JP3511614B2 - Optical fiber screening apparatus and optical fiber screening 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 screening apparatus and an optical fiber screening method for breaking a low strength portion of an optical fiber.

[0002]

2. Description of the Related Art In manufacturing an optical fiber, in order to guarantee the tensile strength of the manufactured optical fiber, a screening is carried out by applying a constant tension to the optical fiber to inspect it for breakage. A screening apparatus used for such screening is disclosed in, for example, Japanese Patent Laid-Open No. 5-31
It is disclosed in Japanese Patent No. 0439. In FIG.
3 shows an optical fiber screening device disclosed in JP-A-310439. In this device, the optical fiber 2 fed from the supply bobbin 1 is wound around a capstan wheel 3, a screening wheel 5, and a tension help wheel 6 and sequentially transferred, and wound by a winding bobbin of a winding machine 7. The capstan belt 4 supports the optical fiber 2 together with the capstan wheel 3. The pay-out dancer roll 8 and the take-up dancer roll 9 are arranged between the supply bobbin 1 and the capstan wheel 3 and between the tension help wheel 6 and the winder 7, respectively, and the linear velocity of the optical fiber to be transferred is set. And absorbs fluctuations in tension. Then, an optical fiber breakage detector 11 is provided between the capstan wheel 3 and the screening wheel 5, and when the breakage of the optical fiber is detected, the winder 7 is suddenly stopped. The winder 7 is suddenly stopped after the break is detected because the winder 7 is detected after the break of the optical fiber is detected.
When the broken end of the broken optical fiber is wound before stopping, the optical fiber already wound on the take-up bobbin is hit by this broken end and is damaged by trauma, resulting in low strength. This is to prevent it.

[0003]

In this type of screening apparatus, there is a demand for increasing the winding speed of the optical fiber in order to shorten the screening time.
However, the following problems occur when the winding speed increases.

First, as the winding speed increases, the distance over which the broken end of the optical fiber travels increases after the break of the optical fiber is detected until the brake is applied and the winder 7 is stopped. In the conventional screening apparatus, the path line length from the screening wheel 5 to the winder 7 was about 6 m. However, as the winding speed increases, the distance traveled by the broken end of the optical fiber after the break detector 11 detects the break until the winder 7 stops exceeds the pass line length. Therefore, it causes a line strike during the screening. Further, when the screening apparatus has a terminal gripping device for performing automatic terminal processing in front of the winder 7, it is not necessary to simply prevent the line from being hit, but before the broken end of the optical fiber passes through the terminal gripping device. It is necessary to stop the winder 7. Otherwise, the terminal is grasped and the automatic terminal treatment cannot be performed. Therefore, the pass line length that can be permitted before stopping is shortened by the distance between the terminal gripping device and the winder 7.

Next, when the optical fiber 2 is wound around the winder 7 and the winding amount increases, the optical fiber 2 and the winding bobbin are wound around the rotary shaft of the winder 7. Since the combined moment of inertia becomes large, the time until the winder 7 stops is generally long. Further, even if the winding speed is increased, the time until the winder 7 is stopped becomes long, and the length of the optical fiber running at the same stop time becomes long. Therefore, the braking force required to stop the winder 7 within a predetermined fiber length after the breakage detector 11 detects breakage of the optical fiber 2 increases as the winding amount of the optical fiber 2 increases. It needs to be increased as the winding speed increases. However, if the braking force is too strong, the optical fiber 2 wound around the winding bobbin may be broken due to the acceleration for sudden stop. Further, if an extremely strong braking force is applied, the take-up bobbin itself may be damaged by the braking torque. Therefore, the braking force for stopping the winder has an upper limit and cannot be increased indefinitely in order to prevent line hitting.

Therefore, in order to shorten the screening time, the object of the present invention is to wind the broken end of the optical fiber onto the winding bobbin even when the optical fiber is screened at a high winding speed. An object of the present invention is to provide an optical fiber screening apparatus and an optical fiber screening method that do not cause a wire strike.

[0007]

In order to achieve this object, the present invention has the following configuration.

The optical fiber screening apparatus according to the present invention comprises a capstan wheel for transporting the wound optical fiber to be inspected by rotation, and a winding operation for winding the optical fiber to be inspected fed from the capstan wheel. Between the machine and the capstan wheel and winder, the screening wheel that applies tension to the optical fiber to be inspected between the capstan wheel and the optical fiber while it is being transferred by rotation drive Breakage detection means for detecting breakage of the fiber and outputting a breakage detection signal, winder stop means for stopping the winder in response to the breakage detection signal output by the breakage detection means, screening wheel and winder a pass line extension means for extending the travel path of the optical fiber from the screening wheel to coiler located between, The inspection light Phi taken up by the winder
A winding amount detecting means for detecting the winding amount of the bar and outputting a winding amount signal , and the pass line extending means determines the length of the traveling path of the optical fiber from the screening wheel to the winder, The length of the optical fiber taken up by the winder is set to be longer than the length of the optical fiber wound after the optical fiber to be inspected is broken until the winder is stopped by the winder stopping means. Winder stop means
According to the winding amount signal output from the winding amount detecting means.
Braking adjustment means to adjust the braking force to stop the machine
Have

Since the path for extending the optical fiber from the screening wheel to the winding machine is lengthened by providing the path line extending means in this way, even if the winding speed is increased, the inside of the running path is broken when the optical fiber is broken. The breaking edge can be stopped with. Therefore, since the broken end of the optical fiber is not wound up by the winder, it is possible to prevent the wire striking. Also, install the pass line extension in this way.
In addition to extending the running path of the optical fiber, it also detects the winding amount.
If the means and the winder stop means are provided, the winding amount detection means
Adjust the braking force to stop the winder according to the winding amount signal of
Can be adjusted. Therefore, the braking force increases as the winding amount increases.
If you increase the
When breaking, stop the broken end of the optical fiber
You can In other words, even if the winding speed is increased, the winding amount
Regardless of, you can avoid hitting the line. Also,
Adjusting the rake force allows more braking force than necessary.
Stop the winder with the braking force according to the winding amount without adding
Since it can be stopped, it does not cause roll collapse etc.
Yes.

The optical fiber screening apparatus according to the present invention comprises a capstan wheel for transporting the wound optical fiber to be inspected by rotation, and a winding operation for winding the optical fiber to be inspected fed from the capstan wheel. Between the machine and the capstan wheel and winder, the screening wheel that applies tension to the optical fiber to be inspected between the capstan wheel and the optical fiber while it is being transferred by rotation drive Breakage detection means for detecting breakage of the fiber and outputting a breakage detection signal, winder stop means for stopping the winder in response to the breakage detection signal output by the breakage detection means, screening wheel and winder And a path line extending means for extending the traveling path of the optical fiber from the screening wheel to the winding machine, A terminal grip portion for gripping an object to be inspected optical fiber is between Surain extension means and winder, the winder
Detecting the winding amount of the inspected optical fiber wound on the
From the winding amount detecting means for outputting a signal, and this winding amount detecting means
Rotation speed of the capstan wheel according to the winding amount signal of
The path line extending means controls the length of the optical fiber running path from the screening wheel to the terminal gripping portion by the winder stopping means after the optical fiber to be inspected is broken. The length of the optical fiber taken up by the winder is made longer until the winder is stopped.

Since the path line extending means is provided to lengthen the traveling path of the optical fiber from the screening wheel to the terminal gripping portion, the terminal gripping portion can perform automatic terminal processing and increase the winding speed. However, when the optical fiber is broken, the broken end of the optical fiber can be stopped in this running path. Therefore, since the broken end of the optical fiber is not wound up by the winder,
You can avoid hitting the line. In addition, like this
Provide a spline extension means to extend the optical fiber running path.
In addition to this, a winding amount detection means and a speed control means are provided.
For example, as the winding speed increases at the beginning of winding and the winding amount increases.
Slows the winding speed of the winder based on the winding amount signal.
When the optical fiber breaks even if the winding speed is increased
In addition, the break end can be stopped in the traveling path. But
The broken end of the optical fiber on the take-up bobbin
I will not get caught because I will not get hit with a line
You can In other words, you can hit the line with almost constant braking force.
Screening fast while avoiding
be able to.

The optical fiber screening apparatus according to the present invention comprises a capstan wheel for transporting the wound optical fiber to be inspected by rotation, and a winding operation for winding the optical fiber to be inspected fed from the capstan wheel. Between the machine and the capstan wheel and winder, the screening wheel that applies tension to the optical fiber to be inspected between the capstan wheel and the optical fiber while it is being transferred by rotation drive Breakage detection means for detecting breakage of the fiber and outputting a breakage detection signal, winder stop means for stopping the winder in response to the breakage detection signal output by the breakage detection means, screening wheel and winder And a path line extending means for extending the traveling path of the optical fiber from the screening wheel to the winding machine, A terminal grip portion for gripping an object to be inspected optical fiber is between Surain extension means and winder, the winder
The winding amount is detected by detecting the winding amount of the optical fiber to be inspected.
And a winding amount detection means for outputting a signal, and the pass line extension means stops the winder after the optical fiber to be inspected breaks the length of the traveling path of the optical fiber from the screening wheel to the terminal gripping portion. The length of the optical fiber wound by the winder is made longer until the winder is stopped by the means. The winder stop means is the winding amount detection means.
The winder is stopped according to the winding amount signal output from
It has a braking adjustment means for adjusting the rake force.
It

Since the path line extending means is provided to lengthen the traveling path of the optical fiber from the screening wheel to the terminal gripping portion, the terminal gripping portion can perform automatic terminal processing and increase the winding speed. However, when the optical fiber is broken, the broken end of the optical fiber can be stopped in this running path. Therefore, since the broken end of the optical fiber is not wound up by the winder,
You can avoid hitting the line. In addition, like this
Extending the optical fiber path by providing a spline extension
In addition to the above, a winding amount detecting means and a winding machine stopping means are provided.
Stop the winder according to the winding amount signal from the winding amount detecting means.
You can adjust the braking force. Therefore, the winding amount increases
If you increase the braking force as you
Even if the optical fiber breaks, the optical fiber is
The breaking end of the bar can be stopped. That is, winding
Even if you increase the speed, you will not hit the line regardless of the winding amount
You can Also, by adjusting the braking force,
Depending on the winding amount, the brake may be applied without applying excessive braking force.
Since the winder can be stopped by the rake force,
It will not happen.

The optical fiber screening apparatus according to the present invention rotationally drives the wound optical fiber to be inspected.
Capstan wheel to be transferred by this caps
Wind the optical fiber to be inspected from the tongue wheel.
Between the take-up winder and the capstan wheel and winder
Yes Capstan wheel while transferring by rotary drive
To the optical fiber to be inspected to break the low strength part.
Screening wheel to be cut off and optical fiber to be inspected
Rupture detection means for detecting the rupture of the vehicle and outputting a rupture detection signal
In response to the fracture detection signal output by this fracture detection means,
Winding machine stopping means for stopping the winding machine, and screening
Located between the wheel and the winder Screening wheel
A pathr that extends the path of the optical fiber from the winder to the winder.
In-extension means, winding amount detection means for detecting the winding amount of the optical fiber to be inspected wound by the winder and outputting a winding amount signal, and the capstan wheel of the capstan wheel according to the winding amount signal from the winding amount detection means. Bei and speed control means for controlling the rotational speed
Well, is the pass line extension means a screening wheel?
The length of the optical fiber running path from the
After the fiber breaks, the winder is stopped by the winder stop means.
Optical fiber that is taken up by the winder until it is stopped
I made it longer than Ba.

In this way, the pass line extension means is provided and the pass line is extended.
Run the optical fiber from the cleaning wheel to the winder
Since the path is longer, the optical fiber can be used even if the winding speed is increased.
When the bar breaks, stop the break end in this runway
be able to. Therefore, the broken end of the optical fiber
Since it is not taken up by the machine, it does not hit the line
You can Further, if the winding amount detection means and the speed control means are provided in addition to the path line extending means thus extending the traveling path of the optical fiber, the winding speed at the beginning of winding can be made high. If the winding speed of the winder is slowed based on the winding amount signal with increasing, the breaking end can be stopped in the running path when the optical fiber breaks even if the winding speed is increased. Therefore, since the broken end of the optical fiber is not wound into the winding bobbin regardless of the winding amount, it is possible to prevent the wire striking. That is,
Screening can be performed at high speed while preventing line hitting even with a substantially constant braking force.

The optical fiber screening apparatus according to the present invention comprises a capstan wheel for transporting the wound optical fiber to be inspected by rotation, and a winding operation for winding the optical fiber to be inspected fed from the capstan wheel. Between the machine and the capstan wheel and winder, the screening wheel that applies tension to the optical fiber to be inspected between the capstan wheel and the optical fiber while it is being transferred by rotation drive Breakage detection means for detecting breakage of the fiber and outputting a breakage detection signal, winder stop means for stopping the winder in response to the breakage detection signal output by the breakage detection means, screening wheel and winder And a path line extending means for extending the traveling path of the optical fiber from the screening wheel to the winding machine, Provided, the pass line extending means, having one or more guide wheels, wound around the object to be inspected optical fiber fed out from the screening wheel guide wheels, and to pay out the winder.

The path line is extended by providing one or more guide wheels wound with the optical fiber in this way, and the length of the optical fiber running path from the screening wheel to the winder is inspected. The length of the optical fiber is set to be longer than the length of the optical fiber wound after the optical fiber is broken and before the winder is stopped. Therefore, even if the winding speed is increased, when the optical fiber breaks, the breaking end can be stopped in this running path. Therefore, since the broken end of the optical fiber is not wound up by the winder, it is possible to prevent the wire striking.

In the optical fiber screening method according to the present invention, a capstan wheel and an optical fiber to be inspected, which are sequentially wound around the screening wheel, are transferred by rotating these, and then are fed out from the screening wheel and further pass line extending means. When the film is wound on the winder via the, the low-strength part is broken by applying tension to the optical fiber to be inspected by rotating the screening wheel between the screening wheel and the capstan wheel, and breaking the optical fiber to be inspected. Is a screening method of an optical fiber that stops the winder by detecting the, the path line extension means, the length of the optical fiber running path from the screening wheel to the winder, the optical fiber to be inspected is broken. Light that is taken up by the winder from the beginning until the winder stops Aiba was to be longer than the length.

Since the optical fiber is wound through the pass line extending means in this way, the traveling path of the optical fiber from the screening wheel to the winding machine can be lengthened. Therefore, even if the winding speed is increased, the breaking end can be stopped in the traveling path when the optical fiber is broken. Therefore, since the broken end of the optical fiber is not wound up by the winder, it is possible to prevent the wire striking.

In the optical fiber screening method according to the present invention, the capstan wheel and the optical fiber to be inspected, which are successively wound around the screening wheel, are transferred by the rotational driving of these, and then are fed out from the screening wheel and further pass line extending means. It is a method of screening an optical fiber in which the low-strength portion is broken by applying tension to the optical fiber to be inspected by rotating the screening wheel between the screening wheel and the capstan wheel when the film is wound onto the winder via the And a breakage detecting step of detecting breakage of the optical fiber to be inspected and outputting a breakage detection signal, a winding amount detecting step of detecting a winding amount of the optical fiber to be inspected wound by the winder, and this winding amount. The winder is stopped according to the winding amount of the optical fiber under test detected in the detection process. And a winder stop step of stopping the winder after receiving the breakage detection signal and receiving the breakage detection signal, and the pass line extension means is configured to wind from the screening wheel. The length of the traveling path of the optical fiber to the winding machine is set to be longer than the length of the optical fiber wound by the winding machine from the break of the optical fiber to be inspected until the winding machine stops.

Since the optical fiber is wound through the pass line extension in this way, the traveling path of the optical fiber from the screening wheel to the winder can be lengthened. Further, the braking force is adjusted in the winding machine stopping step in accordance with the winding amount of the optical fiber detected in the winding amount detecting step. Therefore, even if the winding speed is increased, if the braking force is increased according to the winding amount, the break end can be stopped in the traveling path when the optical fiber breaks. Also, by adjusting the braking force, it is possible to stop the broken end of the optical fiber in the running path with the braking force according to the winding amount without applying more braking force than necessary, so that winding collapse etc. also occur. There is no.

A method for screening an optical fiber according to the present invention includes a capstan wheel and a screening method.
This is the optical fiber to be inspected that is wound around the wheel in sequence.
After being transferred by rotating the
From the roll, and through the pass line extension means
When winding on the winder, the screening wheel and
Screening wheel turns to and from the Pustan wheel
Tension is applied to the optical fiber to be inspected by rolling drive to
And the breaker of the optical fiber to be inspected is detected
Optical fiber screening method to stop
A winding amount detecting step of detecting the winding amount of the optical fiber to be inspected wound by the winder and outputting a winding amount signal, and controlling the rotation speed of the capstan wheel according to the winding amount signal of the winding amount detecting step. A speed control step . Pass line extension hand
The steps are optical fibers from the screening wheel to the winder.
If the optical fiber under test is broken,
The optical fiber wound by the winder until the winder stops.
I tried to make it longer than the length of the fiber.

In this way, the light is transmitted through the pass line extension means.
Since the fiber was taken up, the screening ho
A longer optical fiber path from the reel to the winder
It As a result, the optical fiber breaks even if the winding speed is increased.
You can stop the break end in the road when
It Therefore, the broken end of the optical fiber should be taken up by the winder.
Since it will not be hit, you can avoid hitting the line
It Further, by winding the optical fiber through the pass line extension in this manner, the traveling path of the optical fiber from the screening wheel to the winding machine can be lengthened. Further, the winding amount of the optical fiber can be detected in the winding amount detecting step, and the winding speed can be controlled based on the winding amount in the speed control step. Therefore, if the winding speed is slowed as the winding amount increases, the breaking end can be stopped in the traveling path when the optical fiber is broken.

[0024]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of an optical fiber screening apparatus and a screening method according to the present invention will be described below with reference to the accompanying drawings. In each drawing, the same elements are designated by the same reference numerals and the description thereof is omitted.

(First Embodiment) An embodiment of the present invention will be described with reference to FIGS. 1, 2 and 3.

FIG. 1 is a block diagram of the screening apparatus of the present invention. The optical fiber 2 delivered from the supply bobbin 1 is wound around a capstan wheel 3, a screening wheel 5, and a tension help wheel 6 and sequentially transferred, and wound by a winding bobbin of a winding machine 7. Further, between the capstan wheel 3 and the screening wheel 5 and between the screening wheel 5 and the tension help wheel 6, guide wheels 10 around which optical fibers are wound are arranged.
The capstan belt 4 holds the optical fiber 2 together with the capstan wheel 3. The screening tension is applied to the optical fiber transported between the capstan wheel 3 and the screening wheel 5 by adjusting the axial torque of the screening wheel 5. An intermediate tension that is higher than the winding tension and lower than the screening tension is set in the optical fiber that is transported between the screening wheel 5 and the tension help wheel 6 to prevent the screening wheel 5 from slipping. The pay-out dancer roll 8 and the take-up dancer roll 9 prevent fluctuations in the linear velocity and tension of the optical fiber transferred between the supply bobbin 1 and the capstan wheel 3 and between the tension help wheel 6 and the winder 7. Each is absorbing. Then, a breakage detector 11 is provided between the capstan wheel 3 and the screening wheel 5 as a breakage detecting means for the optical fiber so that the breakage of the optical fiber is detected and the winder 7 is braked and stopped. There is. Further, the screening apparatus of the present invention newly has a pass line extension portion 30 as a pass line extension means between the tension help wheel 6 and the take-up dancer roll 9.

The path line extension 30 comprises four guide wheels 31 arranged so that the traveling directions of the optical fibers alternate, and the optical fibers fed from the tension help wheel 6 are sequentially wound around the guide wheel 31. It is configured to be hung and sent out to the take-up dancer roll 9. By providing such a pass line extension 30, in this embodiment, in addition to the conventional pass line length of about 6 m, a pass line extension 30 of about 5 m can be provided. This makes it easy to extend the pass line. In addition, the guide wheel 31 should just be at least one piece.

Although the optical fiber 2 is supplied from the supply bobbin 1 to the capstan wheel 3 in FIG. 1, the present invention is not limited to such an optical fiber, and other optical fibers may be used. For example, the drawing furnace may be used as the supply means for the optical fiber 2, and the optical fiber 2 obtained by drawing in the drawing furnace may be supplied to the capstan wheel 3 as it is.

FIG. 2 is a side view showing the structure of the winder 7. The winding bobbin 70 attached to the winding machine 7 is rotationally driven by a servo motor 72, and when breakage of the optical fiber 2 is detected, it is suddenly stopped by a brake 71.

FIG. 3 is a block diagram showing the structure of the winder stopping means. As the winder stopping means, the brake device having the configuration shown in FIG. 3 is preferable. In this braking device, the air pressure of the air source 51 is transmitted to the brake 71 through the pressure reducing valve 52, the electromagnetic valve 55, and the pressure increasing device 54 to generate a braking force. The electromagnetic valve 55 opens the valve and sends air pressure to the pressure booster 54 in response to a signal from the breakage detector 11. The pressure booster 54 converts this air pressure into hydraulic pressure to increase the pressure. When air pressure is used in this way, pressure transmission is easy. The brake device is not limited to the configuration shown in FIG.

FIG. 4 shows a perspective view of the breakage detecting means. As the breakage detecting means, the breakage detector 11 having the configuration shown in FIG.
Is preferred. The breakage detector 11 detects the tension of the optical fiber 2 by detecting the bending force applied to the rotation shaft of the detection roller 11a by the detection roller 11a around which the optical fiber is wound and the tension of the optical fiber. And a detector 11b for detecting breakage. Breakage detector 11
Outputs a detection signal when detecting breakage of the optical fiber 2. The breakage detector 11 is not limited to the configuration shown in FIG.
For example, an optical breakage detector may be used. The configuration of the optical breakage detector includes a light source and a light receiver, and detects the presence or absence of an optical fiber between the light source and the light receiver. The optical breakage detector can detect the breakage of the optical fiber in a non-contact manner.

In such a screening device,
FIG. 5 is a graph showing the relationship between the winding speed and the time from the break of the optical fiber to the stop of the winder 7. According to FIG. 5, the time from the break of the optical fiber to the stop of the winder 7 is the time t ₁ from the detection of the break of the optical fiber to the start of the operation of the brake and the operation of the brake. It is divided into the time t ₂ from the start to the stop of the winder.

Time t ₁ until the brake starts to operate
Is the time until the breakage detector 11 detects the breakage of the optical fiber, the time until the breakage detector 11 issues a brake operation command, the time until the solenoid valve for brake operation opens and the actual braking starts. It is the total of time. The time t ₁ from when the break of the optical fiber is detected to when the brake is activated does not change depending on the winding speed v of the optical fiber. The distance traveled by the broken end of the optical fiber at this time is proportional to the winding linear velocity v. In the screening apparatus shown in FIG. 1, this time t ₁ is 0.3 due to experiments.
It turned out to be sec.

The time t ₂ from the start of braking to the stop of the winder 7 is inversely proportional to the strength of the braking force and proportional to the winding speed v of the optical fiber. Further, the distance traveled by the broken end of the optical fiber from the start of braking to the stop of the winder 7 is proportional to the square of the winding linear velocity v.

Therefore, the distance L that the broken optical fiber runs in the time from the break of the optical fiber to the stop of the winder 7 is expressed by L = v × t ₁ + v × v ÷ a ÷ 2. It In addition, a is a braking acceleration corresponding to the braking force. For this braking acceleration, F is the braking force, I is the combined moment of inertia of the winding bobbin and the winding optical fiber, l is the distance from the center of the winding bobbin to the position where the braking force is applied, and dω / dt is Letting angular acceleration about the axis of the take-up bobbin and r be the winding radius of the optical fiber when the optical fiber is broken, I × dω / dt = F × l and a = r × dω
Since there is a relationship of / dt, a = r × F × l ÷ I. It should be noted that this relational expression is theoretically derived and is useful for understanding the present invention, but it does not necessarily mean that such a simple functional relation.

Next, the braking force for stopping the winder will be described. As the optical fiber is wound around the winding bobbin 70, the combined moment of inertia becomes large. Therefore, as shown by the alternate long and short dash line in FIG. 5, the time t ₂ until the winding machine stops even at the same winding speed is long. Become. Also in this case, the braking force needs to be set to a preferable value so as not to hit the line. On the other hand, there is an upper limit to the magnitude of the braking acceleration because of the condition that the winding does not collapse even when the brake is applied. When the braking acceleration is the same, the braking angular acceleration of the winding bobbin increases as the winding radius decreases. However, the condition in which the roll collapse occurs is not simply determined by the braking angular acceleration, but the roll amount becomes larger and the roll collapse easily occurs at the lower braking angular acceleration. From the experience, we obtained the result that the winding collapse occurs with almost the same braking acceleration from the beginning of winding to full winding. Therefore, it is appropriate to consider the upper limit of the braking acceleration as the condition that the winding does not collapse. Except in special cases, the winding machine 7 having the winding bobbin that is hardly wound stops the earliest, so the braking force must be set to a value that does not cause collapse even in this winding state. With the screening device shown in FIG. 1, it was found from an experiment that the maximum braking acceleration that does not collapse the roll is -50 m / sec ² . Therefore,
The braking force was adjusted so that the braking acceleration was −50 m / sec ² with a winding bobbin with almost no optical fiber wound. With this braking force, the braking acceleration of the fully wound winding bobbin becomes -22 m / sec ² .

Screening was carried out by changing the winding speed using this screening apparatus. In the conventional screening device, when screening is performed at a winding speed of 600 m / min, t ₁ = 0.3 sec and a = −2
Since the distance L is 5.27 m under the condition of ² m / sec ² , line striking does not occur even if there is no pass line extension. When the screening apparatus of the present embodiment is used and t ₁ and a are set to the same condition and the screening is performed at a winding speed of 700 m / min, the distance L becomes 6.59 m. Furthermore, when screening is performed at a winding speed of 900 m / min under this condition, the distance L is 9.67 m. In both cases, the optical fiber from the screening wheel to the winder is longer than the length of the optical fiber wound by the winder until the winder is stopped by the brake after the optical fiber is broken by providing the pass line extension. Since the running path of is long, it does not hit the line.

If the screening apparatus has an automatic terminal processing mechanism, it is necessary to hold the terminal, so that the terminal holding apparatus is required. As a screening device having such a terminal gripping device, the configuration shown in FIG. 6 is preferable. According to FIG. 6, in addition to the screening device shown in FIG. 1, a terminal holding device 32 is provided in front of the winder 7.
Is provided. The terminal grasping device 32 arranges the optical fiber 2 at the tip of the nozzle and grasps the optical fiber 2 by sucking air. By this device 32, the upper end terminal processing of the winding bobbin is automatically performed.

In the present embodiment, such a terminal holding device 32 is provided about 0.8 m before the winder 7. In this case, the traveling path length of the optical fiber from the screening wheel to the terminal grip portion is 10.2 m. The pass line extension portion 30 runs the optical fiber from the screening wheel to the terminal grip portion more than the length of the optical fiber wound by the winder until the winder is stopped by the brake after the optical fiber is broken. The road length L must be long. Previous winding speed 900
When screening was performed at m / min, the distance L was 9.
Since the length is 67 m, even if the terminal gripping device is provided, line striking does not occur.

Here, the upper-end terminal treatment is a treatment in which the end of the optical fiber wound on the bobbin is pasted with a tape on the collar of the bobbin, and the fiber between the terminal holding devices is cut from the pasted portion. Further, the automatic terminal processing mechanism is a general term for a mechanism for performing a series of operations for upper mouth terminal processing and an automatic line hanging mechanism at the beginning of winding.

Since the path line extending portion is provided in this way to extend the running path along which the broken end of the optical fiber runs after the optical fiber is broken until the winder stops, even if the winding speed is increased. You can avoid hitting the line.

In the pass line extension portion 30, each guide wheel 31 has a function of changing the traveling direction of the optical fiber. Therefore, it is preferable to provide a plurality of guide wheels 31 and arrange each guide wheel such that the traveling direction of the optical fiber is reversed every time the optical fiber is wound around the guide wheel. In this way, the pass line extension can be made long with a small area. In addition, a plurality of wheels may be superposed on the same or part of the guide wheel 31 so that the optical fiber can be wound multiple times. In this way, the pass line extension 30 can be made longer with the same area.

Another example of the pass line extension means will be described below.

FIG. 7 is a perspective view of the take-up dancer roll. According to FIG. 7, the take-up dancer roll includes a plurality of fixed rollers 91 on the same rotating shaft and a plurality of swing rollers 94 on the same rotating shaft mounted on a swing arm 93 that rotates around a fulcrum 92. In FIG. 7, the fixed roller 91 is one more than the swing roller 94, and the optical fibers are wound by the number of the swing rollers. The diameter of the fixed roller 91 and the swing roller 94 is A =
It is preferably about 80 mm. The optical fiber 2 is wound from one end of the fixed roller 91 group and alternately wound between the swing roller 94 and the fixed roller 91 to be fixed roller 91.
It is paid out from the other end of the group. Also, the swing arm 93
Is configured to rotate in a circular arc at a predetermined angle with one point on the swing arm 93 as a fulcrum 92. This makes it possible to absorb the difference in winding linear velocity and the difference in tension. The rotation angle is preferably about B = ± 15 °, and the radius of the circular arc is preferably about C = 400 mm. Figure 7
In this example, the optical fiber is wound 3 turns, so 400
Since xsin (15 °) × 3 × 2 = 620 mm,
The take-up dancer roll 9 can absorb the excess or deficiency of the pass line caused by the take-up line speed difference and the tension difference within a range of ± 620 mm.

In order to extend the pass line in such a take-up dancer roll as compared with the conventional one, the number of fixed rollers 91 and swing rollers 94 of the take-up dancer roll 9 may be increased. In the conventional take-up dancer roll, the number of swing rollers 94 was three.

Further, the distance D between the fixed roller 91 and the swing roller 94 may be increased in order to extend the pass line as compared with the conventional case. In the conventional winding dancer roll, D = 350 mm. On the other hand, if D = 1 m, then (1−0.35) × 3 × 2 = 3.9 m,
The pass line length can be extended by 3.9 m. Furthermore, D = 1.
If it is 2 m, (1.2-0.35) × 3 × 2 = 5.1
The length of the pass line can be extended by 5.1 m.

The original function of the take-up dancer roll 9 is to absorb the difference in the take-up linear velocity between the capstan wheel 4 and the take-up machine 7. Therefore, in the optical fiber screening apparatus, the take-up dancer roll 9 is configured in a range that absorbs this linear velocity difference. The length required to absorb this difference depends on the characteristics of the motor and the winding amount of the winding bobbin, but generally it is about ± 400 mm at a linear velocity of 600 m / min and ± 600 mm at 1000 m / min. Is enough. If the number of turns of the optical fiber is increased or the fixed roller is placed away from the movable part of the swing roller beyond such a value, the pass line is extended.

(Second Embodiment) In the present embodiment,
A screening device that uses the brake device shown in FIG. 8 instead of the brake device shown in FIG. 3 as a brake device that stops the winder 7 will be described with reference to FIGS. 1 and 8. At this time, since the brake device of the winder 7 is different from that of the first embodiment, the description of FIG. 1 is omitted.

FIG. 8 is a block diagram showing the structure of the winder stopping means. The braking device capable of changing the braking force according to the winding amount of the optical fiber around the winding bobbin preferably has the configuration shown in FIG. The brake device transmits the air pressure of the air source 51 to the brake 71 through the electric pressure control valve 56, the electromagnetic valve 55, and the pressure increasing device 54 to generate a braking force. The electric pressure control valve 56 is the valve control device 5
A brake adjusting device 58 is configured as a brake adjusting means together with 7. The electric pressure control valve 56 is the valve control device 5
According to the control of 7, the air pressure of the air source 51 is adjusted to change the braking force. Since the braking force is adjusted according to the winding amount of the winding bobbin, the valve control device 57 is controlled by the winding amount detecting device 41 which is a winding amount detecting means. In this way, the winding amount is detected by the winding amount detecting device 41, and the electric pressure control valve 56 is controlled based on this value. Therefore, the braking force can be changed according to the winding amount.

The winding amount of the optical fiber is preferably obtained from the rotation speed of the capstan wheel 3. Since the perimeter of the capstan wheel is constant regardless of the winding amount, the winding amount can be easily obtained from the rotation speed.

Next, the relationship between the winding amount and the braking force for stopping the winder in almost the same time regardless of the winding amount of the optical fiber will be described. The relationship between the winding amount and the braking force is not actually a simple functional relationship. In practice, start winding,
Measure the braking force that stops at almost the same time at full winding and at several winding amounts between these, and linearly interpolate the intermediate value based on these values to determine the winding amount. It was found that a relationship that can be fully utilized can be obtained even if the relationship of the braking force is sought. FIG. 9 is a graph showing the relationship between the winding amount and the braking force. In FIG. 9, the horizontal axis represents the winding amount, and the vertical axis represents the pressure increasing device 54 instead of the braking force.
It takes the air pressure applied to. The measured values of the braking force are shown by black circles, and the straight lines that interpolate between the measurement points are shown by broken lines. If the control device that changes the braking force according to the winding amount stores the relationship shown in FIG. 9 to control the braking force,
The time from the detection of the breakage of the optical fiber to the stop of the winder 7 can be made substantially constant. Since such a control device operates by receiving a signal from the winding amount detection device 41,
Valve controller 57 is preferred. Further, a new control device may be provided between the winding amount detection device 41 and the valve control device 57 for control.

Screening was carried out using such a screening device at a winding speed of 1100 m / min. At this time, the braking force was adjusted with each winding amount so that the time until stopping was about 0.42 sec. Winding speed 1
Experiments have shown that at 100 m / min, the difference between the linearly interpolated braking acceleration and the actual braking acceleration falls within a range of about ± 13%. Therefore, the braking acceleration in the middle is
When set to 44 m / sec ² , the maximum braking acceleration is -4
4m / sec ² × 1.13 = −49.7m / sec ² , which is an acceleration that does not cause winding collapse −50m /
It is less than sec ² . The minimum braking acceleration is -44m.
/ Sec ² × 0.87 = −38 m / sec ² .

At this time, the distance L over which the broken end of the optical fiber runs during the time from the break of the optical fiber to the stop of the winder 7 is L = 1100 × 0.3 ÷ 60 + 1100.
× 1100 ÷ 38 ÷ 2 ÷ 60 ÷ 60 = 9.92 m. Since the screening device of this embodiment has the pass line extension, the broken end of the optical fiber stops in the traveling path between the screening wheel and the winder.

By changing the braking force for stopping the winding machine in accordance with the winding amount in this way, the time until the winding machine stops can be made substantially constant regardless of the winding amount.
The broken end of the optical fiber can be stopped in the traveling path from the screening wheel 5 to the winder 7. Therefore, it is possible to prevent the line striking even if the winding speed is increased.

Looking at the operation of the above-described screening apparatus, after the optical fiber 2 wound around the capstan wheel 3 and the screening wheel 5 in sequence is transferred by its rotational drive, the screening wheel 5 is moved.
And the optical fiber 2 is wound up on the winder 7 and the optical fiber 2 is tensioned by rotating the screening wheel 5 between the screening wheel 5 and the capstan wheel 3 to break the low strength portion. In the method, in the breakage detecting step, breakage of the optical fiber 2 is detected by the breakage detector 11, a breakage detection signal is output, and the winding amount of the optical fiber wound around the winder 7 in the winding amount detecting step. Is detected by the winding amount detection device 41, and the braking force for stopping the winder 7 is adjusted by the braking adjustment device 58 in accordance with the winding amount of the optical fiber detected in the winding amount detection step in the braking adjustment step. In the winder stop step, the winder 7 is stopped by the brake 71 after receiving the breakage detection signal and after the braking adjustment step.

In this way, by detecting the winding amount of the optical fiber,
If the braking device is operated after changing the braking force that stops the winder according to the winding amount, the time until the winder stops can be made almost constant regardless of the winding amount. It is possible to stop the breaking end of the device in the traveling path from the screening wheel 5 to the winder 7. Therefore, it is possible to prevent the line striking even if the winding speed is increased.

(Third Embodiment) In the first and second embodiments, the winding speed is the same regardless of the winding amount of the optical fiber. In the present embodiment, a screening device capable of changing the winding speed according to the winding amount will be described with reference to FIGS. 1, 3 and 10. At this time, since the winding speed can be changed with respect to the first embodiment, the description of FIGS. 1 and 3 is the same as that of the first embodiment, and therefore the description is omitted.

In order to change the winding speed according to the winding amount, the structure shown in FIG. 10 is preferable. FIG. 10 is a block diagram showing the relationship between the supply bobbin 1, the capstan wheel 3, the winder 7, and the speed changing device group 43 which is a speed changing means. A speed changing device 43a, a speed changing device 43b, a speed changing device 43c, and a winding amount detecting device 41 are provided corresponding to each of the supply bobbin 1, the capstan wheel 3, and the winder 7. The winding amount signal sent from the winding amount detecting device 41 is input to the speed control device 43b corresponding to the capstan wheel, and the signal from the speed changing device 43b controls the speed changing device 43a and the speed changing device 43c, respectively. There is. The rotation speeds of the supply bobbin 1, the capstan wheel 3, and the winder 7 are controlled by the corresponding speed changing devices 43a to 43c.
The speed changing device 43a of the supply bobbin 1 receives the position signal from the unwinding dancer roll position detecting device 44a, and the speed changing device 43c of the winder 7 receives the position signal from the winding dancer roll position detecting device 44c. It is adjusted so that there is no speed difference with the wheel 3. At this time, the winding speed is preferably slowed as the winding amount increases. This is because when the winding amount increases, the combined moment of inertia of the winding bobbin and the wound optical fiber increases, so that the winding bobbin is hard to stop.

When changing the winding speed, when the drawing furnace is used as the supply means for the optical fiber 2, the control of the supply bobbin 1 is not necessary.

The structure shown in FIG. 10 is preferable for changing the winding speed according to the winding amount of the optical fiber for the following reason. In the screening apparatus shown in FIG. 1, since the supply bobbin 1, the capstan wheel 3, the screening wheel 5, the tension help wheel 6 and the winder 7 are all interlocked, all of the wheels, etc. rotate when the winding speed changes. The speed changes. In an actual screening device, it is the capstan wheel 3 that determines the winding speed. The screening wheel 5 and the tension help wheel 6 have a constant torque mechanism, and the rotation speed is controlled so as to follow the capstan wheel 3. The rotation speed of the supply bobbin 1 is controlled so that the feeding dancer roll 8 keeps around the midpoint. Therefore, the rotation speed of the supply bobbin 1 is preferably controlled by the feedback signal from the feeding dancer roll 8 and the control signal of the rotation speed of the capstan wheel 3. The rotation speed of the winding machine 7 is controlled so that the winding Dasan roll 9 keeps around the midpoint. Therefore, the rotation speed of the winder 7 is equal to that of the winder dancer roll 9
Is preferably controlled by a feedback signal from the control unit and a control signal of the rotation speed of the capstan wheel 3. That is, it is preferable to control the capstan wheel 3 in order to control the winding speed. This is because the capstan wheel 3 determines the winding speed.

As described above, as the combined moment of inertia of the winding bobbin and the wound optical fiber increases and it becomes difficult to stop the winding machine, the winding speed is reduced to suppress the braking acceleration. Even if the winding speed is increased, the broken end of the optical fiber can be stopped in the traveling path of the optical fiber from the screening wheel to the winder.
That is, if the winding speed is increased at the initial stage of winding and the winding speed is reduced as the winding amount increases, the winding machine can be stopped before the broken end of the optical fiber is wound by the winding machine. Therefore, regardless of the winding amount, it is possible to perform high-speed screening while preventing line hitting.

In the screening apparatus according to this embodiment, the winding speed may be controlled continuously with respect to time. In this way, the winding speed can continuously follow the winding amount. Further, the control of the winding speed may be performed discretely with respect to time. In this way, the winding speed discretely follows the winding amount. In this case, the winding speed should be changed gradually within the range that does not cause significant linear velocity difference and tension difference in the optical fiber and within the range of linear velocity difference and tension difference that can be absorbed by the feeding dancer roll and the take-up dancer roll. Is preferred.

In the screening apparatus of this embodiment, the braking apparatus may be the apparatus shown in FIG. In this way, as the combined moment of inertia increases and it becomes more difficult for the winder to stop, the winding speed can be reduced to reduce the braking acceleration, and the braking force can be increased. You can avoid hitting the line.

Looking at the operation of the screening apparatus described above, after the optical fiber 2 wound around the capstan wheel 3 and the screening wheel 5 in sequence is transferred by its rotational drive, the screening wheel 5 is moved.
When the optical fiber 2 is unwound from the winder 7 and wound around the winder 7, tension is applied between the screening wheel 5 and the capstan wheel 4 by rotating the screening wheel 5 to break the low-strength portion of the optical fiber 2. A screening method for detecting breakage of the optical fiber 2 and stopping the winding machine 7, wherein the winding amount of the optical fiber 2 wound on the winding machine 7 by the winding amount detecting device 41 is detected in the winding amount detecting step. By detecting and outputting a winding amount signal, the speed changing device group 43 controls the rotation speed of the capstan wheel 4 in accordance with the winding amount signal of this winding amount detecting step in the speed control step. In the speed control step, the length of the optical fiber wound after the optical fiber 2 is broken until the winder 7 is stopped is shorter than the traveling path of the optical fiber from the screening wheel 5 to the winder 7. It is preferable to control the winding speed in the following speed range. This speed range can be experimentally determined by variously changing the winding amount of the optical fiber wound on the winding bobbin to obtain the speed at which line striking does not occur.

[0065]

As described in detail above, according to the present invention, a path line extending means is provided to intentionally lengthen the length of the traveling path from the screening wheel to the winder so that the breaking end is stopped in the traveling path. Therefore, even if the winding speed of the optical fiber is higher than that of the conventional one, the line striking does not occur. Therefore, the low-strength portion is not newly created by the wire striking in the optical fiber after screening.

Further, a pass line extension means is provided to intentionally lengthen the length of the traveling path from the screening wheel to the winder, and the braking force for stopping the winder when the optical fiber is broken depends on the winding amount. To change it,
Since the breaking end is stopped in the running path, line hitting does not occur even if the winding speed is increased, and winding collapse does not occur regardless of the winding amount.

Further, a pass line extension means is provided to intentionally lengthen the traveling path length from the screening wheel to the winding machine, and the winding speed is reduced in accordance with the winding amount of the winding bobbin at the time of screening. In this way, the breaking end is stopped in the running path, so that line hitting does not occur even when high-speed screening is performed.

[Brief description of drawings]

FIG. 1 is a configuration diagram of an optical fiber screening apparatus of the present invention.

FIG. 2 is a side view of a winder used in the optical fiber screening apparatus according to the first embodiment.

FIG. 3 is a configuration diagram of a brake device used in the optical fiber screening device according to the first embodiment.

FIG. 4 is a perspective view of a breakage detector used in the optical fiber screening apparatus according to the first embodiment.

FIG. 5 is a graph showing the relationship between the winding speed and the time from the break of the optical fiber to the stop of the winder 7.

FIG. 6 is a configuration diagram of an optical fiber screening device having the terminal holding device according to the first embodiment.

FIG. 7 is a perspective view of a take-up dancer roll.

FIG. 8 is a configuration diagram of a brake device used in the optical fiber screening device according to the second embodiment.

FIG. 9 is a graph showing the relationship between the winding amount and the air pressure when changing the braking force.

FIG. 10: Supply bobbin 1, capstan wheel 3
It is a block diagram showing the relationship between the winder 7 and the speed changing device 43.

FIG. 11 is a configuration diagram of an optical fiber screening apparatus in the prior art.

[Explanation of symbols]

1 ... Supply bobbin, 2 ... Inspected optical fiber, 3 ... Capstan wheel, 4 ... Capstan belt, 5 ... Screening wheel, 6 ... Tension help wheel,
7 ... Winding machine, 8 ... Feeding dancer roll, 9 ... Winding dancer roll, 10 ... Guide wheel, 11 ... Optical fiber breakage detector, 30 ... Pass line extension, 31 ... Guide wheel, 32 ... Terminal gripping device , 41 ... Winding amount detection device, 4
3 ... Speed change device group, 43a, 43b, 43c ... Speed change device, 51 ... Air source, 52 ... Pressure reducing valve, 53 ... Electromagnetic valve, 54 ... Pressure increasing device, 56 ... Electric pressure control valve, 58 ...
Braking adjustment device, 70 ... Winding bobbin, 72 ... Servo motor, 71 ... Brake, 91 ... Fixed roller, 92 ... Support point,
93 ... Swing arm, 94 ... Swing roller

Continuation of front page (56) Reference JP-A-5-310439 (JP, A) JP-A-8-12188 (JP, A) JP-A-7-277599 (JP, A) JP-A-5-193976 (JP , A) (58) Fields investigated (Int.Cl. ⁷ , DB name) C03B 37/00-37/16

Claims (6)

(57) [Claims] 1. A capstan wheel for transporting the wound optical fiber to be inspected by rotation, a winder for winding the optical fiber to be inspected fed from the capstan wheel, and the capstan wheel. A screening wheel that is present between the winder and the capstan wheel while being driven by rotation to apply a tension to the optical fiber to be inspected to break the low-strength portion, and a breaking of the optical fiber to be inspected Detecting means for outputting a breakage detection signal, a winder stopping means for stopping the winder by receiving a breakage detection signal output by the breakage detecting means, the screening wheel and the winder. A path line extending means for extending a traveling path of the optical fiber between the screening wheel and the winder, and the winder. Winding amount of the optical fiber to be inspected
And a winding amount detecting means for detecting a winding amount signal, and the winding machine stopping means outputs the winding amount signal.
Brake for stopping the winder according to the winding amount signal
It has a braking adjustment means for adjusting the force, the pass line extension means, the length of the traveling path of the optical fiber from the screening wheel to the winder,
Screening of an optical fiber, which is made longer than the length of the optical fiber wound by the winder until the winder is stopped by the winder stopping means after the optical fiber to be inspected is broken. apparatus. 2. A capstan wheel for transporting the wound optical fiber to be inspected by rotational driving, a winder for winding the optical fiber to be inspected fed from the capstan wheel, and the capstan wheel. A screening wheel that is present between the winder and the capstan wheel while being driven by rotation to apply a tension to the optical fiber to be inspected to break the low-strength portion, and a breaking of the optical fiber to be inspected Detecting means for outputting a breakage detection signal, a winder stopping means for stopping the winder by receiving a breakage detection signal output by the breakage detecting means, the screening wheel and the winder. Path line extending means for extending a traveling path of the optical fiber between the screening wheel and the winder, and the path. A terminal gripping portion between the line extension means and the winder for holding the optical fiber to be inspected, and a winding amount of the optical fiber to be inspected to be wound up by the winder.
Winding amount detecting means for detecting the winding amount signal and outputting the winding amount signal, and the caps according to the winding amount signal from the winding amount detecting means.
The speed control means for controlling the rotation speed of the tongue wheel and the pass line extension means, the length of the traveling path of the optical fiber from the screening wheel to the terminal gripping portion, after the optical fiber to be inspected is broken. An optical fiber screening device characterized in that the length of the optical fiber is longer than the length of the optical fiber wound by the winder until the winder is stopped by the winder stopping means. 3. Rotating a wound optical fiber to be inspected
The capstan wheel that is transferred by drive and this capstan wheel
The optical fiber to be inspected fed from the push-wheel.
The winder for winding the bar, the capstan wheel and the front
It is located between the winding machine and
The optical fiber to be inspected between the capstan wheel and
Screening hoes that apply tension to break low strength parts
And the breakage of the optical fiber to be inspected
The breakage detection means that outputs an output signal and the breakage detection means
Winding to stop the winder in response to the output break detection signal
Machine stopping means, the screening wheel and the winding
Between the machine and the screening wheel
Path line extension that extends the optical fiber running path to the machine
Between the length means, the pass line extension means and the winder
And a terminal gripping portion for gripping the optical fiber to be inspected, and a winding amount detecting means for detecting a winding amount of the optical fiber to be inspected wound on the winder and outputting a winding amount signal , The winding machine stopping means has a braking adjusting means for adjusting a braking force for stopping the winding machine according to a winding amount signal output from the winding amount detecting means, and the pass line extending means is , The screening wheel
Of the traveling path of the optical fiber from the
The length is measured after the optical fiber to be inspected is broken
Until the winder is stopped by the machine stopping means,
Make it longer than the length of the optical fiber wound by the winder
An optical fiber screening device characterized in that 4. Rotating a wound optical fiber to be inspected
The capstan wheel that is transferred by drive and this capstan wheel
The optical fiber to be inspected fed from the push-wheel.
The winder for winding the bar, the capstan wheel and the front
It is located between the winding machine and
The optical fiber to be inspected between the capstan wheel and
Screening hoes that apply tension to break low strength parts
And the breakage of the optical fiber to be inspected
The breakage detection means that outputs an output signal and the breakage detection means
Winding to stop the winder in response to the output break detection signal
Machine stopping means, the screening wheel and the winding
Between the machine and the screening wheel
Path line extension that extends the optical fiber running path to the machine
A lengthening means, a winding amount detecting means for detecting a winding amount of the optical fiber to be inspected wound up by the winding machine and outputting a winding amount signal, and the capstan according to the winding amount signal from the winding amount detecting means. Bei and speed control means for controlling the rotational speed of the wheel
The pass line extension means is the screening wheel.
The length of the optical fiber running path from the reel to the winder,
Stopping the winder after the optical fiber to be inspected is broken
Until the winder is stopped by a step
Specially, it should be longer than the length of the wound optical fiber.
Screening device for an optical fiber according to symptoms. 5. An optical fiber to be inspected, which is wound around a capstan wheel and a screening wheel in sequence, is transferred by rotational driving thereof, is then fed out from the screening wheel, and is further wound around a winder through a pass line extension means. A method for screening an optical fiber, in which a low-strength portion is broken by applying tension to the optical fiber to be inspected by rotationally driving the screening wheel between the screening wheel and the capstan wheel, A fracture detection step of detecting a fracture of the inspection optical fiber and outputting a fracture detection signal,
A winding amount detecting step of detecting the winding amount of the inspected optical fiber wound on the winding machine, and the winding machine according to the winding amount of the inspecting optical fiber detected by the winding amount detecting step. A braking adjustment process for adjusting the braking force to stop the
A winder stop step of stopping the winder after the braking adjustment step in response to the breakage detection signal, and the pass line extension means is a light from the screening wheel to the winder. The length of the fiber path,
A method of screening an optical fiber, wherein the length of the optical fiber is longer than the length of the optical fiber wound by the winder after the optical fiber to be inspected is broken and before the winder is stopped. 6. Capstan wheel and screen
The optical fibers to be inspected that are wound around the
After transferring by these rotary drives, the screen
Extending from the ring wheel, pass line extension means
When winding on the winder via the
The screen between the ears and the capstan wheel.
The inspected optical fiber is driven by rotating the turning wheel.
The tensile strength is applied to the bar to break the low-strength part,
An optical fiber that stops the winder by detecting the breakage of the fiber.
A method of screening an Iba, wherein the optical fiber screening method includes a winding amount detecting step of detecting a winding amount of the optical fiber to be inspected wound by the winder and outputting a winding amount signal, and the winding amount. a speed control step of controlling the rotational speed of the capstan wheel in accordance with the winding quantity signal amount detection step, and have a, the pass line extending means, the screening wheel
The length of the optical fiber running path from the reel to the winder,
The winder stops after the optical fiber under test breaks
Until the length of the optical fiber wound by the winder
Fiber optic screens characterized by being made much longer
Method.