[go: up one dir, main page]
More Web Proxy on the site http://driver.im/

JP2013015744A - Optical connector - Google Patents

Optical connector Download PDF

Info

Publication number
JP2013015744A
JP2013015744A JP2011149750A JP2011149750A JP2013015744A JP 2013015744 A JP2013015744 A JP 2013015744A JP 2011149750 A JP2011149750 A JP 2011149750A JP 2011149750 A JP2011149750 A JP 2011149750A JP 2013015744 A JP2013015744 A JP 2013015744A
Authority
JP
Japan
Prior art keywords
optical fiber
insertion hole
coating
coated optical
fiber insertion
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Pending
Application number
JP2011149750A
Other languages
Japanese (ja)
Inventor
Shigeo Takahashi
茂雄 高橋
Takashi Yamaguchi
敬 山口
Kazuhiro Takizawa
和宏 瀧澤
Tetsuhiro Numata
哲宏 沼田
Kazutoshi Takamizawa
和俊 高見沢
Tokuhito Naito
徳人 内藤
Koichi Katayose
浩一 片寄
Kouji Ishizuka
晃路 石塚
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
SUZUKI GIKEN KK
Fujikura Ltd
Nippon Telegraph and Telephone Corp
Suzuki Giken Co Ltd
Original Assignee
SUZUKI GIKEN KK
Fujikura Ltd
Nippon Telegraph and Telephone Corp
Suzuki Giken Co Ltd
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by SUZUKI GIKEN KK, Fujikura Ltd, Nippon Telegraph and Telephone Corp, Suzuki Giken Co Ltd filed Critical SUZUKI GIKEN KK
Priority to JP2011149750A priority Critical patent/JP2013015744A/en
Publication of JP2013015744A publication Critical patent/JP2013015744A/en
Pending legal-status Critical Current

Links

Images

Landscapes

  • Mechanical Coupling Of Light Guides (AREA)
  • Light Guides In General And Applications Therefor (AREA)

Abstract

PROBLEM TO BE SOLVED: To allow smooth removal of a coating of a coated optical fiber.SOLUTION: A mechanical splicing part for butt joint between a built-in optical fiber and an inserted optical fiber is provided with a coating removal part for removing a coating of a coated optical fiber, and a coating removing member constituting the coating removal part includes a coated optical fiber insertion-side portion having a coated optical fiber insertion hole, and a coating removal-side portion having a bare fiber insertion hole and a coating removing action portion for removing the coating of the coated optical fiber. An inner diameter of the coated optical fiber insertion hole is approximately equal to an outer diameter of the coating of the coated optical fiber, and the bare fiber insertion hole has an intermediate part having an inner diameter approximately equal to an outer diameter of a bare fiber and has, on the entrance side, a taper hole expanded toward the entrance and has, on the exit side, a diameter larger than the outer diameter of the bare fiber. Collisions with an inner wall of the bare fiber insertion hole, of a front end edge of the bare fiber which has had the coating removed therefrom are reduced, and disconnection of the bare fiber due to axial misalignment from a centering groove for butt joint can be prevented.

Description

この発明は、内蔵光ファイバを内蔵するフェルール部の後部にメカニカルスプライス部を一体に備え、前記メカニカルスプライス部に、被覆付き光ファイバの被覆を剥がす作用をする被覆除去部を備えて被覆付き光ファイバ押込みによる突合せ接続が可能なメカニカルスプライス型の現場組立光コネクタに関する。   According to the present invention, a mechanical splice portion is integrally provided at the rear portion of a ferrule portion that incorporates a built-in optical fiber, and the mechanical splice portion is provided with a coating removing portion that acts to peel off the coating of the coated optical fiber. The present invention relates to an on-site optical connector of mechanical splice type capable of butt connection by pushing.

予め被覆付き光ファイバの被覆を剥がして裸ファイバを露出させることなく、光コネクタに被覆付き光ファイバのまま押し込んで対向光ファイバ(内蔵光ファイバ)と突き合わせ接続する技術が報告されている(非特許文献1)。この報告では、裸ファイバ径が0.125mm、被覆部外径が0.25mmの被覆付き光ファイバを対象としている。
この被覆付き光ファイバ押込みによる突合せ接続は、突合せ部の接続モデルとしては、円錐体の軸芯部に内径126mmの孔(調心部)をあけた被覆除去部材を用い、この円錐体状の被覆除去部材の孔先端部(挿入端)に、被覆付き光ファイバの被覆除去に必要な力以上の力で押し当てて、被覆付き光ファイバの被覆を剥がすというものである。
この細い被覆付き光ファイバを被覆除去部材の孔先端部に押し当てて、薄い被覆を裸ファイバを傷つけずに剥がすにためには、被覆付き光ファイバを極めて高い精度で孔先端部に押し当てる必要があり、したがって、被覆付き光ファイバを高い精度で孔先端部まで案内する必要がある。
A technique has been reported in which a coated optical fiber is pushed into an optical connector as it is without being stripped in advance to expose the bare fiber, and butt-connected to the opposing optical fiber (built-in optical fiber) (non-patented) Reference 1). In this report, a coated optical fiber having a bare fiber diameter of 0.125 mm and a coated portion outer diameter of 0.25 mm is targeted.
For this butt connection by pushing the coated optical fiber, as a connection model of the butt portion, a coating removing member having a hole (alignment portion) having an inner diameter of 126 mm in the axial center portion of the cone is used. The coating of the coated optical fiber is peeled off by pressing against the hole tip (insertion end) of the removing member with a force greater than that required for coating removal of the coated optical fiber.
In order to press this thin coated optical fiber against the hole tip of the coating removal member and peel the thin coating without damaging the bare fiber, it is necessary to press the coated optical fiber against the hole tip with extremely high accuracy. Therefore, it is necessary to guide the coated optical fiber to the hole tip with high accuracy.

細い被覆付き光ファイバを被覆除去部材の孔先端部に押し当ててその被覆を剥がすという、上記のような被覆付き光ファイバ押込みによる被覆除去技術を、実際の現場組立光コネクタにおいて実現するには、多くの部分について、具体的な構造を考案する必要がある。
例えば、特許文献1の光コネクタは、内蔵光ファイバを有する突合せ接続方式の光コネクタでなく、光コネクタに挿入した被覆付光ファイバの被覆を除去した裸ファイバをフェルール部の光ファイバ孔に挿入して、その先端を直接接続端面とするものであるが、この光コネクタは、フェルール部に被覆除去部を設けている。
すなわち、フェルール部に設けた光ファイバ保持孔37を、被覆付き光ファイバの外径と略同一内径の第1孔部53と、裸光ファイバの外径と略同一内径の第2孔部55と、第1孔部53と第2孔部55との間に設けた被覆受け部57とを備えた構成として、被覆付き光ファイバ19を被覆付きのまま装着可能にする、というものである。
To realize the coating removal technology by pushing the coated optical fiber as described above, in which the thin coated optical fiber is pressed against the hole tip of the coating removal member and peeled off, in an actual field assembly optical connector, For many parts, it is necessary to devise concrete structures.
For example, the optical connector of Patent Document 1 is not a butt connection type optical connector having a built-in optical fiber, but a bare fiber obtained by removing the coating of the coated optical fiber inserted into the optical connector is inserted into the optical fiber hole of the ferrule part. In this optical connector, the ferrule part is provided with a coating removal part.
That is, the optical fiber holding hole 37 provided in the ferrule part includes a first hole 53 having an inner diameter substantially the same as the outer diameter of the coated optical fiber, and a second hole 55 having an inner diameter substantially the same as the outer diameter of the bare optical fiber. As a configuration including a coating receiving portion 57 provided between the first hole portion 53 and the second hole portion 55, the coated optical fiber 19 can be mounted with the coating.

特開2009−128422JP2009-128422

2009年電子情報通信学会ソサイエティ大会の通信講演論文集2「被覆付き光ファイバ心線の突合せ接続に関する考察」(B−13−8)。Proceedings 2 of the 2009 IEICE Society Conference “Considerations on Butt Connection of Coated Optical Fiber Cores” (B-13-8).

上記の通り、光コネクタ内に被覆除去部を設けたものとして、フェルール部に被覆除去部を設けたもの(特許文献1)があるが、裸ファイバ径が0.125mm、被覆付き光ファイバの被覆部外径が0.25mmという細い被覆付き光ファイバにおける薄い被覆を、細いフェルール部の内部で裸ファイバを傷つけずにかつきれいに剥がすことは簡単なことではないので、フェルール部内に被覆除去部を設ける構造を実用化するには、種々困難な面があると思われる。   As described above, there is an optical connector provided with a coating removal part (Patent Document 1) in which a ferrule part is provided with a coating removal part, but the bare fiber diameter is 0.125 mm, and the coated optical fiber is coated. Since it is not easy to peel off the thin coating of a thin coated optical fiber having an outer diameter of 0.25 mm without damaging the bare fiber inside the thin ferrule part, a coating removal part is provided in the ferrule part. There seems to be various difficulties in putting the structure into practical use.

ところで、内蔵光ファイバを内蔵するフェルール部の後部にメカニカルスプライス部を一体に備えたメカニカルスプライス部一体型光コネクタの内部に被覆除去部を備えた構造とすれば、現場組立光コネクタとして一層優れたものとなる。
しかし、前記の通り、裸ファイバ径が0.125mm、被覆付き光ファイバの被覆部外径が0.25mmという細い被覆付き光ファイバにおける薄い被覆を、裸ファイバを傷つけずにかつきれいに剥がすことは簡単なことではないので、メカニカルスプライス部一体型光コネクタにおいて内部に被覆除去部を備えた構成とするには種々の点で具体的な構造を考案することが必要となる。
特に、メカニカルスプライス部に設ける被覆除去部の具体的構造が大きく被覆除去性能に影響するので、被覆除去部の構造に種々の工夫が必要となる。
By the way, if the structure with a mechanical splice part integrated optical connector with a mechanical splice part integrated in the rear part of the ferrule part incorporating the built-in optical fiber is provided with a coating removal part, it is more excellent as a field assembly optical connector. It will be a thing.
However, as described above, it is easy to peel off a thin coating on a thin coated optical fiber having a bare fiber diameter of 0.125 mm and a coated optical fiber outer diameter of 0.25 mm without damaging the bare fiber. Therefore, it is necessary to devise specific structures in various respects in order to provide a mechanical splice unit-integrated optical connector having a coating removal unit therein.
In particular, since the specific structure of the coating removal portion provided in the mechanical splice portion greatly affects the coating removal performance, various devices are required for the structure of the coating removal portion.

本発明は上記背景のもとになされたもので、メカニカルスプライス部一体型光コネクタにおいて内部に被覆除去部を備えた構成とする場合に、被覆付光ファイバの被覆をスムーズに除去することが可能な被覆除去部を備えたメカニカルスプライス型の現場組立光コネクタを提供することを目的とする。   The present invention has been made based on the above-mentioned background, and in the case where the optical splicer integrated with a mechanical splice is configured to have a coating removal portion inside, it is possible to smoothly remove the coating of the coated optical fiber. An object of the present invention is to provide a mechanically-spliced on-site optical connector having a coating removal portion.

上記課題を解決する請求項1の発明のメカニカルスプライス型の現場組立光コネクタは、内蔵光ファイバを内蔵したフェルール部と、前記フェルール部の後部に取り付けられて、前記内蔵光ファイバと外部から挿入される光ケーブルの外被を除去した被覆付き光ファイバの被覆を除去した挿入光ファイバとを突き合わせ接続するメカニカルスプライス部と、メカニカルスプライス部における前記内蔵光ファイバと挿入光ファイバとの突合せ部より後方側に設けられて前記被覆付き光ファイバの被覆を除去する被覆除去部とを備え、
前記被覆除去部を構成する被覆除去部材は、
被覆付光ファイバを案内する被覆付光ファイバ挿通孔を有する被覆付光ファイバ挿入側部分と、
前記被覆付光ファイバ挿通孔の前方に設けられ、被覆付光ファイバ挿通孔と同軸の裸ファイバ挿通孔を有するとともにその被覆付光ファイバ挿通孔側の端部に被覆付光ファイバの被覆を除去するための筒状刃が形成された被覆除去作用部を持つ被覆除去側部分とを備え、
前記被覆付光ファイバ挿通孔の内径が被覆付光ファイバの被覆部外径とほぼ同一内径であり、かつ前記裸ファイバ挿通孔の中間部分の内径が前記裸ファイバの外径とほぼ同一内径であり、
前記裸ファイバ挿通孔の裸ファイバ外径とほぼ同一内径である中間部分より入口側がテーパ状に広がるテーパ孔となっており、出口側の内径が前記中間部分の内径より大となっていることを特徴とするメカニカルスプライス型の現場組立光コネクタ。
なお、裸ファイバ挿通孔の裸ファイバ外径とほぼ同一内径である中間部分より入口側の部分は、必ずしもその全体がテーパ孔である場合に限らず、テーパ孔の部分より入口側が、テーパ孔の最大径と同径の均一内径孔があってもよい。
According to a first aspect of the present invention, there is provided a mechanical splice type field assembly optical connector of the present invention, wherein a ferrule part including a built-in optical fiber and a rear part of the ferrule part are attached and inserted from the outside with the built-in optical fiber. A mechanical splice part that butt-connects the optical fiber with the coated optical fiber from which the jacket of the optical cable is removed, and a butt connection between the built-in optical fiber and the inserted optical fiber in the mechanical splice part. A coating removing unit provided to remove the coating of the coated optical fiber,
The coating removal member constituting the coating removal unit is
A coated optical fiber insertion side portion having a coated optical fiber insertion hole for guiding the coated optical fiber;
The coated optical fiber is provided in front of the coated optical fiber insertion hole, has a bare fiber insertion hole coaxial with the coated optical fiber insertion hole, and removes the coating of the coated optical fiber at the end of the coated optical fiber insertion hole side. And a coating removal side portion having a coating removal working portion formed with a cylindrical blade for,
The inner diameter of the coated optical fiber insertion hole is substantially the same inner diameter as the outer diameter of the coated optical fiber, and the inner diameter of the intermediate portion of the bare fiber insertion hole is substantially the same as the outer diameter of the bare fiber. ,
A taper hole is formed such that the inlet side is tapered from the intermediate portion having the same inner diameter as the bare fiber outer diameter of the bare fiber insertion hole, and the inner diameter of the outlet side is larger than the inner diameter of the intermediate portion. A mechanical splice type on-site assembly optical connector.
The portion of the bare fiber insertion hole on the inlet side from the intermediate portion that is substantially the same inner diameter as the bare fiber outer diameter is not limited to the case where the whole is a tapered hole. There may be a uniform inner diameter hole having the same diameter as the maximum diameter.

請求項2は請求項1のメカニカルスプライス型の現場組立光コネクタにおいて、
前記裸ファイバ挿通孔における、出口側の内径が前記中間部分の内径より大となっている部分が出口側に広がるテーパ孔となっていることを特徴とする。
A mechanical splice type field assembly optical connector according to claim 1, wherein
A portion of the bare fiber insertion hole in which the inner diameter on the outlet side is larger than the inner diameter of the intermediate portion is a tapered hole extending to the outlet side.

請求項3は請求項1又は2のメカニカルスプライス型の現場組立光コネクタにおいて、
前記被覆除去側部分の裸ファイバ挿通孔における、裸ファイバ外径とほぼ同一内径である部分の長さが0.05mm〜0.5mmであることを特徴とする。
A mechanical splice type field assembly optical connector according to claim 1 or 2, wherein
The length of the portion having the same inner diameter as the outer diameter of the bare fiber in the bare fiber insertion hole in the coating removal side portion is 0.05 mm to 0.5 mm.

請求項4は請求項1〜3のいずれか1項のメカニカルスプライス型の現場組立光コネクタにおいて、
前記被覆除去部材を、その被覆付光ファイバ挿入側部分と被覆除去側部分とを成形材料にて一体成形したことを特徴とする。
A mechanical splice type field assembly optical connector according to any one of claims 1 to 3,
The coating removal member is formed by integrally molding a coated optical fiber insertion side portion and a coating removal side portion with a molding material.

請求項5は請求項1〜4のいずれか1項のメカニカルスプライス型の現場組立光コネクタにおいて、
前記被覆除去部材を、その被覆付光ファイバ挿入側部分と被覆除去側部分とを樹脂にて一体成形したことを特徴とする。
A mechanical splice type field assembly optical connector according to any one of claims 1 to 4, wherein
The coating removal member is formed by integrally molding a coated optical fiber insertion side portion and a coating removal side portion with a resin.

請求項6は請求項4又は5のメカニカルスプライス型の現場組立光コネクタにおいて、
前記被覆除去部材は、被覆付光ファイバ挿通孔の部分と裸ファイバ挿通孔の部分とを形成する中子として1本のコアピンを用いた金型で一体成形したことを特徴とする。
A mechanical splice type field assembly optical connector according to claim 4 or 5, wherein
The coating removing member is integrally formed with a mold using a single core pin as a core for forming a coated optical fiber insertion hole portion and a bare fiber insertion hole portion.

請求項7は請求項1〜6のいずれか1項のメカニカルスプライス型の現場組立光コネク
前記被覆付光ファイバ挿通孔と裸ファイバ挿通孔との間の隙間寸法が0.1〜0.3mmであることを特徴とする。
The mechanical splice type field assembly optical connector according to any one of claims 1 to 6, wherein a gap between the coated optical fiber insertion hole and the bare fiber insertion hole is 0.1 to 0.3 mm. It is characterized by being.

請求項8は請求項1〜7のいずれか1項のメカニカルスプライス型の現場組立光コネクタにおいて、
前記被覆除去部材の被覆除去作用部は、裸ファイバ挿通孔の入口側に向かって先細りとなって孔先端に前記筒状刃が形成される錐体状部を有し、この錐体状部の側面のテーパ角度が20°〜40°であることを特徴とする。
The mechanical splice type field assembly optical connector according to any one of claims 1 to 7,
The sheath removing action portion of the sheath removing member has a cone-shaped portion that is tapered toward the inlet side of the bare fiber insertion hole and the cylindrical blade is formed at the tip of the hole. The side taper angle is 20 ° to 40 °.

請求項9は請求項1〜7のいずれか1項のメカニカルスプライス型の現場組立光コネクタにおいて、
前記被覆除去部材の被覆除去作用部は、裸ファイバ挿通孔の入口側に向かって凹湾曲状をなして先細りとなって孔先端に前記筒状刃が形成される凹湾曲錐体状部を有することを特徴とする。
A mechanical splice type field assembly optical connector according to any one of claims 1 to 7,
The sheath removing action portion of the sheath removing member has a concavely curved cone-like portion that is tapered toward the inlet side of the bare fiber insertion hole and is tapered to form the cylindrical blade at the tip of the hole. It is characterized by that.

請求項10は請求項1〜9のいずれか1項のメカニカルスプライス型の現場組立光コネクタにおいて、
前記被覆除去部材における被覆付光ファイバ挿通孔と裸ファイバ挿通孔との間に形成される空間が、裸ファイバ挿通孔芯と直交する二方向における、裸ファイバ挿通孔の半径方向両側にいずれも0.5mm以上の隙間を形成していることを特徴とする。
A mechanical splice type field assembly optical connector according to any one of claims 1 to 9,
The space formed between the coated optical fiber insertion hole and the bare fiber insertion hole in the coating removal member is zero on both sides in the radial direction of the bare fiber insertion hole in two directions orthogonal to the bare fiber insertion hole core. A gap of 5 mm or more is formed.

本発明のメカニカルスプライス型の現場組立光コネクタによれば、被覆付光ファイバの被覆を除去する被覆除去部材をメカニカルスプライス部に設けるとともに、被覆付光ファイバ挿通孔を有する被覆付光ファイバ挿入側部分と、裸ファイバ挿通孔を有するとともに被覆付光ファイバの被覆を除去するための筒状刃が形成された被覆除去作用部を持つ被覆除去側部分とを備えた構成とし、
前記被覆付光ファイバ挿通孔の内径が被覆付光ファイバの被覆部外径とほぼ同一内径であり、かつ前記裸ファイバ挿通孔の中間部分の内径が前記裸ファイバの外径とほぼ同一内径であり、前記裸ファイバ挿通孔の裸ファイバ外径とほぼ同一内径である中間部分より入口側がテーパ状に広がるテーパ孔となっており、出口側の内径が前記中間部分の内径より大となっており、裸ファイバ挿通孔の中間部分の内径よりその両側の内径が大きいので、裸ファイバを裸ファイバ挿通孔内に挿通させ易いとともに、被覆を除去された裸ファイバの先端の外周(先端のエッジ)が裸ファイバ挿通孔の内壁にぶつかる(接触する)ことが少なくなる(ぶつかる確率が小さくなる)。
すなわち、被覆を除去した裸光ファイバの外径と同一の内径部分が長ければ長いほど、被覆を除去した裸ファイバが裸ファイバ挿通孔の内壁にぶつかり易くなるが、裸ファイバの外径と同一内径の部分を裸ファイバ挿通孔の一部のみとすることで、ぶつかる確率およびぶつかった場合の距離を短くできる。
また、被覆を除去した裸光ファイバの外径と同一の内径部を含む孔のメカニカルスプライス部調心溝側の出口を広げておくことで、被覆を除去した裸光ファイバの外径と同一の内径部分と調心溝部との軸ずれによる裸ファイバ断線(出口孔縁部(エッジ)による断線)の発生を抑制することができる。
なお、裸ファイバ挿通孔の中間部分より出口側もテーパ状にするのが好ましい。
前記裸光ファイバ外径と同一内径の部分の長さSaは、0.5mm以下にするのが適切であるが、短すぎると調心機能を損なうことと考慮すると、0.05mm〜0.5mmとするのが適切である。
According to the mechanical splice type field assembly optical connector of the present invention, a coated optical fiber insertion side portion having a coated optical fiber insertion hole and a coating removing member for removing the coated optical fiber coating is provided in the mechanical splice portion. And a coating removal side portion having a coating removal working portion in which a cylindrical blade for removing the coating of the coated optical fiber is formed, and has a bare fiber insertion hole,
The inner diameter of the coated optical fiber insertion hole is substantially the same inner diameter as the outer diameter of the coated optical fiber, and the inner diameter of the intermediate portion of the bare fiber insertion hole is substantially the same as the outer diameter of the bare fiber. A taper hole in which the inlet side extends in a taper form from an intermediate part that is substantially the same inner diameter as the bare fiber outer diameter of the bare fiber insertion hole, and the inner diameter of the outlet side is larger than the inner diameter of the intermediate part, Since the inner diameter of both sides is larger than the inner diameter of the middle part of the bare fiber insertion hole, it is easy to insert the bare fiber into the bare fiber insertion hole, and the outer periphery (edge of the tip) of the bare fiber from which the coating has been removed is bare. There is less chance of hitting (contacting) the inner wall of the fiber insertion hole (the probability of hitting is reduced).
In other words, the longer the inner diameter portion that is the same as the outer diameter of the bare optical fiber from which the coating has been removed, the easier it is for the bare fiber from which the coating has been removed to hit the inner wall of the bare fiber insertion hole. By making this part only part of the bare fiber insertion hole, the probability of collision and the distance in case of collision can be shortened.
In addition, by opening the outlet on the side of the aligning groove of the mechanical splice part of the hole including the same inner diameter part as the outer diameter of the bare optical fiber from which the coating is removed, the outer diameter of the bare optical fiber from which the coating is removed is the same. It is possible to suppress the occurrence of a bare fiber breakage (breakage due to an exit hole edge (edge)) due to an axial deviation between the inner diameter portion and the aligning groove portion.
It is preferable that the outlet side is also tapered from the middle portion of the bare fiber insertion hole.
The length Sa of the same inner diameter as that of the bare optical fiber is suitably 0.5 mm or less. However, if the length Sa is too short, the alignment function is impaired. Is appropriate.

請求項4によれば、被覆除去部材の被覆付光ファイバ挿入側部分と被覆除去側部分とを一体成形したものなので、被覆付光ファイバ挿入側部分の被覆付光ファイバ挿通孔と被覆除去側部分の裸ファイバ挿通孔との両孔芯を精度よく一致させることができ、被覆除去をスムーズに行うことができ、被覆除去性能を高めることができる。
また、この被覆除去部材をメカニカルスプライス部に装着する際に、被覆付光ファイバ挿入側部分及び被覆除去作用部分とについてそれぞれを調心して固定する必要がないので、作業性がよいし、高い調心精度を確保し易い。
また、一体成形品であるから、量産可能であり、コストを低減できる。
また、被覆付光ファイバ挿通孔の部分と裸ファイバ挿通孔の部分とを形成する中子として1本のコアピンを用いた金型で一体成形すると、被覆付光ファイバ挿入側部分の被覆付光ファイバ挿通孔と被覆除去側部分の裸ファイバ挿通孔との両孔芯をさらに高精度に一致させることができる。
According to the fourth aspect, since the coated optical fiber insertion side portion and the coating removal side portion of the coating removal member are integrally formed, the coated optical fiber insertion hole and the coating removal side portion of the coated optical fiber insertion side portion Both cores with the bare fiber insertion hole can be made to coincide with each other with high accuracy, the coating removal can be performed smoothly, and the coating removal performance can be enhanced.
In addition, when attaching the coating removal member to the mechanical splice, it is not necessary to align and fix the coated optical fiber insertion side portion and the coating removal working portion, so that workability is good and high alignment is achieved. It is easy to ensure accuracy.
Moreover, since it is an integrally molded product, it can be mass-produced and the cost can be reduced.
Further, when a single core pin is used as a core for forming the coated optical fiber insertion hole portion and the bare fiber insertion hole portion, the coated optical fiber on the coated optical fiber insertion side portion is formed. Both hole cores of the insertion hole and the bare fiber insertion hole on the coating removal side portion can be matched with higher accuracy.

請求項7によれば、被覆付光ファイバ挿通孔と裸ファイバ挿通孔との間の隙間寸法aを0.1〜0.3mmとしたので、被覆付光ファイバの被覆を除去する機能を有効に果たすことが可能となる。
すなわち、隙間aが長いと被覆付光ファイバが座屈して被覆を除去することができなくなる。また、隙間aが短すぎると、実質的に被覆の剛性が高くなるので、被覆除去部材の刃の鋭さに限界があることで、被覆が破れずに裸ファイバに沿って波付けパイプのような状態のまま滑ってしまう恐れがある。しかし、0.1〜0.3mmという適切な隙間寸法aとすると、そのような現象を起こさずに、スムーズに被覆を除去することができ、被覆付光ファイバの被覆を除去する機能を有効に果たすことが可能となる。
According to the seventh aspect, since the gap dimension a between the coated optical fiber insertion hole and the bare fiber insertion hole is set to 0.1 to 0.3 mm, the function of removing the coating of the coated optical fiber is made effective. Can be fulfilled.
That is, if the gap a is long, the coated optical fiber is buckled and the coating cannot be removed. Further, if the gap a is too short, the rigidity of the coating is substantially increased. Therefore, there is a limit to the sharpness of the blade of the coating removing member, so that the coating does not break and is similar to a corrugated pipe along the bare fiber. There is a risk of slipping. However, when the appropriate gap size is 0.1 to 0.3 mm, the coating can be removed smoothly without causing such a phenomenon, and the function of removing the coating of the coated optical fiber is effective. Can be fulfilled.

請求項8において、被覆除去部材の被覆除去作用部は、先端に筒状刃が形成される錐体状部を有している。この錐体状部の側面のテーパ角度が10°程度以下であれば、筒状刃の刃先が薄くなり過ぎて、強度が弱くなり破損し易くなり、一方、45°以上であれば、筒状刃の刃先の切れ味が鈍って、被覆除去する際に必要な押込み力(被覆除去力)が増大する。しかし、錐体状部の側面のテーパ角度を20°〜40°の範囲にすると、強度を確保しながら、被覆除去する際に必要な押込み力を低減させることができる。
また、請求項9のように、錐体状部の側面を先端に向かって凹湾曲状をなす形状とすると、筒状刃の刃先では薄くしても刃先から離れるにつれて厚くなる。したがって、切れ味と強度とを兼ね備えた筒状刃を得ることができる。
また、錐体状部の側面が凹湾曲していることで、筒状刃の刃先で切り込んだ筒状の被覆を凹湾曲の側面に沿って押し広げる作用が大となり、筒状の被覆に亀裂が入り易くなり、被覆屑が複数に裂かれ易くなるので、被覆屑を裸ファイバから剥がす作用が効果的に行われる。すなわち、被覆が裸ファイバに沿って波付けパイプのような状態のまま滑ってしまうことを防止する効果がある。これにより被覆除去性能が向上する。
また、被覆が複数に裂かれて複数本に分解された被覆屑となり易いので、被覆屑を収納し易くなる。
また、錐体状部を角錐体状にした場合には、角錐の稜線のエッジ部で被覆が複数に裂かれ易くなる。
In Claim 8, the coating removal action part of a coating removal member has the cone-shaped part by which a cylindrical blade is formed in the front-end | tip. If the taper angle of the side surface of this cone-shaped portion is about 10 ° or less, the cutting edge of the cylindrical blade becomes too thin and the strength is weakened and easily breaks. The sharpness of the blade edge becomes dull, and the pushing force (coating removal force) required for removing the coating increases. However, when the taper angle of the side surface of the cone-shaped portion is in the range of 20 ° to 40 °, it is possible to reduce the pushing force required for removing the coating while securing the strength.
Further, when the side surface of the cone-shaped portion is concavely curved toward the tip as in the ninth aspect, the thickness of the blade edge of the cylindrical blade becomes thicker as it goes away from the edge. Therefore, a cylindrical blade having both sharpness and strength can be obtained.
In addition, since the side surface of the cone-shaped part is concavely curved, the action of spreading the cylindrical coating cut by the cutting edge of the cylindrical blade along the side surface of the concave curved surface becomes large, and the cylindrical coating is cracked. Since the coating waste is easily split into a plurality of pieces, the action of peeling the coating waste from the bare fiber is effectively performed. That is, there is an effect of preventing the coating from sliding along the bare fiber in a state like a corrugated pipe. Thereby, the coating removal performance is improved.
In addition, since the coating is easily split into a plurality of pieces and decomposed into a plurality of pieces, it becomes easy to store the covering waste.
Further, when the pyramidal portion is formed into a pyramid shape, the covering is easily split into a plurality at the edge portion of the pyramid ridgeline.

請求項10によれば、被覆除去部材の被覆付光ファイバ挿通孔と裸ファイバ挿通孔との間に形成される空間が、裸ファイバ挿通孔芯と直交する二方向(実質的に厚み方向と幅方向)における、裸ファイバ挿通孔の半径方向両側にいずれも0.5mm以上の隙間を有するので、被覆屑を収納するスペースを確保することができる。これにより、被覆除去長さを長くすることができる。   According to the tenth aspect, the space formed between the coated optical fiber insertion hole and the bare fiber insertion hole of the coating removal member has two directions (substantially the thickness direction and width) perpendicular to the bare fiber insertion hole core. Direction), both have a gap of 0.5 mm or more on both sides in the radial direction of the bare fiber insertion hole, so that a space for storing the covering waste can be secured. Thereby, the coating removal length can be increased.

本発明のメカニカルスプライス型の現場組立光コネクタの一実施例の斜視図であり、光コネクタを光ケーブルの被覆付き光ファイバに押込み補助治具及びクサビ部材を用いて取り付ける状況を示す図である。It is a perspective view of one Example of the mechanical splice type field assembly optical connector of the present invention, and is a figure showing the situation where an optical connector is attached to an optical fiber with a covering of an optical cable using a pushing auxiliary jig and a wedge member. 図1において、押込み補助治具及びクサビ部材を除いて示した斜視図である。In FIG. 1, it is the perspective view shown except the pushing auxiliary | assistance jig | tool and the wedge member. (a)は図2の平面図、(b)は同正面図、(c)は同底面図である。(A) is a plan view of FIG. 2, (b) is the same front view, and (c) is the same bottom view. 上記光コネクタの縦断面を一部を省略しかつ簡略化して示した図である。It is the figure which abbreviate | omitted and simplified and showed the longitudinal cross-section of the said optical connector. 上記光コネクタにおけるプラグフレームの斜視図である。It is a perspective view of the plug frame in the optical connector. 図5のプラグフレームの詳細を示すもので、(a)は平面図、(b)は正面図、(c)は(b)のA−A断面図、(d)は(a)のB−B断面図、(e)は(a)のB’−B’断面図である。5A and 5B show details of the plug frame of FIG. 5, where FIG. 5A is a plan view, FIG. 5B is a front view, FIG. 5C is a cross-sectional view taken along line AA in FIG. B sectional drawing, (e) is B'-B 'sectional drawing of (a). 上記光コネクタにおけるストップリングの斜視図である。It is a perspective view of the stop ring in the above-mentioned optical connector. 図7のストップリングの詳細を示すもので、(a)は平面図、(b)は正面図、(c)は底面図、(d)は(a)のC−C断面図、(e)は(b)のD−D断面図、(f)は(b)の左側面図、(g)は(b)の右側面図である。7A and 7B show details of the stop ring of FIG. 7, (a) is a plan view, (b) is a front view, (c) is a bottom view, (d) is a cross-sectional view taken along the line CC in (a), (B) is a DD sectional view of (b), (f) is a left side view of (b), and (g) is a right side view of (b). 上記光コネクタにおける可動ガイドの斜視図である。It is a perspective view of the movable guide in the said optical connector. 図9の可動ガイドの詳細を示すもので、(a)は正面図、(b)は平面図、(c)は底面図、(d)は(a)の左側面図、(e)は(a)の右側面図である。9A and 9B show details of the movable guide of FIG. 9, (a) is a front view, (b) is a plan view, (c) is a bottom view, (d) is a left side view of (a), and (e) is ( It is a right view of a). 図10(b)のE−E断面図である。It is EE sectional drawing of FIG.10 (b). 上記光コネクタの内部の部材であるメカニカルスプライス部のベース部の詳細を示すもので、(a)はベース部の正面図、(b)は同平面図、(c)は(a)のF−F断面図、(d)は(b)の右側面図、(e)は(a)のG−G断面図である。The detail of the base part of the mechanical splice part which is a member inside the said optical connector is shown, (a) is a front view of a base part, (b) is the same top view, (c) is F- of (a). F sectional drawing, (d) is a right view of (b), (e) is GG sectional drawing of (a). 図12のベース部に取り付けられる開放ガイドを示すもので、(a)は底面図(図12(c)に対応する図)、(b)は(a)を下から見た図、(d)は(a)の2倍に拡大した左側面図である。12A and 12B show open guides attached to the base portion of FIG. 12, where FIG. 12A is a bottom view (a view corresponding to FIG. 12C), FIG. 12B is a view of FIG. FIG. 3 is a left side view enlarged twice as much as (a). 図12(a)のベース部にフェルールを固定したものに蓋、可動ガイド、被覆除去部材を装着した状態をクサビ部材とともに示す図である。It is a figure which shows the state which attached | attached the cover, the movable guide, and the coating | coated removal member to what fixed the ferrule to the base part of Fig.12 (a) with a wedge member. (a)は図12(d)を拡大した図、(b)は図14の右側面図である。(A) is the figure which expanded FIG.12 (d), (b) is the right view of FIG. 図1〜図3における外被把持部材を蓋体を開いた状態で示した斜視図である。It is the perspective view which showed the jacket holding member in FIGS. 1-3 in the state which opened the cover body. 図14における被覆除去部材を拡大して示したもので、(a)は斜視図、(b)は、被覆付き光ファイバの被覆を除去する状況を併せて示した平面図である。FIG. 15 is an enlarged view of the coating removing member in FIG. 14, (a) is a perspective view, and (b) is a plan view illustrating a situation where the coating of the coated optical fiber is removed. 図16に示した被覆除去部材の詳細構造を示すもので、(a)は平面図、(b)は左側面図、(c)は右側面図、(d)は(a)のK−K断面図、(e)は(d)の要部のJ−J断面図である。FIG. 17 shows a detailed structure of the coating removing member shown in FIG. 16, wherein (a) is a plan view, (b) is a left side view, (c) is a right side view, and (d) is a KK of (a). Sectional drawing and (e) are JJ sectional drawings of the principal part of (d). (a)、(b)、(c)は被覆除去部材の錐体状部が円錐体状部の場合における側面のテーパ角度について説明するもので、(a)は角度θが40°の場合、(b)は角度θが20°の場合、(c)は円錐体状部の側面が凹湾曲面の場合である。 (d)、(e)、(f)は錐体状部が角錐体状部の場合における角錐体状部を正面から見た図(図21(e)に相当する図)であり、(d)は角錐体状部が四角錐体状部の場合、(e)は(d)の四角錐体状部の側面が凹湾曲面の場合、(f)は錐体状部が三角錐体状部でありかつその側面が凹湾曲面である場合を示す。(A), (b), (c) explains the taper angle of the side surface when the cone-shaped portion of the sheath removal member is a cone-shaped portion, (a), when the angle θ is 40 °, (B) is the case where the angle θ is 20 °, and (c) is the case where the side surface of the conical portion is a concave curved surface. (D), (e), (f) is a diagram (a diagram corresponding to FIG. 21 (e)) of the pyramid-shaped portion viewed from the front when the pyramidal-shaped portion is a pyramid-shaped portion; ) Is when the pyramid-shaped portion is a quadrangular pyramid-shaped portion, (e) is when the side surface of the quadrangular pyramid-shaped portion of (d) is a concave curved surface, and (f) is when the pyramid-shaped portion is a triangular pyramid shape. It is a case and the side surface is a concave curved surface. 被覆除去部材における被覆除去側部分45の裸ファイバ挿通孔の形状についての変形例を示すもので、(a)は被覆除去部材の平面図、(b)は左側面図、(c)は右側面図、(d)は(a)のL−L断面図である。The modification about the shape of the bare fiber penetration hole of the coating removal side part 45 in a coating removal member is shown, (a) is a top view of a coating removal member, (b) is a left view, (c) is a right side FIG. 4D is an LL cross-sectional view of FIG. 被覆除去部材における被覆除去側部分45の裸ファイバ挿通孔の形状についての他の変形例を示すもので、被覆除去部材の図23(d)に相当する断面図である。FIG. 24 is a sectional view showing another modification of the shape of the bare fiber insertion hole of the coating removal side portion 45 in the coating removal member and corresponding to FIG. 23D of the coating removal member. 上記の被覆除去部材を樹脂一体成形する金型を模式的に示したもので、(a)は金型の上型と下型とを合せた状態(コアピンは不図示)で示した断面図、(b)は(a)の下型にコアピンを配置した状態を示す平面図(M−M矢視図にコアピンを図示したもの)である。FIG. 2 schematically shows a mold for integrally molding the above-described coating removal member with resin, (a) is a cross-sectional view showing a state in which the upper mold and the lower mold of the mold are combined (the core pin is not shown); (B) is a top view (what showed the core pin in the MM arrow line view) which shows the state which has arrange | positioned the core pin in the lower mold | type of (a).

以下、本発明を実施したメカニカルスプライス型の現場組立光コネクタについて、図面を参照して説明する。   DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a mechanical splice type field assembly optical connector embodying the present invention will be described with reference to the drawings.

図1は本発明の一実施例のメカニカルスプライス型の現場組立光コネクタ1の斜視図であり、メカニカルスプライス型の現場組立光コネクタ1を光ケーブル4の被覆付き光ファイバ5に押込み補助治具14及びクサビ部材15を用いて取り付ける状況を示す図である。図2は図1において、押込み補助治具14及びクサビ部材15を除いて示した斜視図、図3(a)は図2の平面図、(b)は同正面図、(c)は同底面図である。図4は上記メカニカルスプライス型の現場組立光コネクタ1の内部構造の概略を示す縦断面図であり、一部を省略しかつ簡略化して示している。   FIG. 1 is a perspective view of a mechanical splice type field assembly optical connector 1 according to an embodiment of the present invention. The mechanical splice type field assembly optical connector 1 is pushed into a coated optical fiber 5 of an optical cable 4 and an auxiliary jig 14 and It is a figure which shows the condition attached using the wedge member. 2 is a perspective view of FIG. 1 excluding the pushing assist jig 14 and the wedge member 15, FIG. 3 (a) is a plan view of FIG. 2, (b) is the front view thereof, and (c) is the bottom view thereof. FIG. FIG. 4 is a longitudinal sectional view showing an outline of the internal structure of the above-mentioned mechanical splice type field assembly optical connector 1, and a part thereof is omitted and simplified.

このメカニカルスプライス型の現場組立光コネクタ(以下、略して単に光コネクタともいう)1は、内蔵光ファイバ(裸ファイバ)2を内蔵したフェルール部3と、前記フェルール部3の後部に一体に取り付けられて、前記内蔵光ファイバ2と外部から挿入される光ケーブル4の外被4aを除去した被覆付き光ファイバ5の被覆5aを除去された挿入光ファイバ(図17に符号6で示す)とを突き合わせ接続するメカニカルスプライス部7と、前記フェルール部3とメカニカルスプライス部7とが一体化されたメカニカルスプライス部一体化フェルール部8をその前進限を規定して前後に摺動可能に収容するプラグフレーム9と、前記プラグフレーム9に固定されるとともに前記メカニカルスプライス部7をC形板バネ26を介して前方に弾性的に付勢するストップリング10と、コネクタ後端部で前記光ケーブル4の外被4aを把持する外被把持部材11とを備えている。
前記被覆付光ファイバ5の被覆部の外径は0.25mm、被覆を除去した裸ファイバの外径は0.125mmである。
This mechanical splice type field assembly optical connector (hereinafter also simply referred to as an optical connector) 1 is integrally attached to a ferrule part 3 having a built-in optical fiber (bare fiber) 2 and a rear part of the ferrule part 3. Then, the built-in optical fiber 2 and the inserted optical fiber (indicated by reference numeral 6 in FIG. 17) from which the coating 5a of the coated optical fiber 5 from which the jacket 4a of the optical cable 4 inserted from the outside is removed are butt-connected. A mechanical splice portion 7, and a plug frame 9 that accommodates a mechanical splice portion integrated ferrule portion 8, in which the ferrule portion 3 and the mechanical splice portion 7 are integrated, with a forward limit thereof slidably moved back and forth. The mechanical splice 7 is fixed to the plug frame 9 and is moved forward through a C-shaped leaf spring 26. A stop ring 10 for biased, and a jacket gripping member 11 for gripping the envelope 4a of the optical cable 4 with the connector rear end.
The outer diameter of the coated portion of the coated optical fiber 5 is 0.25 mm, and the outer diameter of the bare fiber from which the coating is removed is 0.125 mm.

図5は前記プラグフレーム9の斜視図、図6(a)はプラグフレーム9の平面図、(b)は正面図、(c)は(b)のA−A断面図、(d)は(a)のB−B断面図、(e)は(a)のB’−B’断面図である。
プラグフレーム9は、前記の通りメカニカルスプライス部一体化フェルール部8をその前進限を規定して前後に摺動可能に収容するもので、メカニカルスプライス部一体化フェルール部8の鍔部8aを摺動可能に嵌合させる円筒内面9aを持ち、その先端の段差部9bによって前進限を規定する。また、ストップリング10の前方側の円筒部分10aを嵌入させる円筒内面9cを有する。9dはカバー13の側面にあけた穴部に係合してカバー13を係止する係止部分、9eはストップリング10の係合突起10bに係合してストップリング10を係止する係止部である。9fはクサビ部材15の差込片15aを通過させる孔である。
カバー13は、プラグフレーム9の部分に装着されており、光コネクタ接続の際に挿入するアダプタ内面形状に合せた外形を有するが、コネクタの種類によってカバーの形状及びプラグフレームの形状が変わる。
5 is a perspective view of the plug frame 9, FIG. 6A is a plan view of the plug frame 9, FIG. 5B is a front view, FIG. 5C is a cross-sectional view taken along line AA in FIG. a) BB sectional drawing of (a), (e) is B'-B 'sectional drawing of (a).
As described above, the plug frame 9 accommodates the mechanical splice unit integrated ferrule unit 8 so as to be slidable back and forth with its advance limit, and slides on the flange 8a of the mechanical splice unit integrated ferrule unit 8. It has a cylindrical inner surface 9a to be fitted, and a forward limit is defined by a step 9b at the tip. Further, it has a cylindrical inner surface 9 c into which the cylindrical portion 10 a on the front side of the stop ring 10 is fitted. 9d is a locking portion that engages with a hole formed in the side surface of the cover 13 to lock the cover 13, and 9e is a locking portion that engages with the engagement protrusion 10b of the stop ring 10 to lock the stop ring 10. Part. 9 f is a hole through which the insertion piece 15 a of the wedge member 15 passes.
The cover 13 is attached to the portion of the plug frame 9 and has an outer shape that matches the shape of the inner surface of the adapter that is inserted when the optical connector is connected. The shape of the cover and the shape of the plug frame vary depending on the type of connector.

図7は前記光コネクタにおけるストップリング10の斜視図、図8(a)はストップリング10の平面図、(b)は正面図、(c)は底面図、(d)は(a)のC−C断面図、(e)は(b)のD−D断面図、(f)は(b)の左側面図、(g)は(b)の右側面図である。
ストップリング10は、前記の通り、その円筒部分10aがプラグフレーム9内に嵌合し係合突起10bで係止されるとともに、メカニカルスプライス部7をコイルバネ27を介して前方に弾性的に付勢する。円筒部分10aと反対側の後端側に、後述の可動ガイド21の被覆付光ファイバ誘導部24を収容するコ字形枠部10cで囲まれた空間10c’を持つ。コ字形枠部10cの両側壁10dの内面に可動ガイド21を案内する溝10eを持つ。10fはクサビ部材15の差込片15aを通過させる孔である。
ストップリング10の上部には、外被把持部材11が脱落しないように拘束する前記レバー12がヒンジ軸12aにより回転可能に取り付けられている。
7 is a perspective view of the stop ring 10 in the optical connector, FIG. 8 (a) is a plan view of the stop ring 10, (b) is a front view, (c) is a bottom view, and (d) is C in (a). -C sectional drawing, (e) is DD sectional drawing of (b), (f) is a left view of (b), (g) is a right view of (b).
As described above, the cylindrical portion 10a of the stop ring 10 is fitted into the plug frame 9 and locked by the engaging projection 10b, and the mechanical splice portion 7 is elastically biased forward via the coil spring 27. To do. On the rear end side opposite to the cylindrical portion 10a, there is a space 10c ′ surrounded by a U-shaped frame portion 10c that houses a coated optical fiber guiding portion 24 of the movable guide 21 described later. A groove 10e for guiding the movable guide 21 is provided on the inner surface of both side walls 10d of the U-shaped frame portion 10c. 10 f is a hole through which the insertion piece 15 a of the wedge member 15 passes.
On the top of the stop ring 10, the lever 12 for restraining the outer cover gripping member 11 from falling off is attached rotatably by a hinge shaft 12a.

ストップリング10内には、図9〜図11に示す可動ガイド21の円筒部分22が挿入されている。図9は可動ガイド21の斜視図、図10(a)は可動ガイドの正面図、(b)は平面図、(c)は底面図、(d)は(a)の左側面図、(e)は(a)の右側面図である。図11は図10(b)のE−E断面図である。
可動ガイド21は、詳細は後述するが、図14、図17に示した被覆除去部材20に被覆付き光ファイバ5を押し当ててその被覆5aを除去する被覆除去中に、前記押し当て力で被覆付き光ファイバ5が座屈しない程度の光ファイバ長さ方向の許容隙間mを確保するための被覆付光ファイバ保持構造の一部をなす部材である。前記許容隙間mは2.1mm程度とされている。
この可動ガイド21は、円筒外周面を持つ筒状部22を備えて、この筒状部22が前記メカニカルスプライス部7に被せられるとともに、筒状部22の円筒外周面がストップリング10内に摺動可能に嵌装されており、メカニカルスプライス部7に対して前後方向に移動可能である。
この可動ガイド21は、前記筒状部22の後端に、被覆付光ファイバ5を導入する概略角形の被覆付光ファイバ誘導部24を一体に備えている。この被覆付光ファイバ誘導部24は、図11にも示すように、円錐面状の案内面24aの先端に被覆付光ファイバ径より僅かに大きな内径の被覆付光ファイバ挿通孔24bを備えている。
前記筒状部22の筒状中空部23は被覆付光ファイバ誘導部24の内部まで延出しており、被覆付光ファイバ誘導部24の突き当り部に垂直内壁24cを有する。この垂直内壁24cが後述するように、開放ガイド31の後端面を押す。外被把持部材11で押されて前進する可動ガイド21はその垂直内壁24cがメカニカルスプライス部7の後端面に当たって止まる。この時点では、メカニカルスプライス部7のベース部30の設けた突起30fが、可動ガイド21に設けた係止孔22bに入り込んでいるので、可動ガイド21はその位置から後退しない。
なお、被覆付光ファイバ誘導部24の円錐状の案内面24a及び被覆付光ファイバ挿通孔24bは、その一部を可動片25の案内面25a及び部分孔面25bが形成している。図9ではこの可動片25を外した状態で示している。
なお、被覆付光ファイバ誘導部24の側面には、外被把持部材11の後述するアーム50が通過する溝24dが形成されている。22aはクサビ部材15の差込片15aを通過させる孔である。なお、その他の孔(開口)もある。
なお、図10に示したロックレバー35は、詳細説明は省略するが、可動ガイド21を位置決めされた所定の位置にセットしておき、光ケーブル4の外被を把持した外被把持部材11を前進させて被覆付光ファイバ5を前進させる際に、外被把持部材11が適切なタイミングで可動ガイド21を前方に移動させるように、その適切なタイミングまで可動ガイド21の前進を拘束するためのロック機能を持つ。
A cylindrical portion 22 of the movable guide 21 shown in FIGS. 9 to 11 is inserted into the stop ring 10. 9 is a perspective view of the movable guide 21, FIG. 10A is a front view of the movable guide, FIG. 9B is a plan view, FIG. 9C is a bottom view, FIG. 9D is a left side view of FIG. ) Is a right side view of (a). FIG. 11 is a cross-sectional view taken along line EE in FIG.
Although the details will be described later, the movable guide 21 is coated with the pressing force during the coating removal, in which the coated optical fiber 5 is pressed against the coating removing member 20 shown in FIGS. 14 and 17 to remove the coating 5a. This is a member that constitutes a part of the coated optical fiber holding structure for securing the allowable gap m in the optical fiber length direction such that the attached optical fiber 5 does not buckle. The allowable gap m is about 2.1 mm.
The movable guide 21 includes a cylindrical portion 22 having a cylindrical outer peripheral surface. The cylindrical portion 22 is covered with the mechanical splice portion 7, and the cylindrical outer peripheral surface of the cylindrical portion 22 is slid into the stop ring 10. It is movably fitted and is movable in the front-rear direction with respect to the mechanical splice part 7.
This movable guide 21 is integrally provided with a coated optical fiber guiding portion 24 having a substantially square shape for introducing the coated optical fiber 5 at the rear end of the cylindrical portion 22. As shown in FIG. 11, the coated optical fiber guiding portion 24 includes a coated optical fiber insertion hole 24b having an inner diameter slightly larger than the coated optical fiber diameter at the tip of the conical guide surface 24a. .
The cylindrical hollow portion 23 of the cylindrical portion 22 extends to the inside of the coated optical fiber guiding portion 24, and has a vertical inner wall 24c at the abutting portion of the coated optical fiber guiding portion 24. As will be described later, the vertical inner wall 24c pushes the rear end surface of the opening guide 31. The movable guide 21 that is pushed forward by the outer gripping member 11 stops when the vertical inner wall 24c hits the rear end surface of the mechanical splice portion 7. At this time, since the protrusion 30f provided on the base portion 30 of the mechanical splice portion 7 enters the locking hole 22b provided on the movable guide 21, the movable guide 21 does not retract from the position.
The conical guide surface 24a and the coated optical fiber insertion hole 24b of the coated optical fiber guiding portion 24 are partially formed by the guide surface 25a and the partial hole surface 25b of the movable piece 25. FIG. 9 shows the movable piece 25 removed.
A groove 24d through which an arm 50 (described later) of the jacket holding member 11 passes is formed on the side surface of the coated optical fiber guiding portion 24. 22a is a hole through which the insertion piece 15a of the wedge member 15 passes. There are other holes (openings).
Although the detailed description of the lock lever 35 shown in FIG. 10 is omitted, the movable guide 21 is set at a predetermined position where the outer cover holding member 11 holding the outer cover of the optical cable 4 is advanced. Thus, when the coated optical fiber 5 is advanced, the lock for restricting the advancement of the movable guide 21 to the appropriate timing so that the outer gripping member 11 moves the movable guide 21 forward at the appropriate timing. Has function.

図12は上記光コネクタ1におけるメカニカルスプライス部7の詳細を示すもので、(a)はメカニカルスプライス部7のベース部30の正面図、(b)は同平面図、(c)は(a)のF−F断面図、(d)は(b)の右側面図、(e)は(a)のG−G断面図である。図13は図12のベース部に取り付けられる開放ガイド31を示すもので、(a)は底面図(図12(c)に対応する図)、(b)は(a)を下面から見た図、(d)は(a)の2倍に拡大した左側面図である。
メカニカルスプライス部7は、ベース部30とこのベース部30に被せられる蓋部33と前記ベース部30と蓋部33とを弾性的にクランプするC形板バネとを備えるとともに、ベース部30の蓋部33との合わせ面10cに、内蔵光ファイバ2と挿入光ファイバ6とを収容する調心溝32a及び前記被覆付き光ファイバ5の部分を収容する被覆部収容溝32bを一直線上に備えた構造である。また、被覆部収容溝32bと調心溝32aとの間に、被覆除去部材20を装着する凹所30aを設けている。30b(30b、30b、30b、30b)は、クサビ部材15が差し込まれるクサビ差込部である。このクサビ差込部30bの部分以外の部分はベース部30の合せ面30cより隆起した隆起部30dとなっている。また、ベース部30の合せ面30cに、開放ガイド31を斜めに移動させる作用をする斜め凸条30eを設けている。
12A and 12B show details of the mechanical splice portion 7 in the optical connector 1. FIG. 12A is a front view of the base portion 30 of the mechanical splice portion 7, FIG. 12B is a plan view thereof, and FIG. FF sectional drawing of (b), (d) is a right view of (b), (e) is GG sectional drawing of (a). FIGS. 13A and 13B show the open guide 31 attached to the base portion of FIG. 12, where FIG. 13A is a bottom view (a view corresponding to FIG. 12C), and FIG. 13B is a view of FIG. , (D) is a left side view enlarged twice as large as (a).
The mechanical splice portion 7 includes a base portion 30, a lid portion 33 that covers the base portion 30, a C-shaped leaf spring that elastically clamps the base portion 30 and the lid portion 33, and a lid for the base portion 30. The alignment surface 10c with the portion 33 is provided with an alignment groove 32a for accommodating the built-in optical fiber 2 and the insertion optical fiber 6 and a covering portion receiving groove 32b for accommodating the portion of the coated optical fiber 5 in a straight line. It is. Further, a recess 30a for mounting the coating removing member 20 is provided between the coating portion receiving groove 32b and the alignment groove 32a. 30b (30b 1, 30b 2, 30b 3, 30b 4) is a wedge insertion portion which wedge member 15 is inserted. The portions other than the wedge insertion portion 30 b are raised portions 30 d that are raised from the mating surface 30 c of the base portion 30. In addition, oblique ridges 30 e that act to move the open guide 31 obliquely are provided on the mating surface 30 c of the base portion 30.

開放ガイド31は、図13に示すように、概ね長方形断面の角部に被覆付光ファイバ5を把持するための円弧部と直線部とを持つ切欠き31aを有し、また、ベース部30の合せ面30cの斜め凸条30eに嵌合する斜め凹溝31bを持つ。
図14は 図12(a)のメカニカルスプライス部7にフェルール部3を一体化したメカニカルスプライス部一体化フェルール部8のベース部30に蓋33、開放ガイド31、被覆除去部材20を装着した状態をクサビ部材15ととも簡略化して示す図である。また、可動ガイド21を2点鎖線で示す。
As shown in FIG. 13, the open guide 31 has a notch 31 a having a circular arc part and a straight part for gripping the coated optical fiber 5 at a corner part of a substantially rectangular cross section. There is an oblique groove 31b that fits into the oblique protrusion 30e of the mating surface 30c.
FIG. 14 shows a state in which a cover 33, an opening guide 31, and a sheath removing member 20 are mounted on the base 30 of the mechanical splice unit integrated ferrule unit 8 in which the ferrule unit 3 is integrated with the mechanical splice unit 7 of FIG. It is a figure simplified and shown with the wedge member. The movable guide 21 is indicated by a two-dot chain line.

図15(a)は図12(d)を拡大した図、(b)は(a)に開放ガイド31及び蓋部33を装着した状態で示した図である。   FIG. 15A is an enlarged view of FIG. 12D, and FIG. 15B is a view showing the state in which the opening guide 31 and the lid 33 are attached to FIG.

被覆付光ファイバの被覆を除去する被覆除去部材20は、図17、図18に示すように、厚みの薄い直方体の前方寄りの位置に図示例では貫通の空所40が形成された樹脂一体成形品であり、被覆付光ファイバ5を案内する被覆付光ファイバ挿通孔42を有する被覆付光ファイバ挿入側部分44と、前記被覆付光ファイバ挿通孔42の前方に設けられ、被覆付光ファイバ挿通孔42と同軸の裸ファイバ挿通孔41を有するとともにその被覆付光ファイバ挿通孔42側の端部に被覆付光ファイバ5の被覆を除去するための筒状刃43aが形成された被覆除去作用部43を持つ被覆除去側部分45とを備えている。
前記被覆付光ファイバ挿通孔42の内径Dは被覆付光ファイバ5の被覆部外径とほぼ同一内径であり、かつ前記裸ファイバ挿通孔41の内径dは裸ファイバ6の外径とほぼ同一内径である。なお、被覆付光ファイバ挿通孔42は被覆付光ファイバ5の被覆部外径とほぼ同一内径Dの部分の入口側の部分が入口側に向かったテーパ状に拡がっている。
この被覆除去作用部43の先端部(すなわち筒状刃)43aに、被覆付光ファイバ挿通孔42を通した被覆付光ファイバ5を押し当てることで、被覆付光ファイバ5の被覆を裸ファイバから剥がすように除去する。
被覆5aは、例えば円周方向の2、3箇所で光ファイバ長さ方向に裂けるなどして、裸ファイバ6から除去される。図17(b)に示すように、除去される被覆(被覆屑)5a’は、被覆付き光ファイバ5の被覆5aから取り去られるのでなく、根元の部分で被覆付き光ファイバ5の被覆5aに繋がった状態で裸ファイバ6から剥される。
As shown in FIGS. 17 and 18, the coating removing member 20 that removes the coating of the coated optical fiber has a resin integrated molding in which a through space 40 is formed at a position near the front of a thin rectangular parallelepiped in the illustrated example. A coated optical fiber insertion side portion 44 having a coated optical fiber insertion hole 42 for guiding the coated optical fiber 5, and a coated optical fiber insertion hole 42 provided in front of the coated optical fiber insertion hole 42. A sheath removing action portion having a bare fiber insertion hole 41 coaxial with the hole 42 and a cylindrical blade 43a for removing the coating of the coated optical fiber 5 at the end of the coated optical fiber insertion hole 42 side. And a coating removal side portion 45 having 43.
The inner diameter D of the coated optical fiber insertion hole 42 is substantially the same as the outer diameter of the coated portion of the coated optical fiber 5, and the inner diameter d of the bare fiber insertion hole 41 is substantially the same as the outer diameter of the bare fiber 6. It is. The coated optical fiber insertion hole 42 extends in a tapered shape in which the portion on the inlet side of the portion having the same inner diameter D as the coated portion outer diameter of the coated optical fiber 5 faces the inlet side.
By coating the coated optical fiber 5 through the coated optical fiber insertion hole 42 against the tip end portion (that is, the cylindrical blade) 43a of the coating removing action portion 43, the coating of the coated optical fiber 5 is made from the bare fiber. Remove as if peeled off.
The coating 5a is removed from the bare fiber 6 by, for example, tearing in the length direction of the optical fiber at a few locations in the circumferential direction. As shown in FIG. 17B, the coating (covering waste) 5a ′ to be removed is not removed from the coating 5a of the coated optical fiber 5, but is connected to the coating 5a of the coated optical fiber 5 at the root portion. In this state, it is peeled off from the bare fiber 6.

図18に被覆除去部材20の各部の寸法を示す。被覆除去部材20の幅W=約2.0mm、長さL=約3.3mm、厚みT=約1.0mm、被覆除去作用部(円錐体状部)43の高さh=約0.3mm、裸ファイバ挿通孔41の長さm=約1mm、空所40の幅w=約0.7mmなどである。
このような各部の寸法のなかで、被覆付光ファイバ挿通孔42と裸ファイバ挿通孔41との間の隙間寸法をaは0.1〜0.3mmとするのが適切である。
前記隙間aが長いと被覆付光ファイバが座屈して被覆を除去することができなくなる。また、隙間aが短すぎると、実質的に被覆の剛性が高くなるので、被覆除去部材20が樹脂成形品であり刃の鋭さに限界があることで、被覆が破れずに裸ファイバに沿って波付けパイプのような状態のまま滑ってしまう恐れがある。しかし、0.1〜0.3mmという適切な隙間寸法aとすると、そのような現象を起こさずに、スムーズに被覆を除去することができ、被覆付光ファイバの被覆を除去する機能を有効に果たすことが可能となる。
FIG. 18 shows the dimensions of each part of the coating removal member 20. The width W of the coating removal member 20 is about 2.0 mm, the length L is about 3.3 mm, the thickness T is about 1.0 mm, and the height h of the coating removal portion (conical portion) 43 is about 0.3 mm. The length m of the bare fiber insertion hole 41 is about 1 mm, the width w of the void 40 is about 0.7 mm, and the like.
Among these dimensions, it is appropriate that the clearance a between the coated optical fiber insertion hole 42 and the bare fiber insertion hole 41 is 0.1 to 0.3 mm.
If the gap a is long, the coated optical fiber will buckle and the coating cannot be removed. If the gap a is too short, the rigidity of the coating is substantially increased. Therefore, the coating removal member 20 is a resin molded product, and the sharpness of the blade is limited. There is a risk of slipping like a corrugated pipe. However, when the appropriate gap size is 0.1 to 0.3 mm, the coating can be removed smoothly without causing such a phenomenon, and the function of removing the coating of the coated optical fiber is effective. Can be fulfilled.

被覆除去部材20の被覆除去作用部43は、空所40の前方壁面40aから被覆付光ファイバ挿通孔42側に突出する錐体状をなしており、その先端部では、裸ファイバ挿通孔41の内面に対して厚みが極めて薄くされて、前記の筒状刃43aとなっている。すなわち、裸ファイバ挿通孔41の入口側(後端側)に向かって先細りとなって孔先端に前記筒状刃43aが形成されている。空所40の前方壁面40aから突出する錐体状の部分、すなわちは錐体状部43が覆除去作用部である。   The coating removal action part 43 of the coating removal member 20 has a conical shape protruding from the front wall surface 40a of the void 40 to the coated optical fiber insertion hole 42 side. The thickness is extremely reduced with respect to the inner surface to form the cylindrical blade 43a. That is, the cylindrical blade 43a is formed at the tip of the hole so as to taper toward the inlet side (rear end side) of the bare fiber insertion hole 41. A cone-shaped portion protruding from the front wall surface 40a of the void 40, that is, the cone-shaped portion 43 is the covering removal working portion.

図19に被覆除去作用部である前記錐体状部43の側面の種々の態様を示す。
図17、図18、及び図19(a)、(b)の錐体状部43は円錐体状部である。
この錐体状部43の側面のテーパ角度θは、20°〜40°とするのが適切である。図19(a)はテーパ角θ=40°、図19(b)はテーパ角θ=20°で示している。
錐体状部43の側面のテーパ角度が10°程度以下であれば、筒状刃43aの刃先が薄くなり過ぎて、強度が弱くなり破損し易くなり、一方、45°以上であれば、筒状刃43aの刃先の切れ味が鈍って、被覆除去する際に必要な押込み力(被覆除去力)が増大する。しかし、錐体状部43の側面のテーパ角度θを20°〜40°の範囲にすると、強度を確保しながら、被覆除去する際に必要な押込み力を低減させることができる。
FIG. 19 shows various aspects of the side surface of the cone-shaped portion 43 which is a coating removing action portion.
The cone-shaped part 43 in FIGS. 17, 18 and 19A and 19B is a cone-shaped part.
It is appropriate that the taper angle θ of the side surface of the cone-shaped portion 43 is 20 ° to 40 °. FIG. 19A shows the taper angle θ = 40 °, and FIG. 19B shows the taper angle θ = 20 °.
If the taper angle of the side surface of the cone-shaped portion 43 is about 10 ° or less, the cutting edge of the cylindrical blade 43a becomes too thin and the strength is weakened and easily damaged. The sharpness of the cutting edge of the blade 43a becomes dull, and the pushing force (coating removal force) necessary for removing the coating increases. However, when the taper angle θ of the side surface of the cone-shaped portion 43 is in the range of 20 ° to 40 °, it is possible to reduce the pushing force required for removing the coating while securing the strength.

図19(c)に示した錐体状部43は、先端に向かって先細りの円錐体状部の側面を凹湾曲させた形状としている。このように錐体状部43の側面を凹湾曲面にすると、筒状刃43aの刃先では薄くしても刃先から離れるにつれて厚くなる。したがって、切れ味と強度とを兼ね備えた筒状刃を得ることができる。図示例では先端部でのテーパ角θが20°である。
また、錐体状部43の側面が凹湾曲していることで、筒状刃43aの刃先で切り込んだ筒状の被覆を凹湾曲の側面に沿って押し広げる作用が大となり、筒状の被覆に亀裂が入り易くなり、被覆屑が複数に裂かれ易くなるので、被覆屑を裸ファイバから剥がす作用が効果的に行われる。すなわち、被覆が裸ファイバに沿って波付けパイプのような状態のまま滑ってしまうことを防止する効果がある。これにより被覆除去性能が向上する。
また、被覆が複数に裂かれて複数本に分解された被覆屑となり易いので、被覆屑を収納し易くなる。
The cone-shaped portion 43 shown in FIG. 19C has a shape in which the side surface of the tapered cone-shaped portion is concavely curved toward the tip. Thus, if the side surface of the cone-shaped part 43 is made into a concave curved surface, it will become thick as it leaves | separates from a blade edge, even if it thins at the blade edge of the cylindrical blade 43a. Therefore, a cylindrical blade having both sharpness and strength can be obtained. In the illustrated example, the taper angle θ at the tip is 20 °.
In addition, since the side surface of the cone-shaped portion 43 is concavely curved, the action of spreading the cylindrical coating cut by the cutting edge of the cylindrical blade 43a along the side surface of the concave curved surface becomes large, and the cylindrical coating is made. Since it becomes easy to crack and the coating waste is easily split into a plurality of pieces, the effect of peeling the coating waste from the bare fiber is effectively performed. That is, there is an effect of preventing the coating from sliding along the bare fiber in a state like a corrugated pipe. Thereby, the coating removal performance is improved.
In addition, since the coating is easily split into a plurality of pieces and decomposed into a plurality of pieces, it becomes easy to store the covering waste.

図19(d)の錐体状部43は四角錐体状である。このように錐体状部43を四角錐状などの角錐体状にすると、角錐の稜線のエッジ部で被覆が複数に裂かれ易くなる。
図19(e)の錐体状部43は四角錐体状でかつ側面を凹湾曲させている。また、図19(f)の錐体状部43は三角錐体状でかつ側面を凹湾曲させている。このような形状にすると、稜線のエッジ部による被覆の引裂き効果が向上し、被覆が早期に複数に分解され易くなる。
The cone-shaped part 43 of FIG.19 (d) is a quadrangular pyramid shape. Thus, when the pyramidal portion 43 is formed into a pyramid shape such as a quadrangular pyramid shape, the covering is easily split into a plurality at the edge portion of the ridgeline of the pyramid.
The cone-shaped part 43 of FIG.19 (e) is a quadrangular pyramid shape, and is making the side surface concavely curved. Moreover, the cone-shaped part 43 of FIG.19 (f) is a triangular pyramid shape, and is making the side surface concavely curved. With such a shape, the effect of tearing the coating by the edge portion of the ridge line is improved, and the coating is easily decomposed into a plurality of parts at an early stage.

図18について述べたように、被覆除去部材20は厚みT=約1.0mmの薄い直方体状をなし、前方寄りに貫通の空所40を有し、厚みTの中間高さ位置における空所40の前方側に裸ファイバ挿通孔41、後方側に被覆付光ファイバ挿通孔42を有している。すなわち、裸ファイバ挿通孔41と被覆付光ファイバ挿通孔42との間に形成される空間は、被覆除去部材20の裸ファイバ挿通孔芯を挟む厚み方向の両側の隙間寸法nがそれぞれ0.5mmである。また、被覆除去部材20の裸ファイバ挿通孔芯を挟む幅方向の両側の隙間寸法nもそれぞれ0.5mmである。
この隙間寸法nは実施例では0.5mmとしているが、それ以上(0.5mm以上)であることが望ましい。すなわち、被覆除去部材20における被覆付光ファイバ挿通孔42と裸ファイバ挿通孔41との間に形成される空間は、裸ファイバ挿通孔芯と直交する二方向(厚み方向と幅方向)における、裸ファイバ挿通孔41の半径方向両側にいずれも0.5mm以上の隙間を形成することが望ましい。なお、隙間寸法nの機能上の上限はないが、被覆除去部材20はメカニカルスプライス部7のベース部30にコンパクトに装着する必要があるので、その面からの実際上の上限はある。
被覆付光ファイバ挿通孔42と裸ファイバ挿通孔41との間に形成される空間が、被覆除去部材20の厚み方向の両側にそれぞれ0.5mm以上の隙間nを形成する空間であれば、被覆屑を収納するスペースを確保することができ、これにより、被覆除去長さ(ストリップ長)を長くすることができる。この実施例ではストリップ長として4mmを想定している。なお、図12(a)、(c)に示したベース部30には、被覆屑を収納するための凹所30fを設けている。
As described with reference to FIG. 18, the coating removing member 20 has a thin rectangular parallelepiped shape with a thickness T = about 1.0 mm, and has a through space 40 at the front side. Bare fiber insertion hole 41 is provided on the front side, and coated optical fiber insertion hole 42 is provided on the rear side. That is, the space formed between the bare fiber insertion hole 41 and the coated optical fiber insertion hole 42 has a gap dimension n of 0.5 mm on both sides in the thickness direction sandwiching the bare fiber insertion hole core of the coating removal member 20. It is. Further, the gap dimension n on both sides in the width direction sandwiching the bare fiber insertion hole core of the coating removing member 20 is also 0.5 mm.
The gap dimension n is 0.5 mm in the embodiment, but is preferably larger (0.5 mm or more). That is, the space formed between the coated optical fiber insertion hole 42 and the bare fiber insertion hole 41 in the coating removal member 20 is bare in two directions (thickness direction and width direction) perpendicular to the bare fiber insertion hole core. It is desirable to form a gap of 0.5 mm or more on both sides in the radial direction of the fiber insertion hole 41. Although there is no functional upper limit for the gap dimension n, the covering removal member 20 needs to be mounted compactly on the base part 30 of the mechanical splice part 7, so there is an actual upper limit from that surface.
If the space formed between the coated optical fiber insertion hole 42 and the bare fiber insertion hole 41 is a space where gaps n of 0.5 mm or more are formed on both sides in the thickness direction of the coating removal member 20, respectively, A space for storing the waste can be secured, and thereby, the coating removal length (strip length) can be increased. In this embodiment, a strip length of 4 mm is assumed. In addition, the base part 30 shown to Fig.12 (a), (c) is provided with the recess 30f for accommodating a coating waste.

図20は裸ファイバ挿通孔の径についての変形例を示す。
この被覆除去部材120の裸ファイバ挿通孔141は、裸ファイバ外径とほぼ同一内径である部分141aの前後(出口側及び入口側)がテーパ状に広がるテーパ孔141b、14cとなっている。出口側のテーパ孔を141b、入口側のテーパ孔を14cで示す。
例えば、裸ファイバ外径と同一内径部分141aの長さSaを0.1mm、出口側のテーパ孔141bの長さSbを0.7mm、入口側のテーパ孔14cの長さScを0.2mmとすることができる(なお、図ではその比率では描いていない)。
このように、裸ファイバ挿通孔141の裸ファイバ外径とほぼ同一内径である部分14aの前方及び後方に、それぞれ前方又は後方にテーパ状に広がるテーパ孔141b、14cを設けると、被覆を除去された裸ファイバ6の先端の外周が裸ファイバ挿通孔141の内壁にぶつかる(接触する)ことが少なくなる(ぶつかる確率が小さくなる)。
すなわち、被覆を除去した裸光ファイバ6の外径と同一の内径部分が長ければ長いほど、被覆を除去した裸ファイバ6が裸ファイバ挿通孔の内壁にぶつかり易くなるが、実施例のように裸ファイバの外径と同一内径の部分141aを裸ファイバ挿通孔141の一部のみとすることで、ぶつかる確率およびぶつかった場合の距離を短くできる。また、短いとゴミなどの影響を受けることが少なくなる。また、裸ファイバ挿通孔141に挿入する際に必要な力も小さくすむ。
また、裸ファイバ挿通孔141の出口側(メカニカルスプライス部調心溝側)をテーパ状に広げておく(テーパ孔141b)ことで、被覆を除去した裸光ファイバの外径と同一の内径部分141aと調心溝(図4、図12、図14に示した調心溝32a)との軸ずれによる裸ファイバ断線(出口孔縁部(エッジ)pによる断線)の発生を抑制することができる。
この場合、被覆除去作用部43の裸ファイバ挿通孔141における、裸ファイバ外径と同一内径の部分141aの長さは、短すぎると調心機能を損なうので、0.05mm〜0.5mmとするのが適切である。
なお、裸ファイバ挿通孔141の中間部141aより出口側部分は、テーパ孔141bに代えて、中間部141aの内径より大径の均等内径孔としてもよい。
FIG. 20 shows a modification of the diameter of the bare fiber insertion hole.
The bare fiber insertion hole 141 of the sheath removing member 120 is tapered holes 141b and 14c in which the front and rear (exit side and inlet side) of the portion 141a having the same inner diameter as the bare fiber outer diameter are tapered. The tapered hole on the outlet side is denoted by 141b, and the tapered hole on the inlet side is denoted by 14c.
For example, the length Sa of the inner diameter portion 141a having the same outer diameter as the bare fiber is 0.1 mm, the length Sb of the outlet side tapered hole 141b is 0.7 mm, and the length Sc of the tapered hole 14c on the inlet side is 0.2 mm. (Note that the ratio is not shown in the figure).
Thus, if the tapered holes 141b and 14c that taper forward or backward are provided at the front and rear of the portion 14a having the same inner diameter as the bare fiber outer diameter of the bare fiber insertion hole 141, respectively, the coating is removed. In addition, the outer periphery of the tip of the bare fiber 6 does not hit (contact) the inner wall of the bare fiber insertion hole 141 (the probability of hitting becomes small).
That is, the longer the inner diameter portion that is the same as the outer diameter of the bare optical fiber 6 from which the coating is removed, the easier it is for the bare fiber 6 from which the coating has been removed to hit the inner wall of the bare fiber insertion hole. By making the portion 141a having the same inner diameter as the outer diameter of the fiber only a part of the bare fiber insertion hole 141, the probability of collision and the distance in the case of collision can be shortened. Also, if it is short, it is less affected by dust. In addition, the force required for insertion into the bare fiber insertion hole 141 can be reduced.
Further, the outlet side (mechanical splice alignment groove side) of the bare fiber insertion hole 141 is expanded in a tapered shape (tapered hole 141b), so that the inner diameter portion 141a is the same as the outer diameter of the bare optical fiber from which the coating has been removed. And the occurrence of a bare fiber breakage (breakage due to the edge (edge) p of the exit hole) due to the misalignment of the alignment groove (alignment groove 32a shown in FIGS. 4, 12, and 14) can be suppressed.
In this case, if the length of the portion 141a having the same inner diameter as the bare fiber outer diameter in the bare fiber insertion hole 141 of the coating removing action portion 43 is too short, the alignment function is impaired. Is appropriate.
In addition, it is good also considering the exit side part from the intermediate part 141a of the bare fiber penetration hole 141 as a uniform internal diameter hole larger diameter than the internal diameter of the intermediate part 141a instead of the taper hole 141b.

図21は裸ファイバ挿通孔の径についての他の変形例を示す。
この被覆除去部材120’の裸ファイバ挿通孔141’も、裸ファイバ外径とほぼ同一内径の部分141a’の前後がテーパ状に広がるテーパ孔141b’、14c’となっているが、後方側のテーパ孔14c’は、入口側に設けた裸ファイバ外径より大径の均一内径の孔141d’に続く部分として形成している。
この場合、例えば、裸ファイバ外径と同一内径部分141a’の長さSaを0.1mm、出口側のテーパ孔141b’の長さSbを0.2mm、入口側のテーパ孔141c’の長さScを0.1mm、大径の均一内径孔141d’の長さを0.6mmとすることができる。
この実施例では、出口側のテーパ孔141b’が短く、裸ファイバ外径と同一内径部分141a’が前方の調心溝32aに接近しているので、裸光ファイバ外径と同一内径部分141a’と調心溝32aとの間の軸ずれを防止し易い。
FIG. 21 shows another modification of the diameter of the bare fiber insertion hole.
The bare fiber insertion hole 141 ′ of the sheath removing member 120 ′ also has tapered holes 141 b ′ and 14 c ′ in which the front and back of the portion 141 a ′ having substantially the same inner diameter as the bare fiber outer diameter are tapered. The tapered hole 14c ′ is formed as a portion following a hole 141d ′ having a uniform inner diameter larger than the outer diameter of the bare fiber provided on the inlet side.
In this case, for example, the length Sa of the inner diameter portion 141a ′ that is the same as the outer diameter of the bare fiber is 0.1 mm, the length Sb of the tapered hole 141b ′ on the outlet side is 0.2 mm, and the length of the tapered hole 141c ′ on the inlet side Sc can be 0.1 mm, and the length of the large-diameter uniform inner diameter hole 141d ′ can be 0.6 mm.
In this embodiment, the tapered hole 141b 'on the outlet side is short, and the inner diameter portion 141a' having the same outer diameter as the bare fiber is close to the front alignment groove 32a. Therefore, the inner diameter portion 141a 'having the same outer diameter as the bare optical fiber is used. And misalignment between the alignment groove 32a and the alignment groove 32a.

図22に図17、図18に示した被覆除去部材20を樹脂一体成形する金型の一例を簡略化して示す。
この金型70で被覆除去部材20の被覆付光ファイバ挿入側部分44と被覆除去側部分45とを樹脂一体成形する場合、被覆除去部材20の外形に合わせたキャビティを形成する上型71と下型72との間に、被覆付光ファイバ挿通孔42の部分と裸ファイバ挿通孔41の部分とを形成する中子として1本のコアピン73を配置する。被覆除去部材20の空所40に対応する部分には、上型71及び下型72の底面からそれぞれ隆起する、空所40の輪郭に対応させた隆起部71a、72aを設ける。
このように、被覆付光ファイバ挿通孔42の部分と裸ファイバ挿通孔41の部分とを形成する中子として1本のコアピン73を用いた金型70で樹脂一体成形すると、被覆付光ファイバ挿入側部分44の被覆付光ファイバ挿通孔42と被覆除去側部分45の裸ファイバ挿通孔41との両孔芯を高精度に一致させることができ、被覆除去をスムーズに行うことができ、被覆除去性能を高めることができる。
この被覆除去部材20をメカニカルスプライス部に装着する際に、被覆付光ファイバ挿入側部分及び被覆除去作用部分とについてそれぞれを調心して固定する必要がないので、作業性がよく、また高い調心精度を確保できる。
また、樹脂一体成形品であるから、量産可能であり、コストを低減できる。
樹脂材料としては、熱膨張係数が小さく、強度の高く、また、流動性が高く樹脂成形時に流動性が高く寸法精度を出し易い材料がよいが、例えばPPS(ポリフェニレンスルフィド)、LCP(液晶ポリマー)などを用いることができる。
FIG. 22 shows a simplified example of a mold for integrally molding the coating removing member 20 shown in FIGS. 17 and 18 with resin.
When the coated optical fiber insertion side portion 44 and the coating removal side portion 45 of the coating removal member 20 are integrally molded with this mold 70, an upper die 71 and a lower die that form cavities that match the outer shape of the coating removal member 20 are formed. One core pin 73 is disposed between the mold 72 as a core that forms the coated optical fiber insertion hole 42 and the bare fiber insertion hole 41. The portions corresponding to the voids 40 of the coating removing member 20 are provided with raised portions 71a and 72a corresponding to the contours of the voids 40 that are raised from the bottom surfaces of the upper die 71 and the lower die 72, respectively.
As described above, when the resin is integrally formed with the mold 70 using the single core pin 73 as a core for forming the coated optical fiber insertion hole 42 and the bare fiber insertion hole 41, the coated optical fiber insertion is performed. Both cores of the coated optical fiber insertion hole 42 of the side portion 44 and the bare fiber insertion hole 41 of the coating removal side portion 45 can be made to coincide with each other with high accuracy, and the coating removal can be performed smoothly. Performance can be increased.
When this coating removal member 20 is mounted on the mechanical splice portion, it is not necessary to align and fix the coated optical fiber insertion side portion and the coating removal portion, so that workability is good and high alignment accuracy is achieved. Can be secured.
Moreover, since it is a resin integrated molded product, it can be mass-produced and the cost can be reduced.
As the resin material, a material having a small coefficient of thermal expansion, high strength, high fluidity and high fluidity during resin molding is preferable. For example, PPS (polyphenylene sulfide), LCP (liquid crystal polymer) Etc. can be used.

図16は前記外被把持部材11の蓋体を開いた状態の斜視図である。
この外被把持部材11は、把持部材本体51とこの把持部材本体51にヒンジ部52を介して開閉可能に取り付けられてた蓋体53とを備え、前記把持部材本体51の前方側の左右両側に、可動ガイド21に係合させるための係合爪50aを設けたアーム50を設けている。
前記把持部材本体51は光ケーブル4の外被部分を把持する外被把持部分55と被覆付光ファイバ5の被覆部を把持する被覆把持部分56とを一体に備え、また蓋体53も光ケーブル4の外被部分を把持する外被把持部分57と被覆付光ファイバ5の被覆部を把持する被覆把持部分58とを一体に備えている。すなわち、光ケーブル4の外被部分と被覆付き光ファイバ5の被覆部分とが一体部材で把持される。
把持部材本体51の外被把持部分55は、実施例では概ね断面長方形の外被を持つドロップケーブルである光ケーブル4の外径に合せた深いコ字形枠部61を有し、このコ字形枠部61の左右側壁62の内面に断面三角形の縦長の突起62aを設け、底部に小突起を設けている。
蓋体53の外被把持部分57は、把持部材本体51のコ字形枠部61に被せられる天井部65と、コ字形枠部61に設けた係止用突起61aに係止される係止孔66aを持つ係止部66とからなり、直角状をなしている。
蓋体53の前記天井部65の内側面に円錐状突起65aを設けている。
把持部材本体51側の被覆把持部分56は、その上面に、被覆付光ファイバ5を収容する図示例ではV溝である位置決め溝67aを有している。
なお、被覆除去部材を成形する金型は必ずしも1本のコアピンによる金型に限定されない。
また、成形材料は樹脂を用いるのが好適であるが、ジルコニアなどのセラミックを用いることも考えられる。
FIG. 16 is a perspective view showing a state in which the cover of the outer cover holding member 11 is opened.
The outer gripping member 11 includes a gripping member main body 51 and a lid 53 attached to the gripping member main body 51 via a hinge portion 52 so as to be openable and closable. Further, an arm 50 provided with an engaging claw 50a for engaging with the movable guide 21 is provided.
The gripping member main body 51 is integrally provided with a jacket gripping portion 55 for gripping the jacket portion of the optical cable 4 and a covering gripping portion 56 for gripping the coating portion of the coated optical fiber 5. A jacket grip portion 57 that grips the jacket portion and a covering grip portion 58 that grips the coating portion of the coated optical fiber 5 are integrally provided. That is, the jacket portion of the optical cable 4 and the coated portion of the coated optical fiber 5 are held by the integral member.
The outer gripping portion 55 of the gripping member main body 51 has a deep U-shaped frame portion 61 that matches the outer diameter of the optical cable 4 that is a drop cable having a generally rectangular cross-section outer jacket, and this U-shaped frame portion. A longitudinal projection 62a having a triangular cross section is provided on the inner surface of the left and right side walls 62 of the 61, and a small projection is provided on the bottom.
The covering portion 57 of the lid 53 includes a ceiling portion 65 that covers the U-shaped frame portion 61 of the holding member main body 51 and a locking hole that is locked to a locking projection 61 a provided on the U-shaped frame portion 61. It consists of a locking portion 66 having 66a and has a right angle.
A conical protrusion 65 a is provided on the inner surface of the ceiling portion 65 of the lid 53.
The covering grip portion 56 on the grip member main body 51 side has a positioning groove 67a on the upper surface thereof, which is a V groove in the illustrated example in which the coated optical fiber 5 is accommodated.
In addition, the metal mold | die which shape | molds a coating removal member is not necessarily limited to the metal mold | die by one core pin.
In addition, it is preferable to use a resin as the molding material, but it is also possible to use a ceramic such as zirconia.

上記のメカニカルスプライス型現場組立光コネクタ1を組み立てる際の作業手順及び動作について説明する。
(1)光ケーブル4の外被4aを例えば5cmなどの適宜の長さだけ削除して被覆付き光ファイバ5を露出させる。
(2)次いで、光ケーブル5の外被部分を、蓋体53を開けた外被把持部材11のコ字形枠部61内に収容し、蓋体53を閉じて光ケーブル4の外被を把持した後、被覆付き光ファイバ5を光ファイバ用カッターで正確に所定の長さで切断する。
(3)メカニカルスプライス部7のベース部30にC形板バネで弾性的に装着されている蓋33を、クサビ部材15の差込片15aをメカニカルスプライス部7のクサビ差込部30bに差し込んで開いておく。
(4)この段階で可動ガイド21は、ロックレバー35で位置決めされた所定の位置にセットされており、前に進まない状態になっている。
(5)外被把持部材11で外被を把持された光ケーブル4の被覆付き光ファイバ5を可動ガイド21内に通しメカニカルスプライス部7の被覆部収容溝32bに挿入し、外被把持部材11を前進させて被覆部収容溝32bに沿って送り込む。その際、光コネクタ1の後端部に取り付けた押し込み補助治具14に載せて外被把持部材11を前進させる。
(6)外被把持部材11を、さらに前方に押し込むと、被覆付き光ファイバ5の先端面が被覆除去部材20の被覆除去作用部43の先端面部(円筒状刃)43aに当たり(この当たった時点をA時点と呼ぶ)、引き続き被覆付き光ファイバ5が押し込まれることで、被覆除去作用部43の円筒状刃43aで被覆5aが裸ファイバから剥がされつつ、露出した裸ファイバ6が裸ファイバ挿通孔41を通過してメカニカルスプライス部7の裸ファイバ用の調心溝32a内を前進する。この頃に(この前進の段階で)外被把持部材11が可動ガイド21に当たり(この当たった時点をB時点と呼ぶ)
、外被把持部材11と可動ガイド21とが一体となって動く。
(7)なお、前記の外被把持部材11を押し込む過程における前記A時点(被覆付き光ファイバ5の先端面が被覆除去部材20の被覆除去作用部43の先端面43aに当たった時点)からB時点(外被把持部材11が可動ガイド21に当たった時点)の間に、外被把持部材11のアーム50の先端がロックレバー35を押してロックレバー35を可動ガイド21の側面から離間させる動作があり、この動作で、可動ガイド21の前進を規制していたロックレバー35のロックが解除され、可動ガイド21が前進できる状態となる。
(8)外被把持部材11をさらに前方に押し込むと、外被把持部材11と一体に前進する可動ガイド21の被覆付光ファイバ誘導部24の垂直内壁24cがメカニカルスプライス部7の開放ガイド31の後端面に当たり(接触し)、開放ガイドが作動する状態となる。
(10)外被把持部材11をさらに前方に押し込むと、被覆付き光ファイバ5の被覆除去(剥がし)がさらに進行しつつ裸ファイバ(挿入光ファイバ)6がメカニカルスプライス部7の調心溝32a内を前進して内蔵光ファイバ2に突き当たり、かつ(厳密には突き当たった次の瞬間に)所定の突き合わせ圧力が発生する。被覆除去時の押込み力は5N以下とする。
(11)外被把持部材11・可動ガイド21をさらに押し込むと、可動ガイド21で押された開放ガイド31が、その斜め凹溝31bが嵌合しているメカニカルスプライス部7のベース部30の斜め凸条30eに沿って斜めに前進して断面中心側から外方に離れることで、被覆付き光ファイバ5の把持が開放される。これにより、断面中心側から外方に移動した開放ガイド31が存在していた空間の部分がたわみ空間となって、その空間において被覆付き光ファイバ5にたわみが生じる。すなわち、挿入ファイバ6の内蔵光ファイバ2に対する突き合わせ圧力が被覆付き光ファイバ5のたわみに変換される。このたわみで良好な光接続がなされる適性な突き合わせ圧力が確保される。
(12)この状態でクサビ部材15を抜き取るとC形板バネの挟持力が作用し、メカニカルスプライス部7のベース部30と蓋部33とで内蔵光ファイバ2と裸ファイバである挿入光ファイバ6と被覆付き光ファイバ5とを把持する。
(13)次いで、ストップリング10に取り付けたレバー12を、光ケーブル4の外被を把持している外被把持部材11に被せるように倒して、外被把持部材11が脱落しないように拘束する。
以上でメカニカルスプライス型現場組立光コネクタの組立が完了する。
The work procedure and operation when assembling the mechanical splice type field assembly optical connector 1 will be described.
(1) The sheath 4a of the optical cable 4 is deleted by an appropriate length such as 5 cm to expose the coated optical fiber 5.
(2) Next, after the jacket portion of the optical cable 5 is accommodated in the U-shaped frame portion 61 of the jacket gripping member 11 with the lid 53 opened, the lid 53 is closed and the jacket of the optical cable 4 is gripped. The coated optical fiber 5 is accurately cut to a predetermined length with an optical fiber cutter.
(3) Insert the lid 33 elastically attached to the base part 30 of the mechanical splice part 7 with a C-shaped leaf spring, the insertion piece 15a of the wedge member 15 into the wedge insertion part 30b of the mechanical splice part 7 Keep it open.
(4) At this stage, the movable guide 21 is set at a predetermined position that is positioned by the lock lever 35, and is in a state of not moving forward.
(5) The coated optical fiber 5 of the optical cable 4 gripped by the jacket gripping member 11 is inserted into the movable guide 21 and inserted into the coating portion receiving groove 32b of the mechanical splice portion 7, and the jacket gripping member 11 is It advances and feeds along the coating | coated part accommodation groove | channel 32b. At that time, the outer gripping member 11 is moved forward by being placed on a pushing assist jig 14 attached to the rear end portion of the optical connector 1.
(6) When the jacket holding member 11 is pushed further forward, the tip surface of the coated optical fiber 5 hits the tip surface portion (cylindrical blade) 43a of the sheath removing action portion 43 of the sheath removing member 20 (when this hits) Then, when the coated optical fiber 5 is pushed in, the coated bare fiber 6 is peeled off from the bare fiber by the cylindrical blade 43a of the coat removing action portion 43, and the bare bare fiber 6 is exposed to the bare fiber insertion hole. It passes through 41 and advances in the alignment groove 32a for bare fiber of the mechanical splice part 7. At this time (at this forward stage), the outer gripping member 11 hits the movable guide 21 (the point of contact is called the point B).
The outer covering member 11 and the movable guide 21 are moved together.
(7) From the time point A in the process of pushing in the jacket gripping member 11 (the time point when the front end surface of the coated optical fiber 5 hits the front end surface 43a of the coating removing action portion 43 of the coating removing member 20) B During the time (when the outer gripping member 11 hits the movable guide 21), the operation of the distal end of the arm 50 of the outer gripping member 11 pressing the lock lever 35 to move the lock lever 35 away from the side surface of the movable guide 21. With this operation, the lock lever 35 that restricts the forward movement of the movable guide 21 is unlocked, and the movable guide 21 can move forward.
(8) When the outer cover holding member 11 is pushed further forward, the vertical inner wall 24c of the coated optical fiber guiding portion 24 of the movable guide 21 that moves forward integrally with the outer cover holding member 11 is formed by the open guide 31 of the mechanical splice portion 7. It hits (contacts) the rear end face, and the opening guide is activated.
(10) When the jacket holding member 11 is further pushed forward, the coating removal (peeling) of the coated optical fiber 5 further proceeds while the bare fiber (inserted optical fiber) 6 is in the aligning groove 32a of the mechanical splice portion 7. And a predetermined butt pressure is generated (at the next moment when it is struck). The pushing force when removing the coating is 5N or less.
(11) When the outer gripping member 11 and the movable guide 21 are further pushed in, the open guide 31 pushed by the movable guide 21 is oblique to the base portion 30 of the mechanical splice portion 7 in which the oblique concave groove 31b is fitted. The coating of the coated optical fiber 5 is released by advancing obliquely along the ridge 30e and leaving outward from the center of the cross section. Thereby, the portion of the space where the open guide 31 that has moved outward from the center side of the cross section becomes a bending space, and the coated optical fiber 5 is bent in that space. That is, the butting pressure of the insertion fiber 6 against the built-in optical fiber 2 is converted into the deflection of the coated optical fiber 5. This deflection ensures an appropriate butt pressure for good optical connection.
(12) When the wedge member 15 is removed in this state, the clamping force of the C-shaped leaf spring acts, and the built-in optical fiber 2 and the inserted optical fiber 6 that is a bare fiber are formed by the base portion 30 and the lid portion 33 of the mechanical splice portion 7. And the coated optical fiber 5.
(13) Next, the lever 12 attached to the stop ring 10 is tilted so as to cover the outer cover holding member 11 holding the outer cover of the optical cable 4 and restrained so that the outer cover holding member 11 does not fall off.
This completes the assembly of the mechanical splice type field assembly optical connector.

1 メカニカルスプライス型の現場組立光コネクタ(光コネクタ)
2 内蔵光ファイバ(裸ファイバ)
3 フェルール部
4 光ケーブル
4a 外被(外被部分)
5 被覆付光ファイバ
5a 被覆(被覆部分)
6 挿入光ファイバ(裸ファイバ)
7 メカニカルスプライス部
8 メカニカルスプライス部一体フェルール部
9 プラグフレーム
10 ストップリング
11 外被把持部材
12 レバー
13 カバー
20、120、120’ 被覆除去部材
21 可動ガイド
30 ベース部
33 蓋部
32a 調心溝
32b 被覆部収容溝
30a (被覆除去部材を配置する)凹所
31 開放ガイド
40 空所
41、141、141’ 裸ファイバ挿通孔
141a、141a’ (裸ファイバ挿通孔の)裸ファイバ径と同一内径の部分
141b、141b’ (裸ファイバ挿通孔の出口側の)テーパ状の部分
141c、141c’ (裸ファイバ挿通孔の入口側の)テーパ状の部分
42 被覆付光ファイバ挿通孔
43 被覆除去作用部(錐体状部)
44 被覆付光ファイバ挿入側部分
45 被覆除去側部分
51 把持部材本体
53 蓋体
1. Mechanical splice type on-site assembly optical connector (optical connector)
2 Built-in optical fiber (bare fiber)
3 Ferrule part 4 Optical cable 4a Outer jacket (outer jacket part)
5 Coated optical fiber 5a Coating (coating part)
6 Insertion optical fiber (bare fiber)
7 Mechanical splice part 8 Mechanical splice part integrated ferrule part 9 Plug frame 10 Stop ring 11 Cover member 12 Lever 13 Cover 20, 120, 120 'Cover removal member 21 Movable guide 30 Base part 33 Cover part 32a Alignment groove 32b Cover Part receiving groove 30a (deposit covering member) recess 31 open guide 40 voids 41, 141, 141 'bare fiber insertion holes 141a, 141a' (of bare fiber insertion holes) having the same inner diameter as the bare fiber diameter
141b, 141b ′ Tapered portions 141c, 141c ′ (on the inlet side of the bare fiber insertion hole) Tapered portions 42 (on the inlet side of the bare fiber insertion hole) Covered optical fiber insertion hole 43 Cover removal action portion (cone Body part)
44 Covered optical fiber insertion side portion 45 Cover removal side portion 51 Grip member main body 53 Lid

Claims (10)

内蔵光ファイバを内蔵したフェルール部と、前記フェルール部の後部に取り付けられて、前記内蔵光ファイバと外部から挿入される光ケーブルの外被を除去した被覆付き光ファイバの被覆を除去した挿入光ファイバとを突き合わせ接続するメカニカルスプライス部と、メカニカルスプライス部における前記内蔵光ファイバと挿入光ファイバとの突合せ部より後方側に設けられて前記被覆付き光ファイバの被覆を除去する被覆除去部とを備え、
前記被覆除去部を構成する被覆除去部材は、
被覆付光ファイバを案内する被覆付光ファイバ挿通孔を有する被覆付光ファイバ挿入側部分と、
前記被覆付光ファイバ挿通孔の前方に設けられ、被覆付光ファイバ挿通孔と同軸の裸ファイバ挿通孔を有するとともにその被覆付光ファイバ挿通孔側の端部に被覆付光ファイバの被覆を除去するための筒状刃が形成された被覆除去作用部を持つ被覆除去側部分とを備え、
前記被覆付光ファイバ挿通孔の内径が被覆付光ファイバの被覆部外径とほぼ同一内径であり、かつ前記裸ファイバ挿通孔の中間部分の内径が前記裸ファイバの外径とほぼ同一内径であり、
前記裸ファイバ挿通孔の裸ファイバ外径とほぼ同一内径である中間部分より入口側がテーパ状に広がるテーパ孔となっており、出口側の内径が前記中間部分の内径より大となっていることを特徴とするメカニカルスプライス型の現場組立光コネクタ。
A ferrule part containing a built-in optical fiber, and an insertion optical fiber attached to the rear part of the ferrule part, from which the coating of the coated optical fiber from which the sheath of the built-in optical fiber and the optical cable inserted from the outside is removed is removed A mechanical splice portion that butt-connects, and a coating removal portion that is provided on the rear side of the butt portion between the built-in optical fiber and the insertion optical fiber in the mechanical splice portion and removes the coating of the coated optical fiber,
The coating removal member constituting the coating removal unit is
A coated optical fiber insertion side portion having a coated optical fiber insertion hole for guiding the coated optical fiber;
The coated optical fiber is provided in front of the coated optical fiber insertion hole, has a bare fiber insertion hole coaxial with the coated optical fiber insertion hole, and removes the coating of the coated optical fiber at the end of the coated optical fiber insertion hole side. And a coating removal side portion having a coating removal working portion formed with a cylindrical blade for,
The inner diameter of the coated optical fiber insertion hole is substantially the same inner diameter as the outer diameter of the coated optical fiber, and the inner diameter of the intermediate portion of the bare fiber insertion hole is substantially the same as the outer diameter of the bare fiber. ,
A taper hole is formed such that the inlet side is tapered from the intermediate portion having the same inner diameter as the bare fiber outer diameter of the bare fiber insertion hole, and the inner diameter of the outlet side is larger than the inner diameter of the intermediate portion. A mechanical splice type on-site assembly optical connector.
前記裸ファイバ挿通孔における、出口側の内径が前記中間部分の内径より大となっている部分が出口側に広がるテーパ孔となっていることを特徴とする請求項1記載のメカニカルスプライス型の現場組立光コネクタ。   2. The mechanical splice type site according to claim 1, wherein a portion of the bare fiber insertion hole in which an inner diameter on the outlet side is larger than an inner diameter of the intermediate portion is a tapered hole extending toward the outlet side. Assembly optical connector. 前記被覆除去側部分の裸ファイバ挿通孔における、裸ファイバ外径とほぼ同一内径である部分の長さが0.05mm〜0.5mmであることを特徴とする請求項1又は2記載のメカニカルスプライス型の現場組立光コネクタ。   3. The mechanical splice according to claim 1, wherein a length of a portion having an inner diameter substantially the same as an outer diameter of the bare fiber in the bare fiber insertion hole in the coating removal side portion is 0.05 mm to 0.5 mm. Type field assembly optical connector. 前記被覆除去部材を、その被覆付光ファイバ挿入側部分と被覆除去側部分とを成形材料にて一体成形したことを特徴とする請求項1〜3のいずれか1項に記載のメカニカルスプライス型の現場組立光コネクタ。   The mechanical splice mold according to any one of claims 1 to 3, wherein the coating removing member is formed by integrally molding a coated optical fiber insertion side portion and a coating removal side portion with a molding material. On-site assembly optical connector. 前記被覆除去部材を、その被覆付光ファイバ挿入側部分と被覆除去側部分とを樹脂にて一体成形したことを特徴とする請求項4記載のメカニカルスプライス型の現場組立光コネクタ。   5. The mechanical splice type on-site assembly optical connector according to claim 4, wherein the coating removal member is formed by integrally molding a coated optical fiber insertion side portion and a coating removal side portion with resin. 前記被覆除去部材は、被覆付光ファイバ挿通孔の部分と裸ファイバ挿通孔の部分とを形成する中子として1本のコアピンを用いた金型で一体成形したことを特徴とする請求項4又は5記載のメカニカルスプライス型の現場組立光コネクタ。   The said coating removal member was integrally molded by the metal mold | die using one core pin as a core which forms the part of a coated optical fiber penetration hole, and the part of a bare fiber penetration hole. 5. A field-assembled optical connector of the mechanical splice type according to 5. 前記被覆付光ファイバ挿通孔と裸ファイバ挿通孔との間の隙間寸法が0.1〜0.3mmであることを特徴とする請求項1〜6のいずれか1項に記載のメカニカルスプライス型の現場組立光コネクタ。   The mechanical splice mold according to any one of claims 1 to 6, wherein a gap between the coated optical fiber insertion hole and the bare fiber insertion hole is 0.1 to 0.3 mm. On-site assembly optical connector. 前記被覆除去部材の被覆除去作用部は、裸ファイバ挿通孔の入口側に向かって先細りとなって孔先端に前記筒状刃が形成される錐体状部を有し、この錐体状部の側面のテーパ角度が20°〜40°であることを特徴とする請求項1〜7のいずれか1項に記載のメカニカルスプライス型の現場組立光コネクタ。   The sheath removing action portion of the sheath removing member has a cone-shaped portion that is tapered toward the inlet side of the bare fiber insertion hole and the cylindrical blade is formed at the tip of the hole. The mechanically-spliced field assembly optical connector according to any one of claims 1 to 7, wherein a taper angle of a side surface is 20 ° to 40 °. 前記被覆除去部材の被覆除去作用部は、裸ファイバ挿通孔の入口側に向かって凹湾曲状をなして先細りとなって孔先端に前記筒状刃が形成される凹湾曲錐体状部を有することを特徴とする請求項1〜7のいずれか1項に記載のメカニカルスプライス型の現場組立光コネクタ。   The sheath removing action portion of the sheath removing member has a concavely curved cone-like portion that is tapered toward the inlet side of the bare fiber insertion hole and is tapered to form the cylindrical blade at the tip of the hole. A mechanical splice type field assembly optical connector according to any one of claims 1 to 7. 前記被覆除去部材における被覆付光ファイバ挿通孔と裸ファイバ挿通孔との間に形成される空間が、裸ファイバ挿通孔芯と直交する二方向における、裸ファイバ挿通孔の半径方向両側にいずれも0.5mm以上の隙間を形成していることを特徴とする請求項1〜9のいずれか1項に記載のメカニカルスプライス型の現場組立光コネクタ。
The space formed between the coated optical fiber insertion hole and the bare fiber insertion hole in the coating removal member is zero on both sides in the radial direction of the bare fiber insertion hole in two directions orthogonal to the bare fiber insertion hole core. A mechanical splice type field assembly optical connector according to any one of claims 1 to 9, wherein a gap of 5 mm or more is formed.
JP2011149750A 2011-07-06 2011-07-06 Optical connector Pending JP2013015744A (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
JP2011149750A JP2013015744A (en) 2011-07-06 2011-07-06 Optical connector

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
JP2011149750A JP2013015744A (en) 2011-07-06 2011-07-06 Optical connector

Publications (1)

Publication Number Publication Date
JP2013015744A true JP2013015744A (en) 2013-01-24

Family

ID=47688463

Family Applications (1)

Application Number Title Priority Date Filing Date
JP2011149750A Pending JP2013015744A (en) 2011-07-06 2011-07-06 Optical connector

Country Status (1)

Country Link
JP (1) JP2013015744A (en)

Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN105785522A (en) * 2014-11-13 2016-07-20 国网河南省电力公司南阳供电公司 On-site optical cable butt joint device

Citations (7)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JP2003050320A (en) * 2001-08-07 2003-02-21 Nittoku Eng Co Ltd Method and device for stripping and removing coating of optical fiber
JP2003337227A (en) * 2002-05-21 2003-11-28 Sumitomo Electric Ind Ltd Method and device for removing coating of coated optical fiber ribbon
JP2005178102A (en) * 2003-12-18 2005-07-07 Dai Ichi Kasei Kk Mold for molding resin ferrule and its manufacturing method
JP2008292709A (en) * 2007-05-23 2008-12-04 Sumitomo Electric Ind Ltd Optical connection member
JP2009128422A (en) * 2007-11-20 2009-06-11 Sumitomo Electric Ind Ltd Optical connector and method for attaching optical connector to coated optical fiber
JP2010096983A (en) * 2008-10-16 2010-04-30 Nippon Telegr & Teleph Corp <Ntt> Optical fiber guide
JP2011002821A (en) * 2009-05-18 2011-01-06 Sumitomo Electric Ind Ltd Method of removing coating of optical fiber, member for removing coating, and optical connection member

Patent Citations (7)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JP2003050320A (en) * 2001-08-07 2003-02-21 Nittoku Eng Co Ltd Method and device for stripping and removing coating of optical fiber
JP2003337227A (en) * 2002-05-21 2003-11-28 Sumitomo Electric Ind Ltd Method and device for removing coating of coated optical fiber ribbon
JP2005178102A (en) * 2003-12-18 2005-07-07 Dai Ichi Kasei Kk Mold for molding resin ferrule and its manufacturing method
JP2008292709A (en) * 2007-05-23 2008-12-04 Sumitomo Electric Ind Ltd Optical connection member
JP2009128422A (en) * 2007-11-20 2009-06-11 Sumitomo Electric Ind Ltd Optical connector and method for attaching optical connector to coated optical fiber
JP2010096983A (en) * 2008-10-16 2010-04-30 Nippon Telegr & Teleph Corp <Ntt> Optical fiber guide
JP2011002821A (en) * 2009-05-18 2011-01-06 Sumitomo Electric Ind Ltd Method of removing coating of optical fiber, member for removing coating, and optical connection member

Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN105785522A (en) * 2014-11-13 2016-07-20 国网河南省电力公司南阳供电公司 On-site optical cable butt joint device

Similar Documents

Publication Publication Date Title
US8875403B2 (en) Coating removal tool used for optical fiber and method of removing coating
US7720345B2 (en) Optical connector assembling jig
JP3977335B2 (en) Optical fiber connection method and optical fiber connection tool
JP2009128422A (en) Optical connector and method for attaching optical connector to coated optical fiber
US9958618B2 (en) Method for assembling optical fiber connector
US20220155534A1 (en) Connector removal tool
JP2013015744A (en) Optical connector
JP2013015745A (en) Optical connector
JP5331979B2 (en) Removal tool and adapter removal method using the same
JP4191168B2 (en) Mechanical connection type optical connector
US8991044B2 (en) Method for inserting a wire into a contact pin with a wire insertion tool
JP2006178289A (en) Optical fiber holder and method of machining optical fiber cable
JP2013015748A (en) Optical connector
WO2020013059A1 (en) Optical connector, method for manufacturing optical fiber cable provided with optical connector, and optical fiber connection tool
JP5888881B2 (en) Optical connector
JP4593660B2 (en) Optical connector assembly tool
JP2013015747A (en) Optical connector
JP5367733B2 (en) Coating removal member, coating removal member manufacturing method, and optical connector
KR101838984B1 (en) Feffule for optical connector
JP2007121878A (en) Connecting tool for optical connector
JP2013015746A (en) Optical connector
JP4820782B2 (en) Optical fiber insertion jig
JP4441480B2 (en) Connection jig for optical connectors
JP5664924B2 (en) Connector and connector manufacturing method
JP2013015793A (en) Optical connector and assembling method of the optical connector

Legal Events

Date Code Title Description
A621 Written request for application examination

Free format text: JAPANESE INTERMEDIATE CODE: A621

Effective date: 20130918

A977 Report on retrieval

Free format text: JAPANESE INTERMEDIATE CODE: A971007

Effective date: 20140226

A131 Notification of reasons for refusal

Free format text: JAPANESE INTERMEDIATE CODE: A131

Effective date: 20140902

A521 Written amendment

Free format text: JAPANESE INTERMEDIATE CODE: A523

Effective date: 20141104

A02 Decision of refusal

Free format text: JAPANESE INTERMEDIATE CODE: A02

Effective date: 20150414