UA123646C2 - HYDROGEN SULFUR SULFUR FIBER OPTICAL SENSOR - Google Patents

Abstract

The present invention relates to the control of the occurrence and concentration of hydrogen sulfide in the life support systems of autonomous military modules, control of the gaseous environment in hazardous operating conditions on ships and submarines. The claimed fiber-optic sensor of hydrogen sulfide contains a base of quartz glass, which contains a light guide with a reflective layer at the end, connected to a splitter. The fiber-optic sensor further comprises a fiber-optic sensing element, a bimetallic plate and a reflectometer. The reflectometer is connected to a splitter. The fiber optic sensing element is a set of pre-centered, welded rings made of crown and heavy flint, which are fixed to the base, and on the outside - with part of the fiber, which is made in the form of a coil around the fiber optic sensing element. The bimetallic plate is placed on the second part of the optical fiber, between the splitter and the coil, and is connected via a splitter to the reflectometer. The invention is to compensate for the influence of destabilizing factors on the measuring channel of the hydrogen sulfide sensor, the possibility of creating an extensive network of gas control in special conditions, improving the quality of operation through the use of materials with similar coefficient of thermal propagation and choosing a rational modulation scheme.

Description

The invention belongs to fiber-optic sensors of hydrogen sulfide, which are based on the control of the optical properties of optical fibers. The field of application is control of the appearance and concentration of hydrogen sulfide in the life support systems of autonomous military modules.

To control the gas environment in dangerous operating conditions on ships and submarines |1, 21.

A known optical sensor of hydrogen sulfide, which consists of a semiconductor porous sensitive element, an emitting LED, and a temperature sensor; microcontroller and liquid crystal indicator |Ж).

Disadvantages of the device, which are due to the use of a porous semiconductor sensitive element: - insufficient stability of the characteristics (electrical, sorption, optical) of the semiconductor layer during multiple work cycles "gas exposure - degassing" due to changes in the structure; - the need for the device to be powered; - availability of an additional temperature sensor; - strong dependence of measurement accuracy on the state of pollution of the air mixture; - the need for regular cleaning of the semiconductor porous sensitive element.

The closest in terms of technical essence and the result achieved to the proposed invention is a fiber optic gas analysis sensor consisting of a base, a reflective layer, a main light guide, sensitive light guides, a multiplexer/demultiplexer and a splitter |41.

Disadvantages of the device, which are due to the use of sensitive optical fibers located coaxially to the main optical fiber and welded to the base: - the design of the device is a static structure without the possibility of modification; - there is no thermal compensation for fluctuations in the temperature of the external environment and the controlled gas mixture; - the need to process the main and sensitive optical fibers with extremely high quality to avoid creating conditions for the appearance of parasitic modulation; - the need for a complex support system for the geometry of the tunnel optical channel

From the connection of the main and sensitive optical fibers.

The goal of the invention is to create a fiber-optic sensor of hydrogen sulfide, which does not require an electric power supply, has increased protection of elements, does not depend on the state of the external environment and the controlled gas mixture, and at the same time maintains a high level of sensitivity and speed of devices of known types.

The problem is solved by the fact that a fiber-optic sensor of hydrogen sulfide, containing a base made of quartz glass, which contains a light guide with a reflective layer at the end, is connected to a splitter, which is characterized by the fact that it additionally contains a fiber-optic sensitive element, a bimetallic plate and a reflectometer , while the reflectometer is connected to the splitter, the fiber-optic sensitive element is a set of pre-centered, welded rings made of crown and heavy flint, which are fixed on the base, and on the outside - with a part of the light guide, which is made in the form of a coil around the fiber-optic sensitive element, and the second part of the light guide, between the splitter and the coil, contains a bimetallic plate and is connected through the splitter to the reflectometer.

The technical effect is achieved due to the fact that the combination of optical elements provides: - more adequate localization of the appearance of hydrogen sulfide and the transformation of parameters of the gas environment into changes in the information signal; - compensation of the influence of destabilizing factors on the measuring channel of the hydrogen sulfide sensor; - the possibility of creating an extensive network of gas environment control in special conditions; - improvement of the quality of operation due to the use of materials with a close coefficient of thermal propagation and the selection of a rational modulation scheme of reference radiation; - fire and explosion safety during use

The essence of the invention is explained by the drawing, which shows: a quartz glass base 1, in which a sensitive element is fixed, which is a set of rings 2, made of crown and heavy flint. The rings during installation in the base are subject to centering and then welding. The sensitive element from the outside is connected to a part of the light guide in the form of a coil 3. The light guide in the form of a coil has a reflecting layer 4 at one end. The second part of the light guide between the splitter 6 and the coil contains a bimetallic plate 5 connected to the light guide, which has a preliminary bend. Laser radiation comes from the reflectometer 7, which is both a source and receiver of radiation, to the coil through a splitter.

The radiation reflected from the reflecting layer enters in the reverse direction through the splitter to the reflectometer.

The refractive index range of crown and heavy flint is closest to the refractive index range of hydrogen sulfide. Together, the light guide in the form of a coil, the rings of crown and heavy flint, and the gas medium on the inside of the rings form a three-layer optical waveguide.

When hydrogen sulfide rings appear on the inside of the light guide in the form of a coil, the conditions for full internal reflection of light are violated, which occurs as a response to the tunnel pumping of radiation from the light guide to the outside. The refractive indices of the rings are selected in such a way as to ensure the maximum pumping of optical radiation from the optical fiber to the outside when in contact with hydrogen sulfide in three modes: the appearance of hydrogen sulfide in a "trace" concentration; the appearance of "anxiety" in concentration; appearance in concentration "accident".

Violation of the conditions of complete reflection of light in the light guide in the form of a coil is reflected in the change in the intensity of the radiation reflected from the reflective layer. The radiation is returned through the splitter to the reflectometer, where the information signal |5, 61 is processed.

List of drawing figures.

Fig.1. Fiber-optic hydrogen sulfide sensor: 1 - base; 2 - fiber-optic sensitive element - rings made of crown and heavy flint; C - light guide in the form of a coil; 4 - reflective layer; 5 - bimetallic plate; 6 - splitter; 7 - reflectometer.

Information that confirms the possibility of implementing the invention.

For the implementation of the invention, a combination of rings made of crown and heavy flint, a fiber optic guide and a reflectometer was used.

In the static mode (calibration mode), i.e. in the absence of a gas medium other than atmospheric air, the radiation source of the reflectometer generates

From the radiation that enters the optical fiber in the form of a coil through the splitter. In the light guide in the form of a coil, which is optically connected to the rings, there is a decrease in the intensity of optical radiation passing through it, which is caused by attenuation in the light guide material under the influence of operational factors. The intensity of the radiation returning to the reflectometer is recorded and stored as a correction.

In the dynamic mode (immersion in a controlled gaseous medium), when the gaseous medium enters from the inner side of the sensitive element - crown rings and heavy flint, optical radiation is pumped from the light guide in the form of a coil to the outside, that is, an optical tunnel effect occurs. After that, the radiation, changed in intensity, is reflected from the reflective layer and enters the reflectometer through the corresponding branch of the splitter. In the reflectometer, there is a constant step-by-step control of the radiation intensity coming from all the rings.

The intensity of the registered particle of light will be proportional to the value of the measured parameter of the gas medium, and the distance recorded by the reflectometer will indicate the corresponding ring, that is, the value of the concentration of hydrogen sulfide, which for each concentration will have the corresponding refractive index.

The bimetallic plate is used to create a preliminary bending of the light guide in the area between the light guide in the form of a coil and the splitter. The created bend initiates an additional leakage of radiation outside the optical fiber. As the temperature of the controlled environment increases, the curvature of the plate and previously created losses change. In this way, the information signal is automatically adjusted according to the temperature effect.

Further processing of the radiation will allow obtaining an electrical signal that will be proportional to the concentration of the controlled gas medium.

Sources of information: 1. Ash, Zh. Sensors of measuring systems: in 2 books. Book 2. Trans. from French - M.: Mir, 1992. - 424 p. 2. Udd, Z. Fiber-optic sensors. - M: Technosfera, 2008. - 520 p.

Z. Devices for monitoring hydrogen sulfide in the air based on a sensor with a heterojunction of the p-saA5/p-SiPs type. Electronic resource. Access mode: pOru/Llymlu. ideazapatopeu.gy/Rri/Oyeiai5/297667.

4. Declaration patent of Ukraine Mo 78611, IPC (2011) СО1М 11/02 (2006.1). Fiber-optic gas analyzer/Applicants and patent holders: Sandler, A.K., Tsyupko, Yu.M. - Application 18.09.2012. /Published 25.03.2013, Bull.

Mo 6. 5. Snyder, A., Love, D.

Theory of optical waveguides. - M.: Radio and communication, 1987. - 656 p. 6. Busuryn, V.Y., Nosov, Y.R.

Fiber-optic sensors: physical basis!, question! calculation and application. - M.: Znergoatomizdat, 1990. - 256 p.

Claims (1)

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