SU1053041A1 - Process for electromagnetic probing - Google Patents

Abstract

THE METHOD OF ELECTROMAGNETIC SOUNDING, at which the electromagnetic field is excited, with the measuring electrode electrodes placed on the profile, the electric or magnetic components of the electromagnetic field are measured at a given time interval, starting from the switching on of the current in the supply circuit, or from a given discrete sequence of wavelengths and measurement results judge the structure of the geoelectrical section of the 1st section, in order to increase the detail of the dissection incision, measuring is carried out at timings corresponding to a DC for all separations relative parameter Formation or wavelength spacing to a value at which the measurement is performed.

Description

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The invention can be used to study the geology of the structure, the structure of the flashback in the presence of non-conductive screens, to identify inhomogeneities in the geoelectrical section associated with oil and gas deposits, as well as to study the upper part of the section and the detailed division of horizontal layered media solving engineering and geological problems.

The essence of frequency sounding and sounding by the field formation method as modifications of electromagnetic sounding, with a harmonically varying and unsteady electromagnetic field, consists in measuring the apparent resistivity depending on the wavelength or the formation parameter. The propagation of harmonic oscillations of an electromagnetic field is accompanied by a change in their amplitudes and the appearance of phase shifts with respect to the phase of the supply current. The unsteady and harmonic electromagnetic fields contain the same information about the geoelectrical section, characterizing the section in depth. The most complete information on the longitudinal and transverse resistivity can be obtained by coking the probing frequency or the formation of a floor with a change in spacing. . .

The task of marine electrical prospecting is to determine the electrical characteristics and powers of the geoelectric horizons with sufficient resolution for accurate dissection of the section by depth.

The known method of electromagnetic sounding, characterized by high resolution (the method of transient processes of the MPP), in which the electromagnetic field is excited with an ungrounded loop in the form of rectangular current pulses and in the pauses between these pulses at given time points after the current is disconnected, the parameters of the unsteady state are measured electromagnetic field, which are judged on the structure of the geoelectric section H

However, the MPP is designed to detect local well-conducting bodies under inductive field excitation and does not provide for the study of horizontal-layered structures with a specific electrical resistance higher than the resistance of the overlapping water column. At the same time, the anomalous effect in the WFP method decreases with increasing electrical resistivity of the object under study.

The closest technical solution to the invention is a method of electromagnetic sounding, characterized by high resolution, suitable for detailed study of structures, according to which an electromagnetic field is excited using measuring electrodes placed on a Profile, measuring the electric or magnetic components of an electromagnetic field on a given sequence of spacings at given times tj, starting from the moment of switching on the current in the supply circuit, or from the given discrete pos edovatelnostyu wavelength i, and on the results: the measurement is judged on the structure of the geoelectric section.

Electrodes are placed on a profile with a given sequence.

spacing r ,, g ,, ..., g; Hz,

(where i 1, 2, ..., p is the number of spacings; j 1,2, ... / m is the number of wavelengths), and the phase difference of the signals for each of the specified wavelengths is measured on each successive pair of spacings . The set of wavelengths is set for each pair of spacing so that

p .- "condition is fulfilled - -2-

  "LIL

for a set of wavelengths (tg 3), and a set of excited wavelengths is changed to obtain the maximum phase difference for each pair of spacings. According to the measured phase differences, the structure of the geological section is judged. 2 The disadvantage of the method is the ambiguity of measurement of the recorded parameters due to too high sensitivity to vertical heterogeneity of the section, as well as to changes in the sounding frequency 60 of the separation r if the measurements are made with submerged installation used in marine electrical prospecting.

The aim of the invention is to increase the detail of the dismemberment.

The goal is achieved according to the method of electromagnetic sounding, in which the electromagnetic field is excited, with the help of measuring electrodes placed on the profile, the electric or magnetic components of the electromagnetic field are measured at a predetermined distance tf, starting from the moment current is switched on in the supply circuit, or with a given discrete sequence of wavelengths T (. and judging by the results of measurements about the structure of the geoelectric section, measurements are made in time, corresponding to the constant for all spacings, the ratio of the parameter ti or wavelength to the magnitude of the spacing at which the measurement is made. const, (This means that where ir fi-if tt are the measurement time points p, is the average electrical resistivity The upper layer | U is the magnetic permeability of vacuum. Sounding by this method is possible by varying the wavelength L (in the variant of frequency probes with measuring amplitudes), the analogous condition (1) is const where li N is the angular frequency. The ratio of the time analogue of the wavelength C J to the separation r for all separations is selected from an analysis of theoretical curves equal to 1: 3 and the separation range is chosen from the thickness of the upper layer h of rocks to twice the thickness of the water layer. The measurement results are presented in the form of effective resistances {equal to the product of the measured potential difference at each spacing, subject to condition (1). and (2) on the installation factor. An increase in resolution, t, e, of detail, is achieved because measurements are carried out on a series of separations, subject to the condition (.1), FP provides a complete sounding curve, and on this basis -. possibility of exploration of layers of horizontally layered medium and measurement. Selection at each spacing li “; the ratios -yy const or con gives the opportunity to measure-; nor in the optimal time interval of the transition process, in which the signal is determined by the high-frequency components of its spectrum and is already sufficiently intense to determine it with certainty. Fig, 1 shows the location of the supply and receiving electrodes, Fig, 2 is a block diagram of the measuring equipment. The instrumentation contains 1 and 2 supply and 3-12 receiving electrodes, source 13, switch 14, control device 15, amplification and recording channels 1b., ,,, 16p, preamplifier 17, filter 18, normalizing multiplier 19 / the key 20, the drive 21 and the recorder 22, the electromagnetic field is excited by a source of electric (grounded line) or magnetic type (non-grounded circuit) by a sequence of square current pulses 3. The efficiency p of the exciting pulses -j is two or more times the maximum notch For the measurement time point (to ensure the attenuation of the field from each previous excitation cycle), the measurement is performed with a bottom installation with a set of receiving lines 3-12 located at some distance from the supply dipole 1-2, starting from the moment the current is switched on. Measurements of the potential difference of a non-stationary field are made at n points, observing (1) or (2) for each condition on a series of separations. The measurement results are in the form of effective resistances. equal to the measured potential difference per installation coefficient (equal to the K JrZ dipole installation), the Full Formation (sounding) curve is plotted on a biharithmic scale. Interpretation of sensing data is performed using specially designed pallets by combining experimental curves with theoretical ones. The method is carried out as follows. Measurements are made using a multi-channel braid, which is a multi-strand cable in a rubber or polyethylene hose, each of the cores is output on the outer an electrode, which is a lead ring, covering the cable along its outer surface. Sensors can be towed along the bottom or placed on the bottom with the help of ships or underwater vehicles. Two electrodes 12 are used to drive the field, the remaining 3-12 are for receiving signals. In the particular case, every other electrode of the preceding receiving pair is the first electrode of the subsequent receiving pair (Fig ,one). When etsm distance 2-3, 2-5, 2-7, 2-9, etc. from the second supply electrode 2 to the first of each pair of receiving electrodes 3-12 increase exponentially with a step. The following distances are recommended, respectively 1-1.41-2-2.82, -4-5.66-8- 11,3-16-22, -6-32-49,4-64, In this embodiment, a total of 13 receiving electrodes are used, which form 12 receiving pairs. This setup provides sounding from rock depths of 0.5 m to 15 mm. With this sample of differences in the correlation condition -tp- 2 f- 1, the time analogs t.j of wavelengths should vary from -2 to 128 m. With a specific electrical resistivity of the seabed rocks of 40 mm, the recording time is 0.05; 0, 0.1} 0, .4l; 0.2, 0.82, 0.4; 0.566; 8 1.13} 1.6J 2.26, 3.4; 4.94 cm. In the case of using a harmonic source of observation, it is necessary to carry out the following set of frequencies f 40; 20; 10; five; 2.5u 1.25 0.625V 0.3125, 0.1562; 0.0781, 0.0 .0.0959.6.00977 MHz. The field of formation of a source of pulsed current located at the bottom in the region of time t associated with the distance between the source and receiver g and the specific electric wire of the water and rock-bearing materials “Jfl and 6 is characterized by the ratio Ot 0.2–5, Gjj and 6i - specific electrical conductivity of water and bottom. This corresponds to a ratio of -p- "1:10 for otioshenie. A change in the electrical resistivity of a higher resistive lower medium corresponding to the rocks of the sea bottom leads to drastic changes in the effective resistance values when the values of L 2 g. The smaller the ratio p j the more effective resistance depends on the electrical resistivity of the lower medium. In contrast, as the ratio increases, the differences between the curves correspond to different electrical resistivity and p. Physically, this is explained by the fact that electromagnetic waves propagating through a medium with a low electrical resistivity rapidly fade out and the magnitude of the field at the receiving point in the main wave is determined by electromagnetic waves propagating with a high electrical resistivity in this case along the lower . At low frequencies, the damping effect does not manifest itself and, therefore, on the right-hand side, the effective resistances depend very little on the electrical resistivity of the medium with a relatively high electrical resistivity. Along with damping effects, the effect of uneven current spreading on media with different electrical resistivity acts. Due to this effect, the influence of the medium of small electrical resistivity is manifested in the entire range of wavelengths or their time analogues. In the region of large wavelengths and their temporal counterparts of 4 g, the attenuation effects are much lower than the effect of nonuniform spreading, and in this case, the main effect on the measurement results is produced by a low-resistance medium (sea water). In the case of short wavelengths I, 3 g, the effect of nonuniform spreading remains approximately at the same level, but the attenuation effects increase exponentially, therefore, a medium with a higher electrical resistivity (rocks of the sea bottom) has a greater influence on the measurement results. Analysis of the theoretical curves shows that it is advisable to choose the ratio (1) equal in the range from 1 to 3. The equipment in the variant of temporary changes in the field formation (Fig. 2) ensures the sending of rectangular-shaped current pulses with a duration, -in 2 exceeding the maximum time lag of measurement. The switch 14 is controlled by a control device 15. The measurements are carried out using 12 measuring channels 16-i, each of which is connected to a pair of receiving electrodes. The measuring channel consists of a preamplifier 17, a filter 18, a normalizing amplifier 19, a key 20, an accumulator 21, a registrar. 22, Loshl pre-amplification in the amplifier, the signal is filtered by a filter, frequencies greater than Y, f J are cut off (where tn is VM minimum shedding), and smaller than (where T is the sending period). With the help of the normalizing amplifier 19, the signal is amplified with a gain factor proportional to the coefficient of the corresponding dipole installation. The key 20 is used to sample the signal with a calculated delay, the sample with respect to the leading edge of the pulsed pulse / set from condition (1) or (2). The accumulator 21 is smoothed on accumulator 21. The smoothing values are recorded by the registrar 22. It can be arranged by sequential registration of the measurements accumulated over many channels.

The method makes it possible to increase the sensitivity of marine electrical prospecting to heterogeneities of the electrical resistivity of the seabed in a horizontally layered medium, with the specific resistivity of rock formations greater than the specific: resistance of the aquatic environment. Exploration of the upper part of the seabed during the exploration and geological work on the shelf will provide an opportunity for the strength of soils, in particular, to determine the thickness of the upper layer of unconsolidated rocks and to predict the bearing capacity of soils when laying to the bottom of structures and apparatuses. The basis for the prediction is a close correlation with the relative resistivity of water-saturated soils with their porosity (the correlation coefficient is 0.95-0.98)

Measurements with the installation, consisting of the mountains of

The loops and receiving electric DnPol located at a certain distance from the loop are technically eutective. The possibility of translating measurements in motion with such an arrangement: 5 is completely excluded.

 . The use of a dipole-axial adjustment, a source and a receiver of an eclectic type provides for the possibility of measuring in motion 6 sufficiently: accurate resolution, which increases the performance of the electric; Aeronautical works and applications of applicability in the marine ts electrical prospecting of the method of electro-magnetic soundings.

In comparison with the known ones, the proposed method is also distinguished, along with a greater resolution, with the ability of more informative, while maintaining depth, high projvo | (by measurement, possibility of use in areas with difficult grounding conditions.

Claims (1)

METHOD OF ELECTROMAGNETIC PROBING, in which an electromagnetic field is excited, using the measuring electrodes placed on the profile, measure the electrical or magnetic components of the elec- tric. of a magnetic field at a given sequence of spacings at given times, starting from the moment the current in the supply circuit is turned on, or with a given discrete sequence of wavelengths and according to the measurement results, we judge the structure of the geoelectrical section, which consists in that, in order to increase the detail of the partition section, measurements are carried out at time points corresponding to a constant ratio of the formation parameter or wavelength v to the separation value at which l is measured for all spacings.