RU2527322C1 - Method for geophysical exploration of hydrocarbon deposits - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: method for geophysical exploration of hydrocarbon deposits includes exciting elastic vibrations during repeated excitation of an electromagnetic field; measuring the electromagnetic field at multiple points in the vicinity of an electromagnetic field source before, during and after elastic excitation; using the obtained data to construct a series of geoelectric sections reflecting the relaxation of resistivity caused by elastic action; using the data to construct a 3D image of a prospecting area, while selecting anomalous zones with resistance relaxation in the section; determining presence and properties of hydrocarbon deposits from the value of the anomalous effect and nature of said relaxation.

EFFECT: high accuracy of exploration data.

7 dwg

Description

The invention relates to the field of geophysical exploration of mineral deposits and can be used, in particular, for the detection of hydrocarbon deposits.

A known method of geophysical exploration of hydrocarbon deposits, including the excitation of elastic (seismic) vibrations by a seismic source, registration of seismic vibrations by seismic receivers, the movement of seismic sources along the profile in the intervals between the excitation of seismic vibrations and the excitation of the electric field in the profile zone simultaneously with the excitation of seismic vibrations (RF patent No. 2260822, RF patent No. 2260822, 11/00). The electric field is excited by at least two electrodes located along the profile at a distance from each other, commensurate with the depth of the proposed hydrocarbon deposits, seismic vibrations are recorded at each fixed position of the vibration sources and geophones at least once applying electric current to the supply electrodes and at least once in the absence of electric power to the electrodes. Next, the difference between the seismic records obtained by excitation of the electric field and without excitation of the electric field, or seismic sections obtained from the records by converting them into an image of a seismic section are formed. By the change in the amplitudes of the reflected waves of the seismic and seismoelectric fields, as well as by their difference, the presence of anomalous phenomena due to the presence of a hydrocarbon deposit is judged.

In addition, according to this method, additionally simultaneously with seismic vibrations are recorded using loops or measuring dipoles located along the profile with a step commensurate with the step between the geophones, the magnitude of the electric field is calculated, changes in amplitude characteristics are taken into account when making judgments about the presence of anomalous phenomena, due to the presence of hydrocarbon deposits. The disadvantages of this method include the fact that it is based on the study of the electro-seismic effect, that is, the method is based on the seismic exploration method, which does not always allow localizing the source of anomalies (deposits) in a complex environment with carbonate reservoirs.

There is also known a method of geophysical exploration (RF patent No. 2111980, G01V 11/00, prototype), characterized by conducting electrical exploration and seismic exploration (that is, the excitation of elastic waves and electromagnetic fields and measuring the corresponding responses) on the combined profiles by continuous profiling using sources of electric field and interference sources of elastic vibrations. When implementing the method, a system for initiating and controlling mechanoelectric processes in a heterogeneous geological environment is formed by simultaneously influencing the indicated medium by electric field sources and sources of elastic waves with an intensity exceeding the natural noise background. To this end, before observing from profiles in different parts of the area, experimentally determine the optimal parameters of the initiation system, in which mechanoelectric processes have the maximum intensity and reliability of the separation of electrical and elastic signals, determine the schedule of the process of relaxation of the medium in time after simultaneously switching off the sources of the initiation system. According to the laws of change in the intensity of initiation of the electric field, the value of the total relaxation time t _{rel is determined} to make observations by electrical exploration and seismic exploration. In this case, the differences between the values of the electric field initiated by mechanoelectric processes recorded at the time the sources in the system were turned off and corresponding to the extremum of the graph, and the values of the total relaxation time t _rel of observing seismic and electrical explorations should not exceed the specified measurement accuracy. Then, the optimal parameters of the sources are determined for carrying out observations by electrical exploration and seismic exploration with initiated mechanoelectric processes, and observations are made on profiles by acting on the medium with an initiating system. At the end of the initiation cycle, the sources of electric and elastic fields are simultaneously switched off on the same profile interval placed symmetrically with respect to the center within the initiation limits. The observations are sequentially carried out by electrical exploration and then by seismic exploration, while the total observation time does not exceed the relaxation time t _rel , determined by the schedule of the relaxation of the medium, after the completion of observations by seismic exploration, the initiation system is moved to the length of the observation interval by electrical exploration and seismic exploration and the observation cycle is repeated.

The disadvantage of this method is the high cost of work requiring the use of two methods: seismic and electrical exploration, the complexity of the implementation, as well as insufficient accuracy of interpretation in the presence of a complex built medium and carbonate reservoirs. In this case, the seismic data may be unreliable, and the profile data of electrical exploration during electrical excitation is insufficient to determine the parameters of a complexly constructed medium.

The objective of the invention is to increase the efficiency of prospecting in complexly constructed environments, including fractured carbonate reservoirs.

The technical result obtained by the implementation of the proposed method consists in creating a new technology of seismoelectric works, based on the use of areal multi-sensing soundings by the formation of the field and detailed monitoring of the relaxation of the resistivity of the section during seismoelectric works.

The specified technical result is achieved by the fact that in the method of geophysical exploration of hydrocarbon deposits, including exposure to the medium under study by the source of the electromagnetic field and the source of elastic vibrations, registration of the electromagnetic field, moving the source of the electromagnetic field over the studied area, the allocation of the seismoelectric effect at each position of the source of the electromagnetic field, according to the invention, the excitation of elastic vibrations is carried out in the process of repeated excitation of an electromag total field, and electromagnetic field measurements are carried out at many points in the vicinity of the source of the electromagnetic field before, during and after the elastic effect, the sequence of geoelectric sections is constructed from the totality of the data obtained, which reflect the relaxation of electrical resistivity due to the elastic effect, according to the combined data, 3D display of the search site, with the allocation of anomalous zones in the section with relaxation of resistance, and the magnitude of the anomalous effect and the nature This relaxation is judged by the presence and properties of hydrocarbon deposits.

Figure 1 shows the schemes for conducting multi-sensing soundings, a - by area, b - by profile with cuts, where 1 is the generator loop, 2 is the electromagnetic field sensors, 3 is the common measurement point for the two positions of the generator loop 1, 4 is the source of elastic exposure.

Figure 2 illustrates the manifestation of a seismoelectric effect of the first kind: a - on a sample of a fractured carbonate reservoir, b - on a sample that does not have fracture (Yurubchen).

Figure 3 shows graphs illustrating the process of relaxation of resistivity under the influence of elastic effects on various core samples of carbonate rocks extracted from the same area.

Figure 4 shows the results of assessing the convergence of the model problem of generating a forecast parameter for determining the fracture of samples from the relaxation curves of resistivity (Fig. 4a) in comparison with a similar estimate of convergence in amplitude of the seismoelectric effect (Fig. 4b).

Figure 5 shows a model section with an inhomogeneous VChR characteristic of Eastern Siberia.

Figure 6 shows the results of the isolation in the model section (figure 5) of anomalous objects with relaxation of resistivity on the model area under standard profile observations and 1D interpretation of the data (similar to the prototype).

Fig 7 - the same, according to the invention, with areal multidimensional observations and 3D data interpretation.

Below are the prerequisites for creating a method according to the invention.

According to the results of numerous experimental studies, the seismoelectric activity of both rock samples and individual zones in areas of known hydrocarbon deposits is known. It was found that the manifestation of the seismoelectric effect of the first kind (change and relaxation of the electrical resistance of rocks under the influence of elastic impact) is associated with the presence of microcracks. That is, the effect is actively manifested in fractured, in particular, carbonate reservoirs, and is very weakly noted in rocks that do not have fractures. An example of measuring such an effect for such cases is shown in FIG. On figa shows the change in the resistance of the sample of carbonate rocks before, during and after the elastic impact. It is seen that the resistance of the sample decreased by more than two times. On a rock sample that does not have fractures, the relaxation of resistance of which is shown in Fig.2b, a seismoelectric effect is practically not observed. The observed change in resistance (less than 2%) is associated with the natural drying of the sample. In this case, the effect was measured for various mutually perpendicular directions of the acoustic field (curves 1 and 2, Fig.2b).

In addition, the duration and amplitude of the process of resistance relaxation over time depends on a number of factors and can vary significantly even within the same area, as shown in Fig. 3, where the processes of relaxation of resistance of various samples of carbonate rocks extracted in one area are displayed. It can be seen from the curves that the amplitudes of the change in resistance as a result of acoustic exposure differ by an order of magnitude. The same can be said about the duration of the relaxation process. This indicates the difficulty of determining the parameters of the measurement of the seismoelectric effect over the entire area according to the results of individual experiments, as this, in particular, is proposed in the prototype.

The authors also found that the nature of the relaxation of resistance under the influence of elastic influence is described by the function exp ( a t ^β ), where a - determines the relaxation rate and actually the magnitude of the seismoelectric effect, and β - characterizes the structure of the collector. That is, the measurement of the resistance relaxation process will allow us to solve the problem of not only the presence of the collector, but also the determination of its structural characteristics.

Figure 4 shows the results of a study of the convergence of the process of formation of the forecast parameter for determining the fracture of the sample.

By the forecast parameter, we understand the mathematical combination of the values of the measured data, which allows predicting the real petrophysical characteristics of the geological environment. Or in other words - the establishment of some correlation between such a combination and the corresponding petrophysical characteristic.

As a result of the simulation, it was shown that if relaxation curves are used as the initial data for the formation of the forecast parameter, the process of forming the forecast parameter converges quickly enough and the deviation of the obtained parameter values from the studied petrophysical characteristic does not exceed 5% (Fig. 4a). If, however, only the amplitude of the seismoelectric effect is used as the initial data, then convergence is practically not observed (Fig. 4b).

Thus, in addition to measuring the maximum magnitude of the seismoelectric effect (the difference in the amplitudes of the electric field before and after the action of elastic influence), it is of great interest to study the parameters of the process of relaxation of the medium’s resistance itself, whose characteristics are closely related to the structure of the medium. This requires detailed monitoring of the resistivity of the section during seismoelectric work.

The implementation of this monitoring is the essence of this technical solution.

The method according to the invention is implemented in the following sequence of operations.

At the site of work, a system of areal observations is located. Such a system can be implemented in various modifications (Fig. 1) as an areal system that covers the entire area with equal steps (Fig. 1a), and a profile system with cuts (Fig. 1b). At each location of the generator loop 1, the side of which is determined by the depth of research, multiple soundings are carried out by the method of multi-sensing sounding by field formation (MSSB).

In the process of performing such soundings in the center of the generator loop 1 or at a point located in the immediate vicinity of the generator loop 1, an elastic field is additionally excited using an elastic source 4, for example, using a vibrator, in a mode that minimizes the effect of the vibration source 4 itself on electromagnetic field of the generator loop 1.

Sensors 2 of the electromagnetic field fix the electromagnetic response at a variety of points, for example, located along the profile with cuts (Fig. 1b), at distances up to two sizes of the generator loop 1 before, during and after the elastic action.

At the end of the process of multiple soundings, the duration of which is determined by a priori information or the work schedule, the generator loop 1 and the source 4 of elastic impact move to the next point and the measurement process is repeated. The distance between adjacent points of the generator loop 1 is determined by the depth of sounding and the complexity of the section, general information about which, as a rule, is known.

As a hardware complex for the implementation of the MZSB, multichannel telemetry equipment "Impulse-D" can be used, which allows for areal work with remote sensors.

It is advisable to use hydraulic seismic vibrators as a source of seismic vibrations, since they allow you to control the spectrum of generated seismic vibrations. Work is carried out in a mode, for example, with non-linear sweeps in the frequency band of 10-100 Hz and a duration of about 30 s with ground forces in the range of 100-200 kN. You can use other vibration sources with characteristics other than those listed above. The use of explosive technologies, as a rule, does not allow to achieve the optimal effect.

The set of data obtained during the work on the technology according to the invention on the site allows not only to detect the seismoelectric effect, but also, thanks to the areal observation system and 3D interpretation, to fix in the section a specific object characterized by a certain relaxation of resistivity.

Pre-processing of data consists in isolating the seismoelectric effect at each position of the generator loop 1.

Detailed processing involves a 3D interpretation of all the data obtained in the study area and the isolation of local objects with a relaxation of resistivity, as well as a study of the nature of this relaxation, the parameters of which are associated with the lithology of the medium. Based on the totality of the information received, the presence of hydrocarbon deposits is judged.

The following is a model example of the implementation of the method.

A model of a medium with a non-uniform high-frequency response typical of Eastern Siberia is considered, which significantly complicates seismic operations (Fig. 5). At a depth of eight hundred meters, there is a target horizon in which there is a carbonate reservoir with parameters typical of carbonate rocks identified by the authors during petrophysical studies and physical modeling. During the simulation, it was found that in most samples of fractured carbonate rocks, the seismoelectric effect exceeds 20%. This value was the basis of the calculations. Modeling of measurements was carried out according to the scheme shown in figb.

6, 7 show the results of the selection (according to the measured electromagnetic field) at various stages of monitoring abnormal objects, fixed in the section during the relaxation of resistance due to elastic action.

In this case, Fig. 6 shows the results of the isolation of anomalous objects at times when the collector resistivity changed by 5, 10 and 20 percent with standard profile observations, and Fig. 7 shows the results of 3D interpretation of the measurement data at the same stages of monitoring at observations according to the invention.

It can be seen from the comparison that, according to the results of profile observations and 1D inversion, the relaxing object (collector) is restored with sufficiently significant differences in depth, geometry and resistance. The initial object is located at a depth of 800-1000 m, according to 1D inversion, the conducting zone rises to a depth of 700 m and is strongly stretched along the profile (Figs. 6a, 6c). According to the results of 3D interpretation (Fig. 7), the depth and geometry of the zone of resistance change are clearly determined, allowing not only to fix an object with anomalous mechanoelectric properties, but also to localize it in a section, determining the real changes in its resistance as a result of elastic action.

The resulting objects can be further rejected due to differences in the nature of relaxation processes. Such differences due to lithological features of the environment are clearly visible in figure 3. Moreover, as can be seen from figure 4, monitoring the process of relaxation of resistivity allows not only to fix these differences, but also to establish correlation between the relaxation parameters and the petrophysical characteristics of the reservoir, which together with information on the real resistance of the reservoir allows us to judge its possible oil saturation .

Thus, the application of the proposed method, which includes a set of essential features, according to the claims allows to increase the reliability and efficiency of forecasting hydrocarbon deposits in complex carbonate rocks.

Claims (1)

The method of geophysical exploration of hydrocarbon deposits, including exposure to the medium under study by the source of the electromagnetic field and the source of elastic vibrations, registration of the electromagnetic field, moving the source of the electromagnetic field over the studied area, the allocation of the seismoelectric effect at each position of the source of the electromagnetic field, characterized in that the excitation of elastic vibrations is carried out in the process of repeated excitation of the electromagnetic field, and the measurement of the electromagnetic field is carried out They are used in a number of points in the vicinity of the source of the electromagnetic field before, during and after the elastic impact. Based on the totality of the data obtained, a sequence of geoelectrical sections is constructed, which reflect the relaxation of electrical resistivity due to the elastic effect. Based on the combined data, a 3D display of the survey area is constructed, with highlighting. in the context of anomalous zones with relaxation of resistance, the presence and properties of the halls are judged by the magnitude of the anomalous effect and the nature of this relaxation hydrocarbons ments.

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