RU195098U1 - Fiber optic strain gauge - Google Patents

Abstract

The utility model relates to measuring technique and can be used in sensors of physical quantities. The fiber-optic strain transducer contains an elastic element made in the form of a plate of monocrystalline material and an optical fiber fixed with Bragg fiber gratings is fixed on it. The plate is made in a T-shape, in the form of a central beam and base, and is fixed cantilever. The optical fiber with Bragg fiber gratings is fixed to the plate so that the Bragg fiber gratings are located symmetrically on both sides of the central beam and are fixed between the central beam and the edge of the base. The technical result is the expansion of the arsenal of technical means for the spectral transformation of strains. 1 ill.

Description

The utility model relates to measuring technique, namely to elements of sensors of physical quantities.

A known differential pressure sensor with a sensing element in the form of a fiber-optic transducer beam type. The strain-sensitive element is a plate (beam) on which Bragg fiber gratings can be fixed on both sides, as a result of which differential measurement can be implemented. Patent of the Russian Federation for utility model No. 127461, IPC G01L 9/12, 04/27/2013.

Deformations of the plate in this device are transmitted to fiber gratings mounted on its surfaces. Moreover, the scope of this technical solution is limited due to the lack of the ability to accurately adjust (adjust) the magnitude of the strains of the fiber, since this strain is determined structurally and is comparable with the deformations of the plate of the sensing element. In addition, plastic deformations of the plate can occur in this device, leading to a deterioration in the accuracy of the spectral conversion parameters, which also imposes restrictions on the use of this technical solution.

A known pressure sensor containing an elastic element is a membrane, in the sensitive areas of which Bragg fiber gratings are fixed. This device implements a differential measurement scheme in order to solve the problem of thermal compensation: the fiber gratings are fixed on the membrane in deformation-sensitive areas of the membrane in such a way that under the influence of deformations, the membrane surface experiences strain-tension in one zone and compression-strain in the other . When processing a spectral signal from two Bragg fiber gratings, a difference signal is analyzed. The device allows you to adjust the strain area of the Bragg fiber gratings when they are fixed on the surface of a metal membrane. Patent of the Russian Federation for utility model No. 130073, IPC G01L 11/00, July 10, 2013.

As in the previous case, this technical solution has a limitation in use: the plastic deformations of the metal membrane, as well as the thermal expansion of the metal elastic elements do not allow the use of such a device under the influence of harsh external factors.

Known fiber optic strain transducer containing a Bragg fiber lattice mounted on an elastic element in the form of a single crystal plate. The device allows to eliminate the phenomenon of irreversible plastic deformations of the elastic element and to use this technical solution in the whole class of converters of physical quantities operating under the influence of severe external factors. In this strain transducer, several Bragg fiber gratings symmetrically located relative to the elastic element can be used to implement the differential measurement principle. Patent of the Russian Federation for utility model No. 135119, IPC G01D 5/353, 11.27.2013. This technical solution was made as a prototype.

The prototype lacks structural elements that allow you to set the required value of the working deformation of the fiber gratings at certain deformations of the elastic element. As in the previously discussed device, the deformation of the fiber gratings in the prototype is predetermined structurally and is comparable with the deformation of the plate. This circumstance narrows the scope of this technical solution, since the possibility of adjusting the working area of deformations of Bragg fiber gratings in the process of fixing them on the elastic elements of the transducers is in great demand.

The objective of the utility model is to create a structurally simple fiber-optic strain transducer for devices with high accuracy parameters due to the absence of plastic deformations in the material of the elastic element, which implements the differential measurement.

The technical result is the expansion of the arsenal of technical means for the spectral transformation of strains.

The technical result is achieved by the fact that the fiber-optic strain transducer contains an elastic element made in the form of a plate of single-crystal material, and an optical fiber fixed to it with Bragg fiber gratings, the plate is made in a T-shape in the form of a central beam and base and is fixed cantilever, an optical fiber with Bragg fiber gratings is fixed to the plate so that the Bragg fiber gratings are located symmetrically on both sides of the central beam and and are fixed between the central beam and the edge of the base.

The essence of the utility model is illustrated in the drawing, where:

1 - the base of the elastic element;

2 - supporting element;

3 - optical fiber with Bragg fiber gratings;

4 - the central beam of the elastic element;

5 - adhesive material;

G1, G2 - Bragg fiber gratings.

The fiber-optic strain transducer comprises an elastic element in the form of a T-shaped plate made of single crystal material (e.g., silicon), consisting of two parts: a base 1 fixed in a support element 2, which is generally a part of the transducer supporting structure, and the central beam 4, deformed by external forces (P1 and P2), for fixing optical fiber 3 with Bragg gratings G1 and G2 on it so that the Bragg fiber gratings are located are symmetrically on both sides of the central beam 4 and each are fixed between the central beam 4 and the edge of the base 1. In this case, the fastening points of the optical fiber 3, indicated in the drawing in the form of round zones of adhesive material 5, are located on both sides of each Bragg fiber grating - the edges of the base 1 and on the Central beam 4.

The elastic element of the strain spectral transducer is made of single-crystal material due to the fact that the use of such substrates increases the accuracy of the conversion due to the absence of plastic deformations in the structure of the single-crystal material. As a fixing adhesive material 5 can be used, for example, adhesive brand K300.

Fiber optic strain transducer operates as follows.

The action of external forces P1 and P2 applied to the central beam of the elastic element causes displacements of the central beam 4 relative to the base 1. Transformable deformation caused by external forces P1 and P2 is applied to the central beam of the elastic element 4, while the base of the elastic element 1 in the area of its fastening in the supporting element 2 is not subject to deformation.

Bragg fiber gratings located symmetrically on both sides of the central beam 4 and each secured between the central beam 4 and the edge of the base 1 undergo deformations, and tensile strains of the Bragg fiber grating G1 located on one side of the central beam are simultaneously accompanied by compression strains of the Bragg G2 fiber grating located on its other side than the differential measurement is implemented. Deformations of Bragg fiber gratings, accompanied by changes in their internal structure, change the spectral properties of the radiation transmitted through the optical fiber.

Thanks to the use of an elastic element in the form of a T-shaped plate, it is possible to set the required value of the working deformation of the Bragg fiber gratings G1 and G2 at certain deformations of the elastic element, choosing the indentation of the level of fixation of the optical fiber 3 from the support element 2, since the amplitude of the displacements of the central beam 4 is different for levels of this indentation, various on height. This is calculated depending on the required in each case, the range of deformations of the applied Bragg fiber gratings and the design features of the device as a whole.

Claims (1)

A fiber-optic strain transducer containing an elastic element made in the form of a plate of single-crystal material and an optical fiber fixed to it with Bragg fiber gratings, characterized in that the plate is T-shaped in the form of a central beam and base and is fixed cantilever, with this optical fiber with Bragg fiber gratings is fixed to the plate so that the Bragg fiber gratings are located symmetrically on both sides of the Central beam and fixed enes between the central beam and the edge of the base.

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