RU2388023C1 - Method for marine seismic survey and device for realising said method - Google Patents

Abstract

FIELD: physics; geophysics.

SUBSTANCE: invention is relates to geophysical exploration and may be used in marine seismic survey. The device for marine seismic survey consists of a power supply, an acoustic signal receiver, a device for processing measured signals and a device for exciting elastic vibrations. The device for exciting elastic vibrations is made from a flat-topped metal frame, in the top part of which there is a spark plug connected to the power supply. Electrodes are mounted on the top components of the flat-topped structure. The device is used to excite elastic vibrations in a semi-closed space bordered by the metal frame on three sides, through the spark plug across which voltage is applied. The acoustic signal is picked up. The measured signal is processed. The device described above is also used to generate an electromagnetic field through current pulses. The potential gradient of the electric field generated electrochemically and the potential gradient of the electric field caused by movement of water in the magnetic field of the Earth are also measured.

EFFECT: increased information content of marine seismic survey.

5 cl, 2 dwg

Description

The invention relates to the field of geophysical exploration, and more particularly to methods of marine seismic exploration.

The known method of marine seismic exploration [1] includes the excitation of elastic vibrations, registration of the reflected waves along the profile with a multi-channel receiving device, and also accumulation of information at a fixed midpoint at which, in order to achieve a technical result, which increases the detail and information content of seismic exploration by increasing resolution and noise immunity of seismic data, the movement of the source and the multi-channel receiving device is carried out by I see the direct and reverse course of the ship (vessel) with a successive change in the distance between the source and the receiving device when changing the course, while simultaneously fixing the position of the first and last common midpoints on the profile, the multichannel receiver is positioned vertically with a variable base selected depending on the depth of the layer under study , and the accumulation of information is carried out at both midpoints and at the same time along vertical bases, while additionally moving the multichannel source at many devices in parallel profiles arranged at a distance from each other, selected from the conditions of storing at a common depth point in space.

The known device for marine seismic exploration [2] includes a linear group of working pneumatic emitters of seismic signals associated with floats fixed to the carrier rope by means of flexible elements connected by electric and gas lines to the control panel of the seismic station, and means for placing pneumatic emitters and floats on board the vessel , which is made in the form of a winch equipped with a drum for placement of a supporting rope on it, the side cheeks of the drum contain sockets for mounting a pneumatic radiator th and slots to accommodate the sleeves of electric and gas pipelines, a guide mechanism is fixed in front of the winch drum, orienting the air emitters and floats in the direction of the drum sockets, and the emitters and floats are connected to the carrier rope via carabiners.

The known seismic-acoustic detector [3] contains an acoustic microphone connected to the input of the amplifier of the acoustic channel, and a seismic receiver connected to the input of the amplifier of the seismic channel, a power source and a transmitter, a logical processing unit, an interface unit and a control and control panel.

The known method of geoelectrical exploration [4] includes the excitation of the electromagnetic field in the geological environment by current pulses, in the pauses between which the transient signal is received, filtering by n filters, amplification and registration in digital form, based on which the structure of the medium under study is judged, in which the achievement of the technical result, which consists in increasing the noise immunity, adopted in the pauses between the excitation pulses of the transient signal is filtered, discretely reducing the top the cutoff frequency of the filters passing with a uniform sampling step, the value of n is set not less than the number of determined parameters, and the maximum values are recorded in digital form in the transient signal obtained after each filtering, which are used to judge the parameters of the medium under study.

In the known method of geoelectrical exploration and a device for its implementation [5], an electromagnetic field is excited in a test medium sequentially at two predetermined frequencies using an adjustable source, receive at these frequencies at the measurement points and measure the first and second geometric potential differences of the electric field, according to which mapped parameter, in which to achieve a technical result, which consists in increasing the sensitivity and selectivity of identifying precursors of the earth of shocks, the signal component in phase with the EMF of the source is received at the measurement points, and the distance from the measurement points to the source is set at least 20 km, and the device for implementing the method comprises a horizontal dipole two-frequency alternating current source, a receiver, which includes sensors of the first and second differences of electric potentials, a recorder in which the receiver contains a divider, a synchronous detector, a drive and a control unit.

Known methods and devices [1-5] for performing marine seismic exploration include the artificial excitation of a seismic wave with subsequent registration of an acoustic or electromagnetic signal by means of hydrophones, usually mounted on a trawl, towed by a vessel or receiver of electromagnetic waves. The acoustic signals measured by the hydrophone or the receiver, electromagnetic waves, the signals are further processed (amplification, filtering, etc.) with the selection of a useful signal that carries information about the possible propagation of seismic waves.

The main disadvantage of the known methods and devices for their implementation is that they do not have high information content, as they measure only acoustic or only electromagnetic fields.

The objective of the proposed technical solution is to expand the information content in the implementation of marine seismic exploration.

The problem is solved due to the fact that in the method of marine seismic exploration, which includes the excitation of elastic waves with subsequent registration of the acoustic signal through the receiver of acoustic signals, processing the measured signals, excitation of the electromagnetic field by current pulses, in which the artificial excitation of elastic oscillations is carried out in a semi-closed space, limited metal frame on three sides, by means of a spark plug, to which voltage is supplied, while The potential gradient of the electric field of electrochemical origin and the gradient of the potential of the electric field caused by the movement of water in the Earth’s magnetic field are recorded accurately, while the excitation of elastic vibrations is carried out over the interval of rise, culmination and decline of the lunar tide of the earth’s crust, the gradient of the potential of the electric field due to the movement of water in Earth's magnetic field, register in the infra-low-frequency range of the waveguide seawater - soil, processing of the measured signals they are constructed by constructing the Stern – Brocko binomial tree, and in the device for its implementation, consisting of an elastic oscillation excitation device, an acoustic signal receiver, a power source, a measured signal processing device, the elastic oscillation excitation device is made of a metal frame in the form of a U-shaped structure , in the upper part of which there is a spark plug connected to a power source, and electrodes are installed in the vertical components of the U-shaped design.

New distinctive features of the claimed technical solution are: artificial excitation of elastic vibrations is carried out in a semi-enclosed space bounded by a metal frame on three sides, by means of a spark plug, which is supplied with voltage, while the gradient of the electric field potential of electrochemical origin and the gradient of the electric field potential due to the movement of water in the Earth's magnetic field, while the excitation of elastic vibrations is carried out the gradient of the electric field caused by the movement of water in the Earth’s magnetic field is recorded in the infra-low-frequency range of the waveguide sea water-soil, the processing of the measured signals is carried out by constructing the Stern-Broco binomial tree, and in a device for its implementation, consisting of a device for exciting elastic vibrations, an acoustic signal receiver, a power source, a device for processing measured signals, - the device for the excitation of elastic vibrations is made of a metal frame in the form of a U-shaped structure, in the upper part of which there is an spark plug connected to a power source, and electrodes are installed in the vertical components of the U-shaped structure.

From the prior art, a combination of new features has not been identified, which allows us to conclude that the proposed technical solution meets the patentability condition "inventive step".

The method is implemented as follows.

Fig 1. The device excitation of acoustic and electromagnetic fields. The device consists of a metal body of a U-shaped shape 1, in the upper part of which a spark plug 2 with an excitation coil 3 is mounted, to which a voltage of 30 V is supplied from a power source 4. Electrodes 5 are installed in the vertical components of the U-shaped structure 1.

Figure 2. The block diagram of the device consists of an acoustic and electromagnetic field excitation device 6, multi-channel receivers 7, a logic device 8, a measurement and computing module 9, a hydroacoustic communication channel 10, a block of linear and angular displacement sensors 11.

The device (figure 2) can be installed both on autonomous bottom stations (patents RU No. 2276388, No. 2294000), and underwater observatories and apparatuses or used independently.

When power is supplied to the spark plug 2 through an excitation coil in a semi-enclosed space formed by a U-shaped housing 1 filled with sea water, an electromagnetic field is created and elastic vibrations are excited due to the electrochemical reaction between oxygen and hydrogen ions. Electromagnetic signals in the form of current pulses are received by the electrodes 5 and transmitted to the measuring and computing module 9. At the same time, acoustic signals created by elastic vibrations are received by multichannel receivers of acoustic signals 7.

In this case, electric fields of electrochemical origin are also formed, due to the electrode potentials between the metal casing 1 and the electrolyte (sea water), contact-liquid potentials formed by a closed circuit metal (body), sea water, soil (see, for example: 1. Bogorov V .G., Demenitsyn R.M., Gorodnitsky AM // On the nature and causes of changes in the natural field of the water column vertically // Oceanology, 1969, vol. 9, No. 5, p. 767-772; 2. Antropov L.I. Theoretical electrochemistry. M., 1975-274 p.), The movement of water in a magnetic field Earth. The signals characterizing the electric fields of electrochemical origin are fed to the measuring and computing module, where the signal analysis is performed according to the values of the potential gradient. Electric fields of electrochemical origin have a potential gradient of 300 μV / cm. In this case, by means of the logic device 8, the electric field signals are extracted due to the movement of water in the magnetic field (potential gradient 0.5 μV / cm). By increasing the potential gradient of 6-10 μV / cm, which is recorded in the infra-low frequency range at the 1st resonant frequency of the sea water-ground waveguide, the probability of the occurrence of storm waves (tsunamis) is established.

Using a block of linear and angular displacement sensors, signals are recorded that characterize the tidal oscillations of the Earth's crust (soil). The solid crust of the Earth also experiences tidal fluctuations, as well as the water masses of the oceans. The tidal oscillations of the Earth's crust are also harmonic, i.e. the oscillation phase is a smooth function. However, due to the fact that the crust is a more rigid medium, phase shifts accumulate in adjacent areas of the crust with different elastic characteristics, which are not removed by the formation of amphidromic points, but are removed by the formation of earthquakes. The analysis of the spatiotemporal distribution of the phases of tidal oscillations in the Earth's crust is performed in the measuring and computing module 9 in the following sequence.

Measurement of sea ground vibrations is performed at various points in the sea at different points in time so that the measurements obtained at each measurement point have different values of time intervals relative to the last moment of the upper culmination of the moon at the fixed geographical meridian closest to the moment of measurement. At the same time, the measured values of the ground level at the points of the sea water area, which are arranged in increasing time interval between the nearest previous moment of time of the upper culmination of the moon on a fixed meridian and the moment of measurement, allow us to establish the time course of the level under the influence of the tidal forces of the Earth’s crust, due to the fact that tidal fluctuations at some point in the sea, they have a practically constant phase shift relative to the time of the upper climax of the moon on a fixed geographic meridian e. Since the combinations of the phases of the Moon’s movement around the Earth and the phases of the fluctuation of the sea ground level at some point are repeated with the period of the Moon’s movement around the Earth, the measured values of the sea ground level at a certain point in the sea’s area are arranged according to the increase in the time interval between the nearest previous time point of the upper climax The moons on a fixed geographical meridian and the moment of measurement, represent a change in the phase of the tide, and therefore the temporal course of the level at the measurement point under the action of ilivnyh forces.

According to the measured instrumental values, sea level fluctuations form observation series.

The tide height values of the specific harmonic component of the wave h (t) are determined, which is determined by the amplitude A, the angle of position g (A and g are harmonic constants) and the period T, in accordance with the dependence h (t) = Acos (qt-g), where q is the angular velocity of the harmonic wave in one hour of average time, t is a fixed point in time.

The amplitudes of the harmonic component of the tidal height of the Earth's crust are determined.

To analyze harmonic oscillations, the time axis is divided into equal segments, which are subsequently combined with each other. In the cyclic time thus obtained, the measurement moments describe the changes in the function over one period, which provides a connection between the continental (solar) and oceanic (tidal) time in accordance with the dependence x = y-y _m , where x is the tidal time (the number of tidal days the beginning of the tidal year), y is the date of solar time (the number of days from the beginning of the year), _m is the number of days between solar and tidal time (the number of days from the beginning of the year). Due to the fact that the periods of the measurement time system and the periods of harmonics of the oscillatory process can be incommensurable, the cyclic time is converted to linear in accordance with the dependence r (t) = ω _τ t, where r (t) is cyclic time, t is linear time , ω _τ is the frequency of the cyclic time system.

Next, further processing is performed taking into account the converted time. In this case, the oscillatory process q at each fixed moment of time is a function of two frequencies q (t) = q (ω ₀ t, ω _τ t), and at each moment of time t, the value of the oscillatory process q (t) will be a function of two independent variables: phases φ ₀ (t) = ω ₀ t and phases φ _τ (t) = ω _τ t, which are the coordinates of the phase space.

The values of the tidal height of the Earth's crust h = h (x, y) are determined for a sequential set of discrete time values h = h (x, y, t), for example, by the grid method (see, for example, Lavrentiev M.A., Shabat B.V. Methods of the theory of functions of a variable. M.-L. GITTL, 1958).

According to the obtained values of the tide height for a sequential set of discrete values of time, the oscillation amplitudes of the harmonic component are determined, for example, at the grid nodes.

From the obtained values h = h (x, y, t), the time of the onset of the maximum level is determined.

In the analysis of the periodic component of the oscillatory process, many real numbers are used, which allows us to determine the real variability of the oscillatory process.

The determination of the time interval between the closest previous moment of time of the upper culmination of the Moon and the moment of the upper culmination of the Moon allows us to determine the temporal course of tidal fluctuations of the Earth's crust at various points in the sea and to obtain the spatial course of tidal fluctuations in this area for any astronomical time. The measured values of the Earth’s crust level at some points of the sea area, arranged by increasing the time interval, allow us to determine the time course of the level at the measurement point under the influence of tidal forces by changing the tidal phase.

Due to the fact that the oscillatory process q of the Earth’s crust level at each fixed moment of time will be a function of two frequencies q (t) = q (ω ₀ t, ω _τ t), and at each moment of time t the value of the oscillatory process q (t) will be being a function of two independent variables: phases φ ₀ (t) = ω ₀ t and phases φ _τ (t) = ω _τ t, which are the coordinates of the phase space, then the probability of reliable separation of the periodic component of the oscillatory process increases. In this case, harmonic constants are determined on the basis of a set of real numbers, which allows us to determine the real variability of the oscillatory process of the Earth's crust level. When performing operations to approximate the obtained results, numerical measurements are recorded in the Stern – Broco symbol system (1. Graham R., Knut D., Patashnik O. Concrete mathematics. - M.: Mir; BINOM. Laboratory of knowledge, 2006. - 703 p. 2. Aigner M., Ziegler G. Evidence from the Book. - M.: Mir, 2006. - 256 p.). The hierarchical graph structure of the Stern-Broco system makes it possible to quickly search for close numbers represented with different errors due to primary measurement sensors, since this corresponds to a different number of characters in the Stern-Broco representation. Fewer characters in the view are a sign of a large margin of error. This property of the Stern-Brokaw system allows us to present in a simple way the number given or measured with some error, a number with a larger error by simply reducing the rejection of the last characters. In decimal notation, what takes place in known methods cannot be carried out. Recording a number in the Stern – Broco symbol system contains information not only about the measured value, but also contains information about the error in representing the number, since the sequence of characters in the representation of the number is determined by all the corresponding nodes in the Stern – Broco tree. For the lowest node, you can find its neighbors, both vertically and horizontally, which allows you to evaluate the accuracy of the representation of the number and go to the representation with a different accuracy. The algorithms for finding the nearest and next numbers are known and very efficient from a computational point of view. Representation of a symbolic record of a number in the Stern-Broco system in binary form requires less memory than with the interval representation of numbers, which takes place in the known methods of marine seismic exploration.

The proposed method is implemented on devices having industrial applications, which leads to the absence of technical risks in its application.

The hydro-acoustic communication channel 10 is intended for transmitting measured information to dispatching stations and receiving command signals.

In contrast to the known methods of marine seismic exploration, the proposed method allows to obtain a wider range of signals about the state of geophysical fields, which increases the reliability of the forecast of earthquakes, as well as the occurrence of tsunamis.

Information sources

1. Copyright certificate SU No. 1766180.

2. Patent RU No. 2032190.

3. Patent RU No. 2032222.

4. Copyright certificate SU No. 1770776.

5. Copyright certificate SU No. 1770774.

Claims (5)

1. The method of marine seismic exploration, including the excitation of elastic vibrations followed by registration of the acoustic signal, processing the measured signals, the excitation of the electromagnetic field by current pulses, characterized in that the artificial excitation of elastic vibrations is carried out in a semi-enclosed space bounded by a metal frame on three sides, using a spark plug which is supplied with voltage, while additionally registering the gradient of the potential of the electric field of the electrochemical origin and the potential gradient of the electric field caused by the movement of water in the earth's magnetic field. 2. The method of marine seismic exploration according to claim 1, characterized in that the excitation of elastic vibrations is carried out on a time interval of rise, culmination and decline of the lunar tide of the earth's crust. 3. The method of marine seismic exploration according to claim 1, characterized in that the gradient of the electric field potential due to the movement of water in the Earth's magnetic field is recorded in the infra-low-frequency range of the waveguide, sea water - soil. 4. The method of marine seismic exploration according to claim 1, characterized in that the processing of the measured signals is carried out by constructing a Stern-Broco binomial tree. 5. The device for marine seismic exploration, consisting of a device for exciting elastic waves, an acoustic signal receiver, a power source, a device for processing measured signals, characterized in that the device for generating elastic waves is made of a metal frame in the form of a U-shaped structure, in the upper part of which is installed a spark plug connected to a power source, and electrodes are installed in the vertical components of the U-shaped design.

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