JP3238273B2 - Optical fiber winding machine and its rotation speed control method - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical fiber winder and a method for controlling the number of revolutions thereof.

[0002]

2. Description of the Related Art When a predetermined amount of winding is completed on a take-up bobbin, an optical fiber is cut to be replaced with a new bobbin. In this cutting, the optical fiber is pulled and a large tension is generated. There is. Therefore, in order to prevent the optical fiber from sinking into the already wound optical fiber laminate and damaging the outer surface of the laminated fiber, change the optical fiber line to a relief portion called a dummy roller before the cutting. Need to be done.

Conventionally, the control of the winding speed of a winding machine including a dummy roller and a winding bobbin has been performed by detecting the vertical movement of a dancer roll provided on the upstream side thereof and performing winding based on the detected value. It was performed by feedback control of the drive motor of the machine, but in this method, it was not possible to immediately respond to a change in the moving speed of the optical fiber due to a sudden change in the diameter when the optical fiber rides on the dummy roller from the winding bobbin, For this reason, there is a disadvantage that a large tension is generated and the optical fiber is damaged as in the case of the cutting.

[0004] Therefore, in response to a command which the optical fiber ride from the bobbin to the dummy roller, lower the winding rotational speed corresponding to the ratio of the barrel diameter D ₂ of the roll-up diameter D ₁ and the dummy roller of the winding bobbin According to this method, a sudden increase in the moving speed of the optical fiber is suppressed to prevent a sudden increase in the tension, and the outer surface of the optical fiber is not damaged (see Japanese Patent Application Laid-Open No. Hei 4 (1994)). -15997
No. 3).

[0005]

However, in the above-mentioned conventional control method, the winding speed is reduced in accordance with the ratio of the winding diameter of the winding bobbin to the body diameter of the dummy roller. If such amount is changed or, in the case of performing the switching of the bobbin in the course of a state in which the winding bobbin is not up winding, the variation of the take-up rotational speed in order to initially different from the winding diameter D ₁ of the bobbin set And the tension changes suddenly.

On the other hand, in order to prevent this, it is conceivable to measure the winding diameter of the bobbin immediately before performing the transfer to the dummy roller and input the winding diameter immediately before this as the set value D _1. Can be However, when measuring the winding diameter of the winding bobbin directly, with variations due to measurement error is likely to occur, the operator for the deal with winding amount of change or the like is required to re-enter the setting value D ₁ work Is complicated.

In view of such circumstances, the present invention provides an optical fiber winder and a rotation mechanism thereof that can prevent a sudden increase in tension when changing to a dummy roller even when the winding amount is changed or the bobbin is replaced halfway. It is an object to provide a number control method.

[0008]

In order to achieve the above object,
The present invention has taken the following technical measures. That is, the method of the present invention includes a winding bobbin for an optical fiber and a dummy roller that rotates at the same winding speed around the same axis as the bobbin, and the optical fiber is replaced before the winding bobbin is replaced. In an optical fiber winding machine in which a line is switched to the dummy roller, when the optical fiber line is switched from the winding bobbin to the dummy roller, the moving speed of the optical fiber is divided by the circumference of the dummy roller. The winding speed is switched to the set value.

More specifically, the moving speed of the optical fiber is determined based on the number of rotations of an optical fiber take-up machine provided downstream of the winding bobbin. Further, the apparatus of the present invention includes a winding bobbin for an optical fiber, a dummy roller that rotates at the same winding speed around the same axis as the bobbin, and a line of the optical fiber before replacing the winding bobbin. Switching means for transferring from the winding bobbin to the dummy roller, speed detecting means for detecting the moving speed of the optical fiber,
Dummy speed control means for setting the winding speed to a value obtained by dividing the moving speed of the optical fiber by the circumference of the dummy roller when the switching means is operated.

[0010]

According to the present invention, the moving speed V of the optical fiber 1 is detected in advance, and when the line of the optical fiber 1 is changed over to the dummy roller 9, the moving speed V of the optical fiber 1 is changed to the circumferential length of the dummy roller 9. The winding speed is switched to a value obtained by dividing by π · D ₂ ). As described above, since the rotational speed N ₂ after the transfer is obtained from the value of the moving speed V of the optical fiber 1,
Rotational speed N ₂ is Sadamari to any uniquely regardless of the winding outer diameter D _x of the winding bobbin 4, therefore, regardless of the transfer before the winding outer diameter D _x and rotational speed N _x, speed after transfer N ₂
Can be kept constant.

[0011]

Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 shows an optical fiber winding machine employing the method of the present invention. In the figure, a production line for an optical fiber 1 includes a take-up machine 3 for taking out the optical fiber 1 and sending it downstream, and a winding machine for winding the optical fiber 1 to be unwound from the take-up bobbin 4 rotating in a certain direction. 5 are provided.

The take-up machine 3 includes a capstan 7 driven by a take-up motor 6 and an annular belt 8 circulating in contact with the outer peripheral surface of the capstan 7. By driving the capstan 7 with the optical fiber 1 interposed therebetween, the optical fiber 1
At a constant speed. The take-up motor 6 is provided with means 6A for detecting the number of rotations. The rotation speed detection means 6A is connected to a bobbin speed control means 19 and a dummy speed control means 22, which will be described later, and measures the moving speed of the optical fiber 1 based on the rotation speed by the rotation speed detection means 6A. ing. Note that a tachometer, a pulse generator, or the like can be used as the rotation speed detecting means 6A.

The moving speed of the optical fiber 1 can be measured by a speed sensor provided in the vicinity of the flowing optical fiber 1 or a detector for detecting the number of rotations of the guide roller 24. Preferably, the speed of the optical fiber 1 is detected from the rotation speed of the machine 3. The reason is that the take-off machine 3 is a drive mechanism for determining the speed of the optical fiber 1 and has a structure that is specially designed to prevent the optical fiber 1 from slipping. This is because the speed can be known.

The winding machine 5 comprises a winding bobbin 4 for the optical fiber 1, a dummy roller 9 rotating at the same winding speed as the bobbin 4, a common drive shaft 10 for supporting these coaxially. , A drive motor 1 for rotating the drive shaft 10
And 1. As shown in FIG. 2, the dummy roller 9 is coaxially fixed to the root of the drive shaft 10. It is attached so that it can be inserted and removed in the axial direction. Therefore, when the winding on one winding bobbin 4 is completed, the bobbin 4 is pulled out of the drive shaft 10, and another new bobbin 4 is inserted through the drive shaft 10.

The drive shaft 10 is supported by a slider 13 so as to be reciprocally movable in the axial direction. The optical fiber 1 is distributed to the body 14 of the take-up bobbin 4 by the reciprocal movement of the drive shaft 10 and is taken up without bias. Can be On the other hand, drive shaft 1
The movement range of 0 is set to a range in which the line of the optical fiber 1 reciprocates substantially the entire length of the body portion 14 during the winding to the winding bobbin 4, but the winding to the winding bobbin 4 is completed. When replacing the drive shaft, the drive shaft 10 is projected to the left in FIG.
As a result, the line of the optical fiber 1 moves from the winding bobbin 4 to the dummy roller 9.

Thus, the slider 13
A switching means for switching the line of the optical fiber 1 from the winding bobbin 4 to the dummy roller 9 before replacing the winding bobbin 4 is provided. By moving the guide roller 24 provided immediately downstream of the winding machine 5 in the axial direction of the winding machine 5, the optical fiber 1 can be distributed or the above-mentioned switching means can be configured.
According to this, the line itself of the optical fiber 1 may be reciprocated right and left and an excessive tension may be generated. Therefore, it is preferable to move the winding bobbin 4 and the dummy roller 9 in the axial direction as described above.

A pair of front and rear pulleys 15 are juxtaposed between the take-up machine 3 and the winding machine 5, and a dancer roll 16 is provided between the pulleys 15 so as to be vertically movable. The dancer roll 16 is pivotally supported at the distal end of a vertically swingable guide arm 17, and a dancer position detector including a sensor for detecting the inclination angle of the arm 17 is provided at the base end of the guide arm 17. 18 are provided.

The dancer position detector 18 is connected to a bobbin speed control means 19 for feedback-controlling the rotation speed of the winding machine 5 in response to a change in the speed of the optical fiber 1 caused by the winding of the winding bobbin 4, and The bobbin speed control unit 19 is connected to a control unit 21 of the drive motor 11 via a changeover switch 20. That is, the winding bobbin 4
Optical fiber 1 at the time of winding up because the winding diameter of
Is gradually increased, the dancer roll 16 rises due to an increase in the tension received from the optical fiber 1, and this rise is detected by the dancer position detector 18. Therefore, the bobbin speed control unit 19 issues a command to the control unit 21 to decrease the rotation speed of the drive motor 11 based on the detection value of the dancer position detector 18, thereby moving the optical fiber 1 in the take-off machine 3. Winding machine 5 corresponding to speed V
Is always set to an appropriate value.

Further, in the optical fiber winding machine of the present embodiment, when the switching means is operated, that is, when the line of the optical fiber 1 is changed from the winding bobbin 4 to the dummy roller 9, the winding machine is operated. The dummy speed control means 22 forcibly sets the take-up rotation speed (N ₂ ) to a value obtained by dividing the moving speed (V) of the optical fiber 1 by the circumference (π · D ₂ ) of the dummy roller 9. The switching from the bobbin speed control means 19 to the dummy speed control means 22 is performed by an operation detector 23 including a limit switch for detecting the operation of the switching means and the changeover switch 20.

That is, the dummy speed control means 22 is provided in parallel with the bobbin speed control means 19 between the rotation speed detecting means 6A of the take-up machine 3 and the motor control section 21 of the winding machine 5, and The changeover switch 20 is provided on the output side. The changeover switch 20 is always connected to the bobbin speed control means 19, and when a signal from the operation detector 23 is issued, the bobbin speed control means 19 is turned on.
It is connected to the side.

The bobbin speed control means 19 and the dummy speed control means 22 can actually be incorporated in the same CPU. In this case, whether or not the dummy speed control means 22 is provided is determined only by an operation on a program. Can respond. Next, a method of controlling the number of rotations of the optical fiber winder will be described. First, while the optical fiber 1 is being wound on the winding bobbin 4, the changeover switch 20 is grounded on the bobbin speed control means 19 side, and the feedback control is performed by the means 19. Therefore, when the moving speed of the optical fiber 1 in this case V, and the winding outer diameter of the winding bobbin 4 and D _x, the winding machine 5 is rotated at a rotational speed N _x represented by the following formula I have.

N _x = V / (π · D _x ) On the other hand, when the line of the optical fiber 1 is transferred from the winding bobbin 4 to the dummy roller 9 for exchanging the winding bobbin 4, the operation detector 23 detects the operation of the slider 13, and the changeover switch 2
0 is grounded to the dummy speed control means 22 side. Therefore, the speed of movement of the optical fiber 1 in this case V, when the outer diameter of the dummy roller 9 and D _2, the rotational speed of the winder 5 is forcibly the rotational speed N ₂ which is represented by the following formula Can be switched.

N ₂ = V / (π · D ₂ ) As can be seen from the above equation, in the present invention, the moving speed V of the optical fiber 1 is detected, and from the value of the moving speed V, the number of revolutions N ₂ after the transfer is changed. , The rotational speed N ₂ is uniquely determined irrespective of the winding outer diameter D _x of the winding bobbin 4. Accordingly, the diameter winding out before transfer D _x and rotational speed N _x
Can regardless, the rotational speed N ₂ after transfer is kept constant at.

The above embodiment is illustrative and not restrictive. That is, the scope of the present invention is defined by the appended claims, and all modifications that fall within the meaning of the claims are included in the present invention.

[0025]

As described above, according to the present invention,
Sadamari the rotational speed N ₂ is uniquely without any relationship with the winding outer diameter D _x of the winding bobbin 4, the rotational speed N ₂ after irrespective transfer to transfer before the winding outer diameter D _x and rotational speed N _x Since it can be kept constant, even when the winding amount is changed or the bobbin 4 is replaced halfway, a sudden increase in the tension when changing to the dummy roller 9 can be prevented.

Further, since the moving speed V of the optical fiber 1 is obtained from the rotation speed of the take-up device 3 for the optical fiber 1 provided on the downstream side of the winding bobbin 4, an accurate speed of the optical fiber 1 can be obtained. There is an advantage.

[Brief description of the drawings]

FIG. 1 is a control configuration diagram of an optical fiber winder.

FIG. 2 is a plan view of the optical fiber winder.

[Explanation of symbols]

REFERENCE SIGNS LIST 1 optical fiber 3 take-up machine 4 take-up bobbin 5 take-up machine 9 dummy roller 13 switching means (slider) 16 dancer roll 19 bobbin speed control means 20 change-over switch 22 dummy speed control means D _x outside take-up by winding bobbin Diameter D ₂ Outer diameter of dummy roller N _x Number of winding rotations when winding bobbin N ₂ Number of winding rotations when changing dummy roller

──────────────────────────────────────────────────続 き Continuation of the front page (72) Inventor Shigeo Hiruma 2-3-1 Shinhama, Araimachi, Takasago-shi, Hyogo Kobe Steel, Ltd. Inside Takasago Works (56) References JP-A-4-159997 (JP, A JP-A-48-18542 (JP, A) JP-A-61-170708 (JP, A) JP-A-5-254729 (JP, A) JP-A-2-117566 (JP, A) 39438 (JP, U) (58) Field surveyed (Int. Cl. ⁷ , DB name) B65H 59/38 B65H 54/02 C03B 37/12

Claims (3)

(57) [Claims] 1. A bobbin for winding an optical fiber and a dummy roller rotating at the same winding speed around the same axis as the bobbin, and a line of the optical fiber is changed before the winding bobbin is replaced. In the optical fiber winder adapted to transfer to the dummy roller, when the optical fiber line is changed from the winding bobbin to the dummy roller, a value obtained by dividing a moving speed of the optical fiber by a circumference of the dummy roller. A rotation speed control method for the optical fiber winder, wherein the winding speed is switched. 2. The optical fiber winding machine according to claim 1, wherein the moving speed of the optical fiber is obtained based on the number of rotations of the optical fiber winding machine provided downstream of the winding bobbin. Speed control method. 3. A winding bobbin for an optical fiber, a dummy roller rotating at the same winding speed around the same axis as the bobbin, and winding the optical fiber line before replacing the winding bobbin. Switching means for transferring from the bobbin to the dummy roller, speed detecting means for detecting the moving speed of the optical fiber, and a value obtained by dividing the moving speed of the optical fiber by the circumference of the dummy roller when operating the switching means. An optical fiber winder, comprising: a dummy speed control means for setting the winding speed.