RU2298814C1 - Deformation meter - Google Patents

Abstract

FIELD: geodetic instrument engineering.

SUBSTANCE: deformation meter can be used for measuring deformation of surface of the Earth. Deformation meter has bed, rod, which rod has one end tightly connected with bed by means of split bushing, and the other of rod is connected with technological pin by means of collet clamp. Technological pin is mounted onto rod in axial of magnetostrictive pin. Solenoid is reeled upon the pin. Deformation meter also has rhombus-shaped fixing member, which has cone-shaped pinches at corners. Magnetostrictive pin is tightly fixed in corners of fixing member along its shorter diagonal and it has one end connected with technological pin. The other end of magnetostrictive pin is connected with elastic equal-sized parallelogram shift amplifier, which has cone-shaped pinches at corners. Pinches are connected by pins in one corner along shorter diagonal by differential photosensitive elements. At the opposite corner it is fastened by metal screen having rectangular opening in center and with light-emitting diode, disposed in perpendicular to screen. Planes of photosensitive element and of screen are parallel to plane of shift amplifier. Photosensitive element and light-emitting diode are disposed in symmetry to opening in screen at different sides of screen. Registrar is connected to photosensitive element. Movable part of adjusting unit has cone-shaped recess and it is connected with one angle of shift amplifier by means of cone-shaped rod along longer diagonal. Motionless part of device is connected with reversible engine provided with reduction box.

EFFECT: improved precision of measurement.

1 dwg

Description

The invention relates to the field of geophysical instrumentation and can be used to measure deformations of the earth's surface when searching for precursors and predicting earthquakes, studying the internal structure of the Earth, detecting artificial disturbances of the earth's surface, determining the spatial position of oil and gas deposits, as well as in the design, construction and operation of large hydraulic structures, nuclear power plants and other large industrial facilities.

A well-known deformograph comprising a quartz tube 26 m long, one end of which is fixed on the rock, the other is free, and its displacement relative to the rock is detected galvanometrically using an inductive sensor (see Tidal deformations of the Earth. Proceedings of the Institute of Physics of the Academy of Sciences of the USSR. "Science", 1975. S. 97-103).

The disadvantage of this deformograph is the low measurement accuracy due to the dependence of its readings on atmospheric pressure variations. In addition, the suspension points of such a long pipe can be sources of interference in the readings of the deformograph, and a decrease in the length of the pipe will make it unsuitable for recording geophysical phenomena, since the deformograph’s sensitivity to rock displacements depends on the length of the pipe — with a small pipe length, its sensitivity is small.

The closest in technical essence to the proposed one is a deformograph comprising a bed, a rod, one end of which is rigidly connected to the bed by means of a split sleeve, and the other by a collet clamp with a technological rod, an elastic equilateral parallelogram displacement amplifier with conical clamps in its corners and with fixed help the rods in one of its corners on a small diagonal with a differential photocell, and in the opposite corner with a metal screen with a rectangular hole in the center and LEDs an iodine located perpendicular to the screen, a dovetail regulating device, the movable part of which is connected via a conical rod to one of the angles of the bias amplifier on a large diagonal, and the stationary part is connected to a reversing motor with a gearbox, a recorder connected to a photocell and an engine power supply and LED. The planes of the photocell and the screen are parallel to the plane of the bias amplifier. The LED and photocell are located symmetrically to the hole on the screen on opposite sides of it (see Seismic Instruments. Proceedings of the IPE RAS, issue 28, 1997. P.15-20; DD Churabo. Details and components of devices. M: Mashgiz , 1952. S. 98-101).

The disadvantage of this deformograph is the low measurement accuracy, because the deformograph recording scale is determined using a micrometer screw that biases the dovetail type moving part of the device, which does not provide high accuracy for determining the deformograph recording scale. The presence of the operator to determine the recording scale violates the temperature surrounding the deformograph, which also affects the accuracy of determining the recording scale.

The present invention solves the problem of increasing the efficiency of the deformograph. The technical result is to increase the accuracy of measurements due to the remote determination of the recording scale of the deformograph.

The technical result is achieved in a deformograph comprising a bed, a rod, one end of which is rigidly connected to the bed by means of a split sleeve, and the other by a collet clamp with a technological rod, an elastic equilateral parallelogram bias amplifier with conical clamps in its corners and with rods fixed in one from its corners on a small diagonal by a differential photocell, and in the opposite corner - a metal screen with a rectangular hole in the center and an LED located perpend perpendicular to the screen, while the planes of the photocell and the screen are parallel to the planes of the bias amplifier, and the LED and the photocell are located symmetrically to the hole on the screen on opposite sides of it, a regulating device, the movable part of which is connected via a conical rod to one of the corners of the bias amplifier along its large diagonal, and the fixed part - with a reversible motor with a gearbox, a recorder connected to the photocell, a magnetostrictive rod mounted coaxially to the rod with a solenoid wound on it m, connected to the power supply, and an elastic diamond-shaped fixing device with conical clamps in its corners, while the magnetostrictive rod is rigidly fixed in the corners of the fixing device along its small diagonal, which is connected along the same diagonal with one end to the technological rod and the other with a bias amplifier, power supplies are connected to the circuit of the reversing motor and LED.

Distinctive features of the proposed deformograph are a magnetostrictive rod mounted coaxially to the rod with a solenoid wound on it connected to a power supply unit, an elastic diamond-shaped locking device with conical clamps in its corners, rigid fastening of the magnetostrictive rod in the corners of the fixing device along its small diagonal and connection with the technological rod and bias amplifier. This allows you to increase the accuracy of measurement, the quality of registration of deformation processes, because when an electric current is supplied to the solenoid circuit, the alignment of the rod and the magnetostrictive rod is maintained, which prevents the azimuthal rotation of the bias amplifier and allows you to set different linear deformations of the magnetostrictive rod and work on different measurement ranges.

The deformograph is illustrated in the drawing, which shows a general view of the deformograph.

The deformograph consists of a frame 1, a rod 2, one end of which is rigidly connected to the frame 1 by means of a split sleeve 3, and the other by a collet clamp 4 with a technological rod 5, mounted coaxially to the rod 2 of the magnetostrictive rod 6 with a solenoid 7 wound on it, an elastic diamond-shaped fixing device 8 with conical pinch 9 in its corners. The magnetostrictive rod 6 has conical grooves, and the locking device 8 along the small diagonal has conical protrusions. The magnetostrictive rod 6 is rigidly fixed in the corners of the fixing device 8 along its small diagonal and connected at one end to the technological rod 5 and the other to an elastic equilateral parallelogram bias amplifier 10 with conical clamps 11 in its corners and fixed with rods 12 in one of its angles along the small diagonal by the differential photocell 13, and in the opposite corner, by a metal screen 14 with a rectangular hole 15 in the center and an LED 16 located perpendicular to the screen 14. The planes phot element 13 and the screen 14 are parallel to the plane of the offset amplifier 10. The LED 16 and a photocell 13 are arranged symmetrically on the screen aperture 15 on opposite sides thereof. A recorder 17 is connected to the photocell 13. The movable part 18 of the dovetail control device 19 has a conical recess and is connected via a conical rod 20 to one of the corners of the bias amplifier 10 along a large diagonal, and the stationary part 19 is connected to a reversing motor 21 with a gearbox 22 and the gearbox 22 is connected with a micrometer screw 23 with a reporting device 24 of the moving part 18. Three lifting screws 25 are installed on the fixed part 19 of the device. In this case, two screws 25 are located in a plane perpendicular to the plane Spruce bias 10 and their thrust bearings are equipped with conical spikes 26, and the third is located in the plane of the bias amplifier 10 and its thrust bearing has a polished contact surface with the rock. A power supply 27 is connected to the solenoid 7 circuit of the magnetostrictive rod 6. The frame 1 is equipped with two spikes 28 and a polished protrusion 29, which are located in planes perpendicular to the axis of the rod 2. The base of the deformograph is the distance between the line connecting the conical spikes 28 and the line connecting the axes lifting screws equipped with tapered spikes.

Deformograph works as follows.

The deformograph is transported in a laying box in its three sections. When mounting at the observation point, a frame 1 is installed using levels, and a rod 2 with a collet clip 4 is horizontally fixed in it. The technological rod 5 is fixed in the collet 4 so that the locking device 8 and the bias amplifier 10 are in a vertical plane. The locking device 8 is set to additional small diagonal tension and the magnetostrictive rod 6 is mounted on the conical protrusions of the fixing device 8. This ensures reliable rigid contact of the magnetostrictive rod 6 with the fixing device 8. Then, the dovetail device 19 is horizontally aligned and so that the line connecting the lifting screws to the spikes 26 on the thrust bearings was perpendicular to the large diagonal of the bias amplifier 10, and the conical rod 20 was centered relative to regarding the conical recess of the movable part 18 of the device 19. A high-precision digital voltmeter is connected to the photocell 13, 2 volts of direct current are connected to the power circuit of the LED 16. In this case, the deviation from the zero position will be shown on the digital voltmeter. The engine 21 is turned on so that the conical rod 20 begins to enter the conical recess of the movable part 18 of the device 19. The operation of the engine 21 continues until the countdown on the digital voltmeter becomes zero. Setup is complete. The recorder 17 is connected to the photocell 13. The deformograph is closed with a protective casing.

When the rock is deformed, the rod 2 with the fixing device 8 and the bias amplifier 10 will shift relative to the dovetail device 19, which will lead to the deformation of the bias amplifier 10. In this case, the LED 16, the screen 14 and the photocell 13 will be displaced in planes parallel to the plane bias amplifier 10. Photocell 13 and screen 14 are parallel to the plane of bias amplifier 10, and LED 16 is perpendicular to the plane of bias amplifier 10, with photocell 13 located on one side of screen 14 and LED 16 on the other side metricity rectangular opening 15 of the screen 14.

Depending on the type of rock deformation (compression or tension), one of the components of the differential photocell 13 will be illuminated more and a differential electric current will appear in the photocell 13 circuit, the magnitude and sign of which will characterize the magnitude and type of rock deformation. When the rocks are compressed, the small diagonal of the bias amplifier 10 will increase, when stretched, it will decrease, and an electric current curve will be recorded on the recorder 17, the amplitude of which will be proportional to the deformations of the rocks.

The deformograph sensitivity depends on the ratio of the large diagonal of the bias amplifier 10 to the length of its small diagonal - the larger this ratio, the greater the gain of the bias amplifier 10, the greater the sensitivity of the deformograph. The proposed deformograph uses an offset amplifier 10 similar to the offset amplifier of the prototype. However, unlike the prototype, the proposed deformograph has a device for determining its recording scale.

Изменяем реверс двигателя 21 и при помощи винта 23 проводим отсчет на регистограмме к начальному, т.е. к y₁. Затем включаем блок питания 27 соленоида 7 магнитострикционного стержня 6 и электрический ток в цепи соленоида 7 задаем такой величины I, чтобы величина "сдвига" на регистограмме равнялась также Δy₁, отсюда определяем масштаб записи деформографа

Проведя несколько таких операций, определим величину тока А, соответствующую деформации в мкм горной породы.The deformograph is standardized as follows. The final count y ₁ is taken on the recorder 17 and the count on the reading device 24 of the screw 23 M ₁ and then a “shift” is set to the screw 23 using the motor 21 to the reference M ₂ on the reading device 24 of the screw 23, while the pitch of the screw 23 and the difference of readings ΔM = M ₂ -M ₁ , we obtain the strain value of the large diagonal of the bias amplifier 10 in microns. The "shift" of the ordinate is equal to y ₂ -y ₁ = Δy ₁ mm. The deformograph recording scale is determined from here.

We change the reverse of the engine 21 and use the screw 23 to count down on the register to the initial one, i.e. to y ₁ . Then we turn on the power supply 27 of the solenoid 7 of the magnetostrictive rod 6 and the electric current in the circuit of the solenoid 7 we set such a value I that the value of the "shift" in the register was also Δy ₁ , from here we determine the scale of the deformograph

After several such operations, we determine the value of current A corresponding to the deformation in microns of rock.

Thus, standardization can be carried out in two ways, however, a more accurate way to determine the recording scale when it is done using a magnetostrictive rod 6, which does not require opening the protective cover of the strainmeter, and therefore, the temperature is not violated and the accuracy of determining the recording scale is not reduced.

The proposed deformograph provides a higher quality of registration of rock deformation processes by preventing azimuthal rotation, increases the measurement accuracy, allows you to set various linear deformations and thus standardize the deformograph at different measurement ranges.

Claims (1)

A deformograph comprising a bed, a rod, one end of which is rigidly connected to the bed by means of a split sleeve, and the other with a collet clamp - to the technological rod, an elastic equilateral parallelogram displacement amplifier with conical clamps in its corners and fixed with rods in one of its angles at a small diagonals with a differential photocell, and in the opposite corner with a metal screen with a rectangular hole in the center and an LED located perpendicular to the screen, while the photo plane the element and the screen are parallel to the plane of the bias amplifier, and the LED and photocell are located symmetrically to the hole on the screen on different sides of it, a regulating device, the movable part of which is connected through a conical rod to one of the corners of the bias amplifier on a large diagonal, and the stationary part is connected to a reversing motor with a reducer, a recorder connected to the photocell, and power supplies for the engine and LED, characterized in that it is equipped with a magnetostrictive rod mounted coaxially with the rod with a solenoid wound on it, connected to a power supply unit and an elastic diamond-shaped fixing device with conical clamps in its corners, while the magnetostrictive rod is rigidly fixed in the corners of the fixing device along its small diagonal and connected at one end to the technological rod, and to the amplifier with the other displacement.