JPS63170238A - Optical fiber winding device - Google Patents

Abstract

PURPOSE:To obtain the title optical fiber winding device capable of smoothly winding and transferring even a high-speed wire, by providing a winder having a spare winding drum for winding the leading end of optical fiber having approximately the same diameter as that of the flange part of a winding bobbin and a tension controller for variable-controlling the tension exerted on the optical fiber to be moved onto the winding bobbin drum from the spare winding drum. CONSTITUTION:While the optical fiber F is received by a receiving machine 8, the wiredrawing speed is gradually increased, and the optical fiber end is fixed to the spare drum 13 when the speed is still low. The optical fiber F is wound on the part A1-A0 of the winding drum 13 until the wiredrawing condition is stabilized at high speed, and the optical fiber F is transferred from A0 B0 after the condition is stabilized. In this case, the air cylinder 9e of the tension controller 9 is driven simultaneously with the start of transfer to increase the downward load on a dancer pulley 9c. After the optical fiber winding position is transferred from A0 B0, the downward load on the pulley 9c by the cylinder 9e is released, and steady winding is started under low tension.

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to an optical fiber winding device that winds up an optical fiber from a take-up machine of an optical fiber drawing device.

[Prior art] After winding an optical fiber using an optical fiber drawing device, the structural parameters and transmission characteristics of the optical fiber are tested and
In order to perform the inspection, a fiber length of approximately 6 to 10 m is required at the starting point (lower end) and ending point (upper end) of the optical fiber wound around the winding bobbin. There is no problem in taking out the end of the optical fiber from the upper opening, but the following method is used to take out the optical fiber from the lower opening.

■Rather than winding the optical fiber uniformly over the entire width of the winding bobbin body, wind the required length at one end of the winding bobbin body to form the lower end of the fiber, leaving this part. A method for winding an optical fiber; ■ A method for separating and winding the lower fiber portion by providing an intermediate flange for separating the lower end at a predetermined position on the winding bobbin body; ■ A separate rewinding device after drawing is completed. There was a method of rewinding with a 2-head winder, and a method of switching winding with a two-head winder.

By the way, when winding an optical fiber in an optical fiber drawing device, etc., the structure, transmission characteristics, and other characteristics of the optical fiber do not immediately meet the expected performance from the start of drawing, and various working conditions are stabilized and the optical Draw a considerable length of optical fiber until the fiber properties are stabilized.
It takes. After this unwinding, the optical fiber should be wound onto a winding bobbin, but the drawing speed under stable conditions is, for example, 150 m/sin or 250 i/i.
When the winding speed is +in or higher, it is extremely difficult to fix (fix) the end of the optical fiber at the start of winding to the winding bobbin because the optical fiber breaks more easily than gold r4rJ material or the like. Therefore, there is a natural limit to the linear speed at which the starting end of optical fiber winding can be fixed to the winding bobbin. For example, when done manually by an expert, it is at most 50 to 60 m/a+in.
Even when an automatic terminal fixing device is used, the success rate of fixing decreases as the speed increases, making smooth winding difficult.

[Problems to be solved by the invention] In some cases, the length of the optical fiber is 1000 to ts.
oom, so in methods ① and ① above, a large bobbin area is required for winding the fiber at the beginning of winding (hereinafter referred to as "wasted winding"), and the bobbin becomes unexpectedly large. As a result, the winding device becomes unnecessarily large. In addition, in the method (■), if the winding width of the waste winding part is narrowed, it is likely that the winding collapses. Since the winding diameter of the wire changes suddenly, the winding speed changes suddenly, making it impossible for the speed control dancer pulley to follow the speed control, and wire breakage often occurs. In addition, even if a gap is provided in one or several places of the intermediate collar to allow the optical fiber to pass through, it is only a matter of probability that the optical fiber will successfully pass through the gap. There is no sex. In addition, the rewinding method (■) requires extra man-hours and equipment, resulting in poor productivity. Furthermore, method (■) not only requires an expensive winding machine, but also requires the use of method (■) in order to ensure the bottom end and ensure a good 5 to 10 m length. Although it is a winder, it is functionally a single-head winder and is not practical.

SUMMARY OF THE INVENTION An object of the present invention is to provide an optical fiber winding device that eliminates the drawbacks of the prior art described above, allows smooth winding and transfer even during high-speed drawing, and is compact.

゛ [Means for solving the problem] The present invention provides a winding device for winding an optical fiber from a take-up machine, in which the starting end of the optical fiber is wound with approximately the same diameter as the diameter of the winding bobbin flange. This system is equipped with a winder having a winding drum and a tension device that variably controls the tension applied to the optical fiber being transferred from the waste winding drum to the bobbin body.

[Function] When winding from the waste winding drum to the body through the flange of the winding bobbin, the winding diameter changes suddenly and the winding speed suddenly decreases.

For this reason, adjusting the winding speed using a dancer pulley, etc. cannot cope with this problem, and there is a risk of the optical fiber coming off and breaking. This can be dealt with by increasing the amount.

Further, after being wound onto the body of the winding bobbin, the tension applied to the optical fiber is returned to a low tension and steady winding is performed. The empty or lower end of the starting end of the optical fiber is wound onto the waste winding drum.

[Example] Examples of the present invention will be described below.

Fig. 1 shows the entire optical fiber drawing device, in which a preform (optical fiber preform) 2 is sent downward by a preform feeding device 1, heated and melted in an electric furnace 3, and drawn. . The drawn optical fiber F passes through an outer diameter measuring device 4, is stripped of its primary coating by a pre-coating applicator eI5, is heated and cured by a pre-coating curing device 6, and is further passed through an outer diameter measuring device 7. and is taken over by the take-up machine 8. The optical fiber (optical fiber strand) F that has exited the take-up machine 8 is wound around a tension control device 11 .

The tension control device 9 includes an arm 9b swingably supported by a column 9a having a pulley at the top, a dancer pulley 9C rotatably provided at one end of the arm 9b, and applying tension to the optical fiber F. The arm 9b is mainly composed of an air cylinder 9e connected to the other end of the arm 9b via a spring 9d, and a swing portion 9f having an appropriate amount of play to allow the arm 9b to swing. The arm 9 on the air cylinder 9e side is controlled by the air cylinder 9e of the tension control device 9.
When the end of b is lifted, the dancer booley 9C is pushed down and the tension applied to the optical fiber F increases.

Also, conversely, the air cylinder 9e
When the end of the arm 9b on the e side is lowered, the tension applied to the optical fiber F by the Danner booley 9C is reduced.

The winding l110 is a winding bobbin 11, as shown in FIG.
and a winding machine main body 12 that rotationally drives the winding machine. Further, although not shown, the winding machine 10 is provided with a fiber traverse device, and this fiber traverse device can reversely traverse between 80 and 81 of the body 14 of the winding bobbin 11. A reverse traverse between AO and A1 is also possible. Waste winding drum 13
The diameter is "DO" on the 3% side and is gradually tapered toward the flange 15 of the winding bobbin 11 on the tip side.

Body portion 14 of the winding bobbin 11. The diameters of the collar portions 15 are d and D, respectively.

In the drawing operation of the optical fiber, the drawing speed is gradually raised to an upper limit while being pulled by the pulling machine 8, and the feeding speed of the preform feeder 1 is also increased, gradually approaching the actual working speed and becoming stable. However, 50-60m 1min
When the speed exceeds 11, the end of the optical fiber is
It is extremely difficult to make it stick. Therefore, the optical fiber end is fixed to the waste winding drum 13 while the speed is low, and A1 to A
The optical fiber F is wound up while reversing the traverse between the steps .

After the working conditions have stabilized (that is, the optical fiber properties are considered to have stabilized), the optical fiber is transferred from AO to BO. If we look at the winding movement in detail, we can see that the waste winding drum 1
The diameter DO of No. 3 is almost the same as the diameter of the flange 15 of the winding bobbin 11.
At the moment when the winding material is transferred, the diameter of the winding drum suddenly changes from DO+α (α is the thickness of the winding, not shown)→D−)d. At this time, the winding speed will also suddenly change (in this case, it will suddenly become slow), but if the dancer booley 9C does not respond to this change instantly, it will be impossible to control the winding speed. The optical fiber F comes off from the pulley 9C, resulting in breakage, etc. In order to avoid this, in this embodiment, the air cylinder 9e of the tension control device 9 is operated at the same time as the start of the winding to increase the downward load on the dancer booley 9C. Optical fiber winding position is from AO to B
After winding to position o, the downward load on the dancer booley 9C by the air cylinder 9e is released, and the state shifts to a steady winding state with low tension. In steady winding state, dancer booley 9
The vertical movement of C is absorbed within the play range of the swing portion 9f.

Using this device, the optical fiber tension during winding can be reduced to 0.5
With ~1.5 kg, the winding was 100% successful even at linear speeds of 150 to 250 m/min. Further, the winding tension in a steady state is 10 to 50 g, and if a tension higher than this is applied, an error will occur in measuring the transmission characteristics of the optical fiber after winding is completed. Therefore, tension adjustment by the tension control device 9 is essential.

In the above embodiments, the drawing apparatus for quartz-based optical fiber was mainly explained as an example, but the same structure can also be applied to a multi-component optical fiber manufacturing apparatus that spins from a melting crucible. Further, basic operation is possible even if the spring 9d is omitted in the tension control device 9, and other load devices such as a hydraulic cylinder or an electric motor equipped with a rotary encoder may be used in place of the air cylinder 9e. . Further, in the above embodiment, the waste winding drum 13 is attached to the winding machine 10, but a bobbin-like or cylindrical one that can perform waste winding may be used in a removable manner without being attached. A winding bobbin having a flange having a waste winding body may also be used.

[Effects of the Invention] In summary, according to the present invention, the following effects are achieved.

(1) Since the tension control rIJ device can increase the tension applied to the optical fiber during winding transfer from the waste winding drum to the winding bobbin body, smooth winding and winding can be achieved even during high-speed drawing. , wire breakage, etc. can be reliably prevented.

(I) The starting end of the optical fiber can be wound onto the waste winding drum as the lower opening part in a normal winding operation, and the lower opening part can be easily taken out.

(3) During steady winding of the winding bobbin body, the tension control device lowers the tension on the optical fiber, allowing winding with low tension.

Since the C4 winder is only provided with a waste winding drum, it can be made more compact.

(2) By providing a taper to the waste winding drum, it is possible to easily remove residual wire from the optical fiber in the waste winding drum after winding.

[Brief explanation of the drawing]

FIG. 1 is an overall view showing an optical fiber drawing device equipped with an optical fiber winding device according to the present invention, and FIG. 2 is a plan view showing the configuration of a winding machine in the drawing device. In the figure, 1 is a preform feeding device f1.2 is a preform (optical fiber base material), 3 is an electric furnace, 4 is an outer diameter measuring device, and 5
is a pre-coat applicator, 6 is a pre-coat cure device, and 7 is a pre-coat coating device.
is an outer diameter measuring device, 8 is a take-up unit, 9 is a tension control device, 9a is a column, 9b is an arm, 9C is a dancer booley, 9d is a spring, 9e is an air cylinder, 9f is a swing part, 10 is a winding machine , 11 is a winding bobbin, 12 is a winding machine main body, 13 is a waste winding drum, 14 is a body portion, and 15 is a collar portion.

Claims (2)

[Claims] (1) In a winding device that winds an optical fiber from a take-up machine, there is a winding machine having a waste winding drum that has approximately the same diameter as the diameter of the winding bobbin flange and in which the starting end of the optical fiber is reverberated, and a waste winding drum. An optical fiber winding device comprising: a tension control device that variably controls the tension applied to the optical fiber being transferred from the winding bobbin to the winding bobbin body. (2) The optical fiber winding device according to claim 1, wherein the diameter of the waste winding drum is gradually and gently reduced toward the winding bobbin flange.