SU890317A1 - Device for measuring amplitudes at acoustic logging - Google Patents

Description

I

The invention relates to field geophysical studies of oil and gas wells, and more specifically to acoustic logging equipment, and solves the problem of improving the accuracy of measuring amplitudes in acoustic logging wells.

Devices are known for measuring amplitudes in acoustic logging. These devices contain receivers of acoustic signals, an amplifier, a circuit that provides the first entry of a signal, for example, a selector, a transducer that converts the amplitude of the first entry into the duration of rectangular pulses 1, or direct current t2.

However, these devices have a small dynamic, range and low amplitude measurement accuracy.

Closest to the inventive technical solution is acoustic logging equipment

holding a downhole tool with a three element probe, consisting of current generators to excite emitters and a receiver, polar selectors, an amplifier and filters, and a ground device consisting of an amplifier, switches, coincidence circuits, a synchro generator, peak detectors, narrowband filters, differential schemes and registrar. In this

10 to the equipment of the synchronous generator generates positive and negative pulses, which through the logging cable enter the squash-blue device. After passing the barrier

Claims (3)

The 15 network filtering pulses are separated by polar selectors and alternately act on the current generators of the emitters, sending elastic waves to the rock. Elastic cob lebanis, having passed through the rock, reach the receiver, which converts them into an electrical signal. The last, amplified amplifier, passed the filter. 3 through the logging cable enters the ground equipment. After passing the filter and amplifying with an amplifier, having passed the coincidence circuit (analog key), the signal enters through narrow-band filters and switches to peak detectors, which measure the maximum amplitude of the signal. The coincidence circuit only passes a certain part of the signal, corresponding to the pulse duration, coming from the strobe generator, which, in turn, is triggered by a pulse, from the delay generator. Thus, the charge voltage of accumulative capacities of peak detectors in each radiation cycle reflects the amplitude of the received acoustic signal. The main node of this circuit, which influences the accuracy of amplitude measurements, is the peak detector. In order for both to produce sufficient speed and resolution of amplitude measurements, the peak detector capacitance must be as small as p. However, the voltage of the peak detector should not significantly decrease in each measurement cycle. Therefore, the peak detector capacitance is chosen such that this voltage decreases from cycle to cycle by no more than 10-15%. As a result, the disadvantage of such an amplitude measurement scheme is the low speed and. therefore, measurement accuracy is low. The purpose of the invention is to increase the accuracy of amplitude measurement in acoustic logging of wells. The goal is achieved by the fact that in the device for measuring amplitudes in acoustic logging, consisting of a three-element downhole probe, containing one emitter and two receivers, a current pulse generator for exciting the emitter, a shaper of alternating pulses and an amplifier, while in the well probe outputs receivers are connected to an amplifier, the integrator of current pulses is connected to the radiator and the driver of different-polarity pulses, the output of which is connected to the amplifier, the output of the amplifier is connected to the logging cable connecting the probe with a ground measuring panel containing a filter, an amplifier discriminator of different polarity pulses, an analog key, a shapi7 circuit. 4 vanilla strobe pulses, a peak detector, a synchronous generator and a recorder, and in the ground measurement panel a logging cable is connected to the input of a filter connected in series with the amplifier, an analog key and a peak detector, the output of the amplifier is connected to the discriminator of different polarity pulses, the output of which is connected to the inputs of the strobe-pulse shaping circuit and the synchro-generator, and the first output of the synchro-generator is connected to the second inputs of the strobe-pulse shaping circuit and the peak detector, additionally a step voltage generator, a digital-to-analog converter, a buffer memory, a comparator, a counting pulse generator, an RS flip-flop, the first, second and third single-pulse short pulses, an AND logic circuit and a nonlinear filter are introduced, the first input of the comparator is connected to the peak output detector, and the second - with the first output of the step voltage generator, the output of the comparator through the first one vibrator is connected to the input of the second one vibrator and the R input of the RS flip-flop, the S input of which is connected via the third one vibrator do by a strobe pulse shaping circuit, the trigger output is connected to one of the inputs of the logic circuit AND, the second input of which is connected to the generator of counting pulses, and the output is connected to the trigger input of the stepped voltage generator, which prohibits the input of the last generator and the second generator output stepwise voltage is connected to the first input of the buffer memory, the second recording input of which is connected to the output of the second one-vibrator, the output of the buffer memory through a digital-to-analog converter connected to the input of the nonlinear filter, and the output of the nonlinear filter is connected to the recorder. The step voltage generator contains a binary serial asynchronous counter, NAND logic elements with open collector outputs, an R-2R matrix of resistors and transistor current stabilizers, the inverse outputs of each counter of the counter being connected to transistor current regulators 5 through the corresponding outputs. , and the load on the matrix resistor R-2R. FIG. 1 shows a block diagram of the device; in fig. 2 is a schematic diagram of a step voltage generator. The device detects a downhole ultrasonic probe 1, consisting of acoustic receivers 2 and 3, emitter 4, current pulse generator 5, shaper of alternating pulses 6 and amplifier 7 connected by a logging cable 8 to a ground-based measuring panel 9. Ground measuring panel consists of a filter O, amplifier 11, discriminator of bipolar pulses 12, analog switch 13, strobe pulse shaping circuit 14, clock generator 15, peak detector 16, first and second short pulse pulses 17, 18 and 19, Mpapora 20, RS flip-flop 21, generator of counting pulses 22, logic circuit And 23, step voltage generator 24, buffer memory 25, digital-to-analog converter 26, nonlinear filter 27 and recorder 28. The step voltage generator consists of binary sequential asynchronous counter 29, logical elements AND-30 with open collector outputs, matrix resistors 31 type R-2R and transistor current regulators 32. In the downhole probe, receivers 2 and 3 are connected to the amplifier 7, the current pulse generator is loaded on radiator 4, the input of the polarizer pulse generator is connected to the current pulse generator, and output by the amplifier 7. The downhole ultrasonic probe is connected to the ground measuring cable 8 by a well log 8 the panel where the filter 10 is connected to the amplifier 11, the output of which is loaded on the analog switch 13 and the discriminator of different polarity pulses 12, the output of which is connected to the input of the synchro generator 15. The output of the synchronous generator 15 is connected to the controller which is the input of the strobe pulse shaping circuit 14, and its stroke is connected to the control input of the analog switch 13 loaded on the peak detector 16. One of the inputs of the comparator 20 is connected to the output of the peak detector 16 and the other to the output of the generator 7 "/ pa step voltage 24, the output of the comparator 20 through the one-shot 17 is connected to the input of the one-shot 18 and to the R input of the trigger 21, the S-input of which through the one-shot 19 is connected to the gate stator 14, the direct output of the trigger 21 is connected to one of the logical inputs scheme And 23, and its other input is with a counter-pulse generator 22, and the output of the AND circuit is connected to the trigger input of the step voltage generator 24, and its prohibiting input is connected to the synchronous generator 15, the output of the step voltage generator 24 is connected to the second input of the comparator 20 and with a buffer memory 25, the recording input of which is connected to the one-shot 18. The output of the buffer memory 25 is through a digital-to-analog converter 26 and then a non-linear filter 27 is connected to the recorder 28. In the step voltage generator (Fig. 2) the inverse outputs of each bit of the counter 29 are connected via the corresponding elements (logical) of AND-NOT 30 to the transistor current stabilizers 32, loaded on the matrix 31 of the R-2R resistors. The device works in a dim way. Under the influence of a powerful pulse from the current pulse generator 5 The emitter 4 of the borehole probe generates elastic oscillations, which, having passed through the rock, reach receivers 2 and 3, converting iix into an electrical signal. The latter, amplified by amplifier 7, enters through the logging cable 8 into the ground measuring panel. At the moment when the emitter 4 is triggered, the pulse shaper 6 generates positive and negative synchronization effects, which are mixed with the acoustic logging signal on the amplifier 7 and with it arrive at the surface. The total signal after passing through the ground panel filter 10 and amplification by the amplifier I1 enters the discriminator of different-polarity pulses 12, which generates synchronization pulses fed to the synchro-generator 15. The synchro-generator generates start-up pulses that reset the peak detector 16 7 and the step generator voltage 24. The same pulse starts the strobe pulse formation circuit 14, which generates a pulse equal in duration to the first half-period of the acoustic logging signal . The pulse from the circuit 14 opens the analog key 13, which passes only the first half period of the signal to the peak detector 16. The storage capacitance of the peak detector 16 is charged to a voltage equal to the amplitude of the first half period of the signal and then begins to discharge during the cycle. This slowly varying voltage from the peak detector 16 is fed to one of the inputs of the comparator 20. At the end of the strobe pulse, the one-shot short pulses 19 are triggered from the circuits 14. The pulse from this vibrator overturns into an RS trigger 21. Single state The triggering of this trigger is logically multiplied with pulses from the generator of counting pulses 22 using an AND 23 logic circuit. A stack of counting pulses comes from the AND circuit to the starting input A of the step voltage generator 24. Preliminary the counter 29 of the step voltage generator 24 is set to the zero state by the start of the cycle pulse from the synchronous generator 15 at the input B. The instant of the arrival of the counting pulses with the help of the counter 29 starts their sequential counting. The inverse state of each discharge of the counter 29 through the logic elements AND-30 with open collector outputs is supplied to the emitters of the transient current regulators 32, loaded on the matrix of R-2R resistors. Thus, from the output of the last discharge of this matrix, in the conversion of the binary state of each discharge of the counter 29, a linearly increasing voltage, stepwise form, flows into the direct current. This voltage is applied to the other input of the comparator 20. At the time when the two voltages are equal, a one-shot of short pulses 17 is triggered on the falling edge of the comparator 20, the pulse from which the one-shot 18 is started and the RS-trigger 21 tilts to zero state. The counting stops. With a short pulse from the one-shot 18, the binary state of the counter 29. a generator of step voltage 24 from the outputs G is transferred to the buffer memory 25. Using the digital-to-analog converter 26, the binary code of the measured value is converted into a constant voltage 27, having an upper limit of 2-3 Hz is output to the recorder 28. As a result, all random failures in the measurement process, the frequency spectrum of which is more than 3 Hz, are not reflected by the recorder. Due to the fact that the frequency of the generator of counting pulses can be very high (up to 10 MHz), and the measurement time itself is very short, the peak detector capacity can be reduced in comparison with known devices by an order of magnitude. This, in turn, significantly increases the speed and resolution of the entire device and, consequently, the accuracy of amplitude measurements. In addition, the applied voltage to the recorder, which is proportional to the measured amplitude of the first half-period of the acoustic logging signal, is constant and does not vary from cycle to cycle, which also increases the measurement accuracy. The use of the proposed device for measuring amplitudes in complex acoustic and gamma-gamma logging equipment (SCHAH-2) significantly improves the measurement accuracy, which leads to a high repeatability of the diagrams (about 2-3%) and a reduction in the time required for interpretation of acoustic logging results . The invention of the device for measuring the amplitudes in acoustic logging, coc: from a three-element downhole probe containing one emitter and two receivers, a current pulse generator to excite the emitter, a driver of different polarity pulses and an amplifier, while in the downhole probe the outputs of the receivers are connected to an amplifier The generator of current pulses is connected to the emitter and shaper of different-polarity pulses, the output of which is connected to the amplifier, the output of the amplifier connecting 1} ei to kag -.tazh9. cable, the probe is connected with a logging cable with a ground measuring panel containing a filter, an amplifier discriminator of different polarity pulses, an analog key, a strobe pulse shaping circuit, a peak detector, a synchronous generator and a recorder, and in the ground measuring panel a logging cable is connected to the filter input, connected in series with an amplifier, an analog switch and a peak detector, the output of the amplifier is connected to the discriminator input of different polarity pulses, the output of which is connected to the inputs of the circuit a pulse gate clock, and a sihihrogenerator, and the first sync generator output is connected to the second 1 inputs of the strobe pulse formation circuit and peak detector, characterized in that, in order to improve the measurement accuracy, a step voltage generator, a cis-analog converter, is additionally introduced into it buffer memory, comparator, counting pulse generator, RS-trigger, first, second and third single-pulse short pulses, AND logic and non-linear filter, with this first comparator input connected to the output A second detector with a first output of a step voltage generator, the output of the comparator is connected to the input of the second one-shot and the R-input of the RS flip-flop via the first one-shot ;, S-input is connected to the strobe-pulses through the third one-shot, the output the trigger is connected to one of the inputs of the logic circuit I, the second input of which is connected to the generator of counting pulses, and the output to the trigger input of the step voltage generator, which prohibits the input of the latter, is connected to the second output generator, the second output of the voltage generator is connected to the first input of the buffer memory, the second recording input of which is connected to the output of the second one-oscillator to the registrar. 2. The device according to claim 1, about tl and -that is that the step voltage generator contains a binary serial asynchronous counter and AND-NIC logic gates with open collector outputs, an R-2R resistor matrix and transistor current stabilizers, and the outputs of each bit of the counter, are connected through the corresponding NANDIC logic elements with transistor current stabilizers, loaded on the matrixes of resistors R-2R. Sources of information taken into account in the examination 1.US Patent C 3251029, cl. 340-18, 1966. 2. US patent number 3270316, li. 340-18, 1966. 3. USSR author's certificate 461397, cl. G 01 V 1/40, 1975 (prototype). one 20 f7 27