RU2836129C1 - Fibre-optic device for detecting displacement - Google Patents

Abstract

FIELD: measuring.

SUBSTANCE: invention relates to measurement equipment, namely to displacement sensors, and can be used to register displacement. Fibre-optic device for detecting displacement has a housing made from a movable part and a fixed part with the possibility of being connected to a radiation source and receiver. Between the movable and fixed parts there is an elastic element made in the form of one or more springs. Optical fibre is attached to the movable and fixed parts, wherein the movable element is made with possibility of displacement leading to deformations in the recording part of the optical fibre and changes in transmitted and reflected radiation. Recording part of the optical fibre is made in the form of one or more loops with the possibility of controlled macrobending to change radiation.

EFFECT: possibility of continuous registration of displacement of the controlled object, expanding the arsenal of technical means of registering displacement, simplifying the optical scheme of the device, avoiding the need to adjust the operating point before operating the device, as well as the possibility of transmitting measurement information to a remote terminal directly without additional processing.

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Description

The invention relates to measuring equipment, namely to displacement sensors, and can be used to record displacement.

A patent for a composite structure with an integrated measuring system is known (RU Patent 2641638, G02B 6/02295, 18.01.2018). The composite structure contains a composite material and an optical fiber placed in this composite material. The optical fiber contains a plurality of quantum dots to enhance its nonlinear optical properties. The quantum dots can be placed in the core, in the cladding and/or on the surface of the optical fiber. The optical fiber is designed to transmit signals and is made sensitive to a defect in the composite material. The quantum dots create a nonlinear effect, such as a second-order effect, in response to the presence of a defect in the composite material. Based on the registration and analysis of signals having a nonlinear effect created by the quantum dots, a defect in the composite material can be detected.

The disadvantage of the known device is the use of the measuring system exclusively in conjunction with a composite material.

A seismic trigger is also known (RU patent 2003117763, G01V 1/16, G01V 1/38, 20.12.2004). The seismic trigger is a sealed case with a seismic oscillation receiver attached to its lower part, and a pendulum with distributed mass to its upper part, as well as an optoelectronic sensor of a preset limit value of pendulum deflection, including an optically matched source of coherent light and a photodetector connected by the output through a series-connected photocurrent amplifier and frequency meter to an alarm signaling device.

The disadvantage of the known device is the use of additional sensors and an amplifier in the installation.

The closest device for the same purpose to the claimed device in terms of a combination of features is a differential pressure sensor (RU Patent 2527135, G01L 11/02, 27.08.2014) comprising a housing, a force diaphragm located in the housing, a strain transfer element secured in the center of the force diaphragm, a measuring diaphragm, the plane of which is located at an angle to the plane of the force diaphragm and is offset relative to the central part of the force diaphragm, wherein the center of the measuring diaphragm is connected to the strain transfer element, and a transducer with a sensitive element, the housing is made of two component parts, between which a force diaphragm is installed, forming two chambers in the housing, the articulated walls of the housing are made with recesses, forming support surfaces for the force diaphragm, a measuring diaphragm is installed in each component part of the housing, the centers of the measuring diaphragms are connected by strain transfer elements to the center of the force diaphragm from its opposite sides, the transducers are made in the form of an optical fiber secured to the surface of each measuring diaphragm, and The sensitive elements are made in the form of fiber Bragg gratings fixed in the sensitive zones of the measuring membranes. In the zone of the measuring membrane that is not susceptible to deformation, a temperature-compensating fiber Bragg grating is located. This device is taken as a prototype.

The prototype features that coincide with the essential features of the claimed invention are a housing made of movable and fixed parts, with the ability to connect to a radiation source and receiver; an elastic element is located between the movable and fixed parts; an optical fiber is attached to the movable and fixed parts; the movable element is designed with the ability to shift, leading to deformations in the recording part of the optical fiber and changes in the transmitted and reflected radiation,

The disadvantage of the known device, adopted as a prototype, is the use of Bragg gratings, as well as several membranes with different functions, complicating the design of the registration system.

The task, which the declared technical solution is aimed at solving, is the development of a new fiber-optic device for recording displacement, which has a simple registration system in design, expanding the arsenal of technical means for recording displacement.

The stated problem was solved due to the fact that in the known fiber-optic device for recording displacement, containing a housing made of movable and fixed parts, with the possibility of connection to a source and receiver of radiation, between the movable and fixed parts there is an elastic element, an optical fiber is attached to the movable and fixed parts, the movable element is made with the possibility of displacement leading to deformations in the recording part of the optical fiber and changes in the transmitted and reflected radiation, according to the invention the elastic element is made in the form of one or more springs, the recording part of the optical fiber is made in the form of one or more loops with the possibility of controlled macrobending to change the radiation.

The features of the claimed technical solution that distinguish it from the prototype are that the elastic element is made in the form of one or more springs; the recording part of the optical fiber is made in the form of one or more loops with the possibility of controlled macrobending to change the radiation.

The implementation of the elastic element in the form of one or more springs simplifies the registration system, allowing one to do without the force membrane, the element of deformation transmission.

The claimed design features amplitude signal registration, which significantly simplifies the measuring circuit; it is possible to use a non-coherent radiation source.

The implementation of the recording part of the optical fiber in the form of one or more loops with the possibility of controlled macrobending to change the radiation will allow continuous recording of the displacement of the controlled object, while there is no need to adjust the operating point before operating the device.

Fig. 1 shows a diagram of a fiber-optic displacement recording device.

Fig. 2 shows the design of the sensor, top view.

Fig. 3 shows the design of the sensor, bottom view.

Fig. 4 shows the change in the diameter of the bent fiber.

Fig. 5 shows the dependence of the output power on the fiber bending diameter. The dots indicate the obtained data, the solid line is the approximation of the graph.

Fig. 6 shows the dependence of the fiber bending diameter on the weight of the weights. In the experiment, the weights replaced the constant displacement. The dots indicate the obtained data, the dotted lines are approximations of the graph.

Fig. 7 shows the dependence of the output power on the bias. The fiber in the recording part (RF) was laid in 1, 2, 4 loops. The dots indicate the obtained data, the dashed lines are approximations of the graphs.

The fiber-optic displacement recording device (Fig. 2 - 3) comprises a housing 1 with optical sockets 2A, 2B, made of a movable part 3 and a fixed part 4, with the possibility of connection to a radiation source and receiver. An elastic element 5 is located between the movable 3 and fixed 4 parts. An optical fiber 6 is attached to the movable 3 and fixed 4 parts. The movable element 3 is designed with the possibility of displacement, leading to deformations in the recording part 7 of the optical fiber 6 and changes in the transmitted and reflected radiation. The elastic element 5 is designed in the form of one or more springs. The recording part 7 of the optical fiber 6 is designed in the form of one or more loops with the possibility of controlled macrobending to change the radiation.

The device works as follows.

In Fig. 1, radiation from the source (L) is directed to the recording part (RP) 7 via the bend-resistant fiber 6. The transition from the bend-resistant fiber 6 to the recording part (RP) 7 is carried out thanks to the optical socket 2A, and the signal is output from the recording part (RP) 7 with the help of the optical socket 2B. The recording part (RP) 7 is located in the housing 1 of the sensor. The fiber 6 is located on the fixed part 4, which prevents the fiber 6 from entering the area of the elastic element 5.

In Fig. 2-3, the fiber 6 inside the RF 7 forms two parts: the transport part and the actual recording part. In the transport part, radiation is fed to the recording part and removed from it. The recording part (RF) 7 is one or more loops of fiber, which are placed on the fixed 4 and movable 3 parts.

Due to the movable part 3, the displacement is transferred to the recording part (RP) 7 of the fiber 6. The elastic element 5 is made in the form of one or more springs, the springs perform two functions: the first is to return the movable part 4 to its original state after removing the load, the second is that they create known elastic forces that allow the impact on the measured object to be assessed.

The deformation of the measured object sets in motion the elastic element 5, which transmits the change to the movable part 3, and then to the recording part 7 with the optical fiber 6.

Fig. 4 shows the change in the diameter of the bent fiber, where the diameter d ₀ is the initial one, equal to 25 mm, and d ₁ changes depending on the displacement from 25 to 11 mm.

The radiation passing through the curved fiber leaves the light guide due to the violation of total internal reflection, therefore, the power losses increase. It passes through the recording part (RP) 7, spreads further along the optical fiber 6 and gets to the photodetector (PD). The signal from the photodetector (PD) is processed using specialized programs on the PC.

An experimental setup, the diagram of which is shown in Fig. 1, was implemented to measure the displacement. A Thorlabs SFL1550S laser with an operating wavelength of 1550 nm was used as a radiation source (L). The recording part (RP) was implemented from Corning SMF-28 Ultra optical fiber in the form of a 25 mm loop. The change in power loss under vibration was performed by a Thorlabs RM-200 photodetector.

The measurement results are shown in Figs. 5–7.

The obtained results show that the magnitude of power loss in the recording part depends on the magnitude of the offset.

The advantage of the proposed device is that it allows continuous registration of the displacement of the controlled object by a registration system of simple design. In addition, the arsenal of technical means for registering displacement is expanded, there is no need to adjust the operating point before operating the device, and it becomes possible to transmit measurement information to a remote terminal directly without additional processing.

Claims (1)

A fiber-optic displacement recording device comprising a housing installed with the possibility of connection to a radiation source and receiver, made of movable and fixed parts, between which an elastic element is located, an optical fiber is attached to the movable and fixed parts, wherein the movable element is made with the possibility of displacement, leading to deformations in the recording part of the optical fiber and changes in the transmitted and reflected radiation, characterized in that the elastic element is made in the form of one or more springs, the recording part of the optical fiber is made in the form of one or more loops with the possibility of controlled macrobending to change the radiation.