RU2523770C1 - Procedure for pulsed neutron logging and facility for its implementation - Google Patents

Abstract

FIELD: oil and gas industry.

SUBSTANCE: rocks are irradiated by pulses of a fast neutron generator, inelastic gamma ray spectrometry (IGRS) for neutrons and http://alk.pp.ru:8080/c/m.exe?t=4301645_1_2 The device for pulsed neutron logging is also claimed, and the device comprises a fast neutron generator placed in a protective casing, a scintillation gamma-ray detector coupled optically to a photomultiplier tube, a screen between the fast neutron generator and scintillation gamma-ray detector, an analogue-code converter, the central processing unit, a receiver-transmitter unit, the first and second memory units, a high-voltage software-programmable unit characterised by equipment with an auxiliary time-mode control unit for the fast neutron generator.

EFFECT: improvement of accuracy during pulsed neutron logging.

2 cl, 7 dwg

Description

The invention relates to nuclear geophysics, and more particularly to the field of nuclear physical determinations of the mass contents of elements composing a rock by the method of spectrometric pulsed neutron gamma-ray logging. In particular, the invention can be used to perform carbon-oxygen logging to determine the current oil saturation of reservoir layers crossed by a well.

The known method [1] of pulsed neutron logging, which consists in irradiating rock with pulsed streams of fast neutrons with subsequent registration as a result of the interaction of fast neutrons with the nuclei of rock elements surrounding the downhole tool, inelastic scattering gamma radiation (GINR) and gamma radiation radiation capture (GIRZ). In inelastic scattering and radiation capture, the resulting gamma radiation is characteristic of each element composing the rock. An analysis of the recorded spectra of GINR and GIRZ allows one to obtain information about those elements whose characteristic lines are presented in the recorded spectra. In particular, GINR from carbon and oxygen nuclei allows one to determine the mass contents of carbon and oxygen and through this parameter to reach the oil saturation of reservoirs. GINR reactions occur at neutron energies up to the first MeV. A pulsed neutron generator emits neutrons with an energy of 14 MeV. In a “typical” section (the vast majority of potential hydrocarbon deposits), the time of fast neutron deceleration to lower energy thresholds, at which the GINR reaction is still possible, is 0.1-1 μs, which imposes the possibility of recording the GINR spectra only during the neutron pulse of the generator. Since the lifetime of thermal neutrons in a “typical” section is of the order of hundreds of microseconds, thermal neutrons from previous pulses will still exist in the rock at the moment of generation of neutron pulses at the moment of the generator radiation in the rock, and therefore there will be a background SHIR. The background GIRZ also arises in the case of thermalization of fast neutrons of the generator induced directly in a given neutron pulse. Thus, during the operation of the neutron generator, the GINR spectra are recorded against the background of the GIRZ. Pure GIRZ spectra can be recorded several microseconds after the end of the neutron pulse. Obtaining a “clean” GINR spectrum, the spectrum of which contains information from a number of rock elements of interest, occurs by subtracting from the GINR + GIRZ spectra measured during the neutron pulse, the GIRR spectra measured after the neutron pulse. In this method, neutron generation occurs at a frequency of 20 kHz. The window duration in which the GINR + GIRZ spectra are recorded is 15 μs. The duration of the GIRZ spectrum measurement window is 35 μs. Spectra are accumulated inside the downhole tool and then transmitted to the surface. A time analyzer for 250 channels, included in the recording path of the downhole tool, allows you to track the position of the neutron pulse and adjust the position of the time windows for recording the GINR and GIRZ spectra. Obviously, the process of recording the GINR spectra for their subsequent analysis is an optimization process. Firstly: continuous emission of neutrons from a generator with a fixed neutron yield allows one to obtain the maximum statistics of the GINR + GINR spectra with a relatively minimal load on the measuring path. However, the inability to measure the GIRZ spectrum does not allow us to calculate the “clean” GINR spectrum. An increase in the ratio of the duration of neutron pulses to their duration (duty cycle of neutron pulses) with a fixed neutron yield increases the load of the recording path at the time of recording the GINR + GIRZ spectra and, ultimately, leads to miscalculations and loss of information. The simplest option from the point of view of the recorded spectra is to generate a short (1-2 μs) neutron burst with a power that provides working loading of the spectrometric path of the downhole tool and registration of a gamma quantum in a time window that coincides with the time of the neutron pulse. Most likely, this will be the ginr gamma quantum. Then, after a few microseconds, the GIRZ spectrum is measured and a new neutron pulse is produced after a time when all the neutrons of the transmitted flare are absorbed by the rock. However, this option requires a tremendous amount of time to compile statistics on recorded GINR spectra. The disadvantage of this method is the inability to optimize the measurement, depending on the specific geological and technical conditions for downhole measurements. Correction of the position of the boundaries of the time window for recording the GINR + GIRZ spectra is not enough to optimize measurements.

The known method [3], in which to optimize the measurement modes change the duration of the neutron pulse. To measure the neutron lifetime in the near-wellbore space and the well structure, a relatively weak neutron pulse is first generated, allowing measurements to be made at times as close as possible to the neutron pulse. Its relatively low power allows measurement data to be carried out without overloading the measuring path. This is followed by a more powerful and longer neutron pulse, designed to provide measurements at times representing rock. Due to the fact that this optimization is carried out to measure the lifetime of thermal neutrons in a rock and is strictly set during the manufacture of a downhole tool, the disadvantages of this method include the inability to change, for example, at a given frequency of operation of a neutron generator, the duty cycle of neutron pulses in order to optimize the modes measurements.

A device [2] for conducting pulsed neutron logging. The device contains a pulsed neutron generator, a protection against direct radiation, a gamma-ray detector and a photoelectronic multiplier, an amplifier, an amplitude pulse analyzer, a programming unit, a temperature sensor, a buffer memory, and a telemetry unit located in a protective casing. The generator emits pulses of fast neutrons. The gamma radiation induced by these neutrons registers a gamma-ray detector optically connected to a photoelectronic multiplier, the signal from which, after the amplifier, is fed to an amplitude pulse analyzer, where it is converted to digital form. The programming unit sets the required operating modes, including Defines the time boundaries for the accumulation of spectra. The recorded spectra are stored in a buffer memory; communication with a terrestrial computer is carried out by telemetry.

The disadvantage of this device is the inability to control the operating mode of a pulsed neutron generator in terms of changing the duty cycle of neutron pulses by changing its duration. This does not allow for a given frequency and neutron output of a pulsed neutron generator to measure the GINR spectra with the smallest statistical errors.

A device [1] is known that contains a pulsed neutron source inside the guard, protection of the detector from direct radiation, a scintillation detector optically connected to a photoelectronic multiplier, a multi-parameter analyzer that performs the functions of both an energy and a time analyzer, a detector counting speed controller, a processor unit, memory, input-output information block.

The disadvantage of this device is the irreversibility of setting the time limits for recording the GINR and GIRZ spectra, the impossibility of changing the time modes of the neutron generator — while maintaining the frequency of generation of neutron pulses, it is not possible to change their duration.

Closest to the claimed method is a method of pulsed neutron logging [4], which consists in periodically irradiating rocks with pulses of a fast neutron generator, registering neutron neutron and thermal neutron scattering detectors with real-time gamma radiation detector while continuously moving the downhole tool and the specified quantization step in accordance with depth. The accumulation within the given time cycle of the full amplitude-time spectra of the GINR and GIRZ thermal neutrons over the entire energy range is carried out in i fixed time intervals (i belongs to the interval from 2 to infinity and the position i of fixed time windows is set before the start of downhole research). Usually in practice, 20-30 time intervals of 2-6 microseconds are used. Upon completion of the accumulation of the full amplitude-time spectra, upon request to the downhole tool, the accumulated information is transferred to the surface, where the position of the neutron pulse is calculated, and by summing the previously recorded initial spectra, the GINR + GIRZ spectra during the neutron pulse and the background GIRZ spectrum are obtained. This method allows you to set the temporal boundaries of the summation of the spectra after registration, which, of course, is an advantage. For example, it is possible to process previously registered information using any new algorithms.

The disadvantage of this method is the inability to optimize the accumulation modes of the GINR and GIRZ spectra depending on the measurement statistics. A rigidly specified mode of operation of the neutron generator does not allow varying the set of statistics in the GINR or GIRZ spectra by changing the duty cycle of neutron pulses. As practice shows, industrial generators are tuned to a specific frequency of operation, close to optimal. However, a 2–4-fold spread of the neutron pulse width at a fixed output often provides redundant statistics for the total GINR + GIRZ spectra and does not provide the statistics for the background GIRR spectrum and vice versa. Thus, the optimal mode of operation of the neutron generator cannot be predicted in advance and it is desirable to adjust it depending on specific geological and technical conditions.

Closest to the proposed device is a device for pulsed neutron logging [4], comprising a pulsed fast neutron generator located inside the guard, a shield for protection from direct radiation, a gamma-ray scintillation detector, optically connected to a photoelectron multiplier. A shield for direct radiation protection is located between the pulsed fast neutron generator and the scintillation detector. The device also contains an analog-to-code conversion unit, a central processor unit, a transceiver unit, first and second memory units, a program-controlled high voltage power supply unit of a photoelectronic multiplier, a secondary voltage source, upper and lower connectors.

The disadvantage of this device is the lack of blocks and connections for controlling the temporal modes of operation of a pulsed neutron generator, which does not allow you to configure its duration of the neutron pulse to optimize the measurement of GINR spectra.

The present invention solves the problem of improving accuracy when conducting pulsed neutron logging by changing the duration of the generation of neutron pulses, which minimizes the statistical error in measuring the GINR spectra at a given frequency and neutron output of a pulsed neutron generator.

To solve this problem, a method of pulsed neutron gamma-ray logging, including periodic irradiation of rocks with pulses of a fast neutron generator, registration of gamma radiation of inelastic scattering (GINR) of neutrons and gamma radiation of radiation capture (GIRZ) of thermal neutrons by a real-time gamma radiation detector with continuous movement of the downhole tool and a given quantization step in depth, the accumulation within the specified time cycle of the full amplitude-time spectra of gamma and of inelastic neutron scattering radiation and gamma radiation of thermal neutron capture over the entire energy range in I fixed time windows, where i belongs to the interval from 2 to infinity, and the position i of fixed time windows is set before the start of borehole studies, after the accumulation of the full amplitude-time of gamma radiation spectra of inelastic neutron scattering and gamma radiation of radiation capture of thermal neutrons upon request to the downhole tool transmit to the surface l information, from the amplitude-time spectra transmitted to the surface through the transceiver unit, the time spectrum of the integral count rates changes, which is processed in the analog-code converter unit, is calculated, the boundaries of the time intervals and their position relative to the pulse of the fast neutron generator are set in real time , accumulation in one of the memory blocks of the full amplitude spectra of gamma radiation of inelastic neutron scattering and gamma radiation of radiation thermal neutron capture is carried out within the established time intervals by summing the data accumulated and transmitted to the surface, it additionally provides for determining the optimal pulse duration, for which the downhole tool, after adjusting the recording spectrometric path and heating, is switched on in the neutron generation mode with the maximum neutron pulse duty cycle, applied type of pulsed neutron generator, produce a set of spectra GINR and GIRZ for the time corresponding to the depth quantum during its passage at a given speed of the downhole tool, calculate the statistical error in the given energy regions of the obtained GINR spectra, increase the neutron pulse duration by ΔТ, where the ΔТ value corresponds to the first microseconds, and again set the GINR and GIRZ spectra for a given time and calculate a new statistical error in the given energy regions of the obtained GINR spectra, repeat a similar procedure to the minimum possible the desired value of the duty cycle of neutron pulses, and, based on constantly performed calculations of statistical errors, determine the optimal duration of the neutron pulse.

To solve this problem, a pulsed neutron gamma-ray logging device containing a pulsed fast neutron generator located in a guard, a scintillation gamma-ray detector optically connected to a photoelectronic multiplier, a screen located between the pulsed fast neutron generator and a scintillation detector, an analog- code ”, central processor unit, transceiver unit, first and second memory units, program-controlled high-voltage power supply unit photoelectronic multiplier, secondary voltage source, upper connector, lower connector, while the output of the photoelectronic multiplier is connected to the first input of the analog-to-code conversion unit, the second input of the analog-code conversion unit is connected to the first output of the central processor unit, data bus of the unit the analog-to-code conversion is connected in output to the corresponding inputs of the data buses of the first and second memory blocks, bidirectional inputs and outputs of the first and second memory blocks are connected to the corresponding first and second with the directed inputs and outputs of the central processor unit, the second output of the central processor unit is connected to the first input of the program-controlled high voltage supply unit of the photoelectronic multiplier, the output of which is connected to the input of the photoelectronic multiplier, the third bi-directional input-output of the central processor unit is connected to the third bi-directional output of the transceiver unit , the fourth bi-directional input-output of the CPU unit is connected to the bi-directional input-output of the pulse neutron generator, the output of the transceiver unit is connected to the input of the secondary voltage source, the first, second, third, fourth, fifth and sixth outputs of which are connected to the corresponding inputs of the analog-to-code conversion unit, the first memory unit, the second memory unit, the central processor unit, a software-controlled high voltage power supply unit of a photoelectronic multiplier, a transceiver unit, the first and second bi-directional inputs and outputs of the transceiver unit are connected, respectively, to the first and to the second contacts of the upper and lower connectors, the third contact of the upper connector is connected to the input of the pulsed neutron generator, further comprises a control unit for the temporary mode of the pulsed neutron generator, connected at the first and second inputs to the third output of the central processor unit and the seventh output of the secondary voltage source, and the output control unit of the temporary regime of a pulsed neutron generator is connected to the control input of a pulsed neutron generator.

Due to this, it becomes possible to change the duration of the neutron pulse of a pulsed neutron generator and, thereby, optimize the measurement mode of the GINR spectra.

As a result of solving this problem, the statistical accuracy of obtaining the GINR spectra increases.

The technical essence of the invention is illustrated by drawings, which depict:

figure 1 presents the device pulsed neutron gamma ray logging;

figure 2 shows a diagram of the formation of a temporary spectrum of changes in the integral count rates;

figure 3 shows the time spectrum of the pulsed neutron gamma ray equipment with the maximum possible duty cycle of a neutron pulse for this type of equipment;

figure 4 shows the time spectrum of the equipment of pulsed neutron gamma-ray logging with a duty cycle of a neutron pulse that provides the minimum statistical error in obtaining the GINR spectrum.

figure 5 shows the time spectrum of the pulsed neutron gamma ray equipment with the maximum possible duty cycle of a neutron pulse for this type of equipment;

figure 6 shows the borehole diagrams obtained when setting the time mode of operation of a pulsed neutron generator — statistical errors of the calculated ratios from the GINR spectra.

Figure 7 shows fragments of borehole studies demonstrating a significant reduction in the statistical error of the logging results with the proposed tuning method and the “standard” mode of operation of a pulsed neutron generator.

The device for conducting pulsed neutron gamma-ray logging includes a pulsed fast neutron generator 2, a scintillation gamma-ray detector 4 optically connected to a photoelectronic multiplier 5, a screen 3 located between the pulsed fast neutron generator and a scintillation detector, and a conversion unit “ analog code ”6, central processor unit 7, transceiver unit 8, first 9 and second 10 memory blocks, program-controlled high-voltage photocell supply unit the throne multiplier 11, the secondary voltage source 12, the upper connector 13, the lower connector 14, while the output of the photomultiplier 5 is connected to the first input of the analog-to-code conversion unit 6, the second input of the analog-code conversion unit 6 is connected to the first output CPU unit 7, the data bus of the analog-to-code conversion unit 6 is connected to the corresponding inputs of the data buses of the first 9 and second 10 memory blocks, the bi-directional inputs and outputs of the first 9 and second 10 memory blocks are connected to the corresponding first and the second bi-directional inputs and outputs of the central processor unit 7, the second output of the central processor unit 7 is connected to the first input of the software-controlled high voltage power supply unit of the photomultiplier tube 11, the output of which is connected to the input of the photomultiplier 5, the third bi-directional input-output unit of the central processor 7 is connected with the third bi-directional output of the transceiver unit 8, the fourth bi-directional input-output of the central processor unit 7 is connected to the bi-directional input-in the output of the pulsed neutron generator 2, the output of the transceiver unit 8 is connected to the input of the secondary voltage source 12, the first, second, third, fourth, fifth and sixth outputs of which are connected to the corresponding inputs of the analog-to-code conversion unit 6, the first memory unit 9, the second a memory unit 10, a central processor unit 7, a software-controlled high voltage power supply unit of a photomultiplier tube 11, a transceiver unit 8, the first and second bi-directional inputs / outputs of the transceiver unit 8 values, respectively, to the first and second contacts of the upper 13 and lower 14 connectors, the third contact of the upper connector 13 is connected to the input of a pulsed neutron generator 2.

The device further comprises a control unit 15 for the temporary mode of the pulsed neutron generator 2, connected at the first and second inputs to the third output of the central processor unit 7 and the seventh output of the secondary voltage source 12, with its output a control unit for the temporary 15 mode of the pulsed neutron generator 2 connected to the control input of the pulsed neutron generator 2.

The invention is implemented as follows.

In the protective casing 1 having the upper 13 and lower 14 connectors, the electronic units of the device are located. When a secondary voltage source 12 is supplied to the upper connector 13, the supply voltage starts to work. As a result of its operation, the necessary voltages appear for supplying the analog-to-code conversion unit 6, central processor unit 7, transceiver unit 8, first 9 and second 10 memory blocks, a software-controlled high voltage power supply unit of the photoelectronic multiplier 11, a control unit 15 of the temporary regime of a pulsed neutron generator. The pulsed neutron generator 2 is powered separately by the third core of the geophysical cable connected to the upper connector 13. When the power appears, the unit of the central processor 7 starts to work according to the program located in its permanent storage device. As a result of this, the first 9 and second 10 memory blocks are cleared, the necessary parameters of the analog-to-code conversion block 6 are programmed, for example, gain and discrimination level, the program-controlled high voltage block 11 of the power supply of the photoelectronic multiplier is set up. In this case, one of the two blocks of accumulation of amplitude-time spectra is switched on in the mode of accumulation of spectra from the analog-to-code conversion unit 6, the other in the mode of operation with the central processor unit 7. After that, the device is ready to receive control commands from the surface. The command is received by the transceiver unit 8 and transmitted for decryption and execution to the central processor unit 7. When executing the command, the central processor unit 7 sets the transmitted gain, overlap rejection level, and lower level of discrimination of the analog path on the analog-code conversion unit 6. One of the two memory blocks 9 or 10 is switched on in the spectral accumulation mode, the other, respectively, through the central processor unit 7 and the transceiver unit 8 can transmit information at the time from the surface to the on-board computer.

Preparation for the operating mode of logging begins by commands from the on-board computer to turn on the pulsed neutron generator 2. According to these commands, the on-board computer through the block of the transceiver 8 and the block of the central processor 7 via a bi-directional communication line with the pulsed neutron generator 2 initializes the processes of its preparation for work, which, depending on the modification of the neutron generator 2 used, can take from 2 to 10 minutes. After the preparation of the pulsed neutron generator 2 is completed, the latter informs the on-board computer of readiness via a bi-directional communication line with the central processor unit 7 through the transceiver unit 8.

Actually pulsed neutron logging begins at the command of turning on the generator 2 in work. In this case, the required frequency and duration of neutron pulses are transmitted to the central processor unit 7 from a ground computer. The values obtained by the central processor unit 7 transmits to the control unit 15 the temporary mode of the pulsed neutron generator, which, in turn, generates a sequence of pulses at the control input of the pulsed neutron generator 2. Moreover, the frequency and duration of the 2 pulses generated at the control input of the pulsed neutron generator 2 must correspond to the required frequency and duration of neutron pulses - there is an external synchronization of the operation of a pulsed neutron generator 2, which It begins to emit pulses of neutrons. Screen 3 serves to protect the scintillation detector from direct radiation of a pulsed fast neutron generator 2. Gamma radiation induced by neutrons is detected by a scintillation detector 4. As a result of the interaction of gamma quanta with the phosphor of scintillation detector 4, the latter converts gamma radiation energy into light flashes - scintillation . In this case, the total number of emitted photons is proportional to the energy left by the gamma ray in the detector 4. Next, the photoelectron multiplier 5 converts the light pulse into an electric pulse. The charge collected from the output of the photoelectron multiplier 5, ceteris paribus, is proportional to the number of scintillations of the phosphor of the detector 4, and, therefore, the energy left by the gamma quantum in the detector 4. In traditional switching schemes, the photoelectron multiplier 5 is the current source to the output of which “analog-to-code” converter 6. As a result of the operation of the “analog-to-code” converter 6, a digital code appears on the output of the latter, proportional to the energy of the gamma quantum left in the scintillation detector e 4.

From the output of the analog-to-code conversion unit 6, the data is fed to the input of the memory blocks 9 and 10. In this case, one of the memory blocks is switched on in the spectral accumulation mode, the other at this moment can transfer the accumulated spectra to the central processor unit 7 via the serial interface. In this way, the process of accumulation of amplitude-time spectra occurs.

Functionally, the upper 13 and lower 14 connectors, a secondary voltage source 12, an analog-to-code conversion unit 6, a central processor unit 7, a transceiver unit 8, the first 9 and second 10 memory blocks, a program-controlled high voltage power supply unit of the photoelectric multiplier 11 can to be performed as in the prototype. In the central processor unit, an additional standard serial interface line should be provided for transferring operating modes to the control unit 15 for the temporary mode of a pulsed neutron generator, which is a programmable pulse sequence generator. As a pulsed neutron generator 2, MFNG-701 [5] can be used, which provides for a change in the time modes of operation in a wide range of external synchronization pulses.

Figure 2 shows one of the possible options for the formation of the amplitude-time spectrum.

The proposed method solves the problem of increasing accuracy during pulsed neutron logging by providing a registration mode that most fully takes into account the real geological and technical conditions for measurements and the specific features of a pulsed neutron generator. Since the optimization process is possible only within a certain framework, limited by the technical capabilities of the pulsed neutron tube and its control system, it is advisable to carry out optimization with a fixed neutron output and the frequency of the neutron generator by a parameter such as the duration of the neutron pulse.

The downhole tool is placed in the recording interval. The neutron generator 2 emits neutron pulses with a certain frequency, for example with a fixed frequency of 10 kHz. At the beginning of each emission cycle, the control unit 15 of the time mode of the pulsed neutron generator gives a synchronization pulse, along which the neutron tube begins to “kindle”. After a few microseconds necessary to turn on the neutron tube, the latter begins to emit neutrons with an energy of 14 MeV. The neutron pulse at the initial moment of operation is set by the synchronizing sequence from the control unit 15 of the temporary mode of the pulsed neutron generator with a minimum duration. For example, 5 microseconds. Figure 3 shows the time spectrum of the pulsed neutron gamma-ray logging equipment with the practically maximum possible neutron pulse duty cycle for equipment such as AIMS-E and MFNG-701.

The recorded GINR and GIRZ spectra are transmitted to the surface to calculate the statistical error of the obtained ratio of the count rates in the GINR spectrum. In this case [6], we are talking about the C / O parameter (carbon / oxygen logging), which allows us to estimate the current oil saturation of reservoirs. Calculations can be performed in accordance with [6]. After collecting statistics on a command from the on-board computer through the transceiver 8 and the central processor 7, the control unit 15 is reprogrammed with the temporary regime of a pulsed neutron generator to increase the duration of the synchronizing pulse. This leads to a corresponding increase in the duration of the neutron pulse of the generator. Figure 4 shows the time spectrum of the pulsed neutron gamma-ray logging equipment with an average neutron pulse duration for AIMS-E and MFNG-701 type equipment.

Simultaneously with the increase in the duration of the neutron pulse, the accelerating voltage on the neutron tube of the pulsed neutron generator is reduced to maintain the constancy of the neutron yield reduced to a single time interval (for example, to a second).

With the new set value of the neutron pulse duration, the GINR and GIRZ spectra are again set, transferred to the on-board computer, and the statistical error of the obtained ratio of the counting rates in the GINR spectrum is calculated. Then again change the duration of the neutron pulse. The procedure is repeated until the neutron pulse duty cycle is of the order of 2 — a further decrease in duty cycle is irrational. Figure 5 shows the time spectrum of the pulsed neutron gamma-ray logging equipment with an almost minimally appropriate neutron pulse duty cycle for equipment like AIMS-E and MFNG-701.

The dependence of the statistical error on the time mode of operation of a pulsed neutron generator is built. Figure 6 shows the results of practical tuning to the optimal mode of operation of a pulsed neutron generator MFNG-701 as part of the AIMS-E equipment. Each second, the GINR and GIRZ spectra are transmitted from the downhole tool to the surface, the ratio of the count rates in the carbon and oxygen windows is calculated, but the average value of the ratio and its mean square error are calculated. It is clearly seen that the operating mode of a pulsed neutron generator, implemented at 200-350 seconds of measurement, is the most successful from the point of view of minimizing the statistical error of the measurements. Actually borehole research is carried out precisely at this operating mode of a pulsed neutron generator. Figure 7 shows fragments of borehole studies demonstrating a significant reduction in the statistical error of the logging results with the proposed tuning method (track on the far right) and the “standard” mode of operation (second track on the right) of a pulsed neutron generator.

The method and device for pulsed neutron logging described above are implemented in the AIMS-E apparatus, working in conjunction with a pulsed high-frequency neutron generator MFNG-701.

Information sources

1. “The multiparameter spectroscopy instrument continuous carbon / oxygen log - MSI C / O”, DMChace, MGSchmidt, Dresser Atlas, Dresser Industries, Inc., Houston, Texas, MPDucheck, Dresser Atlas, Dresser Industries, Inc., Calgary, Alberta , Presented at the Canadian Well Logging Society 10 ^th Formation Evaluation Symposium, Calgary, Alberta, September 29 - October 2, 1985.

2. “Methods and apparatus for borehole-corrected spectral analysis of earth formations." US patent No. 4661701, Schlumberger Technology Corporation, Inventor: James A. Gran, Danbury, Conn., Jul. 17, 1985.

3. USA patent. US 7,365,307, Apr. 29,2008, Christian Stoller, Princeton Junction, NJ (US); Peter Wraight, Skillman, NJ (US); Robert A. Adolph, Pennington, NJ (US). Schlumberger Technology Corporation.

4. RF patent No. 2262124, “Method of pulsed neutron gamma-ray logging and device for its implementation”, Bortasevich BC, Khamatdinov RT, Chermensky VG, Velizhanin VA, Sarantsev SN, 26.05. 2004 year

5. Agalakova MI, Butolin SL, Chermensky VG, “New generation pulsed neutron generators developed by NPP Energiya LLC in downhole geophysics”, Collection of reports of the international scientific and technical conference “Portable neutron generators and technologies based on them ”, October 22-26, 2012, VNIIA, Moscow.

6. Instructions for conducting pulsed spectrometric neutron gamma-ray logging with AIMS series equipment and processing measurement results when assessing the current oil saturation of rocks, MI41-17-1399-04 / V.A. Velizhanin, BC Bortasevich, DR Loboda, V. G. . Chermensky et al., Tver: Publishing House. HERS. 2004.

Claims (2)

1. The method of pulsed neutron gamma-ray logging, including periodic irradiation of rocks with pulses of a fast neutron generator, registration of gamma radiation of inelastic scattering (GINR) of neutrons and gamma radiation of radiation capture (GIRZ) of thermal neutrons by a real-time gamma radiation detector with continuous movement of the downhole tool and a given quantization step in depth, accumulation within the specified time cycle of the full amplitude-time spectra of inelastic scattering gamma radiation neutrons and gamma radiation of radiation capture of thermal neutrons over the entire energy range in i fixed time windows, where i belongs to the interval from 2 to infinity, and the position i of fixed time windows is set before the start of downhole research, after the accumulation of the full amplitude-time spectra of gamma- radiation of inelastic neutron scattering and gamma radiation of radiation capture of thermal neutrons upon request to the downhole tool transmit information to the surface, transmitted to the surface through the transceiver unit to the amplitude-time spectra calculate the time spectrum of the change in the integral count rates, which is processed in the analog-to-code converter unit, according to the results of processing in real time, the boundaries of the time intervals and their position relative to the pulse of the fast neutron generator are established, accumulation in one of the blocks memory of the full amplitude spectra of gamma radiation of inelastic neutron scattering and gamma radiation of radiation capture of thermal neutrons stvlyayut within specified time intervals by summing the accumulated and transmitted on the data surface, wherein that before the measurement process, the optimal pulse duration is additionally determined, for which the downhole tool, after adjusting the recording spectrometric path and heating, is switched on in the neutron generation mode with the maximum neutron pulse duty cycle provided by the type of pulsed neutron generator used, a set of GINR and GIRZ spectra is performed for the time, corresponding to the quantum of depth when it passes at a given speed of the downhole tool, calculate the statistical error in the given energy regions of the obtained GINR spectra, increase the neutron pulse duration by ΔТ, where ΔТ corresponds to the first microseconds, again set the GINR and GIRZ spectra for a given time and calculate a new statistical error in the given energy regions of the obtained GINR spectra, repeat the similar procedure to the minimum possible value of the duty cycle of neutron pulses, and, based on constantly conducted calculations of statistical errors, determine the opt mal neutron pulse and with a pulse duration of irradiation is performed periodically rocks. 2. A pulsed neutron gamma-ray logging device containing a pulsed fast neutron generator located in a guard, a gamma-ray scintillation detector optically connected to a photoelectronic multiplier, a screen located between the fast-neutron pulsed generator and a scintillation detector, an analog-to-code conversion unit , central processor unit, transceiver unit, first and second memory units, program-controlled high-voltage power supply unit of a photomultiplier tube, is secondary voltage index, upper connector, lower connector, while the output of the photomultiplier is connected to the first input of the analog-to-code conversion unit, the second input of the analog-to-code conversion unit is connected to the first output of the central processor unit, the data bus of the conversion unit is analog "exit code" is associated with the corresponding inputs of the data buses of the first and second memory blocks, bidirectional inputs and outputs of the first and second memory blocks are associated with the corresponding first and second bi-directional inputs / outputs of the block the central processor, the second output of the central processor unit is connected to the first input of the program-controlled high voltage power supply of the photomultiplier tube, the output of which is connected to the input of the photoelectronic multiplier, the third bi-directional input-output of the central processor unit is connected to the third bi-directional output of the transceiver unit, the fourth bidirectional input is the output of the central processor unit is connected to the bidirectional input-output of a pulsed neutron generator, the output of the unit the emitter is connected to the input of the secondary voltage source, the first, second, third, fourth, fifth and sixth outputs of which are connected to the corresponding inputs of the analog-to-code conversion unit, the first memory unit, the second memory unit, the central processor unit, the program-controlled high unit the voltage of the photoelectronic multiplier, the transceiver unit, the first and second bi-directional inputs and outputs of the transceiver unit are connected, respectively, to the first and second contacts of the upper and lower plugged connectors, the third upper contact terminal connected to the input of pulse neutron generator, wherein which additionally contains a control unit for the temporary mode of a pulsed neutron generator, which is connected at the first and second inputs to the third output of the central processor unit and the seventh output of the secondary voltage source, and is connected to the control input of the pulsed neutron generator by its output.

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