RU2756461C1 - Method for tensioning bragg fiber grating to given value of relative elongation - Google Patents

Abstract

FIELD: measuring technology.

SUBSTANCE: invention relates to measuring technology, namely to the study and creation of sensitive elements of spectral sensors and transducers of physical quantities. On the elastic element in the form of a beam, made of a material with a positive value of the temperature coefficient of expansion, an additional structural element is fixed - a temperature-sensitive element made of a material with a negative value of the temperature coefficient of expansion. The assembly is heated to a predetermined temperature. The Bragg fiber grating is fixed to a thermosensitive element made of a material with a negative temperature coefficient of expansion using an anchoring material. The assembly is cooled. By means of temperature elongation of the temperature sensitive element during its cooling, the Bragg fiber grating is stretched to a predetermined value of the relative elongation.

EFFECT: expanding the arsenal of methods for tensioning the Bragg fiber grating to a given value of the relative elongation.

1 cl, 1 dwg

Description

The invention relates to measuring technology, namely to the study and creation of sensitive elements of spectral sensors and transducers of physical quantities.

From the description of the device of the spectral strain transducer (see RU 149551, IPC G01D 5/353, 01/10/2015), a method for creating a Bragg sensitive element on an elastic plate in the form of a beam is known.

It is known that deformations of the Bragg grating, accompanied by a change in its internal structure, change the spectral properties of the radiation transmitted through it. The error introduced by the thermal expansion of the materials of the sensitive element in the described device is eliminated by using an additional sensitive element formed in the photosensitive layer inside the elastic plate. However, in the case of using a four-layer silicon-quartz component with a photosensitive medium as an elastic plate, the creation of the specified beam-type Bragg transducer requires complex technological operations.

For most of the known transducers of mechanical quantities (force, flow rate of liquid media, pressure, displacement, deformation), beam elastic elements are a widespread technical solution. Fiber Bragg gratings are fixed on elastic beams and their deformations caused by the effect of the measured physical quantity are controlled. To use specific fiber Bragg gratings (depending on the purpose), it is necessary to carry out preliminary studies of their mechanical or spectral properties. For this, the Bragg fiber lattice is fixed on a beam elastic element with a certain predetermined value of the initial tension, expressed in the value of the relative fiber elongation. This fiber tension leads to a shift of the Bragg peak of the fiber grating to the spectral region with a linear sensitivity characteristic. The fiber pre-tensioning process is very laborious and in most cases does not allow for repeatability.

From the description of the device of the fiber-optic strain transducer (see, RU 135119, IPC G01D 5/353, 11/27/2013), a method for creating a Bragg sensitive element on an elastic single crystal plate made in the form of a beam is known. This technical solution can be used to study the properties of Bragg fiber gratings, but does not contain solutions for fiber pretensioning.

There is a known method of compensating for temperature deformations in Bragg transducers of the beam type, in the implementation of which additional temperature-sensitive elements are used, on which an optical fiber with a fiber Bragg grating is fixed. Patent of the Russian Federation for the invention RU 2717170, IPC G01D 5/353, G12B 7/00, G01D 3/028, 03/18/2020. This technical solution was adopted as a prototype.

Compensation of thermal deformations in the described method is carried out through the use of two additional structural elements - temperature-sensitive elements made of a material, the value of the temperature expansion coefficient of which is greater than the value of the thermal expansion coefficient of the elastic element material for fixing an optical fiber with a fiber Bragg grating on these structural elements. This method uses the principle of changing the length of the fiber due to the physical properties of the material of structural elements. The method is simple to implement to provide temperature compensation for the elongation of the sensitive element during its use, but it does not allow solving the problem of fiber pretension (see, RU 2589447, IPC G01B 11/16, G01D 5/353, 10.07.2016).

The objective of the invention is to develop a method for tensioning a Bragg fiber lattice to a predetermined relative elongation, based on the use of a special intermediate structural element on an elastic plate, which is of practical interest in studying the properties of Bragg fiber lattices and does not require complex production technology.

The technical result is to expand the arsenal of methods for tensioning the Bragg fiber lattice to a given value of the relative elongation.

The technical result is achieved by the fact that in the method of tensioning the Bragg fiber lattice to a given value of the relative elongation on an elastic element in the form of a beam, made of a material with a positive value of the temperature coefficient of expansion, an additional structural element is fixed - a temperature-sensitive element made of a material with a negative value of the temperature coefficient expansion, to fix the optical fiber with a fiber Bragg grating on this structural element, the assembly is heated to a predetermined temperature, the fiber Bragg grating is fixed on the thermosensitive element using a fixing material, the assembly is cooled, by means of the temperature elongation of the thermosensitive element when it cools down, the Bragg fiber grating is stretched to a given value of the relative elongation.

The essence of the invention is illustrated by a drawing, which schematically shows an elastic element 1 in the form of a beam, made of a material with a positive value of the temperature coefficient of expansion, with an additional structural element attached to it - a thermosensitive element 3, on which an optical fiber 2 with a fiber is fixed by means of an anchorage material 4 the Bragg lattice (G). The thermosensitive element 3 is made of a material with a negative value of the temperature coefficient of expansion (TCR), which makes it possible to use the ratio of the temperature elongations of the materials to realize the tension of the Bragg fiber lattice to a given value of the relative elongation.

The length of the strain-strain region of the optical fiber is denoted L ₀ . This area is limited by the fiber attachment points on structural element 3.

The method is implemented as follows.

On the elastic element 1 in the form of a beam, made of a material with a positive value of the temperature coefficient of expansion, an additional structural element is fixed - a temperature-sensitive element 3, made of a material with a negative value of the temperature coefficient of expansion, with the possibility of fixing on it an optical fiber 2 with a fiber Bragg grating, an assembly is heated to a predetermined temperature, the Bragg fiber lattice is fixed on the thermosensitive element 3 with the help of the fixing material 4. The assembly is cooled. By means of the temperature elongation of the temperature sensitive element 3 during its cooling, the Bragg fiber lattice is stretched to a predetermined value of the relative elongation.

As anchoring material 4, for example, K300 glue can be used.

As materials with positive and negative TCR can be used, for example, polymer and composite materials.

The thermosensitive element 3 can have a strictly defined length, which is necessary in each specific case (including taking into account the temperature heating of the assembly) to ensure the required value of the relative elongation of the Bragg fiber lattice. This length, as well as the places for fixing the optical fiber, are selected empirically, based on the design tasks set.

Due to the attachment of an additional structural element to the elastic element - a thermosensitive element made of a material with a negative value of the temperature coefficient of expansion, for its subsequent heating, fixation of an optical fiber with a fiber Bragg grating on it, the tension of the Bragg fiber grating to a given value of the relative elongation is realized. Thus, the physical properties and design parameters of an additional structural element, a temperature-sensitive element, determine the magnitude of the relative elongation of the Bragg fiber lattice. This solution allows you to automate the process of creating assemblies and achieve repeatability of fiber tension parameters in serial production.

The elastic element 1 and the additional structural element 3 can be made in the form of rectangular plates, and also contain structural cutouts that determine the necessary form of deformation distribution on their surface for the implementation of the proposed technical solution in a wide area of research on Bragg fiber gratings.

Claims (1)

The method of tensioning a Bragg fiber lattice to a predetermined value of the relative elongation, according to which an optical fiber with a fiber Bragg lattice is fixed on an elastic element in the form of a beam, made of a material with a positive value of the temperature coefficient of expansion, characterized in that an additional structural element - a thermosensitive element made of a material with a negative value of the temperature coefficient of expansion, for fixing an optical fiber with a fiber Bragg grating on this structural element, the assembly is heated to a predetermined temperature, the Bragg fiber grating is fixed on the thermosensitive element using a fixing material, the assembly is cooled by temperature elongation of the thermosensitive element when it cools down, the Bragg fiber lattice is stretched to a predetermined relative elongation.

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