RU2677092C1 - Quartz glass based light emitting optical fiber - Google Patents

Abstract

FIELD: optics.SUBSTANCE: invention relates to the fiber optics, in particular, to the extended light-emitting optical fibers manufacturing technology. Silica glass based light emitting optical fiber comprises core with located inside it scattering centers and reflecting sheath, as well as the light-scattering polymer outer layer, which is in direct contact with the reflective sheath and configured to intercept the scattered light coming out of the core at low angles, in which glassy materials are made from highly pure materials by the chemical vapor deposition modified method. At that, the core is doped with germanium dioxide in the amount of not less than 10 mol. %, the polymer outer layer has a PP larger than that of the glass of the reflecting sheath, and has causing the light scattering optical heterogeneity, and the core scattering (α) optical losses coefficient increases along the fiber BC (x) length in accordance with the formula,where αis the scattering coefficient value on the BC initial segment.EFFECT: increase in the light emitting optical fibers illumination intensity and uniformity, as well as increase in their length to hundreds of meters in order to use them as extended light indicators.1 cl, 1 dwg

Description

The invention relates to fiber optics, in particular, to the technology of manufacturing extended light-emitting fiber optical fibers (hereinafter - VS) for fireproof and electrically isolated indication of the contours of objects located in a dark space. These include underground and underwater mines, as well as tunnels, corridors, stairs, planes, ships and other objects.

There are analogues of the claimed technical solution for the construction of light-emitting aircraft (patent applications US 2011122646 (A1) and WO 2014121172 (A2)) containing a silica glass core, a shell and a plurality of scattering centers located inside the core or at the boundary between the shell and the core.

The disadvantage of these aircraft is the increased level of optical loss due to scattering (from 50 to 6000 dB / km), high luminous intensity and short length not exceeding several meters. Therefore, such aircraft can only serve as small-sized light sources. For extended, hundreds of meters long, light emitting pointers, aircraft design data is not acceptable.

The aforementioned disadvantages are not possessed by aircraft manufactured in accordance with patent application WO2004023181 (A1). This patent is taken as a prototype of the claimed invention, as the technical essence is the closest to the claimed technical solution.

In contrast to the aforementioned analogues containing a core and a reflective shell based on quartz glass, as well as scattering centers located inside the core, in the prototype aircraft are made with an additional external light-scattering polymer layer,

in direct contact with the shell and with the ability to intercept the scattered light emerging from the core at small angles.

Due to the small-angle scattering of radiation from the core, the glow intensity of such SCs is much weaker than that of analogs, but it is sufficient for visual observation of a luminous extended (over 100 meters long) fiber in a dark space.

Solved by the invention, technical problems, including the disadvantages of the prototype, are as follows:

- the intensity of the glow along the length of the fiber decreases, which in accordance with the Bouguer-Lambert-Beer law is due to the exponential nature of the attenuation of the power of the radiation passing through the fiber at a constant value of the optical loss coefficient;

- the length of the aircraft is limited due to the increased level of light absorption by the core, a high level of purity of which is difficult to ensure when foreign particles of light scattering are introduced into it.

Achievable technical result - ensuring uniformity and increasing the intensity of the glow throughout the entire length of the aircraft. This is achieved by fabricating the SC from highly pure glassy materials with optical losses for radiation absorption much smaller than its scattering, and increasing the coefficient of optical losses for scattering radiation along the length of the SC without introducing foreign scattering particles.

The problem is solved in a new design of a light-emitting aircraft, containing a core based on quartz glass, with scattering centers located inside it, and a reflecting shell, as well as a light-scattering polymer outer layer in direct contact with the reflecting shell and made with the possibility of intercepting scattered light emerging from the core at small angles. In contrast to the prototype, the glassy materials of the aircraft were made by a modified chemical vapor deposition method (hereinafter - MCVD) from highly pure materials [Dukel'skii, KV MCVD technology for single-mode low-damping fiber lightguides stable against microbends / KV Dukel'skii, MA Eronyan , AV Komarov, Yu.N. Kondrat'ev, LG Levit, EI Romashova, MM Serkov, AV Khokhlov, VS Shevandin // Journal of Optical Technology. - 2002. - Vol. 69. - Issue 11. - pp. 849], while the core is doped with germanium dioxide (hereinafter - GeO ₂ ) in an amount of not less than 10 mol. %, the polymer outer layer has a refractive index (hereinafter - PP) greater than that of the glass of the reflective shell and has optical heterogeneity, and the coefficient of optical loss of the core due to scattering (α) increases along the length of the aircraft (x) in accordance with the formula confirmed by experimental research:

where α ₀ is the value of the scattering coefficient in the initial segment of the aircraft.

The fabrication of quartz aircraft by the MCVD method solves two problems:

1. The high purity of the materials almost completely eliminates the optical loss of radiation due to the absorption of light compared with the optical loss due to its scattering, thereby increasing the intensity of the glow of the fiber.

2. With an increase in the drawing temperature of the germanosilicate BC, the optical loss coefficient for small-angle scattering increases, which ensures uniform emission of the AC, despite the decrease in the power of radiation propagated through the AC (Fig. 1).

In FIG. Figure 1 shows the calculated dependences of the change in the luminous intensity of the fiber W (x) (curves 1, 2) and the radiation power P (x) (curves 3, 4) passing along the aircraft, on its length (x): dashed lines (2 and 3) for aircraft extended at a constant temperature (α = α ₀ = const); solid lines (1 and 4) for the aircraft, elongated when the temperature changes [α = α ₀ / (1-x * α ₀ )], where α _{0 is} taken equal to 0.0023 m ^-1 .

The outer polymer layer of the fiber, consisting, for example, of an epoxy acrylate composition cured by ultraviolet radiation, also solves two problems aimed at increasing the intensity of the glow of the fiber:

1. Increased compared with the reflective shell of the PP polymer layer ensures the interception of light coming out of the core.

2. The structure of such a polymer is characterized by optical inhomogeneities with a size exceeding the wavelength of the radiation propagated through the BC. It is such inhomogeneities that are the scattering centers that determine the light-emitting properties of the fiber.

The invention is implemented as follows:

Example No. 1.

Billet for drawing aircraft made by MCVD method. The glassy layers of the shell and core were deposited inside an F-300 quartz glass tube with an outer diameter of 22 mm, a wall thickness of 2 mm and a length of 1 m. The radial profile of the PP in the workpiece with an outer diameter of 12.2 mm was measured on a R-101 refractometer . The reflective shell contains about 1.5 mol. % phosphorus oxide and small fluorine additives to obtain PP close to that of quartz glass support tube. Doping of the GeO ₂ core provides an increase in PP by 0.013 compared with the reflective shell, which corresponds to a GeO ₂ content in the core of about 10 mol. %

500 m of aircraft with a diameter of 125 μm with an epoxy acrylate coating with a thickness of about 50 μm cured by ultraviolet radiation is drawn from the preform. The highest mode cutoff wavelength for the aircraft is ≈1.3 μm. In the spectral region of visible radiation, such VSs are low-mode.

To achieve a constant glow intensity along the length of the fiber (x), the optical scattering loss coefficient [α = α ₀ / (1-x * α ₀ )] is changed, increasing the drawing temperature from 2025 to 2200 ° C in accordance with the formula:

,

,

where A and B are coefficients depending on the content of GeO ₂ in the core,

t ₀ is the temperature of fiber drawing, which does not lead to excessive optical losses due to scattering (≈1900 ° С).

Based on special experimental data for an aircraft doped with 10 mol. % Germanium dioxide determined coefficients A and B, equal, respectively, 1,61⋅10 ^-3 m ^-1 and 4,605⋅10 ^-8 m ^{-1 -2} deg. In the initial section of a 500-meter aircraft, α ₀ is equal to 0.0023 m ^-1 , which corresponds to attenuation of 10 dB / km.

A VFL650 optical fiber defect locator with a power of P ₀ = 10 mW is used as a light emitter with a wavelength of 650 nm. Such an aircraft, wound on a coil with a diameter of 160 mm, glows uniformly over a length of 400 meters. The intensity of the glow of the aircraft, equal to 23 μW / m, is sufficient for visual observation in the absence of extraneous light sources. In areas with a removed polymer layer, the aircraft does not glow.

Example No. 2.

The preparation of the light-emitting aircraft is made by analogy with example No. 1, in contrast to which the aircraft is pulled with increasing temperature from 1900 to 2100 ° C.

With the introduction of radiation similar to Example No. 1 to a 500-meter-long aircraft, wound on a coil with a diameter of 160 mm, a uniform glow is observed along the entire length of the aircraft, but the radiation intensity is weaker than in the first example. In the initial portion of the aircraft, the optical loss coefficient is 0.0016 m ^-1 , which corresponds to attenuation of 7 dB / km.

Example No. 3.

The preparation of the light-emitting aircraft was made by analogy with examples No. 1 and No. 2, in contrast to which the aircraft were drawn at a constant temperature of 2025 ° C.

By analogy with the above examples, when radiation was introduced into the aircraft 500 meters long, wound on a coil with a diameter of 160 mm, radiation was observed in the initial section no more than 100 meters long and had a damped character, which confirms the necessity of drawing the aircraft with increasing temperature in accordance with examples No. 1 and No. 2.

The experimental results described in examples No. 1 and No. 2 confirm the obvious industrial applicability of the design of the light-emitting aircraft claimed in the invention, determining the prospect of their use as extended light indicators.

Claims (3)

A quartz glass-based light-emitting optical fiber (hereinafter referred to as BC) containing a core with scattering centers located inside it and a reflecting cladding, as well as a light-scattering polymer outer layer in direct contact with the reflecting cladding and made with the possibility of intercepting the scattered light emerging from the core at small angles, characterized in that the glassy materials of the aircraft are used, made by a special method of chemical vapor deposition from highly pure at the same time, the core is doped with germanium dioxide in an amount of at least 10 mol.%, the polymer outer layer has a refractive index greater than that of the glass of the reflecting shell, and has an optical inhomogeneity that causes light scattering, and the coefficient of optical loss of the core by scattering (α ) increases along the length of the aircraft (x) in accordance with the formula

, where α ₀ is the value of the scattering coefficient in the initial segment of the aircraft.

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