KR20000031179A - Preparation method of the preform for a low loss single mode optical fiber - Google Patents

Abstract

PURPOSE: A method for preparing the preform for a low loss single mode optical fiber is provided, to lower the loss in the range of 1340 to 1460 nm, thereby to broaden the usable wavelength range and to allow the optical fiber to be used in any range between 1280 and 1620 nm. CONSTITUTION: The preform for a low loss single mode optical fiber is prepared by forming a shoot accumulation for a core by flame hydrolyzing a glass source to accumulate a porous glass fine particle of the core and clad composition to a glass load; dehydrating the shoot accumulation for a core in a furnace under the atmosphere containing chlorine gas to remove an OH group; sintering the shoot accumulation to make it be transparent glassed; elongating the glassed shoot accumulation to make a glass rod for a core; flame hydrolyzing the outer portion of the glass rod to accumulate the shoot for a clad; dehydrating the shoot accumulation for a clad in a furnace under the atmosphere containing a chlorine gas to remove an OH group; and sintering the shoot accumulation.

Description

Manufacturing method of base material for low loss single mode fiber

The present invention relates to a method for producing a low-loss single-mode optical fiber base material, and in particular, when produced by a conventional manufacturing method, the OH group is completely processed by the OH group, the loss is generated near the 1385nm wavelength where a large absorption peak appears by the OH group A method for manufacturing a low-loss single-mode optical fiber base material that enables the use of a single-mode transmission optical fiber in the entire wavelength range including the wavelength range of 1340-1460 nm, which was considered to be inoperable due to high loss by making a low-loss single-mode base material. It is about.

In general, it is well known that an optical fiber has a cradle formed on the outer circumferential surface of a core so that a signal having an arbitrary wavelength can be stably transmitted far away while minimizing loss during transmission.

And conventionally, when manufacturing the base material of the glass material for the single mode by the VAD method (Vapor-axial Deposition Method), the glass rod prepared by preparing the porous glass fine particles having a core and clad composition by flame hydrolysis reaction of the glass material ( Sedimentation), and

The state deposited on the seed rod, which is the glass rod, is often referred to as a core suit stack.

A dewatering process of removing the OH group from the core soot deposit in the furnace containing Cl ₂ gas;

A process of transparent vitrification by sintering the core soot deposits from which the OH group is removed at an appropriate temperature;

Stretching the vitrified core soot deposits to a designed outer diameter to make a glass rod for cores,

Performing a hydrolysis reaction on the outer circumferential portion of the glass rod for cores to deposit a Silica suut (hereinafter referred to as clad suut);

The base material for the optical fiber was produced by the process of sintering the clad soot deposit.

However, the conventional single mode optical fiber base material manufacturing method as described above has a problem in that absorption loss due to OH group appears even though the manufactured optical fiber is sufficiently dehydrated.

In particular, as shown in (b) of the graph of FIG. 1, in the conventional optical fiber, the absorption peak due to OH group appears in the vicinity of 1385 nm wavelength. Therefore, the absorption peak due to the OH group in the vicinity of the wavelength of 1340 ~ 1460 nm can be used as a transmission optical fiber. It was impossible.

Therefore, transmission is currently performed only in the wavelength range of 1290 to 1325 nm and 1530 to 1560 nm, and OH ions are concentrated at 1385 nm in the 1340 to 1460 nm wavelength, so the loss is very high at about 1 dB / km, which is used as a wavelength band for transmitting signals. There were disadvantages such as limited use.

Accordingly, the present invention has a loss in the 1340-1460nm wavelength band is lower than the 1310nm wavelength band generally used in the current optical transmission system, it is possible to expand the usable band of more than 100nm compared to the conventional optical fiber and can be used in any wavelength in the 1280 ~ 1620nm wavelength band It is an object of the present invention to provide a method for manufacturing a low-loss single-mode optical fiber base material that makes it possible to use a simpler and lower cost optical fiber in a wide range in many applications.

In order to achieve the above object, the present invention provides a process for forming a core soot deposit by depositing porous glass fine particles having a core and a clad composition on a prepared glass rod by flame hydrolysis of a glass raw material;

Removing the OH group while dewatering the core soot deposit in a furnace containing Cl ₂ gas;

A process of transparent vitrification by sintering the core soot deposit from which the OH group has been removed at an appropriate temperature;

Stretching the vitrified core soot deposits to a designed outer diameter to make a glass rod for cores,

Performing a hydrolysis reaction on the outer circumferential portion of the glass rod for cores to deposit a Silica suut (hereinafter referred to as clad suut);

Removing the OH group while dehydrating the clad soot deposit in a furnace containing Cl ₂ gas;

By causing the base material to be produced by sintering the clad soot sediment in which the dehydration was performed, the loss in the 1340-1460 nm wavelength band was lower than the 1310 nm wavelength band generally used in current optical transmission systems. Therefore, it is possible to expand the usable band of more than 100nm compared to the conventional optical fiber and to be able to use at any wavelength of 1280 ~ 1620nm wavelength to make a simpler and lower cost optical fiber in a wide range in many applications.

1 illustrates a comparison of transmission loss spectra of optical fibers.

a is a transmission loss spectrum of the optical fiber manufactured by the embodiment of the present invention

b is the transmission loss spectrum of the optical fiber manufactured by the conventional method

2 is a flow chart showing a manufacturing process of the present invention.

3 is a schematic representation of a core soot deposit produced by the method of the present invention.

4 is a schematic view of a soot deposit for clad produced by the method of the present invention.

5 is a schematic view of a furnace used for dehydration and sintering of the present invention.

* Nomenclature for the main parts of the drawings

1 seed seed 2 core dragon suit deposit

3: burner 4: raw material and gas

5: core glass rod 6: clad suit pile

7 heater 8 Cl ₂ or SiCl ₄ gas

9: the core tube

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

2 shows a manufacturing process according to an embodiment of the present invention,

A first process of primary deposition in which the porous glass fine particles having a core and clad composition are deposited on the prepared glass rod while forming a soot deposit for the core by flame hydrolysis of the glass raw material,

A second step of removing the OH group while first dehydrating the core soot deposit in a furnace containing Cl ₂ gas;

A third process of firstly sintering the core soot deposits from which the OH groups have been removed and transparent vitrification at an appropriate temperature;

A fourth process of stretching the vitrified core suot deposits to a designed outer diameter to produce a glass rod for cores,

A fifth process of secondary deposition in which a flame hydrolysis reaction is again performed on the outer circumference of the glass rod for cores to deposit the clad suits;

A sixth process of removing the OH group by secondary dehydration of the clad soot deposit in a furnace containing Cl ₂ gas;

The base material is generated by a seventh process of secondary sintering of the clad soot deposit in which the dehydration is performed.

The base material for the optical fiber formed by the manufacturing process as described above is a raw material of Sicl ₄ + H ₂ O and Sicl ₄ + Gecl ₄ + H ₂ O at the bottom of the outer surface of the seed rod 1, which is a glass rod, as shown in FIG. 4) and the flame of the burner (3) is properly applied so that the core suot deposit (2) consisting of SiO ₂ GeO ₂ and clad SiO ₂ is formed on the outer surface of the seed rod (1). do.

He 10 while injecting the gas 8 of cl ₂ or Sicl ₄ into the core tube 9 equipped with the heater 7 on the outer surface of the core soot deposition body 2 shown in FIG. 5. _{~ 20ℓ / min, Cl 2 300} ~ 1200 performs the primary dehydration process for removing OH group from ㏄ / min, a temperature of 900 ~ 1400 ℃ to.

Primary sintering is performed to transparent vitrify the OH group-removed soot deposits 2 at a temperature of 1300 to 1900 ° C. and He 15 to 35 L / min.

The sintered compact of the core soot deposit 2 having a diameter of 70 mm is stretched to a diameter of 20 mm and a length of 500 mm using an acid / hydrogen flame to prepare a glass bar for core 5.

The glass rod 5 for cores prepared as described above is secondly deposited by appropriately applying the flames of the raw material 4 and the burner 3 of Sicl ₄ + H ₂ O at the bottom thereof, as shown in FIG. 4. To produce a clad soot deposit 6 made of SiO ₂ on the outer circumferential surface by a flame hydrolysis reaction.

Then, as shown in FIG. 5, the clad soot deposition body 6 is injected with a gas 8 of cl ₂ or Sicl ₄ of the core tube 9 having the heater 7 mounted on the outer surface thereof. The secondary dehydration process is carried out to remove OH groups under conditions of 10 to 20 L / min, Cl ₂ 300 to 1200 dl / min, and a temperature of 900 to 1400 ° C.

The clad soot deposit 6 and the core glass bar 5 in which the OH group was removed were sintered at a temperature of 1300 to 1900 ° C. to produce a base material of the optical fiber.

The loss characteristics of the optical fiber manufactured using the above base material are 0.32 dB / km at 1310 nm and 0.19 dB / km at 1550 nm, as shown in (a) in FIG. 1, 0.28 dB / km at 1385 nm, which is the peak of the OH group. In particular, the loss reduction effect of the optical fiber manufactured by the conventional method was about twice as high at 1385 nm.

On the other hand, according to the conventional manufacturing process of the base material, two reasons can be considered as the cause of the residual OH group despite the complete dewatering of the core soot deposits.

First, when the transparent vitrified core suot deposits are drawn to an outer diameter designed using an acid / hydrogen flame, water (H ₂ O) generated by the oxyhydrogen flame may be sucked into the core glass rod.

Secondly, when the raw material for flame cladding is produced by flame hydrolysis reaction of glass raw material on the outer circumference of the core glass rod, the moisture contained in the silica deposit is increased in the high temperature sintering process. It is thought that this is because the reaction is generated into the rad interface to generate the OH group bonded to the glass structure.

Therefore, as in the case of core soot sediment, the clad soot sediment is dehydrated in a high temperature furnace, which is a Cl ₂ gas atmosphere, and the water sucked into the core glass rod and the soot sediment is removed by the following equation. It was made.

2Si-OH + Cl ₂ → 2SiO + 2HCl

Therefore, according to the method for producing a low-loss single-mode optical fiber base material of the present invention, the porous glass fine particles having a core and clad composition are deposited on the prepared glass rod while forming a flameout hydrolysis reaction of glass material to form a core suot deposit. And dehydrating the core soot deposit in a furnace containing Cl ₂ gas to remove the OH group, and sintering the core soot deposit from which the OH group is removed at an appropriate temperature to transparent vitrify. Process and stretching the vitrified core soot deposited body to the designed outer diameter to make a core glass rod, and performing hydrohydrolysis reaction on the outer circumference of the core glass rod again to deposit the clad soot. And dehydrating the clad soot deposits in a furnace containing Cl ₂ gas and removing OH groups. The loss of 1340-1460 nm wavelength band is lower than that of the 1310 nm wavelength band normally used in current optical transmission system by allowing the substrate to be produced by sintering and sintering the dewatered clad soot deposit. Compared to the optical fiber, the available band of 100 nm or more can be expanded and any wavelength in the 1280 to 1620 nm wavelength can be used to make a simpler and lower cost optical fiber available in a wide range in many applications.

Claims (2)

A first process of primary deposition in which the porous glass fine particles having a core and clad composition are deposited on the prepared glass rod while forming a soot deposit for the core by flame hydrolysis of the glass raw material, A second step of removing the OH group while first dehydrating the core soot deposit in a furnace containing Cl ₂ gas; A third process of firstly sintering the core soot deposits from which the OH groups have been removed and transparent vitrification at an appropriate temperature; A fourth process of stretching the vitrified core suot deposits to a designed outer diameter to produce a glass rod for cores, A fifth process of secondary deposition in which a flame hydrolysis reaction is again performed on the outer circumference of the glass rod for cores to deposit the clad suits; A sixth process of removing the OH group by secondary dehydration of the clad soot deposit in a furnace containing Cl ₂ gas; A method of manufacturing a base material for low-loss single-mode optical fiber, characterized in that the base material is produced by a seventh process of secondary sintering the clad soot deposits subjected to the dehydration. The method of claim 1, wherein the secondary dehydration is performed by using a clad soot deposit (6) containing Cl ₂ or SiCl ₄ containing He in a core tube (9) having a heater (7) mounted on an outer surface thereof. Method for producing a low-loss single-mode optical fiber base material to remove the OH group in the gas atmosphere conditions in which the gas (8) is injected.