SU1755123A1 - Fiber-optics refractometer - Google Patents

Abstract

The invention relates to a measurement technique and can be applied to measure the refractive index of liquids, during chemical and biological research, and analyzes of fuel. The purpose of the invention is to increase the sensitivity and accuracy of determination. The sensitive element of the refractometer is made in the form of a transmitting and receiving surface-micro-diode fiber-optic elements, which are sections of optical fiber of the same length with reflecting ends, and the protective sheath is removed from the transmitting element and it is placed inside the receiving element, which is optical fiber, the end of which is equipped with a bottom. 1 tab., 1 Il.

Description

The invention relates to a measurement technique and can be applied to measure the refractive index of liquids during chemical and biological research, fuel analysis.

A refractometer is known, which contains a series-connected radiation source, a fiber-optic information transmission line, a measuring section, a radiation receiver, and a measuring section made in the form of a surface-irregular, curved fiber light guide.

The disadvantages of this refractometer are low sensitivity and accuracy, since With this refractometer, there is a narrow measuring range (1.3), 1.4, the difficulty of making a loop-shaped sensing element and a significant amount of liquid required for analysis, since the sensing element must be completely immersed in it.

Closest to the invention is a refractometer, which contains a radiation source, a fiber optic light guide, a transmitting element, a receiving element and a radiation receiver.

The receiving and transmitting elements are surface-micro-inhomogeneous segments of light guides of the same length, parallel to each other in the horizontal plane, directed towards each other and offset relative to each other by distance b a / tg, where is the aperture angle; a is the distance between them.

Refractometer works as follows

A drop of the test liquid is placed between the transmitting and receiving elements and spreads along the entire length of the elements. Light from a source through a fiber-optic light guide enters the transmitting element. Part of the world comes out

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through the end of the fiber, and the rest (flowing modes) passing through the test liquid, falls on the receiving element. At the same time, the amount of light caught on the receiving element depends on the refractive index of the liquid under study. The light from the receiving element through the fiber-optic light enters the radiation receiver, where the luminous flux power is recorded, which is a function of the refractive index of the liquid under study.

The disadvantages of this refractometer are low sensitivity and accuracy of refractive index determination. This is due to the fact that in this refractometer the analyzed fluid does not pass through the entire luminous flux formed by the modes flowing through the side surface of the bare transmitting element, but only that part which comes out of the transmitting element at the places of its contact with the liquid film. Or, in other words, no more than 5–7% of the luminous flux, formed by the modes flowing through the side surface of the bare transmitting element, takes part in the analysis of the fluid

The purpose of the invention is to increase the sensitivity and accuracy of determination.

The goal is achieved by the fact that, in a fiber-optic refractometer containing a successively located radiation source, a fiber-optic light guide with a sensing element made in the form of a transmitting and receiving surface-micronedodorbd sections of a fiber of the same length and a radiation receiver, the output end of the transmitting and the receiving end the elements are made reflective, while the transmitting element is placed inside the receiving element, made in the form of a tubular optical fiber.

The drawing shows a diagram of a fiber optic refractometer

The refractometer contains a radiation source 1, a fiber-optic light guide 2, a transmitting element 3, a receiving element 4, a radiation receiver 5. The ends of the 6 elements 3, 4 are made of light-reflecting. The transmitting element 3 is provided with a plug 7. The receiving element 4 is provided with a bottom 8.

Refractometer works as follows.

The microhang of the test liquid is placed inside the receiving element 4. Then a bare portion of the transmitting element 3 is placed inside the receiving element 4 and secured with a plug 7. Light from

the light source 1 through the fiber-optic light guide 2 enters the transmitting element 3. The light flowing out through the working surface of the transmitting element passes through the liquid under study to the receiving element 4. The amount of light that enters the receiving element 4 depends on refractive index of the test liquid. The light from the receiving element 4 through part 9 of the fiber-optic light guide enters the radiation receiver 5, where the light power is recorded, which is a function of the refractive index of the liquid under study.

Example. For the manufacture of the refractometer, a tubular fiber and an optical fiber with a core diameter of 600 µm were selected, the transmitting and receiving elements had a length of 30 mm, the distance between the fibers was 0.5 mm. A helium-neon laser was used as a radiation source in a laboratory model, and a wattmeter of absorbed power was used as a radiation detector. In the manufacture of active devices, it is recommended to use semiconductor lasers based on arsenide gels as a radiation source, and photodiodes as a radiation receiver.

To determine the index of refraction, a calibration graph was drawn up. To construct the graph, reference fluids were used, the characteristics of which are shown in the table.

This refractometer uses the phenomenon of partial disturbance of the total internal reflection at the border of the transmitting element (core of the optical fiber) - the environment. If the environment for the transmitting element is air with refractive indices of PV 1, then full internal reflection of light takes place on its side surface. When the side surface of the transmitting element (core of the optical fiber) touches the liquid, the conditions for total internal reflection change greatly: the sine of the limit the angle of incidence is increased by times, where is the refractive index of the fluid.

The luminous flux formed by the modes flowing out through the side surface of the transmitting element is transmitted to the receiving element depending on the refractive index of the liquid.

Claims (1)

Invention Formula A fiber refractometer containing a successively located radiation source, a fiber-optic ozotod with a sensitive element made in the form of a transmitting and receiving surface-micro-inhomogeneous sections of the optical fiber of the same length, and a radiation receiver, characterized in that. In order to increase the sensitivity and accuracy of the determination, the output end of the transmitting and input end of the receiving element is made reflective, while the transmitting element is placed inside the receiving element, made in the form of a tubular optical fiber, on. b 7 H // & oЈ / /