JPH0393655A - Production of aluminum-coated optical fiber and apparatus for producing the same - Google Patents

Abstract

PURPOSE:To improve quality by leading drawn optical fiber into molten Al, coating the optical fiber with the molten Al and sensing leaked light from the optical fiber coated with the Al just after taking thereof from the lower part of the molten Al. CONSTITUTION:Quartz glass optical fiber is drawn from the tip of a preform 1 heated in an electric furnace 2, passed through an inlet die 43 while being naturally cooled and introduced into molten Al 42 melted in a melting crucible 41. The resultant Al-coated optical fiber 6 having the Al coating layer, solidified and applied to the periphery thereof is taken from an outlet 44, passed through a take-off device 7 and wound onto a winding reel 9. When all the optical sensors 13 of one or plural optical sensing units 10 provided around the Al- coated optical fiber 6 taken from the outlet die 44 sense no leaked light from the Al-coated optical fiber 6, a control signal is sent to start winding. If any of the optical sensors 13 sense the leaked light, an alarm is raised to take countermeasures.

Description

DETAILED DESCRIPTION OF THE INVENTION (Field of Industrial Application) The present invention relates to a method and apparatus for manufacturing an aluminum-coated optical fiber in which the outer periphery of a glass optical fiber is coated with aluminum.

(Background and Problems of the Invention) Aluminum-coated optical fibers, in which aluminum is coated directly above a glass optical fiber whose core and cladding layers are both made of glass such as quartz glass, have excellent heat resistance, and hydrogen Because it prevents diffusion into the inside of the fiber, there is no deterioration in light transmission, and it has excellent static fatigue properties.
Applications that take advantage of these characteristics are increasing.

The coating of aluminum onto the glass optical fiber is performed in the same process as the drawing of the glass optical fiber. For example, the glass optical fiber that has just been drawn from the preform member is guided into molten aluminum through an inlet die, and the molten aluminum is poured into the glass. This is done by coagulating it around the optical fiber and drawing it out through an exit die. Part of the aluminum layer that has solidified around the glass optical fiber is remelted by the heat of the molten aluminum while the fiber moves through the molten aluminum and reaches the exit die, so the solidification and remelting of this aluminum layer are If the balance is not maintained, the Al main coating 5 as shown in Figure 3.
This results in a so-called single-sided coating, which is formed only on a part of the periphery of the glass optical fiber 3 rather than on the entire circumference.

At the beginning of glass optical fiber drawing and aluminum coating work, so-called lead-out work, it is normal for one side to be coated, and after the optical fiber drawing speed is increased from the slow speed during lead-out work to the speed during steady operation. After a while,
Solidification and remelting are well balanced, and an aluminum-coated optical fiber with a good appearance in which the entire circumference of the glass optical fiber is coated with aluminum can be obtained. When this state is reached, winding of the product is started.

In the past, winding was started after visually confirming that the single-sided coating condition had been resolved and that an aluminum coating covering the entire circumference of the glass optical fiber had been obtained. The outer diameter is extremely thin, about 170 to 1200 um, and it is moving at a relatively fast speed of about 30 to 200 m/min. It is extremely difficult to visually determine whether or not an aluminum coating is formed, and it is easy to make a mistake in judgment. Even after entering a stable operating state in which a good-looking aluminum coating covering the entire circumference of the glass optical fiber is obtained, single-sided coating may occur due to changes in conditions for some reason, such as an increase in the temperature of molten aluminum. In such cases, relying on visual inspection to monitor the single-sided coating is not only labor intensive, but also poses problems in terms of quality assurance.

SUMMARY OF THE INVENTION Accordingly, an object of the present invention is to provide a method and apparatus for manufacturing an aluminum-coated optical fiber that can easily and reliably detect the presence or absence of a single-sided coating during the manufacturing process of the aluminum-coated optical fiber.

(Structure of the Invention) The manufacturing method of the present invention is a method for manufacturing an aluminum-based optical fiber in which a glass optical fiber is guided into molten aluminum below immediately after drawing, and aluminum is coated around the glass optical fiber. The manufacturing apparatus of the present invention is characterized by detecting the presence or absence of leakage light from the aluminum main coated optical fiber immediately after being drawn downward from the glass optical fiber. In some aluminum-coated optical fiber manufacturing equipment, which includes a molten aluminum coating device provided below and a pulling device provided further below, the main aluminum-coated optical fiber is pulled out downward from the molten aluminum coating device. and a photodetector connected to the other end of the optical fiber for optical inspection, the optical fiber for photodetection having its light input tip positioned so as to face the drawn-out aluminum-coated optical fiber. This is a characteristic feature.

(Function) Since the present invention has the above-mentioned structure, if there is a single-sided coating, that is, a portion not coated with aluminum, in the aluminum-mainly coated optical fiber pulled out downward from the molten aluminum coating device, the molten aluminum coating is applied. Leakage light from the aluminum-coated fiber immediately after being pulled out from the device enters the light-incoming tip of the optical detection optical fiber and is detected by the photodetector. can be detected.

(Example) To explain this in detail based on the drawings, 1 wi is an explanatory diagram illustrating an example of the manufacturing method and manufacturing apparatus of the present invention, 1 is a preform base material of a silica glass optical fiber, 2 is a wire drawn electric furnace. Approximately 2200℃ using electric furnace 2
The silica glass optical fiber 3 is pulled out downward from the tip of the base material heated to 1, and is drawn tt. The drawn quartz glass optical fiber 3 passes through an inlet die 43 of a molten aluminum coating device 5 provided below the electric furnace 2 while cooling naturally, and is transferred to a molten aluminum 42 melted in a melting crucible 41.
introduced inside. The temperature of the silica glass optical fiber entering the entrance die 43 is usually about 40 to 100° C., and the molten aluminum 42 solidifies around the introduced silica glass optical fiber 3. A part of the solidified layer is remelted by the heat of molten aluminum while the optical fiber reaches the exit die 44, but the aluminum coated optical fiber 6 having the aluminum coating layer solidified around the quartz glass optical fiber reaches the exit die 44. 44 and is pulled out downward. The drawn out aluminum coated optical fiber 6 is
It is taken up by a take-up device 7 provided below the main molten aluminum coating device, passed through a dancer roll 8, and then wound onto a take-up roll 9. Reference numeral 11 denotes an optical fiber for light detection, and its optical tip 12 is connected to a molten aluminum-coated optical fiber [4] on the exit side of the exit die 44, preferably directly below the exit die 44, and connected to the aluminum-coated optical fiber pulled out from the exit diameter 44. 6, and the photodetecting optical fiber 1
A photodetector 13 is connected to the other end of the photodetector 1 . Three to four sets of light detection units IQ- are provided (only one set is illustrated in FIG. 1), and each unit is connected to The optical tip portion is provided so as to surround the aluminum-coated optical fiber 6 pulled out from the exit die 44, and the aluminum-coated optical fiber 6
This makes it possible to detect leaked light from any part of the entire circumferential surface of the sensor.

It is desirable that a light-shielding hood be attached to the light-input end portion 12 of the light-detecting optical fiber 11 so as to prevent light other than light leaking from the single-sided coated aluminum-coated optical fiber from entering as much as possible.

Further, it is preferable to increase the light incident efficiency by using a lens.

A longitudinal cross-sectional view of such a light entrance tip portion is shown in FIG. In the figure, 11 is a cord of the optical fiber for photodetection, 101 is a ferrule that grips the tip 100 of the core wire, and 102 is a tip case, which is connected integrally with the optical fiber cord 11 for photodetection and a molded part 104. ing. 105 is a condensing lens. A hood 106 is screwed to the flange surface 103 of the case 102 with screws 108, and a mounting flange 107 is provided at the tip of the hood 106.
is provided.

The light detection optical fiber 11 may be a single-core optical fiber or a multi-core optical fiber.
There is no problem with any fiber, but core 41250 ~
A single-core fiber with a large diameter of 1000 nm is preferred.

For the photodetector 13, a pin photodiode, an A1 < Lancier photodiode, a germanium photodiode, a silicon blue cell, or the like is used. As will be described later, the photodetector 13 detects the leaked light from the aluminum-coated optical fiber 6 pulled out from the exit die 44 of the molten aluminum coating device ▲. This indicates that there is a portion that is not coated, that is, there is a single-sided coating. Photodetector 13
In this case, if all of the photodetectors 13 of the plurality of photodetection units no longer detect the leaked light from the aluminum-coated optical fiber 6, An automatic control mechanism that issues an alarm or a control signal to start winding is activated (at the start of operation), or when any of the photodetectors 13 detects leaked light from the aluminum-coated optical fiber 6. It is also possible to connect a signal processing circuit or a control circuit that processes the light detection signal of the photodetector 13 so as to occasionally issue an alarm and record it on a recorder (during normal operation). Note that the manufacturing method of the present invention is applicable not only to the case where the glass optical fiber is drawn from the above-mentioned preform base material using an electric furnace, but also to the case where the glass optical fiber is drawn by the crucible method.

In the case where the aluminum-coated optical fiber pulled out downward from the molten aluminum coating device has a single-sided coating, that is, a portion where the aluminum main body is not coated, the aluminum-coated optical fiber immediately after being pulled out from the molten aluminum coating device This is based on the discovery by the inventors of the present invention that leakage light can be observed from fibers. Leak light! The reason for this measurement can be considered as follows. For example, when drawing a silica glass optical fiber from a preform base material, the temperature is approximately 2200°C.
℃, the tip of the base material in the electric furnace and the glass optical fiber near this tip are in a red-hot state, and the red-hot light emitted from this is the wire drawing JP! - propagates through the core and cladding layers of a glass optical fiber. Since the distance from the lower end of the electric furnace to the outlet of the molten aluminum coating equipment is usually a short distance of 3 m or less, the glass optical fiber is It is thought that the state is likely to cause leakage of light propagating from the core and light propagating from the cladding layer.

If the outer periphery of the glass optical fiber is coated with aluminum, the light will of course be blocked by the aluminum coating and will not leak from the optical fiber, but if a part of the periphery of the glass optical fiber is coated with aluminum. It is thought that there is a part where there is no light, and that light leaks from this part and is observed. Therefore, as described above, if the light input tip of the light detection optical fiber is provided on the exit side of the molten aluminum coating device, preferably directly below the exit, so as to face the aluminum main coated optical fiber to be drawn out, If the aluminum-coated optical fiber has a single-sided coating and there is a portion where the aluminum main body is not coated,
Leakage light from the part where the aluminum is not coated enters the light input tip of the optical detection fiber and is detected by the photodetector, detecting the presence or absence of single-sided coating during the manufacturing process of the aluminum coated optical fiber. can.

(Effects of the Invention) As explained above, according to the manufacturing method and manufacturing apparatus of the present invention, the presence or absence of a single-sided coating can be easily and reliably detected during the manufacturing process of manufacturing an aluminum coated optical fiber. Therefore, at the start of production of aluminum-coated optical fiber, that is, at the time of lead-out work, it is important to check whether the condition of the single-sided coating is consistent or not.
Accurately detects whether or not the entire circumference of the glass optical fiber is coated with aluminum coating, which allows you to accurately judge when to start winding the product, and also automatically starts winding. It also becomes possible to do so. Furthermore, if one-sided coating occurs for some reason after entering a steady operating state, it is possible to reliably eliminate the occurrence of one-sided coating, issue an alarm, and take measures to eliminate one-sided coating. In addition, by recording the occurrence of single-sided coating on a recorder, it is possible to easily know whether or not a product has single-sided coating and the location where single-sided coating is present, which is of great benefit in terms of quality control.

[Brief explanation of drawings]

Fig. 1 is an explanatory diagram for explaining the manufacturing method and manufacturing apparatus of the present invention, Fig. 2 is a cross-sectional view of an example of the light input tip of the optical fiber for photodetection in the present invention, and Fig. 3 is a one-sided coated state. FIG. 2 is a cross-sectional view of the optical fiber shown in FIG. (Explanation of symbols) 1: Preform base material, 2: Drawing electric furnace, 3: Drawn glass optical fiber, A: Molten aluminum coating device, 4
1: Aluminum melting crucible, 42: Molten aluminum coating, 6: Aluminum coated optical fiber, 7: Take-up device, 8: Dancer roll, 9: Take-up reel, upright = light detection unit, 11; Optical fiber for light detection, 12: Light input tip, 13: Photodetector, 100: Optical fiber core tip, 101: Ferrule,
105: Condensing lens, 106: Hood.

Claims (2)

[Claims] (1) In the manufacturing method of aluminum-coated optical fiber, in which a glass optical fiber is guided into molten aluminum below immediately after being drawn, and aluminum is coated around the glass optical fiber, the aluminum coating is immediately after being drawn downward from the molten aluminum. A method for manufacturing an aluminum-coated optical fiber characterized by detecting the presence or absence of light leaking from the fiber. (2) a drawing furnace that draws the glass optical fiber downward;
In an aluminum-coated optical fiber manufacturing apparatus consisting of a molten aluminum coating device provided below the molten aluminum coating device and a take-off device further below the molten aluminum coating device, the molten aluminum coating device draws out the aluminum-coated optical fiber downwardly. It is characterized by comprising a light detection optical fiber whose light receiving tip is positioned so as to face the pulled out aluminum coated optical fiber, and a photodetector connected to the other end of the light detection optical fiber. Equipment for manufacturing aluminum-coated optical fiber.