RU67732U1 - SYSTEM OF HIGH-RESOLUTION GEOELECTRIC EXPLORATION OF NEBRA-SOBELNIKOV - Google Patents

Abstract

Usage: geoelectrical exploration device for sensing the formation of an electromagnetic field (EMF) in the near field (ZSB) and exploration of hydrocarbon deposits (HC).

SUBSTANCE: system contains a transmitter unit, a receiver unit, a switching device, a transceiver antenna, a measurement unit, and a registration unit. The measurement and recording unit is included in the data processing processor, which additionally contains a processing unit as part of the full EMF processing module, an inductive induced polarization (IWP) oscillation isolation module and reference parameters generator, and a data analysis and interpretation unit comprising two (or three) modules comparative analysis.

EFFECT: high-resolution geoelectro-prospecting ZSB-IVP, increasing the resolution, information content and reliability of measurements to highlight the fine structure of the geoelectric section.

1 sec and 6 s. p. f-ly, 2 Fig.

Description

The technical solution relates to geoelectrical exploration devices using evoked polarization technology for sensing the formation of an electromagnetic field (EMF) in the near field (ZSB) and can be used in the study of a geoelectric section and in the exploration of mineral deposits, including hydrocarbon deposits (HC).

The well-known technology of geoelectrical exploration [7, 9] by the ZSB EMF method is based on the study of transient processes occurring in the earth when the EMF is artificially excited by rectangular pulses of direct current and includes excitation of a pulsed EMF and measurement of the transient process in the pauses between current pulses. The geological structure is judged by the field formation curve, which after special processing is presented in the form of a geoelectric section. But the traditional ZSB technology of geoelectro-prospecting has insufficient noise immunity and resolution for the correct implementation of the direct method of mineral exploration.

Recently, a number of geoelectrical exploration systems have been patented [4–6], which implement the ZSB with the release of the effect of induction induced polarization (IWP). These technical solutions are based on experimentally established and theoretically sound (Nebrat

A.G., Christmas Eve V.V. [4, 7-8]) the property of the probing EMF, which consists in the fact that the induced polarization (VP) of the EMF is caused by two components: the VP process and induction induced polarization (IWP). The registration of data using the ZSB-IVP technology and the subsequent processing and interpretation of the measurements of the geoelectric section allow us to obtain a qualitatively new technical result of electrical exploration: to increase the resolution and reliability of the section obtained by isolating the oscillations of the EMF EMP intensity (due to the effects of a finer structure).

Common features of geoelectrical exploration devices [3, 5, 6] are the presence of a transmitter, a receiver, a receiver, and a unit for measuring EMF parameters located in a given area of research, while dipole-symmetric multi-channel and multi-electrode installations are used as sources and receivers of electromagnetic fields.

The reliability and reliability of the results in such devices can be enhanced by a combination of measurements and a comprehensive interpretation of the measured parameters, such as, for example, in the technological complex [2] for the search for oil and gas fields, which includes a module for measuring geophysical field parameters, an information storage unit, a data processing unit, and data analysis and interpretation unit.

However, the device [2] does not take into account all the specifics of geoelectrical exploration and cannot, in some cases, provide adequate resolution when isolating the fine structure of the geoelectric section.

Of the known devices, it most fully describes the class of installations for geoelectro-prospecting, the technological complex [1] of electrical exploration equipment adopted as a prototype, which contains a transmitter unit, a unit located in a given area for studying the geological environment

a receiver, a switching device, a transceiver antenna, an electromagnetic field measuring unit (EMF), and a recording unit, wherein the switching device is connected to a transceiver antenna, to a transmitter unit, and to a receiver unit that is connected to the measurement unit.

However, the complex [1] does not provide for the allocation of the IWP effect and, as a result, the complex [1] does not provide the potential resolution of geoelectro-prospecting due to the insufficiently complete volume of geological information for adequate and unambiguous implementation of direct exploration methods. Moreover, the device [1], in principle, cannot carry out complex processing of a set of measurements using the ZSB – IWP technology (especially the secondary seismoelectric effect (SEE)) and distinguish a thin geological structure.

To eliminate the shortcomings of the devices [1-3], the “High-resolution Geoelectro-exploration System of Nebrat-Sochelnikov” is proposed (the methodological principles of which were developed by these authors [4, 7, 8], which leads to a special name).

The essence of the technical solution is to create a system of high-resolution geoelectrical exploration, which, while preserving the advantages of the prototype, would allow expanding the functionality due to the implementation of the integrated processing of measurement data of the full EMF, the effect of IWP, as well as (additionally) the effect of EVE.

The main technical result of the proposed system is the implementation of the technology of high-resolution geoelectrical prospecting ZSB - IWP with increased noise immunity, resolution, information content and reliability of judging the presence of hydrocarbon deposits in the studied geostructure with direct geoelectro-prospecting methods adequate to seismic exploration. The Nebrat-Christmas Eve system allows synergy of complex processing

data on a new criterion with traditional technology for identifying anomalies of the type of reservoir.

The technical result is achieved as follows.

The high-resolution geoelectrical exploration system contains a transmitter unit, a receiver unit, a switching device, a transceiver antenna, an electromagnetic field measurement unit (EMF) and a registration unit located in a predetermined area for studying the geological environment, while the switching device is connected to a transceiver antenna, to the transmitter unit, and to the unit a receiver that is connected to the measurement unit.

A distinctive feature of the Nebrat-Scoelnikov system is that the measurement unit and the registration unit are included in the data processing processor (AML), which contains a series-connected unit for measuring the full electromagnetic field during sounding by the formation in the near zone in the pauses between current pulses, an information storage unit, a unit data processing (OD), a data analysis and interpretation unit (AID) and a registration unit, and the input of the measurement unit is the input of the AML. In this case, the OD unit includes a module for processing the full EMF caused by the formation in pauses between current pulses generated by the transmitter unit in the transceiver antenna, and an inductive induced polarization (IWP) oscillation isolation module, as well as a generator of theoretical EMF theoretical reference parameters (TEC), and inputs the full EMF processing module and the IVP oscillation isolation module are connected to the output of the information storage unit, and the output of the full EMF processing module, the output of the IVP oscillation isolation module and the output of the waveforms Ateliers of the TEC EMF are connected to the inputs of the AID unit. The AID block includes the first and second comparative analysis modules, the first inputs of which are connected to the output of the full EMF processing module and the output of the IWP oscillation isolation module, respectively, the second inputs to the output of the TEC EMF shaper, and the outputs of the comparative modules

analysis, which are the outputs of the AID unit, are connected to the registration unit.

The system is also characterized in that the module for extracting oscillations of the IWP is made in the form of a computational unit that implements an algorithm for extracting from the measured signal the full EMF oscillations of the IWP by subtracting from the measured sounding curve at a given observation point its averaged moving average value over a given time interval and subsequent normalization the measured oscillation values by the average value of the measured signals at each moment in time.

In addition, the difference between the system is that the AID unit is made in the form of a computer that implements an algorithm for comparing the measurement value of the total EMF and the extracted IWP value with the known and / or theoretical calculated model values specified by the EMF generator.

In special cases, the transceiver antenna is made in the form of a single combined transceiver loop or in the form of a dipole multi-channel installation.

The OD unit of the system may additionally include a secondary seismoelectric effect (VES) extraction module, the input of which is connected to the output of the accumulation unit, the output of the VSE extraction module is connected to the first input of the third comparative analysis module, additionally inserted into the AID unit, the second input of which is connected to the output of the TEC EMF generator , and the output is the third output of the AID unit to the registration unit.

The difference of the system is also that the AID block of the AID processor is capable of displaying the results of joint processing and correlation analysis of data on graphical and / or digital temporary geoelectric sections and diagrams of oscillation values of the IWP, VCE, as well as the full EMF for subsequent isolation of anomalies and

making judgments about the presence of oil and gas fields in the study area and determining their contours, depth and oil and gas productivity by comparing the correlation of the results of the analysis of the data of the study area with the characteristics of known reference hydrocarbon deposits and / or empty traps.

In specific cases of using the system, the AML processor is based on the laptop “personal computer”, the input of which is connected to the transceiver antenna through a switching device, which is also connected to the transmitter unit, which is the source of the pulsed electromagnetic field.

Figure 1 shows the general structural diagram of the high-resolution geoelectrical exploration system of Nebrat-Sochelnikov, figure 2 illustrates the essence and technical result achieved by the ZSB-IVP technology when interpreting the characteristics of a multilayer geological section.

The system (Fig. 1) includes a transmitter unit 1, a receiver unit 2, a switching device 3, a transceiver antenna 4, and an AML processor 5, comprising a full electromagnetic field measuring unit 6, an information storage unit 7, an OD unit 8, an AID unit 9, and a registration unit 10 . Block 8 OD includes a module 11 for processing a full EMF, a module 12 for allocating oscillations of the IWP, a shaper of TEC EMF 13 and a module 16 for allocating HEP. Block 9 AID includes the first, second and third modules 14, 15 and 17 of the comparative analysis.

The system operates as follows.

The transmitter unit 1 generates rectangular pulses and, through a switching device 3, transmits them to a transceiver antenna 4, which can be made in the form of a single combined transceiver loop or in the form of a dipole multi-channel installation. After turning off the supply current in the transmitter unit 1, the AML processor 5 after receiving the receiver by the unit 2 implements a registration algorithm,

processing and interpreting data. In this case, block 6 measures the intensity of the formation of a full electromagnetic field, block 7 serves to accumulate information. Data processing is performed by block 8 OD, and module 11 processes the data of the full electromagnetic field due to the process of pausing between the current pulses generated by the transmitter unit 1 in the transceiver antenna 4. The module 12 for extracting the IED, made in the form of a computing unit, implements an algorithm for extracting from the measured signal the full EMF oscillations by subtracting from the measured sounding curve at a given observation point its averaged moving average value over a given time interval and the next normalization of the measured oscillation values to the average value of the measured signals at each moment in time.

Shaper 13 TEC EMF generates theoretical reference parameters of EMF, for example, in the form of expressions given in [4, 5]. In block 9 AID analysis and interpretation of data coming from block 8 OD (modules 11, 12 and shaper 13) to the inputs of the first and second 14 and 15 modules of comparative analysis. The AID computing unit 9 implements an algorithm for comparing the measured total EMF value in module 14 and extracting the IWP value in module 15 with known and / or theoretical calculated model values specified by the EMF generator TEP 13.

Block 8 OD may additionally include a module 16 allocation VSE, which is similar to the measured oscillations of the IWP is analyzed in the third (additional) module 17 comparative analysis of block 9 AID by comparing with the models of the generator 13 TEC EMF (for example, in the form shown in [5]).

The AID block of the AID processor is capable of displaying the results of joint processing and correlation analysis of data in graphic and / or digital temporary geoelectric sections and

diagrams of the values of the oscillations of the IWP, FEV, and also the full EMF, which are then recorded by block 10. Based on the results of the analysis carried out by block 9 AID, EMF anomalies are identified and a judgment is made on the presence of oil and gas fields in the study area, and their contours, depths and oil and gas productivity by comparing the correlation of the results of the analysis of the data of the study area in modules 14, 15 and 17 with the characteristics of the known reference hydrocarbon deposits specified by the shaper 13 and / or empty traps (figure 2).

In specific cases of using the system, the AML processor 5 is made on the basis of a laptop “personal computer”, the input of which is connected to the transceiver antenna 4 through a switching device 3, also connected to the transmitter unit 1, which is the source of the pulsed electromagnetic field.

Thus, the features of the proposed system provide a qualitatively new technical result: high-resolution geoelectro-prospecting ZSB-IVP, adequate seismic exploration, due to increased resolution, information content and reliability of measurements, as well as due to the synergy of complex data processing according to a new search criterion, which allows to distinguish the fine structure of geoelectric cut.

BACKGROUND OF THE INVENTION

I. Prototype and analogues:

1. RU 36534 U1, 03/10/2004. (prototype).

2. RU 63071 U1, 05/10/2007. (analogue).

3. RU 17634 U1, 04/10/2001. (analogue).

4. RU 2094829 C1, 10.27.1997. (analogue).

II. Additional sources of prior art:

5. RU 14085 U1, 06.27.2000.

6. RU 17811U 1, 04/27/2001.

7. Christmas Eve V.V., Nebrat A.G. et al. Theory and practical possibilities of the ZSB-IVP method in the search for oil and gas. - Physics of the Earth, No. 6, 1994, p. 54-56.

8. Christmas Eve V.V. High resolution electrical exploration. - Novorossiysk: publishing house of the Moscow State University named after adm. F.F. Ushakova, 2006, 41 p.

9. Nebrat A.G. Inductive excitation of induced polarization of rocks during direct searches of oil and gas fields. - News. Mosk. Un-Ser. 4, Geology, 1990, No. 5, pp. 67-70.

Claims (7)

1. A high-resolution geoelectrical exploration system containing a transmitter unit, a receiver unit, a switching device, a transmitting and receiving antenna, an electromagnetic field measuring unit (EMF) and a recording unit located in a predetermined area for studying the geological environment, and the switching device is connected to a transmitting and receiving antenna to a transmitter unit and to the receiver unit, which is connected to the measurement unit, characterized in that the measurement unit and the registration unit are included in the data processing processor (AML), which contains a series-connected unit for measuring the full electromagnetic field during sounding in the near zone during pauses between current pulses, an information storage unit, a data processing unit (OD), a data analysis and interpretation unit (AID), and a recording unit, and the input of the measurement unit is an AML input, in this case, the OD unit includes a module for processing the full electromagnetic field due to the formation in pauses between current pulses generated by the transmitter unit in the transceiver antenna, and an inductive oscillation extraction module caused by EMF larization (IWP), as well as a generator of theoretical reference parameters (TEC), the inputs of the full EMF processing module and the IWP oscillation isolation module are connected to the output of the information storage unit, and the output of the full EMF processing module, the output of the IWP oscillation isolation module and the output of the TEC generator EMFs are connected to the inputs of the AID unit, the AID unit includes the first and second modules of comparative analysis, the first inputs of which are connected to the output of the processing module of the full EMF and the output of the module for isolating the IWP oscillation, respectively, s input - to the output of the shaper TIC EMF, and outputs comparative analysis modules are AID output unit, connected to the recording unit. 2. The system according to claim 1, characterized in that the module for extracting the IWP oscillation is made in the form of a computing unit that implements an algorithm for extracting the full EMF of the IWP oscillation from the measured signal by subtracting from the measured probe curve at a given observation point its averaged moving average value by a given time interval and subsequent normalization of the measured oscillation values to the average value of the measured signals at each time moment. 3. The system according to claim 1, characterized in that the AID unit is made in the form of a calculator that implements an algorithm for comparing the measurement value of the full EMF and the extracted IWP value with known and / or theoretical calculated model values specified by the EMF driver. 4. The system according to claim 1, characterized in that the transceiver antenna is made in the form of one combined transceiver loop or in the form of a dipole multi-channel installation. 5. The system according to claim 1, characterized in that the OD unit further includes a secondary seismoelectric effect (VCE) extraction module, the input of which is connected to the output of the storage unit, the output of the VSE extraction module is connected to the first input of the third comparative analysis module, additionally introduced into the AID unit the second input of which is connected to the output of the TEC EMF shaper, and the output is the third output of the AID block to the registration block. 6. The system according to claims 1 and 5, characterized in that the AID block of the AML processor is capable of displaying the results of joint processing and correlation analysis of data on graphical and / or digital temporary geoelectric sections and diagrams of oscillation values of the IWP, SCE, as well as the full electromagnetic field for subsequent identification of anomalies and making judgments about the presence of oil and gas fields in the study area and determining their contours, occurrence depth and oil and gas productivity by comparing the correlation of analysis results for the data of the study area with the characteristics of known reference hydrocarbon deposits and / or empty traps. 7. The system according to claim 1, characterized in that the AML processor is based on a laptop personal computer, the input of which is connected to the transceiver antenna through a switching device, which is also connected to the transmitter unit, which is the source of the pulsed electromagnetic field.