RU2636799C1 - Method of search and prospecting of hydrocarbon pools (variants) - Google Patents

Abstract

FIELD: oil and gas industry.

SUBSTANCE: according to the first version the method of search and prospecting of hydrocarbon pools consists in three-component seismic receivers placed at a distance from 100 meters to 10,000 meters relative to each other, information signals are registered and recorded with at least two three-component seismic receivers of low-frequency range with synchronous registration of information signals from three channels on three components (x, y, z) in frequency range from 0 Hz to 50 Hz. By measured components (x, y, z) for a period of time which is sufficient to record a statistically significant noise signal in the low-frequency range, the vector characteristics of the measured oscillation fields are calculated: the divergence, rotor, and vector product of horizontal components of received information signals. The presence or absence of hydrocarbon pools is evaluated by ratio of spectral power f1, f2 parameters in the range from 0 Hz to 7 Hz to spectral power of f1, f2 parameters in the range from 0 Hz to 7 Hz. According to the second version the method includes additional generation of seismic vibrations by geophones periodically generating oscillations for 30 -40 sec with a pause for 20 -30 seconds, and the judgment regarding the presence of hydrocarbon pools is provided if the correlation dimension of initial vector field of velocities (F) is in the registration mode the Earth`s seismic noise is greater than the correlation dimension of initial vector field of velocities (F) in the registration mode of information signals with the use of periodic vibrations of the seismic vibrator. According to the third version of the claimed method, the judgment on the presence of hydrocarbon deposits is provided if the correlation dimension of initial field rotor (E) in the registration mode the Earth`s seismic noise is greater than the correlation dimension of initial field rotor (E) in the registration mode of information signals with the use of periodic vibrations of the seismic vibrator.

EFFECT: more reliable detection of hydrocarbon pools.

5 cl

Description

The invention relates to the field of seismic research and can be used in the search for hydrocarbon deposits.

A known method for the exploration of hydrocarbons using four three-component geophones. A method for processing seismic data includes collecting seismic data related to wave fields over a selected volume. Seismic data obtained using seismic receivers are processed, P-wave components and S-wave components are extracted. The seismic receivers are spaced apart from each other by distances shorter than the wavelength of the detected seismic components, preferably less than 1 meter. Then, wavefield characteristics such as divergence and rotor are calculated from the seismic data to thereby determine the seismic components within the seismic data. (US Patent No. 6791901, IPC G01V 1/00; G01V 1/20, publ. 09/14/2004).

The known method processes the data of the classical seismic acquisition scheme with sources, which are used as seismic vibrators, and the receiver is one or three-component vibration sensors. As a result, P waves traveling along the surface and reflected from the inner layers of the S wave are processed. The result of such processing is simply a sign of the presence or absence of deep waves, which does not yet indicate their belonging to the waves from hydrocarbon deposits.

The closest in technical essence and the achieved technical result to the claimed invention is a hydrocarbon search method, which includes recording the earth's seismic noise containing an information signal from a hydrocarbon field at a frequency of 2-5 Hz, followed by analysis. In a known hydrocarbon field, a standard form of information signal is determined. The calculated energy spectrum is used as an information signal. At the proposed field, the same information signal is determined. Break the time range of registration into discrete sections. Each discrete section is analyzed for the presence of a standard form of the information signal, as well as for the presence of distortions of the information signal, which are technogenic in nature. Discrete sections that do not contain the standard form of the information signal, as well as discrete sections containing these distortions, are excluded from further consideration. An analysis is made of the remaining discrete sections with a judgment on the presence or absence of a hydrocarbon field. In this case, the information signal is divided into equal discrete sections, the size of the discrete section corresponds to a time interval corresponding to at least 8-10 periods of the signal of the lowest frequency of the range. Additionally, in the process of registering Earth's seismic noise containing an information signal from a hydrocarbon field, oscillations are generated on the Earth's surface, which is carried out after the start of registration of Earth's seismic noise containing an information signal from a hydrocarbon field and is stopped until the end of registration of Earth's seismic noise containing an information signal from a hydrocarbon field. (RF patent No. 2251716, IPC G01V 1/00, publ. 05/10/2005).

In the known method, the information signal is the energy spectrum of each of the measured components (x, y, z). In order to make a judgment about the presence or absence of a hydrocarbon field, it is proposed to compare the shape of the spectrum above the field and outside the field, while the data is processed using the Fourier transform. The disadvantage of the proposed method is the recording duration of more than 24 hours to determine the shape of the useful signal, while technogenic noise constants and variables can fall into this form, which leads to the lack of reproducibility of the results at different times of the day and seasons. Also known are works on the influence of the lunar phases on the spectral power determined in this way (Thesis. Processing of microseismic signals in the problem of passive low-frequency seismic sounding of the Earth. Scientific library of dissertations and abstracts disserCat http://www.dissercat.com/content/obrabotka-mikroseismicheskikh- signalov-v-zadache-passivnogo-nizkochastotnogo-seismicheskogo- # ixzz4NQuFqPEj).

The use of the Fourier transform in this method is not true, because The Fourier analysis allows only stationary signals to be qualitatively processed, but in reality, noise and a random process of spontaneous oscillations of a hydrocarbon deposit are simultaneously recorded on the surface. Thus, when processing a significant improvement in the quality of analysis is the rejection of spectral (frequency) characteristics and the transition to data processing in the time domain

The technical problem to be solved by the claimed invention is directed is to increase the reliability of detection of hydrocarbon deposits by identifying signals in the time range characterizing the presence of a deposit.

The stated technical problem is solved by the fact that in the method for the search and exploration of hydrocarbon deposits, which consists in placing three-component seismic receivers at observation points of seismic vibrations, the earth's seismic noise containing an information signal from a hydrocarbon field is recorded, information signals are analyzed with a judgment on the presence of or the absence of hydrocarbons, according to the claimed invention, three-component seismic receivers are placed at a distance from 100 meters to 100 00 meters relative to each other, register and record information signals from at least two three-component low-frequency seismic receivers with synchronous acquisition of information signals from three channels in three components (x, y, z) in the frequency range from 0 Hz to 50 Hz over the measured components (x, y, z) for a period of time sufficient to record a statistically significant noise signal in the low-frequency range, vector characteristics of the measured vibration fields of divergence and mouth are calculated OR and the vector product of the horizontal components of the received information signals, evaluate the presence or absence of hydrocarbon deposits in relation to the spectral power of parameters f1, f2, e1, e2 in the range from 0 Hz to 7 Hz, calculated according to the first sensor, to the spectral power of parameters f1, f2 , e1, e2, calculated in the range from 0 Hz to 7 Hz according to the readings of the second sensor, namely

at a statistically significant value of the ratio of the spectral power of parameters f1, f2 in the range from 0 Hz to 7 Hz, calculated according to the readings of the first seismic receiver, to the spectral power of parameters f1, f2, respectively, calculated in the range from 0 Hz to 7 Hz according to the readings the second seismic receiver in the range from 0.6 to 1.5, make a judgment on the presence of hydrocarbon deposits at these observation points;

at the same time, if the value of the ratio of the spectral power of parameters e1, e2 in the range from 0 Hz to 7 Hz, calculated according to the testimony of the first seismic receiver, to the spectral power of parameters e1, e2, respectively, calculated in the range from 0 Hz to 7, is statistically significant throughout the recording of the signal Hz according to the testimony of the second seismic receiver in the range from 0.6 to 1.5, then they make a judgment about the presence of gas-saturated hydrocarbon deposits at these observation points;

with a statistically significant ratio of the spectral power of the parameters f1, f2 in the range from 0 Hz to 7 Hz, calculated according to the testimony of the first geophone, to the spectral power of the parameters f1, f2, calculated in the range from 0 Hz to 7 Hz according to the testimony of the second geophone is more than 3, a judgment on the location of the first geophone above the field and the second geophone outside the field;

at the same time, if the value of the ratio of the spectral power of parameters e1, e2 in the range from 0 Hz to 7 Hz, calculated according to the readings of the first seismic receiver, to the spectral power of parameters e1, e2, respectively, calculated in the range from 0 Hz to 7 Hz according to the testimony of the second seismic receiver is more than 3, then they make a judgment about the location of the first seismic receiver over a gas-saturated field.

The stated technical problem is also solved by the fact that in the method for the search and exploration of hydrocarbon deposits, which consists in placing three-component seismic receivers at observation points of seismic vibrations, the earth's seismic noise containing an information signal from a hydrocarbon field is recorded, information signals are analyzed with a judgment on the presence or absence of hydrocarbons, according to the claimed invention, conduct additional generation of seismic vibrations of seismic vibrators a three-component seismic receivers are placed at a distance from 100 meters to 10,000 meters relative to each other, register and record information signals from at least two three-component seismic receivers, periodically generating oscillations for 30-40 seconds with a pause of 20-30 seconds. low-frequency range with synchronous removal of information signals from three channels in three components (x, y, z) in the frequency range from 0 Hz to 50 Hz, in the measured components (x, y, z) for a period of time sufficient for records of a statistically reliable noise signal in the low-frequency range, calculate the vector characteristics of the measured vibration fields: divergence, rotor and vector product of the horizontal components of the received information signals, a judgment on the presence of hydrocarbon deposits is made if the correlation dimension of the initial field F in the Earth's seismic noise recording mode is greater than correlation dimension of the field F in the mode of recording information signals using periodic oscillations of seismic bratora.

In addition, the judgment on the presence of hydrocarbon deposits is made if the correlation dimension of the field E in the Earth seismic noise registration mode is greater than the correlation dimension of the field E in the information signal registration mode using periodic vibrations of the seismic vibrator.

In addition, the judgment on the presence of hydrocarbon deposits is made if the source field F has an attractor of correlation dimension more than 10 in the seismic background recording mode of the Earth and the source field F has an attractor of correlation dimension from 2 to 6 in the mode of recording information signals using periodic oscillations of the seismic vibrator.

In addition, the judgment on the presence of hydrocarbon deposits is made if the field E has an attractor with a correlation dimension of more than 10 in the registration mode of the Earth's seismic background and there is an attractor in the field E of a correlation dimension from 2 to 6 in the mode of recording information signals using periodic oscillations of the seismic vibrator.

The technical result, the achievement of which is ensured by the implementation of the entire claimed combination of essential features, is to increase the reliability of detection of hydrocarbon deposits.

The inventive method is based on the analysis of three-dimensional vector fields of medium vibrations (speeds or accelerations) measured on the earth's surface by three-component seismic receivers of the low frequency range.

The method of search and exploration of hydrocarbon deposits is as follows.

Pre-determined observation points on the search area and placed at the observation points three-component receivers of seismic vibrations. Three-component seismic receivers are placed at a distance from 100 meters to 10,000 meters relative to each other.

The specified interval is optimal for the implementation of the proposed method. When the receivers are located at a distance of less than 100 meters and the depth of the deposit is more than 1 km, the signals will practically not differ from each other, when the receivers are placed at a distance of more than 10,000 meters, the signal from the deposit is very weakened due to natural physical reasons.

Next, information signals are recorded and recorded from at least two three-component low-frequency seismic receivers with synchronous acquisition of information signals from three channels in three components (x, y, z), i.e. without phase delays between the channels of each seismic receiver and small time delays between seismic receivers.

In this case, registration and recording are carried out in three coordinates (components) of information signals in the frequency range from 0 Hz to 50 Hz. The specified frequency range is optimal for the implementation of the proposed method. At frequencies of more than 50 Hz, almost all technogenic disturbances work. As a result, in the recorded signal of more than 50 Hz, the noise from the reservoir will be at the level of a random low-amplitude additive.

Using the measured components (x, y, z) for a period of time sufficient to record a statistically significant noise signal in the low frequency range, vector characteristics of the measured vibration fields, namely the divergence, rotor and vector product of the horizontal components of the received information signals, are calculated.

The terms “vector field divergence”, “vector field rotor”, “field attractor” used in the description have the following meaning.

If v (x, y, z) is the gas velocity (or fluid flow) field, then the vector field rotor (rot v) is a vector proportional to the angular velocity vector of an infinitesimal particle of a continuous medium.

Divergence of a vector field is a linear differential operator on a vector field that characterizes the flow of a given field through the surface of a sufficiently small (under the conditions of a specific problem) neighborhood of each interior point of the field definition field.

By “field attractor” is meant a compact subset of the phase space, all trajectories from a certain neighborhood of which tend to it at a time tending to infinity. Designations:

1. F (Fx, Fy, Fz) is the initial vector velocity field.

2. E = rot (F). E (Ex, Eu, Ez) is the rotor of the initial field.

The following parameters are analyzed:

1. f1 = [Fx, Fy] is the vector field of P-waves along the profile passing through the field.

2. f2 = Fz-fl = Fz - [Fx, Fy] - the vertical component of the deep S-wave.

3. E = rot (F) is the rotor of the initial field.

4. e1 = [Ex, Eu] is the vector product of the rotor components of the measured field.

5. e2 = Ez-e1 = Ez - [Ex, Eu] - the vertical (deep) component of the rotor field.

6. The presence of attractors of the field E, that is, the ordering of the field over the field.

7. The presence of attractors of the field F.

The effect of seismic noise of a deposit over a hydrocarbon field is taken as the basis (Scientific discovery A-129. Phenomenon of the generation of non-ultrasonic waves by an oil and gas deposit (priority 22.03.97; Arutyunov SL, Davydov VF, Kuznetsov OL, Grafov B. M, Sirotinsky Yu.V. admission 12/25/98; applicant ZAO ANCHAR).

Information signals are recorded and recorded in two modes: only the Earth's seismic background is recorded or the Earth's seismic background is recorded sequentially and information signals are recorded using a seismic vibrator that periodically generates oscillations for 30-40 seconds with a pause of 20-30 seconds.

Information signals are analyzed by methods of vector data analysis with a judgment on the presence or absence of hydrocarbon deposits in relation to the spectral power of parameters f1, f2, e1, e2 in the range from 0 Hz to 7 Hz, calculated according to the first sensor, to the spectral power of parameters f1, f2 calculated in the range from 0 Hz to 7 Hz according to the readings of the second sensor. The presence of gas in the field of hydrocarbons leads to the ordering of field E, thereby reducing the correlation dimension of E. Thus, field E makes it possible to distinguish between hydrocarbon deposits containing gas and hydrocarbon deposits that do not contain gas.

In the course of experimental studies of signals from three-component low-frequency seismic receivers with synchronous signal collection from three channels without phase delays and without time delays, the following criteria for evaluating hydrocarbon deposits were obtained, which ensure high reliability of detection of hydrocarbon deposits.

In the case of simultaneous recording of information signals from two three-component seismic receivers at a statistically significant value of the ratio of the spectral power of parameters f1, f2 in the range from 0 Hz to 7 Hz calculated from the first seismic receiver to the spectral power of parameters f1, f2 respectively calculated in the range from 0 Hz to 7 Hz according to the readings of the second seismic receiver in the range from 0.6 to 1.5, it is judged on the presence of hydrocarbon deposits at these observation points I am. Moreover, if the value of the ratio of the spectral power of the parameters e1, e2 in the range from 0 Hz to 7 Hz, calculated according to the testimony of the first seismic receiver, to the spectral power of the parameters e1, e2, respectively, calculated in the range from 0 Hz to 7 Hz according to the testimony of the second seismic receiver in the range from 0.6 to 1.5, then they make a judgment about the presence of gas-saturated hydrocarbon deposits at these observation points.

With a statistically significant ratio of the spectral power of the parameters f1, f2 in the range from 0 Hz to 7 Hz, calculated according to the testimony of the first seismic receiver, to the spectral power of the parameters f1, f2 calculated in the range from 0 Hz to 7 Hz according to the testimony of the second seismic receiver, is greater than 3, about finding the first geophone above the field, and the second geophone outside the field. Moreover, if the value of the ratio of the spectral power of the parameters e1, e2 in the range from 0 Hz to 7 Hz, calculated according to the testimony of the first seismic receiver, to the spectral power of the parameters e1, e2, respectively, calculated in the range from 0 Hz to 7 Hz according to the testimony of the second seismic receiver is more than 3, then they make a judgment about the location of the first seismic receiver over a gas-saturated field.

It is known that the solutions of dissipative dynamical systems are always in a limited volume of phase space, and they do not fill this entire volume, but over time tend to a subset of it called the attractor of a dynamic system, which has a smaller dimension compared to the dimension of the phase space, which is due to action of dissipative forces and is formalized in the equations of the system. The structure of this subset can be extremely complex. Quite often, these subsets have a fractal or, in other words, structure self-similar at various scales.

To describe the geometric properties of such sets, in particular, concepts of dimensions are introduced (topological dimension, Hausdorff dimension, correlation dimension, information dimension, etc.). Dimensions are important characteristics for the following reasons: firstly, they give an estimate of the number of essential variables needed to describe a dynamical system at the asymptotic stage, and secondly, these are one of the few characteristics that can be estimated from time series in some cases, t .e. directly from the experiment.

From a practical point of view, the correlation dimension is of the greatest interest, since the process of calculating it is much simpler than the others, and it gives a good characterization of the complexity of the attractor of a dynamical system, i.e. degrees of freedom. It is the most common tool for analyzing time series among researchers.

To assess the correlation dimension, the concept of the correlation integral is used, which is defined as follows:

where X, Y are the independent states of the dynamical system. In other words, the correlation dimension C (ε) is the probability of detecting the system in two states, the distance between which is less than ε.

If there exists a constant D such that

C (ε) = const⋅ε ^D as e → 0,

then this constant is called the correlation dimension of the attractor of the system.

In other words, the correlation dimension is the limit

provided that this limit exists.

Conclusions are drawn from the assumption that the higher the gas saturation of the reservoir, the lower the correlation dimension D for field E.

According to the second embodiment of the method, when registering information signals using a seismic vibrator periodically generating oscillations for 30-40 seconds with a pause of 20-30 seconds.

The presence of attractors of the fields E and F indicates the presence of a hydrocarbon deposit.

The judgment on the presence of hydrocarbon deposits is made out of the condition that the correlation dimension of the initial field F in the mode of recording Earth's seismic noise is greater than the correlation dimension of the field F in the mode of recording information signals using periodic vibrations of the seismic vibrator. The judgment on the presence of hydrocarbon deposits is made if the source field F of the attractor has a correlation dimension of more than 10 in the registration mode of the Earth's seismic background and the source field F of the attractor has a correlation dimension of 2 to 6 in the mode of recording information signals using periodic vibrations of the seismic vibrator.

The same effect is also valid for field E. That is, a judgment on the presence of hydrocarbon deposits is made if the correlation dimension of field E in the mode of recording seismic noise of the Earth is greater than the correlation dimension of field E in the mode of recording information signals using periodic oscillations of the seismic vibrator. The judgment on the presence of hydrocarbon deposits is made if the field E has an attractor with a correlation dimension of more than 10 in the mode of recording the earth's seismic background and the presence of an attractor in the field E of a correlation dimension from 2 to 6 in the mode of recording information signals using periodic oscillations of the seismic vibrator.

If, after the action of the seismic vibrator, a certain deterministic component appears in the total microseismic noise, this should lead to a decrease in the correlation dimension calculated for recordings of the microseismic signal after the action of the vibrator compared to the background records before exposure to the vibrator at the same point.

Examples of using.

At the 1st field, 2 wells were considered.

One is empty (without hydrocarbons) HC (B), the second is purely oil (A) (the distance between the wells is 900 m).

The table below shows the calculation parameters of the present method.

Correlation field dimensions at observed points

Attractor Dimensions Field F

Field E

At the 2nd field, 2 wells were considered.

One is empty (without hydrocarbons) HC (B), the second is gas (A) (the distance between the wells is 1,500 m).

The table below shows the calculation parameters of the present method.

Correlation field dimensions at observed points

Attractor Dimensions Field F

Field E

At the 3rd field, 2 points were considered.

Both contain hydrocarbons HC (A) and (B) (gas), (distance between points 1200 m).

The table shows the calculation parameters of the present method

Correlation field dimensions at observed points

Attractor Dimensions Field F

Field E

The proposed method provides high reliability of the detection of hydrocarbon deposits.

Claims (13)

1. The method of search and exploration of hydrocarbon deposits, which consists in placing three-component seismic receivers at observation points of seismic vibrations, recording earth's seismic noise containing an information signal from a hydrocarbon field, analyzing information signals with a judgment on the presence or absence of hydrocarbons, characterized in that three-component seismic receivers are placed at a distance from 100 meters to 10,000 meters relative to each other, register and record information radiation signals from at least two three-component low-frequency seismic receivers with synchronous acquisition of information signals from three channels in three components (x, y, z) in the frequency range from 0 Hz to 50 Hz, in the measured components (x, y, z) over a period of time sufficient to record a statistically significant noise signal in the low-frequency range, vector characteristics of the measured vibration fields are calculated: divergence and rotor and vector product of horizontal components obtained information signals, assess the presence or absence of hydrocarbon deposits in relation to the spectral power of the parameters of the P-wave vector field passing through the field along the profile (f1), the vertical component of the deep S-wave (f2), the vector product of the rotor components of the measured field (e1), vertical ( the deep) components of the rotor field (e2) in the range from 0 Hz to 7 Hz, calculated according to the first sensor, to the spectral power of the parameters of the P-wave vector field passing through the field along the profile i (f1), the vertical component of the deep S-wave (f2), the vector product of the rotor components of the measured field (e1), the vertical (deep) component of the rotor field (e2), calculated in the range from 0 Hz to 7 Hz according to the readings of the second sensor, namely at a statistically significant value of the ratio of the spectral power of the parameter of the P-wave vector field passing through the field along the profile (f1) in the range from 0 Hz to 7 Hz calculated from the first seismic receiver to the spectral power of the parameter of the vector field passing through the field P-waves along the profile (f1), respectively, calculated in the range from 0 Hz to 7 Hz according to the second seismic receiver in the range from 0.6 to 1.5, make a judgment on the presence of hydrocarbon deposits in the data of observation points; at the same time, if the value of the ratio of the spectral power of the parameter of the vector product of the rotor components of the measured field (e1) in the range from 0 Hz to 7 Hz, calculated according to the readings of the first seismic receiver, to the spectral power of the parameter of the vector product of the rotor components of the measured field is statistically reliable throughout the recording of the signal (e1), respectively, calculated in the range from 0 Hz to 7 Hz according to the testimony of the second seismic receiver in the range from 0.6 to 1.5, then a judgment is made about the presence of gas-saturated deposits hydrocarbons at these observation points; at a statistically significant value of the ratio of the spectral power of the parameter of the vertical component of the deep S-wave (f1) in the range from 0 Hz to 7 Hz calculated from the first seismic receiver to the spectral power of the parameter of the vertical component of the deep S-wave (f2) , respectively, calculated in the range from 0 Hz to 7 Hz according to the testimony of the second seismic receiver in the range from 0.6 to 1.5, they make a judgment about the presence of hydrocarbon deposits at these observation points; in this case, if the value of the ratio of the spectral power of the parameter of the vertical (deep) component of the rotor field (e2) in the range from 0 Hz to 7 Hz, calculated according to the testimony of the first seismic receiver, to the spectral power of the parameter of the vertical (deep) component is statistically reliable throughout the recording of the signal rotary field (e2), respectively, calculated in the range from 0 Hz to 7 Hz according to the testimony of the second seismic receiver in the range from 0.6 to 1.5, then make a judgment about the presence of gas-saturated hydrocarbon deposits in observation points; with a statistically significant ratio of the spectral power of the parameter of the P-wave vector field passing through the field along the profile (f1) in the range from 0 Hz to 7 Hz, calculated according to the first seismic receiver, to the spectral power of the parameter of the P-wave vector field passing through the field along the profile ( f1), calculated in the range from 0 Hz to 7 Hz according to the testimony of the second seismic receiver greater than 3, make a judgment about the location of the first geophone above the field, and the second geophone outside the field; at the same time, if the value of the ratio of the spectral power of the parameter of the vector product of the rotor components of the measured field (e1) in the range from 0 Hz to 7 Hz, calculated according to the readings of the first seismic receiver, to the spectral power of the parameter of the vector product of the rotor components of the measured field is statistically reliable throughout the recording of the signal (e1), respectively, calculated in the range from 0 Hz to 7 Hz according to the readings of the second seismic receiver is greater than 3, then they make a judgment on the location of the first seismic receiver over the lawn saturated field; with a statistically significant ratio of the spectral power of the parameter of the vertical component of the deep S-wave (f2) in the range from 0 Hz to 7 Hz, calculated according to the first seismic receiver, to the spectral power of the parameter of the vertical component of the deep S-wave (f2), calculated in the range from 0 Hz to 7 Hz according to the testimony of the second seismic receiver is more than 3, they make a judgment about the location of the first geophysical receiver above the field, and the second geophones outside the field; in this case, if the value of the ratio of the spectral power of the parameter of the vertical (deep) component of the rotor field (e2) in the range from 0 Hz to 7 Hz, calculated according to the testimony of the first seismic receiver, to the spectral power of the parameter of the vertical (deep) component is statistically reliable throughout the recording of the signal rotary field (e2), respectively, calculated in the range from 0 Hz to 7 Hz according to the testimony of the second seismic receiver is greater than 3, then they make a judgment on the location of the first seismic receiver over the gas-saturated field HAND. 2. The method of searching and exploration of hydrocarbon deposits, which consists in placing three-component seismic receivers at the points of observation of seismic vibrations, recording the earth's seismic noise containing an information signal from a hydrocarbon field, analyzing information signals with a judgment on the presence or absence of hydrocarbons, characterized in that conduct additional generation of seismic vibrations by a seismic vibrator, periodically generating oscillations for 30-40 seconds with a pause of 2 0-30 seconds, three-component seismic receivers are placed at a distance from 100 meters to 10,000 meters relative to each other, information signals are recorded and recorded from at least two three-component seismic receivers of the low-frequency range with synchronous acquisition of information signals from three channels in three components ( x, y, z) in the frequency range from 0 Hz to 50 Hz, according to the measured components (x, y, z) for a period of time sufficient to record a statistically significant noise signal in the low-frequency range zone, vector characteristics of the measured vibration fields are calculated: divergence, rotor and vector product of the horizontal components of the received information signals, a judgment on the presence of hydrocarbon deposits is made if the correlation dimension of the initial velocity vector field (F) in the Earth's seismic noise registration mode is greater than the correlation dimension of the initial velocity vector field (F) in the mode of recording information signals using periodic oscillations of the seismic vibrator. 3. A method for the search and exploration of hydrocarbon deposits according to claim 2, characterized in that the judgment on the presence of hydrocarbon deposits is made if the source vector field of velocities (F) has an attractor of correlation dimension more than 10 in the registration mode of the earth's seismic background and the source vector field speeds (F) of the attractor of correlation dimension from 2 to 6 in the mode of recording information signals using periodic oscillations of the seismic vibrator. 4. The method of search and exploration of hydrocarbon deposits, which consists in placing three-component seismic receivers at points of observation of seismic vibrations, recording earth's seismic noise containing an information signal from a hydrocarbon field, analyzing information signals with a judgment on the presence or absence of hydrocarbons, characterized in that conduct additional generation of seismic vibrations by a seismic vibrator, periodically generating oscillations for 30-40 seconds with a pause of 2 0-30 seconds, three-component seismic receivers are placed at a distance from 100 meters to 10,000 meters relative to each other, register and record information signals from at least two three-component seismic receivers of the low-frequency range with synchronous acquisition of information signals from three channels in three components ( x, y, z) in the frequency range from 0 Hz to 50 Hz, according to the measured components (x, y, z) for a period of time sufficient to record a statistically significant noise signal in the low-frequency range On the other hand, vector characteristics of the measured oscillation fields are calculated: divergence, rotor and vector product of the horizontal components of the received information signals, a judgment on the presence of hydrocarbon deposits is made if the correlation dimension of the rotor of the initial field (E) in the Earth's seismic noise registration mode is greater than the correlation dimension of the rotor of the original field (E) in the mode of recording information signals using periodic oscillations of the seismic vibrator. 5. The method for the search and exploration of hydrocarbon deposits according to claim 4, characterized in that the judgment on the presence of hydrocarbon deposits is made when the rotor has an initial field (E) of an attractor with a correlation dimension of more than 10 in the registration mode of the Earth's seismic background and the presence of an attractor at the rotor of the initial field (E) correlation dimension from 2 to 6 in the mode of recording information signals using periodic oscillations of the seismic vibrator.