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JP3449297B2 - Method and apparatus for winding linear body on winding frame - Google Patents
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JP3449297B2 - Method and apparatus for winding linear body on winding frame - Google Patents

Method and apparatus for winding linear body on winding frame

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Publication number
JP3449297B2
JP3449297B2 JP18102999A JP18102999A JP3449297B2 JP 3449297 B2 JP3449297 B2 JP 3449297B2 JP 18102999 A JP18102999 A JP 18102999A JP 18102999 A JP18102999 A JP 18102999A JP 3449297 B2 JP3449297 B2 JP 3449297B2
Authority
JP
Japan
Prior art keywords
linear body
winding
guide member
winding frame
wound
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.)
Expired - Lifetime
Application number
JP18102999A
Other languages
Japanese (ja)
Other versions
JP2001002320A (en
Inventor
一郎 畑中
将之 大久保
茂 末森
只昭 春木
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.)
Sumitomo Electric Industries Ltd
Original Assignee
Sumitomo Electric Industries 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 Sumitomo Electric Industries Ltd filed Critical Sumitomo Electric Industries Ltd
Priority to JP18102999A priority Critical patent/JP3449297B2/en
Publication of JP2001002320A publication Critical patent/JP2001002320A/en
Application granted granted Critical
Publication of JP3449297B2 publication Critical patent/JP3449297B2/en
Anticipated expiration legal-status Critical
Expired - Lifetime legal-status Critical Current

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Description

【発明の詳細な説明】Detailed Description of the Invention

【0001】[0001]

【発明の属する技術分野】本発明は、テープ状光ファイ
バ心線等の特にテープ形状の線状体の巻枠への整列巻取
りに適した巻枠への線状体の巻取り方法及び巻取り装置
に関する。
BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method of winding a linear body on a winding frame suitable for aligning and winding a tape-shaped linear body such as a tape-shaped optical fiber on the winding frame. Regarding the taker.

【0002】[0002]

【従来の技術】図5は、テープ状光ファイバ心線の横断
面図である。複数本の光ファイバ心線11aを平行に並
べて紫外線硬化型樹脂等の一括被覆11bを施したテー
プ状光ファイバ心線11は、厚さtが0.3mm〜0.
4mm程度、幅Wが1mm〜4mm程度の横断面を有す
るテープ状の線状体であって、通常巻枠に整列巻きされ
て搬送される。
2. Description of the Related Art FIG. 5 is a cross-sectional view of a tape-shaped optical fiber core wire. The tape-shaped optical fiber core wire 11 in which a plurality of optical fiber core wires 11a are arranged in parallel and collectively coated with an ultraviolet curable resin 11b has a thickness t of 0.3 mm to 0.
It is a tape-shaped linear body having a cross section of about 4 mm and a width W of about 1 mm to 4 mm, and is usually wound around a winding frame and conveyed.

【0003】図6は、テープ状光ファイバ心線が巻枠に
整列して巻き取られたところを示す横断面図であって、
12は巻枠、13は胴、14は鍔、15は1層目のテー
プ状光ファイバ心線、16は2層目のテープ状光ファイ
バ心線、17は3層目のテープ状光ファイバ心線であ
る。巻枠12は、円筒状の胴13とその両端に円盤状の
鍔14を備え、中心軸O−O’を有し、胴13上にテー
プ状光ファイバ心線11を各層整列して巻取り、更にそ
の上に多層状に巻き取る。図6では3層だけ図示した
が、通常の場合巻取り層数は数十層から百数十層にな
る。
FIG. 6 is a cross-sectional view showing a tape-shaped optical fiber core wire wound in alignment with a winding frame.
12 is a reel, 13 is a barrel, 14 is a collar, 15 is a first-layer tape-shaped optical fiber core wire, 16 is a second-layer tape-shaped optical fiber core wire, and 17 is a third-layer tape-shaped optical fiber core wire. It is a line. The winding frame 12 includes a cylindrical body 13 and disk-shaped collars 14 at both ends thereof, has a central axis OO ′, and winds the tape-shaped optical fiber core wires 11 on the body 13 by aligning each layer. , And then roll it up in multiple layers. Although only three layers are shown in FIG. 6, the number of winding layers is normally several tens to one hundred and several tens.

【0004】巻枠12は、通常胴径200mm〜250
mm、胴幅250mm〜300mm、鍔径400mm程
度の大きさで、テープ状光ファイバ心線11を、巻枠の
胴13上にテープ状光ファイバ心線の幅よりもわずかに
大きいピッチで一周毎に巻取り箇所を巻枠の中心軸方向
にトラバースしながら列をなすようにして整列して巻き
取る。そして、1層目の巻き取りが完了するとトラバー
ス方向がターンして1層目の上に2層目を巻き取る。そ
して、これを繰り返して巻枠の胴面に多層状にテープ状
光ファイバ心線を巻き取る。
The bobbin 12 usually has a body diameter of 200 mm to 250.
mm, a body width of 250 mm to 300 mm, and a collar diameter of about 400 mm, the tape-shaped optical fiber core wire 11 is arranged on the barrel 13 of the winding frame at a pitch slightly larger than the width of the tape-shaped optical fiber core wire. Then, the winding positions are aligned and wound in a row while traversing the winding shaft in the central axis direction of the winding frame. When the winding of the first layer is completed, the traverse direction turns and the second layer is wound on the first layer. Then, by repeating this, the tape-shaped optical fiber core wire is wound in multiple layers on the barrel surface of the winding frame.

【0005】各層のテープ状光ファイバ心線の列と列の
隙間に上層のテープ状光ファイバ心線が落ち込んだり、
隣接する列にテープ状光ファイバ心線が乗り上げたりす
ると、テープ状光ファイバ心線に異常な曲げが生じ、テ
ープ状光ファイバ心線中の光ファイバの伝送特性が悪化
するので、テープ状光ファイバ心線は各層共、整列して
巻き取る必要がある。
[0005] The tape-shaped optical fiber core wires of the upper layer may fall into the spaces between the rows of the tape-shaped optical fiber core wires of each layer,
If the tape-shaped optical fiber cores run on adjacent rows, the tape-shaped optical fiber cores will be abnormally bent, and the transmission characteristics of the optical fibers in the tape-shaped optical fiber cores will deteriorate. It is necessary to wind the core wires in alignment in each layer.

【0006】図7は、巻枠にテープ状光ファイバ心線を
巻き取る装置の主要部を示す斜視図であって、18はト
ラバースガイド、18aはガイドローラ、18bはガイ
ド軸である。この装置では、テープ状光ファイバ心線1
1は、ガイドローラ18aによって巻枠12の胴13上
に案内され、巻枠12の回転によって胴13上に巻き取
られる。また、ガイドローラ18aはガイド軸18bに
沿って一定速度で巻枠12の中心軸方向に移動するの
で、ガイドローラ18aで案内されるテープ状光ファイ
バ心線11の位置も巻枠12の中心軸方向に逐次移動
し、胴13の上に整列してテープ状光ファイバ心線11
を巻き取ることが出来る。
FIG. 7 is a perspective view showing a main part of an apparatus for winding a tape-shaped optical fiber core wire around a winding frame, in which 18 is a traverse guide, 18a is a guide roller, and 18b is a guide shaft. In this device, the tape-shaped optical fiber core wire 1
1 is guided onto the barrel 13 of the reel 12 by the guide roller 18a, and is wound onto the barrel 13 by the rotation of the reel 12. Further, since the guide roller 18a moves along the guide shaft 18b in the central axis direction of the winding frame 12 at a constant speed, the position of the tape-shaped optical fiber core 11 guided by the guide roller 18a is also the central axis of the winding frame 12. In the tape-like optical fiber core 11
Can be wound up.

【0007】なお、1層目の巻取りが完了すると、ガイ
ドローラ18aの移動方向即ちトラバース方向が反転し
て、1層目の上に2層目が巻き取られる。1つの層の巻
取りが完了する毎にトラバース方向の反転即ちターンが
行われ、これが繰り返されて、多い時には200回のタ
ーンが行われる。
When the winding of the first layer is completed, the moving direction of the guide roller 18a, that is, the traverse direction is reversed and the second layer is wound on the first layer. Each time one layer is wound, the traverse direction is reversed or turned, and this is repeated, and when the winding is large, 200 turns are made.

【0008】[0008]

【発明が解決しようとする課題】巻枠の胴径は通常20
0mm〜250mm、鍔径400mm程度の大きさであ
り、ガイドローラを保持するガイド軸は通常巻枠の鍔の
外側に巻枠の中心軸と平行に配置されるので、ガイドロ
ーラを通過したテープ状光ファイバ心線は、巻枠の胴上
に巻き取られるまでには通常200mm以上の空間を走
行する。テープ状光ファイバ心線は厚さ0.3mm、幅
1.1mm程度の極細い線状体であって、テープ状光フ
ァイバ心線の伝送特性を保護するために大きい張力を加
えることは出来ないので、ガイドローラと巻枠の胴上と
の間でテープ状光ファイバ心線が振動等を受けて揺れる
ことがある。
The barrel diameter of the bobbin is usually 20.
It has a size of 0 mm to 250 mm and a flange diameter of 400 mm, and the guide shaft for holding the guide roller is usually arranged outside the flange of the reel in parallel with the center axis of the reel. The optical fiber core wire normally runs in a space of 200 mm or more before being wound on the barrel of the reel. The tape-shaped optical fiber core wire is an extremely thin linear body having a thickness of 0.3 mm and a width of about 1.1 mm, and a large tension cannot be applied to protect the transmission characteristics of the tape-shaped optical fiber core wire. Therefore, the tape-shaped optical fiber core wire may be shaken due to vibration or the like between the guide roller and the body of the winding frame.

【0009】ガイドローラは一定速度でトラバース移動
していても、テープ状光ファイバ心線の揺れによって巻
枠の胴上に到達したテープ状光ファイバ心線の位置が正
常位置からずれることが起こる。テープ状光ファイバ心
線の位置がずれると先に巻き取られたテープ状光ファイ
バ心線の上に乗り上げたり、列間に大きな隙間が生じた
りして、整列巻きが出来なくなる。このような現象は、
巻取り速度が比較的小さい場合には殆ど起こらないが、
巻取り速度が大きくなると発生し易くなり、巻取り速度
の増大と共に頻繁に起こるようになる。従って、生産性
を向上させる上では、巻取り速度が大きくなっても整列
巻きが可能な巻取り方法及び装置が求められている。
Even if the guide roller is traversing at a constant speed, the position of the tape-shaped optical fiber core that has reached the cylinder of the winding frame may deviate from the normal position due to the shaking of the tape-shaped optical fiber core. If the position of the tape-shaped optical fiber core is deviated, the tape-shaped optical fiber core may be climbed onto the previously wound tape-shaped optical fiber or a large gap may be formed between the rows, so that the aligned winding cannot be performed. Such a phenomenon is
It hardly happens when the winding speed is relatively low,
It tends to occur as the winding speed increases, and frequently occurs as the winding speed increases. Therefore, in order to improve productivity, there is a demand for a winding method and device capable of performing aligned winding even when the winding speed is high.

【0010】本発明は、この要求に応える巻枠へのテー
プ状光ファイバ心線等の線状体の巻取り方法及び巻取り
装置を提供するものである。
The present invention provides a winding method and a winding device for winding a linear body such as a tape-shaped optical fiber core wire around a winding frame that meets this demand.

【0011】[0011]

【課題を解決するための手段】本発明の巻枠への線状体
の巻取り方法は、線状体通過孔を有するガイド部材を用
い、該ガイド部材の線状体通過孔の出口中心位置が巻枠
の胴又は巻枠に巻き取られた線状体の表面から巻枠半径
方向に極めて近い距離を保ちながら該ガイド部材を巻枠
の中心軸方向と平行に移動させ、該ガイド部材の線条体
通過孔に線条体を通して該線条体を整列させて前記巻枠
に巻取る方法において線条体はテープ状光ファイバ心
線であって、前記ガイド部材の線状体通過孔の中心線方
向は、該ガイド部材を出た線状体の進行方向に対して巻
枠の中心軸側に5〜30度傾いていることを特徴とする
巻枠への線状体の巻取り方法である。これによって、ガ
イド部材の線状体通過孔の摩擦によって線状体に適当な
張力を与えながら、線状体を巻枠側に押さえ付けること
が出来るので、線状体通過孔を通過した線状体の揺れを
より小さくすることが出来る。
A method of winding a linear body around a reel according to the present invention uses a guide member having a linear body passage hole, and the center position of the outlet of the linear body passage hole of the guide member is used. While moving the guide member parallel to the central axis direction of the reel while maintaining a very close distance in the radial direction of the reel from the surface of the body of the reel or the linear body wound on the reel. in winding Ru method on the winding frame by the該線Article body aligned through striatum striatum passage hole, striatum tape-shaped optical fiber heart
A line, the center line direction of the linear body passage hole of the guide member, it is inclined 5 to 30 degrees toward the central axis of the bobbin with respect to the traveling direction of the linear body exiting the guide member And a method for winding a linear body around a winding frame. By this, the linear body can be pressed against the winding frame side while giving an appropriate tension to the linear body by the friction of the linear body passage hole of the guide member. You can make the body shake smaller.

【0012】 また、該ガイド部材の線状体通過孔の出口
中心位置が巻枠の胴又は巻枠に巻き取られた線状体の表
面から巻枠半径方向に1mm〜5mm離れた位置となる
ように保ちながら該ガイド部材を巻枠の中心軸方向と平
行に移動させ、線状体の巻取り層数の増加に応じて前記
ガイド部材を巻枠の中心軸から離れる方向にかつ該ガイ
ド部材の線状体通過孔の出口中心位置が巻枠に巻き取ら
れた線状体の表面から巻枠半径方向に1mm〜5mm離
れた位置となるように移動させるものである。
Further, the center position of the outlet of the linear body passage hole of the guide member is a position 1 mm to 5 mm away from the surface of the body of the winding frame or the linear body wound on the winding frame in the radial direction of the winding frame. The guide member is moved in parallel with the central axis direction of the winding frame while keeping such a state, and the guide member is moved away from the central axis of the winding frame in accordance with an increase in the number of winding layers of the linear body and the guide member. The center position of the outlet of the linear body passage hole is moved to a position 1 mm to 5 mm away from the surface of the linear body wound on the winding frame in the radial direction of the winding frame.

【0013】 これによって、線状体が細くて軽いもので
あっても、ガイド部材の線状体通過孔を通過して、大き
な距離を走行することなく直に巻枠の胴上又は先に巻き
取られた線状体の上に巻き取ることが出来るので、線状
体は揺れることが少なくなり整列巻きを行なうことが出
来る。
[0013] Thus, even lighter and thinner linear body passes through the linear body passage hole of the guide member, around the torso or on the previous directly bobbin without traveling a greater distance Since the linear body can be wound on the taken linear body, the linear body is less likely to shake and can be aligned and wound.

【0014】[0014]

【発明の実施の形態】図1は本発明にかかる巻枠への線
状体の巻取り装置の主要部を示す図であって、図1
(A)はその斜視図、図1(B)は線状体巻取り部分の
縦断面図である。図1において、1は線状体の一例であ
るテープ状光ファイバ心線、2は巻枠、2aは胴、2b
は鍔、3はガイド部材、3aは線状体通過孔、4はガイ
ド部材位置制御装置、5は表面位置測定手段である。
1 is a diagram showing a main part of a device for winding a linear body around a winding frame according to the present invention.
FIG. 1 (A) is a perspective view thereof, and FIG. 1 (B) is a longitudinal sectional view of a winding portion of the linear body. In FIG. 1, 1 is a tape-shaped optical fiber core which is an example of a linear body, 2 is a winding frame, 2a is a barrel, and 2b
Is a flange, 3 is a guide member, 3a is a linear body passage hole, 4 is a guide member position control device, and 5 is a surface position measuring means.

【0015】図1(A)に示すように、線状体の一例で
あるテープ状光ファイバ心線1を、ガイド部材3の線状
体通過孔3aを通して、ガイド部材3を巻枠2の中心軸
方向と平行に一定速度で移動させながら、巻枠2の胴2
a上にテープ状光ファイバ心線1を整列して巻き取る。
1層目の巻取りが終わるとガイド部材3の移動方向即ち
トラバース方向を反転させて、1層目の上に2層目のテ
ープ状光ファイバ心線1を巻き取る。更に、これを繰り
返してテープ状光ファイバ心線1を巻枠2の胴2a上に
多層に巻き取る。ここで使用するガイド部材3の線状体
通過孔3aは、テープ状光ファイバ心線1の断面よりわ
ずかに大きい断面を有し、テープ状光ファイバ心線1が
線状体通過孔3aに内壁面を摺動しながら通過する孔
で、その孔の長さは5mm以上であることが望ましい。
As shown in FIG. 1 (A), a tape-shaped optical fiber core wire 1 which is an example of a linear body is passed through a linear body passage hole 3a of a guide member 3, and the guide member 3 is placed at the center of a bobbin 2. While moving at a constant speed parallel to the axial direction, the barrel 2 of the reel 2
The tape-shaped optical fiber core wire 1 is aligned and wound on a.
When the winding of the first layer is completed, the moving direction of the guide member 3, that is, the traverse direction is reversed, and the tape-shaped optical fiber core wire 1 of the second layer is wound on the first layer. Further, by repeating this, the tape-shaped optical fiber core wire 1 is wound in multiple layers on the barrel 2a of the winding frame 2. The linear body passage hole 3a of the guide member 3 used here has a cross section slightly larger than the cross section of the tape-shaped optical fiber core wire 1, and the tape-shaped optical fiber core wire 1 is inside the linear body passage hole 3a. It is a hole that slides along the wall surface, and the length of the hole is preferably 5 mm or more.

【0016】ガイド部材3の巻枠2に対する半径方向の
位置関係を、図1(B)によって詳細に説明する。ガイ
ド部材3の線状体通過孔3aを出たテープ状光ファイバ
心線1を巻枠の胴2a上又は先に巻き取られたテープ状
光ファイバ心線の層上に整列して巻き取る。Oは巻枠の
中心軸の位置を示し、OXは水平方向を示す。既に胴2
a上に巻き取られたテープ状光ファイバ心線1の表面に
新しく巻き取られるテープ状光ファイバ心線1が接触す
るが、その接触位置の新しく巻き取られるテープ状光フ
ァイバ心線1の中心を点Qとし、ガイド部材3の線状体
通過孔3aの出口の中心を点Pとする。また、OPと巻
き取られたテープ状光ファイバ心線の表面との交点をR
とする。
The positional relationship of the guide member 3 with respect to the winding frame 2 in the radial direction will be described in detail with reference to FIG. The tape-shaped optical fiber core wire 1 that has exited the linear body passage hole 3a of the guide member 3 is aligned and wound on the barrel 2a of the winding frame or on the layer of the tape-shaped optical fiber core wire that has been previously wound. O indicates the position of the central axis of the reel, and OX indicates the horizontal direction. Already torso 2
The newly wound tape-shaped optical fiber core wire 1 comes into contact with the surface of the tape-shaped optical fiber core wire 1 wound on a, and the center of the newly wound tape-shaped optical fiber core wire 1 at the contact position. Is the point Q, and the center of the outlet of the linear member passage hole 3a of the guide member 3 is the point P. In addition, the intersection of OP and the surface of the wound tape-shaped optical fiber is R
And

【0017】テープ状光ファイバ心線1の厚さ=t、O
R=r、RP=d、PQ=aとすると、△OPQは直角
三角形であるので、次の式が成り立つ。 a2+(r+t/2)2=(r+d)2 この式から、r=150mm、t=0.3mmと仮定す
ると、d=1mmの時はa=17mm、d=5mmの時
はa=40mmとなり、dを1mm〜5mmとすると、
aは略17mm〜40mmに収まることが分かる。従っ
て、本発明にかかる巻枠への線状体の巻取り方法又は装
置においては、ガイド部材3を通過したテープ状光ファ
イバ心線1が接触点Qに至るまでの距離は17mm〜4
0mm程度の短い距離であるので、テープ状光ファイバ
心線の走行時の揺れを十分に抑制することが出来る。
Thickness of the tape-shaped optical fiber core wire 1 = t, O
If R = r, RP = d, and PQ = a, then ΔOPQ is a right triangle, so the following equation holds. a 2 + (r + t / 2) 2 = (r + d) 2 From this equation, assuming that r = 150 mm and t = 0.3 mm, a = 17 mm when d = 1 mm and a = 40 mm when d = 5 mm. And when d is 1 mm to 5 mm,
It can be seen that a falls within approximately 17 mm to 40 mm. Therefore, in the winding method or apparatus for winding the linear body on the winding frame according to the present invention, the distance from the tape-shaped optical fiber core wire 1 passing through the guide member 3 to the contact point Q is 17 mm to 4 mm.
Since the distance is as short as about 0 mm, it is possible to sufficiently suppress the shaking of the tape-shaped optical fiber core wire during traveling.

【0018】また、ガイド部材3の線状体通過孔3aの
中心線方向PSを水平方向からδだけ傾斜させて配置す
る。特にδに対する制限はないが、ガイド部材の動作を
観察し易くするため、δは0度〜30度程度が望まし
い。また、テープ状光ファイバ心線に摩擦力による張力
を与えるために、ガイド部材3の線状体通過孔3aの長
さは5mm以上が好ましい。
Further, the linear member passage hole 3a of the guide member 3 is arranged with the center line direction PS inclined by δ from the horizontal direction. There is no particular limitation on δ, but δ is preferably about 0 to 30 degrees in order to make it easier to observe the operation of the guide member. Further, in order to apply tension due to frictional force to the tape-shaped optical fiber core wire, the length of the linear body passage hole 3a of the guide member 3 is preferably 5 mm or more.

【0019】また、線状体通過孔3aの中心線方向PS
を、線状体通過孔3aを出たテープ状光ファイバ心線1
の進行方向PQに対して巻枠の中心軸O側に5〜30度
傾ける。即ち、∠SPQ=θを5〜30度とする。θが
5度よりも小さいと押さえ付けの効果が少なく、又θが
30度を超えると線状体通過孔の出口でテープ状光ファ
イバ心線に大きな曲げを与えるので、θは5〜30度の
範囲とすることが望ましい。
In addition, in the direction PS of the center line of the linear body passing hole 3a
Is the tape-shaped optical fiber core wire 1 that has exited the linear body passage hole 3a.
5 to 30 degrees toward the central axis O of the winding frame with respect to the traveling direction PQ. That is, ∠SPQ = θ is set to 5 to 30 degrees. When θ is smaller than 5 degrees, the pressing effect is small, and when θ exceeds 30 degrees, the tape-shaped optical fiber core wire is largely bent at the exit of the linear body passage hole, so θ is 5 to 30 degrees. It is desirable to set the range to.

【0020】これによって、ガイド部材を通過するテー
プ状光ファイバ心線にガイド部材によって適当な張力を
与えながら、テープ状光ファイバ心線を巻枠側に押さえ
付けることが出来るので、テープ状光ファイバ心線の揺
れはより小さくなる。なお、この押さえ付けは、線状体
がもつ曲げ弾性を利用するものなので、押さえ付けの効
果は線状体の形状がテープ状光ファイバ心線のようなテ
ープ状である時に特に大きくなる。
As a result, the tape-shaped optical fiber core wire passing through the guide member can be pressed against the winding frame side while applying appropriate tension to the tape-shaped optical fiber core wire by the guide member. The sway of the core wire becomes smaller. Since this pressing uses the bending elasticity of the linear body, the pressing effect is particularly great when the shape of the linear body is a tape-like optical fiber core.

【0021】巻枠に巻き取られたテープ状光ファイバ心
線等の線状体の層数が増加すると、巻枠中心から巻き取
られた線状体の表面までの半径がそれに従って増加する
ので、それに伴ってガイド部材を巻枠の中心軸から離れ
る方向に移動させる位置制御を行なう必要がある。次に
その位置制御について説明する。
When the number of layers of the linear body such as the tape-shaped optical fiber core wire wound around the winding frame increases, the radius from the center of the winding frame to the surface of the wound linear body increases accordingly. Accordingly, it is necessary to perform position control for moving the guide member in a direction away from the central axis of the winding frame. Next, the position control will be described.

【0022】通常、巻き取られた線状体の表面までの半
径に比較して線状体1本の厚さ又は外径は無視出来る程
度であるので、以下線状体の厚さ又は外径は無視して説
明する。図2は巻き取られた線状体の表面とガイド部材
と線状体の位置関係を示す縦断面図で、図3、図4はそ
れぞれ、線状体の表面までの半径の増加に応じてガイド
部材を移動させる時の移動方法の事例を示す縦断面図で
ある。
Usually, the thickness or outer diameter of one linear body is negligible as compared with the radius to the surface of the wound linear body. Therefore, the thickness or outer diameter of the linear body will be described below. Ignore and explain. FIG. 2 is a vertical cross-sectional view showing the positional relationship between the surface of the wound linear body, the guide member and the linear body, and FIGS. 3 and 4 respectively show an increase in radius to the surface of the linear body. It is a longitudinal section showing an example of a moving method when moving a guide member.

【0023】図2、図3、図4において、6、6’は巻
き取られる前の線状体、7、7’は巻枠に巻き取られた
線状体の表面、8、8’はガイド部材、8a、8a’は
線状体通過孔、OXは水平方向、P、P’は線状体通過
孔の出口中心位置、R、R’はOP又はOP’と表面7
又は7’との交点、Q、Q’は線状体6又は6’が表面
7又は7’に接触する点、S、S’は線状体通過孔8a
又は8a’の中心線の延長線がOQ又はOQ’に交わる
点である。
In FIGS. 2, 3, and 4, 6 and 6 ′ are linear bodies before being wound, 7, 7 ′ are the surfaces of the linear bodies wound on the bobbin, and 8 and 8 ′ are Guide members, 8a and 8a 'are linear body passage holes, OX is horizontal, P and P'are outlet center positions of linear body passage holes, and R and R'are OP or OP' and surface 7.
Or 7 ′, Q, Q ′ are points where the linear body 6 or 6 ′ contacts the surface 7 or 7 ′, and S and S ′ are linear body passage holes 8a.
Alternatively, an extension line of the center line of 8a 'intersects OQ or OQ'.

【0024】ガイド部材8又は8’は、これらの位置制
御事例においては平行移動させるので、線状体通過孔8
a、8a’の水平方向からの傾きδは常に一定である。
Since the guide member 8 or 8 ′ is translated in these position control cases, the linear body passage hole 8 is formed.
The inclination δ of a and 8a ′ from the horizontal direction is always constant.

【0025】図2において、巻枠の中心Oから表面7ま
での半径をrとすると、OQ=OR=rとなる。また、
表面7とガイド部材8の線状体通過孔8aの出口中心P
との距離RPをdとすると、OP=OR+RP=r+d
である。また、ガイド部材8の線状体通過孔8aの中心
線方向PSは水平方向に対して角度δだけ傾いているの
で、線状体通過孔8aの出口中心位置Pが巻枠中心から
水平半径方向(X方向)に対して角度βの方向にあると
すると、ガイド部材8からの線状体の出線方向と巻枠中
心に対するガイド部材8の位置方向とのなす角は、∠O
PS=α=β+δとなる。
In FIG. 2, if the radius from the center O of the winding frame to the surface 7 is r, then OQ = OR = r. Also,
The outlet center P of the linear body passage hole 8a of the surface 7 and the guide member 8
If the distance RP to and is d, then OP = OR + RP = r + d
Is. Further, since the center line direction PS of the linear body passage hole 8a of the guide member 8 is inclined by an angle δ with respect to the horizontal direction, the outlet center position P of the linear body passage hole 8a is in the horizontal radial direction from the center of the winding frame. Assuming that it is at an angle β with respect to the (X direction), the angle formed by the direction in which the linear body extends from the guide member 8 and the position direction of the guide member 8 relative to the center of the winding frame is ∠O
PS = α = β + δ.

【0026】また、△OPQは直角三角形となるので、
ガイド部材を出た線状体13の出線方向と線状体通過孔
12aの中心線方向とがなす角をθ、PQ=aとする
と、 a2+r2=(r+d)2 cos(α+θ)=cos(β+δ+θ)=a/(r+
d) という関係が成立し、r、d、β、δが与えられれば、
a、θは決まる。即ち、巻枠に巻き取られた線状体の表
面の半径(r)と、ガイド部材12の位置(d、β)
と、その線状体通過孔の傾き(δ)が決まれば、線状体
通過孔の中心線方向と線状体通過孔を出た線状体の出線
方向との角度(θ)及びガイド部材を出た線状体が巻き
取られるまでの距離(a)が決まる。
Since ΔOPQ is a right triangle,
If the angle formed by the outgoing line direction of the linear body 13 that has exited the guide member and the central line direction of the linear body passage hole 12a is θ, and PQ = a, then a 2 + r 2 = (r + d) 2 cos (α + θ) = Cos (β + δ + θ) = a / (r +
If the relation d) holds and r, d, β and δ are given,
a and θ are determined. That is, the radius (r) of the surface of the linear body wound on the reel and the position (d, β) of the guide member 12
And the inclination (δ) of the linear body passing hole is determined, the angle (θ) between the centerline direction of the linear body passing hole and the outgoing line direction of the linear body passing through the linear body passing hole and the guide The distance (a) until the linear body exiting the member is wound is determined.

【0027】線状体の巻取り層数の増加に応じてrが増
加するので、常にdを1mm〜5mmの範囲とするに
は、ガイド部材の位置も巻枠の中心線から離れる方向に
移動させる必要がある。ガイド部材の位置をORの方向
に移動させる場合、OQと平行な方向に移動させる場合
について考える。
Since r increases as the number of winding layers of the linear body increases, the position of the guide member also moves in the direction away from the center line of the winding frame in order to keep d within the range of 1 mm to 5 mm. Need to let. Consider the case where the position of the guide member is moved in the direction of OR, and the case where it is moved in the direction parallel to OQ.

【0028】図3は、ガイド部材の位置をORの方向に
移動させる場合を説明する縦断面図であって、巻枠の巻
き取られた線状体の表面半径はrからr’に増加し、ガ
イド部材は8から8’に表面半径の増加に合わせて平行
移動すると仮定する。そうすると、PはP’に、Rは
R’に、QはQ’に移動し、PQ=aはP’Q’=a’
に、∠SPQ=θは∠S’P’Q’=θ’に変化する。
FIG. 3 is a vertical cross-sectional view for explaining the case where the position of the guide member is moved in the direction of OR. The surface radius of the wound linear body of the winding frame increases from r to r '. , The guide member translates from 8 to 8'as the surface radius increases. Then, P moves to P ', R moves to R', Q moves to Q ', and PQ = a changes to P'Q' = a '.
Then, ∠SPQ = θ changes to ∠S'P'Q '= θ'.

【0029】この時、RP=R’P’=d、∠OPS=
∠OP’S’=α=β+δは変わらないので、 a2+r2=(r+d)2 cos(β+δ+θ)=a/(r+d) (a’)2+(r’)2=(r’+d)2 cos(β+δ+θ’)=a’/(r’+d) が成り立つ。
At this time, RP = R'P '= d, ∠OPS =
Since ∠OP'S '= α = β + δ does not change, a 2 + r 2 = (r + d) 2 cos (β + δ + θ) = a / (r + d) (a') 2 + (r ') 2 = (r' + d) 2 cos (β + δ + θ ′) = a ′ / (r ′ + d) holds.

【0030】r’>rなので、上記の式からa’>a、
θ’>θが導かれ、線状体通過孔の中心線方向と線状体
通過孔を出た線状体の出線方向とがなす角度(θ)及び
ガイド部材を出た線状体が巻き取られるまでの距離
(a)は、線状体の巻取り層数の増加に応じて大きくな
る。例えば、r=150mm、r’=200mm、d=
1mm又は5mmとすると、a=17mm又は40m
m、a’=20mm又は45mmとなる。従ってこの範
囲に移動では、P’Q’=a’は45mm以下に収まる
ので、線状体の揺れを十分に抑制することが出来る。ま
た、θはθ’となっても1〜2度の増加なので、特に問
題はない。
Since r '> r, from the above equation, a'> a,
θ ′> θ is introduced, and the angle (θ) formed by the center line direction of the linear body passing hole and the outgoing line direction of the linear body passing through the linear body passing hole and the linear body leaving the guide member are The distance (a) before winding is increased with an increase in the number of winding layers of the linear body. For example, r = 150 mm, r ′ = 200 mm, d =
If 1 mm or 5 mm, a = 17 mm or 40 m
m, a ′ = 20 mm or 45 mm. Therefore, when moving within this range, P'Q '= a' falls within 45 mm or less, so that the sway of the linear body can be sufficiently suppressed. Further, even if θ becomes θ ′, there is no problem because it increases by 1 to 2 degrees.

【0031】図4は、ガイド部材の位置をOQと平行な
方向に移動させる場合を説明する縦断面図であって、巻
枠の巻き取られた線状体の表面半径はrからr’に増加
し、ガイド部材は8から8’に表面半径の増加に合わせ
て平行移動すると仮定する。そうすると、PはP’に、
RはR’に、QはQ’に移動し、∠ROX=βは∠R’
OX=β’に、∠OPS=α=β+δは∠OP’S’=
α’=β’+δに、RP=dはR’P’=d’に変化す
る。
FIG. 4 is a vertical cross-sectional view for explaining a case where the position of the guide member is moved in a direction parallel to OQ. The surface radius of the linear body wound on the winding frame is changed from r to r '. It is assumed that the guide member translates from 8 to 8'increase with increasing surface radius. Then P becomes P ',
R moves to R ', Q moves to Q', and ∠ROX = β is ∠R '
OX = β ', ∠OPS = α = β + δ is ∠OP'S' =
α ′ = β ′ + δ, and RP = d changes to R′P ′ = d ′.

【0032】この時、PQ=P’Q’=a、∠SPQ=
∠S’P’Q’=θは変わらないので、 a2+r2=(r+d)2 cos(β+δ+θ)=a/(r+d) a2+(r’)2=(r’+d’)2 cos(β’+δ+θ)=a/(r’+d’) が成り立つ。
At this time, PQ = P'Q '= a, ∠SPQ =
Since ∠S'P'Q '= θ does not change, a 2 + r 2 = (r + d) 2 cos (β + δ + θ) = a / (r + d) a 2 + (r') 2 = (r '+ d') 2 cos (Β ′ + δ + θ) = a / (r ′ + d ′) holds.

【0033】r’>rなので、上記の式からd’<dが
導かれ、巻枠に巻き取られた線状体の表面とガイド部材
の線状体通過孔の出口との距離(d)は、線状体の巻取
り層数の増加に応じて小さくなる。例えば、r=150
mm、r’=200mm、d=1mm又は5mmとする
と、a=17mm又は40mmであるので、d’=0.
7mm又は4mmとなる。従って、dを1mm〜5mm
の範囲内であるように制御するにはdの初期値を1.5
mm〜5mm程度にしておくか、途中でdを増加させる
補正を行なう必要がある。
Since r '> r, d'<d is derived from the above equation, and the distance (d) between the surface of the linear body wound on the winding frame and the outlet of the linear body passage hole of the guide member. Becomes smaller as the number of winding layers of the linear body increases. For example, r = 150
mm, r ′ = 200 mm, d = 1 mm or 5 mm, a = 17 mm or 40 mm, so d ′ = 0.
It becomes 7 mm or 4 mm. Therefore, d is 1 mm to 5 mm
To control the value to be within the range of, the initial value of d is 1.5
It is necessary to set it to about 5 mm to 5 mm, or to perform a correction to increase d in the middle.

【0034】なおこの場合は、線状体通過孔の中心線方
向と線状体通過孔を出た線状体の出線方向との角度
(θ)及びガイド部材を出た線状体が巻き取られるまで
の距離(a)は、線状体の巻取り層数が増加しても変わ
らないので、線状体の走行時の揺れの抑制及び線状体の
押え込みについては、巻取り層数が増加しても均一に行
なうことが出来る。
In this case, the angle (θ) between the center line direction of the linear body passing hole and the outgoing line direction of the linear body passing through the linear body passing hole and the linear body leaving the guide member are wound. The distance (a) until the wire is taken does not change even if the number of winding layers of the linear body is increased. Therefore, regarding the suppression of shaking of the linear body during running and the pressing of the linear body, the number of winding layers is taken. Can be performed even if the number increases.

【0035】以上、巻き取られる線状体の層数の増加に
応じてガイド部材の位置を制御するに当たって、ガイド
部材を巻枠の半径方向に移動させる例、ガイド部材を巻
枠中心から線状体が巻き取られる接触点の方向と平行な
方向へ移動させる例について説明したが、ガイド部材の
移動はこれに限られるものではない。巻き取られた線状
体の層数の増加に応じて、上記以外の方向であっても定
められた方向に定められたピッチで移動させることが出
来る。
As described above, in controlling the position of the guide member in accordance with the increase in the number of layers of the wound linear body, the guide member is moved in the radial direction of the winding frame, for example, the guide member is linear from the center of the winding frame. The example in which the body is moved in a direction parallel to the direction of the wound contact point has been described, but the movement of the guide member is not limited to this. In accordance with the increase in the number of layers of the wound linear body, the linear body can be moved at a predetermined pitch in a predetermined direction even in a direction other than the above.

【0036】なお、ガイド部材の移動に当たっては、図
1(A)に示すガイド部材移動制御装置4を使って、ガ
イド部材3をM2、M3方向に駆動モータ、ボールネジ等
によって移動させれば良い。なお、M1方向はトラバー
ス方向であって、1つの層内の線状体を整列して巻き取
る時に使用するもので常に一定速度で往復移動してい
る。
In order to move the guide member, the guide member movement control device 4 shown in FIG. 1 (A) is used to move the guide member 3 in the directions M 2 and M 3 by a drive motor, a ball screw or the like. good. The M 1 direction is the traverse direction, which is used when aligning and winding the linear bodies in one layer, and always reciprocates at a constant speed.

【0037】また、線状体を巻枠に層状に巻き取る場
合、線状体の1本当たりの厚さ又は外径に層数を掛けた
ものと実際の複数層全体の厚さは異なることが多い。断
面円形の線状体の場合は、上の層の線状体は下の層の線
状体の間に少し落ち込んで俵積み状態で巻き取られるた
め、複数層全体の厚さは外径×層数よりも小さくなる。
また、テープ状線状体の場合は下層の上に上層が重ねら
れるが、層間に若干の隙間が出来るため、複数層全体の
厚さは外径×層数よりも大きくなる。
When the linear body is wound around the winding frame in layers, the thickness of the linear body or the outer diameter multiplied by the number of layers should be different from the actual thickness of the plurality of layers. There are many. In the case of a linear body with a circular cross-section, the linear bodies of the upper layer fall slightly between the linear bodies of the lower layer and are wound up in a bale stack, so the total thickness of multiple layers is the outer diameter x It is smaller than the number of layers.
Further, in the case of a tape-shaped linear body, the upper layer is laminated on the lower layer, but since there is a slight gap between the layers, the total thickness of the plurality of layers becomes larger than (outer diameter) × (number of layers).

【0038】そこで、ガイド部材の位置を正確に制御す
るに当たっては、図1(A)に示すように表面位置測定
手段5を設置して巻き取られた線状体の表面位置を測定
し、巻き取られた線状体表面の巻枠中心からの半径を算
出する。表面位置測定手段5としてはレーザ光を出射し
て反射光を受けて位置を測定するレーザ光線位置測定器
等を用いることが出来る。
Therefore, in order to accurately control the position of the guide member, the surface position measuring means 5 is installed as shown in FIG. 1 (A) to measure the surface position of the wound linear body and The radius of the surface of the taken linear body from the center of the winding frame is calculated. As the surface position measuring means 5, a laser beam position measuring device or the like which emits a laser beam and receives reflected light to measure the position can be used.

【0039】このように実際に巻き取られた線状体の表
面半径を測定することによって、より正確にガイド部材
の位置制御を行なうことが出来る。ガイド部材の移動方
向を予め定めておけば、表面位置測定手段の測定結果
と、図2を使って、d=1mm〜5mm、θ=5度〜3
0度を満たす範囲のガイド部材位置を容易に計算で求め
ることが出来るので、ガイド部材位置制御装置の制御機
構に計算及び指令を出す装置を付加することで容易に位
置制御を行なうことが出来る。
By thus measuring the surface radius of the linear body actually wound up, the position of the guide member can be controlled more accurately. If the moving direction of the guide member is determined in advance, d = 1 mm to 5 mm and θ = 5 degrees to 3 using the measurement result of the surface position measuring means and FIG.
Since the position of the guide member within the range of 0 degrees can be easily calculated, the position control can be easily performed by adding a device for issuing a calculation and a command to the control mechanism of the guide member position control device.

【0040】以上、実際に巻き取られた線状体の表面半
径を測定する例を示したが、線状体の種類、サイズが決
まれば、巻取り層数×線状体の厚さ又は外径と、複数層
全体の厚さの比はほぼ一定である。従って、それらから
実効的な1層当たりの平均厚さを求めておけば、上述し
たような表面位置測定手段を使用せずとも、実効的平均
厚さとガイド部材のトラバースターンから得た層数を使
ってガイド部材を移動させて位置制御を行なえば、ガイ
ド部材の線状体通過孔出口中心と巻き取られた線状体の
表面との距離を1mm〜5mmの範囲内に制御すること
が出来る。
An example of measuring the surface radius of the linear body actually wound has been described above. However, if the type and size of the linear body are determined, the number of winding layers × the thickness of the linear body or the outside can be determined. The ratio between the diameter and the total thickness of the layers is almost constant. Therefore, if the effective average thickness per layer is obtained from them, the effective average thickness and the number of layers obtained from the traverse turns of the guide member can be calculated without using the surface position measuring means as described above. If the guide member is moved to perform position control using the guide member, the distance between the outlet of the linear member passing hole of the guide member and the surface of the wound linear member can be controlled within a range of 1 mm to 5 mm. .

【0041】[0041]

【発明の効果】本発明の巻枠への線状体の巻取り方法
は、ガイド部材の線状体通過孔の中心線方向を、該ガイ
ド部材を出た線状体の進行方向に対して巻枠の中心軸側
に5〜30度傾けることによって、線状体に適当な張力
を与えながら、線状体を巻枠側に押さえ付けることが出
来るので、線状体通過孔を通過した線状体の揺れをより
小さくすることが出来る。
According to the method of winding a linear body around a winding frame of the present invention, the direction of the center line of the linear body passage hole of the guide member is set with respect to the traveling direction of the linear body that exits the guide member. By inclining to the central axis side of the winding frame by 5 to 30 degrees, the linear body can be pressed against the winding frame side while giving an appropriate tension to the linear body. It is possible to make the shaking of the body smaller.

【0042】 また、線状体通過孔の出口中心位置が巻枠
に巻き取られた線状体の表面から巻枠半径方向に1mm
〜5mm離れた位置となるように線状体の巻取り層数の
増加に応じて該ガイド部材を巻枠の中心軸から離れる方
向に移動させながら、該ガイド部材の線状体通過孔に前
記線状体を通過させて前記巻枠へ該線状体を巻き取るも
のであるので、線状体が細くて軽いものであっても、線
状体は揺れることが少なくなり整列巻きを行なうことが
出来る。
Further, the center position of the outlet of the linear body passage hole is 1 mm in the radial direction of the winding frame from the surface of the linear body wound on the winding frame.
While moving the guide member in the direction away from the central axis of the winding frame in accordance with the increase in the number of winding layers of the linear body so as to be located at a position distant by ~ 5 mm, Since the linear body is wound around the winding frame by passing through the linear body, even if the linear body is thin and light, the linear body is less likely to sway, and the line winding is performed. Can be done.

【0043】ガイド部材の巻枠の中心軸から離れる方向
への移動に伴う位置制御に当たって、その移動方向を例
えば巻枠半径方向あるいは巻枠への線状体の接触位置半
径方向と平行な方向等に予め定めて、層数の増加に応じ
て一定ピッチでガイド部材を移動させることにすれば、
ガイド部材の位置制御は容易である。また、その移動方
向を巻枠への線状体の接触位置半径方向と平行な方向等
にすれば、ガイド部材の移動によっても、ガイド部材か
ら出た線状体の接触位置までの距離及び線状体通過孔方
向と線状体出線方向との傾きが変わらないので、より均
一な条件で巻取りを行なうことが出来る。
In the position control accompanying the movement of the guide member in the direction away from the central axis of the winding frame, the movement direction is, for example, the radial direction of the winding frame or the direction parallel to the radial direction of the contact position of the linear body with the winding frame. In advance, if the guide member is moved at a constant pitch as the number of layers increases,
Position control of the guide member is easy. Further, if the moving direction is set in a direction parallel to the radial direction of the contact position of the linear body with the winding frame, the distance and the line from the guide member to the contact position of the linear body can be moved by the movement of the guide member. Since the inclinations of the linear body passing hole direction and the linear body outgoing line direction do not change, winding can be performed under more uniform conditions.

【0044】また、表面位置測定手段を設置して線状体
の表面位置を測定し、それに基づいてガイド部材の移動
を制御すれば、線状体の実際の位置を正確に把握するこ
とが出来るので、ガイド部材のより精密な位置制御を行
なうことが出来る。
If the surface position measuring means is installed to measure the surface position of the linear body and the movement of the guide member is controlled based on this, the actual position of the linear body can be accurately grasped. Therefore, more precise position control of the guide member can be performed.

【図面の簡単な説明】[Brief description of drawings]

【図1】本発明にかかる巻枠への線状体の巻取り装置の
主要部を示す図であって、(A)はその斜視図、(B)
は線状体巻取り部分の縦断面図である。
FIG. 1 is a diagram showing a main part of a device for winding a linear body around a winding frame according to the present invention, in which (A) is a perspective view thereof and (B) is a diagram showing the same.
FIG. 4 is a vertical cross-sectional view of a linear body winding portion.

【図2】本発明にかかる巻枠への線状体の巻取り方法に
おいて、巻き取られた線状体の表面とガイド部材と線状
体の位置関係を説明する縦断面図である。
FIG. 2 is a vertical cross-sectional view for explaining the positional relationship between the surface of the wound linear body, the guide member, and the linear body in the method for winding the linear body around the winding frame according to the present invention.

【図3】本発明にかかる巻枠への線状体の巻取り方法に
おいて、巻き取られた線状体の層数の増加に応じてガイ
ド部材を半径方向に移動させる事例を説明する縦断面図
である。
FIG. 3 is a longitudinal cross-sectional view for explaining an example of moving the guide member in the radial direction according to the increase in the number of layers of the wound linear body in the winding method of the linear body around the winding frame according to the present invention. It is a figure.

【図4】本発明にかかる巻枠への線状体の巻取り方法に
おいて、巻き取られた線状体の層数の増加に応じてガイ
ド部材を巻枠中心から接触点に至る方向と平行に移動さ
せる事例を説明する縦断面図である。
FIG. 4 is a view showing a method of winding a linear body around a winding frame according to the present invention, in which a guide member is parallel to a direction from a center of the winding frame to a contact point as the number of layers of the wound linear body increases. It is a longitudinal cross-sectional view for explaining an example of moving to.

【図5】テープ状光ファイバ心線の横断面図である。FIG. 5 is a cross-sectional view of a tape-shaped optical fiber core wire.

【図6】テープ状光ファイバ心線が巻枠に巻き取られた
ところを示す横断面図である。
FIG. 6 is a transverse cross-sectional view showing a tape-shaped optical fiber core wound around a winding frame.

【図7】従来技術によるテープ状光ファイバ心線の巻取
り装置の主要部を示す斜視図である。
FIG. 7 is a perspective view showing a main part of a winding device for a tape-shaped optical fiber core wire according to a conventional technique.

【符号の説明】[Explanation of symbols]

1:線状体の一例であるテープ状光ファイバ心線 2:巻枠 2a:胴 2b:鍔 3:ガイド部材 3a:線状体通過孔 4:ガイド部材位置制御装置 5:表面位置測定手段 6、6’:巻き取られる前の線状体 7、7’:巻枠に巻き取られた線状体の表面 8、8’:ガイド部材 8a、8a’:線状体通過孔 OX:水平方向 P、P’:線状体通過孔の出口中心位置 Q、Q’:線状体6又は6’が表面7又は7’に接触す
る点 R、R’:OP又はOP’と表面7又は7’との交点 S、S’:線状体通過孔8a又は8a’の中心線の延長
線がOQ又はOQ’に交わる点
1: Tape-shaped optical fiber core wire which is an example of a linear body 2: Winding frame 2a: Body 2b: Collar 3: Guide member 3a: Linear body passage hole 4: Guide member position control device 5: Surface position measuring means 6 , 6 ': linear body 7 before being wound, 7': surface 8 of the linear body wound on the winding frame, 8 ': guide members 8a, 8a': linear body passage hole OX: horizontal direction P, P ': Exit center position Q of the linear body passage hole, Q': Point R, R ': OP or OP' and surface 7 or 7 at which the linear body 6 or 6'contacts the surface 7 or 7 '. Intersection point S, S'with ': Point where extension of center line of linear body passage hole 8a or 8a' intersects OQ or OQ '

フロントページの続き (72)発明者 春木 只昭 神奈川県横浜市栄区田谷町1番地 住友 電気工業株式会社横浜製作所内 (56)参考文献 特開 昭62−235172(JP,A) 実開 平3−15858(JP,U) 実開 昭55−90670(JP,U) (58)調査した分野(Int.Cl.7,DB名) B65H 54/28 B65H 54/02 G02B 6/44 391 H01B 13/00 Front page continuation (72) Inventor Tadaaki Haruki, 1 Taya-cho, Sakae-ku, Yokohama-shi, Kanagawa Sumitomo Electric Industries, Ltd. Yokohama Works (56) Reference JP 62-235172 (JP, A) Sankaihei 3- 15858 (JP, U) Actual development Sho 55-90670 (JP, U) (58) Fields investigated (Int.Cl. 7 , DB name) B65H 54/28 B65H 54/02 G02B 6/44 391 H01B 13/00

Claims (7)

(57)【特許請求の範囲】(57) [Claims] 【請求項1】 線状体通過孔を有するガイド部材を用
い、該ガイド部材の線状体通過孔の出口中心位置が巻枠
の胴又は巻枠に巻き取られた線状体の表面から巻枠半径
方向に極めて近い距離を保ちながら該ガイド部材を巻枠
の中心軸方向と平行に移動させ、該ガイド部材の線条体
通過孔に線条体を通して該線条体を整列させて前記巻枠
に巻取る方法において線条体はテープ状光ファイバ心
線であって、前記ガイド部材の線状体通過孔の中心線方
向は、該ガイド部材を出た線状体の進行方向に対して巻
枠の中心軸側に5〜30度傾いていることを特徴とする
巻枠への線状体の巻取り方法。
1. A guide member having a linear body passage hole is used, and an outlet center position of the linear body passage hole of the guide member is wound from the body of the winding frame or the surface of the linear body wound on the winding frame. The guide member is moved in parallel with the central axis direction of the winding frame while maintaining a distance very close to the radial direction of the frame, and the linear member is passed through the linear member passage hole of the guide member to align the linear member with the winding member. in winding Ru method to the frame, striatum tape-shaped optical fiber heart
A line, the center line direction of the linear body passage hole of the guide member, it is inclined 5 to 30 degrees toward the central axis of the bobbin with respect to the traveling direction of the linear body exiting the guide member A method for winding a linear body around a reel.
【請求項2】 ガイド部材の線状体通過孔の出口中心位
置が巻枠の胴又は巻枠に巻き取られた線状体の表面から
巻枠半径方向に1mm〜5mm離れた位置となるように
保ちながら該ガイド部材を巻枠の中心軸方向と平行に移
動させ、線状体の巻取り層数の増加に応じて前記ガイド
部材を巻枠の中心軸から離れる方向にかつ該ガイド部材
の線状体通過孔の出口中心位置が巻枠に巻き取られた線
状体の表面から巻枠半径方向に1mm〜5mm離れた位
置となるように移動させることを特徴とする請求項1に
記載の巻枠への線状体の巻取り方法。
2. The outlet center position of the linear body passage hole of the guide member is located at a position 1 mm to 5 mm away from the surface of the body of the winding frame or the linear body wound on the winding frame in the radial direction of the winding frame. The guide member is moved in parallel with the direction of the central axis of the winding frame while keeping the same, and the guide member is moved in a direction away from the central axis of the winding frame in accordance with an increase in the number of winding layers of the linear body. in claim 1 in which the outlet center position of the linear body passage hole, characterized in that the moving such that the position away 1mm~5mm from the wound surface of the linear body in the winding frame to the winding frame radially
A method for winding a linear body on the reel described above.
【請求項3】線状体通過孔を有するガイド部材を用い、
該ガイド部材の線状体通過孔の出口中心位置が巻枠の胴
又は巻枠に巻き取られた線状体の表面から巻枠半径方向
極めて近い距離を保ちながら該ガイド部材を巻枠の中
心軸方向と平行に移動させ、該ガイド部材の線条体通過
孔に線条体を通して該線条体を整列させて前記巻枠に巻
る装置において線条体はテープ状光ファイバ心線で
あって、前記ガイド部材の線状体通過孔の中心線方向
を、該ガイド部材を出た線状体の進行方向に対して巻枠
の中心軸側に5〜30度傾け、該ガイド部材の線状体通
過孔に線状体を通過させて前記巻枠へ該線状体を整列さ
せて多層状に巻き取ることを特徴とする巻枠への線状体
の巻取り装置。
3. A guide member having a linear body passage hole is used,
The guide member of the bobbin is kept at a very close distance in the radial direction of the bobbin from the surface of the body of the bobbin or the wire wound on the bobbin so that the outlet center position of the wire passage hole of the guide member is very close . central axis parallel to the direction moved, in the apparatus that the winding <br/> said spool aligning the該線Article body through striatum apertures in the striatum of the guide member, striatum tape Optical fiber core
Then, the centerline direction of the linear body passage hole of the guide member is inclined to the central axis side of the winding frame by 5 to 30 degrees with respect to the traveling direction of the linear body that exits the guide member, An apparatus for winding a linear body on a winding frame, wherein the linear body is passed through the linear body passage hole, the linear body is aligned with the winding frame, and is wound in a multi-layer form.
【請求項4】 ガイド部材の線状体通過孔の出口中心位
置が巻枠の胴又は巻枠に巻き取られた線状体の表面から
巻枠半径方向に1mm〜5mm離れた位置となるように
保ちながら該ガイド部材を巻枠の中心軸方向と平行に移
動させ、線状体の巻取り層数の増加に応じて前記ガイド
部材を巻枠の中心軸から離れる方向にかつ該ガイド部材
の線状体通過孔の出口中心位置が巻枠に巻き取られた線
状体の表面から巻枠半径方向に1mm〜5mm離れた位
置となるように位置制御することを特徴とする請求項3
に記載の巻枠への線状体の巻取り装置。
4. The outlet center position of the linear body passage hole of the guide member is located at a position 1 mm to 5 mm away from the surface of the body of the winding frame or the linear body wound on the winding frame in the radial direction of the winding frame. The guide member is moved in parallel with the direction of the central axis of the winding frame while keeping the same, and the guide member is moved in a direction away from the central axis of the winding frame in accordance with an increase in the number of winding layers of the linear body. claim outlet center position of the linear body passing holes, characterized in that position control so that the position away 1mm~5mm from the wound surface of the linear body to reel the spool radial direction 3
An apparatus for winding a linear body on a reel according to item 1.
【請求項5】 前記巻枠への前記線状体の巻取り層数の
増加に応じて、前記ガイド部材を巻枠の中心軸から離れ
る側の予め定めた方向に予め定めたピッチで移動させる
ことにより該ガイド部材の位置制御を行なうことを特徴
とする請求項に記載の巻枠への線状体の巻取り装置。
5. The guide member is moved at a predetermined pitch in a predetermined direction away from the central axis of the winding frame in accordance with an increase in the number of winding layers of the linear body on the winding frame. The device for winding a linear body around a winding frame according to claim 4 , wherein the position of the guide member is controlled by doing so.
【請求項6】 前記ガイド部材を移動させる予め定めた
方向は、巻枠中心から前記線状体の巻取り位置へ向かう
半径方向と平行な方向であり、前記予め定めたピッチ
は、巻取り層数1層当たりの平均厚さであることを特徴
とする請求項に記載の巻枠への線状体の巻取り装置。
6. The predetermined direction in which the guide member is moved is parallel to the radial direction from the center of the winding frame to the winding position of the linear body, and the predetermined pitch is the winding layer. The winding device for winding a linear body around a winding frame according to claim 5 , wherein an average thickness per several layers.
【請求項7】 前記巻枠へ巻き取られた線状体の表面位
置を測定する表面位置測定手段を備え、該表面位置測定
手段の測定結果に基づいて、前記ガイド部材を巻枠の中
心軸から離れる方向に移動させることを特徴とする請求
に記載の巻枠への線状体の巻取り装置。
7. A surface position measuring means for measuring the surface position of the linear body wound on the winding frame is provided, and the guide member is attached to the center axis of the winding frame based on the measurement result of the surface position measuring means. The device for winding a linear body onto a reel according to claim 4 , wherein the device is moved in a direction away from.
JP18102999A 1999-06-28 1999-06-28 Method and apparatus for winding linear body on winding frame Expired - Lifetime JP3449297B2 (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
JP18102999A JP3449297B2 (en) 1999-06-28 1999-06-28 Method and apparatus for winding linear body on winding frame

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
JP18102999A JP3449297B2 (en) 1999-06-28 1999-06-28 Method and apparatus for winding linear body on winding frame

Publications (2)

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JP2001002320A JP2001002320A (en) 2001-01-09
JP3449297B2 true JP3449297B2 (en) 2003-09-22

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Country Link
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* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JP5707769B2 (en) * 2010-08-03 2015-04-30 住友電気工業株式会社 Winding method and winding device for optical fiber ribbon
JP7538597B2 (en) * 2019-12-13 2024-08-22 キヤノンメディカルシステムズ株式会社 Winding device and winding method
KR20250179788A (en) * 2024-06-24 2025-12-31 엘에스전선 주식회사 Optical Fiber Ribbon Bobbin and a Winding System for the Optical Fiber Ribbon.

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