JP2005274839A - Optical connection structure and manufacturing method thereof, and end face processing method of optical transmission medium - Google Patents

Optical connection structure and manufacturing method thereof, and end face processing method of optical transmission medium Download PDF

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JP2005274839A
JP2005274839A JP2004086343A JP2004086343A JP2005274839A JP 2005274839 A JP2005274839 A JP 2005274839A JP 2004086343 A JP2004086343 A JP 2004086343A JP 2004086343 A JP2004086343 A JP 2004086343A JP 2005274839 A JP2005274839 A JP 2005274839A
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optical
transmission medium
optical transmission
adhesive
optical fiber
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JP2005274839A5 (en
JP4043448B2 (en
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Masayoshi Suzuki
正義 鈴木
Kyoichi Sasaki
恭一 佐々木
Tatsushi Kobayashi
辰志 小林
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Tomoegawa Co Ltd
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Tomoegawa Paper Co Ltd
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Priority to CN2011101805926A priority patent/CN102213801A/en
Priority to KR1020087015579A priority patent/KR20080067015A/en
Priority to EP11005822A priority patent/EP2392954A1/en
Priority to KR1020097005174A priority patent/KR20090033279A/en
Priority to US10/579,459 priority patent/US7422375B2/en
Priority to EP11005824A priority patent/EP2400326A1/en
Priority to KR1020067012149A priority patent/KR100820524B1/en
Priority to KR1020087002906A priority patent/KR100867261B1/en
Priority to EP11005823A priority patent/EP2418524A1/en
Priority to CN200810124982XA priority patent/CN101349788B/en
Priority to PCT/JP2004/017065 priority patent/WO2005050273A1/en
Priority to EP04818916.1A priority patent/EP1686402B1/en
Publication of JP2005274839A publication Critical patent/JP2005274839A/en
Publication of JP2005274839A5 publication Critical patent/JP2005274839A5/ja
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Priority to HK09105776.0A priority patent/HK1128332A1/en
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Abstract

<P>PROBLEM TO BE SOLVED: To provide an optical connection structure having a simple structure permitting a simple and close contact between an optical transmission medium and a connecting member, and to provide a manufacturing method therefor. <P>SOLUTION: The optical connection structure holds an adhesive connecting member consisting of a single material with a reflective index matching property between the end faces of optical transmission media with cores to be faced to each other or between an optical transmission medium with a core and an optical component, and when expressing the minimum value of the distance from the core center of the optical transmission medium to the peripheral part of the adhesive connecting member by D<SB>1</SB>, the maximum value by D<SB>2</SB>, the radius of the optical transmission medium by R, and the radius of the core of the optical transmission medium by r, the structure satisfies D<SB>1</SB>≥r, and D<SB>2</SB>≤1.5R. This optical connection structure is manufactured by shifting a sheet-like adhesive connection member 2 relatively to the optical fiber in the direction of the optical fiber 1 while pressing the end face of the optical fiber 1 against the sheet-like adhesive connection member 2 and cutting off a part of the sheet-like adhesive connection member in the state of being stuck to the end face, and subsequently joining the optical fiber to which an adhesive connecting member 21 is adhered on the end face, to another optical fiber or an optical component. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

本発明は、光伝送媒体同士、あるいは光伝送媒体と光学部品との光学接続構造とそれを用いた光学接続方法に関するものである。   The present invention relates to an optical connection structure between optical transmission media or between an optical transmission medium and an optical component, and an optical connection method using the same.

特許第2676705号公報Japanese Patent No. 2676705 特開平05−34532号公報JP 05-34532 A 特開昭55−153912号公報JP-A-55-153912 特開平05−157935号公報。Japanese Patent Laid-Open No. 05-157935.

光ファイバの接続方法としては、光ファイバ同士、あるいは光ファイバを挿入したフェルール同士を突き合わせることにより、物理的に接続する方法が一般的によく用いられている。その場合の例として、メカニカルスプライス、光コネクタ等が挙げられるが、一般に永久接続の場合はメカニカルスプライスが、また着脱が頻繁に行われる場合には光コネクタが有効であり、広く利用されている。両者ともに光ファイバ端面に、軸方向の押圧力をかけることによって物理的な接続をさせるが、光コネクタ接続の場合は、一般的には光ファイバが脆くて弱いために、光ファイバをフェルールに挿入して保護し、それにより光ファイバの端面の物理的接触を可能としている。   As a method for connecting optical fibers, a method of physically connecting optical fibers or ferrules into which optical fibers are inserted is generally used. Examples of such cases include mechanical splices and optical connectors. In general, mechanical splices are effective for permanent connection, and optical connectors are effective when they are frequently attached and detached. In both cases, physical connection is made by applying axial pressure to the end face of the optical fiber, but in the case of optical connector connection, the optical fiber is generally weak and weak, so the optical fiber is inserted into the ferrule. Protection, thereby allowing physical contact of the end face of the optical fiber.

この物理的な接続において、光ファイバの位置決め精度や端面形状は、接続特性に大きく影響する。例えば、端面の角度のずれや端面形状が荒れていたりすると、突き合わせた光ファイバ端部間に空気が入ることにより、接続端面でフレネル反射が大きくなる為、接続損失が大きくなる。   In this physical connection, the positioning accuracy and end face shape of the optical fiber greatly affect the connection characteristics. For example, when the angle of the end face is shifted or the end face shape is rough, air enters between the end portions of the optical fibers that are abutted to increase Fresnel reflection at the connecting end face, thereby increasing the connection loss.

これを改良する方法として、これまで様々な研究がなされてきた。その一つとして、例えば光ファイバの端面あるいは光ファイバの端面とフェルールを高度に研磨処理をする方法が挙げられる。しかし、研磨処理には多大な時間と経費が必要であり、汎用的に行われる接続方法としては問題があり、その改善が大きな課題となっていた。   Various researches have been made to improve this. As one of them, for example, there is a method of highly polishing an end face of an optical fiber or an end face of an optical fiber and a ferrule. However, the polishing process requires a great amount of time and money, and there is a problem as a general-purpose connection method, and its improvement has been a major issue.

さらに、研磨工程を必要とせずに、カットしたままの状態の光ファイバを接続する方法が検討されてきた。その一つとして、光ファイバの接続端面に光ファイバのコアと同等、あるいは近似した屈折率を有する液状の屈折率整合剤を介在させて接続する方法が提案されている。この方法は、屈折率整合剤を光ファイバ端面に塗布し、光ファイバを突き合わせるものであり、それによって、接続端面への空気の侵入を防ぎ、空気によって生じるフレネル反射を回避し、接続損失を低減する。しかしながら、この方法の場合、一般には屈折率整合剤として、シリコーン系やパラフィン系の液状或いはグリース状のものが使用されているために、非常に小さな面積である光ファイバ端面に一定量の屈折率整合剤を塗布することが困難である。屈折率整合剤が過剰に塗布されると、接続部周囲の汚染や、それによる埃などの付着が問題となる。さらに、屈折率整合剤は一般的に流れ易い性質を有しているために、接続部から流出し、光学的な安定性を得ることが困難となる。さらにまた、光ファイバを着脱可能にすると使い勝手が良くなるが、液状またはグリース状の屈折率整合剤を使用して着脱可能にすると、着脱毎に屈折率整合剤の拭き取りや再度一定量塗布する作業が必要になるために多大な時間がかかり、作業効率が悪いという問題があった。   Furthermore, a method for connecting an optical fiber in a cut state without requiring a polishing step has been studied. As one of the methods, there has been proposed a method in which a liquid refractive index matching agent having a refractive index equivalent to or close to that of the optical fiber core is interposed on the connection end face of the optical fiber. In this method, a refractive index matching agent is applied to the end face of the optical fiber to abut the optical fiber, thereby preventing air from entering the connecting end face, avoiding Fresnel reflection caused by air, and reducing connection loss. To reduce. However, in this method, since a silicone-based or paraffin-based liquid or grease-like material is generally used as the refractive index matching agent, a certain amount of refractive index is applied to the end face of the optical fiber having a very small area. It is difficult to apply a matching agent. When the refractive index matching agent is applied excessively, contamination around the connecting portion and adhesion of dust and the like thereby become a problem. Furthermore, since the refractive index matching agent generally has a property of easily flowing, it flows out of the connecting portion and it is difficult to obtain optical stability. Furthermore, if the optical fiber is made detachable, it becomes easier to use, but if it is made detachable using a liquid or grease-like refractive index matching agent, the work of wiping off the refractive index matching agent and applying a certain amount again each time it is detached. This requires a lot of time and is inefficient.

これに対し、固体の屈折率整合部材を用いる方法が検討されている。例えば、光ファイバの端面に透明な整合材フィルムを接着層、粘着材層を介さずに直接取りつけた構造のものが提案されている(特許文献1)。しかしながら、整合材フィルムが硬い材料となるため、光ファイバの押圧力の調節が難しく、過剰な押圧力がかかると光ファイバに折れや欠けが起こる可能性があった。また、光ファイバの接続時の固定状態が、整合材フィルムの機械的あるいは熱的な要因による膨張、収縮による影響を受けやすく、常に安定した接続形態を保つことは困難であった。   On the other hand, a method using a solid refractive index matching member has been studied. For example, a structure in which a transparent matching material film is directly attached to an end face of an optical fiber without using an adhesive layer or an adhesive material layer has been proposed (Patent Document 1). However, since the alignment material film is a hard material, it is difficult to adjust the pressing force of the optical fiber, and if an excessive pressing force is applied, the optical fiber may be broken or chipped. Further, the fixed state at the time of connecting the optical fiber is easily affected by expansion and contraction due to mechanical or thermal factors of the alignment material film, and it has been difficult to always maintain a stable connection form.

また、光ファイバのコアと近似した屈折率を持つ透明なゴム弾性体とこれを保持する手段を備えた接続部材を用いて光ファイバを接続する構造のものが提案されている(特許文献2)。しかしながら、ゴム弾性体は光ファイバの径より大きくなるため、ゴム弾性体を保持するための構造が必要になり、ゴム弾性体保持スペースが必要となる。   Further, a structure in which an optical fiber is connected using a transparent rubber elastic body having a refractive index approximate to that of the core of the optical fiber and a connecting member having means for holding the same is proposed (Patent Document 2). . However, since the rubber elastic body is larger than the diameter of the optical fiber, a structure for holding the rubber elastic body is required, and a rubber elastic body holding space is required.

また、光ファイバの接続部の片面に粘着材が塗布された誘電体膜を貼り付ける方法が提案されている(特許文献3)。この方法によれば、誘電体膜の片面が粘着性を有するために片側の光ファイバとの密着性及び保持力を上げることができるが、他方の面の密着力が十分でなく、また上記と同様に光ファイバが破損する恐れがあった。また粘着材層と誘電体膜との2層構造であるために、各層の界面の間でも反射が起きるため、接続損失が起きてしまうという問題があった。さらに粘着材層が薄膜であるために、粘着材層表面の強度は弱く、突き合わせた光ファイバの端面や、そのバリによって傷が付き易いという問題があった。   In addition, a method has been proposed in which a dielectric film coated with an adhesive material is attached to one side of a connection portion of an optical fiber (Patent Document 3). According to this method, since one surface of the dielectric film has adhesiveness, the adhesion and holding power with the optical fiber on one side can be increased, but the adhesion on the other surface is not sufficient, and Similarly, the optical fiber may be broken. Further, since the adhesive material layer and the dielectric film have a two-layer structure, there is a problem in that reflection occurs between the interfaces of the respective layers, resulting in connection loss. Furthermore, since the adhesive material layer is a thin film, the strength of the adhesive material layer surface is weak, and there is a problem that the end face of the optical fiber that has been abutted and its burrs are easily damaged.

さらにまた、屈折率整合性をもつ部材(酸化膜)を光伝送媒体に密着するように設ける方法として、光ファイバのコア端面よりレーザー光を入射して光出力端面にレーザー光による熱酸化膜を形成する方法が提案されている(特許文献4)。この場合、レーザー光の強度調節や酸化膜の原材料の供給量、酸化膜原料液体の温度により酸化膜状態が変化するため、所定の状態に調節することが困難となり、生産効率が悪かった。また、液状の原料をガス化して反応室に送り込む装置が必要となり、設備にかかる費用からコスト高を引き起こしていた。   Furthermore, as a method of providing a member (oxide film) having refractive index matching so as to be in close contact with the optical transmission medium, laser light is incident from the core end face of the optical fiber, and a thermal oxide film by laser light is applied to the light output end face. A forming method has been proposed (Patent Document 4). In this case, since the state of the oxide film changes depending on the intensity adjustment of the laser beam, the supply amount of the raw material of the oxide film, and the temperature of the oxide film raw material liquid, it becomes difficult to adjust to the predetermined state, and the production efficiency is poor. In addition, an apparatus for gasifying the liquid raw material and sending it to the reaction chamber is required, which causes high costs due to the cost of the equipment.

以上のように屈折率整合剤その他の接続部材を光ファイバ同士の端部に挟んで光学接続する構造においては、上記の種々の問題が発生していた。本発明は、これらの諸問題を解決することを目的としてなされたものである。すなわち、本発明の目的は、従来の提案よりも単純な構造で、光伝送媒体と接続部材とを簡単に密着させることができる光学接続構造の作製方法を提供することにある。本発明の他の目的は、単純な構造で容易に作製可能な光学接続構造を提供することにある。   As described above, in the structure in which the refractive index matching agent and other connecting members are optically connected with the end portions of the optical fibers being sandwiched, the above-described various problems have occurred. The present invention has been made for the purpose of solving these problems. That is, an object of the present invention is to provide a method of manufacturing an optical connection structure that can easily adhere an optical transmission medium and a connection member with a simpler structure than conventional proposals. Another object of the present invention is to provide an optical connection structure that can be easily manufactured with a simple structure.

本発明者等は、検討の結果、粘着性接続部材を用いることにより、光ファイバ等の光伝送媒体同士あるいは光伝送媒体と光学部品との光学接続を非常に簡単に行うことができることを見出し、本発明を完成するに至った。   As a result of the study, the present inventors have found that optical connection between optical transmission media such as optical fibers or optical transmission media and optical components can be performed very easily by using an adhesive connection member, The present invention has been completed.

すなわち、本発明の光学接続構造は、互いに対向するコアを有する光伝送媒体の端面またはコアを有する光伝送媒体と光学部品との間に、屈折率整合性を有する単一層からなる粘着性接続部材が挟置された光学接続構造において、光伝送媒体のコアの中心から、粘着性接続部材の周辺部までの距離の最小値をD、最大値をD、該光伝送媒体の半径をR、該光伝送媒体のコア径をrとしたとき、D≧r、かつ、D≦1.5Rを満足することを特徴とする。この場合、互いに対向する光伝送媒体の端面または光伝送媒体と光学部品との間に挟置された粘着性接続部材は、前記光伝送媒体および前記光学部品の端面形状に対応して変形してもよい。粘着性接続部材が、光伝送媒体および光学部品の端面形状に対応して変形するとは、後述の図2に示すように、光ファイバによる突き合わせにより、粘着性接続部材が内部に凹んで変形している状態を意味する。あるいは、後述の図6に示すように、端面が球面の場合は、この球面形状に密着して変形することを意味する。このような変形により、接続部に空気の層ができることを防ぎ、それによる光損失の増加を防止できる。 That is, the optical connection structure of the present invention is an adhesive connection member comprising a single layer having refractive index matching between an optical transmission medium having an end face of an optical transmission medium having cores facing each other or an optical component. In the optical connection structure in which is inserted, the minimum value of the distance from the center of the core of the optical transmission medium to the peripheral part of the adhesive connection member is D 1 , the maximum value is D 2 , and the radius of the optical transmission medium is R When the core diameter of the optical transmission medium is r, D 1 ≧ r and D 2 ≦ 1.5R are satisfied. In this case, the adhesive connection member sandwiched between the end surfaces of the optical transmission mediums facing each other or between the optical transmission medium and the optical component is deformed corresponding to the end surface shapes of the optical transmission medium and the optical component. Also good. The adhesive connecting member is deformed corresponding to the end face shape of the optical transmission medium and the optical component. As shown in FIG. 2 described later, the adhesive connecting member is dented and deformed by an optical fiber butt. Means the state. Alternatively, as shown in FIG. 6 to be described later, when the end surface is a spherical surface, it means that the end surface is in close contact with the spherical shape and deformed. By such a deformation, it is possible to prevent an air layer from being formed in the connection portion, thereby preventing an increase in light loss.

また、本発明の光学接続構造の作製方法は、上記の光学接続構造を作製するためのものであって、光伝送媒体の端面をシート状粘着性接続部材に押し当てて密着させたまま、シート状粘着性接続部材を光伝送媒体に対して該光伝送媒体の軸方向に相対的に移動させることにより、シート状粘着性接続部材の一部を端面に付着した状態で切り離す工程、および端面に粘着性接続部材が付着した光伝送媒体を、他の光伝送媒体又は光学部品と接合する工程を有することを特徴とする。この作製方法は、光伝送媒体が多心の光ファイバである場合、特に有効である。   The method for producing an optical connection structure of the present invention is for producing the above-mentioned optical connection structure, wherein the end face of the optical transmission medium is pressed against the sheet-like adhesive connection member and kept in close contact with the sheet. Detaching part of the sheet-like adhesive connecting member attached to the end surface by moving the adhesive connecting member relative to the optical transmission medium in the axial direction of the optical transmission medium; and It has the process of joining the optical transmission medium with which the adhesive connection member adhered to another optical transmission medium or an optical component. This manufacturing method is particularly effective when the optical transmission medium is a multi-core optical fiber.

上記の場合、光学接続前のシート状粘着性接続部材は、支持部材に支持されているのが好ましい。また、支持部材は、光伝送媒体を挿入するための貫通孔を有し、支持部材の一端にシート状粘着性接続部材が該貫通孔を塞ぐように貼着されているものが好ましい。さらにまた、支持部材における貫通孔は、少なくとも一方に整列溝が設けられた2つの部材を重ねることにより形成されたものであってもよい。この場合には、その貫通孔を塞ぐようにシート状粘着性接続部材を貼着した状態で、光伝送媒体を貫通孔に挿入し、光伝送媒体をシート状粘着性接続部材に押し当てて密着させたまま、シート状粘着性接続部材を光伝送媒体に対して光伝送媒体の軸方向に相対的に移動させることにより、シート状粘着性接続部材の一部を端面に貼着した状態で切り離し、次いで支持部材を2つの部材に分離して光伝送媒体を取り出すことができる。次いで、それを他の光伝送媒体又は光学部品と接合すればよい。   In the above case, it is preferable that the sheet-like adhesive connecting member before optical connection is supported by the support member. The support member preferably has a through-hole for inserting the optical transmission medium, and a sheet-like adhesive connecting member is attached to one end of the support member so as to close the through-hole. Furthermore, the through hole in the support member may be formed by overlapping two members provided with alignment grooves on at least one side. In this case, with the sheet-like adhesive connecting member stuck so as to close the through-hole, the optical transmission medium is inserted into the through-hole, and the optical transmission medium is pressed against the sheet-like adhesive connecting member to adhere In this state, the sheet-like adhesive connecting member is moved relative to the optical transmission medium in the axial direction of the optical transmission medium, so that a part of the sheet-like adhesive connecting member is detached from the end face. Then, the optical transmission medium can be taken out by separating the support member into two members. Then, it may be joined to another optical transmission medium or optical component.

また、本発明の光伝送媒体端面処理方法は、上記の光学接続構造を作製するためのものであって、光伝送媒体の端面をシート状粘着性接続部材に押し当てて密着させたまま、シート状粘着性接続部材を該光伝送媒体に対して該光伝送媒体の軸方向に相対的に移動させることにより、シート状粘着性接続部材の一部を端面に貼着した状態で切り離すことを特徴とする。   The optical transmission medium end face processing method of the present invention is for producing the optical connection structure described above, wherein the end face of the optical transmission medium is pressed against the sheet-like adhesive connection member and kept in close contact with the sheet. The adhesive adhesive connecting member is moved relative to the optical transmission medium in the axial direction of the optical transmission medium, so that a part of the adhesive adhesive connecting sheet is cut off in a state of being attached to the end face. And

本発明により作製された光学接続構造においては、光学接続部材が単一の層構造であるため、光の反射が起きることがない。また、粘着性接続部材が、光伝送媒体端面のみに密着しているので、周囲を汚染することなく、周囲から汚染を受けることもない。さらに粘着性を有し、光伝送媒体の端面及びその近傍に接着しているため、粘着性接続部材を保持する特別の支持手段や構造物を新たに設ける必要がなく、省スペース化が図れる。また、本発明に用いる粘着性接続部材は粘着性であるため、柔軟に内部変形させることにより、光伝送媒体端部間に空気が入りにくくなり、研磨工程を必要とせずに低損失で接続が可能であり、かつ粘着材の復元力により複数回の光学接続を行うことができる。   In the optical connection structure manufactured according to the present invention, since the optical connection member has a single layer structure, no light is reflected. Further, since the adhesive connecting member is in close contact with only the end face of the optical transmission medium, the surroundings are not contaminated and the surroundings are not contaminated. Furthermore, since it has adhesiveness and adheres to the end face of the optical transmission medium and its vicinity, it is not necessary to newly provide a special support means or structure for holding the adhesive connecting member, and space saving can be achieved. In addition, since the adhesive connection member used in the present invention is adhesive, it is difficult for air to enter between the end portions of the optical transmission medium by flexibly deforming, and connection can be made with low loss without requiring a polishing process. It is possible and the optical connection can be performed a plurality of times by the restoring force of the adhesive material.

本発明の光学接続構造の作製方法によると、光ファイバの相対的な移動だけで容易に光ファイバ端部に粘着性接続部材を密着させることができ、複雑な装置や高価な設備を用いることなく、また製造時における環境条件を厳密に設定することなく、互いに対向する該光伝送媒体の端面もしくは光伝送媒体と光学部品との間に、屈折率整合性を有する単一の層からなる粘着性接続部材が挟置された光学接続構造を簡単に作製することができる。また、その粘着性接続部材が、光伝送媒体の半径の1.5倍以下で光伝送媒体のコア半径と同等以上のサイズを有するものが容易に作製でき、周囲を汚染することなく、周囲から汚染を受けることもない。また、粘着性接続部材の濡れ性と接着力により、他の光伝送媒体や光学部品と容易に密着し、この密着状態を保持することができる。さらに、多数本の光ファイバに対しても、一括で均一に光ファイバの端面に粘着性接続部材を密着させることができるという利点がある。   According to the method for producing an optical connection structure of the present invention, an adhesive connection member can be easily brought into close contact with an end portion of an optical fiber only by relative movement of the optical fiber, without using a complicated device or expensive equipment. Further, without strictly setting environmental conditions at the time of manufacture, the adhesiveness composed of a single layer having refractive index matching between the end faces of the optical transmission medium facing each other or between the optical transmission medium and the optical component An optical connection structure in which the connection member is sandwiched can be easily produced. In addition, the adhesive connecting member can be easily manufactured having a size equal to or larger than the core radius of the optical transmission medium at 1.5 times or less the radius of the optical transmission medium, and without contaminating the surroundings. There is no pollution. Further, due to the wettability and adhesive force of the adhesive connecting member, it can be easily brought into close contact with other optical transmission media and optical components, and this close contact state can be maintained. Furthermore, there is an advantage that the adhesive connecting member can be brought into close contact with the end face of the optical fiber evenly for a large number of optical fibers.

まず、本発明の光学接続構造について説明する。図1は、本発明の光学接続構造の最も基本的な例を示す側面図であり、光伝送媒体として上記のように端面処理した光ファイバを用いて、他の光ファイバと接合する場合を示している。すなわち、2本の光ファイバ1aと1bが粘着性接続部材21を介して付き合わされており、それによって光ファイバが光学的に接続された光学接続構造が形成されている。なお、2つの光ファイバは先端より数10mmを被覆除去し、先端がカットされている。   First, the optical connection structure of the present invention will be described. FIG. 1 is a side view showing the most basic example of the optical connection structure of the present invention, and shows a case where an optical fiber whose end face is processed as described above is used as an optical transmission medium and is joined to another optical fiber. ing. That is, the two optical fibers 1a and 1b are attached together via the adhesive connection member 21, thereby forming an optical connection structure in which the optical fibers are optically connected. The two optical fibers are covered with several tens of millimeters from the tip, and the tip is cut.

図2は、後記する図4又は図5に示すようにして端面処理された光ファイバ1aを他の光ファイバ1bと突き合わせ、押圧することによって粘着性接続部材21が変形した状態の光学接続構造を示している。この場合、押圧による粘着性接続部材の変形は、光ファイバのコアの中心から粘着性接続部材21の周辺部までの距離の最小値Dがコアの半径r以上であって、最大値Dが、光ファイバの半径Rの1.5倍以内になるようにすればよい。 FIG. 2 shows an optical connection structure in a state where the adhesive connection member 21 is deformed by abutting and pressing the optical fiber 1a whose end face has been processed as shown in FIG. Show. In this case, the deformation of the adhesive connecting member due to the pressing is such that the minimum value D 1 of the distance from the center of the core of the optical fiber to the peripheral part of the adhesive connecting member 21 is equal to or larger than the radius r of the core, and the maximum value D 2. However, it should be within 1.5 times the radius R of the optical fiber.

図3は、本発明の光学接続した光ファイバの端面における粘着性接続部材が貼着した状態を説明する図であって、図3(a)は光ファイバ端部の側面図、図3(b)は平面図である。図において、Dは、コア11とクラッド12よりなる光ファイバ1のコアの中心Cから粘着性接続部材21の周辺部までの距離、Rは光ファイバの半径、rはコアの半径であって、本発明においては、光ファイバ1の中心Cから粘着性接続部材21の周辺部までの距離Dの最小値Dはコアの半径r以上であって、かつ、最大値D光ファイバの半径Rの1.5倍以下である。 FIG. 3 is a diagram illustrating a state in which an adhesive connecting member is attached to the end face of the optically connected optical fiber according to the present invention. FIG. 3A is a side view of the end of the optical fiber, and FIG. ) Is a plan view. In the figure, D is the distance from the center C of the optical fiber 1 consisting of the core 11 and the clad 12 to the periphery of the adhesive connecting member 21, R is the radius of the optical fiber, and r is the radius of the core, in the present invention, the minimum value D 1 of distance D to the peripheral portion of the adhesive connecting member 21 from the center C of the optical fiber 1 is a is a radius r or more cores, and the maximum value D 2 is the optical fiber The radius R is 1.5 times or less.

本発明においては、シート状粘着性接続部材の占有範囲を、最小でもコア11全域を覆うことができ、最大でも光ファイバ端面から1.5倍を超えて過剰にはみ出さない程度にすることによって、粘着性を有する接続部材が光伝送媒体の端面または端面近傍にのみ存在するために、汚染が防止でき、また、埃の付着が起きにくくなり、取り扱い性が向上する。また、接続部材を保持する特別の手段または構造物を新たに設ける必要が無く、極めて単純な接続構造となり、省スペース化を図ることができる。Dが光ファイバのコアの半径rより小さい場合は、光が伝送するコア部分で、粘着性接続部材が接触しない部分が存在することになり、その部分で光損失が起きる。また、Dが1.5Rよりも大きい場合は、粘着性接続部材の光ファイバ端面を除いた部分の占めている割合が大きくなり、周囲からの塵や埃の付着が起きやすくなることや、粘着性接続部材が他の部品と接触する恐れが生じるため、良好な接続性能が維持できなくなる場合がある。なお、光ファイバに押圧をかけるときに、粘着性接続部材に均一に押圧がかかるようにするため、また光ファイバ端面より粘着性接続部材がはみ出さないようにするために、おおよそD=Dであることが好ましく、おおよそD=D=rであることがより好ましい。 In the present invention, the occupation range of the sheet-like adhesive connecting member can cover the entire area of the core 11 at a minimum, and at a maximum does not exceed 1.5 times from the end face of the optical fiber. In addition, since the adhesive connecting member exists only on the end face of the optical transmission medium or in the vicinity of the end face, the contamination can be prevented, and the adhesion of dust is less likely to occur, thereby improving the handleability. In addition, it is not necessary to newly provide a special means or structure for holding the connection member, so that the connection structure is extremely simple and space can be saved. If D 1 is the radius r is smaller than the core of the optical fiber, the core portion through which light is transmitted, will be the portion adhesive connecting member is not in contact exists, light loss occurs at that portion. Further, when D 2 is greater than 1.5R, the proportion occupying the portion excluding the optical fiber end face of the adhesive connecting member is increased, it tends to occur the adhesion of dust and dirt from the surroundings and, Since the adhesive connecting member may come into contact with other components, good connection performance may not be maintained. Incidentally, when making the pressing the optical fiber, for to take more evenly pressed against the adhesive connecting member, also in order to prevent overflow adhesive connecting member from the optical fiber end surface, roughly D 1 = D 2 is preferable, and it is more preferable that D 1 = D 2 = r.

本発明で用いられる光伝送媒体としては、上記で示した光ファイバのほかに光導波路などがあげられるが、その種類は特に限定されず、光を伝送するものであれば如何なるものでもよい。また、光ファイバも何等限定されるものではなく、その用途に応じて適宜選択すればよい。例えば、石英、プラスチック等の材料からなる光ファイバを用いることができる。また、光導波路としては、ポリイミド光導波路、PMMA光導波路、エポキシ光導波路などが利用される。さらに、使用する2つの光伝送媒体の種類が異なっていてもシート状粘着性接続部材の濡れ性により密着することができるので、安定して接続することが可能である。また、異なる外径の光伝送媒体であっても、コア径が同じであれば、本発明を適用することができる。なお、光ファイバの本数、光導波路の枚数も何等限定されるものではない。   Examples of the optical transmission medium used in the present invention include an optical waveguide in addition to the above-described optical fiber, but the type is not particularly limited, and any optical transmission medium may be used as long as it transmits light. Also, the optical fiber is not limited in any way, and may be appropriately selected according to the application. For example, an optical fiber made of a material such as quartz or plastic can be used. As the optical waveguide, a polyimide optical waveguide, a PMMA optical waveguide, an epoxy optical waveguide, or the like is used. Furthermore, even if the two types of optical transmission media to be used are different, the sheet-like adhesive connecting member can be brought into close contact with each other, so that stable connection can be achieved. Further, the present invention can be applied to optical transmission media having different outer diameters as long as the core diameter is the same. The number of optical fibers and the number of optical waveguides are not limited at all.

本発明において光伝送媒体と光学接続される光学部品としては、光学レンズ、フィルタなどがあげられ、その種類に関しては特に限定されるものではない。光学レンズは、例えば両凸、両凹、凹凸、平凸、非球面等の各種形状や、コリメートレンズ、ロッドレンズなどがあげられ、フィルタとしては、例えば一般光通信用フィルタのほか、多層膜フィルタやポリイミドフィルタ等があげられる。   Examples of the optical component optically connected to the optical transmission medium in the present invention include an optical lens and a filter, and the type thereof is not particularly limited. Examples of the optical lens include various shapes such as biconvex, biconcave, concavo-convex, plano-convex, and aspherical surfaces, collimating lenses, rod lenses, and the like. Examples of filters include multi-layer filters in addition to general optical communication filters. And a polyimide filter.

本発明に用いる粘着性接続部材は、光伝送媒体または光学部品に接触したときに、適度なタック性を伴って、光伝送媒体の端部に密着する部材であればよい。好ましくは、光伝送媒体との間で脱着性を有し、凝集破壊せず、取り外した光伝送媒体に粘着性物質が付着しない材料が使用される。具体的には、高分子材料、例えばアクリル系、エポキシ系、ビニル系、シリコーン系、ゴム系、ウレタン系、メタクリル系、ナイロン系、ビスフェノール系、ジオール系、ポリイミド系、フッ素化エポキシ系、フッ素化アクリル系等の各種粘着材を使用することができ、本発明においては、これをフィルム化したものをシート状粘着性接続部材として使用する。その中でも、耐環境性、接着性の面からは、シリコーン系、アクリル系が好ましく使用される。また、架橋剤、添加剤、軟化剤、粘着調整剤等の添加により適宜に接着力、濡れ性を調節してもよく、また耐水性や耐湿性、耐熱性を付加してもよい。また後述の光伝送媒体の端面へのシート状粘着性接続部材の貼着後に、これらの性質の調整を行っても構わない。なお、材料によっては多孔構造となることもあるが、接続時に粘着性接続部材に適当な押圧力を加えることにより、粘着性接続部材を圧縮すれば、空気をなくすこともでき、光損失に影響を与えない。   The adhesive connecting member used in the present invention may be a member that adheres to the end of the optical transmission medium with appropriate tackiness when it comes into contact with the optical transmission medium or the optical component. Preferably, a material that has detachability with respect to the optical transmission medium, does not cause cohesive failure, and does not adhere to the removed optical transmission medium is used. Specifically, polymer materials such as acrylic, epoxy, vinyl, silicone, rubber, urethane, methacryl, nylon, bisphenol, diol, polyimide, fluorinated epoxy, fluorinated Various adhesive materials such as acrylic can be used. In the present invention, a film-like adhesive connecting member is used as a sheet-like adhesive connecting member. Among these, silicone and acrylic are preferably used from the viewpoint of environmental resistance and adhesiveness. Further, the adhesive force and wettability may be appropriately adjusted by adding a crosslinking agent, an additive, a softening agent, a tackifier, and the like, and water resistance, moisture resistance, and heat resistance may be added. Further, these properties may be adjusted after the sheet-like adhesive connecting member is attached to the end face of the optical transmission medium described later. Depending on the material, it may have a porous structure, but by compressing the adhesive connection member by applying an appropriate pressing force to the adhesive connection member at the time of connection, air can be eliminated, affecting light loss. Not give.

本発明に用いる粘着性接続部材は、光伝送媒体間、及び光伝送媒体と光学部品間で屈折率整合性を有していることが必要である。この場合の屈折率整合性とは、粘着性接続部材の屈折率と光伝送媒体及び光学部品との屈折率との近似の程度をいう。本発明に用いるシート状粘着性接続部材の屈折率は、光伝送媒体及び光学部品の屈折率に近いものであれば特に限定されないが、フレネル反射の回避による伝送損失の面からそれらの屈折率の差が、±0.1以内であることが好ましく、±0.05以内であるものが特に好ましく使用される。なお、光伝送媒体と光学部品の屈折率の差が大きい場合には、光伝送媒体と光学部品の屈折率の平均値とシート状粘着性接続部材の屈折率が上記の範囲内であることが好ましい。   The adhesive connecting member used in the present invention needs to have refractive index matching between the optical transmission medium and between the optical transmission medium and the optical component. In this case, the refractive index matching means an approximate degree of the refractive index of the adhesive connecting member and the refractive indexes of the optical transmission medium and the optical component. The refractive index of the sheet-like adhesive connecting member used in the present invention is not particularly limited as long as it is close to the refractive index of the optical transmission medium and the optical component, but from the aspect of transmission loss due to avoidance of Fresnel reflection, The difference is preferably within ± 0.1, particularly preferably within ± 0.05. When the difference in refractive index between the optical transmission medium and the optical component is large, the average refractive index between the optical transmission medium and the optical component and the refractive index of the sheet-like adhesive connecting member may be within the above range. preferable.

また、本発明に用いる粘着性接続部材は、単一の層から構成される。本発明でいう単一の層から構成されるとは、2層、3層構造のように異種材料が接する界面がシート状粘着性接続部材内には存在しないという意味であり、光の波長オーダで均一に混ざり合った系を排除するものではない。本発明に用いる粘着性接続部材は、上記のように粘着性を持つ単一の層からなる極めて単純な構造である。この単一の層構造の部材を用いることにより、光反射が起きることなく接続することができるので、低損失な接続を行うことが可能である。また、光ファイバの端面にバリがあっても、粘着性接続部材に傷が付きにくく、さらに、表面が濡れ性を有することにより、突き合わされる2つの光ファイバの端部に容易に密着させることができ、かつその接着力により、光ファイバとの密着性を保持することができる。同時に屈折率整合性を有しているため、良好な光学接続を行うことが可能である。その上、表面に濡れ性及び接着力があるために、光ファイバの付き合せ時に過剰な押圧を加える必要がなく、光ファイバの折れや欠けが起こる恐れはない。更に粘着材の特性として再剥離性を有するために複数回の着脱を行っても繰り返し使用することが可能である。   Moreover, the adhesive connection member used for this invention is comprised from a single layer. The term “consisting of a single layer” as used in the present invention means that there is no interface in the sheet-like adhesive connecting member that is in contact with different materials, such as a two-layer or three-layer structure. This does not exclude systems that are uniformly mixed. The adhesive connecting member used in the present invention has a very simple structure composed of a single layer having adhesiveness as described above. By using the member having the single layer structure, the connection can be made without light reflection, so that a low-loss connection can be made. In addition, even if there are burrs on the end face of the optical fiber, the adhesive connecting member is not easily scratched, and the surface has wettability so that it can be easily brought into close contact with the ends of the two optical fibers to be abutted. The adhesiveness with the optical fiber can be maintained by the adhesive force. At the same time, since it has refractive index matching, it is possible to perform a good optical connection. In addition, since the surface has wettability and adhesive force, it is not necessary to apply excessive pressure when attaching the optical fibers, and there is no fear that the optical fibers will be broken or chipped. Furthermore, since it has removability as a characteristic of the adhesive material, it can be used repeatedly even if it is attached and detached a plurality of times.

また、本発明において、2つの光ファイバの光学接続の場合、粘着性接続部材は突き合わされた光ファイバの端部にのみ設けられるため、光ファイバの径とほぼ同じサイズとなり、粘着性接続部材の占有範囲は極めて小さくすることが可能であり、非常にシンプルな構造に設計できる。また、周囲のゴミや塵などと接触することも無いため、汚染されることもなく、流れ出ることもないため、周囲を汚染することもない。   Further, in the present invention, in the case of optical connection of two optical fibers, the adhesive connecting member is provided only at the end of the optical fiber that is abutted, so that the diameter of the adhesive connecting member is approximately the same as the diameter of the optical fiber. The occupation range can be made extremely small and can be designed in a very simple structure. Moreover, since it does not come into contact with surrounding dust or dust, it is not contaminated and does not flow out, so that it does not pollute the surroundings.

次に、本発明の光学接続構造の作製方法を、光伝送媒体として端部を被覆除去し、カットした光ファイバを用いる場合について説明すると、まず、光ファイバの端部が上記のシート状粘着性接続部材に密着するまで、光ファイバをシート状粘着性接続部材に対して相対的に移動させる。次に光ファイバを、さらに軸方向に移動させることにより、シート状粘着性接続部材の一部が光ファイバの端面に貼着した状態で切り離され、光ファイバ端面に粘着性接続部材が貼着して、光ファイバの端面処理が行なわれる。以上のように、本発明においては、光ファイバの移動だけで容易に光ファイバ端部に粘着性接続部材を貼着させることができ、複雑な装置や高額な設備を用いる必要がない。続いて、この端面処理された光ファイバを、他の光ファイバその他の光学部品と突き合わせて接合し、本発明の光学接続構造が作製される。   Next, the method for producing the optical connection structure of the present invention will be described in the case of using an optical fiber whose end is covered and cut as an optical transmission medium. First, the end of the optical fiber has the above-mentioned sheet-like adhesive property. The optical fiber is moved relative to the sheet-like adhesive connecting member until it is in close contact with the connecting member. Next, by further moving the optical fiber in the axial direction, a part of the sheet-like adhesive connection member is cut off in a state of being attached to the end face of the optical fiber, and the adhesive connection member is attached to the end face of the optical fiber. Thus, the end face processing of the optical fiber is performed. As described above, in the present invention, the adhesive connecting member can be easily attached to the end portion of the optical fiber only by moving the optical fiber, and it is not necessary to use a complicated apparatus or expensive equipment. Subsequently, the optical fiber subjected to the end face treatment is abutted with and joined to other optical fibers and other optical components, and the optical connection structure of the present invention is manufactured.

なお、本明細書において、「シート状粘着性接続部材を光伝送媒体に対して光伝送媒体の軸方向に相対的に移動させる」とは、粘着性接続部材および光ファイバのいずれを移動してもよいことを意味する。また、その移動速度や移動距離は適宜選択して用いればよい。   In this specification, “the sheet-like adhesive connecting member is moved relative to the optical transmission medium in the axial direction of the optical transmission medium” means that either the adhesive connecting member or the optical fiber is moved. Means good. Further, the moving speed and the moving distance may be appropriately selected and used.

本発明において用いるシート状粘着性接続部材は、2層或いは3層構成のものであってもよく、光ファイバ端面に設けられた粘着性接続部材が単層であれば構わない。例えば薄膜の保護層を粘着層に貼り付けたものをシート状粘着性接続部材とし、本発明の光伝送媒体の端面に粘着性接続部材を設け、使用に際して保護層を剥がして用いてもよい。   The sheet-like adhesive connecting member used in the present invention may have a two-layer or three-layer structure, and the adhesive connecting member provided on the end face of the optical fiber may be a single layer. For example, a thin film protective layer attached to an adhesive layer may be used as a sheet-like adhesive connecting member, and an adhesive connecting member may be provided on the end face of the optical transmission medium of the present invention, and the protective layer may be peeled off before use.

本発明において、シート状粘着性接続部材のサイズや厚みは仕様により適宜選択して用いればよい。また、破損やしわがないように設置できればよい。さらにシート状粘着性接続部材の光伝送媒体に対する載置の角度や位置の設定は、使用する光伝送媒体によって適宜選択してよく、光伝送媒体の端面が斜めにカットされていた場合はその角度に合わせて載置すればよい。   In the present invention, the size and thickness of the sheet-like adhesive connecting member may be appropriately selected and used according to specifications. Moreover, what is necessary is just to be able to install so that there may be no damage and wrinkles. Further, the setting of the mounting angle and position of the sheet-like adhesive connecting member with respect to the optical transmission medium may be appropriately selected depending on the optical transmission medium to be used, and if the end face of the optical transmission medium is cut obliquely, the angle It may be placed according to.

光伝送媒体の端面同士または光伝送媒体と光学部品が突き合わされる前にシート状粘着性接合部材によって形成される粘着性接合部材の初期の厚みは、シート状粘着性接合部材の厚みに依存するが、シート状粘着性接合部材の厚みtは、1μm≦t≦150μmの範囲であることが好ましい。粘着性接続部材の厚みが1μmより薄くなると取り扱い性が非常に困難になり、また柔軟性が維持できなくなるために光伝送媒体の突き当てにより光伝送媒体あるいは光学部品の破損を引き起こす可能性が高くなってしまう。逆に150μm以上であると、光伝送媒体を突き当てることによって粘着性接続部材を変形させた場合であっても光伝送媒体端面同士または光伝送媒体と光学部品との間隔が開きすぎてしまうために光損失が大きくなってしまう。より好ましくは2.5μm≦t≦100μm、更に好ましくは、5μm≦t≦50μmである。   The initial thickness of the adhesive bonding member formed by the sheet-like adhesive bonding member before the end faces of the optical transmission medium or the optical transmission medium and the optical component are abutted depends on the thickness of the sheet-like adhesive bonding member. However, the thickness t of the sheet-like adhesive bonding member is preferably in the range of 1 μm ≦ t ≦ 150 μm. When the thickness of the adhesive connecting member is less than 1 μm, the handling becomes very difficult, and the flexibility cannot be maintained, so that the optical transmission medium or optical component is likely to be damaged by the abutment of the optical transmission medium. turn into. On the other hand, if the thickness is 150 μm or more, even when the adhesive connection member is deformed by abutting the optical transmission medium, the distance between the optical transmission medium end faces or between the optical transmission medium and the optical component is too wide. The light loss will increase. More preferably, 2.5 μm ≦ t ≦ 100 μm, and still more preferably 5 μm ≦ t ≦ 50 μm.

また、光ファイバ端面同士または光伝送媒体と光学部品が突き合わされ、挟持された場合の粘着性接続部材の厚みは、突き合わせ時の押圧力に依存するが、50μm以下であるのが好ましく、より好ましくは20μm以下である。突き合わされた後の厚みが50μmより大きいと、突き合わされた光ファイバ間隔が大きすぎるために光損失が増大し、光伝送用の接続構造として適さない場合がある。このことは、光ファイバ以外の光伝送媒体を用いた場合でも、また、光伝送媒体と光学部品との間でも同様である。   In addition, the thickness of the adhesive connecting member when the optical fiber end faces or the optical transmission medium and the optical component are abutted and sandwiched depends on the pressing force at the time of abutting, but is preferably 50 μm or less. Is 20 μm or less. If the thickness after being butted is larger than 50 μm, the gap between the optic fibers butted is too large, resulting in an increase in optical loss, which may not be suitable as a connection structure for optical transmission. This is the same even when an optical transmission medium other than an optical fiber is used, or between an optical transmission medium and an optical component.

本発明によれば、粘着性接続部材は内部変形するので、その膜厚がある程度厚い場合であっても2本の光ファイバ間の端面を近接させることができる。このため、粘着性接続部材の初期の膜厚を厚くすることができ、シート状粘着性接続部材の取り扱いが非常に簡便となる。また、突き合わされる光ファイバの端面角度に傾斜があったり、端面形状が変形していても、粘着性接続部材が光ファイバの端面に密着しながら内部に変形するため光ファイバ端部間に空気が入りにくくなり、研磨技術を用いることなく低損失な光学接続を実現することができる。また、粘着性接続部材の持つ接着力により光ファイバに振動あるいは熱的な変化があっても光ファイバを安定して接続することができる。さらに、粘着材表面が柔軟であるため、突き合わしたときの光ファイバの破損が無く、光学接続時の取り扱い性も極めて良好である。さらにまた、粘着性接続部材は、一度変形しても、その弾性により復元するため、着脱を繰り返した後でも、粘着性接続部材を貼着した光ファイバは光学接続に複数回の使用が可能である。   According to the present invention, since the adhesive connecting member is deformed internally, the end face between the two optical fibers can be brought close to each other even when the film thickness is somewhat thick. For this reason, the initial film thickness of the adhesive connecting member can be increased, and the handling of the sheet-like adhesive connecting member becomes very simple. Further, even if the end face angle of the optical fiber to be abutted is inclined or the end face shape is deformed, the adhesive connecting member is deformed to the inside while closely contacting the end face of the optical fiber. This makes it possible to realize a low-loss optical connection without using a polishing technique. Further, the optical fiber can be stably connected even if the optical fiber is vibrated or thermally changed due to the adhesive force of the adhesive connecting member. Further, since the surface of the adhesive material is flexible, the optical fiber is not damaged when it is abutted, and the handling property at the time of optical connection is very good. Furthermore, since the adhesive connection member is deformed once and restored by its elasticity, the optical fiber with the adhesive connection member attached can be used multiple times for optical connection even after repeated attachment and detachment. is there.

図4は、本発明の光伝送媒体の端面処理方法の一例の工程図であり、シート状粘着性接続部材を貼着する最も基本的な例を示すものである。この図の場合、光伝送媒体として光ファイバが用いられている。図4において、端部を被覆除去し、カットした光ファイバ1の側方にシート状粘着性接続部材2が設置されている。シート状粘着性接続部材の両端は、図示されていない他の適宜の部材により位置が固定されている。まず、光ファイバ1の端部がシート状粘着性接続部材2に密着するまで、光ファイバをシート状粘着性接続部材に対して相対的に移動させる。次に光ファイバを、さらに軸方向に移動させることにより、シート状粘着性接続部材の一部が光ファイバの端面に貼着した状態で切り離され、光ファイバ端面に粘着性接続部材21を設けることができる。   FIG. 4 is a process diagram of an example of the end face processing method for an optical transmission medium according to the present invention, and shows the most basic example of sticking a sheet-like adhesive connecting member. In the case of this figure, an optical fiber is used as the optical transmission medium. In FIG. 4, a sheet-like adhesive connecting member 2 is installed on the side of the cut optical fiber 1 with the end portion removed. The positions of both ends of the sheet-like adhesive connecting member are fixed by other appropriate members not shown. First, the optical fiber is moved relative to the sheet-like adhesive connecting member until the end of the optical fiber 1 is in close contact with the sheet-like adhesive connecting member 2. Next, by moving the optical fiber further in the axial direction, a part of the sheet-like adhesive connecting member is cut off in a state of being stuck to the end face of the optical fiber, and the adhesive connecting member 21 is provided on the end face of the optical fiber. Can do.

また、図5は本発明におけるシート状粘着性接続部材を貼着する他の例を説明する工程図である。図5においては、光ファイバ1の端部がシート状粘着性接続部材2に密着するまで、光ファイバをシート状粘着性接続部材に対して相対的に移動させる。その後、光ファイバを逆方向に移動させることにより、粘着性接続部材の粘着性を利用し、シート状粘着性接続部材の一部が光ファイバの端面に貼着した状態で切り離され、光ファイバ端面に粘着性接続部材21を設けることができる。この方法によれば、図4に示す方法よりも光ファイバの移動範囲を小さくすることができるため、作製スペースをさらに省スペース化できると言う利点がある。   Moreover, FIG. 5 is process drawing explaining the other example which sticks the sheet-like adhesive connection member in this invention. In FIG. 5, the optical fiber is moved relative to the sheet-like adhesive connecting member until the end of the optical fiber 1 is in close contact with the sheet-like adhesive connecting member 2. Thereafter, by moving the optical fiber in the opposite direction, the adhesive property of the adhesive connection member is utilized, and the sheet-like adhesive connection member is cut off in a state of being stuck to the end surface of the optical fiber. The adhesive connecting member 21 can be provided on the substrate. According to this method, since the moving range of the optical fiber can be made smaller than the method shown in FIG. 4, there is an advantage that the manufacturing space can be further reduced.

図6は光ファイバと光学部品との光学接続構造を作製する場合の一例を示す工程図である。すなわち、端部を被覆除去し、カットした光ファイバ1aの端面に、上記のようにして粘着性接続部材21を付着させ、光学レンズ3と、所定の間隔で配置する(図6(a))。次いで光ファイバを光学レンズに接触させるまで移動させることにより、光ファイバと光学レンズを光学的に接続した光学接続構造が形成される(図6(b))。図に示すように中央部より外周部に向けて段階的にあるいは連続的に厚みが薄くなるような凸形状の光学部品であっても、本発明によれば容易に光学接続を行なうことができる。また、上記方法によれば、光学部品を固定した状態で安定な接続を保持することができる。なお、粘着性接続部材は光学レンズに貼り付ける必要はなく、少なくとも光ファイバのコア部だけを光学レンズに接触するようにすればよい。したがって、粘着性接続部材を容易に光学レンズから剥がすことも可能であり、光学レンズが汚染されることを防止することも可能である。   FIG. 6 is a process diagram showing an example in the case of producing an optical connection structure between an optical fiber and an optical component. That is, the end portion is covered and the adhesive connecting member 21 is attached to the end surface of the cut optical fiber 1a as described above, and is arranged at a predetermined interval from the optical lens 3 (FIG. 6A). . Next, by moving the optical fiber until it comes into contact with the optical lens, an optical connection structure in which the optical fiber and the optical lens are optically connected is formed (FIG. 6B). As shown in the figure, even if the optical component has a convex shape whose thickness decreases stepwise or continuously from the central portion toward the outer peripheral portion, optical connection can be easily performed according to the present invention. . Moreover, according to the said method, a stable connection can be hold | maintained in the state which fixed the optical component. The adhesive connection member does not need to be attached to the optical lens, and at least only the core portion of the optical fiber needs to be in contact with the optical lens. Therefore, the adhesive connecting member can be easily peeled from the optical lens, and the optical lens can be prevented from being contaminated.

図7は、本発明の光学接続構造を作製する好ましい一例を説明する工程図であって、接続用整列部材を用いて光学接続構造を形成する場合を示している。すなわち、上記のようにして、先端を被覆除去し、カットして、端面に粘着性接続部材21を貼着した光ファイバ1aを、貫通孔を有する接続用整列部材4の貫通孔43に挿入する(図7(a))。次に対向側の貫通孔より先端を被覆除去し、カットした光ファイバ1bを挿入し、その光ファイバの端面を粘着性接続部材に押し当てることにより、光学的な接続を行う(図7b))。本発明において、粘着性接続部材は、接続に必要な最小限の範囲で光ファイバ端面を覆っているので、狭い貫通孔を有する整列部材内であっても使用できる。また、粘着性接続部材を保持するための特別な部材は必要とされないため、光ファイバの軸方向の移動を自由に行うことができる。したがって、光学部品の実装の際には、接続状態を維持したまま自由に光ファイバの位置を調節することができる。また、接続用整列部材を用いることにより粘着性接続部材を接続用整列部材内に収納できるため、取り扱い性と埃・塵の付着防止効果を向上させることができる。   FIG. 7 is a process diagram for explaining a preferred example of producing the optical connection structure of the present invention, and shows a case where the optical connection structure is formed by using a connecting alignment member. That is, as described above, the optical fiber 1a with the tip end covered and cut, and the adhesive connecting member 21 attached to the end face is inserted into the through hole 43 of the connecting alignment member 4 having the through hole. (FIG. 7A). Next, the tip is covered and removed from the through hole on the opposite side, the cut optical fiber 1b is inserted, and the optical fiber is connected by pressing the end face of the optical fiber against the adhesive connecting member (FIG. 7b)) . In the present invention, since the adhesive connecting member covers the end face of the optical fiber to the minimum extent necessary for connection, it can be used even in an alignment member having a narrow through hole. Moreover, since a special member for holding the adhesive connecting member is not required, the optical fiber can be freely moved in the axial direction. Therefore, when the optical component is mounted, the position of the optical fiber can be freely adjusted while maintaining the connection state. Further, since the adhesive connecting member can be accommodated in the connecting alignment member by using the connecting alignment member, it is possible to improve the handleability and the dust / dust adhesion preventing effect.

図8は、本発明の光伝送媒体の端面処理方法の一例の工程図であって、1枚のシート状粘着性接続部材から複数の光ファイバの端面処理が行なわれる場合を示している。すなわち、図8に示すように先端を被覆除去し、カットした光ファイバテープ心線10を、光ファイバの軸方向に移動して、光ファイバ1a〜1dの端面を、図示されていない支持部材で支持されたシート状粘着性接続部材2に接触させる(図8(a))。そして、更に移動させることにより、シート状粘着性接続部材の一部が光ファイバの端面に貼着した状態で切り離され、各光ファイバ1a〜1dの端面に粘着性接続部材21a〜21dを一括して設けることができる(図8(b))。この場合、光ファイバテープ心線10の光ファイバ先端のカットにばらつきがあってもその影響を受けないため、各光ファイバに同じように接続部材を密着させることができる。なお、図においては4本の光ファイバを示しているが、その本数は特に限定されるものではない。   FIG. 8 is a process diagram of an example of an end surface processing method for an optical transmission medium according to the present invention, showing a case where end surface processing of a plurality of optical fibers is performed from one sheet-like adhesive connecting member. That is, as shown in FIG. 8, the tip is covered and removed, the cut optical fiber ribbon 10 is moved in the axial direction of the optical fiber, and the end faces of the optical fibers 1a to 1d are supported by a support member (not shown). The sheet-like adhesive connecting member 2 supported is brought into contact (FIG. 8A). And by making it move further, a part of sheet-like adhesive connection member is cut off in a state where it is stuck to the end face of the optical fiber, and the adhesive connection members 21a to 21d are put together on the end faces of the optical fibers 1a to 1d. (FIG. 8B). In this case, even if there is a variation in the cut of the optical fiber tip of the optical fiber ribbon 10, the connection member can be brought into close contact with each optical fiber in the same manner. In the figure, four optical fibers are shown, but the number is not particularly limited.

図9は、本発明の光伝送媒体の端面処理方法の一例の工程図であって、シート状粘着性接続部材を支持する支持部材を使用した場合の一例を示している。図において、支持部材5は1つの貫通孔53を有しており、貫通孔は光ファイバ心線または光ファイバ素線が挿入できる。支持部材の片面には貫通孔を覆うようにシート状接着性接続部材2が貼りけられている。先端を被覆除去し、カットした光ファイバ1を貫通孔53に挿入し(図9(a))、シート状接着性接続部材と光ファイバ1の端面が接触するまで移動させ(図9(b))、さらに光ファイバを移動させて貫通孔を貫通することにより、シート状粘着性接続部材の一部が光ファイバの端面に貼着した状態で切り離され、光ファイバ端面に粘着性接続部材21を貼着することができる。(図9(c))。この図に示す場合、シート状粘着性接続部材2を支持する支持部材5を設けることにより、シート状粘着性接続部材の切り離しを光ファイバの形状に合わせて行うことができるため、良好な歩留まりで処理することができる。また、一定の角度を有している光ファイバの端面であっても、確実に粘着性接続部材を付着させることができる。   FIG. 9 is a process diagram of an example of the end face processing method for an optical transmission medium according to the present invention, and shows an example in the case of using a support member that supports a sheet-like adhesive connection member. In the figure, the support member 5 has one through hole 53 into which an optical fiber core or an optical fiber can be inserted. A sheet-like adhesive connection member 2 is attached to one side of the support member so as to cover the through hole. The tip of the optical fiber 1 is removed, and the cut optical fiber 1 is inserted into the through-hole 53 (FIG. 9A), and moved until the sheet-like adhesive connecting member and the end face of the optical fiber 1 are in contact (FIG. 9B). ) Further, by moving the optical fiber and penetrating the through hole, a part of the sheet-like adhesive connecting member is cut off in a state of being stuck to the end face of the optical fiber, and the adhesive connecting member 21 is attached to the end face of the optical fiber. Can be attached. (FIG. 9 (c)). In the case shown in this figure, by providing the support member 5 that supports the sheet-like adhesive connecting member 2, the sheet-like adhesive connecting member can be separated according to the shape of the optical fiber, so that the yield is good. Can be processed. Moreover, even if it is the end surface of the optical fiber which has a fixed angle, an adhesive connection member can be reliably made to adhere.

図10は、本発明の光伝送媒体の端面処理方法の一例の工程図であって、シート状粘着性接続部材を支持する支持部材を使用した場合の他の一例を示している。また、図11は支持部材の断面図である。これらの図の場合、支持部材は、光ファイバを案内するV字状整列溝54を有する下部基板51の上に、ガラスなどの上部平板52を載置した構造を有しており、整列溝54と上部平板52とによって貫通孔が形成されている。支持部材の一端には、シート状粘着性接続部材2が貼着固定されている(図10(a))。このような支持部材を用いる場合、光ファイバ1を整列溝に載置した後、上部平板52を下部基板51の上に載せることも可能である(図10(a))。そして整列溝に載置した光ファイバ1は、整列溝に沿って軸方向に移動させることにより、その端面をシート状粘着性接続部材2に接触して密着させ(図10(b))、さらに移動させて、その端面に粘着性接続部材21を貼着することができる(図10(c))。また、貫通孔を貫通した後、上部平板52を外すことにより、粘着性接続部材を設けた光ファイバ1を上方より容易に取り出すことができる(図10(d))。   FIG. 10 is a process diagram of an example of the end face processing method for an optical transmission medium according to the present invention, and shows another example in the case of using a support member that supports a sheet-like adhesive connecting member. FIG. 11 is a cross-sectional view of the support member. In these drawings, the support member has a structure in which an upper flat plate 52 such as glass is placed on a lower substrate 51 having a V-shaped alignment groove 54 for guiding an optical fiber. Through holes are formed by the upper flat plate 52. The sheet-like adhesive connection member 2 is stuck and fixed to one end of the support member (FIG. 10A). When such a supporting member is used, it is possible to place the upper flat plate 52 on the lower substrate 51 after placing the optical fiber 1 in the alignment groove (FIG. 10A). Then, the optical fiber 1 placed in the alignment groove is moved in the axial direction along the alignment groove, thereby bringing the end face into contact with the sheet-like adhesive connecting member 2 (FIG. 10B), and It can be moved and the adhesive connection member 21 can be stuck to the end surface (FIG.10 (c)). Further, after penetrating the through hole, the upper flat plate 52 is removed, whereby the optical fiber 1 provided with the adhesive connecting member can be easily taken out from above (FIG. 10D).

図12は本発明の光伝送媒体の端面処理方法の一例の工程図であって、シート状粘着性接続部材を支持する支持部材を使用した場合のさらに他の一例を示している。図において、支持部材5は、中央付近にシート状粘着性接続部材を支持する深溝55を有し、また、その深溝を挟んだ両側には、同軸の一対の貫通孔53を有し、光ファイバの整列機能を有すると共に、シート状粘着性接続部材を支持する機能も同時に備えている(図12(a))。まずシート状粘着性接続部材2を貫通孔に対して垂直になるように深溝55に挿入する(図12(b))。次に被覆除去し、カットした光ファイバ1aを片方の貫通孔53に挿入し、貫通孔内で光ファイバの端面をシート材に接触させ、更に光ファイバを移動させて、他方の貫通孔に挿入させる。これによって、シート状粘着性接続部材の一部が切り離され、光ファイバの端部に粘着性接続部材21が貼着する(図12(c))。次に、もう片側の貫通孔より他の光ファイバ1bを挿入し、粘着性接続部材に密着するまで移動させる(図12(d))。この図に示す場合、整列機能を備えた一つの支持部材で光ファイバを接続することができる。その際、光ファイバの接続点の位置は自由に設定できるため、取り扱い性と作業性が格段に向上する。   FIG. 12 is a process diagram of an example of the end face processing method for an optical transmission medium of the present invention, and shows still another example in the case of using a support member that supports a sheet-like adhesive connection member. In the figure, the support member 5 has a deep groove 55 for supporting the sheet-like adhesive connecting member near the center, and has a pair of coaxial through holes 53 on both sides of the deep groove, and an optical fiber. And a function of supporting the sheet-like adhesive connecting member at the same time (FIG. 12A). First, the sheet-like adhesive connecting member 2 is inserted into the deep groove 55 so as to be perpendicular to the through hole (FIG. 12B). Next, the coating is removed and the cut optical fiber 1a is inserted into one through hole 53, the end face of the optical fiber is brought into contact with the sheet material in the through hole, and the optical fiber is further moved and inserted into the other through hole. Let Thereby, a part of the sheet-like adhesive connecting member is cut off, and the adhesive connecting member 21 is attached to the end of the optical fiber (FIG. 12C). Next, another optical fiber 1b is inserted from the other through-hole and moved until it comes into close contact with the adhesive connecting member (FIG. 12 (d)). In the case shown in this figure, the optical fibers can be connected by a single support member having an alignment function. At that time, the position of the connection point of the optical fiber can be freely set, so that handling and workability are remarkably improved.

本発明において、図7に示されるような接続用整列部材や、図9および10に示されるようなシート状粘着性接続部材の支持部材を用いたときの光ファイバ同士の位置合わせ方法は、光ファイバ端面が同軸上で位置合わせされていればよく、特に限定されるものではない。図7に示すように貫通孔に挿入したり、あるいは図10に示すようにV字状整列溝などの整列溝の上に光ファイバを載置したりしてもよい。なお、V字状整列溝などの整列溝の場合は、例えばガラスなどの平板を上から押さえ込み、その溝を囲うことにより貫通孔としてもよく、この場合、光ファイバの載置を上部から行うことが可能となるため、光ファイバ同士を粘着性接続部材を介して仮接続させて載置することができ、接続部の位置を自由に設定することが可能になる。また、光ファイバの載置をしやすくするために貫通孔先端をコーン状にするなどの加工を施しても構わない。   In the present invention, the alignment method for optical fibers when using the connecting alignment member as shown in FIG. 7 and the support member for the sheet-like adhesive connecting member as shown in FIGS. There is no particular limitation as long as the fiber end faces are aligned on the same axis. The optical fiber may be inserted into the through hole as shown in FIG. 7, or placed on an alignment groove such as a V-shaped alignment groove as shown in FIG. In the case of an alignment groove such as a V-shaped alignment groove, a through hole may be formed by pressing a flat plate such as glass from above and surrounding the groove. In this case, the optical fiber is placed from above. Therefore, the optical fibers can be temporarily connected via the adhesive connection member and placed, and the position of the connection portion can be freely set. Also, processing such as making the tip of the through hole into a cone shape may be performed to facilitate placement of the optical fiber.

接続用整列部材やシート状粘着性接続部材を支持するための支持部材のサイズは特に限定させるものではなく、光ファイバの種類または本数によって適宜選択すればよく、その形状も特に限定されるものではない。例えば、半円柱状形、直方体状形などの形状が挙げられる。更に貫通孔や整列溝の構造、位置、形状も特に限定されるものではない。また、例えばMTコネクタフェルールなどの既存の部材も前記接続用整列部材あるいは支持部材として用いても良い。更に接続用整列部材を構成する材料も特に限定されるものではないが、例えばポリアセタール樹脂のような摩擦係数が小さい材料や熱変形しにくいなどの機械特性が良好な材料、ステンレス鋼、三フッ化エチレン樹脂、テトラフルオロエチレン樹脂などの腐食しない材料、または化学物質や溶剤に対して反応性が小さい材料であることが好ましい。   The size of the support member for supporting the connecting alignment member and the sheet-like adhesive connection member is not particularly limited, and may be appropriately selected depending on the type or number of optical fibers, and the shape is not particularly limited. Absent. Examples of the shape include a semi-cylindrical shape and a rectangular parallelepiped shape. Further, the structure, position, and shape of the through holes and the alignment grooves are not particularly limited. Further, for example, an existing member such as an MT connector ferrule may be used as the connecting alignment member or the support member. Further, the material constituting the connecting alignment member is not particularly limited. For example, a material having a low coefficient of friction such as polyacetal resin, a material having good mechanical properties such as heat deformation, stainless steel, trifluoride, etc. A material that does not corrode, such as an ethylene resin or a tetrafluoroethylene resin, or a material that has low reactivity with chemical substances or solvents is preferable.

以下、本発明の光学接続構造とその作製方法、特に粘着性接続部材の設置工程を実施例によって説明するが、本発明はこれらに限定されるものではない。   Hereinafter, although the optical connection structure of the present invention and the manufacturing method thereof, in particular, the installation process of the adhesive connection member will be described with reference to examples, the present invention is not limited thereto.

図13に示すようにして光ファイバの端面処理を行なった。すなわち、光学部材のシート状粘着性接続部材2として、屈折率1.46に調節したアクリル系粘着材をシート化し、厚み25μm、サイズ8mm×16mmのシートを用いた。これをシートと同等のサイズのU字型の支持部材5にしわがないように貼り付けた(図13(a))。次に、1本の光ファイバ1(古河電工製、外径250μm、クラッド径125μm、コア径10μm)の被覆を端部から20mm除去し、光ファイバ素線を剥き出しにし、端部から10mmのところで光ファイバ素線をカットした。次に、支持部材に貼り付けたシート材を光ファイバ素線の端面に密着させて配置した(図13(b))。そして、光ファイバ端面に接触して密着するシート状粘着性接続部材を非接触部分から切り離されるまで光ファイバ1を移動させた(図13(c))。次いで、端面に粘着性接続部材21が貼着した光ファイバを上方に移動し、光ファイバをシートを支持する支持部材5より取り外した(図13(d))。この場合、光ファイバに接する面における粘着性接続部材の周辺部は、コアの中心から50μm〜65μm程度であった。   The end face processing of the optical fiber was performed as shown in FIG. That is, as the sheet-like adhesive connecting member 2 of the optical member, an acrylic adhesive material adjusted to a refractive index of 1.46 was formed into a sheet, and a sheet having a thickness of 25 μm and a size of 8 mm × 16 mm was used. This was affixed to the U-shaped support member 5 having the same size as the sheet so as not to be wrinkled (FIG. 13A). Next, the coating of one optical fiber 1 (manufactured by Furukawa Electric Co., Ltd., outer diameter 250 μm, cladding diameter 125 μm, core diameter 10 μm) is removed 20 mm from the end, and the optical fiber is bare and 10 mm from the end. The optical fiber was cut. Next, the sheet material affixed to the support member was disposed in close contact with the end face of the optical fiber (FIG. 13B). And the optical fiber 1 was moved until the sheet-like adhesive connection member which contact | connects and adheres to an optical fiber end surface was cut | disconnected from the non-contact part (FIG.13 (c)). Next, the optical fiber having the adhesive connecting member 21 attached to the end face was moved upward, and the optical fiber was removed from the support member 5 that supports the sheet (FIG. 13D). In this case, the peripheral portion of the adhesive connecting member on the surface in contact with the optical fiber was about 50 μm to 65 μm from the center of the core.

この粘着性接続部材21を具備した光ファイバ1aを図14に示すような幅が250μm、高さ250μmのV字状整列溝44を中央に有する下部基板41(10mm×40mm×10mm)のV字状整列溝内に載置し、他方、先端を被覆除去し、カットした光ファイバ1bを対向するように載置した。2つの光ファイバ1a及び1bをV字状整列溝に沿わせて、粘着性接続部材21が密着するまで近づけ、この状態で、上方からガラス製の上部平板42をV字状整列溝を有する下部基板に載せて固定した。   The optical fiber 1a provided with the adhesive connecting member 21 has a V-shaped lower substrate 41 (10 mm × 40 mm × 10 mm) having a V-shaped alignment groove 44 having a width of 250 μm and a height of 250 μm as shown in FIG. On the other hand, the tip was covered and the cut optical fiber 1b was placed so as to face each other. The two optical fibers 1a and 1b are placed along the V-shaped alignment groove until the adhesive connecting member 21 comes into close contact, and in this state, the upper plate 42 made of glass is formed from above with a lower portion having the V-shaped alignment groove. It was fixed on the substrate.

以上のようにして、2つの光ファイバをV字状整列溝内にて周囲の汚染が起きることなく簡単に接続させることができた。また、粘着性接続部材の柔軟性により光ファイバの端面周辺の自由度が増すために光ファイバに過剰な押圧力がかからなくなり、その結果、光ファイバの破損が起こることなく、極めて良好な取り扱い性で光学接続を行うことができた。また、粘着性接続部材の粘着性により光ファイバ端面が密着するために接続損失が0.3dBと小さかった。形成された光ファイバの接続構造において、Dは50μm、Dは65μmであった。 As described above, two optical fibers could be easily connected in the V-shaped alignment groove without surrounding contamination. In addition, the flexibility of the adhesive connection member increases the degree of freedom around the end face of the optical fiber, so that no excessive pressing force is applied to the optical fiber. As a result, the optical fiber is not damaged and is handled extremely well. We were able to make an optical connection. Moreover, since the end face of the optical fiber was brought into close contact due to the adhesiveness of the adhesive connecting member, the connection loss was as small as 0.3 dB. In the connection structure of the formed optical fiber, D 1 is 50 [mu] m, D 2 was 65 .mu.m.

また、図13に示す光ファイバの端面処理方法は、光ファイバを移動させるだけで、簡単に支持部材に固定した接続部材を光ファイバ端面に貼着させることができ、取り扱い性が良好であった。  Further, the end face processing method of the optical fiber shown in FIG. 13 can easily attach the connecting member fixed to the support member to the end face of the optical fiber simply by moving the optical fiber, and the handleability is good. .

実施例1と同様に粘着性接続部材の光ファイバ端面への貼着を行なった。光学接続工程において、光ファイバと光ファイバの端面同士が粘着性接続部材を介して突き合わされるときに、粘着性接続部材が厚さ10μmになるまで光ファイバを押し当て、内部変形させる工程を採用した以外は実施例1と同様の方法で光ファイバを光学的に接続した。このとき、接続損失を測定したところ、0.2dBであった。このように粘着性接続部材を変形させることで、さらに光ファイバ間の端面を近接させることができるため、より低損失な接続を実現することができた。この実施例の場合、Dはファイバクラッド径より小さく(実測不能)、Dは約85μmであった。 In the same manner as in Example 1, the adhesive connecting member was attached to the end face of the optical fiber. In the optical connection process, when the end faces of the optical fiber and the optical fiber are abutted with each other through the adhesive connection member, the optical fiber is pressed until the adhesive connection member has a thickness of 10 μm and internally deformed. The optical fibers were optically connected in the same manner as in Example 1 except that. At this time, the connection loss was measured and found to be 0.2 dB. By deforming the adhesive connecting member in this way, the end faces between the optical fibers can be brought closer to each other, so that a lower loss connection can be realized. In this embodiment, D 1 is smaller than the fiber clad diameter (immeasurable), D 2 is about 85 .mu.m.

図15に示すようにして光ファイバ1とロッドレンズ6の接続を行なった。すなわち、実施例1の方法で作製した端面に粘着性接続部材2が貼着した光ファイバ1を、下部基板41のV字状整列溝44に設置した。一方、ロッドレンズ6(mflends社製、外径2mmφ)を2.1mmφの貫通孔71を有し、端面が下部基板に突き合わされているレンズ用固定部材7に挿入し、レンズ用固定部材の端面にロッドレンズの端面を合わせ、ロッドレンズがV字状整列溝44と同軸上に位置合わせされた状態にし、ロッドレンズを接着剤でレンズ用固定部材に固定した。次に、光ファイバをV字状整列溝に這わせるように移動させて光ファイバの端面の粘着性接続部材をロッドレンズに接触させた。その後、光ファイバを上部平板42と下部基板41で挟み込み、さらに光ファイバ固定部材8でそれらを挟み、固定した。このように、光ファイバとレンズのようにサイズの異なる光学部品の接続であっても、光学部品を固定した状態で容易に安定な接続をすることができ、また光ファイバを押し当てて粘着性接続部材を接触させることによって、レンズと粘着性接続部材は最小限の面積で、接触させることができ、また簡単に剥がすことができる。   The optical fiber 1 and the rod lens 6 were connected as shown in FIG. That is, the optical fiber 1 having the adhesive connecting member 2 adhered to the end face produced by the method of Example 1 was installed in the V-shaped alignment groove 44 of the lower substrate 41. On the other hand, the rod lens 6 (manufactured by mfriends, outer diameter 2 mmφ) is inserted into the lens fixing member 7 having a through hole 71 of 2.1 mmφ and the end surface is abutted against the lower substrate, and the end surface of the lens fixing member The end face of the rod lens was aligned with the rod lens so that the rod lens was aligned coaxially with the V-shaped alignment groove 44, and the rod lens was fixed to the lens fixing member with an adhesive. Next, the optical fiber was moved so as to lie along the V-shaped alignment groove, and the adhesive connecting member on the end face of the optical fiber was brought into contact with the rod lens. Thereafter, the optical fibers were sandwiched between the upper flat plate 42 and the lower substrate 41, and were further sandwiched and fixed by the optical fiber fixing member 8. In this way, even when connecting optical components of different sizes such as optical fiber and lens, stable connection can be easily made with the optical components fixed, and the optical fiber can be pressed against the adhesive. By bringing the connecting member into contact, the lens and the adhesive connecting member can be brought into contact with each other with a minimum area, and can be easily peeled off.

図10に示すようにして、光ファイバの端面処理を行なった。すなわち、シート状粘着性接続部材を支持する支持部材として、上部平板52、下部基板51の2つの部材(共にサイズ10mm×20mm×10mm、プラスチック製)により構成されており、上部支持部材は平板であり、下部支持部材は中央に幅250μmのV字状整列溝を設けた平板からなっていた。この2つの部材は図示されていない側面の2つのヒンジによって接合され、その2つの部材を合わせると1つの貫通孔が形成されるものであった。次に、その貫通孔に対して垂直方向の片端面に実施例1と同様のシート状粘着性接続部材2を密着させて配置した(a)。次いで、先端から30mmの被覆を除去し、20mmにカットした光ファイバ1を反対側端面の貫通孔に挿入し、光学部材のシート材に突き当たるまで光ファイバを移動させた(b)。そして、貫通孔を貫通するまで光ファイバを移動させ、シート状粘着性接続部材の一部を切り離して分離させた(c)。次いで、光ファイバ先端がシート状粘着性接続部材に対して10mm移動した後、上部平板を上方に開放し、光ファイバを下部基板より取り外した(d)。この場合、光ファイバに接する面における粘着性接続部材の周辺部は、コアの中心から60μm〜75μm程度であった。   As shown in FIG. 10, the end face processing of the optical fiber was performed. That is, as a supporting member for supporting the sheet-like adhesive connecting member, the upper supporting plate 52 and the lower substrate 51 are composed of two members (both sizes 10 mm × 20 mm × 10 mm, made of plastic), and the upper supporting member is a flat plate. The lower support member was a flat plate provided with a V-shaped alignment groove having a width of 250 μm in the center. These two members were joined by two hinges on the side surface not shown, and when the two members were combined, one through hole was formed. Next, the same sheet-like adhesive connection member 2 as that of Example 1 was disposed in close contact with one end surface in the direction perpendicular to the through hole (a). Next, the coating of 30 mm was removed from the tip, the optical fiber 1 cut to 20 mm was inserted into the through hole on the opposite end surface, and the optical fiber was moved until it hits the sheet material of the optical member (b). Then, the optical fiber was moved until it penetrated the through hole, and a part of the sheet-like adhesive connecting member was separated and separated (c). Next, after the tip of the optical fiber moved 10 mm relative to the sheet-like adhesive connecting member, the upper flat plate was opened upward, and the optical fiber was removed from the lower substrate (d). In this case, the peripheral portion of the adhesive connecting member on the surface in contact with the optical fiber was about 60 μm to 75 μm from the center of the core.

この製造方法において、光ファイバを貫通孔に挿入し、さらに移動させるだけで、簡単に支持部材に密着したシート状粘着性接続部材を光ファイバに密着させることができ、極めて良好な取り扱い性で端面に粘着性接続部材を備えた光ファイバを製造することができた。また貫通孔を有する支持部材を用いて接続部材のシート材を密着させて配置することにより常にシート材の状態が安定して製造することができるため、良好な歩留まりを維持することができた。さらに支持部材が上部部材と下部部材により構成され、上部部材を開放することにより、接続部材付きの光ファイバを支持部材から無理なく取り外すことが可能となった。   In this manufacturing method, by simply inserting the optical fiber into the through hole and moving it further, the sheet-like adhesive connecting member that is in close contact with the support member can be brought into intimate contact with the optical fiber. An optical fiber having an adhesive connecting member can be manufactured. Moreover, since the sheet | seat material of a connection member was closely_contact | adhered and arrange | positioned using the supporting member which has a through-hole, since the state of a sheet | seat material can always be manufactured stably, the favorable yield could be maintained. Furthermore, the supporting member is composed of an upper member and a lower member, and by opening the upper member, the optical fiber with the connecting member can be removed from the supporting member without difficulty.

図16に示すようにして光ファイバの光学接続を行った。接続用整列部材4(サイズ10mm×20mm×40mm)は、中央に幅0.25mmの深溝45と一対の貫通孔43を有していた。一方、実施例1で用いたシート状粘着性接続部材2を、中央に空洞を有する透明のプラスチック樹脂の支持部材5(2mm角厚み0.1mm)2枚で挟み込み、シート状粘着性接続部材を内包したカートリッジを作製した。このカートリッジを、図16(a)に示すように、接続用整列部材の深溝45に装着した。先端25mmを被覆除去し、カットした光ファイバ1a、1bを貫通孔にそれぞれ挿入し、一方の光ファイバ1aをカートリッジに内包された粘着性接続部材のシート材に接触させ(b)、更にゆっくり押し込むことにより、粘着性接続部材21が光ファイバの端面に貼着されるようにした(c)。この光ファイバを適当な位置まで移動させ、接続用整列部材に接着剤で固定した。次に対向するもう一方の光ファイバ1bを移動し、粘着性接続部材に接触させた。その後、この光ファイバを接続用整列部材に接着剤で固定した。   The optical connection of the optical fiber was performed as shown in FIG. The connecting alignment member 4 (size 10 mm × 20 mm × 40 mm) had a deep groove 45 having a width of 0.25 mm and a pair of through holes 43 at the center. On the other hand, the sheet-like adhesive connecting member 2 used in Example 1 is sandwiched between two transparent plastic resin supporting members 5 (2 mm square thickness 0.1 mm) having a cavity in the center, and the sheet-like adhesive connecting member is An encapsulated cartridge was produced. As shown in FIG. 16A, this cartridge was mounted in the deep groove 45 of the connecting alignment member. The tip of 25 mm is removed from the coating, and the cut optical fibers 1a and 1b are inserted into the through holes, respectively, and one optical fiber 1a is brought into contact with the sheet material of the adhesive connecting member contained in the cartridge (b) and further slowly pushed in. Thus, the adhesive connecting member 21 was adhered to the end face of the optical fiber (c). The optical fiber was moved to an appropriate position and fixed to the connecting alignment member with an adhesive. Next, the other optical fiber 1b facing each other was moved and brought into contact with the adhesive connecting member. Thereafter, the optical fiber was fixed to the connecting alignment member with an adhesive.

以上のようにして、接続用整列部材内で、粘着性接続部材のシート材を内包し、かつシート状粘着性接続部材からその一部を切り離し、そのまま光学接続することで、粘着性接続部材の貼着から光ファイバの接続までを一つの部材によって行うことができた。これによって、構造的に安定した光学接続が可能となり、光学接続構造の作製後に、粘着性接続部材にゴミや塵の付着を防止することができ、生産効率が向上した。この場合、Dはファイバクラッド径より小さく(実測不能)、Dは約65μmであった。 As described above, in the connecting alignment member, the sheet material of the adhesive connection member is included, and a part thereof is separated from the sheet-like adhesive connection member and optically connected as it is. The process from sticking to connection of optical fiber could be performed by one member. As a result, structurally stable optical connection is possible, and after the optical connection structure is produced, dust and dust can be prevented from adhering to the adhesive connection member, and the production efficiency is improved. In this case, D 1 is smaller than the fiber clad diameter (immeasurable), D 2 is about 65 .mu.m.

本発明の光学接続構造の最も基本的な例を示す側面図である。It is a side view which shows the most basic example of the optical connection structure of this invention. 本発明により作製された光学接続構造の一例を示す側面図である。It is a side view which shows an example of the optical connection structure produced by this invention. 光ファイバの端面に粘着性接続部材が貼着した状態を説明するための説明図であり、(a)は光ファイバ端部の側面図、(b)は平面図である。It is explanatory drawing for demonstrating the state which the adhesive connection member stuck on the end surface of an optical fiber, (a) is a side view of an optical fiber edge part, (b) is a top view. 本発明の光伝送媒体の端面処理方法の一例を説明するための工程図である。It is process drawing for demonstrating an example of the end surface processing method of the optical transmission medium of this invention. 本発明の光伝送媒体の端面処理方法の他の一例を説明するための工程図である。It is process drawing for demonstrating another example of the end surface processing method of the optical transmission medium of this invention. 光ファイバとレンズとの光学接続構造を作製する場合の一例を示す工程図である。It is process drawing which shows an example in the case of producing the optical connection structure of an optical fiber and a lens. 本発明の光学接続構造を作製する一例を説明する工程図である。It is process drawing explaining an example which produces the optical connection structure of this invention. 本発明の光伝送媒体の端面処理方法の一例の工程図であるIt is process drawing of an example of the end surface processing method of the optical transmission medium of this invention. 本発明の光伝送媒体の端面処理方法の他の一例の工程図である。It is process drawing of another example of the end surface processing method of the optical transmission medium of this invention. 本発明の光伝送媒体の端面処理方法の他の一例の工程図である。It is process drawing of another example of the end surface processing method of the optical transmission medium of this invention. 本発明に使用する図10の支持部材のA−A線断面図である。It is the sectional view on the AA line of the supporting member of FIG. 10 used for this invention. 本発明の光伝送媒体の端面処理方法の他の一例の工程図である。It is process drawing of another example of the end surface processing method of the optical transmission medium of this invention. 実施例1の光伝送媒体の端面処理方法の一例の工程図である。6 is a process diagram of an example of an end face processing method for an optical transmission medium according to Embodiment 1. 実施例1に用いた接続用整列部材の(a)は側面図であり、(b)はB−B線断面図である。(A) of the alignment member for a connection used for Example 1 is a side view, (b) is a BB sectional drawing. 実施例3の光ファイバ1とロッドレンズの光学接続構造を作製する工程図である。It is process drawing which produces the optical connection structure of the optical fiber 1 of Example 3, and a rod lens. 実施例5の光学接続構造を作製する工程図である。FIG. 10 is a process drawing for producing the optical connection structure of Example 5.

符号の説明Explanation of symbols

1、1a〜1d…光ファイバ、10…光ファイバテープ心線、11…コア、12…クラッド、2…シート状粘着性接続部材、21…粘着性接続部材、3…レンズ、4…接続用整列部材、41…下部基板、42…上部平板、43…貫通孔、44…V字状整列溝、45…深溝、5…支持部材、51…下部基板、52…上部平板、53、…貫通孔、54…V字状整列溝、55…深溝、6…ロッドレンズ、7…レンズ用固定部材、71…貫通孔、8 …光ファイバ固定部材。   DESCRIPTION OF SYMBOLS 1, 1a-1d ... Optical fiber, 10 ... Optical fiber ribbon, 11 ... Core, 12 ... Cladding, 2 ... Sheet-like adhesive connection member, 21 ... Adhesive connection member, 3 ... Lens, 4 ... Connection alignment 41, lower substrate, 42 ... upper flat plate, 43 ... through hole, 44 ... V-shaped alignment groove, 45 ... deep groove, 5 ... support member, 51 ... lower substrate, 52 ... upper flat plate, 53, ... through hole, 54 ... V-shaped alignment groove, 55 ... Deep groove, 6 ... Rod lens, 7 ... Lens fixing member, 71 ... Through hole, 8 ... Optical fiber fixing member.

Claims (12)

互いに対向するコアを有する光伝送媒体の端面またはコアを有する光伝送媒体と光学部品との間に、屈折率整合性を有する単一層からなる粘着性接続部材が挟置された光学接続構造であって、光伝送媒体のコアの中心から粘着性接続部材の周辺部までの距離の最小値をD、最大値をD、光伝送媒体の半径をR、光伝送媒体のコアの半径をrとしたとき、D≧r、かつ、D≦1.5Rを満足することを特徴とする光学接続構造。 An optical connection structure in which an adhesive connection member made of a single layer having refractive index matching is sandwiched between an optical transmission medium and an optical component having an end face of an optical transmission medium having cores facing each other or an optical component. The minimum value of the distance from the center of the core of the optical transmission medium to the periphery of the adhesive connecting member is D 1 , the maximum value is D 2 , the radius of the optical transmission medium is R, and the radius of the core of the optical transmission medium is r In this case, the optical connection structure satisfies D 1 ≧ r and D 2 ≦ 1.5R. 前記粘着性接続部材が、前記光伝送媒体および前記光学部品の端面形状に対応して変形して該端面に密着することを特徴とする請求項1記載の光学接続構造。   2. The optical connection structure according to claim 1, wherein the adhesive connection member is deformed corresponding to an end surface shape of the optical transmission medium and the optical component and is in close contact with the end surface. 前記光伝送媒体が多心の光ファイバであることを特徴とする請求項1記載の光学接続構造。   The optical connection structure according to claim 1, wherein the optical transmission medium is a multi-core optical fiber. 請求項1の光学接続構造を作製する方法であって、光伝送媒体の端面をシート状粘着性接続部材に押し当てて密着させたまま、該シート状粘着性接続部材を該光伝送媒体に対して光伝送媒体の軸方向に相対的に移動させることにより、シート状粘着性接続部材の一部を端面に付着した状態で切り離す工程、および端面に粘着性接続部材が付着した光伝送媒体を、他の光伝送媒体又は光学部品と接合する工程を有することを特徴とする光学接続構造の作製方法。   The method for producing an optical connection structure according to claim 1, wherein the sheet-like adhesive connection member is attached to the optical transmission medium while the end face of the optical transmission medium is pressed against and adhered to the sheet-like adhesive connection member. The step of separating a part of the sheet-like adhesive connecting member attached to the end surface by relatively moving in the axial direction of the optical transmission medium, and the optical transmission medium having the adhesive connecting member attached to the end surface, A method for producing an optical connection structure, comprising a step of bonding to another optical transmission medium or an optical component. 前記光伝送媒体が多心の光ファイバであることを特徴とする請求項4記載の光学接続構造の作製方法。   5. The method for producing an optical connection structure according to claim 4, wherein the optical transmission medium is a multi-core optical fiber. シート状粘着性接続部材が支持部材に支持されていることを特徴とする請求項4に記載の光学接続構造の作製方法。   The method for producing an optical connection structure according to claim 4, wherein the sheet-like adhesive connection member is supported by a support member. 前記支持部材が光伝送媒体を挿入するための貫通孔を有し、該支持部材の一端にシート状粘着性接続部材が貫通孔を塞ぐように貼着されていることを特徴とする請求項6に記載の光学接続構造の作製方法。   7. The support member has a through hole for inserting an optical transmission medium, and a sheet-like adhesive connecting member is attached to one end of the support member so as to close the through hole. A manufacturing method of the optical connection structure described in 1. 前記支持部材が、少なくとも一方に整列溝を有する2つの部材を重ねたものであって、該整列溝によって貫通孔が形成されることを特徴とする請求項7記載の光学接続構造の作製方法。   8. The method for producing an optical connection structure according to claim 7, wherein the support member is formed by superposing two members having alignment grooves on at least one side, and through holes are formed by the alignment grooves. 少なくとも一方に整列溝を有する2つの部剤を重ねることによって形成される前記支持部材の前記貫通孔の中で、光伝送媒体端面に粘着性接続部材を貼着した後、該支持部剤を2つの部剤に分離させ、該光伝送媒体が該貫通孔から取り出される工程を有することを特徴とする請求項8記載の光学接続構造の作製方法。   After sticking the adhesive connecting member to the end face of the optical transmission medium in the through hole of the support member formed by stacking two parts having alignment grooves on at least one side, the support member is 9. The method for producing an optical connection structure according to claim 8, further comprising a step of separating the optical transmission medium into two parts and taking out the optical transmission medium from the through hole. 端面に粘着性接続部材が付着した光伝送媒体を他の光伝送媒体又は光学部品と接合する工程が、整列溝もしくは貫通孔を有する整列部材又は貫通孔を有する支持部材を用いて行われることを特徴とする請求項4記載の光学接続構造の作製方法。   The step of joining the optical transmission medium having the adhesive connecting member attached to the end face to another optical transmission medium or an optical component is performed using an alignment member having an alignment groove or a through hole or a support member having a through hole. The method for producing an optical connection structure according to claim 4. 光伝送媒体の端面をシート状粘着性接続部材に押し当てて密着させたまま、該シート状粘着性接続部材を光伝送媒体に対して光伝送媒体の軸方向に相対的に移動させることにより、シート状粘着性接続部材の一部を光伝送媒体の端面に貼着した状態で切り離すことを特徴とする、請求項1の光学接続構造を作製するための光伝送媒体の端面処理方法。   By moving the sheet-like adhesive connecting member relative to the optical transmission medium in the axial direction of the optical transmission medium while keeping the end face of the optical transmission medium pressed against and in close contact with the sheet-like adhesive connecting member, 2. A method of treating an end face of an optical transmission medium for producing an optical connection structure according to claim 1, wherein a part of the sheet-like adhesive connecting member is cut off in a state of being adhered to the end face of the optical transmission medium. シート状粘着性接続部材が支持部材に支持されていることを特徴とする請求項11に記載の光伝送媒体の端面処理方法。   The method for treating an end face of an optical transmission medium according to claim 11, wherein the sheet-like adhesive connecting member is supported by a support member.
JP2004086343A 2003-11-19 2004-03-24 OPTICAL CONNECTION STRUCTURE AND METHOD FOR MANUFACTURING THE SAME Expired - Lifetime JP4043448B2 (en)

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JP2004086343A JP4043448B2 (en) 2004-03-24 2004-03-24 OPTICAL CONNECTION STRUCTURE AND METHOD FOR MANUFACTURING THE SAME
CN200810124982XA CN101349788B (en) 2003-11-19 2004-11-17 Optical connection structure and optical connection method thereof
EP11005822A EP2392954A1 (en) 2003-11-19 2004-11-17 Optical connection structure and optical connection method
KR1020097005174A KR20090033279A (en) 2003-11-19 2004-11-17 Optical connection structure and optical connection method
US10/579,459 US7422375B2 (en) 2003-11-19 2004-11-17 Optical connection structure and optical connection method
EP11005824A EP2400326A1 (en) 2003-11-19 2004-11-17 Optical connection structure and optical connection method
KR1020067012149A KR100820524B1 (en) 2003-11-19 2004-11-17 Optical connection structure and optical connection method
KR1020087002906A KR100867261B1 (en) 2003-11-19 2004-11-17 Optical connection structure and optical connection method
CN2011101805926A CN102213801A (en) 2003-11-19 2004-11-17 Optical connection structure and optical connection method
KR1020087015579A KR20080067015A (en) 2003-11-19 2004-11-17 Optical connection structure and optical connection method
PCT/JP2004/017065 WO2005050273A1 (en) 2003-11-19 2004-11-17 Optical connection structure and optical connection method
EP04818916.1A EP1686402B1 (en) 2003-11-19 2004-11-17 Optical connection structure and optical connection method
EP11005823A EP2418524A1 (en) 2003-11-19 2004-11-17 Optical connection structure and optical connection method
HK09105776.0A HK1128332A1 (en) 2003-11-19 2009-06-26 Optical connection structure and optical connection method

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US7583884B2 (en) 2006-04-28 2009-09-01 Tomoegawa Co., Ltd. Refractive index matching tape adhering device
KR20070106420A (en) * 2006-04-28 2007-11-01 가부시키가이샤 도모에가와 세이시쇼 Refractive index matching tape adhering device
EP1850158A1 (en) * 2006-04-28 2007-10-31 Tomoegawa Co., Ltd. Refractive index matching tape adhering device
JP2008070545A (en) * 2006-09-13 2008-03-27 Hitachi Cable Ltd Mechanical splice
US7478954B2 (en) 2006-09-27 2009-01-20 Electronics And Telecommunications Research Institute Structure and method for optical connection between optical transmitter and optical receiver
JP2008164795A (en) * 2006-12-27 2008-07-17 Hitachi Cable Ltd Optical connector
JP2008170879A (en) * 2007-01-15 2008-07-24 Hitachi Cable Ltd Optical connector
JP4636088B2 (en) * 2008-01-16 2011-02-23 日立電線株式会社 Manufacturing method of optical connector
JP2008102556A (en) * 2008-01-16 2008-05-01 Hitachi Cable Ltd Optical connector
JP2009244556A (en) * 2008-03-31 2009-10-22 Tomoegawa Paper Co Ltd Optical connection structure and method
JP2010096903A (en) * 2008-10-15 2010-04-30 Yazaki Corp Optical fiber module and method of manufacturing the same
WO2010092654A1 (en) * 2009-02-12 2010-08-19 株式会社フジクラ Optical connector
US8408814B2 (en) 2009-02-12 2013-04-02 Fujikura Ltd. Optical connector
JP2013092807A (en) * 2009-02-12 2013-05-16 Fujikura Ltd Optical connector
JP5205452B2 (en) * 2009-02-12 2013-06-05 株式会社フジクラ Optical connector
JP2010271387A (en) * 2009-05-19 2010-12-02 Sumitomo Electric Ind Ltd Optical connector and method of assembling the same
JP2011090267A (en) * 2009-10-26 2011-05-06 Furukawa Electric Co Ltd:The Optical fiber end face structure, optical fiber connection structure, optical connector, mechanical splice, and connection method with optical fiber end face structure
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JP2016153849A (en) * 2015-02-20 2016-08-25 株式会社フジクラ Optical fiber connector, mechanical splice, and optical fiber connecting method

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