RU2780574C2 - Research complex for marine electrical exploration and its implementation method - Google Patents

Abstract

FIELD: geophysics.

SUBSTANCE: invention relates to the field of geophysics, namely to marine electrical exploration in order to identify oil and gas fields. A research complex for marine electrical exploration includes a vessel, on which there are equipment for the formation of discrete multipolar pulses, a non-emitting ballast device, equipment for reading and recording information from bottom stations equipped with scythes with receiving electrodes, place registration equipment, and a towed generator line. Additional electrodes are placed on scythes of bottom stations along with main receiving electrodes. Moreover, an additional electrode is located from each main electrode at a distance from 1 m to one tenth of the length of the generator line. Additional measuring channels are formed between main and additional electrodes. A method for marine electrical exploration consists in that, during the passage of the generator line in the immediate vicinity of bottom stations, signals of additional channels formed by main and additional electrodes are measured. The position of the center of the generator line is compared during the passage above the intended position of the receiving line with a signal time sweep. If time of passage by the receiving time line, relatively to which the measured signal is symmetrical, does not match, a wrong position of electrodes is fixed. To determine a true position of receiving electrodes, coordinates of receiving electrodes are first shifted along a profile so that the moment of passage of the center of the generator line above them approximately corresponds to time, relatively to which the measured signal is symmetrical. Then, probing curves are built on the fundamental harmonic relatively to the intended center of the measuring line, and trial calculations are carried out, changing positions of the receiving line, achieving a coincidence of a shape of measured and theoretical curves. The position of electrodes, corresponding to the best match, is assumed to be true.

EFFECT: obtaining a research complex for marine electrical exploration.

4 cl, 5 dwg

Description

The invention relates to the field of geophysics, namely to electrical exploration, more precisely, to methods for conducting marine electrical exploration in order to identify oil and gas fields and equipment used in these conditions.

Electrical exploration is one of the leading geophysical methods used in water areas both in the search for minerals and in engineering surveys. Currently, various methods are widely used for marine exploration related to the impact of electromagnetic field pulses on the seabed, recording changes in the electromagnetic parameters of bottom rocks and analyzing the data obtained to detect existing anomalies and determine their nature (RU 2236028, 2004; SU 1122998, 1984; SU 1798666, 1996; SU 1434385, 1988; US 4298840, 1981; US 4617518, 1986), which are carried out using various research apparatus and equipment.

The most promising methods for research are electrical prospecting methods (RU 2236028, 2004; RU 2253881, 2005; SU 1798666, 1997; SU 1434385, 1988; US 4298840; US 4617518), which make it possible to take into account both the conductivity and the polarizability of seabed rocks when constructing a profile. .

For measurements, as a rule, a ship is used with a generator, an excitation field formation unit that provides the generation of discrete bipolar pulses in a horizontal towed dipole with supply electrodes, a data recording and processing unit, as well as recording devices, which are used as a set of bottom stations equipped with horizontal and/or vertical electromagnetic field sensors. In this case, the excitation of the electromagnetic field is carried out using a generator line placed in the area of the stations, the signals are recorded by the receiving electrodes of the bottom stations, the removal from the stations of the received information about the electrical resistance of the seabed rocks, on the basis of which the profile of the seabed rocks is modeled, is carried out by the recording unit and data processing (GB 2402745, 2003; RU 48645, 2005; RU 53460, 2006; RU 2375728, 2006; RU 2324956, 2007; US 7800374, 2010; US 8076942, 2011). The specific composition of the equipment and the measurement technique are selected based on the characteristics of the seabed area under study.

The closest to the claimed solution is the technology of marine electrical exploration (RU 2612726, 2015) developed earlier by the authors, which is implemented as follows. A generator line is towed behind a small vessel on the sea surface, where bipolar current pulses are formed with a pause between them, and the time sweep of the signals is recorded using multichannel bottom stations equipped with receiving lines (braids). The measuring spacings on the receiving lines are formed by pairs of receiving electrodes located symmetrically with respect to the bottom station. In this case, the receiving lines are laid out in such a way that the bottom stations are located at certain, predetermined points of the profile, the position of which is controlled according to the data of the GPS receiver indicators. After the placement of bottom stations is completed, the small-sized vessel goes to the starting point of the excitation profile and, using a generator line, forms bipolar rectangular pulses with a given duration and duty cycle, which have a polarizing effect on the rocks of the shelf. The duration of pulses and pauses, depending on the tasks and features of the equipment used, ranges from 0.5 to 16 seconds. When interpreting information, information about the field is used, both during the passage of current and in the pause between pulses in a wide spatio-temporal region, and not only the resistance of the medium is determined, but also its polarization characteristics, and when analyzing signals, sections of the profile are distinguished, where signals of electrodynamic formation and the formation of the induced polarization have opposite signs, the changes of which along the profile reveal the anomalies of the induced polarization.

The disadvantage of this solution is that during the placement of stations and bottom streamers under the influence of currents, their significant drift from the discharge point is possible and, as a result, the impossibility of reliably determining the coordinates of the measuring electrodes, which, in turn, can lead to significant errors in interpretation.

To determine the position of stations and electrodes, various technical solutions are used that use acoustic measurements (http://docplayer.ru/38963763-Metody-i-sredstva-izmereniya-parametrov-okeanicheskoy-sredy-avtomaticheskimi-mnogocelevymi-donnymi-stanciyami.html). But for their implementation in marine electrical prospecting, in addition to a significant increase in the cost of equipment, significant costs of ship time would be required, not related to direct electrical survey measurements. No other solutions are currently proposed in the literature.

The task solved by the authors was the development of a technology that would improve the quality of measurements due to a more reliable determination of the coordinates of the measuring electrodes.

This problem was solved by installing additional electrodes on the measuring streamers within the framework of the research complex, adding additional measuring channels at the stations, and developing an information processing system based on the registration of signals coming from bottom stations.

The technical result in relation to the device consists in the use of a research complex containing a vessel with a generator, an excitation field formation unit, a horizontal towed dipole, and a data processing unit, as well as recording devices, which use a set of bottom stations equipped with streamers containing, as the main receiving electrodes M ₁ and N ₁ and additional electrodes M ₂ and N ₂ that are installed at a distance from the main electrode of more than 1 m and less than one tenth of the length of the generator line. Installation of electrodes at a distance of less than 1 m does not allow obtaining reliable information about the coordinates of the electrodes, and at a distance greater than one tenth of the length of the generator line, the accuracy of determining the location of the electrodes decreases due to the increasing influence of environmental factors (flow, bottom irregularities, etc.) .).

It is optimal to install additional electrodes at a distance of 1-10 m from the main electrodes.

If it is necessary to obtain information about the position of the station, use an additional channel formed by electrodes M ₃ N ₃ located on the spit on both sides of the station.

The technical result in relation to the method is achieved as follows. During the passage of the generator line in the immediate vicinity of the bottom stations, the signals of the additional channel formed by the main and additional electrodes are measured. After that, the position of the center of the generator line is compared during the passage over the expected position of the receiving line with the time base of the signal. If the time of passage past the receiving line does not correspond to the time with respect to which the measured signal is symmetrical, the incorrect location of the main electrodes caused by external factors is fixed. In this case, the coordinates of the receiving electrodes are first shifted along the profile so that the moment when the center of the generator line passes over them approximately corresponds to the time relative to which the measured signal is symmetrical, and then the probing curves are built at the fundamental harmonic, relative to the supposed center of the measuring line, and test calculations are carried out, by changing the position of the receiving line, achieving the coincidence of the shape of the measured and theoretical curves, and the position of the electrodes corresponding to the best match is taken as true. As a reference model for calculations, a two-layer section is taken, in which the thickness of the first layer (water) is set based on the echo sounder readings, and the electrical resistivity is set from preliminary resistivity measurements. The electrical resistivity of the second layer is set as an average value over the area of work.

The general view of the complex is shown in Fig. 1, where the following designations are used: 1 - a vessel with a generator, an excitation field formation unit, and data recording and processing units; 2 - generator line (dipole); 3 - ballast device; 4 - bottom stations; 5 - receiving line (spit) of the bottom station; M ₁ , N ₁ - main receiving electrodes; M ₂ , N ₂ , M ₃ , N ₃ - additional receiving electrodes.

On FIG. 2, using the example of determining the coordinates of the main electrode N ₁ by using a pair of electrodes M ₂ , N ₁ , shows the expected position of the receiving electrodes (a) and comparing the time of passage of the center of the generator line above them with the time base of the recorded signals (b).

On FIG. 3 shows the expected position of the receiving electrodes, the position of the generator line at the time corresponding to the center of symmetry of the recorded signals (a) and the time base of the recorded signals (b).

On FIG. Figure 4 shows the found position of the receiving electrodes (a) and comparison of the time of passage of the center of the generator line above them with the time base of the recorded signals (b).

On FIG. Figure 5 shows the experimental (solid) and calculated (dashed line) sounding curves at the fundamental harmonic before (a) and after (b) positioning.

The device works as follows. Vessel 1 is used, equipped with a generator and an excitation field formation unit and data recording and processing units, towed by a generator line 2 and a ballast device 3. When entering the research area from the vessel 1, bottom stations 4 are placed on each profile with a given interval, on the spits 5 of which along with the main receiving electrodes M ₁ , N ₁ additional receiving electrodes are installed; M ₂ , N ₂ , and M ₃ , N ₃ . The descent is carried out in such a way that the spits 5 are located along the profile, while fixing the coordinates of the stations by the GPS signal.

After setting up the stations, the vessel 1 enters the zone where the station is located and, using the generator line 2, generates rectangular pulses of different polarity with a given duration and duty cycle, which have a polarizing effect on the rocks of the shelf. The duration of pulses and pauses, depending on the tasks and features of the equipment used, ranges from 0.5 to 16 seconds. During pauses, as a rule, a non-radiating ballast device 3 is connected to the ship's generator, which reduces load surges of the ship's generator. When this information is obtained both from the main pairs of electrodes M ₁ N ₁ and from additional pairs of electrodes M ₁ N ₂ and M ₂ N ₁ determine the position of the electrodes M ₁ N ₂ and M ₂ N ₁ .

If it is necessary to obtain information about the position of the station 4, use the channel formed by the electrodes M ₃ N ₃ located on the spit 5 on both sides of the station. Conduct a comparison of the position of the center of the generator line during the passage over the intended position of the receiving line with the time base of the signal (Fig. 2). When the coordinates are set correctly, the time of passing the receiving line approximately corresponds to the time with respect to which the measured signal is symmetrical. Otherwise, fix the error in the coordinates of the electrodes of the station relative to the specified coordinates. To establish the true coordinates, first, the coordinates of the receiving electrodes are shifted along the profile so that the moment the center of the generator line passes over them approximately corresponds to the time relative to which the measured signal is symmetrical (Fig. 3), then the sounding curves are plotted on the fundamental harmonic, relative to the supposed center of the measuring line. After that, a number of test calculations are carried out, changing the position of the receiving line, achieving the coincidence of the shape of the measured and theoretical curves. The position of the electrodes corresponding to the best match is taken as true (Fig. 4).

The use of the proposed complex allows to improve the quality of measurements by determining the true position of the measuring electrodes. In addition, when using the proposed device, there is an additional opportunity to use new channels as a source of information about the geoelectric structure of the section.

Claims (4)

1. A research complex for marine electrical exploration, including a vessel on which is located equipment for generating discrete bipolar pulses, a non-radiating ballast device, equipment for reading and writing information from bottom stations equipped with streamers with receiving electrodes, equipment for registering a place, a towed generator line, characterized in that on the streamers of bottom stations, along with the main receiving electrodes, additional electrodes are placed, and the additional electrode is located from each main electrode at a distance of 1 m to one tenth of the length of the generator line, while additional measuring channels are formed between the main and additional electrodes. 2. Research complex according to claim 1, characterized in that the additional electrode is installed at a distance of 1-10 m from the main electrode. 3. A method of marine electrical reconnaissance, which consists in placing on the bottom along the observation profile a system of bottom stations with streamers equipped with receiving electrodes, excitation in a horizontal generator line while the vessel is moving along the observation profile of bipolar current pulses with a pause between them and obtaining information from the main pairs of receiving electrodes. electrodes, characterized in that during the passage of the generator line in the immediate vicinity of the bottom stations, measurements are made of the signals of additional channels formed by the main and additional electrode located from the main electrode at a distance of 1 m to one tenth of the length of the generator line, the position of the center of the generator line is compared lines during the passage over the expected position of the receiving line with a time base of the signal, if the time of passage past the receiving line of time does not match, with respect to which the measured signal is symmetrical, the wrong location of the electrodes is fixed and determine the true position of the receiving electrodes, for which, first, the coordinates of the receiving electrodes are shifted along the profile so that the moment the center of the generator line passes over them approximately corresponds to the time relative to which the measured signal is symmetrical, and then the sounding curves are plotted on the fundamental harmonic relative to the supposed center of the measuring line and test calculations are carried out, changing the position of the receiving line, achieving the coincidence of the shape of the measured and theoretical curves, and the position of the electrodes corresponding to the best match is taken as true. 4. The method according to claim 3, characterized in that a two-layer section is taken as a reference model for calculations, in which the thickness of the first layer - water is set based on the readings of the echo sounder, and the electrical resistivity - from preliminary resistive measurements, and the electrical resistivity of the second layer is set as an average value over the area of work.

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