JP6349928B2 - Optical fiber resin supply device and optical fiber manufacturing method - Google Patents

Description

  The present invention relates to an optical fiber resin supply apparatus and an optical fiber manufacturing method.

  2. Description of the Related Art There is known a continuous resin supply device that continuously supplies resin without interrupting the supply of an optical fiber to a resin-coated die when manufacturing an optical fiber (see, for example, Patent Documents 1 and 2).

Japanese Utility Model Publication No. 61-86433 JP-A-6-227846

  In a resin supply device in the drawing process (for example, the resin supply devices in Patent Documents 1 and 2 above), a sub tank is connected to the main tank with a pipe for resin supply, and the resin is supplied from the sub tank so that the main tank does not become empty. ing. Then, by supplying the resin from the main tank through the resin supply pipe to the die, the resin is continuously supplied without interruption during a series of drawing.

However, when the production of the optical fiber is stopped for a predetermined period or longer (for example, when it is stopped for a long time due to continuous holidays, etc.), the resin supply is stopped (the resin stops flowing in the pipe). There is a risk of resin hardening in the sub tank. Even if it does not harden, the temperature of each place such as in each pipe or tank is different, so that the viscosity of the resin in each place is different. For this reason, when the production of the optical fiber is resumed as it is, it takes time to adjust the coating diameter of the optical fiber resin and the adjustment of the uneven thickness, and the waste waste increases and the yield is lowered.
In order to prevent this, generally, when the production of an optical fiber is stopped for a predetermined period or longer, resin removal and cleaning of pipes and tanks are performed. In that case, when manufacturing is resumed, operations such as preparation of a resin tank, introduction of resin into the tank, and overflow of the resin are required. Further, at this time, if the air bubbles in the pipe are not sufficiently removed, there is a risk that a quality defect due to air bubbles in the resin may occur.

  Accordingly, the object of the present invention is to generate quality defects due to bubbles in the resin during re-operation even when the operation of the optical fiber is stopped for a predetermined period or longer without performing operations such as resin removal and cleaning of the piping and tank. Another object of the present invention is to provide an optical fiber resin supply device and an optical fiber manufacturing method capable of suppressing an increase in resin disposal due to an overflow operation.

An optical fiber resin supply device of the present invention capable of solving the above-described problems includes a first tank for supplying resin to a resin-coated die for an optical fiber via a resin supply pipe, and a resin supply pipe to the first tank. A second tank for replenishing the resin, and a resin supply device for an optical fiber that supplies the resin to the resin-coated die,
A circulation resin pipe is provided for returning the resin to the second tank from the connection point to the resin-coated die in the resin supply pipe.

The optical fiber manufacturing method of the present invention is a method of coating an optical fiber resin supplied from an optical fiber resin supply device on a glass fiber, and curing the coated optical fiber resin to produce an optical fiber. A fiber manufacturing method comprising:
The optical fiber resin supply device is:
A first tank that supplies resin to a resin-coated die for optical fiber via a resin supply pipe, a second tank that supplies resin to the first tank via a resin supply pipe, and a pipe connection point to the resin-coated die A circulation resin pipe for returning the resin to the second tank from
When manufacturing optical fiber,
While supplying resin from the second tank to the first tank via the resin supply pipe, supplying resin from the first tank to the resin-coated die via the resin supply pipe,
When stopping the production of optical fiber for a predetermined period of time,
Resin is sent from the second tank to the first tank through the resin replenishment pipe, and the resin is returned from the first tank to the second tank through the resin supply pipe and the circulation resin pipe. Circulate.

  According to the present invention, when the production of an optical fiber is stopped for a predetermined period or longer, the occurrence of quality defects due to bubbles in the resin or the overflow operation is not performed at the time of resumption without performing operations such as resin removal and washing of pipes and tanks. The increase in resin disposal due to can be suppressed.

It is the schematic of the resin supply apparatus for optical fibers in the case of manufacturing an optical fiber. It is the schematic of the resin supply apparatus for optical fibers which concerns on embodiment of this invention in the case of stopping manufacture of an optical fiber more than predetermined period.

[Description of Embodiment of Present Invention]
An optical fiber resin supply device according to an embodiment of the present invention is
(1) The resin coating includes a first tank that supplies resin to a resin-coated die for optical fiber via a resin supply pipe, and a second tank that supplies resin to the first tank via a resin supply pipe. An optical fiber resin supply device for supplying resin to a die,
A circulation resin pipe is provided for returning the resin to the second tank from the connection point to the resin-coated die in the resin supply pipe.
Since a resin pipe for circulation is provided to return the resin to the second tank from the pipe connection point to the resin-coated die, the resin is contained in each tank and pipe even when the production of the optical fiber is stopped for a predetermined period or longer. Can continue to flow. Thereby, when the production of the optical fiber is stopped for a predetermined period or longer, it is not necessary to perform operations such as resin removal and cleaning of each pipe and tank. In addition, it is possible to suppress the occurrence of quality defects due to bubbles in the resin when the production of the optical fiber is resumed and the increase in resin discard due to the overflow operation.

An optical fiber manufacturing method according to an embodiment of the present invention is as follows.
(2) An optical fiber manufacturing method for manufacturing an optical fiber by coating an optical fiber resin supplied from an optical fiber resin supply device on a glass fiber and curing the coated optical fiber resin. ,
The optical fiber resin supply device is:
A first tank that supplies resin to a resin-coated die for optical fiber via a resin supply pipe, a second tank that supplies resin to the first tank via a resin supply pipe, and a pipe connection point to the resin-coated die A circulation resin pipe for returning the resin to the second tank from
When manufacturing optical fiber,
While supplying resin from the second tank to the first tank via the resin supply pipe, supplying resin from the first tank to the resin-coated die via the resin supply pipe,
When stopping the production of optical fiber for a predetermined period of time,
Resin is sent from the second tank to the first tank through the resin replenishment pipe, and the resin is returned from the first tank to the second tank through the resin supply pipe and the circulation resin pipe. Circulate.
When the production of optical fiber is stopped for a predetermined period or longer, it is not necessary to carry out operations such as resin removal and washing of each pipe and tank by continuing to flow resin into each pipe and tank. It is possible to suppress the occurrence of poor quality due to bubbles in the resin and the increase in resin discard due to overflow work when restarting.

(3) When the production of the optical fiber is stopped for a predetermined period or longer,
A first liquid feeding step of sending a predetermined amount of resin from the second tank to the first tank via the resin supply pipe;
A second liquid feeding step of sending a predetermined amount of resin from the first tank to the second tank through the resin supply pipe and the circulation resin pipe is sequentially repeated.
If the resin is continuously circulated, the resin in each tank may be lost. For this reason, for example, the resin can be prevented from running out of resin in each tank by repeating the step of sending a predetermined amount of resin that fills the pipe with the resin.

(4) Resin liquid feeding for a predetermined time between at least one of the first liquid feeding step and the second liquid feeding step and between the second liquid feeding step and the first liquid feeding step. A liquid feed stop step for stopping is provided.
Providing a liquid feeding stop step for stopping the resin liquid feeding for a predetermined time is advantageous in terms of cost compared to the case where the resin is kept flowing.

[Details of the embodiment of the present invention]
Specific examples of an optical fiber resin supply device and an optical fiber manufacturing method according to an embodiment of the present invention will be described below with reference to the drawings.
In addition, this invention is not limited to these illustrations, is shown by the claim, and intends that all the changes within the meaning and range equivalent to a claim are included.

FIG. 1 and FIG. 2 are schematic views of an optical fiber resin supply apparatus according to an embodiment of the present invention. FIG. 1 shows a case where an optical fiber is manufactured, and FIG. Show the case.
As shown in FIGS. 1 and 2, an optical fiber resin supply device 1 includes a first tank 4 that supplies resin to a resin-coated die 2 through a resin supply pipe 3, and a resin supply pipe 5 to the first tank 4. Then, a second tank 6 for replenishing the resin is provided, and a circulation resin pipe 7 for returning the resin to the second tank 6 from a connection point to the resin-coated die 2 in the resin supply pipe 3.

  The first tank 4 is a tank that functions as a main tank that supplies resin to the resin-coated die 2, and the second tank 6 is a tank that functions as a sub tank that replenishes resin in the main tank. A liquid resin is stored inside the first tank 4 and the second tank 6, and, for example, by pressurizing the inside of the tank with high-pressure nitrogen gas or the like, piping connected to each tank (resin supply piping 3, resin The resin can be fed through the supply pipe 5 and the circulation resin pipe 7).

A coupler 3 c is provided at the tip of the resin supply pipe 3. Further, the resin-coated die 2 is provided with a coupler 2a at a connection point to a pipe (resin supply pipe 3). A coupler 7 b is also provided at the tip of the circulation resin pipe 7.
The coupler 3c can be connected to the coupler 2a of the resin-coated die 2 or the coupler 7b of the circulation resin pipe 7.
The connecting means for each pipe may be connected by means other than a coupler.

  When manufacturing an optical fiber, the coupler 3c and the coupler 2a are connected as shown in FIG. As a result, the resin can be supplied from the first tank 4 to the resin-coated die 2 through the resin supply pipe 3. The resin-coated die 2 is placed in the heating container 8 to make it difficult to solidify the internal resin. The resin filled in the resin-coated die 2 is coated on the glass fiber 10 drawn from the glass base material 9, and the coated optical fiber 11 is manufactured.

  On the other hand, when the production of the optical fiber is stopped for a predetermined period or longer, the coupler 3c and the coupler 7b are connected as shown in FIG. Thus, the resin can be returned from the first tank 4 to the second tank 6 through the resin supply pipe 3 and the circulation resin pipe 7.

  In addition, each of the resin supply pipe 3, the resin supply pipe 5, and the circulation resin pipe 7 is wound with tape heaters 3a, 5a, and 7a to prevent the resin from solidifying in each pipe. It is warm. A valve 3b for controlling the supply of resin is provided in the middle of the resin supply pipe 3. A valve 5b for controlling resin supply is provided in the middle of the resin supply pipe 5.

Next, an optical fiber manufacturing method according to this embodiment will be described.
As shown in FIG. 1, the coupler 3 c of the resin supply pipe 3 and the coupler 2 a of the resin-coated die 2 are connected. Pressure is applied to the first tank 4 to supply resin from the first tank 4 to the resin-coated die 2 through the resin supply pipe 3. The resin filled in the resin-coated die 2 is coated on the glass fiber 10 drawn from the glass base material 9, and the coated optical fiber 11 is manufactured. When the resin in the first tank 4 is low, the resin is appropriately supplied from the second tank 6 to the first tank 4 through the resin supply pipe 5.

Next, a case where production of an optical fiber is stopped for a predetermined period or more will be described. The case of stopping for a predetermined period or longer is, for example, a case where a production line or the like is stopped for a long period due to consecutive holidays or the like.
In the above case, the coupler 3c of the resin supply pipe 3 and the coupler 7b of the resin pipe 7 for circulation are connected to obtain the state shown in FIG. 2, and the resin is circulated in each pipe as follows.
[First liquid feeding step]
(Procedure 1) The pressure in the first tank 4 is released, and the pressure in the second tank 6 is applied with high-pressure nitrogen gas or the like.
(Procedure 2) The valve 5b of the resin supply pipe 5 is opened, and a predetermined amount of resin is fed from the second tank 6 to the first tank 4 through the resin supply pipe 5.
(Procedure 3) The valve 5b of the resin supply pipe 5 is closed, and liquid feeding from the second tank 6 to the first tank 4 is completed.
[Second liquid feeding step]
(Procedure 4) The pressure in the second tank 6 is released, and the pressure is applied to the first tank 4 with high-pressure nitrogen gas or the like.
(Procedure 5) The valve 3b of the resin supply pipe 3 is opened, and a predetermined amount of resin is fed from the first tank 4 to the second tank 6 through the resin supply pipe 3 and the circulation resin pipe 7.
(Procedure 6) The valve 3b of the resin supply pipe 3 is closed, and liquid feeding from the first tank 4 to the second tank 6 is completed.
When the procedure 6 is completed, the procedure returns to the procedure 1 of the first liquid feeding step, and the procedure 1 to the procedure 6 are repeated.
The predetermined amount of resin is preferably an amount that fills each pipe with the resin.

According to this embodiment, when the production of the optical fiber is stopped for a predetermined period or longer, as described above, each pipe (resin supply pipe 3, resin supply pipe 5, circulation resin pipe 7) and each tank (first Resin continues to flow into tank 4 and second tank 6).
Thereby, it is not necessary to carry out operations such as resin removal and cleaning of each pipe (resin supply pipe 3, resin supply pipe 5, circulation resin pipe 7) and each tank (first tank 4, second tank 6). In addition, it is possible to suppress the occurrence of quality defects due to bubbles in the resin and the increase in resin disposal due to overflow work when resuming the production of the optical fiber.
Further, it is possible to prevent the resin in each tank from running out by repeating the step of sending a predetermined amount of resin that fills the pipe with the resin.

When the production of the optical fiber according to the embodiment is stopped for a predetermined period or longer, between the first liquid feeding step and the second liquid feeding step, and between the second liquid feeding step and the first liquid feeding step. A liquid feeding stop step for stopping the liquid feeding of the resin for a predetermined time may be provided on at least one of these.
Thus, by providing a liquid feeding stop step for stopping the liquid feeding of the resin for a predetermined time (for example, a time enough for the resin not to solidify), it is advantageous in terms of cost compared to the case where the resin is kept flowing.

[Example]
When the production of the optical fiber is stopped for 5 days, 1 kg of resin is circulated from the second tank 6 to the first tank 4 and from the first tank 4 to the second tank 6 in the state of FIG. Procedure 1 to procedure 6 were repeated. At this time, a liquid feeding stop step of 8 hours was provided between Procedure 6 and Procedure 1.
The resin-coated die 2 was also heated in the heating container 8 without being removed from the wire drawing device. When the production of the optical fiber is resumed, resin removal and cleaning of each pipe (resin supply pipe 3, resin supply pipe 5, circulation resin pipe 7) and each tank (first tank 4, second tank 6) are performed. Without drawing, an optical fiber product was manufactured by drawing.

[Comparative example]
In the comparative example, when the production of the optical fiber was stopped for 5 days, the state shown in FIG. 1 was obtained, and the resin was not circulated. When the production of the optical fiber is resumed, resin removal and cleaning of each pipe (resin supply pipe 3, resin supply pipe 5, circulation resin pipe 7) and each tank (first tank 4, second tank 6) are performed. Without drawing, an optical fiber product was manufactured by drawing.

In the comparative example, when the operation of the optical fiber production was resumed, quality defects (bubbles and uneven thickness defects) occurred in the product (optical fiber) coating.
On the other hand, in the examples, no quality defect occurred in the coating of the product (optical fiber) when the production of the optical fiber was resumed. Further, in the example, it was not necessary to remove and wash the resin of each pipe (resin supply pipe 3, resin supply pipe 5, circulation resin pipe 7) and each tank (first tank 4, second tank 6). So we could reduce the work cost.

DESCRIPTION OF SYMBOLS 1 Optical fiber resin supply apparatus 2 Resin coating die 3 Resin supply piping 4 1st tank 5 Resin replenishment piping 6 2nd tank 7 Circulation resin piping 8 Heating container 9 Glass base material 10 Glass fiber 11 Covered optical fiber

Claims (4)

A first tank for supplying a resin to a resin-coated die for an optical fiber via a resin supply pipe; and a second tank for supplying a resin to the first tank via a resin supply pipe; An optical fiber resin supply device for supplying
A resin pipe for circulation is provided to return the resin to the second tank from the connection point to the resin-coated die in the resin supply pipe ;
A valve for controlling the supply of resin is provided in the middle of the resin supply pipe,
In the middle of the resin supply pipe, a valve for controlling the supply of resin was provided.
Resin supply device for optical fiber. An optical fiber manufacturing method for manufacturing an optical fiber by coating an optical fiber resin supplied from an optical fiber resin supply device on a glass fiber and curing the coated optical fiber resin,
The optical fiber resin supply device is:
A first tank that supplies resin to a resin-coated die for optical fiber via a resin supply pipe, a second tank that supplies resin to the first tank via a resin supply pipe, and a pipe connection point to the resin-coated die A circulation resin pipe for returning the resin to the second tank from
When manufacturing optical fiber,
While supplying resin from the second tank to the first tank via the resin supply pipe, supplying resin from the first tank to the resin-coated die via the resin supply pipe,
When stopping the production of optical fiber for a predetermined period of time,
Resin is sent from the second tank to the first tank through the resin replenishment pipe, and the resin is returned from the first tank to the second tank through the resin supply pipe and the circulation resin pipe. An optical fiber manufacturing method for circulation. When the production of the optical fiber is stopped for a predetermined period or longer,
A first liquid feeding step of sending a predetermined amount of resin from the second tank to the first tank via the resin supply pipe;
3. The optical fiber manufacturing method according to claim 2, wherein a second liquid feeding step of sending a predetermined amount of resin from the first tank to the second tank through the resin supply pipe and the circulation resin pipe is sequentially repeated. .   Resin feeding is stopped for a predetermined time between at least one of the first liquid feeding step and the second liquid feeding step and between the second liquid feeding step and the first liquid feeding step. The method for manufacturing an optical fiber according to claim 3, further comprising a liquid feeding stop step.

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