact surface 11n from three sides. As a result, the adhesive 17 can be introduced into the second recess 11p and the second bottom surface 11q. Then, the air bubbles contained in the adhesive 17 can be released to the outside from the portion 11r not surrounded by the second contact surface 11n of the second bottom surface 11q. The second recess 11p is open on one side of the direction D3 that intersects both the connection direction D1 and the direction D2. The direction D3 corresponds to the width direction (short direction) of the optical connection component 11, and is, for example, a direction orthogonal to both the connection direction D1 and the direction D2.

The depth H2 from the second contact surface 11n to the second bottom surface 11q is, for example, 10 μm or more and 110 μm or less, preferably 90 μm or more and 110 μm or less, and 100 μm as an example. For example, the angle (second angle) of the normal L2 of the second bottom surface 11q with respect to the connection direction D1 is 0 ° or more and less than 1 °.

The guide holes 11m are provided on both ends of the direction D2 when viewed from the first bottom surface 11j and the second bottom surface 11q. Each guide hole 11m has a cylindrical hole portion 11t extending in the connection direction D1 at the first end portion 11a, and a taper 11s whose diameter gradually increases from the cylindrical hole portion 11t toward the second contact surface 11n. The angle of the taper 11s with respect to the connection direction D1 is, for example, 20 ° or more and 40 ° or less. The taper 11s suppresses the intrusion of the adhesive 17 into the first end portion 11a side of the cylindrical hole portion 11t.

Next, the effects obtained from the optical connection component 11, the optical connector 10, and the optical connection structure 1 according to the present embodiment will be described in detail. The optical connection component 11 is a spacer used for space-coupled optical connection. The optical connection component 11 includes a first end portion 11a facing the mating connector and a second end portion 11b having a second contact surface 11n that contacts the MT ferrule 12. Therefore, by interposing the resin optical connection component 11 between the MT ferrule 12 and the mating connector, it is possible to eliminate the need for polishing the end face 12a of the MT ferrule 12.

Further, since the optical connection component 11 has the first recess 11h, a space-coupled connection can be realized. Then, since the optical connection component 11 has the second recess 11p, the adhesive 17 can be put into the second recess 11p. Further, since the MT ferrule 12 itself does not require special processing or the like, it is possible to eliminate the need for a ferrule having a special shape.

In the present embodiment, the first recess 11h is surrounded on all sides by the first contact surface 11g. Therefore, when the first contact surface 11g is connected to the mating connector, the first recess 11h is sealed and the connection can be stabilized. In addition, it is possible to prevent dirt from entering the inside of the first recess 11h after connection.

In the present embodiment, the second recess 11p is surrounded on three sides by the second contact surface 11n. Therefore, since the second recess 11p is surrounded from three sides, the adhesive 17 can be injected from the unenclosed portion 11r into the second recess 11p. In addition, air bubbles inside the adhesive 17 can be released from the unenclosed portion 11r of the second recess 11p.

In the present embodiment, the depth H1 from the first contact surface 11g to the first bottom surface 11j may be 90 μm or more and 110 μm or less. In this case, the occurrence of dew condensation inside the first recess 11h can be suppressed, and the invasion of dirt into the inside of the first recess 11h can be suppressed.

In the present embodiment, the depth H2 from the second contact surface 11n to the second bottom surface 11q may be 90 μm or more and 110 μm or less. In this case, the adhesive 17 can be more reliably injected into the second recess 11p.

In the present embodiment, both the first angle, which is the angle of the normal line L1 of the first bottom surface 11j with respect to the connection direction D1, and the second angle, which is the angle of the normal line L2 of the second bottom surface 11q with respect to the connection direction D1, are 0. More than ° and less than 1 °. The first bottom surface 11j is AR-coated. Therefore, by AR-coating the first bottom surface 11j of the first recess 11h, optical loss due to reflection can be suppressed.

In the present embodiment, the guide hole 11m has a taper 11s whose diameter increases toward the second contact surface 11n. Therefore, it is possible to prevent the adhesive 17 from passing through the guide hole 11 m when the optical connector 10 is being manufactured.

In the present embodiment, since the optical connector 10 and the optical connection structure 1 include the optical connection component 11, the same effect as that of the optical connection component 11 can be obtained. Further, in the optical connector 10 and the optical connection component 11 according to the embodiment, the GRIN lens 15 and the optical fiber 14 are connected by fusion. Therefore, the peeling of the GRIN lens 15 from the optical fiber 14 can be suppressed, and the deviation of the optical axis can be suppressed. Further, since the front end surface 15a of the GRIN lens 15 is exposed to the opening of the optical fiber holding hole 12h, a beam expansion type spatial coupling can be realized.

(Second Embodiment)
Next, the optical connector 20 according to the second embodiment will be described with reference to FIG. FIG. 6 is an enlarged side sectional view of the optical connection component 11, the MT ferrule 12, and the GRIN lens 25 of the optical connector 20 according to the second embodiment. The optical connector 20 includes a GRIN lens 25 that is different from the GRIN lens 15 described above, and this point is different from the first embodiment. Hereinafter, the description overlapping with the first embodiment will be omitted as appropriate.

The GRIN lens 25 has a tip surface 25a exposed to the opening of the optical fiber holding hole 12h of the MT ferrule 12. The tip surface 25a of the GRIN lens 25 is formed by, for example, a mechanical cutter or a laser cutter. By the way, when the tip surface 25a of the GRIN lens 25 is formed by a mechanical cutter or a laser cutter, the normal line L3 of the tip surface 25a may be tilted with respect to the connection direction D1. The angle θ1 of the normal line L3 of the tip surface 25a with respect to the connection direction D1 is, for example, 1 ° or more and 8 ° or less. This angle θ1 corresponds to, for example, an angle variation when the tip surface 25a is formed by a mechanical cutter or a laser cutter.

As described above, in the second embodiment, the angle θ1 of the normal line L3 of the tip surface 25a of the GRIN lens 25 with respect to the connection direction D1 is 1 ° or more and 8 ° or less. Even in such a case, the difference in refractive index between the GRIN lens 25 and the optical connection component 11 can be suppressed by interposing the adhesive 17 between the tip surface 25a and the optical connection component 11. Therefore, it is possible to suppress the deviation of the angle of the light emitted from the tip surface 25a with respect to the connection direction D1.

(Third Embodiment)
Subsequently, the optical connection component 31 and the optical connector 30 according to the third embodiment will be described with reference to FIG. 7. FIG. 7 is an enlarged side sectional view of the optical connection component 31, the MT ferrule 12, and the GRIN lens 25 of the optical connector 30 according to the third embodiment. The optical connector 30 includes an optical connection component 31 different from the above-mentioned optical connection component 11.

The optical connection component 31 includes a first end portion 31a and a second end portion 31b that are different from the first end portion 11a and the second end portion 11b described above, respectively. The first end portion 31a includes a first contact surface 11g that contacts the mating connector, a first recess 31h surrounded by the first contact surface 11g, and a first bottom surface 31j that is the bottom of the first recess 31h. Has. The second end portion 31b has a second contact surface 11n that contacts the MT ferrule 12, a second recess 31p that is surrounded by the second contact surface 11n from three sides, and a second bottom surface 31q that is the bottom of the second recess 31p. And have. In the optical connector 30, each of the plurality of optical fibers is fixed in a state where the front end surface 25a of the GRIN lens 25 is in contact with the second bottom surface 31q.

The angle θ2 (first angle) of the normal L4 of the first bottom surface 31j with respect to the connection direction D1 is 1 ° or more and 8 ° or less. Further, the angle θ3 (second angle) of the normal line L5 of the second bottom surface 31q with respect to the connection direction D1 is 1 ° or more and 8 ° or less. The GRIN lens 25 has a tip surface 25a whose normal line is inclined with respect to the connection direction D1 as described above. The tip surface 25a is formed so as to be oblique by, for example, a mechanical cutter or a laser cutter.

As described above, in the optical connection component 31 and the optical connector 30 according to the third embodiment, the angle θ2 which is the angle of the normal line L4 of the first bottom surface 31j with respect to the connection direction D1 and the normal line L5 of the second bottom surface 31q with respect to the connection direction D1. The angle θ3, which is the angle of, is 1 ° or more and 8 ° or less. Therefore, since the normal line L4 of the first bottom surface 31j and the normal line L5 of the second bottom surface 31q are inclined with respect to the connection direction D1, the reflected return light can be suppressed even if the AR coating is not applied.

In the optical connector 30, each of the plurality of optical fibers is fixed in a state where the front end surface 25a of the GRIN lens 25 is in contact with the second bottom surface 31q. Therefore, since the air layer does not intervene between the tip surface 25a of the GRIN lens 25 and the optical connection component 31, the optical loss can be suppressed more reliably.

(Fourth Embodiment)
Next, the optical connector 40 according to the fourth embodiment will be described with reference to FIG. FIG. 8 is an enlarged side sectional view of the optical connection component 31, the MT ferrule 12, and the GRIN lens 15 of the optical connector 40. The angle of the normal of the tip surface 15a of the GRIN lens 15 with respect to the connection direction D1 is 0 ° or more and less than 1 °. On the other hand, the angle θ3 of the normal L5 of the second bottom surface 31q of the optical connection component 31 with respect to the connection direction D1 is 1 ° or more and 8 ° or less. Assuming that the refractive index of the tip surface 15a of the GRIN lens 15 is n1, the refractive index of the adhesive 17 is n2, and the refractive index of the optical connection component 31 is n3, the value of n1 is substantially the same as the value of n2. The value of n3 is different from the value of n1 and the value of n2. For example, the value of n3 is larger than either the value of n1 and the value of n2. The difference between the value of n1 and the value of n2 is, for example, 0.001 or less.

As described above, in the fourth embodiment, the difference between the refractive index n1 of the GRIN lens 15 and the refractive index n2 of the adhesive 17 is 0.001 or less. The angle θ3, which is the angle of the normal line L5 of the second bottom surface 31q with respect to the connection direction D1, is 1 ° or more and 8 ° or less. Therefore, the reflected return light can be suppressed by tilting the normal line L5 of the second bottom surface 31q of the optical connection component 31 with respect to the optical axis. Further, since the difference between the refractive index n1 of the GRIN lens 15 and the refractive index n2 of the adhesive 17 is small, the optics generated between the GRIN lens 15 and the adhesive 17 without tilting the tip surface 15a of the GRIN lens 15. Loss can be suppressed. Therefore, it is possible to save the trouble of tilting the tip surface 15a of the GRIN lens 15 and to further reliably suppress the optical loss.

(Fifth Embodiment)
Subsequently, the optical connector 50 and the optical connection component 51 according to the fifth embodiment will be described with reference to FIG. FIG. 9 is an enlarged side sectional view of the optical connection component 51, the MT ferrule 12, and the GRIN lens 25 of the optical connector 50. The material of the optical connection component 51 is, for example, the same amorphous material as the material of the MT ferrule 12. The main component of the material of the optical connection component 51 is, for example, polyetherimide (PEI: Poly Ether Imide) or cycloolefin polymer (COP). The optical connection component 51 is fixed to the MT ferrule 12 by welding. In order to facilitate welding, the material of MT ferrule 12 may contain, for example, carbon.

As described above, in the optical connector 50 and the optical connection component 51 according to the fifth embodiment, the material of the optical connection component 51 and the material of the MT ferrule 12 are the same as each other. The optical connection component 51 and the MT ferrule 12 are welded to each other. Therefore, since the material of the optical connection component 51 and the material of the MT ferrule 12 are the same, the optical connection component 51 can be integrated with the MT ferrule 12. Further, the optical loss between the MT ferrule 12 and the optical connection component 51 can be suppressed.

The embodiments of the optical connection component, the optical connector, and the optical connection structure according to the present disclosure have been described above. However, the optical connection component, the optical connector, and the optical connection structure according to the present disclosure are not limited to the above-described embodiments and can be variously modified. That is, the configurations of the optical connection component, the optical connector, and each part of the optical connection structure can be changed as appropriate.

For example, in the above-described embodiment, the normal line L4 of the first bottom surface 31j with respect to the connection direction D1 and the normal line L5 of the second bottom surface 31q with respect to the connection direction D1 are on the same side (the first bottom surface 31j and the second bottom surface 31q). An example of tilting (so that is close to parallel) was described. However, the normal of the first bottom surface and the normal of the second bottom surface may be inclined to different sides from each other, and the inclination direction of these normals can be changed as appropriate.

1 ... Optical connection structure, 10, 20, 30, 40, 50 ... Optical connector, 11, 31, 51 ... Optical connection component, 11a, 31a ... First end, 11b, 31b ... Second end, 11c, 11d ... Side, 11e ... Upper, 11f ... Lower, 11g ... First contact surface, 11h, 31h ... First recess, 11j, 31j ... First bottom surface, 11m ... Guide hole, 11n ... Second contact surface, 11p , 31p ... 2nd recess, 11q, 31q ... 2nd bottom surface, 11r ... location, 11s ... taper, 11t ... cylindrical hole, 12 ... MT ferrule, 12a ... end face, 12b ... rear end face, 12c ... side, 12e ... Upper surface, 12f ... Lower surface, 12g ... Window hole, 12h ... Optical fiber holding hole, 13 ... Optical waveguide member, 14 ... Optical fiber, 14a ... Core, 14b ... Clad, 15, 25 ... GRIN lens, 15a, 25a ... Tip surface , 16 ... guide pin, 17 ... adhesive, D1 ... connection direction, D2, D3 ... direction, L1, L2, L3, L4, L5 ... normal, S ... space, θ1, θ2, θ3 ... angle.

Claims (13)

An optical connection component that is a resin spacer used for space-coupled optical connection.
The first end facing the mating connector along the connection direction to connect to the mating connector, and
The first end is provided with a second end located on the opposite side of the connection direction.
The first end is
It has a first contact surface that comes into contact with the mating connector, a first recess surrounded by the first contact surface, and a first bottom surface that is the bottom of the first recess.
The second end is
It has a second contact surface that contacts the MT ferrule, a second recess surrounded by the second contact surface, and a second bottom surface that is the bottom of the second recess.
The first bottom surface and the second bottom surface face a plurality of optical fiber holding holes included in the MT ferrule.
At least a pair of guide pins inserted into the mating connector and the MT ferrule can be inserted, and at least a pair of guide holes penetrating from the first contact surface to the second contact surface are further provided.
The resin has a transmittance of 80% or more and 100% or less with respect to light having a wavelength of 1210 nm or more and 1650 nm or less.
Optical connection parts. The first recess is surrounded on all sides by the first contact surface.
The optical connection component according to claim 1. The second recess is surrounded on three sides by the second contact surface.
The optical connection component according to claim 1 or 2. The depth from the first contact surface to the first bottom surface is 90 μm or more and 110 μm or less.
The optical connection component according to any one of claims 1 to 3. The depth from the second contact surface to the second bottom surface is 90 μm or more and 110 μm or less.
The optical connection component according to any one of claims 1 to 4. The first angle, which is the angle of the normal of the first bottom surface with respect to the connection direction, and the second angle, which is the angle of the normal of the second bottom surface with respect to the connection direction, are both 0 ° or more and less than 1 °. Yes,
The first bottom surface is AR coated.
The optical connection component according to any one of claims 1 to 5. The first angle, which is the angle of the normal of the first bottom surface with respect to the connection direction, and the second angle, which is the angle of the normal of the second bottom surface with respect to the connection direction, are both 1 ° or more and 8 ° or less. is there,
The optical connection component according to any one of claims 1 to 5. The guide hole has a taper that expands in diameter toward the second contact surface side.
The optical connection component according to any one of claims 1 to 7. The optical connection component according to any one of claims 1 to 8, a plurality of optical fibers, and an MT ferrule are provided.
A GRIN lens is fused and connected to the tip of each of the plurality of optical fibers.
The MT ferrule is
With the end face facing the second end of the optical connection component,
A plurality of optical fiber holding holes having an opening at the end face, extending in the connecting direction, and holding each of the plurality of optical fibers.
The end face is provided with at least a pair of guide holes into which the guide pins are inserted.
The tip surface of the GRIN lens is exposed from the opening of the optical fiber holding hole.
The second contact surface of the optical connection component is fixed to the end surface by an adhesive in a state where the guide hole of the MT ferrule and the guide hole of the optical connection component are aligned with each other.
Optical connector. Each of the plurality of optical fibers is fixed in a state where the tip surface of the GRIN lens is in contact with the second bottom surface.
The optical connector according to claim 9. The difference between the refractive index of the GRIN lens and the refractive index of the adhesive is 0.001 or less.
The second angle, which is the angle of the normal of the second bottom surface of the optical connection component with respect to the connection direction, is 1 ° or more and 8 ° or less.
The optical connector according to claim 9 or 10. The material of the optical connection component and the material of the MT ferrule are the same as each other.
The optical connection component and the MT ferrule are welded to each other.
The optical connector according to any one of claims 9 to 11. The first contact surface of the first optical connector according to any one of claims 9 to 12 and the first equivalent of the second optical connector according to any one of claims 9 to 12. The contact surfaces come into contact with each other,
The first optical connector and the second optical connector are positioned by inserting guide pins into the guide holes of the MT ferrule and the guide holes of the optical connection component.
Optical connection structure.

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