JPH0650512Y2 - Optical fiber base metal dehydration sintering furnace - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Industrial application] The present invention relates to a dehydration sintering furnace for a porous preform of an optical fiber.

[Prior Art] FIG. 3 shows an example thereof.

12 is a container for dehydration sintering, 14 is a gas inlet for dehydration, 16 is an electric furnace, 18 is a porous base material, 20 is a dummy rod, which is usually used as it is at the time of deposition, 22 is a traverser 24 is a rotating means.

-Operation: The porous base material 18 is heated by the electric furnace 16 while feeding the dehydration gas (Cl ₂ + He or the like) from the gas inlet 14 into the container 12.

At that time, the driver 22 moves the porous base material 18 up and down via the dummy rod 20, and the rotating means 24 rotates the porous base material 18 via the dummy rod 20.

[Problems to be solved by the invention] (1) Since the dummy rod 20 is usually made of glass, it is dangerous when broken. (2) Since the dummy rod 20 has a considerable thickness, airtightness with the container 12 (3) The porous base material 18 may bend unless it is heated uniformly. Therefore, as described above, the porous base material 18 is rotated by the rotating means 24.
Need to rotate.

(4) The above problems (1) to (3) are caused by using the dummy rod 20 made of glass for suspending the porous base material 18.

Therefore, it is considered to suspend the porous base material 18 with a wire. However, in that case, it is necessary to use expensive platinum, and the platinum wire also deteriorates due to the dehydrating gas and becomes gradually thinner, so that it cannot be used for a long time.

[Purpose of Invention] The disadvantages of suspending the porous base material 18 by the glass dummy rod 20 are eliminated. Also, make it possible to use wires other than platinum. Even if platinum wire is used, it should be possible to use it for a long time.

[Means for Solving the Problems] This invention, as shown in FIG. 1a, (1) uses a wire 26 to suspend the porous base material 18, and (2) surrounds the wire 26 with a protective tube 30. (3) Measures are taken to flow a gas (He, oxygen, nitrogen, etc.) that does not react with the wire 26 into the protective tube 30.

(4) Incidentally, as shown in FIG. 2a, the protection tube 30 may be a telescope type including a plurality of divided tubes.

[Description] [1] Structure As shown in FIG. 1a, the wire 26 that suspends the porous base material 18 is directly connected to the porous base material 18.
Since it cannot be connected to, the base 21 of the dummy rod used in the conventional deposition is left and connected to it.

The upper end of the wire 26 is connected to a wire winder or traverser 28, which allows the base material 18 to be raised and lowered.

A protective tube 30 is provided around the wire 26. At this time, the container
The wire 26 in 12 is entirely surrounded by the protective tube 30 (so that the bare wire 26 is not exposed below the protective tube 30).

The protection tube 30 is made of glass, for example. Its lower end is
Slightly cover the base 21 of the dummy rod.

Further, the protective tube 30 is preferably as thin as possible within the range where it does not adhere to the wire 26. If this tube 30 is thick, back flow or diffusion of the dehydrating gas occurs, and the wire is likely to deteriorate. If it is thin, the flow rate will increase with the same amount of gas, making it difficult for backflow to occur.

A stopper 34 is provided at a portion where the wire 26 penetrates the upper end of the protective tube 30 to prevent gas from escaping. The stopper 34 is made of, for example, Banton rubber.

Immediately below the plug 34 is a sealing gas inlet 36. He or the like is used as the seal gas, but basically, even if mixed with the dehydrating gas, it does not adversely affect the characteristics of the optical fiber.
And it is good if it does not react with the wire.

[2] Action A seal gas such as He is continuously flown through the inlet 36, and the wire winder or traverser 28 moves the base material 18 up and down via the wire 26.

At that time, even if the base material 18 moves up and down, the lower end of the protective tube 30 is
Always keep it over the base 21 of the dummy rod. That is, even when the base material 18 goes down, the wire 26 is not exposed to the outside of the protection tube 30, and the protection tube 30 moves up and down while always maintaining a fixed relation with the wire 26 (Fig. 1b). .

Therefore, a seal between the protective tube 30 and the container 12 is required. However, since the protective tube 30 can be made thinner than the dummy rod 20, sealing is easier than in the case of the dummy rod 20.

Others are the same as the above-mentioned conventional case.

[3] Alternative structure As shown in Fig. 2a, the protective pipe 30 is, for example, three divided pipes 3
Telescope type consisting of 1,32,33. That is, the divided pipe 31 is in the divided pipe 32, the divided pipe 32 is in the divided pipe 33,
Each will have a structure that allows it to enter and exit in a nested manner.

The dividing pipe 33 is fixed to the container 12.

Other parts are the same as in the case of the first embodiment.

[4] Its action When the wire 26 is wound by the winder 28 and the base material 18 is lifted, the bottom split pipe 31 enters the split pipe 32 above it. When the dividing pipe 31 is fully inserted into the dividing pipe 32, the dividing pipe 32 enters the dividing pipe 33 (Fig. 2b).

On the contrary, when the wire 26 is rewound and the base material 18 descends, the divided pipes 31 and 32 descend by their own weight.

The lower end of the split pipe 31 is always in a position covering the base 21 of the dummy rod, and the wire 26 is not exposed to the outside of the protective pipe 30.

In this case, even if the base material 18 moves up and down, the position of the upper end of the protection tube 30 does not move. On the other hand, in the case of Fig. 1a, the base metal
Since the protection tube 30 moved up and down along with the up and down of 18, it was necessary to have an allowance (same as the traverse length of the base material 18) above and below the container 12 for the protection tube 30. But this first
In the case of Figure 2a, this is not necessary. Therefore, the ceiling of the building can be lowered.

In this case, it is better to use the wire winder 28 to wind the wire 26 without using the traverser.

Further, as described above, the top split pipe 33 of the protection pipe 30 is a container.
Fixing against 12 facilitates the seal between them.

[Example] A part of the one used at the time of deposition was used as it is as the dummy rod base 21; it had a length of 200 mm, a diameter of 30 mm, a wire made of carbon fiber was used as the wire 26, and the lower end thereof was used as the dummy rod base 21. The base material 18 was hung through the small hole made.

The material of the protection tube 30 is glass, the inner diameter is 10 mmφ, and Viton rubber is used for the stopper 34. While flowing He from the seal gas inlet 36 at 1000 cc / min, the base material
Dehydration sintering was performed only by vertical movement without rotating 18.

Other conditions are the same as when suspending the base material with a conventional dummy rod, and the dehydration gas is Cl ₂ 100cc / mi.
n + He 10 l / min, the maximum heating temperature by the furnace 16 was 1650 ° C.

As a result, the same base material as in the conventional case was obtained in which the base material 18 was hung by the dummy rod 20 and dehydrated and sintered while rotating.

[Advantages of the Invention] (1) Since the wire 26 is surrounded by the protective tube 30 and the inert gas is allowed to flow in the protective tube 30, a material other than expensive platinum can be used as the wire, and a platinum wire can be used. Even when it is used, it is not easily deteriorated by the dehydration gas (it is not easily thinned), so that it can be used for a long period of time and the cost can be reduced.

(2) When the protection tube 30 is a telescope type consisting of a plurality of divided tubes, it is not necessary to provide a margin for moving the protection tube 30 up and down above the container 12 as described above. Only, the ceiling of the building can be lowered.

[Brief description of drawings]

 FIG. 1a is an illustration of an example of the present invention, FIG. 1b is an illustration of its operation, FIG. 2a is an illustration of another example of the present invention, FIG. 2b is an illustration of its operation, and FIG. The figure is an illustration of the prior art. 12: Container, 14: Gas inlet 16: Electric furnace, 18: Porous base material 20: Dummy rod, 22: Traverser 24: Rotating means, 26: Wire 28 Wire winder or traverser 30: Protective tube, 31, 32 , 33: Split pipe 34: Stopper, 36: Seal gas inlet

Claims (2)

[Scope of utility model registration request] 1. A porous preform 18 is suspended in a vessel 12 so that it can be moved up and down and heated in a dehydration gas atmosphere. The porous preform 18 is suspended in a dehydration sintering furnace for optical fiber preforms. Use wire 26 to
A dewatering and sintering furnace for optical fiber base material in which a gas that does not react with the wire 26 is flown into the protective tube 30 by surrounding the 26 with a protective tube 30. 2. The dehydration sintering furnace for optical fiber preform according to claim 1, wherein the protective tube 30 is a telescope type consisting of a plurality of divided tubes.