RU2181492C2 - Method of vibration seismic prospecting and source of seismic vibrations for its realization - Google Patents

Abstract

FIELD: seismology. SUBSTANCE: given method can be used for geophysical investigations and allows presence of hydrocarbon fields on deflecting level to be effectively registered . Vibration signals with various similar frequencies are simultaneously generated into geological medium. One of signals is monofrequency signal and frequency of one or more other signals is changed smoothly. Reflected signals are received, waves with combination ( summary or difference ) frequencies are isolated and used to evaluate nonlinearity of medium. Parameters of correlation signal are chosen from condition of isolation of wave with combination frequencies. Source of seismic vibrations has two or more radiation plates as minimum. Vibration exciter is attached to frame on which plate with rod of vibration exciter being passed through is also fixed. One of radiation plates is hinged to rod and the rest are hinge-jointed to proper column jointed to plate. EFFECT: simplified design of source, enhanced efficiency of method and guaranteed kinematic independence of plates. 5 cl, 2 dwg

Description

 The group of inventions relates to seismology and can be used for geophysical surveys.

 Vibrational seismic exploration is a method of generating waves in which the loads transferred to the medium are harmonic or quasi-harmonic (Vibrational seismic exploration, edited by MB Schneerson, M., Nedra, 1990).

 Based on the classical concepts, it is argued that the processes of excitations and wave propagation in real media are linear. The theory and practice of seismic exploration as a whole and its vibrational modification show that, in general, this thesis is justified, however, recent studies show that in real media along with linear non-linear components of wave fields appear.

 As laboratory and field studies have shown, physical non-linearity is associated with the very characteristics of the rocks. These include heterogeneity, fracturing, porosity and other structural defects of various scale levels. Fracturing most significantly affects nonlinear properties, since cracks open most easily, therefore, the elastic expansion modulus is smaller than the compression modulus - as the cracks close, the latter tends to the modulus of a continuous medium.

 Two-and three-phase media possess strong nonlinear properties: collector-fluid, collector-fluid-gas. The role of gas bubbles is special: they impart extremely high non-linearity to liquids, just as non-linearity to a solid indicates fracturing. It follows that oil and gas fields should have stronger nonlinear properties than their host environment (Problems of nonlinear seismic, Academy of Sciences of the USSR, Institute of Physics of the Earth, ed.: Doctor of Physics and Mathematics A.V. Nikolaev , Ph.D. I.N. Galkin, M., "Science", 1987, p. 12-13).

 A large number of methods of vibroseismic exploration are known, which consist in creating and receiving oscillations with their subsequent processing, see, for example, the seismic exploration method (RF patent 1721562 A1, publ. 23.03.92, BI 11), which provides only monochromatic excitation of oscillations , i.e. does not allow to identify nonlinear phenomena of the geological environment.

 Closest to the proposed method is a vibration reconnaissance method, which consists in generating vibration signals with different initial mono frequencies in the geological environment and emitting signals with combination (difference) frequencies (SU 1408397, G 01 V 1/00, 1988).

 This method allows you to detect areas of the geological environment with non-linear properties and make a conclusion about the presence of hydrocarbon deposits.

 However, this method is not effective enough when conducting reconnaissance using the method of reflected waves.

 The technical result of the invention is to increase the efficiency and resolution of reconnaissance by providing the ability to effectively use the correlation processing of vibrograms.

 A known source of seismic vibrations (RF patent 2094827, class G 01 V 1/147, 1997) containing two emitting plates pivotally connected to one of the plates by one end of the rack, a pathogen, a movable rod of which is connected to the second end of the rack, a device for changes in the angle of inclination of the rack relative to the pathogen and the lock of its position. The invention also provides various types of communication of the additional plate with the rod of the exciter and the radiating plate to control the parameters of seismic pulses.

 The disadvantage of this technical solution is that the radiating plates are kinematically connected to each other. This leads to the complexity of the design and the inability to actuate each plate separately.

 The technical result of the proposed device is to simplify the design of the source of seismic vibrations and ensure the kinematic independence of the radiating plates.

 The technical result is achieved by the fact that in the method of vibrational seismic exploration, which consists in generating signals in the geological environment, one of which is mono-frequency, receiving signals and emitting waves with combination frequencies, according to the invention, the other or other generated signals are signals with a varying frequency, reflected signals are used as received signals and correlated with at least one signal, the parameters of which are selected from the condition of wave allocation with combination frequencies ami.

 The technical result is also achieved by the fact that the source of seismic vibrations for vibrational seismic exploration, containing at least two emitting plates associated with a vibration exciter fixed to the frame, is equipped with a plate fixed to the frame through which the rod of the vibration exciter is passed, one of which emits plates pivotally connected to the specified rod, and each of the other radiating plates pivotally connected to the rack, pivotally mounted on the plate. The plate can be mounted on the frame with the ability to move along the rod of the exciter. Each rack can be made of variable length, and other radiating plates should be placed around one radiating plate.

For a better understanding of the proposal, a variant of its specific implementation is given with links to the accompanying drawings, on which:
figure 1 - structural diagram of the proposed device;
figure 2 is a view along aa (see figure 1).

 The proposed source of seismic vibrations contains a rigid movable rod 1 of the exciter, with a hinged end 2 of which is connected to the central radiating plate 3. At the same time, an intermediate plate 4 is installed on the chassis of the source of seismic vibrations, through which a rigid movable rod 1 of the activator passes. On the outer ring 5 of the intermediate plate 4, brackets 6 are mounted for attaching the uprights 7, which, in turn, are pivotally connected to additional radiating plates 8. In addition, the intermediate plate 4 has the ability to move along the vertical axis.

 Each rack 7 is made of variable length.

 For compactness, the radiating plates 8 are located around the central plate 3.

 The method of vibrational seismic as follows.

The initial monofrequency f _{1 is} supplied to the central radiating plate 3, and a smoothly changing frequency f ₂ or frequencies f ₂ , f ₃ , etc., is supplied to the additional (or additional) plate 8.

 To use the nonlinear phenomena of the geological environment in vibrational seismic exploration, the proposed method is based on the principle of interaction of wave fields, which leads to the formation of waves with combination frequencies.

It is based on the following provisions:
- a geological environment that does not contain a hydrocarbon component is more or less homogeneous and, as a result, its nonlinear properties are not large;
- the geological environment containing hydrocarbon raw materials is characterized by significant non-linear properties.

 When harmonic (quasiharmonic) oscillations are reflected from the reflecting horizon, which limits the nonlinearity region, waves interact, resulting in the formation of combination waves (with total or difference frequencies), which can easily be distinguished by correlating field vibration records (vibrograms) with the signal, parameters which is specially chosen for the detection of waves with Raman frequencies.

 The reconnaissance method provides for work with two (or more) simultaneously generated waves of different frequencies: one or more signals with a smoothly changing frequency (sweep signal), and the other with a monofrequency.

The frequency range of the sweep signal is selected based on experience in the study area. Mono signal parameters are selected based on the following conditions:
- the frequency of the mono signal should be less than the minimum frequency of the sweep signal in order to avoid the appearance of a signal with a negative frequency;
- the difference frequencies of the sweep signal and the mono signal should be within the frequency range of the recording equipment.

 Vibration is recorded by single geophones or groups of geophones.

 When tracking the reflecting horizon in the zone of a hydrocarbon deposit, reflected waves of combination frequencies will be observed, the selection of which will be carried out by an appropriate selection of signal parameters for correlation of field records.

 Due to the fact that the initial characteristics of the signals sent to the geological environment are known, the selection of signals for correlation is carried out in a known manner, focused on the allocation of waves with difference and with total frequencies.

For example, suppose that a monosignal with a frequency f ₁ = 10 Hz and a duration of 15 s and a sweep signal with an initial frequency f _2H = 20 Hz and a final frequency f _2K = 80 Hz and a duration of 15 s are also generated into the ground. Then the frequencies of the correlation signals will vary from f _3H = 20 ± 10 Hz to f _3K = 80 ± 10 Hz for a duration of 15 s.

 The occurrence of waves with combination frequencies will determine the presence of a hydrocarbon deposit. In this case, when correlating field records, materials suitable for structural constructions will be obtained.

 Using one mono-frequency generated signal and another or another signal with a changing frequency of signals (sweep signals) allows you to receive waves with Raman smoothly changing frequencies. This makes it possible to use the correlation method for processing the received signals, which is very effective in recording sweep signals and provides high resolution.

 The proposed method and device allows you to quickly and reliably register areas of nonlinearity of the medium and determine the presence of hydrocarbon deposits, their depth and boundaries.

Claims (5)

 1. The method of vibrational seismic exploration, which consists in generating signals in the geological environment, one of which is monofrequency, receiving signals and extracting waves with combination frequencies, characterized in that the other or other generated signals are signals with a varying frequency, as received use the reflected signals and correlate with at least one signal, the parameters of which are selected from the condition of the allocation of waves with combination frequencies.  2. A source of seismic vibrations for vibrational seismic exploration, containing at least two emitting plates associated with a vibration exciter fixed to the frame, characterized in that it is equipped with a plate fixed to the frame through which the rod of the vibration exciter is passed, one of which emits plates pivotally connected to the specified rod, and each of the other radiating plates pivotally connected to the rack, pivotally mounted on the plate.  3. The source according to claim 2, characterized in that the plate is mounted on the frame with the possibility of movement along the pathogen stem.  4. The source according to claim 2 or 3, characterized in that each rack is made of variable length.  5. A source according to any one of paragraphs. 2-4, characterized in that these other radiating plates are located around one radiating plate.

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