SU1628027A1 - Method of seismic prospecting - Google Patents

Abstract

The invention relates to exploration using sources of code pulse type and can be used to distribute oil, mineral deposits and ore fields and engineering seismic studies for the purpose of the invention. Seismic Productivity Performance b w / pomes osledoo tepchostei zad-t t IM1 inteo with m sledka-ri impe v v f i / o olny, olpe oat elnost Hakor x r | e s Gc-ismi1 ect- g, 11 caught by nile Khodnev / pogledo ltegyunsstei derivatives into different blocks when yuminzyuschih 4d etpm Res tgirch | u “l pulsed seismic frame is produced by squeezing i nc-accumulation of seismic signals in the lake, understanding blocks 1z pflly 1 or sl

Description

SUBSTANCE: invention relates to seismic exploration with the use of superficial non-explosive sources of code-pulse action and can be used for prospecting and exploration of gas and ore deposits and in engineering seismic surveys.

The purpose of the invention is the PERGRAPE of the production of labor for reducing the time of registration and processing. 1 physical observations

The drawing shows timing diagrams of sequences

In the drawing, 1 and 2 are indicated — the initial additional sequences of pulsed different polar influences 3

formed according to the law of additional sequences, namely, the polarity of the effects in both sequences t x 1 and 2 satisfies the condition that the numbers of opposite polarities are equal and the numbers of the same number are equal to each in 1 and 2 4 and b sent to the environment first and The second additional sequences FGI-IRR from the following one after the other of the original complementary sequences 1 and 2, b - Mexflv time interval sent by the sequences set not less than the propagation time reflected waves to the most deeply explored reflective

ABOUT

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horizon, 7 - interval between impulse effects, equal to the interval 8 following the original additional sequences 1 and 2, 9 and 10 - sequences formed from the first initial sequence when the sequences are excited by source 1 and 12 - sequences formed from the second initial sequence when exciting sequences source, 13 and AND - sequences used to encode the phase of the original sequence when excited by a source

The method is carried out as follows.

The seismic oscillation source and seismic wave detection system are used. At this synchronization pulses, the seismic source control unit and the registration system are simultaneously triggered by the seismic source control software. 5 | multidirectional impulses At first intervals intervals b, on which excite the first l and second 5 additional sequences of different pulse npravlenn1, set to smaller values of the duration of the investigated part of the response of the medium and the durations of sequences 4 and 5 are set single First and second excited by the second i and 4 and 5 contain odgihm: the number of pulses, and the amplitude 1 of the pulses set equal intervals of 7 tracks The pulses in the sequences are also set to be the same, smaller than the duration of the studied part of the response of the medium. This allows the source of seismic vibrations to excite the maximum energy set time The total number of pulses in two excited sequences is determined by a given excitation energy of seismic oscillations at the physical point of the profile. Having set a specified number of pulses in each excited sequence, they are formed from the initial sequences 1 and 2, and the number of pulses in each of the two source sequences 1 and 2 The number of pulses in the source sequences 1 and 2 is chosen the same and no less than two times less than the number of pulses in each oh from the excited sequences 4 and 5 The optimal number of pulses in each initial sequence is determined based on the volume of the first and second memory blocks and the speed of the seismic signal accumulation operation.

The first and second initial sequences 1 and 2 formed in the excited sequences follow one after the other, that is, the first initial sequence is followed by the second, and the second initial sequence is followed by the first, etc. At the same time, the intervals 8 of spacing of the initial sequences 1 and 2 of multidirectional pulses during the formation of the excited sequences are set equal to the intervals 1 of the succession of pulses in the initial sequences. The initial sequences in the formation of the excited sequences are encoded in phase in accordance with the law of additional sequences. The initial sequences in the first excited sequence of multidirectional pulses are encoded with the first additional sequence 13, and the initial sequences into the second excited sequence with the second additional sequence 14 The phase coding of the initial sequences is performed in the following way . If the source sequence corresponds to a positive impulse of the coding additional sequence, then the original sequence is formed with direct polarity (phase 0), and fi; Ui of the original sequence corresponds to a negative impulse of the coding additional sequence, then the original sequence is formed in the inverse polarity (phase).

The first 4 and second 5 thus generated sequences of multidirectional impulses are sent to a source of seismic vibrations, which transmits them to the test environment. The excited vibrations pass through the medium under investigation and are recorded by the seismic receivers of the recording system. In this case, the recorded seismic signals are accumulated, caused by the excitation of the first source sequence 1 in the first storage unit, and caused by the excitation of the second source sequence 2 - in the second memory block, and the time interval at which the recorded seismic signals are accumulated is not less than the radiation time of the initial sequence and the duration of the studied part of the response of the medium, and the signs of the accumulation of seismic signals are set t according to the law of coding additional sequences 13 and 14.

But when the excitation of the second sequence of multidirectional pulses is completed, the accumulated seismic signals in the first and second storage units are temporarily compressed in a known manner to obtain a resultant pulse seismogram. The resulting impulse seismogram thus obtained does not contain correlation noise.

Such a sequence of excitation, recording, and processing of signals shortens the time required to obtain the final pulsed seismograms, which improves the processing performance of physical points with specialized observations. In order to enable the excitation of pulse sequences of longer duration while maintaining the relative identity of the operation of the sources, each of the original additional sequences 1 and 2 in the sent additional sequences -1 and 5 are triggered by different sources.

Claims (2)

Claim 1. Seismic exploration method, based on the excitation and recording of seismic vibrations to two of the same magnitude and on the duration of additional sequences of oppositely directed actions with equal amplitudes and intervals followed in g .azh; oh sequence, and the number of effects in both additional sequences set equal, and their polarities - satisfying the condition of equality of numbers of opposite polarities products with the same number of impacts in both sequences, the time interval between the sequences is set to not less than the propagation time of the reflected waves to the deepest reflecting horizon, characterized by the fact that, in order to increase productivity, additional sequences are formed from two successive sequences. initial additional sequences of impulse actions with the number of impulse actions in each initial additional n sequences not exceeding half of the impacts in each additional sequence, and with intervals following the initial additional sequences equal to the interval following the impacts, and the accumulation of seismic signals from the effects from the first and second initial additional sequences is done separately, the initial phases of the original additional sequences and signs of their accumulation set in accordance with the order of formation of polarities of impacts in additional x sequences, accumulation time interval seismic signals are set to not less than the sum of the durations of the original; Node more consistently v of the pacnpocioahf time of the reflected e-mails of the most profound spreading of its reflecting horizon, while the resulting seismogram is obtained by temporarily ihati of separately accumulated seismic signals. 2. The method according to claim 1, wherein by the fact that each of the two initial / .executive sequences of impulse effects is excited by different sources.