RU2700009C1 - Seismic survey method - Google Patents

Abstract

FIELD: geophysics.

SUBSTANCE: invention relates to geophysics and can be used in soil geophysics aimed at studying elastic properties of soil and underlying soils. Disclosed is a method of seismic survey, which is based on excitation of seismic vibrations with a vibration source and detection of oscillations by immersible seismic receivers located in the near-surface zone. Difference lies in the fact that it allows studying the elastic properties of the near-surface zone above the maximum depth of immersion of the seismic receiver and below it. This is achieved by detecting oscillations at different depths, starting from the soil layer, during the pile immersion, to the end of which the seismic receiver is attached. Seismogram similar to a seismogram of vertical seismic profiling is formed from seismic records obtained at different depths of the seismic receiver. Seismic receiver is pressed inside the medium by means of a vibration source attached to the upper end of the pile, to the lower end of which a seismic receiver is attached. At each depth of the seismic receiver, oscillations from the vibration source, located at a distance from the pressed pile, which is comparable to the depth of the seismic receiver, are additionally recorded. This allows recording not only longitudinal, but also transverse and exchange waves. In this case, to the end of the pile, a three-component seismometer is attached, and waves of different types are separated in a straight longitudinal wave using its polarization.

EFFECT: high information value of the obtained data owing to recording seismic vibrations at different depths located between the earth's surface and the maximum depth of the seismic receiver immersion.

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Description

The invention relates to surface and downhole seismic exploration, and can also be used in soil geophysics, aimed at studying the elastic properties of soils and underlying soils.

The installation of seismic receivers on or near the earth's surface, within the soil layer, inevitably leads to a decrease in the resolution of seismic exploration due to superimposed microseismic records on the seismic record, as well as low-frequency oscillations arising at the contact of the seismic receiver with a loose medium. In addition, a strong absorption of informative components of the spectrum of seismic vibrations located in the high-frequency part of the spectrum occurs in the upper loose layer. Theoretical and experimental studies have long established that immersion of geophones below the soil layer provides a higher resonance frequency at the contact with the environment [IP Pasechnik The results of an experimental study of resonance phenomena in the vibrational system soil-seismograph // Bulletin of the USSR Academy of Sciences, ser. geophys., No. 3, 1952.]. From this it followed that the greater the immersion depth of the seismic receiver, the less parasitic low-frequency resonance oscillations appear that impede seismic surveys in a wide frequency range.

There is a known method of seismic exploration, in which, in order to isolate useful waves and suppress interference, the seismic receivers are immersed in the low-speed zone and set them on bedrock [Monastyrev V.K., Bobrovnik II, Konovalov Yu.G., Budnikov A .AND. The method of seismic exploration // USSR Author's Certificate No. 199441, published July 13, 1967, Bull. No. 15.]. In this method, seismic receivers are pressed under loose formations until reliable contact with dense rocks is obtained. Thus, microseisms are weakened and the effect of absorption of seismic waves in loose rocks is reduced.

The main limitation of the known method is the absence of any quantitative information about the elastic properties of the rocks located above the geophone, immersed by pressing into bedrock, and directly below it. This information is important for studying the conditions of excitation of oscillations in seismic exploration using ground-based pulsed and vibrational oscillation sources. Data on seismic velocities in the upper part of the section are necessary for entering static corrections into seismic records. In addition, in soil geophysics, quantitative information about the depth of the soil and its elastic properties is necessary for the implementation of soil mapping.

Closest to the invention in essence and purpose (prototype) is a method of non-explosive excitation of a broadband seismic pulse using a pile source, which can be buried under the zone of low speeds [Chichinin I.S. Pile source of seismic waves // Geophysics, Geophysical Instrumentation, No. 1 (21), 2015]. In this method, the excitation of vibroseismic vibrations is carried out at different points within a given depth interval, and then the obtained records are summarized after converting them into a pulsed form and introducing static shifts into them, compensating for differences in the depths of excitation. Information on the magnitude of the static shift is obtained from the sensor attached to the lower end of the pile, pressed into the medium.

The main disadvantage of this method is the lack of valuable information on the elastic properties of rocks located above and below the depth interval in which the source of vibrations is located. In addition, the excitation of vibrations by means of a pile, in which the lower end (tip) has a diameter larger than the pile itself, does not eliminate spurious oscillations in the form of standing waves excited directly in the pile. Therefore, the sensor located at the tip of the pile will detect, in an undistorted form, mainly a direct wave, and the subsequent part of the recording will be distorted by resonant noise due to poor contact of the pile with the walls of the hole formed when it is pressed into the ground.

The purpose of the invention is the study of the elastic properties of the near-surface zone.

This goal is achieved by the fact that in the method of seismic exploration, which consists in the excitation of seismic vibrations and registration of vibrations by submersible geophones located in the near-surface zone, in the process of immersing the geophones at different immersion depths located between the earth's surface and the maximum depth of immersion, the oscillations are recorded from obtained at different depths of seismic records form a seismogram on which incident and ascending waves are traced, along which m inverse problem solutions determined seismic velocity and position of seismic boundaries. In one of the modifications of the method, the immersed seismic receiver is attached to the lower end of the pile, and a vibration source is attached to its upper part with the possibility of using it both to immerse the pile and to excite seismic vibrations. In another modification of the method, a three-component seismic receiver is attached to the end of the pile, and vibrations are additionally excited by a vibration source located in the near-surface zone at a distance from the pile, commensurate with the depth of the three-component geophone.

Compared with the prototype, the proposed method for seismic exploration in accordance with the invention is characterized by such significant differences:

- expansion of functionality, consisting in obtaining additional quantitative information about the elastic properties of rocks located above the end of the pile, and directly below it;

- the ability to use detailed information about the elastic properties of rocks located in the near-surface zone for introducing static corrections into seismic records, as well as for mapping soils and soils:

- the ability to predict seismic velocities below the maximum depth of immersion of the seismic receiver from reflected waves obtained by additional excitation of oscillations by a source removed from the pile.

The essence of the proposed method is as follows.

The best way to immerse geophones at a given depth is to attach it to the lower end of the pile, which is crushed to the desired depth by acting on its upper end of continuous mechanical vibrations using a special device attached to the upper end of the pile. The excitation of mechanical vibrations is provided in a known manner by means of an electromechanical transducer. If the band of vibrations excited by such a transducer is provided in a sufficiently wide range, then the seismic receiver will record vibrations in the frequency range corresponding to a given range of the reference electrical signal. In vibro-seismic exploration, such a signal is called a sweep signal. The bandwidth of the excited frequencies corresponds to the working frequency band used in engineering seismic exploration in the studied area.

If the seismic signals excited by a sweep signal are sequentially recorded by the seismic receiver located at the end of the immersed pile, then from the records obtained in this way, you can mount a seismogram similar to a seismogram of vertical seismic profiling (VSP) [Shekhtman G.A. Vertical seismic profiling // M .: EAGE Geomodel LLC, 2017. - 284 s]. The subsequent conversion of such a seismogram into a pulsed form can be performed in two ways: 1) by forming a cross-correlation function between the sweep signal and the recorded records (vibrograms); by deconvolving vibrograms using a sweep signal as a reference signal [Shekhtman GA, Kuznetsov VM Deconvolution of VSP vibrograms - an alternative to correlation processing or its help? // Seismic exploration technologies, No. 2, 2005, 80-85].

The seismogram obtained by the described method will contain incident and ascending waves, which can be separated by known methods. The incident waves contain information about the propagation velocities and the depths of the boundaries located above the maximum depth of immersion of the geophone, and the rising waves will contain information about the depths of the boundaries located above the maximum depth of immersion of the geophone and below it. In addition, the ascending reflected waves along with the incident waves contain information about the acoustic stiffness of the rocks (impedance) located below the interval in which vibrations are recorded at different depths. This information can be obtained by known methods by solving the inverse dynamic problem.

The excitation of oscillations in the upper part of the pile containing the seismic receiver at its lower end provides a seismogram characteristic of the longitudinal VSP profile. Moreover, information about the medium under study is limited only by longitudinal waves. To excite transverse and converted waves, it is necessary to excite oscillations by a source located not at the pile, but away from it at a distance commensurate with the depth of the geophones. At the same time, a three-component seismic receiver is attached to the lower end of the immersed pile, which makes it possible to separate the waves in the direction of approach in accordance with their polarization. The use of transverse waves makes it possible to determine their velocities, and for longitudinal waves, a non-longitudinal vertical profile allows, by solving the inverse kinematic problem from the reflected waves, to determine the velocities in the rocks located below the seismic receiver, as well as the position of the seismic boundaries. This information will make it possible to convert the impedances obtained by solving the inverse dynamic problem to the depth scale.

The method is as follows.

In areas where there are no contraindications for driving piles, points are drawn for the location of submersible geophones. A seismic receiver is attached to the lower part of the pile, and a vibration source designed to push in the piles is attached to its upper part. The range of excited frequencies is chosen so that it includes the frequency accepted as optimal when piling in this section. Starting from the moment the piles are submerged inside the medium, with a certain vertical step, seismic vibrations are recorded by a seismic receiver attached to the bottom of the pile. The vertical step is taken, as usual, equal to a quarter of the minimum wavelength of the excited oscillations. From the obtained records, a seismogram is made, which is then converted into a pulsed form by known methods.

At each depth, designed to register vibrations, seismic records are additionally obtained from a vibration source located at a distance from the pressed pile, commensurate with the depth of the seismic receiver. From the records obtained from such a vibration source, seismograms are formed that are similar to seismograms of a non-longitudinal VSP. When registering vibrations with a three-component seismic receiver, the recording components are oriented using direct-wave polarization.

At the stage of processing data on the totality of seismic records obtained at different depths of geophones, pushed by means of a pile into the test medium, by solving the inverse kinematic and inverse dynamic problems, the elastic properties of rocks located above and below the interval for recording seismic vibrations are determined.

Claims (3)

1. The method of seismic exploration, consisting in the excitation of seismic vibrations by a vibration source and registration of vibrations by submersible geophones located in the near-surface zone, characterized in that in order to study the elastic properties of the near-surface zone during immersion of geophones at different immersion depths located between the earth's surface and the maximum depth immersion, carry out registration of vibrations, from the obtained at different depths of seismic records form a seismogram, on which oslezhivayut falling and rising wave, which by solving the inverse problem of determining the seismic velocity and position of seismic boundaries. 2. The seismic exploration method according to claim 1, characterized in that the immersed seismic receiver is attached to the lower end of the pile, and a vibration source is attached to its upper part with the possibility of using it both to immerse the pile and to excite seismic vibrations. 3. The method according to PP. 1 and 2, characterized in that a three-component seismic receiver is attached to the end of the pile and additionally excite vibrations with a vibration source located in the near-surface zone at a distance from the pile, commensurate with the depth of the three-component geophone.