SU1553717A1 - Method and apparatus for locating shock-prone portions of rock mass - Google Patents

Abstract

The invention relates to mining and is intended to predict the impact and offensive hazard of sections of a rock massif (IHL). The goal is to increase the reliability and accuracy of determining the degree of shock hazard of IHL sites. For this purpose, an elastic vibration transducer 1 is installed in the IHL area and acoustic emission signals (AE) are received. IN EACH SIGNAL, A MOMENT OF ITS COMING TO CONVERTER 1 AND A MOMENT OF ACHIEVEMENT BY THE SIGNAL OF THE MAXIMUM. MEASURE THE INTERVAL OF TIME BETWEEN ELECTED MOMENTS, WHICH DETERMINE THE DISTANCE TO THE SOURCE. ALLOCATE SIGNALS TO WHICH DO NOT EXCEED THE SPECIFIED SIGNAL. THEN MEASURING IN THE POINT OF RECEPTION THE AMPLITUDE OF THE SIGNAL (AS) AND FOR A DIFFERENT RANGE, CONSIDERING THE SIGNAL DUMPING DURING THE DISTRIBUTION IN IHL, restore the AU in the source. The restored AEs determine the intensity of the AE process — the number of pulses per unit of time and the amplitude distribution. Only those AE signals are taken into account, in which the speakers in the source exceeds the minimum for a given range. The obtained values of the AE intensity and its distribution index are grouped into two classes corresponding to the shock-hazardous and non-hazardous states of IHL sites. The boundary between the classes is the process parameters characterizing the degree of impact hazard of the IHL portion. A device for implementing the method, comprising a serially connected converter 1, a preamplifier 2, a filter 3, an amplifier 4, an amplitude selector 5, as well as a recording unit 11 and a gate driver 6, is additionally equipped with a generator 12, comparison blocks 13 and 14 and successively connected trigger 7, counters 8 and 9 and AC calculating unit 10. The device produces screenings of AE signals, the sources of which are outside the specified range and the speakers whose source is less than the minimum for a given range. 2 sec. f-ly, 3 ill.

Description

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The moment of its arrival at the converter 1 and the moment of reaching the maximum by the signal are given. The time interval between the allotted moments is measured over which the distance to the source is determined. Signals that do not reach the specified range are detected. Then, at the point of reception, the amplitude of the Signal (AC) and at a certain distance are measured, taking into account the attenuation of the propagation signal at 11HP, the AC is restored at the source. According to the reconstructed: AS, the intensity of the pro- essa AE-the number of pulses unit of the belt and the amplitude distribution index are determined. Only those signals A3 are taken into account, in which the AC in the source exceeds the minimum Al of the specified range. The obtained values of the intensity A3 and its distribution index are grouped into two

The invention relates to mining and can be used in the (prediction of the hazard and hazardousness of areas in a mountain massif.

The purpose of the invention is to improve the reliability and accuracy of determining the degree of shock hazard of the parts of the array.

FIG. 1 shows a block diagram of the device; in fig. 2 is a block diagram of an amplitude selector; Fig, 3 is a block diagram of the driver gate;

The method is carried out as follows.

Previously, one of the known methods, for example, on the difference in the time of arrival of signals from one acoustic emission source on four transducers, determines the distances from the sources to each transducer and the time intervals (utA, a (c) between the time of arrival and the time it reaches the signal then set the value of the coefficient K according to the distance from the sensor to the source of acoustic emission from At max

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R is the distance from the sensor to the source of acoustic emission; K is a constant coefficient;

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class, corresponding to the shock and non-hazardous states of CHP sections. The boundary between the classes is the process parameters that characterize the degree of impact hazard of the HGP region. A device for implementing the method, comprising a serially connected converter 1, a preamplifier 2, a filter 3, an amplifier 4, an amplitude selector 5, as well as a recording unit 1 and a gate driver 6, is additionally equipped with a generator 12, comparison blocks 13 and 14 and sequentially connected trigger 7, counters 8 and 9 and the AC calculator JO. The device performs the screening of AE signals, the sources of which are outside the predetermined range and the speakers which in the source are smaller than the minimum specified range, 2 sec. F-ly, Zil,

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Q

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& tMC | KC is the time interval between the moment of arrival and the moment of reaching the maximum signal.

Next, the reception range is set and the maximum amplitude of the signal at the source is determined, which is necessary to receive the signal at a given distance, based on the attenuation of the signal when it propagates in the rock mass.

At the section of the rock mass, the shock hazard of which is determined, an elastic vibration transducer is installed and acoustic emission signals are received, 3 each signal is marked when it arrives at the converter and when the signal reaches its maximum, and the time interval between the selected moments is measured. are the distance to the source. Signals are selected, the range to which does not exceed the specified one. The amplitude of the signal at the point of reception and over a certain range is measured, taking into account the attenuation of the signal as it propagates in the rocks, and the amplitude of the signal from the source is restored. The intensity of the acoustic emission process — the number of pulses per unit time and the amplitude distribution index — is determined from the reconstructed amplitudes of the signals. Moreover, only the tol515537 is taken into account.

These are acoustic emission signals whose amplitude at the source exceeds the minimum for a given range. Then, the obtained values of the acoustic emission process parameters — the intensity and amplitude distribution index — are compared with the process parameters characterizing the degree of impact hazard of the section of the massif of this field.

The process parameters that characterize the degree of impact hazard of a portion of the array of a given field are determined as follows. 15

According to the results of the determination of the parameters of the acoustic emission process under the conditions of various shock hazard determined by approved methods, the values of these parameters are grouped into two classes corresponding to the shock and unsafe conditions of the sections of the array. The boundary between the classes is the process parameters characterizing the degree of impact hazard 25 of a section of the massif of a given field.

A device for determining the shock hazard of rock mass sections contains successively connected converter 1, preamplifier 2, filter 3, amplifier 4, amplitude selector 5, as well as sequentially connected strobe 6, trigger 7, auxiliary gg counter 8, main counter 9, an amplitude calculation unit 10, a recording unit 11, a generator 12 connected to the counting input of the auxiliary counter 8, a first comparison unit 13, 40 whose input is connected to the output of the main counter 9 and the output to the second input the amplitude calculation unit 10, the second comparison unit 14, the input of which is connected to the output of the amplitude calculation unit 10 45, and the output - to the second input of the registering unit 11. Moreover, the input of the gate generator 6 is connected to the output of the amplifier 4, and the first output of the amplitude selector 50 5 - to the zero inputs of counters 8 and 9.

The amplitude selector 5 (FIG. 2) consists of the first threshold element 15, 55 of the first counter 16, the coding block 17 and the threshold former 18, the delay line 19 and the second generator 20 whose output is connected in series

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to the counting input of the counter 16. The gate former 6 (Fig. 3) consists of the second threshold element 21, the second counter 22 and the third generator 23, the output of which is connected to the counting input of the counter 22,

The device works as follows.

Converter 1 converts the elastic acoustic emission shchpuls into electrical signals, which, after preamplification in preamplifier 2, filtering in filter 3, amplification in amplifier 4, simultaneously arrive at the amplitude selector 5 and at the gate driver 6. In the amplitude selector 5 (Fig. 2), when the input signal exceeds the threshold level of the element 15, it is triggered and the counter is enabled by the counter 164, which by the first pulse from the second generator 20 goes to the next state and outputs the corresponding signal to the coding block 17. A change in the state of the counter 16 leads to a change in the voltage at the output of the threshold former 18, which places the first threshold element 15 in a non-floating state.

3, as a result of this, counter 16 is in the state corresponding to the maximum amplitude of the input acoustic emission pulse. When a strobe pulse arrives at input E, coding unit 17 will generate a signal corresponding to the maximum amplitude of the emission pulse, and after passing the signal through delay line 19, the first counter 16 is reset.

The strobe formation is carried out in block 6 (Fig. 3). In the absence of acoustic emission pulses, the second threshold element 2 is in the zero state. When this occurs, the counting of the clock pulses of the third generator 23 by the second counter 22 with a limited speed. After filling the counter 22, a unit appears at its output, which prohibits further counting of the counter 22 c from the output of the strobe generator b to the input E of the amplitude selector 5. The strobe-pulse sets trigger 1 to one and prohibits the pulse counting of generator 12 counter 3. After a delay in the line 19 of the amplitude delay

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of the selector 5, the strobe pulse zeroed the first counter 16 and, on the output D of the amplitude selector 5, zeroed the main 9 and auxiliary 8 counters.

When an acoustic emission pulse arrives, each positive half-period of oscillations in a pulse when the threshold level of the element 21 is exceeded translates it into an excess time in one state. The unit 22 emerging at the output of the threshold element zeroes the counter 22, while the first entry of the acoustic emission signal, the trigger 7 is set to the zero state and destroys the pulse count of the generator 12 by an auxiliary counter 8, during the negative half-period of oscillations in the impu se emission counter 22 reads the generator 23 pulses After acoustic emission pulse counter 22 is filled with a limited capacity and its output is on a unit which prohibits the further expense of the counter 22 and sets flip-flop 7 in a single state. Thus, a strobe pulse occurs at the output of the imaging unit 6 at the end of the emission pulse, if between its end and the arrival of the next pulse, a time longer than the longest half-period of oscillations in the emission pulse passes.

At the same time, when an emission pulse is applied, each time the first threshold element 15 of the amplitude selector 5 triggers the output signal C, the contents of the auxiliary counter 8 are overwritten into the main counter 9, thus

Thus, by the time of the acoustic emission pulse, the main counter 9 recorded the number m of act pulses proportional to the time interval between the moment of the first entry and the moment when the signal reaches its maximum or distance to the source of acoustic emission.

The number of pulses recorded in the counter 9 is compared in the first comparison block 13 with the number of pulses corresponding to a given range. If the number of pulses in the counter 9 exceeds the number of pulses recorded in block 13, then on the computation block 8

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neither amplitude prohibits the signal, and no amplitude calculation is performed. The range of the acoustic emission source is greater than the specified one. If the number of pulses in the counter 9 does not exceed the number of pulses in block 13, then block 10 receives the enabling signal.

At the end of the emission signal, a strobe pulse is formed, and from the amplitude selector encoding unit 17, the calculation unit 10 receives the amplitude code of the acoustic emission signal at the receiving point. Upon receipt of this information, the calculating unit 10, taking into account the number of pulses in the counter 9, determines the amplitude of the acoustic emission signal at the source, which enters the comparison unit 14 and the recording unit 11. If the amplitude at the source exceeds the minimum for a given range, then the comparison unit 14 allows registration in block 11. Otherwise, registration is prohibited. After a strobe-pulse delay by delay line 19, counters 16, 8, and 9 are reset, and the device returns to its original state,

Thus, in the proposed method and device, acoustic emission signals are screened out, the sources of which are outside the predetermined range, and the amplitudes of which in the source are less than the minimum for a given distance. The intensity and amplitude distribution index are determined from the reconstructed amplitudes of the signals and the source. This increases the reliability and accuracy of the shock hazard determination and provides additional protection against interference,

45 Formula of invention

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1. A method for determining the impact hazard of rock mass sections, including receiving acoustic emission signals of mountain massifs, determining the intensity and amplitude distribution of signals and determining the degree of shock hazard of the mountain massif, characterized in that, in order to increase the reliability and accuracy of determining the degree of shock hazard of sections array, set the time of the first arrival of each signal

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acoustic emission and the moment when the signal reaches its maximum, measure the time interval between the selected moments, then determine the distance to the source of the specified acoustic emission signals, set the distance of the subsequent reception of signals and extract the acoustic emission signals to which the range does not exceed The amplitudes of the signals at the receiving point are measured, after which the amplitudes of the signals in the acoustic emission source are restored, and the intensity and the amplitude distribution are determined by restored amplitudes of signals whose amplitude at the source exceeds the minimum for a given range, after which the restored and previously determined intensities and distribution indices are grouped into two classes and set the boundary between them, and the degree of impact of the mountain rock mass is determined by the location of the recovered values intensity and amplitude distribution relative to the indicated limit.

2. A device for determining the risk of hazardous areas of the rock mass, containing successively connected transducer of elastic vibrations, preamplifier, filter, amplifier, amplitude selector, and

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also the registering block and the strobe shaper, whose input is connected to the amplifier output, and the first output is connected to the second input of the amplitude selector, characterized in that, in order to increase the reliability and accuracy of determining the shock-hazardous sections, the device is equipped with a series-connected trigger, an auxiliary counter, the main a counter, an amplitude calculation unit, and a generator, the first and second comparison units, wherein the first and second inputs of the trigger are connected respectively to the first and second the gate driver outputs, the output of the amplitude computing unit is connected in parallel to the first input of the recording unit and to the input of the second comparison unit, the output of which is connected to the second input of the recording unit, the generator output connected to the second input of the auxiliary counter, the input of the first comparison unit is connected to the output of the main counter and the output is to the second input of the amplitude calculator, the third input of which is connected to the first output of the amplitude selector, the second output of which is connected to the control Valid mu main counter, and the third output is connected to inputs zeroed yuschim main and auxiliary counters.

Fig.Z

Claims (2)

Claim 1. A method for determining the impact hazard of rock mass sections, including receiving acoustic emission signals of rock mass sections, determining the intensity and amplitude distribution of signals and determining the degree of impact hazard of a rock mass, which consists in that, in order to increase the reliability and accuracy of determining the degree shock hazard areas of the array, set the moment of the first arrival of each signal 9 1553717 acoustic emission and the moment the signal reaches its maximum, measure the time interval between the selected moments, then determine the distance to the source of these acoustic emission signals, set the range for subsequent reception of signals and emit acoustic emission signals, the range to which does not exceed the specified measure the amplitude of the signals at the point of reception, and then restore the amplitude of the signals in the source of acoustic emission, and the intensity and index of the amplitude distribution of 45 determine lyayut amplitudes of the restored signals whose amplitude exceeds the minimum at the source for a predetermined distance, and then the recovered ₂ 0 previously defined intensity distribution and indicators are grouped into two classes and set the boundary between them, and the degree of bump hazard rock massif 25 defined by lyayut the place where the restored intensity values and the amplitude distribution index fall relative to the specified boundary. 2. A device for determining the hazardousness of sections of a rock massif, comprising a series-connected elastic oscillation transformer, a preamplifier, a filter, an amplifier, an amplitude selector, as well as a recording unit and a gate driver, the input of which is connected to the amplifier output and the first output is connected to the second input of the amplitude selector, distinguishing it with the fact that, in order to increase the reliability and accuracy of determining shock hazardous areas, the device is equipped with a trigger connected in series, a powerful counter, a main counter, an amplitude calculation unit, and also a generator, first and second comparison units, while the first and second inputs of the trigger are connected respectively to the first and second outputs of the gate former, the output of the amplitude calculation unit is connected in parallel to the first input of the recording unit and to the input of the second comparison unit, the output of which is connected to the second input of the recording unit, and the output of the generator is connected to the second input of the auxiliary counter, the input of the first comparison unit connected to the output of the main counter, and the output to the second input of the amplitude calculation unit, the third input of which is connected to the first output of the amplitude selector, the second output of which is connected to the control input of the main counter, and the third output is connected to zeroing inputs of the main and auxiliary counters. FIG. 2 * . Compiled by V. Tychina