RU160808U1 - INTEGRATED GEOPHYSICAL EQUIPMENT - Google Patents

Abstract

Integrated geophysical equipment, including an acoustic logging probe, comprising an acoustic insulator body with acoustic emitters and an elastic oscillation receiver, a pulsed neutron logging tool containing a neutron generator and secondary gamma radiation indicators, and a common electronics unit, while the acoustic insulator housing is spaced between acoustic emitters, a receiver of elastic vibrations, a pulsed neutron generator and indicators of secondary gamma radiation along the axis of the device, and the general electronics block contains a master pulse generator (generator), connected via one output to the acoustic pulse frequency divider, which is connected to two high-voltage pulse generators, the output of each of which is connected to the corresponding emitter of elastic vibrations, the second output of the generator is connected to the input of the pulse frequency divider of the generator neutrons, the output of which is connected to the input of a high-voltage pulse generator, the output of which is connected to a pulsed neutron generator, the third the radiator is connected to the input of the block of digitization of information signals and to the inputs of the selective amplifier and a program-controlled amplifier, the outputs of which are connected to the block of digitization of information signals that transmit data via a wireline cable to the surface, in addition, the output of the receiver of elastic vibrations is connected to the input of the selective amplifier, and the outputs of the secondary gamma radiation indicators are connected to a program-controlled amplifier.

Description

The utility model relates to the oil and gas industry and is intended for complex geophysical studies of cased wells.

Known nuclear-geophysical methods for logging production wells for identifying potentially productive intervals behind the casing for the purpose of re-opening the casing: the method of broadband pulsed neutron gamma-ray logging (INGK), the method of spectrometric pulsed neutron gamma-ray logging (SINGC), which are used to determine the mineralization of formation water (Kuchurin E.S., Shabiev I.Kh., Glukhov V.A. Modern technologies for researching production wells based on the use of nuclear-geophysical methods logging // Modern nuclear geophysics in the search, exploration and development of oil and gas fields. Coll. Works, Moscow, VNIIgeosystem, 2004, pp. 48-51).

Known equipment designed to determine the neutron characteristics of rocks and assess the oil and gas saturation of the collectors by multichannel registration of unsteady flows of thermal neutrons or gamma rays of radiation capture simultaneously on two probes in cased and uncased exploration and production wells of oil and gas fields (Instrumental complexes of the two-probe INC. TsSP-2INNK-43/60 (TsSP-2INGK-43). Catalog of NPP VNIIGIS http://vniigis.com/razr_radio.shtml).

Downhole tools are a two-module cylindrical design with placement in the upper part of the body of the electronic circuit with detectors, in the bottom - the actual neutron emitter with a power supply. The electronic circuit of the device is a system for collecting information from detectors with its expansion into a time spectrum and a system for transmitting this information via a wireline cable to a ground-based on-board recorder. The basis of the electronic circuit is a high-performance microcontroller.

According to the results of the studies, the indicated equipment identifies potentially productive intervals in the wells and makes a second opening of the casing.

However, the secondary opening is associated with the possibility of flooding due to poor insulation of the cement ring behind the casing. Acoustic logging and cementing quality control equipment ZAS-02 (ZAS-03) (Catalog of NLP VNIIGIS OJSC (http://vniigis.com/razr_amkis.shtml) allows us to solve the problem of identifying the intervals of presence of low-strength cement, determining volume-contact defects of cement stone and lithological partitioning of the section, allocation of reservoirs and assessment of their porosity.

Additional geophysical surveys, the materials of which could give reliable data on the state of casing isolation from neighboring aquifers, increase the costs of oil producers.

A more effective method is the use of integrated equipment that combines the ability to conduct radioactive logging and an acoustic logging tool.

Known integrated equipment for logging horizontal wells (Device for logging horizontal wells. Pat. RF №2353955, G01V5 / 10, prior. September 18, 2007, publ. April 27, 2009).

The known device contains autonomous geophysical modules lowered into the well, interconnected into an assembly, to the upper part of which is attached a means for connecting the assembly to the drill pipe string. The assembly contains modules of gamma-ray logging, three-probe neutron-neutron logging, multi-probe electric side logging, wave acoustic logging, acoustic profiler, inclinometer installed in any sequence. The assembly may also further comprise a gamma-ray spectrometric module and / or a gamma-gamma-ray lithoplastic density module.

Each autonomous geophysical module contains an autonomous power supply, signal and memory conversion units.

The set of modules used allows us to qualitatively solve the problem of isolating reservoirs, determining porosity, permeability, rock density, material composition, fracturing, determining water-oil-saturated reservoirs within a reservoir with changing characteristics, as well as determining the diameter of a well and the technical condition of its wellbore.

The assembly of individual modules installed on a drill pipe string allows solving the problems of researching wells during drilling, but is not structurally suitable for lowering on a wireline to the well in order to identify potentially productive intervals and to monitor the technical condition of wells at a late stage of operation.

Known integrated logging tool for cased wells containing an acoustic logging module and a pulsed neutron logging module (WO No. 2012/036689, prior. September 16, 2010, publ. March 22, 2012). Using the assembly of borehole modules lowered into the borehole on a cable, the productive formations are studied by pulsed neutron logging and the state of the cement stone behind the casing is estimated using acoustic logging. Each module is equipped with its own electronic circuit with a memory unit, where a part of the data obtained during the measurement is entered, and connected to a common electric bus, through which data are transmitted to the surface via cable.

The disadvantages of the known complex include large dimensions due to the connection of two separate devices, which complicate the hoisting operations, significant expenses on the element base for the assembly of electrical circuits, separately for each probe, the presence of several electrical connections between the device modules, which reduce the reliability of data transmission.

The objective of the claimed integrated geophysical equipment is to increase reliability by introducing functional elements into the probe’s design that provide simultaneous digital transmission of measured data from acoustic sensors and pulsed neutron gamma-ray sensors.

This problem is solved by the fact that complex geophysical equipment, including an acoustic logging probe, comprising a case of an acoustic insulator with acoustic emitters and a receiver of elastic vibrations, and a pulsed neutron logging probe, containing a neutron generator and indicators of secondary gamma radiation, while also in the case of an acoustic insulator a pulsed neutron generator and indicators of secondary gamma radiation spaced apart along the axis of the device are placed, and the common electronics block contains giving a pulse generator (generator) connected in one output to the acoustic pulse frequency divider, which is connected to two high-voltage pulse generators, the output of each of which is connected to the corresponding emitter of elastic vibrations, the second output of the generator is connected to the input of the frequency divider of the neutron generator pulses, the output of which is connected to the input of the generator of high-voltage pulses, the output of which is connected with a pulsed neutron generator, the third output of the generator is connected to the input of the digitizer block information signals and with inputs of a selective amplifier and a program-controlled amplifier, the outputs of which are connected to a block of digitizing information signals that transmit data via a wireline cable to the surface, in addition, the output of the receiver of elastic vibrations is connected to the input of the selective amplifier, and the outputs of the secondary gamma indicators radiation connected to a programmable amplifier.

In FIG. 1 shows the layout of integrated geophysical equipment.

In FIG. 2 is a functional block diagram of the equipment. The complex equipment is made of articulated electronics unit 1 and the probe part 2, made in the form of an acoustic insulator (Fig. 1). The body of the acoustic insulator 2 can be alternating elements of materials with different acoustic stiffness, made in the form of metal half cylinders with internal grooves and washers between them, and a protective shell that ensures the tightness of the internal cavity of the acoustic insulator from the effects of liquid and gas filling the well, and guarantees the stability of the acoustic characteristics of the entire insulator as a whole (ed. certificate of the USSR No. 1045188, prior. 12.02.1982, publ. 30.09.1983).

Acoustic emitters 3 and 4, spaced 0.25 m apart, and an elastic oscillation receiver 5 located 1.5 m from the nearest emitter 4 are installed in the probe part 2 body. A pulsed neutron generator 6 and secondary gamma indicators are located inside the probe part 2 -radiations 7 and 8, separated by 0.4 m and located from the pulsed neutron generator 6 at a distance, respectively: 0.6 m is the nearest indicator of gamma radiation 7 and at a distance of 1.0 m is the far indicator of gamma radiation 8. The indicator of gamma radiation 8 is combined on an insulator body 2 having an acoustic radiator 3, and gamma radiation indicator 7 on the housing is an acoustic insulator 2 at a distance of 0.15 m from the acoustic transducer 4.

The total length of the probe part 2 of the device is 2.05 m, and the length of the electronics unit is -1.5 m.

The functional block diagram of the device (Fig. 2) consists of a master pulse generator 9 (generator), the first output connected to an acoustic pulse frequency divider 10, which is connected to two high-voltage pulse generators 11 and 12, the output of each of which is connected to a corresponding elastic emitter oscillations 3 and 4 (acoustic emitter).

The second output of the generator 9 is connected to the input of the frequency divider of the pulses of the neutron generator 13, the output of which is connected to the high-voltage pulse generator 14, the output of which is connected to the pulsed neutron generator 6 (GII).

The output of the elastic oscillation receiver 5 is connected to the input of the selective amplifier 15, and the outputs of the gamma radiation indicators 7 and 8 are connected to a program-controlled amplifier 16.

The third output of the generator 9 is connected to the inputs of a selective amplifier 15, a program-controlled amplifier 16 and to the input of a block for digitizing information signals 17.

The output of the selective amplifier 15 and the output of the program-controlled amplifier 16 are connected to the block for digitizing information signals 17, the output of which is connected to the wireline cable 18.

The equipment operates as follows.

Acoustic emitters 3, 4 and the receiver of elastic vibrations 5, controlled by the presented functional diagram, perform the function of an acoustic control device for cementing wells.

A pulsed neutron generator 6 and two secondary gamma-radiation indicators 7 and 8, controlled by the presented functional diagram, perform the function of a broadband pulsed neutron gamma-ray logging (INGK) device or the function of a spectrometric pulsed neutron gamma-ray logging (SINGC) device.

In the process of acoustic monitoring of well cementing, synchronizing pulses from a generator 9 with a frequency of 50 Hz are supplied to a block of a frequency divider of acoustic pulses 10, from which, with a frequency of 25 Hz, they are alternately supplied to high-voltage pulse generators 11 and 12, which alternately excite acoustic emitters 3 and 4.

Elastic vibrations from emitters 3 and 4, passing through the casing and cement stone, go to the receiver of elastic vibrations 5, and from it to the input of the selective amplifier 15, equipped with a circuit for temporary selection to extract the amplitude of the longitudinal wave, where the temporary selection of the longitudinal wave and its subsequent amplification, after which the signal enters the digitizing unit 17.

In the process of the device performing the function of separation in the rock behind the column of oil-saturated intervals, the synchronizing pulses from the generator 9 are fed to the block of the frequency divider of the pulses of the neutron generator 13, the output of which is connected to the input of the generator of high-voltage pulses 14, high-voltage pulses of which with a frequency of 12.5 Hz excite pulse neutron generator 6 (GII). The neutron pulses passing through the column, cement ring and rock undergo capture by the nuclei of chlorine, carbon and oxygen, accompanied by radiation of secondary gamma radiation, which is received by indicators of secondary gamma radiation 7 and 8.

When registering the intensity of the secondary gamma radiation of chlorine atoms, the device according to the algorithm of the program-controlled amplifier 16 performs the function of a broadband pulsed neutron generator (INGK), and if the intensity of the secondary gamma radiation of carbon and oxygen atoms is recorded, the device performs the function of a spectrometric pulsed neutron generator ( SINGC).

A signal proportional to the intensity of the secondary gamma radiation from the indicators 7 and 8 is fed to different inputs of a program-controlled amplifier 16, where it is processed according to the corresponding algorithm and fed to the block for digitizing information signals 17.

The operation of the selective amplifier 15, the program-controlled amplifier 16 and the digitizing unit 17 is controlled by a master pulse generator 9.

Data is linked to the geological section through the gamma-ray (Gamma) channel, which uses gamma radiation sensors 7 and 8, which record the natural background of gamma radiation when the device is lowered into the well to the desired reservoir. To do this, at the command of the surface, the generator 9 is turned off, which does not activate the block chain to excite the pulsed neutron generator 6. In this case, the gamma radiation indicators 7 and 8 will act as a detector of the coupling joints of the column.

The layout of the integrated device is built and operates on the principle of maximum unification of the operation of the main elements, which allows to reduce its dimensions and reduce the cost of manufacturing the device and, accordingly, increase the profitability of its operation.

Claims (1)

Integrated geophysical equipment, including an acoustic logging probe, comprising an acoustic insulator body with acoustic emitters and an elastic oscillation receiver, a pulsed neutron logging tool containing a neutron generator and secondary gamma radiation indicators, and a common electronics unit, while the acoustic insulator housing is spaced between acoustic emitters, a receiver of elastic vibrations, a pulsed neutron generator and indicators of secondary gamma radiation along the axis of the device, and the general electronics block contains a master pulse generator (generator), connected via one output to the acoustic pulse frequency divider, which is connected to two high-voltage pulse generators, the output of each of which is connected to the corresponding emitter of elastic vibrations, the second output of the generator is connected to the input of the pulse frequency divider of the generator neutrons, the output of which is connected to the input of a high-voltage pulse generator, the output of which is connected to a pulsed neutron generator, the third the rotor is connected to the input of the block of digitization of information signals and to the inputs of the selective amplifier and a program-controlled amplifier, the outputs of which are connected to the block of digitization of information signals that transmit data via a wireline cable to the surface, in addition, the output of the receiver of elastic vibrations is connected to the input of the selective amplifier, and the outputs of the secondary gamma radiation indicators are connected to a program-controlled amplifier.

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