JP2019214483A - Drawing device for optical fiber - Google Patents

Abstract

To provide a drawing device for optical fiber capable of increasing collection efficiency for cooling gas and suppressing an optical fiber from shifting in position.SOLUTION: The present invention relates to a drawing device 1 for optical fiber comprising a cooling device 10 cooling a glass fiber G1 having been drawn, and the cooling device 10 is configured to let a traveling glass fiber G1 pass through the cooling device 10 in a vertical direction to cool the glass fiber G1 with cooling gas, and comprises: cooling gas introduction ports 13a, 13b for introducing the cooling gas into the cooling device 10; a pressurization part 21 provided below the cooling gas introduction ports 13a, 13b and raising some pressure inside the cooling device 10; and cooling gas discharge ports 15a, 15b provided in an inner surface of the cooling device 10 above the pressurization part 21, and discharging the cooling gas. The cooling gas discharge ports 15a, 15b are provided below the cooling gas introduction ports 13a, 13b, and also connected to a cooling gas collection device 17.SELECTED DRAWING: Figure 1

Description

  The present invention relates to an optical fiber drawing apparatus.

Patent Document 1 discloses an optical fiber cooling device in which a pressurizing chamber is provided at an outlet of a cooling device, and gas is supplied to the pressurizing chamber to suppress release of cooling gas from the outlet of the cooling device. ing.
Patent Document 2 discloses a gas introduction mechanism that blows clean air near the outlet of an optical fiber to suppress the release of cooling gas from the outlet and covers the entire forced cooling cylinder with a housing. There is described an optical fiber drawing apparatus for recovering a cooling gas by a gas recovery mechanism provided in a section.

JP-A-2005-074590 JP-A-2004-142976

  The optical fiber cooling device described in Patent Literature 1 is not provided with a cooling gas recovery mechanism, and thus the effect of reducing the amount of cooling gas used is considered to be limited. On the other hand, the optical fiber drawing apparatus described in Patent Literature 2 is provided with a cooling gas recovery mechanism, but the dust deposited in the housing is soared by the cooling gas, and the dust is deposited on the optical fiber surface at the optical fiber inlet. There was a risk of adhesion. In addition, a cooling gas recovery port is present near the optical fiber inlet, and the flow of the recovered cooling gas causes the optical fiber to deflect and come into contact with the inner surface of the forced cooling cylinder, thereby deteriorating the strength of the optical fiber. There was a fear.

  SUMMARY OF THE INVENTION It is an object of the present invention to provide an optical fiber drawing apparatus that can increase the efficiency of recovering cooling gas and suppress line deviation of an optical fiber.

An optical fiber drawing apparatus according to one embodiment of the present invention,
An optical fiber drawing device including a cooling device that cools the glass fiber after drawing,
The cooling device,
A device that cools the glass fiber with a cooling gas by passing the traveling glass fiber in a vertical direction inside the cooling device,
A cooling gas inlet for introducing the cooling gas into the cooling device,
A pressurizing unit provided below the cooling gas inlet, for increasing a partial pressure inside the cooling device,
A cooling gas discharge port for discharging the cooling gas, provided on the inner surface of the cooling device above the pressurizing unit,
The cooling gas discharge port is provided below the cooling gas introduction port, and is connected to a cooling gas recovery device.

  According to the optical fiber drawing apparatus of the invention described above, the efficiency of collecting the cooling gas can be increased, and the optical fiber can be prevented from being out of line.

It is a figure showing the schematic structure of the optical fiber drawing device concerning this embodiment.

(Description of Embodiment of the Present Invention)
First, embodiments of the present invention will be listed and described.
An optical fiber drawing apparatus according to one embodiment of the present invention,
(1) An optical fiber drawing apparatus provided with a cooling device for cooling a glass fiber after drawing,
The cooling device,
A device that cools the glass fiber with a cooling gas by passing the traveling glass fiber in a vertical direction inside the cooling device,
A cooling gas inlet for introducing the cooling gas into the cooling device,
A pressurizing unit provided below the cooling gas inlet, for increasing a partial pressure inside the cooling device,
A cooling gas discharge port for discharging the cooling gas, provided on the inner surface of the cooling device above the pressurizing unit,
The cooling gas discharge port is provided below the cooling gas introduction port, and is connected to a cooling gas recovery device.
According to the above configuration, since the pressurizing section is provided below the cooling gas inlet, there is an effect that the cooling gas pulled by the optical fiber stays in the cooling device. Further, since the cooling gas discharge port at the top of the pressurizing section is connected to the cooling gas recovery device, the efficiency of recovering the cooling gas remaining in the cooling device can be increased. In addition, since the cooling gas discharge port is provided above the pressurizing section and below the cooling gas introduction port, the cooling gas discharge port exists at a position close to the input and output lines of the optical fiber. Will not do. For this reason, the flow velocity of the cooling gas at the incoming and outgoing portions of the optical fiber can be suppressed, so that the optical fiber can be prevented from moving.

(2) In the cooling device, a plurality of the cooling gas discharge ports may be provided at positions symmetric with respect to the running glass fiber.
According to the above configuration, by providing the plurality of cooling gas discharge ports at positions symmetrical with respect to the traveling glass fiber, it is possible to prevent the optical fiber from being asymmetrically cooled.

(3) The cooling gas may be a helium gas.
According to the above configuration, since the helium gas has a good heat exchange rate, the cooling efficiency can be increased by using the helium gas as the cooling gas. In addition, since helium gas is relatively expensive, the cost can be reduced by increasing the efficiency of helium gas recovery.

(Details of the embodiment of the present invention)
A specific example of an optical fiber drawing apparatus 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.

An example of an optical fiber drawing apparatus according to the present embodiment will be described with reference to FIG.
As shown in FIG. 1, the optical fiber drawing apparatus 1 includes a drawing furnace 100 for heating the optical fiber preform G, and a cooling apparatus 10 for cooling the glass fiber G1 drawn from the optical fiber preform G. Have.
Further, the optical fiber drawing apparatus 1 includes a resin coating device 110 for coating the outer periphery of the cooled glass fiber G1 with a coating resin, and a resin curing furnace 120 for curing the coated resin.
Further, the optical fiber drawing apparatus 1 includes a plurality of guide rollers 130 (only one is shown in the figure) for guiding the optical fiber wire G2 on which the coating resin is formed, and a winding device that winds the optical fiber wire G2. Machine 140.

  The drawing furnace 100 has a heater 101 arranged so as to surround the optical fiber preform G. The lower end side of the optical fiber preform G set in the drawing furnace 100 is heated by the heater 101. The optical fiber preform G softened by the heating is stretched downward and reduced in diameter to form a glass fiber G1. The glass fiber G <b> 1 having a reduced diameter is fed into a cooling device 10 arranged on the downstream side (the lower side in FIG. 1) of the drawing furnace 100.

  The cooling device 10 in the optical fiber drawing apparatus 1 of the present embodiment includes a cooling main body 11 and a pressurizing unit 21. The pressurizing section 21 is disposed below the cooling main body 11 in the traveling direction of the glass fiber G1 (the vertical direction in FIG. 1). The cooling main unit 11 and the pressurizing unit 21 have, for example, a half-split structure in which a pair of semi-cooling main units and a half pressurizing unit can be opened and closed.

  In the cooling main body 11, a fiber passage 12 through which the glass fiber G1 is inserted is provided in the center portion (inside) of the cooling main body 11 so as to vertically penetrate the cooling main body 11. The fiber passage 12 is, for example, a cylindrical passage formed in the center portion of the cooling main body 11 when a pair of semi-cooling main bodies are brought into abutment with each other and closed. The glass fiber G1 enters from a passage entrance 12a provided at the upper end of the fiber passage 12, and exits from a passage exit 12b provided at the lower end of the fiber passage 12.

  The fiber passage 12 is provided with a plurality of cooling gas inlets 13 (13a, 13b) for introducing a cooling gas such as helium gas into the fiber passage 12. The fiber passage 12 is provided with a plurality of cooling gas discharge ports 15 (15a, 15b) for discharging the cooling gas in the fiber passage 12 to the outside. The cooling gas outlet 15 (15a, 15b) is provided below the cooling gas inlet 13 (13a, 13b) in the traveling direction of the glass fiber G1. The cooling gas discharge port 15 (15a, 15b) is provided at a position below the cooling main body 11 and near the passage outlet 12b.

  The cooling gas inlets 13a and 13b are provided at positions symmetrical with respect to the running glass fiber G1 (at 180-degree intervals) in a plane orthogonal to the fiber passage 12. Note that the position where the cooling gas inlet is provided may be any position that is symmetrical with respect to the glass fiber G1, and for example, four cooling gas inlets may be provided at intervals of 90 degrees. Further, the cooling gas inlets 13 (13a, 13b) may be provided in a plurality of stages in the vertical direction of the fiber passage 12. In this example, cooling gas inlets 13 (13a, 13b) are provided in two stages.

  The cooling gas inlet 13 (13a, 13b) is connected to a cooling gas supply path 14 (14a, 14b) for introducing a cooling gas from outside. The cooling gas supply path 14 (14a, 14b) is connected to a cooling gas supply device (not shown) capable of supplying a cooling gas.

  The cooling gas discharge ports 15a and 15b are provided at positions (180-degree intervals) that are symmetric about the running glass fiber G1 in a plane orthogonal to the fiber passage 12. The cooling gas discharge ports 15 a and 15 b are provided on the inner surface of the cooling main body 11. The position where the cooling gas discharge ports are provided may be any position that is symmetrical with respect to the glass fiber G1, and for example, four cooling gas discharge ports may be provided at 90 ° intervals.

  A cooling gas discharge passage 16 (16a, 16b) for discharging a cooling gas to the outside is connected to the cooling gas discharge port 15 (15a, 15b). The cooling gas discharge path 16 (16a, 16b) is connected to a cooling gas recovery device 17 that can recover the cooling gas.

  The cooling main body 11 having such a configuration cools the glass fiber G1 traveling in the vertical direction along the fiber passage 12 with the cooling gas introduced from the cooling gas inlet 13 (13a, 13b). Further, the cooling main body 11 discharges the cooling gas used for cooling the glass fiber G1 from the cooling gas discharge ports 15 (15a, 15b) to the cooling gas recovery device 17.

  The pressurizing unit 21 is for increasing the pressure of a part of the cooling device 10, and a pressurizing chamber 23 as a part of the cooling device 10 is provided therein.

  The pressurizing unit 21 is provided so as to surround the passage outlet 12 b of the fiber passage 12 provided at the lower end of the cooling main body 11. A fiber passage 22 through which the glass fiber G <b> 1 is inserted is provided at the center of the pressurizing unit 21 so as to penetrate the pressurizing unit 21 in the up-down direction so as to communicate with the fiber passage 12 of the cooling main body 11. The fiber passage 22 is, for example, a cylindrical passage formed in a central portion of the pressurizing portion 21 when the pair of semi-pressurizing portions abut against each other to be closed. The above-described pressurizing chamber 23 is provided inside the pressurizing section 21 so as to cover the glass fiber G1 immediately after exiting from the passage outlet 12b of the cooling main body section 11.

  A gas outlet 24 (24a, 24b) for blowing gas such as clean air is formed in the fiber passage 22. The gas outlets 24a and 24b are provided at positions symmetrical with respect to the running glass fiber G1 (at 180-degree intervals) in a plane orthogonal to the fiber passage 22. A gas supply passage 25 (25a, 25b) for supplying gas is connected to the gas outlet 24 (24a, 24b). The gas supply passage 25 (25a, 25b) is formed in a shape that is inclined upward so that gas can be blown out into the pressurizing chamber 23.

  The position at which the gas outlets are provided may be any position that is symmetrical with respect to the glass fiber G1, and for example, four gas outlets may be provided at 90-degree intervals. As the gas blown out from the gas outlet, an inert gas such as nitrogen gas may be used in addition to air.

  In the pressurizing unit 21 having such a configuration, the glass fiber G1 emitted from the passage outlet 12b of the cooling main body 11 passes through the fiber passage 22 from the passage outlet 22a provided at the lower end of the fiber passage 22. Get out. The pressurizing section 21 blows out gas from the gas outlets 24 a and 24 b toward the glass fiber G <b> 1 traveling up and down along the fiber passage 22, so that the pressure of the pressurizing chamber 23 (part of the inside of the cooling device 10) is increased. Is higher than the pressure in the fiber passage 12 of the cooling main body 11.

  Meanwhile, in an optical fiber drawing apparatus, for example, there is a configuration in which a mechanism for collecting a cooling gas is provided at an upper end of the cooling apparatus. In the case of this configuration, the cooling recovery port (the cooling gas discharge port in the present embodiment) is provided near the glass fiber inlet portion (the passage inlet 12a in the present embodiment). The wire may be blurred and come into contact with the inner surface of the fiber passage, so that the strength of the glass fiber may be deteriorated.

  On the other hand, according to the optical fiber drawing apparatus 1 of the present embodiment, the cooling gas discharge port 15 is provided below the cooling gas introduction port 13 and above the pressurizing section 21. ing. That is, the cooling gas discharge port 15 is located at a position separated from the passage inlet 12a where the glass fiber G1 enters and the passage outlet 22a where the glass fiber G1 exits in the cooling device 10. For this reason, the flow velocity of the cooling gas at the passage inlet 12a and the passage outlet 22a can be suppressed, and line deviation of the glass fiber G1 can be suppressed.

  Further, a pressurizing section 21 is provided below the cooling main body section 11 and below the cooling gas inlet 13, and the pressure in the pressurizing chamber 23 is the pressure in the fiber passage 12 of the cooling main body section 11. Higher than the pressure. For this reason, the cooling gas drawn downward by the traveling of the glass fiber G1 can be suppressed by the pressure applied by the pressurizing unit 21, and can remain in the fiber passage 12 of the cooling main unit 11. Since the cooling gas in the fiber passage 12 is recovered through the cooling gas discharge port 15 provided near the passage outlet 12b of the cooling main body 11 and immediately above the pressurizing chamber 23, the inside of the fiber passage 12 is It is possible to efficiently collect the cooling gas remaining in the tank with a small intake capacity.

  Further, by using helium gas having a high heat exchange rate as the cooling gas, the cooling efficiency can be increased. Since helium gas is relatively expensive, the cost can be reduced by increasing the recovery efficiency of helium gas as described above.

  Further, since the cooling gas discharge ports 15a and 15b are provided at positions symmetrical with respect to the running glass fiber G1, the glass fiber G1 can be uniformly cooled and the glass fiber G1 can be uniformly suctioned. By acting, line blurring of the glass fiber G1 can be suppressed.

  While the invention has been described in detail and with reference to specific embodiments, it will be apparent to those skilled in the art that various changes and modifications can be made without departing from the spirit and scope of the invention. In addition, the number, position, shape, and the like of the constituent members described above are not limited to the above-described embodiment, and can be changed to numbers, positions, shapes, and the like that are suitable for carrying out the present invention.

1: Drawing device for optical fiber 10: Cooling device 11: Cooling body 12: Fiber passage 12a: Passage inlet 12b: Passage outlet 13 (13a, 13b): Cooling gas inlet 15 (15a, 15b): Cooling gas outlet 17: Cooling gas recovery device 21: Pressurizing section 22: Fiber passage 22a: Passage outlet 23: Pressurizing chamber 24 (24a, 24b): Gas outlet G1: Glass fiber

Claims (3)

An optical fiber drawing device including a cooling device that cools the glass fiber after drawing,
The cooling device,
A device that cools the glass fiber with a cooling gas by passing the traveling glass fiber in a vertical direction inside the cooling device,
A cooling gas inlet for introducing the cooling gas into the cooling device,
A pressurizing unit provided below the cooling gas inlet, for increasing a partial pressure inside the cooling device,
A cooling gas discharge port for discharging the cooling gas, provided on the inner surface of the cooling device above the pressurizing unit,
The cooling gas discharge port is provided below the cooling gas introduction port, and is connected to a cooling gas recovery device,
Optical fiber drawing equipment.   The optical fiber drawing device according to claim 1, wherein the cooling device is provided with a plurality of the cooling gas discharge ports at positions symmetric with respect to the running glass fiber.   The optical fiber drawing device according to claim 1, wherein the cooling gas is a helium gas.

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