SU1714126A1 - Method for detection of discontinuities in rock mass - Google Patents

Abstract

The invention relates to mining and can be used in the study of artificial formations and mountain ranges to monitor stress state and the detection of heterogeneities. The purpose of the invention is to improve the accuracy and increase the resolution. The method consists in emitting ultrasonic pulses into the array and receiving them after passing the monitored section with the help of transferable transducers. At the same time, the amplitude of the received information signals (ICs) is measured and the location of the heterogeneity is determined from the change in amplitudes of the received ICs. The sounding signal is emitted at two different frequencies fi < h with a single piezoelectric rod radiator by changing its orientation by 90 ° in relation to its longitudinal axis. The amplitude of the IC is measured at these frequencies in a number of points along the profile of the array under study by a directional receiver. The presence of non-uniformity in the array is judged by the change in magnitude (D Ai2 fa) :( A Ail 'fi) for each measurement point, where Aii Ai2 is the amplitude of the IC at the frequencies fi and f2 at each control point, respectively. 3 ill. SUMMARY The invention relates to mining and can be used to study artificial and mountain massifs in order to monitor the stress state, to detect discontinuities. for example, lithological boundaries, boundaries of ore bodies. contacts of crystal-containing cavities with enclosing rocks. The purpose of the invention is to improve the accuracy and increase the resolution of detecting inhomogeneities in the massif, ensuring universality. In FIG. 1 shows a rod piezo transducer and the direction of propagation of oscillations with frequencies fi and fa; Fig. 2 shows the arrangement of the transmitter and receiver of the probing signal in the study of the array; in Fig. 3, the array investigation scheme for detecting inhomogeneities. A method for evaluating the elastic properties and detecting inhomogeneities in the array consists of this. that the rod piezoelectric emitter emits elastic waves that are VJ ^ s with > & > &

Description

The invention relates to mining and can be used to study artificial and mountain ranges in order to control the stress state, detect heterogeneities, for example, lithological 'boundaries, the boundaries of ore bodies, contacts of crystal-containing cavities with the surrounding rocks.

The aim of the invention is to increase accuracy and increase the resolution of detecting heterogeneities in the array, ensuring versatility.

resolution increase. The method consists in emitting ultrasonic pulses into the array and receiving them after passing through the controlled section using movable transducers. In this case, the amplitude of the received information signals (IP) is measured and the location of the heterogeneity is determined by the change in the amplitudes of the received IP. The probe signal is emitted at two different frequencies fi <f2 by one rod piezoelectric emitter by changing its orientation by 90 ° with respect to its longitudinal axis. The amplitude of the IC is measured at these frequencies at a number of points along the profile of the array under study by a directional receiver. The presence of heterogeneity in the array is judged by the change in the value (Δ Ai2 f2) :( Δ Ats · fi) for each measurement point, where Af-j Αϊ2 are the IP amplitudes at the frequencies ft and f2, respectively, at each control point. 3 ill.

Figure 1 presents the rod piezoelectric transducer and the direction of the propagation of oscillations with frequencies fi and f2: figure 2 - arrangement of the emitter and receiver of the probe signal in the study of the array; Fig. 3 is a diagram of an array study for detecting heterogeneities.

A method for evaluating elastic properties and detecting inhomogeneities in an array is that a rod piezoelectric radiator emits elastic waves that

1714126A1 have two resonant frequencies .. The first wave with a resonant frequency fi (higher0) propagates in the direction of the longitudinal axis of the emitter, and the second wave with a frequency f2 (lower) propagates in a direction perpendicular to the direction of wave propagation with a frequency of Ϊ2.

When examining a section of the rock mass, the orientation of the emitter is changed relative to its longitudinal axis, providing radiation of elastic waves at frequencies fi nf2 (Fig. 2). In position Г, the emitter 3 provides sounding of the studied section of the array at a frequency f 1, in position 2, in which the emitter is located at an angle of 90 ° relative to position 1, the sounding of the studied array is performed at a frequency f2.

The result is the sounding of the studied sections of the array 4 in order to detect inhomogeneities at different frequencies. The piezoceramic receiver 5 having a sharp radiation pattern records the amplitudes of the received signals Ai and Ar, emitted at the frequencies fi and f2, respectively.

Registration of incoming information signals (measuring their amplitudes) is carried out on the surface (along the profile) of the array under study at a number of points located at a certain fixed distance (I) between them (points 6, 7).

As a result of this, a series of measurement data of the amplitudes Aii and A, 2 of information signals is generated that characterize the elastic (physico-mechanical) properties of the array under study at frequencies fi and f2 in specific directions between the emitter 3 and receiver 5 (Fig. 3). After taking measurements, calculate the value

ΔΑϊ ₂ f2 AAC · fi 'on which the change is judged on the presence of heterogeneity in the studied ^ array where Δ Αϊ2 = APG ^- APG

Ap2 - Atg ~. amplitudes of information signals measured at a frequency f2 at neighboring monitoring points along the array profile;

Δ Aj- | = Agi Amr!

Αηι, Аг “are the amplitudes of information signals measured at a frequency fi at neighboring monitoring points along the profile of the array.

In the claims, the mathematical expression is corrected and the explanation for it in the following form:

ΔΑϊ2 · f2 ΔΑίΐ · f <’.

where ΔΑΐ2 ^{: =} Αη2 At!

Arg> Arg ~ information signal amplitudes measured at a frequency fg at neighboring monitoring points along the array profile;

ΔΑϊ- | ⁼⁼ Ani ~ Ami;

Αηι, PGA ^_ amplitude of information signals measured at the frequency fi in the adjacent control points along the profile of the array;

f2> fi are the frequencies emitted by the rod piezoelectric emitter when its orientation changes.

To study the artificial massif, represented by a sand-cement foundation in a mine, the proposed method used a rod piezoelectric emitter having resonant frequencies fi = 5.6 kHz and f2 '= 4.2 kHz. When examining the array of the proposed method, the following values of the amplitude of the information signal are obtained. In the absence of heterogeneity: Ap = 680 μV, Ai2 = 830 μV. In the presence of heterogeneity (contact of ore bodies) A21 = 640 μV; A22 = 810 mkv.

Calculate the values

ΔΑί2 · f2 Δ Aii <1 at measuring points (680 -640) -5.6 _224 (830 -810) -4.2 84 ’

Relative signal changes calculated by the classical method

An _ 680 A12 _ 830 Agt 640 ’A22 810 '

A comparison of the results shows an increase in the indicator characterizing the presence of heterogeneity in the array, which indicates an increase in accuracy and an increase in resolution due to the application of the proposed control method.

Claims (1)

They have two resonant frequencies. The first wave with the resonant frequency fi (more high) propagates in the direction of the longitudinal axis of the radiator, and the second wave with a frequency f2 (lower) propagates in the direction perpendicular to the direction of propagation of the wave with frequency fa. When investigating a section of a mountain massif, a change is made in the orientation of the radiator relative to its longitudinal axis, providing emission of elastic waves at frequencies fi and f2 (Fig. 2). In position 1, the emitter 3 provides sensing of the investigated area of the array. The frequency f i, in position 2, in which the emitter is located at an angle of 90 ° with respect to position 1, is probed on the array under study at a frequency f2. As a result, the probed portions of array 4 are probed to detect inhomogeneities at different frequencies. A piezoceramic receiver 5 having a sharp radiation pattern records the amplitudes of incoming signals AI and A2, emitted at frequencies fi and f2, respectively. Registration of incoming information signals (measurement of their amplitudes) is carried out on the surface (by the profile) of the array under study at a number of points located at a certain fixed distance (I) between them (points 6, 7). As a result, a series of measurement data of the amplitudes Aii and A | 2 of information signals is formed, which characterize the elastic (physicomechanical) properties of the array under study at frequencies fi and f2 in specific directions between radiator 3 and receiver 5 (FIG. 3). After the measurements are made, the value of A Ai2 f2 AAii -fr is calculated by the change of which it is judged that there is a heterogeneity in the array under study where YES | 2 Ap2 -A, Ap2. At2 is the amplitude of information signals measured at the frequency f2 at adjacent points of control over the array profile; Aats Ap1 –A Ani, Am2 amplitudes of information signals measured at frequency fi at adjacent control points along an array profile. In the claims, the mathematical expression is corrected and explained to it in the following form: YES | 2 f2 AAA and fi where AAi2 App2-Am2;. Ap2. At2 amplitudes of information signals, measured at a frequency f2 at adjacent points of control along the array profile; AAii Ap1 –A Ani Ap2 amplitudes of information signals measured at frequency fi at adjacent control points along the array profile; f2 fi are the frequencies emitted by a rod piezoelectric radiator when its orientation is changed.,. To study an artificial array represented by a sand-cement inlay in a mine working, the proposed method used a rod piezoelectric transducer having resonant frequencies fi 5.6 kHz and f2 4.2 kHz. In the study of the array by the proposed method, the following values of the amplitude of the information signal were obtained. In the absence of heterogeneity: Au 680 µV, Ai2 830 µV. In the presence of heterogeneity (contact ore bodies) A21 640 µV; A22 810 µV Calculate the values of AA | 2 f2 AAA and fi at the measuring points (680-640) 5.6 224 (830-810) -4.2 84 Calculate the relative signal changes when measured by the classical method M 680 Ai2 830 A2G 640 A22 810 Comparing the obtained results shows an increase in the indicator characterizing the presence of heterogeneity in the array, which indicates an increase in accuracy and an increase in resolution due to the application of the proposed control method. Formula from surroundings. A method for detecting inhomogeneities in an array, consisting of emitting ultrasound pulses into an array, receiving them after passing a controlled section using rotated receivers, amplitude changes, received information signals, determining the location of an inhomogeneity changing the amplitudes of information signals, characterized in that; In order to increase accuracy and increase resolution, ultrasonic pulses are emitted at two different frequencies by one rod piezoelectric transducer by changing its orientation by 90 ° relative to its longitudinal axis, while measuring the amplitudes of the information signal at these frequencies in a number of points over the profile of the array under study by a directional receiver, and the presence of inhomogeneity in the array is judged by the change in the value of AA | 2 f2 AAA and fi for each measurement point, where AI is the amplitude of the information signal at a frequency fi at each control point; A | 2 is the amplitude of the information signal at the frequency f2 at each control point; fi h frequencies emitted when its orientation changes; AAii All — A21 — amplitude difference at adjacent measurement points at frequency fi; A Ai2 Ai2 - A22 is the amplitude difference at adjacent measurement points at frequency f2. Jz l t Phage 2 Fi.Z