RU2517780C2 - Method for hydrocarbon prospecting on north sea shelf - Google Patents

Abstract

FIELD: physics, navigation.

SUBSTANCE: invention relates to seismic prospecting and can be used to prospect for hydrocarbons under the seabed and ocean floor, including in ice conditions on the North Sea shelf. The method employs zero buoyancy seismic hydroacoustic detection systems which are mounted at the bottom and in the water layer over the surface of the bottom. The seismic hydroacoustic detection systems give full information on the seismic hydroacoustic field at a measurement point. Said systems receive signals for hardware analysis of amplitude spectra of all components of the oscillating speed on three coordinate axes and hydroacoustic pressure, which enables to calculate amplitude spectra, as well as active and reactive components of the power spectrum of said components.

EFFECT: high accuracy of locating hydrocarbon deposits.

2 cl, 7 dwg

Description

The invention relates to the field of seismic exploration and can be used to search for hydrocarbons under the seabed, including in ice conditions on the shelf of the North Seas.

Currently, seismic exploration methods using non-explosive sources of seismic energy are being developed. The development of this method is devoted to the present invention. As sources of seismic energy, seabed oscillations from the influence of natural factors — microseisms — are considered (see Dozorov et al. “On the Relationship between Low-Frequency Noise in the Ocean and Seismic Vibration of the Bottom.” // Oceanology, 1991, Volume 31, No. 3, p. .514-519).

Microseisms at frequencies of 0.3 Hz and below propagate in the form of surface waves over distances of hundreds and thousands of kilometers from their sources. Microseisms occur under the influence of distant earthquakes, due to wind effects on the surface of the ocean and swell, under the direct influence of fluctuations in atmospheric pressure in the vicinity of large atmospheric eddies on the surface of water areas and land, as well as due to the generation of internal gravitational waves in the layers of ocean water, especially in areas with a long shelf.

Among the analogues of the invention is RF patent No. 2434250, “A method for recording seismic signals in the sea during the search for underwater hydrocarbon deposits”, in which, using seismic receivers installed at the bottom of the sea, microseismic waves are recorded and analyzed, and a judgment is made on the presence or absence hydrocarbons are performed for transverse microseismic waves.

The disadvantage of this invention is the lack of information on the hydroacoustic field in a seismic wave, which allows you to tune out interference and highlight a useful signal that carries information about the presence of hydrocarbon deposits.

The closest analogue selected as a prototype is the patent of the Russian Federation No. 2386984, "Method for the search for hydrocarbons."

The essence of the method described in this patent is as follows.

The seismic receivers are located at the bottom of the sea, they perform a spectral-time analysis of the recorded information signals in discrete sections of the sea located at a distance of 50-1000 m from each other, in the frequency range of 0.1-20 Hz for a measurement time of at least 60 minutes, delete the sections with man-made interference. Seismic signals that are uniform in power are analyzed, and the dispersion spectrum of the spectral lines of the power spectra is determined. The presence of hydrocarbon deposits is judged by the increase in the amplitude of the spectral lines in the dispersion spectrum. The daily variations of the microseismic wave field are taken into account using a stationary seismic station.

The disadvantage of this invention is the lack of information about the hydroacoustic field in the seismic wave, which allows you to tune out interference and better identify a useful signal that carries information about the presence of hydrocarbon deposits. At the same time, the seismic station can be sucked into the deep layers of silt, which prevents its rise.

The aim of the invention is to increase the reliability of detection of hydrocarbon deposits while increasing the reliability of the rise of the seismic-hydroacoustic receiving system.

The essence of the claimed invention lies in the fact that they use seismic hydroacoustic receiving systems with zero buoyancy, which are placed not on the bottom, but in the water layer above the bottom surface. Seismic-hydroacoustic receiving systems provide complete information about the seismic-hydroacoustic field at the measurement point. With their help, signals are received for the hardware analysis of the amplitude spectra of all components of the vibrational velocity along the three coordinate axes X, Y, Z and hydroacoustic pressure P, which allows us to calculate the amplitude spectra, as well as the active and reactive components of the power spectrum of these components.

The technical effect is to increase the accuracy of determining the location of hydrocarbon deposits, since during the propagation of a quasi-transverse wave caused by microseisms, the highest signal-to-noise ratios are observed in the water layer near the bottom. Zero buoyancy further increases the signal-to-noise ratio. The introduction of the sonar pressure channel allows you to more reliably determine the useful signal. At the same time, the reliability of picking up receivers from silt in a number of regions of the North Seas is increasing.

This object is achieved by the fact that in the method of searching for hydrocarbons on the shelf of the North Seas, including the registration of seismic waves in the studied area of the shelf, the calculation of spectral-temporal characteristics, the analysis of temporal records of signals and their spectra in each measured area for the presence of seismic interference and the exclusion of these intervals records from further consideration, take into account the daily variations of the microseismic wave field, analyze seismic signals that are uniform in power, determine the specific ktr dispersions of the spectral lines and by increasing the amplitude of the spectral lines in the dispersion spectrum, one judges the presence of hydrocarbon deposits, characterized in that they use seismic-hydroacoustic receiving systems with zero buoyancy and place them in the water layer above the bottom surface, register and analyze the amplitude spectrum of the components of the vibrational velocity along three axes of coordinates and hydroacoustic pressure, while the active and reactive parts of the power spectrum of microseismic waves are isolated and analyzed, along orym then determined vertical sectional structure of the seabed in the test area, the presence of hydrocarbons and the depth.

Zero buoyancy of seismic-hydroacoustic receiving systems in conjunction with underwater vehicles allows you to create underwater vehicles (uninhabited or inhabited) that move in the water column or hover above the bottom, and make measurements in the North Seas under the thickness of ice.

The studies found that the spectral characteristics of the microseismic field are identical both in the soil of the seabed and in the bottom water layer.

Figure 1 shows the spectra of microseismic noise in the frequency range of 0.1-0.4 Hz, recorded when the seismic receiver is located on the shore.

Figure 2 shows the spectra of microseismic noise in the frequency range 0.01-1.0 Hz, recorded when the seismic-hydroacoustic receiving system is located near the bottom under the ice.

Figure 3 shows the spectra of microseismic noise in the frequency range 0.1-0.4 Hz, recorded when the seismic-hydroacoustic receiving system is located near the bottom.

The spectra of the vertical seismic channel are shown in all figures.

The spectra presented were recorded during tests on March 21, 2012 from 13 h 40 min to 13 h 45 min under ice conditions in the Vladimirovskaya bay of Lake Ladoga at a distance of about 0.5 m from the bottom. The spectra practically coincide in figure 1 and figure 3, while in figure 2 the same receiving device located in the bottom layer, when spectral analysis in the frequency range of 0.01-1 Hz, has emissions at frequencies below 0.025 Hz, which are caused by fluctuations in the ice cover.

These results confirm the possibility of seismic exploration for the analysis of microseisms in ice conditions, taking into account the frequency difference of their spectrum from the spectrum of oscillations of the ice cover, and also that seismic exploration by analyzing microseismic vibrations can use seismic technology of the structure of the seabed deposits according to their spectral characteristics recorded in the bottom layer that for a number of areas of the North Seas with silty soil is fundamental to ensure the rise of the receiving system.

We made measurements not only of vibrational velocity, but also of hydroacoustic pressure synchronously with it.

The use of a hydroacoustic pressure receiver in seismic measurements is a new feature of the invention. Also a new feature is the joint recording and analysis of the amplitude spectra of P and V, which we use to obtain power spectra of P ² and V ² .

Below are the results of measurements of signals caused by an industrial explosion in a quarry outside the reservoir, remote from the measurement site by about 60 km. These measurements were performed in the same region of Lake Ladoga in the bottom layer with a depth of 18 m. The frequency range of measurements was selected at 1–10 Hz.

On figa shows the power spectra of the vertical component of the vibrational velocity V _z , and on figb. - hydroacoustic pressure R. On figv - active, and on fig.4g - the reactive part of the mutual power spectrum P and V _z .

The use of the active and reactive parts of the mutual power spectrum P and V _{z is} also a new feature. We will reveal its essential value below. The algorithm and equipment for measuring the mutual spectrum of electrical signals are given in the book: A. Novikov. Correlation measurements in ship acoustics. L., ". Shipbuilding", 1971., on pages 42, 49, 101 and 216. It does not consider seismic measurements. Currently, computer programs are used to build spectra and the mutual spectrum.

Microseismic waves (their spectra are shown in figs. 4a, 4b) are most likely excited by a Rayleigh wave, since with a large distance to the source of the explosion (at a distance of 60 km) all other types of waves in the water layer of low height have already died out. Doubts remain, maybe these microseisms are caused by some kind of near-field interference, for example, from the vibrations of ice or water from swimming near marine (lake) animals, and not by the Rayleigh wave.

It can be seen from FIG. 4c that the active part of the mutual power spectrum is positive. With the polarities of the receivers P and V chosen by us, this indicates the reception of signals from the soil, and not from the surface, that is, from a Rayleigh wave propagating along the bottom surface. Indication of the direction of arrival of the wave (from the bottom) is a new and significant result from the use of the active and reactive parts of the mutual power spectrum P and V _z . Previously, it was not given by seismologists, since this requires the use of a seismic-hydroacoustic station with a vertical channel V _z and channel R.

In addition, a maximum of 2-3 spectral lines are visible in the spectra of FIGS. 4a and 4b. At the same time, in Figs. 4c and 4d, when measuring the mutual power spectrum, 7-8 spectral lines (peaks) are clearly visible, which means that when measuring mutual spectra, the signal-to-noise ratio improves. This also confirms the essentiality of this feature of the application for the invention, corresponding to the purpose of the invention: increasing the reliability of detection of reflective layers. The use, in addition to the vertical channel Z, of the horizontal channels X, Y is necessary for the classification of sound waves of signals and interference.

Next, we consider the construction of vertical sections of the identified reflections.

Consider the spectra in figa and 4b. One can see that in the spectrum of vibrational velocity there are frequencies of 4 Hz and 5.5 Hz, and in the spectrum of seismic-acoustic pressure the frequency is 2.9 Hz. The spectral components of the vibrational velocity at a frequency of 4 Hz (fundamental frequency) and 5.5 Hz are associated with reflection from a more sonic boundary, that is, these are the layers most promising for the detection of hydrocarbons. The reflection at a frequency of 2.9 Hz in the spectrum of acoustic pressure can be considered as reflection from a hard base. Apparently, it serves as the basis for placing on it a sound-soft layer. The study of all other reflections of acoustic pressure from acoustically rigid layers can be discarded, since there are no pairs of sound-soft and sound-hard layers. Thus, the use of a sonar pressure receiver P can improve the reliability of detection of hydrocarbon deposits, as it allows you to separate the reflections of the signals received by the receivers P and V.

Having determined the main frequencies of the spectral components of the vibrational velocity of the microseism fsp and knowing the type of wave - Rayleigh wave, we determine the depth of the reflecting layer at a frequency fsp. First, the wavelength λ is determined by the formula λ = c / fsp, where c is the Rayleigh wave velocity in accordance with the patent [A. Gorbatikov. Patent for invention RU 2271554 C1 dated March 25, 2005: “Method of seismic exploration”] and article [Gorbatikov A.V., Sobisevich A.L., Sobisevich L.E. et al. Deep-seated technology of the Earth's crust using a natural low-frequency microseismic field. "Natural and related technological disasters." Volume 1. "Seismic processes and disasters." Moscow, IPP RAS, 2008]. It is in the first approximation equal to c = 1700-2000 m / s Further, in accordance with the indicated literature, the depth of the reflecting boundary H is determined by the formula: H = 0.5 λ, taking the Rayleigh wave velocity c = 1700 m / s.

Let us calculate for the main frequency of the sound-soft layer 4.3 Hz:

wavelength λ = 1700 / 4.3 = 380 m,

the depth of the sound-soft layer N = 0.5 * 380 m = 190 m.

We will calculate for a frequency of 2.9 Hz the underlying hard layer corresponding to the reflection from the bottom of the acoustic pressure wave P:

wavelength λ = 1700 / 2.9 = 590 m;

the depth of the underlying sound-hard layer Н = 0.5 * 590 m = 295 m.

Thus, a sound-soft layer was found at depths from 190 to 295 m under the shallow coastal part of Lake Ladoga. Since approximately 40 km from the measurement site in Lake Ladoga there are depths of 200 m, it is possible that this is an underground layer of water or an underground lake, from which drinking water from wells at such depths is provided in many places of the Karelian Isthmus. The obtained result confirms the possibility of searching not only oil and gas fields, but also underground water reserves, which are very promising in the zones of fresh water shortage.

Continuing the measurements in the chosen geographical direction until the disappearance of the investigated reflection from this sound-soft layer, we can find the boundary of the disappearance of this layer. Repeating these measurements at parallel courses (at a distance of 0.5 wavelengths at the studied frequency), we find the contours (boundaries) of this layer, presumably containing hydrocarbons or water. A more accurate conclusion about hydrocarbon or water deposits (having a density and sound velocity close to oil) can be made by examining the contours of the entire deposit area and examining scientific assumptions about their nature.

As with the other aforementioned passive methods for studying hydrocarbon deposits, it is recommended that the sound velocity be determined by receivers spaced a long distance, and then the test well is drilled.

Figure 4c (the active part of the mutual spectrum) shows that due to the increase in the signal / noise ratio, a greater number of reflections from the reflecting bottom layers is determined than separately in the spectra P and V. Thanks to this, all the most characteristic reflection frequencies can be determined: 1.2; 1.4; 2.1; 2.9; 3.4; 4.3; 5.6 Hz. Performing calculations for these spectral components of the Rayleigh wave according to the above formula allows us to construct a vertical section of the seabed for all reflecting boundaries N. The calculated depths of the reflecting layers (vertical section) are as follows: 150; 190; 250; 300; 400; 600; 700 m.

The presented method is aimed at increasing the reliability of exploration of hydrocarbon deposits for industrially used methods of the above sources, based on the study of the frequency spectra of microseisms. This confirms the industrial applicability of the invention.

According to paragraph 2 of the claims of the invention, seismic-hydroacoustic receiving systems are placed in a mobile underwater station (uninhabited or inhabited) having zero buoyancy. The use of underwater stations reduces interference from communication cables with the provided vessel, that is, it increases the reliability of measurements. Zero buoyancy ensures the reliability of the lifting station.

The use of at least three seismic-hydroacoustic receiving systems allows one of them to be used for synchronous measurements as a reference station, and the other two as moving stations.

Claims (2)

1. A method of searching for hydrocarbons on the shelf of the North Seas, including the registration of seismic waves in the studied area of the shelf, the calculation of spectral-temporal characteristics, the analysis of time records of signals and their spectra in each measured area for the presence of seismic interference and the exclusion of these recording intervals from further consideration, the daily variations of the microseismic wave field are taken into account, seismic signals with uniform power are analyzed, the dispersion spectrum of the spectral lines is determined, and By calculating the amplitude of the spectral lines in the dispersion spectrum, one judges the presence of a hydrocarbon deposit, characterized in that they use seismic-hydroacoustic receiving systems with zero buoyancy and place them in the water layer above the bottom surface, register and analyze the amplitude spectrum of the components of the vibrational velocity along three coordinate axes and hydroacoustic pressure in this case, the active and reactive parts of the power spectrum of microseismic waves are isolated and analyzed, by which the vertical section is then determined h the structure of the seabed, the presence and depth of hydrocarbons. 2. The method according to claim 1, characterized in that the seismic-hydroacoustic receiving systems are placed in a mobile underwater station (uninhabited or inhabited) having zero buoyancy, using at least three seismic-hydroacoustic receiving systems.

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