SU1278746A1 - Method of checking acoustical logging equipment - Google Patents

Abstract

The invention relates to well logging, to methods for calibrating acoustic logging equipment. The purpose of the invention is to improve the accuracy of the calibration of acoustic logging equipment by taking into account the systematic error of the equipment when measuring the attenuation coefficient of elastic waves arising from the difference in intensity of the emitters of the downhole tool. Achievement of the target is additionally measured at the output of the electro-acoustic transducer with the amplitude Aj, of elastic waves propagating along the reference tube from the far-emitter. The Converter in the initial position. Establish between the far emitter and the receiver of the downhole tool. At the output of the transducer, the amplitude AS of elastic waves propagating along the reference tube from the near-emitter is measured. In this case, the electroacoustic transducer is moved in the direction of the receiver to a distance S equal to the distance between the radiators. The systematic error is determined by the ratio of the amplitudes in the measurement of the attenuation coefficient of elastic waves. The amplitudes Ag and A are measured (L at various distances of the electro-acoustic transducer relative to the far-emitter. The transducer is moved from the initial position to L (L is the distance between the far-emitter and the receiver of the downhole tool). The initial position of the transducer is determined by the center the interval in which the amplitude there A has the maximum value “iU Od when moving the transducer past the distant radiator. 2 Cp f-crystals, 2 ill.

Description

The invention relates to well logging, well-known methods for calibrating acoustic logging equipment.

The purpose of the invention is to improve the accuracy of the calibration of acoustic logging equipment by taking into account the systematic error of the equipment when measuring the attenuation coefficient of elastic waves arising due to the difference in the intensities of the emitters of the downhole tool.

The method of calibration of acoustic logging equipment is performed by the following sequence of operations.

1. The borehole tool of the equipment being tested is installed and centered in the reference pipe.

2. Simultaneously with the near-emitter of the device, the electro-acoustic emitter of the installation is excited.

3. Install the transducer between the near emitter and the receiver of the downhole tool.

4. Set the reference values of the interval time of propagation of the DT and the attenuation coefficient of the other wave, moving the electroacoustic emitter to a fixed distance in the direction of the receiver.

5. Record TL and oL values measured by the instrument.

6. Determine the instrumental error by comparing the measured values of T and oL with / LT and about 1 o.

7. Switch electroacoustic transducer to elastic wave receiver mode.

8. Install the transducer in front of the far-emitter of the downhole tool and determine the beginning of the range (0) in the middle of the interval in which the amplitude A has the maximum value.

9. Install the transducer between the far-emitter and the receiver of the downhole tool.

10. Measured at the output of the transducer amplitude Ap elastic waves from the far receiver.

11.Move Converter

the distance S (base probe) in the direction of the receiver downhole tool.

12. Measurement of the amplitude A g of elastic waves from the near-emitter at the output of the transducer.

five

0

five

5 o

five

40

five

thirty

45

50

13.. Determined by the ratio of the amplitudes of the systematic error for the attenuation coefficient. arising from the difference in intensity

emitters dB / m:

l 20. A ,, & ci - Ig -

B ar

14. Repeat for paragraphs. 8-12 operations at various points in the range from O to L, in order to increase the accuracy of determining the intensity of the radiators (L is the distance between the far radiator and the receiver of the downhole tool).

Fig. 1 shows an example of an implementation of a calibration installation for carrying out the proposed method; Figs. 2 is a graph of the amplitude A of elastic waves measured at the output of the transducer versus the distance between it and the emitter of the downhole tool.

The calibration installation contains a reference pipe 1 and a housing 2 filled with liquid 3, an electro-acoustic transducer 4 placed on the outer surface of the pipe 1, a transducer movement mechanism 5 (for example, in the form of a drive and a screw pair) connected mechanically to the transducer 4, a magnitude sensor 6 moving the converter, switch 7, generator B of calibrated electric pulses and meter 9 pulse amplitudes (for example, an oscilloscope).

The calibration unit also contains a downhole tool 10 with two radiators (I1, I2) and one receiver (P), a logging tool 11 and a surface tool 12, the clock pulses from which are fed to the generator 8 of calibrated electrical pulses and the meter 9 of the pulses.

The verification of acoustic logging equipment is performed as follows.

The downhole tool 10 of the test apparatus is installed in the reference pipe 1 and centered in it by means of the tool centralizers.

Switch 7 is set to position A. In this case, simultaneously with the near-emitter I1 of the device, electroacoustic transducer 4 is energized from generator 8 of calibrated electric pulses, which are triggered by ground-based device clock 12. Install converter 4 between the near-emitter I1 and receiver of the downhole device and move it to fixed distances relative to the far-source radiator I2 of the device, set the reference values of the interval time & Td of propagation and coefficient Ani ot elastic waves in the working range of measurements and recorded at these points measured values .rennye apparatus & .T and - The equipment is then determined error tours, comparing the measured values of M and - with standard diesel fuel and oi,.

Then, the switch 7 is set to position B. In this case, the electro-acoustic transducer 4 is connected to the pulse amplitude measuring device 9 and operates as a receiver of elastic waves propagating through the reference pipe from i-. borehole device emitters. First, a transducer is installed between the far-source radiator I2 and the receiver for a distance X relative to the far-emitter and measured

at its output, the amplitude A of other waves from the far-emitter, then the transducer is moved towards the receiver of the downhole tool to a distance S equal to the distance between the radiators of the device, and the amplitude Ag of elastic waves from the near-emitter of the device is measured at its output relative to the amplitudes Ag and A determine the systematic error of the instrument when measuring the attenuation coefficient of elastic waves, which arises due to the difference in the intensity of the radiators of the downhole tool using the formula, dB / m

.. -isA,

(one)

In order to increase the accuracy of determining the difference in the intensities of the emitters, to measure the amplitudes of the elastic waves A and A.

The values of X lie in the range from O to L, where L is the distance between the far source and receiver of the downhole tool. In this case, the difference in the intensities of the emitters can be estimated at all possible amplitudes for a given probe length L and for

calculation of systematic error by the formula (1) (take the average value of A / A and the maximum value

A, / A, f.

The initial position of the transducer X O, at which it is located opposite the far-emitter of the downhole tool, is determined by the midpoint of the interval in which the amplitude A has the maximum value. FIG. Figure 2 shows the experimentally obtained dependence of the amplitude A of elastic waves, measured at the output of the transducer, on the distance X between the transducer and the radiator of the downhole tool with radiator sizes (height along the axis of the device) approximately equal to the transducer sizes.

The proposed method of calibration of acoustic logging equipment in comparison with the known method makes it possible to significantly increase the accuracy of equipment calibration by determining the systematic error of the equipment when measuring the attenuation coefficient ot of elastic waves.

20 25

Claims (3)

The invention relates to well-geophysical well studies, and in particular to methods for calibrating acoustic logging equipment. The purpose of the invention is to improve the accuracy of the calibration of acoustic logging equipment by taking into account the systematic error of the equipment when measuring the attenuation coefficient of elastic waves arising due to the difference in the intensities of the emitters of the downhole tool. The method of calibration of acoustic logging equipment is performed by the following sequence of operations. 1. The borehole tool of the equipment being tested is installed and centered in the reference pipe. 2. Simultaneously with the near-emitter of the device, the electro-acoustic emitter of the installation is excited. 3. Install the transducer between the near emitter and the receiver of the downhole tool. 4. Set the reference values of the interval time of propagation of the DT and the attenuation coefficient oL of the other wave, moving the electro-acoustic emitter to fixed distances towards the receiver 5. Register the values of CT and oL measured by the equipment. 6. Determine the instrumental error by comparing the measured values of T and oL with / LT and about 1 o. 7. Switch electroacoustic transducer to receive mode of elastic waves. 8. Install the converter in front of the far-emitter of the downhole tool and determine the beginning of the range (0) in the middle of the interval in which the amplitude A has the maximum value. 9. Install a transducer between the far-source transmitter and the downhole tool. 10. Measured at the output of the transducer, the amplitude Ap of elastic waves from the far receiver. 11. Move the transducer to distance S (probe base) to the receiver side of the downhole tool. 12. At the output of the transducer, measure the amplitude A g of elastic waves from the near emitter. 13. Determine the systematic error of the attenuation coefficient l with respect to the amplitudes. arising from the difference in intensity of emitters, dB / m: l 20. A ,, & ci - Ig - bAr 14. Repeat para. 8-12 operations at various points in the range from O to L, in order to increase the accuracy of determining the intensity of the radiators (L is the distance between the far radiator and the receiver of the downhole tool). FIG. 1 shows an example of an implementation of a calibration installation for carrying out the method of the present invention; FIG. 2 is a graph of the amplitude A of elastic waves measured at the output of the transducer versus the distance between it and the emitter of the downhole tool. The calibration installation contains a reference pipe 1 and a housing 2 filled with liquid 3, an electro-acoustic transducer 4 placed on the outer surface of the pipe 1, a transducer movement mechanism 5 (for example, in the form of a drive and a screw pair) connected mechanically to the transducer 4, a magnitude sensor 6 moving the converter, switch 7, generator B of calibrated electric pulses and meter 9 pulse amplitudes (for example, an oscilloscope). The calibration unit also contains a downhole tool 10 with two radiators (I1, I2) and one receiver (P), a logging tool 11 and a surface tool 12, the clock pulses from which are fed to the generator 8 of calibrated electrical pulses and the meter 9 of the pulses. The verification of acoustic logging equipment is performed as follows. The downhole tool 10 of the test apparatus is installed in the reference pipe 1 and centered in it by means of the tool centralizers. Switch 7 is set to position A. In this case, simultaneously with the near-emitter I1 of the device, electroacoustic transducer 4 is energized from generator 8 of calibrated electric pulses, which are triggered by ground-based device clock 12. Install converter 4 between the near-emitter I1 and receiver of the downhole device and move it to fixed distances relative to the far-source radiator I2 of the device, set reference values for the interval time & Td of propagation and the coefficient Ani ot elastic waves in the working range of measurements and recorded at these points measurable values .rennye apparatus & .T sZatem determined and the Machine errors stages, comparing the measured values of M and - with standard diesel fuel and oi,. Then, the switch 7 is set to position B. In this case, the electroacoustic transducer 4 is connected to the pulse amplitude measuring device 9 and operates as a receiver of elastic waves propagating through the reference tube from i-. borehole device emitters. First, the transducer is installed between the far-end radiator I2 and the receiver at a distance X relative to the far-end radiator and the amplitude A of other waves from the far radiator is measured at its output, then the transducer is moved to the receiver side of the downhole tool at a distance S equal to the distance between the radiators device, and measured at its output, the amplitude Ag of elastic waves from the near emitter of the device with respect to the amplitudes Ag and A determine the systematic error of the equipment when measuring the attenuation coefficient elastic waves arising due to the difference in the intensity of the radiators of the downhole tool using the formula, dB / m. -isA. In order to improve the accuracy of determining the difference in the intensities of the emitters, measuring the amplitudes of the elastic waves A and A.- produced at several b X values lying in the range from O to L, where L is the distance between the far-source transmitter and the receiver of the downhole tool. At the same time, the difference in intensity of the emitters can be estimated at all possible amplitudes for a given probe length L and to calculate the systematic error using formula (1) (take the average value A / A and the maximum value A, / A, f. The initial position of the converter X O, where it is located opposite the far-emitter of the downhole tool, is determined by the middle of the interval in which the amplitude A has the maximum value Figure 2 shows the experimentally obtained dependence of the amplitude A of the elastic waves measured at the output of The generator, from the distance X between the transducer and the emitter of the downhole tool with radiator dimensions (height along the axis of the instrument) is approximately equal to the transducer's size. The proposed method of calibration of acoustic logging equipment in comparison with the known one can significantly improve the accuracy of instrument calibration by determining the systematic error instrumentation in measuring the attenuation coefficient ot of elastic waves. Claim 1. Method of calibration of acoustic logging equipment, based on measurement of parameters of elastic waves propagating along a reference pipe filled with liquid, from a transmitter of a downhole tool and an electro-acoustic transducer moved along the outer surface of a pipe along it, characterized in that The accuracy of the calibration due to the systematic error resulting from the difference in the intensities of the emitters of a multi-element downhole tool is additionally measured at the output In an electroacoustic converter, the amplitude A – p of elastic waves propagating through the reference tube from the far emitter, the converter is set to the initial / position between the far source and receiver of the downhole tool, then measured at the output of the transducer, the amplitude Ag of elastic waves propagating along the reference tube from transducer, moving the electroacoustic transducer towards the receiver of the downhole tool to a distance S equal to the distance between the radiators of the device relative to determining amplitudes of the systematic error in the measurement apparatus extinction coefficient cA elastic waves, 2. The method according to claim 1, characterized in that the amplitudes of the elastic waves Ag and A are measured at different distances of the electro-acoustic transducer relative to the far-side radiator of the downhole tool or at continuous moving the electroacoustic transducer in the range from the initial position to L, where L is the distance between the far transmitter and receiver of the downhole tool, 3. The method according to paragraphs. 1 and 2, characterized in that the initial position of the electroacoustic transducer is determined by the midpoint of the interval in which the amplitude A. has a maximum value when the transducer is moved past the far-emitter. dmm FI9.2