RU2724364C1 - Method of multicomponent electromagnetic survey in water area and system for implementation thereof - Google Patents

Abstract

FIELD: measurement.SUBSTANCE: invention relates to the field of studying the geologic environment using an electromagnetic field. Summary: multicomponent electromagnetic survey system comprises excitation signal of electric field Ex and receiver of reflected electric field Ex signals towed behind research vessel, magnetic frames for receiving reflected magnetic field signals Hy and Hz, located on a receiver of reflected electric field signals, a hardware-software system for processing the obtained data and simulating the section of the geological environment. Magnetic frames for receiving reflected magnetic field signals Hy and Hz contain bearing frames, upper parts of which are located on surface of water reservoir and have elements of buoyancy, and measuring frame located between lower parts of bearing frames and having weighting agents for imparting negative buoyancy. Method using system of multicomponent electromagnetic survey consists in excitation of electric field Ex, receiving the signal of electric field Ex and magnetic fields Hy and Hz, which are reflected from bottom of water area, processing data and simulating geological section corresponding to simultaneous distribution of electric field Ex and magnetic field Hy and Hz.EFFECT: high accuracy of modeling a geologic section.2 cl, 4 dwg

Description

The invention relates to the field of studying the geological environment using an electromagnetic field and is intended for the implementation of exploratory and engineering-geological studies.

To study the geological environment, electromagnetic soundings are used. Their essence lies in the excitation and registration of various components of the electromagnetic field and modeling of the geoelectric section from the measured components of the electromagnetic field. In the water area, one of the varieties of electromagnetic sounding is most often used - sounding the formation of a field in the near zone (ZSB). A feature of this technology is the registration of the electromagnetic field in time mode.

Traditionally, marine geophysical surveys use the ZSB installation (for example, the source http://geophys.geol.msu.ru/ STUDY / 3KURS / 3_ZSB.pdf., Viewed September 20, 2019) containing the source of excitation of electric field signals in the axis plane X in the form of dipole AB, towed behind the research vessel, a receiver of reflected signals of the electric field in the plane of the X axis in the form of a dipole or dipoles MN, a hardware-software complex for processing the obtained data and modeling the section of the geological environment. In this case, the method of electromagnetic surveying in the water area is to excite the electric field Ex in the plane of the X-axis, receive the signal of the electric field Ex reflected from the bottom of the water in the plane of the X-axis, process the data and simulate a section of the geological environment.

The disadvantage of this system and method is the low information content of geophysical surveys, since here only one component is used for analysis - the Ex component.

A known electromagnetic shooting system in the water area (US patent No. 4617518, published October 14, 1986), adopted as the closest analogue to the claimed system, containing a source of electric dipole current, towed behind the research vessel parallel to the surface of the reservoir and separated from the bottom of the reservoir by a distance of less than one quarter of the distance between the surface of the reservoir and the bottom, a receiver including an array of electric dipole detectors towed behind the vessel in parallel with the dipole current source, an array of triaxial magnetic field sensors installed in controlled instrument boxes towed behind the vessel on the sides of the dipole current source. The system also contains dipole antennas intended for direct study of the bottom under the dipole current source, consisting of electric dipole detectors, with one dipole antenna parallel and the other perpendicular to the dipole current source.

The method of electromagnetic shooting in the water area, taken as the closest analogue to the claimed method, is that they excite the electric field Ex in the plane of the X axis, receive the electric field signal Ex reflected from the bottom of the water area and the magnetic field signal Hx, process the data and simulate a geological section Wednesday.

The considered system and method allows to obtain data on a geological section based on two reflected signals of an electric and magnetic field. However, as in the previous case, they do not allow to collect accurate data on the studied geological environment, since the analysis is based on data in only one plane. Another disadvantage of these systems and methods is the bottom location of the sensors of the electric and magnetic fields. Work on the Arctic

shelf (for example, in the Russian Federation) with a shallow depth of the water area of 20-50 m, where significant bottom currents occur, which will lead to noncollinearity of the location of signal sources and receivers. In turn, such a violation of the geometry of the installation at the time of shooting will entail inaccuracies in the measurement of the electric and magnetic fields and errors in determining the geological section.

The technical problem solved by the present invention is the creation of a method and system of multicomponent electromagnetic surveys in the water area, which allow the most informative presentation of information about the studied geological environment.

The technical result of the invention is to increase the accuracy of calculations of the geological section due to the distribution and measurement of the three components of the electric and magnetic fields.

The technical result is achieved when using a multi-component electromagnetic shooting system containing:

- the source of excitation of the electric field signals Ex in the form of a dipole AB and the receiver of the reflected signals of the electric field Ex in the form of dipoles (dipoles) MN, towed behind a research vessel;

- magnetic frames for receiving the reflected signals of the magnetic field Hy and Hz located on the receiver of the reflected signals of the electric field;

- hardware-software complex for processing the obtained data and modeling the section of the geological environment;

- in this case, the magnetic frames for receiving the reflected signals of the magnetic field Hy and Hz contain supporting frames, the upper parts of which are located on the surface of the reservoir and have buoyancy elements, and a measuring frame located between the lower parts of the supporting frames and having weighting agents to impart negative buoyancy.

The technical result is achieved due to the method of multi-component electromagnetic shooting, using the claimed

a multi-component electromagnetic imaging system, which consists in the fact that:

- excite the electric field Ex;

- receive the signal of the electric field Ex and magnetic fields Hy and Hz reflected from the bottom of the water area; - process the data and simulate a geological section corresponding to the simultaneous distribution of the electric field Ex and the magnetic field Hy and Hz in the planes of the X, Y, and Z axes. The axis coincides with the axis of motion of the vessel towing the source of excitation of the electric field signals Ex in the form dipole AB and the receiver of the reflected signals of the electric field Ex in the form of dipoles (dipoles) MN, for the Y axis - the axis perpendicular to them, for the Z axis - the vertical axis. According to the claimed invention, dipole AB excites an electric field Ex in the plane of the X axis, however, the excited electric field is spherical, that is, propagating the signal along all three axes X, Y, Z. According to Maxwell's laws, a spherical electric field generates a spherical magnetic field in the planes axes X, Y, Z, which is used for analysis. The study of the geological environment is simultaneously carried out along all three axes of the space X, Y, Z, and not one, as was the case with the above analogues. As a result, the claimed system and method allow measurements to be made on three components: one component of the electric field Ex and two components of the magnetic field Hy and Hz. Thus, the solution allows more accurate modeling of the geological section, which corresponds to the simultaneous distribution of these fields. In FIG. 1 shows the construction of a magnetic frame for receiving reflected magnetic field signals in the Y and Z planes (front view). In FIG. 2 shows the construction of a magnetic frame for receiving reflected magnetic field signals in the planes of the Y and Z axes (side view).

In FIG. Figure 3 shows the sources of electric field excitation in the plane of the X axis — dipoles AB. In FIG. Figure 4 shows the receivers of the reflected signals of the electric field in the plane of the X-axis - dipoles MN and M1N1., On which the magnetic frames are located for receiving the reflected signals of the magnetic field in the planes of the Y and Z axes.

The magnetic frame for receiving reflected magnetic field signals in the planes of the Y and Z axes contains two supporting frames 1 and a measuring frame 2.

As the specified load-bearing frames 1, gel-filled load-bearing frames of 1000 × 800 mm of neutral buoyancy are used. As the indicated measuring frame 2, a gel-filled towed frame 800x800 mm is used.

Coils of copper wire are located inside the gel filled carrier frames 1 and the measuring frame 2, which are sensors for receiving reflected magnetic field signals in the Y and Z planes.

In the inner part of the structures of the supporting frames 1 and the measuring frame 2, stretch marks are installed to strengthen 3.

The upper parts of the supporting frames 1 are located on the surface of the water area 4 and have buoyancy elements 5, which are used fenders with a volume of 95 l, a length of 1020 mm, a width of 375 mm and a weight of 6.2 kg.

The measuring frame 2 is located between the lower parts of the supporting frames 1 and is perpendicular to them. Weighting agents are mounted on the measuring frame 2 to impart negative buoyancy 6.

Magnetic frames for receiving reflected magnetic field signals in the planes of the Y and Z axes using towing hooks 7, cable cable 8, overhead load stabilizing 9, floating anchor-parachute 10 PVC 550x800 mm with variable opening diameter are towed behind the research vessel (Fig. 1 , 2).

In FIG. 3 shows a dipole AB having a structure to ensure its buoyancy due to the indicated elements 5 and deepening due to these weighting agents 6.

Magnetic frames for receiving reflected magnetic field signals in the Y and Z planes with bearing frames 1 and measuring frame 2 are mounted on the reflected electric field receivers — dipoles MN and M1N1 (Fig. 4). Measuring frame 2 must be towed at a depth of 1 m with a vessel speed of 4-4.5 knots. This speed is established experimentally, when the ship is not yet blowing away by the wind. In this case, strict parallelism of the AB dipole to the MN dipoles is provided, which is necessary to further improve the accuracy of the measurements. The immersion of the measuring frame 2 to a depth of not less than 1 m is necessary to obtain the elimination of wave noise and to obtain the maximum signal / noise value.

By means of electric current excitation sources - dipoles AB - they excite an electric field in the plane of the X axis. The excited electric field is spherical, that is, propagating the signal along the three axes X, Y, Z and generating a spherical magnetic field. Then, by means of dipoles MN, a reflected electric field signal is received in the plane of the X axis and the first component for research is obtained, Ex, and through magnetic frames for receiving reflected magnetic field signals in the planes of the Y and Z axes, the second and third components for research are obtained, Hy and Hz. Using software and hardware and software simulate a geological section, which corresponds to the simultaneous distribution of the electric field and magnetic field. Such a simultaneous interpretation of the electric field and magnetic field and the reconstruction of the geological section in both magnetic and electric fields can significantly increase the accuracy of calculations and increase the overall information content of the research.

The inventive system and method of multicomponent electromagnetic surveying due to the near-surface installation of sources and receivers of an electric and magnetic field signal can be used in water areas of any depth, including for work in the Arctic shelf of the Russian Federation with a shallow bottom depth, which indicates the wider functionality of this inventions for the study of a geological section.

Claims (2)

1. A multi-component electromagnetic imaging system, characterized in that it contains an excitation source of electric field signals Ex in the form of dipole AB and a receiver of reflected signals of the electric field Ex in the form of dipole MN, towed behind the research vessel, magnetic frames for receiving reflected magnetic field signals Hy and Hz located on the receiver of the reflected signals of the electric field, a hardware-software complex for processing the obtained data and modeling the cross section of the geological environment, while the magnetic frames for receiving the reflected signals of the magnetic field Hy and Hz contain supporting frames, the upper parts of which are located on the surface of the reservoir and have elements buoyancy, and a measuring frame located between the lower parts of the bearing frames and having weighting agents to impart negative buoyancy. 2. The method of multicomponent electromagnetic surveying using the system according to claim 1 of the formula, which excites an electric field Ex, receives the signal of the electric field Ex and magnetic fields Hy and Hz reflected from the bottom of the water area, processes the data and simulates a geological section corresponding to the simultaneous the distribution of the electric field Ex and the magnetic field Hy and Hz.

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