SU995046A1 - Device for measuring elastic wave damping coefficient in acoustic well-logging - Google Patents

Description

(54) DEVICE FOR MEASURING THE DIFFERENTIAL RATE OF ELASTIC WAVES DURING THE ACOUSTIC SURROUND

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The invention relates to geophysical field investigations, and more specifically, to acoustic logging equipment for oil and gas wells, and solves the problem of improving the accuracy of measuring the attenuation coefficient of elastic waves propagating in mountainous rocks intersected by bore holes.

A device containing a three-element borehole device with a single radiator and two receivers is known, including an electronic circuit consisting of an amplifier, a filter, a threshold device, a strobe circuit, two controllers and 1x Peak detectors, the shape of rectangular pulse world drivers, differentiating chains limiters, mixer and synchronizer. The borehole 1fnb6r is connected by a logging cable to a ground control unit containing a time interval measurement circuit.

The channel signals from each of the receivers are amplified and fed to the strobe circuit, which passes only the first half of the received signal. Signal amplitude for

Each channel is fused with peak detector capacitors.

After the capacitors of the peak detectors of both channels are charged, they are discharged through controlled KpeMtraS bottoms and limiting resistances. The width of the discharge pulse depends on the amplitude of the voltage up to which the capacitor was charged. Rectangular pulses are formed from exponential pulses.

®. the forms, which are then differentiated, and the pulses corresponding to their falling edges, and then they shift at the output. Takkak the rank of both condzhsatorov; The peak detectors start at one moment, the time interval between the O1NH1 pulses is proportional to the natural logarithm of the ratio of the amplitudes of the first arrivals over the two channels and is measured by the standard time interval calculation scheme located in the ground control panel 1.

Claims (2)

However, the device has a low point,.  of the measurement of the attenuation coefficient due to faults caused by the nonidentical characteristics of peak detectors, the difference in the storage of the result of fixing the amplitudes of the first arrivals by non-ideetic discharge circuits of the capacitors of peak detectors.  The closest technical solution complains about a device for measuring the attenuation coefficient of elastic waves in acoustic logging, which contains a three-element downhole device connected by a logging cable to a surface computational panel, including a low-pass filter with an amplifier, a threshold device, an analog switch, a synchronizer, a peak detector , window shaper, exponential “function generator, short pulse one-shot, comparator, RS-pulse of the counting pulse time window, reversible count tchik, digital-to-analog converter, a generator of counting pulses and three logical elements I.  In the terrestrial computing panel low pass filter.  The amplifier is connected to the logging cable, and its output is loaded on an analog switch, a synchronizer and a threshold device, the output of which is connected via the driver of the connection window to the control input of the analog switch and the trigger inputs of the exponential function generator and the short pulse single vibrator.  The input of the peak detector is connected to the output of the analog switch, and the output is connected to the first, the input of the comparator, the second input of which is connected to the output of the exponential function generator.  Comparator output connect with, R in.  The home of the RS-flip-flop of the time window, the 8-input of which is connected to the output of the one-vibrator and one of the inputs of the logical element I, the second input of this element is connected to one of the outputs of the synchronizer, and the output of the same elembig to the input of the set reversing counter meter.  The counting input of the reversible counter is connected to the output of the first logic element I, one of the outputs of which is connected to the output of the RS trigger of the time window, and the other to the generator of counting pulses.  The control inputs for addition and subtraction of the reversal / counter are connected to the synchronizer output, and the counter output is connected to a digital-to-analog converter, the lowering input of which is connected to the output of the third logic element I, one of the inputs of the last one is connected to the output of the comparator, and the other is connected to one of the outputs synchronizer.  The acoustic signal is converted into an electrical device into an electrical signal, which is fed through a logging cable to the ground computation panel, amplified and filtered by a low-pass filter and then fed to a threshold device, where the first entry of the elastic wave is determined at a certain level above the noise level.  The first entry impulse arrives at the window shaper, which generates a pulse equal in duration to one or several half cycles of oscillations of the first arrivals of an elastic wave.  The signal from the window former is controlled by an analog switch transmitting the amplitude of the first to the input of the peak detector or.  subsequent phases of oscillation of the wave pattern of the signal, which captures the maximum amplitude of the gated signal.  The constant level signal from the peak detector is fed to one of the Inputs of the comparator, to the other input of which the signal of the exponentially falling form is fed from a stable voltage level.  At the moment of equality of these voltages, the comparator generates a short pulse that converts the RS-flip-flop of the time window to the zero state. Before that, the RS-flip-flop was set to the single wake state by a single-oscillator signal at the moment of the beginning of the formation of an exponentially falling voltage.  Signals in the form of rectangular pulses, the power of which is proportional to the natural logarithms of the amplitudes of the signals of the first arrivals of the elastic wave, alternately, in cycles corresponding to the reception of the signal from the first and second radiators, arrive at one of the inputs of the logical element I and, logically multiplying with the counting generator pulses pulses of stable frequency, go further to the counting input of the reversible counter.  With this counter, the difference time intervals between pulses from the trigger of the time window are measured, corresponding to different measurement cycles of signals from the first and second radiator.  The digital code of the measured time interval corresponding to the natural logarithm of the signal amplitude ratio for the two channels is converted by a digital-to-analog converter into a constant voltage (current) and outputted by a register 2.  However, in the process of measurements using this device in intervals with a large acoustic attenuation (for example, with good quality of adhesion of cement stone to casing-fub columns during cementmetry), when the amplitudes of the first phases of the waveform signal are commensurate with noises, the accuracy of measuring zatu5, Chania 9 is reduced as a result of faulty situations in the operation of the device, which are displayed on the chart paper and are practically not interpretable.  Failure situations arise as a result of the fact that it is practically impossible to determine the end of the formation of a Hanpejkemui exponentially adherent form, and the release of a reversible counter cannot be infinite.  As a result, in such cases, a counter overflow occurs, after which it is zeroed.  When this is done, a zero value of the coefficient is recorded in the e-gram paper, then it is not. corresponds to geological.  In addition, in the intervals of measurements with a small acoustic attenuation (free column), as well as with unequal transmission coefficient of sigals from both emitters, when the amplitude of the signal from the second {K th emitter slightly exceeds the amplitude of the signal from the first emitter, also There is a failure opuatsi.  It arises as a result of the reversal of the score in which case it is first nullified, L then. a mapping of the spatially imbued interval in the reverse cade occurs.  As a result, the maximum value is recorded in the diagrams of this paper.  This attenuation is also not consistent with the geo-techical (zhtuashsh.  The same “correspondence of the recorded parameter 1f6zh goes in intervals. from the very 6th amplitude it is attenuated when the amplitudes of the first and subsequent wave pattern arrivals are less than the threshold device.  In this case, the trigger is time (the life forms the measurement intervals and the count remains in the zero state, as a result of which the chart paper records the zero values of the damping coefficient.  All these reasons make accurate measurements.  The aim of the invention is to improve the accuracy and stability of the measurement of the attenuation coefficient of elastic waves in acoustic logging.  The goal is achieved by the fact that the device for measuring the attenuation coefficient of elastic will in auxiliary logging, contains a three-arm aelectric device connected by a logging cable to a computational boundary panel with an amplifier, a threshold device, an analog key, a synchronizer, detector, shaper rkia generator of functional function, the first one-shot short pulses, comrator, RS-TIMIIT of the time window of the schenp pulses, reversible counter, qi A analog converter, a generator of% pulses, and first, second, and third logic elements are AND, the input of the low-pass filter with an amplifier is connected to the logging cable, and the output to the powder device is an analog key and a synchronizer, which connects the device through the interface window ei with ursh) 1Yakvtsim in Yudo Analogogr, as well as with the start (By his input of the generator the exponential function and the first one of the short / impulses, the first input of the comparator with the peak detector, and the second one with the output generator expyitsits # 1Yanns funktstskk: the first output from the schroniator: medium with the input of the first | x logical element And, and the second output - with the first input of the second logical element Mt; the output of the RS trigger of the temporary okita udienei with the P1FV input of the third logical control AND, the second input of which is loaded on the calculating generator, and the output of the reversing counter connected to the digital input converter additionally introducing a four and five L (AI) components, and the API, and the API, and the API, and the API, the elements, and the API, connected to the converter NI reversible counter, - the second, third and fourth orders of short pulses, first, second, and second.  the third logs orm and the first and second RS-flip-flops, with the summations of the recourse counter connected to the output of the nepBwo and the second input of the second noriPi and the second log of the 1p; And And, and readings an input.  the reversible counter is connected to the output of the logic element Hi, the koTOjporo input is connected to the output of the second log of the element I, and the second is connected to the output of the first RS flip, the input of the second one short pulse is connected to the second output of the chipper, and the output of the second short vibrator of the voltage switch is loaded. the first and second 8-flip-flops and to the input of the installation of the reversible counter, the output of which is connected to dm11if1 toor1m perepolyyush and zeroing, and the output of the decoder flip-flop is the third simultaneous short pulse Inonii to a first input of the third logic elemshta OR and R-yusodam RP-flop, and the output of the decoder of & 1uleii soediiei through fourth odioviOrator short pulses to a second input of the third logic elemeita Hilti whose output soediiei to a first input of a second OR gate, a second. the input of which is connected to the output of the comparator 1m, and the output - to the R-input of the RS-flip-flop of the time window of the counting pulses whose S-input is connected to the output of the first OR logic element, the first input of the last is connected to the output of the first short pulse single vibrator, which is connected to R- the input of the second RS flip-flop, the second input of the first logical element OR is connected to the output of the fifth logical: then the element I, the first input of which is connected to the output of the second RS-flip-flop, and the second input - to the third output of the synchronizer, the fourth output last on is connected to the recording input of DAC.   The drawing shows the functional diagram of the device.  The device contains a downhole tool of the P1P2I structure (two receivers, one radiator), a logging cable2, a low-pass filter with an amplifier 3, a threshold one.  operation ± 4, analog switch 5, shaper b windows ,.  synchronizer 7, peak detector 8, generator 9 of exponential function, first single vibrator 10 short pulses, first logic element 11, second logic element AND 12, second single vibrator 13 short pulses, comparator 14, first logic element OR 15, reversible counter 16, fourth logical element AND 17, first RS-flip-flop 18 second logical element OR 19, overflow deisfrator 20, zero-zero decoder 21, second RS-trigger 22, RS-flip-flop.  23 time windows of counting pulses, treTitii single vibrator 24 short pulses, fourth single vibrator 25 short pulses, Fifth Lottes element AND 26, third logical element AND 27, generator 28 counting pulses of stable frequency, digital input converter 29 and third logical element OR 30.  Well device 1 is connected by a logging cable: 2 with a ground-based computing one.  a panel where the low-pass filter with amplifier 3 is connected to the inputs of the threshold device 4, the tax key 5 and the synchronizer 7.  The output of the threshold device 4 through the shaper 6 window connected to the inputs of the analog key 5, the generator 9 of the exponential function and the first one-shot 10.  The output of the key 5 through the peak detector 8 is connected to the first of the inputs of the comparator 14, the second input of which is connected to the output of the generator 9 of the exponential function, and the output of the comparator 14 is connected to the second input of the second logical element OR 19, the first input of which is connected to the output of the third logical element OR thirty.  The summing input of the reversible counter 16 is connected to the output of the first logical element 11, the first input of which is connected to the first output of the synchronizer 7, and the second to the input of the second logical element 12 and with the output of the third logical element 27.  The second input of the logic element And 12 is connected to the second output of the synchronizer 7 and to the input of the second one-shot 13, and the output of the Last to the S-inputs of the first and second RS-flip-flops 18 and 22 and to the zero input of the reversing counter 16.  Inserting input reversible counter 16 is connected to the output of the fourth logical element And 17, the first input of which is connected to the output of the second element And 12, and the second to the output of the first RS-flip-flop 18.  The output of the first one-vibro-1 pa 10 is connected to the first input of the first logic element OR 15 and the R input of the second RS flip-flop 22, and the output of the last to the first input of the five AND 26 logic element, the second input of which is connected to the third synchronizer 7 .  The output of the fifth element And 26 is connected to the second input of the first element OR 15, the output of which is loaded to the S-input RS of the time window 23, the R-input of which is connected to the output of the second logical element OR 19.  The output of the reversible counter 16 is loaded onto a digital-to-analog converter 29, an overflow decoder 20, and an zero-encoder 21.  The output of the overflow decoder 20 is connected via the third one-shot 24 to the first input of the third logical element OR 30 and the R-input of the first RS-trigger 18.  The output of the decoder 21 zeroing through the fourth one-shot 25 is connected to the second input of the third logical element OR 30.  The recording input of the digital-to-analog converter 29 is connected to the output of the synchronizer 7.  The device works as follows.  At the beginning of the measurement cycle, the channel from the second receiver of the downhole tool 1 (cycle III) with a certain delay determined by the second one-shot 13, the pulse from the synchronizer 7, the reversing counter 16 is set to the zero state, and the first and second RS-triggers 18 and 22 - in the unit.  Then, at the moment of arrival of the first arrivals of the wave pattern of the signal from the threshold Device 4, the shaper 6 of the window is started, which controls the analog key 5.  At the end of the window pulse, the generator 9 opens an exponential functional, and the first one-shot 10 forms a short pulse, which passes the first logical element OR 15, sets the fiS trigger, 23 time window, to one, thereby allowing the passage of counting pulses from the 28 counting generator impulse through the third logical element And 27 and then the first lopgaesny element And 11 - and the summing input of the reversible counter 16, B. channel measurement cycle from the first receiver; ka (cycle P1) counting pulses from a generator: a torus of 28 counting pulses pass through the third logic element AND 27, the second and fourth logical elements AND 12 and 17 for triggering the input of the reversing counter 16,. ;; :.  In the case of passing through a borehole device 1 ZOY with a large acoustic attenuation, the amplitudes of the first arrivals of the wave pattern signal are such that the trigger 23 of the time window of the counting pulses generates a pulse of considerable duration, which is not enough to measure the reversing counter 16.  In that . In the case of the P2 cycle, the overfill decoder 20 generates a pulse, which, through the third one-shot 24, overturns the first RS-. trigger 18 to zero state.  By the same pattern, the third and second logical elements OR 30 h 19 stop the further passing counting pulses: To the summing input of the reversing counter 16.  In the next cycle, the zero state of the first B8 flip-flop 18 is prohibited, passing.  pulse counting through the fourth logical element I 17 on the calculation of the input of the reversing counter 16.  A pulse from the synchronizer 7 records the maximum binary state of the reversible counter 16 to the digital-analog converter 29, from which the voltage (current) corresponding to the maximum value of the attenuation coefficient is removed.  This value corresponds to the upper limit of the dynamic range for measuring this coefficient for this device.  In the case of passing by the squash equipment, the ZOI with a small acoustic attenuation of the amplitude of the first arrivals of the wave crank in the P1 and P2 cells is maximal and slightly different from each other, and in the case when the transmission coefficient is due to the sensitivity of the receivers.  P2 channel slightly exceeds the transmission coefficient over the P1 channel, the duration of the time window generated by the RS-trigger 23 of the time window in the P2 cycle ,.  longer than the time window in W1kle P1.  In this case, the situation of the reversing counter 16 occurs.  At this moment, the nulling decoder 21 generates a pulse, which, through the third and second logical elements OR 30 and 19, flips the RS flip-flop 21 of the time window and its zero state.  Thereby stops the passage of schelp.    pulses from the fender 28 counting pulses through the third, second and fourth logical elements AND 27, 12 and 17 that subtract the input of the reversible counter 16.  The zero state of the reversible counter is 16 pulses ,.  The cam from the synchronizer 7 is recorded in a digital-to-analog converter 29, the output of which removes the voltage (current) corresponding to the minimum value of the attenuation coefficient.  This value corresponds to the lower limit of the dynamic range, the measurement of this coefficient for this device.  If the well device passes zones with significant acoustic attenuation, when the amplitudes of the first and subsequent arrivals of the wave chart signal are less than the trigger level of the threshold device 4, the window shaper 6 does not pulse, starts the first one vibrator 10, and the second RS flip-flop 22 in cycle III remains in one condition.  Thus, in this cycle, the passage of a pulse from synchronizer 7 through the fifth logical element AND 26, the first logical, is allowed.  the element OR C on the S-input of the trigger 23 of the time window, which is set to one.  The unified cocTOJOOte of this trigger permits the passage of counting pulses from a generator of 28 cm nm: pulses through the third and first logic elements AND 27 and P to the summation of the input of the reverogenic chip 16.  At the moment of overflow, the inverter counter 16 decoder 20 of the refill forms a co-.  Rot impulse, which through Tpettrii one-shot 24 and the third and second logical elements IL I.  30 and 19 prohibits the passage of counting pulses to the up-and-down counter 16.  Pulse from (Schronizer 7, the maximum binary state of the reversing counter 16 is written into the D / A converter 29.  Thus, in this case, the voltage (current) taken from the digital-analog output; converter 29 corresponds to the maximum attenuation coefficient.  The proposed device can {botap, with a borehole device of the structure I1 I2P (two radiator and receiver).  As a result of the use of this device, the accuracy and stability of measuring the coefficient of elastic air waves during acoustic logging of oil and gas wells is improved.  The recording accuracy is improved due to the fact that on a chart paper this parameter registers non-fluctuating fluctuations that make it difficult to interpret the data to be crawled.  This will significantly improve the efficiency of field geophysical work by reducing the time for processing and interpreting the day.  materials of acoustic logging of uncased and omentometry of cased gas wells.  Due to this, the total cost of work on the well is reduced.  m. Formula of the Invention A device for measuring the attenuation coefficient of a will nj by an acoustic logging tool containing a three-element borehole {device, connected; a cable with a ground computational panel, including a bottom filter with a ycwiine, threshold device, analog key, cHH; qpOHB3aiop, peak detector, window generator, exponential fuse generator, single short waveforms, and I have made a pattern. time window of the counting pulses, a reverse analog counter, I digital-to-analog converter, ciKTiibix pulse generator, and first, second, and third logic elements AND, whichever in: the filter stroke is often connected with an amplifier with a logger, fused, a. the output is loaded on a threshold device, an analog and a sihiroshchizator, V1khod threshold: the window shaper device is connected to the u1C input of the analog key, as well as starting up the generator input of the ecenational function and the first one-vibrator of the short Nm lsov of the first comparator input connected to the pic of the comparator chip - with the output of the generator with an exponential function, the first 1-stroke of the snihronnat is connected to the first input of the first loop of the second element I, and the second output - to the first input of the second logical element And, The output of RS-tr of the time window of the time window is connected to the first input of the third logic element I, the bark of which is loaded on the counting pulse generator, and the output of the reverse switch is connected; with a digital-to-analog converter, which is based on the fact that in order to improve accuracy and accuracy (amp; measurement of the attenuation coefficient, the fourth and fifth logical elements AND, the overflow decoder and decrypter zero reset of the reversing counter are added to it) , the second, third and fourth single-pulse short pulses, the first, second and third logical elements OR and the first and second RS-flip-flops, and the summing input of the reversible counter is connected to the output of the first logical element And, the second input of which the second input of the second logic element I is connected to the output of the third logic element I, and the outgoing input of the reversing loop is connected to the upper fourth logic element I, the first input of which is connected to the output of the second logical element I, and the second to the output of the first H8-third signal, the input of the second the single pulse of short pulses is connected to the second output of the synchronizer, and the output of the second one, the short importer, is loaded on the S-sxonu of the first 11 second RS-flip-flops and on the installation input of the cool reversing counter, output cat orogo connected to detsshfratorami overflow and & mulonn, etc. than the output of the decoder overflows through monostable short ikshulsov soedanen to a first input of the third OR gate and the R-input nejmoro RS- mrrepa, and the output de igafratora zeroing through fourth monostable multivibrator of short pulses is connected to the second input the third logical element OR, the output of which is connected to the first input of the second logical element OR, the second input of which is connected to the output of the comparator, and the output to the R input of the RS flip-flop of the time window pulses, the S-input of the cottage is connected to the output of the first logical element OR, the first input of the latter is connected to the output of the first short-pulse pulse oscillator, which is connected to the R-input of the second.  RS-flip-flop, the second input of the first logical element OR is connected to the output of the fifth AND logical gate, the first input of which is connected to the output of the second RS-Tpirr, and the second input - to the third output of the synchronizer, the fourth output of the last connection to the recording input of the digital-analogue transmitter.  Sources of information, P {ity toe in attention during the examination 1. US patent N 3251025, CL.  340-18, published.  1964.   2. USSR author's certificate in accordance with FP 255: 6590 / 18-25, cl. G 01 V 1/40, 1977 (prototype).