JPH0656060U - Continuous winding device for optical fiber cable - Google Patents

Abstract

(57) [Abstract] [Purpose] In an optical fiber cable continuous winding device in which an optical fiber drawn by a drawing device is taken up by a take-up roll while being taken up by a take-up roll, the allowable range of tension and impact applied to the optical fiber It keeps the temperature within the range and performs continuous winding with high reliability. [Structure] Optical fiber 2 sent from take-up roll 1
For storing a predetermined length of wire to the winding device 6 and a pinch roll for gripping the optical fiber 2 near the outlet of the winding device 3 when replacing the winding roll 6a of the winding device 6. Four
And is configured. By holding the optical fiber 2 by the pinch roll 4 and keeping the optical fiber freely handleable on the winding device 6 side, the winding roll 6a can be replaced smoothly. When the winding device 6 restarts winding, the pinch roll 4 is gradually accelerated so that the excessive force of the wire accumulating device 3 is not applied to the optical fiber 2 as a shock or tension exceeding the allowable range. .

Description

[Detailed description of the device]

[0001]

[Industrial applications]

 The present invention relates to a continuous winding device for an optical fiber cable.

[0002]

[Prior art]

 Conventionally, there are several methods for continuously winding an optical fiber, but the most common method is to wind two winding bobbins in parallel with each other and rotate at the same winding speed to empty the full bobbin. There is one that transfers an optical fiber to a bobbin. In this case, the difference in winding thickness between the full bobbin and the empty bobbin is detected based on the degree of slack in the optical fiber, and this is input as a deviation input of the winding speed, and the winding speed is adjusted by matching it with the drawing speed.

[0003]

[Problems to be solved by the device]

 However, when the optical fiber is transferred from the full bobbin to the empty bobbin by the conventional winding method described above, even if an attempt is made to adjust the winding speed of the full bobbin and the winding speed of the empty bobbin to be the same, Since the winding diameter and the winding diameter of the empty bobbin are different, errors are likely to occur. Since the allowable range of tension and impact applied to the optical fiber is much smaller than that of copper wire, if there is an error in the winding speed, it is necessary to instantly correct the error, but with the conventional method. It was not possible to carry out reliable continuous winding.

An object of the present invention is to solve the above-mentioned drawbacks of the prior art, and to suppress tension and impact applied to an optical fiber within an allowable range for continuous winding of an optical fiber cable with high reliability. To provide.

[0005]

[Means for Solving the Problems]

 In order to achieve the above object, the continuous winding device of the present invention is a continuous winding device for an optical fiber cable in which an optical fiber drawn by a drawing device is taken up by a winding device while being taken up by the winding device. A wire storage device that stores the optical fiber sent from the wire to the winding device while storing it for a predetermined length, and grips the optical fiber near the outlet of the wire storage device when replacing the winding bobbin of the winding device. And a pinch roll.

Further, the continuous winding device of the present invention detects the degree of slack of the optical fiber to obtain a tuning correction signal, and the rotation speed of the take-up roll to output a speed signal. Based on the take-up speed sensor, the feed speed sensor that detects the rotational speed of the pinch roll and outputs a speed signal, and the take-up speed command voltage based on the dancer synchronization correction signal and the take-up roll speed signal. A first winding speed command circuit that outputs a signal; and a second winding speed command circuit that outputs a winding speed command voltage signal based on the dancer tuning correction signal and the pinch roll speed signal. Based on the changeover switch that switches the output of these first and second winding speed command circuits, the integrator that compensates for the instantaneous signal voltage fluctuation when switching this switch, and the output signal of this integrator. And a motor controller for driving the winding motor.

Yes

[Action]

 According to the continuous winding device of the present invention configured as described above, while the winding bobbin is being replaced, the optical fiber is grasped by the pinch roll and the optical fiber is freely held on the winding device side. The winding bobbin can be replaced smoothly by keeping it in a handleable state, and when restarting the winding with the winding device, the pinch roll is gradually accelerated so that the excess of the accumulator can be avoided. It is possible to prevent the force from being applied to the optical fiber as a shock or tensile force beyond the allowable range.

When the winding is restarted, the winding speed command voltage signal output to the motor controller is switched to the signal of the second winding speed command circuit by the switch. Then, the motor controller accelerates the winding speed of the winding device in synchronization with the speed of the pinch roll based on the output signal of the second winding speed command circuit. At the time when the optical fiber feeding speed of the pinch roll becomes the same as the take-up setting speed, the take-up speed command voltages of the first and second take-up speed command circuits become equal. At this point, the storage device stops the storage line. Here, when the pinch roll releases the grip of the optical fiber, at the same time, the switch is switched to the first winding speed command circuit. The momentary signal voltage fluctuation when switching the switch is compensated by the integrator, so the signal is smoothly switched without turning off the winding speed command voltage, and the winding motor is always controlled stably. To be done. As a result, the impact and tension applied to the optical fiber are always kept within the allowable range.

[0009]

【Example】

 Hereinafter, an embodiment of the present invention will be described in detail with reference to FIGS.

FIG. 1 is a principle view for explaining an embodiment of an optical fiber continuous winding device of the present invention. In the figure, the optical fiber 2 taken from the take-up roll 1 is taken up by a take-up device 6 via a storage line device 3, a pinch roll 4 and a dancer 5. The take-up roll 1 is composed of a large-diameter drive roll 1a driven by a motor and three small-diameter driven rolls 1b which are rotated by being pressed against the peripheral surface of the drive roll 1a. It is adapted to be pulled out while passing through the driven roll 1b. The drive roll 1a of the take-up roll 1 is provided with a sensor 20 for detecting the take-up speed of the optical fiber 2. The wire storage device 3 includes four fixed rollers 3a arranged according to the height of the fiber outlet of the take-up roll 1, and three wire storage rollers 3b provided so as to be able to move up and down through these fixed rollers 3a. The storage dose of the optical fiber 2 can be adjusted by moving the storage line roller 3b up and down. The pinch roll 4 is composed of a fixed roll 4b provided at a fixed position above the fiber outlet of the storage device 3 and a gripping roll 4a that moves up and down on the fixed roll 4b. The gripping roll 4a is lowered to the fixed roll 4b. The optical fiber 2 can be gripped between the rolls 4a and 4b by bringing them into contact with each other. A sensor 21 for detecting the rotation speed of the pinch roll 4 is provided on the fixed roll 4b side. The dancer 5 has a pulley 5b for accommodating the optical fiber 2 at the tip of the rotating arm 5a biased downward, detects the looseness of the optical fiber 2 by the angle of the rotating arm 5a, and detects it. Output as a signal (tuning correction signal). Therefore, the dancer 5 is provided with a sensor 22 for detecting the turning angle of the turning arm 5a. In addition, in FIG. 1, the broken line portion shows the normal winding state, and the solid line portion shows an example of the state where the optical fiber 2 is being transferred.

FIG. 2 is a block diagram showing a winding motor control circuit of the winding device 6. The control circuit 23 outputs a first winding speed command voltage signal 12 based on the tuning correction signal 7 from the dancer 5 and the winding speed signal 8 of the winding roll 1. And a second winding speed command circuit 11 for outputting a second winding speed command voltage signal 13 based on the tuning correction signal 7 and the pinch roll speed signal 10, and the first and second winding speeds. A change-over switch 14 for changing over the speed command circuits 9 and 11, an integrator 16 for compensating for a momentary signal voltage fluctuation at the time of changing over the switch, and a winding motor 19 based on a signal from the integrator 16. It is composed of a motor controller 18 for driving.

With the above circuit configuration, the tuning correction signal 7 and the take-up speed signal 8 are input to the first winding speed instruction circuit 9, and the same tuning correction signal 7 and the pinch roll speed signal 10 are input to the second winding speed command circuit 9. It is input to the winding speed command circuit 11. The 12 and 13 winding speed command voltage signals output from the first and second winding speed command circuits 9 and 11 are switched by the switching switch 14. During this changeover operation, the winding speed command voltage signal 15 output from the changeover switch 14 becomes 0 V for a moment (the time required to connect the contacts), but the integrator 16 compensates for the momentary voltage fluctuation. As a result, the output voltage signal 17 of the integrator 16 is input to the motor controller 18 while keeping the same voltage as the voltage signal before switching. As a result, the motor controller 18 always operates stably and drives the winding motor 19 appropriately. It goes without saying that the delay time of the integrator 16 is in a range that does not hinder the winding response speed during normal work.

Next, the control operation of the continuous winding device of FIG. 1 will be described in detail with reference to the flowchart of FIG.

First, the take-up roll 1 is decelerated to the take-up set speed (step 31). After the completion of deceleration, the slow stop of the winding bobbin 6 and the storage line of the storage device 3 are simultaneously started (steps 32, 33, 34). When the winding bobbin 6 stops, the pinch roll 4 moves from the broken line portion to the solid line portion and holds the optical fiber 2 (steps 35 and 36). At this time, the changeover switch 14 is simultaneously operated to output the output voltage signal 15 from the winding speed command voltage signal 12 of the first winding speed command circuit 9 to the winding speed command voltage of the second winding speed command circuit 11. Switch to signal 13 (steps 37, 38). The switching of this signal is smoothly performed by the integrator 16. In this state, all of the optical fibers 2 are stored by the storage device 3, and the optical fibers on the exit side of the pinch roll are stopped. During this time, the optical fiber 2 is transferred from the full bobbin to the empty bobbin (step 39), and when it is completed (step 40), the pinch roll 4 is rotated by slow acceleration to send out the optical fiber 2 (step 41). Then, the operation of winding by the winding bobbin 6a is started (step 42). When the feeding speed of the pinch roll 4 becomes the same as the take-up setting speed, the holding roll 4a is raised while the fixed roll 4b of the pinch roll 4 is rotated to release the optical fiber holding (steps 43 and 44). At this time, the changeover switch 14 is simultaneously operated to output the output voltage signal 15 from the winding speed command voltage signal 13 of the second winding speed command circuit 11 to the winding speed command of the first winding speed command circuit 9. Switch to the voltage signal 12 (step 45). The switching of this signal is also smoothly performed by the integrator 16. From this point in time, the storage device 3 starts emitting the optical fiber 2. While the optical fiber 2 is being ejected, the winding speed becomes faster than the take-up setting speed, and the optical fiber 2 is wound while compensating for the emission amount. Then, when the optical fiber 2 of the storage device 3 is exhausted, the storage device 3 is stopped (steps 46 and 47). After that, the take-up roll 1 is accelerated, and when returning to the normal operation, the operation of switching the optical fiber of this device is completed (step 48).

Next, the role of the pinch roll 4 and the switching of the first and second winding speed circuits 9 and 11 will be described in detail. The role of the pinch roll 4 is to hold the optical fiber 2 at the outlet of the accumulator 3 while the winding bobbin 6a is being exchanged by the winding device 6, and to freely move the optical fiber 2 on the winding device 6 side. Make sure that it can be handled and that when the winding device 6 restarts winding, the excess force of the inertia of the storage device 3 will not be applied to the optical fiber 2 as a shock or tension beyond the allowable range. In addition, it is for starting the winding with slow and gentle acceleration. The winding speed command circuit at this time is the second winding speed command circuit 11 which receives the pinch roll speed signal 10 and the tuning correction signal 7. This is because the winding device 6 has to accelerate from the winding speed 0 to the same winding speed as the set winding speed in synchronization with the speed of the pinch roll 4. At the time when the optical fiber feeding speed of the pinch roll 4 becomes the same as the take-up setting speed, the take-up speed command voltages 12, 13 of the first and second take-up speed command circuits 9, 11 become equal. At this time, the storage line device 3 stops the storage line. At this time, the pinch roll 4 releases the optical fiber grip, and at the same time, the winding speed command voltage 12 of the first winding speed command circuit 9 is smoothed without turning off the winding speed command voltage 17 by using the multiplier 16. Is switched to. As a result, the impact and tension applied to the optical fiber 2 can be suppressed within an allowable range.

FIG. 4 shows the output voltage of the changeover switch 14, and FIG. 5 shows the output voltage of the integrator 16. In the figure, a on the vertical axis indicates the output voltage value of the first and second winding speed command circuits, t _{1 on} the horizontal axis indicates the time when the changeover switch 14 starts its operation, and t ₂ indicates the changeover time. The time when the operation of the switch 14 is completed is shown. In FIG. 4 the second winding speed command voltage signal 13 between t ₁ replaces Ri switching of t ₂ to the second winding speed command voltage signal 12 to become 0V, t from t ₁ in FIG. 5 _It can be seen that the same voltage is maintained during the period ₂ . By using the integrator 16 in this way, it is possible to eliminate fluctuations in the winding speed command voltage signal at the time of switching and to eliminate fluctuations in the speed of the winding motor.

[0017]

[Effect of device]

 In short, according to the continuous winding device of the present invention, the following excellent effects can be exhibited.

(1) When the optical fiber is transferred from the full bobbin to the empty bobbin, the optical fiber is not subjected to a shock or a tension exceeding an allowable range, so that highly reliable continuous winding is possible.

(2) For the reason (1) above, the optical fiber can be drawn endlessly by using the continuous winding device of the present invention together with the drawing device for continuously supplying the optical fiber. Therefore, the setup work can be significantly reduced and the productivity can be improved.

[Brief description of drawings]

FIG. 1 is a principle view for explaining an embodiment of a continuous winding device for an optical fiber cable according to the present invention.

FIG. 2 is a block diagram of a winding motor control circuit of the continuous winding device for an optical fiber cable according to the present invention.

FIG. 3 is a flow chart for explaining an optical fiber cutting operation in the continuous winding device for an optical fiber cable according to the present invention.

FIG. 4 is a graph showing changes in the output voltage of the changeover switch.

FIG. 5 is a graph showing changes in the output voltage of the integrator when the changeover switch is changed.

[Explanation of symbols]

 1 take-up roll 2 optical fiber 3 accumulator 4 pinch roll 5 dancer 6 take-up device 7 tuning correction signal 8 take-up speed signal 9 first take-up speed command circuit 10 pinch roll speed signal 11 second take-up speed command Circuit 12 First winding speed command voltage signal 13 Second winding speed command voltage signal 14 Changeover switch 15 Winding speed command voltage signal 16 Integrator 19 Winding motor 18 Motor controller 20 Sensor 21 Sensor 22 Sensor

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Susumu Sawahata 5-1-1 Hidakacho, Hitachi City, Ibaraki Prefecture Hidaka Plant, Hitachi Cable, Ltd. (72) Inventor Tetsuro Nakagawa 5 Hidakacho, Hitachi City, Ibaraki Prefecture 1-1-1 Hitachi Cable Co., Ltd. Hidaka Plant (72) Inventor Shoji Nomura 5-1-1 Hidakacho, Hitachi City, Ibaraki Hitachi Cable Co., Ltd. Hidaka Plant

Claims (2)

[Scope of utility model registration request] 1. A continuous winding device for an optical fiber cable in which an optical fiber drawn by a drawing device is taken up by a take-up roll while being taken up by a take-up roll, and an optical fiber sent from the take-up roll is stored for a predetermined length. A wire accumulating device for feeding the wire winding device to the winding device, and a pinch roll for gripping the optical fiber near the outlet of the wire accumulating device when the winding bobbin of the winding device is replaced, Continuous winding device for optical fiber cable. 2. A dancer that detects the degree of slack of the optical fiber to obtain a tuning correction signal, and a take-up speed sensor that detects the rotational speed of the take-up roll and outputs a speed signal.
A feed speed sensor for detecting the rotation speed of the pinch roll and outputting a speed signal, and a first for outputting a winding speed command voltage signal based on the dancer synchronization correction signal and the speed signal of the take-up roll. A winding speed command circuit, a second winding speed command circuit that outputs a winding speed command voltage signal based on the dancer tuning correction signal and the pinch roll speed signal, and the first and second winding speed command circuits. , A changeover switch for switching the output of the winding speed command circuit, an integrator that compensates for a momentary signal voltage fluctuation when switching this switch, and a winding motor is driven based on the output signal of this integrator. The continuous winding device for an optical fiber cable according to claim 1, further comprising a motor controller.