RU1778516C - Joint of optical deformation meter - Google Patents

Abstract

The invention relates to devices for measuring the deformation of solids and can be used in seismology, construction, surveying, and in testing materials. The aim of the invention is to improve the accuracy of measuring deformations, predominantly low frequency (quasistatic). A base with a monochromatic radiation source installed on it, a beam splitter located along the light beam, mirrors forming the working reference arm of the interferometer, a collimator, a diaphragm, a photodetector and a measuring system connected to it are rigidly connected to a moving platform with balanced masses, separated from the base a gap filled with a damping medium, and the platform support point is located above its center of gravity. The axis of the light source is oriented parallel or perpendicular to the plane of the platform to which the plane mirror of the monochromatic radiation source is rigidly connected, and the rod supporting the movable platform is vertically movable on the base relative to the base, and the outer wall of the gap between the base and the movable platform is thermostated. 1 ill. with C

Description

The invention relates to the field of devices for measuring the deformation of solids and can be used in seismology, construction, surveying.

A laser interferometer for measuring strain is known, comprising a beam splitter, two mirrors, one of which is connected to the base, and the other directly to the object, and a measurement system.

A disadvantage of the known device is that the interference pattern is sensitive to both quasi-static and dynamic deformations. The latter lead to smearing of interference fringes and to a decrease in the accuracy of determination of quasistatic deformations.

A known laser strain gauge containing a beam splitter, mirrors that create the reference and working arms of the interferometer, a modulator and a measuring system,

The known device measures the frequency of radiation in the information beam when reflected from a mirror,

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associated with the test object. In this case, diffraction by an ultrasonic wave of a known frequency is carried out in the modulator, as a result of which a combined frequency is determined using a measuring system, which is determined by the frequency of the ultrasonic wave with the oscillation frequency of the body under study.

In the IPL-ZOK1 instrument of the Novosibirsk Instrument-Making Plant, implemented on the basis of this copyright certificate, when using ultrasound with a frequency of 4.3 MHz, the lower limit of the frequency of the measured displacements is 10 Hz. Measurement of oscillations of a lower frequency leads to a decrease in the accuracy of the data obtained.

Closest to the proposed device is a laser interferometer for measuring deformations, containing a base, a monochromatic radiation source mounted on it, a beam splitter located along the light beam, mirrors that form the working and reference arms of the interferometer, a collimator, a diaphragm, a photodetector and connected to it measuring system. An interferometer is characterized by the presence of a connecting node of an optical strain gauge with an object in the form of axially spring-loaded rods mounted on a base and connecting movable mirrors to the object.

A known device is intended for measuring deformations such as hedgehog waves (tensile waves). When measuring deformations of the bending type, especially slow (quasistatic), this device has low accuracy. This is due to the fact that in the manufacture of the connecting node of the optical strain gauge with the object in the form of axially spring-loaded rods in contact with the object from opposite sides, their

the motion, and hence the motion of the moving mirrors, is synchronous, and when moving does not change the total travel difference in the arms of the interferometer. When using a communication device of a static strain gauge with an object in the form

a single spring-loaded rod mounted on the base and connecting the object to the moving mirror of the optical strain gauge, the interference pattern is sensitive to both quasistatic and dynamic strains, which leads to a decrease in the accuracy of determination of quasistatic strains.

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The aim of the invention is to improve the accuracy of measuring low-frequency quasistatic strains.

The goal is achieved in that the connecting node of the optical strain gauge with the object, containing the base with a conical rod mounted on it, is equipped with a platform with balancer masses, one surface of which is designed to mount the mirror of the meter, and the opposite is made with a conical recess, the platform is mounted on the rod is axisymmetric in such a way that the center of gravity of the platform is located below its fulcrum and is connected to the base through a damping medium placed in a a read only basis thermostated recess, which accommodates the stem tapered portion.

Placing the pivot point of the movable platform above its center of gravity allows the upper plane of said platform to maintain a horizontal position when the angular position of the base changes. The supply of the movable platform with balancer masses also contributes to the stable maintenance of the horizontal position of the upper plane of the movable platform. The presence of a gap filled with a damping medium makes it possible to separate the vibrations in which the optical strain gauge is involved into fast and slow (with respect to the characteristic time constant of the optical strain gauge). In this case, slow deformations that change the angular position of the base of the meter affect the relative position of the mirrors in the working arm of the interferometer and lead to a shift in the fringes of the interference pattern, which makes it possible to determine the magnitude of the deformations. Rapid deformations do not affect the position of the moving mirror of the working arm of the interferometer and are smoothed out.

The device’s operation is based on the well-known property in viscoelastic media that, at small characteristic times of the action of a disturbing force, they deform like elastic bodies, and at large, like liquids. For example, for the Maxwell model adopted in theory of viscoelasticity, the behavior in the viscoelastic body is described by complex module

Y- (lu) Yi -H Y2,

where Y1 V.E E2 + y / Y

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w is the frequency of the current disturbance;

/ - viscosity of the medium;

E is the modulus of elasticity.

YI is similar to Young's modulus for solids, and Y2 is the viscosity coefficient for liquids. The behavior of the medium is determined by the ratio of the elastic modulus E to the viscosity coefficient t, which determines the frequency od characteristic of the given medium. At w / (Oo 1, the medium exhibits elastic properties, and at w / oo 1 - viscous, which confirms the above.

Thus, the gap filled with the appropriate material in the device serves as a filter, which allows one to separate the mechanical vibrations coming to the device into low and high frequency ones.

Thus, the combination of the aforementioned features makes it possible to increase the accuracy of measuring quasistatic type strains by eliminating the interference friction due to the elimination of the influence of vibrational vibrations on the movement of the moving platform relative to the base, and therefore, the interferometer’s working arm rigidly connected to the moving platform relative to motionless.

Thermostabilization allows avoiding changes in the viscoelastic characteristics of the medium filling the gap with fluctuations in the ambient temperature, which also contributes to the achievement of the set goal.

The drawing shows a diagram of a connecting node of an optical strain gauge with an object.

The connecting node of the optical strain gauge with an object consists of a base 1 with a conical rod 2, on which an axisymmetric platform 3 with balancing masses 4 is mounted. One surface of the platform 3 serves to mount a mirror 5, which is an element of the optical strain gauge, and the opposite is made with a conical deepening. The platform 3 is mounted on the rod 2 axisymmetrically so that the center of gravity of the platform 3 is located below its fulcrum on the rod 2. The base 1 is made with a recess 6, in which the platform 3 is installed with a gap. The recess 6 is filled with a damping medium 7 and is equipped with a thermostatic device 8. On the base 1 there are also elements of an optical strain gauge: a radiation source 9, a fixed mirror 10. a beam splitter 11, a diaphragm 12, a radiation receiver 13 connected to a recorder 14.

The connecting node of the optical strain gauge with the object works

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The assembly is set up with the base on the horizontal surface of the object. Platform 3, by means of the balancing masses A, is set in an equilibrium manner.

5 In this case, the mirror of the meter 5 provides the starting point of the optical strain gauge. Deformations of the object cause changes in the angular position of the base 1, and hence

0 the change in the angular position of the platform 3 relative to the base 1. The strain value is judged from the resulting shift in the interference pattern. High-frequency oscillations are transmitted from the base 1 to the platform 3 through the damping medium 7 and the mirror 5 mounted on the platform 3, oscillates synchronously with the mirror of the reference arm 10 and such vibrations are compensated in the overall interference pattern. When exposed to the base 1 oscillations of the low frequency of the platform 3, damped by a layer of medium 7, due to the location of the center of gravity of the platform 3

from below the suspension point it occupies a horizontal position under the action of gravity and, therefore, changes its position relative to the base 1. Thermostatic device 8 serves to preserve

Q in the viscoelastic properties of the damping medium 7. It also allows, by changing the temperature, to reconstruct the coupling unit without changing the substance filling the gap. Example. The assembly of the proposed design, in which a OKG-11 helium-neon laser with a vertical optical axis and a flat mirror is placed on a movable platform, was used as a source of monochromatic radiation, and 30x30x250, supported by creep, was measured to measure the creep the ends, while the gap between the movable platform and the base was 0.5 mm and filled with grade 200 bitumen. The ambient temperature was 20 ° C. The base of the device had three points of support. Two supports were mounted on a horizontal slab, and a third in the middle of the prismatic silt sample0

that one. Then, a constant weight load of 40 kg was applied to the middle of the sample. Under the action of a static load, as a result of creep of the rock sample, an increase in the arrow of its deflection occurred.

For comparison, a similar measurement was carried out using a prototype interferometer with two mirrors mounted on opposite sides of the sample. Such a device did not allow measuring the beam deformation due to the low accuracy of the device, since when fixing the deformations of the bending type, the mirrors move synchronously. Using a laser interferometer according to the prototype with one movable mirror to measure the creep of a rock sample in the same way as in the example, is impossible due to complete smearing of the interference pattern due to the action of the vibrating background.

Thus, the node of the proposed design allows in comparison with the prototype to increase the accuracy of the measurement of quasistatic deformations.

The technical effectiveness of the proposed solution, as follows from the above

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This is due to the possibility of measuring quasistatic deformations of the bending type up to creep with characteristic times of 10 s.

From the foregoing it follows the confirmation of the operability of the proposed device and the attainability of the goal.

Claims (1)

The claims The connecting node of the optical strain gauge with the object, containing a base with a conical rod mounted on it, characterized in that, in order to improve the measurement accuracy of low-frequency quasistatic strains, it is equipped with a platform with balancing masses, one surface of which is intended for mounting the measuring mirror on it, and the opposite is made with a conical recess; the platform is mounted on the rod axisymmetrically so that the center of gravity of the platform is located below its fulcrum and is associated with Warping through a damping medium, placed in a thermostated formed in the base of the recess, which accommodates the conical portion of the rod. // Yu