SU1721224A1 - Hole shot control device - Google Patents

Abstract

The invention relates to well logging and is intended to control perforation explosions when performing hand-held operations. The goal is to increase reliability. The invention makes it possible to increase reliability by receiving an acoustic signal excited by the detonation of perforation charges and propagating through the drilling fluid by the buried sensor 1 in a given time window by the ignition pulse signal. The received signal is filtered in two parallel channels using tunable filters 1, 11 in the range of frequencies depending on the channel, the depth of the expected perforation explosion and the number of charges used. After the standard transformations, the output voltages of the channels are compared with each other, most of them are selected in time, the triggering channel 12 makes a decision about the fact of an explosion and its completeness. In this case, the primary signals of both channels with an ignition pulse are recorded by a logging photo recorder. The use of the device allows for a reduction in well survey costs. 1 il. XJ yu

Description

The invention relates to geophysical exploration of wells, in particular, is intended to fix the explosion and its completeness during perforation.

A device for controlling a perforation explosion containing a receiving acoustic transducer of elastic vibrations propagating along the casing, and a ground control and measuring panel with an amplifier, with a filter with a constant bandwidth of frequencies, a detector, an integrator, a threshold device with an indicator and a photo recorder.

However, the drill pipe string is a communication channel with the characteristic of a band-pass filter, the frequency range of which is in the range of ~ 6-12 kHz. Such high frequencies, propagating over a distance of 3-5 km, experience significant attenuation, caused not only by losses in the pipe material, but also by losses due to reradiation of the acoustic field into the rock. For this reason, there are variations in the attenuation value depending on the rocks crossed by the well and the degree of connection of the casing with the environment. When using lower frequencies due to significant attenuation, the signal level is insufficient. An increase in sensitivity does not lead to the desired result, since noise immunity is simultaneously reduced. Mechanical impacts on the metal structures of the rig excite arcs of waves with a wide frequency spectrum that overlap the specified range. The aforementioned reasons create the conditions for the passage of a perforation explosion or its fixation, when in fact detonation did not occur.

The known device fundamentally does not allow to make a conclusion about the completeness of the perforation explosion. As already noted, the frequency spectrum of the signal is formed by the frequency response of the communication channel (drill pipe string) and for this reason the frequency characteristic is not informational. Since the attenuation value substantially depends on the acoustic parameters of the rocks surrounding the borehole, the connection of the column with rocks and other factors, a half change in the number of detonating charges will have a smaller effect on the signal amplitude than the totality of the listed parameters.

A photo recorder of a known device only detects the triggering of a threshold device, and not the signal itself (a standard well logger cannot register such high frequencies). The resulting diagrams have little information.

The aim of the invention is to increase the reliability of blasting.

This goal is achieved due to the fact that the known device for controlling a perforation explosion containing an elastic oscillation transducer connected to a series-connected amplifier, a first filter, a first detector and a first integrator, a threshold element connected to an audio and first light indicators, a logging recorder is equipped with two matching blocks, a comparison element, two temporary selectors, an inverting block, a shaper, a waiting multivibrator, allowing a trigger, t a unique sound frequency generator, modulator, second filter, second detector, integrator, second and third light indicators, while the elastic vibration transducer is made in the form of a hydrophone installed in the well in the drilling fluid, the first and second filters are tunable with adjacent frequency bands, one of which are higher than the other, with the output of the amplifier connected to the inputs of the second filter and the modulator, the outputs of the integrators connected to two inputs of the comparison element, the output of which is simultaneously connected is connected to the first temporary selector and the inverting unit, and the output of the inverting unit is connected to the input of the second temporary selector, the output of the enable trigger is connected to the second inputs of both temporary selectors, the input of which is connected to the output of the driver, the output of the driver is connected to the input of the waiting multivibrator, the output of which is connected to the installation the input of the enable trigger, the inputs of the two matching blocks are respectively connected to the outputs of the two filters and simultaneously with the output of the driver, the outputs of the matching locks are connected to a logging photorecorder, trigger input audio frequency tone generator connected to the output driver, tone generator and audio frequency output is connected to a modulator whose output is connected to an audio indicator.

When detonation of perforation charges in a well filled with drilling fluid, an acoustic signal arises that arrives at the wellhead through two physical channels — along the drill pipe string and along the drilling fluid. In the known device uses the first channel that transmits relatively high frequencies, but with a large attenuation. This leads to ambiguous conclusions when indicating an explosion. The channel, consisting of a cylindrical cavity filled with drilling fluid, is a waveguide for low-frequency waves of the Lemb type. As experimentally established, the detonation of even a single charge in a well at a bottom depth of about five thousand meters excites an acoustic field lasting about thirty seconds. This process is caused by multiple reflections of the signal at the bottom-surface surface boundaries with insignificant energy losses along the propagation path. The proposed device uses exactly the specified transmission channel.

Since the pressure amplitude drops sharply at the free interface, in order to increase the efficiency of receiving an acoustic signal, the hydrophone must fall to a depth of about 4 of the prevailing signal frequency. The frequency of the excited signal is mainly determined by the frequency of pulsations of the gas bubble that occurs at the time of the explosion of perforation charges, it depends on two main factors - the magnitude (mass) of the explosive charge and the depth of the explosion. In the first case, the dependence is inversely proportional, and in the second case, the pulsation frequency, ceteris paribus, increases with depth.

The boundaries of the cylindrical cavity of the well have a significant effect on the period of pulsation of the gas bubble.

From general physical principles, it can be assumed that the pulsation period is proportional to the distance that passes the boundaries of the gas bubble from the maximum expansion to its collapse.

If we assume that the volume of gas products during the explosion remains constant regardless of the presence or absence of boundaries, then from the equality of the volumes of the spherical and cylindrical cavities, the height of the latter refers to the radius of the sphere, as the ratio of the squares of the radius of the sphere to the radius of the cylindrical cavity h _ 4 z R _С f h2

R sf 3 g _C >'

Substituting the real values of Р _С ф = 150 cm, Hz = 6 cm (Dckb = 120 mm) for the example, we obtain the result b / Р _С ф ~ 870, which suggests that the pulsation period of the gas bubble, ceteris paribus, in a narrow cylindrical cavity (r ^ "PCF) increases by more than two orders of magnitude compared with free space.

Since the number of charges of the punch, the depth of the expected explosion and the diameter of the well are known in advance, the frequency band where the main energy of the oscillatory process is concentrated is also known. In this case, three cases are possible - there is no explosion, a complete explosion, an incomplete explosion. The first of them is not of interest, since there is no acoustic field either. The second is characterized by the coincidence of the main frequency of the acoustic signal with the calculated one, determined by the parameters of the explosion, and the third - by shifting the energy spectrum towards higher frequencies.

Based on the above physical phenomena, a signal is received inside the well by a buried hydrophone. After amplification, the signal is filtered in two parallel channels in the frequency band, one of which corresponds to the calculated one, and the second is biased toward higher frequencies. After standard transformations, including detection and integration, the output voltage of the channels is compared with each other. The greater of the stresses, taking into account the sign, is selectable in time directly or with preliminary inversion. The channel for triggering the threshold device makes a decision about the explosion and its completeness. So, for example, the triggering of a channel with a filter, where the established frequency band corresponds to the calculated one (given explosion depth, well diameter and number of charges), gives reason to conclude that an explosion occurred and, moreover, was complete. An incomplete explosion is identified when the second channel is triggered, the frequency band of which is set higher than the calculated one. The measurement process begins with the appearance of an ignition pulse from an explosive machine, which allows temporary selection in a given time window with a duration determined by the lifetime of the acoustic field excited by the explosion. At the same time, the signals from the outputs of these filters, together with the signal corresponding to the ignition pulse, are fed to a standard log recorder for documenting perforation operations.

The signal of the ignition pulse starts the tone generator of sound frequencies, the signal of which is modulated by the voltage taken from the hydrophone and the amplified amplifier. The modulated sound signals reproduced by the sound indicator are perceived by the operator by ear and, with some training, can be used for operational control, since the explosion signal and random noise bursts have different tonality.

The drawing shows a structural diagram of the proposed device. The device contains a hydrophone 1, an amplifier 2, a first tunable filter 3, a first detector 4, a first integrator 5, matching cascades 6 and 7, a photorecorder 8, a second tunable filter 9, a second detector 10, a second integrator 11, a comparison circuit 12, and a well log 13 elevator, the first temporary selector 14, the inverting stage 15, the driver 16, the first light indicator 17, the second temporary selector 18, the waiting multivibrator 19, the trigger 20 resolution, the second light indicator 21, the third light indicator 22, the current generator 23 sound s frequency modulator 24 and the audible indicator 25.

The hydrophone 1 is connected to an amplifier 2, the output of which is connected to tunable filters 3 and 9, the outputs of the filters are connected to the inputs of two detectors 4 and 10 and simultaneously through the matching stages 6 and 7, are connected to the photo recorder 8, the outputs of two detectors 4 and 10 are connected to the inputs two integrators 5 and 11, and their outputs are connected to two inputs of the comparator 12, the output of the comparator 12 is connected to the first temporary selector 14 and simultaneously through the inverting stage 15 to the second temporary selector 18. each of the temporary selectors the ditch is connected to the indicators 17 and 22, respectively, the driver 16 is connected to the collector 13, and its output is simultaneously connected to the inputs of the matching stages 6 and 7, to the inputs of the standby multivibrator 19 and trigger 20 resolution, the output of the standby multivibrator 19 is connected to the installation input of the trigger 20 resolution and the output of the resolution trigger is connected to the second inputs of the temporary selectors 14 and 18. The triggering input of the tone generator 23 of the sound frequencies is connected to the output of the driver 16, and the output of the tone generator of sound frequencies is connected to a regulator 24, the output of which is connected to the sound indicator 25.

The device operates as follows.

The ignition pulse from the blasting machine through the collector 13 of the logging elevator is fed to the electric detonator of perforation charges and an explosion occurs. The low-frequency acoustic field excited by the pulsations of the gas bubble, propagating through the drilling fluid filling the well, after a while reaches the hydrophone 1. At the same time, the ignition pulse from the collector 13 hits the high-impedance input of the shaper 16. The generated standard pulse from the output of the shaper is fed to the inputs of the waiting multivibrator 19 and trigger 20 permissions. When the resolution trigger is overturned, the blocking voltage is removed from the temporary selectors 14 and 18 and at the same time turns on the light indicator lamp 21, which signals the passage of the ignition pulse. The signal from the hydrophone 1 is amplified in the amplifier 2 and fed to tunable filters 3 and 9. Their parameters and, therefore, the frequency bands are set depending on the diameter of the well, the number of perforation charges and the depth of their installation. In this case, the first of the bandpass filters 3 is tuned to frequencies that correspond to the parameters of the expected explosion, and the tunable filter 9 has a frequency band that is shifted relative to the first towards high frequencies.

If an explosion occurs (complete detonation of all charges), then the acoustic signal without attenuation passes through the tunable filter 3, is detected on the detector 4, and after the integrator 5, the signal envelope voltage goes to the comparison circuit 12. Since the passband of the tunable filter 9 is shifted, the same signal at its output will be attenuated and after passing through similar devices - detector 10, integrator 11, the amplitude of the voltage supplied to the second input of the comparison circuit 12 will be less than the first. In this case, the polarity of the output signal of the comparison circuit 12 turns out to be such that the first time selector 14 is activated (provided that the signal exceeds the threshold level for 10-15 s).

After the operation of the temporary selector 1, the indicator light 17 will turn on and the light will come on, indicating that a complete explosion has occurred. When not all charges are detonated, the signal at the output of the tunable filter 9 will be large in amplitude, and a signal with a voltage of a different polarity will appear at the output of the comparison circuit 12. The first temporary selector 3 for this reason will not work, but thanks to the inverting stage 15, the polarity of the signal will be required to operate the second temporary selector 18. The indicator lamp 22, c, ignoring about an incomplete explosion, will light up. If none of the above two indicators worked, then it can be argued that the explosion did not occur. At the same time, the tone generator 23 of the sound frequencies connected to the modulator 24 is started by the signal from the driver 16, since the control input is connected to the output of the amplifier 2, modulation of the tone signal occurs under the influence of an alternating voltage of the acoustic signal, which will be indicated by the sound indicator 25.

The proposed device eliminates the possibility of triggering from external interference outside the interval of the existence of the acoustic field. To do this, the timing chains of the standby multivibrator 19 are selected so that it rolls over again after a time equal to the signal duration (about 30 s). In this case, the trailing edge of the U-shaped pulse of the waiting multivibrator 19 will set the trigger trigger 20 resolution in its original position, which will block the temporary selectors 14 and 18.

Claims (1)

Claim A control device for a perforation explosion in a well, comprising an elastic oscillation transducer connected to a series-connected amplifier, a first filter, a first detector and a first integrator, a threshold element connected to an audio and first light indicators, a logging recorder, a second filter and a second detector, which that, in order to increase reliability, it is equipped with two matching blocks, a comparison element, two temporary selectors, an inverting block, a shaper waiting for a mule a tivibrator, a trigger trigger, a tone generator of sound frequencies, a modulator, a second integrator, second and third light indicators, while the elastic oscillation transducer is made in the form of a hydrophone with the possibility of installation in the well in the drilling fluid, the first and second filters are tunable with adjacent frequency bands, one of which is higher than the other, with the output of the amplifier connected to the inputs of the second filter and the modulator, the outputs of the integrators connected to two inputs of the comparison element, the output of which simultaneously connected to the first temporary selector and the inverting unit, and the output of the inverting unit is connected to the input of the second temporary selector, the output of the enable trigger is connected to the second inputs of both temporary selectors, the input of which is connected to the output of the driver, the output of the driver is connected to the input of the waiting multivibrator, the output of which is connected to the installation input of the enabling trigger, the inputs of the two matching blocks are respectively connected to the outputs of two filters and simultaneously with the output of the driver Outputs matching blocks are connected to a logging photorecorder, trigger input audio frequency tone generator connected to the output driver, tone generator and audio frequency output is connected to a modulator whose output is connected to an audio indicator.