KR100420175B1 - Optical fiber preform and manufacturing method thereof - Google Patents

Abstract

The present invention relates to an optical fiber base material manufactured by a modified chemical vapor deposition method, and increases the thickness of the clad layer instead of eliminating the barrier layer between the existing core and the clad, thereby increasing the penetration distance of OH from the outside. OH is prevented from penetrating into the core layer from the outside, and by etching a region of a certain distance from the surface after fabrication of the optical fiber base material to remove the OH group diffused in the RIT and the cutting process in advance, 1340 ~ The loss of the 1460 nm wavelength band is reduced, so that the usable band can be expanded by 100 nm or more compared with the conventional optical fiber, and can be used at any wavelength in the 1280 to 1620 nm wavelength band.

Description

Optical fiber preform and manufacturing method

The present invention relates to an optical fiber base material and a method of manufacturing the same. More specifically, the present invention increases the thickness of the clad layer in the optical fiber base material produced by the modified chemical vapor deposition method, thereby increasing the penetration distance of OH from the outside. It prevents OH from penetrating into the core layer from the outside, and also by etching a certain distance from the surface after fabrication of the optical fiber base material to remove the OH group diffused in the RIT and edge process in advance, 1340 ~ The loss of the 1460nm wavelength band is reduced, so that the usable band can be expanded by more than 100nm compared to the conventional optical fiber, and it can be used in any wavelength in the 1280 to 1620nm wavelength band, so that the fiber base material for the optical fiber can be easily used in many applications. And to a method for producing the same.

Fiber preform (母 材: preform) is an intermediate material in the manufacture of optical fiber is formed in the same structure as the optical fiber and melted at a high temperature to draw the fiber (finished) is completed.

Therefore, the structure is formed in the shape of a double cylinder in which a portion called a cladding is wrapped around the core, which is usually the same as the optical fiber.

The optical fiber finished with the optical fiber base material is generally covered with a protective exposure on the outside to protect the inside. The total size excluding the protective coating has a diameter of about 125 μm (1 μm is 1/1000 mm), and the refractive index of the core portion is increased. Since it is higher than the refractive index of the cladding, light is focused on the core portion so that light can travel through total refrection inside the core.

The manufacturing method of the optical fiber base material is caused by the flame hydrolysis reaction on the inside (MCVD method) or the outside (OVD method (outside vapor phase deposition)) while rotating the appropriate mounting table (graphite, fraud rod or high purity quartz tube) in the axial direction. A silicon oxide layer synthesized with germanium, boron, phosphorus and the like is attached several times, and then gradually heated and condensed with a flame of a high temperature of 1700 ° C. or more to complete the base metal. At this time, by adjusting the concentration of elements such as germanium, it is possible to arbitrarily adjust the refractive index distribution of the base material, and the optical properties such as the loss of the optical fiber is almost determined in this process, so proceed very carefully. In addition, a vapor phase axial deposition (VAD) method is also used in which a base material is grown directly on the end of the quartz rod.

1 is a cross-sectional view of an optical fiber base material for explaining the structure of a conventional optical fiber base material, showing a primary base material of a general single mode optical fiber. As shown in FIG. 1, the optical fiber base material forms a core 1 at a central portion thereof, and a blocking layer 2, a cladding layer 3, and a one-tube 4 are sequentially formed on the outside thereof. In the figure, d represents the diameter of the core 1, and D represents the diameter of the cladding layer 3, respectively.

In particular, in the case of an optical fiber preform manufactured by Modified Chemical Vapor Deposition (MCVD) as shown in FIG. 1, an OH barrier layer is provided. It is essential to manufacture a large diameter base material that can be pulled out. In the case of a base material manufacturing process using the MCVD method, how large a core can be deposited is the key to manufacturing a large diameter base material. However, due to the tube condensation during the deposition process and the increase in the thickness of the tube, the vitrification of the core may cause a technical problem in which vitrification is not performed due to a lack of heat transfer to the core layer.

In addition, a single mode optical fiber is manufactured by depositing a cladding layer and a core. In the case of a MC-SM (Matched Cladding-Single Mode) type, the cladding layer is formed of SiO ₂ on P ₂ O ₅ and GeO ₂ to lower the deposition temperature and refractive index. Doped, F and the like, and the core layer for transmitting light is deposited by doping GeO ₂ to SiO ₂ in order to increase the refractive index, and then to produce an optical fiber base material through a condensation and closing process.

In the process of manufacturing the optical fiber base material by the modified chemical vapor deposition method, as the thickness of the deposition layer becomes thick, self-collapse of the tube occurs in the deposition process, and consequently, the tube thickness increases. do.

In addition, a high temperature burner is required to sinter and consolidate the deposited layer, which also increases the time for the collapse process. In addition, when the diameter ratio (D / d) of the cladding layer and the core is made small, the OH absorption loss increases rapidly. That is, moisture (H ₂ O) from the oxygen / hydrogen burner used as a heat source and a small amount of moisture (typically several ppm) contained in the deposition tube are diffused into the deposition layer. . Moisture penetrated combines with P ₂ O ₅ or SiO ₂ deposited in the cladding region to form POH or Si-OH bond bonds, and OH penetrated to the core region combines with SiO ₂ or GeO ₂ deposited in the core layer. Thus, Si-OH or Ge-OH bond bonds are formed while dissolving the Si-O or Ge-O bond bonds.

As described above, the Si-O-H or P-O-H bond bonds formed by bonding with moisture in each deposition region additionally generate an optical loss due to an absorption band in a specific wavelength region. In the case of single-mode optical fiber, the wavelength range that greatly affects the optical loss is 1.24um and 1.385um bands for Si-O-H bonds and long wavelength bands for P-O-H bonds. In addition, OH penetrating into the core region forms non-bridging oxygen (NBO), thereby locally lowering the structural homogeneity of the glass in the core layer, resulting in a density heterogeneity of the core layer. This results in density fluctuations, resulting in increased scattering losses.

In addition, as the deposition layer becomes thicker, the inner and outer diameter of the tube shrinks in the vitrification process simultaneously with the deposition process, thereby making it difficult to obtain an appropriate diameter ratio (that is, the cladding diameter / core diameter = D / d). Not enough distance can be secured to prevent diffusion, resulting in a significant increase in losses by OH.

That is, there is no method of dehydration of water that causes OH loss in the manufactured optical fiber as a method of manufacturing a single mode optical fiber base material using a modified chemical vapor deposition (MCVD) method. In particular, as shown in Fig. 4, the conventional optical fiber A has an absorption peak due to OH groups in the vicinity of the wavelength of 1390 nm, and therefore, it is impossible to use it as a transmission optical fiber due to the large absorption peak of the OH groups in the vicinity of the wavelength of 1340 to 1460 nm.

Therefore, transmission is currently performed only in the wavelength range of 1290 to 1325 nm and 1530 to 1560 nm, and the concentration of OH ions is concentrated at 1390 nm at 1340 to 1460 nm, so the loss is very high at about 1 dB / km. There was a problem such as limited use.

The present invention has been made to solve the above problems, the present invention is that the loss of 1340 ~ 1460nm wavelength band is formed lower than the 1310nm wavelength band commonly used in current optical transmission system to expand the available band compared to the conventional optical fiber It is an object of the present invention to provide a method for producing a low-loss single-mode optical fiber base material which can be used in any wavelength in the wavelength range of 1280 to 1620 nm, thereby reducing losses and making it easy to use a wide range of low cost optical fibers.

1 is a cross-sectional view of an optical fiber base material for explaining the configuration of a conventional optical fiber base material.

2 is a cross-sectional view of an optical fiber base material for explaining the optical fiber base material structure according to the present invention.

3 is a graph of the distribution of O. H of the primary preform according to the present invention.

4 is a graph of loss data measured after the primary preform is etched with a radius of 250 microns.

-Explanation of symbols for the main parts of the drawings-

11: core 13: cladding layer

14: one tube d: core diameter

D: Clad Outer Diameter

In the optical fiber base material of the present invention for realizing the above object, in the optical fiber base material which forms the core, the cladding layer, and the one tube in the form of multiple cylinders, the outer diameter of the cladding layer to prevent OH from penetrating into the core. (D) and the diameter (d) of the core is formed so that the D / d value is 2.0 or more.

The cladding layer is formed in multiple layers. The clad layer is characterized in that it contains POCl ₃ .

In the method for manufacturing an optical fiber base material by sequentially depositing a clad layer and a one tube on a core, the cladding layer is laminated in multiple layers, and the outer cladding layer is characterized in that it is deposited while increasing the amount of POCl ₃ .

Deposition up to one tube, characterized in that the surface is etched more than 500 microns in the first preform after a collapsing process.

The etching process is characterized in that performed with an etching solution mixed with hydrofluoric acid and nitric acid.

Hereinafter, exemplary embodiments of the present invention will be described with reference to the accompanying drawings. In addition, this embodiment is not intended to limit the scope of the present invention, but is presented by way of example only.

FIG. 2 is a cross-sectional view of an optical fiber base material for explaining the configuration of an optical fiber base material according to the present invention, illustrating a primary preform state of a single mode optical fiber. FIG. That is, in the optical fiber base material according to the present invention, the core 11 is formed at the center and the cladding layer 13 and the one-tube 14 are sequentially stacked on the outside thereof. In the figure, d represents the diameter of the core 11, and D represents the diameter of the cladding layer 13, respectively.

However, in order to prevent OH from penetrating and diffusing into the core 11, the D / d value of the outer diameter D of the cladding layer 13 and the diameter d of the core 11 is formed to be 2.0 or more. .

In general, P ₂ O ₅ is used to deposit the cladding layer 13. Since P ₂ O ₅ has a relatively low melting point of about 570 ° C., it is lowered in process temperature by using it with other raw materials. This has the advantage of increasing the deposition efficiency. Thus, P ₂ O ₅ is used to deposit the cladding layer 13, but on the other hand, P ₂ O ₅ doped in the cladding layer 13 has a large hygroscopic property, which is included in the original tube 14. It is to play the role of OH-bridge to deliver OH to the core layer (11). Therefore, since the loss caused by OH in the core layer 1 is increased, in the present invention, the existing deposition step is formed of a clad, core layer instead of the existing cladding layer, barrier layer, and core. In particular, the ratio of the cladding layer to the core (D / d) of 2.0 or more is due to the increase in the distance of the OH due to moisture contained in the chemical into the core layer 11, which is an optical waveguide region during the process. This is to prevent penetration into the core.

In addition, the cladding layer 13 is formed as a multilayer to block OH penetration through the cladding layer 13 as much as possible, and the cladding layer 13 preferably contains POCl ₃ .

Figure 3 is a graph of the O.H concentration distribution of the primary preform according to the present invention. Figure 3 is a graph showing the OH concentration distribution of the primary preform produced by the present invention, it can be seen that the OH concentration is reduced by the slope of the log function from the surface after the production of the primary preform. It was also found that the distribution of OH was concentrated on the outside rather than on the inside.

Therefore, in the method for manufacturing an optical fiber base material by sequentially depositing a clad layer and a one-tube on a core, the cladding layer 13 is laminated in multiple layers, while the outer cladding layer 13 increases the amount of POCl ₃ . Deposit.

When the inner cladding layer 13 contains a minimum amount of POCl ₃ , and the outer cladding layer 13 is deposited while increasing the amount of POCl ₃ , it is possible to effectively improve the deposition efficiency while minimizing the penetration of OH.

In addition, the surface is deposited up to a single tube, and the surface is etched to a radius of more than 250 microns in the first preform state undergoing a collapsing process. At this time, the etching is more preferably 500 micro or more. As shown in FIG. 3, since OH is concentrated at a diffusion distance of about 250 micrometers, most of the OH can be removed by etching about 250 micrometers from the surface.

However, etching at least 500 microns at this time is more preferably applicable to actual products.

In Figure 4 A graph is a characteristic graph of the optical fiber produced by the conventional chemical vapor deposition method, B graph is a characteristic graph of the optical fiber manufactured by the present invention.

A loss data graph measuring optical characteristics of an optical fiber prepared by etching the optical fiber base material of the present invention described above with 250 micrometers, as shown in the drawing, below 0.35 dB / km at 1310 nm, and below 0.21 dB / km at 1550 nm, At 1385nm, which is the peak of OH group, it is very good at 0.31dB / km or less, and especially at 1385nm, the loss reduction effect is about twice that of the optical fiber manufactured by the conventional method.

In other words, even if the D / d increases in the optical fiber base material, the penetration distance of the OH group becomes relatively short again when the fiber is drawn into the optical fiber, but in most MCVD processes, the secondary tube is RIT after the first preform is manufactured. If the primary preform is etched at some distance from the surface, most of the OH concentration will be lost as shown in Figure 3, which can have a significant effect on reducing the amount of loss caused by the OH group when measuring the optical characteristics of the optical fiber after edge cutting. It is.

The etching process is preferably performed with an etching solution mixed with hydrofluoric acid and nitric acid.

As described above, the present invention is formed such that the D / d value of the outer diameter D of the cladding layer 13 of the optical fiber base material and the diameter d of the core 11 is 2.0 or more, and the surface is etched at least 500 microns. Therefore, in the deposition process, the internal OH-blocking layer containing no POCl ₃ is not deposited between the cladding layer and the core layer, and the etching of the outside of the optical fiber base material is performed to the core generated in the subsequent secondary tubing process and the cutting process. There is an advantage that can effectively block the OH diffusion.

In addition, the optical fiber manufactured by the present invention has a loss of 1340 ~ 1460nm wavelength band is less than 0.31dB / km lower than the 1310nm wavelength band commonly used in current optical transmission system, which is 1280 ~ It can be used in any wavelength in the 1620nm wavelength range has the advantage of providing a base material for low-loss single-mode fiber that can be applied in many fields.

Claims (6)

delete In the optical fiber base material which forms the core, the cladding layer, and the one-tube in multiple cylinder form, The D / d value of the outer diameter (D) of the cladding layer and the diameter (d) of the core is formed to be 2.0 or more, wherein the cladding layer is formed in multiple layers. The optical fiber base material according to claim 2, wherein the clad layer contains POCl ₃ . In the optical fiber base material manufacturing method of sequentially depositing a cladding layer and a one tube on the core, The cladding layer is laminated in a multi-layer, the outer cladding layer is an optical fiber base material manufacturing method characterized in that the deposition while increasing the amount of POCl ₃ . The optical fiber base material manufacturing method according to claim 4, wherein the surface of the tube is deposited and the surface is etched with a radius of 250 micrometers or more in a state of collapsing. The method of claim 5, wherein the etching process is performed with an etching solution in which hydrofluoric acid and nitric acid are mixed.